Table of Contents
*****************

Gforth
1 Goals of Gforth
  1.1 Stability Goals
2 Gforth Environment
  2.1 Invoking Gforth
    2.1.1 Code generation options
    2.1.2 Image-specific options of 'gforth.fi'
  2.2 Leaving Gforth
  2.3 Help on Gforth
  2.4 Command-line editing
  2.5 Environment variables
  2.6 Gforth files
  2.7 Gforth in pipes
  2.8 Startup speed
3 Forth Tutorial
  3.1 Starting Gforth
  3.2 Syntax
  3.3 Crash Course
  3.4 Stack
  3.5 Arithmetics
  3.6 Stack Manipulation
  3.7 Using files for Forth code
  3.8 Comments
  3.9 Colon Definitions
  3.10 Decompilation
  3.11 Stack-Effect Comments
  3.12 Types
  3.13 Factoring
  3.14 Designing the stack effect
  3.15 Local Variables
  3.16 Conditional execution
  3.17 Flags and Comparisons
  3.18 General Loops
  3.19 Counted loops
  3.20 Recursion
  3.21 Leaving definitions or loops
  3.22 Return Stack
  3.23 Memory
  3.24 Characters and Strings
  3.25 Alignment
  3.26 Floating Point
  3.27 Files
    3.27.1 Open file for input
    3.27.2 Create file for output
    3.27.3 Scan file for a particular line
    3.27.4 Copy input to output
    3.27.5 Close files
  3.28 Interpretation and Compilation Semantics and Immediacy
  3.29 Execution Tokens
  3.30 Exceptions
  3.31 Defining Words
  3.32 Arrays and Records
  3.33 'POSTPONE'
  3.34 'Literal'
  3.35 Advanced macros
  3.36 Compilation Tokens
  3.37 Wordlists and Search Order
4 An Introduction to Standard Forth
  4.1 Introducing the Text Interpreter
  4.2 Stacks, postfix notation and parameter passing
  4.3 Your first Forth definition
  4.4 How does that work?
  4.5 Forth is written in Forth
  4.6 Review - elements of a Forth system
  4.7 Where To Go Next
  4.8 Exercises
5 Literals in source code
  5.1 Integer and character literals
  5.2 Floating-point number and complex literals
  5.3 String and environment variable literals
  5.4 Literals for tokens and addresses
  5.5 Disambiguating recognizers
6 Forth Words
  6.1 Notation
  6.2 Case insensitivity
  6.3 Comments
  6.4 Boolean Flags
  6.5 Arithmetic
    6.5.1 Single precision
    6.5.2 Double precision
    6.5.3 Mixed precision
    6.5.4 Integer division
    6.5.5 Two-stage integer division
    6.5.6 Bitwise operations
    6.5.7 Numeric comparison
    6.5.8 Floating Point
  6.6 Floating-point comparisons
  6.7 Stack Manipulation
    6.7.1 Data stack
    6.7.2 Floating point stack
    6.7.3 Return stack
    6.7.4 Locals stack
    6.7.5 Stack pointer manipulation
  6.8 Memory
    6.8.1 Memory model
    6.8.2 Dictionary allocation
    6.8.3 Sections
    6.8.4 Heap allocation
      6.8.4.1 Memory blocks and heap allocation
      6.8.4.2 Growable memory buffers
    6.8.5 Memory Access
    6.8.6 Special Memory Accesses
    6.8.7 Address arithmetic
    6.8.8 Memory Blocks
  6.9 Strings and Characters
    6.9.1 Characters
    6.9.2 String representations
    6.9.3 String and Character literals
    6.9.4 String words
    6.9.5 $tring words
    6.9.6 Counted string words
  6.10 Control Structures
    6.10.1 Selection
    6.10.2 General Loops
    6.10.3 Counted Loops
    6.10.4 General loops with multiple exits
    6.10.5 General control structures with 'case'
    6.10.6 Arbitrary control structures
    6.10.7 Calls and returns
    6.10.8 Exception Handling
  6.11 Defining Words
    6.11.1 'CREATE'
    6.11.2 Variables
    6.11.3 Constants
    6.11.4 Values
    6.11.5 Colon Definitions
    6.11.6 Inline Definitions
    6.11.7 Anonymous Definitions
    6.11.8 Quotations
    6.11.9 Supplying the name of a defined word
    6.11.10 User-defined Defining Words
      6.11.10.1 User-defined defining words with colon definitions
      6.11.10.2 User-defined defining words using 'create'
      6.11.10.3 Applications of 'CREATE..DOES>'
      6.11.10.4 The gory details of 'CREATE..DOES>'
      6.11.10.5 Advanced does> usage example
      6.11.10.6 Words with user-defined 'to' etc.
      6.11.10.7 User-defined 'compile,'
      6.11.10.8 Creating from a prototype
      6.11.10.9 Making a word current
      6.11.10.10 'Const-does>'
    6.11.11 Deferred Words
    6.11.12 Synonyms
  6.12 Structures
    6.12.1 Standard Structures
    6.12.2 Value-Flavoured and Defer-Flavoured Fields
    6.12.3 Structure Extension
    6.12.4 Gforth structs
  6.13 User-defined Stacks
  6.14 Interpretation and Compilation Semantics
    6.14.1 Where are interpretation semantics used?
    6.14.2 Where are compilation semantics used?
    6.14.3 Which semantics do existing words have?
    6.14.4 What semantics do normal definitions have?
    6.14.5 How to define immediate words
    6.14.6 How to define combined words
  6.15 Tokens for Words
    6.15.1 Execution token
    6.15.2 Name token
    6.15.3 Compilation token
  6.16 Compiling words
    6.16.1 Literals
    6.16.2 Macros
  6.17 The Text Interpreter
    6.17.1 Input Sources
    6.17.2 Number Conversion
    6.17.3 Interpret/Compile states
    6.17.4 Interpreter Directives
    6.17.5 Recognizers
      6.17.5.1 Default Recognizers
      6.17.5.2 Recognizer order
      6.17.5.3 Define recognizers with existing translators
      6.17.5.4 Defining translators
      6.17.5.5 Performing translator actions
    6.17.6 Text Interpreter Hooks
  6.18 The Input Stream
  6.19 Word Lists
    6.19.1 Vocabularies
    6.19.2 Why use word lists?
    6.19.3 Word list example
  6.20 Environmental Queries
  6.21 Files
    6.21.1 Forth source files
    6.21.2 General files
    6.21.3 Redirection
    6.21.4 Directories
    6.21.5 Search Paths
      6.21.5.1 Source Search Paths
      6.21.5.2 General Search Paths
  6.22 Blocks
  6.23 Other I/O
    6.23.1 Simple numeric output
    6.23.2 Formatted numeric output
    6.23.3 Floating-point output
    6.23.4 Miscellaneous output
    6.23.5 Displaying characters and strings
    6.23.6 Terminal output
      6.23.6.1 Color output
      6.23.6.2 Color themes
    6.23.7 Single-key input
    6.23.8 Line input and conversion
    6.23.9 Pipes
    6.23.10 Xchars and Unicode
    6.23.11 Internationalization and Localization
    6.23.12 Substitute
    6.23.13 CSV Reader
  6.24 OS command line arguments
  6.25 Locals
    6.25.1 Gforth locals
      6.25.1.1 Locals definitions words
      6.25.1.2 Where are locals visible by name?
      6.25.1.3 How long do locals live?
      6.25.1.4 Locals programming style
      6.25.1.5 Locals implementation
    6.25.2 Standard Forth locals
  6.26 Object-oriented Forth
    6.26.1 Why object-oriented programming?
    6.26.2 Object-Oriented Terminology
    6.26.3 The 'objects.fs' model
      6.26.3.1 Properties of the 'objects.fs' model
      6.26.3.2 Basic 'objects.fs' Usage
      6.26.3.3 The 'object.fs' base class
      6.26.3.4 Creating objects
      6.26.3.5 Object-Oriented Programming Style
      6.26.3.6 Class Binding
      6.26.3.7 Method conveniences
      6.26.3.8 Classes and Scoping
      6.26.3.9 Dividing classes
      6.26.3.10 Object Interfaces
      6.26.3.11 'objects.fs' Implementation
      6.26.3.12 'objects.fs' Glossary
    6.26.4 The 'oof.fs' model
      6.26.4.1 Properties of the 'oof.fs' model
      6.26.4.2 Basic 'oof.fs' Usage
      6.26.4.3 The 'oof.fs' base class
      6.26.4.4 Class Declaration
    6.26.5 The 'mini-oof.fs' model
      6.26.5.1 Basic 'mini-oof.fs' Usage
      6.26.5.2 Mini-OOF Example
      6.26.5.3 'mini-oof.fs' Implementation
    6.26.6 Mini-OOF2
    6.26.7 Comparison with other object models
  6.27 Closures
    6.27.1 How do I read outer locals?
    6.27.2 How do I write outer locals?
  6.28 Regular Expressions
  6.29 Programming Tools
    6.29.1 Locating source code definitions
    6.29.2 Locating uses of a word
    6.29.3 Locating exception source
    6.29.4 Examining compiled code
    6.29.5 Examining data
    6.29.6 Forgetting words
    6.29.7 Debugging
    6.29.8 Assertions
    6.29.9 Singlestep Debugger
    6.29.10 Code Coverage and Execution Frequency
  6.30 Multitasker
    6.30.1 Pthreads
      6.30.1.1 Basic multi-tasking
      6.30.1.2 Task-local data
      6.30.1.3 Semaphores
      6.30.1.4 Hardware operations for multi-tasking
      6.30.1.5 Message queues
    6.30.2 Cilk
  6.31 C Interface
    6.31.1 Calling C functions
    6.31.2 Declaring C Functions
    6.31.3 Calling C function pointers from Forth
    6.31.4 Defining library interfaces
    6.31.5 Declaring OS-level libraries
    6.31.6 Callbacks
    6.31.7 How the C interface works
    6.31.8 Low-Level C Interface Words
    6.31.9 Automated interface generation using SWIG
      6.31.9.1 Basic operation
      6.31.9.2 Detailed operation:
      6.31.9.3 Examples
    6.31.10 Migrating from Gforth 0.7
  6.32 Assembler and Code Words
    6.32.1 Definitions in assembly language
    6.32.2 Common Assembler
    6.32.3 Common Disassembler
    6.32.4 386 Assembler
    6.32.5 AMD64 (x86_64) Assembler
    6.32.6 Alpha Assembler
    6.32.7 MIPS assembler
    6.32.8 PowerPC assembler
    6.32.9 ARM Assembler
    6.32.10 Other assemblers
  6.33 Carnal words
    6.33.1 Header fields
    6.33.2 Header methods
    6.33.3 Threading Words
  6.34 Passing Commands to the Operating System
  6.35 Keeping track of Time
  6.36 Miscellaneous Words
7 Error messages
8 Tools
  8.1 'ans-report.fs': Report the words used, sorted by wordset
    8.1.1 Caveats
  8.2 Stack depth changes during interpretation
9 Standard conformance
  9.1 The Core Words
    9.1.1 Implementation Defined Options
    9.1.2 Ambiguous conditions
    9.1.3 Other system documentation
  9.2 The optional Block word set
    9.2.1 Implementation Defined Options
    9.2.2 Ambiguous conditions
    9.2.3 Other system documentation
  9.3 The optional Double Number word set
    9.3.1 Ambiguous conditions
  9.4 The optional Exception word set
    9.4.1 Implementation Defined Options
  9.5 The optional Facility word set
    9.5.1 Implementation Defined Options
    9.5.2 Ambiguous conditions
  9.6 The optional File-Access word set
    9.6.1 Implementation Defined Options
    9.6.2 Ambiguous conditions
  9.7 The optional Floating-Point word set
    9.7.1 Implementation Defined Options
    9.7.2 Ambiguous conditions
  9.8 The optional Locals word set
    9.8.1 Implementation Defined Options
    9.8.2 Ambiguous conditions
  9.9 The optional Memory-Allocation word set
    9.9.1 Implementation Defined Options
  9.10 The optional Programming-Tools word set
    9.10.1 Implementation Defined Options
    9.10.2 Ambiguous conditions
  9.11 The optional Search-Order word set
    9.11.1 Implementation Defined Options
    9.11.2 Ambiguous conditions
10 Should I use Gforth extensions?
11 Model
12 Integrating Gforth into C programs
  12.1 Types
  12.2 Variables
  12.3 Functions
  12.4 Signals
13 Emacs and Gforth
  13.1 Installing gforth.el
  13.2 Emacs Tags
  13.3 Hilighting
  13.4 Auto-Indentation
  13.5 Blocks Files
14 Image Files
  14.1 Image Licensing Issues
  14.2 Image File Background
  14.3 Non-Relocatable Image Files
  14.4 Data-Relocatable Image Files
  14.5 Fully Relocatable Image Files
    14.5.1 'gforthmi'
    14.5.2 'cross.fs'
  14.6 Stack and Dictionary Sizes
  14.7 Running Image Files
  14.8 Modifying the Startup Sequence
15 Engine
  15.1 Portability
  15.2 Threading
    15.2.1 Scheduling
    15.2.2 Direct or Indirect Threaded?
    15.2.3 Dynamic Superinstructions
    15.2.4 DOES>
  15.3 Primitives
    15.3.1 Automatic Generation
    15.3.2 TOS Optimization
    15.3.3 Produced code
  15.4 Performance
16 Cross Compiler
  16.1 Using the Cross Compiler
  16.2 How the Cross Compiler Works
17 MINOS2, a GUI library
  17.1 MINOS2 object framework
    17.1.1 'actor' methods:
    17.1.2 'widget' methods:
  17.2 MINOS2 tutorial
Appendix A Bugs
Appendix B Authors and Ancestors of Gforth
  B.1 Authors and Contributors
  B.2 Pedigree
Appendix C Other Forth-related information
Appendix D Licenses
  D.1 GNU Free Documentation License
    D.1.1 ADDENDUM: How to use this License for your documents
  D.2 GNU GENERAL PUBLIC LICENSE
Word Index
Concept and Word Index
Gforth
******

This manual is for Gforth (version 0.7.9_20250911, September 11, 2025),
a fast and portable implementation of the Standard Forth language.  It
serves as reference manual, but it also contains an introduction to
Forth and a Forth tutorial.

   Authors: Bernd Paysan, Anton Ertl, Gerald Wodni, Neal Crook, David
Kuehling, Jens Wilke Copyright © 1995, 1996, 1997, 1998, 2000, 2003,
2004, 2005, 2006, 2007, 2008, 2009, 2010, 2011, 2012, 2013, 2014, 2015,
2016, 2017, 2018, 2019, 2020, 2021, 2022, 2023, 2024 Free Software
Foundation, Inc.

     Permission is granted to copy, distribute and/or modify this
     document under the terms of the GNU Free Documentation License,
     Version 1.1 or any later version published by the Free Software
     Foundation; with no Invariant Sections, with the Front-Cover texts
     being "A GNU Manual," and with the Back-Cover Texts as in (a)
     below.  A copy of the license is included in the section entitled
     "GNU Free Documentation License."

     (a) The FSF's Back-Cover Text is: "You have freedom to copy and
     modify this GNU Manual, like GNU software.  Copies published by the
     Free Software Foundation raise funds for GNU development."

1 Goals of Gforth
*****************

The goal of the Gforth Project is to develop a standard model for
Standard Forth.  This can be split into several subgoals:

   * Gforth should conform to the Forth Standard.
   * It should be a model, i.e.  it should define all the
     implementation-dependent things.
   * It should become standard, i.e.  widely accepted and used.  This
     goal is the most difficult one.

   To achieve these goals Gforth should be
   * Similar to previous models (fig-Forth, F83)
   * Powerful.  It should provide for all the things that are considered
     necessary today and even some that are not yet considered
     necessary.
   * Efficient.  It should not get the reputation of being exceptionally
     slow.
   * Free.
   * Available on many machines/easy to port.

   Have we achieved these goals?

   Gforth conforms to the Forth-94 (ANS Forth) and Forth-2012 standards.

   We have changed some of the internal data structures (in particular,
the headers) over time, so Gforth does not provide the stability of
implementation details that we originally aimed for; they were too
constraining for a long-term project like Gforth.  However, we still aim
for a high level of stability.

   Gforth is quite popular and is treated by some like a de-facto
standard.

   It has some similarities to and some differences from previous
models.

   It has powerful features, and the version 1.0 indicates that it can
do everything (and more) that we originally envisioned.  That does not
mean that we will stop development.

   We certainly have achieved and exceeded our execution speed goals
(*note Performance::)(1).

   Gforth is free and available on many platforms.

   ---------- Footnotes ----------

   (1) However, in 1998 the bar was raised when the major commercial
Forth vendors switched to native code compilers.

1.1 Stability Goals
===================

Programs that work on earlier versions of Gforth should also work on
newer versions.  However, there are some caveats:

   Internal data structures (including the representation of code) of
Gforth may change between versions, unless they are documented.

   Moreover, we only feel obliged to keep standard words (i.e., with
standard wordset names) and words documented as stable Gforth extensions
(with wordset name 'gforth' or 'gforth-<version>', *note Notation::).
Other words may be removed in newer releases.

   In particular, you may find a word by using 'locate' or otherwise
inspecting Gforth's source code.  You can see the wordset in a comment
right after the stack-effect comment.  E.g., in

     : execute-parsing ( ... addr u xt -- ... ) \ gforth

   the wordset is 'gforth'.

   If there is no wordset for a word, it is an internal factor and may
be removed in a future version.  If the wordset is
'gforth-experimental', 'gforth-internal', or 'gforth-obsolete', the word
may also be removed in a future version.  In particular,
'gforth-experimental' indicates that this is a supported word that we do
not consider stable yet; 'gforth-obsolete' indicates an intent to remove
the word in the next version; and 'gforth-internal' (or no wordset)
indicates that we may remove the word as soon as we no longer use it in
Gforth.

   If you want to use a particular word that is not marked as stable,
please let us know, and we will consider to add the word as stable word
(or we may suggest an alternative to using this word).

2 Gforth Environment
********************

Note: ultimately, the Gforth man page will be auto-generated from the
material in this chapter.

   For related information about the creation of images see *note Image
Files::.

2.1 Invoking Gforth
===================

Gforth is made up of two parts; an executable "engine" (named 'gforth'
or 'gforth-fast') and an image file.  To start it, you will usually just
say 'gforth' - this automatically loads the default image file
'gforth.fi'.  In many other cases the default Gforth image will be
invoked like this:
     gforth [file | -e forth-code] ...
This interprets the contents of the files and the Forth code in the
order they are given.

   In addition to the 'gforth' engine, there is also an engine called
'gforth-fast', which is faster, but gives less informative error
messages (*note Error messages::) and may catch some errors (in
particular, stack underflows and integer division errors) later or not
at all.  You should use it for debugged, performance-critical programs.

   Moreover, there is an engine called 'gforth-itc', which is useful in
some backwards-compatibility situations (*note Direct or Indirect
Threaded?::).

   In general, the command line looks like this:

     gforth[-fast] [engine options] [image options]

   The engine options must come before the rest of the command line.
They are:

'--image-file file'
'-i file'
     Loads the Forth image file instead of the default 'gforth.fi'
     (*note Image Files::).

'--appl-image file'
     Loads the image file and leaves all further command-line arguments
     to the image (instead of processing them as engine options).  This
     is useful for building executable application images on Unix, built
     with 'gforthmi --application ...'.

'--no-0rc'
     Do not load '~/.config/gforthrc0' nor the file specified by
     'GFORTH_ENV'.

'--path path'
'-p path'
     Uses path for searching the image file and Forth source code files
     instead of the default in the environment variable 'GFORTHPATH' or
     the path specified at installation time and the working directory
     '.' (e.g., '/usr/local/share/gforth/0.2.0:.').  A path is given as
     a list of directories, separated by ':' (previous versions had ';'
     for other OSes, but since Cygwin now only accepts
     '/cygdrive/<letter>', and we dropped support for OS/2 and MS-DOS,
     it is ':' everywhere).

'--dictionary-size size'
'-m size'
     Allocate size space for the Forth dictionary space instead of using
     the default specified in the image (default: 8M). The size
     specification for this and subsequent options consists of an
     integer and a unit (e.g., '1G').  The unit can be one of 'b'
     (bytes), 'e' (element size, in this case Cells), 'k' (kilobytes),
     'M' (Megabytes), 'G' (Gigabytes), and 'T' (Terabytes).  If no unit
     is specified, 'e' is used.

'--data-stack-size size'
'-d size'
     Allocate size space for the data stack instead of using the default
     specified in the image (default: 16K).

'--return-stack-size size'
'-r size'
     Allocate size space for the return stack instead of using the
     default specified in the image (default: 15K).

'--fp-stack-size size'
'-f size'
     Allocate size space for the floating point stack instead of using
     the default specified in the image (default: 15.5K). In this case
     the unit specifier 'e' refers to floating point numbers.

'--locals-stack-size size'
'-l size'
     Allocate size space for the locals stack instead of using the
     default specified in the image (default: 14.5K).

'--map_32bit'
     Allocate the dictionary and some other areas in the lower 2GB of
     the address space, if possible.  The purpose of this option is
     debugging convenience.

'--vm-commit'
     Normally, Gforth tries to start up even if there is not enough
     virtual memory for the dictionary and the stacks (using
     'MAP_NORESERVE' on OSs that support it); so you can ask for a
     really big dictionary and/or stacks, and as long as you don't use
     more virtual memory than is available, everything will be fine (but
     if you use more, processes get killed).  With this option you just
     use the default allocation policy of the OS; for OSs that don't
     overcommit (e.g., Solaris), this means that you cannot and should
     not ask for as big dictionary and stacks, but once Gforth
     successfully starts up, out-of-memory won't kill it.

'--help'
'-h'
     Print a message about the command-line options

'--version'
'-v'
     Print version and exit

'--diag'
'-D'
     Checks for and reports some performance problems.

'--debug'
     Print some information useful for debugging on startup.

'--debug-mcheck'
     Try to find and report erroneous usage of 'allocate', 'free', and
     the C functions 'malloc()', 'free()', etc.

'--offset-image'
     Start the dictionary at a slightly different position than would be
     used otherwise (useful for creating data-relocatable images, *note
     Data-Relocatable Image Files::).

'--no-offset-im'
     Start the dictionary at the normal position.

'--clear-dictionary'
     Initialize all bytes in the dictionary to 0 before loading the
     image (*note Data-Relocatable Image Files::).

'--die-on-signal [number]'
     Normally Gforth handles most signals (e.g., the user interrupt
     SIGINT, or the segmentation violation SIGSEGV) by translating it
     into a Forth 'THROW'.  With this option, Gforth exits if it
     receives such a signal.  This option is useful when the engine
     and/or the image might be severely broken (such that it causes
     another signal before recovering from the first); this option
     avoids endless loops in such cases.  The optional number set the
     number of signals to be handled; only the last one will cause
     Gforth to exit.

'--ignore-async-signals'
     Ignore asynchronous signals (e.g., 'SIGINT' generated with
     'Ctrl-c').

2.1.1 Code generation options
-----------------------------

'--no-dynamic'
'--dynamic'
     Disable or enable dynamic superinstructions with replication (*note
     Dynamic Superinstructions::).  Default enabled.

'--no-dynamic-image'
     Disable dynamic native-code generation when loading the Gforth
     image, but generate dynamic native code afterwards.  This option is
     useful when debugging Gforth's code generator.

'--no-super'
     Disable dynamic superinstructions, use just dynamic replication;
     this is useful if you want to patch threaded code (*note Dynamic
     Superinstructions::).

'--ss-number=N'
     Use only the first N static superinstructions compiled into the
     engine (default: use them all; note that only 'gforth-fast' has
     any).  This option is useful for measuring the performance impact
     of static superinstructions.

'--ss-min-codesize'
'--ss-min-ls'
'--ss-min-lsu'
'--ss-min-nexts'
     Use specified metric for determining the cost of a primitive or
     static superinstruction for static superinstruction selection.
     'Codesize' is the native code size of the primitive or static
     superinstruction, 'ls' is the number of loads and stores, 'lsu' is
     the number of loads, stores, and updates, and 'nexts' is the number
     of dispatches (not taking dynamic superinstructions into account),
     i.e.  every primitive or static superinstruction has cost 1.
     Default: 'codesize' if you use dynamic code generation, otherwise
     'nexts'.

'--ss-greedy'
     This option is useful for measuring the performance impact of
     static superinstructions.  By default, an optimal shortest-path
     algorithm is used for selecting static superinstructions.  With
     '--ss-greedy' this algorithm is modified to assume that anything
     after the static superinstruction currently under consideration is
     not combined into static superinstructions.  With '--ss-min-nexts'
     this produces the same result as a greedy algorithm that always
     selects the longest superinstruction available at the moment.
     E.g., if there are superinstructions AB and BCD, then for the
     sequence A B C D the optimal algorithm will select A BCD and the
     greedy algorithm will select AB C D.

'--opt-ip-updates=n'
     Set the level of IP-update optimization (default: 31 (7+3*8)).  n
     is computed as n1+8*n2.

     n1 indicates the use of IP-update optimization in straight-line
     code: 0 means no IP-update optimization, 1 combines IP-update
     optimizations of primitives without inline arguments, 2 also
     eliminates the dead IP updates of ';s', 'execute-;s' and
     fast-throw, >2 eliminates the IP updates in front of several
     frequently-used primitives with inline arguments.

     n2 is the number of ip-updates that can replace a load in a
     backwards or unconditional branch; for conditional forward branches
     only n2/2 ip-updates replace a load (to avoid too many additional
     updates in the fall-through path).

'--code-block-size=size'
     Size of native-code blocks (default: 2M). Gforth allocates as many
     blocks of this size as necessary.

'--print-metrics'
     On exit from Gforth: Print some metrics used during static
     superinstruction selection: 'code size' is the actual size of the
     dynamically generated code.  'Metric codesize' is the sum of the
     codesize metrics as seen by static superinstruction selection;
     there is a difference from 'code size', because not all primitives
     and static superinstructions are compiled into dynamically
     generated code, and because of markers.  The other metrics
     correspond to the 'ss-min-...' options.  This option is useful for
     evaluating the effects of the '--ss-...' options.

'--print-prims'
     When exiting GforthL: Print the primitives with static usage
     counts.  E.g., one line might look like:

          ?branch           1-1  0   21 1575   73 0x5573e4048c33 len= 4+ 25+ 3 send=0

     The columns are, from left to right: name of the primitive,
     stack-caching state transition (from a state with 1 stack item in a
     register to the same state in the example), IP offset for this
     version of the primitive (0 for most primitives, but, e.g., for
     '?branch' there are also versions with 0-zero offset), index of the
     primitive, index of the corresponding branch-to-IP variant (in case
     of a branch), static number of occurrences of the primitive in the
     loaded/compiled code, address of the code of the primitive (or
     '(nil)' if the primitive is not relocatable), length of the parts
     of this code: ip-update+main+dispatch, and whether the primitive
     ends a superblock (i.e., an unconditional branch or the like).

'--print-nonreloc'
     When starting Gforth: Print the non-relocatable primitives.

'--print-sequences'
     When loading the image: For each superblock in the image, print the
     sequence of primitives.

'--tpa-noautomaton'
'--tpa-noequiv'
     These options are about using an automaton for speeding up startup
     and compilation, in particular the shortest-path algorithm used for
     selecting static superinstructions and stack caching variants; tpa
     stands for for "tree-parsing automaton" (although we only have
     sequences, not trees).  In the 'gforth' engine the default is to
     use an automaton with state equivalence (state equivalence reduces
     the number of states compared to having one state for every
     sequence prefix), which is the fastest option and requires the
     least memory.

     With static superinstructions the automaton does not work
     correctly, so Gforth falls back to '--tpa-noautomaton' in that case
     unless you ask for '--tpa-noequiv' ('gforth-fast' uses static
     superinstructions and therefore '--tpa-noautomaton' by default).

     '--tpa-noequiv' turns off state equivalence, which costs memory and
     compiles a little slower than using an automaton.

     '--tpa-noautomaton' turns off using the automaton.  This consumes
     quite a bit more compile time, and should in theory use less memory
     than using an automaton, but apparently there is a bug in Gforth,
     and it consumes more memory.

     The following shows the startup speed and memory consumption of
     Gforth 0.7.9_20240821 run with 'gforth-fast -e bye' (plus the
     options given in the table) on a Core-i5 6600K (Skylake):

           cycles    instructions KB(RSS) other options
          23_309_239  43_534_167   9228   --ss-number=0
          26_399_456  51_895_687  11316   --ss-number=0 --tpa-noequiv
          40_427_672  93_709_354  10988   --ss-number=0 --tpa-noautomaton
          27_599_969  53_126_621  11320
          27_732_944  53_128_381  11320   --tpa-noequiv
          42_960_520  95_466_840  11044   --tpa-noautomaton

'--tpa-trace'
     This option produces data about the number of states generated
     during startup and compilation.

2.1.2 Image-specific options of 'gforth.fi'
-------------------------------------------

As explained above, the image-specific command-line arguments for the
default image 'gforth.fi' consist of a sequence of filenames and '-e
FORTH-CODE' options that are interpreted in the sequence in which they
are given.  The '-e FORTH-CODE' or '--evaluate FORTH-CODE' option
evaluates the Forth code.  This option takes only one argument; if you
want to evaluate more Forth words, you have to quote them or use '-e'
several times.  To exit after processing the command line (instead of
entering interactive mode) append '-e bye' to the command line.  You can
also process the command-line arguments with a Forth program (*note OS
command line arguments::).  If there is an uncaught exception while
processing image options, Gforth will exit with a non-zero exit code.
This is how you run scripts in Gforth.

   If you have several versions of Gforth installed, 'gforth' will
invoke the version that was installed last.  'gforth-<version>' invokes
a specific version.  If your environment contains the variable
'GFORTHPATH', you may want to override it by using the '--path' option.

   On startup, before processing any of the image options, the user
initialization file is included, if it exists.  The user initialization
file is '~/.config/gforthrc0', or, if the environment variable
'GFORTH_ENV' is set, it contains the name of the user initialization
file.  You can suppress loading this file with by setting 'GFORTH_ENV'
to 'off', or with the option '--no-0rc'.

   After processing all the image options and just before printing the
boot message, the user initialization file '~/.config/gforthrc' from
your home directory is included, unless the option '--no-rc' is given.

   Warning levels can be set with

'-W'
     Turn off warnings

'-Won'
     Turn on warnings (level 1)

'-Wall'
     Turn on beginner warnings (level 2)

'-Wpedantic'
     Turn on pedantic warnings (level 3)

'-Werror'
     Turn warnings into errors (level 4)

2.2 Leaving Gforth
==================

You can leave Gforth by typing 'bye' or 'Ctrl-d' (at the start of a
line) or (if you invoked Gforth with the '--die-on-signal' option)
'Ctrl-c'.  When you leave Gforth, all of your definitions and data are
discarded.  For ways of saving the state of the system before leaving
Gforth see *note Image Files::.

'bye' ( -  ) tools-ext
   Exit Gforth (with exit status 0).

2.3 Help on Gforth
==================

Gforth has a simple, text-based online help system.

'help' ( "rest-of-line" -  ) gforth-1.0
   If no name is given, show basic help.  If a documentation node name
is given followed by "::", show the start of the node.  If the name of a
word is given, show the documentation of the word if it exists, or its
source code if not.  If something else is given that is recognized,
shows help on the recognizer.  You can then use the same keys and
commands as after using 'locate' (*note Locating source code
definitions::).

'authors' ( -  ) gforth-1.0
   show the list of authors

'license' ( -  ) gforth-0.2
   print the license statement

2.4 Command-line editing
========================

Gforth maintains a history file that records every line that you type to
the text interpreter.  This file is preserved between sessions, and is
used to provide a command-line recall facility; if you type 'Ctrl-P'
repeatedly you can recall successively older commands from this (or
previous) session(s).  The full list of command-line editing facilities
is:

   * 'Ctrl-p' ("previous") (or up-arrow) to recall successively older
     lines from the history buffer.
   * 'Ctrl-n' ("next") (or down-arrow) to recall successively newer
     lines from the history buffer.  If you moved to an older line
     earlier and gave it to Gforth for text-interpretation, asking for
     the next line as the first editing command gives you the next line
     after the one you selected last time.
   * 'Ctrl-f' (or right-arrow) to move the cursor right,
     non-destructively.
   * 'Ctrl-b' (or left-arrow) to move the cursor left,
     non-destructively.
   * 'Ctrl-h' (backspace) to delete the character to the left of the
     cursor, closing up the line.
   * 'Ctrl-k' to delete ("kill") from the cursor to the end of the line.
   * 'Ctrl-a' to move the cursor to the start of the line.
   * 'Ctrl-e' to move the cursor to the end of the line.
   * <RET> ('Ctrl-m') or <LFD> ('Ctrl-j') to submit the current line.
   * <TAB> to step through all possible full-word completions of the
     word currently being typed.
   * 'Ctrl-d' on an empty line line to terminate Gforth (gracefully,
     using 'bye').
   * 'Ctrl-x' (or 'Ctrl-d' on a non-empty line) to delete the character
     under the cursor.

   When editing, displayable characters are inserted to the left of the
cursor position; the line is always in "insert" (as opposed to
"overstrike") mode.

   On Unix systems, the history file is
'$HOME/.local/share/gforth/history' by default(1).  You can find out the
name and location of your history file using:

     history-file type \ Unix-class systems

     history-file type \ Other systems
     history-dir  type

   If you enter long definitions by hand, you can use a text editor to
paste them out of the history file into a Forth source file for reuse at
a later time.

   Gforth never trims the size of the history file, so you should do
this periodically, if necessary.

   ---------- Footnotes ----------

   (1) i.e.  it is stored in the user's home directory.

2.5 Environment variables
=========================

Gforth uses these environment variables:

   * 'GFORTHHIST' - (Unix systems only) specifies the path for the
     history file '.gforth-history'.  Default:
     '$HOME/.local/share/gforth/history'.

   * 'GFORTHPATH' - specifies the path used when searching for the
     gforth image file and for Forth source-code files (usually '.', the
     current working directory).  Path separator is ':', a typical path
     would be '/usr/local/share/gforth/1.0:.'.

   * 'LANG' - see 'LC_CTYPE'

   * 'LC_ALL' - see 'LC_CTYPE'

   * 'LC_CTYPE' - If this variable contains "UTF-8" on Gforth startup,
     Gforth uses the UTF-8 encoding for strings internally and expects
     its input and produces its output in UTF-8 encoding, otherwise the
     encoding is 8bit (see *note Xchars and Unicode::).  If this
     environment variable is unset, Gforth looks in 'LC_ALL', and if
     that is unset, in 'LANG'.

   * 'GFORTHSYSTEMPREFIX' - specifies what to prepend to the argument of
     'system' before passing it to C's 'system()'.  Default:
     '"./$COMSPEC /c "' on Windows, '""' on other OSs.  The prefix and
     the command are directly concatenated, so if a space between them
     is necessary, append it to the prefix.

   * 'GFORTH' - used by 'gforthmi', *Note gforthmi::.

   * 'GFORTHD' - used by 'gforthmi', *Note gforthmi::.

   * 'TMP', 'TEMP' - (non-Unix systems only) used as a potential
     location for the history file.

   All the Gforth environment variables default to sensible values if
they are not set.

2.6 Gforth files
================

When you install Gforth on a Unix system, it installs files in these
locations by default:

   * '/usr/local/bin/gforth'
   * '/usr/local/bin/gforthmi'
   * '/usr/local/man/man1/gforth.1' - man page.
   * '/usr/local/info' - the Info version of this manual.
   * '/usr/local/lib/gforth/<version>/...' - Gforth '.fi' files.
   * '/usr/local/share/gforth/<version>/TAGS' - Emacs TAGS file.
   * '/usr/local/share/gforth/<version>/...' - Gforth source files.
   * '.../emacs/site-lisp/gforth.el' - Emacs gforth mode.

   You can select different places for installation by using 'configure'
options (listed with 'configure --help').

2.7 Gforth in pipes
===================

Gforth can be used in pipes created elsewhere (described in the
following).  It can also create pipes on its own (*note Pipes::).

   If you pipe into Gforth, your program should read with 'read-file' or
'read-line' from 'stdin' (*note General files::).  'Key' does not
recognize the end of input.  Words like 'accept' echo the input and are
therefore usually not useful for reading from a pipe.  You have to
invoke the Forth program with an OS command-line option, as you have no
chance to use the Forth command line (the text interpreter would try to
interpret the pipe input).

   You can output to a pipe with 'type', 'emit', 'cr' etc.

   When you write to a pipe that has been closed at the other end,
Gforth receives a SIGPIPE signal ("pipe broken").  Gforth translates
this into the exception 'broken-pipe-error'.  If your application does
not catch that exception, the system catches it and exits, usually
silently (unless you were working on the Forth command line; then it
prints an error message and exits).  This is usually the desired
behaviour.

   If you do not like this behaviour, you have to catch the exception
yourself, and react to it.

   Here's an example of an invocation of Gforth that is usable in a
pipe:

     gforth -e ": foo begin pad dup 10 stdin read-file throw dup while \
      type repeat ; foo bye"

   This example just copies the input verbatim to the output.  A very
simple pipe containing this example looks like this:

     cat startup.fs |
     gforth -e ": foo begin pad dup 80 stdin read-file throw dup while \
      type repeat ; foo bye"|
     head

   Pipes involving Gforth's 'stderr' output do not work.

2.8 Startup speed
=================

If Gforth is used for CGI scripts or in shell scripts, its startup speed
may become a problem.  On a 3GHz Core 2 Duo E8400 under 64-bit Linux
2.6.27.8 with libc-2.7, 'gforth-fast -e bye' takes 13.1ms user and 1.2ms
system time ('gforth -e bye' is faster on startup with about 3.4ms user
time and 1.2ms system time, because it subsumes some of the options
discussed below).

   If startup speed is a problem, you may consider the following ways to
improve it; or you may consider ways to reduce the number of startups
(for example, by using Fast-CGI). Note that the first steps below
improve the startup time at the cost of run-time (including
compile-time), so whether they are profitable depends on the balance of
these times in your application.

   An easy step that influences Gforth startup speed is the use of a
number of options that increase run-time, but decrease image-loading
time.

   The first of these that you should try is '--ss-number=0
--ss-states=1' because this option buys relatively little run-time
speedup and costs quite a bit of time at startup.  'gforth-fast
--ss-number=0 --ss-states=1 -e bye' takes about 2.8ms user and 1.5ms
system time.

   The next option is '--no-dynamic' which has a substantial impact on
run-time (about a factor of 2-4 on several platforms), but still makes
startup speed a little faster: 'gforth-fast --ss-number=0 --ss-states=1
--no-dynamic -e bye' consumes about 2.6ms user and 1.2ms system time.

   If the script you want to execute contains a significant amount of
code, it may be profitable to compile it into the image to avoid the
cost of compiling it at startup time.

3 Forth Tutorial
****************

The difference of this chapter from the Introduction (*note
Introduction::) is that this tutorial is more fast-paced, should be used
while sitting in front of a computer, and covers much more material, but
does not explain how the Forth system works.

   This tutorial can be used with any Standard-compliant Forth; any
Gforth-specific features are marked as such and you can skip them if you
work with another Forth.  This tutorial does not explain all features of
Forth, just enough to get you started and give you some ideas about the
facilities available in Forth.  Read the rest of the manual when you are
through this.

   The intended way to use this tutorial is that you work through it
while sitting in front of the console, take a look at the examples and
predict what they will do, then try them out; if the outcome is not as
expected, find out why (e.g., by trying out variations of the example),
so you understand what's going on.  There are also some assignments that
you should solve.

   This tutorial assumes that you have programmed before and know what,
e.g., a loop is.

3.1 Starting Gforth
===================

You can start Gforth by typing its name:

     gforth

   That puts you into interactive mode; you can leave Gforth by typing
'bye'.  While in Gforth, you can edit the command line and access the
command line history with cursor keys, similar to bash.

3.2 Syntax
==========

A "word" is a sequence of arbitrary characters (except white space).
Words are separated by white space.  E.g., each of the following lines
contains exactly one word:

     word
     !@#$%^&*()
     1234567890
     5!a

   A frequent beginner's error is to leave out necessary white space,
resulting in an error like 'Undefined word'; so if you see such an
error, check if you have put spaces wherever necessary.

     ." hello, world" \ correct
     ."hello, world"  \ gives an "Undefined word" error

   Gforth and most other Forth systems ignore differences in case (they
are case-insensitive), i.e., 'word' is the same as 'Word'.  If your
system is case-sensitive, you may have to type all the examples given
here in upper case.

3.3 Crash Course
================

Forth does not prevent you from shooting yourself in the foot.  Let's
try a few ways to crash Gforth:

     0 0 !
     here execute
     ' catch >body 20 erase abort
     ' (quit1) >body 20 erase

   The last two examples are guaranteed to destroy important parts of
Gforth (and most other systems), so you better leave Gforth afterwards
(if it has not finished by itself).  On some systems you may have to
kill gforth from outside (e.g., in Unix with 'kill').

   You will find out later what these lines do and then you will get an
idea why they produce crashes.

   Now that you know how to produce crashes (and that there's not much
to them), let's learn how to produce meaningful programs.

3.4 Stack
=========

The most obvious feature of Forth is the stack.  When you type in a
number, it is pushed on the stack.  You can display the contents of the
stack with '.s'.

     1 2 .s
     3 .s

   '.s' displays the top-of-stack to the right, i.e., the numbers appear
in '.s' output as they appeared in the input.

   You can print the top element of the stack with '.'.

     1 2 3 . . .

   In general, words consume their stack arguments ('.s' is an
exception).

     Assignment: What does the stack contain after '5 6 7 .'?

3.5 Arithmetics
===============

The words '+', '-', '*', '/', and 'mod' always operate on the top two
stack items:

     2 2 .s
     + .s
     .
     2 1 - .
     7 3 mod .

   The operands of '-', '/', and 'mod' are in the same order as in the
corresponding infix expression (this is generally the case in Forth).

   Parentheses are superfluous (and not available), because the order of
the words unambiguously determines the order of evaluation and the
operands:

     3 4 + 5 * .
     3 4 5 * + .

     Assignment: What are the infix expressions corresponding to the
     Forth code above?  Write '6-7*8+9' in Forth notation(1).

   To change the sign, use 'negate':

     2 negate .

     Assignment: Convert -(-3)*4-5 to Forth.

   '/mod' performs both '/' and 'mod'.

     7 3 /mod . .

   Reference: *note Arithmetic::.

   ---------- Footnotes ----------

   (1) This notation is also known as Postfix or RPN (Reverse Polish
Notation).

3.6 Stack Manipulation
======================

Stack manipulation words rearrange the data on the stack.

     1 .s drop .s
     1 .s dup .s drop drop .s
     1 2 .s over .s drop drop drop
     1 2 .s swap .s drop drop
     1 2 3 .s rot .s drop drop drop

   These are the most important stack manipulation words.  There are
also variants that manipulate twice as many stack items:

     1 2 3 4 .s 2swap .s 2drop 2drop

   Two more stack manipulation words are:

     1 2 .s nip .s drop
     1 2 .s tuck .s 2drop drop

     Assignment: Replace 'nip' and 'tuck' with combinations of other
     stack manipulation words.

          Given:          How do you get:
          1 2 3           3 2 1
          1 2 3           1 2 3 2
          1 2 3           1 2 3 3
          1 2 3           1 3 3
          1 2 3           2 1 3
          1 2 3 4         4 3 2 1
          1 2 3           1 2 3 1 2 3
          1 2 3 4         1 2 3 4 1 2
          1 2 3
          1 2 3           1 2 3 4
          1 2 3           1 3

     5 dup * .

     Assignment: Write 17^3 and 17^4 in Forth, without writing '17' more
     than once.  Write a piece of Forth code that expects two numbers on
     the stack (A and B, with B on top) and computes '(a-b)(a+1)'.

   Reference: *note Stack Manipulation::.

3.7 Using files for Forth code
==============================

While working at the Forth command line is convenient for one-line
examples and short one-off code, you probably want to store your source
code in files for convenient editing and persistence.  You can use your
favourite editor (Gforth includes Emacs support, *note Emacs and
Gforth::) to create FILE.FS and use

     s" FILE.FS" included

   to load it into your Forth system.  The file name extension I use for
Forth files is '.fs'.

   You can easily start Gforth with some files loaded like this:

     gforth FILE1.FS FILE2.FS

   If an error occurs during loading these files, Gforth terminates,
whereas an error during 'INCLUDED' within Gforth usually gives you a
Gforth command line.  Starting the Forth system every time gives you a
clean start every time, without interference from the results of earlier
tries.

   I often put all the tests in a file, then load the code and run the
tests with

     gforth CODE.FS TESTS.FS -e bye

   (often by performing this command with 'C-x C-e' in Emacs).  The '-e
bye' ensures that Gforth terminates afterwards so that I can restart
this command without ado.

   The advantage of this approach is that the tests can be repeated
easily every time the program is changed, making it easy to catch bugs
introduced by the change.

   Reference: *note Forth source files::.

3.8 Comments
============

     \ That's a comment; it ends at the end of the line
     ( Another comment; it ends here: )  .s

   '\' and '(' are ordinary Forth words and therefore have to be
separated with white space from the following text.

     \This gives an "Undefined word" error

   The first ')' ends a comment started with '(', so you cannot nest
'('-comments; and you cannot comment out text containing a ')' with '(
... )'(1).

   I use '\'-comments for descriptive text and for commenting out code
of one or more line; I use '('-comments for describing the stack effect,
the stack contents, or for commenting out sub-line pieces of code.

   The Emacs mode 'gforth.el' (*note Emacs and Gforth::) supports these
uses by commenting out a region with 'C-x \', uncommenting a region with
'C-u C-x \', and filling a '\'-commented region with 'M-q'.

   Reference: *note Comments::.

   ---------- Footnotes ----------

   (1) therefore it's a good idea to avoid ')' in word names.

3.9 Colon Definitions
=====================

are similar to procedures and functions in other programming languages.

     : squared ( n -- n^2 )
        dup * ;
     5 squared .
     7 squared .

   ':' starts the colon definition; its name is 'squared'.  The
following comment describes its stack effect.  The words 'dup *' are not
executed, but compiled into the definition.  ';' ends the colon
definition.

   The newly-defined word can be used like any other word, including
using it in other definitions:

     : cubed ( n -- n^3 )
        dup squared * ;
     -5 cubed .
     : fourth-power ( n -- n^4 )
        squared squared ;
     3 fourth-power .

     Assignment: Write colon definitions for 'nip', 'tuck', 'negate',
     and '/mod' in terms of other Forth words, and check if they work
     (hint: test your tests on the originals first).  Don't let the
     'redefined'-Messages spook you, they are just warnings.

   Reference: *note Colon Definitions::.

3.10 Decompilation
==================

You can decompile colon definitions with 'see':

     see squared
     see cubed

   In Gforth 'see' shows you a reconstruction of the source code from
the executable code.  Informations that were present in the source, but
not in the executable code, are lost (e.g., comments).

   You can also decompile the predefined words:

     see .
     see +

3.11 Stack-Effect Comments
==========================

By convention the comment after the name of a definition describes the
stack effect: The part in front of the '--' describes the state of the
stack before the execution of the definition, i.e., the parameters that
are passed into the colon definition; the part behind the '--' is the
state of the stack after the execution of the definition, i.e., the
results of the definition.  The stack comment only shows the top stack
items that the definition accesses and/or changes.

   You should put a correct stack effect on every definition, even if it
is just '( -- )'.  You should also add some descriptive comment to more
complicated words (I usually do this in the lines following ':').  If
you don't do this, your code becomes unreadable (because you have to
work through every definition before you can understand any).

     Assignment: The stack effect of 'swap' can be written like this:
     'x1 x2 -- x2 x1'.  Describe the stack effect of '-', 'drop', 'dup',
     'over', 'rot', 'nip', and 'tuck'.  Hint: When you are done, you can
     compare your stack effects to those in this manual (*note Word
     Index::).

   Sometimes programmers put comments at various places in colon
definitions that describe the contents of the stack at that place (stack
comments); i.e., they are like the first part of a stack-effect comment.
E.g.,

     : cubed ( n -- n^3 )
        dup squared  ( n n^2 ) * ;

   In this case the stack comment is pretty superfluous, because the
word is simple enough.  If you think it would be a good idea to add such
a comment to increase readability, you should also consider factoring
the word into several simpler words (*note Factoring: Factoring
Tutorial.), which typically eliminates the need for the stack comment;
however, if you decide not to refactor it, then having such a comment is
better than not having it.

   The names of the stack items in stack-effect and stack comments in
the standard, in this manual, and in many programs specify the type
through a type prefix, similar to Fortran and Hungarian notation.  The
most frequent prefixes are:

'n'
     signed integer
'u'
     unsigned integer
'c'
     character
'f'
     Boolean flags, i.e.  'false' or 'true'.
'a-addr,a-'
     Cell-aligned address
'c-addr,c-'
     Char-aligned address (note that a Char may have two bytes in
     Windows NT)
'xt'
     Execution token, same size as Cell
'w,x'
     Cell, can contain an integer or an address.  It usually takes 32,
     64 or 16 bits (depending on your platform and Forth system).  A
     cell is more commonly known as machine word, but the term _word_
     already means something different in Forth.
'd'
     signed double-cell integer
'ud'
     unsigned double-cell integer
'r'
     Float (on the FP stack)

   You can find a more complete list in *note Notation::.

     Assignment: Write stack-effect comments for all definitions you
     have written up to now.

3.12 Types
==========

In Forth the names of the operations are not overloaded; so similar
operations on different types need different names; e.g., '+' adds
integers, and you have to use 'f+' to add floating-point numbers.  The
following prefixes are often used for related operations on different
types:

'(none)'
     signed integer
'u'
     unsigned integer
'c'
     character
'd'
     signed double-cell integer
'ud, du'
     unsigned double-cell integer
'2'
     two cells (not-necessarily double-cell numbers)
'm, um'
     mixed single-cell and double-cell operations
'f'
     floating-point (note that in stack comments 'f' represents flags,
     and 'r' represents FP numbers; also, you need to include the
     exponent part in literal FP numbers, *note Floating Point
     Tutorial::).

   If there are no differences between the signed and the unsigned
variant (e.g., for '+'), there is only the prefix-less variant.

   Forth does not perform type checking, neither at compile time, nor at
run time.  If you use the wrong operation, the data are interpreted
incorrectly:

     -1 u.

   If you have only experience with type-checked languages until now,
and have heard how important type-checking is, don't panic!  In my
experience (and that of other Forthers), type errors in Forth code are
usually easy to find (once you get used to it), the increased vigilance
of the programmer tends to catch some harder errors in addition to most
type errors, and you never have to work around the type system, so in
most situations the lack of type-checking seems to be a win (projects to
add type checking to Forth have not caught on).

3.13 Factoring
==============

If you try to write longer definitions, you will soon find it hard to
keep track of the stack contents.  Therefore, good Forth programmers
tend to write only short definitions (e.g., three lines).  The art of
finding meaningful short definitions is known as factoring (as in
factoring polynomials).

   Well-factored programs offer additional advantages: smaller, more
general words, are easier to test and debug and can be reused more and
better than larger, specialized words.

   So, if you run into difficulties with stack management, when writing
code, try to define meaningful factors for the word, and define the word
in terms of those.  Even if a factor contains only two words, it is
often helpful.

   Good factoring is not easy, and it takes some practice to get the
knack for it; but even experienced Forth programmers often don't find
the right solution right away, but only when rewriting the program.  So,
if you don't come up with a good solution immediately, keep trying,
don't despair.

3.14 Designing the stack effect
===============================

In other languages you can use an arbitrary order of parameters for a
function; and since there is only one result, you don't have to deal
with the order of results, either.

   In Forth (and other stack-based languages, e.g., PostScript) the
parameter and result order of a definition is important and should be
designed well.  The general guideline is to design the stack effect such
that the word is simple to use in most cases, even if that complicates
the implementation of the word.  Some concrete rules are:

   * Words consume all of their parameters (e.g., '.').

   * If there is a convention on the order of parameters (e.g., from
     mathematics or another programming language), stick with it (e.g.,
     '-').

   * If one parameter usually requires only a short computation (e.g.,
     it is a constant), pass it on the top of the stack.  Conversely,
     parameters that usually require a long sequence of code to compute
     should be passed as the bottom (i.e., first) parameter.  This makes
     the code easier to read, because the reader does not need to keep
     track of the bottom item through a long sequence of code (or,
     alternatively, through stack manipulations).  E.g., '!' (store,
     *note Memory::) expects the address on top of the stack because it
     is usually simpler to compute than the stored value (often the
     address is just a variable).

   * Similarly, results that are usually consumed quickly should be
     returned on the top of stack, whereas a result that is often used
     in long computations should be passed as bottom result.  E.g., the
     file words like 'open-file' return the error code on the top of
     stack, because it is usually consumed quickly by 'throw'; moreover,
     the error code has to be checked before doing anything with the
     other results.

   These rules are just general guidelines, don't lose sight of the
overall goal to make the words easy to use.  E.g., if the convention
rule conflicts with the computation-length rule, you might decide in
favour of the convention if the word will be used rarely, and in favour
of the computation-length rule if the word will be used frequently
(because with frequent use the cost of breaking the computation-length
rule would be quite high, and frequent use makes it easier to remember
an unconventional order).

3.15 Local Variables
====================

You can define local variables (_locals_) in a colon definition:

     : swap { a b -- b a }
       b a ;
     1 2 swap .s 2drop

   (If your Forth system does not support this syntax, include
'compat/anslocal.fs' first).

   In this example '{ a b -- b a }' is the locals definition; it takes
two cells from the stack, puts the top of stack in 'b' and the next
stack element in 'a'.  '--' starts a comment ending with '}'.  After the
locals definition, using the name of the local will push its value on
the stack.  You can omit the comment part ('-- b a'):

     : swap ( x1 x2 -- x2 x1 )
       { a b } b a ;

   In Gforth you can have several locals definitions, anywhere in a
colon definition; in contrast, in a standard program you can have only
one locals definition per colon definition, and that locals definition
must be outside any control structure.

   With locals you can write slightly longer definitions without running
into stack trouble.  However, I recommend trying to write colon
definitions without locals for exercise purposes to help you gain the
essential factoring skills.

     Assignment: Rewrite your definitions until now with locals

   Reference: *note Locals::.

3.16 Conditional execution
==========================

In Forth you can use control structures only inside colon definitions.
An 'if'-structure looks like this:

     : abs ( n1 -- +n2 )
         dup 0 < if
             negate
         endif ;
     5 abs .
     -5 abs .

   'if' takes a flag from the stack.  If the flag is non-zero (true),
the following code is performed, otherwise execution continues after the
'endif' (or 'else').  '<' compares the top two stack elements and
produces a flag:

     1 2 < .
     2 1 < .
     1 1 < .

   Actually the standard name for 'endif' is 'then'.  This tutorial
presents the examples using 'endif', because this is often less
confusing for people familiar with other programming languages where
'then' has a different meaning.  If your system does not have 'endif',
define it with

     : endif postpone then ; immediate

   You can optionally use an 'else'-part:

     : min ( n1 n2 -- n )
       2dup < if
         drop
       else
         nip
       endif ;
     2 3 min .
     3 2 min .

     Assignment: Write 'min' without 'else'-part (hint: what's the
     definition of 'nip'?).

   Reference: *note Selection::.

3.17 Flags and Comparisons
==========================

In a false-flag all bits are clear (0 when interpreted as integer).  In
a canonical true-flag all bits are set (-1 as a twos-complement signed
integer); in many contexts (e.g., 'if') any non-zero value is treated as
true flag.

     false .
     true .
     true hex u. decimal

   Comparison words produce canonical flags:

     1 1 = .
     1 0= .
     0 1 < .
     0 0 < .
     -1 1 u< . \ type error, u< interprets -1 as large unsigned number
     -1 1 < .

   Gforth supports all combinations of the prefixes '0 u d d0 du f f0'
(or none) and the comparisons '= <> < > <= >='.  Only a part of these
combinations are standard (for details see the standard, *note Numeric
comparison::, *note Floating Point:: or *note Word Index::).

   You can use 'and or xor invert' as operations on canonical flags.
Actually they are bitwise operations:

     1 2 and .
     1 2 or .
     1 3 xor .
     1 invert .

   You can convert a zero/non-zero flag into a canonical flag with '0<>'
(and complement it on the way with '0='; indeed, it is more common to
use '0=' instead of 'invert' for canonical flags).

     1 0= .
     1 0<> .

   While you can use 'if' without '0<>' to test for zero/non-zero, you
sometimes need to use '0<>' when combining zero/non-zero values with
'and or xor' because of their bitwise nature.  The simplest, least
error-prone, and probably clearest way is to use '0<>' in all these
cases, but in some cases you can use fewer '0<>'s.  Here are some stack
effects, where fc represents a canonical flag, and fz represents
zero/non-zero (every fc also works as fz):

     or  ( fz1 fz2 -- fz3 )
     and ( fz1 fc  -- fz2 )
     and ( fc  fz1 -- fz2 )

   So, if you see code like this:

     ( n1 n2 ) 0<> and if

   This tests whether n1 and n2 are non-zero and if yes, performs the
code after 'if'; it treats n1 as zero/non-zero and uses '0<>' to convert
n2 into a canonical flag; the 'and' then produces an fz, which is
consumed by the 'if'.

   You can use the all-bits-set feature of canonical flags and the
bitwise operation of the Boolean operations to avoid 'if's:

     : foo ( n1 -- n2 )
       0= if
         14
       else
         0
       endif ;
     0 foo .
     1 foo .

     : foo ( n1 -- n2 )
       0= 14 and ;
     0 foo .
     1 foo .

     Assignment: Write 'min' without 'if'.

   For reference, see *note Boolean Flags::, *note Numeric comparison::,
and *note Bitwise operations::.

3.18 General Loops
==================

The endless loop is the most simple one:

     : endless ( -- )
       0 begin
         dup . 1+
       again ;
     endless

   Terminate this loop by pressing 'Ctrl-C' (in Gforth).  'begin' does
nothing at run-time, 'again' jumps back to 'begin'.

   A loop with one exit at any place looks like this:

     : log2 ( +n1 -- n2 )
     \ logarithmus dualis of n1>0, rounded down to the next integer
       assert( dup 0> )
       2/ 0 begin
         over 0> while
           1+ swap 2/ swap
       repeat
       nip ;
     7 log2 .
     8 log2 .

   At run-time 'while' consumes a flag; if it is 0, execution continues
behind the 'repeat'; if the flag is non-zero, execution continues behind
the 'while'.  'Repeat' jumps back to 'begin', just like 'again'.

   In Forth there are a number of combinations/abbreviations, like '1+'.
However, '2/' is not one of them; it shifts its argument right by one
bit (arithmetic shift right), and viewed as division that always rounds
towards negative infinity (floored division), like Gforth's '/' (since
Gforth 0.7), but unlike '/' in many other Forth systems.

     -5 2 / . \ -2 or -3
     -5 2/ .  \ -3

   'assert(' is no standard word, but you can get it on systems other
than Gforth by including 'compat/assert.fs'.  You can see what it does
by trying

     0 log2 .

   Here's a loop with an exit at the end:

     : log2 ( +n1 -- n2 )
     \ logarithmus dualis of n1>0, rounded down to the next integer
       assert( dup 0 > )
       -1 begin
         1+ swap 2/ swap
         over 0 <=
       until
       nip ;

   'Until' consumes a flag; if it is zero, execution continues at the
'begin', otherwise after the 'until'.

     Assignment: Write a definition for computing the greatest common
     divisor.

   Reference: *note General Loops::.

3.19 Counted loops
==================

     : ^ ( n1 u -- n )
     \ n = the uth power of n1
       1 swap 0 u+do
         over *
       loop
       nip ;
     3 2 ^ .
     4 3 ^ .

   'U+do' (from 'compat/loops.fs', if your Forth system doesn't have it)
takes two numbers of the stack '( u3 u4 -- )', and then performs the
code between 'u+do' and 'loop' for 'u3-u4' times (or not at all, if
'u3-u4<0').

   You can see the stack effect design rules at work in the stack effect
of the loop start words: Since the start value of the loop is more
frequently constant than the end value, the start value is passed on the
top-of-stack.

   You can access the counter of a counted loop with 'i':

     : fac ( u -- u! )
       1 swap 1+ 1 u+do
         i *
       loop ;
     5 fac .
     7 fac .

   There is also '+do', which expects signed numbers (important for
deciding whether to enter the loop).

     Assignment: Write a definition for computing the nth Fibonacci
     number.

   You can also use increments other than 1:

     : up2 ( n1 n2 -- )
       +do
         i .
       2 +loop ;
     10 0 up2

     : down2 ( n1 n2 -- )
       -do
         i .
       2 -loop ;
     0 10 down2

   Reference: *note Counted Loops::.

3.20 Recursion
==============

Usually the name of a definition is not visible in the definition; but
earlier definitions are usually visible:

     1 0 / . \ "Floating-point unidentified fault" in Gforth on some platforms
     : / ( n1 n2 -- n )
       dup 0= if
         -10 throw \ report division by zero
       endif
       /           \ old version
     ;
     1 0 /

   For recursive definitions you can use 'recursive' (non-standard) or
'recurse':

     : fac1 ( n -- n! ) recursive
      dup 0> if
        dup 1- fac1 *
      else
        drop 1
      endif ;
     7 fac1 .

     : fac2 ( n -- n! )
      dup 0> if
        dup 1- recurse *
      else
        drop 1
      endif ;
     8 fac2 .

     Assignment: Write a recursive definition for computing the nth
     Fibonacci number.

   Reference (including indirect recursion): *Note Calls and returns::.

3.21 Leaving definitions or loops
=================================

'EXIT' exits the current definition right away.  For every counted loop
that is left in this way, an 'UNLOOP' has to be performed before the
'EXIT':

     : ...
      ... u+do
        ... if
          ... unloop exit
        endif
        ...
      loop
      ... ;

   'LEAVE' leaves the innermost counted loop right away:

     : ...
      ... u+do
        ... if
          ... leave
        endif
        ...
      loop
      ... ;

   Reference: *note Calls and returns::, *note Counted Loops::.

3.22 Return Stack
=================

In addition to the data stack Forth also has a second stack, the return
stack; most Forth systems store the return addresses of procedure calls
there (thus its name).  Programmers can also use this stack:

     : foo ( n1 n2 -- )
      .s
      >r .s
      r@ .
      >r .s
      r@ .
      r> .
      r@ .
      r> . ;
     1 2 foo

   '>r' takes an element from the data stack and pushes it onto the
return stack; conversely, 'r>' moves an element from the return to the
data stack; 'r@' pushes a copy of the top of the return stack on the
data stack.

   Forth programmers usually use the return stack for storing data
temporarily, if using the data stack alone would be too complex, and
factoring and locals are not an option:

     : 2swap ( x1 x2 x3 x4 -- x3 x4 x1 x2 )
      rot >r rot r> ;

   The return address of the definition and the loop control parameters
of counted loops usually reside on the return stack, so you have to take
all items, that you have pushed on the return stack in a colon
definition or counted loop, from the return stack before the definition
or loop ends.  You cannot access items that you pushed on the return
stack outside some definition or loop within the definition of loop.

   If you miscount the return stack items, this usually ends in a crash:

     : crash ( n -- )
       >r ;
     5 crash

   You cannot mix using locals and using the return stack (according to
the standard; Gforth has no problem).  However, they solve the same
problems, so this shouldn't be an issue.

     Assignment: Can you rewrite any of the definitions you wrote until
     now in a better way using the return stack?

   Reference: *note Return stack::.

3.23 Memory
===========

You can create a global variable 'v' with

     variable v ( -- addr )

   'v' pushes the address of a cell in memory on the stack.  This cell
was reserved by 'variable'.  You can use '!' (store) to store values
from the stack into this cell and '@' (fetch) to load the value from
memory onto the stack:

     v .
     5 v ! .s
     v @ .

   You can see a raw dump of memory with 'dump':

     v 1 cells .s dump

   'Cells ( n1 -- n2 )' gives you the number of bytes (or, more
generally, address units (aus)) that 'n1 cells' occupy.  You can also
reserve more memory:

     create v2 20 cells allot
     v2 20 cells dump

   creates a variable-like word 'v2' and reserves 20 uninitialized
cells; the address pushed by 'v2' points to the start of these 20 cells
(*note CREATE::).  You can use address arithmetic to access these cells:

     3 v2 5 cells + !
     v2 20 cells dump

   You can reserve and initialize memory with ',':

     create v3
       5 , 4 , 3 , 2 , 1 ,
     v3 @ .
     v3 cell+ @ .
     v3 2 cells + @ .
     v3 5 cells dump

     Assignment: Write a definition 'vsum ( addr u -- n )' that computes
     the sum of 'u' cells, with the first of these cells at 'addr', the
     next one at 'addr cell+' etc.

   The difference between 'variable' and 'create' is that 'variable'
allots a cell, and that you cannot allot additional memory to a variable
in Standard Forth.

   You can also reserve memory without creating a new word:

     here 10 cells allot .
     here .

   The first 'here' pushes the start address of the memory area, the
second 'here' the address after the dictionary area.  You should store
the start address somewhere, or you will have a hard time finding the
memory area again.

   'Allot' manages dictionary memory.  The dictionary memory contains
the system's data structures for words etc.  on Gforth and most other
Forth systems.  It is managed like a stack: You can free the memory that
you have just 'allot'ed with

     -10 cells allot
     here .

   Note that you cannot do this if you have created a new word in the
meantime (because then your 'allot'ed memory is no longer on the top of
the dictionary "stack").

   Alternatively, you can use 'allocate' and 'free' which allow freeing
memory in any order:

     10 cells allocate throw .s
     20 cells allocate throw .s
     swap
     free throw
     free throw

   The 'throw's deal with errors (e.g., out of memory).

   And there is also a garbage collector
(https://www.complang.tuwien.ac.at/forth/garbage-collection.zip), which
eliminates the need to 'free' memory explicitly.

   Reference: *note Memory::.

3.24 Characters and Strings
===========================

On the stack characters take up a cell, like numbers.  In memory they
have their own size (one 8-bit byte on most systems), and therefore
require their own words for memory access:

     create v4
       104 c, 97 c, 108 c, 108 c, 111 c,
     v4 4 chars + c@ .
     v4 5 chars dump

   The preferred representation of strings on the stack is 'addr
u-count', where 'addr' is the address of the first character and
'u-count' is the number of characters in the string.

     v4 5 type

   You get a string constant with

     s" hello, world" .s
     type

   Make sure you have a space between 's"' and the string; 's"' is a
normal Forth word and must be delimited with white space (try what
happens when you remove the space).

   However, this interpretive use of 's"' is quite restricted: the
string exists only until the next call of 's"' (some Forth systems keep
more than one of these strings, but usually they still have a limited
lifetime).

     s" hello," s" world" .s
     type
     type

   You can also use 's"' in a definition, and the resulting strings then
live forever (well, for as long as the definition):

     : foo s" hello," s" world" ;
     foo .s
     type
     type

     Assignment: 'Emit ( c -- )' types 'c' as character (not a number).
     Implement 'type ( addr u -- )'.

   Reference: *note Memory Blocks::.

3.25 Alignment
==============

On many processors cells have to be aligned in memory, if you want to
access them with '@' and '!' (and even if the processor does not require
alignment, access to aligned cells is faster).

   'Create' aligns 'here' (i.e., the place where the next allocation
will occur, and that the 'create'd word points to).  Likewise, the
memory produced by 'allocate' starts at an aligned address.  Adding a
number of 'cells' to an aligned address produces another aligned
address.

   However, address arithmetic involving 'char+' and 'chars' can create
an address that is not cell-aligned.  'Aligned ( addr -- a-addr )'
produces the next aligned address:

     v3 char+ aligned .s @ .
     v3 char+ .s @ .

   Similarly, 'align' advances 'here' to the next aligned address:

     create v5 97 c,
     here .
     align here .
     1000 ,

   Note that you should use aligned addresses even if your processor
does not require them, if you want your program to be portable.

   Reference: *note Address arithmetic::.

3.26 Floating Point
===================

Floating-point (FP) numbers and arithmetic in Forth works mostly as one
might expect, but there are a few things worth noting:

   The first point is not specific to Forth, but so important and yet
not universally known that I mention it here: FP numbers are not reals.
Many properties (e.g., arithmetic laws) that reals have and that one
expects of all kinds of numbers do not hold for FP numbers.  If you want
to use FP computations, you should learn about their problems and how to
avoid them; a good starting point is 'David Goldberg, What Every
Computer Scientist Should Know About Floating-Point Arithmetic
(https://docs.oracle.com/cd/E19957-01/806-3568/ncg_goldberg.html), ACM
Computing Surveys 23(1):5-48, March 1991'.

   In Forth source code literal FP numbers need an exponent, e.g.,
'1e0'; this can also be written shorter as '1e', longer as '+1.0e+0',
and many variations in between.  The reason for this is that, for
historical reasons, Forth interprets a decimal point alone (e.g., '1.')
as indicating a double-cell integer.  Examples:

     2e 2e f+ f.

   Another requirement for literal FP numbers is that the current base
is decimal; with a hex base '1e' is interpreted as an integer.

   Forth has a separate stack for FP numbers in conformance with
Forth-2012.  One advantage of this model is that cells are not in the
way when accessing FP values, and vice versa.  Forth has a set of words
for manipulating the FP stack: 'fdup fswap fdrop fover frot' and
(non-standard) 'fnip ftuck fpick'.

   FP arithmetic words are prefixed with 'F'.  There is the usual set
'f+ f- f* f/ f** fnegate' as well as a number of words for other
functions, e.g., 'fsqrt fsin fln fmin'.  One word that you might expect
is 'f='; but 'f=' is non-standard, because FP computation results are
usually inaccurate, so exact comparison is usually a mistake, and one
should use approximate comparison.  Unfortunately, 'f~', the standard
word for that purpose, is not well designed, so Gforth provides 'f~abs'
and 'f~rel' as well.

   And of course there are words for accessing FP numbers in memory ('f@
f!'), and for address arithmetic ('floats float+ faligned').  There are
also variants of these words with an 'sf' and 'df' prefix for accessing
IEEE format single-precision and double-precision numbers in memory;
their main purpose is for accessing external FP data (e.g., that has
been read from or will be written to a file).

   Here is an example of a dot-product word and its use:

     : v* ( f_addr1 nstride1 f_addr2 nstride2 ucount -- r )
       >r swap 2swap swap 0e r> 0 ?DO
         dup f@ over + 2swap dup f@ f* f+ over + 2swap
       LOOP
       2drop 2drop ;

     create v 1.23e f, 4.56e f, 7.89e f,

     v 1 floats  v 1 floats  3  v* f.

     Assignment: Write a program to solve a quadratic equation.  Then
     read 'Henry G. Baker, You Could Learn a Lot from a Quadratic
     (https://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.111.4448&rep=rep1&type=pdf),
     ACM SIGPLAN Notices, 33(1):30-39, January 1998', and see if you can
     improve your program.  Finally, find a test case where the original
     and the improved version produce different results.

   Reference: *note Floating Point::; *note Floating point stack::;
*note Number Conversion::; *note Memory Access::; *note Address
arithmetic::.

3.27 Files
==========

This section gives a short introduction into how to use files inside
Forth.  It's broken up into five easy steps:

  1. Open an ASCII text file for input
  2. Open a file for output
  3. Read input file until string matches (or some other condition is
     met)
  4. Write some lines from input (modified or not) to output
  5. Close the files.

   Reference: *note General files::.

3.27.1 Open file for input
--------------------------

     s" foo.in"  r/o open-file throw Value fd-in

3.27.2 Create file for output
-----------------------------

     s" foo.out" w/o create-file throw Value fd-out

   The available file modes are r/o for read-only access, r/w for
read-write access, and w/o for write-only access.  You could open both
files with r/w, too, if you like.  All file words return error codes;
for most applications, it's best to pass there error codes with 'throw'
to the outer error handler.

   If you want words for opening and assigning, define them as follows:

     0 Value fd-in
     0 Value fd-out
     : open-input ( addr u -- )  r/o open-file throw to fd-in ;
     : open-output ( addr u -- )  w/o create-file throw to fd-out ;

   Usage example:

     s" foo.in" open-input
     s" foo.out" open-output

3.27.3 Scan file for a particular line
--------------------------------------

     256 Constant max-line
     Create line-buffer  max-line 2 + allot

     : scan-file ( addr u -- )
       begin
           line-buffer max-line fd-in read-line throw
       while
              >r 2dup line-buffer r> compare 0=
          until
       else
          drop
       then
       2drop ;

   'read-line ( addr u1 fd -- u2 flag ior )' reads up to u1 bytes into
the buffer at addr, and returns the number of bytes read, a flag that is
false when the end of file is reached, and an error code.

   'compare ( addr1 u1 addr2 u2 -- n )' compares two strings and returns
zero if both strings are equal.  It returns a positive number if the
first string is lexically greater, a negative if the second string is
lexically greater.

   We haven't seen this loop here; it has two exits.  Since the 'while'
exits with the number of bytes read on the stack, we have to clean up
that separately; that's after the 'else'.

   Usage example:

     s" The text I search is here" scan-file

3.27.4 Copy input to output
---------------------------

     : copy-file ( -- )
       begin
           line-buffer max-line fd-in read-line throw
       while
           line-buffer swap fd-out write-line throw
       repeat
       drop ;

3.27.5 Close files
------------------

     fd-in close-file throw
     fd-out close-file throw

   Likewise, you can put that into definitions, too:

     : close-input ( -- )  fd-in close-file throw ;
     : close-output ( -- )  fd-out close-file throw ;

     Assignment: How could you modify 'copy-file' so that it copies
     until a second line is matched?  Can you write a program that
     extracts a section of a text file, given the line that starts and
     the line that terminates that section?

3.28 Interpretation and Compilation Semantics and Immediacy
===========================================================

When a word is compiled, it behaves differently from being interpreted.
E.g., consider '+':

     1 2 + .
     : foo + ;

   These two behaviours are known as compilation and interpretation
semantics.  For normal words (e.g., '+'), the compilation semantics is
to append the interpretation semantics to the currently defined word
('foo' in the example above).  I.e., when 'foo' is executed later, the
interpretation semantics of '+' (i.e., adding two numbers) will be
performed.

   However, there are words with non-default compilation semantics,
e.g., the control-flow words like 'if'.  You can use 'immediate' to
change the compilation semantics of the last defined word to be equal to
the interpretation semantics:

     : [FOO] ( -- )
      5 . ; immediate

     [FOO]
     : bar ( -- )
       [FOO] ;
     bar
     see bar

   Two conventions to mark words with non-default compilation semantics
are names with brackets (more frequently used) and to write them all in
upper case (less frequently used).

   For some words, such as 'if', using their interpretation semantics is
usually a mistake, so we mark them as 'compile-only', and you get a
warning when you interpret them.

     : flip ( -- )
      6 . ; compile-only \ but not immediate
     flip

     : flop ( -- )
      flip ;
     flop

   In this example, first the interpretation semantics of 'flip' is used
(and you get a warning); the second use of 'flip' uses the compilation
semantics (and you get no warning).  You can also see in this example
that compile-only is a property that is evaluated at text interpretation
time, not at run-time.

   The text interpreter has two states: in interpret state, it performs
the interpretation semantics of words it encounters; in compile state,
it performs the compilation semantics of these words.

   Among other things, ':' switches into compile state, and ';' switches
back to interpret state.  They contain the factors ']' (switch to
compile state) and '[' (switch to interpret state), that do nothing but
switch the state.

     : xxx ( -- )
       [ 5 . ]
     ;

     xxx
     see xxx

   These brackets are also the source of the naming convention mentioned
above.

   Reference: *note Interpretation and Compilation Semantics::.

3.29 Execution Tokens
=====================

'' word' gives you the execution token (XT) of a word.  The XT is a cell
representing the interpretation semantics of a word.  You can execute
these semantics with 'execute':

     ' + .s
     1 2 rot execute .

   The XT is similar to a function pointer in C. However, parameter
passing through the stack makes it a little more flexible:

     : map-array ( ... addr u xt -- ... )
     \ executes xt ( ... x -- ... ) for every element of the array starting
     \ at addr and containing u elements
       { xt }
       cells over + swap ?do
         i @ xt execute
       1 cells +loop ;

     create a 3 , 4 , 2 , -1 , 4 ,
     a 5 ' . map-array .s
     0 a 5 ' + map-array .
     s" max-n" environment? drop .s
     a 5 ' min map-array .

   You can use map-array with the XTs of words that consume one element
more than they produce.  In theory you can also use it with other XTs,
but the stack effect then depends on the size of the array, which is
hard to understand.

   Since XTs are cell-sized, you can store them in memory and manipulate
them on the stack like other cells.  You can also compile the XT into a
word with 'compile,':

     : foo1 ( n1 n2 -- n )
        [ ' + compile, ] ;
     see foo1

   This is non-standard, because 'compile,' has no compilation semantics
in the standard, but it works in good Forth systems.  For the broken
ones, use

     : [compile,] compile, ; immediate

     : foo1 ( n1 n2 -- n )
        [ ' + ] [compile,] ;
     see foo1

   ''' is a word with default compilation semantics; it parses the next
word when its interpretation semantics are executed, not during
compilation:

     : foo ( -- xt )
       ' ;
     see foo
     : bar ( ... "word" -- ... )
       ' execute ;
     see bar
     1 2 bar + .

   You often want to parse a word during compilation and compile its XT
so it will be pushed on the stack at run-time.  '[']' does this:

     : xt-+ ( -- xt )
       ['] + ;
     see xt-+
     1 2 xt-+ execute .

   Many programmers tend to see ''' and the word it parses as one unit,
and expect it to behave like '[']' when compiled, and are confused by
the actual behaviour.  If you are, just remember that the Forth system
just takes ''' as one unit and has no idea that it is a parsing word
(attempts to convenience programmers in this issue have usually resulted
in even worse pitfalls, see 'State'-smartness--Why it is evil and How to
Exorcise it (https://www.complang.tuwien.ac.at/papers/ertl98.ps.gz)).

   Note that the state of the interpreter does not come into play when
creating and executing XTs.  I.e., even when you execute ''' in compile
state, it still gives you the interpretation semantics.  And whatever
that state is, 'execute' performs the semantics represented by the XT
(i.e., for XTs produced with ''' the interpretation semantics).

   Reference: *note Tokens for Words::.

3.30 Exceptions
===============

'throw ( n -- )' causes an exception unless n is zero.

     100 throw .s
     0 throw .s

   'catch ( ... xt -- ... n )' behaves similar to 'execute', but it
catches exceptions and pushes the number of the exception on the stack
(or 0, if the xt executed without exception).  If there was an
exception, the stacks have the same depth as when entering 'catch':

     .s
     3 0 ' / catch .s
     3 2 ' / catch .s

     Assignment: Try the same with 'execute' instead of 'catch'.

   'Throw' always jumps to the dynamically next enclosing 'catch', even
if it has to leave several call levels to achieve this:

     : foo 100 throw ;
     : foo1 foo ." after foo" ;
     : bar ['] foo1 catch ;
     bar .

   It is often important to restore a value upon leaving a definition,
even if the definition is left through an exception.  You can ensure
this like this:

     : ...
        save-x
        ['] word-changing-x catch ( ... n )
        restore-x
        ( ... n ) throw ;

   However, this is still not safe against, e.g., the user pressing
'Ctrl-C' when execution is between the 'catch' and 'restore-x'.

   Gforth provides an alternative exception handling syntax that is safe
against such cases: 'try ... restore ... endtry'.  If the code between
'try' and 'endtry' has an exception, the stack depths are restored, the
exception number is pushed on the stack, and the execution continues
right after 'restore'.

   The safer equivalent to the restoration code above is

     : ...
       save-x
       try
         word-changing-x 0
       restore
         restore-x
       endtry
       throw ;

   Reference: *note Exception Handling::.

3.31 Defining Words
===================

':', 'create', and 'variable' are definition words: They define other
words.  'Constant' is another definition word:

     5 constant foo
     foo .

   You can also use the prefixes '2' (double-cell) and 'f' (floating
point) with 'variable' and 'constant'.

   You can also define your own defining words.  E.g.:

     : variable ( "name" -- )
       create 0 , ;

   You can also define defining words that create words that do
something other than just producing their address:

     : constant ( n "name" -- )
       create ,
     does> ( -- n )
       ( addr ) @ ;

     5 constant foo
     foo .

   The definition of 'constant' above ends at the 'does>'; i.e., 'does>'
replaces ';', but it also does something else: It changes the last
defined word such that it pushes the address of the body of the word and
then performs the code after the 'does>' whenever it is called.

   In the example above, 'constant' uses ',' to store 5 into the body of
'foo'.  When 'foo' executes, it pushes the address of the body onto the
stack, then (in the code after the 'does>') fetches the 5 from there.

   The stack comment near the 'does>' reflects the stack effect of the
defined word, not the stack effect of the code after the 'does>' (the
difference is that the code expects the address of the body that the
stack comment does not show).

   You can use these definition words to do factoring in cases that
involve (other) definition words.  E.g., a field offset is always added
to an address.  Instead of defining

     2 cells constant offset-field1

   and using this like

     ( addr ) offset-field1 +

   you can define a definition word

     : simple-field ( n "name" -- )
       create ,
     does> ( n1 -- n1+n )
       ( addr ) @ + ;

   Definition and use of field offsets now look like this:

     2 cells simple-field field1
     create mystruct 4 cells allot
     mystruct .s field1 .s drop

   If you want to do something with the word without performing the code
after the 'does>', you can access the body of a 'create'd word with
'>body ( xt -- addr )':

     : value ( n "name" -- )
       create ,
     does> ( -- n1 )
       @ ;
     : to ( n "name" -- )
       ' >body ! ;

     5 value foo
     foo .
     7 to foo
     foo .

     Assignment: Define 'defer ( "name" -- )', which creates a word that
     stores an XT (at the start the XT of 'abort'), and upon execution
     'execute's the XT. Define 'is ( xt "name" -- )' that stores 'xt'
     into 'name', a word defined with 'defer'.  Indirect recursion is
     one application of 'defer'.

   Reference: *note User-defined Defining Words::.

3.32 Arrays and Records
=======================

Forth has no standard words for defining arrays, but you can build them
yourself based on address arithmetic.  You can also define words for
defining arrays and records (*note Defining Words: Defining Words
Tutorial.).

   One of the first projects a Forth newcomer sets out upon when
learning about defining words is an array defining word (possibly for
n-dimensional arrays).  Go ahead and do it, I did it, too; you will
learn something from it.  However, don't be disappointed when you later
learn that you have little use for these words (inappropriate use would
be even worse).  I have not found a set of useful array words yet; the
needs are just too diverse, and named, global arrays (the result of
naive use of defining words) are often not flexible enough (e.g.,
consider how to pass them as parameters).  Another such project is a set
of words to help dealing with strings.

   On the other hand, there is a useful set of record words, and it has
been defined in 'compat/struct.fs'; these words are predefined in
Gforth.  They are explained in depth elsewhere in this manual (see *note
Structures::).  The 'simple-field' example above is simplified variant
of fields in this package.

3.33 'POSTPONE'
===============

You can compile the compilation semantics (instead of compiling the
interpretation semantics) of a word with 'POSTPONE':

     : MY-+ ( Compilation: -- ; Run-time of compiled code: n1 n2 -- n )
      POSTPONE + ; immediate
     : foo ( n1 n2 -- n )
      MY-+ ;
     1 2 foo .
     see foo

   During the definition of 'foo' the text interpreter performs the
compilation semantics of 'MY-+', which performs the compilation
semantics of '+', i.e., it compiles '+' into 'foo'.

   This example also displays separate stack comments for the
compilation semantics and for the stack effect of the compiled code.
For words with default compilation semantics these stack effects are
usually not displayed; the stack effect of the compilation semantics is
always '( -- )' for these words, the stack effect for the compiled code
is the stack effect of the interpretation semantics.

   Note that the state of the interpreter does not come into play when
performing the compilation semantics in this way.  You can also perform
it interpretively, e.g.:

     : foo2 ( n1 n2 -- n )
      [ MY-+ ] ;
     1 2 foo .
     see foo

   However, there are some broken Forth systems where this does not
always work, and therefore this practice was been declared non-standard
in 1999.

   Here is another example for using 'POSTPONE':

     : MY-- ( Compilation: -- ; Run-time of compiled code: n1 n2 -- n )
      POSTPONE negate POSTPONE + ; immediate compile-only
     : bar ( n1 n2 -- n )
       MY-- ;
     2 1 bar .
     see bar

   You can define 'ENDIF' (which you can use instead of 'THEN') in this
way:

     : ENDIF ( Compilation: orig -- )
       POSTPONE then ; immediate

     Assignment: Write 'MY-2DUP' that has compilation semantics
     equivalent to '2dup', but compiles 'over over'.

3.34 'Literal'
==============

You cannot 'POSTPONE' numbers:

     : [FOO] POSTPONE 500 ; immediate

   Instead, you can use 'LITERAL (compilation: n --; run-time: -- n )':

     : [FOO] ( compilation: --; run-time: -- n )
       500 POSTPONE literal ; immediate

     : flip [FOO] ;
     flip .
     see flip

   'LITERAL' consumes a number at compile-time (when it's compilation
semantics are executed) and pushes it at run-time (when the code it
compiled is executed).  A frequent use of 'LITERAL' is to compile a
number computed at compile time into the current word:

     : bar ( -- n )
       [ 2 2 + ] literal ;
     see bar

     Assignment: Write ']L' which allows writing the example above as ':
     bar ( -- n ) [ 2 2 + ]L ;'

3.35 Advanced macros
====================

Reconsider 'map-array' from *note Execution Tokens: Execution Tokens
Tutorial.  It frequently performs 'execute', a relatively expensive
operation in some Forth implementations.  You can use 'compile,' and
'POSTPONE' to eliminate these 'execute's and produce a word that
contains the word to be performed directly:

     : compile-map-array ( compilation: xt -- ; run-time: ... addr u -- ... )
     \ at run-time, execute xt ( ... x -- ... ) for each element of the
     \ array beginning at addr and containing u elements
       { xt }
       POSTPONE cells POSTPONE over POSTPONE + POSTPONE swap POSTPONE ?do
         POSTPONE i POSTPONE @ xt compile,
       1 cells POSTPONE literal POSTPONE +loop ;

     : sum-array ( addr u -- n )
      0 rot rot [ ' + compile-map-array ] ;
     see sum-array
     a 5 sum-array .

   You can use the full power of Forth for generating the code; here's
an example where the code is generated in a loop:

     : compile-vmul-step ( compilation: n --; run-time: n1 addr1 -- n2 addr2 )
     \ n2=n1+(addr1)*n, addr2=addr1+cell
       POSTPONE tuck POSTPONE @
       POSTPONE literal POSTPONE * POSTPONE +
       POSTPONE swap POSTPONE cell+ ;

     : compile-vmul ( compilation: addr1 u -- ; run-time: addr2 -- n )
     \ n=v1*v2 (inner product), where the v_i are represented as addr_i u
       0 postpone literal postpone swap
       [ ' compile-vmul-step compile-map-array ]
       postpone drop ;
     see compile-vmul

     : a-vmul ( addr -- n )
     \ n=a*v, where v is a vector that's as long as a and starts at addr
      [ a 5 compile-vmul ] ;
     see a-vmul
     a a-vmul .

   This example uses 'compile-map-array' to show off, but you could also
use 'map-array' instead (try it now!).

   You can use this technique for efficient multiplication of large
matrices.  In matrix multiplication, you multiply every row of one
matrix with every column of the other matrix.  You can generate the code
for one row once, and use it for every column.  The only downside of
this technique is that it is cumbersome to recover the memory consumed
by the generated code when you are done (and in more complicated cases
it is not possible portably).

3.36 Compilation Tokens
=======================

This section is Gforth-specific.  You can skip it.

   '' word compile,' compiles the interpretation semantics.  For words
with default compilation semantics this is the same as performing the
compilation semantics.  To represent the compilation semantics of other
words (e.g., words like 'if' that have no interpretation semantics),
Gforth has the concept of a compilation token (CT, consisting of two
cells), and words 'comp'' and '[comp']'.  You can perform the
compilation semantics represented by a CT with 'execute':

     : foo2 ( n1 n2 -- n )
        [ comp' + execute ] ;
     see foo

   You can compile the compilation semantics represented by a CT with
'postpone,':

     : foo3 ( -- )
       [ comp' + postpone, ] ;
     see foo3

   '[ comp' word postpone, ]' is equivalent to 'POSTPONE word'.  'comp''
is particularly useful for words that have no interpretation semantics:

     ' if
     comp' if .s 2drop

   Reference: *note Tokens for Words::.

3.37 Wordlists and Search Order
===============================

The dictionary is not just a memory area that allows you to allocate
memory with 'allot', it also contains the Forth words, arranged in
several wordlists.  When searching for a word in a wordlist,
conceptually you start searching at the youngest and proceed towards
older words (in reality most systems nowadays use hash-tables); i.e., if
you define a word with the same name as an older word, the new word
shadows the older word.

   Which wordlists are searched in which order is determined by the
search order.  You can display the search order with 'order'.  It
displays first the search order, starting with the wordlist searched
first, then it displays the wordlist that will contain newly defined
words.

   You can create a new, empty wordlist with 'wordlist ( -- wid )':

     wordlist constant mywords

   'Set-current ( wid -- )' sets the wordlist that will contain newly
defined words (the _current_ wordlist):

     mywords set-current
     order

   Gforth does not display a name for the wordlist in 'mywords' because
this wordlist was created anonymously with 'wordlist'.

   You can get the current wordlist with 'get-current ( -- wid)'.  If
you want to put something into a specific wordlist without overall
effect on the current wordlist, this typically looks like this:

     get-current mywords set-current ( wid )
     create someword
     ( wid ) set-current

   You can write the search order with 'set-order ( wid1 .. widn n -- )'
and read it with 'get-order ( -- wid1 .. widn n )'.  The first searched
wordlist is topmost.

     get-order mywords swap 1+ set-order
     order

   Yes, the order of wordlists in the output of 'order' is reversed from
stack comments and the output of '.s' and thus unintuitive.

     Assignment: Define '>order ( wid -- )' which adds 'wid' as first
     searched wordlist to the search order.  Define 'previous ( -- )',
     which removes the first searched wordlist from the search order.
     Experiment with boundary conditions (you will see some crashes or
     situations that are hard or impossible to leave).

   The search order is a powerful foundation for providing features
similar to Modula-2 modules and C++ namespaces.  However, trying to
modularize programs in this way has disadvantages for debugging and
reuse/factoring that overcome the advantages in my experience (I don't
do huge projects, though).  These disadvantages are not so clear in
other languages/programming environments, because these languages are
not so strong in debugging and reuse.

   Reference: *note Word Lists::.

4 An Introduction to Standard Forth
***********************************

The difference of this chapter from the Tutorial (*note Tutorial::) is
that it is slower-paced in its examples, but uses them to dive deep into
explaining Forth internals (not covered by the Tutorial).  Apart from
that, this chapter covers far less material.  It is suitable for reading
without using a computer.

   The primary purpose of this manual is to document Gforth.  However,
since Forth is not a widely-known language and there is a lack of
up-to-date teaching material, it seems worthwhile to provide some
introductory material.  For other sources of Forth-related information,
see *note Forth-related information::.

   The examples in this section should work on any Standard Forth; the
output shown was produced using Gforth.  Each example attempts to
reproduce the exact output that Gforth produces.  If you try out the
examples (and you should), what you should type is shown 'like this' and
Gforth's response is shown 'like this'.  The single exception is that,
where the example shows <RET> it means that you should press the
"carriage return" key.  Unfortunately, some output formats for this
manual cannot show the difference between 'this' and 'this' which will
make trying out the examples harder (but not impossible).

   Forth is an unusual language.  It provides an interactive development
environment which includes both an interpreter and compiler.  Forth
programming style encourages you to break a problem down into many small
fragments ("factoring"), and then to develop and test each fragment
interactively.  Forth advocates assert that breaking the
edit-compile-test cycle used by conventional programming languages can
lead to great productivity improvements.

4.1 Introducing the Text Interpreter
====================================

When you invoke the Forth image, you will see a startup banner printed
and nothing else (if you have Gforth installed on your system, try
invoking it now, by typing 'gforth<RET>').  Forth is now running its
command line interpreter, which is called the "Text Interpreter" (also
known as the "Outer Interpreter").  (You will learn a lot about the text
interpreter as you read through this chapter, for more detail *note The
Text Interpreter::).

   Although it's not obvious, Forth is actually waiting for your input.
Type a number and press the <RET> key:

     45<RET>  ok

   Rather than give you a prompt to invite you to input something, the
text interpreter prints a status message after it has processed a line
of input.  The status message in this case ("' ok'" followed by
carriage-return) indicates that the text interpreter was able to process
all of your input successfully.  Now type something illegal:

     qwer341<RET>
     *the terminal*:2: Undefined word
     >>>qwer341<<<
     Backtrace:
     $2A95B42A20 throw
     $2A95B57FB8 no.extensions

   The exact text, other than the "Undefined word" may differ slightly
on your system, but the effect is the same; when the text interpreter
detects an error, it discards any remaining text on a line, resets
certain internal state and prints an error message.  For a detailed
description of error messages see *note Error messages::.

   The text interpreter waits for you to press carriage-return, and then
processes your input line.  Starting at the beginning of the line, it
breaks the line into groups of characters separated by spaces.  For each
group of characters in turn, it makes two attempts to do something:

   * It tries to treat it as a command.  It does this by searching a
     "name dictionary".  If the group of characters matches an entry in
     the name dictionary, the name dictionary provides the text
     interpreter with information that allows the text interpreter to
     perform some actions.  In Forth jargon, we say that the group of
     characters names a "word", that the dictionary search returns an
     "execution token (xt)" corresponding to the "definition" of the
     word, and that the text interpreter executes the xt.  Often, the
     terms "word" and "definition" are used interchangeably.
   * If the text interpreter fails to find a match in the name
     dictionary, it tries to treat the group of characters as a number
     in the current number base (when you start up Forth, the current
     number base is base 10).  If the group of characters legitimately
     represents a number, the text interpreter pushes the number onto a
     stack (we'll learn more about that in the next section).

   If the text interpreter is unable to do either of these things with
any group of characters, it discards the group of characters and the
rest of the line, then prints an error message.  If the text interpreter
reaches the end of the line without error, it prints the status message
"' ok'" followed by carriage-return.

   This is the simplest command we can give to the text interpreter:

     <RET>  ok

   The text interpreter did everything we asked it to do (nothing)
without an error, so it said that everything is "' ok'".  Try a slightly
longer command:

     12 dup fred dup<RET>
     *the terminal*:3: Undefined word
     12 dup >>>fred<<< dup
     Backtrace:
     $2A95B42A20 throw
     $2A95B57FB8 no.extensions

   When you press the carriage-return key, the text interpreter starts
to work its way along the line:

   * When it gets to the space after the '2', it takes the group of
     characters '12' and looks them up in the name dictionary(1).  There
     is no match for this group of characters in the name dictionary, so
     it tries to treat them as a number.  It is able to do this
     successfully, so it puts the number, 12, "on the stack" (whatever
     that means).
   * The text interpreter resumes scanning the line and gets the next
     group of characters, 'dup'.  It looks it up in the name dictionary
     and (you'll have to take my word for this) finds it, and executes
     the word 'dup' (whatever that means).
   * Once again, the text interpreter resumes scanning the line and gets
     the group of characters 'fred'.  It looks them up in the name
     dictionary, but can't find them.  It tries to treat them as a
     number, but they don't represent any legal number.

   At this point, the text interpreter gives up and prints an error
message.  The error message shows exactly how far the text interpreter
got in processing the line.  In particular, it shows that the text
interpreter made no attempt to do anything with the final character
group, 'dup', even though we have good reason to believe that the text
interpreter would have no problem looking that word up and executing it
a second time.

   ---------- Footnotes ----------

   (1) We can't tell if it found them or not, but assume for now that it
did not

4.2 Stacks, postfix notation and parameter passing
==================================================

In procedural programming languages (like C and Pascal), the
building-block of programs is the "function" or "procedure".  These
functions or procedures are called with "explicit parameters".  For
example, in C we might write:

     total = total + new_volume(length,height,depth);

where new_volume is a function-call to another piece of code, and total,
length, height and depth are all variables.  length, height and depth
are parameters to the function-call.

   In Forth, the equivalent of the function or procedure is the
"definition" and parameters are implicitly passed between definitions
using a shared stack that is visible to the programmer.  Although Forth
does support variables, the existence of the stack means that they are
used far less often than in most other programming languages.  When the
text interpreter encounters a number, it will place ("push") it on the
stack.  There are several stacks (the actual number is
implementation-dependent ...)  and the particular stack used for any
operation is implied unambiguously by the operation being performed.
The stack used for all integer operations is called the "data stack"
and, since this is the stack used most commonly, references to "the data
stack" are often abbreviated to "the stack".

   The stacks have a last-in, first-out (LIFO) organisation.  If you
type:

     1 2 3<RET>  ok

   Then this instructs the text interpreter to placed three numbers on
the (data) stack.  An analogy for the behaviour of the stack is to take
a pack of playing cards and deal out the ace (1), 2 and 3 into a pile on
the table.  The 3 was the last card onto the pile ("last-in") and if you
take a card off the pile then, unless you're prepared to fiddle a bit,
the card that you take off will be the 3 ("first-out").  The number that
will be first-out of the stack is called the "top of stack", which is
often abbreviated to "TOS".

   To understand how parameters are passed in Forth, consider the
behaviour of the definition '+' (pronounced "plus").  You will not be
surprised to learn that this definition performs addition.  More
precisely, it adds two numbers together and produces a result.  Where
does it get the two numbers from?  It takes the top two numbers off the
stack.  Where does it place the result?  On the stack.  You can act out
the behaviour of '+' with your playing cards like this:

   * Pick up two cards from the stack on the table
   * Stare at them intently and ask yourself "what is the sum of these
     two numbers"
   * Decide that the answer is 5
   * Shuffle the two cards back into the pack and find a 5
   * Put a 5 on the remaining ace that's on the table.

   If you don't have a pack of cards handy but you do have Forth
running, you can use the definition '.s' to show the current state of
the stack, without affecting the stack.  Type:

     clearstacks 1 2 3<RET> ok
     .s<RET> <3> 1 2 3  ok

   The text interpreter looks up the word 'clearstacks' and executes it;
it tidies up the stacks (data and floating point stack) and removes any
entries that may have been left on them by earlier examples.  The text
interpreter pushes each of the three numbers in turn onto the stack.
Finally, the text interpreter looks up the word '.s' and executes it.
The effect of executing '.s' is to print the "<3>" (the total number of
items on the stack) followed by a list of all the items on the stack;
the item on the far right-hand side is the TOS.

   You can now type:

     + .s<RET> <2> 1 5  ok

which is correct; there are now 2 items on the stack and the result of
the addition is 5.

   If you're playing with cards, try doing a second addition: pick up
the two cards, work out that their sum is 6, shuffle them into the pack,
look for a 6 and place that on the table.  You now have just one item on
the stack.  What happens if you try to do a third addition?  Pick up the
first card, pick up the second card - ah!  There is no second card.
This is called a "stack underflow" and constitutes an error.  If you try
to do the same thing with Forth it often reports an error (probably a
Stack Underflow or an Invalid Memory Address error).

   The opposite situation to a stack underflow is a "stack overflow",
which simply accepts that there is a finite amount of storage space
reserved for the stack.  To stretch the playing card analogy, if you had
enough packs of cards and you piled the cards up on the table, you would
eventually be unable to add another card; you'd hit the ceiling.  Gforth
allows you to set the maximum size of the stacks.  In general, the only
time that you will get a stack overflow is because a definition has a
bug in it and is generating data on the stack uncontrollably.

   There's one final use for the playing card analogy.  If you model
your stack using a pack of playing cards, the maximum number of items on
your stack will be 52 (I assume you didn't use the Joker).  The maximum
value of any item on the stack is 13 (the King).  In fact, the only
possible numbers are positive integer numbers 1 through 13; you can't
have (for example) 0 or 27 or 3.52 or -2.  If you change the way you
think about some of the cards, you can accommodate different numbers.
For example, you could think of the Jack as representing 0, the Queen as
representing -1 and the King as representing -2.  Your range remains
unchanged (you can still only represent a total of 13 numbers) but the
numbers that you can represent are -2 through 10.

   In that analogy, the limit was the amount of information that a
single stack entry could hold, and Forth has a similar limit.  In Forth,
the size of a stack entry is called a "cell".  The actual size of a cell
is implementation dependent and affects the maximum value that a stack
entry can hold.  A Standard Forth provides a cell size of at least
16-bits, and most desktop systems use a cell size of 32-bits.

   Forth does not do any type checking for you, so you are free to
manipulate and combine stack items in any way you wish.  A convenient
way of treating stack items is as 2's complement signed integers, and
that is what Standard words like '+' do.  Therefore you can type:

     -5 12 + .s<RET> <1> 7  ok

   If you use numbers and definitions like '+' in order to turn Forth
into a great big pocket calculator, you will realise that it's rather
different from a normal calculator.  Rather than typing 2 + 3 = you had
to type 2 3 + (ignore the fact that you had to use '.s' to see the
result).  The terminology used to describe this difference is to say
that your calculator uses "Infix Notation" (parameters and operators are
mixed) whilst Forth uses "Postfix Notation" (parameters and operators
are separate), also called "Reverse Polish Notation".

   Whilst postfix notation might look confusing to begin with, it has
several important advantages:

   * it is unambiguous
   * it is more concise
   * it fits naturally with a stack-based system

   To examine these claims in more detail, consider these sums:

     6 + 5 * 4 =
     4 * 5 + 6 =

   If you're just learning maths or your maths is very rusty, you will
probably come up with the answer 44 for the first and 26 for the second.
If you are a bit of a whizz at maths you will remember the convention
that multiplication takes precedence over addition, and you'd come up
with the answer 26 both times.  To explain the answer 26 to someone who
got the answer 44, you'd probably rewrite the first sum like this:

     6 + (5 * 4) =

   If what you really wanted was to perform the addition before the
multiplication, you would have to use parentheses to force it.

   If you did the first two sums on a pocket calculator you would
probably get the right answers, unless you were very cautious and
entered them using these keystroke sequences:

   6 + 5 = * 4 = 4 * 5 = + 6 =

   Postfix notation is unambiguous because the order that the operators
are applied is always explicit; that also means that parentheses are
never required.  The operators are active (the act of quoting the
operator makes the operation occur) which removes the need for "=".

   The sum 6 + 5 * 4 can be written (in postfix notation) in two
equivalent ways:

     6 5 4 * +      or:
     5 4 * 6 +

   An important thing that you should notice about this notation is that
the order of the numbers does not change; if you want to subtract 2 from
10 you type '10 2 -'.

   The reason that Forth uses postfix notation is very simple to
explain: it makes the implementation extremely simple, and it follows
naturally from using the stack as a mechanism for passing parameters.
Another way of thinking about this is to realise that all Forth
definitions are active; they execute as they are encountered by the text
interpreter.  The result of this is that the syntax of Forth is
trivially simple.

4.3 Your first Forth definition
===============================

Until now, the examples we've seen have been trivial; we've just been
using Forth as a bigger-than-pocket calculator.  Also, each calculation
we've shown has been a "one-off" - to repeat it we'd need to type it in
again(1) In this section we'll see how to add new words to Forth's
vocabulary.

   The easiest way to create a new word is to use a "colon definition".
We'll define a few and try them out before worrying too much about how
they work.  Try typing in these examples; be careful to copy the spaces
accurately:

     : add-two 2 + . ;
     : greet ." Hello and welcome" ;
     : demo 5 add-two ;

Now try them out:

     greet<RET> Hello and welcome  ok
     greet greet<RET> Hello and welcomeHello and welcome  ok
     4 add-two<RET> 6  ok
     demo<RET> 7  ok
     9 greet demo add-two<RET> Hello and welcome7 11  ok

   The first new thing that we've introduced here is the pair of words
':' and ';'.  These are used to start and terminate a new definition,
respectively.  The first word after the ':' is the name for the new
definition.

   As you can see from the examples, a definition is built up of words
that have already been defined; Forth makes no distinction between
definitions that existed when you started the system up, and those that
you define yourself.

   The examples also introduce the words '.' (dot), '."' (dot-quote) and
'dup' (dewp).  Dot takes the value from the top of the stack and
displays it.  It's like '.s' except that it only displays the top item
of the stack and it is destructive; after it has executed, the number is
no longer on the stack.  There is always one space printed after the
number, and no spaces before it.  Dot-quote defines a string (a sequence
of characters) that will be printed when the word is executed.  The
string can contain any printable characters except '"'.  A '"' has a
special function; it is not a Forth word but it acts as a delimiter (the
way that delimiters work is described in the next section).  Finally,
'dup' duplicates the value at the top of the stack.  Try typing '5 dup
.s' to see what it does.

   We already know that the text interpreter searches through the
dictionary to locate names.  If you've followed the examples earlier,
you will already have a definition called 'add-two'.  Lets try modifying
it by typing in a new definition:

     : add-two dup . ." + 2 = " 2 + . ;<RET> redefined add-two  ok

   Forth recognised that we were defining a word that already exists,
and printed a message to warn us of that fact.  Let's try out the new
definition:

     9 add-two<RET> 9 + 2 = 11  ok

All that we've actually done here, though, is to create a new
definition, with a particular name.  The fact that there was already a
definition with the same name did not make any difference to the way
that the new definition was created (except that Forth printed a warning
message).  The old definition of add-two still exists (try 'demo' again
to see that this is true).  Any new definition will use the new
definition of 'add-two', but old definitions continue to use the version
that already existed at the time that they were 'compiled'.

   Before you go on to the next section, try defining and redefining
some words of your own.

   ---------- Footnotes ----------

   (1) That's not quite true.  If you press the up-arrow key on your
keyboard you should be able to scroll back to any earlier command, edit
it and re-enter it.

4.4 How does that work?
=======================

Now we're going to take another look at the definition of 'add-two' from
the previous section.  From our knowledge of the way that the text
interpreter works, we would have expected this result when we tried to
define 'add-two':

     : add-two 2 + . ;<RET>
     *the terminal*:4: Undefined word
     : >>>add-two<<< 2 + . ;

   The reason that this didn't happen is bound up in the way that ':'
works.  The word ':' does two special things.  The first special thing
that it does is to prevent the text interpreter from ever seeing the
characters 'add-two'.  The text interpreter uses a variable called '>IN'
(pronounced "to-in") to keep track of where it is in the input line.
When it encounters the word ':' it behaves in exactly the same way as it
does for any other word; it looks it up in the name dictionary, finds
its xt and executes it.  When ':' executes, it looks at the input
buffer, finds the word 'add-two' and advances the value of '>IN' to
point past it.  It then does some other stuff associated with creating
the new definition (including creating an entry for 'add-two' in the
name dictionary).  When the execution of ':' completes, control returns
to the text interpreter, which is oblivious to the fact that it has been
tricked into ignoring part of the input line.

   Words like ':' - words that advance the value of '>IN' and so prevent
the text interpreter from acting on the whole of the input line - are
called "parsing words".

   The second special thing that ':' does is change the value of a
variable called 'state', which affects the way that the text interpreter
behaves.  When Gforth starts up, 'state' has the value 0, and the text
interpreter is said to be "interpreting".  During a colon definition
(started with ':'), 'state' is set to -1 and the text interpreter is
said to be "compiling".

   In this example, the text interpreter is compiling when it processes
the string "'2 + . ;'".  It still breaks the string down into character
sequences in the same way.  However, instead of pushing the number '2'
onto the stack, it lays down ("compiles") some magic into the definition
of 'add-two' that will make the number '2' get pushed onto the stack
when 'add-two' is "executed".  Similarly, the behaviours of '+' and '.'
are also compiled into the definition.

   Certain kinds of words do not get compiled.  These so-called
"immediate words" get executed (performed now) regardless of whether the
text interpreter is interpreting or compiling.  The word ';' is an
immediate word.  Rather than being compiled into the definition, it
executes.  Its effect is to terminate the current definition, which
includes changing the value of 'state' back to 0.

   When you execute 'add-two', it has a "run-time effect" that is
exactly the same as if you had typed '2 + . <RET>' outside of a
definition.

   In Forth, every word or number can be described in terms of two
properties:

   * Its "interpretation semantics" describe how it will behave when the
     text interpreter encounters it in "interpret" state.  The
     interpretation semantics of a word are represented by its
     "execution token" (*note Execution token::).
   * Its "compilation semantics" describe how it will behave when the
     text interpreter encounters it in "compile" state.  The compilation
     semantics of a word are represented by its "compilation token"
     (*note Compilation token::).

Numbers are always treated in a fixed way:

   * When the number is "interpreted", its behaviour is to push the
     number onto the stack.
   * When the number is "compiled", a piece of code is appended to the
     current definition that pushes the number when it runs.  (In other
     words, the compilation semantics of a number are to postpone its
     interpretation semantics until the run-time of the definition that
     it is being compiled into.)

   Words don't always behave in such a regular way, but most have
default semantics which means that they behave like this:

   * The "interpretation semantics" of the word are to do something
     useful.
   * The "compilation semantics" of the word are to append its
     "interpretation semantics" to the current definition (so that its
     run-time behaviour is to do something useful).

   The actual behaviour of any particular word can be controlled by
using the words 'immediate' and 'compile-only' when the word is defined.
These words set flags in the name dictionary entry of the most recently
defined word, and these flags are retrieved by the text interpreter when
it finds the word in the name dictionary.

   A word that is marked as "immediate" has compilation semantics that
are identical to its interpretation semantics.  In other words, it
behaves like this:

   * The "interpretation semantics" of the word are to do something
     useful.
   * The "compilation semantics" of the word are to do something useful
     (and actually the same thing); i.e., it is executed during
     compilation.

   Marking a word as "compile-only" means that the text interpreter
produces a warning when encountering this word in interpretation state;
ticking the word (with ''' or '[']' also produces a warning.

   It is never necessary to use 'compile-only' (and it is not even part
of Standard Forth, though it is provided by many implementations) but it
is good etiquette to apply it to a word that will not behave correctly
(and might have unexpected side-effects) in interpret state.  For
example, it is only legal to use the conditional word 'IF' within a
definition.  If you forget this and try to use it elsewhere, the fact
that (in Gforth) it is marked as 'compile-only' allows the text
interpreter to generate a helpful warning.

   This example shows the difference between an immediate and a
non-immediate word:

     : show-state state @ . ;
     : show-state-now show-state ; immediate
     : word1 show-state ;
     : word2 show-state-now ;

   The word 'immediate' after the definition of 'show-state-now' makes
that word an immediate word.  These definitions introduce a new word:
'@' (pronounced "fetch").  This word fetches the value of a variable,
and leaves it on the stack.  Therefore, the behaviour of 'show-state' is
to print a number that represents the current value of 'state'.

   When you execute 'word1', it prints the number 0, indicating that the
system is interpreting.  When the text interpreter compiled the
definition of 'word1', it encountered 'show-state' whose compilation
semantics are to append its interpretation semantics to the current
definition.  When you execute 'word1', it performs the interpretation
semantics of 'show-state'.  At the time that 'word1' (and therefore
'show-state') is executed, the system is interpreting.

   When you pressed <RET> after entering the definition of 'word2', you
should have seen the number -1 printed, followed by "' ok'".  When the
text interpreter compiled the definition of 'word2', it encountered
'show-state-now', an immediate word, whose compilation semantics are
therefore to perform its interpretation semantics.  It is executed
straight away (even before the text interpreter has moved on to process
another group of characters; the ';' in this example).  The effect of
executing it is to display the value of 'state' at the time that the
definition of 'word2' is being defined.  Printing -1 demonstrates that
the system is compiling at this time.  If you execute 'word2' it does
nothing at all.

   Before leaving the subject of immediate words, consider the behaviour
of '."' in the definition of 'greet', in the previous section.  This
word is both a parsing word and an immediate word.  Notice that there is
a space between '."' and the start of the text 'Hello and welcome', but
that there is no space between the last letter of 'welcome' and the '"'
character.  The reason for this is that '."' is a Forth word; it must
have a space after it so that the text interpreter can identify it.  The
'"' is not a Forth word; it is a "delimiter".  The examples earlier show
that, when the string is displayed, there is neither a space before the
'H' nor after the 'e'.  Since '."' is an immediate word, it executes at
the time that 'greet' is defined.  When it executes, its behaviour is to
search forward in the input line looking for the delimiter.  When it
finds the delimiter, it updates '>IN' to point past the delimiter.  It
also compiles some magic code into the definition of 'greet'; the xt of
a run-time routine that prints a text string.  It compiles the string
'Hello and welcome' into memory so that it is available to be printed
later.  When the text interpreter gains control, the next word it finds
in the input stream is ';' and so it terminates the definition of
'greet'.

4.5 Forth is written in Forth
=============================

When you start up a Forth compiler, a large number of definitions
already exist.  In Forth, you develop a new application using bottom-up
programming techniques to create new definitions that are defined in
terms of existing definitions.  As you create each definition you can
test and debug it interactively.

   If you have tried out the examples in this section, you will probably
have typed them in by hand; when you leave Gforth, your definitions will
be lost.  You can avoid this by using a text editor to enter Forth
source code into a file, and then loading code from the file using
'include' (*note Forth source files::).  A Forth source file is
processed by the text interpreter, just as though you had typed it in by
hand(1).

   Gforth also supports the traditional Forth alternative to using text
files for program entry (*note Blocks::).

   In common with many, if not most, Forth compilers, most of Gforth is
actually written in Forth.  All of the '.fs' files in the installation
directory(2) are Forth source files, which you can study to see examples
of Forth programming.

   Gforth maintains a history file that records every line that you type
to the text interpreter.  This file is preserved between sessions, and
is used to provide a command-line recall facility.  If you enter long
definitions by hand, you can use a text editor to paste them out of the
history file into a Forth source file for reuse at a later time (for
more information *note Command-line editing::).

   ---------- Footnotes ----------

   (1) Actually, there are some subtle differences - see *note The Text
Interpreter::.

   (2) For example, '/usr/local/share/gforth...'

4.6 Review - elements of a Forth system
=======================================

To summarise this chapter:

   * Forth programs use "factoring" to break a problem down into small
     fragments called "words" or "definitions".
   * Forth program development is an interactive process.
   * The main command loop that accepts input, and controls both
     interpretation and compilation, is called the "text interpreter"
     (also known as the "outer interpreter").
   * Forth has a very simple syntax, consisting of words and numbers
     separated by spaces or carriage-return characters.  Any additional
     syntax is imposed by "parsing words".
   * Forth uses a stack to pass parameters between words.  As a result,
     it uses postfix notation.
   * To use a word that has previously been defined, the text
     interpreter searches for the word in the "name dictionary".
   * Words have "interpretation semantics" and "compilation semantics".
   * The text interpreter uses the value of 'state' to select between
     the use of the "interpretation semantics" and the "compilation
     semantics" of a word that it encounters.
   * The relationship between the "interpretation semantics" and
     "compilation semantics" for a word depends upon the way in which
     the word was defined (for example, whether it is an "immediate"
     word).
   * Forth definitions can be implemented in Forth (called "high-level
     definitions") or in some other way (usually a lower-level language
     and as a result often called "low-level definitions", "code
     definitions" or "primitives").
   * Many Forth systems are implemented mainly in Forth.

4.7 Where To Go Next
====================

Amazing as it may seem, if you have read (and understood) this far, you
know almost all the fundamentals about the inner workings of a Forth
system.  You certainly know enough to be able to read and understand the
rest of this manual and the Standard Forth document, to learn more about
the facilities that Forth in general and Gforth in particular provide.
Even scarier, you know almost enough to implement your own Forth system.
However, that's not a good idea just yet...  better to try writing some
programs in Gforth.

   Forth has such a rich vocabulary that it can be hard to know where to
start in learning it.  This section suggests a few sets of words that
are enough to write small but useful programs.  Use the word index in
this document to learn more about each word, then try it out and try to
write small definitions using it.  Start by experimenting with these
words:

   * Arithmetic: '+ - * / /MOD */ ABS INVERT'
   * Comparison: 'MIN MAX ='
   * Logic: 'AND OR XOR NOT'
   * Stack manipulation: 'DUP DROP SWAP OVER'
   * Loops and decisions: 'IF ELSE THEN ?DO I LOOP'
   * Input/Output: '. ." EMIT CR KEY'
   * Defining words: ': ; CREATE'
   * Memory allocation words: 'ALLOT ,'
   * Tools: 'SEE WORDS .S MARKER'

   When you have mastered those, go on to:

   * More defining words: 'VARIABLE CONSTANT VALUE TO CREATE DOES>'
   * Memory access: '@ !'

   When you have mastered these, there's nothing for it but to read
through the whole of this manual and find out what you've missed.

4.8 Exercises
=============

TODO: provide a set of programming exercises linked into the stuff done
already and into other sections of the manual.  Provide solutions to all
the exercises in a .fs file in the distribution.

5 Literals in source code
*************************

5.1 Integer and character literals
==================================

To push an integer number on the data stack, you write the number in
source code, e.g., '123'.  You can prefix the digits with '-' to
indicate a negative number, e.g.  '-123'.  This works both inside colon
definitions and outside.  The number is interpreted according to the
value in 'base' (*note Number Conversion::).  The digits are '0' to '9'
and 'a' (decimal 10) to 'z' (decimal 35), but only digits smaller than
'base @' are recognized.  The conversion is case-insensitive, so 'A' and
'a' are the same digit.

   You can make the base explicit for the number by using a prefix:

   * '#' - decimal
   * '%' - binary
   * '$' - hexadecimal
   * '&' - decimal (non-standard)
   * '0x' - hexadecimal, if base<33 (non-standard).

   For combinations including base-prefix and sign, the standard order
is to have the base-prefix first (e.g., '#-123'); Gforth supports both
orders.

   You can put a decimal point '.' at the end of a number (or,
non-standardly, anywhere else except before a prefix) to get a
double-cell integer (e.g., '#-123.' or '#-.123' (the same number)).  If
users experienced in another programming language see or write such a
number without base prefix (e.g., '-123.'), they may expect that the
number represents a floating-point value.  To clear up the confusion
early, Gforth warns of such usage; to avoid the warnings, the best
approach is to always write double numbers with a base prefix (e.g.,
'#-123.')

   Here are some examples, with the equivalent decimal number shown
after in braces:

   '$-41' (-65), '%1001101' (205), '%1001.0001' (145, a double-precision
number), '#905' (905), '$abc' (2478), '$ABC' (2478).

   You can get the numeric value of a (character) code point by
surrounding the character with ''' (e.g., ''a'').  The trailing ''' is
required by the standard, but you can leave it away in Gforth.  Note
that this also works for non-ASCII characters.  For many uses, it is
more useful to have the character as a string rather than as a cell; see
below for the string syntax.

5.2 Floating-point number and complex literals
==============================================

For floating-point numbers in Forth, you recognize them due to their
exponent.  I.e.  '1.' is a double-cell integer, and '1e0' is a
floating-point number; the latter can be (and usually is) shortened to
'1e'.  Both the significand (the part before the 'e' or 'E') and the
exponent may have signs (including '+'); the significand must contain at
least one digit and may contain a decimal point, the exponent can be
empty.  Floating-point numbers always use decimal base for both
significand and exponent, and are only recognized when the base is
decimal.  Examples are: '1e 1e0 1.e 1.e0 +1e+0' (which all represent the
same number) '+12.E-4'.

   A Gforth extension (since 1.0) is to write a floating-point number in
scaled notation: It can optionally have a sign, then one or more digits,
then use one of the mostly SI-defined scaling symbols (aka metric
prefixes) or '%', and then optionally more digits.  Here's the full list
of scaling symbols that Gforth accepts:

   * 'Q' 'e30' quetta
   * 'R' 'e27' ronna
   * 'Y' 'e24' yotta
   * 'Z' 'e21' zetta
   * 'X' 'e18' exa (not 'E')
   * 'P' 'e15' peta
   * 'T' 'e12' tera
   * 'G' 'e9' giga
   * 'M' 'e6' mega
   * 'k' 'e3' kilo
   * 'h' 'e2' hecto
   * 'd' 'e-1' deci
   * '%' 'e-2' percent (not 'c')
   * 'm' 'e-3' milli
   * 'u' 'e-6' micro (not 'μ')
   * 'n' 'e-9' nano
   * 'p' 'e-12' pico
   * 'f' 'e-15' femto
   * 'a' 'e-18' atto
   * 'z' 'e-21' zepto
   * 'y' 'e-24' yocto
   * 'r' 'e-27' ronto
   * 'q' 'e-30' quecto

   Unlike most of the rest of Gforth, scaling symbols are treated
case-sensitively.  Using the scaled notation is equivalent to using a
decimal point instead of the scaling symbol and appending the
exponential notation at the end.  Examples of scaled notation: '6k5'
(6500e) '23%' (0.23e).

   In Gforth (since 1.0) you can input a complex number with
'real+imaginaryi', where both 'real' and 'imaginary' are strings that
are recognized as floating-point numbers.  E.g., '1e+2ei'.  This pushes
the values '1e' and '2e' on the floating-point stack, so one might just
as well have written '1e 2e', but '1e+2ei' makes the intent obvious.

5.3 String and environment variable literals
============================================

In Gforth (since 1.0) you can input a string by surrounding it with '"'
(e.g.  '"abc"', '"a b"').  The result is the starting address and byte
(=char) count of the string on the data stack.

   You have to escape any '"' inside the string with '\' (e.g.,
'"double-quote->\"<-"').  In addition, this string syntax supports all
the ways to write control characters that are supported by 's\"' (*note
String and character literals::).  A disadvantage of this string syntax
is that it is non-standard; for standard programs, use 's\"' instead.

   In Gforth (since 1.0) you can input an environment variable by
surrounding its name with '${'...'}', e.g., '${HOME}'; the result is a
string descriptor on the data stack in the format described above.  This
is equivalent to '"HOME" getenv', i.e., the environment variable is
resolved at run-time.

5.4 Literals for tokens and addresses
=====================================

Gforth (since 1.0) also recognizes the following literals:

   You can input an execution token (xt) of a word by prefixing the name
of the word with the backquote '`' (e.g., '`dup').  An advantage over
using ''' or '[']' is you do not need to switch between them when
copying and pasting code from inside to outside a colon definition or
vice versa.  A disadvantage is that this syntax is non-standard.

   You can input a name token (nt) of a word by prefixing the name of
the word with '``' (e.g., '``dup').  This syntax is also non-standard.

   You can input a body address of a word by surrounding it with '<' and
'>' (e.g., '<spaces>').  You can also input an address that is at a
positive offset from the body address (typically an address in that
body), by putting '+' and a number (see syntax above) between the word
name and the closing '>' (e.g., '<spaces+$15>', '<spaces+-3>').  You
will get the body address plus the number.  This feature exists to allow
copying and pasting the output of '...' (*note Examining data::).

   In addition, by default Gforth recognizes words with 'rec-nt' and
'rec-scope', and stores in or adds to value-flavoured words with
'rec-to', but these do not recognize literals, so they are discussed
elsewhere (*note Default Recognizers::).

5.5 Disambiguating recognizers
==============================

In some cases where two recognizers match the same string, you can
specify in Gforth (since 1.0) which recognizer you want to use, with
'recognizer?string', where 'recognizer' is the name of the recognizer
without the 'rec-' prefix, and 'string' is the string you want to
recognize.  E.g., 'float?1.' uses 'rec-float' to recognize a string that
would otherwise be recognized as a double-cell integer number (because
'rec-num' is earlier in the recognizer sequence than 'rec-float').

6 Forth Words
*************

6.1 Notation
============

The Forth words are described in this section in the glossary notation
that has become a de-facto standard for Forth texts:

word     Stack effect   wordset   pronunciation
   Description

WORD
     The name of the word.

STACK EFFECT
     The stack effect is written in the notation 'before -- after',
     where before and after describe the top of stack entries before and
     after the execution of the word.  The rest of the stack is not
     touched by the word.  The top of stack is rightmost, i.e., a stack
     sequence is written as it is typed in.

     Gforth has several stacks, in particular, the data stack, return
     stack and floating-point stack.  However, it uses a unified stack
     effect notation, where one stack effect description describes all
     three stack effects, and the name of the item indicates which stack
     the item is on: floating-point stack items start with r.  Return
     stack items are prefixed with R:, but are otherwise the same as
     data stack items.  E.g., in the stack effect '( w1 w2 -- R:w1 R:w2
     )' w1 is a cell on the data stack, and R:w1 is a cell on the return
     stack with the same value.  So a unified stack effect

          ( r1 n1 R:n2 -- R:n3 n4 r2 )

     is equivalent to the separated stack effect notation

          ( n1 -- n4 ) ( R: n2 -- n3 ) ( F: r1 -- r2 )

     The name of a stack item describes the type and/or the function of
     the item.  See below for a discussion of the types.

     Words generally have different stack effects in different contexts.
     If only one stack effect is shown, it's the stack effect for the
     execution/interpretation semantics.(1)  The stack effect of default
     compilation semantics is '( -- )' and is not shown.

     The stack-effects of non-default compilation semantics are shown if
     they are other than '( -- )'.  Such words usually also have a
     run-time semantics, and their stack effects are then shown as in
     this example

          ; ( compilation colon-sys -- ; run-time nest-sys -- )

     Further stack effects, such as those of defined words, of passed
     xts, are shown in the description part of the glossary entry.

     Also note that in code templates or examples there can be comments
     in parentheses that display the stack picture at this point; there
     is no '--' in these places, because there is no before-after
     situation.

PRONUNCIATION
     How the word is pronounced.

WORDSET
     The wordset specifies if a word has been standardized (indicated by
     a capitalized wordset name), it is an environmental query string
     (indicated by "environment"), or if it is a Gforth-specific word
     (lower case).

     The Forth standard is divided into several word sets.  In theory, a
     standard system need not support all of them, but in practice,
     serious systems on non-tiny machines support almost all
     standardized words (some systems require explicit loading of some
     word sets, however), so it does not increase portability in
     practice to be parsimonious in using word sets.

     For the Gforth-specific words, we have the following categories:

     'gforth'
     'gforth-<version>'
          We intend to permanently support this word in Gforth and it
          has been available since Gforth <version> (possibly not as
          stable word at that time).

          You see 'gforth' in the source code (e.g., when using
          'locate'), and 'gforth-<version>' in the documentation (e.g.,
          when using 'help').  So if you want to know since which Gforth
          version a word is available, use 'help word'.

     'library'
          The word belongs to a library that is independent of Gforth,
          but is delivered with Gforth and documented in this manual.
          Gforth 1.0 includes libraries with the following wordset
          names: mini-oof mini-oof2 minos2 minos2-bidi objects oof
          regexp-cg regexp-pattern regexp-replace cilk

     'gforth-experimental'
          This word is available in the present version and may turn
          into a stable word or may be removed in a future release of
          Gforth.  Feedback welcome.

     'gforth-internal'
          This word is an internal factor, not a supported word, and it
          may be removed in a future release of Gforth.  If you see a
          word in the source code (e.g., with 'locate') without a
          wordset, that word is also an internal factor.

     'gforth-obsolete'
          This word will be removed in a future release of Gforth.

DESCRIPTION
     A description of the behaviour of the word.

   The type of a stack item is specified by the prefix of the name:

'f'
     Boolean flags, i.e.  'false' or 'true'.
'c'
     Char
'w'
'x'
     Cell, can contain an integer or an address
'n'
     signed integer
'u'
     unsigned integer
'd'
     signed double-cell integer
'ud'
     unsigned double-cell integer
'r'
     Float (on the FP stack)
'addr'
     Address without further information
'a-'
     Cell-aligned address
'c-'
     Char-aligned address, address used to point to a character or start
     of a string.
'f-'
     Float-aligned address
'df-'
     Address aligned for IEEE double precision float
'sf-'
     Address aligned for IEEE single precision float
'xt'
     Execution token, same size as Cell
'nt'
     Name token, same size as Cell
'wid'
     Word list ID, same size as Cell
'ior, wior'
     I/O result code, cell-sized.  In Gforth, you can 'throw' iors.
'"'
     String in the input stream (not on the stack), typically
     space-delimited.
'''
     String in the input stream, delimited by the last character before
     the closing '''.  E.g., ''ccc"'' indicates a string in the input
     stream that is terminated by '"'.

   ---------- Footnotes ----------

   (1) Gforth 1.0 does not make a difference between interpretation and
execution semantics.

6.2 Case insensitivity
======================

Gforth is case-insensitive for ASCII characters and case-sensitive for
non-ASCII characters.  I.e., you can invoke Standard words using upper,
lower or mixed case.

   For now, Standard Forth only requires implementations to recognise
Standard words when they are typed entirely in upper case.  You can use
whatever case you like for words that you define, but in a Standard
program you have to use the words in the same case that you defined
them.

   Gforth supports case sensitivity through 'cs-wordlist's
(case-sensitive wordlists, *note Word Lists::).

6.3 Comments
============

Forth supports two styles of comment; the in-line comment starting with
'(' and ending with ')', and the comment to the end of the line line
starting with '\'.  Don't forget the space after the starting word.

'(' ( compilation 'ccc<close-paren>' - ; run-time -  ) core,file "paren"
   Comment, usually till the next ')': parse and discard all subsequent
characters in the parse area until ")" is encountered.  During
interactive input, an end-of-line also acts as a comment terminator.
For file input, it does not; if the end-of-file is encountered whilst
parsing for the ")" delimiter, Gforth will generate a warning.

'\' ( compilation 'ccc<newline>' - ; run-time -  ) core-ext,block-ext "backslash"
   Comment until the end of line: parse and discard all remaining
characters in the parse area, except while 'load'ing from a block: while
'load'ing from a block, parse and discard all remaining characters in
the 64-byte line.

'\G' ( compilation 'ccc<newline>' - ; run-time -  ) gforth-0.2 "backslash-gee"
   Equivalent to '\'.  Used right below the start of a definition to
describe the behaviour of a word.  In Gforth's source code these
comments are those that are then inserted in the documentation.

6.4 Boolean Flags
=================

A Boolean flag is cell-sized.  A cell with all bits clear represents the
flag 'false' and a flag with all bits set represents the flag 'true'.
Words that check a flag (for example, 'IF') will treat a cell that has
any bit set as 'true'.

'true' ( - f  ) core-ext
   'Constant' - f is a cell with all bits set.

'false' ( - f  ) core-ext
   'Constant' - f is a cell with all bits clear.

'on' ( a-addr -  ) gforth-0.2
   Set the (value of the) variable at a-addr to 'true'.

'off' ( a-addr -  ) gforth-0.2
   Set the (value of the) variable at a-addr to 'false'.

'select' ( u1 u2 f - u ) gforth-1.0 "select"
   If f is false, u is u2, otherwise u1.

6.5 Arithmetic
==============

Forth arithmetic is not checked, i.e., you will not hear about integer
overflow on addition or multiplication, you may hear about division by
zero if you are lucky.  The operator is written after the operands, but
the operands are still in the original order.  I.e., the infix '2-1'
corresponds to '2 1 -'.

6.5.1 Single precision
----------------------

By default, numbers in Forth are single-precision integers that are one
cell (a machine word, e.g., 64 bits on a 64-bit system) in size.  They
can be signed or unsigned, depending upon how you treat them.  For the
rules used by the text interpreter for recognising single-precision
integers see *note Literals::.

   '+', '1+', 'under+', '-', '1-', '*' are defined for signed operands,
but they also work for unsigned numbers.  For division words see *note
Integer division::.

'+' ( n1 n2 - n ) core "plus"

'1+' ( n1 - n2 ) core "one-plus"

'under+' ( n1 n2 n3 - n n2 ) gforth-0.3 "under-plus"
   add n3 to n1 (giving n)

'-' ( n1 n2 - n ) core "minus"

'1-' ( n1 - n2 ) core "one-minus"

'*' ( n1 n2 - n ) core "star"

'negate' ( n1 - n2 ) core "negate"

'abs' ( n - u ) core "abs"

'min' ( n1 n2 - n ) core "min"

'max' ( n1 n2 - n ) core "max"

'umin' ( u1 u2 - u ) gforth-0.5 "umin"

'umax' ( u1 u2 - u ) gforth-1.0 "umax"

6.5.2 Double precision
----------------------

For the rules used by the text interpreter for recognising
double-precision integers, see *note Literals::.

   A double precision number is represented by a cell pair, with the
most significant cell at the top-of-stack (TOS). It is trivial to
convert an unsigned single to a double: simply push a '0' onto the TOS.
Numbers are represented by Gforth using 2's complement arithmetic, so
converting a signed single to a (signed) double requires sign-extension
across the most significant cell.  This can be achieved using 's>d'.
You cannot convert a number from single-cell to double-cell without
knowing whether it represents an unsigned or a signed number.  By
contrast, in 2's complement arithmetic the conversion from double to
single just 'drop's the most significant cell, and 'd>s' just documents
the intent.

   'D+' and 'd-' are defined for signed operands, but also work for
unsigned numbers.

's>d' ( n - d  ) core "s-to-d"

'd>s' ( d - n  ) double "d-to-s"

'd+' ( ud1 ud2 - ud ) double "d-plus"

'd-' ( d1 d2 - d ) double "d-minus"

'dnegate' ( d1 - d2 ) double "d-negate"

'dabs' ( d - ud  ) double "d-abs"

'dmin' ( d1 d2 - d  ) double "d-min"

'dmax' ( d1 d2 - d  ) double "d-max"

6.5.3 Mixed precision
---------------------

'm+' ( d1 n - d2 ) double "m-plus"

'm*' ( n1 n2 - d ) core "m-star"

'um*' ( u1 u2 - ud ) core "u-m-star"

6.5.4 Integer division
----------------------

Below you find a considerable number of words for dealing with
divisions.  A major difference between them is in dealing with signed
division: Do the words support signed division?  Those with the 'u'
prefix do not.

   Do signed division words round towards negative infinity (floored
division, suffix 'F'), or towards 0 (symmetric division, suffix 'S').
The standard leaves the issue implementation-defined for most standard
words ('/ mod /mod */ */mod m*/').  Gforth implements these words as
floored (since Gforth 0.7), but there are systems that implement them as
symmetric.  There is only a difference between floored and symmetric
division if the dividend and the divisor have different signs, and the
dividend is not a multiple of the divisor.  The following table
illustrates the results:

                           floored          symmetric
     dividend divisor remainder quotient remainder quotient
         10      7           3   1              3   1
        -10      7           4  -2             -3  -1
         10     -7          -4  -2              3  -1
        -10     -7          -3   1             -3   1

   The common case where floored vs. symmetric makes a difference is
when dividends n1 with varying sign are divided by the same positive
divisor n2; in that case you usually want floored division, because then
the remainder is always positive and does not change sign depending on
the dividend; also, with floored division, the quotient always increases
by 1 when n1 increases by n2, while with symmetric division there is no
increase in the quotient for -n2<n1<n2 (the quotient is 0 in this
range).

   In any case, if you divide numbers where floored vs. symmetric makes
a difference, you should think about which variant is the right one for
you, and then use either the appropriately suffixed Gforth words, or the
standard words 'fm/mod' or 'sm/rem'.

   In the following, "remainder" (symmetric) has the same sign as the
dividend or is 0, while "modulus" (floored) has the same sign as the
divisor or is 0.

   The following words perform single-by-single-cell division:

'/' ( n1 n2 - n  ) core "slash"
   n=n1/n2

'/s' ( n1 n2 - n ) gforth-1.0 "slash-s"

'/f' ( n1 n2 - n ) gforth-1.0 "slash-f"

'u/' ( u1 u2 - u ) gforth-1.0 "u-slash"

'mod' ( n1 n2 - n  ) core
   n is the modulus of n1/n2

'mods' ( n1 n2 - n ) gforth-1.0 "mod-s"

'modf' ( n1 n2 - n ) gforth-1.0 "modf"

'umod' ( u1 u2 - u ) gforth-1.0 "umod"

'/mod' ( n1 n2 - n3 n4  ) core "slash-mod"
   n1=n2*n4+n3; n3 is the modulus, n4 the quotient.

'/mods' ( n1 n2 - n3 n4 ) gforth-1.0 "slash-mod-s"
   n1=n2*n4+n3; n3 is the remainder, n4 the quotient

'/modf' ( n1 n2 - n3 n4 ) gforth-1.0 "slash-mod-f"
   n1=n2*n4+n3; n3 is the modulus, n4 the quotient

'u/mod' ( u1 u2 - u3 u4 ) gforth-1.0 "u-slash-mod"
   u1=u2*u4+u3; u3 is the modulus, u4 the quotient

   The following words perform double-by-single-cell division with
single-cell results; these words are roughly as fast as the words above
on some architectures (e.g., AMD64), but much slower on others (e.g., an
order of magnitude on various ARM A64 CPUs).

'fm/mod' ( d1 n1 - n2 n3 ) core "f-m-slash-mod"
   Floored division: d1 = n3*n1+n2, n1>n2>=0 or 0>=n2>n1.

'sm/rem' ( d1 n1 - n2 n3 ) core "s-m-slash-rem"
   Symmetric division: d1 = n3*n1+n2, sign(n2)=sign(d1) or 0.

'um/mod' ( ud u1 - u2 u3 ) core "u-m-slash-mod"
   ud=u3*u1+u2, 0<=u2<u1

'du/mod' ( d u - n u1 ) gforth-1.0 "du-slash-mod"
   d=n*u+u1, 0<=u1<u; PolyForth style mixed division

'*/' ( ( n1 n2 n3 - n4  ) core "star-slash"
   n4=(n1*n2)/n3, with the intermediate result being double

'*/s' ( n1 n2 n3 - n4 ) gforth-1.0 "star-slash-s"
   n4=(n1*n2)/n3, with the intermediate result being double

'*/f' ( n1 n2 n3 - n4 ) gforth-1.0 "star-slash-f"
   n4=(n1*n2)/n3, with the intermediate result being double

'u*/' ( u1 u2 u3 - u4 ) gforth-1.0 "u-star-slash"
   u4=(u1*u2)/u3, with the intermediate result being double.

'*/mod' ( n1 n2 n3 - n4 n5  ) core "star-slash-mod"
   n1*n2=n3*n5+n4, with the intermediate result (n1*n2) being double; n4
is the modulus, n5 the quotient.

'*/mods' ( n1 n2 n3 - n4 n5 ) gforth-1.0 "star-slash-mod-s"
   n1*n2=n3*n5+n4, with the intermediate result (n1*n2) being double; n4
is the remainder, n5 the quotient

'*/modf' ( n1 n2 n3 - n4 n5 ) gforth-1.0 "star-slash-mod-f"
   n1*n2=n3*n5+n4, with the intermediate result (n1*n2) being double; n4
is the modulus, n5 the quotient

'u*/mod' ( u1 u2 u3 - u4 u5 ) gforth-1.0 "u-star-slash-mod"
   u1*u2=u3*u5+u4, with the intermediate result (u1*u2) being double.

   The following words perform division with double-cell results; these
words are much slower than the words above.

'ud/mod' ( ud1 u2 - urem udquot  ) gforth-0.2 "ud-slash-mod"
   divide unsigned double ud1 by u2, resulting in a unsigned double
quotient udquot and a single remainder urem.

'm*/' ( d1 n2 u3 - dquot  ) double "m-star-slash"
   dquot=(d1*n2)/u3, with the intermediate result being
triple-precision.  In Forth-2012 u3 is only allowed to be a positive
signed number.

   You can use the environmental query 'floored' (*note Environmental
Queries::) to learn whether '/ mod /mod */ */mod m*/' use floored or
symmetric division on the system your program is being loaded on;
alternatively, '-1 3 /' also produces -1 on floored and 0 on symmetric
systems.

   One other aspect of the integer division words is that most of them
can overflow, and division by zero is mathematically undefined.  What
happens if you hit one of these conditions depends on the engine, the
hardware, and the operating system: The engine 'gforth' tries hard to
throw the appropriate error -10 (Division by zero) or -11 (Result out of
range), but on some platforms throws -55 (Floating-point unidentified
fault).  The engine 'gforth-fast' may produce an inappropriate throw
code (and error message), or may produce no error, just produce a bogus
value.  I.e., you should not bet on such conditions being thrown, but
for quicker debugging 'gforth' catches more and produces more accurate
errors than 'gforth-fast'.

6.5.5 Two-stage integer division
--------------------------------

On most hardware, multiplication is significantly faster than division.
So if you have to divide many numbers by the same divisor, it is usually
faster to determine the reciprocal of the divisor once and multiply the
numbers with the reciprocal.  If you divide by a constant, Gforth
performs this optimization automatically.

   However, for cases where the divisor is not known during compilation,
Gforth provides words that allow you to implement this optimization
without to much fuss.

   Let's start with an example: You want to divide all elements of an
array of cells by the same number n.  A straightforward way to implement
this is:

     : array/ ( addr u n -- )
       -rot cells bounds u+do
         i @ over / i !
       1 cells +loop
       drop ;

   A possibly more efficient version looks like this:

     : array/ ( addr u n -- )
       {: | reci[ staged/-size ] :}
       reci[ /f-stage1m
       cells bounds u+do
         i @ reci[ /f-stage2m i !
       1 cells +loop ;

   This example first creates a local buffer 'reci[' with size
'staged/-size' for storing the reciprocal data.  Then '/f-stage1m'
computes the reciprocal of n and stores it in 'reci['.  Finally, inside
the loop '/f-stage2m' uses the data in 'reci[' to compute the quotient.

   There are some limitations: Only positive divisors are supported for
'/f-stage1m'; for 'u/-stage1m' you can use a divisor of 2 or higher.
You get an error if you try to use an unsupported divisor.  You must
initialize the reciprocal buffer for the floored second-stage words with
'/f-stage1m' and for the unsigned second-stage words with 'u/-stage1m'.
You must not modify the reciprocal buffer between the first stage and
the second stage; basically, don't treat it as a memory buffer, but as
something that is only mutable by the first stage; the point of this
rule is that future versions of Gforth will not consider aliasing of
this buffer.

   Measurements show that staged division is not always beneficial:

     break  100 elem
     even   speedup  core
       7      2.09   Skylake (Core i5-6600K)
       -      0.94   Rocket Lake (Xeon E-2388G)
      40      1.09   Golden Cove (Core i3-1315U P-core)
       -      0.85   Gracemont (Core i3-1315U E-core)
       6      1.68   Zen2 (Ryzen 9 3900X)
       -      0.56   Zen3 (Ryzen 7 5800X)

   The words are:

'staged/-size' ( - u  ) gforth-1.0 "staged-slash-size"
   Size of buffer for 'u/-stage1m' or '/f-stage1m'.

'/f-stage1m' ( n a-reci -  ) gforth-1.0 "slash-f-stage1m"
   Compute the reciprocal of n and store it in the buffer a-reci of size
'staged/-size'.  Throws an error if n<1.

'/f-stage2m' ( n1 a-reci - nquotient ) gforth-1.0 "slash-f-stage2m"
   Nquotient is the result of dividing n1 by the divisor represented by
a-reci, which was computed by '/f-stage1m'.

'modf-stage2m' ( n1 a-reci - umodulus ) gforth-1.0 "mod-f-stage2m"
   Umodulus is the remainder of dividing n1 by the divisor represented
by a-reci, which was computed by '/f-stage1m'.

'/modf-stage2m' ( n1 a-reci - umodulus nquotient ) gforth-1.0 "slash-mod-f-stage2m"
   Nquotient is the quotient and umodulus is the remainder of dividing
n1 by the divisor represented by a-reci, which was computed by
'/f-stage1m'.

'u/-stage1m' ( u a-reci -  ) gforth-1.0 "u-slash-stage1m"
   Compute the reciprocal of u and store it in the buffer a-reci of size
'staged/-size'.  Throws an error if u<2.

'u/-stage2m' ( u1 a-reci - uquotient ) gforth-1.0 "u-slash-stage2m"
   Uquotient is the result of dividing u1 by the divisor represented by
a-reci, which was computed by 'u/-stage1m'.

'umod-stage2m' ( u1 a-reci - umodulus ) gforth-1.0 "u-mod-stage2m"
   Umodulus is the remainder of dividing u1 by the divisor represented
by a-reci, which was computed by 'u/-stage1m'.

'u/mod-stage2m' ( u1 a-reci - umodulus uquotient ) gforth-1.0 "u-slash-mod-stage2m"
   Uquotient is the quotient and umodulus is the remainder of dividing
u1 by the divisor represented by a-reci, which was computed by
'u/-stage1m'.

   Gforth currently does not support staged symmetrical division.

   You can recover the divisor from (the address of) a reciprocal with
'staged/-divisor @':

'staged/-divisor' ( addr1 - addr2  ) gforth-1.0 "staged-slash-divisor"
   Addr1 is the address of a reciprocal, addr2 is the address containing
the divisor from which the reciprocal was computed.

   This can be useful when looking at the decompiler output of Gforth: a
division by a constant is often compiled to a literal containing the
address of a reciprocal followed by a second-stage word.

   The performance impact of using these words strongly depends on the
architecture (does it have hardware division?)  and the specific
implementation (how fast is hardware division?), but just to give you an
idea about the relative performance of these words, here are the cycles
per iteration of a microbenchmark (which performs the mentioned word
once per iteration) on two AMD64 implementations; the norm column shows
the normal division word (e.g., 'u/'), while the stg2 column shows the
corresponding stage2 word (e.g., 'u/-stage2m'):

      Skylake              Zen2
     norm stg2           norm stg2
     41.3 15.8 u/        35.2 21.4 u/
     39.8 19.7 umod      36.9 25.8 umod
     44.0 25.3 u/mod     43.0 33.9 u/mod
     48.7 16.9 /f        36.2 22.5 /f
     47.9 20.5 modf      37.9 27.1 modf
     53.0 24.6 /modf     45.8 35.4 /modf
         227.2 u/stage1      101.9 u/stage1
         159.8 /fstage1       97.7 /fstage1

6.5.6 Bitwise operations
------------------------

'and' ( w1 w2 - w ) core "and"

'or' ( w1 w2 - w ) core "or"

'xor' ( w1 w2 - w ) core "x-or"

'invert' ( w1 - w2 ) core "invert"

'mux' ( u1 u2 u3 - u ) gforth-1.0 "mux"
   Multiplex: For every bit in u3: for a 1 bit, select the corresponding
bit from u1, otherwise the corresponding bit from u2.  E.g., '%0011
%1100 %1010 mux' gives '%0110'

'lshift' ( u1 u - u2 ) core "l-shift"
   Shift u1 left by u bits.

'rshift' ( u1 u - u2 ) core "r-shift"
   Shift u1 (cell) right by u bits, filling the shifted-in bits with
zero (logical/unsigned shift).

'arshift' ( n1 u - n2 ) gforth-1.0 "ar-shift"
   Shift n1 (cell) right by u bits, filling the shifted-in bits from the
sign bit of n1 (arithmetic shift).

'dlshift' ( ud1 u - ud2 ) gforth-1.0 "dlshift"
   Shift ud1 (double-cell) left by u bits.

'drshift' ( ud1 u - ud2 ) gforth-1.0 "drshift"
   Shift ud1 (double-cell) right by u bits, filling the shifted-in bits
with zero (logical/unsigned shift).

'darshift' ( d1 u - d2 ) gforth-1.0 "darshift"
   Shift d1 (double-cell) right by u bits, filling the shifted-in bits
from the sign bit of d1 (arithmetic shift).

'2*' ( n1 - n2 ) core "two-star"
   Shift left by 1; also works on unsigned numbers

'2/' ( n1 - n2 ) core "two-slash"
   Arithmetic shift right by 1.  For signed numbers this is a floored
division by 2 (note that '/' is symmetric on some systems, but '2/'
always floors).

'd2*' ( d1 - d2 ) double "d-two-star"
   Shift double-cell left by 1; also works on unsigned numbers

'd2/' ( d1 - d2 ) double "d-two-slash"
   Arithmetic shift right by 1.  For signed numbers this is a floored
division by 2.

'>pow2' ( u1 - u2 ) gforth-1.0 "to-pow2"
   u2 is the lowest power-of-2 number with u2>=u1.

'log2' ( u - n ) gforth-1.0 "log2"
   N is the rounded-down binary logarithm of u, i.e., the index of the
first set bit; if u=0, n=-1.

'pow2?' ( u - f  ) gforth-1.0 "pow-two-query"
   f is true if and only if u is a power of two, i.e., there is exactly
one bit set in u.

'ctz' ( x - u  ) gforth-1.0 "c-t-z"
   count trailing zeros in binary representation of x

   Unlike most other operations, rotation of narrower units cannot
easily be synthesized from rotation of wider units, so using cell-wide
and double-wide rotation operations means that the results depend on the
cell width.  For published algorithms or cell-width-independent results,
you usually need to use a fixed-width rotation operation.

'wrol' ( u1 u - u2 ) gforth-1.0 "wrol"
   Rotate the least significant 16 bits of u1 left by u bits, set the
other bits to 0.

'wror' ( u1 u - u2 ) gforth-1.0 "wror"
   Rotate the least significant 16 bits of u1 right by u bits, set the
other bits to 0.

'lrol' ( u1 u - u2 ) gforth-1.0 "lrol"
   Rotate the least significant 32 bits of u1 left by u bits, set the
other bits to 0.

'lror' ( u1 u - u2 ) gforth-1.0 "lror"
   Rotate the least significant 32 bits of u1 right by u bits, set the
other bits to 0.

'rol' ( u1 u - u2 ) gforth-1.0 "rol"
   Rotate all bits of u1 left by u bits.

'ror' ( u1 u - u2 ) gforth-1.0 "ror"
   Rotate all bits of u1 right by u bits.

'drol' ( ud1 u - ud2 ) gforth-1.0 "drol"
   Rotate all bits of ud1 (double-cell) left by u bits.

'dror' ( ud1 u - ud2 ) gforth-1.0 "dror"
   Rotate all bits of ud1 (double-cell) right by u bits.

6.5.7 Numeric comparison
------------------------

All these comparison words produce -1 (all bits set) if the condition is
true, otherwise 0.  Note that the words that compare for equality ('= <>
0= 0<> d= d<> d0= d0<>') work for for both signed and unsigned numbers.

'<' ( n1 n2 - f ) core "less-than"

'<=' ( n1 n2 - f ) gforth-0.2 "less-or-equal"

'<>' ( n1 n2 - f ) core-ext "not-equals"

'=' ( n1 n2 - f ) core "equals"

'>' ( n1 n2 - f ) core "greater-than"

'>=' ( n1 n2 - f ) gforth-0.2 "greater-or-equal"

'0<' ( n - f ) core "zero-less-than"

'0<=' ( n - f ) gforth-0.2 "zero-less-or-equal"

'0<>' ( n - f ) core-ext "zero-not-equals"

'0=' ( n - f ) core "zero-equals"

'0>' ( n - f ) core-ext "zero-greater-than"

'0>=' ( n - f ) gforth-0.2 "zero-greater-or-equal"

'u<' ( u1 u2 - f ) core "u-less-than"

'u<=' ( u1 u2 - f ) gforth-0.2 "u-less-or-equal"

'u>' ( u1 u2 - f ) core-ext "u-greater-than"

'u>=' ( u1 u2 - f ) gforth-0.2 "u-greater-or-equal"

'within' ( u1 u2 u3 - f ) core-ext "within"
   u2<u3 and u1 in [u2,u3) or: u2>=u3 and u1 not in [u3,u2).  This works
for unsigned and signed numbers (but not a mixture).  Another way to
think about this word is to consider the numbers as a circle (wrapping
around from 'max-u' to 0 for unsigned, and from 'max-n' to min-n for
signed numbers); now consider the range from u2 towards increasing
numbers up to and excluding u3 (giving an empty range if u2=u3); if u1
is in this range, 'within' returns true.

'd<' ( d1 d2 - f ) double "d-less-than"

'd<=' ( d1 d2 - f ) gforth-0.2 "d-less-or-equal"

'd<>' ( d1 d2 - f ) gforth-0.2 "d-not-equals"

'd=' ( d1 d2 - f ) double "d-equals"

'd>' ( d1 d2 - f ) gforth-0.2 "d-greater-than"

'd>=' ( d1 d2 - f ) gforth-0.2 "d-greater-or-equal"

'd0<' ( d - f ) double "d-zero-less-than"

'd0<=' ( d - f ) gforth-0.2 "d-zero-less-or-equal"

'd0<>' ( d - f ) gforth-0.2 "d-zero-not-equals"

'd0=' ( d - f ) double "d-zero-equals"

'd0>' ( d - f ) gforth-0.2 "d-zero-greater-than"

'd0>=' ( d - f ) gforth-0.2 "d-zero-greater-or-equal"

'du<' ( ud1 ud2 - f ) double-ext "d-u-less-than"

'du<=' ( ud1 ud2 - f ) gforth-0.2 "d-u-less-or-equal"

'du>' ( ud1 ud2 - f ) gforth-0.2 "d-u-greater-than"

'du>=' ( ud1 ud2 - f ) gforth-0.2 "d-u-greater-or-equal"

6.5.8 Floating Point
--------------------

For the rules used by the text interpreter for recognising
floating-point numbers see *note Number Conversion::.

   Gforth has a separate floating point stack, but the documentation
uses the unified notation.(1)

   Floating point numbers have a number of unpleasant surprises for the
unwary (e.g., floating point addition is not associative) and even a few
for the wary.  You should not use them unless you know what you are
doing or you don't care that the results you get may be totally bogus.
If you want to learn about the problems of floating point numbers (and
how to avoid them), you might start with 'David Goldberg, What Every
Computer Scientist Should Know About Floating-Point Arithmetic
(https://docs.oracle.com/cd/E19957-01/806-3568/ncg_goldberg.html), ACM
Computing Surveys 23(1):5-48, March 1991'.

   Conversion between integers and floating-point:

's>f' ( n - r ) floating-ext "s-to-f"

'd>f' ( d - r ) floating "d-to-f"

'f>s' ( r - n ) floating-ext "f-to-s"

'f>d' ( r - d ) floating "f-to-d"

   Arithmetics:

'f+' ( r1 r2 - r3 ) floating "f-plus"

'f-' ( r1 r2 - r3 ) floating "f-minus"

'f*' ( r1 r2 - r3 ) floating "f-star"

'f/' ( r1 r2 - r3 ) floating "f-slash"

'fnegate' ( r1 - r2 ) floating "f-negate"

'fabs' ( r1 - r2 ) floating-ext "f-abs"

'fcopysign' ( r1 r2 - r3  ) gforth-1.0
   r3 takes its absolute value from r1 and its sign from r2

'fmax' ( r1 r2 - r3 ) floating "f-max"

'fmin' ( r1 r2 - r3 ) floating "f-min"

'floor' ( r1 - r2 ) floating "floor"
   Round towards the next smaller integral value, i.e., round toward
negative infinity.

'fround' ( r1 - r2 ) floating "f-round"
   Round to the nearest integral value.

'ftrunc' ( r1 - r2  ) floating-ext "f-trunc"
   round towards 0

'f**' ( r1 r2 - r3 ) floating-ext "f-star-star"
   r3 = r1^{r2}

'fsqrt' ( r1 - r2 ) floating-ext "f-square-root"

'fexp' ( r1 - r2 ) floating-ext "f-e-x-p"
   r2 = e^{r1}

'fexpm1' ( r1 - r2 ) floating-ext "f-e-x-p-m-one"
   r2=e^{r1}-1

'fln' ( r1 - r2 ) floating-ext "f-l-n"
   Natural logarithm: r1 = e^{r2}

'flnp1' ( r1 - r2 ) floating-ext "f-l-n-p-one"
   Inverse of 'fexpm1': r1+1 = e^{r2}

'flog' ( r1 - r2 ) floating-ext "f-log"
   The decimal logarithm: r1 = 10^{r2}

'falog' ( r1 - r2 ) floating-ext "f-a-log"
   r2=10^{r1}

'f2*' ( r1 - r2  ) gforth-0.2 "f-two-star"
   Multiply r1 by 2.0e0

'f2/' ( r1 - r2  ) gforth-0.2 "f-two-slash"
   Multiply r1 by 0.5e0

'1/f' ( r1 - r2  ) gforth-0.2 "one-slash-f"
   Divide 1.0e0 by r1.

   Vector arithmetics:

'v*' ( f-addr1 nstride1 f-addr2 nstride2 ucount - r ) gforth-0.5 "v-star"
   dot-product: r=v1*v2.  The first element of v1 is at f_addr1, the
next at f_addr1+nstride1 and so on (similar for v2).  Both vectors have
ucount elements.

'faxpy' ( ra f-x nstridex f-y nstridey ucount - ) gforth-0.5 "faxpy"
   vy=ra*vx+vy, where vy is the vector starting at f_y with stride
nstridey bytes, and vx is the vector starting at f_x with stride
nstridex, and both vectors contain ucount elements.

   Angles in floating point operations are given in radians (a full
circle has 2 pi radians).

'fsin' ( r1 - r2 ) floating-ext "f-sine"

'fcos' ( r1 - r2 ) floating-ext "f-cos"

'fsincos' ( r1 - r2 r3 ) floating-ext "f-sine-cos"
   r2=sin(r1), r3=cos(r1)

'ftan' ( r1 - r2 ) floating-ext "f-tan"

'fasin' ( r1 - r2 ) floating-ext "f-a-sine"

'facos' ( r1 - r2 ) floating-ext "f-a-cos"

'fatan' ( r1 - r2 ) floating-ext "f-a-tan"

'fatan2' ( r1 r2 - r3 ) floating-ext "f-a-tan-two"
   r1/r2=tan(r3).  Forth-2012 does not require, but probably intends
this to be the inverse of 'fsincos'.  In Gforth it is.

'fsinh' ( r1 - r2 ) floating-ext "f-cinch"

'fcosh' ( r1 - r2 ) floating-ext "f-cosh"

'ftanh' ( r1 - r2 ) floating-ext "f-tan-h"

'fasinh' ( r1 - r2 ) floating-ext "f-a-cinch"

'facosh' ( r1 - r2 ) floating-ext "f-a-cosh"

'fatanh' ( r1 - r2 ) floating-ext "f-a-tan-h"

'pi' ( - r  ) gforth-0.2
   'Fconstant' - r is the value pi; the ratio of a circle's area to its
diameter.

   Special values in IEEE754 can be derived by for example dividing by
zero.  The most common ones are defined as floating point constants for
easy usage.

'infinity' ( - r  ) gforth-1.0
   floating point infinity

'inf' ( - r  ) gforth-1.0
   Synonym of 'infinity' to allow copying and pasting from the output of
'...', *Note Examining data::.

'-infinity' ( - r  ) gforth-1.0
   floating point -infinity

'-inf' ( - r  ) gforth-1.0
   Synonym of '-infinity' to allow copying and pasting from the output
of '...', *Note Examining data::.

'NaN' ( - r  ) gforth-1.0
   floating point Not a Number

   ---------- Footnotes ----------

   (1) It's easy to generate the separate notation from that by just
separating the floating-point numbers out: e.g.  '( n r1 u r2 -- r3 )'
becomes '( n u -- ) ( F: r1 r2 -- r3 )'.

6.6 Floating-point comparisons
==============================

One particular problem with floating-point arithmetic is that comparison
for equality often fails when you would expect it to succeed.  For this
reason approximate equality is often preferred (but you still have to
know what you are doing).  Also note that IEEE NaNs may compare
differently from what you might expect.  The comparison words are:

'f~rel' ( r1 r2 r3 - flag  ) gforth-0.5 "f-tilde-rel"
   Approximate equality with relative error: |r1-r2|<r3*|r1+r2|.

'f~abs' ( r1 r2 r3 - flag  ) gforth-0.5 "f-tilde-abs"
   Approximate equality with absolute error: |r1-r2|<r3.

'f~' ( r1 r2 r3 - flag  ) floating-ext "f-proximate"
   Forth-2012 medley for comparing r1 and r2 for equality: r3>0:
'f~abs'; r3=0: bitwise comparison; r3<0: 'fnegate f~rel'.

'f=' ( r1 r2 - f ) gforth-0.2 "f-equals"

'f<>' ( r1 r2 - f ) gforth-0.2 "f-not-equals"

'f<' ( r1 r2 - f ) floating "f-less-than"

'f<=' ( r1 r2 - f ) gforth-0.2 "f-less-or-equal"

'f>' ( r1 r2 - f ) gforth-0.2 "f-greater-than"

'f>=' ( r1 r2 - f ) gforth-0.2 "f-greater-or-equal"

'f0<' ( r - f ) floating "f-zero-less-than"

'f0<=' ( r - f ) gforth-0.2 "f-zero-less-or-equal"

'f0<>' ( r - f ) gforth-0.2 "f-zero-not-equals"

'f0=' ( r - f ) floating "f-zero-equals"

'f0>' ( r - f ) gforth-0.2 "f-zero-greater-than"

'f0>=' ( r - f ) gforth-0.2 "f-zero-greater-or-equal"

6.7 Stack Manipulation
======================

Gforth maintains a number of separate stacks:

   * A data stack (also known as the "parameter stack") - for
     characters, cells, addresses, and double cells.

   * A floating point stack - for holding floating point (FP) numbers.

   * A return stack - for holding the return addresses of colon
     definitions and other (non-FP) data.

   * A locals stack - for holding local variables.

6.7.1 Data stack
----------------

'drop' ( w - ) core "drop"

'nip' ( w1 w2 - w2 ) core-ext "nip"

'dup' ( w - w w ) core "dupe"

'over' ( w1 w2 - w1 w2 w1 ) core "over"

'third' ( w1 w2 w3 - w1 w2 w3 w1 ) gforth-1.0 "third"

'fourth' ( w1 w2 w3 w4 - w1 w2 w3 w4 w1 ) gforth-1.0 "fourth"

'swap' ( w1 w2 - w2 w1 ) core "swap"

'rot' ( w1 w2 w3 - w2 w3 w1 ) core "rote"

'-rot' ( w1 w2 w3 - w3 w1 w2 ) gforth-0.2 "not-rote"

'tuck' ( w1 w2 - w2 w1 w2 ) core-ext "tuck"

'pick' ( S:... u - S:... w ) core-ext "pick"
   Actually the stack effect is ' x0 ... xu u -- x0 ... xu x0 '.

'roll' ( x0 x1 .. xn n - x1 .. xn x0  ) core-ext

'?dup' ( w - S:... w ) core "question-dupe"
   Actually the stack effect is: '( 0 -- 0 | x\0 -- x x )'.  It performs
a 'dup' if x is nonzero.

'2drop' ( w1 w2 - ) core "two-drop"

'2nip' ( w1 w2 w3 w4 - w3 w4 ) gforth-0.2 "two-nip"

'2dup' ( w1 w2 - w1 w2 w1 w2 ) core "two-dupe"

'2over' ( w1 w2 w3 w4 - w1 w2 w3 w4 w1 w2 ) core "two-over"

'2swap' ( w1 w2 w3 w4 - w3 w4 w1 w2 ) core "two-swap"

'2rot' ( w1 w2 w3 w4 w5 w6 - w3 w4 w5 w6 w1 w2 ) double-ext "two-rote"

'2tuck' ( w1 w2 w3 w4 - w3 w4 w1 w2 w3 w4 ) gforth-0.2 "two-tuck"

6.7.2 Floating point stack
--------------------------

'fdrop' ( r - ) floating "f-drop"

'fnip' ( r1 r2 - r2 ) gforth-0.2 "f-nip"

'fdup' ( r - r r ) floating "f-dupe"

'fover' ( r1 r2 - r1 r2 r1 ) floating "f-over"

'fthird' ( r1 r2 r3 - r1 r2 r3 r1 ) gforth-1.0 "fthird"

'ffourth' ( r1 r2 r3 r4 - r1 r2 r3 r4 r1 ) gforth-1.0 "ffourth"

'fswap' ( r1 r2 - r2 r1 ) floating "f-swap"

'frot' ( r1 r2 r3 - r2 r3 r1 ) floating "f-rote"

'f-rot' ( r1 r2 r3 - r3 r1 r2 ) gforth-1.0 "f-not-rote"

'ftuck' ( r1 r2 - r2 r1 r2 ) gforth-0.2 "f-tuck"

'fpick' ( f:... u - f:... r ) gforth-0.4 "fpick"
   Actually the stack effect is ' r0 ... ru u -- r0 ... ru r0 '.

6.7.3 Return stack
------------------

The return stack primarily exists for storing system data, such as
return addresses and loop control parameters, but Forth also allows
programmers to make use of it, albeit with restrictions stemming from
the other uses.  The primary use is for temporary storage of data;
locals also provide this capability, and usually in a more convenient
way; some purists (or puritans) prefer to avoid locals, though.

   In Gforth 1.0 you can use the return stack during text interpretation
(and you cannot use locals for that).  The only limitation here is that
you cannot pass data on the return stack into or out of an included
file, block, or 'evaluate'd string.  Example:

     1 >r
     : foo [ r> ] literal ;
     foo . \ prints 1

   This interpretive usage of return-stack words is non-standard, and
many other Forth systems do not have support this usage, or limit it to
within one line.

   In Gforth you can use the return stack for storing data while you
also keep and access data in locals.  However, the standard puts
restrictions on mixing return stack and locals usage, for easy locals
implementations, and there are systems that actually rely on these
restrictions.  So, if you want to produce a standard compliant program
and you are using local variables in a definition, forget about return
stack manipulations in that word (refer to the standard document for the
exact rules).

'>r' ( w - R:w ) core "to-r"

'r>' ( R:w - w ) core "r-from"

'r@' ( R:w - R:w w  ) core "r-fetch"

'r'@' ( r:w r:w2 - r:w r:w2 w ) gforth-1.0 "r-tick-fetch"
   The second item on the return stack

'rpick' ( R:wu ... R:w0 u - R:wu ... R:w0 wu  ) gforth-1.0
   wu is the uth element on the return stack; '0 rpick' is equivalent to
'r@'.

'rdrop' ( R:w - ) gforth-0.2 "rdrop"

'2>r' ( w1 w2 - R:w1 R:w2 ) core-ext "two-to-r"

'2r>' ( R:w1 R:w2 - w1 w2 ) core-ext "two-r-from"

'2r@' ( R:w1 R:w2 - R:w1 R:w2 w1 w2 ) core-ext "two-r-fetch"

'2rdrop' ( R:w1 R:w2 - ) gforth-0.2 "two-r-drop"

'n>r' ( x1 .. xn n - R:xn..R:x1 R:n  ) tools-ext "n-to-r"
   In Standard Forth, the order of items on the return stack is not
specified, and the only thing you can do with the items on the return
stack is to use 'nr>'

'nr>' ( R:xn..R:x1 R:n - x1 .. xn n  ) tools-ext "n-r-from"
   In Standard Forth, the order of items on the return stack is not
specified, and the only thing you can do with the items on the return
stack is to use 'nr>'

   On some platforms (particularly, 32-bit platforms) floating-point
numbers are not naturally aligned on the return stack and this can lead
to (usually, but not always) small performance disadvantages.

'f>r' ( r - ) gforth-experimental "f-to-r"
   Actual stack effect: '( r -- R:r )'

'fr>' ( - r ) gforth-experimental "f-r-from"
   Actual stack effect: '( R:r -- r )'

'fr@' ( - r ) gforth-experimental "f-r-fetch"
   Actual stack effect: '( R:r -- R:r r )'

6.7.4 Locals stack
------------------

Gforth uses a separate locals stack.  It is described, along with the
reasons for its existence, in *note Locals implementation::.

6.7.5 Stack pointer manipulation
--------------------------------

In the stack effects of the following words, ignore the occurrences of
"..."  in the stack-pointer fetching words.

'sp0' ( - a-addr  ) gforth-0.4 "sp-zero"
   'User' variable - initial value of the data stack pointer.

'sp@' ( S:... - a-addr ) gforth-0.2 "sp-fetch"

'sp!' ( a-addr - S:... ) gforth-0.2 "sp-store"

'fp0' ( - a-addr  ) gforth-0.4 "fp-zero"
   'User' variable - initial value of the floating-point stack pointer.

'fp@' ( f:... - f-addr ) gforth-0.2 "fp-fetch"

'fp!' ( f-addr - f:... ) gforth-0.2 "fp-store"

'rp0' ( - a-addr  ) gforth-0.4 "rp-zero"
   'User' variable - initial value of the return stack pointer.

'rp@' ( - a-addr ) gforth-0.2 "rp-fetch"

'rp!' ( a-addr - ) gforth-0.2 "rp-store"

'lp0' ( - a-addr  ) gforth-0.4 "lp-zero"
   'User' variable - initial value of the locals stack pointer.

'lp@' ( - c-addr ) gforth-0.2 "lp-fetch"
   C_addr is the current value of the locals stack pointer.

'lp!' ( c-addr - ) gforth-internal "lp-store"

6.8 Memory
==========

In addition to the Standard Forth memory allocation words, there is also
a garbage collector
(https://www.complang.tuwien.ac.at/forth/garbage-collection.zip).

6.8.1 Memory model
------------------

Standard Forth considers a Forth system as consisting of several address
spaces, of which only "data space" is managed and accessible with the
memory words in standard programs.  Memory not necessarily in data space
includes the stacks, the code (called code space) and the headers
(called name space).  Gforth allows at least read access to all these
logical spaces, but does not guarantee that code accessing the stacks,
the threaded or native code, or the headers is portable or will work in
the next Gforth version; Gforth provides some accessor words for these
purposes, however.

   Another division of memory is between dictionary and heap memory.(1)
In heap memory you can free allocations in arbitrary order, but you
cannot grow allocations in-place (*note Heap Allocation::).  In
dictionary memory deallocation is impractical for the most part, but you
can grow allocations in place (*note Dictionary allocation::).  Gforth
(since 1.0) allows having several sections of dictionary memory in order
to allow more flexibility in this growing (*note Sections::).

   One relevant concept in this context is the contiguous region: It
means a piece of memory that is contiguous, without any system data
interleaved with it.  In heap memory each allocation forms one
contiguous region, and separate allocations are not contiguous with any
other allocations.  In dictionary memory all allocations in a section
are contiguous, unless something happens that ends the contiguous
region; a typical reason for ending a contiguous region is defining a
word in that section.

   Gforth provides one big address space, and address arithmetic can be
performed between any addresses.  However, in the dictionary headers or
code are interleaved with data, so almost the only contiguous regions
are those described by Standard Forth as contiguous; but you can be sure
that, within a section the dictionary is allocated towards increasing
addresses even between contiguous regions.  The memory order of
allocations in the heap is platform-dependent (and possibly different
from one run to the next).

   ---------- Footnotes ----------

   (1) The term "dictionary" is also used to refer to the search data
structure embodied in word lists and headers.  The search data (word
headers) reside in dictionary memory.

6.8.2 Dictionary allocation
---------------------------

Dictionary allocation is a stack-oriented allocation scheme, i.e., if
you want to deallocate X, you also deallocate everything allocated after
X.

   The allocations using the words below are contiguous and grow the
region towards increasing addresses.  Other words that allocate
dictionary memory of any kind (i.e., defining words including ':noname')
in the same section end the contiguous region and start a new one, but
allocating memory in a different section does not end a contiguous
region.

   In Standard Forth only 'create'd words are guaranteed to produce an
address that is the start of the following contiguous region.  In
particular, the cell allocated by 'variable' is not guaranteed to be
contiguous with following 'allot'ed memory.

   You can deallocate memory by using 'allot' with a negative argument
(with some restrictions, see 'allot').  For larger deallocations use
'marker'.

'here' ( - addr  ) core
   Return the address of the next free location in data space.

'unused' ( - u  ) core-ext
   Return the amount of free space remaining (in address units) in the
region addressed by 'here'.

'allot' ( n -  ) core
   Reserve n address units of data space without initialization.  n is a
signed number, passing a negative n releases memory.  In Forth-2012 you
can only deallocate memory from the current contiguous region in this
way.  In Gforth you can deallocate anything in this way but named words.
The system does not check this restriction.

'->here' ( addr -  ) gforth-1.0 "to-here"
   Change the value of 'here' to addr.

'c,' ( c -  ) core "c-comma"
   Reserve data space for one char and store c in the space.

'f,' ( f -  ) gforth-0.2 "f-comma"
   Reserve data space for one floating-point number and store f in the
space.

',' ( w -  ) core "comma"
   Reserve data space for one cell and store w in the space.

'2,' ( w1 w2 -  ) gforth-0.2 "two-comma"
   Reserve data space for two cells and store the double w1 w2 there, w2
first (lower address).

'w,' ( x -  ) gforth-1.0 "w-comma"
   Reserve 2 bytes of data space and store the least significant 16 bits
of x there.

'l,' ( l -  ) gforth-1.0 "l-comma"
   Reserve 4 bytes of data space and store the least significant 32 bits
of x there.

'x,' ( x -  ) gforth-1.0 "x-comma"
   Reserve 8 bytes of data space and store (the least significant 64
bits) of x there.  Reserve 8 bytes of data space and store w there.

'xd,' ( xd -  ) gforth-1.0 "x-d-comma"
   Reserve 8 bytes of data space and store the least significant 64 bits
of x there.

'A,' ( addr -  ) gforth-0.2 "a-comma"
   Reserve data space for one cell, and store addr there.  For our
cross-compiler this provides the type information necessary for a
relocatable image; normally, though, this is equivalent to ','.

'mem,' ( addr u -  ) gforth-0.6 "mem-comma"
   Reserve u bytes of dictionary space and copy u bytes starting at addr
there.  If you want the memory to be aligned, precede 'mem,' with an
alignment word.

'save-mem-dict' ( addr1 u - addr2 u  ) gforth-0.7
   Copy the memory block addr1 u to a newly 'allot'ed memory block of
size u; the target memory block starts at addr2.

   Memory accesses have to be aligned (*note Address arithmetic::).  So
of course you should allocate memory in an aligned way, too.  I.e.,
before allocating a cell, 'here' must be cell-aligned, etc.  The words
below align 'here' if it is not already.  Basically it is only already
aligned for a type, if the last allocation was a multiple of the size of
this type and if 'here' was aligned for this type before.

   After freshly 'create'ing a word, 'here' is 'align'ed in Standard
Forth ('maxalign'ed in Gforth).

'align' ( -  ) core
   If the data-space pointer is not aligned, reserve enough space to
align it.

'falign' ( -  ) floating "f-align"
   If the data-space pointer is not float-aligned, reserve enough space
to align it.

'sfalign' ( -  ) floating-ext "s-f-align"
   If the data-space pointer is not single-float-aligned, reserve enough
space to align it.

'dfalign' ( -  ) floating-ext "d-f-align"
   If the data-space pointer is not double-float-aligned, reserve enough
space to align it.

'maxalign' ( -  ) gforth-0.2
   Align data-space pointer for all Forth alignment requirements.

6.8.3 Sections
--------------

If you want to do something that allocates memory from the dictionary or
compiles code in the middle of a contiguous region of another dictionary
allocation, or in the middle of a colon definition, that's not possible
with a single dictionary pointer, leading to complicated workarounds.

   Gforth provides dictionary sections to address this problem.  Each
section has its own dictionary pointer, and allocating or compiling
something in one section does not interrupt the contiguity of
allocations in other sections.  In this respect Gforth's sections are
similar to sections and segments in assembly languages.

   One difference is that the most common usage of sections is as a
stack of sections, which is useful for building nested definitions or
dictionary-allocated data structures: Use 'next-section' for the inner
definition or data structure, switch back with 'previous-section'.

   Words like 'latest' (*note Name token::) and 'latestxt' (*note
Anonymous Definitions::) refer to the most recent definition in the
current section.  Quotations (*note Quotations::) and the implicit
quotation of 'does>' (*note User-defined defining words using CREATE::)
are in a different section than the containing definition, so after the
quotation ends (and the section is switched back), words like 'latest'
report the outer definition rather than the quotation.

   An example of such a usage of the section stack is:

     create my2x2matrix
       next-section here 1 , 2 , previous-section ,
       next-section here 3 , 4 , previous-section ,

     \ now print my2x2matrix[0,1], i.e., "2":
     my2x2matrix 0 cells + @ 1 cells + @ .

   This works also for allocating section memory while compiling a
definition, or defining a definition during a contiguous region, e.g.:

     create mydispatchtable
       next-section :noname ." foo" ; previous-section ,
       next-section :noname ." bar" ; previous-section ,

     \ now dispatch mydispatchtable[1]
     mydispatchtable 1 cells + @ execute

   Note that the interpretation semantics of '[:' (*note Quotations::)
switches to the next section internally, so you can write
'mydispatchtable' also as follows:

     create mydispatchtable
       [: ." foo" ;] ,
       [: ." bar" ;] ,

   The interpretation semantics of 'does>' uses a separate section, so
the 'does>' does not end the contiguous region, and you can define a
word 'mydispatch' that includes the dispatch code, as follows:

     create mydispatch
     does> ( u -- )
         ( u addr ) swap cells + @ execute ;
       [: ." foo" ;] ,
       [: ." bar" ;] ,

     1 mydispatch \ prints "bar"

'next-section' ( -  ) gforth-1.0
   Switch to the next section in the section stack.  If there is no such
section yet, create it (with the size being a quarter of the size of the
current section).

'previous-section' ( -  ) gforth-1.0
   Switch to the previous section in the section stack; the now-next
section continues to exist with everything that was put there.  Throw an
exception if there is no previous section.

   The bottom section in the section stack has the size given with the
'--dictionary-size' command-line parameter (*note Invoking Gforth::).

   In addition to the stack of anonymous sections you can also have
named sections that you define with:

'extra-section' ( usize "name" -  ) gforth-1.0
   Define a new word name and create a section s with at least usize
unused bytes.
Name execution '( ... xt -- ... )': When calling name, the current
section is c.  Switch the current section to be s, execute xt, then
switch the current section back to c.

   As an example, here's a variant of the 'my2x2matrix' definition:

     4 cells extra-section myvec

     create my2x2matrix
       ' here myvec 1 ' , myvec 2 ' , myvec ,
       ' here myvec 3 ' , myvec 4 ' , myvec ,

   Currently a named section does not start a dictionary stack, and
using 'next-section' inside a named section throws an error.

   You can show the existing sections with:

'.sections' ( -  ) gforth-1.0 "dot-sections"
   Show all the sections and their status.

   At the time of this writing this outputs:

                 start      size      used name
         $7F9A5A516000     32768        96 noname
         $7F9A5A1A1000    131072       208 noname
         $7F9A5A1C2000    524288      2128 noname
         $7F9A4BDFD000   2097152     32680 noname
     >   $7F9A4BFFE040   8388608    659272 Forth
         $7F9A5A51F000     20480      1448 locals-headers

   The lines describe the different sections: First the section stack,
with sections called 'noname' and (the bottom) 'Forth', then the
extra-sections.  The columns are the start address of the section, the
gross size (including section management overhead), how much of the
section is already used, and the name.  The size and used columns are in
decimal base.

   In the section 'Forth', not all of the remaining size can be used for
'allot'ting memory, because room must be left for 'pad' (*note Memory
Blocks::).  The current section is marked with '>'.  Also, if you use
'word' (*note The Input Stream::), you must leave room in the current
section for the parsed string and its length byte.

6.8.4 Heap allocation
---------------------

Heap allocation supports deallocation of allocated memory in any order.
It does not affect dictionary allocation (i.e., heap allocation does not
end a contiguous region).  In Gforth, these words are implemented using
the standard C library calls malloc(), free() and realloc().

   The memory region produced by one invocation of 'allocate' or
'resize' is internally contiguous.  There is no contiguity between such
a region and any other region (including others allocated from the
heap).

'allocate' ( u - a_addr wior  ) memory
   Allocate u address units of contiguous data space.  This data space
is not initialized.  If the allocation is successful, a-addr is the
start address of the allocated region and wior is 0.  If the allocation
fails, a-addr is arbitrary and wior is a non-zero I/O result code.

'free' ( a_addr - wior  ) memory
   Return the region of data space starting at a-addr to the system.
The region must originally have been obtained using 'allocate' or
'resize', otherwise the result of 'free' is unpredictable.  If the
operation is successful, wior is 0.  If the operation fails, wior is a
non-zero I/O result code.

'resize' ( a_addr1 u - a_addr2 wior  ) memory
   Change the size of the allocated area at a-addr1 to u address units,
possibly moving the contents to a different area.  a-addr2 is the
address of the resulting area.  If the operation is successful, wior is
0.  If the operation fails, wior is a non-zero I/O result code.  If
a-addr1 is 0, Gforth's (but not the Standard) 'resize' 'allocate's u
address units.

6.8.4.1 Memory blocks and heap allocation
.........................................

Additional words for dealing with memory blocks are described in *note
Memory Blocks::.  An alternative to the following words are among the
$tring words (*note $tring words::).

'save-mem' ( addr1 u - addr2 u  ) gforth-0.2
   Copy the memory block addr u to addr2, which is the start of a newly
heap allocated u-byte region.

'extend-mem' ( addr1 u1 u - addr addr2 u2  ) gforth-experimental
   Addr1 u1 is a memory block in heap memory.  Increase the size of this
memory block by u aus, possibly reallocating it.  C-addr2 u2 is the
resulting memory block (u2=u1+u), addr is the start of the u additional
aus (addr=addr2+u1).

'free-mem-var' ( addr -  ) gforth-experimental
   Addr is the address of a 2variable containing a memory block
descriptor c-addr u in heap memory; 'free-mem-var' frees the memory
block and stores 0 0 in the 2variable.

   Usage example:

     2variable myblock
     "foo" save-mem myblock 2!
     myblock 2@ "bar" tuck >r >r extend-mem myblock 2! r> swap r> move
     myblock 2@ type \ prints "foobar"
     myblock free-mem-var

6.8.4.2 Growable memory buffers
...............................

The following words are useful for growable memory buffers.  One can
alternatively use $trings (*note $tring words::), and the differences
are: When the used memory in the buffer shrinks, $trings may resize the
buffer, while 'adjust-buffer' does not, which may be preferable for a
buffer that is reused all the time.  However, $strings have one cell
less memory overhead, and for longer-term storage the shrinking may be
worthwhile.

'buffer%' ( u1 u2 -  ) gforth-experimental "buffer-percent"
   u1 is the alignment and u2 is the size of a buffer descriptor.

'init-buffer' ( addr -  ) gforth-experimental

'adjust-buffer' ( u addr -  ) gforth-experimental
   Adjust buffer% at addr to length u.  This may grow the allocated
area, but never shrinks it.

   You can get the current address and length of such a buffer with
'2@'.

   Typical usage:

     create mybuf  buffer% %allot  mybuf init-buffer
     s" frobnicate" mybuf adjust-buffer  mybuf 2@ move
     mybuf 2@ type
     s" foo"        mybuf adjust-buffer  mybuf 2@ move
     mybuf 2@ type

6.8.5 Memory Access
-------------------

'@' ( a-addr - w ) core "fetch"
   w is the cell stored at a_addr.

'!' ( w a-addr - ) core "store"
   Store w into the cell at a-addr.

'+!' ( n a-addr - ) core "plus-store"
   Add n to the cell at a-addr.

'!@' ( w1 a-addr - w2 ) gforth-experimental "store-fetch"
   Fetch W2 from A_ADDR, then store W1 there.  There is also 'atomic!@'
(*note Hardware operations for multi-tasking::).

'+!@' ( u1 a-addr - u2 ) gforth-experimental "plus-store-fetch"
   Fetch U2 from A_ADDR, then increment this location by U1.  There is
also 'atomic+!@' (*note Hardware operations for multi-tasking::).

'c@' ( c-addr - c ) core "c-fetch"
   c is the char stored at c_addr.

'c!' ( c c-addr - ) core "c-store"
   Store c into the char at c-addr.

'2@' ( a-addr - w1 w2 ) core "two-fetch"
   w2 is the content of the cell stored at a-addr, w1 is the content of
the next cell.

'2!' ( w1 w2 a-addr - ) core "two-store"
   Store w2 into the cell at c-addr and w1 into the next cell.

'f@' ( f-addr - r ) floating "f-fetch"
   r is the float at address f-addr.

'f!' ( r f-addr - ) floating "f-store"
   Store r into the float at address f-addr.

'sf@' ( sf-addr - r ) floating-ext "s-f-fetch"
   Fetch the single-precision IEEE floating-point value r from the
address sf-addr.

'sf!' ( r sf-addr - ) floating-ext "s-f-store"
   Store r as single-precision IEEE floating-point value to the address
sf-addr.

'df@' ( df-addr - r ) floating-ext "d-f-fetch"
   Fetch the double-precision IEEE floating-point value r from the
address df-addr.

'df!' ( r df-addr - ) floating-ext "d-f-store"
   Store r as double-precision IEEE floating-point value to the address
df-addr.

6.8.6 Special Memory Accesses
-----------------------------

This section is about memory accesses useful for communicating with
other software or other computers.  This means that the accesses are of
a certain bit width (independent of Gforth's cell width), are possibly
not naturally aligned and typically have a certain byte order that may
be different from the native byte order of the system that Gforth runs
on.

   We use the following prefixes:

'c'
     8 bits (character)
'w'
     16 bits
'l'
     32 bits
'x'
     64 bits represented as one cell
'xd'
     64 bits represented as two cells

   The 'x'-prefix words do not work properly on 32-bit systems, so for
code that is intended to be portable to 32-bit systems you should use
'xd'-prefix words.  Note that 'xd'-prefix words work on 64-bit systems:
there the upper cell is just 0 (for unsigned values) or a sign extension
of the lower cell.

   The memory-access words below all work with arbitrarily (un)aligned
addresses (unlike '@', '!', 'f@', 'f!', which require alignment on some
hardware), and use native byte order (like these words),

'w@' ( c-addr - u ) gforth-0.5 "w-fetch"
   u is the zero-extended 16-bit value stored at c_addr.

'w!' ( w c-addr - ) gforth-0.7 "w-store"
   Store the bottom 16 bits of w at c_addr.

'l@' ( c-addr - u ) gforth-0.7 "l-fetch"
   u is the zero-extended 32-bit value stored at c_addr.

'l!' ( w c-addr - ) gforth-0.7 "l-store"
   Store the bottom 32 bits of w at c_addr.

'x@' ( c-addr - u ) gforth-1.0 "x-fetch"
   u is the zero-extended 64-bit value stored at c_addr.

'x!' ( w c-addr - ) gforth-1.0 "x-store"
   Store the bottom 64 bits of w at c_addr.

'xd@' ( c-addr - ud ) gforth-1.0 "x-d-fetch"
   ud is the zero-extended 64-bit value stored at c_addr.

'xd!' ( ud c-addr - ) gforth-1.0 "x-d-store"
   Store the bottom 64 bits of ud at c_addr.

   For accesses with a specific byte order, you have to perform
byte-order adjustment immediately after a fetch (before the
sign-extension), or immediately before the store.  The results of these
byte-order adjustment words are always zero-extended.

'wbe' ( u1 - u2  ) gforth-1.0
   Convert 16-bit value in u1 from native byte order to big-endian or
from big-endian to native byte order (the same operation)

'wle' ( u1 - u2  ) gforth-1.0
   Convert 16-bit value in u1 from native byte order to little-endian or
from little-endian to native byte order (the same operation)

'lbe' ( u1 - u2  ) gforth-1.0
   Convert 32-bit value in u1 from native byte order to big-endian or
from big-endian to native byte order (the same operation)

'lle' ( u1 - u2  ) gforth-1.0
   Convert 32-bit value in u1 from native byte order to little-endian or
from little-endian to native byte order (the same operation)

'xbe' ( u1 - u2  ) gforth-1.0
   Convert 64-bit value in u1 from native byte order to big-endian or
from big-endian to native byte order (the same operation)

'xle' ( u1 - u2  ) gforth-1.0
   Convert 64-bit value in u1 from native byte order to little-endian or
from little-endian to native byte order (the same operation)

'xdbe' ( ud1 - ud2  ) gforth-1.0
   Convert 64-bit value in ud1 from native byte order to big-endian or
from big-endian to native byte order (the same operation)

'xdle' ( ud1 - ud2  ) gforth-1.0
   Convert 64-bit value in ud1 from native byte order to little-endian
or from little-endian to native byte order (the same operation)

   For signed fetches with a specific byte order, you have first have to
perform an unsigned fetch and a byte-order correction, and finally use a
sign-extension word:

'c>s' ( x - n ) gforth-1.0 "c-to-s"
   Sign-extend the 8-bit value in x to cell n.

'w>s' ( x - n ) gforth-1.0 "w-to-s"
   Sign-extend the 16-bit value in x to cell n.

'l>s' ( x - n ) gforth-1.0 "l-to-s"
   Sign-extend the 32-bit value in x to cell n.

'x>s' ( x - n  ) gforth-1.0 "x-to-s"
   Sign-extend the 64-bit value in x to cell n.

'xd>s' ( xd - d  ) gforth-1.0 "xd-to-s"
   Sign-extend the 64-bit value in XD to double-cell D.

   Overall, this leads to sequences like

     w@ wbe w>s   \ 16-bit unaligned signed big-endian fetch
     >r lle r> l! \ 32-bit unaligned little-endian store

6.8.7 Address arithmetic
------------------------

Address arithmetic is the foundation on which you can build data
structures like arrays, records (*note Structures::) and objects (*note
Object-oriented Forth::).

   Standard Forth does not specify the sizes of the data types.
Instead, it offers a number of words (e.g., 'cells') for computing sizes
and doing address arithmetic.

   Address arithmetic is performed in terms of address units (aus); on
most systems the address unit is one byte.  There is also
word-addressed(1) hardware in some embedded systems, and on these
systems the au is one cell.  Finally, Forth-2012 also supports systems
where a char needs more than one au.  However, the common practice is
that '1 chars' produces 1, and this will be standardized in the next
release of the standard.

   The basic address arithmetic words are '+' and '-'.  E.g., if you
have the address of a cell, perform '1 cells +', and you will have the
address of the next cell.

   Standard Forth also defines words for aligning addresses for specific
types.  Some hardware requires that accesses to specific data types must
only occur at specific addresses; e.g., that (4-byte) cells may only be
accessed at addresses divisible by 4.  Even if a machine allows
unaligned accesses, it can usually perform aligned accesses faster.

   For the performance-conscious: alignment operations are usually only
necessary during the definition of a data structure, not during the
(more frequent) accesses to it.

   Standard Forth defines no words for character-aligning addresses, but
given that '1 chars'=1 is common practice, that's not a big loss.

   Standard Forth guarantees that addresses returned by 'CREATE'd words
are cell-aligned; in addition, Gforth guarantees that these addresses
are aligned for all Forth purposes.(2)

   Note that the Standard Forth word 'char' has nothing to do with
address arithmetic.

'chars' ( n1 - n2  ) core
   n2 is the number of address units of n1 chars.

'char+' ( c-addr1 - c-addr2 ) core "char-plus"
   '1 chars +'.

'char-' ( c-addr1 - c-addr2  ) gforth-0.7 "char-minus"
   '1 chars -'

'cells' ( n1 - n2 ) core "cells"
   n2 is the number of address units of n1 cells.

'cell+' ( a-addr1 - a-addr2 ) core "cell-plus"
   '1 cells +'

'cell-' ( a-addr1 - a-addr2 ) core "cell-minus"
   '1 cells -'

'cell/' ( n1 - n2 ) gforth-1.0 "cell-divide"
   N2 is the number of cells that fit into n1 aus, rounded towards
negative infinity.

'cell' ( - u  ) gforth-0.2
   'Constant' - '1 cells'

'aligned' ( c-addr - a-addr ) core "aligned"
   a-addr is the smallest aligned address greater than or equal to
c-addr.

'floats' ( n1 - n2 ) floating "floats"
   n2 is the number of address units of n1 floats.

'float+' ( f-addr1 - f-addr2 ) floating "float-plus"
   '1 floats +'.

'float' ( - u  ) gforth-0.3
   'Constant' - the number of address units corresponding to a
floating-point number.

'float/' ( n1 - n2 ) gforth-1.0 "float-divide"
   N2 is the number of floats that fit into n1 aus, rounded towards
negative infinity.

'faligned' ( c-addr - f-addr ) floating "f-aligned"
   f-addr is the first float-aligned address greater than or equal to
c-addr.

'sfloats' ( n1 - n2 ) floating-ext "s-floats"
   n2 is the number of address units of n1 single-precision IEEE
floating-point numbers.

'sfloat+' ( sf-addr1 - sf-addr2  ) floating-ext "s-float-plus"
   '1 sfloats +'.

'sfloat/' ( n1 - n2 ) gforth-1.0 "s-float-divide"
   N2 is the number of sfloats that fit into n1 aus, rounded towards
negative infinity.

'sfaligned' ( c-addr - sf-addr ) floating-ext "s-f-aligned"
   sf-addr is the first single-float-aligned address greater than or
equal to c-addr.

'dfloats' ( n1 - n2 ) floating-ext "d-floats"
   n2 is the number of address units of n1 double-precision IEEE
floating-point numbers.

'dfloat+' ( df-addr1 - df-addr2  ) floating-ext "d-float-plus"
   '1 dfloats +'.

'dfloat/' ( n1 - n2 ) gforth-1.0 "d-float-divide"
   N2 is the number of dfloats that fit into n1 aus, rounded towards
negative infinity.

'dfaligned' ( c-addr - df-addr ) floating-ext "d-f-aligned"
   df-addr is the first double-float-aligned address greater than or
equal to c-addr.

'maxaligned' ( addr1 - addr2  ) gforth-0.2
   addr2 is the first address after addr1 that satisfies all alignment
restrictions.

'*aligned' ( addr1 n - addr2  ) gforth-1.0 "star-aligned"
   ADDR2 is the aligned version of ADDR1 with respect to the alignment
N; N must be a power of 2.

'*align' ( n -  ) gforth-1.0 "star-align"
   Align 'here' with respect to the alignment N.

'waligned' ( addr - addr'  ) gforth-1.0
   Addr' is the next even address >= addr.

'walign' ( -  ) gforth-1.0
   Align 'here' to even.

'laligned' ( addr - addr'  ) gforth-1.0
   Addr' is the next address >= addr divisible by 4.

'lalign' ( -  ) gforth-1.0
   Align 'here' to be divisible by 4.

'xaligned' ( addr - addr'  ) gforth-1.0
   Addr' is the next address >= addr divisible by 8.

'xalign' ( -  ) gforth-1.0
   Align 'here' to be divisible by 8.

   The environmental query 'address-unit-bits' (*note Environmental
Queries::) and the following words may be useful to those who want to
write software portable to non-byte-addressed machines.

'/w' ( - u  ) gforth-0.7 "slash-w"
   address units for a 16-bit value

'/l' ( - u  ) gforth-0.7 "slash-l"
   address units for a 32-bit value

'/x' ( - u  ) gforth-1.0 "slash-x"
   address units for a 64-bit value

   ---------- Footnotes ----------

   (1) In Forth terminology: cell-addressed.

   (2) Some SIMD extensions of some instruction sets impose more severe
alignment constraints that 'create' currently does not satisfy.

6.8.8 Memory Blocks
-------------------

Memory blocks often represent character strings; For ways of storing
character strings in memory see *note String representations::.  For
other string-processing words see *note Displaying characters and
strings::.

   In case you want to write a program that is portable to systems with
'1 chars' > 1 (not recommended), you have to note the difference between
words that take a number of aus (e.g., 'erase') and words that take a
number of chars (e.g., 'blank'), and insert 'chars' as appropriate.

   When copying characters between overlapping memory regions, use
'move'.  'Cmove' and 'cmove>' tend to be slower than a well-implemented
'move'.

'move' ( c-from c-to ucount - ) core "move"
   Copy the contents of ucount aus at c-from to c-to.  'move' works
correctly even if the two areas overlap.

'cmove' ( c-from c-to u - ) string "c-move"
   Copy the contents of ucount characters from data space at c-from to
c-to.  The copy proceeds 'char'-by-'char' from low address to high
address; i.e., for overlapping areas it is safe if c-to<=c-from.

'cmove>' ( c-from c-to u - ) string "c-move-up"
   Copy the contents of ucount characters from data space at c-from to
c-to.  The copy proceeds 'char'-by-'char' from high address to low
address; i.e., for overlapping areas it is safe if c-to>=c-from.

'fill' ( c-addr u c - ) core "fill"
   Store c in u chars starting at c-addr.

'erase' ( addr u -  ) core-ext
   Clear all bits in u aus starting at addr.

'blank' ( c-addr u -  ) string
   Store the space character into u chars starting at c-addr.

'pad' ( - c-addr  ) core-ext
   C-ADDR is the address of a transient region that can be used as
temporary data storage.  At least 84 characters of space is available.

6.9 Strings and Characters
==========================

6.9.1 Characters
----------------

Forth supports chars (aka bytes), used by words such as 'c@'; these can
be used to represent an ASCII character.

   Forth also supports extended characters, which may be represented by
a sequence of several bytes (i.e., several chars).  A common character
encoding is the UTF-8 representation of Unicode.

   In general, most code does not have to worry about extended
characters: In the string representation it does not matter whether a
byte is a part of an extended character, or it is a character by itself,
and words that consume chars (like 'emit') also work when the extended
character is transferred as a sequence of chars.  Forth still provides
words for dealing with extended characters (*note Xchars and Unicode::).

   In Unicode terms, chars are code units, whereas extended characters
are code points.  Note that an Unicode abstract character can consist of
a sequence of code points, but Forth (like other programming languages)
has no data type for individual abstract characters; of course, they can
be represented as strings.

   You can use the usual integer words on chars and Xchars on the stack,
but Gforth also has some words for dealing with chars on the stack:

'toupper' ( c1 - c2 ) gforth-0.2 "toupper"
   If c1 is a lower-case ASCII character, c2 is the equivalent
upper-case character, otherwise c2 is c1.

6.9.2 String representations
----------------------------

Forth commonly represents strings as cell pair c-addr u on the stack; u
is the length of the string in bytes (aka chars), and c-addr is the
address of the first byte of the string.  Note that a code point may be
represented by a sequence of several chars in the string (and a Unicode
"abstract character" may consist of several code points).  *Note String
words::.

   Another string representation is used with the string library of
words containing '$'.  It represents the string on the stack through the
address of a cell-sized string handle, which can be located in, e.g., a
variable.  *Note $tring words::.

   A legacy string representation are "counted strings", represented on
the stack by c-addr.  The char addressed by c-addr contains a
character-count, n, of the string and the string occupies the subsequent
n char addresses in memory.  Counted strings are limited to 255 bytes in
length.  While counted strings may look attractive due to needing only
one stack item, due to their limitations we recommend avoiding them,
especially as input parameters of words.  *Note Counted string words::.

6.9.3 String and Character literals
-----------------------------------

The nicest way to write a string literal is to write it as '"STRING"'.
For these kinds of string literals as well as for 's\"' some sequences
are not put in the resulting string as is, but are replaced as shown
below.  The sequences are mostly the same as in C (exceptions noted):

'\a'
     7 '#bell' (alert)
'\b'
     8 '#bs' (backspace)
'\e'
     27 '#esc' (escape, not in C99)
'\f'
     12 '#ff' (form feed)
'\l'
     10 '#lf' (line feed, not in C)
'\m'
     13 10 CR LF (not in C)
'\n'
     sequence produced by 'newline' (in C this produces a LF)
'\q'
     34 '"' (double quote, not in C)
'\r'
     13 '#cr' (carriage return)
'\t'
     9 '#tab' (horizontal tab)
'\uXXXX'
     Unicode code point XXXX (in hex); auto-merges surrogate pairs (not
     in Forth-2012 nor C)
'\UXXXXXXXX'
     Unicode code point XXXXXXXX (in hex, not in Forth-2012 nor C)
'\v'
     11 VT (vertical tab)
'\xXX'
     raw byte (not code point) XX (in hex)
'\z'
     0 NUL (not in C)
'\\'
     '\'
'\"'
     '"' (the '\"' does not terminate the string; not in Forth-2012)
'\XXX'
     raw byte; XXX is 1-3 octal digits (not in Forth-2012).

   A '\' before any other character is reserved.

   Note that '\x'XX produces raw bytes, while '\u'XXXX and '\U'XXXXXXXX
produce code points for the current encoding.  E.g., if we use UTF-8
encoding and want to encode ä (code point U+00E4), you can write the
letter ä itself, or write '\xc3\xa4' (the UTF-8 bytes for this code
point), '\u00e4', or '\U000000e4'.

   The '"STRING"' syntax is non-standard, so for portability you may
want to use one of the following words:

's\"' ( Interpretation 'ccc"' - c-addr u  ) core-ext,file-ext "s-backslash-quote"
   Interpretation: Parse the string ccc delimited by a '"' (but not
'\"'), and convert escaped characters as described above.  Store the
resulting string in newly allocated heap memory, and push its descriptor
c-addr u.
Compilation '( 'ccc"' -- )': Parse the string ccc delimited by a '"'
(but not '\"'), and convert escaped characters as described above.
Append the run-time semantics below to the current definition.
Run-time '( -- c-addr u )': Push a descriptor for the resulting string.

'S"' ( Interpretation 'ccc"' - c-addr u  ) core,file "s-quote"
   Interpretation: Parse the string ccc delimited by a '"' (double
quote).  Store the resulting string in newly allocated heap memory, and
push its descriptor c-addr u.
Compilation '( 'ccc"' -- )': Parse the string ccc delimited by a '"'
(double quote).  Append the run-time semantics below to the current
definition.
Run-time '( -- c-addr u )': Push a descriptor for the parsed string.

   All these ways of interpreting strings consume heap memory; normally
you can just live with the string consuming memory until the end of the
Gforth session, but if that is a problem for some reason, you can 'free'
the string when you no longer need it.  Forth-2012 only guarantees two
buffers of 80 characters each, so in standard programs you should assume
that the string lives only until the next-but-one 's"'.

   On the other hand, the compilation semantics of string literals of
any form allocates the string in the dictionary, and you cannot 'free'
it, and it lives as long as the word it is compiled into (also in
Forth-2012).

   Likewise, You can get the code xc of a character C with ''C''.  This
way has been standardized since Forth-2012.  An older way to get it is
to use one of the following words:

'char' ( '<spaces>ccc' - c  ) core,xchar-ext
   Skip leading spaces.  Parse the string ccc and return c, the display
code representing the first character of ccc.

'[char]' ( compilation '<spaces>ccc' - ; run-time - c  ) core,xchar-ext "bracket-char"
   Compilation: skip leading spaces.  Parse the string ccc.  Run-time:
return c, the display code representing the first character of ccc.
Interpretation semantics for this word are undefined.

   You usually use 'char' outside and '[char]' inside colon definitions,
or you just use ''C''.

   Note that, e.g.,

     "C" type

is (slightly) more efficient than

     'C' xemit

because the latter converts the code point into a sequence of bytes and
individually 'emit's them.  Similarly, dealing with general characters
is usually more efficient when representing them as strings rather than
code points.

   There are the following words for producing commonly-used characters
and strings that cannot be produced with 'S"' or ''C'':

'newline' ( - c-addr u ) gforth-0.5 "newline"
   String containing the newline sequence of the host OS

'bl' ( - c-char  ) core "b-l"
   c-char is the character value for a space.

'#tab' ( - c  ) gforth-0.2 "number-tab"

'#lf' ( - c  ) gforth-0.2 "number-l-f"

'#cr' ( - c  ) gforth-0.2 "number-c-r"

'#ff' ( - c  ) gforth-0.2 "number-f-f"

'#bs' ( - c  ) gforth-0.2 "number-b-s"

'#del' ( - c  ) gforth-0.2 "number-del"

'#bell' ( - c  ) gforth-0.2 "number-bell"

'#esc' ( - c  ) gforth-0.5 "number-esc"

'#eof' ( - c  ) gforth-0.7 "number-e-o-f"
   actually EOT (ASCII code 4 aka '^D')

6.9.4 String words
------------------

Words that are used for memory blocks are also useful for strings, so
for words that move, copy, and fill strings, see *note Memory Blocks::.
For words that display characters and strings, see *note Displaying
characters and strings::.

   The following words work on previously existing strings:

'compare' ( c-addr1 u1 c-addr2 u2 - n ) string "compare"
   Compare two strings lexicographically, based on the values of the
bytes in the strings (i.e., case-sensitive and without locale-specific
collation order).  If they are equal, n is 0; if the string in c_addr1
u1 is smaller, n is -1; if it is larger, n is 1.

'str=' ( c-addr1 u1 c-addr2 u2 - f  ) gforth-0.6 "str-equals"
   Bytewise equality

'str<' ( c-addr1 u1 c-addr2 u2 - f  ) gforth-0.6 "str-less-than"
   Bytewise lexicographic comparison.

'string-prefix?' ( c-addr1 u1 c-addr2 u2 - f  ) gforth-0.6 "string-prefix-question"
   Is C-ADDR2 U2 a prefix of C-ADDR1 U1?

'string-suffix?' ( c-addr1 u1 c-addr2 u2 - f  ) gforth-1.0 "string-suffix-question"
   Is C-ADDR2 U2 a suffix of C-ADDR1 U1?

'search' ( c-addr1 u1 c-addr2 u2 - c-addr3 u3 flag  ) string
   Search the string specified by c-addr1, u1 for the string specified
by c-addr2, u2.  If flag is true: match was found at c-addr3 with u3
characters remaining.  If flag is false: no match was found; c-addr3, u3
are equal to c-addr1, u1.

'scan' ( c-addr1 u1 c - c-addr2 u2 ) gforth-0.2 "scan"
   Skip all characters not equal to c.  The result starts with c or is
empty.  'Scan' is limited to single-byte (ASCII) characters.  Use
'search' to search for multi-byte characters.

'scan-back' ( c-addr u1 c - c-addr u2  ) gforth-0.7
   The last occurrence of c in c-addr u1 is at c-addr+u2-1; if it does
not occur, u2=0.

'skip' ( c-addr1 u1 c - c-addr2 u2 ) gforth-0.2 "skip"
   Skip all characters equal to c.  The result starts with the first
non-c character, or it is empty.  'Scan' is limited to single-byte
(ASCII) characters.

'$split' ( c-addr u char - c-addr u1 c-addr2 u2  ) gforth-0.7 "string-split"
   Divides a string c-addr u into two, with char as separator.  U1 is
the length of the string up to, but excluding the first occurrence of
the separator, c-addr2 u2 is the part of the input string behind the
separator.  If the separator does not occur in the string, u1=u, u2=0
and c-addr2=c-addr+u.

'nosplit?' ( addr1 u1 addr2 u2 -  addr1 u1 addr2 u2 flag  ) gforth-experimental "nosplit-question"
   Used on the result of '$split', flag is true if and only if the
separator does not occur in the input string of '$split'.

'-trailing' ( c_addr u1 - c_addr u2  ) string "dash-trailing"
   Adjust the string specified by c-addr, u1 to remove all trailing
spaces.  u2 is the length of the modified string.

'/string' ( c-addr1 u1 n - c-addr2 u2 ) string "slash-string"
   Adjust the string specified by c-addr1, u1 to remove n characters
from the start of the string.

'safe/string' ( c-addr1 u1 n - c-addr2 u2 ) gforth-1.0 "safe-slash-string"
   Adjust the string specified by c-addr1, u1 to remove n characters
from the start of the string.  Unlike '/string', 'safe/string' removes
at least 0 and at most u1 characters.

'insert' ( c-addr1 u1 c-addr2 u2 -  ) gforth-0.7
   Move the contents of the buffer c-addr2 u2 towards higher addresses
by u1 chars, and copy the string c-addr1 u1 into the first u1 chars of
the buffer.

'delete' ( c-addr u u1 -  ) gforth-0.7
   In the memory block c-addr u, delete the first u1 chars by copying
the contents of the block starting at c-addr+u1 there; fill the u1
characters at the end of the block with blanks.

'cstring>sstring' ( c-addr - c-addr u  ) gforth-0.2 "cstring-to-sstring"
   C-addr is the start address of a zero-terminated string, u is its
length.

   The following words compare case-insensitively for ASCII characters,
but case-sensitively for non-ASCII characters (like in lookup in
wordlists).

'capscompare' ( c-addr1 u1 c-addr2 u2 - n ) gforth-0.7 "capscompare"
   Compare two strings lexicographically, based on the values of the
bytes in the strings, but comparing ASCII characters case-insensitively,
and non-ASCII characters case-sensitively and without locale-specific
collation order.  If they are equal, n is 0; if the first string is
smaller, n is -1; if the first string is larger, n is 1.

'capsstring-prefix?' ( c-addr1 u1 c-addr2 u2 - f  ) gforth-1.0 "capsstring-prefix-question"
   Like 'string-prefix?', but case-insensitive for ASCII characters: Is
C-ADDR2 U2 a prefix of C-ADDR1 U1?

'capssearch' ( c-addr1 u1 c-addr2 u2 - c-addr3 u3 flag  ) gforth-1.0
   Like 'search', but case-insensitive for ASCII characters: Search for
c-addr2 u2 in c-addr1 u1; flag is true if found.

   The following words create or extend strings on the heap:

's+' ( c-addr1 u1 c-addr2 u2 - c-addr u  ) gforth-0.7 "s-plus"
   c-addr u is a newly 'allocate'd string that contains the
concatenation of c-addr1 u1 (first) and c-addr2 u2 (second).

'append' ( c-addr1 u1 c-addr2 u2 - c-addr u  ) gforth-0.7
   C-addr u is the concatenation of c-addr1 u1 (first) and c-addr2 u2
(second).  c-addr1 u1 is an 'allocate'd string, and 'append' 'resize's
it (possibly moving it to a new address) to accomodate u characters.

'>string-execute' ( ... xt - ... c-addr u  ) gforth-1.0 "to-string-execute"
   Execute xt while the standard output ('type', 'emit', and everything
that uses them) is redirected to a string.  The resulting string is
c-addr u, which is in heap memory; it is the responsibility of the
caller of '>string-execute' to 'free' this string.

'$tmp' ( xt - addr u  ) gforth-1.0 "string-t-m-p"
   Like '>string-execute', but the result is deallocated when '$tmp' is
invoked the next time, and you must not 'free' it yourself.

   One could define 's+' using '>string-execute', as follows:

     : s+ ( c-addr1 u1 c-addr2 u2 -- c-addr u )
       [: 2swap type type ;] >string-execute ;

   For concatenating just two strings '>string-execute' is inefficient,
but for concatenating many strings '>string-execute' can be more
efficient.

6.9.5 $tring words
------------------

The following string library stores strings in ordinary cell-size
variables (string handles).  These handles contain a pointer to a
cell-counted string allocated from the heap.  The string library
originates from bigFORTH.

   Because there is only one permanent reference to the contents (the
one in the handle), the string can be relocated or deleted without
worrying about dangling references; this requires that the programmer
uses references produced by, e.g., '$@' only for temporary purposes,
i.e., these references are not passed out, e.g., as return values or
stored in global memory, and words that may change the handle are not
called while these references exist.

   This library is complemented by the cell-pair representation: You use
the $tring words for variable strings which are cumbersome with the
c-addr u representation.  You use the cell-pair representation for
processing (e.g., inspecting) strings while they do not change.

'$!' ( addr1 u $addr -  ) gforth-0.7 "string-store"
   stores a newly allocated string buffer at an address, frees the
previous buffer if necessary.

'$@' ( $addr - addr2 u  ) gforth-0.7 "string-fetch"
   returns the stored string.

'$@len' ( $addr - u  ) gforth-0.7 "string-fetch-len"
   returns the length of the stored string.

'$!len' ( u $addr -  ) gforth-0.7 "string-store-len"
   changes the length of the stored string.  Therefore we must change
the memory area and adjust address and count cell as well.

'$+!len' ( u $addr - addr  ) gforth-1.0 "string-plus-store-len"
   make room for u bytes at the end of the memory area referenced by
$addr; addr is the address of the first of these bytes.

'$del' ( $addr off u -  ) gforth-0.7 "string-del"
   Deletes U bytes at offset OFF bytes in the string $ADDR.

'$ins' ( addr1 u $addr off -  ) gforth-0.7 "string-ins"
   Inserts string ADDR1 U at offset OFF bytes in the string $ADDR.

'$+!' ( addr1 u $addr -  ) gforth-0.7 "string-plus-store"
   appends a string to another.

'c$+!' ( char $addr -  ) gforth-1.0 "c-string-plus-store"
   append a character to a string.

'$free' ( $addr -  ) gforth-1.0 "string-free"
   free the string pointed to by addr, and set addr to 0

'$init' ( $addr -  ) gforth-1.0 "string-init"
   store an empty string there, regardless of what was in before

'$iter' ( .. $addr char xt - ..  ) gforth-0.7 "string-iter"
   Splits the string in $addr using char as separator.  For each part,
its descriptor c-addr u is pushed and xt '( ... c-addr u -- ... )' is
executed.

'$over' ( addr u $addr off -  ) gforth-1.0 "string-over"
   Overwrite U bytes at offset OFF bytes in the string $ADDR with the
string at ADDR U.

'$exec' ( xt $addr -  ) gforth-1.0 "string-exec"
   execute xt while the standard output (TYPE, EMIT, and everything that
uses them) is appended to the string in $ADDR.

'$.' ( $addr -  ) gforth-1.0 "string-dot"
   print a string, shortcut

'$slurp' ( fid $addr -  ) gforth-1.0 "string-slurp"
   Read the file fid until the end (without closing it) and put the read
data into the string at $addr.

'$slurp-file' ( c-addr u $addr -  ) gforth-1.0 "string-slurp-file"
   Put all the data in the file named c-addr u into the string at $addr.

'$+slurp' ( fid $addr -  ) gforth-1.0 "string-plus-slurp"
   Read the file fid until the end (without closing it) and append the
read data to the string at $addr.

'$+slurp-file' ( c-addr u $addr -  ) gforth-1.0 "string-plus+slurp-file"
   Append all the data in the file named c-addr u to the string at
$addr.

'$[]' ( u $[]addr - addr'  ) gforth-1.0 "string-array"
   Addr' is the address of the uth element of the string array $[]addr.
The array is resized if needed.

'$[]!' ( c-addr u n $[]addr -  ) gforth-1.0 "string-array-store"
   Store string c-addr y into the string array $[]addr at index n.  The
array is resized if needed.

'$[]+!' ( c-addr u n $[]addr -  ) gforth-1.0 "string-array-plus-store"
   Append the string c-addr u to the string at index n.  The array is
resized if needed.  Don't confuse this with '$+[]!'.

'$+[]!' ( c-addr u $[]addr -  ) gforth-1.0 "string-append-array"
   Store the string c-addr u as the new last element of string array
$[]addr.  The array is resized if needed.

'$[]@' ( n $[]addr - addr u  ) gforth-1.0 "string-array-fetch"
   fetch a string from array index n -- return the zero string if empty,
and don't accidentally grow the array.

'$[]#' ( $[]addr - len  ) gforth-1.0 "string-array-num"
   return the number of elements in an array

'$[]map' ( $[]addr xt -  ) gforth-1.0 "string-array-map"
   execute XT for all elements of the string array $[]ADDR.  xt is (
ADDR U - ), getting one string at a time

'$[]slurp' ( fid $[]addr -  ) gforth-1.0 "string-array-slurp"
   slurp a file FID line by line into a string array $[]ADDR

'$[]slurp-file' ( addr u $[]addr -  ) gforth-1.0 "string-array-slurp-file"
   slurp a named file ADDR U line by line into a string array $[]ADDR

'$[].' ( $[]addr -  ) gforth-1.0 "string-array-dot"
   print all array entries

'$[]free' ( $[]addr -  ) gforth-1.0 "string-array-free"
   $[]ADDR contains the address of a cell-counted string that contains
the addresses of a number of cell-counted strings; $[]free frees these
strings, frees the array, and sets addr to 0

'$Variable' ( "name" -  ) gforth-1.0 "string-variable"
   Defines a string variable whose content is preserved across
savesystem

'$[]Variable' ( "name" -  ) gforth-1.0 "string-array-variable"
   Defines a string array variable whose content is preserved across
savesystem

6.9.6 Counted string words
--------------------------

Counted strings store the length as byte at the address pointed to,
followed by the bytes of the string.  Their possible length is severely
limited, and you cannot create a substring in-place without destroying
the input string.  Therefore we recommend against using counted strings.
Nevertheless, if you have to deal with counted strings, here are some
words for that:

'count' ( c-addr1 - c-addr2 u ) core "count"
   c-addr2 is the first character and u the length of the counted string
at c-addr1.

   The following word has no useful interpretation semantics (unlike
's"') and no interpretive counterpart (unlike '[char]'), so you should
use it only inside colon definitions (if at all):

'C"' ( compilation "ccc<quote>" - ; run-time  - c-addr  ) core-ext "c-quote"
   Compilation: parse a string ccc delimited by a '"' (double quote).
At run-time, return c-addr which specifies the counted string ccc.
Interpretation semantics are undefined.

'place' ( c-addr1 u c-addr2 -  ) gforth-experimental "place"
   Create a counted string of length U at C-ADDR2 and copy the string
C-ADDR1 U into that location.  Up to 256 bytes starting at C-ADDR2 will
be written, so make sure that the buffer at c-addr2 has that much space
(or check that u+1 does not exceed the buffer size before calling
'place')

'string,' ( c-addr u -  ) gforth-0.2 "string-comma"
   Reserve u+1 bytes of dictionary space and store the string c-addr u
there as counted string.

6.10 Control Structures
=======================

Control structures in Forth cannot be used interpretively, only in a
colon definition(1).  We do not like this limitation, but have not seen
a satisfying way around it yet, although many schemes have been
proposed.

   ---------- Footnotes ----------

   (1) To be precise, in Standard Forth the control-flow words have no
interpretation semantics, and in Gforth the interpretation semantics of
the control-flow words are not useful for interpretive control flow
(*note Interpretation and Compilation Semantics::).

6.10.1 Selection
----------------

     flag IF
       code
     THEN

   If flag is non-zero (as far as 'IF' etc.  are concerned, a non-zero
cell represents truth), code is executed.

   You may wonder why 'then' ends an 'if' construct, which is at odds
with the usage of 'then' in some other programming languages, and with
the idiom "if ...  then ..."  in English.  According to 'Webster's New
Encyclopedic Dictionary', "then (adv.)"  has the following meanings:
     ...  2b: following next after in order ...  3d: as a necessary
     consequence (if you were there, then you saw them).
   Forth's 'then' has the meaning 2b, whereas 'THEN' in Pascal and many
other programming languages has the meaning 3d.  If you do not like this
usage of 'then', Gforth (but not Standard Forth) also has 'endif', which
can be used in its place.  Adding 'ENDIF' to a system that only supplies
'THEN' is simple:
     : ENDIF   POSTPONE then ; immediate

     flag IF
       code1
     ELSE
       code2
     THEN

   If FLAG is true, code1 is executed, otherwise code2 is executed.

   Gforth also provides the words '?DUP-IF' and '?DUP-0=-IF', so you can
avoid using '?dup'.  Using these alternatives is also more efficient
than using '?dup'.  Definitions in Standard Forth for 'ENDIF', '?DUP-IF'
and '?DUP-0=-IF' are provided in 'compat/control.fs'.

     x
     CASE
       x1 OF code1 ENDOF
       x2 OF code2 ENDOF
       ...
       ( x ) default-code ( x )
     ENDCASE ( )

   Executes the first codei, where the xi is equal to x.  If no xi
matches, the optional default-code is executed.  The optional default
case can be added by simply writing the code after the last 'ENDOF'.  It
may use x, which is on top of the stack, but must not consume it.  The
value x is consumed by this construction (either by an 'OF' that
matches, or by the 'ENDCASE', if no OF matches).  Example:

     : num-name ( n -- c-addr u )
      case
        0 of s" zero " endof
        1 of s" one "  endof
        2 of s" two "  endof
        \ default case:
        s" other number"
        rot \ get n on top so ENDCASE can drop it
      endcase ;

   Programming style note:

   To keep the code understandable, you should ensure that you change
the stack in the same way (wrt.  number and types of stack items
consumed and pushed) on all paths through a selection structure.

6.10.2 General Loops
--------------------

     BEGIN
       code1
       flag WHILE
         code2
     REPEAT

   code1 is executed and flag is computed.  If it is true, code2 is
executed and the loop is restarted; If flag is false, execution
continues after the 'REPEAT'.

     BEGIN
       code
       flag
     UNTIL

   code is executed.  The loop is restarted if 'flag' is false.

   Programming style note:

   To keep the code understandable, a complete iteration of the loop
should not change the number and types of the items on the stacks.

     BEGIN
       code
     AGAIN

   This is an endless loop.  You can leave it by leaving the enclosing
colon definition with 'exit' or 'throw', or with 'while' (*note General
loops with multiple exits::).

6.10.3 Counted Loops
--------------------

The basic counted loop is:
     limit start ?DO
       body
     LOOP

   This performs one iteration for every integer, starting from start
and up to, but excluding limit.  The counter, or index, can be accessed
with 'i'.  For example, the loop:
     10 0 ?DO
       i .
     LOOP
prints '0 1 2 3 4 5 6 7 8 9'

   The index of the innermost loop can be accessed with 'i', the index
of the next loop with 'j', and the index of the third loop with 'k'.

   You can access the limit of the innermost loop with 'i'' and 'i''-'i'
with 'delta-i'.  E.g., running

     : foo 7 5 ?do cr i . i' . delta-i . loop ;

   prints

     5 7 2
     6 7 1

   The loop control data are kept on the return stack, so there are some
restrictions on mixing return stack accesses and counted loop words.  In
particuler, if you put values on the return stack outside the loop, you
cannot read them inside the loop(1).  If you put values on the return
stack within a loop, you have to remove them before the end of the loop
and before accessing the index of the loop.

   There are several variations on the counted loop:

   * 'LEAVE' leaves the innermost counted loop immediately; execution
     continues after the associated 'LOOP' or 'NEXT'.  For example:

          10 0 ?DO  i DUP . 3 = IF LEAVE THEN LOOP
     prints '0 1 2 3'

   * 'UNLOOP' prepares for an abnormal loop exit, e.g., via 'EXIT'.
     'UNLOOP' removes the loop control parameters from the return stack
     so 'EXIT' can get to its return address.  For example:

          : demo 10 0 ?DO i DUP . 3 = IF UNLOOP EXIT THEN LOOP ." Done" ;
     prints '0 1 2 3'

   * If start is greater than limit, a '?DO' loop is entered (and 'LOOP'
     iterates until they become equal by wrap-around arithmetic).  This
     behaviour is usually not what you want.  Therefore, Gforth offers
     '+DO' and 'U+DO' (as replacements for '?DO'), which do not enter
     the loop if start is greater than limit; '+DO' is for signed loop
     parameters, 'U+DO' for unsigned loop parameters.

   * '?DO' can be replaced by 'DO'.  'DO' always enters the loop,
     independent of the loop parameters.  Do not use 'DO', even if you
     know that the loop is entered in any case.  Such knowledge tends to
     become invalid during maintenance of a program, and then the 'DO'
     will make trouble.

   * 'LOOP' can be replaced with 'n +LOOP'; this updates the index by n
     instead of by 1.  The loop is terminated when the border between
     limit-1 and limit is crossed.  E.g.:

          4 0 +DO  i .  2 +LOOP
     prints '0 2'

          4 1 +DO  i .  2 +LOOP
     prints '1 3'

   * The behaviour of 'n +LOOP' is peculiar when n is negative:

          -1 0 ?DO  i .  -1 +LOOP
     prints '0 -1'

          0 0 ?DO  i .  -1 +LOOP
     prints nothing.

     We recommend not combining '?DO' with '+LOOP'.  Gforth offers
     several alternatives:

     If you want '-1 +LOOP''s behaviour of including an iteration where
     'I'=limit, start the loop with '-[DO' or 'U-[DO' (where the '[' is
     inspired by the mathematical notation for inclusive ranges, e.g.,
     [1,n]):

          -1 0 -[DO  i .  -1 +LOOP

     prints '0 -1'.

          0 0 -[DO  i .  -1 +LOOP

     prints '0'.

          0 -1 -[DO  i .  -1 +LOOP

     prints nothing.

     If you want to exclude the limit, you instead use '1 -LOOP' (or
     generally 'u -LOOP') and start the loop with '?DO', '-DO' or
     'U-DO'.  '-LOOP' terminates the loop when the border between
     limit+1 and limit is crossed.  E.g.:

          -2 0 -DO  i .  1 -LOOP
     prints '0 -1'

          -1 0 -DO  i .  1 -LOOP
     prints '0'

          0 0 -DO  i .  1 -LOOP
     prints nothing.

     Unfortunately, '+DO', 'U+DO', '-DO', 'U-DO' and '-LOOP' are not
     defined in Standard Forth.  However, an implementation for these
     words that uses only standard words is provided in
     'compat/loops.fs'.

   * A common task is to iterate over the elements of an array, forwards
     or backwards.  Iterating over the addresses of the elements has two
     benefits: It avoids the need to keep the start address of the array
     around, reducing the data stack load; and it avoids the need to
     perform address computations in every iteration.  The disadvantage
     is that, starting with the usual array representations addr uelems
     or addr ubytes, some processing is required to produce a start and
     limit address.  Gforth has 'bounds' for getting there from the addr
     ubytes representation, so you can write a forward loop through a
     cell array 'v' as:

          create v 1 , 3 , 7 ,
          : foo v 3 cells bounds U+DO i @ . cell +LOOP ;
          foo

     which prints '1 3 7'.  Preprocessing the inputs for walking
     backwards is more involved, so Gforth provide a loop construct of
     the form 'MEM-DO'...'LOOP' that does it for you: It takes an array
     in addr ubytes representation and the element size, and iterates
     over the addresses of the elements in backwards order:

          create v 1 , 3 , 7 ,
          : foo1 v 3 cell array>mem MEM-DO i @ . LOOP ;
          foo1

     This prints '7 3 1'.  'ARRAY>MEM' converts the addr uelems
     uelemsize representation into the addr ubytes uelemsize
     representation expected by 'MEM-DO'.  This loop is finished with
     'LOOP' which decrements by uelemsize when it finishes a 'MEM-DO'.

     Gforth also adds 'MEM+DO' for completeness.  It takes the same
     parameters as 'MEM-DO', but walks forwards through the array:

          create v 1 , 3 , 7 ,
          : foo2 v 3 cell array>mem MEM+DO i @ . LOOP ;
          foo2

     prints '1 3 7'.

   * Another counted loop is:
          n
          FOR
            body
          NEXT
     This is the preferred loop of native code compiler writers who are
     too lazy to optimize '?DO' loops properly.  This loop structure is
     not defined in Standard Forth.  In Gforth, this loop iterates n+1
     times; 'i' produces values starting with n and ending with 0.
     Other Forth systems may behave differently, even if they support
     'FOR' loops.  To avoid problems, don't use 'FOR' loops.

   The counted-loop words are:

'?DO' ( compilation - do-sys ; run-time w1 w2 - | loop-sys  ) core-ext "question-do"
   *Note Counted Loops::.

'+DO' ( compilation - do-sys ; run-time n1 n2 - | loop-sys  ) gforth-0.2 "plus-do"
   *Note Counted Loops::.

'U+DO' ( compilation - do-sys ; run-time u1 u2 - | loop-sys  ) gforth-0.2 "u-plus-do"
   *Note Counted Loops::.

'bounds' ( u1 u2 - u3 u1 ) gforth-0.2 "bounds"
   Given a memory block represented by starting address addr and length
u in aus, produce the end address addr+u and the start address in the
right order for 'u+do' or '?do'.

'-[do' ( compilation - do-sys ; run-time n1 n2 - | loop-sys  ) gforth-experimental "minus-bracket-do"
   Start of a counted loop with negative stride; Skips the loop if
n2<n1; such a counted loop ends with '+loop' where the increment is
negative; it runs as long as 'I'>=n1.

'u-[do' ( compilation - do-sys ; run-time u1 u2 - | loop-sys  ) gforth-experimental "u-minus-bracket-do"
   Start of a counted loop with negative stride; Skips the loop if
u2<u1; such a counted loop ends with '+loop' where the increment is
negative; it runs as long as 'I'>=u1.

'-DO' ( compilation - do-sys ; run-time n1 n2 - | loop-sys  ) gforth-0.2 "minus-do"
   *Note Counted Loops::.

'U-DO' ( compilation - do-sys ; run-time u1 u2 - | loop-sys  ) gforth-0.2 "u-minus-do"
   *Note Counted Loops::.

'array>mem' ( uelements uelemsize - ubytes uelemsize  ) gforth-experimental "array-to-mem"
   ubytes=uelements*uelemsize

'mem+do' ( compilation - w xt do-sys; run-time addr ubytes +nstride -  ) gforth-experimental "mem-plus-do"
   Starts a counted loop that starts with 'I' as addr and then steps
upwards through memory with nstride wide steps as long as
'I'<addr+ubytes.  Must be finished with 'loop'.

'mem-do' ( compilation - w xt do-sys; run-time addr ubytes +nstride -  ) gforth-experimental "mem-minus-do"
   Starts a counted loop that starts with 'I' as addr+ubytes-nstride and
then steps backwards through memory with -nstride wide steps as long as
'I'>=addr.  Must be finished with 'loop'.

'DO' ( compilation - do-sys ; run-time w1 w2 - loop-sys  ) core
   *Note Counted Loops::.

'FOR' ( compilation - do-sys ; run-time u - loop-sys  ) gforth-0.2
   *Note Counted Loops::.

'LOOP' ( compilation do-sys - ; run-time loop-sys1 - | loop-sys2  ) core
   Finish a counted loop.  If started with 'mem+do' or 'mem-do', the
stride (increment) and terminating condition is given by these words,
otherwise the stride is 1 and the loop ends when the limit is reached
(the last iteration has 'i'=limit-1).

'+LOOP' ( compilation do-sys - ; run-time loop-sys1 n - | loop-sys2  ) core "plus-loop"
   *Note Counted Loops::.

'-LOOP' ( compilation do-sys - ; run-time loop-sys1 u - | loop-sys2  ) gforth-0.2 "minus-loop"
   *Note Counted Loops::.

'NEXT' ( compilation do-sys - ; run-time loop-sys1 - | loop-sys2  ) gforth-0.2
   *Note Counted Loops::.

'i' ( R:n - R:n n ) core "i"
   n is the index of the innermost counted loop.

'j' ( R:n R:w1 R:w2 - n R:n R:w1 R:w2 ) core "j"
   n is the index of the next-to-innermost counted loop.

'k' ( R:n R:w1 R:w2 R:w3 R:w4 - n R:n R:w1 R:w2 R:w3 R:w4 ) gforth-0.3 "k"
   n is the index of the third-innermost counted loop.

'i'' ( R:w R:w2 - R:w R:w2 w ) gforth-0.2 "i-tick"
   The limit of the innermost counted loop

'delta-i' ( r:ulimit r:u - r:ulimit r:u u2 ) gforth-1.0 "delta-i"
   u2='I''-'I' (difference between limit and index).

'LEAVE' ( compilation - ; run-time loop-sys -  ) core
   *Note Counted Loops::.

'?LEAVE' ( compilation - ; run-time f | f loop-sys -  ) gforth-0.2 "question-leave"
   *Note Counted Loops::.

'unloop' ( R:w1 R:w2 - ) core "unloop"

'DONE' ( compilation do-sys - ; run-time -  ) gforth-0.2
   resolves all LEAVEs up to the do-sys

   The standard does not allow using 'CS-PICK' and 'CS-ROLL' on do-sys.
Gforth allows it, except for the do-sys produced by 'MEM+DO' and
'MEM-DO', but it's your job to ensure that for every '?DO' etc.  there
is exactly one 'UNLOOP' on any path through the definition ('LOOP' etc.
compile an 'UNLOOP' on the fall-through path).  Also, you have to ensure
that all 'LEAVE's are resolved (by using one of the loop-ending words or
'DONE').

   ---------- Footnotes ----------

   (1) Not in a way that is portable.

6.10.4 General loops with multiple exits
----------------------------------------

For counted loops, you can use 'leave' in several places.  For 'begin'
loops, you have the following options:

   Use 'exit' (possibly several times) in the loop to leave not just the
loop, but the whole colon definition.  E.g.,:

     : foo
       begin
         condition1 while
           condition2 if
             exit-code2 exit then
           condition3 if
             exit-code3 exit then
         ...
       repeat
       exit-code1 ;

   The disadvantage of this approach is that, if you want to have some
common code afterwards, you either have to wrap 'foo' in another
definition that contains the common code, or you have to call the common
code several times, from each exit-code.

   Another approach is to use several 'while's in a 'begin' loop.  You
have to append a 'then' behind the loop for every additional 'while'.
E.g.,;

     begin
       condition1 while
         condition2 while
           condition3 while
     again then then then

   Here I used 'again' at the end of the loop so that I would have a
'then' for each 'while'; 'repeat' would result in one less 'then', but
otherwise the same behaviour.  For an explanation of why this works,
*Note Arbitrary control structures::.

   We can have common code afterwards, but, as presented above, we
cannot have different exit-codes for the different exits.  You can have
these different exit-codes, as follows:

     begin
       condition1 while
         condition2 while
           condition3 while
     again then exit-code3
     else exit-code2 then
     else exit-code1 then

   This is relatively hard to comprehend, because the exit-codes are
relatively far from the exit conditions (it does not help that we are
not used to such control structures, either).  The following extended
'case' does not have this problem.

6.10.5 General control structures with 'case'
---------------------------------------------

Gforth provides an extended 'case' that solves the problems of the
multi-exit loops discussed above, and offers additional options.  You
can find a portable implementation of this extended 'case' in
'compat/caseext.fs'.

   There are three additional words in the extension.  The first is
'?of' which allows general tests (rather than just testing for equality)
in a 'case'; e.g.,

     : sgn ( n -- -1|0|1 )
       ( n ) case
         dup 0 < ?of drop -1 endof
         dup 0 > ?of drop 1  endof
         \ otherwise leave the 0 on the stack
       0 endcase ;

   Note that 'endcase' drops a value, which works fine much of the time
with 'of', but usually not with '?of', so we leave a 0 on the stack for
'endcase' to drop.  The n that is passed into 'sgn' is also 0 if neither
'?of' triggers, and that is then passed out.

   The second additional word is 'next-case', which allows turning
'case' into a loop.  Our triple-exit loop becomes:

     case
       condition1 ?of exit-code1 endof
       condition2 ?of exit-code2 endof
       condition3 ?of exit-code3 endof
       ...
     next-case
     common code afterwards

   As you can see, this solves both problems of the variants discussed
above (*note General loops with multiple exits::).  Note that
'next-case' does not drop a value, unlike 'endcase'.(1)

   The last additional word is 'contof', which is used instead of
'endof' and starts the next iteration instead of leaving the loop.  This
can be used in ways similar to Dijkstra's guarded command do, e.g.:

     : gcd ( n1 n2 -- n )
         case
             2dup > ?of tuck - contof
             2dup < ?of over - contof
         endcase ;

   Here the two '?of's have different ways of continuing the loop; when
neither '?of' triggers, the two numbers are equal and are the gcd.
'Endcase' drops one of them, leaving the other as n.

   You can also combine these words.  Here's an example that uses each
of the 'case' words once, except 'endcase':

     : collatz ( u -- )
         \ print the 3n+1 sequence starting at u until we reach 1
         case
             dup .
             1 of endof
             dup 1 and ?of 3 * 1+ contof
             2/
         next-case ;

   This example keeps the current value of the sequence on the stack.
If it is 1, the 'of' triggers, drops the value, and leaves the 'case'
structure.  For odd numbers, the '?of' triggers, computes 3n+1, and
starts the next iteration with 'contof'.  Otherwise, if the number is
even, it is divided by 2, and the loop is restarted with 'next-case'.

   The 'case' words are:

'case' ( compilation  - case-sys ; run-time  -  ) core-ext
   Start a 'case' structure.

'endcase' ( compilation case-sys - ; run-time x -  ) core-ext "end-case"
   Finish the 'case' structure; drop x, and continue behind the
'endcase'.  Dropping x is useful in the original 'case' construct (with
only 'of's), but you may have to supply an x in other cases (especially
when using '?of').

'next-case' ( compilation case-sys - ; run-time -  ) gforth-1.0
   Restart the 'case' loop by jumping to the matching 'case'.  Note that
'next-case' does not drop a cell, unlike 'endcase'.

'of' ( compilation  - of-sys ; run-time x1 x2 - |x1  ) core-ext
   If x1=x2, continue (dropping both); otherwise, leave x1 on the stack
and jump behind 'endof' or 'contof'.

'?of' ( compilation  - of-sys ; run-time  f -  ) gforth-1.0 "question-of"
   If f is true, continue; otherwise, jump behind 'endof' or 'contof'.

'endof' ( compilation case-sys1 of-sys - case-sys2 ; run-time  -  ) core-ext "end-of"
   Exit the enclosing 'case' structure by jumping behind
'endcase'/'next-case'.

'contof' ( compilation case-sys1 of-sys - case-sys2 ; run-time  -  ) gforth-1.0 "cont-of"
   Restart the 'case' loop by jumping to the enclosing 'case'.

Internally, of-sys is an 'orig'; and case-sys is a cell and some
stack-depth information, 0 or more 'orig's, and a 'dest'.

   ---------- Footnotes ----------

   (1) The name 'next-case' has a '-', unlike the other 'case' words,
because VFX Forth has a 'next-case' that works like Gforth's
'next-case', but also contains a 'nextcase' that drops a value; in VFX
you need to pair 'next-case' with 'begincase', however.

6.10.6 Arbitrary control structures
-----------------------------------

Standard Forth permits and supports using control structures in a
non-nested way.  Information about incomplete control structures is
stored on the control-flow stack.  This stack may be implemented on the
Forth data stack, and this is what we have done in Gforth.

   An orig entry represents an unresolved forward branch, a dest entry
represents a backward branch target.  A few words are the basis for
building any control structure possible (except control structures that
need storage, like calls, coroutines, and backtracking).

'IF' ( compilation - orig ; run-time f -  ) core
   At run-time, if f=0, execution continues after the 'THEN' (or 'ELSE')
that consumes the orig, otherwise right after the 'IF' (*note
Selection::).

'AHEAD' ( compilation - orig ; run-time -  ) tools-ext
   At run-time, execution continues after the 'THEN' that consumes the
orig.

'THEN' ( compilation orig - ; run-time -  ) core
   The 'IF', 'AHEAD', 'ELSE' or 'WHILE' that pushed orig jumps right
after the 'THEN' (*note Selection::).

'BEGIN' ( compilation - dest ; run-time -  ) core
   The 'UNTIL', 'AGAIN' or 'REPEAT' that consumes the dest jumps right
behind the 'BEGIN' (*note General Loops::).

'UNTIL' ( compilation dest - ; run-time f -  ) core
   At run-time, if f=0, execution continues after the 'BEGIN' that
produced dest, otherwise right after the 'UNTIL' (*note General
Loops::).

'AGAIN' ( compilation dest - ; run-time -  ) core-ext
   At run-time, execution continues after the 'BEGIN' that produced the
dest (*note General Loops::).

'CS-PICK' ( dest0/orig0 dest1/orig1 ... destu/origu u - ... dest0/orig0  ) tools-ext "c-s-pick"

'CS-ROLL' ( destu/origu .. dest0/orig0 u - .. dest0/orig0 destu/origu  ) tools-ext "c-s-roll"

'CS-DROP' ( dest/orig -  ) gforth-1.0

   The Standard words 'cs-pick' and 'cs-roll' allow you to manipulate
the control-flow stack in a portable way.  Without them, you would need
to know how many stack items are occupied by a control-flow entry (Many
systems use one cell.  In Gforth they currently take four cells, but
this may change in the future).

   When using 'cs-pick' and 'cs-drop' on an orig, you need to use one
'cs-drop' for every 'cs-pick' (and vice versa) of a given orig, because
the orig must be resolved by 'then' exactly once.

   Some standard control structure words are built from these words:

'ELSE' ( compilation orig1 - orig2 ; run-time -  ) core
   At run-time, execution continues after the 'THEN' that consumes the
orig; the 'IF', 'AHEAD', 'ELSE' or 'WHILE' that pushed orig1 jumps right
after the 'ELSE'.  (*note Selection::).

'WHILE' ( compilation dest - orig dest ; run-time f -  ) core
   At run-time, if f=0, execution continues after the 'REPEAT' (or
'THEN' or 'ELSE') that consumes the orig, otherwise right after the
'WHILE' (*note General Loops::).

'REPEAT' ( compilation orig dest - ; run-time -  ) core
   At run-time, execution continues after the 'BEGIN' that produced the
dest; the 'WHILE', 'IF', 'AHEAD' or 'ELSE' that pushed orig jumps right
after the 'REPEAT'.  (*note General Loops::).

Gforth adds some more control-structure words:

'ENDIF' ( compilation orig - ; run-time -  ) gforth-0.2
   Same as 'THEN'.

'?dup-IF' ( compilation - orig ; run-time n - n|  ) gforth-0.2 "question-dupe-if"
   This is the preferred alternative to the idiom "'?DUP IF'", since it
can be better handled by tools like stack checkers.  Besides, it's
faster.

'?DUP-0=-IF' ( compilation - orig ; run-time n - n|  ) gforth-0.2 "question-dupe-zero-equals-if"

6.10.7 Calls and returns
------------------------

A definition can be called simply be writing the name of the definition
to be called.  Normally a definition is invisible during its own
definition.  If you want to write a directly recursive definition, you
can use 'recursive' to make the current definition visible, or 'recurse'
to call the current definition directly.

'recursive' ( compilation - ; run-time -  ) gforth-0.2
   Make the current definition visible, enabling it to call itself
recursively.

'recurse' ( ... - ...  ) core
   Alias to the current definition.

For examples of using these words, *Note Recursion Tutorial::.

   Programming style note:

   I prefer using 'recursive' to 'recurse', because calling the
definition by name is more descriptive (if the name is well-chosen) than
the somewhat cryptic 'recurse'.  E.g., in a quicksort implementation, it
is much better to read (and think) "now sort the partitions" than to
read "now do a recursive call".

   For mutual recursion, Gforth offers the defining word 'forward'.  You
can use it to create a forward reference which is resolved
automatically, and does not incur additional costs like the indirection
of 'Defer'.  However, these forward definitions only work for colon
definitions.  Here's a usage example:

     forward foo

     : bar ( ... -- ... )
      ... foo ... ;

     : foo ( ... -- ... ) \ resolves the forward definition
      ... bar ... ;

   The words used for forward definitions are:

'forward' ( "name" -  ) gforth-1.0
   Defines a forward reference to a colon definition.  Defining a colon
definition with the same name in the same wordlist resolves the forward
references.  Use '.unresolved' to check whether any forwards are
unresolved.

'.unresolved' ( -  ) gforth-1.0 "dot-unresolved"
   print all unresolved forward references

   In Standard Forth, you use 'Defer'red words for mutual recursion,
like this:

     Defer foo

     : bar ( ... -- ... )
      ... foo ... ;

     :noname ( ... -- ... )
      ... bar ... ;
     IS foo

   Deferred words are discussed in more detail in *note Deferred
Words::.

   The current definition returns control to the calling definition when
the end of the definition is reached or 'EXIT' is encountered.

'EXIT' ( compilation - ; run-time nest-sys -  ) core
   Return to the calling definition; usually used as a way of forcing an
early return from a definition.  Before 'EXIT'ing you must clean up the
return stack and 'UNLOOP' any outstanding '?DO'...'LOOP's.

'?EXIT' ( -  ) gforth-0.2 "question-exit"
   Return to the calling definition if f is true.

6.10.8 Exception Handling
-------------------------

If a word detects an error condition that it cannot handle, it can
'throw' an exception.  In the simplest case, this will terminate your
program, and report an appropriate error.

'throw' ( y1 .. ym nerror - y1 .. ym / z1 .. zn nerror  ) exception
   If nerror is 0, drop it and continue.  Otherwise, transfer control to
the next dynamically enclosing exception handler, reset the stacks
accordingly, and push nerror.

'fast-throw' ( ... nerror - ... nerror ) gforth-experimental "fast-throw"
   Lightweight 'throw' variant: only for non-zero nerrors, and does not
store a backtrace or deal with missing 'catch'.

   'Throw' consumes a cell-sized error number on the stack.  There are
some predefined error numbers in Standard Forth (see 'errors.fs').  In
Gforth (and most other systems) you can use the iors produced by various
words as error numbers (e.g., a typical use of 'allocate' is 'allocate
throw').  Gforth also provides the word 'exception' to define your own
error numbers (with decent error reporting); a Standard Forth version of
this word (but without the error messages) is available in
'compat/except.fs'.  And finally, you can use your own error numbers
(anything outside the range -4095..0), but won't get nice error
messages, only numbers.  For example, try:

     -10 throw                    \ Standard defined
     -267 throw                   \ system defined
     s" my error" exception throw \ user defined
     7 throw                      \ arbitrary number

'exception' ( addr u - n  ) gforth-0.2
   N is a previously unused 'throw' value in the range (-4095...-256).
Consecutive calls to 'exception' return consecutive decreasing numbers.
Gforth uses the string ADDR U as an error message.

   There are also cases where you have a word (typically modeled after
POSIX' 'strerror') for converting an error number into a string.  You
can use the following word to get these strings into Gforth's error
handling:

'exceptions' ( xt n1 - n2  ) gforth-1.0
   Xt '( +n -- c-addr u )' converts an error number in the range 0<=n<n1
into an error message.  'Exceptions' reserves n1 error codes in the
range n2-n1<n3<=n2.  When (at some later point in time) the Gforth error
code n3 in that range is thrown, it pushes n2-n3 and then executes xt to
produce the error message.

   As an example, if the 'errno' errors (and the conversion using
'strerror') was not already directly supported by Gforth, you could tie
'strerror' in as follows:

     ' strerror 1536 exceptions constant errno-base
     : errno-ior ( -- n )
     \ n is the Gforth ior corresponding to the value in errno, so
     \ we have to convert between the ranges here.
     \ ERRNO is not a Gforth word, so you  would have to use the
     \ C interface to access it.
       errno errno-base over - swap 0<> and ;

   When you call a C function that can set 'errno' (with the C
interface, *note C Interface::), you can use one of the following words
for converting that error into a 'throw':

'?errno-throw' ( f -  ) gforth-1.0 "question-errno-throw"
   If f<>0, throws an error code based on the value of 'errno'.

'?ior' ( x -  ) gforth-1.0 "question-i-o-r"
   If f=-1, throws an error code based on the value of 'errno'.

   Which of these you should use depends on how the C function indicates
that an error has happened.  When the system then catches a throw
performed by one of these words, it produces the proper error message
(such as "Permission denied").

   Note that the errno numbers are not directly used as throw codes
(because the Forth standard specifies that positive throw codes must not
be system-defined), but maps them into a different number range.

   A common idiom to 'THROW' a specific err# if a flag is true is this:

     ( flag ) 0<> err# and throw

   Your program can provide exception handlers to catch exceptions.  An
exception handler can be used to correct the problem, or to clean up
some data structures and just throw the exception to the next exception
handler.  Note that 'throw' jumps to the dynamically innermost exception
handler.  The system's exception handler is outermost, and just prints
an error and restarts command-line interpretation (or, in batch mode
(i.e., while processing the shell command line), leaves Gforth).

   The Standard Forth way to catch exceptions is 'catch':

'catch' ( x1 .. xn xt - y1 .. ym 0 / z1 .. zn error  ) exception
   'Executes' xt.  If execution returns normally, 'catch' pushes 0 on
the stack.  If execution returns through 'throw', all the stacks are
reset to the depth on entry to 'catch', and the TOS (the xt position) is
replaced with the throw code.

'catch-nobt' ( x1 .. xn xt - y1 .. ym 0 / z1 .. zn error  ) gforth-experimental
   perform a catch that does not record backtraces on errors

'nothrow' ( -  ) gforth-0.7
   Use this (or the standard sequence '['] false catch 2drop') after a
'catch' or 'endtry' that does not rethrow; this ensures that the next
'throw' will record a backtrace.

   The most common use of exception handlers is to clean up the state
when an error happens.  E.g.,

     base @ >r hex \ actually the HEX should be inside foo to protect
                   \ against exceptions between HEX and CATCH
     ['] foo catch ( nerror|0 )
     r> base !
     ( nerror|0 ) throw \ pass it on

   A use of 'catch' for handling the error 'myerror' might look like
this:

     ['] foo catch
     CASE
       myerror OF ... ( do something about it ) nothrow ENDOF
       dup throw \ default: pass other errors on, do nothing on non-errors
     ENDCASE

   Having to wrap the code into a separate word is often cumbersome,
therefore Gforth provides an alternative syntax:

     TRY
       code1
       IFERROR
         code2
       THEN
       code3
     ENDTRY

   This performs code1.  If code1 completes normally, execution
continues with code3.  If there is an exception in code1 or before
'endtry', the stacks are reset to the depth during 'try', the throw
value is pushed on the data stack, and execution continues at code2, and
finally falls through to code3.

'try' ( compilation  - orig ; run-time  - R:sys1  ) gforth-0.5
   Start an exception-catching region.

'endtry' ( compilation  - ; run-time  R:sys1 -  ) gforth-0.5
   End an exception-catching region.

'iferror' ( compilation  orig1 - orig2 ; run-time  -  ) gforth-0.7
   Starts the exception handling code (executed if there is an exception
between 'try' and 'endtry').  This part has to be finished with 'then'.

   If you don't need code2, you can write 'restore' instead of 'iferror
then':

     TRY
       code1
     RESTORE
       code3
     ENDTRY

   The cleanup example from above in this syntax:

     base @ { oldbase }
     TRY
       hex foo \ now the hex is placed correctly
       0       \ value for throw
     RESTORE
       oldbase base !
     ENDTRY
     throw

   An additional advantage of this variant is that an exception between
'restore' and 'endtry' (e.g., from the user pressing 'Ctrl-C') restarts
the execution of the code after 'restore', so the base will be restored
under all circumstances.

   However, you have to ensure that this code does not cause an
exception itself, otherwise the 'iferror'/'restore' code will loop.
Moreover, you should also make sure that the stack contents needed by
the 'iferror'/'restore' code exist everywhere between 'try' and
'endtry'; in our example this is achieved by putting the data in a local
before the 'try' (you cannot use the return stack because the exception
frame (sys1) is in the way there).

   This kind of usage corresponds to Lisp's 'unwind-protect'.

   If you do not want this exception-restarting behaviour, you achieve
this as follows:

     TRY
       code1
     ENDTRY-IFERROR
       code2
     THEN

   If there is an exception in code1, then code2 is executed, otherwise
execution continues behind the 'then' (or in a possible 'else' branch).
This corresponds to the construct

     TRY
       code1
     RECOVER
       code2
     ENDTRY

   in Gforth before version 0.7.  So you can directly replace
'recover'-using code; however, we recommend that you check if it would
not be better to use one of the other 'try' variants while you are at
it.

   To ease the transition, Gforth provides two compatibility files:
'endtry-iferror.fs' provides the 'try ... endtry-iferror ... then'
syntax (but not 'iferror' or 'restore') for old systems;
'recover-endtry.fs' provides the 'try ... recover ... endtry' syntax on
new systems, so you can use that file as a stopgap to run old programs.
Both files work on any Gforth (they just do nothing if the system
already has the syntax it implements), so you can unconditionally
'require' one of these files, even if you use a mix old and new Gforths.

'restore' ( compilation  orig1 - ; run-time  -  ) gforth-0.7
   Starts restoring code, that is executed if there is an exception, and
if there is no exception.

'endtry-iferror' ( compilation  orig1 - orig2 ; run-time  R:sys1 -  ) gforth-0.7
   End an exception-catching region while starting exception-handling
code outside that region (executed if there is an exception between
'try' and 'endtry-iferror').  This part has to be finished with 'then'
(or 'else'...'then').

   Here's the error handling example:

     TRY
       foo
     ENDTRY-IFERROR
       CASE
         myerror OF ... ( do something about it ) nothrow ENDOF
         throw \ pass other errors on
       ENDCASE
     THEN

   Programming style note:

   As usual, you should ensure that the stack depth is statically known
at the end: either after the 'throw' for passing on errors, or after the
'ENDTRY' (or, if you use 'catch', after the end of the selection
construct for handling the error).

   There are two alternatives to 'throw': 'Abort"' is conditional and
you can provide an error message.  'Abort' just produces an "Aborted"
error.

   The problem with these words is that exception handlers cannot
differentiate between different 'abort"'s; they just look like '-2
throw' to them (the error message cannot be accessed by standard
programs).  Similarly, 'abort' looks like '-1 throw' to exception
handlers.

'ABORT"' ( compilation 'ccc"' - ; run-time ... f -  ) core,exception-ext "abort-quote"
   If any bit of f is non-zero, perform the function of '-2 throw',
displaying the string ccc if there is no exception frame on the
exception stack.

'abort' ( ?? - ??  ) core,exception-ext
   '-1 throw'.

   For problems that are not that awful that you need to abort
execution, you can just display a warning.  The variable 'warnings'
allows to tune how many warnings you see.

'WARNING"' ( compilation 'ccc"' - ; run-time f -  ) gforth-1.0 "warning-quote"
   if f is non-zero, display the string ccc as warning message.

'warnings' ( - addr  ) gforth-0.2
   Set warnings level to
'0'
     turns warnings off
'-1'
     turns normal warnings on
'-2'
     turns beginner warnings on
'-3'
     turns pedantic warnings on
'-4'
     turns warnings into errors (including beginner warnings)

6.11 Defining Words
===================

Defining words are used to extend Forth by creating new entries in the
dictionary.

6.11.1 'CREATE'
---------------

The simplest defining word is 'CREATE', used like this:

     CREATE new-word1

   'CREATE' is a parsing word, i.e., it takes an argument from the input
stream ('new-word1' in our example).  It generates a dictionary entry
for 'new-word1'.  When 'new-word1' is executed, all that it does is
leave an address on the stack.  The address represents the value of the
dictionary pointer ('HERE') at the time that 'new-word1' was defined.
Therefore, 'CREATE' is a way of associating a name with the address of a
region of memory.

'Create' ( "name" -  ) core

   Note that Standard Forth guarantees only for 'create' that its body
is contiguous with the following dictionary allocations (e.g., 'allot',
*note Dictionary allocation::).  Also, in Standard Forth only 'create'd
words can be modified with 'does>' (*note User-defined Defining
Words::).  And in Standard Forth '>body' can only be applied to
'create'd words.

   By extending this example to reserve some memory in data space, we
end up with something like a variable.  Here are two different ways to
do it:

     CREATE new-word2 1 cells allot  \ reserve 1 cell without initializing it
     CREATE new-word3 4 ,            \ reserve 1 cell and initialise it (to 4)

   The variable can be examined and modified using '@' ("fetch") and '!'
("store") like this:

     new-word2 @ .      \ get address, fetch from it and display
     1234 new-word2 !   \ new value, get address, store to it

   A similar mechanism can be used to create arrays.  For example, an
80-character text buffer:

     CREATE text-buf 80 allot \ uninitialized

     text-buf 0 + c@ \ the 1st character (offset 0)
     text-buf 3 + c@ \ the 4th character (offset 3)

   You can build arbitrarily complex data structures by allocating
appropriate areas of memory.  For further discussions of this, and to
learn about some Gforth tools that make it easier, *Note Structures::.

6.11.2 Variables
----------------

The previous section showed how a sequence of commands could be used to
generate a variable.  As a final refinement, the whole code sequence can
be wrapped up in a defining word, making it easier to create new
variables:

     : myvariableX ( "name" -- a-addr ) CREATE 1 cells allot ;
     : myvariable0 ( "name" -- a-addr ) CREATE 0 , ;

     myvariableX foo \ variable foo starts off with an unknown value
     myvariable0 joe \ whilst joe is initialised to 0

     45 3 * foo !   \ set foo to 135
     1234 joe !     \ set joe to 1234
     3 joe +!       \ increment joe by 3.. to 1237

   Not surprisingly, there is no need to define 'myvariableX', since
Forth already has a definition 'Variable'.  Standard Forth does not
guarantee that a 'Variable' is initialised when it is created (i.e., it
may behave like 'myvariableX').  In contrast, Gforth's 'Variable'
initialises the variable to 0 (i.e., it behaves exactly like
'myvariable0').  Forth also provides '2Variable' and 'fvariable' for
double and floating-point variables, respectively - they are initialised
to #0.  and 0e in Gforth.  If you use a 'Variable' to store a boolean,
you can use 'on' and 'off' to toggle its state (*note Boolean Flags::).

'Variable' ( "name" -  ) core
   Define name and reserve a cell at addr.
name execution: '( -- addr )'.

'AVariable' ( "name" -  ) gforth-0.2
   Works like 'variable', but (when used in cross-compiled code) tells
the cross-compiler that the cell stored in the variable is an address.

'2Variable' ( "name" -  ) double "two-variable"
   Define name and reserve two cells starting at addr.
name execution: '( -- addr )'.

'fvariable' ( "name" -  ) floating "f-variable"
   Define name and reserve a float at f-addr.
name execution: '( -- f-addr )'.

   Finally, for buffers of arbitrary length there is

'buffer:' ( u "name" -  ) core-ext "buffer-colon"
   Define name and reserve u bytes starting at addr.  Gforth initializes
the reserved bytes to 0, but the standard does not guarantee this.
name execution: '( -- addr )'.

6.11.3 Constants
----------------

'Constant' allows you to declare a fixed value and refer to it by name.
For example:

     12 Constant INCHES-PER-FOOT \ is integer appropriate
     2.54e fconstant CM-PER-INCH

   A 'Variable' can be both read and written, so its run-time behaviour
is to supply an address through which its current value can be
manipulated.  In contrast, the value of a 'Constant' cannot be changed
once it has been declared(1) so it's not necessary to supply the address
- it is more efficient to return the value of the constant directly.
That's exactly what happens; the run-time effect of a constant is to put
its value on the top of the stack (You can find one way of implementing
'Constant' in *note User-defined Defining Words::).

   Forth also provides '2Constant' and 'fconstant' for defining double
and floating-point constants, respectively.

'Constant' ( w "name" -  ) core
   Define name.
name execution: ( - w )

'AConstant' ( addr "name" -  ) gforth-0.2
   Like 'constant', but defines a constant for an address (this only
makes a difference in the cross-compiler).

'2Constant' ( w1 w2 "name" -  ) double "two-constant"
   Define name.
name execution: ( - w1 w2 )

'fconstant' ( r "name" -  ) floating "f-constant"
   Define name.
name execution: ( - r )

   ---------- Footnotes ----------

   (1) Well, often it can be - but not in a Standard, portable way.
It's safer to use a 'Value' (read on).

6.11.4 Values
-------------

A 'Value' behaves like a 'Constant', but it can be changed.  'TO' and
'+TO' are parsing words that change a value.  Alternatively, you can
change a value 'v' by writing '->v' (equivalent to 'TO v') or '+>v'
(equivalent to '+TO v').

   Here are some examples:

     12 value apples \ Define APPLES with an initial value of 12
     34 to apples    \ Change the value of APPLES. TO is a parsing word
     34 ->apples     \ Change the value of APPLES. Non-standard usage
     1  +to apples   \ Increment APPLES.  Non-standard usage.
     1  +>apples     \ Increment APPLES.  Non-standard usage.
     apples          \ puts 36 on the top of the stack.

'Value' ( w "name" -  ) core-ext
   Define name with the initial value w
name execution: ( - w2 ) push the current value of name.
'to name' run-time: ( w3 - ) change the value of name to w3.
'+to name' run-time: ( n|u - ) increment the value of name by n|u

'AValue' ( w "name" -  ) gforth-0.6
   Like 'value', but defines a value for an address (this only makes a
difference in the cross-compiler).

'2Value' ( w1 w2 "name" -  ) double-ext "two-value"
   Define name with the initial value w
name execution: ( - w3 w4 ) push the current value of name.
'to name' run-time: ( w5 w6 - ) change the value of name to w5 w6.
'+to name' run-time: ( d|ud - ) increment the value of name by d|ud

'fvalue' ( r "name" -  ) floating-ext "f-value"
   Define name with the initial value r
name execution: ( - r2 ) push the current value of name.
'to name' run-time: ( r3 - ) change the value of name to r3.
'+to name' run-time: ( r4 - ) increment the value of name by r4

'TO' ( value ... "name" -  ) core-ext
   Name is a value-flavoured word, ...  is optional additional
addressing information, e.g., for a value-flavoured field.  At run-time,
perform the to name semantics: change name (with the same additional
addressing information) to push value.  The type of value depends on the
type of name (see the defining word for name for the actual type).  An
alternative syntax is to write '->name'.

'+TO' ( value ... "name" -  ) gforth-1.0 "plus-TO"
   Name is a value-flavoured word, ...  is optional additional
addressing information, e.g., for a value-flavoured field.  At run-time,
perform the +to name semantics: if name (with the same additional
addressing information) pushed value1 before, change it to push value2,
the sum of the value1 and value.  The type of value depends on the type
of name (see the defining word for name for the actual type).  An
alternative syntax is to write '+>name'.

   Words that produce their value on execution and that can be changed
with 'to' or '+to' are called value-flavoured (in contrast to the
variable-flavoured words that produce their address on execution).  They
are defined be some of the words listed above, but also by some locals
definitions words (*note Locals definition words::) and some field
definition words (*note Value-Flavoured and Defer-Flavoured Fields::).

   Sometimes you want to take the address of a value-flavoured word.
Because this has some potential performance disadvantages, Gforth asks
you to be explicit about it, and define the word as addressable.  Once
you have done that, you can get the address with 'addr'.  The following
example is equivalent to the one above:

     12 addressable: value apples
     34 addr apples ! \ Change the value of APPLES.  ADDR is a parsing word
     1 +to apples     \ Increment APPLES
     addr apples @    \ puts 35 on the top of the stack.

'addressable:' ( -  ) gforth-experimental "addressable-colon"
   'Addressable:' should be used in front of a defining word for a
value-flavoured word (e.g., 'value').  It allows to use 'addr' on the
word defined by that defining word.

'addr' ( interpretation "name" ... - addr; compilation "name" - ; run-time ... - addr  ) gforth-1.0
   Name is an 'addressable:' value-flavoured word, ...  is optional
additional addressing information, e.g., for a value-flavoured field.
Addr is the address where the value of name (taking the additional
address information into account) is stored.

   For now using 'addr' on a non-'addressable:' value results in a
warning.  In the future, when we change the code generation in a way
that results in potentially faster code for non-'addressable:' values,
but where the use of 'addr' on such values could produce unexpected
results, such usage will result in an error.

6.11.5 Colon Definitions
------------------------

     : name ( ... -- ... )
         word1 word2 word3 ;

Creates a word called 'name' that, upon execution, executes 'word1 word2
word3'.  'name' is a "(colon) definition".

   The explanation above is somewhat superficial.  For simple examples
of colon definitions see *note Your first definition::.  For an in-depth
discussion of some of the issues involved, *Note Interpretation and
Compilation Semantics::.

':' ( "name" - colon-sys  ) core "colon"

';' ( compilation colon-sys - ; run-time nest-sys -  ) core "semicolon"

6.11.6 Inline Definitions
-------------------------

We plan to to perform automatic inlining eventually, but for now you can
perform inlining with

'inline:' ( "name" - inline:-sys  ) gforth-experimental "inline-colon"
   Start inline colon definition.  The code between 'inline:' and
';inline' has to compile (not perform) the code to be inlined, but the
resulting definition name is a colon definition that performs the
inlined code.  Note that the compiling code must have the stack effect
'( -- )', otherwise you will get an error when Gforth tries to create
the colon definition for name.

';inline' ( inline:-sys -  ) gforth-experimental "semi-inline"
   end inline definition started with 'inline:'

   As an example, you can define an inlined word and use it with

     inline: my2dup ( a b -- a b a b )
         ]] over over [[ ;inline

     #1. my2dup d. d.
     : foo my2dup ;
     #1. foo d. d.
     see foo

   Inline words are related to macros (*note Macros::); the difference
is that a macro has immediate compilation semantics while an
'inline:'-defined word has default compilation semantics; this means
that you normally use a macro only inside a colon definition, while you
can use an 'inline:' word also interpretively.  But that also means that
you can do some things with macros that you cannot do as an 'inline:'
word.  E.g.,

     \ Doesn't work:
     \   inline: endif ]] then [[ ;inline
     \ Instead, write a macro:
     : endif ]] then [[ ; immediate

   Conversely, for words that would be fine as non-immediate colon
definitions, define them as non-immediate colon definitions or (if
utmost performance is required) as 'inline:' words; don't define them as
macros, because then you cannot properly use them interpretively:

     : another2dup ]] over over [[ ; immediate
     \ Doesn't work:
     \   #1. another2dup d. d.

   You may wonder why you have to write compiling code between 'inline:'
and ';inline'.  That's because the implementation of an inline word like
'my2dup' above works similar to:

     : compile-my2dup ( xt -- )
         drop ]] over over [[ ;

     : my2dup [ 0 compile-my2dup ] ;
     ' compile-my2dup set-optimizer

   The 'DROP' and '0' are there because 'compile-my2dup' is the
implementation of 'compile,' for 'my2dup', and 'compile,' expects an xt
(*note User-defined compile-comma::).

6.11.7 Anonymous Definitions
----------------------------

Sometimes you want to define an "anonymous word"; a word without a name.
You can do this with:

':noname' ( - xt colon-sys  ) core-ext "colon-no-name"

   This leaves the execution token for the word on the stack after the
closing ';'.  Here's an example in which a deferred word is initialised
with an 'xt' from an anonymous colon definition:

     Defer deferred
     :noname ( ... -- ... )
       ... ;
     IS deferred

Gforth provides an alternative way of doing this, using two separate
words:

'noname' ( -  ) gforth-0.2
   The next defined word will be anonymous.  The defining word will
leave the input stream alone.  The xt of the defined word will be given
by 'latestxt', its nt by 'latestnt' (*note Name token::).

'latestxt' ( - xt  ) gforth-0.6
   xt is the execution token of the most recent word defined in the
current section.

The previous example can be rewritten using 'noname' and 'latestxt':

     Defer deferred
     noname : ( ... -- ... )
       ... ;
     latestxt IS deferred

'noname' works with any defining word, not just ':'.

   'latestxt' also works when the last word was not defined as 'noname'.
It also has the useful property that it is valid as soon as the header
for a definition has been built.  Thus:

     latestxt . : foo [ latestxt . ] ; ' foo .

prints 3 numbers; the last two are the same.

6.11.8 Quotations
-----------------

A quotation is an anonymous colon definition inside another colon
definition.  Quotations are useful when dealing with words that consume
an execution token, like 'catch' or 'outfile-execute'.  E.g.  consider
the following example of using 'outfile-execute' (*note Redirection::):

     : some-warning ( n -- )
         cr ." warning# " . ;

     : print-some-warning ( n -- )
         ['] some-warning stderr outfile-execute ;

   Here we defined 'some-warning' as a helper word whose xt we could
pass to outfile-execute.  Instead, we can use a quotation to define such
a word anonymously inside 'print-some-warning':

     : print-some-warning ( n -- )
       [: cr ." warning# " . ;] stderr outfile-execute ;

   The quotation is bounded by '[:' and ';]'.  It produces an execution
token at run-time.

'[:' ( compile-time: - quotation-sys flag colon-sys  ) gforth-1.0 "bracket-colon"
   Starts a quotation in the next section.

';]' ( compile-time: quotation-sys - ; run-time: - xt  ) gforth-1.0 "semi-bracket"
   Ends a quotation (represented by xt) and switch to the previous
section.  'Latestxt' and 'latestnt' refer to the last word in the
current section, i.e., not to the quotation.

6.11.9 Supplying the name of a defined word
-------------------------------------------

By default, a defining word takes the name for the defined word from the
input stream.  Sometimes you want to supply the name from a string.  You
can do this with:

'nextname' ( c-addr u -  ) gforth-0.2
   The next defined word will have the name C-ADDR U; the defining word
will leave the input stream alone.

   For example:

     s" foo" nextname create

is equivalent to:

     create foo

'nextname' works with any defining word.

6.11.10 User-defined Defining Words
-----------------------------------

You can define new defining words in terms of any existing defining
word, but ':' and 'create'...'does>'/'set-does>' are particularly
flexible, whereas the children of, e.g., 'constant' are all just
constants.

6.11.10.1 User-defined defining words with colon definitions
............................................................

Colon definitions are very flexible, so you can write a defining word
that defines a new colon definition at its run-time.  Here is an
example:

     : myconstant {: w -- :}
       : w postpone literal postpone ; ;

   When defining '5 myconstant five', 'myconstant' first stashes w in a
local (for reasons explained later), then calls ':', which starts the
definition of 'five'.  Then it uses 'postpone literal' (*note Compiling
words::) to compile w (i.e., 5) into this colon definition, and then
'postpone ;' to end it.  You can look at the result with 'see five':

     : five  #5 ;

   Can't we just leave w on the data stack for consumption by 'postpone
literal'?  No: ':' pushes a colon-sys on the data stack, so we have to
first move w elsewhere so we can later access it.  In this example, we
used a local variable, but moving w on the return stack and back would
also have been an option.

   A more convenient, but Gforth-specific way to write 'myconstant' is:

     : myconstant {: w -- :}
       : ]] w ; [[ ;

   The features used in this code are explained elsewhere (*note
Macros::).

   A disadvantage of this approach is that it consumes more memory than
the approach of the next section: E.g, here are the memory costs of
defining 'five' with the various implementations:

     builtin  : does> set-does> opt
        48   64   48     48      48  bytes header+threaded code
         0   23    0      0       0  bytes native code
        16   16   32     16      16  compiled threaded code
         4   23   34      7       4  compiled native code

   Builtin refers to using 'constant', : to using 'myconstant' (defined
above), does> to using 'myconstant2', set-does> to using 'myconstant3'
(both from *note User-defined defining words using CREATE::), and opt to
using 'myconstant4' (*note User-defined compile-comma::).

   The lines where the label starts with "bytes" report the space
consumption of defining the word 'five' itself; the native code is for
gforth-fast on AMD64 (native code for the gforth engine is larger).

   The lines where the label starts with "compiled" report the space
consumption (also in bytes) for the invocation of 'five' in the word ':
foo five * ;'.  The native code can be bigger or smaller in other
contexts.

6.11.10.2 User-defined defining words using 'create'
....................................................

If you want the words defined with your defining words to behave
differently from words defined with standard defining words, you can
write your defining word like this:

     : def-word ( "name" -- )
         CREATE code1
     DOES> ( ... -- ... )
         code2 ;

     def-word name

   This fragment defines a "defining word" 'def-word' and then executes
it.  When 'def-word' executes, it 'CREATE's a new word name, and
executes the code code1.  The code code2 is not executed at this time.
The word name is sometimes called a "child" of 'def-word'.

   When you execute name, the address of the body of name is pushed on
the data stack and code2 is executed.  The address of the body of name
is the address 'HERE' returns immediately after the 'CREATE', i.e., the
address a 'create'd word returns by default).

   You can understand the behaviour of 'def-word' and 'name' by
considering the following definitions:
     : def-word1 ( "name" -- )
         CREATE code1 ;

     : action1 ( ... -- ... )
         code2 ;

     def-word1 name1

Using 'name1 action1' is equivalent to using 'name'.

   You can use 'def-word' to define a set of child words that behave
similarly; they all have a common run-time behaviour determined by
code2.  Typically, the code1 sequence builds a data area in the body of
the child word.  The structure of the data is common to all children of
'def-word', but the data values are specific - and private - to each
child word.

   As an example, here's how you can define 'myconstant2' with 'does>':

     : myconstant2 ( w "name" -- )
         create ,
     does> ( -- w )
         @ ;

   Here 'create' defines a word name, then ',' stores w in name's data
area, then the 'does>' changes name's behaviour and returns to the
caller of 'myconstant2': When name is invoked, the new behaviour first
pushes the address of the data area (as before), but then also performs
the code after the 'does>'.  In the present case, this code fetches the
value of the constant from the data area.

   The stack effect besides the 'does' reflects the stack effect of name
execution, not the stack effect of the code after the 'does>' (this is
not common practice yet but we still recommend it).

   'Does>' splits the definition into two subdefinitions and has a
number of disadvantages.  Alternatively, Gforth allows you to provide
the second part as an execution token by using 'set-does>'.  So the
general scheme is:

     : def-word ( "name" -- ; name execution: ... -- ... )
         create code1
         xt-code2 set-does>
         code3 ;

   The difference from the definition using 'does>' is that on name
execution, after pushing the data address, xt-code2 is 'execute'd,
rather than calling the code after the 'does>'.  This also allows
putting code3 in def-word; this is particularly relevant when you want
to also use 'set-optimizer' (*note User-defined compile-comma::) on the
defined word, because 'does>'/'set-does>' calls 'set-optimizer' itself,
so using 'set-optimizer' before 'does>'/'set-does>' has no effect.

   Here xt-code2 could be the xt of an existing word, or it could be
provided through a quotation (*note Quotations::).

   Another advantage of 'set-does>' is that the result is a little more
efficient if the execution token passed to it is that of a primitive.
This advantages comes to fruition in:

     : myconstant3 ( w "name" -- ; name execution: -- w )
         create ,
         ['] @ set-does> ;

   During name execution, after pushing the body address of name, '@' is
executed.

   The efficiency advantage shows up in the comparisons of compiled code
size (*note User-defined defining words with colon definitions::); the
execution time also benefits.

6.11.10.3 Applications of 'CREATE..DOES>'
.........................................

You may wonder how to use this feature.  Here are some usage patterns:

   When you see a sequence of code occurring several times, and you can
identify a meaning, you will factor it out as a colon definition.  When
you see similar colon definitions, you can factor them using
'CREATE..DOES>'.  E.g., an assembler usually defines several words that
look very similar:
     : ori, ( reg-target reg-source n -- )
         0 asm-reg-reg-imm ;
     : andi, ( reg-target reg-source n -- )
         1 asm-reg-reg-imm ;

This could be factored with:
     : reg-reg-imm ( op-code -- )
         CREATE ,
     DOES> ( reg-target reg-source n -- )
         @ asm-reg-reg-imm ;

     0 reg-reg-imm ori,
     1 reg-reg-imm andi,

   Another view of 'CREATE..DOES>' is to consider it as a crude way to
supply a part of the parameters for a word (known as "currying" in the
functional language community).  E.g., '+' needs two parameters.
Creating versions of '+' with one parameter fixed can be done like this:

     : curry+ ( n1 "name" -- )
         CREATE ,
     DOES> ( n2 -- n1+n2 )
         @ + ;

      3 curry+ 3+
     -2 curry+ 2-

6.11.10.4 The gory details of 'CREATE..DOES>'
.............................................

'DOES>' ( compilation colon-sys1 - colon-sys2  ) core "does"
   Changes the current word such that it pushes its body address and
then calls the code behind the 'does>'.  Also changes the 'compile,'
implementation accordingly.  Call 'set-optimizer' afterwards if you want
a more efficient implementation.

   You can put the 'does>'-part in a different definition than the
'create' part.  This allows us to, e.g., select among different
'DOES>'-parts:
     : does1
     DOES> ( ... -- ... )
         code1 ;

     : does2
     DOES> ( ... -- ... )
         code2 ;

     : def-word ( ... -- ... )
         create ...
         IF
            does1
         ELSE
            does2
         THEN ;

   In this example, the selection of whether to use 'does1' or 'does2'
is made at definition-time, i.e., at the time when the child word is
'CREATE'd.

   Note that the property of 'does>' to end the definition makes it
necessary to introduce extra definitions 'does1' and 'does2'.  You can
avoid that with 'set-does>':

     : def-word ( ... -- ... )
         create ...
         IF
            [: code1 ;] set-does>
         ELSE
            [: code2 ;] set-does>
         THEN ;

'set-does>' ( xt -  ) gforth-1.0 "set-does-to"
   Changes the current word such that it pushes its body address and
then executes xt.  Also changes the 'compile,' implementation
accordingly.  Call 'set-optimizer' afterwards if you want a more
efficient implementation.

   In a standard program you can apply a 'DOES>'-part only if the last
word was defined with 'CREATE'.  In Gforth, the 'DOES>'-part will
override the behaviour of the last word defined in any case.  In a
standard program, you can use 'DOES>' only in a colon definition.  In
Gforth, you can also use it in interpretation state, in a kind of
one-shot mode; for example:
     CREATE name ( ... -- ... )
       initialization
     DOES>
       code ;

is equivalent to the standard:
     :noname
     DOES>
         code ;
     CREATE name EXECUTE ( ... -- ... )
         initialization

   Gforth also supports quotations in interpreted code, and quotations
save and restore the current definition, so you can also write the
example above also as:

     CREATE name ( ... -- ... )
       initialization
     [: code ;] set-does>

'>body' ( xt - a-addr  ) core "to-body"
   a-addr is the address of the body (aka parameter field or data field)
of the word represented by xt

   You can access the data area of a 'create'd word with '>body',
including words where the behaviour has been changed with
'does>'/'set-does>'.  So if you know that 'five' has been defined with,
e.g., 'myconstant3' (*note User-defined defining words using CREATE::),
you can change its value with

     7 ' five >body !

   and performing 'five' will then push 7.  By contrast, for words
defined with 'myconstant' (defined using ':', *note User-defined
defining words with colon definitions::) you cannot change the value in
this way.

   However, if a word uses 'set-optimizer' (*note User-defined
compile-comma::) for a more efficient implementation of the compiled
code for a word, in many cases the compiled code does not read data from
the body of this word, and in that case changing the data by using
'>body' will not have the desired effect.  So looking at the source code
of a defining word and seeing 'create' is not enough to conclude that
you can change the data and it will affect all existing uses.  An
example of that is 'myconstant4' (*note User-defined compile-comma::).

   So it's a good idea to document whether the intention behind a
defining word using 'create' is that it's data should be changeable
through '>body'.

6.11.10.5 Advanced does> usage example
......................................

The MIPS disassembler ('arch/mips/disasm.fs') contains many words for
disassembling instructions, that follow a very repetitive scheme:

     :noname DISASM-OPERANDS s" INST-NAME" type ;
     ENTRY-NUM cells TABLE + !

   Of course, this inspires the idea to factor out the commonalities to
allow a definition like

     DISASM-OPERANDS ENTRY-NUM TABLE define-inst INST-NAME

   The parameters DISASM-OPERANDS and TABLE are usually correlated.
Moreover, before I wrote the disassembler, there already existed code
that defines instructions like this:

     ENTRY-NUM INST-FORMAT INST-NAME

   This code comes from the assembler and resides in
'arch/mips/insts.fs'.

   So I had to define the INST-FORMAT words that performed the scheme
above when executed.  At first I chose to use run-time code-generation:

     : INST-FORMAT ( entry-num "name" -- ; compiled code: addr w -- )
       :noname Postpone DISASM-OPERANDS
       name Postpone sliteral Postpone type Postpone ;
       swap cells TABLE + ! ;

   Note that this supplies the other two parameters of the scheme above.

   An alternative would have been to write this using 'create'/'does>':

     : INST-FORMAT ( entry-num "name" -- )
       here name string, ( entry-num c-addr ) \ parse and save "name"
       noname create , ( entry-num )
       latestxt swap cells TABLE + !
     does> ( addr w -- )
       \ disassemble instruction w at addr
       @ >r
       DISASM-OPERANDS
       r> count type ;

   Somehow the first solution is simpler, mainly because it's simpler to
shift a string from definition-time to use-time with 'sliteral' than
with 'string,' and friends.

   I wrote a lot of words following this scheme and soon thought about
factoring out the commonalities among them.  Note that this uses a
two-level defining word, i.e., a word that defines ordinary defining
words.

   This time a solution involving 'postpone' and friends seemed more
difficult (try it as an exercise), so I decided to use a
'create'/'does>' word; since I was already at it, I also used
'create'/'does>' for the lower level (try using 'postpone' etc.  as an
exercise), resulting in the following definition:

     : define-format ( disasm-xt table-xt -- )
         \ define an instruction format that uses disasm-xt for
         \ disassembling and enters the defined instructions into table
         \ table-xt
         create 2,
     does> ( u "inst" -- )
         \ defines an anonymous word for disassembling instruction inst,
         \ and enters it as u-th entry into table-xt
         2@ swap here name string, ( u table-xt disasm-xt c-addr ) \ remember string
         noname create 2,      \ define anonymous word
         execute latestxt swap ! \ enter xt of defined word into table-xt
     does> ( addr w -- )
         \ disassemble instruction w at addr
         2@ >r ( addr w disasm-xt R: c-addr )
         execute ( R: c-addr ) \ disassemble operands
         r> count type ; \ print name

   Note that the tables here (in contrast to above) do the 'cells +' by
themselves (that's why you have to pass an xt).  This word is used in
the following way:

     ' DISASM-OPERANDS ' TABLE define-format INST-FORMAT

   As shown above, the defined instruction format is then used like
this:

     ENTRY-NUM INST-FORMAT INST-NAME

   In terms of currying, this kind of two-level defining word provides
the parameters in three stages: first DISASM-OPERANDS and TABLE, then
ENTRY-NUM and INST-NAME, finally 'addr w', i.e., the instruction to be
disassembled.

   Of course this did not quite fit all the instruction format names
used in 'insts.fs', so I had to define a few wrappers that conditioned
the parameters into the right form.

   If you have trouble following this section, don't worry.  First, this
is involved and takes time (and probably some playing around) to
understand; second, this is the first two-level 'create'/'does>' word I
have written in seventeen years of Forth; and if I did not have
'insts.fs' to start with, I may well have elected to use just a
one-level defining word (with some repeating of parameters when using
the defining word).  So it is not necessary to understand this, but it
may improve your understanding of Forth.

6.11.10.6 Words with user-defined 'to' etc.
...........................................

When you define a word _x_, you can set its execution semantics with
'set-does>' (*note User-defined defining words using CREATE::) or
'set-execute' (*note Header methods::).  But you can also change the
semantics of

     to _x_        \ aka ->_x_
     +to _x_       \ aka +>_x_
     action-of _x_ \ aka `_x_ defer@
     is _x_        \ aka `_x_ defer!
     addr _x_

   This is all achieved through a common mechanism described in this
section.  As an example, let's define 'dvalue' (it behaves in Gforth
exactly like '2value', *note Values::).  The code is as follows,
explained below:

     : d+! ( d addr -- )
       dup >r 2@ d+ r> 2! ;

     \                  to +to action-of is  addr
     to-table: d!-table 2! d+!    n/a    n/a [noop]

     ' >body d!-table to-class: dvalue-to

     : dvalue ( d "name" -- )
       create 2,
       ['] 2@ set-does>
       ['] dvalue-to set-to ;

     #5. dvalue x
     #2. +to x
     x d. \ prints 7

   First, we define the support word 'd+!'.

   Next, we define 'd!-table', a table of the various 'to'-like actions.

   For actions that are not supported, we put 'n/a' in the table, and
when you try to use, e.g., 'is x', exception -21 (unsupported operation)
is thrown.

   For the 'to' and '+to' actions, we have to provide words with the
stack effect '( d addr -- )', where addr is the address where the data
of the value-flavoured word is stored.  For 'addr' (only supported for
'addressable:' words), we have to provide a word with the stack effect
'( addr1 -- addr2 )'; in the usual case, both addresses are the same,
and we can just provide '[noop]'.  For the general case, see the
description of 'to-table:' below.

   Next, the defining word 'to-class:' combines the 'd!-table' with the
address-computation word '>body', resulting in the definition of
'dvalue-to'.(1)  The address-computation word has the stack effect '(
... xt -- addr )'.  When invoking '+to x', the xt of 'x' is pushed and
then the address-computation word ('>body') is called; the result is the
address that is then passed on to 'd+!' (from 'd!-table').

   For 'dvalue' that's all, but in other cases, e.g., value-flavoured
fields (*note Value-Flavoured and Defer-Flavoured Fields::), additional
stack items can be consumed by the address-computation word, and those
have to be provided by the user as stack-top values when invoking, e.g.,
'to field'.

   Next, we have the definition of 'dvalue', which is a straightforward
'create'...'set-does>' word that also tells name with 'set-to' how it
should behave for 'to' etc.

   Finally, we use 'dvalue' to define 'x' and use it.  The line using
'+to' exercises the 'set-to' mechanism:

     #2. +to x

   performs

     #2. ' x >body d+!

   The '>body' is the address-computation word given in the definition
of 'dvalue-to', and the 'd+!' is the '+to' entry in 'd!-table'.

   These are the words mentioned above:

'to-table:' ( "name" "to-word" "+to-word" "addr-word" "action-of-word" "is-word" -  ) gforth-experimental "to-table-colon"
   Create a table name with entries for 'TO', '+TO', 'ACTION-OF', 'IS',
and 'ADDR'.  The words for these entries are called with xt on the
stack, where xt belongs to the word behind 'to' (or '+to' etc.).  Use
'n/a' to mark unsupported operations.  Default entries operations can be
left away at the end of the line; the default is for the 'addr' entry is
'[noop]' while the default for the other entries is 'n/a'.

   The stack effects of the actions are:

   * For the 'to' and '+to' action: '( value addr -- )', where value has
     the appropriate type (e.g., a double-cell in our 'dvalue' example).

   * For the 'action-of' action: '( addr -- xt )'

   * For the 'is' action: '( xt addr -- )'

   * For the 'addr' action: '( addr1 -- addr2 )'

   The addr input parameter in all these cases is the address of the
memory where the value of the xt is stored.

   The default mechanism means that 'd!-table' could instead have been
defined as follows:

     \                  to +to action-of is  addr
     to-table: d!-table 2! d+!

'n/a' ( -  ) gforth-experimental "not-available"
   This word can be ticked, but throws an "Operation not supported"
exception on interpretation and compilation.  Use this for methods etc.
that aren't supported.

'to-class:' ( xt table "name" -  ) gforth-experimental "to-class-colon"
   Create a to-class implementation name, where XT '( ... xt -- addr )'
computes the address to access the data, and TABLE (created with
'to-table:') contains the words for accessing it.

'>uvalue' ( xt - addr  ) gforth-internal "to-uvalue"
   Xt is the xt of a word x defined with 'uvalue'; addr is the address
of the data of x in the current task.  This word is useful for building,
e.g., 'uvalue'.  Do not use it to circumvent that you cannot get the
address of a uvalue with 'addr'; in the future Gforth may perform
optimizations that assume that uvalues can only be accessed through
their name.

'set-to' ( to-xt -  ) gforth-1.0
   Changes the implementations of the to-class methods of the most
recently defined word to come from the to-class that has the xt to-xt.

   ---------- Footnotes ----------

   (1) The same to-table is often combined with different address
computation words (e.g., for global values, user values, value-flavoured
fields and locals), that's why the definition of the to-table is
separated from the definition of the to-class.

6.11.10.7 User-defined 'compile,'
.................................

You can also change the implementation of 'compile,' for a word, with

'set-optimizer' ( xt -  ) gforth-1.0
   Changes the current word such that 'compile,'ing it executes xt (with
the same stack contents as passed to 'compile,').  Note that 'compile,'
must be consistent with 'execute', so you must use 'set-optimizer' only
to install a more efficient implementation of the same behaviour.

'opt:' ( compilation - colon-sys2 ; run-time - nest-sys  ) gforth-1.0 "opt-colon"
   Starts a nameless colon definition; when it is complete, this colon
definition will become the 'compile,' implementation of the latest word
(before the 'opt:').

   Note that the resulting 'compile,' must still be equivalent to
'postpone literal postpone execute', so 'set-optimizer' is useful for
efficiency, not for changing the behaviour.  There is nothing that
prevents you from shooting yourself in the foot, however.  You can check
whether your uses of 'set-optimizer' are correct by comparing the
results when you use it with the results you get when you disable your
uses by first defining

     : set-optimizer drop ;

   As an example of the use of 'set-optimizer', we can enhance
'myconstant3' as follows.

     : myconstant4 ( n "name" -- ; name: -- n )
       create ,
       ['] @ set-does>
       [: >body @ postpone literal ;] set-optimizer
     ;

   The only change is the addition of the 'set-optimizer' line.  When
you define a constant and compile it:

     5 myconstant4 five
     : foo five ;

   the compiled 'five' in 'foo' is now compiled to the literal 5 instead
of a generic invocation of 'five'.  The quotation has the same stack
effect as 'compile,': '( xt -- )'.  The passed xt belongs to the
'compile,'d word, i.e., 'five' in the example.  In the example the xt is
first converted to the body address, then the value 5 at that place is
fetched, and that value is compiled with the 'postpone literal' (*note
Literals::).

   This use of 'set-optimizer' assumes that the user does not change the
value of a constant with, e.g., '6 ' five >body !'.  While 'five' has
been defined with 'create', that is an implementation detail of
'CONSTANT', and if you don't document it, the user must not rely on it.
And if you use 'set-optimizer' in a way that assumes that the body does
not change (like is done here), you must not document that 'create' is
used; and conversely, if you document it, you have to write the
'compile,' implementation such that it can deal with changing bodies.

   Note that the call to 'set-optimizer' has to be performed after the
call to 'set-does>' (or 'does>', because 'set-does>' overwrites the
'compile,' implementation itself.

   We can also apply 'set-optimizer' to individual words rather than
inside a defining word like 'constant'.  In this case, the xt of the
word passed to optimizer is usually unnecessary and is 'drop'ped.  As an
simple example, let's define a word that is inlined when being compiled:

     : compile-my2dup ( xt -- )
       drop ]] over over [[ ;

     : my2dup over over ;
     ' compile-my2dup set-optimizer

     : foo my2dup ;
     see my2dup

   An alternative way to define 'my2dup' is:

     : my2dup over over ;
     opt: drop ]] over over [[ ;

   'Opt:' starts an anonymous definition that is then (internally)
attached to 'my2dup' with 'set-optimize'.

   Finally an even more convenient way to write this is to use 'inline:'
(*note Inline Definitions::), but it is limited to inlining.

   The engine 'gforth-itc' uses ',' for 'compile,' in nearly all cases
and 'set-optimizer' usually has no effect there.

6.11.10.8 Creating from a prototype
...................................

In the above we show how to define a word by first using 'create', and
then modifying it with 'immediate', 'set-does>', 'set-to',
'set-optimizer' etc.

   An alternative way is to create a prototype using these words, and
then create a new word from that prototype.  This kind of copying does
not cover the body, so that has to be allocated and initialized
explicitly.  Taking 'dvalue' above, we could instead define it as:

     create dvalue-prototype ( -- d )
     `2@ set-does>
     `dvalue-to set-to

     : dvalue ( d "name" -- ; name: -- d )
       ``dvalue-prototype create-from 2, reveal ;

   An advantage of this approach is that creating words with 'dvalue' is
now faster.(1)  But this advantage is only relevant if the number of
words created with this defining word is huge.

'create-from' ( nt "name" -  ) gforth-1.0
   Create a word name that behaves like nt, but with an empty body.  nt
must be the nt of a named word.  The resulting header is not yet
'reveal'ed; use 'reveal' to reveal it or 'latest' to get its xt.
Creating a word with 'create-from' without using any 'set-' words is
faster than if you create a word using 'set-' words, 'immediate', or
'does>'.  You can use 'noname' with 'create-from'.

'reveal' ( -  ) gforth-0.2
   Put the current word in the wordlist current at the time of the
header definition.

'reveal!' ( xt wid -  ) core-ext "reveal-store"
   Add XT to a wordlist.  Mapped to 'DEFER!'.

   The performance advantage does not extend to using 'noname' with the
defining word.  Therefore we also have

'noname-from' ( xt -  ) gforth-1.0
   Create a nameless word that behaves like xt, but with an empty body.
xt must be the nt of a nameless word.

   Here's a usage example:

     ``dvalue-prototype noname create-from
     latestnt constant noname-dvalue-prototype

     : noname-dvalue ( d -- xt ; xt execution: -- d )
       noname-dvalue-prototype noname-from 2,
       latestxt ;

   ---------- Footnotes ----------

   (1) The non-prototype method first duplicates the header methods of
'create', modify them, and eventually deduplicate them.  The
'create-from' approach eliminates this overhead.

6.11.10.9 Making a word current
...............................

Many words mentioned above, such as 'immediate' or 'set-optimizer'
change the "current" or "most recently defined" word.  Sometimes you
want to change an earlier word.  You can do this with

'make-latest' ( nt -  ) gforth-1.0
   Make nt the latest definition, which can be manipulated by
'immediate' and 'set-*' operations.  If you have used (especially
compiled) the word referred to by nt already, do not change the
behaviour of the word (only its implementation), otherwise you may get a
surprising mix of behaviours that is not consistent between Gforth
engines and versions.

6.11.10.10 'Const-does>'
........................

A frequent use of 'create'...'does>' is for transferring some values
from definition-time to run-time.  Other ways of achieving this are
closures (*note Closures::), and with colon definitions (*note
User-defined defining words with colon definitions::), but another way
of achieving this is to use

'const-does>' ( run-time: w*uw r*ur uw ur "name" -  ) gforth-obsolete "const-does"
   Defines NAME and returns.

   NAME execution: pushes W*UW R*UR, then performs the code following
the 'const-does>'.

   A typical use of this word is:

     : curry+ ( n1 "name" -- )
     1 0 CONST-DOES> ( n2 -- n1+n2 )
         + ;

     3 curry+ 3+

   Here the '1 0' means that 1 cell and 0 floats are transferred from
definition to run-time.

   The advantages of using 'const-does>' compared to
'create}...@word{does>' are:

   * You don't have to deal with storing and retrieving the values,
     i.e., your program becomes more writable and readable.

   * When using 'does>', you have to introduce a '@' that cannot be
     optimized away automatically (because the system does not know
     whether you allow to access the data with '>body'...'!').  You can
     address this problem with 'set-optimizer' (*note User-defined
     compile-comma::), but 'const-does>' avoids it; however, the current
     implementation is still not particularly efficient.

   A Standard Forth implementation of 'const-does>' is available in
'compat/const-does.fs'.

6.11.11 Deferred Words
----------------------

The defining word 'Defer' allows you to define a word by name without
defining its behaviour; the definition of its behaviour is deferred.
Here are two situation where this can be useful:

   * Where you want to allow the behaviour of a word to be altered
     later, and for all precompiled references to the word to change
     when its behaviour is changed.
   * For mutual recursion: *Note Calls and returns::.

   In the following example, 'foo' always invokes the version of 'greet'
that prints "'Good morning'" whilst 'bar' always invokes the version
that prints "'Hello'".  There is no way of getting 'foo' to use the
later version without re-ordering the source code and recompiling it.

     : greet ." Good morning" ;
     : foo ... greet ... ;
     : greet ." Hello" ;
     : bar ... greet ... ;

   This problem can be solved by defining 'greet' as a 'Defer'red word.
The behaviour of a 'Defer'red word can be defined and redefined at any
time by using 'IS' to associate the xt of a previously-defined word with
it.  The previous example becomes:

     Defer greet ( -- )
     : foo ... greet ... ;
     : bar ... greet ... ;
     : greet1 ( -- ) ." Good morning" ;
     : greet2 ( -- ) ." Hello" ;
     ' greet2 IS greet  \ make greet behave like greet2

   Programming style note:

   You should write a stack comment for every deferred word, and put
only XTs into deferred words that conform to this stack effect.
Otherwise it's too difficult to use the deferred word.

   One thing to note is that 'IS' has special compilation semantics,
such that it parses the name at compile time (like 'TO'):

     : set-greet ( xt -- )
       IS greet ;

     ' greet1 set-greet

'Defer' ( "name" -  ) core-ext
   Define a deferred word name; you have to set it to an xt before
executing it.
name execution: execute the most recent xt that name has been set to.
'Is name' run-time: ( xt - ) Set name to execute xt.
'Action-of name' run-time: ( - xt ) Xt is currently assigned to name.

'IS' ( xt ... "name" -  ) core-ext
   Name is a defer-flavoured word, ...  is optional additional
addressing information, e.g., for a defer-flavoured field.  At run-time,
perform the is name semantics: change name (with the same additional
addressing information) to execute xt.

   You can extract the xt of a 'defer'red word with 'action-of':

     action-of greet ( xt ) >name id.

'action-of' ( interpretation "name" ... - xt; compilation "name" - ; run-time ... - xt  ) core-ext
   Name is a defer-flavoured word, ...  is optional additional
addressing information, e.g., for a defer-flavoured field.  At run-time,
perform the action-of name semantics: Push the xt, that name (possibly
with additional addressing data on the stack) executes.

   One usage for deferred words is the definition of a an action (e.g.,
initialization) in several pieces, each piece in a different source file
dealing with the matters of that source file.  This can be done with

     defer myspeech ( -- )
     :noname cr ." <central message>" ; is myspeech

     \ and in every source file where you want to add a piece, something like
     :noname ( -- )
       cr ." <introduction>"
       [ action-of myspeech compile, ]
       cr ." <conclusion>"
     ; is myspeech

   The '[ action-of myspeech compile, ]' calls the previous content of
'myspeech'.  Gforth offers the words ':is' and 'defers' to express the
last definition more conveniently:

     :is myspeech ( -- )
       cr ." <introduction>"
       defers myspeech
       cr ." <conclusion>" ;

':is' ( "name" -  ) gforth-experimental "colon-is"
   define a noname that is assigned to the deferred word NAME at ';'.

'defers' ( compilation "name" - ; run-time ... - ...  ) gforth-0.2
   Compiles the present contents of the deferred word name into the
current definition.  I.e., this produces static binding as if name was
not deferred.

   Another usage is to change a deferred word temporarily, and later
change it back.  Gforth provides words for supporting this usage.  The
use of 'preserve' is shown in this example:

     : smalltalk ( -- )
       greet ."  Isn't the weather nice?" ;

     \ here GREET performs GREET2
     : when-in-rome ( xt -- )
       [: ." Buon Giorno!" ;] is greet
       execute
       preserve greet \ Equivalent to: ['] greet2 is greet
     ;

     ' greet1 is greet
     greet \ "Good Morning"
     ' smalltalk when-in-rome \ "Buon Giorno! Isn't the weather nice?"
     greet \ "Hello"

'preserve' ( compilation "name" - ; run-time -  ) gforth-1.0
   Name has to be a defer-flavoured word that does not consume
additional stack items for addressing (i.e., not a defer-flavoured
field).  'Preserve name' changes name at run-time to execute the same XT
that it had at compile time.  I.e., 'Preserve name' is equivalent to '[
action-of name ] literal is name'.

   'Preserve' is only appropriate when you want to restore the deferred
word to a fixed xt.  If you want to change a deferred temporarily and
then restore its old run-time value, use 'wrap-xt':

     : when-in-rome2 ( xt -- )
       [: ." Buon Giorno!" ;] ['] greet rot wrap-xt ;

     ' greet1 is greet
     greet \ "Good Morning"
     ' smalltalk when-in-rome2 \ "Buon Giorno! Isn't the weather nice?"
     greet \ "Good Morning"

'wrap-xt' ( ... xt1 xt2 xt3 - ...  ) gforth-1.0
   Set deferred word xt2 to xt1 and execute xt3.  Restore afterwards.

   For implementing words like 'wrap-xt' to which you pass the xt of a
deferred word, you cannot use 'is' and 'action-of', which consume a name
from the input stream.  Instead, you use the words 'defer!' and
'defer@'.

'defer!' ( xt xt-deferred -  ) core-ext "defer-store"
   xt-deferred belongs to a word defined with 'defer', it is changed to
execute xt on execution.
If xt-deferred belongs to another defer-flavoured word (e.g., a
defer-flavoured field), the location associated with ...  xt-deferred is
changed to execut xt.
If xt-deferred is the xt of a word that is not defer-flavoured, throw
-21 (Unsupported operation).

'defer@' ( ... xt-deferred - xt  ) core-ext "defer-fetch"
   If xt-deferred belongs to a word defined with 'defer', xt represents
the word currently associated with the deferred word xt-deferred.
If xt-deferred belongs to another defer-flavoured word (e.g., a
defer-flavoured field), xt is the word associated with the location
indicated by ...  xt-deferred (e.g., for a defer-flavoured field ...  is
the structure address).
If xt-deferred is the xt of a word that is not defer-flavoured, throw
-21 (Unsupported operation).

   A deferred word can only inherit execution semantics from the xt
(because that is all that an xt can represent - for more discussion of
this *note Tokens for Words::); by default it will have default
interpretation and compilation semantics deriving from this execution
semantics.  However, you can change the interpretation and compilation
semantics of the deferred word in the usual ways:

     : bar .... ; immediate
     Defer fred immediate
     Defer jim

     ' bar IS jim  \ jim has default semantics
     ' bar IS fred \ fred is immediate

6.11.12 Synonyms
----------------

The defining word 'synonym' allows you to define a word by name that has
the same behaviour as some other word.  Here are two situation where
this can be useful:

   * When you want access to a word's definition from a different word
     list (for an example of this, see the definitions in the 'Root'
     word list in the Gforth source).
   * When you want to create a synonym; a definition that can be known
     by either of two names (for example, 'THEN' and 'ENDIF' can be
     defined as synonyms).

'Synonym' ( "name" "oldname" -  ) tools-ext
   Define name to behave the same way as oldname: Same interpretation
semantics, same compilation semantics, same 'to', '+to', 'is',
'action-of' and 'addr' semantics.

   Gforth also offers the Gforth-specific 'alias', that allows to define
another word with the same execution token, but otherwise default
semantics (no copying of compilation or other semantics).  You can then
change, e.g., the compilation semantics with, e.g., 'immediate'.

'Alias' ( xt "name" -  ) gforth-0.2
   Define name as a word that performs xt.  Unlike for deferred words,
aliases don't have an indirection overhead when compiled.

   Example:

     : foo ." foo" ; immediate

     ' foo Alias bar1           \ bar1 is not an immediate word
     ' foo Alias bar2 immediate \ bar2 is an immediate word
     synonym bar3 foo           \ bar3 is an immediate word
     : test-bar1 bar1 ; \ no output
     test-bar1          \ "foo"
     : test-bar2 bar2 ; \ "foo"
     test-bar2          \ no output
     : test-bar3 bar3 ; \ "foo"
     test-bar3          \ no output

   Both synonyms and aliases have a different nt than the original, but
ticking it (or using 'name>interpret') produces the same xt as the
original (*note Tokens for Words::).

6.12 Structures
===============

A structure (aka record) is a collection of fields that are stored
together.  The fields can have different types and are accessed by name.
There are typically several instances of a structure, otherwise
programmers tend to prefer using a variable or somesuch for each field.

   In Forth you can use raw address arithmetic to access fields of
structures, but using field names and defining field access words with
the defining words described in this section makes the code more
readable.

6.12.1 Standard Structures
--------------------------

The Forth 2012 standard defines a number of words for defining fields
and structures.

   A typical example of defining a structure with several fields is:

     0 \ offset of first field, 0 in the usual case
       field: intlist-next ( intlist -- addr1 )
       field: intlist-val  ( intlist -- addr2 )
     constant intlist ( -- u )

   An equivalent alternative way of defining this structure is:

     begin-structure intlist ( -- u )
       field: intlist-next ( intlist -- addr1 )
       field: intlist-val  ( intlist -- addr2 )
     end-structure

   'Intlist' returns the size of the structure.  The convention for the
field names here is to prepend the structure name, so that you don't run
into conflicts when several structures have 'next' and 'val' fields; in
Forth, by default field names are in the same wordlist (i.e., the same
name space) as the other words (including other field names), and trying
to use the search order (*note Word Lists::) for avoiding conflicts is
rather cumbersome (unless you use the scope recognizer *note Default
Recognizers::).

   You can then use that to allocate an instance of that structure and
then use the field words to access the fields of that instance:

     intlist allocate throw constant my-intlist1
     0 my-intlist1 intlist-next !
     5 my-intlist1 intlist-val  !

     intlist allocate throw constant my-intlist2
     my-intlist1 my-intlist2 intlist-next !
     7           my-intlist2 intlist-val !

     : intlist-sum ( intlist -- n )
     \ "intlist" is a pointer to the first element of a linked list
     \ "n" is the sum of the intlist-val fields in the linked list
         0 BEGIN ( intlist1 n1 )
             over
         WHILE ( list1 n1 )
             over intlist-val @ +
             swap intlist-next @ swap
         REPEAT
         nip ;

     my-intlist2 intlist-sum . \ prints "12"

   In addition to 'field:' for cell-aligned and cell-sized fields, you
can define fields sized and aligned for various types with:

'begin-structure' ( "name" - struct-sys 0  ) facility-ext

'end-structure' ( struct-sys +n -  ) facility-ext
   end a structure started with 'begin-structure'

'cfield:' ( u1 "name" - u2  ) facility-ext "c-field-colon"
   Define a char-sized field

'field:' ( u1 "name" - u2  ) facility-ext "field-colon"
   Define an aligned cell-sized field

'2field:' ( u1 "name" - u2  ) gforth-0.7 "two-field-colon"
   Define an aligned double-cell-sized field

'ffield:' ( u1 "name" - u2  ) floating-ext "f-field-colon"
   Define a faligned float-sized field

'sffield:' ( u1 "name" - u2  ) floating-ext "s-f-field-colon"
   Define a sfaligned sfloat-sized field

'dffield:' ( u1 "name" - u2  ) floating-ext "d-f-field-colon"
   Define a dfaligned dfloat-sized field

'wfield:' ( u1 "name" - u2  ) gforth-1.0 "w-field-colon"
   Define a naturally aligned field for a 16-bit value.

'lfield:' ( u1 "name" - u2  ) gforth-1.0 "l-field-colon"
   Define a naturally aligned field for a 32-bit value.

'xfield:' ( u1 "name" - u2  ) gforth-1.0 "x-field-colon"
   Define a naturally aligned field for a 64-bit-value.

   If you need something beyond these field types, you can use '+field'
to define fields of arbitrary size.  You have to ensure the correct
alignment yourself in this case.  E.g., if you want to put one struct
inside another struct, you would do it with

     0
       cfield:                nested-foo
       aligned intlist +field nested-bar
     constant nested

   In this example the field 'nested-bar' contains an intlist structure,
so the size of 'intlist' is passed to '+field'.  An 'intlist' must be
cell-aligned (it contains cell fields), and this is achieved by aligning
the current field offset with 'aligned' before the field definition.
Our recommendation is to always precede the usage of '+field' with an
appropriate alignment word (except if character-alignment is good enough
for the field); this ensures that the field will stay correctly aligned
even if other fields are later inserted before the '+field'-defined
field.

'+field' ( noffset1 nsize "name" - noffset2  ) facility-ext "plus-field"
   Defining word; defines name '( addr1 -- addr2 )', where addr2 is
addr1+noffset1.  noffset2 is noffset1+nsize.

   The first field is at the base address of a structure and the word
for this field (e.g., 'list-next') actually does not change the address
on the stack.  You may be tempted to leave it away in the interest of
run-time and space efficiency.  This is not necessary, because Gforth
and other Forth systems optimize this case: If you compile a first-field
word, no code is generated.  So, in the interest of readability and
maintainability you should include the word for the field when accessing
the field.

6.12.2 Value-Flavoured and Defer-Flavoured Fields
-------------------------------------------------

In addition to the variable-flavoured fields that produce an address
(*note Standard Structures::), Gforth also provides value-flavoured
fields.  Like all fields, value-flavoured fields consume the start
address of the struct, but they produce their value and you can apply
'to', '+to' and (if the field is 'addressable:', *note Values::) 'addr'
on them.  E.g., we can do something like the 'intlist' definition (*note
Standard Structures::):

     0
                    value: intlist>next ( intlista -- intlista1 )
       addressable: value: intlist>val  ( intlista -- n )
     constant intlista ( -- u )

   This means that there are the following ways of accessing
'intlist>val':

     intlist>val ( intlista -- n )
     ->intlist>val ( n intlista -- ) \ aka  to intlist>val
     +>intlist>val ( n intlista -- ) \ aka +to intlist>val
     addr intlist>val ( intlista -- addr )

   And here's the earlier example (*note Standard Structures::)
rewritten to use 'intlista':

     intlista allocate throw constant my-intlista1
     0 my-intlista1 to intlist>next
     5 my-intlista1 to intlist>val

     intlista allocate throw constant my-intlista2
     my-intlista1 my-intlista2 to intlist>next
     7            my-intlista2 to intlist>val

     : intlista-sum ( intlista -- n )
     \ "intlista" is a pointer to the first element of a linked list
     \ "n" is the sum of the intlist>val fields in the linked list
         0 BEGIN ( intlista1 n1 )
             over
         WHILE ( list1 n1 )
             over intlist>val +
             swap intlist>next swap
         REPEAT
         nip ;

     my-intlista2 intlista-sum . \ prints "12"

   Depending on the type of the field, the value can be something
different than a single cell.

'value:' ( u1 "name" - u2  ) gforth-experimental "value-colon"
   Name is a value-flavoured field; in-memory-size: cell; on-stack: cell

'cvalue:' ( u1 "name" - u2  ) gforth-experimental "cvalue-colon"
   Name is a value-flavoured field; in-memory-size: char; on-stack:
unsigned cell

'wvalue:' ( u1 "name" - u2  ) gforth-experimental "wvalue-colon"
   Name is a value-flavoured field; in-memory-size: 16 bits; on-stack:
unsigned cell

'lvalue:' ( u1 "name" - u2  ) gforth-experimental "lvalue-colon"
   Name is a value-flavoured field; in-memory-size: 32 bits; on-stack:
unsigned cell

'scvalue:' ( u1 "name" - u2  ) gforth-experimental "scvalue-colon"
   Name is a value-flavoured field; in-memory-size: char; on-stack:
signed cell

'swvalue:' ( u1 "name" - u2  ) gforth-experimental "swvalue-colon"
   Name is a value-flavoured field; in-memory-size: 16 bits; on-stack:
signed cell

'slvalue:' ( u1 "name" - u2  ) gforth-experimental "slvalue-colon"
   Name is a value-flavoured field; in-memory-size: 32 bits; on-stack:
signed cell

'2value:' ( u1 "name" - u2  ) gforth-experimental "two-value-colon"
   Name is a value-flavoured field; in-memory-size: 2 cells; on-stack: 2
cells; '+to' performs double-cell addition ('d+').

'fvalue:' ( u1 "name" - u2  ) gforth-experimental "fvalue-colon"
   Name is a value-flavoured field; in-memory-size: float; on-stack:
float

'sfvalue:' ( u1 "name" - u2  ) gforth-experimental "sfvalue-colon"
   Name is a value-flavoured field; in-memory-size: 32-bit float;
on-stack: float

'dfvalue:' ( u1 "name" - u2  ) gforth-experimental "dfvalue-colon"
   Name is a value-flavoured field; in-memory-size: 64-bit float;
on-stack: float

'zvalue:' ( u1 "name" - u2  ) gforth-experimental "zvalue-colon"
   Name is a value-flavoured field; in-memory-size: 2 floats; on-stack:
2 floats; '+to' performs componentwise addition.

'$value:' ( u1 "name" - u2  ) gforth-experimental "dollar-value-colon"
   Name is a value-flavoured field; in-memory-size: cell; on-stack:
c-addr u (*note $tring words::); '( c-addr u ) +to name' appends c-addr
u to the string in the field.

   Gforth also has field words for dealing with dynamically-sized
arrays.  A field for such an array contains just a cell that points to
the actual data, and this cell has to be set to 0 before accessing the
array the first time.  When accessing the field (without operator, or
with 'to' or '+to'), there has to be the index and the structure address
on the stack, with the structure address on top.  Any further items
consumed by 'to' or '+to' are below the index on the stack.  The array
expands to the size given by the maximum access; any unset elements are
0; for '$value[]' accessing them produces a 0-length (i.e., empty)
string.

   Here is a usage example:

     0
       value[]:  bla>x[]
       $value[]: bla>$y[]
     constant bla

     bla allocate throw constant mybla
     mybla bla erase \ set all fields to 0

     5 2 mybla to bla>x[] \ access at index 2
     7 0 mybla to bla>x[] \ access at index 0
     2 mybla bla>x[] . \ prints "5"
     3 mybla bla>x[] . \ prints "0"
     "foo" 2 mybla to bla>$y[]  \ access at index 2
     "bla" 1 mybla to bla>$y[]  \ access at index 1
     "bar" 2 mybla +to bla>$y[] \ access at index 2
     0 mybla bla>$y[] . . \ prints "0 0"
     1 mybla bla>$y[] type \ prints "bla"
     2 mybla bla>$y[] type \ prints "foobar"

'value[]:' ( u1 "name" - u2  ) gforth-experimental "value-left-bracket-right-bracket-colon"
   Name is a value-flavoured array field; in-memory-size: cell;
on-stack: cell

'$value[]:' ( u1 "name" - u2  ) gforth-experimental "dollar-value-left-bracket-right-bracket-colon"
   Name is a value-flavoured array field; in-memory-size: cell;
on-stack: c-addr u (*note $tring words::); '( c-addr u ) +to name'
appends c-addr u to the string in the array element.

   Finally, you can define defer-flavoured fields.  Here is a usage
example:

     0
       addressable: defer: foo'bar
     constant foo

     foo allocate throw constant my-foo
     :noname ." test" ; my-foo is foo'bar
     my-foo foo'bar                   \ prints "test"
     my-foo addr foo'bar @ execute   \ prints "test"
     my-foo action-of foo'bar execute \ prints "test"
     my-foo `foo'bar defer@ execute   \ prints "test"
     :noname ." test1" ; my-foo `foo'bar defer!
     my-foo foo'bar                   \ prints "test1"

'defer:' ( u1 "name" - u2  ) gforth-experimental "defer-colon"
   Name is a defer-flavoured field

   For documentation of 'is', 'action-of', 'defer@', 'defer!', see *Note
Deferred Words::.  Note however, that when used on defer-flavoured
fields, all these words consume the start address of the structure,
unlike for words defined with 'defer'.

6.12.3 Structure Extension
--------------------------

You can create a new structure starting with an existing structure and
its fields.  E.g., if we also want to define 'floatlist', we can factor
out the '...-next' field into a general structure 'list' without
payload, and then define 'intlist' and 'floatlist' as extensions of
'list':(1)

     0
       field: list-next ( list -- addr )
     constant list ( -- u )

     list
       field: intlist-val ( intlist -- addr )
     constant intlist ( -- u )

     list
       ffield: floatlist-val ( floatlist -- addr )
     constant floatlist ( -- u )

   Note that in this variant there is no 'intlist-next' nor a
'floatlist-next', just a 'list-next'; so when you use, e.g., a
'floatlist', the organization through extension of 'list' is exposed.
This may make it harder to refactor things, so you may prefer to also
introduce synonyms 'intlist-next' and 'floatlist-next'.

   If you prefer to use 'begin-structure'...'end-structure', you can do
the equivalent definition as follows:

     begin-structure list ( -- u )
       field: list-next ( list -- addr )
     end-structure

     list extend-structure intlist
       field: intlist-val  ( intlist -- addr )
     end-structure

     list extend-structure floatlist
       ffield: floatlist-val  ( floatlist -- addr )
     end-structure

'extend-structure' ( n "name" - struct-sys n  ) gforth-1.0
   Start a new structure name as extension of an existing structure with
size n.

   ---------- Footnotes ----------

   (1) This feature is also known as _extended records_ in Oberon.

6.12.4 Gforth structs
---------------------

Gforth has had structs before the standard had them; they are a little
different, and you can still use them.  One benefit of the Gforth
structs is that they propagate knowledge of alignment requirements, so
if you build the 'nested' structure (*note Standard Structures::), you
do not need to look inside 'intlist' to find out the proper alignment,
and you also do not need to mention alignment at all.  Instead, this
example would look like:

     struct
       cell% field intlist-next
       cell% field intlist-val
     end-struct intlist%

     struct
       char%    field nested-foo
       intlist% field nested-bar
     end-struct nested%

   The fields are variable-flavoured, i.e., they work in the same way as
those defined with 'field:', '+field' etc.

   A disadvantage of the Gforth structs is that, with the standard going
for something else, you need to learn additional material to write and
understand code that uses them.  Another disadvantage of the Gforth
structs is that they do not support value-flavoured or defer-flavoured
fields.  On the balance, in our opinion the disadvantages now outweigh
the advantages, so we recommend using the standard structure words
(*note Standard Structures::).  Nevertheless, here is the documentation
for Gforth's structs.

   The 'list' and 'intlist' examples look like this with Gforth structs:

     struct
       cell% field list-next
     end-struct list%

     list%
       cell% field intlist-val
     end-struct intlist%

   'Intlist%' contains information about size and alignment, and you use
'%size' to get the size, e.g., for allocation:

     intlist% %size allocate throw constant my-intlist1

   A shorthand for that is

     intlist% %alloc constant my-intlist1

   The fields behave the same way, so the rest of the example works as
with standard structures.

   In addition to specifying single cells with 'cell%', you can also
specify an array of, e.g., 10 cells like this:

       cell% 10 * field bla-blub
       \ equivalent to the standard:
       \ aligned 10 cells +field bla-blub

   You can use 'cell% 10 *' not just with 'field', but also in other
places where an alignment and size is expected, e.g., with '%alloc'.

'%align' ( align size -  ) gforth-0.4 "percent-align"
   Align the data space pointer to the alignment ALIGN.

'%alignment' ( align size - align  ) gforth-0.4 "percent-alignment"
   The alignment of the structure.

'%alloc' ( align size - addr  ) gforth-0.4 "percent-alloc"
   Allocate SIZE address units with alignment ALIGN, giving a data block
at ADDR; 'throw' an ior code if not successful.

'%allocate' ( align size - addr ior  ) gforth-0.4 "percent-allocate"
   Allocate SIZE address units with alignment ALIGN, similar to
'allocate'.

'%allot' ( align size - addr  ) gforth-0.4 "percent-allot"
   Allot SIZE address units of data space with alignment ALIGN; the
resulting block of data is found at ADDR.

'cell%' ( - align size  ) gforth-0.4 "cell-percent"

'char%' ( - align size  ) gforth-0.4 "char-percent"

'dfloat%' ( - align size  ) gforth-0.4 "d-float-percent"

'double%' ( - align size  ) gforth-0.4 "double-percent"

'end-struct' ( align size "name" -  ) gforth-0.2
   Define a structure/type descriptor NAME with alignment ALIGN and size
SIZE1 (SIZE rounded up to be a multiple of ALIGN).
'name' execution: - ALIGN SIZE1

'field' ( align1 offset1 align size "name" -  align2 offset2  ) gforth-0.2
   Create a field NAME with offset OFFSET1, and the type given by ALIGN
SIZE.  OFFSET2 is the offset of the next field, and ALIGN2 is the
alignment of all fields.
'name' execution: ADDR1 - ADDR2.
ADDR2=ADDR1+OFFSET1

'float%' ( - align size  ) gforth-0.4 "float-percent"

'sfloat%' ( - align size  ) gforth-0.4 "s-float-percent"

'%size' ( align size - size  ) gforth-0.4 "percent-size"
   The size of the structure.

'struct' ( - align size  ) gforth-0.2
   An empty structure, used to start a structure definition.

6.13 User-defined Stacks
========================

Gforth supports user-defined stacks.  They are used for implementing
features such as recognizer sequences, but you can also define stacks
for your own purposes.  And these stacks actually support inserting and
deleting at both ends, so they are actually double-ended queues
(deques).  In addition, they support inserting and deleting in the
middle.

   In Gforth the stacks grow as necessary, but the interface is designed
to also support resource-constrained systems that allocate fixed-size
stacks, where exceeding the stack size results in an error.  So you
should provide the size parameter accordingly.

   A stacks is represented on the data stack by a cell.

'stack' ( n - stack  ) gforth-experimental
   Create an unnamed stack with at least N cells space.

'stack:' ( n "name" -  ) gforth-experimental "stack-colon"
   Create a named stack with at least N cells space.

'stack>' ( stack - x  ) gforth-experimental "stack-from"
   Pop item x from top of stack.

'>stack' ( x stack -  ) gforth-experimental "to-stack"
   Push x to top of stack.

'>back' ( x stack -  ) gforth-experimental "to-back"
   Insert x at the bottom of stack.

'back>' ( stack - x  ) gforth-experimental "back-from"
   Remove item x from bottom of stack.

'+after' ( x1 x2 stack -  ) gforth-experimental "plus-after"
   Insert X1 below every occurrence X2 in stack.

'-stack' ( x stack -  ) gforth-experimental "minus-stack"
   Delete every occurrence of x from anywhere in stack.

'set-stack' ( x1 .. xn n stack -  ) gforth-experimental
   Overwrite the contents of stack with n elements from the data stack,
with xn becoming the top of stack.

'get-stack' ( stack - x1 .. xn n  ) gforth-experimental
   Push the contents of stack on the data stack, with the top element in
stack being pushed as xn.

6.14 Interpretation and Compilation Semantics
=============================================

In Gforth every named word has interpretation and compilation semantics,
i.e., separate actions that are performed in various contexts.

   In principle these semantics can be anything and completely
independent of each other, but in practice they are usually connected,
and words usually have default compilation semantics (compile the
interpretation semantics) or immediate compilation semantics (perform
the interpretation semantics); a few have other combinations of
interpretation and compilation semantics (combined words).

   The standard also discusses execution semantics, but it uses them
only to define interpretation and/or compilation semantics, so they are
not as essential as interpretation and compilation semantics.  In
particular, for every word in the standard that has both interpretation
and execution semantics, they are the same.  In Gforth (since 1.0), they
are always the same, and this manual uses the terms interchangeably,
usually preferring interpretation semantics.  In the description of
defining words, you see "name execution", which describes the
interpretation/execution semantics of name.

   Some named words also have some of 'to'/'+to'/'action-of'/'is'/'addr
name' semantics, but these are mostly discussed elsewhere (*note
Values::, *note Deferred Words::, *note Words with user-defined TO
etc.::)

6.14.1 Where are interpretation semantics used?
-----------------------------------------------

The most common use of the interpretation semantics of a word w is when
w is text-interpreted in interpretation state, the default state of the
text interpreter.

   I.e., when you start Gforth and type

     s" hello" type

   the text interpreter performs the interpretation semantics of the
words 's"' and 'type'.

   Also, when you get the execution token of a word w with '`w', '' w'
or '['] w' (*note Execution token::), the execution token represents the
interpretation semantics.

   When you get the execution token of the most recently defined word
with 'latestxt' (*note Anonymous Definitions::), that also refers to the
interpretation semantics of the word.

   Finally, 'name>interpret' (*note Name token::) produces an execution
token that represents the interpretation semantics of the word.

6.14.2 Where are compilation semantics used?
--------------------------------------------

The most common use of the compilation semantics of a word w is when w
is text-interpreted in compile state, the state right after starting a
definition with, e.g., ':'.

     : hello
       s" hello" type ;

   In this example, the text interpreter performs the compilation
semantics of 's"', 'type' and ';' (after first performing the
interpretation semantics of ':')

   When you postpone a word, you also use the compilation semantics.

     : compile-+ ( -- ) \ compiled code: ( n1 n2 -- n )
       POSTPONE + ;

     : foo ( n1 n2 -- n )
       [ compile-+ ] ;

     see foo

   Here the 'POSTPONE +' compiles (rather than performs) the compilation
semantics of '+' into 'compile-+'.  In the definition of 'foo', (the
interpretation semantics of) 'compile-+' is performed, which in turn
performs the compilation semantics of '+', i.e., it compiles '+' into
'foo'.

   The compilation semantics is represented by a compilation token
(*note Compilation token::).  You can get the compilation token of a
word w with '``w name>compile', 'comp' w', or '[comp'] w'.  The first
form first gets the name token of w and then accesses the compilation
token with 'name>compile'.

6.14.3 Which semantics do existing words have?
----------------------------------------------

For words built into Gforth, the documentation specifies the semantics.

   Most words have default compilation semantics.  For such words (e.g.,
'!', *note Memory Access::) the documentation describes the
interpretation semantics without explicitly labeling as such.  The
compilation semantics of these words is to compile the interpretation
semantics into the current definition; the stack effect of performing
the default compilation semantics is '( -- )'.

   Some words have non-default compilation semantics.  This is either
indicated by labels for interpretation, compilation, and/or run-time in
the stack effects (e.g., for 'IF', *note Arbitrary control
structures::), or by having separate paragraphs for interpretation,
compilation, and/or run-time in the prose (e.g., for 'S"', *note String
and character literals::).

   You may wonder about the run-time semantics mentioned in the previous
paragraphs.  For some words (e.g., 'if'), the compilation semantics
compiles something that is not the interpretation/execution semantics.
We (and the standard) describe the behaviour of the code that these
words compile with under the label "run-time semantics"; if you see
"run-time" in a word description (e.g., in its stack effect), that
usually refers to run-time semantics that the compilation semantics of
the word compiles.

   Concerning the description of the various semantics, both the
standard and this manual describe the interpretation/execution semantics
of words with default semantics without preceding these semantics with a
label (the label "execution" or "interpretation" would be appropriate).
The compilation semantics of such words are the implied default
compilation semantics (*note What semantics do normal definitions
have?::).

   For words that have some non-default semantics, the standard
specifies the different semantics of the word in separate subsections,
each preceded with a label ("interpretation:", "compilation:", and, if
necessary, "execution:" or "run-time:"(1)).  This manual often takes a
more informal approach.  The approach taken in this manual may be more
accommodating for everyday use, while the standard approach is more
precise for reasoning about details of the language.

   ---------- Footnotes ----------

   (1) In some cases the standard leaves the subsection for
interpretation or compilation semantics away, and leaves it to the
default mechanism to derive those semantics from execution semantics.

6.14.4 What semantics do normal definitions have?
-------------------------------------------------

Most defining words normally produce words with default interpretation
semantics and default compilation semantics; those that do not (e.g,
'synonym' or 'interpret/compile:') are documented appropriately.

   The interpretation semantics of the newly defined word name are
described in the "name execution:" part of the description of the
defining word.  Things are a little more complicated for colon
definitions (*note Colon Definitions::) and words using
'create'...'does>' (*note User-defined defining words using CREATE::),
but again, the description of what these words do is about the
interpretation semantics.

   For a word w with default compilation semantics, the compilation
semantics are to compile the interpretation semantics.  More formally:
to append the interpretation semantics of w to the interpretation
semantics of the current definition.  As an example, consider the
definition

     : name ... w ... ;

   Here the interpretation semantics of w is appended to the
interpretation semantics of name.

6.14.5 How to define immediate words
------------------------------------

You can change the compilation semantics of a word to be the same as the
interpretation semantics with

'immediate' ( -  ) core
   Change the compilation semantics of a word to be the same as its
interpretation semantics.

   A contrived example:

     : [foo]
       ." foo" ; immediate

     : bar
       [foo] ; \ prints "foo"
     bar \ no output

   The 'immediate' causes '[foo]' to perform the interpretation
semantics during the definition of 'bar' rather than compiling them.  A
convention sometimes (but not always) used for immediate words is to
have their names in brackets, e.g.  '[']'.

   A common use of 'immediate' is to define macros (*note Macros::).

   The text interpretation of a macro in interpret state is often a
mistake, so you can turn the macro into a 'compile-only' word with

'compile-only' ( -  ) gforth-0.2
   Mark the last definition as compile-only; as a result, the text
interpreter and ''' will warn when they encounter such a word.

   Example:

     : endif
       postpone then ; immediate compile-only

     : foo
       if ." true" endif ;

     endif \ "warning: endif is compile-only"

   The warning is followed by a stack underflow error because 'then'
wants to consume an orig (*note Arbitrary control structures::).

   Note that compiling code while the text interpreter is in interpret
state is not a problem in itself, even if a number of words are marked
'compile-only'.  A more serious problem is compiling code if the current
definition is not an unfinished colon definition: there is no way to run
the resulting code.  Gforth warns about that even if a word is not
marked compile-only or if you text-interpret it in compile state:

     : compile-+
       postpone + ;

     : foo [ compile-+ ] ; \ no warning; interpretation semantics of compile-+

     compile-+ \ warning: Compiling outside a definition
     if        \ warning: IF is compile-only
               \ warning: Compiling outside a definition
     compile-+ \ warning: Compiling outside a definition
     then      \ warning: THEN is compile-only
     ] if      \ warning: Compiling outside a definition
       +       \ warning: Compiling outside a definition
       then
     [

   Note that switching to compile state in the last four lines silences
the "is compile-only" warnings, because in these lines the compilation
semantics of the words is performed.

   Why does 'then' not produce "Compiling outside a definition" warnings
in the example above?  'Then' does not generate any code by itself, it
just changes the target of the code compiled by the matching 'if' or
'ahead'.

'restrict' ( -  ) gforth-0.2
   A synonym for 'compile-only'

6.14.6 How to define combined words
-----------------------------------

In a few cases (and most of those are a bad idea) you want to define a
word that has some other combination of interpretation and compilation
semantics than words with default compilation semantics or immediate
words (a combined word(1)).  The following contrived example shows how
you can define a combined word:

     : foo ." foo" ;
     : bar ." bar" ;
     ' foo ' bar interpret/compile: foobar1

     foobar1     \ "foo"
     ] foobar1 [ \ "bar"

'interpret/compile:' ( int-xt comp-xt "name" -  ) gforth-0.2 "interpret-slash-compile-colon"
   Defines name.
Name execution: execute int-xt.
Name compilation: execute comp-xt.

   There are two kinds of uses for combined words:

   One use of combined words is parsing words that should be
copy-pasteable between interpreted and compiled code; these words should
parse at text-interpret time both in their interpretation and their
compilation semantics (like an immediate word), but then should perform
an action in their interpretation semantics and compile that action in
their compilation semantics, like a normal word.  An example is '."' in
Gforth:

     : ."-int ( 'ccc"' -- )  '"' parse type ;
     : ."-comp ( 'ccc"' -- ) '"' parse postpone sliteral postpone type ;

     ' ."-int ' ."-comp interpret/compile: ."
     ( interpretation 'ccc"' -- ; compilation 'ccc"' -- ; run-time -- )

     ." foo"         \ "foo"
     : foo ." foo" ;
     foo             \ "foo"

   The parsing code is the same in both cases, the action 'type' is
directly executed in the interpretation semantics and compiled in the
compilation semantics.  The compilation semantics also contains
'postpone sliteral' to transfer the parsed string from
text-interpretation time to the run-time of the action.  This kind of
parse/literal/action split with the use of 'postpone' is typical for the
implementations of the compilation semantics of such parsing words, and
the interpretation semantics consist just of the parse and the action
parts.

   We discourage the definition of additional combined words for
copy-pasteability.  They do not work as intended within ']]'...'[['
(*note Macros::) and their behaviour is also confusing in other
contexts, e.g., when ticking or 'postpone'ing such a word.  A way to
achieve copy-pasteability without needing to define combined words is
recognizers (*note Recognizers::).  '"foo" type' uses the string
recognizer (*note Default Recognizers::) and can be copied and pasted
between interpreted code, compiled code and code inside ']]'...'[['
without problem.

   On the other hand, combined words are still far better than
'state'-smart words.(2)

   The other kind of use of combined words is for words like '[:' (*note
Quotations::).  These are not parsing words, but '[:'...';]' sequences
should be copy-pasteable between interpreted and compiled code; the
whole sequence pushes an xt at its run-time.  At text-interpret time, it
restores the state at the end to what it was at the start.  Ideally we
would find a clean way to implement all this without needing combined
words, but for now the implementation is pretty messy, including
combined words.

   Some people also have the idea to use combined words for
optimization.  However, the resulting words do not work as intended with
'[compile]' (*note Macros::).  Gforth has a better mechanism for
optimization: 'set-optimizer' (*note User-defined compile-comma::).

   Some people worry about the aesthetics of 'interpret/compile:' and
have proposed alternative syntaxes, and the following ones are supported
in Gforth:

     : foobar2
       ." foo" ;
     [: ." bar" ;] set-compsem

     foobar2     \ "foo"
     ] foobar2 [ \ "bar"

     : foobar3
       ." foo" ;
     compsem:
       ." bar" ;

     foobar3     \ "foo"
     ] foobar3 [ \ "bar"

     : foobar4
       ." bar" ;
     intsem:
       ." foo" ;

     foobar4     \ "foo"
     ] foobar4 [ \ "bar"

   You can use 'where' (*note Locating uses of a word::) to find out how
rarely which syntax is used in Gforth.

'set-compsem' ( xt -  ) gforth-experimental
   change compilation semantics of the last defined word

'compsem:' ( -  ) gforth-experimental "comp-sem-colon"
   Changes the compilation semantics of the current definition to
perform the definition starting at the 'compsem:'.

'intsem:' ( -  ) gforth-experimental "int-sem-colon"
   The current definition's compilation semantics are changed to perform
its interpretation semantics.  Then its interpretation semantics are
changed to perform the definition starting at the 'intsem:' (without
affecting the compilation semantics).  Note that if you then call
'immediate', the compilation semantics are changed to perform the word's
new interpretation semantics.

   ---------- Footnotes ----------

   (1) Some people call combined words "NDCS", but immediate words also
have non-default compilation semantics

   (2) 'State'-smart words are immediate words that do 'state'-dependent
things at run-time.  For a more detailed discussion of this topic, see
M.  Anton Ertl, ''State'-smartness--Why it is Evil and How to Exorcise
it (https://www.complang.tuwien.ac.at/papers/ertl98.ps.gz)', EuroForth
'98.

6.15 Tokens for Words
=====================

This section describes the creation and use of tokens that represent
words.

6.15.1 Execution token
----------------------

An "execution token" (_xt_) represents some behaviour of a word.  You
can use 'execute' to invoke the behaviour represented by the xt and
'compile,' (*note Macros::) to compile it into the current definition.
Other uses include deferred words (*note Deferred Words::).

   In particular, there is _the_ execution token of a word that
represents its interpretation semantics (*note Interpretation and
Compilation Semantics::).

   For a named word x, you can use '`x' to get its execution token:

     5 `. ( n xt )
     execute ( )        \ "5"
     : foo `. execute ;
     5 foo              \ "5"

   However, the tick-recognizer that recognizes the '`' prefix is a
Gforth extension, so you may prefer to use the Standard Forth words:

''' ( "name" - xt  ) core "tick"
   xt represents name's interpretation semantics.

'[']' ( compilation. "name" - ; run-time. - xt  ) core "bracket-tick"
   xt represents name's interpretation semantics.

   These are parsing words (whereas '`x' is treated as a literal by a
recognizer), and you may find the behaviour in interpreted and compiled
code unintuitive:

     5 ' .   ( n xt )
     execute ( )          \ "5"

     : foo ['] . ;
     5 foo execute        \ "5"

     : bar ' dup ;
     5 bar . drop execute \ "5"

   ''' parses at run-time, so if you put it in a colon definition, as in
'bar', it does not consume the next word in the colon definition, but
the next word at run-time (i.e., the '.' in the invocation of 'bar').
If you want to put a literal xt in a colon definition without writing
'`x', write '['] x'.

   Gforth's '`x', ''' and '[']' warn when you use them on compile-only
words, because such usage may be non-portable between different Forth
systems.

   You get the xt of the most recently defined word with 'latestxt'
(*note Anonymous Definitions::).  For words defined using 'noname', this
is the usual way of getting a token.

   For words defined with ':noname', the definition already pushes the
xt, so you do not need to use 'latestxt' for ':noname'-defined words.

     :noname ." hello" ;
     execute

   An xt occupies one cell and can be manipulated like any other cell.

   In Standard Forth the xt is just an abstract data type (i.e., defined
by the operations that produce or consume it).  The concrete
implementation (since Gforth 1.0) is the body address (for old hands:
PFA) of the word; in Gforth 0.7 and earlier, the xt was implemented as
code field address (CFA, 2 cells before the PFA).

'execute' ( xt - ) core "execute"
   Perform the semantics represented by the execution token, xt.

'execute-exit' ( compilation - ; run-time xt nest-sys -  ) gforth-1.0
   Execute 'xt' and return from the current definition, in a
tail-call-optimized way: The return address 'nest-sys' and the locals
are deallocated before executing 'xt'.

'perform' ( a-addr - ) gforth-0.2 "perform"
   '@ execute'.

   '[Noop]' is sometimes used as a placeholder execution token:

'[noop]' ( -  ) gforth-experimental "bracket-noop"
   Does nothing, both when executed and when compiled.

'noop' ( - ) gforth-0.2 "noop"
   Does nothing.  However, code generation does not optimize it away;
use '[noop]' for that.

6.15.2 Name token
-----------------

A "name token" (nt) represents a word, primarily a named word, but in
Gforth since 1.0 unnamed words have a name token, too.

   The name token is a cell-sized abstract data type that occurs as
argument or result of the words below.

   You get the nt of a word x with '``x' (since Gforth 1.0) or with

'find-name' ( c-addr u - nt | 0  ) gforth-0.2
   Find the name c-addr u in the current search order.  Return its nt,
if found, otherwise 0.

'find-name-in' ( c-addr u wid - nt | 0  ) gforth-1.0
   Find the name c-addr u in the word list wid.  Return its nt, if
found, otherwise 0.

'latest' ( - nt  ) gforth-0.6
   NT is the name token of the last word defined in the current section.
NT is 0 if the last word has no name.

'latestnt' ( - nt  ) gforth-1.0
   nt is the name token of the most recent word (named or unnamed)
defined in the current section.

'>name' ( xt - nt|0  ) gforth-0.2 "to-name"
   nt is the primary name token of the word represented by xt.  Returns
0 if xt is not an xt (using a heuristic check that has a small chance of
misidentifying a non-xt as xt), or (before Gforth 1.0) if the primary nt
is of an unnamed word.  As of Gforth 1.0, every xt has a primary nt.
Several words can have the same xt, but only one of them has the primary
nt of that xt.

'xt>name' ( xt - nt  ) gforth-1.0 "xt-to-name"
   Produces the primary nt for an xt.  If xt is not an xt, nt is not
guaranteed to be an nt.

   You can get all the nts in a wordlist with

'traverse-wordlist' ( ... xt wid - ...  ) tools-ext
   perform xt ( ...  nt - f ...  )  once for every word nt in the
wordlist wid, until f is false or the wordlist is exhausted.  xt is free
to use the stack underneath.

   You can use the nt to access the interpretation and compilation
semantics of a word, its name, and the next word in the wordlist:

'name>interpret' ( nt - xt  ) tools-ext "name-to-interpret"
   xt represents the interpretation semantics of the word nt.

'name>compile' ( nt - w xt  ) tools-ext "name-to-compile"
   w xt is the compilation token for the word nt (*note Compilation
token::).

'name>string' ( nt - addr u  ) tools-ext "name-to-string"
   addr count is the name of the word represented by nt.

'id.' ( nt -  ) gforth-0.6 "i-d-dot"
   Print the name of the word represented by NT.

'.id' ( nt -  ) gforth-0.6 "dot-i-d"
   F83 name for 'id.'.

'compile-only?' ( nt - flag  ) gforth-1.0 "compile-only-question"
   true if nt is marked as compile-only.

'obsolete?' ( nt - flag  ) gforth-1.0 "obsolete-question"
   true if nt is obsolete, i.e., will be removed in a future version of
Gforth.

'name>link' ( nt1 - nt2 / 0  ) gforth-1.0 "name-to-link"
   For a word nt1, returns the previous word nt2 in the same wordlist,
or 0 if there is no previous word.

   As a usage example, the following code lists all the words in
'forth-wordlist' with non-default compilation semantics (including
immediate words):

     : ndcs-words ( wid -- )
       [: dup name>compile ['] compile, <> if over id. then 2drop true ;]
       swap traverse-wordlist ;

     forth-wordlist ndcs-words

   This code assumes that a word has default compilation semantics if
the xt part of its compilation token is the xt of 'compile,'.

   Since Gforth 1.0 (but not in earlier versions or many other Forth
systems), nameless words (*note Anonymous Definitions::) have nts,
compilation semantics, and 'name>string' works on them (producing a
zero-length name).  They are not in a wordlist, however.  You can get
the nt of a nameless word with 'latestnt'.

   Since Gforth 1.0, for most words the concrete implementation of their
nt is the same address as its xt (this is the primary nt for the xt).
However, synonyms, aliases, and words defined with 'interpret/compile:'
get their xt from another word, but still have an nt of their own (that
is different from the xt).  Therefore, you cannot use xts and nts
interchangeably, even if you are prepared to write code specific to
Gforth 1.0.  You do not get these alternate nts for the xt with '>name'.

   The closest thing to the nt in classic Forth systems like fig-Forth
is the name field address (NFA), but there are significant differences:
in older Forth systems each word has a unique NFA, LFA, CFA and PFA (in
this order, or LFA, NFA, CFA, PFA) and there are words for getting from
one to the next.  By contrast, in Gforth in general there is an n:1
relation between name tokens and the xt representing interpretation
semantics; i.e., when you pass different nts to 'name>interpret', the
result may be the same xt.

   Another difference is that the NFA usually points to the start of the
header, whereas the nt in Gforth 1.0 points to the body (and header
fields are accessed with a negative offset).

   Moreover, all of the header fields of the old system correspond to
fields in Gforth, but Gforth 1.0 has a few additional ones (*note Header
fields::).

6.15.3 Compilation token
------------------------

The compilation semantics of a word is represented by a "compilation
token" consisting of two cells: w xt.  The top cell xt is an execution
token.  The compilation semantics represented by the compilation token
can be performed with 'execute', which consumes the whole compilation
token, with an additional stack effect determined by the represented
compilation semantics.

   At present, the w part of a compilation token is an execution token,
and the xt part represents either 'execute' or 'compile,'(1).  However,
don't rely on that knowledge, unless necessary; future versions of
Gforth may introduce unusual compilation tokens (e.g., a compilation
token that represents the compilation semantics of a literal).

   You get the compilation token of, e.g., 'if' in a standard way with
'name>compile', e.g., '' if name>compile', but there are also parsing
words to get the compilation token of a word:

'[COMP']' ( compilation "name" - ; run-time - w xt  ) gforth-0.2 "bracket-comp-tick"
   Compilation token w xt represents name's compilation semantics.

'COMP'' ( "name" - w xt  ) gforth-0.2 "comp-tick"
   Compilation token w xt represents name's compilation semantics.

   You can perform the compilation semantics represented by the
compilation token with 'execute'.  You can compile the compilation
semantics with 'postpone,'.  I.e., '``x name>compile postpone,' is
equivalent to 'postpone x'.

'postpone,' ( w xt -  ) gforth-0.2 "postpone-comma"
   Compile the compilation semantics represented by the compilation
token w xt.

   ---------- Footnotes ----------

   (1) Depending upon the compilation semantics of the word.  If the
word has default compilation semantics, the xt will represent
'compile,'.  Otherwise (e.g., for immediate words), the xt will
represent 'execute'.

6.16 Compiling words
====================

In contrast to most other languages, Forth has no strict boundary
between compilation and run-time.  E.g., you can run arbitrary code
between defining words (or for computing data used by defining words
like 'constant').  Moreover, 'Immediate' (*note Interpretation and
Compilation Semantics::) and '['...']'  (see *note Literals::) allow
running arbitrary code while compiling a colon definition (exception:
any dictionary space you allot must be in a different section, *note
Sections::).

6.16.1 Literals
---------------

The simplest and most frequent example is to compute a literal during
compilation.  E.g., the following definition prints an array of strings,
one string per line:

     : .strings ( addr u -- ) \ gforth
         2* cells bounds U+DO
             cr i 2@ type
         2 cells +LOOP ;

   With a simple-minded compiler like Gforth 0.7, this computes '2
cells' on every loop iteration.  You can compute this value at compile
time and compile it into the definition like this:

     : .strings ( addr u -- ) \ gforth
         2* cells bounds U+DO
             cr i 2@ type
         [ 2 cells ] literal +LOOP ;

   '[' switches the text interpreter to interpret state (you will get an
'ok' prompt if you type this example interactively and insert a newline
between '[' and ']'), so it performs the interpretation semantics of '2
cells'; this computes a number.  ']'  switches the text interpreter back
into compile state.  It then performs 'Literal''s compilation semantics,
which are to compile this number into the current word.  You can
decompile the word with 'see .strings' to see the effect on the compiled
code.(1)

   You can also optimize the '2* cells' into '[ 2 cells ] literal *' in
this way.(2)

'[' ( -  ) core "left-bracket"
   Enter interpretation state.  Immediate word.

']' ( -  ) core "right-bracket"
   Enter compilation state.

'Literal' ( compilation n - ; run-time - n  ) core
   Compilation semantics: ( n - ) compile the run-time semantics.
Run-time Semantics: ( - n ).
Interpretation semantics: not defined in the standard.

'lit,' ( x -  ) gforth-1.0 "lit-comma"
   This is a non-immediate variant of 'literal'
Execution semantics: Compile the following semantis:
Compiled semantics: ( - x ).

'ALiteral' ( compilation addr - ; run-time - addr  ) gforth-0.2
   Works like 'literal', but (when used in cross-compiled code) tells
the cross-compiler that the literal is an address.

']L' ( compilation: n - ; run-time: - n  ) gforth-0.5 "right-bracket-L"
   equivalent to '] literal'

   There are also words for compiling other data types than single cells
as literals:

'2Literal' ( compilation w1 w2 - ; run-time  - w1 w2  ) double "two-literal"
   Compilation semantics: ( w1 w2 - ) compile the run-time semantics.
Run-time Semantics: ( - w1 w2 ).
Interpretation semantics: not defined in the standard.

   doc-2lit,
'FLiteral' ( compilation r - ; run-time - r  ) floating "f-literal"
   Compilation semantics: ( r - ) compile the run-time semantics.
Run-time Semantics: ( - r ).
Interpretation semantics: not defined in the standard.

'flit,' ( r -  ) gforth-1.0 "flit-comma"
   This is a non-immediate variant of 'fliteral'
Execution semantics: Compile the following semantis:
Compiled semantics: ( - r ).

'SLiteral' ( Compilation c-addr1 u - ; run-time - c-addr2 u  ) string
   Compilation semantics: ( c-addr1 u - ) Copy the string described by
c-addr1 u to c-addr2 u and compile the run-time semantics.
Run-time Semantics: ( - c-addr2 u ).
Interpretation semantics: not defined in the standard.

'slit,' ( c-addr1 u -  ) gforth-1.0 "slit-comma"
   This is a non-immediate variant of 'sliteral'
Execution semantics: Copy the string described by c-addr1 u to c-addr2 u
and Compile the following semantis:
Compiled semantics: ( - c-addr2 u ).

   You might be tempted to pass data from outside a colon definition to
the inside on the data stack.  This does not work, because ':' pushes a
colon-sys, making stuff below unaccessible.  E.g., this does not work:

     5 : foo literal ; \ error: "unstructured"

   Instead, you have to pass the value in some other way, e.g., through
the return stack:

     5 >r : foo [ r> ] literal ;

   The interpretive use of the return stack is Gforth-specific; the use
of a variable also works on other Forth systems:

     variable temp
     5 temp !
     : foo [ temp @ ] literal ;

   ---------- Footnotes ----------

   (1) In Gforth 1.0, the compiler performs constant folding, and 'see'
of the original '.strings' will show the same effect.

   (2) In Gforth 1.0, '2 cells *' is sufficient.

6.16.2 Macros
-------------

'Literal' and friends compile data values into the current definition.
You can also write words that compile other words into the current
definition.  E.g.,

     : compile-+ ( -- ) \ compiled code: ( n1 n2 -- n )
       POSTPONE + ;

     : foo ( n1 n2 -- n )
       [ compile-+ ] ;
     1 2 foo .

   This is equivalent to ': foo + ;' ('see foo' to check this).  What
happens in this example?  'Postpone' compiles the compilation semantics
of '+' into 'compile-+'; later the text interpreter executes 'compile-+'
and thus the compilation semantics of +, which compile (the execution
semantics of) '+' into 'foo'.

'postpone' ( "name" -  ) core
   Compiles the compilation semantics of name.

   Compiling words like 'compile-+' are usually immediate (*note How to
define immediate words::) so you do not have to switch to interpret
state to execute them; modifying the last example accordingly produces:

     : [compile-+] ( compilation: --; interpretation: -- )
       \ compiled code: ( n1 n2 -- n )
       POSTPONE + ; immediate

     : foo ( n1 n2 -- n )
       [compile-+] ;
     1 2 foo .

   You will occasionally find the need to POSTPONE several words;
putting POSTPONE before each such word is cumbersome, so Gforth provides
a more convenient syntax: ']] ... [['.  This allows us to write
'[compile-+]' as:

     : [compile-+] ( compilation: --; interpretation: -- )
       ]] + [[ ; immediate

']]' ( -  ) gforth-0.6 "right-bracket-bracket"
   Switch into postpone state: All words and recognizers are processed
as if they were preceded by 'postpone'.  Postpone state ends when '[['
is recognized.

   The unusual direction of the brackets indicates their function: ']]'
switches from compilation to postponing (i.e., compilation of
compilation), just like ']' switches from immediate execution
(interpretation) to compilation.  Conversely, '[[' switches from
postponing to compilation, ananlogous to '[' which switches from
compilation to immediate execution.

   The real advantage of ']] '...' [[' becomes apparent when there are
many words to POSTPONE. E.g., the word 'compile-map-array' (*note
Advanced macros Tutorial::) can be written much shorter as follows:

     : compile-map-array ( compilation: xt -- ; run-time: ... addr u -- ... )
     \ at run-time, execute xt ( ... x -- ... ) for each element of the
     \ array beginning at addr and containing u elements
       {: xt: xt :}
       ]] cells over + swap ?do
         i @ xt 1 cells +loop [[ ;

     : sum-array ( addr u -- n )
       0 [ ' + compile-map-array ] ;

   If you then say 'see sum-array', it shows the following code:

     : sum-array
       #0 over + swap ?do
         i @ + #8 +LOOP
     ;

   In addition to ']]'...'[[', this example shows off some other
features:

   * It uses a defer-flavoured (defined with 'xt:' local 'xt';
     mentioning such a local inside ']]'...'[[' results in 'compile,'ing
     the xt in the local, i.e., ']] xt [[' is equivalent to 'action-of
     xt compile,'.

   * Not used in the example, but related to the previous point: For a
     normal (value-flavoured) local, using it inside ']]'...'[['
     compiles the value of the local, i.e., ']] x [[' is equivalent to
     'x ]] literal [['.

   * It uses the literal '1' inside ']]'...'[['.  This results in
     'postpone'ing the '1', i.e.  compiling it when 'compile-map-array'
     is run.  ']] 1 [[' is equivalent to '1 ]] literal [['.

   * When 'compile-map-array' is run, '1 cells' is compiled and
     optimized into '#8' by Gforth's constant folding.

   Note that parsing words such as 's\"' don't parse at postpone time
and therefore not inside ']]'...'[['.  Instead of 's\" mystring\n"' you
can use the string recognizer and write '"mystring\n"', which works
inside ']]'...'[['.  Likewise, the parsing word '[']' does not parse
inside ']]'...'[[' while the recognizer notation starting with '`' works
inside ']]'...'[['.

   But if you prefer to use 's\"' (or have a parsing word that has no
recognizer replacement), you can do it by switching back to compilation:

     ]] ... [[ s\" mystring\n" ]] sliteral ... [[

   Definitions of ']]' and friends in Standard Forth are provided in
'compat/macros.fs'.

   Immediate compiling words are similar to macros in other languages
(in particular, Lisp).  The important differences to macros in, e.g., C
are:

   * You use the same language for defining and processing macros, not a
     separate preprocessing language and processor.

   * Consequently, the full power of Forth is available in macro
     definitions.  E.g., you can perform arbitrarily complex
     computations, or generate different code conditionally or in a loop
     (e.g., *note Advanced macros Tutorial::).  This power is very
     useful when writing a parser generators or other code-generating
     software.

   * Macros defined using 'postpone' etc.  deal with the language at a
     higher level than strings; name binding happens at macro definition
     time, so you can avoid the pitfalls of name collisions that can
     happen in C macros.  Of course, Forth is a liberal language and
     also allows to shoot yourself in the foot with text-interpreted
     macros like

          : [compile-+] s" +" evaluate ; immediate

     Apart from binding the name at macro use time, using 'evaluate'
     also makes your definition 'state'-smart (*note state-smartness::).

   You may want the macro to compile a number into a word.  The word to
do it is 'literal', but you have to 'postpone' it, so its compilation
semantics take effect when the macro is executed, not when it is
compiled:

     : [compile-5] ( -- ) \ compiled code: ( -- n )
       5 POSTPONE literal ; immediate

     : foo [compile-5] ;
     foo .

   A more convenient, but less portable way to write '[compile-5]' is:

     : [compile-5] ( -- ) \ compiled code: ( -- n )
       ]] 5 [[ ; immediate

   You may want to pass parameters to a macro, that the macro should
compile into the current definition.  If the parameter is a number, then
you can use 'postpone literal' (similar for other values).

   If you want to pass a word that is to be compiled, the usual way is
to pass an execution token and 'compile,' it:

     : twice ( xt -- ) \ compiled code: ... -- ...
       dup compile, compile, ;

     : 2+ ( n1 -- n2 )
       [ ' 1+ twice ] ;

'compile,' ( xt -  ) core-ext "compile-comma"
   Append the semantics represented by xt to the current definition.
When the resulting code fragment is run, it behaves the same as if xt is
'execute'd.

   A more convenient, but less portable way to write 'twice' is:

     : twice {: xt: xt -- :} \ compiled code: ... -- ...
       ]] xt xt [[ ;

   An alternative that allows you to pass the compilation semantics as
parameters is to use the compilation token (*note Compilation token::).
The same example in this technique:

     : ctwice ( ... ct -- ... ) \ compiled code: ... -- ...
       2dup 2>r execute 2r> execute ;

     : 2+ ( n1 -- n2 )
       [ ``1+ name>compile ctwice ] ;

   In particular, you want to pass the compilation token and 'execute'
it in case of words without interpretation semantics or with non-default
and non-immediate compilation semantics (i.e., not for '1+').

   In the example above '2>r' and '2r>' ensure that 'ctwice' works even
if the executed compilation semantics has an effect on the data stack.

   You can also define complete definitions with these words; this
provides an alternative to using 'does>' (*note User-defined Defining
Words::).  E.g., instead of

     : curry+ ( n1 "name" -- )
         CREATE ,
     DOES> ( n2 -- n1+n2 )
         @ + ;

   you could define

     : curry+ ( n1 "name" -- )
       \ name execution: ( n2 -- n1+n2 )
       >r : r> POSTPONE literal POSTPONE + POSTPONE ; ;

     -3 curry+ 3-
     see 3-

   The sequence '>r : r>' is necessary, because ':' puts a colon-sys on
the data stack that makes everything below it unaccessible.

   A more convenient, but less portable way to define 'curry+' is:

     : curry+ ( n1 "name" -- )
       \ name execution: ( n2 -- n1+n2 )
       {: n1 :} : ]] n1 + ; [[ ;

   This way of writing defining words is sometimes more, sometimes less
convenient than using 'does>' (*note Advanced does> usage example::).
One advantage of this method is that it can be optimized better, because
the compiler knows that the value compiled with 'literal' is fixed,
whereas the data associated with a 'create'd word can be changed.

'[compile]' ( compilation "name" - ; run-time ? - ?  ) core-ext "bracket-compile"
   Legacy word.  Use 'postpone' instead.  Works like 'postpone' if name
has non-default compilation semantics.  If name has default compilation
semantics (i.e., is a normal word), compiling '[compile] name' is
equivalent to compiling name (i.e.  '[compile]' is redundant in this
case.

'in-colon-def?' ( - flag  ) gforth-experimental "in-colon-def-question"
   allows to check if there currently is an active colon definition
where you can append code to.

6.17 The Text Interpreter
=========================

The text interpreter processes Forth source code, and performs the
semantics of the words in the source code.  The text interpreter works
on Forth source code coming from the standard input (the "user input
device" in Forth standard terminology), from a file (through 'included'
and friends), from 'evaluate', or from a 'load'ed block.

   The text interpreter is also called the outer interpreter, in
contrast to the inner interpreter of traditional Forth implementations
which interprets the threaded code that is the output of the Forth
compiler on these implementations; many Forth systems nowadays compile
to native code and have no inner interpreter.  Concerning Gforth's
approach, *note Engine::.

   The text interpreter works line by line (using 'refill').  Therefore,
most parsing words (e.g., ''' and 's"') only try to find their parsed
arguments in the current line; if a word parses across line boundaies,
that is stated explicitly in the documentation of the word.  However, a
block is interpreted like one line, their division into "lines" is just
for display purposes; 'Evaluate' interprets the string as a whole.  The
current line/block/string is available to programs through 'source', and
its content is valid until the current line is changed; it has to be
treated as read-only region.

   Within a line, the text interpreter parses for white-space-delimited
words (with 'parse-name').  The text interpreter's position within the
line is stored in '>in', and by changing '>in', a program can change
where the text interpreter or parsing word continues to parse.

   The text interpreter then tries to recognize the word with one of the
recognizers in the system recognizer sequence.  On success, this
produces a _translator_ and additional data, which represents the
recognized word on the stack, as far as the text interpreter is
concerned (*note Define recognizers with existing translators::).

   It then performs the interpretation, compilation, or postponing
action of the translator, depending on the state of the text
interpreter: Is it inside ']]'...'[['?  If not, what is the value of
'state'?  E.g., when a word from the search order is recognized, and the
text interpreter is in compile state, the compilation semantics of this
word will be performed.  This translator action may perform additional
parsing, e.g., when the recognizer has recognized a parsing word.  If no
recognizer recognizes the word, the text interpreter 'throw's -13
("undefined word").

   The text interpreter then continues to parse, recognize, and
translate words.  At the end of the line, it 'refill's and continues
with the next line.  At the end of an input source (e.g., at the end of
a file), the text interpreter returns to its caller, and that caller
(e.g., 'included') restores the previous input stream before returning
itself.

   If an exception is not caught earlier, the same unnesting of input
streams and the associated calls are performed.  If not 'catch'
intervenes, the 'throw' is eventually caught by the system.  In Gforth,
the system then prints an error message with a backtrace of both the
call stack and the stack of nested input streams (*note Error
messages::).  In interactive mode, Gforth then calls a text interpreter
for the user input device, while in scripting mode (while processing OS
command-line arguments, *note Scripting mode::) Gforth then terminates
with a non-zero exit code.

   You can read about this in more detail in *note Input Sources::.

'source' ( - c-addr u  ) core "source"
   c-addr u is the input buffer, i.e., the line/block/'evaluate'd-string
currently processed by the text interpreter

'>in' ( - addr  ) core "to-in"
   Addr contains the offset into 'source' where the text interpreter or
parsing words parse next.  Addr can be different for different tasks,
and for different input streams within a task.

'tib' ( - addr  ) core-ext-obsolescent "t-i-b"

'#tib' ( - addr  ) core-ext-obsolescent "number-t-i-b"
   Addr is the address of a cell containing the number of characters in
the terminal input buffer.  Addr can be different for different tasks,
and for different input streams within a task.  OBSOLESCENT: 'source'
supersedes the function of this word.

'state' ( - a-addr  ) core,tools-ext
   Don't use 'state'!  'State' is the state of the text interpreter, and
ordinary words should work independently of it; in particular, 'state'
does not tell you whether the interpretation semantics or compilation
semantics of a word are being performed.  See ''State'-smartness-Why it
is evil and how to exorcise it'.  For an alternative to 'state'-smart
words, see *note How to define combined words::.
A-addr is the address of a cell containing the compilation state flag.
0 => interpreting, -1 => compiling.  A standard program must not store
into 'state', but instead use '[' and ']'.

6.17.1 Input Sources
--------------------

By default, the text interpreter processes input from the user input
device (the keyboard) when Forth starts up.  The text interpreter can
process input from any of these sources:

   * The user input device - the keyboard.
   * A file, using the words described in *note Forth source files::.
   * A text string, using 'evaluate'; a variant of this is when Gforth
     processes an OS command line argument of the form '-e string'.
   * A block, *note Blocks::.

   A program can identify the current input device from the values of
'source-id' and 'blk'.

'evaluate' ( ... addr u - ...  ) core,block
   Save the current input source specification.  Store '-1' in
'source-id' and '0' in 'blk'.  Set '>IN' to '0' and make the string
c-addr u the input source and input buffer.  Interpret.  When the parse
area is empty, restore the input source specification.

'source-id' ( - 0 | -1 | fileid  ) core-ext,file "source-i-d"
   Return 0 (the input source is the user input device), -1 (the input
source is a string being processed by 'evaluate') or a fileid (the input
source is the file specified by fileid).

'blk' ( - addr  ) block "b-l-k"
   addr contains the current block number (or 0 if the current input
source is not a block).

'save-input' ( - x1 .. xn n  ) core-ext
   The n entries xn - x1 describe the current state of the input source
specification, in some platform-dependent way that can be used by
'restore-input'.

'restore-input' ( x1 .. xn n - flag  ) core-ext
   Attempt to restore the input source specification to the state
described by the n entries xn - x1.  flag is true if the restore fails.
In recent (how recent?)  Gforth, it is possible to save and restore
between different active input streams.  Note that closing the input
streams must happen in the reverse order as they have been opened, but
as long as they are both active, everything is allowed.  These Gforth
versions only produce non-zero flags as results of 'catch'ing some
exception, and the flag itself is the 'throw'n ball and can be
re'throw'n.

'query' ( -  ) core-ext-obsolescent
   Make the user input device the input source.  Receive input into the
Terminal Input Buffer.  Set '>IN' to zero.  OBSOLETE: This Forth-94 word
has been de-standardized in Forth-2012.  It is superceeded by 'accept'.

6.17.2 Number Conversion
------------------------

You get an overview of how the text interpreter converts its numeric
input in *note Literals in source code::.  This section describes some
related words.

   By default, the number base used for integer number conversion is
given by the contents of the variable 'base'.  Note that a lot of
confusion can result from unexpected values of 'base'.  If you change
'base' anywhere, make sure to save the old value and restore it
afterwards; better yet, use 'base-execute', which does this for you.  In
general I recommend keeping 'base' decimal, and using the prefixes
described in *note Literals in source code:: for the popular non-decimal
bases.

'base-execute' ( i*x xt u - j*x  ) gforth-0.7
   execute xt with the content of 'BASE' being u, and restoring the
original 'BASE' afterwards.

'base' ( - a-addr  ) core
   'User' variable - a-addr is the address of a cell that stores the
number base used by default for number conversion during input and
output.  Don't store to 'base', use 'base-execute' instead.

'hex' ( -  ) core-ext
   Set 'base' to $10 (hexadecimal).  In many cases 'base-execute' is a
better alternative.

'decimal' ( -  ) core
   Set 'base' to #10 (decimal).  In many cases 'base-execute' is a
better alternative.

'dpl' ( - a-addr  ) gforth-0.2 "Decimal-PLace"
   'User' variable - a-addr is the address of a cell that stores the
position of the decimal point in the most recent numeric conversion.
Initialised to -1.  After the conversion of a number containing no
decimal point, 'dpl' is -1.  After the conversion of '2.' it holds 0.
After the conversion of 234123.9 it contains 1, and so forth.

Number conversion has a number of traps for the unwary:

   * You cannot determine the current number base using the code
     sequence 'base @ .' - the number base is always 10 in the current
     number base.  Instead, use something like 'base @ dec.'
   * There is a word 'bin' but it does not set the number base!  (*note
     General files::).
   * Standard Forth requires the '.' of a double-precision number to be
     the final character in the string.  Gforth allows the '.' to be
     anywhere.
   * The number conversion process does not check for overflow.

   You can read numbers into your programs with the words described in
*note Line input and conversion::.

6.17.3 Interpret/Compile states
-------------------------------

A standard program is not permitted to change 'state' explicitly.
However, it can change 'state' implicitly, using the words '[' and ']'.
When '[' is executed it switches 'state' to interpret state, and
therefore the text interpreter starts interpreting.  When ']' is
executed it switches 'state' to compile state and therefore the text
interpreter starts compiling.  The most common usage for these words is
for switching into interpret state and back from within a colon
definition; this technique can be used to compile a literal (for an
example, *note Literals::) or for conditional compilation (for an
example, *note Interpreter Directives::).

6.17.4 Interpreter Directives
-----------------------------

These words are usually used in interpret state; typically to control
which parts of a source file are processed by the text interpreter.
There are only a few Standard Forth words, but Gforth supplements these
with a rich set of immediate control structure words to compensate for
the fact that the non-immediate versions can only be used in compile
state (*note Control Structures::).  Typical usage:

     [undefined] \G [if]
       : \G source >in ! drop ; immediate
     [endif]

   So if the system does not define '\G', compile replacement code (with
reduced functionality).

'[IF]' ( flag -  ) tools-ext "bracket-if"
   If flag is 'TRUE' do nothing (and therefore execute subsequent words
as normal).  If flag is 'FALSE', parse and discard words from the parse
area (refilling it if necessary using 'REFILL') including nested
instances of '[IF]'..  '[ELSE]'..  '[THEN]' and '[IF]'..  '[THEN]' until
the balancing '[ELSE]' or '[THEN]' has been parsed and discarded.
Immediate word.

'[ELSE]' ( -  ) tools-ext "bracket-else"
   Parse and discard words from the parse area (refilling it if
necessary using 'REFILL') including nested instances of '[IF]'..
'[ELSE]'..  '[THEN]' and '[IF]'..  '[THEN]' until the balancing '[THEN]'
has been parsed and discarded.  '[ELSE]' only gets executed if the
balancing '[IF]' was 'TRUE'; if it was 'FALSE', '[IF]' would have parsed
and discarded the '[ELSE]', leaving the subsequent words to be executed
as normal.  Immediate word.

'[THEN]' ( -  ) tools-ext "bracket-then"
   Do nothing; used as a marker for other words to parse and discard up
to.  Immediate word.

'[ENDIF]' ( -  ) gforth-0.2 "bracket-end-if"
   Do nothing; synonym for '[THEN]'

'[defined]' ( "<spaces>name" - flag  ) tools-ext "bracket-defined"
   returns true if name is found in current search order.  Immediate
word.

'[undefined]' ( "<spaces>name" - flag  ) tools-ext "bracket-undefined"
   returns false if name is found in current search order.  Immediate
word.

'[IFDEF]' ( "<spaces>name" -  ) gforth-0.2 "bracket-if-def"
   If name is found in the current search-order, behave like '[IF]' with
a 'TRUE' flag, otherwise behave like '[IF]' with a 'FALSE' flag.
Immediate word.

'[IFUNDEF]' ( "<spaces>name" -  ) gforth-0.2 "bracket-if-un-def"
   If name is not found in the current search-order, behave like '[IF]'
with a 'TRUE' flag, otherwise behave like '[IF]' with a 'FALSE' flag.
Immediate word.

'[?DO]' ( n-limit n-index -  ) gforth-0.2 "bracket-question-do"

'[DO]' ( n-limit n-index -  ) gforth-0.2 "bracket-do"

'[LOOP]' ( -  ) gforth-0.2 "bracket-loop"

'[+LOOP]' ( n -  ) gforth-0.2 "bracket-question-plus-loop"

'[FOR]' ( n -  ) gforth-0.2 "bracket-for"

'[NEXT]' ( n -  ) gforth-0.2 "bracket-next"

'[I]' ( run-time - n  ) gforth-0.2 "bracket-i"
   At run-time, '[I]' pushes the loop index of the
text-interpretation-time '[do]' iteration.  If you want to process the
index at interpretation time, interpret '[I]' interpretevely, or use
'INT-[I]'.

'INT-[I]' ( - n  ) gforth-1.0 "int-bracket-i"
   Push the loop index of the '[do]' iteration at text interpretation
time.

'[BEGIN]' ( -  ) gforth-0.2 "bracket-begin"

'[UNTIL]' ( flag -  ) gforth-0.2 "bracket-until"

'[AGAIN]' ( -  ) gforth-0.2 "bracket-again"

'[WHILE]' ( flag -  ) gforth-0.2 "bracket-while"

'[REPEAT]' ( -  ) gforth-0.2 "bracket-repeat"

   You can use '#line' to change Gforth's idea about the current source
line number and source file.  This is useful in cases where the Forth
file is generated from some other source code file, and you want to get,
e.g.  error messages etc.  that refer to the original source code; then
the Forth-code generator needs to insert '#line' lines in the Forth code
wherever appropriate.

'#line' ( "u" "["file"]" -  ) gforth-1.0 "number-line"
   Set the line number to u and (if present) the file name to file.
Consumes the rest of the line.

6.17.5 Recognizers
------------------

The recognizer concepts factor the central part of the text interpreter:
The processing of one word after its name has been parsed.

   Unfortunately, there is no consensus on the exact words used for
dealing with recognizers yet, so the words and descriptions in this
section just reflect what is currently implemented in Gforth.  They can
and most likely will change in the future.  Therefore, the documentation
has also received less love than anything expected to be of permanent
use.

   Most programs just use the text interpreter as-is, and you can skip
this chapter completely in this case, but if you are curious, *note
Default Recognizers::.  The next level of recognizer usage is to change
which of the existing recognizers are used and in what order (*note
Recognizer order::).  You may also want to define a new recognizer using
an existing translator (*note Define recognizers with existing
translators::).  If no existing translator fits, you can define a new
translator (*note Defining translators::).  Finally, you may want to
process a word using a recognizer (sequence) and the resulting
translator (*note Performing translator actions::).

6.17.5.1 Default Recognizers
............................

Type '.recognizers' to find out with which recognizers are currently
being used by Gforth.  When invoked in a colon definition after defining
a local, the output of '.recognizers' is (at the time of this writing):

   'rec-nt ( rec-locals search-order ( Forth Forth Root ) ) rec-scope
rec-num rec-float rec-complex rec-string rec-to rec-dtick rec-tick
rec-body rec-env rec-meta'

   Here the notation name ( name1 ...  namen ) indicates that name is a
recognizer sequence that contains the recognizers name1 ...  namen.

   The recognizers in this sequence are:

'rec-nt'
     Recognizes locals and words in the search order.

'rec-locals'
     Recognizes locals.

'search-order'
     Recognizes words in the search order.  This is shown as recognizer
     sequence, because the wordlists (*note Word Lists::) themselves are
     also recognizers: They implement the recognizer interface (*note
     Define recognizers with existing translators::) in addition to
     working with 'find-name-in'.

'rec-scope'
     Recognizes 'voc1:voc2:..vocn:word', where voc1 is a vocabulary in
     the search order, voc2 is a vocabulary found in voc1, and so on,
     until word is found in vocn; the translator of this recognizer
     performs the semantics of word.  Example: 'environment:max-n'.

'rec-num'
     Single-cell integers ('#-15', '$-f'), characters (''A''), and
     double-cell integers '#-15.', with or without number prefixes
     (*note Integer and character literals::).

'rec-float'
     Floating-point numbers ('1e', *note Floating-point number and
     complex literals::)

'rec-complex'
     Complex numbers ('1e+2ei', *note Floating-point number and complex
     literals::)

'rec-string'
     Strings ('"abc"', *note String and environment variable
     literals::).

'rec-to'
     Recognizes '->v' (equivalent to 'to v'), '+>v' (equivalent to '+to
     v'), and ''>v' (equivalent to 'addr v'), where v is a
     value-flavoured word (*note Values::).  Also recognizes '@>d'
     (equivalent to 'action-of d'), and '=>d' (equivalent to 'is d'),
     where d is a defer-flavoured word (*note Deferred Words::).

'rec-dtick'
     Recognizes '``word' and produces the name token of word (*note
     Literals for tokens and addresses::).

'rec-tick'
     Recognizes '`word' and produces the execution token of word (*note
     Literals for tokens and addresses::).

'rec-body'
     Recognizes '<word>' for the body address of word and '<word+num'
     for an offset num from the body address of word (*note Literals for
     tokens and addresses::).

'rec-env'
     Recognizes '${env}' for the string contained at run-time in the
     environment variable env *note String and environment variable
     literals::).

'rec-meta'
     Recognizes 'rec?string', e.g., 'float?1.'.  'Rec-rec' is a
     recognizer found in the search order (e.g., 'rec-float', and this
     recognizer then tries to recognize string (e.g, '1.'), and the
     result becomes the result of 'rec-meta'.  This may be useful in
     cases where you want to use a specific recognizer, e.g., to deal
     with conflicts.

   The order of the recognizers is significant, because they are tried
from left to right, and the first recognizer that recognizes a word is
actually used.  E.g., if you define a local 'b', it will supersede
Gforth's predefined word 'b'.

   In most cases, however, recognizers are designed to avoid matching
the same strings as other recognizers.  E.g., 'rec-env' (the environment
variable recognizer) requires braces to avoid a conflict with the number
recognizer when recognizing environment variables like 'ADD'; i.e.,
'rec-env' recognizes '${ADD}', while 'rec-num' recognizes '$ADD'.

   There are a few cases where Gforth's recognizers can recognize the
same string, however:

   * Word names can be anything, so they can conflict with any other
     recognizer (and locals and the search order are searched before
     other recognizers).

     However, there are no conflicts of Gforth-defined words with
     decimal numbers prefixed with '#' or hex numbers prefixed with '$',
     so it is a good practice to use these prefixes (that's also a good
     idea to make sure that the right base is used).  An older practice
     (before number prefixes were introduced) was to prefix hex numbers
     with '0'.

     In the code bases we have looked at, starting words with ''' (quote
     aka tick) is much more common than starting them with '`'
     (backquote aka backtick), so the recognizers for the xt and the nt
     use '`' to reduce the number of conflicts.

   * Both the integer recognizer 'rec-num' and the floating-point
     recognizer 'rec-float' recognize, e.g., '1.'.  Because 'rec-num' is
     (by default) first, '1.' is recognized as a double-cell integer.
     If you change the recognizer order to use 'rec-float' first, '1.'
     is recognized as a floating-point number, but loading code written
     in Standard Forth may behave in a non-standard way.

     In any case, it's a good practice to avoid that conflict in your
     own code as follows: Always write double-cell integers with a
     number prefix, e.g., '#1.'; and always write floating-point numbers
     with an 'e', e.g., '1e'.

   * We have seen a few word names that start with '->'.  You can avoid
     a conflict by using 'to myvalue' or 'to?->myvalue' (the latter
     works with 'postpone').

   Note that most Forth systems do not support all the recognizers we
describe above, but 'rec-locals search-order rec-num rec-float' are
relatively common (even if a system uses a hard-coded text interpreter
instead of the flexible recognizer system).

   You can use 'locate' (*note Locating source code definitions::) to
determine which recognizer recognizes a piece of source code.  E.g.:

     locate float?1.

   will show that 'rec-meta' recognizes 'float?1.'.  However, if the
recognizer recognizes a dictionary word (e.g., the scope recognizer),
locate will show that word.

   Wordlists are also recognizers, as can be seen by the search order
being shown as recognizer sequence containing the wordlists, .  A
wordlist recognizes the words that it contains.  Just 'execute' the
wordlist-id, and it will behave as a recognizer:

     "dup" forth-wordlist execute

   produces the translator token of 'translate-nt' on the top-of-stack,
and the name token of 'dup' below that.

'.recognizers' ( -  ) gforth-experimental "dot-recognizers"
   Print the system recognizer order, with the first-searched recognizer
leftmost.

'rec-nt' ( addr u - nt translate-nt | 0  ) gforth-experimental
   recognize a name token

'rec-locals' ( addr u - nt translate-locals | 0  ) gforth-experimental
   search the locals wordlist and if found replace the translator with
'translate-locals'.

'rec-scope' ( addr u - nt rectype-nt | 0  ) gforth-experimental
   Recognizes strings of the form (simplified) 'wordlist:word', where
wordlist is found in the search order.  The result is the same as for
'rec-nt' for word (the ordinary word recognizer) if the search order
consists only of wordlist.  The general form can have several wordlists
preceding word, separated by ':'; the first (leftmost) wordlist is found
in the search order, the second in the first, etc.  word is the looked
up in the last (rightmost) wordlist.

'rec-num' ( addr u - n/d table | 0  ) gforth-experimental
   converts a number to a single/double integer

'rec-float' ( addr u - r translate-float | 0  ) gforth-experimental
   recognize floating point numbers

'rec-complex' ( addr u - z translate-complex | 0  ) gforth-1.0
   Complex numbers are always in the format a+bi, where a and b are
floating point numbers including their signs

'rec-string' ( addr u - addr u' scan-translate-string | 0  ) gforth-experimental
   Convert strings enclosed in double quotes into string literals,
escapes are treated as in 'S\"'.

'rec-to' ( addr u - n xt translate-to | 0  ) gforth-experimental
   words prefixed with '->' are treated as if preceeded by 'TO', with
'+>' as '+TO', with ''>' as 'ADDR', with '@>' as 'ACTION-OF', and with
'=>' as 'IS'.

'rec-dtick' ( addr u - nt translate-num | 0  ) gforth-experimental
   words prefixed with '``' return their nt.  Example: '``S"' gives the
nt of 'S"'.

'rec-tick' ( addr u - xt translate-num | 0  ) gforth-experimental
   words prefixed with '`' return their xt.  Example: '`dup' gives the
xt of dup.

'rec-body' ( addr u - xt translate-num | 0  ) gforth-experimental
   words bracketed with ''<'' ''>'' return their body.  Example: '<dup>'
gives the body of dup

'rec-env' ( addr u - addr u translate-env | 0  ) gforth-1.0
   words enclosed by '${' and '}' are passed to 'getenv' to get the
OS-environment variable as string.  Example: '${HOME}' gives the home
directory.

'rec-meta' ( addr u - xt translate-to | 0  ) gforth-1.0
   words prefixed with RECOGNIZER'?' are processed by 'rec-'RECOGNIZER
to disambiguate recognizers.  Example: 'hex num?cafe num?add' will be
parsed as number only Example: 'float?123.' will be parsed as float

6.17.5.2 Recognizer order
.........................

You may prefer to use a different recognizer sequence, but with (some of
the) existing recognizers.  You can use the following words for that:

'forth-recognize' ( c-addr u - ... translate-xt  ) recognizer
   The system recognizer: 'forth-recognize' is a 'defer'red word that
contains a recognizer (sequence).  The system's text interpreter calls
'forth-recognize'.

'recognizer-sequence:' ( xt1 .. xtn n "name" -  ) gforth-experimental "recognizer-sequence-colon"
   Define name, a recognizer sequence that first searches xtn and last
searches xt1.  name is a recognizer itself, which makes recognizer
sequences nestable.  The order of operands is inspired by 'get-order'
and 'set-order'.

   You probably don't want to create a new recognizer sequence every
time you want to change the system recognizer sequence.  There are two
ways to change an existing recognizer sequence:

   * Put one or more 'defer'red words in a recognizer sequence, and
     change the recognizer in this word later.  If you do not want such
     a deferred word to recognize anything for now, put 'rec-nothing' in
     it.

   * The body of a recognizer sequence is a 'stack' (*note User-defined
     Stacks::), and you can use the words for manipulating stacks on it.
     In particular, if you add a recognizer with '>stack', that
     recognizer will be tried first; if you add it with '>back', it will
     be tried last.

'rec-nothing' ( c-addr u - 0  ) gforth-experimental
   This recognizer recognizes nothing.  It can be useful as a
placeholder.

   Here is an example of adding 'rec-nothing' as last recognizer to the
system recognizers:

     ' rec-nothing action-of forth-recognize >body >back

6.17.5.3 Define recognizers with existing translators
.....................................................

A recognizer is a Forth word with the stack effect '( c-addr u -- ...
translator | 0 )'.  c-addr u describes the string to be recognized.  If
the recognizer does not recognize the string, it returns 0.  If it does
recognize the string, it returns a translator, and a translator-specific
amount of additional data ("...").  When performing a translator action,
the translator consumes this additional data.  E.g., when you perform

     "5" rec-num

   it pushes '5 translate-num' on the stack, and when the compilation
action of 'translate-num' is performed, both stack items are removed
from the stack.  This compilation action also compiles a literal 5 into
the current definition.

   You typically write a recognizer as ordinary colon definition that
examines the string in some way, and if the string is accepted by this
recognizer, the recognizer pushes a translator and (below that)
additional data.  E.g., a simple variant of 'rec-tick' can be
implemented as follows:

     : rec-tick ( addr u -- xt translate-num | 0 )
         over c@ '`' = if
             1 /string find-name dup if
                 name>interpret translate-num then
             exit then
         2drop 0 ;

   The only appropriate use of a translator (plus data) on the stack is
to pass it to one of the words for performing translator actions (*note
Performing translator actions::).

   A number of translators already exist in Gforth and can be used in a
recognizer you write.  If none of them is appropriate for your
recognizer, read the next section about defining your own translators.

   For each translator, _additional data_ is documented; a recognizer
that returns a certain translator also has to return the additional data
below it.

   The text interpreter passes the output of the recognizer to a
translator action (*note Performing translator actions::), which removes
the translator and all the additional data from the stack, may perform
additional parsing, and then invokes the interpreting run-time of the
translator, or the compiling run-time, or the postponing run-time.

   For each system-defined translator we specify the interpreting
run-time explicitly.  Unless otherwise specified the compiling run-time
compiles the interpreting run-time.  The postponing run-time compiles
the compiling run-time.

   In the 'rec-tick' example above, if the recognizer recognizes, say,
'`dup', it returns xt translator, where translator is the value returned
by 'translate-num', and xt is the execution token of 'dup'.  So xt is
the additional data for this translator.  If the text interpreter then
performs the compiling action, that action first removes these two stack
items, and compiles code that pushes xt.

'translate-nt' ( - translator  ) gforth-experimental
   Additional data: '( nt )'.
Interpreting run-time: '( ... -- ... )'
Perform the interpretation semantics of nt.
Compiling run-time: '( ... -- ... )'
Perform the compilation semantics of nt.

'translate-num' ( - translator  ) gforth-experimental
   Additional data: '( x )'.
Interpreting run-time: '( -- x )'

'translate-dnum' ( - translator  ) gforth-experimental
   Additional data: '( xd )'.
Interpreting run-time: '( -- dx )'

'translate-float' ( - translator  ) gforth-experimental
   Additional data: '( r )'.
Interpreting run-time: '( -- r )'

'translate-complex' ( - translator  ) gforth-experimental
   Additional data: '( r1 r2 )'.
Interpreting run-time: '( -- r1 r2 )'

'translate-string' ( - translator  ) gforth-experimental
   Additional data: '( c-addr1 u1 )'.
Interpreting run-time: '( -- c-addr2 u2 )'
c-addr2 u2 is the result of translating the '\'-escapes in c-addr1 u1.

'scan-translate-string' (  - translator  ) gforth-experimental
   Additional data: '( c-addr1 u1 'ccc"' )'.
Every translator action also parses until the first non-escaped '"'.
The string c-addr u and the parsed input are concatenated, then the
'\'-escapes are translated, giving c-addr2 u2.
Interpreting run-time: '( -- c-addr2 u2 )'

'translate-env' ( - translator  ) gforth-experimental
   Additional data: '( c-addr1 u1 )'.
Interpreting run-time: '( -- c-addr2 u2 )'
c-addr2 u2 is the content of the environment variable with name c-addr1
u1.

'translate-to' ( - translator  ) gforth-experimental
   Additional data: '( n xt )'.
xt belongs to a value-flavoured (or defer-flavoured) word, n is the
index into the 'to-table:' for xt (*note Words with user-defined TO
etc.::).
Interpreting run-time: '( ... -- ... )'
Perform the to-action with index n in the 'to-table:' of xt.  Additional
stack effects depend on n and xt.

   One way to write a recognizer is to call 'forth-recognize' on a
substring, and then look at the result to see if something was
recognized that the whole-string recognizer actually deals with.  E.g.,
'rec-tick' and 'rec-dtick' do this and then check whether
'forth-recognize' has pushed nt 'translate-nt'; the benefit of this
approach is that, e.g.  '`environment:max-n' works, where 'rec-scope'
recognizes 'environment:max-n'.  The specific check for an nt used in
'rec-tick' and 'rec-dtick' is 'forth-recognize-nt?'; it is implemented
on top of the more general 'try-recognize'.

'try-recognize' ( c-addr u xt - ... translator | 0  ) gforth-experimental
   Try to recognize C-ADDR U with 'forth-recognize', then execute XT '(
... translator -- ... true | false )'.  If XT returns 0, reset the
stacks to the depths at the start of 'try-recognize', drop three data
stack items, and push 0.  Otherwise return the results of executing XT.

'forth-recognize-nt?' ( c-addr u - nt | 0  ) gforth-experimental "forth-recognize-nt-question"
   If 'forth-recognize' produces a result nt 'translate-nt', return nt,
otherwise 0.

6.17.5.4 Defining translators
.............................

A translator is a table of three actions: interpretation, compilation,
and postponing.  You should design the translator and its actions like
the system-defined translators, with additional data, maybe some
parsing, and at least an interpreting run-time (and in the normal case
let the compiling run-time and postponing run-time follow from that,
*note Define recognizers with existing translators::).  You then have to
define the action words to implement the sequence: consume the
additional data, possibly scan, then perform the run-time appropriate
for the action.

   You define a translator with

'translate:' ( int-xt comp-xt post-xt "name" -  ) gforth-experimental "translate-colon"

   To make this a little more concrete, here is an implementation for
'translate-num':

     ' noop                       ( x -- x )                             \ int-xt
     ' lit,                       ( compilation: x -- ; run-time: -- x ) \ comp-xt
     :noname lit, postpone lit, ; ( postponing: x -- ;  run-time: -- x ) \ post-xt
     translate: translate-num

   If a recognizer for a single-cell literal (e.g., 'rec-tick') matches
the input string, it pushes the value x of the literal (the xt of the
ticked word in case of 'rec-tick') on the data stack and the xt of
'translate-num'.  When the interpretation semantics is needed, int-xt is
'execute'd, and x stays on the stack.  For the compilation semantics, x
is compiled into the current definition as literal.

   For postponing, more time levels are involved: at text-interpretation
time (when the recognizer runs and the translator action is performed)
the current definition is d1.  When d1 runs, the current definition is
d2(1).  The post-xt of the 'translate-num' implementation above first
compiles x into d1 and also compiles 'lit,' into d1 (that's the
'postpone lit,' part).  When d1 runs, it pushes x and then the 'lit,'
compiles x into d2.

   Many literal translators follow this scheme.

   A translator that is quite different is 'translate-nt'.  Here's an
implementation:

     : name-intsem ( ... nt -- ... )
       name>interpret execute-exit ;
     : name-compsem ( ... nt -- ... )
       name>compile execute-exit ;
     : name-compcompsem ( nt -- )
       lit, postpone name-compsem ;
     ' name-intsem ' name-compsem ' name-compcompsem translate: translate-nt

   'Name-intsem' performs the interpretation semantics of nt, by getting
the xt of the interpretation semantics and executing it.  Here
'execute-exit' is used, in order for return-stack words to work (that's
a Gforth 1.0 feature).  Also, in Gforth 1.0 all words have
interpretation semantics, so the result of 'name-interpret' is not
tested for 0.

   'Name-compsem' performs the compilation semantics of nt.

   'Name-compcompsem' compiles the compilation semantics of nt.  This is
achieved by compiling nt and 'name-compsem' into the current definition
d1.  When d1 runs, the result performs the compilation semantics of nt
at that time.

   ---------- Footnotes ----------

   (1) If there is no current definition when something is compiled,
Gforth outputs a warning.

6.17.5.5 Performing translator actions
......................................

There are the following words for performing the various translator
actions:

'interpreting' ( ... translator - ...  ) gforth-experimental
   Perform the interpreting action of translator.  For a system-defined
translator, first consume the translator and translator-specific
additional stack items and possibly perform additional scanning
specified for the translator, then perform the 'interpreting' run-time
specified for the translator.  For a user-defined translator, remove
translator from the stack and execute its int-xt.

'compiling' ( ... translator - ...  ) gforth-experimental
   Perform the compiling action of translator.  For a system-defined
translator, first consume the translator and translator-specific
additional stack items and possibly perform additional scanning
specified for the translator, then perform the 'compiling' run-time
specified for the translator, or, if none is specified, compile the
'interpreting' run-time.  For a user-defined translator, remove
translator from the stack and execute its comp-xt.

'postponing' ( ... translator -  ) gforth-experimental
   Perform the postponing action of translator.  For a system-defined
translator, first consume the translator and translator-specific
additional stack items and possibly perform additional scanning
specified for the translator, then compile the 'compiling' run-time.
For a user-defined translator, remove translator from the stack and
execute its post-xt.

'?found' ( token|0 - token  ) gforth-experimental "question-found"
   'throw's -13 (undefined word) if TOKEN is 0.

   Their typical use is in a text interpreter.  A simple text
interpreter could look like this:

     : myinterpret ( -- )
       \ refill happens outside
       begin
         parse-name dup while
           forth-recognize ?found state @ if compiling else interpreting then
       repeat
       2drop ;

   This text interpreter itself does not deal with postponing; ']]' can
be implemented as a text interpreter that performs the postponing:

     : ]] ( -- )
       \ works only within a line
       begin
         parse-name dup 0= abort" [[ missing"
         2dup "[[" str= 0= while
           forth-recognize ?found postponing
        repeat
        2drop ; immediate

6.17.6 Text Interpreter Hooks
-----------------------------

'before-line' ( -  ) gforth-1.0
   Deferred word called before the text interpreter parses the next line

'before-word' ( -  ) gforth-0.7
   Deferred word called before the text interpreter parses the next word

'line-end-hook' ( -  ) gforth-0.7
   called at every end-of-line when text-interpreting from a file

6.18 The Input Stream
=====================

The text interpreter reads from the input stream, which can come from
several sources (*note Input Sources::).  Some words, in particular
defining words, but also words like ''', read parameters from the input
stream instead of from the stack.

   Such words are called parsing words, because they parse the input
stream.  Parsing words are hard to use in other words, because it is
hard to pass program-generated parameters through the input stream.
They also usually have an unintuitive combination of interpretation and
compilation semantics when implemented naively, leading to various
approaches that try to produce a more intuitive behaviour (*note
Combined words::).

   It should be obvious by now that parsing words are a bad idea.  If
you want to implement a parsing word for convenience, also provide a
factor of the word that does not parse, but takes the parameters on the
stack.  To implement the parsing word on top if it, you can use the
following words:

'parse' ( xchar "ccc<xchar>" - c-addr u  ) core-ext,xchar-ext
   Parse ccc, delimited by xchar, in the parse area.  c-addr u specifies
the parsed string within the parse area.  If the parse area was empty, u
is 0.

'string-parse' ( c-addr1 u1 "ccc<string>" - c-addr2 u2  ) gforth-1.0
   Parse ccc, delimited by the string c-addr1 u1, in the parse area.
c-addr2 u2 specifies the parsed string within the parse area.  If the
parse area was empty, u2 is 0.

'parse-name' ( "name" - c-addr u  ) core-ext
   Get the next word from the input buffer

'parse-word' ( - c-addr u  ) gforth-obsolete
   old name for 'parse-name'; this word has a conflicting behaviour in
some other systems.

'name' ( - c-addr u  ) gforth-obsolete
   old name for 'parse-name'

'word' ( char "<chars>ccc<char>- c-addr  ) core
   We recommend to use 'parse-name' instead of 'word'.  Skip leading
delimiters.  Parse ccc, delimited by char, in the parse area.  c-addr is
the address of a transient region containing the parsed string in
counted-string format.  If the parse area was empty or contained no
characters other than delimiters, the resulting string has zero length.
A program may replace characters within the counted string.
OBSOLESCENT: the counted string has a trailing space that is not
included in its length.

'refill' ( - flag  ) core-ext,block-ext,file-ext
   Attempt to fill the input buffer from the input source.  When the
input source is the user input device, attempt to receive input into the
terminal input device.  If successful, make the result the input buffer,
set '>IN' to 0 and return true; otherwise return false.  When the input
source is a block, add 1 to the value of 'BLK' to make the next block
the input source and current input buffer, and set '>IN' to 0; return
true if the new value of 'BLK' is a valid block number, false otherwise.
When the input source is a text file, attempt to read the next line from
the file.  If successful, make the result the current input buffer, set
'>IN' to 0 and return true; otherwise, return false.  A successful
result includes receipt of a line containing 0 characters.

   If you have to deal with a parsing word that does not have a
non-parsing factor, you can use 'execute-parsing' to pass a string to
it:

'execute-parsing' ( ... addr u xt - ...  ) gforth-0.6
   Make addr u the current input source, execute xt '( ... -- ... )',
then restore the previous input source.

   Example:

     5 s" foo" ' constant execute-parsing
     \ equivalent to
     5 constant foo

   A definition of this word in Standard Forth is provided in
'compat/execute-parsing.fs'.

   If you want to run a parsing word on a file, the following word
should help:

'execute-parsing-file' ( i*x fileid xt - j*x  ) gforth-0.6
   Make fileid the current input source, execute xt '( i*x -- j*x )',
then restore the previous input source.

6.19 Word Lists
===============

A wordlist is a list of named words; you can add new words and look up
words by name (and you can remove words in a restricted way with
markers).  Every named (and 'reveal'ed) word is in one wordlist.

   The text interpreter searches the wordlists present in the search
order (a stack of wordlists), from the top to the bottom.  Within each
wordlist, the search starts conceptually at the newest word; i.e., if
two words in a wordlist have the same name, the newer word is found.

   New words are added to the "compilation wordlist" (aka current
wordlist).

   A word list is identified by a cell-sized word list identifier (wid)
in much the same way as a file is identified by a file handle.  The
numerical value of the wid has no (portable) meaning, and might change
from session to session.

   The Standard Forth "Search order" word set is intended to provide a
set of low-level tools that allow various different schemes to be
implemented.  Gforth also provides 'vocabulary', a traditional Forth
word.  'compat/vocabulary.fs' provides an implementation in Standard
Forth.

'forth-wordlist' ( - wid  ) search
   'Constant' - wid identifies the word list that includes all of the
standard words provided by Gforth.  When Gforth is invoked, this word
list is the compilation word list and is at the top of the search order.

'definitions' ( -  ) search
   Set the compilation word list to be the same as the word list that is
currently at the top of the search order.

'get-current' ( - wid  ) search
   wid is the identifier of the current compilation word list.

'set-current' ( wid -  ) search
   Set the compilation word list to the word list identified by wid.

'in-wordlist' ( wordlist "defining-word" -  ) gforth-experimental
   execute DEFINING-WORD with WORDLIST as one-shot current directory.
Example: 'gui-wordlist in-wordlist : init-gl ... ;' will define
'init-gl' in the 'gui-wordlist' wordlist.

'in' ( "voc" "defining-word" -  ) gforth-experimental
   execute DEFINING-WORD with VOC as one-shot current directory.
Example: 'in gui : init-gl ... ;' will define 'init-gl' in the 'gui'
vocabulary.

'get-order' ( - widn .. wid1 n  ) search
   Copy the search order to the data stack.  The current search order
has n entries, of which wid1 represents the wordlist that is searched
first (the word list at the top of the search order) and widn represents
the wordlist that is searched last.

'set-order' ( widn .. wid1 n -  ) search
   If N=0, empty the search order.  If N=-1, set the search order to the
implementation-defined minimum search order (for Gforth, this is the
word list 'Root').  Otherwise, replace the existing search order with
the N wid entries such that WID1 represents the word list that will be
searched first and WIDN represents the word list that will be searched
last.

'wordlist' ( - wid  ) search
   Create a new, empty word list represented by wid.

'table' ( - wid  ) gforth-0.2
   Create a lookup table (case-sensitive, no warnings).

'cs-wordlist' ( - wid  ) gforth-1.0
   Create a case-sensitive wordlist.

'cs-vocabulary' ( "name" -  ) gforth-1.0
   Create a case-sensitive vocabulary

'>order' ( wid -  ) gforth-0.5 "to-order"
   Push WID on the search order.

'previous' ( -  ) search-ext
   Drop the wordlist at the top of the search order.

'also' ( -  ) search-ext
   Like 'DUP' for the search order.  Usually used before a vocabulary
(e.g., 'also Forth'); the combined effect is to push the wordlist
represented by the vocabulary on the search order.

'Forth' ( -  ) search-ext
   Replace the wid at the top of the search order with the wid
associated with the word list 'forth-wordlist'.

'Only' ( -  ) search-ext
   Set the search order to the implementation-defined minimum search
order (for Gforth, this is the word list 'Root').

'order' ( -  ) search-ext
   Print the search order and the compilation word list.  The word lists
are printed in the order in which they are searched (which is reversed
with respect to the conventional way of displaying stacks).  The
compilation word list is displayed last.

'.voc' ( wid -  ) gforth-0.2 "dot-voc"
   print the name of the wordlist represented by WID.  Can only print
names defined with 'vocabulary' or 'wordlist constant', otherwise prints
'address'.

'find' ( c-addr - xt +-1 | c-addr 0  ) core,search
   We recommend to use 'find-name' instead of 'find'.  Search all word
lists in the current search order for the definition named by the
counted string at c-addr.  If the definition is not found, return 0.  If
the definition is found return 1 (if the definition has non-default
compilation semantics) or -1 (if the definition has default compilation
semantics).  The xt returned in interpret state represents the
interpretation semantics.  The xt returned in compile state represented
either the compilation semantics (for non-default compilation semantics)
or the run-time semantics that the compilation semantics would
'compile,' (for default compilation semantics).  The Forth-2012 standard
does not specify clearly what the returned xt represents (and also talks
about immediacy instead of non-default compilation semantics), so this
word is questionable in portable programs.  If non-portability is ok,
'find-name' and friends are better (*note Name token::).

'search-wordlist' ( c-addr count wid - 0 | xt +-1  ) search
   Search the word list identified by wid for the definition named by
the string at c-addr count.  If the definition is not found, return 0.
If the definition is found return 1 (if the definition is immediate) or
-1 (if the definition is not immediate) together with the xt.  In
Gforth, the xt returned represents the interpretation semantics.
Forth-2012 does not specify clearly what xt represents.

'words' ( -  ) tools
   Display a list of all of the definitions in the word list at the top
of the search order.

'vlist' ( -  ) gforth-0.2
   Old (pre-Forth-83) name for 'WORDS'.

'wordlist-words' ( wid -  ) gforth-0.6
   Display the contents of the wordlist wid.

'mwords' ( ["pattern"] -  ) gforth-1.0
   list all words matching the optional parameter PATTERN; if none, all
words match.  Words are listed old to new.  Pattern match like 'search'
(default), you can switch to globbing with '' mword-filename-match is
mword-match'.

'Root' ( -  ) gforth-0.2
   Add the root wordlist to the search order stack.  This vocabulary
makes up the minimum search order and contains only a search-order
words.

'Vocabulary' ( "name" -  ) gforth-0.2
   Create a definition "name" and associate a new word list with it.
The run-time effect of "name" is to replace the wid at the top of the
search order with the wid associated with the new word list.

'seal' ( -  ) gforth-0.2
   Remove all word lists from the search order stack other than the word
list that is currently on the top of the search order stack.

'vocs' ( -  ) gforth-0.2
   List vocabularies and wordlists defined in the system.

'current' ( - addr  ) gforth-0.2
   'Variable' - holds the wid of the compilation word list.

'context' ( - addr  ) gforth-0.2
   'context' '@' is the wid of the word list at the top of the search
order.

'map-vocs' ( ... xt - ...  ) gforth-1.0
   Perform xt ( ...  wid - ...  )  for all wordlists (including tables
and cs-wordlists) in the system.

6.19.1 Vocabularies
-------------------

Here is an example of creating and using a new wordlist using Standard
Forth words:

     wordlist constant my-new-words-wordlist
     : my-new-words get-order nip my-new-words-wordlist swap set-order ;

     \ add it to the search order
     also my-new-words

     \ alternatively, add it to the search order and make it
     \ the compilation word list
     also my-new-words definitions
     \ type "order" to see the problem

   The problem with this example is that 'order' has no way to associate
the name 'my-new-words' with the wid of the word list (in Gforth,
'order' and 'vocs' will display '???' for a wid that has no associated
name).  There is no Standard way of associating a name with a wid.

   In Gforth, this example can be re-coded using 'vocabulary', which
associates a name with a wid:

     vocabulary my-new-words

     \ add it to the search order
     also my-new-words

     \ alternatively, add it to the search order and make it
     \ the compilation word list
     my-new-words definitions
     \ type "order" to see that the problem is solved

6.19.2 Why use word lists?
--------------------------

Here are some reasons why people use wordlists:

   * To prevent a set of words from being used outside the context in
     which they are valid.  Two classic examples of this are an
     integrated editor (all of the edit commands are defined in a
     separate word list; the search order is set to the editor word list
     when the editor is invoked; the old search order is restored when
     the editor is terminated) and an integrated assembler (the op-codes
     for the machine are defined in a separate word list which is used
     when a 'CODE' word is defined).

   * To organize the words of an application or library into a
     user-visible set (in 'forth-wordlist' or some other common
     wordlist) and a set of helper words used just for the
     implementation (hidden in a separate wordlist).  This keeps
     'words'' output smaller, separates implementation and interface,
     and reduces the chance of name conflicts within the common
     wordlist.

   * To prevent a name-space clash between multiple definitions with the
     same name.  For example, when building a cross-compiler you might
     have a word 'IF' that generates conditional code for your target
     system.  By placing this definition in a different word list you
     can control whether the host system's 'IF' or the target system's
     'IF' get used in any particular context by controlling the order of
     the word lists on the search order stack.

   The downsides of using wordlists are:

   * Debugging becomes more cumbersome.

   * Name conflicts worked around with wordlists are still there, and
     you have to arrange the search order carefully to get the desired
     results; if you forget to do that, you get hard-to-find errors (as
     in any case where you read the code differently from the compiler;
     'see' can help seeing which of several possible words the name
     resolves to in such cases).  'See' displays just the name of the
     words, not what wordlist they belong to, so it might be misleading.
     Using unique names is a better approach to avoid name conflicts.

   * You have to explicitly undo any changes to the search order.  In
     many cases it would be more convenient if this happened implicitly.
     Gforth currently does not provide such a feature, but it may do so
     in the future.

6.19.3 Word list example
------------------------

The following example is from the garbage collector
(https://www.complang.tuwien.ac.at/forth/garbage-collection.zip) and
uses wordlists to separate public words from helper words:

     get-current ( wid )
     vocabulary garbage-collector also garbage-collector definitions
     ... \ define helper words
     ( wid ) set-current \ restore original (i.e., public) compilation wordlist
     ... \ define the public (i.e., API) words
         \ they can refer to the helper words
     previous \ restore original search order (helper words become invisible)

6.20 Environmental Queries
==========================

Forth-94 introduced the idea of "environmental queries" as a way for a
program running on a system to determine certain characteristics of the
system.  The Standard specifies a number of strings that might be
recognised by a system, and a way of querying them:

'environment?' ( c-addr u - false / ... true  ) core "environment-query"
   c-addr, u specify a counted string.  If the string is not recognised,
return a 'false' flag.  Otherwise return a 'true' flag and some
(string-specific) information about the queried string.

   Note that, whilst the documentation for (e.g.)  'ADDRESS-UNIT-BITS'
shows it returning one cell on the stack, querying it using
'environment?' will return an additional item; the 'true' flag that
shows that the string was recognised; so for querying
'ADDRESS-UNIT-BITS' the stack effect of 'environment?' is '( c-addr u --
n true )'.

   Several environmental queries deal with the system's limits:

'ADDRESS-UNIT-BITS' ( - n  ) environment
   Size of one address unit, in bits.

'MAX-CHAR' ( - u  ) environment
   Maximum value of any character in the character set

'/COUNTED-STRING' ( - n  ) environment "slash-counted-string"
   Maximum size of a counted string, in characters.

'/HOLD' ( - n  ) environment "slash-hold"
   Size of the pictured numeric string output buffer, in characters.

'/PAD' ( - n  ) environment "slash-pad"
   Size of the scratch area pointed to by 'PAD', in characters.

'CORE' ( - f  ) environment
   True if the complete core word set is present.  Always true for
Gforth.

'CORE-EXT' ( - f  ) environment
   True if the complete core extension word set is present.  Always true
for Gforth.

'FLOORED' ( - f  ) environment
   True if '/' etc.  perform floored division

'MAX-N' ( - n  ) environment
   Largest usable signed integer.

'MAX-U' ( - u  ) environment
   Largest usable unsigned integer.

'MAX-D' ( - d  ) environment
   Largest usable signed double.

'MAX-UD' ( - ud  ) environment
   Largest usable unsigned double.

'return-stack-cells' ( - n  ) environment
   Maximum size of the return stack, in cells.

'stack-cells' ( - n  ) environment
   Maximum size of the data stack, in cells.

'floating-stack' ( - n  ) environment
   N is non-zero, showing that Gforth maintains a separate
floating-point stack of depth N.

'#locals' ( - n  ) environment "number-locals"
   The maximum number of locals in a definition

'wordlists' ( - n  ) environment
   the maximum number of wordlists usable in the search order

'max-float' ( - r  ) environment
   The largest usable floating-point number (implemented as largest
finite number in Gforth)

'XCHAR-ENCODING' ( - addr u  ) environment
   Returns a printable ASCII string that reperesents the encoding, and
use the preferred MIME name (if any) or the name in
<http://www.iana.org/assignments/character-sets> like "ISO-LATIN-1" or
"UTF-8", with the exception of "ASCII", where we prefer the alias
"ASCII".

'MAX-XCHAR' ( - xchar  ) environment
   Maximal value for xchar.  This depends on the encoding.

'XCHAR-MAXMEM' ( - u  ) environment
   Maximal memory consumed by an xchar in address units

   Several environmental queries are there for determining the presence
of the Forth-94 version of a wordset; they all have the stack effect '(
-- f )' if the string is present (so the 'environment?' stack effect for
these queries is '( c-addr u -- false / f true )'.

   'block block-ext double double-ext exception exception-ext facility
facility-ext file file-ext floating floating-ext locals locals-ext
memory-alloc memory-alloc-ext tools tools-ext search-order
search-order-ext string string-ext'

   These wordset queries were rarely used and implemented, so Forth-2012
did not introduce a way to query for the Forth-2012 variants of the
wordsets.  Instead, the idea is that you use '[defined]' (*note
Interpreter Directives::) instead.

   Forth-200x (a group that works on the next standard; the documents
that they produce are also called Forth-200x) defines extension queries
for the extension proposals once they finish changing (CfV stage), so
programs using these proposals can check whether a system has them, and
maybe load the reference implementation (if one exists).  If
'environment?' finds such a query, then the corresponding proposal on
<www.forth200x.org> is implemented on the system (but the absence tells
you nothing, as usual with 'environment?').  These queries have the
stack effect '( -- )', which means that for them 'environment?' has the
stack effect '( c-addr u -- false / true )', which is more convenient
than that of wordset queries.  A number of these proposals have been
incorporated into Forth-2012.  The extension queries are also not
particularly popular among Forth system implementors, so going for
'[defined]' may be the better approach.  Anyway, Gforth implements the
following extension queries:

   'X:2value X:buffer X:deferred X:defined X:ekeys X:escaped-strings
X:extension-query X:fp-stack X:ftrunc X:fvalue X:locals X:n-to-r
X:number-prefixes X:parse-name X:required X:s-escape-quote X:s-to-f
X:structures X:synonym X:text-substitution X:throw-iors
X:traverse-wordlist X:xchar'

   In addition, Gforth implements the following Gforth-specific queries:

'gforth' ( - c-addr u  ) gforth-environment
   Counted string representing a version string for this version of
Gforth (for versions>0.3.0).  The version strings of the various
versions are guaranteed to be ordered lexicographically.

'os-class' ( - c-addr u  ) gforth-environment
   Counted string representing a description of the host operating
system.

'os-type' ( - c-addr u  ) gforth-environment
   Counted string equal to "$host_os"

   The Standard requires that the header space used for environmental
queries be distinct from the header space used for definitions.

   Typically, a Forth system supports environmental queries by creating
a set of definitions in a wordlist that is only used for environmental
queries; that is what Gforth does.  There is no Standard way of adding
definitions to the set of recognised environmental queries, but in
Gforth and other systems that use the wordlist mechanism, the wordlist
used to honour environmental queries can be manipulated just like any
other word list.

'environment-wordlist' ( - wid  ) gforth-0.2
   wid identifies the word list that is searched by environmental
queries (present in SwiftForth and VFX).

'environment' ( -  ) gforth-0.6
   A vocabulary for 'environment-wordlist' (present in Win32Forth and
VFX).

   Here are some examples of using environmental queries:

     s" address-unit-bits" environment? 0=
     [IF]
          cr .( environmental attribute address-units-bits unknown... ) cr
     [ELSE]
          drop \ ensure balanced stack effect
     [THEN]

     \ this might occur in the prelude of a standard program that uses THROW
     s" exception" environment? [IF]
        0= [IF]
           : throw abort" exception thrown" ;
        [THEN]
     [ELSE] \ we don't know, so make sure
        : throw abort" exception thrown" ;
     [THEN]

     s" gforth" environment? [IF] .( Gforth version ) TYPE
                             [ELSE] .( Not Gforth..) [THEN]

     \ a program using v*
     s" gforth" environment? [IF]
       s" 0.5.0" compare 0< [IF] \ v* is a primitive since 0.5.0
        : v* ( f_addr1 nstride1 f_addr2 nstride2 ucount -- r )
          >r swap 2swap swap 0e r> 0 ?DO
            dup f@ over + 2swap dup f@ f* f+ over + 2swap
          LOOP
          2drop 2drop ;
       [THEN]
     [ELSE] \
       : v* ( f_addr1 nstride1 f_addr2 nstride2 ucount -- r )
       ...
     [THEN]

   Here is an example of adding a definition to the environment word
list:

     get-current environment-wordlist set-current
     true constant block
     true constant block-ext
     set-current

   You can see what definitions are in the environment word list like
this:

     environment-wordlist wordlist-words

6.21 Files
==========

Gforth provides facilities for accessing files that are stored in the
host operating system's file-system.  Files that are processed by Gforth
can be divided into two categories:

   * Files that are processed by the Text Interpreter ("Forth source
     files").
   * Files that are processed by some other program ("general files").

6.21.1 Forth source files
-------------------------

The simplest way to interpret the contents of a file is to use one of
these two formats:

     include mysource.fs
     s" mysource.fs" included

   You usually want to include a file only if it is not included already
(by, say, another source file).  In that case, you can use one of these
three formats:

     require mysource.fs
     needs mysource.fs
     s" mysource.fs" required

   It is good practice to write your source files such that interpreting
them does not change the stack.  Source files designed in this way can
be used with 'required' and friends without complications.  For example:

     1024 require foo.fs drop

   Here you want to pass the argument 1024 (e.g., a buffer size) to
'foo.fs'.  Interpreting 'foo.fs' has the stack effect ( n - n ), which
allows its use with 'require'.  Of course with such parameters to
required files, you have to ensure that the first 'require' fits for all
uses (i.e., 'require' it early in the master load file).

'include-file' ( i*x wfileid - j*x  ) file
   Interpret (process using the text interpreter) the contents of the
file WFILEID.

'included' ( i*x c-addr u - j*x  ) file
   'include-file' the file whose name is given by the string C-ADDR U.

'included?' ( c-addr u - f  ) gforth-0.2 "included-question"
   True only if the file C-ADDR U is in the list of earlier included
files.  If the file has been loaded, it may have been specified as, say,
'foo.fs' and found somewhere on the Forth search path.  To return 'true'
from 'included?', you must specify the exact path to the file, even if
that is './foo.fs'

'include' ( ... "file" - ...  ) file-ext
   'include-file' the file FILE.

'required' ( i*x addr u - i*x  ) file-ext
   'include-file' the file with the name given by ADDR U, if it is not
'included' (or 'required') already.  Currently this works by comparing
the name of the file (with path) against the names of earlier included
files.

'require' ( ... "file" - ...  ) file-ext
   'include-file' FILE only if it is not included already.

'needs' ( ... "name" - ...  ) gforth-0.2
   An alias for 'require'; exists on other systems (e.g., Win32Forth).

'\\\' ( -  ) gforth-1.0 "triple-backslash"
   skip remaining source file

'.included' ( -  ) gforth-0.5 "dot-included"
   List the names of the files that have been 'included'.

'sourcefilename' ( - c-addr u  ) gforth-0.2
   The name of the source file which is currently the input source.  The
result is valid only while the file is being loaded.  If the current
input source is no (stream) file, the result is undefined.  In Gforth,
the result is valid during the whole session (but not across
'savesystem' etc.).

'sourceline#' ( - u  ) gforth-0.2 "sourceline-number"
   The line number of the line that is currently being interpreted from
a (stream) file.  The first line has the number 1.  If the current input
source is not a (stream) file, the result is undefined.

   A definition in Standard Forth for 'required' is provided in
'compat/required.fs'.

6.21.2 General files
--------------------

Files are opened/created by name and type.  The following file access
methods (FAMs) are recognised:

'r/o' ( - fam  ) file "r-o"

'r/w' ( - fam  ) file "r-w"

'w/o' ( - fam  ) file "w-o"

'bin' ( fam1 - fam2  ) file

'+fmode' ( fam1 rwxrwxrwx - fam2  ) gforth-1.0 "plus-f-mode"
   add file access mode to fam - for create-file only

   When a file is opened/created, it returns a file identifier, wfileid
that is used for all other file commands.  All file commands also return
a status value, wior, that is 0 for a successful operation and an
implementation-defined non-zero value in the case of an error.

'open-file' ( c-addr u wfam - wfileid wior ) file "open-file"

'create-file' ( c-addr u wfam - wfileid wior ) file "create-file"

'close-file' ( wfileid - wior ) file "close-file"

'delete-file' ( c-addr u - wior ) file "delete-file"

'rename-file' ( c-addr1 u1 c-addr2 u2 - wior ) file-ext "rename-file"
   Rename file c_addr1 u1 to new name c_addr2 u2

'read-file' ( c-addr u1 wfileid - u2 wior ) file "read-file"
   Read u1 characters from file wfileid into the buffer at c_addr.  A
non-zero wior indicates an error.  U2 indicates the length of the read
data.  End-of-file is not an error and is indicated by u2$<$u1 and
wior=0.

'read-line' ( c_addr u1 wfileid - u2 flag wior  ) file
   Reads a line from wfileid into the buffer at c_addr u1.  Gforth
supports all three common line terminators: LF, CR and CRLF. A non-zero
wior indicates an error.  A false flag indicates that 'read-line' has
been invoked at the end of the file.  u2 indicates the line length
(without terminator): u2$<$u1 indicates that the line is u2 chars long;
u2=u1 indicates that the line is at least u1 chars long, the u1 chars of
the buffer have been filled with chars from the line, and the next slice
of the line with be read with the next 'read-line'.  If the line is u1
chars long, the first 'read-line' returns u2=u1 and the next read-line
returns u2=0.

'key-file' ( fd - key  ) gforth-0.4
   Read one character n from wfileid.  This word disables buffering for
wfileid.  If you want to read characters from a terminal in
non-canonical (raw) mode, you have to put the terminal in non-canonical
mode yourself (using the C interface); the exception is 'stdin': Gforth
automatically puts it into non-canonical mode.

'key?-file' ( wfileid - f ) gforth-0.4 "key-q-file"
   f is true if at least one character can be read from wfileid without
blocking.  If you also want to use 'read-file' or 'read-line' on the
file, you have to call 'key?-file' or 'key-file' first (these two words
disable buffering).

'file-eof?' ( wfileid - flag ) gforth-0.6 "file-eof-query"
   FLAG is true if the end-of-file indicator for WFILEID is set.

'write-file' ( c-addr u1 wfileid - wior ) file "write-file"

'write-line' ( c-addr u wfileid - ior  ) file

'emit-file' ( c wfileid - wior ) gforth-0.2 "emit-file"

'flush-file' ( wfileid - wior ) file-ext "flush-file"

'file-status' ( c-addr u - wfam wior ) file-ext "file-status"

'file-position' ( wfileid - ud wior ) file "file-position"

'reposition-file' ( ud wfileid - wior ) file "reposition-file"

'file-size' ( wfileid - ud wior ) file "file-size"

'resize-file' ( ud wfileid - wior ) file "resize-file"

'slurp-file' ( c-addr1 u1 - c-addr2 u2  ) gforth-0.6
   C-ADDR1 U1 is the filename, C-ADDR2 U2 is the file's contents

'slurp-fid' ( fid - addr u  ) gforth-0.6
   ADDR U is the content of the file FID

'stdin' ( - wfileid ) gforth-0.4 "stdin"
   The standard input file of the Gforth process.

'stdout' ( - wfileid ) gforth-0.2 "stdout"
   The standard output file of the Gforth process.

'stderr' ( - wfileid ) gforth-0.2 "stderr"
   The standard error output file of the Gforth process.

6.21.3 Redirection
------------------

You can redirect the output of 'type' and 'emit' and all the words that
use them (all output words that don't have an explicit target file) to
an arbitrary file with the 'outfile-execute', used like this:

     : some-warning ( n -- )
         cr ." warning# " . ;

     : print-some-warning ( n -- )
         ['] some-warning stderr outfile-execute ;

   After 'some-warning' is executed, the original output direction is
restored; this construct is safe against exceptions.  Similarly, there
is 'infile-execute' for redirecting the input of 'key' and its users
(any input word that does not take a file explicitly).

'outfile-execute' ( ... xt file-id - ...  ) gforth-0.7
   execute xt with the output of 'type' etc.  redirected to file-id.

'outfile-id' ( - file-id  ) gforth-0.2
   File-id is used by 'emit', 'type', and any output word that does not
take a file-id as input.  By default 'outfile-id' produces the process's
'stdout', unless changed with 'outfile-execute'.

'infile-execute' ( ... xt file-id - ...  ) gforth-0.7
   execute xt with the input of 'key' etc.  redirected to file-id.

'infile-id' ( - file-id  ) gforth-0.4
   File-id is used by 'key', '?key', and anything that refers to the
"user input device".  By default 'infile-id' produces the process's
'stdin', unless changed with 'infile-execute'.

   If you do not want to redirect the input or output to a file, you can
also make use of the fact that 'key', 'emit' and 'type' are deferred
words (*note Deferred Words::).  However, in that case you have to worry
about the restoration and the protection against exceptions yourself;
also, note that for redirecting the output in this way, you have to
redirect both 'emit' and 'type'.

6.21.4 Directories
------------------

You can split a file name into a directory and base component:

'basename' ( c-addr1 u1 - c-addr2 u2  ) gforth-0.7
   Given a file name c-addr1 u1, c-addr2 u2 is the part of it with any
leading directory components removed.

'dirname' ( c-addr1 u1 - c-addr1 u2  ) gforth-0.7
   C-addr1 u2 is the directory name of the file name c-addr1 u1,
including the final '/'.  If caddr1 u1 does not contain a '/', u2=0.

   You can open and read directories similar to files.  Reading gives
you one directory entry at a time; you can match that to a filename
(with wildcards).

'open-dir' ( c-addr u - wdirid wior ) gforth-0.5 "open-dir"
   Open the directory specified by c-addr, u and return dir-id for
futher access to it.

'read-dir' ( c-addr u1 wdirid - u2 flag wior ) gforth-0.5 "read-dir"
   Attempt to read the next entry from the directory specified by dir-id
to the buffer of length u1 at address c-addr.  If the attempt fails
because there is no more entries, ior=0, flag=0, u2=0, and the buffer is
unmodified.  If the attempt to read the next entry fails because of any
other reason, return ior<>0.  If the attempt succeeds, store file name
to the buffer at c-addr and return ior=0, flag=true and u2 equal to the
size of the file name.  If the length of the file name is greater than
u1, store first u1 characters from file name into the buffer and
indicate "name too long" with ior, flag=true, and u2=u1.

'close-dir' ( wdirid - wior ) gforth-0.5 "close-dir"
   Close the directory specified by dir-id.

'filename-match' ( c-addr1 u1 c-addr2 u2 - flag ) gforth-0.5 "match-file"
   match the file name C_ADDR1 U1 with the pattern C_ADDR2 U2.  Patterns
match char by char except for the special characters '*' and '?', which
are wildcards for several ('*') or one ('?')  character.

'get-dir' ( c-addr1 u1 - c-addr2 u2 ) gforth-0.7 "get-dir"
   Store the current directory in the buffer specified by c-addr1, u1.
If the buffer size is not sufficient, return 0 0

'set-dir' ( c-addr u - wior ) gforth-0.7 "set-dir"
   Change the current directory to c-addr, u.  Return an error if this
is not possible

'=mkdir' ( c-addr u wmode - wior ) gforth-0.7 "equals-mkdir"
   Create directory c-addr u with mode wmode.

'mkdir-parents' ( c-addr u mode - ior  ) gforth-0.7
   create the directory c-addr u and all its parents with mode mode
(modified by umask)

6.21.5 Search Paths
-------------------

If you specify an absolute filename (i.e., a filename starting with '/'
or '~', or with ':' in the second position (as in 'C:...')) for
'included' and friends, that file is included just as you would expect.

   If the filename starts with './', this refers to the directory that
the present file was 'included' from.  This allows files to include
other files relative to their own position (irrespective of the current
working directory or the absolute position).  This feature is essential
for libraries consisting of several files, where a file may include
other files from the library.  It corresponds to '#include "..."' in C.
If the current input source is not a file, '.' refers to the directory
of the innermost file being included, or, if there is no file being
included, to the current working directory.

   For relative filenames (not starting with './'), Gforth uses a search
path similar to Forth's search order (*note Word Lists::).  It tries to
find the given filename in the directories present in the path, and
includes the first one it finds.  There are separate search paths for
Forth source files and general files.  If the search path contains the
directory '.', this refers to the directory of the current file, or the
working directory, as if the file had been specified with './'.

   Use '~+' to refer to the current working directory (as in the
'bash').

'absolute-file?' ( addr u - flag  ) gforth-1.0 "absolute-file-question"
   A filename is absolute if it starts with a / or a ~ (~ expansion), or
if it is in the form ./*, extended regexp: ^[/~]|./, or if it has a
colon as second character ("C:...").  Paths simply containing a / are
not absolute!

6.21.5.1 Source Search Paths
............................

The search path is initialized when you start Gforth (*note Invoking
Gforth::).  You can display it and change it using 'fpath' in
combination with the general path handling words.

'fpath' ( - path-addr  ) gforth-0.4

'.fpath' ( -  ) gforth-0.4 "dot-fpath"
   Display the contents of the Forth search path.

'file>fpath' ( addr1 u1 - addr2 u2  ) gforth-1.0 "file-to-fpath"
   Searches for a file with the name c-addr1 u1 in the 'fpath'.  If
successful, c-addr u2 is the absolute file name or the file name
relative to the current working directory.  Throws an exception if the
file cannot be opened.

Here is an example of using 'fpath' and 'require':

     fpath path= /usr/lib/forth/|./
     require timer.fs

6.21.5.2 General Search Paths
.............................

Your application may need to search files in several directories, like
'included' does.  To facilitate this, Gforth allows you to define and
use your own search paths, by providing generic equivalents of the Forth
search path words:

'open-path-file' ( addr1 u1 path-addr - wfileid addr2 u2 0 | ior  ) gforth-0.2
   Look in path PATH-ADDR for the file specified by ADDR1 U1.  If found,
the resulting path and an (read-only) open file descriptor are returned.
If the file is not found, IOR is what came back from the last attempt at
opening the file (in the current implementation).

'file>path' ( c-addr1 u1 path-addr - c-addr2 u2  ) gforth-1.0 "file-to-path"
   Searches for a file with the name c-addr1 u1 in path stored in
path-addr.  If successful, c-addr u2 is the absolute file name or the
file name relative to the current working directory.  Throws an
exception if the file cannot be opened.

'clear-path' ( path-addr -  ) gforth-0.5
   Set the path path-addr to empty.

'also-path' ( c-addr len path-addr -  ) gforth-0.4
   add the directory c-addr len to path-addr.

'.path' ( path-addr -  ) gforth-0.4 "dot-path"
   Display the contents of the search path PATH-ADDR.

'path+' ( path-addr  "dir" -  ) gforth-0.4 "path-plus"
   Add the directory DIR to the search path PATH-ADDR.

'path=' ( path-addr "dir1|dir2|dir3" -  ) gforth-0.4 "path-equals"
   Make a complete new search path; the path separator is |.

   Here's an example of creating a custom search path:
     variable mypath \ no special allocation required, just a variable
     mypath path= /lib|/usr/lib \ assign initial directories
     mypath path+ /usr/local/lib \ append directory
     mypath .path \ output:"/lib /usr/lib /usr/local/lib"

   Search file and show resulting path:
     s" libm.so" mypath open-path-file throw type close-file \ output:"/lib/libm.so"

6.22 Blocks
===========

When you run Gforth on a modern desk-top computer, it runs under the
control of an operating system which provides certain services.  One of
these services is FILE SERVICES, which allows Forth source code and data
to be stored in files and read into Gforth (*note Files::).

   Traditionally, Forth has been an important programming language on
systems where it has interfaced directly to the underlying hardware with
no intervening operating system.  Forth provides a mechanism, called
"blocks", for accessing mass storage on such systems.

   A block is a 1024-byte data area, which can be used to hold data or
Forth source code.  No structure is imposed on the contents of the
block.  A block is identified by its number; blocks are numbered
contiguously from 1 to an implementation-defined maximum.

   A typical system that used blocks but no operating system might use a
single floppy-disk drive for mass storage, with the disks formatted to
provide 256-byte sectors.  Blocks would be implemented by assigning the
first four sectors of the disk to block 1, the second four sectors to
block 2 and so on, up to the limit of the capacity of the disk.  The
disk would not contain any file system information, just the set of
blocks.

   On systems that do provide file services, blocks are typically
implemented by storing a sequence of blocks within a single "blocks
file".  The size of the blocks file will be an exact multiple of 1024
bytes, corresponding to the number of blocks it contains.  This is the
mechanism that Gforth uses.

   Only one blocks file can be open at a time.  If you use block words
without having specified a blocks file, Gforth defaults to the blocks
file 'blocks.fb'.  Gforth uses the Forth search path when attempting to
locate a blocks file (*note Source Search Paths::).

   When you read and write blocks under program control, Gforth uses a
number of "block buffers" as intermediate storage.  These buffers are
not used when you use 'load' to interpret the contents of a block.

   The behaviour of the block buffers is analogous to that of a cache.
Each block buffer has three states:

   * Unassigned
   * Assigned-clean
   * Assigned-dirty

   Initially, all block buffers are unassigned.  In order to access a
block, the block (specified by its block number) must be assigned to a
block buffer.

   The assignment of a block to a block buffer is performed by 'block'
or 'buffer'.  Use 'block' when you wish to modify the existing contents
of a block.  Use 'buffer' when you don't care about the existing
contents of the block(1).

   Once a block has been assigned to a block buffer using 'block' or
'buffer', that block buffer becomes the current block buffer.  Data may
only be manipulated (read or written) within the current block buffer.

   When the contents of the current block buffer has been modified it is
necessary, _before calling 'block' or 'buffer' again_, to either abandon
the changes (by doing nothing) or mark the block as changed
(assigned-dirty), using 'update'.  Using 'update' does not change the
blocks file; it simply changes a block buffer's state to assigned-dirty.
The block will be written implicitly when it's buffer is needed for
another block, or explicitly by 'flush' or 'save-buffers'.

   'Flush' writes all assigned-dirty blocks back to the blocks file on
disk.  Leaving Gforth with 'bye' also performs a 'flush'.

   In Gforth, 'block' and 'buffer' use a direct-mapped algorithm to
assign a block buffer to a block.  That means that any particular block
can only be assigned to one specific block buffer, called (for the
particular operation) the victim buffer.  If the victim buffer is
unassigned or assigned-clean it is allocated to the new block
immediately.  If it is assigned-dirty its current contents are written
back to the blocks file on disk before it is allocated to the new block.

   Although no structure is imposed on the contents of a block, it is
traditional to display the contents as 16 lines each of 64 characters.
A block provides a single, continuous stream of input (for example, it
acts as a single parse area) - there are no end-of-line characters
within a block, and no end-of-file character at the end of a block.
There are two consequences of this:

   * The last character of one line wraps straight into the first
     character of the following line
   * The word '\' - comment to end of line - requires special treatment;
     in the context of a block it causes all characters until the end of
     the current 64-character "line" to be ignored.

   In Gforth, when you use 'block' with a non-existent block number, the
current blocks file will be extended to the appropriate size and the
block buffer will be initialised with spaces.

   Gforth includes a simple block editor (type 'use blocked.fb 0 list'
for details) but doesn't encourage the use of blocks; the mechanism is
only provided for backward compatibility.

   Common techniques that are used when working with blocks include:

   * A screen editor that allows you to edit blocks without leaving the
     Forth environment.
   * Shadow screens; where every code block has an associated block
     containing comments (for example: code in odd block numbers,
     comments in even block numbers).  Typically, the block editor
     provides a convenient mechanism to toggle between code and
     comments.
   * Load blocks; a single block (typically block 1) contains a number
     of 'thru' commands which 'load' the whole of the application.

   See Frank Sergeant's Pygmy Forth to see just how well blocks can be
integrated into a Forth programming environment.

'open-blocks' ( c-addr u -  ) gforth-0.2
   Use the file, whose name is given by c-addr u, as the blocks file.

'use' ( "file" -  ) gforth-0.2
   Use file as the blocks file.

'block-offset' ( - addr  ) gforth-0.5
   User variable containing the number of the first block (default since
0.5.0: 0).  Block files created with Gforth versions before 0.5.0 have
the offset 1.  If you use these files you can: '1 offset !'; or add 1 to
every block number used; or prepend 1024 characters to the file.

'get-block-fid' ( - wfileid  ) gforth-0.2
   Return the file-id of the current blocks file.  If no blocks file has
been opened, use 'blocks.fb' as the default blocks file.

'block-position' ( u -  ) block
   Position the block file to the start of block u.

'list' ( u -  ) block-ext
   Display block u.  In Gforth, the block is displayed as 16 numbered
lines, each of 64 characters.

'scr' ( - a-addr  ) block-ext "s-c-r"
   'User' variable containing the block number of the block most
recently processed by 'list'.

'block' ( u - a-addr  ) block
   If a block buffer is assigned for block u, return its start address,
a-addr.  Otherwise, assign a block buffer for block u (if the assigned
block buffer has been 'update'd, transfer the contents to mass storage),
read the block into the block buffer and return its start address,
a-addr.

'buffer' ( u - a-addr  ) block
   If a block buffer is assigned for block u, return its start address,
a-addr.  Otherwise, assign a block buffer for block u (if the assigned
block buffer has been 'update'd, transfer the contents to mass storage)
and return its start address, a-addr.  The subtle difference between
'buffer' and 'block' mean that you should only use 'buffer' if you don't
care about the previous contents of block u.  In Gforth, this simply
calls 'block'.

'empty-buffers' ( -  ) block-ext
   Mark all block buffers as unassigned; if any had been marked as
assigned-dirty (by 'update'), the changes to those blocks will be lost.

'empty-buffer' ( buffer -  ) gforth-0.2

'update' ( -  ) block
   Mark the state of the current block buffer as assigned-dirty.

'updated?' ( n - f  ) gforth-0.2 "updated-question"
   Return true if 'updated' has been used to mark block n as
assigned-dirty.

'save-buffers' ( -  ) block
   Transfer the contents of each 'update'd block buffer to mass storage,
then mark all block buffers as assigned-clean.

'save-buffer' ( buffer -  ) gforth-0.2

'flush' ( -  ) block
   Perform the functions of 'save-buffers' then 'empty-buffers'.

'load' ( i*x u - j*x  ) block
   Text-interpret block u.  Block 0 cannot be 'load'ed.

'thru' ( i*x n1 n2 - j*x  ) block-ext
   'load' the blocks n1 through n2 in sequence.

'+load' ( i*x n - j*x  ) gforth-0.2 "plus-load"
   Used within a block to load the block specified as the current block
+ n.

'+thru' ( i*x n1 n2 - j*x  ) gforth-0.2 "plus-thru"
   Used within a block to load the range of blocks specified as the
current block + n1 thru the current block + n2.

'-->' ( -  ) gforth-0.2 "chain"
   If this symbol is encountered whilst loading block n, discard the
remainder of the block and load block n+1.  Used for chaining multiple
blocks together as a single loadable unit.  Not recommended, because it
destroys the independence of loading.  Use 'thru' (which is standard) or
'+thru' instead.

'block-included' ( a-addr u -  ) gforth-0.2
   Use within a block that is to be processed by 'load'.  Save the
current blocks file specification, open the blocks file specified by
a-addr u and 'load' block 1 from that file (which may in turn chain or
load other blocks).  Finally, close the blocks file and restore the
original blocks file.

   ---------- Footnotes ----------

   (1) The Standard Forth definition of 'buffer' is intended not to
cause disk I/O; if the data associated with the particular block is
already stored in a block buffer due to an earlier 'block' command,
'buffer' will return that block buffer and the existing contents of the
block will be available.  Otherwise, 'buffer' will simply assign a new,
empty block buffer for the block.

6.23 Other I/O
==============

6.23.1 Simple numeric output
----------------------------

The simplest output functions are those that display numbers from the
data stack.  Numbers are displayed in the base (aka radix) stored in
'base' (*note Number Conversion::).

'.' ( n -  ) core "dot"
   Display (the signed single number) N in free-format, followed by a
space.

'dec.' ( n -  ) gforth-0.2 "dec-dot"
   Display n as a signed decimal number, followed by a space.

'h.' ( u -  ) gforth-1.0 "h-dot"
   Display u as an unsigned hex number, prefixed with a "$" and followed
by a space.

'hex.' ( u -  ) gforth-0.2 "hex-dot"
   Display u as an unsigned hex number, prefixed with a '$' and followed
by a space.  Another name for this word is 'h.', which is present in
several other systems, but not in Gforth before 1.0.

'u.' ( u -  ) core "u-dot"
   Display (the unsigned single number) U in free-format, followed by a
space.

'.r' ( n1 n2 -  ) core-ext "dot-r"
   Display N1 right-aligned in a field N2 characters wide.  If more than
N2 characters are needed to display the number, all digits are
displayed.  If appropriate, N2 must include a character for a leading
"-".

'u.r' ( u n -  ) core-ext "u-dot-r"
   Display U right-aligned in a field N characters wide.  If more than N
characters are needed to display the number, all digits are displayed.

'dec.r' ( u n -  ) gforth-0.5 "dec-dot-r"
   Display u as a unsigned decimal number in a field n characters wide.

'd.' ( d -  ) double "d-dot"
   Display (the signed double number) D in free-format.  followed by a
space.

'ud.' ( ud -  ) gforth-0.2 "u-d-dot"
   Display (the signed double number) UD in free-format, followed by a
space.

'd.r' ( d n -  ) double "d-dot-r"
   Display D right-aligned in a field N characters wide.  If more than N
characters are needed to display the number, all digits are displayed.
If appropriate, N must include a character for a leading "-".

'ud.r' ( ud n -  ) gforth-0.2 "u-d-dot-r"
   Display UD right-aligned in a field N characters wide.  If more than
N characters are needed to display the number, all digits are displayed.

6.23.2 Formatted numeric output
-------------------------------

Forth traditionally uses a technique called "pictured numeric output"
for formatted printing of integers.  In this technique, digits are
extracted from the number (using the current output radix defined by
'base', *note Number Conversion::), converted to ASCII codes and
prepended to a string that is built in a scratch-pad area of memory
(*note Implementation-defined options: core-idef.).  Arbitrary
characters can be prepended to the string during the extraction process.
The completed string is specified by an address and length and can be
manipulated ('TYPE'ed, copied, modified) under program control.

   All of the integer output words described in the previous section
(*note Simple numeric output::) are implemented in Gforth using pictured
numeric output.

   Three important things to remember about pictured numeric output:

   * It always operates on double-precision numbers; to display a
     single-precision number, convert it first (for ways of doing this
     *note Double precision::).
   * It always treats the double-precision number as though it were
     unsigned.  The examples below show ways of printing signed numbers.
   * The string is built up from right to left; least significant digit
     first.

   Standard Forth supports a single output buffer (aka hold area) that
you empty and initialize with '<#' and for which you get the result
string with '#>'.

   Gforth additionally supports nested usage of this buffer, allowing,
e.g., to nest output from the debugging tracer '~~' inside code dealing
with the hold area: '<<#' starts a new nest, '#>' produces the result
string, and '#>>' unnests: the hold area for the nest is reclaimed, and
'#>' now produces the string for the next-outer nest.  All of Gforth's
higher-level numeric output words use '<<#' ...  '#>' ...  '#>>' and can
be nested inside other users of the hold area.

'<#' ( -  ) core "less-number-sign"
   Initialise/clear the pictured numeric output string.

'<<#' ( -  ) gforth-0.5 "less-less-number-sign"
   Start a hold area that ends with '#>>'.  Can be nested in each other
and in '<#'.  Note: if you do not match up the '<<#'s with '#>>'s, you
will eventually run out of hold area; you can reset the hold area to
empty with '<#'.

'#' ( ud1 - ud2  ) core "number-sign"
   Used between '<<#' and '#>'.  Prepend the least-significant digit
(according to 'base') of UD1 to the pictured numeric output string.  UD2
is UD1/BASE, i.e., the number representing the remaining digits.

'#s' ( ud - 0 0  ) core "number-sign-s"
   Used between '<<#' and '#>'.  Prepend all digits of UD to the
pictured numeric output string.  '#s' will convert at least one digit.
Therefore, if UD is 0, '#s' will prepend a "0" to the pictured numeric
output string.

'hold' ( char -  ) core
   Used between '<<#' and '#>'.  Prepend the character CHAR to the
pictured numeric output string.

'holds' ( addr u -  ) core-ext
   Used between '<<#' and '#>'.  Prepend the string 'addr u' to the
pictured numeric output string.

'sign' ( n -  ) core
   Used between '<<#' and '#>'.  If N (a SINGLE number) is negative,
prepend "'-'" to the pictured numeric output string.

'#>' ( xd - addr u  ) core "number-sign-greater"
   Complete the pictured numeric output string by discarding XD and
returning ADDR U; the address and length of the formatted string.  A
Standard program may modify characters within the string.  Does not
release the hold area; use '#>>' to release a hold area started with
'<<#', or '<#' to release all hold areas.

'#>>' ( -  ) gforth-0.5 "number-sign-greater-greater"
   Release the hold area started with '<<#'.

Here are some examples of using pictured numeric output:

     : my-u. ( u -- )
       \ Simplest use of pns.. behaves like Standard u.
       0              \ convert to unsigned double
       <<#            \ start conversion
       #s             \ convert all digits
       #>             \ complete conversion
       TYPE SPACE     \ display, with trailing space
       #>> ;          \ release hold area

     : cents-only ( u -- )
       0              \ convert to unsigned double
       <<#            \ start conversion
       # #            \ convert two least-significant digits
       #>             \ complete conversion, discard other digits
       TYPE SPACE     \ display, with trailing space
       #>> ;          \ release hold area

     : dollars-and-cents ( u -- )
       0              \ convert to unsigned double
       <<#            \ start conversion
       # #            \ convert two least-significant digits
       '.' hold       \ insert decimal point
       #s             \ convert remaining digits
       '$' hold       \ append currency symbol
       #>             \ complete conversion
       TYPE SPACE     \ display, with trailing space
       #>> ;          \ release hold area

     : my-. ( n -- )
       \ handling negatives.. behaves like Standard .
       s>d            \ convert to signed double
       swap over dabs \ leave sign byte followed by unsigned double
       <<#            \ start conversion
       #s             \ convert all digits
       rot sign       \ get at sign byte, append "-" if needed
       #>             \ complete conversion
       TYPE SPACE     \ display, with trailing space
       #>> ;          \ release hold area

     : account. ( n -- )
       \ accountants don't like minus signs, they use parentheses
       \ for negative numbers
       s>d            \ convert to signed double
       swap over dabs \ leave sign byte followed by unsigned double
       <<#            \ start conversion
       2 pick         \ get copy of sign byte
       0< IF ')' hold THEN \ right-most character of output
       #s             \ convert all digits
       rot            \ get at sign byte
       0< IF '(' hold THEN
       #>             \ complete conversion
       TYPE SPACE     \ display, with trailing space
       #>> ;          \ release hold area


   Here are some examples of using these words:

     1 my-u. 1
     hex -1 my-u. decimal FFFFFFFF
     1 cents-only 01
     1234 cents-only 34
     2 dollars-and-cents $0.02
     1234 dollars-and-cents $12.34
     123 my-. 123
     -123 my. -123
     123 account. 123
     -456 account. (456)

6.23.3 Floating-point output
----------------------------

Floating-point output is always displayed using base 10.

'f.' ( r -  ) floating-ext "f-dot"
   Display (the floating-point number) r without exponent, followed by a
space.

'fe.' ( r -  ) floating-ext "f-e-dot"
   Display r using engineering notation (with exponent dividable by 3),
followed by a space.

'fs.' ( r -  ) floating-ext "f-s-dot"
   Display r using scientific notation (with exponent), followed by a
space.

'fp.' ( r -  ) floating-ext "f-p-dot"
   Display r using SI prefix notation (with exponent dividable by 3,
converted into SI prefixes if available), followed by a space.

   Examples of printing the number 1234.5678E23 in the different
floating-point output formats are shown below.

     f. 123456780000000000000000000.
     fe. 123.456780000000E24
     fs. 1.23456780000000E26
     fp. 123.456780000000Y

   The length of the output is influenced by:

'precision' ( - u  ) floating-ext
   u is the number of significant digits currently used by 'F.' 'FE.'
and 'FS.'

'set-precision' ( u -  ) floating-ext
   Set the number of significant digits currently used by 'F.' 'FE.' and
'FS.' to u.

   You can control the output in more detail with:

'f.rdp' ( rf +nr +nd +np -  ) gforth-0.6 "f-dot-rdp"
   Print float rf formatted.  The total width of the output is nr.  For
fixed-point notation, the number of digits after the decimal point is
+nd and the minimum number of significant digits is np.  'Set-precision'
has no effect on 'f.rdp'.  Fixed-point notation is used if the number of
siginicant digits would be at least np and if the number of digits
before the decimal point would fit.  If fixed-point notation is not
used, exponential notation is used, and if that does not fit, asterisks
are printed.  We recommend using nr>=7 to avoid the risk of numbers not
fitting at all.  We recommend nr>=np+5 to avoid cases where 'f.rdp'
switches to exponential notation because fixed-point notation would have
too few significant digits, yet exponential notation offers fewer
significant digits.  We recommend nr>=nd+2, if you want to have
fixed-point notation for some numbers; the smaller the value of np, the
more cases are shown in fixed-point notation (cases where few or no
significant digits remain in fixed-point notation).  We recommend np>nr,
if you want to have exponential notation for all numbers.

   To give you a better intuition of how they influence the output, here
are some examples of parameter combinations; in each line the same
number is printed, in each column the same parameter combination is used
for printing:

         12 13 0    7 3 4   7 3 0   7 3 1   7 5 1   7 7 1   7 0 2  4 2 1
     |-1.234568E-6|-1.2E-6| -0.000|-1.2E-6|-1.2E-6|-1.2E-6|-1.2E-6|****|
     |-1.234568E-5|-1.2E-5| -0.000|-1.2E-5|-.00001|-1.2E-5|-1.2E-5|****|
     |-1.234568E-4|-1.2E-4| -0.000|-1.2E-4|-.00012|-1.2E-4|-1.2E-4|****|
     |-1.234568E-3|-1.2E-3| -0.001| -0.001|-.00123|-1.2E-3|-1.2E-3|****|
     |-1.234568E-2|-1.2E-2| -0.012| -0.012|-.01235|-1.2E-2|-1.2E-2|-.01|
     |-1.234568E-1|-1.2E-1| -0.123| -0.123|-.12346|-1.2E-1|-1.2E-1|-.12|
     |-1.2345679E0| -1.235| -1.235| -1.235|-1.23E0|-1.23E0|-1.23E0|-1E0|
     |-1.2345679E1|-12.346|-12.346|-12.346|-1.23E1|-1.23E1|   -12.|-1E1|
     |-1.2345679E2|-1.23E2|-1.23E2|-1.23E2|-1.23E2|-1.23E2|  -123.|-1E2|
     |-1.2345679E3|-1.23E3|-1.23E3|-1.23E3|-1.23E3|-1.23E3| -1235.|-1E3|
     |-1.2345679E4|-1.23E4|-1.23E4|-1.23E4|-1.23E4|-1.23E4|-12346.|-1E4|
     |-1.2345679E5|-1.23E5|-1.23E5|-1.23E5|-1.23E5|-1.23E5|-1.23E5|-1E5|

   You can generate a string instead of displaying the number with:

'f>str-rdp' ( rf +nr +nd +np - c-addr nr  ) gforth-0.6 "f-to-str-rdp"
   Convert rf into a string at c-addr nr.  The conversion rules and the
meanings of nr +nd np are the same as for 'f.rdp'.  The result in in the
pictured numeric output buffer and will be destroyed by anything
destroying that buffer.

'f>buf-rdp' ( rf c-addr +nr +nd +np -  ) gforth-0.6 "f-to-buf-rdp"
   Convert rf into a string at c-addr nr.  The conversion rules and the
meanings of nr nd np are the same as for 'f.rdp'.

   There is also a primitive used for implementing higher-level
FP-to-string words:

'represent' ( r c-addr u - n f1 f2 ) floating "represent"
   Convert the decimal significand (aka mantissa) of r into a string in
buffer c-addr u; n is the exponent, f1 is true if r is negative, and f2
is true if r is valid (a finite number in Gforth).

6.23.4 Miscellaneous output
---------------------------

'cr' ( -  ) core "c-r"
   Output a newline (of the favourite kind of the host OS). Note that
due to the way the Forth command line interpreter inserts newlines, the
preferred way to use 'cr' is at the start of a piece of text; e.g., 'cr
." hello, world"'.

'space' ( -  ) core
   Display one space.

'spaces' ( u -  ) core
   Display U spaces.

'out' ( - addr  ) gforth-1.0
   'Addr' contains a number that tries to give the position of the
cursor within the current line on the user output device: It resets to 0
on 'cr', increases by the number of characters by 'type' and 'emit', and
decreases on 'backspaces'.  Unfortunately, it does not take into account
tabs, multi-byte characters, or the existence of Unicode characters with
width 0 and 2, so it only works for simple cases.

'.\"' ( compilation 'ccc"' - ; run-time -  ) gforth-0.6 "dot-backslash-quote"
   Like '."', but translates C-like \-escape-sequences (see 'S\"').

'."' ( compilation 'ccc"' - ; run-time -  ) core "dot-quote"
   Compilation: Parse a string ccc delimited by a " (double quote).  At
run-time, display the string.  Interpretation semantics for this word
are undefined in standard Forth.  Gforth's interpretation semantics are
to display the string.

'.(' ( compilation&interpretation 'ccc<close-paren>' -  ) core-ext "dot-paren"
   Compilation and interpretation semantics: Parse a string ccc
delimited by a ')' (right parenthesis).  Display the string.  This is
often used to display progress information during compilation; see
examples below.

   If you don't want to worry about whether to use '.( hello)' or '."
hello"', you can write '"hello" type', which gives you what you usually
want (but is less portable to other Forth systems).

As an example, consider the following text, stored in a file 'test.fs':

     .( text-1)
     : my-word
       ." text-2" cr
       .( text-3)
       "text-4" type
     ;

     ." text-5"
     "text-6" type

   When you load this code into Gforth, the following output is
generated:

     include test.fs <RET> text-1text-3text-5text-6 ok

   * Messages 'text-1' and 'text-3' are displayed because '.(' is an
     immediate word; it behaves in the same way whether it is used
     inside or outside a colon definition.
   * Message 'text-5' is displayed because of Gforth's added
     interpretation semantics for '."'.
   * Message 'text-6' is displayed because '"text-6" type' is
     interpreted.
   * Message 'text-2' is not displayed, because the text interpreter
     performs the compilation semantics for '."' within the definition
     of 'my-word'.
   * Message 'text-4' is not displayed, because '"text-4" type' is
     compiled into 'my-word'.

6.23.5 Displaying characters and strings
----------------------------------------

'type' ( c-addr u -  ) core
   If U>0, display U characters from a string starting with the
character stored at C-ADDR.

'xemit' ( xc -  ) xchar "x-emit"
   Prints an xchar on the terminal.

'emit' ( c -  ) core
   Send the byte c to the current output; for ASCII characters, 'emit'
is equivalent to 'xemit'.

'typewhite' ( addr n -  ) gforth-0.2
   Like type, but white space is printed instead of the characters.

6.23.6 Terminal output
----------------------

If you are outputting to a terminal, you may want to control the
positioning of the cursor:

'at-xy' ( x y -  ) facility "at-x-y"
   Put the curser at position x y.  The top left-hand corner of the
display is at 0 0.

'at-deltaxy' ( dx dy -  ) gforth-0.7
   With the current position at x y, put the cursor at x+dx y+dy.

   In order to know where to position the cursor, it is often helpful to
know the size of the screen:

'form' ( - nlines ncols  ) gforth-0.2

   And sometimes you want to use:

'page' ( -  ) facility
   Clear the screen

   Note that on non-terminals you should use '12 emit', not 'page', to
get a form feed.

6.23.6.1 Color output
.....................

The following words are used to create (semantic) colorful output;
further output is produced in the color and style given by the word; the
actual color and style depends on the theme (see below).

'default-color' ( -  ) gforth-1.0
   use system-default color

'error-color' ( -  ) gforth-1.0
   error color: red

'error-hl-inv' ( -  ) gforth-1.0
   color mod for error highlight inverse

'error-hl-ul' ( -  ) gforth-1.0
   color mod for error highlight underline

'warning-color' ( -  ) gforth-1.0
   color for warnings: blue/yellow on black terminals

'info-color' ( -  ) gforth-1.0
   color for info: green/cyan on black terminals

'success-color' ( -  ) gforth-1.0
   color for success: green

'input-color' ( -  ) gforth-1.0
   color for user-input: black/white (both bold)

'status-color' ( -  ) gforth-1.0
   color mod for status bar

'compile-color' ( -  ) gforth-1.0
   color mod for status bar in compile mode

6.23.6.2 Color themes
.....................

Depending on whether you prefer bright or dark background the foreground
colors-theme can be changed by:

'light-mode' ( -  ) gforth-1.0
   color theme for white background

'dark-mode' ( -  ) gforth-1.0
   color theme for black background

'uncolored-mode' ( -  ) gforth-1.0
   This mode does not set colors, but uses the default ones.

'magenta-input' ( -  ) gforth-1.0
   make input color easily recognizable (useful in presentations)

'default-input' ( -  ) gforth-1.0
   make input color easily recognizable (useful in presentations)

   Gforth tries to select the best mode automatically.  You can set the
environment variable 'GFORTH_INIT' to 'light', 'dark', 'uncolored', or
'auto' (same effect if not setting it at all), to tell Gforth your
preference, as well as 'magenta' or 'default' for the input color
preference.  Concatenate options with space as separator.

6.23.7 Single-key input
-----------------------

If you want to get a single printable character, you can use 'key'; to
check whether a character is available for 'key', you can use 'key?'.

'key' ( - char  ) core
   Receive (but do not display) one character, CHAR.

'key-ior' ( - char|ior  ) gforth-1.0
   Receive (but do not display) one character, CHAR, in case of an error
or interrupt, return the negative IOR instead.

'key?' ( - flag  ) facility "key-question"
   Determine whether a character is available.  If a character is
available, FLAG is true; the next call to 'key' will yield the
character.  Once 'key?' returns true, subsequent calls to 'key?' before
calling 'key' or 'ekey' will also return true.

'xkey?' ( - flag  ) xchar "x-key-query"

   If you want to process a mix of printable and non-printable
characters, you can do that with 'ekey' and friends.  'Ekey' produces a
keyboard event that you have to convert into a character with
'ekey>char' or into a key identifier with 'ekey>fkey'.

   Typical code for using EKEY looks like this:

     ekey ekey>xchar if ( xc )
       ... \ do something with the character
     else ekey>fkey if ( key-id )
       case
         k-up                                  of ... endof
         k-f1                                  of ... endof
         k-left k-shift-mask or k-ctrl-mask or of ... endof
         ...
       endcase
     else ( keyboard-event )
       drop \ just ignore an unknown keyboard event type
     then then

'ekey' ( - u  ) facility-ext "e-key"
   Receive a keyboard event U (encoding implementation-defined).

'ekey>xchar' ( u - u false | xc true  ) xchar-ext "e-key-to-x-char"
   Convert keyboard event U into xchar 'xc' if possible.

'ekey>char' ( u - u false | c true  ) facility-ext "e-key-to-char"
   Convert keyboard event U into character 'c' if possible.  Note that
non-ASCII characters produce 'false' from both 'ekey>char' and
'ekey>fkey'.  Instead of 'ekey>char', use 'ekey>xchar' if available.

'ekey>fkey' ( u1 - u2 f  ) facility-ext "e-key-to-f-key"
   If u1 is a keyboard event in the special key set, convert keyboard
event U1 into key id U2 and return true; otherwise return U1 and false.

'ekey?' ( - flag  ) facility-ext "e-key-question"
   True if a keyboard event is available.

   The key identifiers for cursor keys are:

'k-left' ( - u  ) facility-ext

'k-right' ( - u  ) facility-ext

'k-up' ( - u  ) facility-ext

'k-down' ( - u  ) facility-ext

'k-home' ( - u  ) facility-ext
   aka Pos1

'k-end' ( - u  ) facility-ext

'k-prior' ( - u  ) facility-ext
   aka PgUp

'k-next' ( - u  ) facility-ext
   aka PgDn

'k-insert' ( - u  ) facility-ext

'k-delete' ( - u  ) facility-ext
   the <DEL> key on my xterm, not backspace

   The key identifiers for function keys (aka keypad keys) are:

'k-f1' ( - u  ) facility-ext "k-f-1"

'k-f2' ( - u  ) facility-ext "k-f-2"

'k-f3' ( - u  ) facility-ext "k-f-3"

'k-f4' ( - u  ) facility-ext "k-f-4"

'k-f5' ( - u  ) facility-ext "k-f-5"

'k-f6' ( - u  ) facility-ext "k-f-6"

'k-f7' ( - u  ) facility-ext "k-f-7"

'k-f8' ( - u  ) facility-ext "k-f-8"

'k-f9' ( - u  ) facility-ext "k-f-9"

'k-f10' ( - u  ) facility-ext "k-f-10"

'k-f11' ( - u  ) facility-ext "k-f-11"

'k-f12' ( - u  ) facility-ext "k-f-12"

   Note that 'k-f11' and 'k-f12' are not as widely available.

   You can combine these key identifiers with masks for various shift
keys:

'k-shift-mask' ( - u  ) facility-ext

'k-ctrl-mask' ( - u  ) facility-ext

'k-alt-mask' ( - u  ) facility-ext

   There are a number of keys that have ASCII values, and therefore are
unlikely to be reported as special keys, but the combination of these
keys with shift keys may be reported as a special key:

'k-enter' ( - u  ) gforth-1.0

'k-backspace' ( - u  ) gforth-1.0

'k-tab' ( - u  ) gforth-1.0

   Moreover, there the following key codes for keys and other events:

'k-winch' ( - u  ) gforth-1.0
   A key code that may be generated when the user changes the window
size.

'k-pause' ( - u  ) gforth-1.0

'k-mute' ( - u  ) gforth-1.0

'k-volup' ( - u  ) gforth-1.0

'k-voldown' ( - u  ) gforth-1.0

'k-sel' ( - u  ) gforth-1.0

'k-eof' ( - u  ) gforth-1.0

   Note that, even if a Forth system has 'ekey>fkey' and the key
identifier words, the keys are not necessarily available or it may not
necessarily be able to report all the keys and all the possible
combinations with shift masks.  Therefore, write your programs in such a
way that they are still useful even if the keys and key combinations
cannot be pressed or are not recognized.

   Examples: Older keyboards often do not have an F11 and F12 key.  If
you run Gforth in an xterm, the xterm catches a number of combinations
(e.g., <Shift-Up>), and never passes it to Gforth.  Finally, Gforth
currently does not recognize and report combinations with multiple shift
keys (so the <shift-ctrl-left> case in the example above would never be
entered).

   Gforth recognizes various keys available on ANSI terminals (in MS-DOS
you need the ANSI.SYS driver to get that behaviour); it works by
recognizing the escape sequences that ANSI terminals send when such a
key is pressed.  If you have a terminal that sends other escape
sequences, you will not get useful results on Gforth.  Other Forth
systems may work in a different way.

   Gforth also provides a few words for outputting names of function
keys:

'fkey.' ( u -  ) gforth-1.0 "fkey-dot"
   Print a string representation for the function key u.  U must be a
function key (possibly with modifier masks), otherwise there may be an
exception.

'simple-fkey-string' ( u1 - c-addr u  ) gforth-1.0
   c-addr u is the string name of the function key u1.  Only works for
simple function keys without modifier masks.  Any u1 that does not
correspond to a simple function key currently produces an exception.

6.23.8 Line input and conversion
--------------------------------

For ways of storing character strings in memory see *note String
representations::.

   Words for inputting one line from the keyboard:

'accept' ( c-addr +n1 - +n2  ) core
   Get a string of up to N1 characters from the user input device and
store it at C-ADDR.  N2 is the length of the received string.  The user
indicates the end by pressing <RET>.  Gforth supports all the editing
functions available on the Forth command line (including history and
word completion) in 'accept'.

'edit-line' ( c-addr n1 n2 - n3  ) gforth-0.6
   edit the string with length N2 in the buffer C-ADDR N1, like
'accept'.

   Conversion words:

's>number?' ( addr u - d f  ) gforth-0.5 "s-to-number-question"
   converts string addr u into d, flag indicates success

's>unumber?' ( c-addr u - ud flag  ) gforth-0.5 "s-to-unumber-question"
   converts string c-addr u into ud, flag indicates success

'>number' ( ud1 c-addr1 u1 - ud2 c-addr2 u2  ) core "to-number"
   Attempt to convert the character string C-ADDR1 U1 to an unsigned
number in the current number base.  The double UD1 accumulates the
result of the conversion to form UD2.  Conversion continues,
left-to-right, until the whole string is converted or a character that
is not convertable in the current number base is encountered (including
+ or -).  For each convertable character, UD1 is first multiplied by the
value in 'BASE' and then incremented by the value represented by the
character.  C-ADDR2 is the location of the first unconverted character
(past the end of the string if the whole string was converted).  U2 is
the number of unconverted characters in the string.  Overflow is not
detected.

'>float' ( c-addr u - f:... flag ) floating "to-float"
   Actual stack effect: ( c_addr u - r t | f ).  Attempt to convert the
character string c-addr u to internal floating-point representation.  If
the string represents a valid floating-point number, r is placed on the
floating-point stack and flag is true.  Otherwise, flag is false.  A
string of blanks is a special case and represents the floating-point
number 0.

'>float1' ( c-addr u c - f:... flag ) gforth-1.0 "to-float1"
   Actual stack effect: ( c_addr u c - r t | f ).  Attempt to convert
the character string c-addr u to internal floating-point representation,
with c being the decimal separator.  If the string represents a valid
floating-point number, r is placed on the floating-point stack and flag
is true.  Otherwise, flag is false.  A string of blanks is a special
case and represents the floating-point number 0.

   Obsolescent input and conversion words:

'convert' ( ud1 c-addr1 - ud2 c-addr2  ) core-ext-obsolescent
   Obsolescent: superseded by '>number'.

'expect' ( c-addr +n -  ) core-ext-obsolescent
   Receive a string of at most +n characters, and store it in memory
starting at c-addr.  The string is displayed.  Input terminates when the
<return> key is pressed or +n characters have been received.  The normal
Gforth line editing capabilites are available.  The length of the string
is stored in 'span'; it does not include the <return> character.
OBSOLESCENT: superceeded by 'accept'.

'span' ( - c-addr  ) core-ext-obsolescent
   'Variable' - c-addr is the address of a cell that stores the length
of the last string received by 'expect'.  OBSOLESCENT.

6.23.9 Pipes
------------

In addition to using Gforth in pipes created by other processes (*note
Gforth in pipes::), you can create your own pipe with 'open-pipe', and
read from or write to it.

'open-pipe' ( c-addr u wfam - wfileid wior ) gforth-0.2 "open-pipe"
   c-addr u is the name/path of an OS-level program.  If wfam is 'r/o',
the standard output of the program is piped into the Gforth process and
can be read from wfileid.  If wfam is 'w/o', data written to wfileid is
piped as standard input into the program.  wior is 0 if and only if
opening the pipe succeeded.

'close-pipe' ( wfileid - wretval wior ) gforth-0.2 "close-pipe"
   Closes a pipe wfileid opened with 'open-pipe'

   If you write to a pipe, Gforth can throw a 'broken-pipe-error'; if
you don't catch this exception, Gforth will catch it and exit, usually
silently (*note Gforth in pipes::).  Since you probably do not want
this, you should wrap a 'catch' or 'try' block around the code from
'open-pipe' to 'close-pipe', so you can deal with the problem yourself,
and then return to regular processing.

'broken-pipe-error' ( - n  ) gforth-0.6
   the error number for a broken pipe

6.23.10 Xchars and Unicode
--------------------------

ASCII is only appropriate for the English language.  Most western
languages however fit somewhat into the Forth frame, since a byte is
sufficient to encode the few special characters in each (though not
always the same encoding can be used; latin-1 is most widely used,
though).  For other languages, different char-sets have to be used,
several of them variable-width.  To deal with this problem, characters
are often represented as Unicode codepoints on the stack, and as UTF-8
byte strings in memory.  An Unicode codepoint often represents one
application-level character, but Unicode also supports decomposed
characters that consist of several code points, e.g., a base letter and
a combining diacritical mark.

   An Unicode codepoint can consume more than one byte in memory, so we
adjust our terminology: A char is a raw byte in memory or a value in the
range 0-255 on the stack.  An xchar (for extended char) stands for one
codepoint; it is represented by one or more bytes in memory and may have
larger values on the stack.  ASCII characters are the same as chars and
as xchars: values in the range 0-127, and a single byte with that value
in memory.

   When using UTF-8 encoding, all other codepoints take more than one
byte/char.  In most cases, you can just treat such characters as strings
in memory and don't need to use the following words, but if you want to
deal with individual codepoints, the following words are useful.  We
currently have no words for dealing with decomposed characters.

   The xchar words add a few data types:

   * XC is an extended char (xchar) on the stack.  It occupies one cell,
     and is a subset of unsigned cell.  On 16 bit systems, only the BMP
     subset of the Unicode character set (i.e., codepoints <65536) can
     be represented on the stack.  If you represent your application
     characters as strings at all times, you can avoid this limitation.

   * XC-ADDR is the address of an xchar in memory.  Alignment
     requirements are the same as C-ADDR.  The memory representation of
     an xchar differs from the stack representation, and depends on the
     encoding used.  An xchar may use a variable number of chars in
     memory.

   * XC-ADDR U is a buffer of xchars in memory, starting at XC-ADDR, U
     chars (i.e., bytes, not xchars) long.

'xc-size' ( xc - u  ) xchar "x-c-size"
   Computes the memory size of the xchar XC in chars.

'x-size' ( xc-addr u1 - u2  ) xchar
   Computes the memory size of the first xchar stored at XC-ADDR in
chars.

'xc@' ( xc-addr - xc  ) xchar-ext "xc-fetch"
   Fetchs the xchar XC at XC-ADDR1.

'xc@+' ( xc-addr1 - xc-addr2 xc  ) xchar "x-c-fetch-plus"
   Fetchs the xchar XC at XC-ADDR1.  XC-ADDR2 points to the first memory
location after XC.

'xc@+?' ( xc-addr1 u1 - xc-addr2 u2 xc  ) gforth-experimental "x-c-fetch-plus-query"
   Fetchs the first xchar XC of the string XC-ADDR1 U1.  XC-ADDR2 U2 is
the remaining string after XC.

'xc!+?' ( xc xc-addr1 u1 - xc-addr2 u2 f  ) xchar "x-c-store-plus-query"
   Stores the xchar XC into the buffer starting at address XC-ADDR1, U1
chars large.  XC-ADDR2 points to the first memory location after XC, U2
is the remaining size of the buffer.  If the xchar XC did fit into the
buffer, F is true, otherwise F is false, and XC-ADDR2 U2 equal XC-ADDR1
U1.  XC!+?  is safe for buffer overflows, and therefore preferred over
XC!+.

'xc!+' ( xc xc-addr1 - xc-addr2  ) xchar "x-c-store"
   Stores the xchar XC at XC-ADDR1.  XC-ADDR2 is the next unused address
in the buffer.  Note that this writes up to 4 bytes, so you need at
least 3 bytes of padding after the end of the buffer to avoid
overwriting useful data if you only check the address against the end of
the buffer.

'xchar+' ( xc-addr1 - xc-addr2  ) xchar "x-char-plus"
   Adds the size of the xchar stored at XC-ADDR1 to this address, giving
XC-ADDR2.

'xchar-' ( xc-addr1 - xc-addr2  ) xchar-ext "x-char-minus"
   Goes backward from XC_ADDR1 until it finds an xchar so that the size
of this xchar added to XC_ADDR2 gives XC_ADDR1.

'+x/string' ( xc-addr1 u1 - xc-addr2 u2  ) xchar-ext "plus-x-slash-string"
   Step forward by one xchar in the buffer defined by address XC-ADDR1,
size U1 chars.  XC-ADDR2 is the address and u2 the size in chars of the
remaining buffer after stepping over the first xchar in the buffer.

'x\string-' ( xc-addr u1 - xc-addr u2  ) xchar-ext "x-backslash-string-minus"
   Step backward by one xchar in the buffer defined by address XC-ADDR
and size U1 in chars, starting at the end of the buffer.  XC-ADDR is the
address and U2 the size in chars of the remaining buffer after stepping
backward over the last xchar in the buffer.

'-trailing-garbage' ( xc-addr u1 - xc-addr u2  ) xchar-ext "minus-trailing-garbage"
   Examine the last XCHAR in the buffer XC-ADDR U1--if the encoding is
correct and it repesents a full char, U2 equals U1, otherwise, U2
represents the string without the last (garbled) xchar.

'x-width' ( xc-addr u - n  ) xchar-ext
   N is the number of monospace ASCII chars that take the same space to
display as the the xchar string starting at XC-ADDR, using U chars;
assuming a monospaced display font, i.e.  char width is always an
integer multiple of the width of an ASCII char.

'xkey' ( - xc  ) xchar "x-key"
   Reads an xchar from the terminal.  This will discard all input events
up to the completion of the xchar.

'xc-width' ( xc - n  ) xchar-ext "x-c-width"
   XC has a width of N times the width of a normal fixed-width glyph.

'xhold' ( xc -  ) xchar-ext "x-hold"
   Used between '<<#' and '#>'.  Prepend XC to the pictured numeric
output string.  Alternatively, use 'holds'.

'xc,' ( xchar -  ) xchar "x-c-comma"

6.23.11 Internationalization and Localization
---------------------------------------------

Programs for end users require to address those in their native
language.  There is a decades old proposal for such a facility that has
been split from other proposals for international character sets like
Xchars (*note Xchars and Unicode::) and Substitute (*note Substitute::).
Messages displayed on the screen need to be translated from the native
language of the developers to the local languages of the user.

   Strings subject to translation are declared with 'L" 'STRING'"'.
This returns a locale string identifier (LSID). LSIDs are opaque types,
taking a cell on the stack.  LSIDs can be translated into a locale;
locales are languages and country-specific variants of that language.

'L"' ( "lsid<">" - lsid  ) gforth-experimental "l-quote"
   Parse a string and define a new lsid, if the string is uniquely new.
Identical strings result in identical lsids, which allows to refer to
the same lsid from multiple locations using the same string.

'LU"' ( "lsid<">" - lsid  ) gforth-experimental "l-unique-quote"
   Parse a string and always define a new lsid, even if the string is
not unique.

'native@' ( lsid - addr u  ) gforth-experimental "native-fetch"
   fetch native string from an LSID

'locale@' ( lsid - addr u  ) gforth-experimental "locale-fetch"
   fetch the localized string in the current language and country

'locale!' ( addr u lsid -  ) gforth-experimental "locale-store"
   Store localized string ADDR U for the current locale and country in
LSID.

'Language' ( "name" -  ) gforth-experimental
   define a locale.  Executing that locale makes it the current locale.

'Country' ( <lang> "name" -  ) gforth-experimental
   define a variant (typical: country) for the current locale.
Executing that locale makes it the current locale.  You can create
variants of variants (a country may have variants within, e.g.  think of
how many words for rolls/buns there are in many languages).

'locale-file' ( fid -  ) gforth-experimental "locale-file"
   read lines from FID into the current locale.

'included-locale' ( addr u -  ) gforth-experimental "included-locale"
   read lines from the file ADDR U into the current locale.

'include-locale' ( "name" -  ) gforth-experimental "include-locale"
   read lines from the file "NAME" into the current locale.

'locale-csv' ( "name" -  ) gforth-experimental "locale-csv"
   import comma-separated value table into locales.  first line contains
locale names, "program" and "default" are special entries; generic
languages must preceed translations for specific countries.  Entries
under "program" (must be leftmost) are used to search for the lsid; if
empty, the line number-1 is the lsid index.

'.locale-csv' ( -  ) gforth-experimental "dot-locale-csv"
   write the locale database in CSV format to the terminal output.

'locale-csv-out' ( "name" -  ) gforth-experimental "locale-csv-out"
   Create file "NAME" and write the locale database out to the file
"NAME" in CSV format.

6.23.12 Substitute
------------------

This is a simple text macro replacement facility.  Texts in the form
'"text %macro% text"' are processed, and the macro variables enclosed in
''%'' are replaced with their associated strings.  Two consecutive '%'
are replaced by one '%'.  Macros are defined in a specific wordlist, and
return a string upon execution; the standard defines only one way to
declare macros, 'replaces', which creates a macro that just returns a
string.

'macros-wordlist' ( - wid  ) gforth-experimental
   wordlist for string replacement macros

'replaces' ( addr1 len1 addr2 len2 -  ) string-ext
   create a macro with name ADDR2 LEN2 and content ADDR1 LEN1.  If the
macro already exists, just change the content.

'replacer:' ( "name" -  ) gforth-experimental "replacer-colon"
   Start a colon definition name in 'macros-wordlist', i.e.  this colon
definition is a macro.  It must have the stack effect ( - ADDR U ).

'.substitute' ( addr1 len1 - n / ior  ) gforth-experimental "dot-substitute"
   substitute all macros in text ADDR1 LEN1 and print the result.  N is
the number of substitutions or, if negative, a throwable IOR.

'$substitute' ( addr1 len1 - addr2 len2 n/ior  ) gforth-experimental "string-substitute"
   substitute all macros in text ADDR1 LEN1.  N is the number of
substitutions, if negative, it's a throwable IOR, ADDR2 LEN2 the result.

'substitute' ( addr1 len1 addr2 len2 - addr2 len3 n/ior  ) string-ext
   substitute all macros in text ADDR1 LEN1, and copy the result to
ADDR2 LEN2.  N is the number of substitutions or, if negative, a
throwable IOR, ADDR2 LEN3 the result.

'unescape' ( addr1 u1 dest - dest u2  ) string-ext
   double all delimiters in ADDR1 U1, so that substitute will result in
the original text.  Note that the buffer DEST does not have a size, as
in worst case, it will need just twice as many characters as U1.  DEST
U2 is the resulting string.

'$unescape' ( addr1 u1 - addr2 u2  ) gforth-experimental "string-unescape"
   same as 'unescape', but creates a temporary destination string with
'$tmp'.

6.23.13 CSV Reader
------------------

Comma-separated values (CSV) are a popular text format to interchange
data.  Gforth provides words for reading CSV files (with all features,
including newlines in quoted strings).

'read-csv' ( addr u xt -  ) gforth-experimental
   Read CVS file ADDR U and execute XT for every field found.  XT has
the stack effect '( addr u field line -- )', i.e.  the field string (in
de-quoted form), the current field number (starting with 0), and the
current line (starting with 1).

'csv-separator' ( - c  ) gforth-experimental
   CSV field separator (default is ',', hence the name
"comma-separated"); this is a value and can be changed with 'to
csv-separator'.

'csv-quote' ( - c  ) gforth-experimental
   CSV quote character (default is '"'); this is a value and can be
changed with 'to csv-quote'.

'.quoted-csv' ( c-addr u -  ) gforth-experimental "dot-quoted-csv"
   print a field in CSV format, i.e., with enough quotes that 'read-csv'
will produce c-addr u when encountering the output of '.quoted-csv'.

6.24 OS command line arguments
==============================

The usual way to pass arguments to Gforth programs on the command line
is via the '-e' option, e.g.

     gforth -e "123 456" foo.fs -e bye

   However, you may want to interpret the command-line arguments
directly.  In that case, you can access the (image-specific)
command-line arguments through 'next-arg':

'next-arg' ( - addr u  ) gforth-0.7
   get the next argument from the OS command line, consuming it; if
there is no argument left, return '0 0'.

   Here's an example program 'echo.fs' for 'next-arg':

     : echo ( -- )
         begin
             next-arg 2dup 0 0 d<> while
                 type space
         repeat
         2drop ;

     echo cr bye

   This can be invoked with

     gforth echo.fs hello world

   and it will print

     hello world

   The next lower level of dealing with the OS command line are the
following words:

'arg' ( u - addr count  ) gforth-0.2
   Return the string for the uth command-line argument; returns '0 0' if
the access is beyond the last argument.  '0 arg' is the program name
with which you started Gforth.  The next unprocessed argument is always
'1 arg', the one after that is '2 arg' etc.  All arguments already
processed by the system are deleted.  After you have processed an
argument, you can delete it with 'shift-args'.

'shift-args' ( -  ) gforth-0.7
   '1 arg' is deleted, shifting all following OS command line parameters
to the left by 1, and reducing 'argc @'.  This word can change 'argv @'.

   Finally, at the lowest level Gforth provides the following words:

'argc' ( - addr  ) gforth-0.2
   'Variable' - the number of command-line arguments (including the
command name).  Changed by 'next-arg' and 'shift-args'.

'argv' ( - addr  ) gforth-0.2
   'Variable' - a pointer to a vector of pointers to the command-line
arguments (including the command-name).  Each argument is represented as
a C-style zero-terminated string.  Changed by 'next-arg' and
'shift-args'.

6.25 Locals
===========

Local variables can make Forth programming more enjoyable and Forth
programs easier to read.

   Gforth implements an extended version of the standard Forth locals.

6.25.1 Gforth locals
--------------------

Locals can be defined with

     {: local1 local2 ... -- comment :}
   or
     {: local1 local2 ... :}
   or
     {: local1 local2 ... | ulocal0 ulocal1 -- comment :}

   E.g.,
     : max {: n1 n2 -- n3 :}
      n1 n2 > if
        n1
      else
        n2
      endif ;

   The similarity of locals definitions with stack comments is intended.
A locals definition often replaces the stack comment of a word.  The
order of the locals corresponds to the order in a stack comment and
everything after the '--' is really a comment.

   The name of the local may be preceded by a type specifier, e.g., 'F:'
for a floating point value:

     : CX* {: F: Ar F: Ai F: Br F: Bi -- Cr Ci :}
     \ complex multiplication
      Ar Br f* Ai Bi f* f-
      Ar Bi f* Ai Br f* f+ ;

   Gforth currently supports cells ('W:', 'W^'), doubles ('D:', 'D^'),
floats ('F:', 'F^'), characters ('C:', 'C^'), and xts ('xt:') in several
flavours:

"value-flavoured"
     (*note Values::) A value-flavoured local (defined with 'W:', 'D:'
     etc.)  produces its value and can be changed with 'TO' and '+TO'.
     Also, if you put 'addressable:' in front of the locals definition,
     you can get its address with 'ADDR' (*note How long do locals
     live?::).

"variable-flavoured"
     (*note Variables::) A variable-flavoured local (defined with 'W^'
     etc.)  produces its address (*note How long do locals live?::).
     E.g., the standard word 'emit' can be defined in terms of 'type'
     like this:

          : emit {: C^ char* -- :}
              char* 1 type ;

"defer-flavoured"
     (*note Deferred Words::) A defer-flavoured local (defined with
     'XT:') 'execute's the xt; you can use 'action-of' (*note Deferred
     Words::) to get the xt out of a defer-flavoured local.  If the
     local is defined with 'addressable: xt:', you can use 'addr' to get
     the address where the xt is stored (*note How long do locals
     live?::).  E.g., the standard word 'execute' can be defined with a
     defer-flavoured local like this:

          : execute {: xt: x -- :}
            x ;

   A local without type specifier is a 'W:' local.  You can also leave
away the 'w:' if you use 'addressable:'.

   All flavours of locals are initialized with values from the data or
(for FP locals) FP stack, with the exception being locals defined behind
'|': Gforth initializes them to 0; some Forth systems leave them
uninitialized.

   Gforth supports the square bracket notation for local buffers and
data structures.  These locals are similar to variable-flavored locals,
the size is specified as a constant expression.  A declaration looks
'name[ size ]'.  The Forth expression 'size' is evaluated during
declaration, it must have the stack effect '( -- +n )', giving the size
in bytes.  The square bracket '[' is part of the defined name.

   Local data structures are initialized by copying size bytes from an
address passed on the stack; uninitialized local data structures (after
'|' in the declaration) are not erased, they just contain whatever data
there was on the locals stack before.

   Example:

     begin-structure test-struct
       field: a1
       field: a2
     end-structure

     : test-local {: foo[ test-struct ] :}
         foo[ a1 !  foo[ a2 !
         foo[ test-struct dump ;

   Gforth allows defining locals everywhere in a colon definition.  This
poses the following questions:

6.25.1.1 Locals definitions words
.................................

This section documents the words used for defining locals.  Note that
the run-times for the words (like 'W:') that define a local are
performed from the rightmost defined local to the leftmost defined
local, such that the rightmost local gets the top of stack.

'{:' ( - hmaddr u wid 0  ) local-ext "open-brace-colon"
   Start locals definitions.

'--' ( hmaddr u wid 0 ... -  ) local-ext "dash-dash"
   During a locals definitions with '{:' everything from '--' to ':}' is
ignored.  This is typically used when you want to make a locals
definition serve double duty as a stack effect description.

'|' ( -  ) local-ext "bar"
   Locals defined behind '|' are not initialized from the stack; so the
run-time stack effect of the locals definitions after '|' is '( -- )'.

':}' ( hmaddr u wid 0 xt1 ... xtn -  ) gforth-1.0 "colon-close-brace"
   Ends locals definitions.

'{' ( - hmaddr u wid 0  ) gforth-0.2 "open-brace"
   Start locals definitions.  The Forth-2012 standard name for this word
is '{:'.

'}' ( hmaddr u wid 0 xt1 ... xtn -  ) gforth-0.2 "close-brace"
   Ends locals definitions.  The Forth-2012 standard name for this word
is ':}'.

'locals|' ( ... "name ..." -  ) local-ext "locals-bar"
   Don't use 'locals| this read can't you|'!  Use '{: you can read this
:}' instead.!  A portable and free '{:' implementation can be found in
'compat/xlocals.fs'.

'W:' ( compilation "name" - a-addr xt; run-time x -  ) gforth-0.2 "w-colon"
   Define value-flavoured cell local name '( -- x1 )'

'W^' ( compilation "name" - a-addr xt; run-time x -  ) gforth-0.2 "w-caret"
   Define variable-flavoured cell local name '( -- a-addr )'

'D:' ( compilation "name" - a-addr xt; run-time x1 x2 -  ) gforth-0.2 "d-colon"
   Define value-flavoured double local name '( -- x3 x4 )'

'D^' ( compilation "name" - a-addr xt; run-time x1 x2 -  ) gforth-0.2 "d-caret"
   Define variable-flavoured double local name '( -- a-addr )'

'C:' ( compilation "name" - a-addr xt; run-time c -  ) gforth-0.2 "c-colon"
   Define value-flavoured char local name '( -- c1 )'

'C^' ( compilation "name" - a-addr xt; run-time c -  ) gforth-0.2 "c-caret"
   Define variable-flavoured char local name '( -- c-addr )'

'F:' ( compilation "name" - a-addr xt; run-time r -  ) gforth-0.2 "f-colon"
   Define value-flavoured float local name '( -- r1 )'

'F^' ( compilation "name" - a-addr xt; run-time r -  ) gforth-0.2 "f-caret"
   Define variable-flavoured float local name '( -- f-addr )'

'z:' ( compilation "name" - a-addr xt; run-time z -  ) gforth-1.0 "z-colon"
   Define value-flavoured complex local name '( -- z1 )'

'XT:' ( compilation "name" - a-addr xt; run-time xt1 -  ) gforth-1.0 "x-t-colon"
   Define defer-flavoured cell local name '( ... -- ... )'

   Note that '|', '--' and ':}' are not normally in the search order
(they are in the vocabulary 'locals-types'), and on some Forth systems
they may not even be words (and the standard documents them under '{:',
not as separate word).  '}' is also in 'locals-types'.

6.25.1.2 Where are locals visible by name?
..........................................

Basically, the answer is that locals are visible where you would expect
it in block-structured languages, and sometimes a little longer.  If you
want to restrict the scope of a local, enclose its definition in
'SCOPE'...'ENDSCOPE'.

'scope' ( compilation  - scope ; run-time  -  ) gforth-0.2

'endscope' ( compilation scope - ; run-time  -  ) gforth-0.2

   These words behave like control structure words, so you can use them
with 'CS-PICK' and 'CS-ROLL' to restrict the scope in arbitrary ways.

   If you want a more exact answer to the visibility question, here's
the basic principle: A local is visible in all places that can only be
reached through the definition of the local(1).  In other words, it is
not visible in places that can be reached without going through the
definition of the local.  E.g., locals defined in 'IF'...'THEN' are
visible until the 'THEN', locals defined in 'BEGIN'...'UNTIL' are
visible after the 'UNTIL' (until, e.g., a subsequent 'ENDSCOPE').

   The reasoning behind this solution is: We want to have the locals
visible as long as it is meaningful.  The user can always make the
visibility shorter by using explicit scoping.  In a place that can only
be reached through the definition of a local, the meaning of a local
name is clear.  In other places it is not: How is the local initialized
at the control flow path that does not contain the definition?  Which
local is meant, if the same name is defined twice in two independent
control flow paths?

   This should be enough detail for nearly all users, so you can skip
the rest of this section.  If you really must know all the gory details
and options, read on.

   In order to implement this rule, the compiler has to know which
places are unreachable.  It knows this automatically after 'AHEAD',
'AGAIN', 'EXIT' and 'LEAVE'; in other cases (e.g., after most 'THROW's),
you can use the word 'UNREACHABLE' to tell the compiler that the control
flow never reaches that place.  If 'UNREACHABLE' is not used where it
could, the only consequence is that the visibility of some locals is
more limited than the rule above says.  If 'UNREACHABLE' is used where
it should not (i.e., if you lie to the compiler), you can produce code
whose behaviour is best determined by looking at the implementation
(which may change).

'UNREACHABLE' ( -  ) gforth-0.2

   Another problem with this rule is that at 'BEGIN', the compiler does
not know which locals will be visible on the incoming back-edge.  All
problems discussed in the following are due to this ignorance of the
compiler (we discuss the problems using 'BEGIN' loops as examples; the
discussion also applies to '?DO' and other loops).  Perhaps the most
insidious example is:
     AHEAD
     BEGIN
       x
     [ 1 CS-ROLL ] THEN
       {: x :}
       ...
     UNTIL

   This should be legal according to the visibility rule.  The use of
'x' can only be reached through the definition; but that appears
textually below the use.

   From this example it is clear that the visibility rules cannot be
fully implemented without major headaches.  Our implementation treats
common cases as advertised and the exceptions are treated in a safe way:
The compiler makes a reasonable guess about the locals visible after a
'BEGIN'; if it is too pessimistic, the user will get a spurious error
about the local not being defined; if the compiler is too optimistic, it
will notice this later and issue a warning.  In the case above the
compiler would complain about 'x' being undefined at its use.  You can
see from the obscure examples in this section that it takes quite
unusual control structures to get the compiler into trouble, and even
then it will often do fine.

   If the 'BEGIN' is reachable from above, the most optimistic guess is
that all locals visible before the 'BEGIN' will also be visible after
the 'BEGIN'.  This guess is valid for all loops that are entered only
through the 'BEGIN', in particular, for normal
'BEGIN'...'WHILE'...'REPEAT' and 'BEGIN'...'UNTIL' loops and it is
implemented in our compiler.  When the branch to the 'BEGIN' is finally
generated by 'AGAIN' or 'UNTIL', the compiler checks the guess and warns
the user if it was too optimistic:
     IF
       {: x :}
     BEGIN
       \ x ?
     [ 1 cs-roll ] THEN
       ...
     UNTIL

   Here, 'x' lives only until the 'BEGIN', but the compiler
optimistically assumes that it lives until the 'THEN'.  It notices this
difference when it compiles the 'UNTIL' and issues a warning.  The user
can avoid the warning, and make sure that 'x' is not used in the wrong
area by using explicit scoping:
     IF
       SCOPE
       {: x :}
       ENDSCOPE
     BEGIN
     [ 1 cs-roll ] THEN
       ...
     UNTIL

   Since the guess is optimistic, there will be no spurious error
messages about undefined locals.

   If the 'BEGIN' is not reachable from above (e.g., after 'AHEAD' or
'EXIT'), the compiler cannot even make an optimistic guess, as the
locals visible after the 'BEGIN' may be defined later.

   It pessimistically assumes that all locals are visible that were
visible at the latest place outside any control structure (i.e., where
nothing is on the control-flow stack).  This means that in:

     : foo
       IF {: z :} THEN
       {: x :}
       AHEAD
         BEGIN
           ( * )
         [ 1 CS-ROLL ] THEN
         {: y :}
         ...
       UNTIL ;

   At the place marked with '( * )', 'x' is visible, but 'y' is not
(although, according to the reachability rule it should); 'z' is not and
should not be visible there.

   However, you can use 'ASSUME-LIVE' to make the compiler assume that
the same locals are visible at the BEGIN as at the point where the top
control-flow stack item was created.

'ASSUME-LIVE' ( orig - orig  ) gforth-0.2

E.g.,
     IF
       {: x :}
       AHEAD
         ASSUME-LIVE
         BEGIN
           x
         [ 1 CS-ROLL ] THEN
         ...
       UNTIL
     THEN

   Here 'x' would not be visible at the use of 'x', because its
definition is inside a control structure, but by using ASSUME-LIVE the
programmer tells the compiler that the locals visible at the 'AHEAD'
should be visible at the 'BEGIN'.

   Other cases where the locals are defined before the 'BEGIN' can be
handled by inserting an appropriate 'CS-ROLL' before the 'ASSUME-LIVE'
(and changing the control-flow stack manipulation behind the
'ASSUME-LIVE').

   Cases where locals are defined in a 'BEGIN' loop and should be
visible in that loop before the definition can only be handled by
rearranging the loop.  E.g., the "most insidious" example above can be
arranged into:
     BEGIN
       {: x :}
       ... 0=
     WHILE
       x
     REPEAT

   The ideas in this section have also been published in M. Anton Ertl,
'Automatic Scoping of Local Variables
(https://www.complang.tuwien.ac.at/papers/ertl94l.ps.gz)', EuroForth
'94.

   ---------- Footnotes ----------

   (1) In compiler construction terminology, all places dominated by the
definition of the local.

6.25.1.3 How long do locals live?
.................................

The right answer for the lifetime question would be: A local lives at
least as long as it can be accessed.  For a regular value-flavoured
local this means: until the end of its visibility.  However, an
addressable value-flavoured or variable-flavoured local could be
accessed through its address far beyond its visibility scope.
Ultimately, this would mean that such locals would have to be garbage
collected.  Since this entails un-Forth-like implementation
complexities, we adopted the same cowardly solution as some other
languages (e.g., C): The local lives only as long as it is visible;
afterwards its address is invalid (and programs that access it
afterwards are erroneous).

6.25.1.4 Locals programming style
.................................

The freedom to define locals anywhere has the potential to change
programming styles dramatically.  In particular, the need to use the
return stack for intermediate storage vanishes.  Moreover, all stack
manipulations (except 'PICK's and 'ROLL's with run-time determined
arguments) can be eliminated: If the stack items are in the wrong order,
just write a locals definition for all of them; then write the items in
the order you want.

   This seems a little far-fetched and eliminating stack manipulations
is unlikely to become a conscious programming objective.  Still, the
number of stack manipulations will be reduced dramatically if local
variables are used liberally (e.g., compare 'max' (*note Gforth
locals::) with a traditional implementation of 'max').

   This shows one potential benefit of locals: making Forth programs
more readable.  Of course, this benefit will only be realized if the
programmers continue to honour the principle of factoring instead of
using the added latitude to make the words longer.

   Using 'TO' can and should be avoided.  Without 'TO', every
value-flavoured local has only a single assignment and many advantages
of functional languages apply to Forth.  I.e., programs are easier to
analyse, to optimize and to read: It is clear from the definition what
the local stands for, it does not turn into something different later.

   E.g., a definition using 'TO' might look like this:
     : strcmp {: addr1 u1 addr2 u2 -- n :}
      u1 u2 min 0
      ?do
        addr1 c@ addr2 c@ -
        ?dup-if
          unloop exit
        then
        addr1 char+ TO addr1
        addr2 char+ TO addr2
      loop
      u1 u2 - ;
   Here, 'TO' is used to update 'addr1' and 'addr2' at every loop
iteration.  'strcmp' is a typical example of the readability problems of
using 'TO'.  When you start reading 'strcmp', you think that 'addr1'
refers to the start of the string.  Only near the end of the loop you
realize that it is something else.

   This can be avoided by defining two locals at the start of the loop
that are initialized with the right value for the current iteration.
     : strcmp {: addr1 u1 addr2 u2 -- n :}
      addr1 addr2
      u1 u2 min 0
      ?do {: s1 s2 :}
        s1 c@ s2 c@ -
        ?dup-if
          unloop exit
        then
        s1 char+ s2 char+
      loop
      2drop
      u1 u2 - ;
   Here it is clear from the start that 's1' has a different value in
every loop iteration.

6.25.1.5 Locals implementation
..............................

Gforth uses an extra locals stack.  The most compelling reason for this
is that the return stack is not float-aligned; using an extra stack also
eliminates the problems and restrictions of using the return stack as
locals stack.  Like the other stacks, the locals stack grows toward
lower addresses.  A few primitives allow an efficient implementation;
you should not use them directly, but they appear in the output of
'see', so they are documented here:

'@localn' ( noffset - w ) gforth-internal "fetch-local-n"

'f@localn' ( noffset - r ) gforth-1.0 "f-fetch-local-n"

'!localn' ( w noffset - ) gforth-internal "store-local-n"

'lp+n' ( noffset - c-addr ) gforth-internal "lp-plus-n"

'lp+!' ( noffset - ) gforth-1.0 "lp-plus-store"
   When used with negative noffset allocates memory on the local stack;
when used with a positive noffset drops memory from the local stack

'>l' ( w - ) gforth-0.2 "to-l"

'f>l' ( r - ) gforth-0.2 "f-to-l"

   See also 'lp@', 'lp!' (*note Stack pointer manipulation::).

   In addition to these primitives, some specializations of these
primitives for commonly occurring inline arguments are provided for
efficiency reasons, e.g., '@local0' as specialization of '0 @localn'.

   Combinations of conditional branches and 'lp+!#' like '?branch-lp+!#'
(the locals pointer is only changed if the branch is taken) are provided
for efficiency and correctness in loops.

   A special area in the dictionary space is reserved for keeping the
local variable names.  '{:' switches the dictionary pointer to this area
and ':}' switches it back and generates the locals initializing code.
'W:' etc. are normal defining words.  This special area is cleared at
the start of every colon definition.

   A special feature of Gforth's dictionary is used to implement the
definition of locals without type specifiers: every word list (aka
vocabulary) has its own methods for searching etc.  (*note Word
Lists::).  For the present purpose we defined a word list with a special
search method: When it is searched for a word, it actually creates that
word using 'W:'.  '{:' changes the search order to first search the word
list containing ':}', 'W:' etc., and then the word list for defining
locals without type specifiers.  This implementation was designed before
Gforth acquired recognizers; for a reimplementation we would use
recognizers.

   The lifetime rules support a stack discipline within a colon
definition: The lifetime of a local is either nested with other locals
lifetimes or it does not overlap them.

   At 'BEGIN', 'IF', and 'AHEAD' no code for locals stack pointer
manipulation is generated.  Between control structure words locals
definitions can push locals onto the locals stack.  'AGAIN' is the
simplest of the other three control flow words.  It has to restore the
locals stack depth of the corresponding 'BEGIN' before branching.  The
code looks like this:
current-locals-size dest-locals-size - 'lp+!'
'branch' <begin>

   'UNTIL' is a little more complicated: If it branches back, it must
adjust the stack just like 'AGAIN'.  But if it falls through, the locals
stack must not be changed.  The compiler generates the following code:
'?branch-lp+!#' <begin> current-locals-size - dest-locals-size
   The locals stack pointer is only adjusted if the branch is taken.

   'THEN' can produce somewhat inefficient code:
current-locals-size dest-locals-size - 'lp+!'
<orig target>:
orig-locals-size new-locals-size - 'lp+!'
   The second 'lp+!#' adjusts the locals stack pointer from the level at
the orig point to the level after the 'THEN'.  The first 'lp+!#' adjusts
the locals stack pointer from the current level to the level at the orig
point, so the complete effect is an adjustment from the current level to
the right level after the 'THEN'.  This effect happens e.g., if there is
an 'ELSE' and the code before the 'ELSE' defines locals, and they have a
different size than those after the 'ELSE'.  In general we recommend not
to work around this shortcoming (except in performance-critical code).
We intend to eliminate this shortcoming at some point.

   In a conventional Forth implementation a dest control-flow stack
entry is just the target address and an orig entry is just the address
to be patched.  Our locals implementation adds a word list to every orig
or dest item.  It is the list of locals visible (or assumed visible) at
the point described by the entry.  Our implementation also adds a tag to
identify the kind of entry, in particular to differentiate between live
and dead (reachable and unreachable) orig entries.

   A few unusual operations have to be performed on locals word lists:

'common-list' ( list1 list2 - list3  ) gforth-internal

'sub-list?' ( list1 list2 - f  ) gforth-internal "sub-list-question"

'list-size' ( list - u  ) gforth-internal

   Several features of our locals word list implementation make these
operations easy to implement: The locals word lists are organised as
linked lists; the tails of these lists are shared, if the lists contain
some of the same locals; and the address of a name is greater than the
address of the names behind it in the list.

   Another important implementation detail is the variable 'dead-code'.
It is used by 'BEGIN' and 'THEN' to determine if they can be reached
directly or only through the branch that they resolve.  'dead-code' is
set by 'UNREACHABLE', 'AHEAD', 'EXIT' etc., and cleared at the start of
a colon definition, by 'BEGIN' and usually by 'THEN'.

   Counted loops are similar to other loops in most respects, but
'LEAVE' requires special attention: It performs basically the same
service as 'AHEAD', but it does not create a control-flow stack entry.
Therefore the information has to be stored elsewhere; traditionally, the
information was stored in the target fields of the branches created by
the 'LEAVE's, by organizing these fields into a linked list.
Unfortunately, this clever trick does not provide enough space for
storing our extended control flow information.  Therefore, we introduce
another stack, the leave stack.  It contains the control-flow stack
entries for all unresolved 'LEAVE's.

   Local names are kept until the end of the colon definition, even if
they are no longer visible in any control-flow path.  In a few cases
this may lead to increased space needs for the locals name area, but
usually less than reclaiming this space would cost in code size.

6.25.2 Standard Forth locals
----------------------------

The Forth-2012 standard defines a syntax for locals is restricted
version of Gforth's locals:

   * Locals can only be cell-sized values (no type specifiers are
     allowed).
   * Locals can be defined only outside control structures.
   * Only one locals definition is allowed per colon definition.
   * Locals can interfere with explicit usage of the return stack.  For
     the exact (and long) rules, see the standard.  If you don't use
     return stack accessing words in a definition using locals, you will
     be all right.  The purpose of this rule is to make locals
     implementation on the return stack easier.
   * The whole locals definition must be in one line.

   The Standard Forth locals wordset itself consists of two words: '{:'
and:

'(local)' ( addr u -  ) local "paren-local-paren"

   The Forth-2012 locals extension wordset also defines a syntax using
'locals|', but it is so awful that we strongly recommend not to use it
and another, better syntax (the one using '{:' was standardized).  We
have implemented this syntax to make porting to Gforth easy, but do not
document it here.  The problem with this syntax is that the locals are
defined in an order reversed with respect to the standard stack comment
notation, making programs harder to read, and easier to misread and
miswrite.

6.26 Object-oriented Forth
==========================

Gforth comes with three packages for object-oriented programming:
'objects.fs', 'oof.fs', and 'mini-oof.fs'; none of them is preloaded, so
you have to 'include' them before use.  The most important differences
between these packages (and others) are discussed in *note Comparison
with other object models::.  All packages are written in Standard Forth
and can be used with any other Standard Forth.

6.26.1 Why object-oriented programming?
---------------------------------------

Often we have to deal with several data structures (_objects_), that
have to be treated similarly in some respects, but differently in
others.  Graphical objects are the textbook example: circles, triangles,
dinosaurs, icons, and others, and we may want to add more during program
development.  We want to apply some operations to any graphical object,
e.g., 'draw' for displaying it on the screen.  However, 'draw' has to do
something different for every kind of object.

   We could implement 'draw' as a big 'CASE' control structure that
executes the appropriate code depending on the kind of object to be
drawn.  This would be not be very elegant, and, moreover, we would have
to change 'draw' every time we add a new kind of graphical object (say,
a spaceship).

   What we would rather do is: When defining spaceships, we would tell
the system: "Here's how you 'draw' a spaceship; you figure out the
rest".

   This is the problem that all systems solve that (rightfully) call
themselves object-oriented; the object-oriented packages presented here
solve this problem (and not much else).

6.26.2 Object-Oriented Terminology
----------------------------------

This section is mainly for reference, so you don't have to understand
all of it right away.  The terminology is mainly Smalltalk-inspired.  In
short:

_class_
     a data structure definition with some extras.

_object_
     an instance of the data structure described by the class
     definition.

_instance variables_
     fields of the data structure.

_selector_
     (or _method selector_) a word (e.g., 'draw') that performs an
     operation on a variety of data structures (classes).  A selector
     describes _what_ operation to perform.  In C++ terminology: a
     (pure) virtual function.

_method_
     the concrete definition that performs the operation described by
     the selector for a specific class.  A method specifies _how_ the
     operation is performed for a specific class.

_selector invocation_
     a call of a selector.  One argument of the call (the TOS
     (top-of-stack)) is used for determining which method is used.  In
     Smalltalk terminology: a message (consisting of the selector and
     the other arguments) is sent to the object.

_receiving object_
     the object used for determining the method executed by a selector
     invocation.  In the 'objects.fs' model, it is the object that is on
     the TOS when the selector is invoked.  (_Receiving_ comes from the
     Smalltalk _message_ terminology.)

_child class_
     a class that has (_inherits_) all properties (instance variables,
     selectors, methods) from a _parent class_.  In Smalltalk
     terminology: The subclass inherits from the superclass.  In C++
     terminology: The derived class inherits from the base class.

6.26.3 The 'objects.fs' model
-----------------------------

This section describes the 'objects.fs' package.  This material also has
been published in M. Anton Ertl, 'Yet Another Forth Objects Package
(https://www.complang.tuwien.ac.at/forth/objects/objects.html)', Forth
Dimensions 19(2), pages 37-43.

   This section assumes that you have read *note Structures::.

   The techniques on which this model is based have been used to
implement the parser generator, Gray, and have also been used in Gforth
for implementing the various flavours of word lists (hashed or not,
case-sensitive or not, special-purpose word lists for locals etc.).

   Marcel Hendrix provided helpful comments on this section.

6.26.3.1 Properties of the 'objects.fs' model
.............................................

   * It is straightforward to pass objects on the stack.  Passing
     selectors on the stack is a little less convenient, but possible.

   * Objects are just data structures in memory, and are referenced by
     their address.  You can create words for objects with normal
     defining words like 'constant'.  Likewise, there is no difference
     between instance variables that contain objects and those that
     contain other data.

   * Late binding is efficient and easy to use.

   * It avoids parsing, and thus avoids problems with state-smartness
     and reduced extensibility; for convenience there are a few parsing
     words, but they have non-parsing counterparts.  There are also a
     few defining words that parse.  This is hard to avoid, because all
     standard defining words parse (except ':noname'); however, such
     words are not as bad as many other parsing words, because they are
     not state-smart.

   * It does not try to incorporate everything.  It does a few things
     and does them well (IMO). In particular, this model was not
     designed to support information hiding (although it has features
     that may help); you can use a separate package for achieving this.

   * It is layered; you don't have to learn and use all features to use
     this model.  Only a few features are necessary (*note Basic Objects
     Usage::, *note The Objects base class::, *note Creating
     objects::.), the others are optional and independent of each other.

   * An implementation in Standard Forth is available.

6.26.3.2 Basic 'objects.fs' Usage
.................................

You can define a class for graphical objects like this:

     object class \ "object" is the parent class
       selector draw ( x y graphical -- )
     end-class graphical

   This code defines a class 'graphical' with an operation 'draw'.  We
can perform the operation 'draw' on any 'graphical' object, e.g.:

     100 100 t-rex draw

where 't-rex' is a word (say, a constant) that produces a graphical
object.

   How do we create a graphical object?  With the present definitions,
we cannot create a useful graphical object.  The class 'graphical'
describes graphical objects in general, but not any concrete graphical
object type (C++ users would call it an _abstract class_); e.g., there
is no method for the selector 'draw' in the class 'graphical'.

   For concrete graphical objects, we define child classes of the class
'graphical', e.g.:

     graphical class \ "graphical" is the parent class
       cell% field circle-radius

     :noname ( x y circle -- )
       circle-radius @ draw-circle ;
     overrides draw

     :noname ( n-radius circle -- )
       circle-radius ! ;
     overrides construct

     end-class circle

   Here we define a class 'circle' as a child of 'graphical', with field
'circle-radius' (which behaves just like a field (*note Structures::);
it defines (using 'overrides') new methods for the selectors 'draw' and
'construct' ('construct' is defined in 'object', the parent class of
'graphical').

   Now we can create a circle on the heap (i.e., 'allocate'd memory)
with:

     50 circle heap-new constant my-circle

'heap-new' invokes 'construct', thus initializing the field
'circle-radius' with 50.  We can draw this new circle at (100,100) with:

     100 100 my-circle draw

   Note: You can only invoke a selector if the object on the TOS (the
receiving object) belongs to the class where the selector was defined or
one of its descendents; e.g., you can invoke 'draw' only for objects
belonging to 'graphical' or its descendents (e.g., 'circle').
Immediately before 'end-class', the search order has to be the same as
immediately after 'class'.

6.26.3.3 The 'object.fs' base class
...................................

When you define a class, you have to specify a parent class.  So how do
you start defining classes?  There is one class available from the
start: 'object'.  It is ancestor for all classes and so is the only
class that has no parent.  It has two selectors: 'construct' and
'print'.

6.26.3.4 Creating objects
.........................

You can create and initialize an object of a class on the heap with
'heap-new' ( ...  class - object ) and in the dictionary (allocation
with 'allot') with 'dict-new' ( ...  class - object ).  Both words
invoke 'construct', which consumes the stack items indicated by "..."
above.

   If you want to allocate memory for an object yourself, you can get
its alignment and size with 'class-inst-size 2@' ( class - align size ).
Once you have memory for an object, you can initialize it with
'init-object' ( ...  class object - ); 'construct' does only a part of
the necessary work.

6.26.3.5 Object-Oriented Programming Style
..........................................

This section is not exhaustive.

   In general, it is a good idea to ensure that all methods for the same
selector have the same stack effect: when you invoke a selector, you
often have no idea which method will be invoked, so, unless all methods
have the same stack effect, you will not know the stack effect of the
selector invocation.

   One exception to this rule is methods for the selector 'construct'.
We know which method is invoked, because we specify the class to be
constructed at the same place.  Actually, I defined 'construct' as a
selector only to give the users a convenient way to specify
initialization.  The way it is used, a mechanism different from selector
invocation would be more natural (but probably would take more code and
more space to explain).

6.26.3.6 Class Binding
......................

Normal selector invocations determine the method at run-time depending
on the class of the receiving object.  This run-time selection is called
late binding.

   Sometimes it's preferable to invoke a different method.  For example,
you might want to use the simple method for 'print'ing 'object's instead
of the possibly long-winded 'print' method of the receiver class.  You
can achieve this by replacing the invocation of 'print' with:

     [bind] object print

in compiled code or:

     bind object print

in interpreted code.  Alternatively, you can define the method with a
name (e.g., 'print-object'), and then invoke it through the name.  Class
binding is just a (often more convenient) way to achieve the same
effect; it avoids name clutter and allows you to invoke methods directly
without naming them first.

   A frequent use of class binding is this: When we define a method for
a selector, we often want the method to do what the selector does in the
parent class, and a little more.  There is a special word for this
purpose: '[parent]'; '[parent] _selector_' is equivalent to '[bind]
_parent selector_', where '_parent_' is the parent class of the current
class.  E.g., a method definition might look like:

     :noname
       dup [parent] foo \ do parent's foo on the receiving object
       ... \ do some more
     ; overrides foo

   In 'Object-oriented programming in ANS Forth' (Forth Dimensions,
March 1997), Andrew McKewan presents class binding as an optimization
technique.  I recommend not using it for this purpose unless you are in
an emergency.  Late binding is pretty fast with this model anyway, so
the benefit of using class binding is small; the cost of using class
binding where it is not appropriate is reduced maintainability.

   While we are at programming style questions: You should bind
selectors only to ancestor classes of the receiving object.  E.g., say,
you know that the receiving object is of class 'foo' or its descendents;
then you should bind only to 'foo' and its ancestors.

6.26.3.7 Method conveniences
............................

In a method you usually access the receiving object pretty often.  If
you define the method as a plain colon definition (e.g., with
':noname'), you may have to do a lot of stack gymnastics.  To avoid
this, you can define the method with 'm: ... ;m'.  E.g., you could
define the method for 'draw'ing a 'circle' with

     m: ( x y circle -- )
       ( x y ) this circle-radius @ draw-circle ;m

   When this method is executed, the receiver object is removed from the
stack; you can access it with 'this' (admittedly, in this example the
use of 'm: ... ;m' offers no advantage).  Note that I specify the stack
effect for the whole method (i.e.  including the receiver object), not
just for the code between 'm:' and ';m'.  You cannot use 'exit' in
'm:...;m'; instead, use 'exitm'.(1)

   You will frequently use sequences of the form 'this _field_' (in the
example above: 'this circle-radius').  If you use the field only in this
way, you can define it with 'inst-var' and eliminate the 'this' before
the field name.  E.g., the 'circle' class above could also be defined
with:

     graphical class
       cell% inst-var radius

     m: ( x y circle -- )
       radius @ draw-circle ;m
     overrides draw

     m: ( n-radius circle -- )
       radius ! ;m
     overrides construct

     end-class circle

   'radius' can only be used in 'circle' and its descendent classes and
inside 'm:...;m'.

   You can also define fields with 'inst-value', which is to 'inst-var'
what 'value' is to 'variable'.  You can change the value of such a field
with '[to-inst]'.  E.g., we could also define the class 'circle' like
this:

     graphical class
       inst-value radius

     m: ( x y circle -- )
       radius draw-circle ;m
     overrides draw

     m: ( n-radius circle -- )
       [to-inst] radius ;m
     overrides construct

     end-class circle

   ---------- Footnotes ----------

   (1) Moreover, for any word that calls 'catch' and was defined before
loading 'objects.fs', you have to redefine it like I redefined 'catch':
': catch this >r catch r> to-this ;'

6.26.3.8 Classes and Scoping
............................

Inheritance is frequent, unlike structure extension.  This exacerbates
the problem with the field name convention (*note Standard
Structures::): One always has to remember in which class the field was
originally defined; changing a part of the class structure would require
changes for renaming in otherwise unaffected code.

   To solve this problem, I added a scoping mechanism (which was not in
my original charter): A field defined with 'inst-var' (or 'inst-value')
is visible only in the class where it is defined and in the descendent
classes of this class.  Using such fields only makes sense in
'm:'-defined methods in these classes anyway.

   This scoping mechanism allows us to use the unadorned field name,
because name clashes with unrelated words become much less likely.

   Once we have this mechanism, we can also use it for controlling the
visibility of other words: All words defined after 'protected' are
visible only in the current class and its descendents.  'public'
restores the compilation (i.e.  'current') word list that was in effect
before.  If you have several 'protected's without an intervening
'public' or 'set-current', 'public' will restore the compilation word
list in effect before the first of these 'protected's.

6.26.3.9 Dividing classes
.........................

You may want to do the definition of methods separate from the
definition of the class, its selectors, fields, and instance variables,
i.e., separate the implementation from the definition.  You can do this
in the following way:

     graphical class
       inst-value radius
     end-class circle

     ... \ do some other stuff

     circle methods \ now we are ready

     m: ( x y circle -- )
       radius draw-circle ;m
     overrides draw

     m: ( n-radius circle -- )
       [to-inst] radius ;m
     overrides construct

     end-methods

   You can use several 'methods'...'end-methods' sections.  The only
things you can do to the class in these sections are: defining methods,
and overriding the class's selectors.  You must not define new selectors
or fields.

   Note that you often have to override a selector before using it.  In
particular, you usually have to override 'construct' with a new method
before you can invoke 'heap-new' and friends.  E.g., you must not create
a circle before the 'overrides construct' sequence in the example above.

6.26.3.10 Object Interfaces
...........................

In this model you can only call selectors defined in the class of the
receiving objects or in one of its ancestors.  If you call a selector
with a receiving object that is not in one of these classes, the result
is undefined; if you are lucky, the program crashes immediately.

   Now consider the case when you want to have a selector (or several)
available in two classes: You would have to add the selector to a common
ancestor class, in the worst case to 'object'.  You may not want to do
this, e.g., because someone else is responsible for this ancestor class.

   The solution for this problem is interfaces.  An interface is a
collection of selectors.  If a class implements an interface, the
selectors become available to the class and its descendents.  A class
can implement an unlimited number of interfaces.  For the problem
discussed above, we would define an interface for the selector(s), and
both classes would implement the interface.

   As an example, consider an interface 'storage' for writing objects to
disk and getting them back, and a class 'foo' that implements it.  The
code would look like this:

     interface
       selector write ( file object -- )
       selector read1 ( file object -- )
     end-interface storage

     bar class
       storage implementation

     ... overrides write
     ... overrides read1
     ...
     end-class foo

(I would add a word 'read' ( file - object ) that uses 'read1'
internally, but that's beyond the point illustrated here.)

   Note that you cannot use 'protected' in an interface; and of course
you cannot define fields.

   In the Neon model, all selectors are available for all classes;
therefore it does not need interfaces.  The price you pay in this model
is slower late binding, and therefore, added complexity to avoid late
binding.

6.26.3.11 'objects.fs' Implementation
.....................................

An object is a piece of memory, like one of the data structures
described with 'struct...end-struct'.  It has a field 'object-map' that
points to the method map for the object's class.

   The _method map_(1) is an array that contains the execution tokens
(xts) of the methods for the object's class.  Each selector contains an
offset into a method map.

   'selector' is a defining word that uses 'CREATE' and 'DOES>'.  The
body of the selector contains the offset; the 'DOES>' action for a class
selector is, basically:

     ( object addr ) @ over object-map @ + @ execute

   Since 'object-map' is the first field of the object, it does not
generate any code.  As you can see, calling a selector has a small,
constant cost.

   A class is basically a 'struct' combined with a method map.  During
the class definition the alignment and size of the class are passed on
the stack, just as with 'struct's, so 'field' can also be used for
defining class fields.  However, passing more items on the stack would
be inconvenient, so 'class' builds a data structure in memory, which is
accessed through the variable 'current-interface'.  After its definition
is complete, the class is represented on the stack by a pointer (e.g.,
as parameter for a child class definition).

   A new class starts off with the alignment and size of its parent, and
a copy of the parent's method map.  Defining new fields extends the size
and alignment; likewise, defining new selectors extends the method map.
'overrides' just stores a new xt in the method map at the offset given
by the selector.

   Class binding just gets the xt at the offset given by the selector
from the class's method map and 'compile,'s (in the case of '[bind]')
it.

   I implemented 'this' as a 'value'.  At the start of an 'm:...;m'
method the old 'this' is stored to the return stack and restored at the
end; and the object on the TOS is stored 'TO this'.  This technique has
one disadvantage: If the user does not leave the method via ';m', but
via 'throw' or 'exit', 'this' is not restored (and 'exit' may crash).
To deal with the 'throw' problem, I have redefined 'catch' to save and
restore 'this'; the same should be done with any word that can catch an
exception.  As for 'exit', I simply forbid it (as a replacement, there
is 'exitm').

   'inst-var' is just the same as 'field', with a different 'DOES>'
action:
     @ this +
   Similar for 'inst-value'.

   Each class also has a word list that contains the words defined with
'inst-var' and 'inst-value', and its protected words.  It also has a
pointer to its parent.  'class' pushes the word lists of the class and
all its ancestors onto the search order stack, and 'end-class' drops
them.

   An interface is like a class without fields, parent and protected
words; i.e., it just has a method map.  If a class implements an
interface, its method map contains a pointer to the method map of the
interface.  The positive offsets in the map are reserved for class
methods, therefore interface map pointers have negative offsets.
Interfaces have offsets that are unique throughout the system, unlike
class selectors, whose offsets are only unique for the classes where the
selector is available (invocable).

   This structure means that interface selectors have to perform one
indirection more than class selectors to find their method.  Their body
contains the interface map pointer offset in the class method map, and
the method offset in the interface method map.  The 'does>' action for
an interface selector is, basically:

     ( object selector-body )
     2dup selector-interface @ ( object selector-body object interface-offset )
     swap object-map @ + @ ( object selector-body map )
     swap selector-offset @ + @ execute

   where 'object-map' and 'selector-offset' are first fields and
generate no code.

   As a concrete example, consider the following code:

     interface
       selector if1sel1
       selector if1sel2
     end-interface if1

     object class
       if1 implementation
       selector cl1sel1
       cell% inst-var cl1iv1

     ' m1 overrides construct
     ' m2 overrides if1sel1
     ' m3 overrides if1sel2
     ' m4 overrides cl1sel2
     end-class cl1

     create obj1 object dict-new drop
     create obj2 cl1    dict-new drop

   The data structure created by this code (including the data structure
for 'object') is shown in the figure (objects-implementation.eps),
assuming a cell size of 4.

   ---------- Footnotes ----------

   (1) This is Self terminology; in C++ terminology: virtual function
table.

6.26.3.12 'objects.fs' Glossary
...............................

'bind' ( ... "class" "selector" - ...  ) objects
   Execute the method for SELECTOR in CLASS.

'<bind>' ( class selector-xt - xt  ) objects "less-bind-to"
   XT is the method for the selector SELECTOR-XT in CLASS.

'bind'' ( "class" "selector" - xt  ) objects "bind-tick"
   XT is the method for SELECTOR in CLASS.

'[bind]' ( compile-time: "class" "selector" - ; run-time: ... object - ...  ) objects "left-bracket-bind-right-bracket"
   Compile the method for SELECTOR in CLASS.

'class' ( parent-class - align offset  ) objects
   Start a new class definition as a child of PARENT-CLASS.  ALIGN
OFFSET are for use by FIELD etc.

'class->map' ( class - map  ) objects "class-to-map"
   MAP is the pointer to CLASS's method map; it points to the place in
the map to which the selector offsets refer (i.e., where OBJECT-MAPs
point to).

'class-inst-size' ( class - addr  ) objects
   Give the size specification for an instance (i.e.  an object) of
CLASS; used as 'class-inst-size 2@ ( class -- align size )'.

'class-override!' ( xt sel-xt class-map -  ) objects "class-override-store"
   XT is the new method for the selector SEL-XT in CLASS-MAP.

'class-previous' ( class -  ) objects
   Drop CLASS's wordlists from the search order.  No checking is made
whether CLASS's wordlists are actually on the search order.

'class>order' ( class -  ) objects "class-to-order"
   Add CLASS's wordlists to the head of the search-order.

'construct' ( ... object -  ) objects
   Initialize the data fields of OBJECT.  The method for the class
OBJECT just does nothing: '( object -- )'.

'current'' ( "selector" - xt  ) objects "current-tick"
   XT is the method for SELECTOR in the current class.

'[current]' ( compile-time: "selector" - ; run-time: ... object - ...  ) objects "left-bracket-current-right-bracket"
   Compile the method for SELECTOR in the current class.

'current-interface' ( - addr  ) objects
   Variable: contains the class or interface currently being defined.

'dict-new' ( ... class - object  ) objects
   'allot' and initialize an object of class CLASS in the dictionary.

'end-class' ( align offset "name" -  ) objects
   NAME execution: '-- class'
End a class definition.  The resulting class is CLASS.

'end-class-noname' ( align offset - class  ) objects
   End a class definition.  The resulting class is CLASS.

'end-interface' ( "name" -  ) objects
   'name' execution: '-- interface'
End an interface definition.  The resulting interface is INTERFACE.

'end-interface-noname' ( - interface  ) objects
   End an interface definition.  The resulting interface is INTERFACE.

'end-methods' ( -  ) objects
   Switch back from defining methods of a class to normal mode
(currently this just restores the old search order).

'exitm' ( -  ) objects
   'exit' from a method; restore old 'this'.

'heap-new' ( ... class - object  ) objects
   'allocate' and initialize an object of class CLASS.

'implementation' ( interface -  ) objects
   The current class implements INTERFACE.  I.e., you can use all
selectors of the interface in the current class and its descendents.

'init-object' ( ... class object -  ) objects
   Initialize a chunk of memory (OBJECT) to an object of class CLASS;
then performs 'construct'.

'inst-value' ( align1 offset1 "name" - align2 offset2  ) objects
   NAME execution: '-- w'
W is the value of the field NAME in 'this' object.

'inst-var' ( align1 offset1 align size "name" - align2 offset2  ) objects
   NAME execution: '-- addr'
ADDR is the address of the field NAME in 'this' object.

'interface' ( -  ) objects
   Start an interface definition.

'm:' ( - xt colon-sys; run-time: object -  ) objects "m-colon"
   Start a method definition; OBJECT becomes new 'this'.

':m' ( "name" - xt; run-time: object -  ) objects "colon-m"
   Start a named method definition; OBJECT becomes new 'this'.  Has to
be ended with ';m'.

';m' ( colon-sys -; run-time: -  ) objects "semicolon-m"
   End a method definition; restore old 'this'.

'method' ( xt "name" -  ) objects
   'name' execution: '... object -- ...'
Create selector NAME and makes XT its method in the current class.

'methods' ( class -  ) objects
   Makes CLASS the current class.  This is intended to be used for
defining methods to override selectors; you cannot define new fields or
selectors.

'object' ( - class  ) objects
   the ancestor of all classes.

'overrides' ( xt "selector" -  ) objects
   replace default method for SELECTOR in the current class with XT.
'overrides' must not be used during an interface definition.

'[parent]' ( compile-time: "selector" - ; run-time: ... object - ...  ) objects "left-bracket-parent-right-bracket"
   Compile the method for SELECTOR in the parent of the current class.

'print' ( object -  ) objects
   Print the object.  The method for the class OBJECT prints the address
of the object and the address of its class.

'protected' ( -  ) objects
   Set the compilation wordlist to the current class's wordlist

'public' ( -  ) objects
   Restore the compilation wordlist that was in effect before the last
'protected' that actually changed the compilation wordlist.

'selector' ( "name" -  ) objects
   NAME execution: '... object -- ...'
Create selector NAME for the current class and its descendents; you can
set a method for the selector in the current class with 'overrides'.

'this' ( - object  ) objects
   the receiving object of the current method (aka active object).

'<to-inst>' ( w xt -  ) objects "less-to-inst-to"
   store W into the field XT in 'this' object.

'[to-inst]' ( compile-time: "name" - ; run-time: w -  ) objects "left-bracket-to-inst-right-bracket"
   store W into field NAME in 'this' object.

'to-this' ( object -  ) objects
   Set 'this' (used internally, but useful when debugging).

'xt-new' ( ... class xt - object  ) objects
   Make a new object, using 'xt ( align size -- addr )' to get memory.

6.26.4 The 'oof.fs' model
-------------------------

This section describes the 'oof.fs' package.

   The package described in this section has been used in bigFORTH since
1991, and used for two large applications: a chromatographic system used
to create new medicaments, and a graphic user interface library (MINOS).

   You can find a description (in German) of 'oof.fs' in 'Object
oriented bigFORTH' by Bernd Paysan, published in 'Vierte Dimension'
10(2), 1994.

6.26.4.1 Properties of the 'oof.fs' model
.........................................

   * This model combines object oriented programming with information
     hiding.  It helps you writing large application, where scoping is
     necessary, because it provides class-oriented scoping.

   * Named objects, object pointers, and object arrays can be created,
     selector invocation uses the "object selector" syntax.  Selector
     invocation to objects and/or selectors on the stack is a bit less
     convenient, but possible.

   * Selector invocation and instance variable usage of the active
     object is straightforward, since both make use of the active
     object.

   * Late binding is efficient and easy to use.

   * State-smart objects parse selectors.  However, extensibility is
     provided using a (parsing) selector 'postpone' and a selector '''.

   * An implementation in Standard Forth is available.

6.26.4.2 Basic 'oof.fs' Usage
.............................

This section uses the same example as for 'objects' (*note Basic Objects
Usage::).

   You can define a class for graphical objects like this:

     object class graphical \ "object" is the parent class
       method draw ( x y -- )
     class;

   This code defines a class 'graphical' with an operation 'draw'.  We
can perform the operation 'draw' on any 'graphical' object, e.g.:

     100 100 t-rex draw

where 't-rex' is an object or object pointer, created with e.g.
'graphical : t-rex'.

   How do we create a graphical object?  With the present definitions,
we cannot create a useful graphical object.  The class 'graphical'
describes graphical objects in general, but not any concrete graphical
object type (C++ users would call it an _abstract class_); e.g., there
is no method for the selector 'draw' in the class 'graphical'.

   For concrete graphical objects, we define child classes of the class
'graphical', e.g.:

     graphical class circle \ "graphical" is the parent class
       cell var circle-radius
     how:
       : draw ( x y -- )
         circle-radius @ draw-circle ;

       : init ( n-radius -- )
         circle-radius ! ;
     class;

   Here we define a class 'circle' as a child of 'graphical', with a
field 'circle-radius'; it defines new methods for the selectors 'draw'
and 'init' ('init' is defined in 'object', the parent class of
'graphical').

   Now we can create a circle in the dictionary with:

     50 circle : my-circle

':' invokes 'init', thus initializing the field 'circle-radius' with 50.
We can draw this new circle at (100,100) with:

     100 100 my-circle draw

   Note: You can only invoke a selector if the receiving object belongs
to the class where the selector was defined or one of its descendents;
e.g., you can invoke 'draw' only for objects belonging to 'graphical' or
its descendents (e.g., 'circle').  The scoping mechanism will check if
you try to invoke a selector that is not defined in this class
hierarchy, so you'll get an error at compilation time.

6.26.4.3 The 'oof.fs' base class
................................

When you define a class, you have to specify a parent class.  So how do
you start defining classes?  There is one class available from the
start: 'object'.  You have to use it as ancestor for all classes.  It is
the only class that has no parent.  Classes are also objects, except
that they don't have instance variables; class manipulation such as
inheritance or changing definitions of a class is handled through
selectors of the class 'object'.

   'object' provides a number of selectors:

   * 'class' for subclassing, 'definitions' to add definitions later on,
     and 'class?' to get type informations (is the class a subclass of
     the class passed on the stack?).

     'object-class' ( "name" -  ) oof

     'object-definitions' ( -  ) oof

     'object-class?' ( o - flag  ) oof "class-query"

   * 'init' and 'dispose' as constructor and destructor of the object.
     'init' is invocated after the object's memory is allocated, while
     'dispose' also handles deallocation.  Thus if you redefine
     'dispose', you have to call the parent's dispose with 'super
     dispose', too.

     'object-init' ( ... -  ) oof

     'object-dispose' ( -  ) oof

   * 'new', 'new[]', ':', 'ptr', 'asptr', and '[]' to create named and
     unnamed objects and object arrays or object pointers.

     'object-new' ( - o  ) oof

     'object-new[]' ( n - o  ) oof "new-array"

     'object-:' ( "name" -  ) oof "define"

     'object-ptr' ( "name" -  ) oof

     'object-asptr' ( o "name" -  ) oof

     'object-[]' ( n "name" -  ) oof "array"

   * '::' and 'super' for explicit scoping.  You should use explicit
     scoping only for super classes or classes with the same set of
     instance variables.  Explicitly-scoped selectors use early binding.

     'object-::' ( "name" -  ) oof "scope"

     'object-super' ( "name" -  ) oof

   * 'self' to get the address of the object

     'object-self' ( - o  ) oof

   * 'bind', 'bound', 'link', and 'is' to assign object pointers and
     instance defers.

     'object-bind' ( o "name" -  ) oof

     'object-bound' ( class addr "name" -  ) oof

     'object-link' ( "name" - class addr  ) oof

     'object-is' ( xt "name" -  ) oof

   * ''' to obtain selector tokens, 'send' to invocate selectors form
     the stack, and 'postpone' to generate selector invocation code.

     'object-'' ( "name" - xt  ) oof "tick"

     'object-postpone' ( "name" -  ) oof

   * 'with' and 'endwith' to select the active object from the stack,
     and enable its scope.  Using 'with' and 'endwith' also allows you
     to create code using selector 'postpone' without being trapped by
     the state-smart objects.

     'object-with' ( o -  ) oof

     'object-endwith' ( -  ) oof

6.26.4.4 Class Declaration
..........................

   * Instance variables

     'var' ( size -  ) oof
     Create an instance variable

   * Object pointers

     'ptr' ( -  ) oof
     Create an instance pointer

     'asptr' ( class -  ) oof
     Create an alias to an instance pointer, cast to another class.

   * Instance defers

     'defer' ( -  ) oof
     Create an instance defer

   * Method selectors

     'early' ( -  ) oof
     Create a method selector for early binding.

     'method' ( -  ) oof
     Create a method selector.

   * Class-wide variables

     'static' ( -  ) oof
     Create a class-wide cell-sized variable.

   * End declaration

     'how:' ( -  ) oof "how-to"
     End declaration, start implementation

     'class;' ( -  ) oof "end-class"
     End class declaration or implementation

6.26.5 The 'mini-oof.fs' model
------------------------------

Gforth's third object oriented Forth package is a 12-liner.  It uses a
mixture of the 'objects.fs' and the 'oof.fs' syntax, and reduces to the
bare minimum of features.  This is based on a posting of Bernd Paysan in
comp.lang.forth.

6.26.5.1 Basic 'mini-oof.fs' Usage
..................................

There is a base class ('class', which allocates one cell for the object
pointer) plus seven other words: to define a method, a variable, a
class; to end a class, to resolve binding, to allocate an object and to
compile a class method.

'object' ( - a-addr  ) mini-oof
   OBJECT is the base class of all objects.

'method' ( m v "name" - m' v  ) mini-oof2
   Define a selector NAME; increments the number of selectors M (in
bytes).

'var' ( m v size "name" - m v'  ) mini-oof2
   define an instance variable with SIZE bytes by the name NAME, and
increments the amount of storage per instance M by SIZE.

'class' ( class - class methods vars  ) mini-oof2
   start a class definition with superclass CLASS, putting the size of
the methods table and instance variable space on the stack.

'end-class' ( class methods vars "name" -  ) mini-oof2
   finishs a class definition and assigns a name NAME to the newly
created class.  Inherited methods are copied from the superclass.

'defines' ( xt class "name" -  ) mini-oof
   Bind XT to the selector NAME in class CLASS.

'new' ( class - o  ) mini-oof
   Create a new incarnation of the class CLASS.

'::' ( class "name" -  ) mini-oof "double-colon"
   Compile the method for the selector NAME of the class CLASS (not
immediate!).

6.26.5.2 Mini-OOF Example
.........................

A short example shows how to use this package.  This example, in
slightly extended form, is supplied as 'moof-exm.fs'

     object class
       method init
       method draw
     end-class graphical

   This code defines a class 'graphical' with an operation 'draw'.  We
can perform the operation 'draw' on any 'graphical' object, e.g.:

     100 100 t-rex draw

   where 't-rex' is an object or object pointer, created with e.g.
'graphical new Constant t-rex'.

   For concrete graphical objects, we define child classes of the class
'graphical', e.g.:

     graphical class
       cell var circle-radius
     end-class circle \ "graphical" is the parent class

     :noname ( x y -- )
       circle-radius @ draw-circle ; circle defines draw
     :noname ( r -- )
       circle-radius ! ; circle defines init

   There is no implicit init method, so we have to define one.  The
creation code of the object now has to call init explicitly.

     circle new Constant my-circle
     50 my-circle init

   It is also possible to add a function to create named objects with
automatic call of 'init', given that all objects have 'init' on the same
place:

     : new: ( .. o "name" -- )
         new dup Constant init ;
     80 circle new: large-circle

   We can draw this new circle at (100,100) with:

     100 100 my-circle draw

6.26.5.3 'mini-oof.fs' Implementation
.....................................

Object-oriented systems with late binding typically use a
"vtable"-approach: the first variable in each object is a pointer to a
table, which contains the methods as function pointers.  The vtable may
also contain other information.

   So first, let's declare selectors:

     : method ( m v "name" -- m' v ) Create  over , swap cell+ swap
       DOES> ( ... o -- ... ) @ over @ + @ execute ;

   During selector declaration, the number of selectors and instance
variables is on the stack (in address units).  'method' creates one
selector and increments the selector number.  To execute a selector, it
takes the object, fetches the vtable pointer, adds the offset, and
executes the method xt stored there.  Each selector takes the object it
is invoked with as top of stack parameter; it passes the parameters
(including the object) unchanged to the appropriate method which should
consume that object.

   Now, we also have to declare instance variables

     : var ( m v size "name" -- m v' ) Create  over , +
       DOES> ( o -- addr ) @ + ;

   As before, a word is created with the current offset.  Instance
variables can have different sizes (cells, floats, doubles, chars), so
all we do is take the size and add it to the offset.  If your machine
has alignment restrictions, put the proper 'aligned' or 'faligned'
before the variable, to adjust the variable offset.  That's why it is on
the top of stack.

   We need a starting point (the base object) and some syntactic sugar:

     Create object  1 cells , 2 cells ,
     : class ( class -- class selectors vars ) dup 2@ ;

   For inheritance, the vtable of the parent object has to be copied
when a new, derived class is declared.  This gives all the methods of
the parent class, which can be overridden, though.

     : end-class  ( class selectors vars "name" -- )
       Create  here >r , dup , 2 cells ?DO ['] noop , 1 cells +LOOP
       cell+ dup cell+ r> rot @ 2 cells /string move ;

   The first line creates the vtable, initialized with 'noop's.  The
second line is the inheritance mechanism, it copies the xts from the
parent vtable.

   We still have no way to define new methods, let's do that now:

     : defines ( xt class "name" -- ) ' >body @ + ! ;

   To allocate a new object, we need a word, too:

     : new ( class -- o )  here over @ allot swap over ! ;

   Sometimes derived classes want to access the method of the parent
object.  There are two ways to achieve this with Mini-OOF: first, you
could use named words, and second, you could look up the vtable of the
parent object.

     : :: ( class "name" -- ) ' >body @ + @ compile, ;

   Nothing can be more confusing than a good example, so here is one.
First let's declare a text object (called 'button'), that stores text
and position:

     object class
       cell var text
       cell var len
       cell var x
       cell var y
       method init
       method draw
     end-class button

Now, implement the two methods, 'draw' and 'init':

     :noname ( o -- )
      >r r@ x @ r@ y @ at-xy  r@ text @ r> len @ type ;
      button defines draw
     :noname ( addr u o -- )
      >r 0 r@ x ! 0 r@ y ! r@ len ! r> text ! ;
      button defines init

To demonstrate inheritance, we define a class 'bold-button', with no new
data and no new selectors:

     button class
     end-class bold-button

     : bold   27 emit ." [1m" ;
     : normal 27 emit ." [0m" ;

The class 'bold-button' has a different draw method to 'button', but the
new method is defined in terms of the draw method for 'button':

     :noname bold [ button :: draw ] normal ; bold-button defines draw

Finally, create two objects and apply selectors:

     button new Constant foo
     s" thin foo" foo init
     page
     foo draw
     bold-button new Constant bar
     s" fat bar" bar init
     1 bar y !
     bar draw

6.26.6 Mini-OOF2
----------------

Mini-OOF2 is very similar to Mini-OOF in many respects, but differs
significantly in a few aspects.  In particular, Mini-OOF2 has a current
object variable, and uses the primitives '>o' and 'o>' to manipulate
that object stack.  All method invocations and instance variable
accesses refer to the current object.

'>o' ( c-addr - r:c-old ) new "to-o"
   Set the current object to C_ADDR, the previous current object is
pushed to the return stack

'o>' ( r:c-addr - ) new "o-restore"
   Restore the previous current object from the return stack

   To ease passing an object pointer to method invocation or instance
variable accesses, the additional recognizer 'rec-moof2' is activated.

'rec-moof2' ( addr u - xt translate-moof2 | 0  ) mini-oof2 "rec-moof-two"
   Very simplistic dot-parser, transforms '.'SELECTOR/IVAR to '>o'
SELECTOR/IVAR 'o>'.

   To assign methods to selectors, use XT CLASS 'is' SELECTOR, so no
'defines' necessary.  For early binding of methods, '[' CLASS '] defers'
SELECTOR is used, no need for '::'.  Instead of writing ':noname' CODE
';' CLASS 'is' SELECTOR, you can also use the syntactic sugar CLASS
':method' SELECTOR CODE ';'.

':method' ( class "name" -  ) gforth-experimental "colon-method"
   define a noname that is assigned to the deferred word NAME in CLASS
at ';'.

6.26.7 Comparison with other object models
------------------------------------------

Many object-oriented Forth extensions have been proposed ('A survey of
object-oriented Forths' (SIGPLAN Notices, April 1996) by Bradford J.
Rodriguez and W. F. S. Poehlman lists 17).  This section discusses the
relation of the object models described here to two well-known and two
closely-related (by the use of method maps) models.  Andras Zsoter
helped us with this section.

   The most popular model currently seems to be the Neon model (see
'Object-oriented programming in ANS Forth' (Forth Dimensions, March
1997) by Andrew McKewan) but this model has a number of limitations (1):

   * It uses a '_selector object_' syntax, which makes it unnatural to
     pass objects on the stack.

   * It requires that the selector parses the input stream (at compile
     time); this leads to reduced extensibility and to bugs that are
     hard to find.

   * It allows using every selector on every object; this eliminates the
     need for interfaces, but makes it harder to create efficient
     implementations.

   Another well-known publication is 'Object-Oriented Forth' (Academic
Press, London, 1987) by Dick Pountain.  However, it is not really about
object-oriented programming, because it hardly deals with late binding.
Instead, it focuses on features like information hiding and overloading
that are characteristic of modular languages like Ada (83).

   In Does late binding have to be slow?
(http://www.forth.org/oopf.html) (Forth Dimensions 18(1) 1996, pages
31-35) Andras Zsoter describes a model that makes heavy use of an active
object (like 'this' in 'objects.fs'): The active object is not only used
for accessing all fields, but also specifies the receiving object of
every selector invocation; you have to change the active object
explicitly with '{ ... }', whereas in 'objects.fs' it changes more or
less implicitly at 'm: ... ;m'.  Such a change at the method entry point
is unnecessary with Zsoter's model, because the receiving object is the
active object already.  On the other hand, the explicit change is
absolutely necessary in that model, because otherwise no one could ever
change the active object.  An Standard Forth implementation of this
model is available through <http://www.forth.org/oopf.html>.

   The 'oof.fs' model combines information hiding and overloading
resolution (by keeping names in various word lists) with object-oriented
programming.  It sets the active object implicitly on method entry, but
also allows explicit changing (with '>o...o>' or with 'with...endwith').
It uses parsing and state-smart objects and classes for resolving
overloading and for early binding: the object or class parses the
selector and determines the method from this.  If the selector is not
parsed by an object or class, it performs a call to the selector for the
active object (late binding), like Zsoter's model.  Fields are always
accessed through the active object.  The big disadvantage of this model
is the parsing and the state-smartness, which reduces extensibility and
increases the opportunities for subtle bugs; essentially, you are only
safe if you never tick or 'postpone' an object or class (Bernd
disagrees, but I (Anton) am not convinced).

   The 'mini-oof.fs' model is quite similar to a very stripped-down
version of the 'objects.fs' model, but syntactically it is a mixture of
the 'objects.fs' and 'oof.fs' models.

   ---------- Footnotes ----------

   (1) A longer version of this critique can be found in 'On
Standardizing Object-Oriented Forth Extensions' (Forth Dimensions, May
1997) by Anton Ertl.

6.27 Closures
=============

Gforth provides flat closures (called closures in the following).
Closures are similar to quotations (*note Quotations::), but the
execution token (xt) that represents a closure does not just refer to
code, but also to data.  Running the code of a closure definition
creates a closure data structure (also referred to as "closure"), that
is represented by an execution token.  The closure data structure needs
to be allocated somewhere, and in Gforth this memory is managed
explicitly.

   As an example, consider a word that sums up the results of a function
'( n -- r)' across a range of input values:

     : sum {: limit start xt -- r :}
       0e limit start ?do
         i xt execute f+
       loop ;

   You can add up the values of the function 1/n for n=1..10 with:

     11 1 [: s>f -1e f** ;] sum f.

   Yes, you can do it shorter and more efficiently with '1/f', but bear
with me.  If you want to add up 1/n^2, you can write

     11 1 [: s>f -2e f** ;] sum f.

   Now if you want to deal with additional exponents and these exponents
are known at compile time, you can create a new quotation for every
exponent.  But you may prefer to provide an exponent and produce an xt
without having to write down a quotation every time.  If the value of
the exponent is only known at run-time, producing such an xt is possible
in Forth, but even more involved, and consumes dictionary memory (with
limited deallocation options).  Closures come to the rescue:

     : 1/n^r ( r -- xt; xt execution: n -- r1 )
       fnegate [f:h ( n -r ) s>f fswap f** ;] ;

     11 1 3e   1/n^r dup >r sum f. r> free-closure
     11 1 0.5e 1/n^r dup >r sum f. r> free-closure

   When '1/n^r' runs, it creates a closure that incorporates a
floating-point number (indicated by the 'f' in '[f:h'), in particular
the value -r.  It also references the code between '[f:h' and ';]'.  The
memory for the closure comes from the heap, i.e.  'allocate'd memory
(indicated by the 'h' in '[f:h').  '1/n^r' produces an xt representing
this closure.  This xt is then passed to 'sum' and 'execute'd there.

   When the closure is executed (in 'sum'), -r is pushed (in addition to
the n that has already been pushed before the 'execute') and the code of
the closure is run.

   The code above shows a pure-stack closure (no locals involved).
Pure-stack closures start with a word with the naming scheme '[T:A'
where the type T can be 'n' (cell), 'd' (double-cell), or 'f' (FP). The
allocator A can be 'l' (local), 'd' (dictionary), 'h' (heap), or 'h1':
'Allocate' the closure on the heap and 'free' it after the first
execution; this is used for passing data to another task with
'send-event' (*note Message queues::).  A pure-stack closure consumes
one T from a stack at closure creation time (when the code containing
the closure definition is run), and pushes an xt.  After creating the
closure, execution continues behind the ';]'.

   When the xt is executed (directly with 'execute' or indirectly
through, e.g., 'compile,' or a deferred word), it pushes the stack item
that was consumed at closure creation time and then runs the code inside
the closure definition (up to the ';]').  You can deallocate
heap-allocated closures with

'free-closure' ( xt -  ) gforth-1.0
   Free the heap-allocated closure xt.

   Like a quotation, a (flat) closure cannot access locals of the
enclosing definition(s).

   The words for starting pure-stack closure definitions are:

'[n:l' ( compilation - colon-sys; run-time: n - xt ; xt execution: - n  ) gforth-1.0 "open-bracket-n-colon-l"

'[d:l' ( compilation - colon-sys; run-time: d - xt ; xt execution: - d  ) gforth-1.0 "open-bracket-d-colon-l"

'[f:l' ( compilation - colon-sys; run-time: r - xt ; xt execution: - r  ) gforth-1.0 "open-bracket-r-colon-l"

'[n:d' ( compilation - colon-sys; run-time: n - xt ; xt execution: - n  ) gforth-1.0 "open-bracket-n-colon-d"

'[d:d' ( compilation - colon-sys; run-time: d - xt ; xt execution: - d  ) gforth-1.0 "open-bracket-d-colon-d"

'[f:d' ( compilation - colon-sys; run-time: r - xt ; xt execution: - r  ) gforth-1.0 "open-bracket-r-colon-d"

'[n:h' ( compilation - colon-sys; run-time: n - xt ; xt execution: - n  ) gforth-1.0 "open-bracket-n-colon-h"

'[d:h' ( compilation - colon-sys; run-time: d - xt ; xt execution: - d  ) gforth-1.0 "open-bracket-d-colon-h"

'[f:h' ( compilation - colon-sys; run-time: r - xt ; xt execution: - r  ) gforth-1.0 "open-bracket-r-colon-h"

'[n:h1' ( compilation - colon-sys; run-time: n - xt ; xt execution: - n  ) gforth-1.0 "open-bracket-n-colon-h1"

'[d:h1' ( compilation - colon-sys; run-time: d - xt ; xt execution: - d  ) gforth-1.0 "open-bracket-d-colon-h1"

'[f:h1' ( compilation - colon-sys; run-time: r - xt ; xt execution: - r  ) gforth-1.0 "open-bracket-r-colon-h1"

   If you want to pass more than one stack item from closure creation to
execution time, defining more such words becomes unwieldy, and the code
inside the closure definition might have to juggle many stack items, so
Gforth does not provide such additional words.  Instead, Gforth offers
flat closures that define locals.  Here's the example above, but using
locals-defining closures:

     : 1/n^r ( r -- xt; xt execution: n -- r1 )
       fnegate [{: f: -r :}h s>f -r f** ;] ;

   The number, types, and order of the locals are used for specifying
how many and which stack items are consumed at closure creation time.
At closure execution time these values become the values of the locals.
The locals definition ends with a word with a naming scheme ':}A', where
A specifies where the closure is allocated: 'l' (local), 'd'
(dictionary), 'h' (heap), or 'h1' (heap, 'free' on first execution).

   Note that the locals are still strictly local to one execution of the
xt, and any changes to the locals (e.g., with 'to') do not change the
values stored in the closure; i.e., in the next execution of the closure
the locals will be initialized with the values that closure creation
consumed.

'[{:' ( compilation - hmaddr u latest wid 0 ; instantiation ... - xt  ) gforth-1.0 "start-closure"
   Starts a closure.  Closures started with '[{:' define locals for use
inside the closure.  The locals-definition part ends with ':}l', ':}h',
':}h1', ':}d' or ':}xt'.  The rest of the closure definition is Forth
code.  The closure ends with ';]'.  When the closure definition is
encountered during execution (closure creation time), the values going
into the locals are consumed, and an execution token (xt) is pushed on
the stack; when that execution token is executed (with 'execute',
through 'compile,' or a deferred word), the code in the closure is
executed (closure execution time).  If the xt of a closure is executed
multiple times, the values of the locals at the start of code execution
are those from closure-creation time, unaffected by any locals-changes
in earlier executions of the closure.

':}l' ( hmaddr u latest latestnt wid 0 a-addr1 u1 ... -  ) gforth-1.0 "close-brace-locals"
   Ends a closure's locals definition.  The closure will be allocated on
the locals stack.

':}d' ( hmaddr u latest latestnt wid 0 a-addr1 u1 ... -  ) gforth-1.0 "colon-close-brace-d"
   Ends a closure's locals definition.  The closure will be allocated in
the dictionary.

':}h' ( hmaddr u latest latestnt wid 0 a-addr1 u1 ... -  ) gforth-1.0 "colon-close-brace-h"
   Ends a closure's locals definition.  At the run-time of the
surrounding definition this allocates the closure on the heap; you are
then responsible for deallocating it with 'free-closure'.

':}h1' ( hmaddr u latest latestnt wid 0 a-addr1 u1 ... -  ) gforth-1.0 "colon-close-brace-h-one"
   Ends a closure's locals definition.  The closure is deallocated after
the first execution, so this is a one-shot closure, particularly useful
in combination with 'send-event' (*note Message queues::).

':}xt' ( hmaddr u latest latestnt wid 0 a-addr1 u1 ... -  ) gforth-1.0 "colon-close-brace-x-t"
   Ends a closure's locals definition.  The closure will be allocated by
the xt on the stack, so the closure's run-time stack effect is '( ...
xt-alloc -- xt-closure )'.

'>addr' ( ... xt - addr  ) gforth-internal "to-addr"
   Obtain the address ADDR of the 'addressable:' value-flavoured word
XT.  For some value-flavoured words, additional inputs may be consumed.

   If you look at closures in other languages (e.g., Scheme), they are
quite different: data is passed by accessing and possibly changing
locals of enclosing definitions (lexical scoping).  Gforth's closures
are based on the flat closures used in the implementation of Scheme, so
by writing the code appropriately (see the following subsections) you
can do the same things with Gforth's closures as with lexical-scoping
closures.

   In our programming we have not missed lexical scoping, except when
trying to convert code (usually textbook examples) coming from another
language.  I.e., in our experience flat closures are as useful and
similarly convenient as lexical scoping.  For comparison, if Gforth
supported lexical scoping instead of flat closures, the definition of
'1/n^r' might look as follows:

     \ this does not work in Gforth:
     : 1/n^r ( r -- xt; xt execution: n -- r1 )
       fnegate {: -r :} [:h s>f -r f** ;] ;

   But if you want to know how to convert lexical scoping to Gforth's
flat closures, the following subsections explain it.

6.27.1 How do I read outer locals?
----------------------------------

As long as you only read the value of locals, you can duplicate them as
needed, so a way to convert an access to an outer local for flat
closures is to just pass the values on the stack to the closures and
define them again as locals there.  Here's an example: Consider the
following code for a hypothetical Gforth with a quotation-like syntax
for lexical-scoping closures:

     \ does not work; [:d would dictionary-allocate the closure
     : ...
       ... {: a b :} ...
       [:d ...
         ... {: c d :} ...
         [:d ... a b c d ... ;]
         ...
       ;]
       ... ;

   you can convert it to flat closures as follows:

     : ...
       ... {: a b :} ...
       a b [{: a b :}d ...
         ... {: c d :} ...
         a b c d [{: a b c d :}d
           ... a b c d ... ;]
         ...
       ;]
       ... ;

   Only those locals that are read in the closure need to be passed in.

   This process is called _closure conversion_ in the programming
language implementation literature.

6.27.2 How do I write outer locals?
-----------------------------------

A local instance that is written and read must exist at only one
location, its home location.  The address of this home location is only
read and can be duplicated and passed around.  A textbook example might
look like this in a hypothetical Gforth with lexical-scoping and
explicit dictionary allocation:

     \ does not work
     : counter ( -- xt-inc xt-val )
       0 {: n :}d
       [:d n 1+ to n ;]
       [:d n ;]
     ;
     \ for usage example see below

   Instead, you allocate the home location, and pass its address around:

     : counter ( -- xt-inc xt-val )
       align here {: np :} 0 , \ home location
       np [{: np :}d 1 np +! ;]
       np [{: np :}d np @ ;]
     ;
     \ usage example
     counter \ first instance
     dup execute . \ prints 0
     over execute
     over execute
     dup execute . \ prints 2
     counter \ second instance
     over execute
     dup execute . \ prints 1
     2swap \ work on first instance again
     dup execute . \ prints 2

   This introduction of a home location is called _assignment
conversion_ in the programming language implementation literature.

   You can also use pure-stack closures in this case:

     : counter ( -- xt-inc xt-val )
       align here {: np :} 0 , \ home location
       np [n:d 1 swap +! ;]
       np [n:d @ ;]
     ;
     \ same usage

   Instead of dictionary allocation you can also 'allocate' on the heap.
For local allocation of the home location you can use variable-flavoured
locals (*note Gforth locals::), but of course then the closures must not
be used after leaving the definition in which the home location is
defined.  E.g.

     : counter-example ( -- )
       0 {: w^ np :} \ home location
       np [n:d 1 swap +! ;]
       np [n:d @ ;]
       dup execute cr .
       over execute
       over execute
       dup execute cr .
       2drop
     ;
     counter-example \ prints 0 and 2

   There is actually rarely a reason to use home locations at all,
because what the textbook examples do with closures and writable locals
can be done in Gforth more directly with structs (*note Structures::) or
objects (*note Object-oriented Forth::), or in the counter example,
simply with 'create':

     : counter ( "name" -- )
       create 0 , ;
     : counter-inc ( addr -- )
       1 swap +! ;
     : counter-val ( addr -- )
       @ ;
     \ usage example
     counter a
     a counter-val . \ prints 0
     a counter-inc
     a counter-inc
     a counter-val . \ prints 2
     counter b
     b counter-inc
     b counter-val . \ prints 1
     a counter-val . \ prints 2

   Still, for dictionary and heap allocation Gforth has a home-location
definition syntax based on the locals-definition syntax.  Here's a
heap-allocation version of 'counter' using closures and the locals-like
home-location syntax:

     : counter ( -- handle xt-inc xt-val )
       0 <{: w^ np :}h
       np [n:h 1 swap +! ;]
       np [n:h @ ;]
       ;> -rot ;
     \ usage example
     counter \ first instance
     dup execute . \ prints 0
     over execute
     over execute
     dup execute . \ prints 2
     counter \ second instance
     over execute
     dup execute . \ prints 1
     free-closure free-closure free throw \ back to first instance
     dup execute . \ prints 2
     free-closure free-clouse free throw

   Here '<{:' starts a locals scope (similar to a closure itself), then
you define (variable-flavoured) locals.  ':}h' (or ':}d') finishes the
locals definition.  Now (and up to ';>') you can use the names of the
defined locals.  Finally, ';>' ends the scope and pushes the start
address of the allocated home-location block (also when using ':}d' for
dictionary allocation), for 'free'ing the home-location block later.

   We have produced no uses of '<{:' and ';>' in the first 6 years that
they were present in (development) Gforth.  We think that the reason is
that one prefers structs or objects for modifiable data.  Therefore, we
intend to remove these words in the future.  If you want to see them
preserved, contact us and make a case for them.

'<{:' ( compilation - colon-sys ; run-time -  ) gforth-obsolete "start-homelocation"
   Starts defining a home location block.

';>' ( compilation colon-sys - ; run-time - addr  ) gforth-obsolete "end-homelocation"
   Ends defining a home location; addr is the start address of the
home-location block (used for deallocation).

6.28 Regular Expressions
========================

Regular expressions are pattern matching algorithms for strings found in
many contemporary languages.  You can add regular expression
functionality to Gforth with 'require regexp.fs'.

   The classical implementation for this pattern matching is a
backtracking algorithm, which is also necessary if you want to have
features like backreferencing.  Gforth implements regular expressions by
providing a language to define backtracking programs for pattern
matching.  Basic element is the control structure 'FORK' ... 'JOIN',
which is a forward call within a word, and therefore allows to code a
lightweight try and fail control structure.

'FORK' ( compilation - orig ; run-time f -  ) gforth-0.7
   AHEAD-like control structure: calls the code after JOIN.

'JOIN' ( orig -  ) gforth-0.7
   THEN-like control structure for FORK

   You can program any sort of arbitrary checks yourself by computing a
flag and '?LEAVE' when the check fails.  Your regular expression code is
enclosed in '((' and '))'.

'((' ( addr u -  ) regexp-pattern "paren-paren"
   start regexp block

'))' ( - flag  ) regexp-pattern "close-paren-close-paren"
   end regexp block

   Pattern matching in regular expressions have character sets as
elements, so a number of functions allow you to create and modify
character sets (called 'charclass').  All characters here are bytes, so
this doesn't extend to unicode characters.

'charclass' ( -  ) regexp-cg
   Create a charclass

'+char' ( char -  ) regexp-cg "plus-char"
   add a char to the current charclass

'-char' ( char -  ) regexp-cg
   remove a char from the current charclass

'..char' ( start end -  ) regexp-cg "dot-dot-char"
   add a range of chars to the current charclass

'+chars' ( addr u -  ) regexp-cg "plus-chars"
   add a string of chars to the current charclass

'+class' ( class -  ) regexp-cg "plus-class"
   union of charclass CLASS and the current charclass

'-class' ( class -  ) regexp-cg
   subtract the charclass CLASS from the current charclass

   There are predefined charclasses and tests for them, and generic
checks.  If a check fails, the next possible alternative of the regular
expression is tried, or a loop is terminated.

'c?' ( addr class -  ) regexp-pattern "c-question"
   check ADDR for membership in charclass CLASS

'-c?' ( addr class -  ) regexp-pattern "-c-question"
   check ADDR for not membership in charclass CLASS

'\d' ( addr - addr'  ) regexp-pattern "backslash-d"
   check for digit

'\s' ( addr - addr'  ) regexp-pattern "backslash-s"
   check for blanks

'.?' ( addr - addr'  ) regexp-pattern "dot-question"
   check for any single charachter

'-\d' ( addr - addr'  ) regexp-pattern "-backslash-d"
   check for not digit

'-\s' ( addr - addr'  ) regexp-pattern "-backslash-s"
   check for not blank

'`' ( "char" -  ) regexp-pattern "backtick"
   check for particular char

'`?' ( "char" -  ) regexp-pattern "backtick-question"

'-`' ( "char" -  ) regexp-pattern "-backtick"
   check for particular char

   You can certainly also check for start and end of the string, and for
whole string constants.

'\^' ( addr - addr  ) regexp-pattern "backslash-caret"
   check for string start

'\$' ( addr - addr  ) regexp-pattern "backslash-dollar"
   check for string end

'str=?' ( addr1 addr u - addr2  ) regexp-pattern "str-equals-question"
   check for a computed string on the stack (possibly a backreference)

'="' ( <string>" -  ) regexp-pattern "equals-quote"
   check for string

   Loops that check for repeated character sets can be greedy or
non-greedy.

'{**' ( addr - addr addr  ) regexp-pattern "begin-greedy-star"
   greedy zero-or-more pattern

'**}' ( sys -  ) regexp-pattern "end-greedy-star"
   end of greedy zero-or-more pattern

'{++' ( addr - addr addr  ) regexp-pattern "begin-greedy-plus"
   greedy one-or-more pattern

'++}' ( sys -  ) regexp-pattern "end-greedy-plus"
   end of greedy one-or-more pattern

'{*' ( addr - addr addr  ) regexp-pattern "begin-non-greedy-star"
   non-greedy zero-or-more pattern

'*}' ( addr addr' - addr'  ) regexp-pattern "end-non-greedy-star"
   end of non-greedy zero-or-more pattern

'{+' ( addr - addr addr  ) regexp-pattern "begin-non-greedy-plus"
   non-greedy one-or-more pattern

'+}' ( addr addr' - addr'  ) regexp-pattern "end-non-greedy-plus"
   end of non-greedy one-or-more pattern

   Example: Searching for a substring really is a non-greedy match of
anything in front of it.

'//' ( -  ) regexp-pattern "slash-slash"
   search for string

   Alternatives are written with

'{{' ( addr - addr addr  ) regexp-pattern "begin-alternatives"
   Start of alternatives

'||' ( addr addr - addr addr  ) regexp-pattern "next-alternative"
   separator between alternatives

'}}' ( addr addr - addr  ) regexp-pattern "end-alternatives"
   end of alternatives

   You can use up to 9 variables named '\1' to '\9' to refer to matched
substrings

'\(' ( addr - addr  ) regexp-pattern "backslash-paren"
   start of matching variable; variables are referred as \\1-9

'\)' ( addr - addr  ) regexp-pattern "backslash-close-paren"
   end of matching variable

'\0' ( - addr u  ) regexp-pattern "backslash-zero"
   the whole string

   Certainly, you can also write code to replace patterns you found.

's>>' ( addr - addr  ) regexp-replace "s-to-to"
   Start replace pattern region

'>>' ( addr - addr  ) regexp-replace "to-to"
   Start arbitrary replacement code, the code shall compute a string on
the stack and pass it to '<<'

'<<' ( run-addr addr u - run-addr  ) regexp-replace "less-less"
   Replace string from start of replace pattern region with ADDR U

'<<"' ( "string<">" -  ) regexp-replace "less-less-quote"
   Replace string from start of replace pattern region with STRING

's//' ( addr u - ptr  ) regexp-replace "s-slash-slash"
   start search/replace loop

'//s' ( ptr -  ) regexp-replace "slash-slash-s"
   search end

'//o' ( ptr addr u - addr' u'  ) regexp-replace "slash-slash-o"
   end search/replace single loop

'//g' ( ptr addr u - addr' u'  ) regexp-replace "slash-slash-g"
   end search/replace all loop

   Examples can be found in 'test/regexp-test.fs'.

6.29 Programming Tools
======================

6.29.1 Locating source code definitions
---------------------------------------

Many programming systems are organized as an integrated development
environment (IDE) where the editor is the hub of the system, and allows
building and running programs.  If you want that, Gforth has it, too
(*note Emacs and Gforth::).

   However, several Forth systems have a different kind of IDE: The
Forth command line is the hub of the environment; you can view the
source from there in various ways, and call an editor if needed.

   Gforth also implements such an IDE. It mostly follows the conventions
of SwiftForth where they exist, but implements features beyond them.

   An advantage of this approach is that it allows you to use your
favourite editor: set the environment variable 'EDITOR' to your
favourite editor, and the editing commands will call that editor; Gforth
invokes some GUI editors in the background (so you do not need to finish
editing to continue with your Forth session), terminal editors in the
foreground (default for editors not known to Gforth is foreground).  If
you have not set 'EDITOR', the default editor is 'vi'.

'locate' ( "name" -  ) gforth-1.0
   Show the source code of the word name and set the current location
there.

'xt-locate' ( nt/xt -  ) gforth-1.0
   Show the source code of the word xt and set the current location
there.

   The _current location_ is set by a number of other words in addition
to 'locate'.  Also, when an error happens while loading a file, the
location of the error becomes the current location.

   A number of words work with the current location:

'l' ( -  ) gforth-1.0
   Display source code lines at the current location.

'n' ( -  ) gforth-1.0
   Display lines behind the current location, or behind the last 'n' or
'b' output (whichever was later).

'b' ( -  ) gforth-1.0
   Display lines before the current location, or before the last 'n' or
'b' output (whichever was later).

'g' ( -  ) gforth-0.7
   Enter the editor at the current location, or at the start of the last
'n' or 'b' output (whichever was later).

   You can control how many lines 'l', 'n' and 'b' show by changing the
values:

'before-locate' ( - u  ) gforth-1.0
   number of lines shown before current location (default 3).

'after-locate' ( - u  ) gforth-1.0
   number of lines shown after current location (default 12).

   Finally, you can directly go to the source code of a word in the
editor with

'edit' ( "name" -  ) gforth-1.0
   Enter the editor at the location of "name"

   You can see the definitions of similarly-named words with

'browse' ( "subname" -  ) gforth-1.0
   Show all places where a word with a name that contains subname is
defined ('mwords'-like, *note Word Lists::).  You can then use 'ww',
'nw' or 'bw' (*note Locating uses of a word::) to inspect specific
occurrences more closely.

6.29.2 Locating uses of a word
------------------------------

'where' ( "name" -  ) gforth-1.0
   Show all places where name is used (text-interpreted).  You can then
use 'ww', 'nw' or 'bw' to inspect specific occurrences more closely.
Gforth's 'where' does not show the definition of name; use 'locate' for
that.

'ww' ( u -  ) gforth-1.0
   The next 'l' or 'g' shows the 'where' result with index u

'nw' ( -  ) gforth-1.0
   The next 'l' or 'g' shows the next 'where' result; if the current one
is the last one, after 'nw' there is no current one.  If there is no
current one, after 'nw' the first one is the current one.

'bw' ( -  ) gforth-1.0
   The next 'l' or 'g' shows the previous 'where' result; if the current
one is the first one, after 'bw' there is no current one.  If there is
no current one, after 'bw' the last one is the current one.

'gg' ( -  ) gforth-1.0
   The next 'ww', 'nw', 'bw', 'bb', 'nb', 'lb' (but not 'locate',
'edit', 'l' or 'g') puts it result in the editor (like 'g').  Use 'gg
gg' to make this permanent rather than one-shot.

'll' ( -  ) gforth-1.0
   The next 'ww', 'nw', 'bw', 'bb', 'nb', 'lb' (but not 'locate',
'edit', 'l' or 'g') displays in the Forth system (like 'l').  Use 'll
ll' to make this permanent rather than one-shot.

'whereg' ( "name" -  ) gforth-1.0
   Like 'where', but puts the output in the editor.  In Emacs, you can
then use the compilation-mode commands (*note (emacs)Compilation Mode::)
to inspect specific occurrences more closely.

'short-where' ( -  ) gforth-1.0
   Set up 'where' to use a short file format (default).

'expand-where' ( -  ) gforth-1.0
   Set up 'where' to use a fully expanded file format (to pass to e.g.
editors).

'prepend-where' ( -  ) gforth-1.0
   Set up 'where' to show the file on a separate line, followed by
'where' lines without file names (like SwiftForth).

   The data we have on word usage also allows us to show which words
have no uses:

'unused-words' ( -  ) gforth-1.0
   list all words without usage

6.29.3 Locating exception source
--------------------------------

'tt' ( u -  ) gforth-1.0

'nt' (  -  ) gforth-1.0

'bt' ( -  ) gforth-1.0

6.29.4 Examining compiled code
------------------------------

And finally, 'see' and friends show compiled code.  Some of the things
in the source code are not present in the compiled code (e.g.,
formatting and comments), but this is useful to see what threaded code
or native code is produced by macros and Gforth's optimization features.

'see' ( "<spaces>name" -  ) tools
   Locate NAME using the current search order.  Display the definition
of NAME.  Since this is achieved by decompiling the definition, the
formatting is mechanised and some source information (comments,
interpreted sequences within definitions etc.)  is lost.

'xt-see' ( xt -  ) gforth-0.2
   Decompile the definition represented by xt.

'simple-see' ( "name" -  ) gforth-0.6
   Decompile the colon definition name, showing a line for each cell,
and try to guess a meaning for the cell, and show that.

'xt-simple-see' ( xt -  ) gforth-1.0
   Decompile the colon definition xt like 'simple-see'

'simple-see-range' ( addr1 addr2 -  ) gforth-0.6
   Decompile code in [addr1,addr2) like 'simple-see'

'see-code' ( "name" -  ) gforth-0.7
   Like 'simple-see', but also shows the dynamic native code for the
inlined primitives.  For static superinstructions, it shows the
primitive sequence instead of the first primitive (the other primitives
of the superinstruction are shown, too).  For primitives for which
native code is generated, it shows the number of stack items in
registers at the beginning and at the end (e.g., '1->1' means 1 stack
item is in a register at the start and at the end).  For each primitive
or superinstruction with native code, the inline arguments and component
primitives are shown first, then the native code.

'xt-see-code' ( xt -  ) gforth-1.0
   Decompile the colon definition xt like 'see-code'.

'see-code-range' ( addr1 addr2 -  ) gforth-0.7
   Decompile code in [addr1,addr2) like 'see-code'.

   As an example, consider:

     : foo x f@ fsin drop over ;

   This is not particularly useful, but it demonstrates the various code
generation differences.  Compiling this on 'gforth-fast' on AMD64 and
then using 'see-code foo' outputs:

     $7FD0CEE8C510 lit f@     1->1
     $7FD0CEE8C518 x
     $7FD0CEE8C520 f@
     7FD0CEB51697:   movsd   [r12],xmm15
     7FD0CEB5169D:   mov     rax,$00[r13]
     7FD0CEB516A1:   sub     r12,$08
     7FD0CEB516A5:   add     r13,$18
     7FD0CEB516A9:   movsd   xmm15,[rax]
     7FD0CEB516AE:   mov     rcx,-$08[r13]
     7FD0CEB516B2:   jmp     ecx
     $7FD0CEE8C528 fsin
     $7FD0CEE8C530 drop    1->0
     7FD0CEB516B4:   add     r13,$08
     $7FD0CEE8C538 over    0->1
     7FD0CEB516B8:   mov     r8,$10[r15]
     7FD0CEB516BC:   add     r13,$08
     $7FD0CEE8C540 ;s    1->1
     7FD0CEB516C0:   mov     r10,[rbx]
     7FD0CEB516C3:   add     rbx,$08
     7FD0CEB516C7:   lea     r13,$08[r10]
     7FD0CEB516CB:   mov     rcx,-$08[r13]
     7FD0CEB516CF:   jmp     ecx

   First, you see a threaded-code cell for a static superinstruction
with the components 'lit' and 'f@', starting and ending with one data
stack item in a register ('1->1'); this is followed by the cell for the
argument 'x' of 'lit', and the cell for the 'f@' component of the
superinstruction; the latter cell is not used, but is there for
Gforth-internal reasons.

   Next, the dynamically generated native code for the superinstruction
'lit f@' is shown; note that this native code is not mixed with the
threaded code in memory, as you can see by comparing the addresses.

   If you want to understand the native code shown here: the
threaded-code instruction pointer is in 'r13', the data stack pointer in
'r15'; the first data stack register is 'r8' (i.e., the top of stack
resides there if there is one data stack item in a register); the return
stack pointer is in 'rbx', the FP stack pointer in 'r12', and the top of
the floating-pont stack in 'xmm15'.  Note that the register assignments
vary between engines, so you may see a different register assignment for
this code.

   The dynamic native code for 'lit f@' ends with a dispatch jump (aka
NEXT), because the code for the next word 'fsin' in the definition is
not dynamically generated.

   Next, you see the threaded-code cell for 'fsin'.  There is no
dynamically-generated native code for this word, and 'see-code' does not
show the static native code for it (you can look at it with 'see fsin').
Like all words with static native code in 'gforth-fast', the effect on
the data stack representation is '1->1' (for 'gforth', '0->0'), but this
is not shown.

   Next, you see the threaded-code cell for 'drop'; the native-code
variant used here starts with one data stack item in registers, and ends
with zero data stack items in registers ('1->0').  This is followed by
the native code for this variant of 'drop'.  There is no NEXT here,
because the native code falls through to the code for the next word.

   Next, you see the threaded-code cell for 'over' followed by the
dynamically-generated native code in the '0->1' variant.

   Finally, you see the threaded and native code for ';s' (the primitive
compiled for ';' in 'foo').  ';s' performs control flow (it returns), so
it has to end with a NEXT.

6.29.5 Examining data
---------------------

The following words inspect the stack non-destructively:

'...' ( x1 .. xn - x1 .. xn  ) gforth-1.0 "dot-dot-dot"
   smart version of '.s'

'.s' ( -  ) tools "dot-s"
   Display the number of items on the data stack, followed by a list of
the items (but not more than specified by 'maxdepth-.s'; TOS is the
right-most item.

'f.s' ( -  ) gforth-0.2 "f-dot-s"
   Display the number of items on the floating-point stack, followed by
a list of the items (but not more than specified by 'maxdepth-.s'; TOS
is the right-most item.

'f.s-precision' ( - u  ) gforth-1.0 "f-dot-s-precision"
   A 'value'.  U is the field width for f.s output.  Other precision
details are derived from that value.

'maxdepth-.s' ( - addr  ) gforth-0.2 "maxdepth-dot-s"
   A variable containing 9 by default.  '.s' and 'f.s' display at most
that many stack items.

   There is a word '.r' but it does not display the return stack!  It is
used for formatted numeric output (*note Simple numeric output::).

   The following words work on the stack as a whole, either by
determining the depth or by clearing them:

'depth' ( - +n  ) core "depth"
   +N is the number of values that were on the data stack before +N
itself was placed on the stack.

'fdepth' ( - +n  ) floating "f-depth"
   +n is the current number of (floating-point) values on the
floating-point stack.

'clearstack' ( ... -  ) gforth-0.2 "clear-stack"
   remove and discard all/any items from the data stack.

'fclearstack' ( r0 .. rn -  ) gforth-1.0 "f-clearstack"
   clear the floating point stack

'clearstacks' ( ... -  ) gforth-0.7 "clear-stacks"
   empty data and FP stack

   The following words inspect memory.

'?' ( a-addr -  ) tools "question"
   Display the contents of address A-ADDR in the current number base.

'dump' ( addr u -  ) tools "dump"
   Display U lines of memory starting at address ADDR.  Each line
displays the contents of 16 bytes.  When Gforth is running under an
operating system you may get 'Invalid memory address' errors if you
attempt to access arbitrary locations.

6.29.6 Forgetting words
-----------------------

Forth allows you to forget words (and everything that was allotted in
the dictionary after them) in a LIFO manner.

'marker' ( "<spaces> name" -  ) core-ext
   Create a definition, name (called a mark) whose execution semantics
are to remove itself and everything defined after it.

   The most common use of this feature is during program development:
when you change a source file, forget all the words it defined and load
it again (since you also forget everything defined after the source file
was loaded, you have to reload that, too).  Note that effects like
storing to variables and destroyed system words are not undone when you
forget words.  With a system like Gforth, that is fast enough at
starting up and compiling, I find it more convenient to exit and restart
Gforth, as this gives me a clean slate.

   Here's an example of using 'marker' at the start of a source file
that you are debugging; it ensures that you only ever have one copy of
the file's definitions compiled at any time:

     [IFDEF] my-code
         my-code
     [THEN]

     marker my-code
     init-included-files

     \ .. definitions start here
     \ .
     \ .
     \ end

6.29.7 Debugging
----------------

Languages with a slow edit/compile/link/test development loop tend to
require sophisticated tracing/stepping debuggers to facilate debugging.

   A much better (faster) way in fast-compiling languages is to add
printing code at well-selected places, let the program run, look at the
output, see where things went wrong, add more printing code, etc., until
the bug is found.

   The simple debugging aids provided in 'debugs.fs' are meant to
support this style of debugging.

   The word '~~' prints debugging information (by default the source
location and the stack contents).  It is easy to insert.  If you use
Emacs it is also easy to remove ('C-x ~' in the Emacs Forth mode to
query-replace them with nothing).  The deferred words 'printdebugdata'
and '.debugline' control the output of '~~'.  The default source
location output format works well with Emacs' compilation mode, so you
can step through the program at the source level using 'C-x `' (the
advantage over a stepping debugger is that you can step in any direction
and you know where the crash has happened or where the strange data has
occurred).

'~~' ( -  ) gforth-0.2 "tilde-tilde"
   Prints the source code location of the '~~' and the stack contents
with '.debugline'.

'printdebugdata' ( -  ) gforth-0.2 "print-debug-data"

'.debugline' ( nfile nline -  ) gforth-0.6 "print-debug-line"
   Print the source code location indicated by NFILE NLINE, and
additional debugging information; the default '.debugline' prints the
additional information with 'printdebugdata'.

'debug-fid' ( - file-id  ) gforth-1.0 "File-id"
   debugging words for output.  By default it is the process's 'stderr'.

   '~~' (and assertions) will usually print the wrong file name if a
marker is executed in the same file after their occurrence.  They will
print '*somewhere*' as file name if a marker is executed in the same
file before their occurrence.

'once' ( -  ) gforth-1.0
   do the following up to THEN only once

'~~bt' ( -  ) gforth-1.0 "tilde-tilde-bt"
   print stackdump and backtrace

'~~1bt' ( -  ) gforth-1.0 "tilde-tilde-one-bt"
   print stackdump and backtrace once

'???' ( -  ) gforth-0.2 "question-question-question"
   Open a debuging shell

'WTF??' ( -  ) gforth-1.0 "WTF-question-question"
   Open a debugging shell with backtrace and stack dump

'!!FIXME!!' ( -  ) gforth-1.0 "store-store-FIXME-store-store"
   word that should never be reached

'replace-word' ( xt1 xt2 -  ) gforth-1.0
   make xt2 do xt1, both need to be colon definitions

'~~Variable' ( "name" -  ) gforth-1.0 "tilde-tilde-Variable"
   Variable that will be watched on every access

'~~Value' ( n "name" -  ) gforth-1.0 "tilde-tilde-Value"
   Value that will be watched on every access

'+ltrace' ( -  ) gforth-1.0 "plus-ltrace"
   turn on line tracing

'-ltrace' ( -  ) gforth-1.0
   turn off line tracing

'#loc' ( nline nchar "file" -  ) gforth-1.0 "number-loc"
   set next word's location to NLINE NCHAR in "FILE"

6.29.8 Assertions
-----------------

It is a good idea to make your programs self-checking, especially if you
make an assumption that may become invalid during maintenance (for
example, that a certain field of a data structure is never zero).
Gforth supports "assertions" for this purpose.  They are used like this:

     assert( flag )

   The code between 'assert(' and ')' should compute a flag, that should
be true if everything is alright and false otherwise.  It should not
change anything else on the stack.  The overall stack effect of the
assertion is '( -- )'.  E.g.

     assert( 1 1 + 2 = ) \ what we learn in school
     assert( dup 0<> ) \ assert that the top of stack is not zero
     assert( false ) \ this code should not be reached

   The need for assertions is different at different times.  During
debugging, we want more checking, in production we sometimes care more
for speed.  Therefore, assertions can be turned off, i.e., the assertion
becomes a comment.  Depending on the importance of an assertion and the
time it takes to check it, you may want to turn off some assertions and
keep others turned on.  Gforth provides several levels of assertions for
this purpose:

'assert0(' ( -  ) gforth-0.2 "assert-zero"
   Important assertions that should always be turned on.

'assert1(' ( -  ) gforth-0.2 "assert-one"
   Normal assertions; turned on by default.

'assert2(' ( -  ) gforth-0.2 "assert-two"
   Debugging assertions.

'assert3(' ( -  ) gforth-0.2 "assert-three"
   Slow assertions that you may not want to turn on in normal debugging;
you would turn them on mainly for thorough checking.

'assert(' ( -  ) gforth-0.2 "assert-paren"
   Equivalent to 'assert1('

')' ( -  ) gforth-0.2 "close-paren"
   End an assertion.  Generic end, can be used for other similar
purposes

   The variable 'assert-level' specifies the highest assertions that are
turned on.  I.e., at the default 'assert-level' of one, 'assert0(' and
'assert1(' assertions perform checking, while 'assert2(' and 'assert3('
assertions are treated as comments.

   The value of 'assert-level' is evaluated at compile-time, not at
run-time.  Therefore you cannot turn assertions on or off at run-time;
you have to set the 'assert-level' appropriately before compiling a
piece of code.  You can compile different pieces of code at different
'assert-level's (e.g., a trusted library at level 1 and newly-written
code at level 3).

'assert-level' ( - a-addr  ) gforth-0.2
   All assertions above this level are turned off.

   If an assertion fails, a message compatible with Emacs' compilation
mode is produced and the execution is aborted (currently with 'ABORT"'.
If there is interest, we will introduce a special throw code.  But if
you intend to 'catch' a specific condition, using 'throw' is probably
more appropriate than an assertion).

   Assertions (and '~~') will usually print the wrong file name if a
marker is executed in the same file after their occurrence.  They will
print '*somewhere*' as file name if a marker is executed in the same
file before their occurrence.

   Definitions in Standard Forth for these assertion words are provided
in 'compat/assert.fs'.

6.29.9 Singlestep Debugger
--------------------------

The singlestep debugger works only with the engine 'gforth-itc'.

   When you create a new word there's often the need to check whether it
behaves correctly or not.  You can do this by typing 'dbg badword'.  A
debug session might look like this:

     : badword 0 DO i . LOOP ;  ok
     2 dbg badword
     : badword
     Scanning code...

     Nesting debugger ready!

     400D4738  8049BC4 0              -> [ 2 ] 00002 00000
     400D4740  8049F68 DO             -> [ 0 ]
     400D4744  804A0C8 i              -> [ 1 ] 00000
     400D4748 400C5E60 .              -> 0 [ 0 ]
     400D474C  8049D0C LOOP           -> [ 0 ]
     400D4744  804A0C8 i              -> [ 1 ] 00001
     400D4748 400C5E60 .              -> 1 [ 0 ]
     400D474C  8049D0C LOOP           -> [ 0 ]
     400D4758  804B384 ;              ->  ok

   Each line displayed is one step.  You always have to hit return to
execute the next word that is displayed.  If you don't want to execute
the next word in a whole, you have to type 'n' for 'nest'.  Here is an
overview what keys are available:

<RET>
     Next; Execute the next word.

n
     Nest; Single step through next word.

u
     Unnest; Stop debugging and execute rest of word.  If we got to this
     word with nest, continue debugging with the calling word.

d
     Done; Stop debugging and execute rest.

s
     Stop; Abort immediately.

   Debugging large application with this mechanism is very difficult,
because you have to nest very deeply into the program before the
interesting part begins.  This takes a lot of time.

   To do it more directly put a 'BREAK:' command into your source code.
When program execution reaches 'BREAK:' the single step debugger is
invoked and you have all the features described above.

   If you have more than one part to debug it is useful to know where
the program has stopped at the moment.  You can do this by the 'BREAK"
string"' command.  This behaves like 'BREAK:' except that string is
typed out when the "breakpoint" is reached.

'dbg' ( "name" -  ) gforth-0.2

'break:' ( -  ) gforth-0.4 "break-colon"

'break"' ( 'ccc"' -  ) gforth-0.4 "break-quote"

6.29.10 Code Coverage and Execution Frequency
---------------------------------------------

If you run extensive tests on your code, you often want to figure out if
the tests exercise all parts of the code.  This is called (test)
coverage.  The file 'coverage.fs' contains tools for measuring the
coverage as well as execution frequency.

   Code coverage inserts counting code in every basic block
(straight-line code sequence) loaded after 'coverage.fs'.  Each time
that code is run, it increments the counter for that basic block.  Later
you can show the source file with the counts inserted in these basic
blocks.

'nocov[' ( -  ) gforth-1.0 "nocov-bracket"
   (Immediate) Turn coverage off temporarily.

']nocov' ( -  ) gforth-1.0 "bracket-nocov"
   (Immediate) End of temporary turned off coverage.

'coverage?' ( - f  ) gforth-internal "coverage-question"
   Value: Coverage check on/off

'cov+' ( -  ) gforth-experimental "cov-plus"
   (Immediate) Place a coverage counter here.

'?cov+' ( flag - flag  ) gforth-experimental "question-cov-plus"
   (Immediate) A coverage counter for a flag; in the coverage output you
see three numbers behind '?cov': The first is the number of executions
where the top-of-stack was non-zero; the second is the number of
executions where it was zero; the third is the total number of
executions.

'.coverage' ( -  ) gforth-experimental "dot-coverage"
   Show code with execution frequencies.

'annotate-cov' ( -  ) gforth-experimental
   For every file with coverage information, produce a '.cov' file that
has the execution frequencies inserted.  We recommend to use 'bw-cover'
first (with the default 'color-cover' you get escape sequences in the
files).

'cov%' ( -  ) gforth-experimental "cov-percent"
   Print the percentage of basic blocks loaded after 'coverage.fs' that
are executed at least once.

'.cover-raw' ( -  ) gforth-experimental "dot-cover-raw"
   Print raw execution counts.

   By default, the counts are shown in colour (using ANSI escape
sequences), but you can use 'bw-cover' to show them in parenthesized
form without escape sequences.

'bw-cover' ( -  ) gforth-1.0
   Print execution counts in parentheses (source-code compatible).

'color-cover' ( -  ) gforth-1.0
   Print execution counts in colours (default).

   You can save and reload the coverage counters in binary format, to
aggregate coverage counters across several test runs of the same
program.

'save-cov' ( -  ) gforth-experimental
   Save coverage counters.

'load-cov' ( -  ) gforth-experimental
   Load coverage counters.

'cover-filename' ( - c-addr u  ) gforth-experimental
   C-addr u is the file name of the file that is used by 'save-cov' and
'load-cov'.  The file name depends on the code compiled since
'coverage.fs' was loaded.

6.30 Multitasker
================

Gforth offers two multitaskers: a traditional, cooperative round-robin
multitasker, and a pthread-based multitasker which allows to run several
threads concurrently on multi-core machines.  The pthread-based is now
marked as experimental feature, as standardization of Forth multitaskers
will likely change the names of words without changing their semantics.

6.30.1 Pthreads
---------------

Posix threads can run in parallel on several cores, or with pre-emptive
multitasking on onecore.  However, many of the following words are the
same as in the traditional cooperative multi-tasker.

   In addition, there are words that allow you to make sure that only
one task at a time changes something, and for communicating between
tasks.  These words are necessary for pre-emptive and multi-core
multi-tasking, because the cooperative-multitasking way of performing
transactions between calls to 'pause' does not work in this environment.

6.30.1.1 Basic multi-tasking
............................

Tasks can be created with 'newtask' or 'newtask4' with a given amount of
stack space (either all the same or each stack's size specified).

'newtask' ( stacksize - task  ) gforth-experimental
   creates task; each stack (data, return, FP, locals) has size
stacksize.

'task' ( ustacksize "name" -  ) gforth-experimental
   creates a task name; each stack (data, return, FP, locals) has size
ustacksize.
name execution: ( - task )

'newtask4' ( u-data u-return u-fp u-locals - task  ) gforth-experimental "newtask-four"
   creates task with data stack size u-data, return stack size u-return,
FP stack size u-fp and locals stack size u-locals.

   If you don't know which stack sizes to use for the task, you can use
the size(s) of the main task:

'stacksize' ( - u  ) gforth-experimental
   u is the data stack size of the main task.

'stacksize4' ( - u-data u-return u-fp u-locals  ) gforth-experimental "stacksize-four"
   Pushes the data, return, FP, and locals stack sizes of the main task.

   A task is created in an inactive state.  To let it run, you have to
activate it with one of the following words:

'initiate' ( xt task -  ) gforth-experimental
   Let task execute xt.  Upon return from the xt, the task terminates
itself (VFX compatible).  Use one-time executable closures to pass
arbitrary paramenters to a task.

   The following legacy words provide the same functionality as
'initiate', but with a different interface: Like 'does>', they split
their containing colon definition in two parts: The part before
'activate'/'pass' runs in the activating task, and returns to its caller
after activating the task.  The part behind 'activate'/'pass' is
executed in the activated target task.

'activate' ( run-time nest-sys1 task -  ) gforth-experimental
   Let task perform the code behind 'activate', and return to the caller
of the word containing 'activate'.  When the task returns from the code
behind 'activate', it terminates itself.

'pass' ( x1 .. xn n task -  ) gforth-experimental
   Pull x1 ..  xn n from the current task's data stack and push x1 ..
xn on task's data stack.  Let task perform the code behind 'pass', and
return to the caller of the word containing 'pass'.  When the task
returns from the code behind 'pass', it terminates itself.

   You can also do creation and activation in one step:

'execute-task' ( xt - task  ) gforth-experimental
   Create a new task TASK with the same stack sizes as the main task.
Let task execute xt.  Upon return from the xt, the task terminates
itself.

   Apart from terminating by running to the end, a task can terminate
itself with 'kill-task'.  Other tasks can terminate it with 'kill'.

'kill-task' ( -  ) gforth-experimental
   Terminate the current task.

'kill' ( task -  ) gforth-experimental
   Terminate task.

   Tasks can also temporarily stop themselves or be stopped:

'halt' ( task -  ) gforth-experimental
   Stop task (no difference from 'sleep')

'sleep' ( task -  ) gforth-experimental
   Stop task (no difference from 'halt')

'stop' ( -  ) gforth-experimental
   stops the current task, and waits for events (which may restart it)

'stop-ns' ( timeout -  ) gforth-experimental
   Stop with timeout (in nanoseconds), better replacement for ms

'stop-dns' ( dtimeout -  ) gforth-experimental
   Stop with timeout (in nanoseconds), better replacement for ms Stop
with dtimeout (in nanoseconds), better replacement for ms

'thread-deadline' ( d -  ) gforth-experimental
   stop until absolute time D in nanoseconds, base is 1970-1-1 0:00 UTC,
but you usually will want to base your deadlines on a time you get with
'ntime'.

   Using 'stop-dns' is easier to code, but if you want your task to wake
up at regular intervals rather than some time after it finished its last
piece of work, the way to go is to work with deadlines.

   A task restarts when the timeout is over or when another task wakes
it with:

'wake' ( task -  ) gforth-experimental
   Wake task

'restart' ( task -  ) gforth-experimental
   Wake task (no difference from 'wake')

   There is also:

'pause' ( -  ) gforth-experimental
   voluntarily switch to the next waiting task ('pause' is the
traditional cooperative task switcher; in the pthread multitasker, you
don't need 'pause' for cooperation, but you still can use it e.g.  when
you have to resort to polling for some reason).  This also checks for
events in the queue.

6.30.1.2 Task-local data
........................

In Forth every task has essentially the same task-local data, called
"user" area (early Forth systems were multi-user systems and there often
was one user per task).  The task result of, e.g.  'newtask' is the
start address of its user area.  Each task gets the user data defined by
the system (e.g., 'base').  You can define additional user data with:

'User' ( "name" -  ) gforth-0.2
   Name is a user variable (1 cell).
Name execution: ( - addr )
Addr is the address of the user variable in the current task.

'AUser' ( "name" -  ) gforth-0.2
   Name is a user variable containing an address (this only makes a
difference in the cross-compiler).

'uallot' ( n1 - n2  ) gforth-0.3
   Reserve n1 bytes of user data.  n2 is the offset of the start of the
reserved area within the user area.

'UValue' ( "name" -  ) gforth-1.0
   Name is a user value.
Name execution: ( - x )

'UDefer' ( "name" -  ) gforth-1.0
   Name is a task-local deferred word.
Name execution: ( ...  - ...  )

   There are also the following words for dealing with user data.

'up@' ( - a-addr ) new "up-fetch"
   Addr is the start of the user area of the current task (addr also
serves as the task identifier of the current task).

'user'' ( "name" - u  ) gforth-experimental "user-tick"
   U is the offset of the user variable name in the user area of each
task.

''s' ( addr1 task - addr2  ) gforth-experimental "tick-s"
   With addr1 being an address in the user data of the current task,
addr2 is the corresponding address in task's user data.

   The pictured numeric output buffer is also task-local, but other
areas like dictionary or 'PAD' are shared.

6.30.1.3 Semaphores
...................

A cooperative multitasker can ensure that there is no other task
interacting between two invocations of 'pause'.  Pthreads however are
really concurrent tasks (at least on a multi-core CPU), and therefore,
several techniques to avoid conflicts when accessing the same resources.

   Semaphores can only be acquired by one thread, all other threads have
to wait until the semapohre is released.

'semaphore' ( "name" -  ) gforth-experimental
   create a named semaphore name
name execution: ( - semaphore )

'lock' ( semaphore -  ) gforth-experimental
   lock the semaphore

'unlock' ( semaphore -  ) gforth-experimental
   unlock the semaphore

   The other approach to prevent concurrent access is the critical
section.  Here, we implement a critical section with a semaphore, so you
have to specify the semaphore which is used for the critical section.
Only those critical sections which use the same semaphore are mutually
exclusive.

'critical-section' ( xt semaphore -  ) gforth-experimental
   Execute xt while locking semaphore.  After leaving xt, semaphore is
unlocked even if an exception is thrown.

6.30.1.4 Hardware operations for multi-tasking
..............................................

Atomic hardware operations perform the whole operation, without any
other task seeing an intermediate state.  These operations can be used
to synchronize tasks without using slow OS primitives, but compared to
the non-atomic sequences of operations they tend to be slow.  Atomic
operations only work correctly on aligned addresses, even on hardware
that otherwise does not require alignment.

'atomic!@' ( w1 a-addr - w2 ) gforth-experimental "atomic-store-fetch"
   Fetch W2 from A_ADDR, then store W1 there, combined into an atomic
operation.

'atomic+!@' ( u1 a-addr - u2 ) gforth-experimental "atomic-plus-store-fetch"
   Fetch W2 from A_ADDR, then increment this location by U1.  This
atomic operation is commonly known as fetch-and-add.

'atomic?!@' ( unew uold a-addr - uprev ) gforth-experimental "atomic-question-store-fetch"
   Fetch UPREV from A_ADDR, compare it to UOLD, and if equal, store UNEW
there.  This atomic operation is commonly known as compare-and-swap.

   There are also the non-atomic '!@' and '+!@' (otherwise the same
behaviour, *note Memory Access::).

   Another hardware operation is the memory barrier.  Unfortunately
modern hardware often can reorder memory operations relative to other
memory operations (as seen by a different core), and the memory barrier
suppresses this reordering for one point in the execution of the task.

'barrier' ( - ) gforth-experimental "barrier"
   All memory operations before the barrier are performed before any
memory operation after the barrier.

6.30.1.5 Message queues
.......................

Gforth's message queues are a variant of the actor model.

   The sending task tells the receiving task to execute an xt with the
stack effect '( -- )' (an _event_ in the name of the words below; the
actor model would call these xts _messages_), and when the receiving
task is ready, it will execute the xt, possibly after other xts from its
message queue.

   The execution order between xts from different tasks is arbitrary,
the order between xts from the same task is the sending order.

   In many cases you do not just want to pass the xts of existing words,
but also parameters.  You can construct execute-once closures (defined
using ':}h1', *note Closures::) to achieve that, e.g., with

     : .-in-task ( n task -- )
       >r [{: n :}h1 n . ;] r> send-event ;

     5 my-task .-in-task \ my-task prints 5

'send-event' ( xt task -  ) gforth-experimental
   Inter-task communication: send XT '( -- )' to TASK.  TASK executes
the xt at some later point in time.  To pass parameters, construct a
one-shot closure that contains the parameters (*note Closures::) and
pass the xt of that closure.

   In order to execute xts received from other tasks, perform one of the
following words in the receiving task:

'?events' ( -  ) gforth-experimental "question-events"
   Execute all event xts in the current task's message queue, one xt at
a time.

'event-loop' ( -  ) gforth-experimental
   Wait for event xts and execute these xts when they arrive, one at a
time.  Return to waiting if no event xts are in the queue.  This word
never returns.

   Alternatively, when a task is 'stop'ped, it is also ready for
receiving xts, and receiving an xt will not just execute the xt, but
also continue execution after the 'stop'.

6.30.2 Cilk
-----------

Gforth's Cilk is a framework for dividing work between multiple tasks
running on several cores, inspired by the programming language of the
same name.  Use 'require cilk.fs' if you want to use Cilk.

   The idea is that you identify subproblems that can be solved in
parallel, and the framework assigns worker tasks to these subproblems.
In particular, you use one of the 'spawn' words for each subtask.
Eventually you need to wait with 'cilk-sync' for the subproblems to be
solved.

   Currently all the spawning has to happen from one task, and
'cilk-sync' waits for all subproblems to complete, so using the current
Gforth Cilk for recursive algorithms is not straightforward.

   Do not divide the subproblems too finely, in order to avoid overhead;
how fine is too fine depends on how uniform the run-time for the
subproblems is, but for problems with substantial run-time, having
5*'cores' subproblems is probably a good starting point.

'cores' ( - u  ) cilk
   A value containing the number of worker tasks to use.  By default
this is the number of hardware threads (with SMT/HT), if we can
determine that, otherwise 1.  If you want to use a different number,
change 'cores' before calling 'cilk-init'.

'cilk-init' ( -  ) cilk
   Start the worker tasks if not already done.

'spawn' ( xt -  ) cilk
   Execute xt ( - ) in a worker task.  Use one-time executable closures
to pass heap-allocated closures, allowing to pass arbitrary data from
the spawner to the code running in the worker.
E.g.: '( n r ) [{: n f: r :}h1 code ;] spawn'

'spawn1' ( x xt -  ) cilk "spawn-one"
   Execute xt ( x - ) in a worker task.

'spawn2' ( x1 x2 xt -  ) cilk "spawn-two"
   Execute xt ( x1 x2 - ) in a worker task.

'cilk-sync' ( -  ) cilk
   Wait for all subproblems to complete.

'cilk-bye' ( -  ) cilk
   Terminate all workers.

6.31 C Interface
================

Gforth's C interface works by compiling a wrapper library that contains
C functions which take parameters from the Forth stacks and calls the C
functions.  This wrapper library is compiled by the C compiler.
Compilation results are cached, so that Gforth only needs to rerun the C
compilation if the wrapper library has to change.  This build process is
automatic, and done at the end of a interface declaration.  Gforth uses
libtool and GCC for that process.

   The C interface is now mostly complete, callbacks have been added,
but for structs, we use Forth2012 structs, which don't have independent
scopes.  The offsets of those structs are extracted from header files
with a SWIG plugin.

6.31.1 Calling C functions
--------------------------

Once a C function is declared (see *note Declaring C Functions::), you
can call it as follows: You push the arguments on the stack(s), and then
call the word for the C function.  The arguments have to be pushed in
the same order as the arguments appear in the C documentation (i.e., the
first argument is deepest on the stack).  Integer and pointer arguments
have to be pushed on the data stack, floating-point arguments on the FP
stack; these arguments are consumed by the called C function.

   On returning from the C function, the return value, if any, resides
on the appropriate stack: an integer return value is pushed on the data
stack, an FP return value on the FP stack, and a void return value
results in not pushing anything.  Note that most C functions have a
return value, even if that is often not used in C; in Forth, you have to
'drop' this return value explicitly if you do not use it.

   The C interface automatically converts between the C type and the
Forth type as necessary, on a best-effort basis (in some cases, there
may be some loss).

   As an example, consider the POSIX function 'lseek()':

     off_t lseek(int fd, off_t offset, int whence);

   This function takes three integer arguments, and returns an integer
argument, so a Forth call for setting the current file offset to the
start of the file could look like this:

     fd @ 0 SEEK_SET lseek -1 = if
       ... \ error handling
     then

   You might be worried that an 'off_t' does not fit into a cell, so you
could not pass larger offsets to lseek, and might get only a part of the
return values.  In that case, in your declaration of the function (*note
Declaring C Functions::) you should declare it to use double-cells for
the off_t argument and return value, and maybe give the resulting Forth
word a different name, like 'dlseek'; the result could be called like
this:

     fd @ 0. SEEK_SET dlseek -1. d= if
       ... \ error handling
     then

   Passing and returning structs or unions is currently not supported by
our interface(1).

   Calling functions with a variable number of arguments (_variadic_
functions, e.g., 'printf()') is only supported by having you declare one
function-calling word for each argument pattern, and calling the
appropriate word for the desired pattern.

   ---------- Footnotes ----------

   (1) If you know the calling convention of your C compiler, you
usually can call such functions in some way, but that way is usually not
portable between platforms, and sometimes not even between C compilers.

6.31.2 Declaring C Functions
----------------------------

Before you can call 'lseek' or 'dlseek', you have to declare it.  The
declaration consists of two parts:

The C part
     is the C declaration of the function, or more typically and
     portably, a C-style '#include' of a file that contains the
     declaration of the C function.

The Forth part
     declares the Forth types of the parameters and the Forth word name
     corresponding to the C function.

   For the words 'lseek' and 'dlseek' mentioned earlier, the
declarations are:

     \c #define _FILE_OFFSET_BITS 64
     \c #include <sys/types.h>
     \c #include <unistd.h>
     c-function lseek lseek n n n -- n
     c-function dlseek lseek n d n -- d

   The C part of the declarations is prefixed by '\c', and the rest of
the line is ordinary C code.  You can use as many lines of C
declarations as you like, and they are visible for all further function
declarations.

   The Forth part declares each interface word with 'c-function',
followed by the Forth name of the word, the C name of the called
function, and the stack effect of the word.  The stack effect contains
an arbitrary number of types of parameters, then '--', and then exactly
one type for the return value.  The possible types are:

'n'
     single-cell integer

'a'
     address (single-cell)

'd'
     double-cell integer

'r'
     floating-point value

'func'
     C function pointer

'void'
     no value (used as return type for void functions)

   To deal with variadic C functions, you can declare one Forth word for
every pattern you want to use, e.g.:

     \c #include <stdio.h>
     c-function printf-nr printf a n r -- n
     c-function printf-rn printf a r n -- n

   Note that with C functions declared as variadic (or if you don't
provide a prototype), the C interface has no C type to convert to, so no
automatic conversion happens, which may lead to portability problems in
some cases.  You can add the C type cast in curly braces after the Forth
type.  This also allows to pass e.g.  structs to C functions, which in
Forth cannot live on the stack.

     c-function printfll printf a n{(long long)} -- n
     c-function pass-struct pass_struct a{*(struct foo *)} -- n

   This typecasting is not available to return values, as C does not
allow typecasts for lvalues.

'\c' ( "rest-of-line" -  ) gforth-0.7 "backslash-c"
   One line of C declarations for the C interface

'c-function' ( "forth-name" "c-name" "{type}" "--" "type" -  ) gforth-0.7
   Define a Forth word forth-name.  Forth-name has the specified stack
effect and calls the C function 'c-name'.

'c-value' ( "forth-name" "c-name" "--" "type" -  ) gforth-1.0
   Define a Forth word forth-name.  Forth-name has the specified stack
effect and gives the C value of 'c-name'.

'c-variable' ( "forth-name" "c-name" -  ) gforth-1.0
   Define a Forth word forth-name.  Forth-name returns the address of
'c-name'.

   In order to work, this C interface invokes GCC at run-time and uses
dynamic linking.  If these features are not available, there are other,
less convenient and less portable C interfaces in 'lib.fs' and
'oldlib.fs'.  These interfaces are mostly undocumented and mostly
incompatible with each other and with the documented C interface; you
can find some examples for the 'lib.fs' interface in 'lib.fs'.

6.31.3 Calling C function pointers from Forth
---------------------------------------------

If you come across a C function pointer (e.g., in some C-constructed
structure) and want to call it from your Forth program, you could use
the structures as described above by defining a macro.  Or you use
'c-funptr'.

'c-funptr' ( "forth-name" <{>"c-typecast"<}> "{type}" "--" "type" -  ) gforth-1.0
   Define a Forth word forth-name.  Forth-name has the specified stack
effect plus the called pointer on top of stack, i.e.  '( {type} ptr --
type )' and calls the C function pointer 'ptr' using the typecast or
struct access 'c-typecast'.

   Let us assume that there is a C function pointer type 'func1' defined
in some header file 'func1.h', and you know that these functions take
one integer argument and return an integer result; and you want to call
functions through such pointers.  Just define

     \c #include <func1.h>
     c-funptr call-func1 {((func1)ptr)} n -- n

   and then you can call a function pointed to by, say 'func1a' as
follows:

     -5 func1a call-func1 .

   The Forth word 'call-func1' is similar to 'execute', except that it
takes a C 'func1' pointer instead of a Forth execution token, and it is
specific to 'func1' pointers.  For each type of function pointer you
want to call from Forth, you have to define a separate calling word.

6.31.4 Defining library interfaces
----------------------------------

You can give a name to a bunch of C function declarations (a library
interface), as follows:

     c-library lseek-lib
     \c #define _FILE_OFFSET_BITS 64
     ...
     end-c-library

   The effect of giving such a name to the interface is that the names
of the generated files will contain that name, and when you use the
interface a second time, it will use the existing files instead of
generating and compiling them again, saving you time.  The generated
file contains a 128 bit hash (not cryptographically safe, but good
enough for that purpose) of the source code, so changing the
declarations will cause a new compilation.  Normally these files are
cached in '$HOME/.gforth/'ARCHITECTURE'/libcc-named', so if you
experience problems or have other reasons to force a recompilation, you
can delete the files there.

   Note that you should use 'c-library' before everything else having
anything to do with that library, as it resets some setup stuff.  The
idea is that the typical use is to put each
'c-library'...'end-c-library' unit in its own file, and to be able to
include these files in any order.  All other words dealing with the C
interface are hidden in the vocabulary 'c-lib', which is put on top o
the search stack by 'c-library' and removed by 'end-c-library'.

   Note that the library name is not allocated in the dictionary and
therefore does not shadow dictionary names.  It is used in the file
system, so you have to use naming conventions appropriate for file
systems.  The name is also used as part of the C symbols, but characters
outside the legal C symbol names are replaced with underscores.  Also,
you shall not call a function you declare after 'c-library' before you
perform 'end-c-library'.

   A major benefit of these named library interfaces is that, once they
are generated, the tools used to generated them (in particular, the C
compiler and libtool) are no longer needed, so the interface can be used
even on machines that do not have the tools installed.  The build system
of Gforth can even cross-compile these libraries, so that the libraries
are available for platforms on which build tools aren't installed.

'c-library-name' ( c-addr u -  ) gforth-0.7
   Start a C library interface with name c-addr u.

'c++-library-name' ( c-addr u -  ) gforth-1.0 "c-plus-plus-library-name"
   Start a C++ library interface with name c-addr u.

'c-library' ( "name" -  ) gforth-0.7
   Parsing version of 'c-library-name'

'c++-library' ( "name" -  ) gforth-1.0 "c-plus-plus-library"
   Parsing version of 'c++-library-name'

'end-c-library' ( -  ) gforth-0.7
   Finish and (if necessary) build the latest C library interface.

6.31.5 Declaring OS-level libraries
-----------------------------------

For calling some C functions, you need to link with a specific OS-level
library that contains that function.  E.g., the 'sin' function requires
linking a special library by using the command line switch '-lm'.  In
our C interface you do the equivalent thing by calling 'add-lib' as
follows:

     clear-libs
     s" m" add-lib
     \c #include <math.h>
     c-function sin sin r -- r

   First, you clear any libraries that may have been declared earlier
(you don't need them for 'sin'); then you add the 'm' library (actually
'libm.so' or somesuch) to the currently declared libraries; you can add
as many as you need.  Finally you declare the function as shown above.
Typically you will use the same set of library declarations for many
function declarations; you need to write only one set for that, right at
the beginning.

   Note that you must not call 'clear-libs' inside
'c-library...end-c-library'; however, 'c-library' performs the function
of 'clear-libs', so 'clear-libs' is not necessary, and you usually want
to put 'add-lib' calls inside 'c-library...end-c-library'.

'clear-libs' ( -  ) gforth-0.7
   Clear the list of libs

'add-lib' ( c-addr u -  ) gforth-0.7
   Add library libstring to the list of libraries, where string is
represented by c-addr u.

'add-libpath' ( c-addr u -  ) gforth-0.7
   Add path string to the list of library search pathes, where string is
represented by c-addr u.

'add-framework' ( c-addr u -  ) gforth-1.0
   Add framework libstring to the list of frameworks, where string is
represented by c-addr u.

'add-incdir' ( c-addr u -  ) gforth-1.0
   Add path c-addr u to the list of include search pathes

'add-cflags' ( c-addr u -  ) gforth-1.0
   add any kind of cflags to compilation

'add-ldflags' ( c-addr u -  ) gforth-1.0
   add flag to linker

6.31.6 Callbacks
----------------

In some cases you have to pass a function pointer to a C function, i.e.,
the library wants to call back to your application (and the pointed-to
function is called a callback function).  You can pass the address of an
existing C function (that you get with 'lib-sym', *note Low-Level C
Interface Words::), but if there is no appropriate C function, you
probably want to define the function as a Forth word.  Then you need to
generate a callback as described below:

   You can generate C callbacks from Forth code with 'c-callback'.

'c-callback' ( "forth-name" "{type}" "--" "type" -  ) gforth-1.0
   Define a callback instantiator with the given signature.  The
callback instantiator forth-name '( xt -- addr )' takes an XT, and
returns the ADDRess of the C function handling that callback.

'c-callback-thread' ( "forth-name" "{type}" "--" "type" -  ) gforth-1.0
   Define a callback instantiator with the given signature.  The
callback instantiator forth-name '( xt -- addr )' takes an XT, and
returns the ADDRess of the C function handling that callback.  This
callback is safe when called from another thread

   This precompiles a number of callback functions (up to the value
'callback#').  The prototype of the C function is deduced from its Forth
signature.  If this is not sufficient, you can add types in curly braces
after the Forth type.

     c-callback vector4double: f f f f -- void
     c-callback vector4single: f{float} f{float} f{float} f{float} -- void

6.31.7 How the C interface works
--------------------------------

The documented C interface works by generating a C code out of the
declarations.

   In particular, for every Forth word declared with 'c-function', it
generates a wrapper function in C that takes the Forth data from the
Forth stacks, and calls the target C function with these data as
arguments.  The C compiler then performs an implicit conversion between
the Forth type from the stack, and the C type for the parameter, which
is given by the C function prototype.  After the C function returns, the
return value is likewise implicitly converted to a Forth type and
written back on the stack.

   The '\c' lines are literally included in the C code (but without the
'\c'), and provide the necessary declarations so that the C compiler
knows the C types and has enough information to perform the conversion.

   These wrapper functions are eventually compiled and dynamically
linked into Gforth, and then they can be called.

   The libraries added with 'add-lib' are used in the compile command
line to specify dependent libraries with '-lLIB', causing these
libraries to be dynamically linked when the wrapper function is linked.

6.31.8 Low-Level C Interface Words
----------------------------------

'open-lib' ( c-addr1 u1 - u2 ) gforth-0.4 "open-lib"

'lib-sym' ( c-addr1 u1 u2 - u3 ) gforth-0.4 "lib-sym"

'lib-error' ( - c-addr u ) gforth-0.7 "lib-error"
   Error message for last failed 'open-lib' or 'lib-sym'.

'call-c' ( ... w - ... ) gforth-0.2 "call-c"
   Call the C function pointed to by w.  The C function has to access
the stack itself.  The stack pointers are exported into a ptrpair
structure passed to the C function, and returned in that form.

6.31.9 Automated interface generation using SWIG
------------------------------------------------

SWIG, the Simple Wrapper Interface Generator, is used to create C
interfaces for a lot of programming languages.  The SWIG version
extended with a Forth module can be found on github
(https://github.com/GeraldWodni/swig).

6.31.9.1 Basic operation
........................

C-headers are parsed and converted to Forth-Sourcecode which uses the
previously describe C interface functions.

6.31.9.2 Detailed operation:
............................

  1. Select a target, in this example we are using 'example.h'
  2. Create an interface file for the header.  This can be used to pass
     options, switches and define variables.  In the simplest case it
     just instructs to translate all of 'example.h':
          %module example
          %insert("include")
          {
              #include "example.h"
          }
          %include "example.h"
  3. Use SWIG to create a '.fsi-c' file.
     'swig -forth -stackcomments -use-structs -enumcomments -o
     example-fsi.c example.i'.
     FSI stands "Forth Source Independent" meaning it can be transferred
     to any host having a C-compiler.  SWIG is not required past this
     point.
  4. On the target machine compile the '.fsi-c' file to a '.fsx' (x
     stands for executable)
     'gcc -o example.fsx example-fsi.c'
     The compilation will resolve all constants to the values on the
     target.
  5. The last step is to run the executable and capture its output to a
     '.fs' "Forth Source" file.
     './example.fsx -gforth > example.fs'
     This code can now be used on the target platform.

6.31.9.3 Examples
.................

You can find some examples in SWIG's Forth Example section
(https://github.com/GeraldWodni/swig/tree/master/Examples/forth).

   A lot of interface files can be found in Forth Posix C-Interface
(https://github.com/GeraldWodni/posix) and Forth C-Interface Modules
(https://github.com/GeraldWodni/forth-c-interfaces).

   Contribution to the Forth C-Interface Module repository
(https://github.com/GeraldWodni/forth-c-interfaces) is always welcome.

6.31.10 Migrating from Gforth 0.7
---------------------------------

In this version, you can use '\c', 'c-function' and 'add-lib' only
inside 'c-library'...'end-c-library'.  'add-lib' now always starts from
a clean slate inside a 'c-library', so you don't need to use
'clear-libs' in most cases.

   If you have a program that uses these words outside
'c-library'...'end-c-library', just wrap them in
'c-library'...'end-c-library'.  You may have to add some instances of
'add-lib', however.

6.32 Assembler and Code Words
=============================

6.32.1 Definitions in assembly language
---------------------------------------

Gforth provides ways to implement words in assembly language (using
'abi-code'...'end-code'), and also ways to define defining words with
arbitrary run-time behaviour (like 'does>'), where (unlike 'does>') the
behaviour is not defined in Forth, but in assembly language (with
';code').

   However, the machine-independent nature of Gforth poses a few
problems: First of all, Gforth runs on several architectures, so it can
provide no standard assembler.  It does provide assemblers for several
of the architectures it runs on, though.  Moreover, you can use a
system-independent assembler in Gforth, or compile machine code directly
with ',' and 'c,'.

   Another problem is that the virtual machine registers of Gforth (the
stack pointers and the virtual machine instruction pointer) depend on
the installation and engine.  Also, which registers are free to use also
depend on the installation and engine.  So any code written to run in
the context of the Gforth virtual machine is essentially limited to the
installation and engine it was developed for (it may run elsewhere, but
you cannot rely on that).

   Fortunately, you can define 'abi-code' words in Gforth that are
portable to any Gforth running on a platform with the same calling
convention (ABI); typically this means portability to the same
architecture/OS combination, sometimes crossing OS boundaries).

'assembler' ( -  ) tools-ext
   A vocubulary: Replaces the wordlist at the top of the search order
with the assembler wordlist.

'init-asm' ( -  ) gforth-0.2
   Pushes the assembler wordlist on the search order.

'abi-code' ( "name" - colon-sys  ) gforth-1.0 "abi-code"
   Start a native code definition that is called using the platform's
ABI conventions corresponding to the C-prototype:
     Cell *function(Cell *sp, Float **fpp);
   The FP stack pointer is passed in by providing a reference to a
memory location containing the FP stack pointer and is passed out by
storing the changed FP stack pointer there (if necessary).

';abi-code' ( -  ) gforth-1.0 "semicolon-abi-code"
   Ends the colon definition, but at run-time also changes the last
defined word X (which must be a 'create'd word) to call the following
native code using the platform's ABI convention corresponding to the C
prototype:
      Cell *function(Cell *sp, Float **fpp, Address body);
   The FP stack pointer is passed in by providing a reference to a
memory location containing the FP stack pointer and is passed out by
storing the changed FP stack pointer there (if necessary).  The
parameter body is the body of X.

'end-code' ( colon-sys -  ) gforth-0.2 "end-code"
   End a code definition.  Note that you have to assemble the return
from the ABI call (for 'abi-code') or the dispatch to the next VM
instruction (for 'code' and ';code') yourself.

'code' ( "name" - colon-sys  ) tools-ext
   Start a native code definition that runs in the context of the Gforth
virtual machine (engine).  Such a definition is not portable between
Gforth installations, so we recommend using 'abi-code' instead of
'code'.  You have to end a 'code' definition with a dispatch to the next
virtual machine instruction.

';code' ( compilation. colon-sys1 - colon-sys2  ) tools-ext "semicolon-code"
   The code after ';code' becomes the behaviour of the last defined word
(which must be a 'create'd word).  The same caveats apply as for 'code',
so we recommend using ';abi-code' instead.

'flush-icache' ( c-addr u - ) gforth-0.2 "flush-icache"
   Make sure that the instruction cache of the processor (if there is
one) does not contain stale data at c-addr and u bytes afterwards.
'END-CODE' performs a 'flush-icache' automatically.  Caveat:
'flush-icache' might not work on your installation; this is usually the
case if direct threading is not supported on your machine (take a look
at your 'machine.h') and your machine has a separate instruction cache.
In such cases, 'flush-icache' does nothing instead of flushing the
instruction cache.

   If 'flush-icache' does not work correctly, 'abi-code' words etc.
will not work (reliably), either.

   The typical usage of these words can be shown most easily by analogy
to the equivalent high-level defining words:

     : foo                              abi-code foo
        <high-level Forth words>              <assembler>
     ;                                  end-code

     : bar                              : bar
        <high-level Forth words>           <high-level Forth words>
        CREATE                             CREATE
           <high-level Forth words>           <high-level Forth words>
        DOES>                              ;code
           <high-level Forth words>           <assembler>
     ;                                  end-code

   For using 'abi-code', take a look at the ABI documentation of your
platform to see how the parameters are passed (so you know where you get
the stack pointers) and how the return value is passed (so you know
where the data stack pointer is returned).  The ABI documentation also
tells you which registers are saved by the caller (caller-saved), so you
are free to destroy them in your code, and which registers have to be
preserved by the called word (callee-saved), so you have to save them
before using them, and restore them afterwards.  For some architectures
and OSs we give short summaries of the parts of the calling convention
in the appropriate sections.  More reverse-engineering oriented people
can also find out about the passing and returning of the stack pointers
through 'see abi-call'.

   Most ABIs pass the parameters through registers, but some (in
particular the most common 386 (aka IA-32) calling conventions) pass
them on the architectural stack.  The common ABIs all pass the return
value in a register.

   Other things you need to know for using 'abi-code' is that both the
data and the FP stack grow downwards (towards lower addresses) in
Gforth, with '1 cells' size per cell, and '1 floats' size per FP value.

   Here's an example of using 'abi-code' on the 386 architecture:

     abi-code my+ ( n1 n2 -- n )
     4 sp d) ax mov \ sp into return reg
     ax )    cx mov \ tos
     4 #     ax add \ update sp (pop)
     cx    ax ) add \ sec = sec+tos
     ret            \ return from my+
     end-code

   An AMD64 variant of this example can be found in *note AMD64
Assembler::.

   Here's a 386 example that deals with FP values:

     abi-code my-f+ ( r1 r2 -- r )
     8 sp d) cx mov  \ load address of fp
     cx )    dx mov  \ load fp
     .fl dx )   fld  \ r2
     8 #     dx add  \ update fp
     .fl dx )   fadd \ r1+r2
     .fl dx )   fstp \ store r
     dx    cx ) mov  \ store new fp
     4 sp d) ax mov  \ sp into return reg
     ret             \ return from my-f+
     end-code

6.32.2 Common Assembler
-----------------------

The assemblers in Gforth generally use a postfix syntax, i.e., the
instruction name follows the operands.

   The operands are passed in the usual order (the same that is used in
the manual of the architecture).  Since they all are Forth words, they
have to be separated by spaces; you can also use Forth words to compute
the operands.

   The instruction names usually end with a ','.  This makes it easier
to visually separate instructions if you put several of them on one
line; it also avoids shadowing other Forth words (e.g., 'and').

   Registers are usually specified by number; e.g., (decimal) '11'
specifies registers R11 and F11 on the Alpha architecture (which one,
depends on the instruction).  The usual names are also available, e.g.,
's2' for R11 on Alpha.

   Control flow is specified similar to normal Forth code (*note
Arbitrary control structures::), with 'if,', 'ahead,', 'then,',
'begin,', 'until,', 'again,', 'cs-roll', 'cs-pick', 'else,', 'while,',
and 'repeat,'.  The conditions are specified in a way specific to each
assembler.

   The rest of this section is of interest mainly for those who want to
define 'code' words (instead of the more portable 'abi-code' words).

   Note that the register assignments of the Gforth engine can change
between Gforth versions, or even between different compilations of the
same Gforth version (e.g., if you use a different GCC version).  If you
are using 'CODE' instead of 'ABI-CODE', and you want to refer to
Gforth's registers (e.g., the stack pointer or TOS), I recommend
defining your own words for referring to these registers, and using them
later on; then you can adapt to a changed register assignment.

   The most common use of these registers is to end a 'code' definition
with a dispatch to the next word (the 'next' routine).  A portable way
to do this is to jump to '' noop >code-address' (of course, this is less
efficient than integrating the 'next' code and scheduling it well).
When using 'ABI-CODE', you can just assemble a normal subroutine return
(but make sure you return the data stack pointer).

   Another difference between Gforth versions is that the top of stack
is kept in memory in 'gforth' and, on most platforms, in a register in
'gforth-fast'.  For 'ABI-CODE' definitions, any stack caching registers
are guaranteed to be flushed to the stack, allowing you to reliably
access the top of stack in memory.

6.32.3 Common Disassembler
--------------------------

You can disassemble a 'code' word with 'see' (*note Debugging::).  You
can disassemble a section of memory with

'discode' ( addr u -  ) gforth-0.2
   hook for the disassembler: disassemble u bytes of code at addr

   There are two kinds of disassembler for Gforth: The Forth
disassembler (available on some CPUs) and the gdb disassembler
(available on platforms with 'gdb' and 'mktemp').  If both are
available, the Forth disassembler is used by default.  If you prefer the
gdb disassembler, say

     ' disasm-gdb is discode

   If neither is available, 'discode' performs 'dump'.

   The Forth disassembler generally produces output that can be fed into
the assembler (i.e., same syntax, etc.).  It also includes additional
information in comments.  In particular, the address of the instruction
is given in a comment before the instruction.

   The gdb disassembler produces output in the same format as the gdb
'disassemble' command (*note Source and machine code: (gdb)Machine
Code.), in the default flavour (AT&T syntax for the 386 and AMD64
architectures).

   'See' may display more or less than the actual code of the word,
because the recognition of the end of the code is unreliable.  You can
use 'discode' if it did not display enough.  It may display more, if the
code word is not immediately followed by a named word.  If you have
something else there, you can follow the word with 'align latest ,' to
ensure that the end is recognized.

6.32.4 386 Assembler
--------------------

The 386 assembler included in Gforth was written by Bernd Paysan, it's
available under GPL, and originally part of bigFORTH.

   The 386 disassembler included in Gforth was written by Andrew McKewan
and is in the public domain.

   The disassembler displays code in an Intel-like prefix syntax.

   The assembler uses a postfix syntax with AT&T-style parameter order
(i.e., destination last).

   The assembler includes all instruction of the Athlon, i.e.  486 core
instructions, Pentium and PPro extensions, floating point, MMX, 3Dnow!,
but not ISSE. It's an integrated 16- and 32-bit assembler.  Default is
32 bit, you can switch to 16 bit with .86 and back to 32 bit with .386.

   There are several prefixes to switch between different operation
sizes, '.b' for byte accesses, '.w' for word accesses, '.d' for
double-word accesses.  Addressing modes can be switched with '.wa' for
16 bit addresses, and '.da' for 32 bit addresses.  You don't need a
prefix for byte register names ('AL' et al).

   For floating point operations, the prefixes are '.fs' (IEEE single),
'.fl' (IEEE double), '.fx' (extended), '.fw' (word), '.fd'
(double-word), and '.fq' (quad-word).  The default is '.fx', so you need
to specify '.fl' explicitly when dealing with Gforth FP values.

   The MMX opcodes don't have size prefixes, they are spelled out like
in the Intel assembler.  Instead of move from and to memory, there are
PLDQ/PLDD and PSTQ/PSTD.

   The registers lack the 'e' prefix; even in 32 bit mode, eax is called
ax.  Immediate values are indicated by postfixing them with '#', e.g.,
'3 #'.  Here are some examples of addressing modes in various syntaxes:

     Gforth          Intel (NASM)   AT&T (gas)      Name
     .w ax           ax             %ax             register (16 bit)
     ax              eax            %eax            register (32 bit)
     3 #             offset 3       $3              immediate
     1000 #)         byte ptr 1000  1000            displacement
     bx )            [ebx]          (%ebx)          base
     100 di d)       100[edi]       100(%edi)       base+displacement
     20 ax *4 i#)    20[eax*4]      20(,%eax,4)     (index*scale)+displacement
     di ax *4 i)     [edi][eax*4]   (%edi,%eax,4)   base+(index*scale)
     4 bx cx di)     4[ebx][ecx]    4(%ebx,%ecx)    base+index+displacement
     12 sp ax *2 di) 12[esp][eax*2] 12(%esp,%eax,2) base+(index*scale)+displacement

   You can use 'L)' and 'LI)' instead of 'D)' and 'DI)' to enforce
32-bit displacement fields (useful for later patching).

   Some example of instructions are:

     ax bx mov             \ move ebx,eax
     3 # ax mov            \ mov eax,3
     100 di d) ax mov      \ mov eax,100[edi]
     4 bx cx di) ax mov    \ mov eax,4[ebx][ecx]
     .w ax bx mov          \ mov bx,ax

   The following forms are supported for binary instructions:

     <reg> <reg> <inst>
     <n> # <reg> <inst>
     <mem> <reg> <inst>
     <reg> <mem> <inst>
     <n> # <mem> <inst>

   The shift/rotate syntax is:

     <reg/mem> 1 # shl \ shortens to shift without immediate
     <reg/mem> 4 # shl
     <reg/mem> cl shl

   Precede string instructions ('movs' etc.)  with '.b' to get the byte
version.

   The control structure words 'IF' 'UNTIL' etc.  must be preceded by
one of these conditions: 'vs vc u< u>= 0= 0<> u<= u> 0< 0>= ps pc < >=
<= >'.  (Note that most of these words shadow some Forth words when
'assembler' is in front of 'forth' in the search path, e.g., in 'code'
words).  Currently the control structure words use one stack item, so
you have to use 'roll' instead of 'cs-roll' to shuffle them (you can
also use 'swap' etc.).

   Based on the Intel ABI (used in Linux), 'abi-code' words can find the
data stack pointer at '4 sp d)', and the address of the FP stack pointer
at '8 sp d)'; the data stack pointer is returned in 'ax'; 'Ax', 'cx',
and 'dx' are caller-saved, so you do not need to preserve their values
inside the word.  You can return from the word with 'ret', the
parameters are cleaned up by the caller.

   For examples of 386 'abi-code' words, see *note Assembler
Definitions::.

6.32.5 AMD64 (x86_64) Assembler
-------------------------------

The AMD64 assembler is a slightly modified version of the 386 assembler,
and as such shares most of the syntax.  Two new prefixes, '.q' and
'.qa', are provided to select 64-bit operand and address sizes
respectively.  64-bit sizes are the default, so normally you only have
to use the other prefixes.  Also there are additional register operands
'R8'-'R15'.

   The registers lack the 'e' or 'r' prefix; even in 64 bit mode, 'rax'
is called 'ax'.  Additional register operands are available to refer to
the lowest-significant byte of all registers: 'R8L'-'R15L', 'SPL',
'BPL', 'SIL', 'DIL'.

   The Linux-AMD64 calling convention is to pass the first 6 integer
parameters in rdi, rsi, rdx, rcx, r8 and r9 and to return the result in
rax and rdx; to pass the first 8 FP parameters in xmm0-xmm7 and to
return FP results in xmm0-xmm1.  So 'abi-code' words get the data stack
pointer in 'di' and the address of the FP stack pointer in 'si', and
return the data stack pointer in 'ax'.  The other caller-saved registers
are: r10, r11, xmm8-xmm15.  This calling convention reportedly is also
used in other non-Microsoft OSs.

   Windows x64 passes the first four integer parameters in rcx, rdx, r8
and r9 and return the integer result in rax.  The other caller-saved
registers are r10 and r11.

   On the Linux platform, according to
<https://uclibc.org/docs/psABI-x86_64.pdf> page 21 the registers AX CX
DX SI DI R8 R9 R10 R11 are available for scratch.

   The addressing modes for the AMD64 are:

     \ running word A produces a memory error as the registers are not initialised ;-)
     ABI-CODE A  ( -- )
         500        #               AX  MOV     \ immediate
             DX              AX  MOV     \ register
             200             AX  MOV     \ direct addressing
             DX  )           AX  MOV     \ indirect addressing
         40  DX  D)          AX  MOV     \ base with displacement
             DX  CX      I)  AX  MOV     \ scaled index
             DX  CX  *4  I)  AX  MOV     \ scaled index
         40  DX  CX  *4  DI) AX  MOV     \ scaled index with displacement

             DI              AX  MOV     \ SP Out := SP in
                                 RET
     END-CODE

   Here are a few examples of an AMD64 'abi-code' words:

     abi-code my+  ( n1 n2 -- n3 )
     \ SP passed in di, returned in ax,  address of FP passed in si
     8 di d) ax lea        \ compute new sp in result reg
     di )    dx mov        \ get old tos
     dx    ax ) add        \ add to new tos
     ret
     end-code

     \ Do nothing
     ABI-CODE aNOP  ( -- )
            DI  )       AX      LEA          \ SP out := SP in
                                RET
     END-CODE

     \ Drop TOS
     ABI-CODE aDROP  ( n -- )
        8   DI  D)      AX      LEA          \ SPout := SPin - 1
                                RET
     END-CODE

     \ Push 5 on the data stack
     ABI-CODE aFIVE   ( -- 5 )
        -8  DI  D)      AX      LEA          \ SPout := SPin + 1
        5   #           AX  )   MOV          \ TOS := 5
                                RET
     END-CODE

     \ Push 10 and 20 into data stack
     ABI-CODE aTOS2  ( -- n n )
        -16 DI  D)      AX      LEA          \ SPout := SPin + 2
        10  #       8   AX  D)  MOV          \ TOS - 1 := 10
        20  #           AX  )   MOV          \ TOS := 20
                                RET
     END-CODE

     \ Get Time Stamp Counter as two 32 bit integers
     \ The TSC is incremented every CPU clock pulse
     ABI-CODE aRDTSC   ( -- TSCl TSCh )
                                RDTSC        \ DX:AX := TSC
        $FFFFFFFF #     AX      AND          \ Clear upper 32 bit AX
       0xFFFFFFFF #     DX      AND          \ Clear upper 32 bit DX
            AX          R8      MOV          \ Temporarily save AX
        -16 DI  D)      AX      LEA          \ SPout := SPin + 2
            R8      8   AX  D)  MOV          \ TOS-1 := saved AX = TSC low
            DX          AX  )   MOV          \ TOS := Dx = TSC high
                                RET
     END-CODE

     \ Get Time Stamp Counter as 64 bit integer
     ABI-CODE RDTSC   ( -- TSC )
                                RDTSC        \ DX:AX := TSC
        $FFFFFFFF #     AX      AND          \ Clear upper 32 bit AX
        32  #           DX      SHL          \ Move lower 32 bit DX to upper 32 bit
            AX          DX      OR           \ Combine AX with DX in DX
        -8  DI  D)      AX      LEA          \ SPout := SPin + 1
            DX          AX  )   MOV          \ TOS := DX
                                RET
     END-CODE

     VARIABLE V

     \ Assign 4 to variable V
     ABI-CODE V=4 ( -- )
            BX                  PUSH         \ Save BX, used by gforth
        V   #           BX      MOV          \ BX := address of V
        4   #           BX )    MOV          \ Write 4 to V
            BX                  POP          \ Restore BX
            DI  )       AX      LEA          \ SPout := SPin
                                RET
     END-CODE

     VARIABLE V

     \ Assign 5 to variable V
     ABI-CODE V=5 ( -- )
        V   #           CX      MOV          \ CX := address of V
        5   #           CX )    MOV          \ Write 5 to V
        DI )            AX      LEA          \ SPout := SPin
                                RET
     END-CODE

     ABI-CODE TEST2  ( -- n n )
        -16 DI  D)  AX          LEA          \ SPout := SPin + 2
        5   #       CX          MOV          \ CX := 5
        5   #       CX          CMP
        0= IF
            1   #   8   AX  D)      MOV      \ If CX = 5 then TOS - 1 := 1  <--
        ELSE
            2   #   8   AX  D)      MOV      \ else TOS - 1 := 2
        THEN
        6   #       CX          CMP
        0= IF
            3   #       AX  )       MOV      \ If CX = 6 then TOS := 3
        ELSE
            4   #       AX  )       MOV      \ else TOS := 4  <--
        THEN
                                RET
     END-CODE

     \ Do four loops. Expect : ( 4 3 2 1 -- )
     ABI-CODE LOOP4  ( -- n n n n )
            DI          AX      MOV          \ SPout := SPin
        4   #           DX      MOV          \ DX := 4  loop counter
        BEGIN
            8   #           AX      SUB      \ SP := SP + 1
                DX          AX  )   MOV      \ TOS := DX
            1   #           DX      SUB      \ DX := DX - 1
        0= UNTIL
                                RET
     END-CODE

   Here's a AMD64 example that deals with FP values:

     abi-code my-f+  ( r1 r2 -- r )
     \ SP passed in di, returned in ax,  address of FP passed in si
     si )       dx mov         \ load fp
     8 dx d)  xmm0 movsd       \ r2
     dx )     xmm0 addsd       \ r1+r2
     xmm0  8 dx d) movsd       \ store r
     8 #      si ) add         \ update fp
     di         ax mov         \ sp into return reg
     ret
     end-code

6.32.6 Alpha Assembler
----------------------

The Alpha assembler and disassembler were originally written by Bernd
Thallner.

   The register names 'a0'-'a5' are not available to avoid shadowing hex
numbers.

   Immediate forms of arithmetic instructions are distinguished by a '#'
just before the ',', e.g., 'and#,' (note: 'lda,' does not count as
arithmetic instruction).

   You have to specify all operands to an instruction, even those that
other assemblers consider optional, e.g., the destination register for
'br,', or the destination register and hint for 'jmp,'.

   You can specify conditions for 'if,' by removing the first 'b' and
the trailing ',' from a branch with a corresponding name; e.g.,

     11 fgt if, \ if F11>0e
       ...
     endif,

   'fbgt,' gives 'fgt'.

6.32.7 MIPS assembler
---------------------

The MIPS assembler was originally written by Christian Pirker.

   Currently the assembler and disassembler covers most of the MIPS32
architecture and doesn't support FP instructions.

   The register names '$a0'-'$a3' are not available to avoid shadowing
hex numbers.  Use register numbers '$4'-'$7' instead.

   Nothing distinguishes registers from immediate values.  Use explicit
opcode names with the 'i' suffix for instructions with immediate
argument.  E.g.  'addiu,' in place of 'addu,'.

   Where the architecture manual specifies several formats for the
instruction (e.g., for 'jalr,'),use the one with more arguments (i.e.
two for 'jalr,').  When in doubt, see 'arch/mips/testasm.fs' for an
example of correct use.

   Branches and jumps in the MIPS architecture have a delay slot.  You
have to fill it manually (the simplest way is to use 'nop,'), the
assembler does not do it for you (unlike 'as').  Even 'if,', 'ahead,',
'until,', 'again,', 'while,', 'else,' and 'repeat,' need a delay slot.
Since 'begin,' and 'then,' just specify branch targets, they are not
affected.  For branches the argument specifying the target is a relative
address.  Add the address of the delay slot to get the absolute address.

   Note that you must not put branches nor jumps (nor control-flow
instructions) into the delay slot.  Also it is a bad idea to put
pseudo-ops such as 'li,' into a delay slot, as these may expand to
several instructions.  The MIPS I architecture also had load delay
slots, and newer MIPSes still have restrictions on using 'mfhi,' and
'mflo,'.  Be careful to satisfy these restrictions, the assembler does
not do it for you.

   Some example of instructions are:

     $ra  12 $sp  sw,         \ sw    ra,12(sp)
     $4    8 $s0  lw,         \ lw    a0,8(s0)
     $v0  $0  lui,            \ lui   v0,0x0
     $s0  $s4  $12  addiu,    \ addiu s0,s4,0x12
     $s0  $s4  $4  addu,      \ addu  s0,s4,$a0
     $ra  $t9  jalr,          \ jalr  t9

   You can specify the conditions for 'if,' etc.  by taking a
conditional branch and leaving away the 'b' at the start and the ',' at
the end.  E.g.,

     4 5 eq if,
       ... \ do something if $4 equals $5
     then,

   The calling conventions for 32-bit MIPS machines is to pass the first
4 arguments in registers '$4'..'$7', and to use '$v0'-'$v1' for return
values.  In addition to these registers, it is ok to clobber registers
'$t0'-'$t8' without saving and restoring them.

   If you use 'jalr,' to call into dynamic library routines, you must
first load the called function's address into '$t9', which is used by
position-indirect code to do relative memory accesses.

   Here is an example of a MIPS32 'abi-code' word:

     abi-code my+  ( n1 n2 -- n3 )
       \ SP passed in $4, returned in $v0
       $t0  4 $4  lw,         \ load n1, n2 from stack
       $t1  0 $4  lw,
       $t0  $t0  $t1  addu,   \ add n1+n2, result in $t0
       $t0  4 $4  sw,         \ store result (overwriting n1)
       $ra  jr,               \ return to caller
       $v0  $4  4  addiu,     \ (delay slot) return uptated SP in $v0
     end-code

6.32.8 PowerPC assembler
------------------------

The PowerPC assembler and disassembler were contributed by Michal
Revucky.

   This assembler does not follow the convention of ending mnemonic
names with a ",", so some mnemonic names shadow regular Forth words (in
particular: 'and or xor fabs'); so if you want to use the Forth words,
you have to make them visible first, e.g., with 'also forth'.

   Registers are referred to by their number, e.g., '9' means the
integer register 9 or the FP register 9 (depending on the instruction).

   Because there is no way to distinguish registers from immediate
values, you have to explicitly use the immediate forms of instructions,
i.e., 'addi,', not just 'add,'.

   The assembler and disassembler usually support the most general form
of an instruction, but usually not the shorter forms (especially for
branches).

6.32.9 ARM Assembler
--------------------

The ARM assembler includes all instruction of ARM architecture version
4, and the BLX instruction from architecture 5.  It does not (yet) have
support for Thumb instructions.  It also lacks support for any
co-processors.

   The assembler uses a postfix syntax with the same operand order as
used in the ARM Architecture Reference Manual.  Mnemonics are suffixed
by a comma.

   Registers are specified by their names 'r0' through 'r15', with the
aliases 'pc', 'lr', 'sp', 'ip' and 'fp' provided for convenience.  Note
that 'ip' refers to the"intra procedure call scratch register" ('r12')
and does not refer to an instruction pointer.  'sp' refers to the ARM
ABI stack pointer ('r13') and not the Forth stack pointer.

   Condition codes can be specified anywhere in the instruction, but
will be most readable if specified just in front of the mnemonic.  The
'S' flag is not a separate word, but encoded into instruction mnemonics,
ie.  just use 'adds,' instead of 'add,' if you want the status register
to be updated.

   The following table lists the syntax of operands for general
instructions:

     Gforth          normal assembler      description
     123 #           #123                  immediate
     r12             r12                   register
     r12 4 #LSL      r12, LSL #4           shift left by immediate
     r12 r1 LSL      r12, LSL r1           shift left by register
     r12 4 #LSR      r12, LSR #4           shift right by immediate
     r12 r1 LSR      r12, LSR r1           shift right by register
     r12 4 #ASR      r12, ASR #4           arithmetic shift right
     r12 r1 ASR      r12, ASR r1           ... by register
     r12 4 #ROR      r12, ROR #4           rotate right by immediate
     r12 r1 ROR      r12, ROR r1           ... by register
     r12 RRX         r12, RRX              rotate right with extend by 1

   Memory operand syntax is listed in this table:

     Gforth            normal assembler      description
     r4 ]              [r4]                  register
     r4 4 #]           [r4, #+4]             register with immediate offset
     r4 -4 #]          [r4, #-4]             with negative offset
     r4 r1 +]          [r4, +r1]             register with register offset
     r4 r1 -]          [r4, -r1]             with negated register offset
     r4 r1 2 #LSL -]   [r4, -r1, LSL #2]     with negated and shifted offset
     r4 4 #]!          [r4, #+4]!            immediate preincrement
     r4 r1 +]!         [r4, +r1]!            register preincrement
     r4 r1 -]!         [r4, +r1]!            register predecrement
     r4 r1 2 #LSL +]!  [r4, +r1, LSL #2]!    shifted preincrement
     r4 -4 ]#          [r4], #-4             immediate postdecrement
     r4 r1 ]+          [r4], r1              register postincrement
     r4 r1 ]-          [r4], -r1             register postdecrement
     r4 r1 2 #LSL ]-   [r4], -r1, LSL #2     shifted postdecrement
     ' xyz >body [#]   xyz                   PC-relative addressing

   Register lists for load/store multiple instructions are started and
terminated by using the words '{' and '}' respectively.  Between braces,
register names can be listed one by one or register ranges can be formed
by using the postfix operator 'r-r'.  The '^' flag is not encoded in the
register list operand, but instead directly encoded into the instruction
mnemonic, ie.  use '^ldm,' and '^stm,'.

   Addressing modes for load/store multiple are not encoded as
instruction suffixes, but instead specified like an addressing mode, Use
one of 'DA', 'IA', 'DB', 'IB', 'DA!', 'IA!', 'DB!' or 'IB!'.

   The following table gives some examples:

     Gforth                           normal assembler
     r4 ia  { r0 r7 r8 }  stm,        stmia    r4, {r0,r7,r8}
     r4 db!  { r0 r7 r8 }  ldm,       ldmdb    r4!, {r0,r7,r8}
     sp ia!  { r0 r15 r-r }  ^ldm,    ldmfd    sp!, {r0-r15}^

   Control structure words typical for Forth assemblers are available:
'if,' 'ahead,' 'then,' 'else,' 'begin,' 'until,' 'again,' 'while,'
'repeat,' 'repeat-until,'.  Conditions are specified in front of these
words:

     r1 r2 cmp,    \ compare r1 and r2
     eq if,        \ equal?
        ...          \ code executed if r1 == r2
     then,

   Example of a definition using the ARM assembler:

     abi-code my+ ( n1 n2 --  n3 )
        \ arm abi: r0=SP, r1=&FP, r2,r3,r12 saved by caller
        r0 IA!  { r2 r3 }  ldm,     \ pop r2 = n2, r3 = n1
        r3  r2  r3         add,     \ r3 = n1+n1
        r3  r0 -4 #]!      str,     \ push r3
        pc  lr             mov,     \ return to caller, new SP in r0
     end-code

6.32.10 Other assemblers
------------------------

If you want to contribute another assembler/disassembler, please contact
us (<anton@mips.complang.tuwien.ac.at>) to check if we have such an
assembler already.  If you are writing them from scratch, please use a
similar syntax style as the one we use (i.e., postfix, commas at the end
of the instruction names, *note Common Assembler::); make the output of
the disassembler be valid input for the assembler, and keep the style
similar to the style we used.

   Hints on implementation: The most important part is to have a good
test suite that contains all instructions.  Once you have that, the rest
is easy.  For actual coding you can take a look at 'arch/mips/disasm.fs'
to get some ideas on how to use data for both the assembler and
disassembler, avoiding redundancy and some potential bugs.  You can also
look at that file (and *note Advanced does> usage example::) to get
ideas how to factor a disassembler.

   Start with the disassembler, because it's easier to reuse data from
the disassembler for the assembler than the other way round.

   For the assembler, take a look at 'arch/alpha/asm.fs', which shows
how simple it can be.

6.33 Carnal words
=================

These words deal with the mechanics of Gforth (in Forth circles called
"carnal knowledge" of a Forth system), but we consider them stable
enough to document them.

6.33.1 Header fields
--------------------

In Gforth 1.0 we switched to a new word header layout.  For a detailed
description, read: Bernd Paysan and M. Anton Ertl.  'The new Gforth
header (http://www.euroforth.org/ef19/papers/paysan.pdf)'.  In 35th
EuroForth Conference, pages 5-20, 2019.  Since this paper was published,
xt and nt have been changed to point to the parameter field, like the
body, but otherwise it is still up-to-date.

   This section explains just the data structure and the words used to
access it.  A header has the following fields:

     name
     >f+c
     >link
     >cfa
     >namehm
     >body

   Currently Gforth has the names shown above for getting from the
xt/nt/body to the field, but apart from the standard '>body' they are
not stable Gforth words.  Instead, we provide access words.  Note that
the documented access words have survived the reorganization of the
header layout.

   Some of the words expect an nt, some expect an xt.  Given that both
nt and xt point to the body of a word, what is the difference?  For most
words, the xt and nt use the same header, and with nt=xt, they point to
the same place.  However, for a synonym (*note Synonyms::) there is a
difference; consider the example

     create x
     synonym y x
     synonym z y

   In this case the nt of 'z' points to the body of 'z', while the xt of
'z' points to the body of 'x'.  Words defined with 'alias' or 'forward'
(*note Calls and returns::) also have different nts and xts.

   The name field is variable-length and is accessed with 'name>string'
(*note Name token::).

   The '>f+c' field contains flags and the name length (count).  You
read the count with 'name>string', and the flags with 'compile-only?'
and 'obsolete?' (*note Name token::).

   The '>link' field contains a link to the previous word in the same
word list.  You can read it with 'name>link' (*note Name token::).

   The name, '>f+c' and '>link' fields are not present for 'noname'
words, but 'name>string' and 'name>link' work nevertheless, producing 0
0 and 0, respectively.

   The '>cfa' field (aka code field) contains the code address used for
'execute'ing the word; you can read it with '>code-address' and write it
with 'code-address!' (*note Threading Words::).

   The '>namehm' field contains the address of the header methods table,
described below.  You access it by performing or accessing header
methods (*note Header methods::).

   The '>body' (aka parameter) field contains data or threaded code
specific to the word type; its length depends on the word type.  E.g.,
for a 'constant' it contains a cell with the value of the constant.  You
can access it through '>body' (*note CREATE..DOES> details::), but this
is only standard for words you defined with 'create'.

6.33.2 Header methods
---------------------

The new Gforth word header is object-oriented and supports the following
methods (method selectors):

     .hm label method          overrider        field
               execute         set-execute      >cfa
     opt:      opt-compile,    set-optimizer    >hmcompile,
     to:       (to)            set-to           >hmto
     extra:                                     >hmextra
     >int:     name>interpret  set->int         >hm>int
     >comp:    name>compile    set->comp        >hm>comp
     >string:  name>string     set-name>string  >hm>string
     >link:    name>link       set-name>link    >hm>link

   Many of these words are not stable Gforth words, but Gforth has
stable higher-level words that we mention below.

   You can look at the header methods of a word with

'.hm' ( nt -  ) gforth-1.0 "dot-h-m"
   print the header methods of nt

   Overrider (setter) words change the method implementation for the
most recent definition.  Quotations or closures restore the previous
most recent definition when they are completed, so they are not
considered most recent, and you can do things like:

     : my2dup over over ;
     [: drop ]] over over [[ ;] set-optimizer

   The 'execute' method is actually stored in the '>cfa' field in the
header rather than in the header-methods table for performance reasons;
also it is implemented through a native-code address, while the other
methods are implemented by calling an xt.  The high-level way to set
this method is

'set-execute' ( ca -  ) gforth-1.0
   Changes the current word such that it jumps to the native code at ca.
Also changes the 'compile,' implementation to the most general (and
slowest) one.  Call 'set-optimizer' afterwards if you want a more
efficient 'compile,' implementation.

   To get a code address for use with 'set-execute', you can use words
like 'docol:' or '>code-address', *Note Threading Words::.

   As an alternative to 'set-execute', there is also 'set-does>' (*note
User-defined Defining Words::), which takes an xt.

   Moreover, there are the low-level 'code-address!' and 'definer!'
(*note Threading Words::).

   The 'opt-compile,' method is what 'compile,' does on most Gforth
engines ('gforth-itc' uses ',' instead).  You can define a more
efficient implementation of 'compile,' for the current word with
'set-optimizer' (*note User-defined compile-comma::).  Note that the end
result must be equivalent to 'postpone literal postpone execute'.

   As an example of the use of 'set-optimizer', consider the following
definition of 'constant':

     : constant ( n "name" -- ; name: -- n )
       create ,
       ['] @ set-does>
     ;

     5 constant five
     : foo five ; see foo

   The Forth system does not know that the value of a constant must not
be changed, and just sees a 'create'd word (which can be changed with
'>body'), and 'foo' first pushes the body address of 'five' and then
fetches from there.  With 'set-optimizer' the definition of 'constant'
can be optimized as follows:

     : constant ( n "name" -- ; name: -- n )
       create ,
       ['] @ set-does>
       [: >body @ postpone literal ;] set-optimizer
     ;

   Now 'foo' contains the literal 5 rather than a call to 'five'.

   Note that 'set-execute' and 'set-does>' perform 'set-optimizer'
themselves in order to ensure that 'execute' and 'compile,' agree, so if
you want to add your own optimizer, you should add it afterwards.

   The '(to)' method and 'set-to' are used for implementing 'to _name_'
semantics etc.  (*note Words with user-defined TO etc.::).

   The '>hmextra' field is used for cases where additional data needs to
be stored in the header methods table.  In particular, it stores the xt
passed to 'set-does>' (and 'does>' calls 'set-does>') and the code
address behind ';abi-code'.

   The methods above all consume an xt, not an nt, but the override
words work on the most recent definition.  This means that if you use,
e.g., 'set-optimizer' on a synonym, the effect will probably not be what
you intended: When 'compile,'ing the xt of the word, the 'opt-compile,'
implementation of the original word will be used, not the freshly-set
one of the synonym.

   The following methods consume an nt.

   The 'name>interpret' method is implemented as noop for most words,
except synonyms and similar words.

'set->int' ( xt -  ) gforth-1.0 "set-to-int"
   Sets the implementation of the 'name>interpret ( nt -- xt2 )' method
of the current word to xt.

   The 'name>compile' method produces the compilation semantics of the
nt.  By changing it with 'set->comp', you can change the compilation
semantics, but it's not as simple as just pushing the xt of the desired
compilation semantics, because of the stack effect of 'name>compile'.
Generally you should avoid changing the compilation semantics, and if
you do, use a higher-level word like 'immediate' or
'interpret/compile:', *Note Combined words::.

'set->comp' ( xt -  ) gforth-1.0 "set-to-comp"
   Sets the implementation of the 'name>compile ( nt -- w xt2 )' method
of the current word to xt.

'immediate?' ( nt - flag  ) gforth-1.0 "immediate-question"
   true if the word nt has non-default compilation semantics (that's not
quite according to the definition of immediacy, but many people mean
that when they call a word "immediate").

   'Name>string' and 'Name>link' are methods in order to make it
possible to eliminate the name, '>f+c' and 'link' fields from noname
headers, but still produce meaningful results when using these words.
You will typically not change the implementations of these methods
except with 'noname', but we still have

'set-name>string' ( xt -  ) gforth-1.0 "set-name-to-string"
   Sets the implementation of the 'name>string ( nt -- addr u )' method
of the current word to xt.

'set-name>link' ( xt -  ) gforth-1.0 "set-name-to-link"
   Sets the implementation of the 'name>link ( nt1 -- nt2|0 )' method of
the current word to xt.

6.33.3 Threading Words
----------------------

The terminology used here stems from indirect threaded Forth systems; in
such a system, the XT of a word is represented by the CFA (code field
address) of a word; the CFA points to a cell that contains the code
address.  The code address is the address of some machine code that
performs the run-time action of invoking the word (e.g., the 'dovar:'
routine pushes the address of the body of the word (a variable) on the
stack).

   These words provide access to code fields, code addresses and other
threading stuff in Gforth.  It more or less abstracts away the
differences between direct and indirect threading.

   Up to and including Gforth 0.7, the code address (plus, for
'does>'-defined words, the address returned by '>does-code') was
sufficient to know the type of the word.  However, since Gforth-1.0 the
behaviour or at least implementation of words like 'compile,' and
'name>compile' can be determined independently as described in *note
Header methods::.

   To create a code field and at the same time initialize the header
methods use 'create-from' (*note Creating from a prototype::).

   The following words were designed before the introduction of header
methods, and are therefore not the best (and recommended) way to deal
with different word types in Gforth.

   In an indirect threaded Forth, you can get the code address of name
with '' name @'; in Gforth you can get it with '' name >code-address',
independent of the threading method.

'threading-method' ( - n ) gforth-0.2 "threading-method"
   0 if the engine is direct threaded.  Note that this may change during
the lifetime of an image.

'>code-address' ( xt - c_addr  ) gforth-0.2 "to-code-address"
   c-addr is the code address of the word xt.

'code-address!' ( c_addr xt -  ) gforth-obsolete "code-address-store"
   Change a code field with code address c-addr at xt.

   The code addresses produced by various defining words are produced by
the following words:

'docol:' ( - addr  ) gforth-0.2 "docol-colon"
   The code address of a colon definition.

'docon:' ( - addr  ) gforth-0.2 "docon-colon"
   The code address of a 'CONSTANT'.

'dovar:' ( - addr  ) gforth-0.2 "dovar-colon"
   The code address of a 'CREATE'd word.

'douser:' ( - addr  ) gforth-0.2 "douser-colon"
   The code address of a 'USER' variable.

'dodefer:' ( - addr  ) gforth-0.2 "dodefer-colon"
   The code address of a 'defer'ed word.

'dofield:' ( - addr  ) gforth-0.2 "dofield-colon"
   The code address of a 'field'.

'dovalue:' ( - addr  ) gforth-0.7 "dovalue-colon"
   The code address of a 'CONSTANT'.

'dodoes:' ( - addr  ) gforth-0.6 "dodoes-colon"
   The code address of a 'DOES>'-defined word.

'doabicode:' ( - addr  ) gforth-1.0 "doabicode-colon"
   The code address of a 'ABI-CODE' definition.

   For a word X defined with 'set-does>', the code address points to
'dodoes:', and the '>hmextra' field of the header methods contains the
xt of the word that is called after pushing the body address of X.

   If you want to know whether a word is a 'DOES>'-defined word, and
what Forth code it executes, '>does-code' tells you that:

'>does-code' ( xt1 - xt2  ) gforth-0.2 "to-does-code"
   If xt1 is the execution token of a child of a 'set-does>'-defined
word, xt2 is the xt passed to 'set-does>', i.e, the xt of the word that
is executed when executing xt1 (but first the body address of xt1 is
pushed).  If xt1 does not belong to a 'set-does>'-defined word, xt2 is
0.

   You can use the resulting xt2 with 'set-does>' (preferred) to change
the latest word or with

'does-code!' ( xt2 xt1 -  ) gforth-0.2 "does-code-store"
   Change xt1 to be a 'xt2 set-does>'-defined word.

   to change an arbitrary word.

   The following two words generalize '>code-address', '>does-code',
'code-address!', and 'does-code!':

'>definer' ( xt - definer  ) gforth-0.2 "to-definer"
   DEFINER is a unique identifier for the way the XT was defined.  Words
defined with different 'does>'-codes have different definers.  The
definer can be used for comparison and in 'definer!'.

'definer!' ( definer xt -  ) gforth-obsolete "definer-store"
   The word represented by XT changes its behaviour to the behaviour
associated with DEFINER.

   'Code-address!', 'does-code!', and 'definer!' update the
'opt-compile,' method to a somewhat generic compiler for that word type
(in particular, primitives get the slow 'general-compile,' method rather
than the primitive-specific 'peephole-compile,').

6.34 Passing Commands to the Operating System
=============================================

Gforth allows you to pass an arbitrary string to the host operating
system shell (if such a thing exists) for execution.

'sh' ( "..." -  ) gforth-0.2
   Execute the rest of the command line as shell command(s).
Afterwards, '$?' produces the exit status of the command.

'system' ( c-addr u -  ) gforth-0.2
   Pass the string specified by C-ADDR U to the host operating system
for execution in a sub-shell.  Afterwards, '$?' produces the exit status
of the command.  The value of the environment variable
'GFORTHSYSTEMPREFIX' (or its default value) is prepended to the string
(mainly to support using 'command.com' as shell in Windows instead of
whatever shell Cygwin uses by default; *note Environment variables::).

'sh-get' ( c-addr u - c-addr2 u2  ) gforth-1.0
   Run the shell command addr u; c-addr2 u2 is the output of the
command.  The exit code is in '$?', the output also in 'sh$ 2@'.

'$?' ( - n  ) gforth-0.2 "dollar-question"
   'Value' - the exit status returned by the most recently executed
'system' command.

'getenv' ( c-addr1 u1 - c-addr2 u2 ) gforth-0.2 "getenv"
   The string c-addr1 u1 specifies an environment variable.  The string
c-addr2 u2 is the host operating system's expansion of that environment
variable.  If the environment variable does not exist, c-addr2 u2
specifies a string 0 characters in length.

6.35 Keeping track of Time
==========================

'ms' ( n -  ) facility-ext

'ns' ( d -  ) gforth-1.0

'time&date' ( - nsec nmin nhour nday nmonth nyear  ) facility-ext "time-and-date"
   Report the current time of day.  Seconds, minutes and hours are
numbered from 0.  Months are numbered from 1.

'>time&date&tz' ( udtime - nsec nmin nhour nday nmonth nyear fdst ndstoff c-addrtz utz ) gforth-1.0 "to-time-and-date"
   Convert time in seconds since 1.1.1970 0:00Z to the current time of
day.  Seconds, minutes and hours are numbered from 0.  Months are
numbered from 1.

'utime' ( - dtime ) gforth-0.5 "utime"
   Report the current time in microseconds since some epoch.  Use
'#1000000 um/mod nip' to convert to seconds

'ntime' ( - dtime ) gforth-1.0 "ntime"
   Report the current time in nanoseconds since some epoch.

'cputime' ( - duser dsystem ) gforth-0.5 "cputime"
   duser and dsystem are the respective user- and system-level CPU times
used since the start of the Forth system (excluding child processes), in
microseconds (the granularity may be much larger, however).  On
platforms without the getrusage call, it reports elapsed time (since
some epoch) for duser and 0 for dsystem.

6.36 Miscellaneous Words
========================

This section lists the Standard Forth words that are not documented
elsewhere in this manual.  Ultimately, they all need proper homes.

'quit' ( ?? - ??  ) core
   Empty the return stack, make the user input device the input source,
enter interpret state and start the text interpreter.

   The following Standard Forth words are not currently supported by
Gforth (*note Standard conformance::):

   'EDITOR' 'EMIT?' 'FORGET'

7 Error messages
****************

A typical Gforth error message looks like this:

     in file included from \evaluated string/:-1
     in file included from ./yyy.fs:1
     ./xxx.fs:4: Invalid memory address
     >>>bar<<<
     Backtrace:
     $400E664C @
     $400E6664 foo

   The message identifying the error is 'Invalid memory address'.  The
error happened when text-interpreting line 4 of the file './xxx.fs'.
This line is given (it contains 'bar'), and the word on the line where
the error happened, is pointed out (with '>>>' and '<<<').

   The file containing the error was included in line 1 of './yyy.fs',
and 'yyy.fs' was included from a non-file (in this case, by giving
'yyy.fs' as command-line parameter to Gforth).

   At the end of the error message you find a return stack dump that can
be interpreted as a backtrace (possibly empty).  On top you find the top
of the return stack when the 'throw' happened, and at the bottom you
find the return stack entry just above the return stack of the topmost
text interpreter.

   To the right of most return stack entries you see a guess for the
word that pushed that return stack entry as its return address.  This
gives a backtrace.  In our case we see that 'bar' called 'foo', and
'foo' called '@' (and '@' had an _Invalid memory address_ exception).

   Note that the backtrace is not perfect: We don't know which return
stack entries are return addresses (so we may get false positives); and
in some cases (e.g., for 'abort"') we cannot determine from the return
address the word that pushed the return address, so for some return
addresses you see no names in the return stack dump.

   The return stack dump represents the return stack at the time when a
specific 'throw' was executed.  In programs that make use of 'catch', it
is not necessarily clear which 'throw' should be used for the return
stack dump (e.g., consider one 'throw' that indicates an error, which is
caught, and during recovery another error happens; which 'throw' should
be used for the stack dump?).  Gforth presents the return stack dump for
the first 'throw' after the last executed (not returned-to) 'catch' or
'nothrow'; this works well in the usual case.  To get the right
backtrace, you usually want to insert 'nothrow' or '['] false catch
2drop' after a 'catch' if the error is not rethrown.

   'Gforth' is able to do a return stack dump for throws generated from
primitives (e.g., invalid memory address, stack empty etc.);
'gforth-fast' is only able to do a return stack dump from a directly
called 'throw' (including 'abort' etc.).  Given an exception caused by a
primitive in 'gforth-fast', you will typically see no return stack dump
at all; however, if the exception is caught by 'catch' (e.g., for
restoring some state), and then 'throw'n again, the return stack dump
will be for the first such 'throw'.

   'gforth-fast' also does not attempt to differentiate between division
by zero and division overflow, because that costs time in every
division.

8 Tools
*******

See also *note Emacs and Gforth::.

8.1 'ans-report.fs': Report the words used, sorted by wordset
=============================================================

If you want to label a Forth program as Standard Program, you must
document which wordsets the program uses.

   The 'ans-report.fs' tool makes it easy for you to determine which
words from which wordset and which non-standard words your application
uses.  You simply have to include 'ans-report.fs' before loading the
program you want to check.  After loading your program, you can get the
report with 'print-ans-report'.  A typical use is to run this as batch
job like this:
     gforth ans-report.fs myprog.fs -e "print-ans-report bye"

   The output looks like this (for 'compat/control.fs'):
     The program uses the following words
     from CORE :
     : POSTPONE THEN ; immediate ?dup IF 0=
     from BLOCK-EXT :
     \
     from FILE :
     (

   'ans-report.fs' reports both Forth-94 and Forth-2012 wordsets.  For
words that are in both standards, it reports the wordset without suffix
(e.g., 'CORE-EXT').  For Forth-2012-only words, it reports the wordset
with a '-2012' suffix (e.g., 'CORE-EXT-2012'); and likewise for the
words that are Forth-94-only (i.e., that have been removed in
Forth-2012).

8.1.1 Caveats
-------------

Note that 'ans-report.fs' just checks which words are used, not whether
they are used in a standard-conforming way!

   Some words are defined in several wordsets in the standard.
'ans-report.fs' reports them for only one of the wordsets, and not
necessarily the one you expect.  It depends on usage which wordset is
the right one to specify.  E.g., if you only use the compilation
semantics of 'S"', it is a Core word; if you also use its interpretation
semantics, it is a File word.

8.2 Stack depth changes during interpretation
=============================================

Sometimes you notice that, after loading a file, there are items left on
the stack.  The tool 'depth-changes.fs' helps you find out quickly where
in the file these stack items are coming from.

   The simplest way of using 'depth-changes.fs' is to include it before
the file(s) you want to check, e.g.:

     gforth depth-changes.fs my-file.fs

   This will compare the stack depths of the data and FP stack at every
empty line (in interpretation state) against these depths at the last
empty line (in interpretation state).  If the depths are not equal, the
position in the file and the stack contents are printed with '~~' (*note
Debugging::).  This indicates that a stack depth change has occurred in
the paragraph of non-empty lines before the indicated line.  It is a
good idea to leave an empty line at the end of the file, so the last
paragraph is checked, too.

   Checking only at empty lines usually works well, but sometimes you
have big blocks of non-empty lines (e.g., when building a big table),
and you want to know where in this block the stack depth changed.  You
can check all interpreted lines with

     gforth depth-changes.fs -e "' all-lines is depth-changes-filter" my-file.fs

   This checks the stack depth at every end-of-line.  So the depth
change occurred in the line reported by the '~~' (not in the line
before).

   Note that, while this offers better accuracy in indicating where the
stack depth changes, it will often report many intentional stack depth
changes (e.g., when an interpreted computation stretches across several
lines).  You can suppress the checking of some lines by putting
backslashes at the end of these lines (not followed by white space), and
using

     gforth depth-changes.fs -e "' most-lines is depth-changes-filter" my-file.fs

9 Standard conformance
**********************

To the best of our knowledge, Gforth is a

   ANS Forth System and a Forth-2012 System
   * providing the Core Extensions word set
   * providing the Block word set
   * providing the Block Extensions word set
   * providing the Double-Number word set
   * providing the Double-Number Extensions word set
   * providing the Exception word set
   * providing the Exception Extensions word set
   * providing the Facility word set
   * providing the Facility Extensions word set, except 'EMIT?'
   * providing the File Access word set
   * providing the File Access Extensions word set
   * providing the Floating-Point word set
   * providing the Floating-Point Extensions word set
   * providing the Locals word set
   * providing the Locals Extensions word set
   * providing the Memory-Allocation word set
   * providing the Memory-Allocation Extensions word set
   * providing the Programming-Tools word set
   * providing the Programming-Tools Extensions word set, except
     'EDITOR' and 'FORGET'
   * providing the Search-Order word set
   * providing the Search-Order Extensions word set
   * providing the String word set
   * providing the String Extensions word set
   * providing the Extended-Character wordset

   Gforth has the following environmental restrictions:

   * While processing the OS command line, if an exception is not
     caught, Gforth exits with a non-zero exit code instead of
     performing QUIT.

   * When an 'throw' is performed after a 'query', Gforth does not
     always restore the input source specification in effect at the
     corresponding catch.

   In addition, Standard Forth systems are required to document certain
implementation choices.  This chapter tries to meet these requirements
for the Forth-94 standard.  For the Forth-2012 standard, we decided to
produce the additional documentation only if there is demand.  So if you
are really missing this documentation, please let us know.

   In many cases, the following documentation gives a way to ask the
system for the information instead of providing the information
directly, in particular, if the information depends on the processor,
the operating system or the installation options chosen, or if they are
likely to change during the maintenance of Gforth.

9.1 The Core Words
==================

9.1.1 Implementation Defined Options
------------------------------------

(Cell) aligned addresses:
     processor-dependent.  Gforth's alignment words perform natural
     alignment (e.g., an address aligned for a datum of size 8 is
     divisible by 8).  Unaligned accesses usually result in a '-23
     THROW'.

'EMIT' and non-graphic characters:
     The character is output using the C library function (actually,
     macro) 'putc'.

character editing of 'ACCEPT' and 'EXPECT':
     This is modeled on the GNU readline library (*note Command Line
     Editing: (readline)Readline Interaction.) with Emacs-like key
     bindings.  'Tab' deviates a little by producing a full word
     completion every time you type it (instead of producing the common
     prefix of all completions).  *Note Command-line editing::.

character set:
     The character set of your computer and display device.  Gforth is
     8-bit-clean (but some other component in your system may make
     trouble).

Character-aligned address requirements:
     installation-dependent.  Currently a character is represented by a
     C 'unsigned char'; in the future we might switch to 'wchar_t'
     (Comments on that requested).

character-set extensions and matching of names:
     Any character except the ASCII NUL character can be used in a name.
     Matching is case-insensitive (except in 'TABLE's).  The matching is
     performed using the C library function 'strncasecmp', whose
     function is probably influenced by the locale.  E.g., the 'C'
     locale does not know about accents and umlauts, so they are matched
     case-sensitively in that locale.  For portability reasons it is
     best to write programs such that they work in the 'C' locale.  Then
     one can use libraries written by a Polish programmer (who might use
     words containing ISO Latin-2 encoded characters) and by a French
     programmer (ISO Latin-1) in the same program (of course, 'WORDS'
     will produce funny results for some of the words (which ones,
     depends on the font you are using)).  Also, the locale you prefer
     may not be available in other operating systems.  Hopefully,
     Unicode will solve these problems one day.

conditions under which control characters match a space delimiter:
     If 'word' is called with the space character as a delimiter, all
     white-space characters (as identified by the C macro 'isspace()')
     are delimiters.  'Parse', on the other hand, treats space like
     other delimiters.  'Parse-name', which is used by the outer
     interpreter (aka text interpreter) by default, treats all
     white-space characters as delimiters.

format of the control-flow stack:
     The data stack is used as control-flow stack.  The size of a
     control-flow stack item in cells is given by the constant
     'cs-item-size'.  At the time of this writing, an item consists of a
     (pointer to a) locals list (third), an address in the code
     (second), and a tag for identifying the item (TOS). The following
     tags are used: 'defstart', 'live-orig', 'dead-orig', 'dest',
     'do-dest', 'scopestart'.

conversion of digits > 35
     The characters '[\]^_'' are the digits with the decimal value
     36-41.  There is no way to input many of the larger digits.

display after input terminates in 'ACCEPT' and 'EXPECT':
     The cursor is moved to the end of the entered string.  If the input
     is terminated using the 'Return' key, a space is typed.

exception abort sequence of 'ABORT"':
     The error string is stored into the variable 'abort-string' and a
     '-2 throw' is performed.

input line terminator:
     For interactive input, 'C-m' (CR) and 'C-j' (LF) terminate lines.
     One of these characters is typically produced when you type the
     'Enter' or 'Return' key.

maximum size of a counted string:
     's" /counted-string" environment? drop .'.  Currently 255
     characters on all platforms, but this may change.

maximum size of a parsed string:
     Given by the constant '/line'.  Currently 255 characters.

maximum size of a definition name, in characters:
     MAXU/8

maximum string length for 'ENVIRONMENT?', in characters:
     MAXU/8

method of selecting the user input device:
     The user input device is the standard input.  There is currently no
     way to change it from within Gforth.  However, the input can
     typically be redirected in the command line that starts Gforth.

method of selecting the user output device:
     'EMIT' and 'TYPE' output to the file-id stored in the value
     'outfile-id' ('stdout' by default).  Gforth uses unbuffered output
     when the user output device is a terminal, otherwise the output is
     buffered.

methods of dictionary compilation:
     What are we expected to document here?

number of bits in one address unit:
     's" address-units-bits" environment? drop .'.  8 in all current
     platforms.

number representation and arithmetic:
     Processor-dependent.  Binary two's complement on all current
     platforms.

ranges for integer types:
     Installation-dependent.  Make environmental queries for 'MAX-N',
     'MAX-U', 'MAX-D' and 'MAX-UD'.  The lower bounds for unsigned (and
     positive) types is 0.  The lower bound for signed types on two's
     complement and one's complement machines machines can be computed
     by adding 1 to the upper bound.

read-only data space regions:
     The whole Forth data space is writable.

size of buffer at 'WORD':
     'PAD HERE - .'.  104 characters on 32-bit machines.  The buffer is
     shared with the pictured numeric output string.  If overwriting
     'PAD' is acceptable, it is as large as the remaining dictionary
     space, although only as much can be sensibly used as fits in a
     counted string.

size of one cell in address units:
     '1 cells .'.

size of one character in address units:
     '1 chars .'.  1 on all current platforms.

size of the keyboard terminal buffer:
     Varies.  You can determine the size at a specific time using 'lp@
     tib - .'.  It is shared with the locals stack and TIBs of files
     that include the current file.  You can change the amount of space
     for TIBs and locals stack at Gforth startup with the command line
     option '-l'.

size of the pictured numeric output buffer:
     'PAD HERE - .'.  104 characters on 32-bit machines.  The buffer is
     shared with 'WORD'.

size of the scratch area returned by 'PAD':
     The remainder of dictionary space.  'unused pad here - - .'.

system case-sensitivity characteristics:
     Dictionary searches are case-insensitive (except in 'TABLE's).
     However, as explained above under character-set extensions, the
     matching for non-ASCII characters is determined by the locale you
     are using.  In the default 'C' locale all non-ASCII characters are
     matched case-sensitively.

system prompt:
     ' ok' in interpret state, ' compiled' in compile state.

division rounding:
     The ordinary division words '/ mod /mod */ */mod' perform floored
     division (with the default installation of Gforth).  You can check
     this with 's" floored" environment? drop .'.  If you write programs
     that need a specific division rounding, best use 'fm/mod' or
     'sm/rem' for portability.

values of 'STATE' when true:
     -1.

values returned after arithmetic overflow:
     On two's complement machines, arithmetic is performed modulo
     2**bits-per-cell for single arithmetic and 4**bits-per-cell for
     double arithmetic (with appropriate mapping for signed types).
     Division by zero typically results in a '-55 throw' (Floating-point
     unidentified fault) or '-10 throw' (divide by zero).  Integer
     division overflow can result in these throws, or in '-11 throw'; in
     'gforth-fast' division overflow and divide by zero may also result
     in returning bogus results without producing an exception.

whether the current definition can be found after DOES>:
     No.

9.1.2 Ambiguous conditions
--------------------------

a name is neither a word nor a number:
     '-13 throw' (Undefined word).

a definition name exceeds the maximum length allowed:
     '-19 throw' (Word name too long)

addressing a region not inside the various data spaces of the forth system:
     The stacks, code space and header space are accessible.  Machine
     code space is typically readable.  Accessing other addresses gives
     results dependent on the operating system.  On decent systems: '-9
     throw' (Invalid memory address).

argument type incompatible with parameter:
     This is usually not caught.  Some words perform checks, e.g., the
     control flow words, and issue a 'ABORT"' or '-12 THROW' (Argument
     type mismatch).

attempting to obtain the execution token of a word with undefined execution semantics:
     The execution token represents the interpretation semantics of the
     word.  Gforth defines interpretation semantics for all words; for
     words where the standard does not define interpretation semantics,
     but defines the execution semantics (except 'LEAVE'), the
     interpretation semantics are to perform the execution semantics.
     For words where the standard defines no interprtation semantics,
     but defined compilation semantics (plus 'LEAVE'), the
     interpretation semantics are to perform the compilation semantics.
     Some words are marked as compile-only, and ''' gives a warning for
     these words.

dividing by zero:
     On some platforms, this produces a '-10 throw' (Division by zero);
     on other systems, this typically results in a '-55 throw'
     (Floating-point unidentified fault).

insufficient data stack or return stack space:
     Depending on the operating system, the installation, and the
     invocation of Gforth, this is either checked by the memory
     management hardware, or it is not checked.  If it is checked, you
     typically get a '-3 throw' (Stack overflow), '-5 throw' (Return
     stack overflow), or '-9 throw' (Invalid memory address) (depending
     on the platform and how you achieved the overflow) as soon as the
     overflow happens.  If it is not checked, overflows typically result
     in mysterious illegal memory accesses, producing '-9 throw'
     (Invalid memory address) or '-23 throw' (Address alignment
     exception); they might also destroy the internal data structure of
     'ALLOCATE' and friends, resulting in various errors in these words.

insufficient space for loop control parameters:
     Like other return stack overflows.

insufficient space in the dictionary:
     If you try to allot (either directly with 'allot', or indirectly
     with ',', 'create' etc.)  more memory than available in the
     dictionary, you get a '-8 throw' (Dictionary overflow).  If you try
     to access memory beyond the end of the dictionary, the results are
     similar to stack overflows.

interpreting a word with undefined interpretation semantics:
     Gforth defines interpretation semantics for all words; for words
     where the standard defines execution semantics (except 'LEAVE'),
     the interpretation semantics are to perform the execution
     semantics.  For words where the standard defines no interprtation
     semantics, but defined compilation semantics (plus 'LEAVE'), the
     interpretation semantics are to perform the compilation semantics.
     Some words are marked as compile-only, and text-interpreting them
     gives a warning.

modifying the contents of the input buffer or a string literal:
     These are located in writable memory and can be modified.

overflow of the pictured numeric output string:
     '-17 throw' (Pictured numeric output string overflow).

parsed string overflow:
     'PARSE' cannot overflow.  'WORD' does not check for overflow.

producing a result out of range:
     On two's complement machines, arithmetic is performed modulo
     2**bits-per-cell for single arithmetic and 4**bits-per-cell for
     double arithmetic (with appropriate mapping for signed types).
     Division by zero typically results in a '-10 throw' (divide by
     zero) or '-55 throw' (floating point unidentified fault).  Overflow
     on division may result in these errors or in '-11 throw' (result
     out of range).  'Gforth-fast' may silently produce bogus results on
     division overflow or division by zero.  'Convert' and '>number'
     currently overflow silently.

reading from an empty data or return stack:
     The data stack is checked by the outer (aka text) interpreter after
     every word executed.  If it has underflowed, a '-4 throw' (Stack
     underflow) is performed.  Apart from that, stacks may be checked or
     not, depending on operating system, installation, and invocation.
     If they are caught by a check, they typically result in '-4 throw'
     (Stack underflow), '-6 throw' (Return stack underflow) or '-9
     throw' (Invalid memory address), depending on the platform and
     which stack underflows and by how much.  Note that even if the
     system uses checking (through the MMU), your program may have to
     underflow by a significant number of stack items to trigger the
     reaction (the reason for this is that the MMU, and therefore the
     checking, works with a page-size granularity).  If there is no
     checking, the symptoms resulting from an underflow are similar to
     those from an overflow.  Unbalanced return stack errors can result
     in a variety of symptoms, including '-9 throw' (Invalid memory
     address) and Illegal Instruction (typically '-260 throw').

unexpected end of the input buffer, resulting in an attempt to use a zero-length string as a name:
     'Create' and its descendants perform a '-16 throw' (Attempt to use
     zero-length string as a name).  Words like ''' probably will not
     find what they search.  Note that it is possible to create
     zero-length names with 'nextname' (should it not?).

'>IN' greater than input buffer:
     The next invocation of a parsing word returns a string with length
     0.

'RECURSE' appears after 'DOES>':
     Compiles a recursive call to the code after 'DOES>'.

argument input source different than current input source for 'RESTORE-INPUT':
     '-12 THROW'.  Note that, once an input file is closed (e.g.,
     because the end of the file was reached), its source-id may be
     reused.  Therefore, restoring an input source specification
     referencing a closed file may lead to unpredictable results instead
     of a '-12 THROW'.

     In the future, Gforth may be able to restore input source
     specifications from other than the current input source.

data space containing definitions gets de-allocated:
     Deallocation with 'allot' is not checked.  This typically results
     in memory access faults or execution of illegal instructions.

data space read/write with incorrect alignment:
     Processor-dependent.  Typically results in a '-23 throw' (Address
     alignment exception).  Under Linux-Intel on a 486 or later
     processor with alignment turned on, incorrect alignment results in
     a '-9 throw' (Invalid memory address).  There are reportedly some
     processors with alignment restrictions that do not report
     violations.

data space pointer not properly aligned, ',', 'C,':
     Like other alignment errors.

less than u+2 stack items ('PICK' and 'ROLL'):
     Like other stack underflows.

loop control parameters not available:
     Not checked.  The counted loop words simply assume that the top of
     return stack items are loop control parameters and behave
     accordingly.

most recent definition does not have a name ('IMMEDIATE'):
     'abort" last word was headerless"'.

name not defined by 'VALUE' used by 'TO':
     '-32 throw' (Invalid name argument) (unless name is a local or was
     defined by 'CONSTANT'; in the latter case it just changes the
     constant).

name not found (''', 'POSTPONE', '[']', '[COMPILE]'):
     '-13 throw' (Undefined word)

parameters are not of the same type ('DO', '?DO', 'WITHIN'):
     Gforth behaves as if they were of the same type.  I.e., you can
     predict the behaviour by interpreting all parameters as, e.g.,
     signed.

'POSTPONE' or '[COMPILE]' applied to 'TO':
     Assume ': X POSTPONE TO ; IMMEDIATE'.  'X' performs the compilation
     semantics of 'TO'.

String longer than a counted string returned by 'WORD':
     Not checked.  The string will be ok, but the count will, of course,
     contain only the least significant bits of the length.

u greater than or equal to the number of bits in a cell ('LSHIFT', 'RSHIFT'):
     Processor-dependent.  Typical behaviours are returning 0 and using
     only the low bits of the shift count.

word not defined via 'CREATE':
     '>BODY' produces the PFA of the word no matter how it was defined.

     'DOES>' changes the execution semantics of the last defined word no
     matter how it was defined.  E.g., 'CONSTANT DOES>' is equivalent to
     'CREATE , DOES>'.

words improperly used outside '<#' and '#>':
     Not checked.  As usual, you can expect memory faults.

9.1.3 Other system documentation
--------------------------------

nonstandard words using 'PAD':
     None.

operator's terminal facilities available:
     After processing the OS's command line, Gforth goes into
     interactive mode, and you can give commands to Gforth
     interactively.  The actual facilities available depend on how you
     invoke Gforth.

program data space available:
     'UNUSED .' gives the remaining dictionary space.  The total
     dictionary space can be specified with the '-m' switch (*note
     Invoking Gforth::) when Gforth starts up.

return stack space available:
     You can compute the total return stack space in cells with 's"
     RETURN-STACK-CELLS" environment? drop .'.  You can specify it at
     startup time with the '-r' switch (*note Invoking Gforth::).

stack space available:
     You can compute the total data stack space in cells with 's"
     STACK-CELLS" environment? drop .'.  You can specify it at startup
     time with the '-d' switch (*note Invoking Gforth::).

system dictionary space required, in address units:
     Type 'here forthstart - .' after startup.  At the time of this
     writing, this gives 80080 (bytes) on a 32-bit system.

9.2 The optional Block word set
===============================

9.2.1 Implementation Defined Options
------------------------------------

the format for display by 'LIST':
     First the screen number is displayed, then 16 lines of 64
     characters, each line preceded by the line number.

the length of a line affected by '\':
     64 characters.

9.2.2 Ambiguous conditions
--------------------------

correct block read was not possible:
     Typically results in a 'throw' of some OS-derived value (between
     -512 and -2048).  If the blocks file was just not long enough,
     blanks are supplied for the missing portion.

I/O exception in block transfer:
     Typically results in a 'throw' of some OS-derived value (between
     -512 and -2048).

invalid block number:
     '-35 throw' (Invalid block number)

a program directly alters the contents of 'BLK':
     The input stream is switched to that other block, at the same
     position.  If the storing to 'BLK' happens when interpreting
     non-block input, the system will get quite confused when the block
     ends.

no current block buffer for 'UPDATE':
     'UPDATE' has no effect.

9.2.3 Other system documentation
--------------------------------

any restrictions a multiprogramming system places on the use of buffer addresses:
     No restrictions (yet).

the number of blocks available for source and data:
     depends on your disk space.

9.3 The optional Double Number word set
=======================================

9.3.1 Ambiguous conditions
--------------------------

d outside of range of n in 'D>S':
     The least significant cell of d is produced.

9.4 The optional Exception word set
===================================

9.4.1 Implementation Defined Options
------------------------------------

'THROW'-codes used in the system:
     The codes -256--511 are used for reporting signals.  The mapping
     from OS signal numbers to throw codes is -256-signal.  The codes
     -512--2047 are used for OS errors (for file and memory allocation
     operations).  The mapping from OS error numbers to throw codes is
     -512-'errno'.  One side effect of this mapping is that undefined OS
     errors produce a message with a strange number; e.g., '-1000 THROW'
     results in 'Unknown error 488' on my system.

9.5 The optional Facility word set
==================================

9.5.1 Implementation Defined Options
------------------------------------

encoding of keyboard events ('EKEY'):
     Keys corresponding to ASCII characters are encoded as ASCII
     characters.  Other keys are encoded with the constants 'k-left',
     'k-right', 'k-up', 'k-down', 'k-home', 'k-end', 'k1', 'k2', 'k3',
     'k4', 'k5', 'k6', 'k7', 'k8', 'k9', 'k10', 'k11', 'k12', 'k-winch',
     'k-eof'.

duration of a system clock tick:
     System dependent.  With respect to 'MS', the time is specified in
     microseconds.  How well the OS and the hardware implement this, is
     another question.

repeatability to be expected from the execution of 'MS':
     System dependent.  On Unix, a lot depends on load.  If the system
     is lightly loaded, and the delay is short enough that Gforth does
     not get swapped out, the performance should be acceptable.  Under
     MS-DOS and other single-tasking systems, it should be good.

9.5.2 Ambiguous conditions
--------------------------

'AT-XY' can't be performed on user output device:
     Largely terminal dependent.  No range checks are done on the
     arguments.  No errors are reported.  You may see some garbage
     appearing, you may see simply nothing happen.

9.6 The optional File-Access word set
=====================================

9.6.1 Implementation Defined Options
------------------------------------

file access methods used:
     'R/O', 'R/W' and 'BIN' work as you would expect.  'W/O' translates
     into the C file opening mode 'w' (or 'wb'): The file is cleared, if
     it exists, and created, if it does not (with both 'open-file' and
     'create-file').  Under Unix 'create-file' creates a file with 666
     permissions modified by your umask.

file exceptions:
     The file words do not raise exceptions (except, perhaps, memory
     access faults when you pass illegal addresses or file-ids).

file line terminator:
     System-dependent.  Gforth uses C's newline character as line
     terminator.  What the actual character code(s) of this are is
     system-dependent.

file name format:
     System dependent.  Gforth just uses the file name format of your
     OS.

information returned by 'FILE-STATUS':
     'FILE-STATUS' returns the most powerful file access mode allowed
     for the file: Either 'R/O', 'W/O' or 'R/W'.  If the file cannot be
     accessed, 'R/O BIN' is returned.  'BIN' is applicable along with
     the returned mode.

input file state after an exception when including source:
     All files that are left via the exception are closed.

ior values and meaning:
     The iors returned by the file and memory allocation words are
     intended as throw codes.  They typically are in the range
     -512--2047 of OS errors.  The mapping from OS error numbers to iors
     is -512-errno.

maximum depth of file input nesting:
     limited by the amount of return stack, locals/TIB stack, and the
     number of open files available.  This should not give you troubles.

maximum size of input line:
     '/line'.  Currently 255.

methods of mapping block ranges to files:
     By default, blocks are accessed in the file 'blocks.fb' in the
     current working directory.  The file can be switched with 'USE'.

number of string buffers provided by 'S"':
     As many as memory available; the strings are stored in memory
     blocks allocated with ALLOCATE indefinitely.

size of string buffer used by 'S"':
     '/line'.  currently 255.

9.6.2 Ambiguous conditions
--------------------------

attempting to position a file outside its boundaries:
     'REPOSITION-FILE' is performed as usual: Afterwards,
     'FILE-POSITION' returns the value given to 'REPOSITION-FILE'.

attempting to read from file positions not yet written:
     End-of-file, i.e., zero characters are read and no error is
     reported.

file-id is invalid ('INCLUDE-FILE'):
     An appropriate exception may be thrown, but a memory fault or other
     problem is more probable.

I/O exception reading or closing file-id ('INCLUDE-FILE', 'INCLUDED'):
     The ior produced by the operation, that discovered the problem, is
     thrown.

named file cannot be opened ('INCLUDED'):
     The ior produced by 'open-file' is thrown.

requesting an unmapped block number:
     There are no unmapped legal block numbers.  On some operating
     systems, writing a block with a large number may overflow the file
     system and have an error message as consequence.

using 'source-id' when 'blk' is non-zero:
     'source-id' performs its function.  Typically it will give the id
     of the source which loaded the block.  (Better ideas?)

9.7 The optional Floating-Point word set
========================================

9.7.1 Implementation Defined Options
------------------------------------

format and range of floating point numbers:
     System-dependent; the 'double' type of C.

results of 'REPRESENT' when float is out of range:
     System dependent; 'REPRESENT' is implemented using the C library
     function 'ecvt()' and inherits its behaviour in this respect.

rounding or truncation of floating-point numbers:
     System dependent; the rounding behaviour is inherited from the
     hosting C compiler.  IEEE-FP-based (i.e., most) systems by default
     round to nearest, and break ties by rounding to even (i.e., such
     that the last bit of the mantissa is 0).

size of floating-point stack:
     's" FLOATING-STACK" environment? drop .' gives the total size of
     the floating-point stack (in floats).  You can specify this on
     startup with the command-line option '-f' (*note Invoking
     Gforth::).

width of floating-point stack:
     '1 floats'.

9.7.2 Ambiguous conditions
--------------------------

'df@' or 'df!' used with an address that is not double-float aligned:
     System-dependent.  Typically results in a '-23 THROW' like other
     alignment violations.

'f@' or 'f!' used with an address that is not float aligned:
     System-dependent.  Typically results in a '-23 THROW' like other
     alignment violations.

floating-point result out of range:
     System-dependent.  Can result in a '-43 throw' (floating point
     overflow), '-54 throw' (floating point underflow), '-41 throw'
     (floating point inexact result), '-55 THROW' (Floating-point
     unidentified fault), or can produce a special value representing,
     e.g., Infinity.

'sf@' or 'sf!' used with an address that is not single-float aligned:
     System-dependent.  Typically results in an alignment fault like
     other alignment violations.

'base' is not decimal ('REPRESENT', 'F.', 'FE.', 'FS.'):
     The floating-point number is converted into decimal nonetheless.

Both arguments are equal to zero ('FATAN2'):
     System-dependent.  'FATAN2' is implemented using the C library
     function 'atan2()'.

Using 'FTAN' on an argument r1 where cos(r1) is zero:
     System-dependent.  Anyway, typically the cos of r1 will not be zero
     because of small errors and the tan will be a very large (or very
     small) but finite number.

d cannot be presented precisely as a float in 'D>F':
     The result is rounded to the nearest float.

dividing by zero:
     Platform-dependent; can produce an Infinity, NaN, '-42 throw'
     (floating point divide by zero) or '-55 throw' (Floating-point
     unidentified fault).

exponent too big for conversion ('DF!', 'DF@', 'SF!', 'SF@'):
     System dependent.  On IEEE-FP based systems the number is converted
     into an infinity.

float<1 ('FACOSH'):
     Platform-dependent; on IEEE-FP systems typically produces a NaN.

float<=-1 ('FLNP1'):
     Platform-dependent; on IEEE-FP systems typically produces a NaN (or
     a negative infinity for float=-1).

float<=0 ('FLN', 'FLOG'):
     Platform-dependent; on IEEE-FP systems typically produces a NaN (or
     a negative infinity for float=0).

float<0 ('FASINH', 'FSQRT'):
     Platform-dependent; for 'fsqrt' this typically gives a NaN, for
     'fasinh' some platforms produce a NaN, others a number (bug in the
     C library?).

|float|>1 ('FACOS', 'FASIN', 'FATANH'):
     Platform-dependent; IEEE-FP systems typically produce a NaN.

integer part of float cannot be represented by d in 'F>D':
     Platform-dependent; typically, some double number is produced and
     no error is reported.

string larger than pictured numeric output area ('f.', 'fe.', 'fs.'):
     'Precision' characters of the numeric output area are used.  If
     'precision' is too high, these words will smash the data or code
     close to 'here'.

9.8 The optional Locals word set
================================

9.8.1 Implementation Defined Options
------------------------------------

maximum number of locals in a definition:
     's" #locals" environment? drop .'.  Currently 15.  This is a lower
     bound, e.g., on a 32-bit machine there can be 41 locals of up to 8
     characters.  The number of locals in a definition is bounded by the
     size of locals-buffer, which contains the names of the locals.

9.8.2 Ambiguous conditions
--------------------------

executing a named local in interpretation state:
     Compiles the local into the current definition (just as in compile
     state); in addition text-interpreting a local in interpretation
     state gives an "is compile-only" warning.

name not defined by 'VALUE' or '(LOCAL)' ('TO'):
     '-32 throw' (Invalid name argument)

9.9 The optional Memory-Allocation word set
===========================================

9.9.1 Implementation Defined Options
------------------------------------

values and meaning of ior:
     The iors returned by the file and memory allocation words are
     intended as throw codes.  They typically are in the range
     -512--2047 of OS errors.  The mapping from OS error numbers to iors
     is -512-errno.

9.10 The optional Programming-Tools word set
============================================

9.10.1 Implementation Defined Options
-------------------------------------

ending sequence for input following ';CODE' and 'CODE':
     'END-CODE'

manner of processing input following ';CODE' and 'CODE':
     The 'ASSEMBLER' vocabulary is pushed on the search order stack, and
     the input is processed by the text interpreter, (starting) in
     interpret state.

search order capability for 'EDITOR' and 'ASSEMBLER':
     The Search-Order word set.

source and format of display by 'SEE':
     The source for 'see' is the executable code used by the inner
     interpreter.  The current 'see' tries to output Forth source code
     (and on some platforms, assembly code for primitives) as well as
     possible.

9.10.2 Ambiguous conditions
---------------------------

deleting the compilation word list ('FORGET'):
     Not implemented (yet).

fewer than u+1 items on the control-flow stack ('CS-PICK', 'CS-ROLL'):
     This typically results in an 'abort"' with a descriptive error
     message (may change into a '-22 throw' (Control structure mismatch)
     in the future).  You may also get a memory access error.  If you
     are unlucky, this ambiguous condition is not caught.

name can't be found ('FORGET'):
     Not implemented (yet).

name not defined via 'CREATE':
     ';CODE' behaves like 'DOES>' in this respect, i.e., it changes the
     execution semantics of the last defined word no matter how it was
     defined.

'POSTPONE' applied to '[IF]':
     After defining ': X POSTPONE [IF] ; IMMEDIATE'.  'X' is equivalent
     to '[IF]'.

reaching the end of the input source before matching '[ELSE]' or '[THEN]':
     Continue in the same state of conditional compilation in the next
     outer input source.  Currently there is no warning to the user
     about this.

removing a needed definition ('FORGET'):
     Not implemented (yet).

9.11 The optional Search-Order word set
=======================================

9.11.1 Implementation Defined Options
-------------------------------------

maximum number of word lists in search order:
     's" wordlists" environment? drop .'.  Currently 16.

minimum search order:
     'root root'.

9.11.2 Ambiguous conditions
---------------------------

changing the compilation word list (during compilation):
     The word is entered into the word list that was the compilation
     word list at the start of the definition.  Any changes to the name
     field (e.g., 'immediate') or the code field (e.g., when executing
     'DOES>') are applied to the latest defined word (as reported by
     'latest' or 'latestxt'), if possible, irrespective of the
     compilation word list.

search order empty ('previous'):
     'abort" Vocstack empty"'.

too many word lists in search order ('also'):
     'abort" Vocstack full"'.

10 Should I use Gforth extensions?
**********************************

As you read through the rest of this manual, you will see documentation
for Standard words, and documentation for some appealing Gforth
extensions.  You might ask yourself the question: "Should I restrict
myself to the standard, or should I use the extensions?"

   The answer depends on the goals you have for the program you are
working on:

   * Is it just for yourself or do you want to share it with others?

   * If you want to share it, do the others all use Gforth?

   * If it is just for yourself, do you want to restrict yourself to
     Gforth?

   If restricting the program to Gforth is ok, then there is no reason
not to use extensions.  It is still a good idea to keep to the standard
where it is easy, in case you want to reuse these parts in another
program that you want to be portable.

   If you want to be able to port the program to other Forth systems,
there are the following points to consider:

   * Most Forth systems that are being maintained support Standard
     Forth.  So if your program complies with the standard, it will be
     portable among many systems.

   * A number of the Gforth extensions can be implemented in Standard
     Forth using public-domain files provided in the 'compat/'
     directory.  These are mentioned in the text in passing.  There is
     no reason not to use these extensions, your program will still be
     Standard Forth compliant; just include the appropriate compat files
     with your program.

   * The tool 'ans-report.fs' (*note Standard Report::) makes it easy to
     analyse your program and determine what non-Standard words it
     relies upon.  However, it does not check whether you use standard
     words in a non-standard way.

   * Some techniques are not standardized by Standard Forth, and are
     hard or impossible to implement in a standard way, but can be
     implemented in most Forth systems easily, and usually in similar
     ways (e.g., accessing word headers).  Forth has a rich historical
     precedent for programmers taking advantage of
     implementation-dependent features of their tools (for example,
     relying on a knowledge of the dictionary structure).  Sometimes
     these techniques are necessary to extract every last bit of
     performance from the hardware, sometimes they are just a
     programming shorthand.

   * Does using a Gforth extension save more work than the porting this
     part to other Forth systems (if any) will cost?

   * Is the additional functionality worth the reduction in portability
     and the additional porting problems?

   In order to perform these considerations, you need to know what's
standard and what's not.  This manual generally states if something is
non-standard, but the authoritative source is the standard document
(https://forth-standard.org/standard/words).  Appendix A of the Standard
(RATIONALE) provides a valuable insight into the thought processes of
the technical committee.

   Note also that portability between Forth systems is not the only
portability issue; there is also the issue of portability between
different platforms (processor/OS combinations).

11 Model
********

This chapter has yet to be written.  It will contain information, on
which internal structures you can rely.

12 Integrating Gforth into C programs
*************************************

Several people like to use Forth as scripting language for applications
that are otherwise written in C, C++, or some other language.

   The Forth system ATLAST provides facilities for embedding it into
applications; unfortunately it has several disadvantages: most
importantly, it is not based on Standard Forth, and it is apparently
dead (i.e., not developed further and not supported).  The facilities
provided by Gforth in this area are inspired by ATLAST's facilities, so
making the switch should not be hard.

   We also tried to design the interface such that it can easily be
implemented by other Forth systems, so that we may one day arrive at a
standardized interface.  Such a standard interface would allow you to
replace the Forth system without having to rewrite C code.

   You embed the Gforth interpreter by linking with the library
'libgforth.a' or 'libgforth.so' (give the compiler the option
'-lgforth', or for one of the other engines '-lgforth-fast',
'-lgforth-itc', or '-lgforth-ditc').  All global symbols in this library
that belong to the interface, have the prefix 'gforth_'; if a common
interface emerges, the functions may also be available through
'#define's with the prefix 'forth_'.

   You can include the declarations of Forth types, the functions and
variables of the interface with '#include <gforth.h>'.

   You can now run a Gforth session by either calling 'gforth_main' or
using the components:

     Cell gforth_main(int argc, char **argv, char **env)
     {
       Cell retvalue=gforth_start(argc, argv);

       if(retvalue == -56) { /* throw-code for quit */
         retvalue = gforth_bootmessage();     // show boot message
         if(retvalue == -56)
           retvalue = gforth_quit(); // run quit loop
       }
       gforth_cleanup();
       gforth_printmetrics();
       // gforth_free_dict(); // if you want to restart, do this

       return retvalue;
     }

   To interact with the Forth interpreter, there's 'Xt gforth_find(Char
* name)' and 'Cell gforth_execute(Xt xt)'.

   More documentation needs to be put here.

12.1 Types
==========

'Cell', 'UCell': data stack elements.

   'Float': float stack element.

   'Address', 'Xt', 'Label': pointer typies to memory, Forth words, and
Forth instructions inside the VM.

12.2 Variables
==============

Data and FP Stack pointer.  Area sizes.  Accessing the Stacks

   'gforth_SP', 'gforth_FP'.

12.3 Functions
==============

     void *gforth_engine(Xt *, stackpointers *);
     Cell gforth_main(int argc, char **argv, char **env);
     int gforth_args(int argc, char **argv, char **path, char **imagename);
     ImageHeader* gforth_loader(char* imagename, char* path);
     user_area* gforth_stacks(Cell dsize, Cell rsize, Cell fsize, Cell lsize);
     void gforth_free_stacks(user_area* t);
     void gforth_setstacks(user_area * t);
     void gforth_free_dict();
     Cell gforth_go(Xt* ip0);
     Cell gforth_boot(int argc, char** argv, char* path);
     void gforth_bootmessage();
     Cell gforth_start(int argc, char ** argv);
     Cell gforth_quit();
     Xt gforth_find(Char * name);
     Cell gforth_execute(Xt xt);
     void gforth_cleanup();
     void gforth_printmetrics();
     void gforth_setwinch();

12.4 Signals
============

Gforth sets up signal handlers to catch exceptions and window size
changes.  This may interfere with your C program.

13 Emacs and Gforth
*******************

Gforth comes with 'gforth.el', an improved version of 'forth.el' by
Goran Rydqvist (included in the TILE package).  The improvements are:

   * A better handling of indentation.
   * A custom hilighting engine for Forth-code.
   * Comment paragraph filling ('M-q')
   * Commenting ('C-x \') and uncommenting ('C-u C-x \') of regions
   * Removal of debugging tracers ('C-x ~', *note Debugging::).
   * Support of the 'info-lookup' feature for looking up the
     documentation of a word.
   * Support for reading and writing blocks files.

   To get a basic description of these features, enter Forth mode and
type 'C-h m'.

   In addition, Gforth supports Emacs quite well: The source code
locations given in error messages, debugging output (from '~~') and
failed assertion messages are in the right format for Emacs' compilation
mode (*note Running Compilations under Emacs: (emacs)Compilation.) so
the source location corresponding to an error or other message is only a
few keystrokes away ('C-x `' for the next error, 'C-c C-c' for the error
under the cursor).

   Moreover, for words documented in this manual, you can look up the
glossary entry quickly by using 'C-h TAB' ('info-lookup-symbol', *note
Documentation Commands: (emacs)Documentation.).  This feature requires
Emacs 20.3 or later and does not work for words containing ':'.

13.1 Installing gforth.el
=========================

To make the features from 'gforth.el' available in Emacs, add the
following lines to your '.emacs' file:

     (autoload 'forth-mode "gforth.el")
     (setq auto-mode-alist (cons '("\\.fs\\'" . forth-mode)
                                 auto-mode-alist))
     (autoload 'forth-block-mode "gforth.el")
     (setq auto-mode-alist (cons '("\\.fb\\'" . forth-block-mode)
                                 auto-mode-alist))
     (add-hook 'forth-mode-hook (function (lambda ()
        ;; customize variables here:
        (setq forth-indent-level 4)
        (setq forth-minor-indent-level 2)
        (setq forth-hilight-level 3)
        ;;; ...
     )))

13.2 Emacs Tags
===============

If you 'require' 'etags.fs', a new 'TAGS' file will be produced (*note
Tags Tables: (emacs)Tags.) that contains the definitions of all words
defined afterwards.  You can then find the source for a word using
'M-.'.  Note that Emacs can use several tags files at the same time
(e.g., one for the Gforth sources and one for your program, *note
Selecting a Tags Table: (emacs)Select Tags Table.).  The TAGS file for
the preloaded words is '$(datadir)/gforth/$(VERSION)/TAGS' (e.g.,
'/usr/local/share/gforth/0.2.0/TAGS').  To get the best behaviour with
'etags.fs', you should avoid putting definitions both before and after
'require' etc., otherwise you will see the same file visited several
times by commands like 'tags-search'.

13.3 Hilighting
===============

'gforth.el' comes with a custom source hilighting engine.  When you open
a file in 'forth-mode', it will be completely parsed, assigning faces to
keywords, comments, strings etc.  While you edit the file, modified
regions get parsed and updated on-the-fly.

   Use the variable 'forth-hilight-level' to change the level of
decoration from 0 (no hilighting at all) to 3 (the default).  Even if
you set the hilighting level to 0, the parser will still work in the
background, collecting information about whether regions of text are
"compiled" or "interpreted".  Those information are required for
auto-indentation to work properly.  Set 'forth-disable-parser' to
non-nil if your computer is too slow to handle parsing.  This will have
an impact on the smartness of the auto-indentation engine, though.

   Sometimes Forth sources define new features that should be hilighted,
new control structures, defining-words etc.  You can use the variable
'forth-custom-words' to make 'forth-mode' hilight additional words and
constructs.  See the docstring of 'forth-words' for details (in Emacs,
type 'C-h v forth-words').

   'forth-custom-words' is meant to be customized in your '.emacs' file.
To customize hilighing in a file-specific manner, set
'forth-local-words' in a local-variables section at the end of your
source file (*note Variables: (emacs)Local Variables in Files.).

   Example:
     0 [IF]
        Local Variables:
        forth-local-words:
           ((("t:") definition-starter (font-lock-keyword-face . 1)
             "[ \t\n]" t name (font-lock-function-name-face . 3))
            ((";t") definition-ender (font-lock-keyword-face . 1)))
        End:
     [THEN]

13.4 Auto-Indentation
=====================

'forth-mode' automatically tries to indent lines in a smart way,
whenever you type <TAB> or break a line with 'C-m'.

   Simple customization can be achieved by setting 'forth-indent-level'
and 'forth-minor-indent-level' in your '.emacs' file.  For historical
reasons 'gforth.el' indents per default by multiples of 4 columns.  To
use the more traditional 3-column indentation, add the following lines
to your '.emacs':

     (add-hook 'forth-mode-hook (function (lambda ()
        ;; customize variables here:
        (setq forth-indent-level 3)
        (setq forth-minor-indent-level 1)
     )))

   If you want indentation to recognize non-default words, customize it
by setting 'forth-custom-indent-words' in your '.emacs'.  See the
docstring of 'forth-indent-words' for details (in Emacs, type 'C-h v
forth-indent-words').

   To customize indentation in a file-specific manner, set
'forth-local-indent-words' in a local-variables section at the end of
your source file (*note Variables: (emacs)Local Variables in Files.).

   Example:
     0 [IF]
        Local Variables:
        forth-local-indent-words:
           ((("t:") (0 . 2) (0 . 2))
            ((";t") (-2 . 0) (0 . -2)))
        End:
     [THEN]

13.5 Blocks Files
=================

'forth-mode' Autodetects blocks files by checking whether the length of
the first line exceeds 1023 characters.  It then tries to convert the
file into normal text format.  When you save the file, it will be
written to disk as normal stream-source file.

   If you want to write blocks files, use 'forth-blocks-mode'.  It
inherits all the features from 'forth-mode', plus some additions:

   * Files are written to disk in blocks file format.
   * Screen numbers are displayed in the mode line (enumerated beginning
     with the value of 'forth-block-base')
   * Warnings are displayed when lines exceed 64 characters.
   * The beginning of the currently edited block is marked with an
     overlay-arrow.

   There are some restrictions you should be aware of.  When you open a
blocks file that contains tabulator or newline characters, these
characters will be translated into spaces when the file is written back
to disk.  If tabs or newlines are encountered during blocks file
reading, an error is output to the echo area.  So have a look at the
'*Messages*' buffer, when Emacs' bell rings during reading.

   Please consult the docstring of 'forth-blocks-mode' for more
information by typing 'C-h v forth-blocks-mode').

14 Image Files
**************

An image file is a file containing an image of the Forth dictionary,
i.e., compiled Forth code and data residing in the dictionary.  By
convention, we use the extension '.fi' for image files.

14.1 Image Licensing Issues
===========================

An image created with 'gforthmi' (*note gforthmi::) or 'savesystem'
(*note Non-Relocatable Image Files::) includes the original image; i.e.,
according to copyright law it is a derived work of the original image.

   Since Gforth is distributed under the GNU GPL, the newly created
image falls under the GNU GPL, too.  In particular, this means that if
you distribute the image, you have to make all of the sources for the
image available, including those you wrote.  For details see *note GNU
General Public License (Section 3): Copying.

   If you create an image with 'cross' (*note cross.fs::), the image
contains only code compiled from the sources you gave it; if none of
these sources is under the GPL, the terms discussed above do not apply
to the image.  However, if your image needs an engine (a gforth binary)
that is under the GPL, you should make sure that you distribute both in
a way that is at most a _mere aggregation_, if you don't want the terms
of the GPL to apply to the image.

14.2 Image File Background
==========================

Gforth consists not only of primitives (in the engine), but also of
definitions written in Forth.  Since the Forth compiler itself belongs
to those definitions, it is not possible to start the system with the
engine and the Forth source alone.  Therefore we provide the Forth code
as an image file in nearly executable form.  When Gforth starts up, a C
routine loads the image file into memory, optionally relocates the
addresses, then sets up the memory (stacks etc.)  according to
information in the image file, and (finally) starts executing Forth
code.

   The default image file is 'gforth.fi' (in the 'GFORTHPATH').  You can
use a different image by using the '-i', '--image-file' or
'--appl-image' options (*note Invoking Gforth::), e.g.:

     gforth-fast -i myimage.fi

   There are different variants of image files, and they represent
different compromises between the goals of making it easy to generate
image files and making them portable.

   Win32Forth 3.4 and Mitch Bradley's 'cforth' use relocation at
run-time.  This avoids many of the complications discussed below (image
files are data relocatable without further ado), but costs performance
(one addition per memory access) and makes it difficult to pass
addresses between Forth and library calls or other programs.

   By contrast, the Gforth loader performs relocation at image load
time.  The loader also has to replace tokens that represent primitive
calls with the appropriate code-field addresses (or code addresses in
the case of direct threading).

   There are three kinds of image files, with different degrees of
relocatability: non-relocatable, data-relocatable, and fully relocatable
image files.

   These image file variants have several restrictions in common; they
are caused by the design of the image file loader:

   * There is only one segment; in particular, this means, that an image
     file cannot represent 'ALLOCATE'd memory chunks (and pointers to
     them).  The contents of the stacks are not represented, either.

   * The only kinds of relocation supported are: adding the same offset
     to all cells that represent data addresses; and replacing special
     tokens with code addresses or with pieces of machine code.

     If any complex computations involving addresses are performed, the
     results cannot be represented in the image file.  Several
     applications that use such computations come to mind:

        - Hashing addresses (or data structures which contain addresses)
          for table lookup.  If you use Gforth's 'table's or 'wordlist's
          for this purpose, you will have no problem, because the hash
          tables are recomputed automatically when the system is
          started.  If you use your own hash tables, you will have to do
          something similar.

        - There's a cute implementation of doubly-linked lists that uses
          'XOR'ed addresses.  You could represent such lists as
          singly-linked in the image file, and restore the doubly-linked
          representation on startup.(1)

        - The code addresses of run-time routines like 'docol:' cannot
          be represented in the image file (because their tokens would
          be replaced by machine code in direct threaded
          implementations).  As a workaround, compute these addresses at
          run-time with '>code-address' from the executions tokens of
          appropriate words (see the definitions of 'docol:' and friends
          in 'kernel/getdoers.fs').

        - On many architectures addresses are represented in machine
          code in some shifted or mangled form.  You cannot put 'CODE'
          words that contain absolute addresses in this form in a
          relocatable image file.  Workarounds are representing the
          address in some relative form (e.g., relative to the CFA,
          which is present in some register), or loading the address
          from a place where it is stored in a non-mangled form.

   ---------- Footnotes ----------

   (1) In my opinion, though, you should think thrice before using a
doubly-linked list (whatever implementation).

14.3 Non-Relocatable Image Files
================================

These files are simple memory dumps of the dictionary.  They are
specific to the executable (i.e., 'gforth' file) they were created with.
What's worse, they are specific to the place on which the dictionary
resided when the image was created.  Now, there is no guarantee that the
dictionary will reside at the same place the next time you start Gforth,
so there's no guarantee that a non-relocatable image will work the next
time (Gforth will complain instead of crashing, though).  Indeed, on OSs
with (enabled) address-space randomization non-relocatable images are
unlikely to work.

   You can create a non-relocatable image file with 'savesystem', e.g.:

     gforth app.fs -e "savesystem app.fi bye"

'savesystem' ( "image" -  ) gforth-0.2

14.4 Data-Relocatable Image Files
=================================

These files contain relocatable data addresses, but fixed code addresses
(instead of tokens).  They are specific to the executable (i.e.,
'gforth' file) they were created with.  Also, they disable dynamic
native code generation (typically a factor of 2 in speed).  You get a
data-relocatable image, if you pass the engine you want to use through
the 'GFORTHD' environment variable to 'gforthmi' (*note gforthmi::),
e.g.

     GFORTHD="/usr/bin/gforth-fast --no-dynamic" gforthmi myimage.fi source.fs

   Note that the '--no-dynamic' is required here for the image to work
(otherwise it will contain references to dynamically generated code that
is not saved in the image).

14.5 Fully Relocatable Image Files
==================================

These image files have relocatable data addresses, and tokens for code
addresses.  They can be used with different binaries (e.g., with and
without debugging) on the same machine, and even across machines with
the same data formats (byte order, cell size, floating point format),
and they work with dynamic native code generation.  However, they are
usually specific to the version of Gforth they were created with.  The
files 'gforth.fi' and 'kernl*.fi' are fully relocatable.

   There are two ways to create a fully relocatable image file:

14.5.1 'gforthmi'
-----------------

You will usually use 'gforthmi'.  If you want to create an image file
that contains everything you would load by invoking Gforth with 'gforth
options', you simply say:
     gforthmi file options

   E.g., if you want to create an image 'asm.fi' that has the file
'asm.fs' loaded in addition to the usual stuff, you could do it like
this:

     gforthmi asm.fi asm.fs

   'gforthmi' is implemented as a sh script and works like this: It
produces two non-relocatable images for different addresses and then
compares them.  Its output reflects this: first you see the output (if
any) of the two Gforth invocations that produce the non-relocatable
image files, then you see the output of the comparing program: It
displays the offset used for data addresses and the offset used for code
addresses; moreover, for each cell that cannot be represented correctly
in the image files, it displays a line like this:

          78DC         BFFFFA50         BFFFFA40

   This means that at offset $78dc from 'forthstart', one input image
contains $bffffa50, and the other contains $bffffa40.  Since these cells
cannot be represented correctly in the output image, you should examine
these places in the dictionary and verify that these cells are dead
(i.e., not read before they are written).

   If you insert the option '--application' in front of the image file
name, you will get an image that uses the '--appl-image' option instead
of the '--image-file' option (*note Invoking Gforth::).  When you
execute such an image on Unix (by typing the image name as command), the
Gforth engine will pass all options to the image instead of trying to
interpret them as engine options.

   If you type 'gforthmi' with no arguments, it prints some usage
instructions.

   There are a few wrinkles: After processing the passed options, the
words 'savesystem' and 'bye' must be visible.  A special doubly indirect
threaded version of the 'gforth' executable is used for creating the
non-relocatable images; you can pass the exact filename of this
executable through the environment variable 'GFORTHD' (default:
'gforth-ditc'); if you pass a version that is not doubly indirect
threaded, you will not get a fully relocatable image, but a
data-relocatable image (*note Data-Relocatable Image Files::), because
there is no code address offset).  The normal 'gforth' executable is
used for creating the relocatable image; you can pass the exact filename
of this executable through the environment variable 'GFORTH'.

14.5.2 'cross.fs'
-----------------

You can also use 'cross', a batch compiler that accepts a Forth-like
programming language (*note Cross Compiler::).

   'cross' allows you to create image files for machines with different
data sizes and data formats than the one used for generating the image
file.  You can also use it to create an application image that does not
contain a Forth compiler.  These features are bought with restrictions
and inconveniences in programming.  E.g., addresses have to be stored in
memory with special words ('A!', 'A,', etc.)  in order to make the code
relocatable.

14.6 Stack and Dictionary Sizes
===============================

If you invoke Gforth with a command line flag for the size (*note
Invoking Gforth::), the size you specify is stored in the dictionary.
If you save the dictionary with 'savesystem' or create an image with
'gforthmi', this size will become the default for the resulting image
file.  E.g., the following will create a fully relocatable version of
'gforth.fi' with a 1MB dictionary:

     gforthmi gforth.fi -m 1M

   In other words, if you want to set the default size for the
dictionary and the stacks of an image, just invoke 'gforthmi' with the
appropriate options when creating the image.

   Note: For cache-friendly behaviour (i.e., good performance), you
should make the sizes of the stacks modulo, say, 2K, somewhat different.
E.g., the default stack sizes are: data: 16k (mod 2k=0); fp: 15.5k (mod
2k=1.5k); return: 15k(mod 2k=1k); locals: 14.5k (mod 2k=0.5k).

14.7 Running Image Files
========================

You can invoke Gforth with an image file image instead of the default
'gforth.fi' with the '-i' flag (*note Invoking Gforth::):
     gforth -i image

   If your operating system supports starting scripts with a line of the
form '#! ...', you just have to type the image file name to start Gforth
with this image file (note that the file extension '.fi' is just a
convention).  I.e., to run Gforth with the image file image, you can
just type image instead of 'gforth -i image'.  This works because every
'.fi' file starts with a line of this format:

     #! /usr/local/bin/gforth-0.4.0 -i

   The file and pathname for the Gforth engine specified on this line is
the specific Gforth executable that it was built against; i.e.  the
value of the environment variable 'GFORTH' at the time that 'gforthmi'
was executed.

   You can make use of the same shell capability to make a Forth source
file into an executable.  For example, if you place this text in a file:

     #! /usr/local/bin/gforth

     ." Hello, world" CR
     bye

and then make the file executable (chmod +x in Unix), you can run it
directly from the command line.  The sequence '#!' is used in two ways;
firstly, it is recognised as a "magic sequence" by the operating
system(1) secondly it is treated as a comment character by Gforth.
Because of the second usage, a space is required between '#!' and the
path to the executable (moreover, some Unixes require the sequence '#!
/').

   Most Unix systems (including Linux) support exactly one option after
the binary name.  If that is not enough, you can use the following
trick:

     #! /bin/sh
     : ## ; 0 [if]
     exec gforth -m 10M -d 1M $0 "$@"
     [then]
     ." Hello, world" cr
     bye \ caution: this prevents (further) processing of "$@"

   First this script is interpreted as shell script, which treats the
first two lines as (mostly) comments, then performs the third line,
which invokes gforth with this script ('$0') as parameter and its
parameters as additional parameters ('"$@"').  Then this script is
interpreted as Forth script, which first defines a colon definition
'##', then ignores everything up to '[then]' and finally processes the
following Forth code.  You can also use

     #0 [if]

   in the second line, but this works only in Gforth-0.7.0 and later.

   The 'gforthmi' approach is the fastest one, the shell-based one is
slowest (needs to start an additional shell).  An additional advantage
of the shell approach is that it is unnecessary to know where the Gforth
binary resides, as long as it is in the '$PATH'.

'#!' ( -  ) gforth-0.2 "hash-bang"
   An alias for '\'

   ---------- Footnotes ----------

   (1) The Unix kernel actually recognises two types of files:
executable files and files of data, where the data is processed by an
interpreter that is specified on the "interpreter line" - the first line
of the file, starting with the sequence #!.  There may be a small limit
(e.g., 32) on the number of characters that may be specified on the
interpreter line.

14.8 Modifying the Startup Sequence
===================================

You can add your own initialization to the startup sequence of an image
through the deferred word ''cold'.  ''cold' is invoked just before the
image-specific command line processing (i.e., loading files and
evaluating ('-e') strings) starts.

   A sequence for adding your initialization usually looks like this:

     :noname
         Defers 'cold \ do other initialization stuff (e.g., rehashing wordlists)
         ... \ your stuff
     ; IS 'cold

   After ''cold', Gforth processes the image options (*note Invoking
Gforth::), and then it performs 'bootmessage', another deferred word.
This normally prints Gforth's startup message and does nothing else.

   So, if you want to make a turnkey image (i.e., an image for an
application instead of an extended Forth system), you can do this in
several ways:

   * If you want to do your interpretation of the OS command-line
     arguments, hook into ''cold'.  In that case you probably also want
     to build the image with 'gforthmi --application' (*note gforthmi::)
     to keep the engine from processing OS command line options.  You
     can then do your own command-line processing with 'next-arg'

   * If you want to have the normal Gforth processing of OS command-line
     arguments, but specify your own command-line options, hook into
     'process-option'.

   * If you want to have more options in addition to the ones that come
     with Gforth, define words into the 'options' vocabulary.

   * If you want to display your own boot message, hook into
     'bootmessage'.

   In either case, you probably do not want the word that you execute in
these hooks to exit normally, but use 'bye' or 'throw'.  Otherwise the
Gforth startup process would continue and eventually present the Forth
command line to the user.

''cold' ( -  ) gforth-0.2 "tick-cold"
   Hook (deferred word) for things to do right before interpreting the
OS command-line arguments.  Normally does some initializations that you
also want to perform.

'bootmessage' ( -  ) gforth-0.4
   Hook (deferred word) executed right after interpreting the OS
command-line arguments.  Normally prints the Gforth startup message.

'process-option' ( addr u - ... xt | 0  ) gforth-0.7
   Recognizer that processes an option, returns an execute-only xt to
process the option

15 Engine
*********

Reading this chapter is not necessary for programming with Gforth.  It
may be helpful for finding your way in the Gforth sources.

   The ideas in this section have also been published in the following
papers: Bernd Paysan, 'ANS fig/GNU/??? Forth' (in German), Forth-Tagung
'93; M. Anton Ertl, 'A Portable Forth Engine
(https://www.complang.tuwien.ac.at/papers/ertl93.ps.Z)', EuroForth '93;
M. Anton Ertl, 'Threaded code variations and optimizations (extended
version) (https://www.complang.tuwien.ac.at/papers/ertl02.ps.gz)',
Forth-Tagung '02.

15.1 Portability
================

An important goal of the Gforth Project is availability across a wide
range of personal machines.  fig-Forth, and, to a lesser extent, F83,
achieved this goal by manually coding the engine in assembly language
for several then-popular processors.  This approach is very
labor-intensive and the results are short-lived due to progress in
computer architecture.

   Others have avoided this problem by coding in C, e.g., Mitch Bradley
(cforth), Mikael Patel (TILE) and Dirk Zoller (pfe).  This approach is
particularly popular for UNIX-based Forths due to the large variety of
architectures of UNIX machines.  Unfortunately an implementation in C
does not mix well with the goals of efficiency and with using
traditional techniques: Indirect or direct threading cannot be expressed
in C, and switch threading, the fastest technique available in C, is
significantly slower.  Another problem with C is that it is very
cumbersome to express double integer arithmetic.

   Fortunately, there is a portable language that does not have these
limitations: GNU C, the version of C processed by the GNU C compiler
(*note Extensions to the C Language Family: (gcc)C Extensions.).  Its
labels as values feature (*note Labels as Values: (gcc)Labels as
Values.) makes direct and indirect threading possible, its 'long long'
type (*note Double-Word Integers: (gcc)Long Long.) corresponds to
Forth's double numbers on many systems.  GNU C is freely available on
all important (and many unimportant) UNIX machines, VMS, 80386s running
MS-DOS, the Amiga, and the Atari ST, so a Forth written in GNU C can run
on all these machines.

   Writing in a portable language has the reputation of producing code
that is slower than assembly.  For our Forth engine we repeatedly looked
at the code produced by the compiler and eliminated most
compiler-induced inefficiencies by appropriate changes in the source
code.

   However, register allocation cannot be portably influenced by the
programmer, leading to some inefficiencies on register-starved machines.
We use explicit register declarations (*note Variables in Specified
Registers: (gcc)Explicit Reg Vars.) to improve the speed on some
machines.  They are turned on by using the configuration flag
'--enable-force-reg' ('gcc' switch '-DFORCE_REG').  Unfortunately, this
feature not only depends on the machine, but also on the compiler
version: On some machines some compiler versions produce incorrect code
when certain explicit register declarations are used.  So by default
'-DFORCE_REG' is not used.

15.2 Threading
==============

GNU C's labels as values extension (available since 'gcc-2.0', *note
Labels as Values: (gcc)Labels as Values.) makes it possible to take the
address of label by writing '&&label'.  This address can then be used in
a statement like 'goto *address'.  I.e., 'goto *&&x' is the same as
'goto x'.

   With this feature an indirect threaded 'NEXT' looks like:
     cfa = *ip++;
     ca = *cfa;
     goto *ca;
   For those unfamiliar with the names: 'ip' is the Forth instruction
pointer; the 'cfa' (code-field address) corresponds to Standard Forth's
execution token and points to the code field of the next word to be
executed; The 'ca' (code address) fetched from there points to some
executable code, e.g., a primitive or the colon definition handler
'docol'.

   Direct threading is even simpler:
     ca = *ip++;
     goto *ca;

   Of course we have packaged the whole thing neatly in macros called
'NEXT' and 'NEXT1' (the part of 'NEXT' after fetching the cfa).

15.2.1 Scheduling
-----------------

There is a little complication: Pipelined and superscalar processors,
i.e., RISC and some modern CISC machines can process independent
instructions while waiting for the results of an instruction.  The
compiler usually reorders (schedules) the instructions in a way that
achieves good usage of these delay slots.  However, on our first tries
the compiler did not do well on scheduling primitives.  E.g., for '+'
implemented as
     n=sp[0]+sp[1];
     sp++;
     sp[0]=n;
     NEXT;
   the 'NEXT' comes strictly after the other code, i.e., there is nearly
no scheduling.  After a little thought the problem becomes clear: The
compiler cannot know that 'sp' and 'ip' point to different addresses
(and the version of 'gcc' we used would not know it even if it was
possible), so it could not move the load of the cfa above the store to
the TOS. Indeed the pointers could be the same, if code on or very near
the top of stack were executed.  In the interest of speed we chose to
forbid this probably unused "feature" and helped the compiler in
scheduling: 'NEXT' is divided into several parts: 'NEXT_P0', 'NEXT_P1'
and 'NEXT_P2').  '+' now looks like:
     NEXT_P0;
     n=sp[0]+sp[1];
     sp++;
     NEXT_P1;
     sp[0]=n;
     NEXT_P2;

   There are various schemes that distribute the different operations of
NEXT between these parts in several ways; in general, different schemes
perform best on different processors.  We use a scheme for most
architectures that performs well for most processors of this
architecture; in the future we may switch to benchmarking and choosing
the scheme on installation time.

15.2.2 Direct or Indirect Threaded?
-----------------------------------

Threaded forth code consists of references to primitives (simple machine
code routines like '+') and to non-primitives (e.g., colon definitions,
variables, constants); for a specific class of non-primitives (e.g.,
variables) there is one code routine (e.g., 'dovar'), but each variable
needs a separate reference to its data.

   Traditionally Forth has been implemented as indirect threaded code,
because this allows to use only one cell to reference a non-primitive
(basically you point to the data, and find the code address there).

   However, threaded code in Gforth (since 0.6.0) uses two cells for
non-primitives, one for the code address, and one for the data address;
the data pointer is an immediate argument for the virtual machine
instruction represented by the code address.  We call this
_primitive-centric_ threaded code, because all code addresses point to
simple primitives.  E.g., for a variable, the code address is for 'lit'
(also used for integer literals like '99').

   Primitive-centric threaded code allows us to use (faster) direct
threading as dispatch method, completely portably (direct threaded code
in Gforth before 0.6.0 required architecture-specific code).  It also
eliminates the performance problems related to I-cache consistency that
386 implementations have with direct threaded code, and allows
additional optimizations.

   There is a catch, however: the XT parameter of 'execute' can occupy
only one cell, so how do we pass non-primitives with their code _and_
data addresses to them?  Our answer is to use indirect threaded dispatch
for 'execute' and other words that use a single-cell xt.  So, normal
threaded code in colon definitions uses direct threading, and 'execute'
and similar words, which dispatch to xts on the data stack, use indirect
threaded code.  We call this _hybrid direct/indirect_ threaded code.

   The engines 'gforth' and 'gforth-fast' use hybrid direct/indirect
threaded code.  This means that with these engines you cannot use ',' to
compile an xt.  Instead, you have to use 'compile,'.

   If you want to compile xts with ',', use 'gforth-itc'.  This engine
uses plain old indirect threaded code.  It still compiles in a
primitive-centric style, so you cannot use 'compile,' instead of ','
(e.g., for producing tables of xts with '] word1 word2 ... [').  If you
want to do that, you have to use 'gforth-itc' and execute '' , is
compile,'.  Your program can check if it is running on a hybrid
direct/indirect threaded engine or a pure indirect threaded engine with
'threading-method' (*note Threading Words::).

15.2.3 Dynamic Superinstructions
--------------------------------

The engines 'gforth' and 'gforth-fast' use another optimization: Dynamic
superinstructions with replication.  As an example, consider the
following colon definition:

     : squared ( n1 -- n2 )
       dup * ;

   Gforth compiles this into the threaded code sequence

     dup
     *
     ;s

   Use 'simple-see' (*note Examining compiled code::) to see the
threaded code of a colon definition.

   In normal direct threaded code there is a code address occupying one
cell for each of these primitives.  Each code address points to a
machine code routine, and the interpreter jumps to this machine code in
order to execute the primitive.  The routines for these three primitives
are (in 'gforth-fast' on the 386):

     Code dup
     ( $804B950 )  add     esi , # -4  \ $83 $C6 $FC
     ( $804B953 )  add     ebx , # 4  \ $83 $C3 $4
     ( $804B956 )  mov     dword ptr 4 [esi] , ecx  \ $89 $4E $4
     ( $804B959 )  jmp     dword ptr FC [ebx]  \ $FF $63 $FC
     end-code
     Code *
     ( $804ACC4 )  mov     eax , dword ptr 4 [esi]  \ $8B $46 $4
     ( $804ACC7 )  add     esi , # 4  \ $83 $C6 $4
     ( $804ACCA )  add     ebx , # 4  \ $83 $C3 $4
     ( $804ACCD )  imul    ecx , eax  \ $F $AF $C8
     ( $804ACD0 )  jmp     dword ptr FC [ebx]  \ $FF $63 $FC
     end-code
     Code ;s
     ( $804A693 )  mov     eax , dword ptr [edi]  \ $8B $7
     ( $804A695 )  add     edi , # 4  \ $83 $C7 $4
     ( $804A698 )  lea     ebx , dword ptr 4 [eax]  \ $8D $58 $4
     ( $804A69B )  jmp     dword ptr FC [ebx]  \ $FF $63 $FC
     end-code

   With dynamic superinstructions and replication the compiler does not
just lay down the threaded code, but also copies the machine code
fragments, usually without the jump at the end.

     ( $4057D27D )  add     esi , # -4  \ $83 $C6 $FC
     ( $4057D280 )  add     ebx , # 4  \ $83 $C3 $4
     ( $4057D283 )  mov     dword ptr 4 [esi] , ecx  \ $89 $4E $4
     ( $4057D286 )  mov     eax , dword ptr 4 [esi]  \ $8B $46 $4
     ( $4057D289 )  add     esi , # 4  \ $83 $C6 $4
     ( $4057D28C )  add     ebx , # 4  \ $83 $C3 $4
     ( $4057D28F )  imul    ecx , eax  \ $F $AF $C8
     ( $4057D292 )  mov     eax , dword ptr [edi]  \ $8B $7
     ( $4057D294 )  add     edi , # 4  \ $83 $C7 $4
     ( $4057D297 )  lea     ebx , dword ptr 4 [eax]  \ $8D $58 $4
     ( $4057D29A )  jmp     dword ptr FC [ebx]  \ $FF $63 $FC

   Only when a threaded-code control-flow change happens (e.g., in
';s'), the jump is appended.  This optimization eliminates many of these
jumps and makes the rest much more predictable.  The speedup depends on
the processor and the application; on the Athlon and Pentium III this
optimization typically produces a speedup by a factor of 2.

   The code addresses in the direct-threaded code are set to point to
the appropriate points in the copied machine code, in this example like
this:

     primitive  code address
        dup       $4057D27D
        *         $4057D286
        ;s        $4057D292

   Thus there can be threaded-code jumps to any place in this piece of
code.  This also simplifies decompilation quite a bit.

   'See-code' (*note Examining compiled code::) shows the threaded code
intermingled with the native code of dynamic superinstructions.  These
days some additional optimizations are applied for the
dynamically-generated native code, so the output of 'see-code squared'
on 'gforth-fast' on one particular AMD64 installation looks like this:

     $7FB689C678C8 dup    1->2
     7FB68990C1B2:   mov     r15,r8
     $7FB689C678D0 *    2->1
     7FB68990C1B5:   imul    r8,r15
     $7FB689C678D8 ;s    1->1
     7FB68990C1B9:   mov     rbx,[r14]
     7FB68990C1BC:   add     r14,$08
     7FB68990C1C0:   mov     rax,[rbx]
     7FB68990C1C3:   jmp     eax

   You can disable this optimization with '--no-dynamic'.  You can use
the copying without eliminating the jumps (i.e., dynamic replication,
but without superinstructions) with '--no-super'; this gives the branch
prediction benefit alone; the effect on performance depends on the CPU;
on the Athlon and Pentium III the speedup is a little less than for
dynamic superinstructions with replication.

   One use of these options is if you want to patch the threaded code.
With superinstructions, many of the dispatch jumps are eliminated, so
patching often has no effect.  These options preserve all the dispatch
jumps.

   On some machines dynamic superinstructions are disabled by default,
because it is unsafe on these machines.  However, if you feel
adventurous, you can enable it with '--dynamic'.

15.2.4 DOES>
------------

One of the most complex parts of a Forth engine is 'dodoes', i.e., the
chunk of code executed by every word defined by a 'CREATE'...'DOES>'
pair; actually with primitive-centric code, this is only needed if the
xt of the word is 'execute'd.  The main problem here is: How to find the
Forth code to be executed, i.e.  the code after the 'DOES>' (the
'DOES>'-code)?  There are two solutions:

   In fig-Forth the code field points directly to the 'dodoes' and the
'DOES>'-code address is stored in the cell after the code address (i.e.
at 'CFA cell+').  It may seem that this solution is illegal in the
Forth-79 and all later standards, because in fig-Forth this address lies
in the body (which is illegal in these standards).  However, by making
the code field larger for all words this solution becomes legal again.
We use this approach.  Leaving a cell unused in most words is a bit
wasteful, but on the machines we are targeting this is hardly a problem.

15.3 Primitives
===============

15.3.1 Automatic Generation
---------------------------

Since the primitives are implemented in a portable language, there is no
longer any need to minimize the number of primitives.  On the contrary,
having many primitives has an advantage: speed.  In order to reduce the
number of errors in primitives and to make programming them easier, we
provide a tool, the primitive generator ('prims2x.fs' aka Vmgen, *note
Vmgen: (vmgen)Top.), that automatically generates most (and sometimes
all) of the C code for a primitive from the stack effect notation.  The
source for a primitive has the following form:

Forth-name  ( stack-effect )        category    [pronounc.]
['""'glossary entry'""']
C code
[':'
Forth code]

   The items in brackets are optional.  The category and glossary fields
are there for generating the documentation, the Forth code is there for
manual implementations on machines without GNU C. E.g., the source for
the primitive '+' is:
     +    ( n1 n2 -- n )   core    plus
     n = n1+n2;

   This looks like a specification, but in fact 'n = n1+n2' is C code.
Our primitive generation tool extracts a lot of information from the
stack effect notations(1): The number of items popped from and pushed on
the stack, their type, and by what name they are referred to in the C
code.  It then generates a C code prelude and postlude for each
primitive.  The final C code for '+' looks like this:

     I_plus: /* + ( n1 n2 -- n ) */  /* label, stack effect */
     /*  */                          /* documentation */
     NAME("+")                       /* debugging output (with -DDEBUG) */
     {
     DEF_CA                          /* definition of variable ca (indirect threading) */
     Cell n1;                        /* definitions of variables */
     Cell n2;
     Cell n;
     NEXT_P0;                        /* NEXT part 0 */
     n1 = (Cell) sp[1];              /* input */
     n2 = (Cell) TOS;
     sp += 1;                        /* stack adjustment */
     {
     n = n1+n2;                      /* C code taken from the source */
     }
     NEXT_P1;                        /* NEXT part 1 */
     TOS = (Cell)n;                  /* output */
     NEXT_P2;                        /* NEXT part 2 */
     }

   This looks long and inefficient, but the GNU C compiler optimizes
quite well and produces optimal code for '+' on, e.g., the R3000 and the
HP RISC machines: Defining the 'n's does not produce any code, and using
them as intermediate storage also adds no cost.

   There are also other optimizations that are not illustrated by this
example: assignments between simple variables are usually for free (copy
propagation).  If one of the stack items is not used by the primitive
(e.g.  in 'drop'), the compiler eliminates the load from the stack (dead
code elimination).  On the other hand, there are some things that the
compiler does not do, therefore they are performed by 'prims2x.fs': The
compiler does not optimize code away that stores a stack item to the
place where it just came from (e.g., 'over').

   While programming a primitive is usually easy, there are a few cases
where the programmer has to take the actions of the generator into
account, most notably '?dup', but also words that do not (always) fall
through to 'NEXT'.

   For more information

   ---------- Footnotes ----------

   (1) We use a one-stack notation, even though we have separate data
and floating-point stacks; The separate notation can be generated easily
from the unified notation.

15.3.2 TOS Optimization
-----------------------

An important optimization for stack machine emulators, e.g., Forth
engines, is keeping one or more of the top stack items in registers.  If
a word has the stack effect in1...inx '--' out1...outy, keeping the top
n items in registers
   * is better than keeping n-1 items, if x>=n and y>=n, due to fewer
     loads from and stores to the stack.
   * is slower than keeping n-1 items, if x<>y and x<n and y<n, due to
     additional moves between registers.

   In particular, keeping one item in a register is never a
disadvantage, if there are enough registers.  Keeping two items in
registers is a disadvantage for frequent words like '?branch',
constants, variables, literals and 'i'.  Therefore our generator only
produces code that keeps zero or one items in registers.  The generated
C code covers both cases; the selection between these alternatives is
made at C-compile time using the switch '-DUSE_TOS'.  'TOS' in the C
code for '+' is just a simple variable name in the one-item case,
otherwise it is a macro that expands into 'sp[0]'.  Note that the GNU C
compiler tries to keep simple variables like 'TOS' in registers, and it
usually succeeds, if there are enough registers.

   The primitive generator performs the TOS optimization for the
floating-point stack, too ('-DUSE_FTOS').  For floating-point operations
the benefit of this optimization is even larger: floating-point
operations take quite long on most processors, but can be performed in
parallel with other operations as long as their results are not used.
If the FP-TOS is kept in a register, this works.  If it is kept on the
stack, i.e., in memory, the store into memory has to wait for the result
of the floating-point operation, lengthening the execution time of the
primitive considerably.

   The TOS optimization makes the automatic generation of primitives a
bit more complicated.  Just replacing all occurrences of 'sp[0]' by
'TOS' is not sufficient.  There are some special cases to consider:
   * In the case of 'dup ( w -- w w )' the generator must not eliminate
     the store to the original location of the item on the stack, if the
     TOS optimization is turned on.
   * Primitives with stack effects of the form '--' out1...outy must
     store the TOS to the stack at the start.  Likewise, primitives with
     the stack effect in1...inx '--' must load the TOS from the stack at
     the end.  But for the null stack effect '--' no stores or loads
     should be generated.

15.3.3 Produced code
--------------------

To see what assembly code is produced for the primitives on your machine
with your compiler and your flag settings, type 'make engine.s' and look
at the resulting file 'engine.s'.  Alternatively, you can also
disassemble the code of primitives with 'see' on some architectures.

15.4 Performance
================

On RISCs the Gforth engine is very close to optimal; i.e., it is usually
impossible to write a significantly faster threaded-code engine.

   On register-starved machines like the 386 architecture processors
improvements are possible, because 'gcc' does not utilize the registers
as well as a human, even with explicit register declarations; e.g.,
Bernd Beuster wrote a Forth system fragment in assembly language and
hand-tuned it for the 486; this system is 1.19 times faster on the Sieve
benchmark on a 486DX2/66 than Gforth compiled with 'gcc-2.6.3' with
'-DFORCE_REG'.  The situation has improved with gcc-2.95 and
gforth-0.4.9; now the most important virtual machine registers fit in
real registers (and we can even afford to use the TOS optimization),
resulting in a speedup of 1.14 on the sieve over the earlier results.
And dynamic superinstructions provide another speedup (but only around a
factor 1.2 on the 486).

   The potential advantage of assembly language implementations is not
necessarily realized in complete Forth systems: We compared Gforth-0.5.9
(direct threaded, compiled with 'gcc-2.95.1' and '-DFORCE_REG') with
Win32Forth 1.2093 (newer versions are reportedly much faster), LMI's NT
Forth (Beta, May 1994) and Eforth (with and without peephole (aka
pinhole) optimization of the threaded code); all these systems were
written in assembly language.  We also compared Gforth with three
systems written in C: PFE-0.9.14 (compiled with 'gcc-2.6.3' with the
default configuration for Linux: '-O2 -fomit-frame-pointer -DUSE_REGS
-DUNROLL_NEXT'), ThisForth Beta (compiled with 'gcc-2.6.3 -O3
-fomit-frame-pointer'; ThisForth employs peephole optimization of the
threaded code) and TILE (compiled with 'make opt').  We benchmarked
Gforth, PFE, ThisForth and TILE on a 486DX2/66 under Linux.  Kenneth
O'Heskin kindly provided the results for Win32Forth and NT Forth on a
486DX2/66 with similar memory performance under Windows NT. Marcel
Hendrix ported Eforth to Linux, then extended it to run the benchmarks,
added the peephole optimizer, ran the benchmarks and reported the
results.

   We used four small benchmarks: the ubiquitous Sieve; bubble-sorting
and matrix multiplication come from the Stanford integer benchmarks and
have been translated into Forth by Martin Fraeman; we used the versions
included in the TILE Forth package, but with bigger data set sizes; and
a recursive Fibonacci number computation for benchmarking calling
performance.  The following table shows the time taken for the
benchmarks scaled by the time taken by Gforth (in other words, it shows
the speedup factor that Gforth achieved over the other systems).

     relative       Win32-    NT       eforth       This-
     time     Gforth Forth Forth eforth  +opt   PFE Forth  TILE
     sieve      1.00  2.16  1.78   2.16  1.32  2.46  4.96 13.37
     bubble     1.00  1.93  2.07   2.18  1.29  2.21        5.70
     matmul     1.00  1.92  1.76   1.90  0.96  2.06        5.32
     fib        1.00  2.32  2.03   1.86  1.31  2.64  4.55  6.54

   You may be quite surprised by the good performance of Gforth when
compared with systems written in assembly language.  One important
reason for the disappointing performance of these other systems is
probably that they are not written optimally for the 486 (e.g., they use
the 'lods' instruction).  In addition, Win32Forth uses a comfortable,
but costly method for relocating the Forth image: like 'cforth', it
computes the actual addresses at run time, resulting in two address
computations per 'NEXT' (*note Image File Background::).

   The speedup of Gforth over PFE, ThisForth and TILE can be easily
explained with the self-imposed restriction of the latter systems to
standard C, which makes efficient threading impossible (however, the
measured implementation of PFE uses a GNU C extension: *note Defining
Global Register Variables: (gcc)Global Reg Vars.).  Moreover, current C
compilers have a hard time optimizing other aspects of the ThisForth and
the TILE source.

   The performance of Gforth on 386 architecture processors varies
widely with the version of 'gcc' used.  E.g., 'gcc-2.5.8' failed to
allocate any of the virtual machine registers into real machine
registers by itself and would not work correctly with explicit register
declarations, giving a significantly slower engine (on a 486DX2/66
running the Sieve) than the one measured above.

   Note that there have been several releases of Win32Forth since the
release presented here, so the results presented above may have little
predictive value for the performance of Win32Forth today (results for
the current release on an i486DX2/66 are welcome).

   In 'Translating Forth to Efficient C
(https://www.complang.tuwien.ac.at/papers/ertl&maierhofer95.ps.gz)' by
M.  Anton Ertl and Martin Maierhofer (presented at EuroForth '95), an
indirect threaded version of Gforth is compared with Win32Forth, NT
Forth, PFE, ThisForth, and several native code systems; that version of
Gforth is slower on a 486 than the version used here.  You can find a
newer version of these measurements at
<https://www.complang.tuwien.ac.at/forth/performance.html>.  You can
find numbers for Gforth on various machines in 'Benchres'.

16 Cross Compiler
*****************

The cross compiler is used to bootstrap a Forth kernel.  Since Gforth is
mostly written in Forth, including crucial parts like the outer
interpreter and compiler, it needs compiled Forth code to get started.
The cross compiler allows to create new images for other architectures,
even running under another Forth system.

16.1 Using the Cross Compiler
=============================

The cross compiler uses a language that resembles Forth, but isn't.  The
main difference is that you can execute Forth code after definition,
while you usually can't execute the code compiled by cross, because the
code you are compiling is typically for a different computer than the
one you are compiling on.

   The Makefile is already set up to allow you to create kernels for new
architectures with a simple make command.  The generic kernels using the
GCC compiled virtual machine are created in the normal build process
with 'make'.  To create a embedded Gforth executable for e.g.  the 8086
processor (running on a DOS machine), type

     make kernl-8086.fi

   This will use the machine description from the 'arch/8086' directory
to create a new kernel.  A machine file may look like that:

     \ Parameter for target systems                         06oct92py

         4 Constant cell             \ cell size in bytes
         2 Constant cell<<           \ cell shift to bytes
         5 Constant cell>bit         \ cell shift to bits
         8 Constant bits/char        \ bits per character
         8 Constant bits/byte        \ bits per byte [default: 8]
         8 Constant float            \ bytes per float
         8 Constant /maxalign        \ maximum alignment in bytes
     false Constant bigendian        \ byte order
     ( true=big, false=little )

     include machpc.fs               \ feature list

   This part is obligatory for the cross compiler itself, the feature
list is used by the kernel to conditionally compile some features in and
out, depending on whether the target supports these features.

   There are some optional features, if you define your own primitives,
have an assembler, or need special, nonstandard preparation to make the
boot process work.  'asm-include' includes an assembler, 'prims-include'
includes primitives, and '>boot' prepares for booting.

     : asm-include    ." Include assembler" cr
       s" arch/8086/asm.fs" included ;

     : prims-include  ." Include primitives" cr
       s" arch/8086/prim.fs" included ;

     : >boot          ." Prepare booting" cr
       s" ' boot >body into-forth 1+ !" evaluate ;

   These words are used as sort of macro during the cross compilation in
the file 'kernel/main.fs'.  Instead of using these macros, it would be
possible -- but more complicated -- to write a new kernel project file,
too.

   'kernel/main.fs' expects the machine description file name on the
stack; the cross compiler itself ('cross.fs') assumes that either
'mach-file' leaves a counted string on the stack, or 'machine-file'
leaves an address, count pair of the filename on the stack.

   The feature list is typically controlled using 'SetValue', generic
files that are used by several projects can use 'DefaultValue' instead.
Both functions work like 'Value', when the value isn't defined, but
'SetValue' works like 'to' if the value is defined, and 'DefaultValue'
doesn't set anything, if the value is defined.

     \ generic mach file for pc gforth                       03sep97jaw

     true DefaultValue NIL  \ relocating

     >ENVIRON

     true DefaultValue file          \ controls the presence of the
                                     \ file access wordset
     true DefaultValue OS            \ flag to indicate a operating system

     true DefaultValue prims         \ true: primitives are c-code

     true DefaultValue floating      \ floating point wordset is present

     true DefaultValue glocals       \ gforth locals are present
                                     \ will be loaded
     true DefaultValue dcomps        \ double number comparisons

     true DefaultValue hash          \ hashing primitives are loaded/present

     true DefaultValue xconds        \ used together with glocals,
                                     \ special conditionals supporting gforths'
                                     \ local variables
     true DefaultValue header        \ save a header information

     true DefaultValue backtrace     \ enables backtrace code

     false DefaultValue ec
     false DefaultValue crlf

     cell 2 = [IF] &32 [ELSE] &256 [THEN] KB DefaultValue kernel-size

     &16 KB          DefaultValue stack-size
     &15 KB &512 +   DefaultValue fstack-size
     &15 KB          DefaultValue rstack-size
     &14 KB &512 +   DefaultValue lstack-size

16.2 How the Cross Compiler Works
=================================

17 MINOS2, a GUI library
************************

17.1 MINOS2 object framework
============================

MINOS2 is a GUI library, written in 'mini-oof2.fs''s object model.  It
has two main class hierarchies:

'actor' ( - class  ) minos2
   class for the actions bound to a component.

'widget' ( - class  ) minos2
   class for visual components

17.1.1 'actor' methods:
-----------------------

'caller-w' ( - optr  ) minos2
   pointer back to the widget embedding the actor

'active-w' ( - optr  ) minos2
   pointer to the active subwidget embedding the actor

'act-name$' ( - addr u  ) minos2 "act-name-string"
   Debugging aid: name of the actor

'clicked' ( rx ry bmask n -  ) minos2
   processed clicks

'scrolled' ( axis dir -  ) minos2
   process scrolling

'touchdown' ( $rxy*n bmask -  ) minos2
   raw click down

'touchup' ( $rxy*n bmask -  ) minos2
   raw click up

'ukeyed' ( addr u -  ) minos2
   key event, string of printable unicode characters

'ekeyed' ( ekey -  ) minos2
   key event, non-printable key

'?inside' ( rx ry - act / 0  ) minos2 "query-inside"
   check if coordinates are inside the widget

'focus' ( -  ) minos2
   put widget into focus

'defocus' ( -  ) minos2
   put widget out of focus

'entered' ( -  ) minos2
   react on cursor entering the widget area

'left' ( -  ) minos2
   react on cursor leaving the widget area

'show' ( -  ) minos2
   widget is shown

'hide' ( -  ) minos2
   widget is hidden

'get' ( - something  ) minos2
   getter for the value behind the widget

'set' ( something -  ) minos2
   setter for the value behind the widget

'show-you' ( -  ) minos2
   make widget visible

17.1.2 'widget' methods:
------------------------

'parent-w' ( - optr  ) minos2
   pointer to parent widget

'act' ( - optr  ) minos2
   pointer to actor

'name$' ( - addr u  ) minos2 "name-string"
   Widget name for debugging and searching

'x' ( - r  ) minos2
   widget x coordinate

'y' ( - r  ) minos2
   widget y coordinate

'w' ( - r  ) minos2
   widget width

'h' ( - r  ) minos2
   widget height above baseline

'd' ( - r  ) minos2
   widget depth below baseline

'gap' ( - r  ) minos2
   gap between lines

'baseline' ( - r  ) minos2
   minimun skip per line

'kerning' ( - r  ) minos2
   add kerning

'raise' ( - r  ) minos2
   raise/lower box

'border' ( - r  ) minos2
   surrounding border, all directions

'borderv' ( - r  ) minos2
   vertical border offset

'bordert' ( - r  ) minos2
   top border offset

'borderl' ( - r  ) minos2
   left border offset

'w-color' ( - r  ) minos2
   widget color index (into color map), if any

'draw-init' ( -  ) minos2
   init draw

'draw' ( -  ) minos2
   draw widget

'split' ( firstflag rstart1 rx - o rstart2  ) minos2
   split a widget into parts for typesetting paragraphs

'lastfit' ( -  ) minos2
   fit last widget element in a box

'hglue' ( - rtyp rsub radd  ) minos2
   calculate horizontal glue

'dglue' ( - rtyp rsub radd  ) minos2
   calculate vertical glue below baseline

'vglue' ( - rtyp rsub radd  ) minos2
   calculate vertical glue above baseline

'hglue@' ( - rtyp rsub radd  ) minos2 "hglue-fetch"
   cached variant of 'hglue'

'dglue@' ( - rtyp rsub radd  ) minos2 "dglue-fetch"
   cached variant of 'dglue'

'vglue@' ( - rtyp rsub radd  ) minos2 "vglue-fetch"
   cached variant of 'vglue'

'xywh' ( - rx0 ry0 rw rh  ) minos2
   widget bounding box, starting at the top left corner

'xywhd' ( - rx ry rw rh rd  ) minos2
   widget bounding box, starting at the left baseline point

'!resize' ( rx ry rw rh rd -  ) minos2 "store-resize"
   resize a widget

'!size' ( -  ) minos2 "store-size"
   let the widget self-determine its size

'dispose-widget' ( -  ) minos2
   get rid of a widget

'.widget' ( -  ) minos2 "print-widget"
   debugging: Print informations about the widget

'par-split' ( rw -  ) minos2
   split a paragraph by width RW

'resized' ( -  ) minos2
   widget is resized

   Components are composed using a boxes&glue model similar to LaTeX,
including paragraph breaking.  For the sake of simplicity and
portability, MINOS2 only supports a single window, and uses OpenGL for
rendering.

   MINOS2 furthermore supports animations with the 'animation' class.  A
color index texture is used for different color schemes, and transition
between neighboring schemes can also be animated.

'>animate' ( rdelta addr xt -  ) minos2 "to-animate"
   create a new animation, calling XT with stack effect '( addr r0..1 --
)' repeatedly, until the RDELTA timeout expired; last call is always
with argument 1E for the time.

   You can create named color indexes and assign them color values for
the currently active color scheme.

'color:' ( rgba "name" -  ) minos2 "color-colon"
   Create a (possibly shared) color index initialized with RGBA

'new-color:' ( rgba "name" -  ) minos2 "new-color-colon"
   Create a unique color index initialized with RGBA

'text-color:' ( rgba "name" -  ) minos2 "text-color-colon"
   Create a unique text color index initialized with RGBA, the
corresponding emoji color is set to white.

'text-emoji-color:' ( rgbatext rgbaemoji "name" -  ) minos2 "text-emoji-color-colon"
   Create a unique text color index initialized with RGBATEXT, the
corresponding emoji color is set to RGBAEMOJI.

'fade-color:' ( rgba1 rgba2 "name" -  ) minos2 "fade-color-colon"
   Create a unique pair of text color index initialized with RGBA1 and
RGBA2, the corresponding emoji color is set to white.  By slowly
shifting the index from one to the next index, the object will shift its
color using a linear interpolation when redrawn.

'text-emoji-fade-color:' ( rgbatext1 ~2 rgbaemoji1 ~2 "name" -  ) minos2 "text-emoji-fade-color-colon"
   Create a unique pair of text color index initialized with RGBATEXT1
and ~2, the corresponding emoji color pair is set to RGBAEMOJI1 to ~2.
By slowly shifting the index from one to the next index, the object will
shift its color using a linear interpolation when redrawn.

're-color' ( rgba "name" -  ) minos2
   assign the named color index "NAME" in the current color scheme with
the value RGBA.

're-text-color' ( rgba "name" -  ) minos2
   assign the named text color index "NAME" in the current color scheme
with the value RGBA.

're-emoji-color' ( rgbatext rgbaemoji "name" -  ) minos2
   assign the named text and emoji color index "NAME" in the current
color scheme with the value RGBATEXT and RGBAEMOJI.

're-fade-color' ( rgba1 rgba2 "name" -  ) minos2
   assign the named color index pair "NAME" in the current color scheme
with the value RGBA1 and RGBA2.

're-text-emoji-fade-color' ( rgbatext1 ~2 rgbaemoji1 ~2 "name" -  ) minos2
   assign the named color index pair "NAME" in the current color scheme
with the value RGBATEXT1 and ~2 resp.  RGBAEMOJI1 and ~2.

   For a number of specific objects, there are early bound methods, that
only work on these objects

   * Viewport

     'vp-top' ( o:vp -  ) minos2
     scroll viewport to top

     'vp-bottom' ( o:vp -  ) minos2
     scroll viewport to bottom

     'vp-left' ( o:vp -  ) minos2
     scroll viewport to left

     'vp-right' ( o:vp -  ) minos2
     scroll viewport to right

     'vp-reslide' ( o:vp -  ) minos2
     Adjust the sliders of a viewport after scrolling

     'vp-needed' ( xt -  ) minos2
     collect needs in viewport's vp-need

17.2 MINOS2 tutorial
====================

Tutorials are small files, each showing a bit of MINOS2.  For the common
framework, the file 'minos2/tutorial/tutorial.fs' needs to be loaded
first; all other tutorials in the command line argument are included
from within that file.  Scroll wheel or previous/next mouse buttons as
well as clicking on the left or right edge of the window allow
navigation between the different tutorials loaded.

   I.e.  to load the buttons tutorial, you start Gforth with

     gforth minos2/tutorial/tutorial.fs buttons.fs

   Available tutorials:

   * 'buttons.fs': Clickable buttons

   * 'plots.fs': Plot functions

   * 'markdown.fs': Markdown document viewer

   * 'screenshot.fs': Screenshot function

Appendix A Bugs
***************

Known bugs are described in the file 'BUGS' in the Gforth distribution.

   If you find a bug, please submit a bug report through
<https://savannah.gnu.org/bugs/?func=addbug&group=gforth>.

   * A program (or a sequence of keyboard commands) that reproduces the
     bug.
   * A description of what you think constitutes the buggy behaviour.
   * The Gforth version used (it is announced at the start of an
     interactive Gforth session).
   * The machine and operating system (on Unix systems 'uname -a' will
     report this information).
   * The installation options (you can find the configure options at the
     start of 'config.status') and configuration ('configure' output or
     'config.cache').
   * A complete list of changes (if any) you (or your installer) have
     made to the Gforth sources.

   For a thorough guide on reporting bugs read *note How to Report Bugs:
(gcc)Bug Reporting.

Appendix B Authors and Ancestors of Gforth
******************************************

B.1 Authors and Contributors
============================

The Gforth project was started in mid-1992 by Bernd Paysan and Anton
Ertl.  The third major author was Jens Wilke.  Neal Crook contributed a
lot to the manual.  Assemblers and disassemblers were contributed by
Andrew McKewan, Christian Pirker, Bernd Thallner, and Michal Revucky.
Lennart Benschop (who was one of Gforth's first users, in mid-1993) and
Stuart Ramsden inspired us with their continuous feedback.  Lennart
Benshop contributed 'glosgen.fs', while Stuart Ramsden has been working
on automatic support for calling C libraries.  Helpful comments also
came from Paul Kleinrubatscher, Christian Pirker, Dirk Zoller, Marcel
Hendrix, John Wavrik, Barrie Stott, Marc de Groot, Jorge Acerada, Bruce
Hoyt, Robert Epprecht, Dennis Ruffer and David N. Williams.  Since the
release of Gforth-0.2.1 there were also helpful comments from many
others; thank you all, sorry for not listing you here (but digging
through my mailbox to extract your names is on my to-do list).

   Gforth also owes a lot to the authors of the tools we used (GCC, CVS,
and autoconf, among others), and to the creators of the Internet: Gforth
was developed across the Internet, and its authors did not meet
physically for the first 4 years of development.

B.2 Pedigree
============

Gforth descends from bigFORTH (1993) and fig-Forth.  Of course, a
significant part of the design of Gforth was prescribed by Standard
Forth.

   Bernd Paysan wrote bigFORTH, a descendent from TurboForth, an
unreleased 32 bit native code version of VolksForth for the Atari ST,
written mostly by Dietrich Weineck.

   VolksForth was written by Klaus Schleisiek, Bernd Pennemann, Georg
Rehfeld and Dietrich Weineck for the C64 (called UltraForth there) in
the mid-80s and ported to the Atari ST in 1986.  It descends from
fig-Forth.

   A team led by Bill Ragsdale implemented fig-Forth on many processors
in 1979.  Robert Selzer and Bill Ragsdale developed the original
implementation of fig-Forth for the 6502 based on microForth.

   The principal architect of microForth was Dean Sanderson.  microForth
was FORTH, Inc.'s first off-the-shelf product.  It was developed in 1976
for the 1802, and subsequently implemented on the 8080, the 6800 and the
Z80.

   All earlier Forth systems were custom-made, usually by Charles Moore,
who discovered (as he puts it) Forth during the late 60s.  The first
full Forth existed in 1971.

   A part of the information in this section comes from 'The Evolution
of Forth (https://www.forth.com/resources/evolution/index.html)' by
Elizabeth D. Rather, Donald R. Colburn and Charles H. Moore, presented
at the HOPL-II conference and preprinted in SIGPLAN Notices 28(3), 1993.
You can find more historical and genealogical information about Forth
there.  For a more general (and graphical) Forth family tree look see
'<https://www.complang.tuwien.ac.at/forth/family-tree/>, Forth Family
Tree and Timeline'.

Appendix C Other Forth-related information
******************************************

There is an active news group (comp.lang.forth) discussing Forth
(including Gforth) and Forth-related issues.  Its FAQs
(https://www.complang.tuwien.ac.at/forth/faq/faq-general-2.html)
(frequently asked questions and their answers) contains a lot of
information on Forth.  You should read it before posting to
comp.lang.forth.

   The Forth standard is most usable in its HTML form
(https://forth-standard.org/).

Appendix D Licenses
*******************

D.1 GNU Free Documentation License
==================================

                      Version 1.2, November 2002

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     form.  Otherwise they must appear on printed covers that bracket
     the whole aggregate.

  8. TRANSLATION

     Translation is considered a kind of modification, so you may
     distribute translations of the Document under the terms of section
     4.  Replacing Invariant Sections with translations requires special
     permission from their copyright holders, but you may include
     translations of some or all Invariant Sections in addition to the
     original versions of these Invariant Sections.  You may include a
     translation of this License, and all the license notices in the
     Document, and any Warranty Disclaimers, provided that you also
     include the original English version of this License and the
     original versions of those notices and disclaimers.  In case of a
     disagreement between the translation and the original version of
     this License or a notice or disclaimer, the original version will
     prevail.

     If a section in the Document is Entitled "Acknowledgements",
     "Dedications", or "History", the requirement (section 4) to
     Preserve its Title (section 1) will typically require changing the
     actual title.

  9. TERMINATION

     You may not copy, modify, sublicense, or distribute the Document
     except as expressly provided for under this License.  Any other
     attempt to copy, modify, sublicense or distribute the Document is
     void, and will automatically terminate your rights under this
     License.  However, parties who have received copies, or rights,
     from you under this License will not have their licenses terminated
     so long as such parties remain in full compliance.

  10. FUTURE REVISIONS OF THIS LICENSE

     The Free Software Foundation may publish new, revised versions of
     the GNU Free Documentation License from time to time.  Such new
     versions will be similar in spirit to the present version, but may
     differ in detail to address new problems or concerns.  See
     <http://www.gnu.org/copyleft/>.

     Each version of the License is given a distinguishing version
     number.  If the Document specifies that a particular numbered
     version of this License "or any later version" applies to it, you
     have the option of following the terms and conditions either of
     that specified version or of any later version that has been
     published (not as a draft) by the Free Software Foundation.  If the
     Document does not specify a version number of this License, you may
     choose any version ever published (not as a draft) by the Free
     Software Foundation.

D.1.1 ADDENDUM: How to use this License for your documents
----------------------------------------------------------

To use this License in a document you have written, include a copy of
the License in the document and put the following copyright and license
notices just after the title page:

       Copyright (C)  YEAR  YOUR NAME.
       Permission is granted to copy, distribute and/or modify this document
       under the terms of the GNU Free Documentation License, Version 1.2
       or any later version published by the Free Software Foundation;
       with no Invariant Sections, no Front-Cover Texts, and no Back-Cover
       Texts.  A copy of the license is included in the section entitled ``GNU
       Free Documentation License''.

   If you have Invariant Sections, Front-Cover Texts and Back-Cover
Texts, replace the "with...Texts."  line with this:

         with the Invariant Sections being LIST THEIR TITLES, with
         the Front-Cover Texts being LIST, and with the Back-Cover Texts
         being LIST.

   If you have Invariant Sections without Cover Texts, or some other
combination of the three, merge those two alternatives to suit the
situation.

   If your document contains nontrivial examples of program code, we
recommend releasing these examples in parallel under your choice of free
software license, such as the GNU General Public License, to permit
their use in free software.

D.2 GNU GENERAL PUBLIC LICENSE
==============================

                        Version 3, 29 June 2007

     Copyright © 2007 Free Software Foundation, Inc. <http://fsf.org/>

     Everyone is permitted to copy and distribute verbatim copies of this
     license document, but changing it is not allowed.

Preamble
========

The GNU General Public License is a free, copyleft license for software
and other kinds of works.

   The licenses for most software and other practical works are designed
to take away your freedom to share and change the works.  By contrast,
the GNU General Public License is intended to guarantee your freedom to
share and change all versions of a program--to make sure it remains free
software for all its users.  We, the Free Software Foundation, use the
GNU General Public License for most of our software; it applies also to
any other work released this way by its authors.  You can apply it to
your programs, too.

   When we speak of free software, we are referring to freedom, not
price.  Our General Public Licenses are designed to make sure that you
have the freedom to distribute copies of free software (and charge for
them if you wish), that you receive source code or can get it if you
want it, that you can change the software or use pieces of it in new
free programs, and that you know you can do these things.

   To protect your rights, we need to prevent others from denying you
these rights or asking you to surrender the rights.  Therefore, you have
certain responsibilities if you distribute copies of the software, or if
you modify it: responsibilities to respect the freedom of others.

   For example, if you distribute copies of such a program, whether
gratis or for a fee, you must pass on to the recipients the same
freedoms that you received.  You must make sure that they, too, receive
or can get the source code.  And you must show them these terms so they
know their rights.

   Developers that use the GNU GPL protect your rights with two steps:
(1) assert copyright on the software, and (2) offer you this License
giving you legal permission to copy, distribute and/or modify it.

   For the developers' and authors' protection, the GPL clearly explains
that there is no warranty for this free software.  For both users' and
authors' sake, the GPL requires that modified versions be marked as
changed, so that their problems will not be attributed erroneously to
authors of previous versions.

   Some devices are designed to deny users access to install or run
modified versions of the software inside them, although the manufacturer
can do so.  This is fundamentally incompatible with the aim of
protecting users' freedom to change the software.  The systematic
pattern of such abuse occurs in the area of products for individuals to
use, which is precisely where it is most unacceptable.  Therefore, we
have designed this version of the GPL to prohibit the practice for those
products.  If such problems arise substantially in other domains, we
stand ready to extend this provision to those domains in future versions
of the GPL, as needed to protect the freedom of users.

   Finally, every program is threatened constantly by software patents.
States should not allow patents to restrict development and use of
software on general-purpose computers, but in those that do, we wish to
avoid the special danger that patents applied to a free program could
make it effectively proprietary.  To prevent this, the GPL assures that
patents cannot be used to render the program non-free.

   The precise terms and conditions for copying, distribution and
modification follow.

TERMS AND CONDITIONS
====================

  0. Definitions.

     "This License" refers to version 3 of the GNU General Public
     License.

     "Copyright" also means copyright-like laws that apply to other
     kinds of works, such as semiconductor masks.

     "The Program" refers to any copyrightable work licensed under this
     License.  Each licensee is addressed as "you".  "Licensees" and
     "recipients" may be individuals or organizations.

     To "modify" a work means to copy from or adapt all or part of the
     work in a fashion requiring copyright permission, other than the
     making of an exact copy.  The resulting work is called a "modified
     version" of the earlier work or a work "based on" the earlier work.

     A "covered work" means either the unmodified Program or a work
     based on the Program.

     To "propagate" a work means to do anything with it that, without
     permission, would make you directly or secondarily liable for
     infringement under applicable copyright law, except executing it on
     a computer or modifying a private copy.  Propagation includes
     copying, distribution (with or without modification), making
     available to the public, and in some countries other activities as
     well.

     To "convey" a work means any kind of propagation that enables other
     parties to make or receive copies.  Mere interaction with a user
     through a computer network, with no transfer of a copy, is not
     conveying.

     An interactive user interface displays "Appropriate Legal Notices"
     to the extent that it includes a convenient and prominently visible
     feature that (1) displays an appropriate copyright notice, and (2)
     tells the user that there is no warranty for the work (except to
     the extent that warranties are provided), that licensees may convey
     the work under this License, and how to view a copy of this
     License.  If the interface presents a list of user commands or
     options, such as a menu, a prominent item in the list meets this
     criterion.

  1. Source Code.

     The "source code" for a work means the preferred form of the work
     for making modifications to it.  "Object code" means any non-source
     form of a work.

     A "Standard Interface" means an interface that either is an
     official standard defined by a recognized standards body, or, in
     the case of interfaces specified for a particular programming
     language, one that is widely used among developers working in that
     language.

     The "System Libraries" of an executable work include anything,
     other than the work as a whole, that (a) is included in the normal
     form of packaging a Major Component, but which is not part of that
     Major Component, and (b) serves only to enable use of the work with
     that Major Component, or to implement a Standard Interface for
     which an implementation is available to the public in source code
     form.  A "Major Component", in this context, means a major
     essential component (kernel, window system, and so on) of the
     specific operating system (if any) on which the executable work
     runs, or a compiler used to produce the work, or an object code
     interpreter used to run it.

     The "Corresponding Source" for a work in object code form means all
     the source code needed to generate, install, and (for an executable
     work) run the object code and to modify the work, including scripts
     to control those activities.  However, it does not include the
     work's System Libraries, or general-purpose tools or generally
     available free programs which are used unmodified in performing
     those activities but which are not part of the work.  For example,
     Corresponding Source includes interface definition files associated
     with source files for the work, and the source code for shared
     libraries and dynamically linked subprograms that the work is
     specifically designed to require, such as by intimate data
     communication or control flow between those subprograms and other
     parts of the work.

     The Corresponding Source need not include anything that users can
     regenerate automatically from other parts of the Corresponding
     Source.

     The Corresponding Source for a work in source code form is that
     same work.

  2. Basic Permissions.

     All rights granted under this License are granted for the term of
     copyright on the Program, and are irrevocable provided the stated
     conditions are met.  This License explicitly affirms your unlimited
     permission to run the unmodified Program.  The output from running
     a covered work is covered by this License only if the output, given
     its content, constitutes a covered work.  This License acknowledges
     your rights of fair use or other equivalent, as provided by
     copyright law.

     You may make, run and propagate covered works that you do not
     convey, without conditions so long as your license otherwise
     remains in force.  You may convey covered works to others for the
     sole purpose of having them make modifications exclusively for you,
     or provide you with facilities for running those works, provided
     that you comply with the terms of this License in conveying all
     material for which you do not control copyright.  Those thus making
     or running the covered works for you must do so exclusively on your
     behalf, under your direction and control, on terms that prohibit
     them from making any copies of your copyrighted material outside
     their relationship with you.

     Conveying under any other circumstances is permitted solely under
     the conditions stated below.  Sublicensing is not allowed; section
     10 makes it unnecessary.

  3. Protecting Users' Legal Rights From Anti-Circumvention Law.

     No covered work shall be deemed part of an effective technological
     measure under any applicable law fulfilling obligations under
     article 11 of the WIPO copyright treaty adopted on 20 December
     1996, or similar laws prohibiting or restricting circumvention of
     such measures.

     When you convey a covered work, you waive any legal power to forbid
     circumvention of technological measures to the extent such
     circumvention is effected by exercising rights under this License
     with respect to the covered work, and you disclaim any intention to
     limit operation or modification of the work as a means of
     enforcing, against the work's users, your or third parties' legal
     rights to forbid circumvention of technological measures.

  4. Conveying Verbatim Copies.

     You may convey verbatim copies of the Program's source code as you
     receive it, in any medium, provided that you conspicuously and
     appropriately publish on each copy an appropriate copyright notice;
     keep intact all notices stating that this License and any
     non-permissive terms added in accord with section 7 apply to the
     code; keep intact all notices of the absence of any warranty; and
     give all recipients a copy of this License along with the Program.

     You may charge any price or no price for each copy that you convey,
     and you may offer support or warranty protection for a fee.

  5. Conveying Modified Source Versions.

     You may convey a work based on the Program, or the modifications to
     produce it from the Program, in the form of source code under the
     terms of section 4, provided that you also meet all of these
     conditions:

       a. The work must carry prominent notices stating that you
          modified it, and giving a relevant date.

       b. The work must carry prominent notices stating that it is
          released under this License and any conditions added under
          section 7.  This requirement modifies the requirement in
          section 4 to "keep intact all notices".

       c. You must license the entire work, as a whole, under this
          License to anyone who comes into possession of a copy.  This
          License will therefore apply, along with any applicable
          section 7 additional terms, to the whole of the work, and all
          its parts, regardless of how they are packaged.  This License
          gives no permission to license the work in any other way, but
          it does not invalidate such permission if you have separately
          received it.

       d. If the work has interactive user interfaces, each must display
          Appropriate Legal Notices; however, if the Program has
          interactive interfaces that do not display Appropriate Legal
          Notices, your work need not make them do so.

     A compilation of a covered work with other separate and independent
     works, which are not by their nature extensions of the covered
     work, and which are not combined with it such as to form a larger
     program, in or on a volume of a storage or distribution medium, is
     called an "aggregate" if the compilation and its resulting
     copyright are not used to limit the access or legal rights of the
     compilation's users beyond what the individual works permit.
     Inclusion of a covered work in an aggregate does not cause this
     License to apply to the other parts of the aggregate.

  6. Conveying Non-Source Forms.

     You may convey a covered work in object code form under the terms
     of sections 4 and 5, provided that you also convey the
     machine-readable Corresponding Source under the terms of this
     License, in one of these ways:

       a. Convey the object code in, or embodied in, a physical product
          (including a physical distribution medium), accompanied by the
          Corresponding Source fixed on a durable physical medium
          customarily used for software interchange.

       b. Convey the object code in, or embodied in, a physical product
          (including a physical distribution medium), accompanied by a
          written offer, valid for at least three years and valid for as
          long as you offer spare parts or customer support for that
          product model, to give anyone who possesses the object code
          either (1) a copy of the Corresponding Source for all the
          software in the product that is covered by this License, on a
          durable physical medium customarily used for software
          interchange, for a price no more than your reasonable cost of
          physically performing this conveying of source, or (2) access
          to copy the Corresponding Source from a network server at no
          charge.

       c. Convey individual copies of the object code with a copy of the
          written offer to provide the Corresponding Source.  This
          alternative is allowed only occasionally and noncommercially,
          and only if you received the object code with such an offer,
          in accord with subsection 6b.

       d. Convey the object code by offering access from a designated
          place (gratis or for a charge), and offer equivalent access to
          the Corresponding Source in the same way through the same
          place at no further charge.  You need not require recipients
          to copy the Corresponding Source along with the object code.
          If the place to copy the object code is a network server, the
          Corresponding Source may be on a different server (operated by
          you or a third party) that supports equivalent copying
          facilities, provided you maintain clear directions next to the
          object code saying where to find the Corresponding Source.
          Regardless of what server hosts the Corresponding Source, you
          remain obligated to ensure that it is available for as long as
          needed to satisfy these requirements.

       e. Convey the object code using peer-to-peer transmission,
          provided you inform other peers where the object code and
          Corresponding Source of the work are being offered to the
          general public at no charge under subsection 6d.

     A separable portion of the object code, whose source code is
     excluded from the Corresponding Source as a System Library, need
     not be included in conveying the object code work.

     A "User Product" is either (1) a "consumer product", which means
     any tangible personal property which is normally used for personal,
     family, or household purposes, or (2) anything designed or sold for
     incorporation into a dwelling.  In determining whether a product is
     a consumer product, doubtful cases shall be resolved in favor of
     coverage.  For a particular product received by a particular user,
     "normally used" refers to a typical or common use of that class of
     product, regardless of the status of the particular user or of the
     way in which the particular user actually uses, or expects or is
     expected to use, the product.  A product is a consumer product
     regardless of whether the product has substantial commercial,
     industrial or non-consumer uses, unless such uses represent the
     only significant mode of use of the product.

     "Installation Information" for a User Product means any methods,
     procedures, authorization keys, or other information required to
     install and execute modified versions of a covered work in that
     User Product from a modified version of its Corresponding Source.
     The information must suffice to ensure that the continued
     functioning of the modified object code is in no case prevented or
     interfered with solely because modification has been made.

     If you convey an object code work under this section in, or with,
     or specifically for use in, a User Product, and the conveying
     occurs as part of a transaction in which the right of possession
     and use of the User Product is transferred to the recipient in
     perpetuity or for a fixed term (regardless of how the transaction
     is characterized), the Corresponding Source conveyed under this
     section must be accompanied by the Installation Information.  But
     this requirement does not apply if neither you nor any third party
     retains the ability to install modified object code on the User
     Product (for example, the work has been installed in ROM).

     The requirement to provide Installation Information does not
     include a requirement to continue to provide support service,
     warranty, or updates for a work that has been modified or installed
     by the recipient, or for the User Product in which it has been
     modified or installed.  Access to a network may be denied when the
     modification itself materially and adversely affects the operation
     of the network or violates the rules and protocols for
     communication across the network.

     Corresponding Source conveyed, and Installation Information
     provided, in accord with this section must be in a format that is
     publicly documented (and with an implementation available to the
     public in source code form), and must require no special password
     or key for unpacking, reading or copying.

  7. Additional Terms.

     "Additional permissions" are terms that supplement the terms of
     this License by making exceptions from one or more of its
     conditions.  Additional permissions that are applicable to the
     entire Program shall be treated as though they were included in
     this License, to the extent that they are valid under applicable
     law.  If additional permissions apply only to part of the Program,
     that part may be used separately under those permissions, but the
     entire Program remains governed by this License without regard to
     the additional permissions.

     When you convey a copy of a covered work, you may at your option
     remove any additional permissions from that copy, or from any part
     of it.  (Additional permissions may be written to require their own
     removal in certain cases when you modify the work.)  You may place
     additional permissions on material, added by you to a covered work,
     for which you have or can give appropriate copyright permission.

     Notwithstanding any other provision of this License, for material
     you add to a covered work, you may (if authorized by the copyright
     holders of that material) supplement the terms of this License with
     terms:

       a. Disclaiming warranty or limiting liability differently from
          the terms of sections 15 and 16 of this License; or

       b. Requiring preservation of specified reasonable legal notices
          or author attributions in that material or in the Appropriate
          Legal Notices displayed by works containing it; or

       c. Prohibiting misrepresentation of the origin of that material,
          or requiring that modified versions of such material be marked
          in reasonable ways as different from the original version; or

       d. Limiting the use for publicity purposes of names of licensors
          or authors of the material; or

       e. Declining to grant rights under trademark law for use of some
          trade names, trademarks, or service marks; or

       f. Requiring indemnification of licensors and authors of that
          material by anyone who conveys the material (or modified
          versions of it) with contractual assumptions of liability to
          the recipient, for any liability that these contractual
          assumptions directly impose on those licensors and authors.

     All other non-permissive additional terms are considered "further
     restrictions" within the meaning of section 10.  If the Program as
     you received it, or any part of it, contains a notice stating that
     it is governed by this License along with a term that is a further
     restriction, you may remove that term.  If a license document
     contains a further restriction but permits relicensing or conveying
     under this License, you may add to a covered work material governed
     by the terms of that license document, provided that the further
     restriction does not survive such relicensing or conveying.

     If you add terms to a covered work in accord with this section, you
     must place, in the relevant source files, a statement of the
     additional terms that apply to those files, or a notice indicating
     where to find the applicable terms.

     Additional terms, permissive or non-permissive, may be stated in
     the form of a separately written license, or stated as exceptions;
     the above requirements apply either way.

  8. Termination.

     You may not propagate or modify a covered work except as expressly
     provided under this License.  Any attempt otherwise to propagate or
     modify it is void, and will automatically terminate your rights
     under this License (including any patent licenses granted under the
     third paragraph of section 11).

     However, if you cease all violation of this License, then your
     license from a particular copyright holder is reinstated (a)
     provisionally, unless and until the copyright holder explicitly and
     finally terminates your license, and (b) permanently, if the
     copyright holder fails to notify you of the violation by some
     reasonable means prior to 60 days after the cessation.

     Moreover, your license from a particular copyright holder is
     reinstated permanently if the copyright holder notifies you of the
     violation by some reasonable means, this is the first time you have
     received notice of violation of this License (for any work) from
     that copyright holder, and you cure the violation prior to 30 days
     after your receipt of the notice.

     Termination of your rights under this section does not terminate
     the licenses of parties who have received copies or rights from you
     under this License.  If your rights have been terminated and not
     permanently reinstated, you do not qualify to receive new licenses
     for the same material under section 10.

  9. Acceptance Not Required for Having Copies.

     You are not required to accept this License in order to receive or
     run a copy of the Program.  Ancillary propagation of a covered work
     occurring solely as a consequence of using peer-to-peer
     transmission to receive a copy likewise does not require
     acceptance.  However, nothing other than this License grants you
     permission to propagate or modify any covered work.  These actions
     infringe copyright if you do not accept this License.  Therefore,
     by modifying or propagating a covered work, you indicate your
     acceptance of this License to do so.

  10. Automatic Licensing of Downstream Recipients.

     Each time you convey a covered work, the recipient automatically
     receives a license from the original licensors, to run, modify and
     propagate that work, subject to this License.  You are not
     responsible for enforcing compliance by third parties with this
     License.

     An "entity transaction" is a transaction transferring control of an
     organization, or substantially all assets of one, or subdividing an
     organization, or merging organizations.  If propagation of a
     covered work results from an entity transaction, each party to that
     transaction who receives a copy of the work also receives whatever
     licenses to the work the party's predecessor in interest had or
     could give under the previous paragraph, plus a right to possession
     of the Corresponding Source of the work from the predecessor in
     interest, if the predecessor has it or can get it with reasonable
     efforts.

     You may not impose any further restrictions on the exercise of the
     rights granted or affirmed under this License.  For example, you
     may not impose a license fee, royalty, or other charge for exercise
     of rights granted under this License, and you may not initiate
     litigation (including a cross-claim or counterclaim in a lawsuit)
     alleging that any patent claim is infringed by making, using,
     selling, offering for sale, or importing the Program or any portion
     of it.

  11. Patents.

     A "contributor" is a copyright holder who authorizes use under this
     License of the Program or a work on which the Program is based.
     The work thus licensed is called the contributor's "contributor
     version".

     A contributor's "essential patent claims" are all patent claims
     owned or controlled by the contributor, whether already acquired or
     hereafter acquired, that would be infringed by some manner,
     permitted by this License, of making, using, or selling its
     contributor version, but do not include claims that would be
     infringed only as a consequence of further modification of the
     contributor version.  For purposes of this definition, "control"
     includes the right to grant patent sublicenses in a manner
     consistent with the requirements of this License.

     Each contributor grants you a non-exclusive, worldwide,
     royalty-free patent license under the contributor's essential
     patent claims, to make, use, sell, offer for sale, import and
     otherwise run, modify and propagate the contents of its contributor
     version.

     In the following three paragraphs, a "patent license" is any
     express agreement or commitment, however denominated, not to
     enforce a patent (such as an express permission to practice a
     patent or covenant not to sue for patent infringement).  To "grant"
     such a patent license to a party means to make such an agreement or
     commitment not to enforce a patent against the party.

     If you convey a covered work, knowingly relying on a patent
     license, and the Corresponding Source of the work is not available
     for anyone to copy, free of charge and under the terms of this
     License, through a publicly available network server or other
     readily accessible means, then you must either (1) cause the
     Corresponding Source to be so available, or (2) arrange to deprive
     yourself of the benefit of the patent license for this particular
     work, or (3) arrange, in a manner consistent with the requirements
     of this License, to extend the patent license to downstream
     recipients.  "Knowingly relying" means you have actual knowledge
     that, but for the patent license, your conveying the covered work
     in a country, or your recipient's use of the covered work in a
     country, would infringe one or more identifiable patents in that
     country that you have reason to believe are valid.

     If, pursuant to or in connection with a single transaction or
     arrangement, you convey, or propagate by procuring conveyance of, a
     covered work, and grant a patent license to some of the parties
     receiving the covered work authorizing them to use, propagate,
     modify or convey a specific copy of the covered work, then the
     patent license you grant is automatically extended to all
     recipients of the covered work and works based on it.

     A patent license is "discriminatory" if it does not include within
     the scope of its coverage, prohibits the exercise of, or is
     conditioned on the non-exercise of one or more of the rights that
     are specifically granted under this License.  You may not convey a
     covered work if you are a party to an arrangement with a third
     party that is in the business of distributing software, under which
     you make payment to the third party based on the extent of your
     activity of conveying the work, and under which the third party
     grants, to any of the parties who would receive the covered work
     from you, a discriminatory patent license (a) in connection with
     copies of the covered work conveyed by you (or copies made from
     those copies), or (b) primarily for and in connection with specific
     products or compilations that contain the covered work, unless you
     entered into that arrangement, or that patent license was granted,
     prior to 28 March 2007.

     Nothing in this License shall be construed as excluding or limiting
     any implied license or other defenses to infringement that may
     otherwise be available to you under applicable patent law.

  12. No Surrender of Others' Freedom.

     If conditions are imposed on you (whether by court order, agreement
     or otherwise) that contradict the conditions of this License, they
     do not excuse you from the conditions of this License.  If you
     cannot convey a covered work so as to satisfy simultaneously your
     obligations under this License and any other pertinent obligations,
     then as a consequence you may not convey it at all.  For example,
     if you agree to terms that obligate you to collect a royalty for
     further conveying from those to whom you convey the Program, the
     only way you could satisfy both those terms and this License would
     be to refrain entirely from conveying the Program.

  13. Use with the GNU Affero General Public License.

     Notwithstanding any other provision of this License, you have
     permission to link or combine any covered work with a work licensed
     under version 3 of the GNU Affero General Public License into a
     single combined work, and to convey the resulting work.  The terms
     of this License will continue to apply to the part which is the
     covered work, but the special requirements of the GNU Affero
     General Public License, section 13, concerning interaction through
     a network will apply to the combination as such.

  14. Revised Versions of this License.

     The Free Software Foundation may publish revised and/or new
     versions of the GNU General Public License from time to time.  Such
     new versions will be similar in spirit to the present version, but
     may differ in detail to address new problems or concerns.

     Each version is given a distinguishing version number.  If the
     Program specifies that a certain numbered version of the GNU
     General Public License "or any later version" applies to it, you
     have the option of following the terms and conditions either of
     that numbered version or of any later version published by the Free
     Software Foundation.  If the Program does not specify a version
     number of the GNU General Public License, you may choose any
     version ever published by the Free Software Foundation.

     If the Program specifies that a proxy can decide which future
     versions of the GNU General Public License can be used, that
     proxy's public statement of acceptance of a version permanently
     authorizes you to choose that version for the Program.

     Later license versions may give you additional or different
     permissions.  However, no additional obligations are imposed on any
     author or copyright holder as a result of your choosing to follow a
     later version.

  15. Disclaimer of Warranty.

     THERE IS NO WARRANTY FOR THE PROGRAM, TO THE EXTENT PERMITTED BY
     APPLICABLE LAW. EXCEPT WHEN OTHERWISE STATED IN WRITING THE
     COPYRIGHT HOLDERS AND/OR OTHER PARTIES PROVIDE THE PROGRAM "AS IS"
     WITHOUT WARRANTY OF ANY KIND, EITHER EXPRESSED OR IMPLIED,
     INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
     MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. THE ENTIRE
     RISK AS TO THE QUALITY AND PERFORMANCE OF THE PROGRAM IS WITH YOU.
     SHOULD THE PROGRAM PROVE DEFECTIVE, YOU ASSUME THE COST OF ALL
     NECESSARY SERVICING, REPAIR OR CORRECTION.

  16. Limitation of Liability.

     IN NO EVENT UNLESS REQUIRED BY APPLICABLE LAW OR AGREED TO IN
     WRITING WILL ANY COPYRIGHT HOLDER, OR ANY OTHER PARTY WHO MODIFIES
     AND/OR CONVEYS THE PROGRAM AS PERMITTED ABOVE, BE LIABLE TO YOU FOR
     DAMAGES, INCLUDING ANY GENERAL, SPECIAL, INCIDENTAL OR
     CONSEQUENTIAL DAMAGES ARISING OUT OF THE USE OR INABILITY TO USE
     THE PROGRAM (INCLUDING BUT NOT LIMITED TO LOSS OF DATA OR DATA
     BEING RENDERED INACCURATE OR LOSSES SUSTAINED BY YOU OR THIRD
     PARTIES OR A FAILURE OF THE PROGRAM TO OPERATE WITH ANY OTHER
     PROGRAMS), EVEN IF SUCH HOLDER OR OTHER PARTY HAS BEEN ADVISED OF
     THE POSSIBILITY OF SUCH DAMAGES.

  17. Interpretation of Sections 15 and 16.

     If the disclaimer of warranty and limitation of liability provided
     above cannot be given local legal effect according to their terms,
     reviewing courts shall apply local law that most closely
     approximates an absolute waiver of all civil liability in
     connection with the Program, unless a warranty or assumption of
     liability accompanies a copy of the Program in return for a fee.

END OF TERMS AND CONDITIONS
===========================

How to Apply These Terms to Your New Programs
=============================================

If you develop a new program, and you want it to be of the greatest
possible use to the public, the best way to achieve this is to make it
free software which everyone can redistribute and change under these
terms.

   To do so, attach the following notices to the program.  It is safest
to attach them to the start of each source file to most effectively
state the exclusion of warranty; and each file should have at least the
"copyright" line and a pointer to where the full notice is found.

     ONE LINE TO GIVE THE PROGRAM'S NAME AND A BRIEF IDEA OF WHAT IT DOES.
     Copyright (C) YEAR NAME OF AUTHOR

     This program is free software: you can redistribute it and/or modify
     it under the terms of the GNU General Public License as published by
     the Free Software Foundation, either version 3 of the License, or (at
     your option) any later version.

     This program is distributed in the hope that it will be useful, but
     WITHOUT ANY WARRANTY; without even the implied warranty of
     MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
     General Public License for more details.

     You should have received a copy of the GNU General Public License
     along with this program.  If not, see <http://www.gnu.org/licenses/>.

   Also add information on how to contact you by electronic and paper
mail.

   If the program does terminal interaction, make it output a short
notice like this when it starts in an interactive mode:

     PROGRAM Copyright (C) YEAR NAME OF AUTHOR
     This program comes with ABSOLUTELY NO WARRANTY; for details type 'show w'.
     This is free software, and you are welcome to redistribute it
     under certain conditions; type 'show c' for details.

   The hypothetical commands 'show w' and 'show c' should show the
appropriate parts of the General Public License.  Of course, your
program's commands might be different; for a GUI interface, you would
use an "about box".

   You should also get your employer (if you work as a programmer) or
school, if any, to sign a "copyright disclaimer" for the program, if
necessary.  For more information on this, and how to apply and follow
the GNU GPL, see <http://www.gnu.org/licenses/>.

   The GNU General Public License does not permit incorporating your
program into proprietary programs.  If your program is a subroutine
library, you may consider it more useful to permit linking proprietary
applications with the library.  If this is what you want to do, use the
GNU Lesser General Public License instead of this License.  But first,
please read <http://www.gnu.org/philosophy/why-not-lgpl.html>.

Word Index
**********

This index is a list of Forth words that have "glossary" entries within
this manual.  Each word is listed with its stack effect and wordset.

* Menu:

* - ( N1 N2 -- N ) core:                 Single precision.  (line  4020)
* -- ( HMADDR U WID 0 ... -- ) local-ext: Locals definition words.
                                                            (line 13421)
* --> ( -- ) gforth-0.2:                 Blocks.            (line 12188)
* -[do ( COMPILATION -- DO-SYS ; RUN-TIME N1 N2 -- | LOOP-SYS ) gforth-experimental: Counted Loops.
                                                            (line  6547)
* -\d ( ADDR -- ADDR' ) regexp-pattern:  Regular Expressions.
                                                            (line 15605)
* -\s ( ADDR -- ADDR' ) regexp-pattern:  Regular Expressions.
                                                            (line 15608)
* -` ( "CHAR" -- ) regexp-pattern:       Regular Expressions.
                                                            (line 15616)
* ->here ( ADDR -- ) gforth-1.0:         Dictionary allocation.
                                                            (line  5052)
* -c? ( ADDR CLASS -- ) regexp-pattern:  Regular Expressions.
                                                            (line 15593)
* -char ( CHAR -- ) regexp-cg:           Regular Expressions.
                                                            (line 15571)
* -class ( CLASS -- ) regexp-cg:         Regular Expressions.
                                                            (line 15583)
* -DO ( COMPILATION -- DO-SYS ; RUN-TIME N1 N2 -- | LOOP-SYS ) gforth-0.2: Counted Loops.
                                                            (line  6557)
* -inf ( -- R ) gforth-1.0:              Floating Point.    (line  4701)
* -infinity ( -- R ) gforth-1.0:         Floating Point.    (line  4698)
* -LOOP ( COMPILATION DO-SYS -- ; RUN-TIME LOOP-SYS1 U -- | LOOP-SYS2 ) gforth-0.2: Counted Loops.
                                                            (line  6591)
* -ltrace ( -- ) gforth-1.0:             Debugging.         (line 16148)
* -rot ( W1 W2 W3 -- W3 W1 W2 ) gforth-0.2: Data stack.     (line  4791)
* -stack ( X STACK -- ) gforth-experimental: User-defined Stacks.
                                                            (line  9156)
* -trailing ( C_ADDR U1 -- C_ADDR U2 ) string: String words.
                                                            (line  5997)
* -trailing-garbage ( XC-ADDR U1 -- XC-ADDR U2 ) xchar-ext: Xchars and Unicode.
                                                            (line 13081)
* , ( W -- ) core:                       Dictionary allocation.
                                                            (line  5062)
* ; ( COMPILATION COLON-SYS -- ; RUN-TIME NEST-SYS -- ) core: Colon Definitions.
                                                            (line  7505)
* ;] ( COMPILE-TIME: QUOTATION-SYS -- ; RUN-TIME: -- XT ) gforth-1.0: Quotations.
                                                            (line  7643)
* ;> ( COMPILATION COLON-SYS -- ; RUN-TIME -- ADDR ) gforth-obsolete: How do I write outer locals?.
                                                            (line 15525)
* ;abi-code ( -- ) gforth-1.0:           Assembler Definitions.
                                                            (line 17216)
* ;code ( COMPILATION. COLON-SYS1 -- COLON-SYS2 ) tools-ext: Assembler Definitions.
                                                            (line 17239)
* ;inline ( INLINE:-SYS -- ) gforth-experimental: Inline Definitions.
                                                            (line  7521)
* ;m ( COLON-SYS --; RUN-TIME: -- ) objects: Objects Glossary.
                                                            (line 14583)
* : ( "NAME" -- COLON-SYS ) core:        Colon Definitions. (line  7503)
* :: ( CLASS "NAME" -- ) mini-oof:       Basic Mini-OOF Usage.
                                                            (line 14902)
* :} ( HMADDR U WID 0 XT1 ... XTN -- ) gforth-1.0: Locals definition words.
                                                            (line 13430)
* :}d ( HMADDR U LATEST LATESTNT WID 0 A-ADDR1 U1 ... -- ) gforth-1.0: Closures.
                                                            (line 15315)
* :}h ( HMADDR U LATEST LATESTNT WID 0 A-ADDR1 U1 ... -- ) gforth-1.0: Closures.
                                                            (line 15319)
* :}h1 ( HMADDR U LATEST LATESTNT WID 0 A-ADDR1 U1 ... -- ) gforth-1.0: Closures.
                                                            (line 15324)
* :}l ( HMADDR U LATEST LATESTNT WID 0 A-ADDR1 U1 ... -- ) gforth-1.0: Closures.
                                                            (line 15311)
* :}xt ( HMADDR U LATEST LATESTNT WID 0 A-ADDR1 U1 ... -- ) gforth-1.0: Closures.
                                                            (line 15329)
* :is ( "NAME" -- ) gforth-experimental: Deferred Words.    (line  8520)
* :m ( "NAME" -- XT; RUN-TIME: OBJECT -- ) objects: Objects Glossary.
                                                            (line 14579)
* :method ( CLASS "NAME" -- ) gforth-experimental: Mini-OOF2.
                                                            (line 15097)
* :noname ( -- XT COLON-SYS ) core-ext:  Anonymous Definitions.
                                                            (line  7576)
* ! ( W A-ADDR -- ) core:                Memory Access.     (line  5357)
* !!FIXME!! ( -- ) gforth-1.0:           Debugging.         (line 16133)
* !@ ( W1 A-ADDR -- W2 ) gforth-experimental: Memory Access.
                                                            (line  5363)
* !localn ( W NOFFSET -- ) gforth-internal: Locals implementation.
                                                            (line 13758)
* !resize ( RX RY RW RH RD -- ) minos2:  widget methods.    (line 20903)
* !size ( -- ) minos2:                   widget methods.    (line 20906)
* ? ( A-ADDR -- ) tools:                 Examining data.    (line 16030)
* ??? ( -- ) gforth-0.2:                 Debugging.         (line 16127)
* ?cov+ ( FLAG -- FLAG ) gforth-experimental: Code Coverage.
                                                            (line 16322)
* ?DO ( COMPILATION -- DO-SYS ; RUN-TIME W1 W2 -- | LOOP-SYS ) core-ext: Counted Loops.
                                                            (line  6533)
* ?dup ( W -- S:... W ) core:            Data stack.        (line  4800)
* ?DUP-0=-IF ( COMPILATION -- ORIG ; RUN-TIME N -- N| ) gforth-0.2: Arbitrary control structures.
                                                            (line  6884)
* ?dup-IF ( COMPILATION -- ORIG ; RUN-TIME N -- N| ) gforth-0.2: Arbitrary control structures.
                                                            (line  6879)
* ?errno-throw ( F -- ) gforth-1.0:      Exception Handling.
                                                            (line  7028)
* ?events ( -- ) gforth-experimental:    Message queues.    (line 16651)
* ?EXIT ( -- ) gforth-0.2:               Calls and returns. (line  6960)
* ?found ( TOKEN|0 -- TOKEN ) gforth-experimental: Performing translator actions.
                                                            (line 10995)
* ?inside ( RX RY -- ACT / 0 ) minos2:   actor methods.     (line 20783)
* ?ior ( X -- ) gforth-1.0:              Exception Handling.
                                                            (line  7031)
* ?LEAVE ( COMPILATION -- ; RUN-TIME F | F LOOP-SYS -- ) gforth-0.2: Counted Loops.
                                                            (line  6615)
* ?of ( COMPILATION -- OF-SYS ; RUN-TIME F -- ) gforth-1.0: General control structures with CASE.
                                                            (line  6782)
* . ( N -- ) core:                       Simple numeric output.
                                                            (line 12221)
* .? ( ADDR -- ADDR' ) regexp-pattern:   Regular Expressions.
                                                            (line 15602)
* ... ( X1 .. XN -- X1 .. XN ) gforth-1.0: Examining data.  (line 15984)
* ..char ( START END -- ) regexp-cg:     Regular Expressions.
                                                            (line 15574)
* ." ( COMPILATION 'CCC"' -- ; RUN-TIME -- ) core: Miscellaneous output.
                                                            (line 12546)
* .( ( COMPILATION&INTERPRETATION 'CCC<CLOSE-PAREN>' -- ) core-ext: Miscellaneous output.
                                                            (line 12552)
* .\" ( COMPILATION 'CCC"' -- ; RUN-TIME -- ) gforth-0.6: Miscellaneous output.
                                                            (line 12543)
* .cover-raw ( -- ) gforth-experimental: Code Coverage.     (line 16342)
* .coverage ( -- ) gforth-experimental:  Code Coverage.     (line 16329)
* .debugline ( NFILE NLINE -- ) gforth-0.6: Debugging.      (line 16105)
* .fpath ( -- ) gforth-0.4:              Source Search Paths.
                                                            (line 11935)
* .hm ( NT -- ) gforth-1.0:              Header methods.    (line 18018)
* .id ( NT -- ) gforth-0.6:              Name token.        (line  9703)
* .included ( -- ) gforth-0.5:           Forth source files.
                                                            (line 11678)
* .locale-csv ( -- ) gforth-experimental: i18n and l10n.    (line 13164)
* .path ( PATH-ADDR -- ) gforth-0.4:     General Search Paths.
                                                            (line 11975)
* .quoted-csv ( C-ADDR U -- ) gforth-experimental: CSV reading and writing.
                                                            (line 13238)
* .r ( N1 N2 -- ) core-ext:              Simple numeric output.
                                                            (line 12241)
* .recognizers ( -- ) gforth-experimental: Default Recognizers.
                                                            (line 10660)
* .s ( -- ) tools:                       Examining data.    (line 15987)
* .sections ( -- ) gforth-1.0:           Sections.          (line  5230)
* .substitute ( ADDR1 LEN1 -- N / IOR ) gforth-experimental: Substitute.
                                                            (line 13193)
* .unresolved ( -- ) gforth-1.0:         Calls and returns. (line  6934)
* .voc ( WID -- ) gforth-0.2:            Word Lists.        (line 11224)
* .widget ( -- ) minos2:                 widget methods.    (line 20912)
* ' ( "NAME" -- XT ) core:               Execution token.   (line  9574)
* 'cold ( -- ) gforth-0.2:               Modifying the Startup Sequence.
                                                            (line 20073)
* 's ( ADDR1 TASK -- ADDR2 ) gforth-experimental: Task-local data.
                                                            (line 16547)
* ( ( COMPILATION 'CCC<CLOSE-PAREN>' -- ; RUN-TIME -- ) core,file: Comments.
                                                            (line  3950)
* (( ( ADDR U -- ) regexp-pattern:       Regular Expressions.
                                                            (line 15554)
* (local) ( ADDR U -- ) local:           Standard Forth locals.
                                                            (line 13894)
* ) ( -- ) gforth-0.2:                   Assertions.        (line 16197)
* )) ( -- FLAG ) regexp-pattern:         Regular Expressions.
                                                            (line 15557)
* [ ( -- ) core:                         Literals.          (line  9848)
* [: ( COMPILE-TIME: -- QUOTATION-SYS FLAG COLON-SYS ) gforth-1.0: Quotations.
                                                            (line  7640)
* [?DO] ( N-LIMIT N-INDEX -- ) gforth-0.2: Interpreter Directives.
                                                            (line 10438)
* ['] ( COMPILATION. "NAME" -- ; RUN-TIME. -- XT ) core: Execution token.
                                                            (line  9577)
* [{: ( COMPILATION -- HMADDR U LATEST WID 0 ; INSTANTIATION ... -- XT ) gforth-1.0: Closures.
                                                            (line 15297)
* [+LOOP] ( N -- ) gforth-0.2:           Interpreter Directives.
                                                            (line 10444)
* [AGAIN] ( -- ) gforth-0.2:             Interpreter Directives.
                                                            (line 10464)
* [BEGIN] ( -- ) gforth-0.2:             Interpreter Directives.
                                                            (line 10460)
* [bind] ( COMPILE-TIME: "CLASS" "SELECTOR" -- ; RUN-TIME: ... OBJECT -- ... ) objects: Objects Glossary.
                                                            (line 14491)
* [char] ( COMPILATION '<SPACES>CCC' -- ; RUN-TIME -- C ) core,xchar-ext: String and character literals.
                                                            (line  5889)
* [COMP'] ( COMPILATION "NAME" -- ; RUN-TIME -- W XT ) gforth-0.2: Compilation token.
                                                            (line  9781)
* [compile] ( COMPILATION "NAME" -- ; RUN-TIME ? -- ? ) core-ext: Macros.
                                                            (line 10153)
* [current] ( COMPILE-TIME: "SELECTOR" -- ; RUN-TIME: ... OBJECT -- ... ) objects: Objects Glossary.
                                                            (line 14524)
* [d:d ( COMPILATION -- COLON-SYS; RUN-TIME: D -- XT ; XT EXECUTION: -- D ) gforth-1.0: Closures.
                                                            (line 15258)
* [d:h ( COMPILATION -- COLON-SYS; RUN-TIME: D -- XT ; XT EXECUTION: -- D ) gforth-1.0: Closures.
                                                            (line 15264)
* [d:h1 ( COMPILATION -- COLON-SYS; RUN-TIME: D -- XT ; XT EXECUTION: -- D ) gforth-1.0: Closures.
                                                            (line 15270)
* [d:l ( COMPILATION -- COLON-SYS; RUN-TIME: D -- XT ; XT EXECUTION: -- D ) gforth-1.0: Closures.
                                                            (line 15252)
* [defined] ( "<SPACES>NAME" -- FLAG ) tools-ext: Interpreter Directives.
                                                            (line 10420)
* [DO] ( N-LIMIT N-INDEX -- ) gforth-0.2: Interpreter Directives.
                                                            (line 10440)
* [ELSE] ( -- ) tools-ext:               Interpreter Directives.
                                                            (line 10404)
* [ENDIF] ( -- ) gforth-0.2:             Interpreter Directives.
                                                            (line 10417)
* [f:d ( COMPILATION -- COLON-SYS; RUN-TIME: R -- XT ; XT EXECUTION: -- R ) gforth-1.0: Closures.
                                                            (line 15260)
* [f:h ( COMPILATION -- COLON-SYS; RUN-TIME: R -- XT ; XT EXECUTION: -- R ) gforth-1.0: Closures.
                                                            (line 15266)
* [f:h1 ( COMPILATION -- COLON-SYS; RUN-TIME: R -- XT ; XT EXECUTION: -- R ) gforth-1.0: Closures.
                                                            (line 15272)
* [f:l ( COMPILATION -- COLON-SYS; RUN-TIME: R -- XT ; XT EXECUTION: -- R ) gforth-1.0: Closures.
                                                            (line 15254)
* [FOR] ( N -- ) gforth-0.2:             Interpreter Directives.
                                                            (line 10446)
* [I] ( RUN-TIME -- N ) gforth-0.2:      Interpreter Directives.
                                                            (line 10450)
* [IF] ( FLAG -- ) tools-ext:            Interpreter Directives.
                                                            (line 10396)
* [IFDEF] ( "<SPACES>NAME" -- ) gforth-0.2: Interpreter Directives.
                                                            (line 10428)
* [IFUNDEF] ( "<SPACES>NAME" -- ) gforth-0.2: Interpreter Directives.
                                                            (line 10433)
* [LOOP] ( -- ) gforth-0.2:              Interpreter Directives.
                                                            (line 10442)
* [n:d ( COMPILATION -- COLON-SYS; RUN-TIME: N -- XT ; XT EXECUTION: -- N ) gforth-1.0: Closures.
                                                            (line 15256)
* [n:h ( COMPILATION -- COLON-SYS; RUN-TIME: N -- XT ; XT EXECUTION: -- N ) gforth-1.0: Closures.
                                                            (line 15262)
* [n:h1 ( COMPILATION -- COLON-SYS; RUN-TIME: N -- XT ; XT EXECUTION: -- N ) gforth-1.0: Closures.
                                                            (line 15268)
* [n:l ( COMPILATION -- COLON-SYS; RUN-TIME: N -- XT ; XT EXECUTION: -- N ) gforth-1.0: Closures.
                                                            (line 15250)
* [NEXT] ( N -- ) gforth-0.2:            Interpreter Directives.
                                                            (line 10448)
* [noop] ( -- ) gforth-experimental:     Execution token.   (line  9634)
* [parent] ( COMPILE-TIME: "SELECTOR" -- ; RUN-TIME: ... OBJECT -- ... ) objects: Objects Glossary.
                                                            (line 14602)
* [REPEAT] ( -- ) gforth-0.2:            Interpreter Directives.
                                                            (line 10468)
* [THEN] ( -- ) tools-ext:               Interpreter Directives.
                                                            (line 10413)
* [to-inst] ( COMPILE-TIME: "NAME" -- ; RUN-TIME: W -- ) objects: Objects Glossary.
                                                            (line 14627)
* [undefined] ( "<SPACES>NAME" -- FLAG ) tools-ext: Interpreter Directives.
                                                            (line 10424)
* [UNTIL] ( FLAG -- ) gforth-0.2:        Interpreter Directives.
                                                            (line 10462)
* [WHILE] ( FLAG -- ) gforth-0.2:        Interpreter Directives.
                                                            (line 10466)
* ] ( -- ) core:                         Literals.          (line  9851)
* ]] ( -- ) gforth-0.6:                  Macros.            (line  9970)
* ]L ( COMPILATION: N -- ; RUN-TIME: -- N ) gforth-0.5: Literals.
                                                            (line  9868)
* ]nocov ( -- ) gforth-1.0:              Code Coverage.     (line 16313)
* { ( -- HMADDR U WID 0 ) gforth-0.2:    Locals definition words.
                                                            (line 13433)
* {: ( -- HMADDR U WID 0 ) local-ext:    Locals definition words.
                                                            (line 13418)
* {{ ( ADDR -- ADDR ADDR ) regexp-pattern: Regular Expressions.
                                                            (line 15669)
* {* ( ADDR -- ADDR ADDR ) regexp-pattern: Regular Expressions.
                                                            (line 15649)
* {** ( ADDR -- ADDR ADDR ) regexp-pattern: Regular Expressions.
                                                            (line 15637)
* {+ ( ADDR -- ADDR ADDR ) regexp-pattern: Regular Expressions.
                                                            (line 15655)
* {++ ( ADDR -- ADDR ADDR ) regexp-pattern: Regular Expressions.
                                                            (line 15643)
* } ( HMADDR U WID 0 XT1 ... XTN -- ) gforth-0.2: Locals definition words.
                                                            (line 13437)
* }} ( ADDR ADDR -- ADDR ) regexp-pattern: Regular Expressions.
                                                            (line 15675)
* @ ( A-ADDR -- W ) core:                Memory Access.     (line  5354)
* @localn ( NOFFSET -- W ) gforth-internal: Locals implementation.
                                                            (line 13754)
* * ( N1 N2 -- N ) core:                 Single precision.  (line  4024)
* *} ( ADDR ADDR' -- ADDR' ) regexp-pattern: Regular Expressions.
                                                            (line 15652)
* **} ( SYS -- ) regexp-pattern:         Regular Expressions.
                                                            (line 15640)
* */ ( ( N1 N2 N3 -- N4 ) core:          Integer division.  (line  4176)
* */f ( N1 N2 N3 -- N4 ) gforth-1.0:     Integer division.  (line  4182)
* */mod ( N1 N2 N3 -- N4 N5 ) core:      Integer division.  (line  4188)
* */modf ( N1 N2 N3 -- N4 N5 ) gforth-1.0: Integer division.
                                                            (line  4196)
* */mods ( N1 N2 N3 -- N4 N5 ) gforth-1.0: Integer division.
                                                            (line  4192)
* */s ( N1 N2 N3 -- N4 ) gforth-1.0:     Integer division.  (line  4179)
* *align ( N -- ) gforth-1.0:            Address arithmetic.
                                                            (line  5652)
* *aligned ( ADDR1 N -- ADDR2 ) gforth-1.0: Address arithmetic.
                                                            (line  5648)
* / ( N1 N2 -- N ) core:                 Integer division.  (line  4129)
* // ( -- ) regexp-pattern:              Regular Expressions.
                                                            (line 15664)
* //g ( PTR ADDR U -- ADDR' U' ) regexp-replace: Regular Expressions.
                                                            (line 15714)
* //o ( PTR ADDR U -- ADDR' U' ) regexp-replace: Regular Expressions.
                                                            (line 15711)
* //s ( PTR -- ) regexp-replace:         Regular Expressions.
                                                            (line 15708)
* /COUNTED-STRING ( -- N ) environment:  Environmental Queries.
                                                            (line 11423)
* /f ( N1 N2 -- N ) gforth-1.0:          Integer division.  (line  4134)
* /f-stage1m ( N A-RECI -- ) gforth-1.0: Two-stage integer division.
                                                            (line  4297)
* /f-stage2m ( N1 A-RECI -- NQUOTIENT ) gforth-1.0: Two-stage integer division.
                                                            (line  4301)
* /HOLD ( -- N ) environment:            Environmental Queries.
                                                            (line 11426)
* /l ( -- U ) gforth-0.7:                Address arithmetic.
                                                            (line  5680)
* /mod ( N1 N2 -- N3 N4 ) core:          Integer division.  (line  4147)
* /modf ( N1 N2 -- N3 N4 ) gforth-1.0:   Integer division.  (line  4153)
* /modf-stage2m ( N1 A-RECI -- UMODULUS NQUOTIENT ) gforth-1.0: Two-stage integer division.
                                                            (line  4309)
* /mods ( N1 N2 -- N3 N4 ) gforth-1.0:   Integer division.  (line  4150)
* /PAD ( -- N ) environment:             Environmental Queries.
                                                            (line 11429)
* /s ( N1 N2 -- N ) gforth-1.0:          Integer division.  (line  4132)
* /string ( C-ADDR1 U1 N -- C-ADDR2 U2 ) string: String words.
                                                            (line  6001)
* /w ( -- U ) gforth-0.7:                Address arithmetic.
                                                            (line  5677)
* /x ( -- U ) gforth-1.0:                Address arithmetic.
                                                            (line  5683)
* \ ( COMPILATION 'CCC<NEWLINE>' -- ; RUN-TIME -- ) core-ext,block-ext: Comments.
                                                            (line  3957)
* \( ( ADDR -- ADDR ) regexp-pattern:    Regular Expressions.
                                                            (line 15681)
* \) ( ADDR -- ADDR ) regexp-pattern:    Regular Expressions.
                                                            (line 15684)
* \\\ ( -- ) gforth-1.0:                 Forth source files.
                                                            (line 11675)
* \^ ( ADDR -- ADDR ) regexp-pattern:    Regular Expressions.
                                                            (line 15622)
* \$ ( ADDR -- ADDR ) regexp-pattern:    Regular Expressions.
                                                            (line 15625)
* \0 ( -- ADDR U ) regexp-pattern:       Regular Expressions.
                                                            (line 15687)
* \c ( "REST-OF-LINE" -- ) gforth-0.7:   Declaring C Functions.
                                                            (line 16862)
* \d ( ADDR -- ADDR' ) regexp-pattern:   Regular Expressions.
                                                            (line 15596)
* \G ( COMPILATION 'CCC<NEWLINE>' -- ; RUN-TIME -- ) gforth-0.2: Comments.
                                                            (line  3963)
* \s ( ADDR -- ADDR' ) regexp-pattern:   Regular Expressions.
                                                            (line 15599)
* # ( UD1 -- UD2 ) core:                 Formatted numeric output.
                                                            (line 12319)
* #! ( -- ) gforth-0.2:                  Running Image Files.
                                                            (line 20017)
* #> ( XD -- ADDR U ) core:              Formatted numeric output.
                                                            (line 12342)
* #>> ( -- ) gforth-0.5:                 Formatted numeric output.
                                                            (line 12349)
* #bell ( -- C ) gforth-0.2:             String and character literals.
                                                            (line  5931)
* #bs ( -- C ) gforth-0.2:               String and character literals.
                                                            (line  5927)
* #cr ( -- C ) gforth-0.2:               String and character literals.
                                                            (line  5923)
* #del ( -- C ) gforth-0.2:              String and character literals.
                                                            (line  5929)
* #eof ( -- C ) gforth-0.7:              String and character literals.
                                                            (line  5935)
* #esc ( -- C ) gforth-0.5:              String and character literals.
                                                            (line  5933)
* #ff ( -- C ) gforth-0.2:               String and character literals.
                                                            (line  5925)
* #lf ( -- C ) gforth-0.2:               String and character literals.
                                                            (line  5921)
* #line ( "U" "["FILE"]" -- ) gforth-1.0: Interpreter Directives.
                                                            (line 10477)
* #loc ( NLINE NCHAR "FILE" -- ) gforth-1.0: Debugging.     (line 16151)
* #locals ( -- N ) environment:          Environmental Queries.
                                                            (line 11465)
* #s ( UD -- 0 0 ) core:                 Formatted numeric output.
                                                            (line 12324)
* #tab ( -- C ) gforth-0.2:              String and character literals.
                                                            (line  5919)
* #tib ( -- ADDR ) core-ext-obsolescent: The Text Interpreter.
                                                            (line 10241)
* %align ( ALIGN SIZE -- ) gforth-0.4:   Gforth structs.    (line  9070)
* %alignment ( ALIGN SIZE -- ALIGN ) gforth-0.4: Gforth structs.
                                                            (line  9073)
* %alloc ( ALIGN SIZE -- ADDR ) gforth-0.4: Gforth structs. (line  9076)
* %allocate ( ALIGN SIZE -- ADDR IOR ) gforth-0.4: Gforth structs.
                                                            (line  9080)
* %allot ( ALIGN SIZE -- ADDR ) gforth-0.4: Gforth structs. (line  9084)
* %size ( ALIGN SIZE -- SIZE ) gforth-0.4: Gforth structs.  (line  9112)
* ` ( "CHAR" -- ) regexp-pattern:        Regular Expressions.
                                                            (line 15611)
* `? ( "CHAR" -- ) regexp-pattern:       Regular Expressions.
                                                            (line 15614)
* + ( N1 N2 -- N ) core:                 Single precision.  (line  4013)
* +! ( N A-ADDR -- ) core:               Memory Access.     (line  5360)
* +!@ ( U1 A-ADDR -- U2 ) gforth-experimental: Memory Access.
                                                            (line  5367)
* +} ( ADDR ADDR' -- ADDR' ) regexp-pattern: Regular Expressions.
                                                            (line 15658)
* ++} ( SYS -- ) regexp-pattern:         Regular Expressions.
                                                            (line 15646)
* +after ( X1 X2 STACK -- ) gforth-experimental: User-defined Stacks.
                                                            (line  9153)
* +char ( CHAR -- ) regexp-cg:           Regular Expressions.
                                                            (line 15568)
* +chars ( ADDR U -- ) regexp-cg:        Regular Expressions.
                                                            (line 15577)
* +class ( CLASS -- ) regexp-cg:         Regular Expressions.
                                                            (line 15580)
* +DO ( COMPILATION -- DO-SYS ; RUN-TIME N1 N2 -- | LOOP-SYS ) gforth-0.2: Counted Loops.
                                                            (line  6536)
* +field ( NOFFSET1 NSIZE "NAME" -- NOFFSET2 ) facility-ext: Standard Structures.
                                                            (line  8774)
* +fmode ( FAM1 RWXRWXRWX -- FAM2 ) gforth-1.0: General files.
                                                            (line 11710)
* +load ( I*X N -- J*X ) gforth-0.2:     Blocks.            (line 12180)
* +LOOP ( COMPILATION DO-SYS -- ; RUN-TIME LOOP-SYS1 N -- | LOOP-SYS2 ) core: Counted Loops.
                                                            (line  6588)
* +ltrace ( -- ) gforth-1.0:             Debugging.         (line 16145)
* +thru ( I*X N1 N2 -- J*X ) gforth-0.2: Blocks.            (line 12184)
* +TO ( VALUE ... "NAME" -- ) gforth-1.0: Values.           (line  7445)
* +x/string ( XC-ADDR1 U1 -- XC-ADDR2 U2 ) xchar-ext: Xchars and Unicode.
                                                            (line 13070)
* < ( N1 N2 -- F ) core:                 Numeric comparison.
                                                            (line  4472)
* <{: ( COMPILATION -- COLON-SYS ; RUN-TIME -- ) gforth-obsolete: How do I write outer locals?.
                                                            (line 15522)
* <# ( -- ) core:                        Formatted numeric output.
                                                            (line 12310)
* << ( RUN-ADDR ADDR U -- RUN-ADDR ) regexp-replace: Regular Expressions.
                                                            (line 15699)
* <<" ( "STRING<">" -- ) regexp-replace: Regular Expressions.
                                                            (line 15702)
* <<# ( -- ) gforth-0.5:                 Formatted numeric output.
                                                            (line 12313)
* <= ( N1 N2 -- F ) gforth-0.2:          Numeric comparison.
                                                            (line  4474)
* <> ( N1 N2 -- F ) core-ext:            Numeric comparison.
                                                            (line  4476)
* <bind> ( CLASS SELECTOR-XT -- XT ) objects: Objects Glossary.
                                                            (line 14485)
* <to-inst> ( W XT -- ) objects:         Objects Glossary.  (line 14624)
* = ( N1 N2 -- F ) core:                 Numeric comparison.
                                                            (line  4478)
* =" ( <STRING>" -- ) regexp-pattern:    Regular Expressions.
                                                            (line 15631)
* =mkdir ( C-ADDR U WMODE -- WIOR ) gforth-0.7: Directories.
                                                            (line 11885)
* > ( N1 N2 -- F ) core:                 Numeric comparison.
                                                            (line  4480)
* >= ( N1 N2 -- F ) gforth-0.2:          Numeric comparison.
                                                            (line  4482)
* >> ( ADDR -- ADDR ) regexp-replace:    Regular Expressions.
                                                            (line 15695)
* >addr ( ... XT -- ADDR ) gforth-internal: Closures.       (line 15334)
* >animate ( RDELTA ADDR XT -- ) minos2: widget methods.    (line 20930)
* >back ( X STACK -- ) gforth-experimental: User-defined Stacks.
                                                            (line  9147)
* >body ( XT -- A-ADDR ) core:           CREATE..DOES> details.
                                                            (line  7943)
* >code-address ( XT -- C_ADDR ) gforth-0.2: Threading Words.
                                                            (line 18177)
* >definer ( XT -- DEFINER ) gforth-0.2: Threading Words.   (line 18238)
* >does-code ( XT1 -- XT2 ) gforth-0.2:  Threading Words.   (line 18220)
* >float ( C-ADDR U -- F:... FLAG ) floating: Line input and conversion.
                                                            (line 12923)
* >float1 ( C-ADDR U C -- F:... FLAG ) gforth-1.0: Line input and conversion.
                                                            (line 12931)
* >in ( -- ADDR ) core:                  The Text Interpreter.
                                                            (line 10234)
* >l ( W -- ) gforth-0.2:                Locals implementation.
                                                            (line 13766)
* >name ( XT -- NT|0 ) gforth-0.2:       Name token.        (line  9668)
* >number ( UD1 C-ADDR1 U1 -- UD2 C-ADDR2 U2 ) core: Line input and conversion.
                                                            (line 12910)
* >o ( C-ADDR -- R:C-OLD ) new:          Mini-OOF2.         (line 15077)
* >order ( WID -- ) gforth-0.5:          Word Lists.        (line 11199)
* >pow2 ( U1 -- U2 ) gforth-1.0:         Bitwise operations.
                                                            (line  4417)
* >r ( W -- R:W ) core:                  Return stack.      (line  4876)
* >stack ( X STACK -- ) gforth-experimental: User-defined Stacks.
                                                            (line  9144)
* >string-execute ( ... XT -- ... C-ADDR U ) gforth-1.0: String words.
                                                            (line  6054)
* >time&date&tz ( UDTIME -- NSEC NMIN NHOUR NDAY NMONTH NYEAR FDST NDSTOFF C-ADDRTZ UTZ ) gforth-1.0: Keeping track of Time.
                                                            (line 18295)
* >uvalue ( XT -- ADDR ) gforth-internal: Words with user-defined TO etc..
                                                            (line  8200)
* | ( -- ) local-ext:                    Locals definition words.
                                                            (line 13426)
* || ( ADDR ADDR -- ADDR ADDR ) regexp-pattern: Regular Expressions.
                                                            (line 15672)
* ~~ ( -- ) gforth-0.2:                  Debugging.         (line 16099)
* ~~1bt ( -- ) gforth-1.0:               Debugging.         (line 16124)
* ~~bt ( -- ) gforth-1.0:                Debugging.         (line 16121)
* ~~Value ( N "NAME" -- ) gforth-1.0:    Debugging.         (line 16142)
* ~~Variable ( "NAME" -- ) gforth-1.0:   Debugging.         (line 16139)
* $! ( ADDR1 U $ADDR -- ) gforth-0.7:    $tring words.      (line  6094)
* $!len ( U $ADDR -- ) gforth-0.7:       $tring words.      (line  6104)
* $? ( -- N ) gforth-0.2:                Passing Commands to the OS.
                                                            (line 18274)
* $. ( $ADDR -- ) gforth-1.0:            $tring words.      (line  6143)
* $[] ( U $[]ADDR -- ADDR' ) gforth-1.0: $tring words.      (line  6161)
* $[]! ( C-ADDR U N $[]ADDR -- ) gforth-1.0: $tring words.  (line  6165)
* $[]. ( $[]ADDR -- ) gforth-1.0:        $tring words.      (line  6194)
* $[]@ ( N $[]ADDR -- ADDR U ) gforth-1.0: $tring words.    (line  6177)
* $[]# ( $[]ADDR -- LEN ) gforth-1.0:    $tring words.      (line  6181)
* $[]+! ( C-ADDR U N $[]ADDR -- ) gforth-1.0: $tring words. (line  6169)
* $[]free ( $[]ADDR -- ) gforth-1.0:     $tring words.      (line  6197)
* $[]map ( $[]ADDR XT -- ) gforth-1.0:   $tring words.      (line  6184)
* $[]slurp ( FID $[]ADDR -- ) gforth-1.0: $tring words.     (line  6188)
* $[]slurp-file ( ADDR U $[]ADDR -- ) gforth-1.0: $tring words.
                                                            (line  6191)
* $[]Variable ( "NAME" -- ) gforth-1.0:  $tring words.      (line  6206)
* $@ ( $ADDR -- ADDR2 U ) gforth-0.7:    $tring words.      (line  6098)
* $@len ( $ADDR -- U ) gforth-0.7:       $tring words.      (line  6101)
* $+! ( ADDR1 U $ADDR -- ) gforth-0.7:   $tring words.      (line  6118)
* $+!len ( U $ADDR -- ADDR ) gforth-1.0: $tring words.      (line  6108)
* $+[]! ( C-ADDR U $[]ADDR -- ) gforth-1.0: $tring words.   (line  6173)
* $+slurp ( FID $ADDR -- ) gforth-1.0:   $tring words.      (line  6153)
* $+slurp-file ( C-ADDR U $ADDR -- ) gforth-1.0: $tring words.
                                                            (line  6157)
* $del ( $ADDR OFF U -- ) gforth-0.7:    $tring words.      (line  6112)
* $exec ( XT $ADDR -- ) gforth-1.0:      $tring words.      (line  6139)
* $free ( $ADDR -- ) gforth-1.0:         $tring words.      (line  6124)
* $init ( $ADDR -- ) gforth-1.0:         $tring words.      (line  6127)
* $ins ( ADDR1 U $ADDR OFF -- ) gforth-0.7: $tring words.   (line  6115)
* $iter ( .. $ADDR CHAR XT -- .. ) gforth-0.7: $tring words.
                                                            (line  6130)
* $over ( ADDR U $ADDR OFF -- ) gforth-1.0: $tring words.   (line  6135)
* $slurp ( FID $ADDR -- ) gforth-1.0:    $tring words.      (line  6146)
* $slurp-file ( C-ADDR U $ADDR -- ) gforth-1.0: $tring words.
                                                            (line  6150)
* $split ( C-ADDR U CHAR -- C-ADDR U1 C-ADDR2 U2 ) gforth-0.7: String words.
                                                            (line  5986)
* $substitute ( ADDR1 LEN1 -- ADDR2 LEN2 N/IOR ) gforth-experimental: Substitute.
                                                            (line 13197)
* $tmp ( XT -- ADDR U ) gforth-1.0:      String words.      (line  6060)
* $unescape ( ADDR1 U1 -- ADDR2 U2 ) gforth-experimental: Substitute.
                                                            (line 13212)
* $value: ( U1 "NAME" -- U2 ) gforth-experimental: Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8885)
* $value[]: ( U1 "NAME" -- U2 ) gforth-experimental: Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8926)
* $Variable ( "NAME" -- ) gforth-1.0:    $tring words.      (line  6202)
* 0< ( N -- F ) core:                    Numeric comparison.
                                                            (line  4484)
* 0<= ( N -- F ) gforth-0.2:             Numeric comparison.
                                                            (line  4486)
* 0<> ( N -- F ) core-ext:               Numeric comparison.
                                                            (line  4488)
* 0= ( N -- F ) core:                    Numeric comparison.
                                                            (line  4490)
* 0> ( N -- F ) core-ext:                Numeric comparison.
                                                            (line  4492)
* 0>= ( N -- F ) gforth-0.2:             Numeric comparison.
                                                            (line  4494)
* 1- ( N1 -- N2 ) core:                  Single precision.  (line  4022)
* 1/f ( R1 -- R2 ) gforth-0.2:           Floating Point.    (line  4634)
* 1+ ( N1 -- N2 ) core:                  Single precision.  (line  4015)
* 2, ( W1 W2 -- ) gforth-0.2:            Dictionary allocation.
                                                            (line  5065)
* 2! ( W1 W2 A-ADDR -- ) core:           Memory Access.     (line  5381)
* 2@ ( A-ADDR -- W1 W2 ) core:           Memory Access.     (line  5377)
* 2* ( N1 -- N2 ) core:                  Bitwise operations.
                                                            (line  4402)
* 2/ ( N1 -- N2 ) core:                  Bitwise operations.
                                                            (line  4405)
* 2>r ( W1 W2 -- R:W1 R:W2 ) core-ext:   Return stack.      (line  4891)
* 2Constant ( W1 W2 "NAME" -- ) double:  Constants.         (line  7385)
* 2drop ( W1 W2 -- ) core:               Data stack.        (line  4804)
* 2dup ( W1 W2 -- W1 W2 W1 W2 ) core:    Data stack.        (line  4808)
* 2field: ( U1 "NAME" -- U2 ) gforth-0.7: Standard Structures.
                                                            (line  8733)
* 2Literal ( COMPILATION W1 W2 -- ; RUN-TIME -- W1 W2 ) double: Literals.
                                                            (line  9874)
* 2nip ( W1 W2 W3 W4 -- W3 W4 ) gforth-0.2: Data stack.     (line  4806)
* 2over ( W1 W2 W3 W4 -- W1 W2 W3 W4 W1 W2 ) core: Data stack.
                                                            (line  4810)
* 2r@ ( R:W1 R:W2 -- R:W1 R:W2 W1 W2 ) core-ext: Return stack.
                                                            (line  4895)
* 2r> ( R:W1 R:W2 -- W1 W2 ) core-ext:   Return stack.      (line  4893)
* 2rdrop ( R:W1 R:W2 -- ) gforth-0.2:    Return stack.      (line  4897)
* 2rot ( W1 W2 W3 W4 W5 W6 -- W3 W4 W5 W6 W1 W2 ) double-ext: Data stack.
                                                            (line  4814)
* 2swap ( W1 W2 W3 W4 -- W3 W4 W1 W2 ) core: Data stack.    (line  4812)
* 2tuck ( W1 W2 W3 W4 -- W3 W4 W1 W2 W3 W4 ) gforth-0.2: Data stack.
                                                            (line  4816)
* 2Value ( W1 W2 "NAME" -- ) double-ext: Values.            (line  7425)
* 2value: ( U1 "NAME" -- U2 ) gforth-experimental: Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8865)
* 2Variable ( "NAME" -- ) double:        Variables.         (line  7341)
* A, ( ADDR -- ) gforth-0.2:             Dictionary allocation.
                                                            (line  5085)
* abi-code ( "NAME" -- COLON-SYS ) gforth-1.0: Assembler Definitions.
                                                            (line 17208)
* abort ( ?? -- ?? ) core,exception-ext: Exception Handling.
                                                            (line  7227)
* ABORT" ( COMPILATION 'CCC"' -- ; RUN-TIME ... F -- ) core,exception-ext: Exception Handling.
                                                            (line  7222)
* abs ( N -- U ) core:                   Single precision.  (line  4028)
* absolute-file? ( ADDR U -- FLAG ) gforth-1.0: Search Paths.
                                                            (line 11920)
* accept ( C-ADDR +N1 -- +N2 ) core:     Line input and conversion.
                                                            (line 12891)
* AConstant ( ADDR "NAME" -- ) gforth-0.2: Constants.       (line  7381)
* act ( -- OPTR ) minos2:                widget methods.    (line 20819)
* act-name$ ( -- ADDR U ) minos2:        actor methods.     (line 20762)
* action-of ( INTERPRETATION "NAME" ... -- XT; COMPILATION "NAME" -- ; RUN-TIME ... -- XT ) core-ext: Deferred Words.
                                                            (line  8491)
* activate ( RUN-TIME NEST-SYS1 TASK -- ) gforth-experimental: Basic multi-tasking.
                                                            (line 16435)
* active-w ( -- OPTR ) minos2:           actor methods.     (line 20759)
* actor ( -- CLASS ) minos2:             MINOS2 object framework.
                                                            (line 20747)
* add-cflags ( C-ADDR U -- ) gforth-1.0: Declaring OS-level libraries.
                                                            (line 17021)
* add-framework ( C-ADDR U -- ) gforth-1.0: Declaring OS-level libraries.
                                                            (line 17014)
* add-incdir ( C-ADDR U -- ) gforth-1.0: Declaring OS-level libraries.
                                                            (line 17018)
* add-ldflags ( C-ADDR U -- ) gforth-1.0: Declaring OS-level libraries.
                                                            (line 17024)
* add-lib ( C-ADDR U -- ) gforth-0.7:    Declaring OS-level libraries.
                                                            (line 17006)
* add-libpath ( C-ADDR U -- ) gforth-0.7: Declaring OS-level libraries.
                                                            (line 17010)
* addr ( INTERPRETATION "NAME" ... -- ADDR; COMPILATION "NAME" -- ; RUN-TIME ... -- ADDR ) gforth-1.0: Values.
                                                            (line  7477)
* ADDRESS-UNIT-BITS ( -- N ) environment: Environmental Queries.
                                                            (line 11417)
* addressable: ( -- ) gforth-experimental: Values.          (line  7472)
* adjust-buffer ( U ADDR -- ) gforth-experimental: Growable memory buffers.
                                                            (line  5336)
* after-locate ( -- U ) gforth-1.0:      Locating source code definitions.
                                                            (line 15780)
* AGAIN ( COMPILATION DEST -- ; RUN-TIME -- ) core-ext: Arbitrary control structures.
                                                            (line  6837)
* AHEAD ( COMPILATION -- ORIG ; RUN-TIME -- ) tools-ext: Arbitrary control structures.
                                                            (line  6820)
* Alias ( XT "NAME" -- ) gforth-0.2:     Synonyms.          (line  8631)
* align ( -- ) core:                     Dictionary allocation.
                                                            (line  5109)
* aligned ( C-ADDR -- A-ADDR ) core:     Address arithmetic.
                                                            (line  5592)
* ALiteral ( COMPILATION ADDR -- ; RUN-TIME -- ADDR ) gforth-0.2: Literals.
                                                            (line  9864)
* allocate ( U -- A_ADDR WIOR ) memory:  Heap Allocation.   (line  5269)
* allot ( N -- ) core:                   Dictionary allocation.
                                                            (line  5045)
* also ( -- ) search-ext:                Word Lists.        (line 11205)
* also-path ( C-ADDR LEN PATH-ADDR -- ) gforth-0.4: General Search Paths.
                                                            (line 11972)
* and ( W1 W2 -- W ) core:               Bitwise operations.
                                                            (line  4367)
* annotate-cov ( -- ) gforth-experimental: Code Coverage.   (line 16332)
* append ( C-ADDR1 U1 C-ADDR2 U2 -- C-ADDR U ) gforth-0.7: String words.
                                                            (line  6049)
* arg ( U -- ADDR COUNT ) gforth-0.2:    OS command line arguments.
                                                            (line 13280)
* argc ( -- ADDR ) gforth-0.2:           OS command line arguments.
                                                            (line 13294)
* argv ( -- ADDR ) gforth-0.2:           OS command line arguments.
                                                            (line 13298)
* array>mem ( UELEMENTS UELEMSIZE -- UBYTES UELEMSIZE ) gforth-experimental: Counted Loops.
                                                            (line  6563)
* arshift ( N1 U -- N2 ) gforth-1.0:     Bitwise operations.
                                                            (line  4387)
* asptr ( CLASS -- ) oof:                Class Declaration. (line 14832)
* assembler ( -- ) tools-ext:            Assembler Definitions.
                                                            (line 17201)
* assert-level ( -- A-ADDR ) gforth-0.2: Assertions.        (line 16213)
* assert( ( -- ) gforth-0.2:             Assertions.        (line 16194)
* assert0( ( -- ) gforth-0.2:            Assertions.        (line 16181)
* assert1( ( -- ) gforth-0.2:            Assertions.        (line 16184)
* assert2( ( -- ) gforth-0.2:            Assertions.        (line 16187)
* assert3( ( -- ) gforth-0.2:            Assertions.        (line 16190)
* ASSUME-LIVE ( ORIG -- ORIG ) gforth-0.2: Where are locals visible by name?.
                                                            (line 13620)
* at-deltaxy ( DX DY -- ) gforth-0.7:    Terminal output.   (line 12619)
* at-xy ( X Y -- ) facility:             Terminal output.   (line 12615)
* atomic!@ ( W1 A-ADDR -- W2 ) gforth-experimental: Hardware operations for multi-tasking.
                                                            (line 16595)
* atomic?!@ ( UNEW UOLD A-ADDR -- UPREV ) gforth-experimental: Hardware operations for multi-tasking.
                                                            (line 16603)
* atomic+!@ ( U1 A-ADDR -- U2 ) gforth-experimental: Hardware operations for multi-tasking.
                                                            (line 16599)
* AUser ( "NAME" -- ) gforth-0.2:        Task-local data.   (line 16521)
* authors ( -- ) gforth-1.0:             Help on Gforth.    (line   885)
* AValue ( W "NAME" -- ) gforth-0.6:     Values.            (line  7421)
* AVariable ( "NAME" -- ) gforth-0.2:    Variables.         (line  7337)
* b ( -- ) gforth-1.0:                   Locating source code definitions.
                                                            (line 15766)
* back> ( STACK -- X ) gforth-experimental: User-defined Stacks.
                                                            (line  9150)
* barrier ( -- ) gforth-experimental:    Hardware operations for multi-tasking.
                                                            (line 16615)
* base ( -- A-ADDR ) core:               Number Conversion. (line 10330)
* base-execute ( I*X XT U -- J*X ) gforth-0.7: Number Conversion.
                                                            (line 10326)
* baseline ( -- R ) minos2:              widget methods.    (line 20843)
* basename ( C-ADDR1 U1 -- C-ADDR2 U2 ) gforth-0.7: Directories.
                                                            (line 11842)
* before-line ( -- ) gforth-1.0:         Text Interpreter Hooks.
                                                            (line 11024)
* before-locate ( -- U ) gforth-1.0:     Locating source code definitions.
                                                            (line 15777)
* before-word ( -- ) gforth-0.7:         Text Interpreter Hooks.
                                                            (line 11027)
* BEGIN ( COMPILATION -- DEST ; RUN-TIME -- ) core: Arbitrary control structures.
                                                            (line  6828)
* begin-structure ( "NAME" -- STRUCT-SYS 0 ) facility-ext: Standard Structures.
                                                            (line  8722)
* bin ( FAM1 -- FAM2 ) file:             General files.     (line 11708)
* bind ( ... "CLASS" "SELECTOR" -- ... ) objects: Objects Glossary.
                                                            (line 14482)
* bind' ( "CLASS" "SELECTOR" -- XT ) objects: Objects Glossary.
                                                            (line 14488)
* bl ( -- C-CHAR ) core:                 String and character literals.
                                                            (line  5916)
* blank ( C-ADDR U -- ) string:          Memory Blocks.     (line  5730)
* blk ( -- ADDR ) block:                 Input Sources.     (line 10285)
* block ( U -- A-ADDR ) block:           Blocks.            (line 12136)
* block-included ( A-ADDR U -- ) gforth-0.2: Blocks.        (line 12195)
* block-offset ( -- ADDR ) gforth-0.5:   Blocks.            (line 12115)
* block-position ( U -- ) block:         Blocks.            (line 12125)
* bootmessage ( -- ) gforth-0.4:         Modifying the Startup Sequence.
                                                            (line 20078)
* border ( -- R ) minos2:                widget methods.    (line 20852)
* borderl ( -- R ) minos2:               widget methods.    (line 20861)
* bordert ( -- R ) minos2:               widget methods.    (line 20858)
* borderv ( -- R ) minos2:               widget methods.    (line 20855)
* bounds ( U1 U2 -- U3 U1 ) gforth-0.2:  Counted Loops.     (line  6542)
* break: ( -- ) gforth-0.4:              Singlestep Debugger.
                                                            (line 16292)
* break" ( 'CCC"' -- ) gforth-0.4:       Singlestep Debugger.
                                                            (line 16294)
* broken-pipe-error ( -- N ) gforth-0.6: Pipes.             (line 12980)
* browse ( "SUBNAME" -- ) gforth-1.0:    Locating source code definitions.
                                                            (line 15791)
* bt ( -- ) gforth-1.0:                  Locating exception source.
                                                            (line 15858)
* buffer ( U -- A-ADDR ) block:          Blocks.            (line 12143)
* buffer: ( U "NAME" -- ) core-ext:      Variables.         (line  7351)
* buffer% ( U1 U2 -- ) gforth-experimental: Growable memory buffers.
                                                            (line  5331)
* bw ( -- ) gforth-1.0:                  Locating uses of a word.
                                                            (line 15814)
* bw-cover ( -- ) gforth-1.0:            Code Coverage.     (line 16349)
* bye ( -- ) tools-ext:                  Leaving Gforth.    (line   868)
* c-callback ( "FORTH-NAME" "{TYPE}" "---" "TYPE" -- ) gforth-1.0: Callbacks.
                                                            (line 17040)
* c-callback-thread ( "FORTH-NAME" "{TYPE}" "---" "TYPE" -- ) gforth-1.0: Callbacks.
                                                            (line 17045)
* c-function ( "FORTH-NAME" "C-NAME" "{TYPE}" "---" "TYPE" -- ) gforth-0.7: Declaring C Functions.
                                                            (line 16865)
* c-funptr ( "FORTH-NAME" <{>"C-TYPECAST"<}> "{TYPE}" "---" "TYPE" -- ) gforth-1.0: Calling C function pointers.
                                                            (line 16892)
* c-library ( "NAME" -- ) gforth-0.7:    Defining library interfaces.
                                                            (line 16967)
* c-library-name ( C-ADDR U -- ) gforth-0.7: Defining library interfaces.
                                                            (line 16961)
* c-value ( "FORTH-NAME" "C-NAME" "---" "TYPE" -- ) gforth-1.0: Declaring C Functions.
                                                            (line 16869)
* c-variable ( "FORTH-NAME" "C-NAME" -- ) gforth-1.0: Declaring C Functions.
                                                            (line 16873)
* c, ( C -- ) core:                      Dictionary allocation.
                                                            (line  5055)
* C: ( COMPILATION "NAME" -- A-ADDR XT; RUN-TIME C -- ) gforth-0.2: Locals definition words.
                                                            (line 13458)
* c! ( C C-ADDR -- ) core:               Memory Access.     (line  5374)
* c? ( ADDR CLASS -- ) regexp-pattern:   Regular Expressions.
                                                            (line 15590)
* C" ( COMPILATION "CCC<QUOTE>" -- ; RUN-TIME -- C-ADDR ) core-ext: Counted string words.
                                                            (line  6228)
* c@ ( C-ADDR -- C ) core:               Memory Access.     (line  5371)
* C^ ( COMPILATION "NAME" -- A-ADDR XT; RUN-TIME C -- ) gforth-0.2: Locals definition words.
                                                            (line 13461)
* c++-library ( "NAME" -- ) gforth-1.0:  Defining library interfaces.
                                                            (line 16970)
* c++-library-name ( C-ADDR U -- ) gforth-1.0: Defining library interfaces.
                                                            (line 16964)
* c>s ( X -- N ) gforth-1.0:             Special Memory Accesses.
                                                            (line  5504)
* c$+! ( CHAR $ADDR -- ) gforth-1.0:     $tring words.      (line  6121)
* call-c ( ... W -- ... ) gforth-0.2:    Low-Level C Interface Words.
                                                            (line 17095)
* caller-w ( -- OPTR ) minos2:           actor methods.     (line 20756)
* capscompare ( C-ADDR1 U1 C-ADDR2 U2 -- N ) gforth-0.7: String words.
                                                            (line  6028)
* capssearch ( C-ADDR1 U1 C-ADDR2 U2 -- C-ADDR3 U3 FLAG ) gforth-1.0: String words.
                                                            (line  6039)
* capsstring-prefix? ( C-ADDR1 U1 C-ADDR2 U2 -- F ) gforth-1.0: String words.
                                                            (line  6035)
* case ( COMPILATION -- CASE-SYS ; RUN-TIME -- ) core-ext: General control structures with CASE.
                                                            (line  6765)
* catch ( X1 .. XN XT -- Y1 .. YM 0 / Z1 .. ZN ERROR ) exception: Exception Handling.
                                                            (line  7057)
* catch-nobt ( X1 .. XN XT -- Y1 .. YM 0 / Z1 .. ZN ERROR ) gforth-experimental: Exception Handling.
                                                            (line  7063)
* cell ( -- U ) gforth-0.2:              Address arithmetic.
                                                            (line  5589)
* cell- ( A-ADDR1 -- A-ADDR2 ) core:     Address arithmetic.
                                                            (line  5582)
* cell/ ( N1 -- N2 ) gforth-1.0:         Address arithmetic.
                                                            (line  5585)
* cell% ( -- ALIGN SIZE ) gforth-0.4:    Gforth structs.    (line  9088)
* cell+ ( A-ADDR1 -- A-ADDR2 ) core:     Address arithmetic.
                                                            (line  5579)
* cells ( N1 -- N2 ) core:               Address arithmetic.
                                                            (line  5576)
* cfield: ( U1 "NAME" -- U2 ) facility-ext: Standard Structures.
                                                            (line  8727)
* char ( '<SPACES>CCC' -- C ) core,xchar-ext: String and character literals.
                                                            (line  5885)
* char- ( C-ADDR1 -- C-ADDR2 ) gforth-0.7: Address arithmetic.
                                                            (line  5573)
* char% ( -- ALIGN SIZE ) gforth-0.4:    Gforth structs.    (line  9090)
* char+ ( C-ADDR1 -- C-ADDR2 ) core:     Address arithmetic.
                                                            (line  5570)
* charclass ( -- ) regexp-cg:            Regular Expressions.
                                                            (line 15565)
* chars ( N1 -- N2 ) core:               Address arithmetic.
                                                            (line  5567)
* cilk-bye ( -- ) cilk:                  Cilk.              (line 16710)
* cilk-init ( -- ) cilk:                 Cilk.              (line 16692)
* cilk-sync ( -- ) cilk:                 Cilk.              (line 16707)
* class ( CLASS -- CLASS METHODS VARS ) mini-oof2: Basic Mini-OOF Usage.
                                                            (line 14888)
* class ( PARENT-CLASS -- ALIGN OFFSET ) objects: Objects Glossary.
                                                            (line 14494)
* class->map ( CLASS -- MAP ) objects:   Objects Glossary.  (line 14498)
* class-inst-size ( CLASS -- ADDR ) objects: Objects Glossary.
                                                            (line 14503)
* class-override! ( XT SEL-XT CLASS-MAP -- ) objects: Objects Glossary.
                                                            (line 14507)
* class-previous ( CLASS -- ) objects:   Objects Glossary.  (line 14510)
* class; ( -- ) oof:                     Class Declaration. (line 14858)
* class>order ( CLASS -- ) objects:      Objects Glossary.  (line 14514)
* clear-libs ( -- ) gforth-0.7:          Declaring OS-level libraries.
                                                            (line 17003)
* clear-path ( PATH-ADDR -- ) gforth-0.5: General Search Paths.
                                                            (line 11969)
* clearstack ( ... -- ) gforth-0.2:      Examining data.    (line 16019)
* clearstacks ( ... -- ) gforth-0.7:     Examining data.    (line 16025)
* clicked ( RX RY BMASK N -- ) minos2:   actor methods.     (line 20765)
* close-dir ( WDIRID -- WIOR ) gforth-0.5: Directories.     (line 11869)
* close-file ( WFILEID -- WIOR ) file:   General files.     (line 11722)
* close-pipe ( WFILEID -- WRETVAL WIOR ) gforth-0.2: Pipes. (line 12970)
* cmove ( C-FROM C-TO U -- ) string:     Memory Blocks.     (line  5714)
* cmove> ( C-FROM C-TO U -- ) string:    Memory Blocks.     (line  5719)
* code ( "NAME" -- COLON-SYS ) tools-ext: Assembler Definitions.
                                                            (line 17232)
* code-address! ( C_ADDR XT -- ) gforth-obsolete: Threading Words.
                                                            (line 18180)
* color-cover ( -- ) gforth-1.0:         Code Coverage.     (line 16352)
* color: ( RGBA "NAME" -- ) minos2:      widget methods.    (line 20938)
* common-list ( LIST1 LIST2 -- LIST3 ) gforth-internal: Locals implementation.
                                                            (line 13840)
* COMP' ( "NAME" -- W XT ) gforth-0.2:   Compilation token. (line  9784)
* compare ( C-ADDR1 U1 C-ADDR2 U2 -- N ) string: String words.
                                                            (line  5948)
* compile-color ( -- ) gforth-1.0:       Terminal output.   (line 12669)
* compile-only ( -- ) gforth-0.2:        How to define immediate words.
                                                            (line  9361)
* compile-only? ( NT -- FLAG ) gforth-1.0: Name token.      (line  9706)
* compile, ( XT -- ) core-ext:           Macros.            (line 10093)
* compiling ( ... TRANSLATOR -- ... ) gforth-experimental: Performing translator actions.
                                                            (line 10978)
* compsem: ( -- ) gforth-experimental:   How to define combined words.
                                                            (line  9523)
* const-does> ( RUN-TIME: W*UW R*UR UW UR "NAME" -- ) gforth-obsolete: Const-does>.
                                                            (line  8393)
* Constant ( W "NAME" -- ) core:         Constants.         (line  7377)
* construct ( ... OBJECT -- ) objects:   Objects Glossary.  (line 14517)
* context ( -- ADDR ) gforth-0.2:        Word Lists.        (line 11289)
* contof ( COMPILATION CASE-SYS1 OF-SYS -- CASE-SYS2 ; RUN-TIME -- ) gforth-1.0: General control structures with CASE.
                                                            (line  6789)
* convert ( UD1 C-ADDR1 -- UD2 C-ADDR2 ) core-ext-obsolescent: Line input and conversion.
                                                            (line 12941)
* CORE ( -- F ) environment:             Environmental Queries.
                                                            (line 11432)
* CORE-EXT ( -- F ) environment:         Environmental Queries.
                                                            (line 11436)
* cores ( -- U ) cilk:                   Cilk.              (line 16686)
* count ( C-ADDR1 -- C-ADDR2 U ) core:   Counted string words.
                                                            (line  6220)
* Country ( <LANG> "NAME" -- ) gforth-experimental: i18n and l10n.
                                                            (line 13142)
* cov% ( -- ) gforth-experimental:       Code Coverage.     (line 16338)
* cov+ ( -- ) gforth-experimental:       Code Coverage.     (line 16319)
* cover-filename ( -- C-ADDR U ) gforth-experimental: Code Coverage.
                                                            (line 16365)
* coverage? ( -- F ) gforth-internal:    Code Coverage.     (line 16316)
* cputime ( -- DUSER DSYSTEM ) gforth-0.5: Keeping track of Time.
                                                            (line 18307)
* cr ( -- ) core:                        Miscellaneous output.
                                                            (line 12523)
* Create ( "NAME" -- ) core:             CREATE.            (line  7271)
* create-file ( C-ADDR U WFAM -- WFILEID WIOR ) file: General files.
                                                            (line 11720)
* create-from ( NT "NAME" -- ) gforth-1.0: Creating from a prototype.
                                                            (line  8332)
* critical-section ( XT SEMAPHORE -- ) gforth-experimental: Semaphores.
                                                            (line 16581)
* CS-DROP ( DEST/ORIG -- ) gforth-1.0:   Arbitrary control structures.
                                                            (line  6845)
* CS-PICK ( DEST0/ORIG0 DEST1/ORIG1 ... DESTU/ORIGU U -- ... DEST0/ORIG0 ) tools-ext: Arbitrary control structures.
                                                            (line  6841)
* CS-ROLL ( DESTU/ORIGU .. DEST0/ORIG0 U -- .. DEST0/ORIG0 DESTU/ORIGU ) tools-ext: Arbitrary control structures.
                                                            (line  6843)
* cs-vocabulary ( "NAME" -- ) gforth-1.0: Word Lists.       (line 11196)
* cs-wordlist ( -- WID ) gforth-1.0:     Word Lists.        (line 11193)
* cstring>sstring ( C-ADDR -- C-ADDR U ) gforth-0.2: String words.
                                                            (line  6020)
* csv-quote ( -- C ) gforth-experimental: CSV reading and writing.
                                                            (line 13234)
* csv-separator ( -- C ) gforth-experimental: CSV reading and writing.
                                                            (line 13229)
* ctz ( X -- U ) gforth-1.0:             Bitwise operations.
                                                            (line  4428)
* current ( -- ADDR ) gforth-0.2:        Word Lists.        (line 11286)
* current-interface ( -- ADDR ) objects: Objects Glossary.  (line 14527)
* current' ( "SELECTOR" -- XT ) objects: Objects Glossary.  (line 14521)
* cvalue: ( U1 "NAME" -- U2 ) gforth-experimental: Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8841)
* d ( -- R ) minos2:                     widget methods.    (line 20837)
* d- ( D1 D2 -- D ) double:              Double precision.  (line  4065)
* D: ( COMPILATION "NAME" -- A-ADDR XT; RUN-TIME X1 X2 -- ) gforth-0.2: Locals definition words.
                                                            (line 13452)
* d. ( D -- ) double:                    Simple numeric output.
                                                            (line 12254)
* d.r ( D N -- ) double:                 Simple numeric output.
                                                            (line 12262)
* D^ ( COMPILATION "NAME" -- A-ADDR XT; RUN-TIME X1 X2 -- ) gforth-0.2: Locals definition words.
                                                            (line 13455)
* d+ ( UD1 UD2 -- UD ) double:           Double precision.  (line  4063)
* d< ( D1 D2 -- F ) double:              Numeric comparison.
                                                            (line  4513)
* d<= ( D1 D2 -- F ) gforth-0.2:         Numeric comparison.
                                                            (line  4515)
* d<> ( D1 D2 -- F ) gforth-0.2:         Numeric comparison.
                                                            (line  4517)
* d= ( D1 D2 -- F ) double:              Numeric comparison.
                                                            (line  4519)
* d> ( D1 D2 -- F ) gforth-0.2:          Numeric comparison.
                                                            (line  4521)
* d>= ( D1 D2 -- F ) gforth-0.2:         Numeric comparison.
                                                            (line  4523)
* d>f ( D -- R ) floating:               Floating Point.    (line  4568)
* d>s ( D -- N ) double:                 Double precision.  (line  4061)
* d0< ( D -- F ) double:                 Numeric comparison.
                                                            (line  4525)
* d0<= ( D -- F ) gforth-0.2:            Numeric comparison.
                                                            (line  4527)
* d0<> ( D -- F ) gforth-0.2:            Numeric comparison.
                                                            (line  4529)
* d0= ( D -- F ) double:                 Numeric comparison.
                                                            (line  4531)
* d0> ( D -- F ) gforth-0.2:             Numeric comparison.
                                                            (line  4533)
* d0>= ( D -- F ) gforth-0.2:            Numeric comparison.
                                                            (line  4535)
* d2* ( D1 -- D2 ) double:               Bitwise operations.
                                                            (line  4410)
* d2/ ( D1 -- D2 ) double:               Bitwise operations.
                                                            (line  4413)
* dabs ( D -- UD ) double:               Double precision.  (line  4069)
* dark-mode ( -- ) gforth-1.0:           Terminal output.   (line 12681)
* darshift ( D1 U -- D2 ) gforth-1.0:    Bitwise operations.
                                                            (line  4398)
* dbg ( "NAME" -- ) gforth-0.2:          Singlestep Debugger.
                                                            (line 16290)
* debug-fid ( -- FILE-ID ) gforth-1.0:   Debugging.         (line 16110)
* dec. ( N -- ) gforth-0.2:              Simple numeric output.
                                                            (line 12225)
* dec.r ( U N -- ) gforth-0.5:           Simple numeric output.
                                                            (line 12251)
* decimal ( -- ) core:                   Number Conversion. (line 10339)
* default-color ( -- ) gforth-1.0:       Terminal output.   (line 12642)
* default-input ( -- ) gforth-1.0:       Terminal output.   (line 12690)
* defer ( -- ) oof:                      Class Declaration. (line 14837)
* Defer ( "NAME" -- ) core-ext:          Deferred Words.    (line  8474)
* defer: ( U1 "NAME" -- U2 ) gforth-experimental: Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8947)
* defer! ( XT XT-DEFERRED -- ) core-ext: Deferred Words.    (line  8574)
* defer@ ( ... XT-DEFERRED -- XT ) core-ext: Deferred Words.
                                                            (line  8583)
* defers ( COMPILATION "NAME" -- ; RUN-TIME ... -- ... ) gforth-0.2: Deferred Words.
                                                            (line  8523)
* definer! ( DEFINER XT -- ) gforth-obsolete: Threading Words.
                                                            (line 18243)
* defines ( XT CLASS "NAME" -- ) mini-oof: Basic Mini-OOF Usage.
                                                            (line 14896)
* definitions ( -- ) search:             Word Lists.        (line 11153)
* defocus ( -- ) minos2:                 actor methods.     (line 20789)
* delete ( C-ADDR U U1 -- ) gforth-0.7:  String words.      (line  6015)
* delete-file ( C-ADDR U -- WIOR ) file: General files.     (line 11724)
* delta-i ( R:ULIMIT R:U -- R:ULIMIT R:U U2 ) gforth-1.0: Counted Loops.
                                                            (line  6609)
* depth ( -- +N ) core:                  Examining data.    (line 16011)
* df! ( R DF-ADDR -- ) floating-ext:     Memory Access.     (line  5402)
* df@ ( DF-ADDR -- R ) floating-ext:     Memory Access.     (line  5398)
* dfalign ( -- ) floating-ext:           Dictionary allocation.
                                                            (line  5121)
* dfaligned ( C-ADDR -- DF-ADDR ) floating-ext: Address arithmetic.
                                                            (line  5640)
* dffield: ( U1 "NAME" -- U2 ) floating-ext: Standard Structures.
                                                            (line  8742)
* dfloat/ ( N1 -- N2 ) gforth-1.0:       Address arithmetic.
                                                            (line  5636)
* dfloat% ( -- ALIGN SIZE ) gforth-0.4:  Gforth structs.    (line  9092)
* dfloat+ ( DF-ADDR1 -- DF-ADDR2 ) floating-ext: Address arithmetic.
                                                            (line  5633)
* dfloats ( N1 -- N2 ) floating-ext:     Address arithmetic.
                                                            (line  5629)
* dfvalue: ( U1 "NAME" -- U2 ) gforth-experimental: Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8877)
* dglue ( -- RTYP RSUB RADD ) minos2:    widget methods.    (line 20882)
* dglue@ ( -- RTYP RSUB RADD ) minos2:   widget methods.    (line 20891)
* dict-new ( ... CLASS -- OBJECT ) objects: Objects Glossary.
                                                            (line 14530)
* dirname ( C-ADDR1 U1 -- C-ADDR1 U2 ) gforth-0.7: Directories.
                                                            (line 11846)
* discode ( ADDR U -- ) gforth-0.2:      Common Disassembler.
                                                            (line 17377)
* dispose-widget ( -- ) minos2:          widget methods.    (line 20909)
* dlshift ( UD1 U -- UD2 ) gforth-1.0:   Bitwise operations.
                                                            (line  4391)
* dmax ( D1 D2 -- D ) double:            Double precision.  (line  4073)
* dmin ( D1 D2 -- D ) double:            Double precision.  (line  4071)
* dnegate ( D1 -- D2 ) double:           Double precision.  (line  4067)
* DO ( COMPILATION -- DO-SYS ; RUN-TIME W1 W2 -- LOOP-SYS ) core: Counted Loops.
                                                            (line  6576)
* doabicode: ( -- ADDR ) gforth-1.0:     Threading Words.   (line 18210)
* docol: ( -- ADDR ) gforth-0.2:         Threading Words.   (line 18186)
* docon: ( -- ADDR ) gforth-0.2:         Threading Words.   (line 18189)
* dodefer: ( -- ADDR ) gforth-0.2:       Threading Words.   (line 18198)
* dodoes: ( -- ADDR ) gforth-0.6:        Threading Words.   (line 18207)
* does-code! ( XT2 XT1 -- ) gforth-0.2:  Threading Words.   (line 18230)
* DOES> ( COMPILATION COLON-SYS1 -- COLON-SYS2 ) core: CREATE..DOES> details.
                                                            (line  7870)
* dofield: ( -- ADDR ) gforth-0.2:       Threading Words.   (line 18201)
* DONE ( COMPILATION DO-SYS -- ; RUN-TIME -- ) gforth-0.2: Counted Loops.
                                                            (line  6620)
* double% ( -- ALIGN SIZE ) gforth-0.4:  Gforth structs.    (line  9094)
* douser: ( -- ADDR ) gforth-0.2:        Threading Words.   (line 18195)
* dovalue: ( -- ADDR ) gforth-0.7:       Threading Words.   (line 18204)
* dovar: ( -- ADDR ) gforth-0.2:         Threading Words.   (line 18192)
* dpl ( -- A-ADDR ) gforth-0.2:          Number Conversion. (line 10343)
* draw ( -- ) minos2:                    widget methods.    (line 20870)
* draw-init ( -- ) minos2:               widget methods.    (line 20867)
* drol ( UD1 U -- UD2 ) gforth-1.0:      Bitwise operations.
                                                            (line  4459)
* drop ( W -- ) core:                    Data stack.        (line  4775)
* dror ( UD1 U -- UD2 ) gforth-1.0:      Bitwise operations.
                                                            (line  4462)
* drshift ( UD1 U -- UD2 ) gforth-1.0:   Bitwise operations.
                                                            (line  4394)
* du/mod ( D U -- N U1 ) gforth-1.0:     Integer division.  (line  4173)
* du< ( UD1 UD2 -- F ) double-ext:       Numeric comparison.
                                                            (line  4537)
* du<= ( UD1 UD2 -- F ) gforth-0.2:      Numeric comparison.
                                                            (line  4539)
* du> ( UD1 UD2 -- F ) gforth-0.2:       Numeric comparison.
                                                            (line  4541)
* du>= ( UD1 UD2 -- F ) gforth-0.2:      Numeric comparison.
                                                            (line  4543)
* dump ( ADDR U -- ) tools:              Examining data.    (line 16033)
* dup ( W -- W W ) core:                 Data stack.        (line  4779)
* early ( -- ) oof:                      Class Declaration. (line 14842)
* edit ( "NAME" -- ) gforth-1.0:         Locating source code definitions.
                                                            (line 15786)
* edit-line ( C-ADDR N1 N2 -- N3 ) gforth-0.6: Line input and conversion.
                                                            (line 12898)
* ekey ( -- U ) facility-ext:            Single-key input.  (line 12740)
* ekey? ( -- FLAG ) facility-ext:        Single-key input.  (line 12755)
* ekey>char ( U -- U FALSE | C TRUE ) facility-ext: Single-key input.
                                                            (line 12746)
* ekey>fkey ( U1 -- U2 F ) facility-ext: Single-key input.  (line 12751)
* ekey>xchar ( U -- U FALSE | XC TRUE ) xchar-ext: Single-key input.
                                                            (line 12743)
* ekeyed ( EKEY -- ) minos2:             actor methods.     (line 20780)
* ELSE ( COMPILATION ORIG1 -- ORIG2 ; RUN-TIME -- ) core: Arbitrary control structures.
                                                            (line  6859)
* emit ( C -- ) core:                    Displaying characters and strings.
                                                            (line 12602)
* emit-file ( C WFILEID -- WIOR ) gforth-0.2: General files.
                                                            (line 11767)
* empty-buffer ( BUFFER -- ) gforth-0.2: Blocks.            (line 12156)
* empty-buffers ( -- ) block-ext:        Blocks.            (line 12152)
* end-c-library ( -- ) gforth-0.7:       Defining library interfaces.
                                                            (line 16973)
* end-class ( ALIGN OFFSET "NAME" -- ) objects: Objects Glossary.
                                                            (line 14533)
* end-class ( CLASS METHODS VARS "NAME" -- ) mini-oof2: Basic Mini-OOF Usage.
                                                            (line 14892)
* end-class-noname ( ALIGN OFFSET -- CLASS ) objects: Objects Glossary.
                                                            (line 14537)
* end-code ( COLON-SYS -- ) gforth-0.2:  Assembler Definitions.
                                                            (line 17227)
* end-interface ( "NAME" -- ) objects:   Objects Glossary.  (line 14540)
* end-interface-noname ( -- INTERFACE ) objects: Objects Glossary.
                                                            (line 14544)
* end-methods ( -- ) objects:            Objects Glossary.  (line 14547)
* end-struct ( ALIGN SIZE "NAME" -- ) gforth-0.2: Gforth structs.
                                                            (line  9096)
* end-structure ( STRUCT-SYS +N -- ) facility-ext: Standard Structures.
                                                            (line  8724)
* endcase ( COMPILATION CASE-SYS -- ; RUN-TIME X -- ) core-ext: General control structures with CASE.
                                                            (line  6768)
* ENDIF ( COMPILATION ORIG -- ; RUN-TIME -- ) gforth-0.2: Arbitrary control structures.
                                                            (line  6876)
* endof ( COMPILATION CASE-SYS1 OF-SYS -- CASE-SYS2 ; RUN-TIME -- ) core-ext: General control structures with CASE.
                                                            (line  6785)
* endscope ( COMPILATION SCOPE -- ; RUN-TIME -- ) gforth-0.2: Where are locals visible by name?.
                                                            (line 13491)
* endtry ( COMPILATION -- ; RUN-TIME R:SYS1 -- ) gforth-0.5: Exception Handling.
                                                            (line  7109)
* endtry-iferror ( COMPILATION ORIG1 -- ORIG2 ; RUN-TIME R:SYS1 -- ) gforth-0.7: Exception Handling.
                                                            (line  7188)
* entered ( -- ) minos2:                 actor methods.     (line 20792)
* environment ( -- ) gforth-0.6:         Environmental Queries.
                                                            (line 11554)
* environment-wordlist ( -- WID ) gforth-0.2: Environmental Queries.
                                                            (line 11550)
* environment? ( C-ADDR U -- FALSE / ... TRUE ) core: Environmental Queries.
                                                            (line 11403)
* erase ( ADDR U -- ) core-ext:          Memory Blocks.     (line  5727)
* error-color ( -- ) gforth-1.0:         Terminal output.   (line 12645)
* error-hl-inv ( -- ) gforth-1.0:        Terminal output.   (line 12648)
* error-hl-ul ( -- ) gforth-1.0:         Terminal output.   (line 12651)
* evaluate ( ... ADDR U -- ... ) core,block: Input Sources. (line 10274)
* event-loop ( -- ) gforth-experimental: Message queues.    (line 16655)
* exception ( ADDR U -- N ) gforth-0.2:  Exception Handling.
                                                            (line  6995)
* exceptions ( XT N1 -- N2 ) gforth-1.0: Exception Handling.
                                                            (line  7005)
* execute ( XT -- ) core:                Execution token.   (line  9621)
* execute-exit ( COMPILATION -- ; RUN-TIME XT NEST-SYS -- ) gforth-1.0: Execution token.
                                                            (line  9624)
* execute-parsing ( ... ADDR U XT -- ... ) gforth-0.6: The Input Stream.
                                                            (line 11102)
* execute-parsing-file ( I*X FILEID XT -- J*X ) gforth-0.6: The Input Stream.
                                                            (line 11118)
* execute-task ( XT -- TASK ) gforth-experimental: Basic multi-tasking.
                                                            (line 16448)
* EXIT ( COMPILATION -- ; RUN-TIME NEST-SYS -- ) core: Calls and returns.
                                                            (line  6955)
* exitm ( -- ) objects:                  Objects Glossary.  (line 14551)
* expand-where ( -- ) gforth-1.0:        Locating uses of a word.
                                                            (line 15837)
* expect ( C-ADDR +N -- ) core-ext-obsolescent: Line input and conversion.
                                                            (line 12944)
* extend-mem ( ADDR1 U1 U -- ADDR ADDR2 U2 ) gforth-experimental: Memory blocks and heap allocation.
                                                            (line  5301)
* extend-structure ( N "NAME" -- STRUCT-SYS N ) gforth-1.0: Structure Extension.
                                                            (line  8997)
* extra-section ( USIZE "NAME" -- ) gforth-1.0: Sections.   (line  5210)
* f- ( R1 R2 -- R3 ) floating:           Floating Point.    (line  4578)
* f-rot ( R1 R2 R3 -- R3 R1 R2 ) gforth-1.0: Floating point stack.
                                                            (line  4837)
* f, ( F -- ) gforth-0.2:                Dictionary allocation.
                                                            (line  5058)
* F: ( COMPILATION "NAME" -- A-ADDR XT; RUN-TIME R -- ) gforth-0.2: Locals definition words.
                                                            (line 13464)
* f! ( R F-ADDR -- ) floating:           Memory Access.     (line  5387)
* f. ( R -- ) floating-ext:              Floating-point output.
                                                            (line 12427)
* f.rdp ( RF +NR +ND +NP -- ) gforth-0.6: Floating-point output.
                                                            (line 12463)
* f.s ( -- ) gforth-0.2:                 Examining data.    (line 15992)
* f.s-precision ( -- U ) gforth-1.0:     Examining data.    (line 15997)
* f@ ( F-ADDR -- R ) floating:           Memory Access.     (line  5384)
* f@localn ( NOFFSET -- R ) gforth-1.0:  Locals implementation.
                                                            (line 13756)
* f* ( R1 R2 -- R3 ) floating:           Floating Point.    (line  4580)
* f** ( R1 R2 -- R3 ) floating-ext:      Floating Point.    (line  4605)
* f/ ( R1 R2 -- R3 ) floating:           Floating Point.    (line  4582)
* F^ ( COMPILATION "NAME" -- A-ADDR XT; RUN-TIME R -- ) gforth-0.2: Locals definition words.
                                                            (line 13467)
* f+ ( R1 R2 -- R3 ) floating:           Floating Point.    (line  4576)
* f< ( R1 R2 -- F ) floating:            Floating-point comparisons.
                                                            (line  4737)
* f<= ( R1 R2 -- F ) gforth-0.2:         Floating-point comparisons.
                                                            (line  4739)
* f<> ( R1 R2 -- F ) gforth-0.2:         Floating-point comparisons.
                                                            (line  4735)
* f= ( R1 R2 -- F ) gforth-0.2:          Floating-point comparisons.
                                                            (line  4733)
* f> ( R1 R2 -- F ) gforth-0.2:          Floating-point comparisons.
                                                            (line  4741)
* f>= ( R1 R2 -- F ) gforth-0.2:         Floating-point comparisons.
                                                            (line  4743)
* f>buf-rdp ( RF C-ADDR +NR +ND +NP -- ) gforth-0.6: Floating-point output.
                                                            (line 12508)
* f>d ( R -- D ) floating:               Floating Point.    (line  4572)
* f>l ( R -- ) gforth-0.2:               Locals implementation.
                                                            (line 13768)
* f>r ( R -- ) gforth-experimental:      Return stack.      (line  4913)
* f>s ( R -- N ) floating-ext:           Floating Point.    (line  4570)
* f>str-rdp ( RF +NR +ND +NP -- C-ADDR NR ) gforth-0.6: Floating-point output.
                                                            (line 12502)
* f~ ( R1 R2 R3 -- FLAG ) floating-ext:  Floating-point comparisons.
                                                            (line  4729)
* f~abs ( R1 R2 R3 -- FLAG ) gforth-0.5: Floating-point comparisons.
                                                            (line  4726)
* f~rel ( R1 R2 R3 -- FLAG ) gforth-0.5: Floating-point comparisons.
                                                            (line  4723)
* f0< ( R -- F ) floating:               Floating-point comparisons.
                                                            (line  4745)
* f0<= ( R -- F ) gforth-0.2:            Floating-point comparisons.
                                                            (line  4747)
* f0<> ( R -- F ) gforth-0.2:            Floating-point comparisons.
                                                            (line  4749)
* f0= ( R -- F ) floating:               Floating-point comparisons.
                                                            (line  4751)
* f0> ( R -- F ) gforth-0.2:             Floating-point comparisons.
                                                            (line  4753)
* f0>= ( R -- F ) gforth-0.2:            Floating-point comparisons.
                                                            (line  4755)
* f2* ( R1 -- R2 ) gforth-0.2:           Floating Point.    (line  4628)
* f2/ ( R1 -- R2 ) gforth-0.2:           Floating Point.    (line  4631)
* fabs ( R1 -- R2 ) floating-ext:        Floating Point.    (line  4586)
* facos ( R1 -- R2 ) floating-ext:       Floating Point.    (line  4663)
* facosh ( R1 -- R2 ) floating-ext:      Floating Point.    (line  4679)
* fade-color: ( RGBA1 RGBA2 "NAME" -- ) minos2: widget methods.
                                                            (line 20952)
* falign ( -- ) floating:                Dictionary allocation.
                                                            (line  5113)
* faligned ( C-ADDR -- F-ADDR ) floating: Address arithmetic.
                                                            (line  5610)
* falog ( R1 -- R2 ) floating-ext:       Floating Point.    (line  4625)
* false ( -- F ) core-ext:               Boolean Flags.     (line  3979)
* fasin ( R1 -- R2 ) floating-ext:       Floating Point.    (line  4661)
* fasinh ( R1 -- R2 ) floating-ext:      Floating Point.    (line  4677)
* fast-throw ( ... NERROR -- ... NERROR ) gforth-experimental: Exception Handling.
                                                            (line  6975)
* fatan ( R1 -- R2 ) floating-ext:       Floating Point.    (line  4665)
* fatan2 ( R1 R2 -- R3 ) floating-ext:   Floating Point.    (line  4667)
* fatanh ( R1 -- R2 ) floating-ext:      Floating Point.    (line  4681)
* faxpy ( RA F-X NSTRIDEX F-Y NSTRIDEY UCOUNT -- ) gforth-0.5: Floating Point.
                                                            (line  4644)
* fclearstack ( R0 .. RN -- ) gforth-1.0: Examining data.   (line 16022)
* fconstant ( R "NAME" -- ) floating:    Constants.         (line  7389)
* fcopysign ( R1 R2 -- R3 ) gforth-1.0:  Floating Point.    (line  4588)
* fcos ( R1 -- R2 ) floating-ext:        Floating Point.    (line  4654)
* fcosh ( R1 -- R2 ) floating-ext:       Floating Point.    (line  4673)
* fdepth ( -- +N ) floating:             Examining data.    (line 16015)
* fdrop ( R -- ) floating:               Floating point stack.
                                                            (line  4821)
* fdup ( R -- R R ) floating:            Floating point stack.
                                                            (line  4825)
* fe. ( R -- ) floating-ext:             Floating-point output.
                                                            (line 12431)
* fexp ( R1 -- R2 ) floating-ext:        Floating Point.    (line  4610)
* fexpm1 ( R1 -- R2 ) floating-ext:      Floating Point.    (line  4613)
* ffield: ( U1 "NAME" -- U2 ) floating-ext: Standard Structures.
                                                            (line  8736)
* ffourth ( R1 R2 R3 R4 -- R1 R2 R3 R4 R1 ) gforth-1.0: Floating point stack.
                                                            (line  4831)
* field ( ALIGN1 OFFSET1 ALIGN SIZE "NAME" -- ALIGN2 OFFSET2 ) gforth-0.2: Gforth structs.
                                                            (line  9101)
* field: ( U1 "NAME" -- U2 ) facility-ext: Standard Structures.
                                                            (line  8730)
* file-eof? ( WFILEID -- FLAG ) gforth-0.6: General files.  (line 11760)
* file-position ( WFILEID -- UD WIOR ) file: General files. (line 11773)
* file-size ( WFILEID -- UD WIOR ) file: General files.     (line 11777)
* file-status ( C-ADDR U -- WFAM WIOR ) file-ext: General files.
                                                            (line 11771)
* file>fpath ( ADDR1 U1 -- ADDR2 U2 ) gforth-1.0: Source Search Paths.
                                                            (line 11938)
* file>path ( C-ADDR1 U1 PATH-ADDR -- C-ADDR2 U2 ) gforth-1.0: General Search Paths.
                                                            (line 11963)
* filename-match ( C-ADDR1 U1 C-ADDR2 U2 -- FLAG ) gforth-0.5: Directories.
                                                            (line 11872)
* fill ( C-ADDR U C -- ) core:           Memory Blocks.     (line  5724)
* find ( C-ADDR -- XT +-1 | C-ADDR 0 ) core,search: Word Lists.
                                                            (line 11229)
* find-name ( C-ADDR U -- NT | 0 ) gforth-0.2: Name token.  (line  9652)
* find-name-in ( C-ADDR U WID -- NT | 0 ) gforth-1.0: Name token.
                                                            (line  9656)
* fkey. ( U -- ) gforth-1.0:             Single-key input.  (line 12873)
* flit, ( R -- ) gforth-1.0:             Literals.          (line  9885)
* FLiteral ( COMPILATION R -- ; RUN-TIME -- R ) floating: Literals.
                                                            (line  9879)
* fln ( R1 -- R2 ) floating-ext:         Floating Point.    (line  4616)
* flnp1 ( R1 -- R2 ) floating-ext:       Floating Point.    (line  4619)
* float ( -- U ) gforth-0.3:             Address arithmetic.
                                                            (line  5602)
* float/ ( N1 -- N2 ) gforth-1.0:        Address arithmetic.
                                                            (line  5606)
* float% ( -- ALIGN SIZE ) gforth-0.4:   Gforth structs.    (line  9108)
* float+ ( F-ADDR1 -- F-ADDR2 ) floating: Address arithmetic.
                                                            (line  5599)
* floating-stack ( -- N ) environment:   Environmental Queries.
                                                            (line 11461)
* floats ( N1 -- N2 ) floating:          Address arithmetic.
                                                            (line  5596)
* flog ( R1 -- R2 ) floating-ext:        Floating Point.    (line  4622)
* floor ( R1 -- R2 ) floating:           Floating Point.    (line  4595)
* FLOORED ( -- F ) environment:          Environmental Queries.
                                                            (line 11440)
* flush ( -- ) block:                    Blocks.            (line 12171)
* flush-file ( WFILEID -- WIOR ) file-ext: General files.   (line 11769)
* flush-icache ( C-ADDR U -- ) gforth-0.2: Assembler Definitions.
                                                            (line 17244)
* fm/mod ( D1 N1 -- N2 N3 ) core:        Integer division.  (line  4164)
* fmax ( R1 R2 -- R3 ) floating:         Floating Point.    (line  4591)
* fmin ( R1 R2 -- R3 ) floating:         Floating Point.    (line  4593)
* fnegate ( R1 -- R2 ) floating:         Floating Point.    (line  4584)
* fnip ( R1 R2 -- R2 ) gforth-0.2:       Floating point stack.
                                                            (line  4823)
* focus ( -- ) minos2:                   actor methods.     (line 20786)
* FOR ( COMPILATION -- DO-SYS ; RUN-TIME U -- LOOP-SYS ) gforth-0.2: Counted Loops.
                                                            (line  6579)
* FORK ( COMPILATION -- ORIG ; RUN-TIME F -- ) gforth-0.7: Regular Expressions.
                                                            (line 15544)
* form ( -- NLINES NCOLS ) gforth-0.2:   Terminal output.   (line 12625)
* Forth ( -- ) search-ext:               Word Lists.        (line 11210)
* forth-recognize ( C-ADDR U -- ... TRANSLATE-XT ) recognizer: Recognizer order.
                                                            (line 10727)
* forth-recognize-nt? ( C-ADDR U -- NT | 0 ) gforth-experimental: Define recognizers with existing translators.
                                                            (line 10888)
* forth-wordlist ( -- WID ) search:      Word Lists.        (line 11148)
* forward ( "NAME" -- ) gforth-1.0:      Calls and returns. (line  6928)
* fourth ( W1 W2 W3 W4 -- W1 W2 W3 W4 W1 ) gforth-1.0: Data stack.
                                                            (line  4785)
* fover ( R1 R2 -- R1 R2 R1 ) floating:  Floating point stack.
                                                            (line  4827)
* fp! ( F-ADDR -- F:... ) gforth-0.2:    Stack pointer manipulation.
                                                            (line  4946)
* fp. ( R -- ) floating-ext:             Floating-point output.
                                                            (line 12439)
* fp@ ( F:... -- F-ADDR ) gforth-0.2:    Stack pointer manipulation.
                                                            (line  4944)
* fp0 ( -- A-ADDR ) gforth-0.4:          Stack pointer manipulation.
                                                            (line  4941)
* fpath ( -- PATH-ADDR ) gforth-0.4:     Source Search Paths.
                                                            (line 11933)
* fpick ( F:... U -- F:... R ) gforth-0.4: Floating point stack.
                                                            (line  4841)
* fr@ ( -- R ) gforth-experimental:      Return stack.      (line  4919)
* fr> ( -- R ) gforth-experimental:      Return stack.      (line  4916)
* free ( A_ADDR -- WIOR ) memory:        Heap Allocation.   (line  5275)
* free-closure ( XT -- ) gforth-1.0:     Closures.          (line 15242)
* free-mem-var ( ADDR -- ) gforth-experimental: Memory blocks and heap allocation.
                                                            (line  5307)
* frot ( R1 R2 R3 -- R2 R3 R1 ) floating: Floating point stack.
                                                            (line  4835)
* fround ( R1 -- R2 ) floating:          Floating Point.    (line  4599)
* fs. ( R -- ) floating-ext:             Floating-point output.
                                                            (line 12435)
* fsin ( R1 -- R2 ) floating-ext:        Floating Point.    (line  4652)
* fsincos ( R1 -- R2 R3 ) floating-ext:  Floating Point.    (line  4656)
* fsinh ( R1 -- R2 ) floating-ext:       Floating Point.    (line  4671)
* fsqrt ( R1 -- R2 ) floating-ext:       Floating Point.    (line  4608)
* fswap ( R1 R2 -- R2 R1 ) floating:     Floating point stack.
                                                            (line  4833)
* ftan ( R1 -- R2 ) floating-ext:        Floating Point.    (line  4659)
* ftanh ( R1 -- R2 ) floating-ext:       Floating Point.    (line  4675)
* fthird ( R1 R2 R3 -- R1 R2 R3 R1 ) gforth-1.0: Floating point stack.
                                                            (line  4829)
* ftrunc ( R1 -- R2 ) floating-ext:      Floating Point.    (line  4602)
* ftuck ( R1 R2 -- R2 R1 R2 ) gforth-0.2: Floating point stack.
                                                            (line  4839)
* fvalue ( R "NAME" -- ) floating-ext:   Values.            (line  7431)
* fvalue: ( U1 "NAME" -- U2 ) gforth-experimental: Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8869)
* fvariable ( "NAME" -- ) floating:      Variables.         (line  7345)
* g ( -- ) gforth-0.7:                   Locating source code definitions.
                                                            (line 15770)
* gap ( -- R ) minos2:                   widget methods.    (line 20840)
* get ( -- SOMETHING ) minos2:           actor methods.     (line 20804)
* get-block-fid ( -- WFILEID ) gforth-0.2: Blocks.          (line 12121)
* get-current ( -- WID ) search:         Word Lists.        (line 11157)
* get-dir ( C-ADDR1 U1 -- C-ADDR2 U2 ) gforth-0.7: Directories.
                                                            (line 11877)
* get-order ( -- WIDN .. WID1 N ) search: Word Lists.       (line 11173)
* get-stack ( STACK -- X1 .. XN N ) gforth-experimental: User-defined Stacks.
                                                            (line  9163)
* getenv ( C-ADDR1 U1 -- C-ADDR2 U2 ) gforth-0.2: Passing Commands to the OS.
                                                            (line 18278)
* gforth ( -- C-ADDR U ) gforth-environment: Environmental Queries.
                                                            (line 11527)
* gg ( -- ) gforth-1.0:                  Locating uses of a word.
                                                            (line 15819)
* h ( -- R ) minos2:                     widget methods.    (line 20834)
* h. ( U -- ) gforth-1.0:                Simple numeric output.
                                                            (line 12228)
* halt ( TASK -- ) gforth-experimental:  Basic multi-tasking.
                                                            (line 16464)
* heap-new ( ... CLASS -- OBJECT ) objects: Objects Glossary.
                                                            (line 14554)
* help ( "REST-OF-LINE" -- ) gforth-1.0: Help on Gforth.    (line   876)
* here ( -- ADDR ) core:                 Dictionary allocation.
                                                            (line  5038)
* hex ( -- ) core-ext:                   Number Conversion. (line 10335)
* hex. ( U -- ) gforth-0.2:              Simple numeric output.
                                                            (line 12232)
* hglue ( -- RTYP RSUB RADD ) minos2:    widget methods.    (line 20879)
* hglue@ ( -- RTYP RSUB RADD ) minos2:   widget methods.    (line 20888)
* hide ( -- ) minos2:                    actor methods.     (line 20801)
* hold ( CHAR -- ) core:                 Formatted numeric output.
                                                            (line 12330)
* holds ( ADDR U -- ) core-ext:          Formatted numeric output.
                                                            (line 12334)
* how: ( -- ) oof:                       Class Declaration. (line 14855)
* i ( R:N -- R:N N ) core:               Counted Loops.     (line  6597)
* i' ( R:W R:W2 -- R:W R:W2 W ) gforth-0.2: Counted Loops.  (line  6606)
* id. ( NT -- ) gforth-0.6:              Name token.        (line  9700)
* IF ( COMPILATION -- ORIG ; RUN-TIME F -- ) core: Arbitrary control structures.
                                                            (line  6815)
* iferror ( COMPILATION ORIG1 -- ORIG2 ; RUN-TIME -- ) gforth-0.7: Exception Handling.
                                                            (line  7112)
* immediate ( -- ) core:                 How to define immediate words.
                                                            (line  9338)
* immediate? ( NT -- FLAG ) gforth-1.0:  Header methods.    (line 18121)
* implementation ( INTERFACE -- ) objects: Objects Glossary.
                                                            (line 14557)
* in ( "VOC" "DEFINING-WORD" -- ) gforth-experimental: Word Lists.
                                                            (line 11168)
* in-colon-def? ( -- FLAG ) gforth-experimental: Macros.    (line 10160)
* in-wordlist ( WORDLIST "DEFINING-WORD" -- ) gforth-experimental: Word Lists.
                                                            (line 11163)
* include ( ... "FILE" -- ... ) file-ext: Forth source files.
                                                            (line 11660)
* include-file ( I*X WFILEID -- J*X ) file: Forth source files.
                                                            (line 11646)
* include-locale ( "NAME" -- ) gforth-experimental: i18n and l10n.
                                                            (line 13154)
* included ( I*X C-ADDR U -- J*X ) file: Forth source files.
                                                            (line 11650)
* included-locale ( ADDR U -- ) gforth-experimental: i18n and l10n.
                                                            (line 13151)
* included? ( C-ADDR U -- F ) gforth-0.2: Forth source files.
                                                            (line 11653)
* inf ( -- R ) gforth-1.0:               Floating Point.    (line  4694)
* infile-execute ( ... XT FILE-ID -- ... ) gforth-0.7: Redirection.
                                                            (line 11822)
* infile-id ( -- FILE-ID ) gforth-0.4:   Redirection.       (line 11825)
* infinity ( -- R ) gforth-1.0:          Floating Point.    (line  4691)
* info-color ( -- ) gforth-1.0:          Terminal output.   (line 12657)
* init-asm ( -- ) gforth-0.2:            Assembler Definitions.
                                                            (line 17205)
* init-buffer ( ADDR -- ) gforth-experimental: Growable memory buffers.
                                                            (line  5334)
* init-object ( ... CLASS OBJECT -- ) objects: Objects Glossary.
                                                            (line 14561)
* initiate ( XT TASK -- ) gforth-experimental: Basic multi-tasking.
                                                            (line 16423)
* inline: ( "NAME" -- INLINE:-SYS ) gforth-experimental: Inline Definitions.
                                                            (line  7513)
* input-color ( -- ) gforth-1.0:         Terminal output.   (line 12663)
* insert ( C-ADDR1 U1 C-ADDR2 U2 -- ) gforth-0.7: String words.
                                                            (line  6010)
* inst-value ( ALIGN1 OFFSET1 "NAME" -- ALIGN2 OFFSET2 ) objects: Objects Glossary.
                                                            (line 14565)
* inst-var ( ALIGN1 OFFSET1 ALIGN SIZE "NAME" -- ALIGN2 OFFSET2 ) objects: Objects Glossary.
                                                            (line 14569)
* INT-[I] ( -- N ) gforth-1.0:           Interpreter Directives.
                                                            (line 10456)
* interface ( -- ) objects:              Objects Glossary.  (line 14573)
* interpret/compile: ( INT-XT COMP-XT "NAME" -- ) gforth-0.2: How to define combined words.
                                                            (line  9428)
* interpreting ( ... TRANSLATOR -- ... ) gforth-experimental: Performing translator actions.
                                                            (line 10970)
* intsem: ( -- ) gforth-experimental:    How to define combined words.
                                                            (line  9527)
* invert ( W1 -- W2 ) core:              Bitwise operations.
                                                            (line  4373)
* IS ( XT ... "NAME" -- ) core-ext:      Deferred Words.    (line  8481)
* j ( R:N R:W1 R:W2 -- N R:N R:W1 R:W2 ) core: Counted Loops.
                                                            (line  6600)
* JOIN ( ORIG -- ) gforth-0.7:           Regular Expressions.
                                                            (line 15547)
* k ( R:N R:W1 R:W2 R:W3 R:W4 -- N R:N R:W1 R:W2 R:W3 R:W4 ) gforth-0.3: Counted Loops.
                                                            (line  6603)
* k-alt-mask ( -- U ) facility-ext:      Single-key input.  (line 12819)
* k-backspace ( -- U ) gforth-1.0:       Single-key input.  (line 12827)
* k-ctrl-mask ( -- U ) facility-ext:     Single-key input.  (line 12817)
* k-delete ( -- U ) facility-ext:        Single-key input.  (line 12781)
* k-down ( -- U ) facility-ext:          Single-key input.  (line 12766)
* k-end ( -- U ) facility-ext:           Single-key input.  (line 12771)
* k-enter ( -- U ) gforth-1.0:           Single-key input.  (line 12825)
* k-eof ( -- U ) gforth-1.0:             Single-key input.  (line 12847)
* k-f1 ( -- U ) facility-ext:            Single-key input.  (line 12786)
* k-f10 ( -- U ) facility-ext:           Single-key input.  (line 12804)
* k-f11 ( -- U ) facility-ext:           Single-key input.  (line 12806)
* k-f12 ( -- U ) facility-ext:           Single-key input.  (line 12808)
* k-f2 ( -- U ) facility-ext:            Single-key input.  (line 12788)
* k-f3 ( -- U ) facility-ext:            Single-key input.  (line 12790)
* k-f4 ( -- U ) facility-ext:            Single-key input.  (line 12792)
* k-f5 ( -- U ) facility-ext:            Single-key input.  (line 12794)
* k-f6 ( -- U ) facility-ext:            Single-key input.  (line 12796)
* k-f7 ( -- U ) facility-ext:            Single-key input.  (line 12798)
* k-f8 ( -- U ) facility-ext:            Single-key input.  (line 12800)
* k-f9 ( -- U ) facility-ext:            Single-key input.  (line 12802)
* k-home ( -- U ) facility-ext:          Single-key input.  (line 12768)
* k-insert ( -- U ) facility-ext:        Single-key input.  (line 12779)
* k-left ( -- U ) facility-ext:          Single-key input.  (line 12760)
* k-mute ( -- U ) gforth-1.0:            Single-key input.  (line 12839)
* k-next ( -- U ) facility-ext:          Single-key input.  (line 12776)
* k-pause ( -- U ) gforth-1.0:           Single-key input.  (line 12837)
* k-prior ( -- U ) facility-ext:         Single-key input.  (line 12773)
* k-right ( -- U ) facility-ext:         Single-key input.  (line 12762)
* k-sel ( -- U ) gforth-1.0:             Single-key input.  (line 12845)
* k-shift-mask ( -- U ) facility-ext:    Single-key input.  (line 12815)
* k-tab ( -- U ) gforth-1.0:             Single-key input.  (line 12829)
* k-up ( -- U ) facility-ext:            Single-key input.  (line 12764)
* k-voldown ( -- U ) gforth-1.0:         Single-key input.  (line 12843)
* k-volup ( -- U ) gforth-1.0:           Single-key input.  (line 12841)
* k-winch ( -- U ) gforth-1.0:           Single-key input.  (line 12833)
* kerning ( -- R ) minos2:               widget methods.    (line 20846)
* key ( -- CHAR ) core:                  Single-key input.  (line 12705)
* key-file ( FD -- KEY ) gforth-0.4:     General files.     (line 11747)
* key-ior ( -- CHAR|IOR ) gforth-1.0:    Single-key input.  (line 12708)
* key? ( -- FLAG ) facility:             Single-key input.  (line 12712)
* key?-file ( WFILEID -- F ) gforth-0.4: General files.     (line 11754)
* kill ( TASK -- ) gforth-experimental:  Basic multi-tasking.
                                                            (line 16459)
* kill-task ( -- ) gforth-experimental:  Basic multi-tasking.
                                                            (line 16456)
* l ( -- ) gforth-1.0:                   Locating source code definitions.
                                                            (line 15759)
* l, ( L -- ) gforth-1.0:                Dictionary allocation.
                                                            (line  5073)
* l! ( W C-ADDR -- ) gforth-0.7:         Special Memory Accesses.
                                                            (line  5448)
* L" ( "LSID<">" -- LSID ) gforth-experimental: i18n and l10n.
                                                            (line 13120)
* l@ ( C-ADDR -- U ) gforth-0.7:         Special Memory Accesses.
                                                            (line  5445)
* l>s ( X -- N ) gforth-1.0:             Special Memory Accesses.
                                                            (line  5510)
* lalign ( -- ) gforth-1.0:              Address arithmetic.
                                                            (line  5664)
* laligned ( ADDR -- ADDR' ) gforth-1.0: Address arithmetic.
                                                            (line  5661)
* Language ( "NAME" -- ) gforth-experimental: i18n and l10n.
                                                            (line 13139)
* lastfit ( -- ) minos2:                 widget methods.    (line 20876)
* latest ( -- NT ) gforth-0.6:           Name token.        (line  9660)
* latestnt ( -- NT ) gforth-1.0:         Name token.        (line  9664)
* latestxt ( -- XT ) gforth-0.6:         Anonymous Definitions.
                                                            (line  7595)
* lbe ( U1 -- U2 ) gforth-1.0:           Special Memory Accesses.
                                                            (line  5476)
* LEAVE ( COMPILATION -- ; RUN-TIME LOOP-SYS -- ) core: Counted Loops.
                                                            (line  6612)
* left ( -- ) minos2:                    actor methods.     (line 20795)
* lfield: ( U1 "NAME" -- U2 ) gforth-1.0: Standard Structures.
                                                            (line  8748)
* lib-error ( -- C-ADDR U ) gforth-0.7:  Low-Level C Interface Words.
                                                            (line 17092)
* lib-sym ( C-ADDR1 U1 U2 -- U3 ) gforth-0.4: Low-Level C Interface Words.
                                                            (line 17090)
* license ( -- ) gforth-0.2:             Help on Gforth.    (line   888)
* light-mode ( -- ) gforth-1.0:          Terminal output.   (line 12678)
* line-end-hook ( -- ) gforth-0.7:       Text Interpreter Hooks.
                                                            (line 11030)
* list ( U -- ) block-ext:               Blocks.            (line 12128)
* list-size ( LIST -- U ) gforth-internal: Locals implementation.
                                                            (line 13844)
* lit, ( X -- ) gforth-1.0:              Literals.          (line  9859)
* Literal ( COMPILATION N -- ; RUN-TIME -- N ) core: Literals.
                                                            (line  9854)
* ll ( -- ) gforth-1.0:                  Locating uses of a word.
                                                            (line 15824)
* lle ( U1 -- U2 ) gforth-1.0:           Special Memory Accesses.
                                                            (line  5480)
* load ( I*X U -- J*X ) block:           Blocks.            (line 12174)
* load-cov ( -- ) gforth-experimental:   Code Coverage.     (line 16362)
* locale-csv ( "NAME" -- ) gforth-experimental: i18n and l10n.
                                                            (line 13157)
* locale-csv-out ( "NAME" -- ) gforth-experimental: i18n and l10n.
                                                            (line 13167)
* locale-file ( FID -- ) gforth-experimental: i18n and l10n.
                                                            (line 13148)
* locale! ( ADDR U LSID -- ) gforth-experimental: i18n and l10n.
                                                            (line 13135)
* locale@ ( LSID -- ADDR U ) gforth-experimental: i18n and l10n.
                                                            (line 13132)
* locals| ( ... "NAME ..." -- ) local-ext: Locals definition words.
                                                            (line 13441)
* locate ( "NAME" -- ) gforth-1.0:       Locating source code definitions.
                                                            (line 15745)
* lock ( SEMAPHORE -- ) gforth-experimental: Semaphores.    (line 16569)
* log2 ( U -- N ) gforth-1.0:            Bitwise operations.
                                                            (line  4420)
* LOOP ( COMPILATION DO-SYS -- ; RUN-TIME LOOP-SYS1 -- | LOOP-SYS2 ) core: Counted Loops.
                                                            (line  6582)
* lp! ( C-ADDR -- ) gforth-internal:     Stack pointer manipulation.
                                                            (line  4961)
* lp@ ( -- C-ADDR ) gforth-0.2:          Stack pointer manipulation.
                                                            (line  4958)
* lp+! ( NOFFSET -- ) gforth-1.0:        Locals implementation.
                                                            (line 13762)
* lp+n ( NOFFSET -- C-ADDR ) gforth-internal: Locals implementation.
                                                            (line 13760)
* lp0 ( -- A-ADDR ) gforth-0.4:          Stack pointer manipulation.
                                                            (line  4955)
* lrol ( U1 U -- U2 ) gforth-1.0:        Bitwise operations.
                                                            (line  4445)
* lror ( U1 U -- U2 ) gforth-1.0:        Bitwise operations.
                                                            (line  4449)
* lshift ( U1 U -- U2 ) core:            Bitwise operations.
                                                            (line  4380)
* LU" ( "LSID<">" -- LSID ) gforth-experimental: i18n and l10n.
                                                            (line 13125)
* lvalue: ( U1 "NAME" -- U2 ) gforth-experimental: Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8849)
* m: ( -- XT COLON-SYS; RUN-TIME: OBJECT -- ) objects: Objects Glossary.
                                                            (line 14576)
* m* ( N1 N2 -- D ) core:                Mixed precision.   (line  4080)
* m*/ ( D1 N2 U3 -- DQUOT ) double:      Integer division.  (line  4210)
* m+ ( D1 N -- D2 ) double:              Mixed precision.   (line  4078)
* macros-wordlist ( -- WID ) gforth-experimental: Substitute.
                                                            (line 13182)
* magenta-input ( -- ) gforth-1.0:       Terminal output.   (line 12687)
* make-latest ( NT -- ) gforth-1.0:      Making a word current.
                                                            (line  8376)
* map-vocs ( ... XT -- ... ) gforth-1.0: Word Lists.        (line 11293)
* marker ( "<SPACES> NAME" -- ) core-ext: Forgetting words. (line 16045)
* max ( N1 N2 -- N ) core:               Single precision.  (line  4032)
* MAX-CHAR ( -- U ) environment:         Environmental Queries.
                                                            (line 11420)
* MAX-D ( -- D ) environment:            Environmental Queries.
                                                            (line 11449)
* max-float ( -- R ) environment:        Environmental Queries.
                                                            (line 11471)
* MAX-N ( -- N ) environment:            Environmental Queries.
                                                            (line 11443)
* MAX-U ( -- U ) environment:            Environmental Queries.
                                                            (line 11446)
* MAX-UD ( -- UD ) environment:          Environmental Queries.
                                                            (line 11452)
* MAX-XCHAR ( -- XCHAR ) environment:    Environmental Queries.
                                                            (line 11482)
* maxalign ( -- ) gforth-0.2:            Dictionary allocation.
                                                            (line  5125)
* maxaligned ( ADDR1 -- ADDR2 ) gforth-0.2: Address arithmetic.
                                                            (line  5644)
* maxdepth-.s ( -- ADDR ) gforth-0.2:    Examining data.    (line 16001)
* mem-do ( COMPILATION -- W XT DO-SYS; RUN-TIME ADDR UBYTES +NSTRIDE -- ) gforth-experimental: Counted Loops.
                                                            (line  6571)
* mem, ( ADDR U -- ) gforth-0.6:         Dictionary allocation.
                                                            (line  5090)
* mem+do ( COMPILATION -- W XT DO-SYS; RUN-TIME ADDR UBYTES +NSTRIDE -- ) gforth-experimental: Counted Loops.
                                                            (line  6566)
* method ( -- ) oof:                     Class Declaration. (line 14845)
* method ( M V "NAME" -- M' V ) mini-oof2: Basic Mini-OOF Usage.
                                                            (line 14880)
* method ( XT "NAME" -- ) objects:       Objects Glossary.  (line 14586)
* methods ( CLASS -- ) objects:          Objects Glossary.  (line 14590)
* min ( N1 N2 -- N ) core:               Single precision.  (line  4030)
* mkdir-parents ( C-ADDR U MODE -- IOR ) gforth-0.7: Directories.
                                                            (line 11888)
* mod ( N1 N2 -- N ) core:               Integer division.  (line  4138)
* modf ( N1 N2 -- N ) gforth-1.0:        Integer division.  (line  4143)
* modf-stage2m ( N1 A-RECI -- UMODULUS ) gforth-1.0: Two-stage integer division.
                                                            (line  4305)
* mods ( N1 N2 -- N ) gforth-1.0:        Integer division.  (line  4141)
* move ( C-FROM C-TO UCOUNT -- ) core:   Memory Blocks.     (line  5710)
* ms ( N -- ) facility-ext:              Keeping track of Time.
                                                            (line 18287)
* mux ( U1 U2 U3 -- U ) gforth-1.0:      Bitwise operations.
                                                            (line  4375)
* mwords ( ["PATTERN"] -- ) gforth-1.0:  Word Lists.        (line 11263)
* n ( -- ) gforth-1.0:                   Locating source code definitions.
                                                            (line 15762)
* n/a ( -- ) gforth-experimental:        Words with user-defined TO etc..
                                                            (line  8190)
* n>r ( X1 .. XN N -- R:XN..R:X1 R:N ) tools-ext: Return stack.
                                                            (line  4899)
* name ( -- C-ADDR U ) gforth-obsolete:  The Input Stream.  (line 11072)
* name>compile ( NT -- W XT ) tools-ext: Name token.        (line  9693)
* name>interpret ( NT -- XT ) tools-ext: Name token.        (line  9690)
* name>link ( NT1 -- NT2 / 0 ) gforth-1.0: Name token.      (line  9713)
* name>string ( NT -- ADDR U ) tools-ext: Name token.       (line  9697)
* name$ ( -- ADDR U ) minos2:            widget methods.    (line 20822)
* NaN ( -- R ) gforth-1.0:               Floating Point.    (line  4705)
* native@ ( LSID -- ADDR U ) gforth-experimental: i18n and l10n.
                                                            (line 13129)
* needs ( ... "NAME" -- ... ) gforth-0.2: Forth source files.
                                                            (line 11672)
* negate ( N1 -- N2 ) core:              Single precision.  (line  4026)
* new ( CLASS -- O ) mini-oof:           Basic Mini-OOF Usage.
                                                            (line 14899)
* new-color: ( RGBA "NAME" -- ) minos2:  widget methods.    (line 20941)
* newline ( -- C-ADDR U ) gforth-0.5:    String and character literals.
                                                            (line  5913)
* newtask ( STACKSIZE -- TASK ) gforth-experimental: Basic multi-tasking.
                                                            (line 16398)
* newtask4 ( U-DATA U-RETURN U-FP U-LOCALS -- TASK ) gforth-experimental: Basic multi-tasking.
                                                            (line 16407)
* NEXT ( COMPILATION DO-SYS -- ; RUN-TIME LOOP-SYS1 -- | LOOP-SYS2 ) gforth-0.2: Counted Loops.
                                                            (line  6594)
* next-arg ( -- ADDR U ) gforth-0.7:     OS command line arguments.
                                                            (line 13254)
* next-case ( COMPILATION CASE-SYS -- ; RUN-TIME -- ) gforth-1.0: General control structures with CASE.
                                                            (line  6774)
* next-section ( -- ) gforth-1.0:        Sections.          (line  5194)
* nextname ( C-ADDR U -- ) gforth-0.2:   Supplying names.   (line  7655)
* nip ( W1 W2 -- W2 ) core-ext:          Data stack.        (line  4777)
* nocov[ ( -- ) gforth-1.0:              Code Coverage.     (line 16310)
* noname ( -- ) gforth-0.2:              Anonymous Definitions.
                                                            (line  7590)
* noname-from ( XT -- ) gforth-1.0:      Creating from a prototype.
                                                            (line  8350)
* noop ( -- ) gforth-0.2:                Execution token.   (line  9637)
* nosplit? ( ADDR1 U1 ADDR2 U2 -- ADDR1 U1 ADDR2 U2 FLAG ) gforth-experimental: String words.
                                                            (line  5993)
* nothrow ( -- ) gforth-0.7:             Exception Handling.
                                                            (line  7066)
* nr> ( R:XN..R:X1 R:N -- X1 .. XN N ) tools-ext: Return stack.
                                                            (line  4904)
* ns ( D -- ) gforth-1.0:                Keeping track of Time.
                                                            (line 18289)
* nt ( -- ) gforth-1.0:                  Locating exception source.
                                                            (line 15856)
* ntime ( -- DTIME ) gforth-1.0:         Keeping track of Time.
                                                            (line 18304)
* nw ( -- ) gforth-1.0:                  Locating uses of a word.
                                                            (line 15809)
* o> ( R:C-ADDR -- ) new:                Mini-OOF2.         (line 15081)
* object ( -- A-ADDR ) mini-oof:         Basic Mini-OOF Usage.
                                                            (line 14877)
* object ( -- CLASS ) objects:           Objects Glossary.  (line 14595)
* object-: ( "NAME" -- ) oof:            The OOF base class.
                                                            (line 14772)
* object-:: ( "NAME" -- ) oof:           The OOF base class.
                                                            (line 14784)
* object-' ( "NAME" -- XT ) oof:         The OOF base class.
                                                            (line 14806)
* object-[] ( N "NAME" -- ) oof:         The OOF base class.
                                                            (line 14778)
* object-asptr ( O "NAME" -- ) oof:      The OOF base class.
                                                            (line 14776)
* object-bind ( O "NAME" -- ) oof:       The OOF base class.
                                                            (line 14795)
* object-bound ( CLASS ADDR "NAME" -- ) oof: The OOF base class.
                                                            (line 14797)
* object-class ( "NAME" -- ) oof:        The OOF base class.
                                                            (line 14749)
* object-class? ( O -- FLAG ) oof:       The OOF base class.
                                                            (line 14753)
* object-definitions ( -- ) oof:         The OOF base class.
                                                            (line 14751)
* object-dispose ( -- ) oof:             The OOF base class.
                                                            (line 14763)
* object-endwith ( -- ) oof:             The OOF base class.
                                                            (line 14817)
* object-init ( ... -- ) oof:            The OOF base class.
                                                            (line 14761)
* object-is ( XT "NAME" -- ) oof:        The OOF base class.
                                                            (line 14801)
* object-link ( "NAME" -- CLASS ADDR ) oof: The OOF base class.
                                                            (line 14799)
* object-new ( -- O ) oof:               The OOF base class.
                                                            (line 14768)
* object-new[] ( N -- O ) oof:           The OOF base class.
                                                            (line 14770)
* object-postpone ( "NAME" -- ) oof:     The OOF base class.
                                                            (line 14808)
* object-ptr ( "NAME" -- ) oof:          The OOF base class.
                                                            (line 14774)
* object-self ( -- O ) oof:              The OOF base class.
                                                            (line 14790)
* object-super ( "NAME" -- ) oof:        The OOF base class.
                                                            (line 14786)
* object-with ( O -- ) oof:              The OOF base class.
                                                            (line 14815)
* obsolete? ( NT -- FLAG ) gforth-1.0:   Name token.        (line  9709)
* of ( COMPILATION -- OF-SYS ; RUN-TIME X1 X2 -- |X1 ) core-ext: General control structures with CASE.
                                                            (line  6778)
* off ( A-ADDR -- ) gforth-0.2:          Boolean Flags.     (line  3985)
* on ( A-ADDR -- ) gforth-0.2:           Boolean Flags.     (line  3982)
* once ( -- ) gforth-1.0:                Debugging.         (line 16118)
* Only ( -- ) search-ext:                Word Lists.        (line 11214)
* open-blocks ( C-ADDR U -- ) gforth-0.2: Blocks.           (line 12109)
* open-dir ( C-ADDR U -- WDIRID WIOR ) gforth-0.5: Directories.
                                                            (line 11854)
* open-file ( C-ADDR U WFAM -- WFILEID WIOR ) file: General files.
                                                            (line 11718)
* open-lib ( C-ADDR1 U1 -- U2 ) gforth-0.4: Low-Level C Interface Words.
                                                            (line 17088)
* open-path-file ( ADDR1 U1 PATH-ADDR -- WFILEID ADDR2 U2 0 | IOR ) gforth-0.2: General Search Paths.
                                                            (line 11957)
* open-pipe ( C-ADDR U WFAM -- WFILEID WIOR ) gforth-0.2: Pipes.
                                                            (line 12963)
* opt: ( COMPILATION -- COLON-SYS2 ; RUN-TIME -- NEST-SYS ) gforth-1.0: User-defined compile-comma.
                                                            (line  8230)
* or ( W1 W2 -- W ) core:                Bitwise operations.
                                                            (line  4369)
* order ( -- ) search-ext:               Word Lists.        (line 11218)
* os-class ( -- C-ADDR U ) gforth-environment: Environmental Queries.
                                                            (line 11532)
* os-type ( -- C-ADDR U ) gforth-environment: Environmental Queries.
                                                            (line 11536)
* out ( -- ADDR ) gforth-1.0:            Miscellaneous output.
                                                            (line 12535)
* outfile-execute ( ... XT FILE-ID -- ... ) gforth-0.7: Redirection.
                                                            (line 11814)
* outfile-id ( -- FILE-ID ) gforth-0.2:  Redirection.       (line 11817)
* over ( W1 W2 -- W1 W2 W1 ) core:       Data stack.        (line  4781)
* overrides ( XT "SELECTOR" -- ) objects: Objects Glossary. (line 14598)
* pad ( -- C-ADDR ) core-ext:            Memory Blocks.     (line  5733)
* page ( -- ) facility:                  Terminal output.   (line 12629)
* par-split ( RW -- ) minos2:            widget methods.    (line 20915)
* parent-w ( -- OPTR ) minos2:           widget methods.    (line 20816)
* parse ( XCHAR "CCC<XCHAR>" -- C-ADDR U ) core-ext,xchar-ext: The Input Stream.
                                                            (line 11055)
* parse-name ( "NAME" -- C-ADDR U ) core-ext: The Input Stream.
                                                            (line 11065)
* parse-word ( -- C-ADDR U ) gforth-obsolete: The Input Stream.
                                                            (line 11068)
* pass ( X1 .. XN N TASK -- ) gforth-experimental: Basic multi-tasking.
                                                            (line 16440)
* path+ ( PATH-ADDR "DIR" -- ) gforth-0.4: General Search Paths.
                                                            (line 11978)
* path= ( PATH-ADDR "DIR1|DIR2|DIR3" -- ) gforth-0.4: General Search Paths.
                                                            (line 11981)
* pause ( -- ) gforth-experimental:      Basic multi-tasking.
                                                            (line 16500)
* perform ( A-ADDR -- ) gforth-0.2:      Execution token.   (line  9629)
* pi ( -- R ) gforth-0.2:                Floating Point.    (line  4683)
* pick ( S:... U -- S:... W ) core-ext:  Data stack.        (line  4795)
* place ( C-ADDR1 U C-ADDR2 -- ) gforth-experimental: Counted string words.
                                                            (line  6233)
* postpone ( "NAME" -- ) core:           Macros.            (line  9947)
* postpone, ( W XT -- ) gforth-0.2:      Compilation token. (line  9792)
* postponing ( ... TRANSLATOR -- ) gforth-experimental: Performing translator actions.
                                                            (line 10987)
* pow2? ( U -- F ) gforth-1.0:           Bitwise operations.
                                                            (line  4424)
* precision ( -- U ) floating-ext:       Floating-point output.
                                                            (line 12453)
* prepend-where ( -- ) gforth-1.0:       Locating uses of a word.
                                                            (line 15841)
* preserve ( COMPILATION "NAME" -- ; RUN-TIME -- ) gforth-1.0: Deferred Words.
                                                            (line  8547)
* previous ( -- ) search-ext:            Word Lists.        (line 11202)
* previous-section ( -- ) gforth-1.0:    Sections.          (line  5199)
* print ( OBJECT -- ) objects:           Objects Glossary.  (line 14605)
* printdebugdata ( -- ) gforth-0.2:      Debugging.         (line 16103)
* process-option ( ADDR U -- ... XT | 0 ) gforth-0.7: Modifying the Startup Sequence.
                                                            (line 20082)
* protected ( -- ) objects:              Objects Glossary.  (line 14609)
* ptr ( -- ) oof:                        Class Declaration. (line 14829)
* public ( -- ) objects:                 Objects Glossary.  (line 14612)
* query ( -- ) core-ext-obsolescent:     Input Sources.     (line 10305)
* quit ( ?? -- ?? ) core:                Miscellaneous Words.
                                                            (line 18320)
* r'@ ( R:W R:W2 -- R:W R:W2 W ) gforth-1.0: Return stack.  (line  4882)
* r@ ( R:W -- R:W W ) core:              Return stack.      (line  4880)
* r/o ( -- FAM ) file:                   General files.     (line 11702)
* r/w ( -- FAM ) file:                   General files.     (line 11704)
* r> ( R:W -- W ) core:                  Return stack.      (line  4878)
* raise ( -- R ) minos2:                 widget methods.    (line 20849)
* rdrop ( R:W -- ) gforth-0.2:           Return stack.      (line  4889)
* re-color ( RGBA "NAME" -- ) minos2:    widget methods.    (line 20964)
* re-emoji-color ( RGBATEXT RGBAEMOJI "NAME" -- ) minos2: widget methods.
                                                            (line 20972)
* re-fade-color ( RGBA1 RGBA2 "NAME" -- ) minos2: widget methods.
                                                            (line 20976)
* re-text-color ( RGBA "NAME" -- ) minos2: widget methods.  (line 20968)
* re-text-emoji-fade-color ( RGBATEXT1 ~2 RGBAEMOJI1 ~2 "NAME" -- ) minos2: widget methods.
                                                            (line 20980)
* read-csv ( ADDR U XT -- ) gforth-experimental: CSV reading and writing.
                                                            (line 13223)
* read-dir ( C-ADDR U1 WDIRID -- U2 FLAG WIOR ) gforth-0.5: Directories.
                                                            (line 11858)
* read-file ( C-ADDR U1 WFILEID -- U2 WIOR ) file: General files.
                                                            (line 11729)
* read-line ( C_ADDR U1 WFILEID -- U2 FLAG WIOR ) file: General files.
                                                            (line 11735)
* rec-body ( ADDR U -- XT TRANSLATE-NUM | 0 ) gforth-experimental: Default Recognizers.
                                                            (line 10707)
* rec-complex ( ADDR U -- Z TRANSLATE-COMPLEX | 0 ) gforth-1.0: Default Recognizers.
                                                            (line 10686)
* rec-dtick ( ADDR U -- NT TRANSLATE-NUM | 0 ) gforth-experimental: Default Recognizers.
                                                            (line 10699)
* rec-env ( ADDR U -- ADDR U TRANSLATE-ENV | 0 ) gforth-1.0: Default Recognizers.
                                                            (line 10711)
* rec-float ( ADDR U -- R TRANSLATE-FLOAT | 0 ) gforth-experimental: Default Recognizers.
                                                            (line 10683)
* rec-locals ( ADDR U -- NT TRANSLATE-LOCALS | 0 ) gforth-experimental: Default Recognizers.
                                                            (line 10667)
* rec-meta ( ADDR U -- XT TRANSLATE-TO | 0 ) gforth-1.0: Default Recognizers.
                                                            (line 10716)
* rec-moof2 ( ADDR U -- XT TRANSLATE-MOOF2 | 0 ) mini-oof2: Mini-OOF2.
                                                            (line 15087)
* rec-nothing ( C-ADDR U -- 0 ) gforth-experimental: Recognizer order.
                                                            (line 10753)
* rec-nt ( ADDR U -- NT TRANSLATE-NT | 0 ) gforth-experimental: Default Recognizers.
                                                            (line 10664)
* rec-num ( ADDR U -- N/D TABLE | 0 ) gforth-experimental: Default Recognizers.
                                                            (line 10680)
* rec-scope ( ADDR U -- NT RECTYPE-NT | 0 ) gforth-experimental: Default Recognizers.
                                                            (line 10671)
* rec-string ( ADDR U -- ADDR U' SCAN-TRANSLATE-STRING | 0 ) gforth-experimental: Default Recognizers.
                                                            (line 10690)
* rec-tick ( ADDR U -- XT TRANSLATE-NUM | 0 ) gforth-experimental: Default Recognizers.
                                                            (line 10703)
* rec-to ( ADDR U -- N XT TRANSLATE-TO | 0 ) gforth-experimental: Default Recognizers.
                                                            (line 10694)
* recognizer-sequence: ( XT1 .. XTN N "NAME" -- ) gforth-experimental: Recognizer order.
                                                            (line 10732)
* recurse ( ... -- ... ) core:           Calls and returns. (line  6899)
* recursive ( COMPILATION -- ; RUN-TIME -- ) gforth-0.2: Calls and returns.
                                                            (line  6895)
* refill ( -- FLAG ) core-ext,block-ext,file-ext: The Input Stream.
                                                            (line 11085)
* rename-file ( C-ADDR1 U1 C-ADDR2 U2 -- WIOR ) file-ext: General files.
                                                            (line 11726)
* REPEAT ( COMPILATION ORIG DEST -- ; RUN-TIME -- ) core: Arbitrary control structures.
                                                            (line  6869)
* replace-word ( XT1 XT2 -- ) gforth-1.0: Debugging.        (line 16136)
* replacer: ( "NAME" -- ) gforth-experimental: Substitute.  (line 13189)
* replaces ( ADDR1 LEN1 ADDR2 LEN2 -- ) string-ext: Substitute.
                                                            (line 13185)
* reposition-file ( UD WFILEID -- WIOR ) file: General files.
                                                            (line 11775)
* represent ( R C-ADDR U -- N F1 F2 ) floating: Floating-point output.
                                                            (line 12515)
* require ( ... "FILE" -- ... ) file-ext: Forth source files.
                                                            (line 11669)
* required ( I*X ADDR U -- I*X ) file-ext: Forth source files.
                                                            (line 11663)
* resize ( A_ADDR1 U -- A_ADDR2 WIOR ) memory: Heap Allocation.
                                                            (line  5282)
* resize-file ( UD WFILEID -- WIOR ) file: General files.   (line 11779)
* resized ( -- ) minos2:                 widget methods.    (line 20918)
* restart ( TASK -- ) gforth-experimental: Basic multi-tasking.
                                                            (line 16495)
* restore ( COMPILATION ORIG1 -- ; RUN-TIME -- ) gforth-0.7: Exception Handling.
                                                            (line  7184)
* restore-input ( X1 .. XN N -- FLAG ) core-ext: Input Sources.
                                                            (line 10294)
* restrict ( -- ) gforth-0.2:            How to define immediate words.
                                                            (line  9409)
* return-stack-cells ( -- N ) environment: Environmental Queries.
                                                            (line 11455)
* reveal ( -- ) gforth-0.2:              Creating from a prototype.
                                                            (line  8340)
* reveal! ( XT WID -- ) core-ext:        Creating from a prototype.
                                                            (line  8344)
* rol ( U1 U -- U2 ) gforth-1.0:         Bitwise operations.
                                                            (line  4453)
* roll ( X0 X1 .. XN N -- X1 .. XN X0 ) core-ext: Data stack.
                                                            (line  4798)
* Root ( -- ) gforth-0.2:                Word Lists.        (line 11269)
* ror ( U1 U -- U2 ) gforth-1.0:         Bitwise operations.
                                                            (line  4456)
* rot ( W1 W2 W3 -- W2 W3 W1 ) core:     Data stack.        (line  4789)
* rp! ( A-ADDR -- ) gforth-0.2:          Stack pointer manipulation.
                                                            (line  4953)
* rp@ ( -- A-ADDR ) gforth-0.2:          Stack pointer manipulation.
                                                            (line  4951)
* rp0 ( -- A-ADDR ) gforth-0.4:          Stack pointer manipulation.
                                                            (line  4948)
* rpick ( R:WU ... R:W0 U -- R:WU ... R:W0 WU ) gforth-1.0: Return stack.
                                                            (line  4885)
* rshift ( U1 U -- U2 ) core:            Bitwise operations.
                                                            (line  4383)
* S" ( INTERPRETATION 'CCC"' -- C-ADDR U ) core,file: String and character literals.
                                                            (line  5860)
* s// ( ADDR U -- PTR ) regexp-replace:  Regular Expressions.
                                                            (line 15705)
* s\" ( INTERPRETATION 'CCC"' -- C-ADDR U ) core-ext,file-ext: String and character literals.
                                                            (line  5850)
* s+ ( C-ADDR1 U1 C-ADDR2 U2 -- C-ADDR U ) gforth-0.7: String words.
                                                            (line  6045)
* s>> ( ADDR -- ADDR ) regexp-replace:   Regular Expressions.
                                                            (line 15692)
* s>d ( N -- D ) core:                   Double precision.  (line  4059)
* s>f ( N -- R ) floating-ext:           Floating Point.    (line  4566)
* s>number? ( ADDR U -- D F ) gforth-0.5: Line input and conversion.
                                                            (line 12904)
* s>unumber? ( C-ADDR U -- UD FLAG ) gforth-0.5: Line input and conversion.
                                                            (line 12907)
* safe/string ( C-ADDR1 U1 N -- C-ADDR2 U2 ) gforth-1.0: String words.
                                                            (line  6005)
* save-buffer ( BUFFER -- ) gforth-0.2:  Blocks.            (line 12169)
* save-buffers ( -- ) block:             Blocks.            (line 12165)
* save-cov ( -- ) gforth-experimental:   Code Coverage.     (line 16359)
* save-input ( -- X1 .. XN N ) core-ext: Input Sources.     (line 10289)
* save-mem ( ADDR1 U -- ADDR2 U ) gforth-0.2: Memory blocks and heap allocation.
                                                            (line  5297)
* save-mem-dict ( ADDR1 U -- ADDR2 U ) gforth-0.7: Dictionary allocation.
                                                            (line  5095)
* savesystem ( "IMAGE" -- ) gforth-0.2:  Non-Relocatable Image Files.
                                                            (line 19832)
* scan ( C-ADDR1 U1 C -- C-ADDR2 U2 ) gforth-0.2: String words.
                                                            (line  5972)
* scan-back ( C-ADDR U1 C -- C-ADDR U2 ) gforth-0.7: String words.
                                                            (line  5977)
* scan-translate-string ( -- TRANSLATOR ) gforth-experimental: Define recognizers with existing translators.
                                                            (line 10850)
* scope ( COMPILATION -- SCOPE ; RUN-TIME -- ) gforth-0.2: Where are locals visible by name?.
                                                            (line 13489)
* scr ( -- A-ADDR ) block-ext:           Blocks.            (line 12132)
* scrolled ( AXIS DIR -- ) minos2:       actor methods.     (line 20768)
* scvalue: ( U1 "NAME" -- U2 ) gforth-experimental: Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8853)
* seal ( -- ) gforth-0.2:                Word Lists.        (line 11279)
* search ( C-ADDR1 U1 C-ADDR2 U2 -- C-ADDR3 U3 FLAG ) string: String words.
                                                            (line  5966)
* search-wordlist ( C-ADDR COUNT WID -- 0 | XT +-1 ) search: Word Lists.
                                                            (line 11245)
* see ( "<SPACES>NAME" -- ) tools:       Examining compiled code.
                                                            (line 15868)
* see-code ( "NAME" -- ) gforth-0.7:     Examining compiled code.
                                                            (line 15887)
* see-code-range ( ADDR1 ADDR2 -- ) gforth-0.7: Examining compiled code.
                                                            (line 15901)
* select ( U1 U2 F -- U ) gforth-1.0:    Boolean Flags.     (line  3988)
* selector ( "NAME" -- ) objects:        Objects Glossary.  (line 14616)
* semaphore ( "NAME" -- ) gforth-experimental: Semaphores.  (line 16565)
* send-event ( XT TASK -- ) gforth-experimental: Message queues.
                                                            (line 16642)
* set ( SOMETHING -- ) minos2:           actor methods.     (line 20807)
* set->comp ( XT -- ) gforth-1.0:        Header methods.    (line 18117)
* set->int ( XT -- ) gforth-1.0:         Header methods.    (line 18105)
* set-compsem ( XT -- ) gforth-experimental: How to define combined words.
                                                            (line  9520)
* set-current ( WID -- ) search:         Word Lists.        (line 11160)
* set-dir ( C-ADDR U -- WIOR ) gforth-0.7: Directories.     (line 11881)
* set-does> ( XT -- ) gforth-1.0:        CREATE..DOES> details.
                                                            (line  7911)
* set-execute ( CA -- ) gforth-1.0:      Header methods.    (line 18035)
* set-name>link ( XT -- ) gforth-1.0:    Header methods.    (line 18136)
* set-name>string ( XT -- ) gforth-1.0:  Header methods.    (line 18132)
* set-optimizer ( XT -- ) gforth-1.0:    User-defined compile-comma.
                                                            (line  8224)
* set-order ( WIDN .. WID1 N -- ) search: Word Lists.       (line 11179)
* set-precision ( U -- ) floating-ext:   Floating-point output.
                                                            (line 12457)
* set-stack ( X1 .. XN N STACK -- ) gforth-experimental: User-defined Stacks.
                                                            (line  9159)
* set-to ( TO-XT -- ) gforth-1.0:        Words with user-defined TO etc..
                                                            (line  8208)
* sf! ( R SF-ADDR -- ) floating-ext:     Memory Access.     (line  5394)
* sf@ ( SF-ADDR -- R ) floating-ext:     Memory Access.     (line  5390)
* sfalign ( -- ) floating-ext:           Dictionary allocation.
                                                            (line  5117)
* sfaligned ( C-ADDR -- SF-ADDR ) floating-ext: Address arithmetic.
                                                            (line  5625)
* sffield: ( U1 "NAME" -- U2 ) floating-ext: Standard Structures.
                                                            (line  8739)
* sfloat/ ( N1 -- N2 ) gforth-1.0:       Address arithmetic.
                                                            (line  5621)
* sfloat% ( -- ALIGN SIZE ) gforth-0.4:  Gforth structs.    (line  9110)
* sfloat+ ( SF-ADDR1 -- SF-ADDR2 ) floating-ext: Address arithmetic.
                                                            (line  5618)
* sfloats ( N1 -- N2 ) floating-ext:     Address arithmetic.
                                                            (line  5614)
* sfvalue: ( U1 "NAME" -- U2 ) gforth-experimental: Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8873)
* sh ( "..." -- ) gforth-0.2:            Passing Commands to the OS.
                                                            (line 18258)
* sh-get ( C-ADDR U -- C-ADDR2 U2 ) gforth-1.0: Passing Commands to the OS.
                                                            (line 18270)
* shift-args ( -- ) gforth-0.7:          OS command line arguments.
                                                            (line 13288)
* short-where ( -- ) gforth-1.0:         Locating uses of a word.
                                                            (line 15834)
* show ( -- ) minos2:                    actor methods.     (line 20798)
* show-you ( -- ) minos2:                actor methods.     (line 20810)
* sign ( N -- ) core:                    Formatted numeric output.
                                                            (line 12338)
* simple-fkey-string ( U1 -- C-ADDR U ) gforth-1.0: Single-key input.
                                                            (line 12878)
* simple-see ( "NAME" -- ) gforth-0.6:   Examining compiled code.
                                                            (line 15877)
* simple-see-range ( ADDR1 ADDR2 -- ) gforth-0.6: Examining compiled code.
                                                            (line 15884)
* skip ( C-ADDR1 U1 C -- C-ADDR2 U2 ) gforth-0.2: String words.
                                                            (line  5981)
* sleep ( TASK -- ) gforth-experimental: Basic multi-tasking.
                                                            (line 16467)
* slit, ( C-ADDR1 U -- ) gforth-1.0:     Literals.          (line  9896)
* SLiteral ( COMPILATION C-ADDR1 U -- ; RUN-TIME -- C-ADDR2 U ) string: Literals.
                                                            (line  9890)
* slurp-fid ( FID -- ADDR U ) gforth-0.6: General files.    (line 11784)
* slurp-file ( C-ADDR1 U1 -- C-ADDR2 U2 ) gforth-0.6: General files.
                                                            (line 11781)
* slvalue: ( U1 "NAME" -- U2 ) gforth-experimental: Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8861)
* sm/rem ( D1 N1 -- N2 N3 ) core:        Integer division.  (line  4167)
* source ( -- C-ADDR U ) core:           The Text Interpreter.
                                                            (line 10230)
* source-id ( -- 0 | -1 | FILEID ) core-ext,file: Input Sources.
                                                            (line 10280)
* sourcefilename ( -- C-ADDR U ) gforth-0.2: Forth source files.
                                                            (line 11681)
* sourceline# ( -- U ) gforth-0.2:       Forth source files.
                                                            (line 11688)
* sp! ( A-ADDR -- S:... ) gforth-0.2:    Stack pointer manipulation.
                                                            (line  4939)
* sp@ ( S:... -- A-ADDR ) gforth-0.2:    Stack pointer manipulation.
                                                            (line  4937)
* sp0 ( -- A-ADDR ) gforth-0.4:          Stack pointer manipulation.
                                                            (line  4934)
* space ( -- ) core:                     Miscellaneous output.
                                                            (line 12529)
* spaces ( U -- ) core:                  Miscellaneous output.
                                                            (line 12532)
* span ( -- C-ADDR ) core-ext-obsolescent: Line input and conversion.
                                                            (line 12952)
* spawn ( XT -- ) cilk:                  Cilk.              (line 16695)
* spawn1 ( X XT -- ) cilk:               Cilk.              (line 16701)
* spawn2 ( X1 X2 XT -- ) cilk:           Cilk.              (line 16704)
* split ( FIRSTFLAG RSTART1 RX -- O RSTART2 ) minos2: widget methods.
                                                            (line 20873)
* stack ( N -- STACK ) gforth-experimental: User-defined Stacks.
                                                            (line  9135)
* stack-cells ( -- N ) environment:      Environmental Queries.
                                                            (line 11458)
* stack: ( N "NAME" -- ) gforth-experimental: User-defined Stacks.
                                                            (line  9138)
* stack> ( STACK -- X ) gforth-experimental: User-defined Stacks.
                                                            (line  9141)
* stacksize ( -- U ) gforth-experimental: Basic multi-tasking.
                                                            (line 16414)
* stacksize4 ( -- U-DATA U-RETURN U-FP U-LOCALS ) gforth-experimental: Basic multi-tasking.
                                                            (line 16417)
* staged/-divisor ( ADDR1 -- ADDR2 ) gforth-1.0: Two-stage integer division.
                                                            (line  4336)
* staged/-size ( -- U ) gforth-1.0:      Two-stage integer division.
                                                            (line  4294)
* state ( -- A-ADDR ) core,tools-ext:    The Text Interpreter.
                                                            (line 10247)
* static ( -- ) oof:                     Class Declaration. (line 14850)
* status-color ( -- ) gforth-1.0:        Terminal output.   (line 12666)
* stderr ( -- WFILEID ) gforth-0.2:      General files.     (line 11793)
* stdin ( -- WFILEID ) gforth-0.4:       General files.     (line 11787)
* stdout ( -- WFILEID ) gforth-0.2:      General files.     (line 11790)
* stop ( -- ) gforth-experimental:       Basic multi-tasking.
                                                            (line 16470)
* stop-dns ( DTIMEOUT -- ) gforth-experimental: Basic multi-tasking.
                                                            (line 16476)
* stop-ns ( TIMEOUT -- ) gforth-experimental: Basic multi-tasking.
                                                            (line 16473)
* str< ( C-ADDR1 U1 C-ADDR2 U2 -- F ) gforth-0.6: String words.
                                                            (line  5957)
* str= ( C-ADDR1 U1 C-ADDR2 U2 -- F ) gforth-0.6: String words.
                                                            (line  5954)
* str=? ( ADDR1 ADDR U -- ADDR2 ) regexp-pattern: Regular Expressions.
                                                            (line 15628)
* string-parse ( C-ADDR1 U1 "CCC<STRING>" -- C-ADDR2 U2 ) gforth-1.0: The Input Stream.
                                                            (line 11060)
* string-prefix? ( C-ADDR1 U1 C-ADDR2 U2 -- F ) gforth-0.6: String words.
                                                            (line  5960)
* string-suffix? ( C-ADDR1 U1 C-ADDR2 U2 -- F ) gforth-1.0: String words.
                                                            (line  5963)
* string, ( C-ADDR U -- ) gforth-0.2:    Counted string words.
                                                            (line  6240)
* struct ( -- ALIGN SIZE ) gforth-0.2:   Gforth structs.    (line  9115)
* sub-list? ( LIST1 LIST2 -- F ) gforth-internal: Locals implementation.
                                                            (line 13842)
* substitute ( ADDR1 LEN1 ADDR2 LEN2 -- ADDR2 LEN3 N/IOR ) string-ext: Substitute.
                                                            (line 13201)
* success-color ( -- ) gforth-1.0:       Terminal output.   (line 12660)
* swap ( W1 W2 -- W2 W1 ) core:          Data stack.        (line  4787)
* swvalue: ( U1 "NAME" -- U2 ) gforth-experimental: Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8857)
* Synonym ( "NAME" "OLDNAME" -- ) tools-ext: Synonyms.      (line  8621)
* system ( C-ADDR U -- ) gforth-0.2:     Passing Commands to the OS.
                                                            (line 18262)
* table ( -- WID ) gforth-0.2:           Word Lists.        (line 11190)
* task ( USTACKSIZE "NAME" -- ) gforth-experimental: Basic multi-tasking.
                                                            (line 16402)
* text-color: ( RGBA "NAME" -- ) minos2: widget methods.    (line 20944)
* text-emoji-color: ( RGBATEXT RGBAEMOJI "NAME" -- ) minos2: widget methods.
                                                            (line 20948)
* text-emoji-fade-color: ( RGBATEXT1 ~2 RGBAEMOJI1 ~2 "NAME" -- ) minos2: widget methods.
                                                            (line 20958)
* THEN ( COMPILATION ORIG -- ; RUN-TIME -- ) core: Arbitrary control structures.
                                                            (line  6824)
* third ( W1 W2 W3 -- W1 W2 W3 W1 ) gforth-1.0: Data stack. (line  4783)
* this ( -- OBJECT ) objects:            Objects Glossary.  (line 14621)
* thread-deadline ( D -- ) gforth-experimental: Basic multi-tasking.
                                                            (line 16480)
* threading-method ( -- N ) gforth-0.2:  Threading Words.   (line 18173)
* throw ( Y1 .. YM NERROR -- Y1 .. YM / Z1 .. ZN NERROR ) exception: Exception Handling.
                                                            (line  6970)
* thru ( I*X N1 N2 -- J*X ) block-ext:   Blocks.            (line 12177)
* tib ( -- ADDR ) core-ext-obsolescent:  The Text Interpreter.
                                                            (line 10239)
* time&date ( -- NSEC NMIN NHOUR NDAY NMONTH NYEAR ) facility-ext: Keeping track of Time.
                                                            (line 18291)
* TO ( VALUE ... "NAME" -- ) core-ext:   Values.            (line  7437)
* to-class: ( XT TABLE "NAME" -- ) gforth-experimental: Words with user-defined TO etc..
                                                            (line  8195)
* to-table: ( "NAME" "TO-WORD" "+TO-WORD" "ADDR-WORD" "ACTION-OF-WORD" "IS-WORD" -- ) gforth-experimental: Words with user-defined TO etc..
                                                            (line  8162)
* to-this ( OBJECT -- ) objects:         Objects Glossary.  (line 14630)
* touchdown ( $RXY*N BMASK -- ) minos2:  actor methods.     (line 20771)
* touchup ( $RXY*N BMASK -- ) minos2:    actor methods.     (line 20774)
* toupper ( C1 -- C2 ) gforth-0.2:       Characters.        (line  5766)
* translate-complex ( -- TRANSLATOR ) gforth-experimental: Define recognizers with existing translators.
                                                            (line 10841)
* translate-dnum ( -- TRANSLATOR ) gforth-experimental: Define recognizers with existing translators.
                                                            (line 10833)
* translate-env ( -- TRANSLATOR ) gforth-experimental: Define recognizers with existing translators.
                                                            (line 10857)
* translate-float ( -- TRANSLATOR ) gforth-experimental: Define recognizers with existing translators.
                                                            (line 10837)
* translate-nt ( -- TRANSLATOR ) gforth-experimental: Define recognizers with existing translators.
                                                            (line 10822)
* translate-num ( -- TRANSLATOR ) gforth-experimental: Define recognizers with existing translators.
                                                            (line 10829)
* translate-string ( -- TRANSLATOR ) gforth-experimental: Define recognizers with existing translators.
                                                            (line 10845)
* translate-to ( -- TRANSLATOR ) gforth-experimental: Define recognizers with existing translators.
                                                            (line 10863)
* translate: ( INT-XT COMP-XT POST-XT "NAME" -- ) gforth-experimental: Defining translators.
                                                            (line 10907)
* traverse-wordlist ( ... XT WID -- ... ) tools-ext: Name token.
                                                            (line  9682)
* true ( -- F ) core-ext:                Boolean Flags.     (line  3976)
* try ( COMPILATION -- ORIG ; RUN-TIME -- R:SYS1 ) gforth-0.5: Exception Handling.
                                                            (line  7106)
* try-recognize ( C-ADDR U XT -- ... TRANSLATOR | 0 ) gforth-experimental: Define recognizers with existing translators.
                                                            (line 10882)
* tt ( U -- ) gforth-1.0:                Locating exception source.
                                                            (line 15854)
* tuck ( W1 W2 -- W2 W1 W2 ) core-ext:   Data stack.        (line  4793)
* type ( C-ADDR U -- ) core:             Displaying characters and strings.
                                                            (line 12595)
* typewhite ( ADDR N -- ) gforth-0.2:    Displaying characters and strings.
                                                            (line 12606)
* u-[do ( COMPILATION -- DO-SYS ; RUN-TIME U1 U2 -- | LOOP-SYS ) gforth-experimental: Counted Loops.
                                                            (line  6552)
* U-DO ( COMPILATION -- DO-SYS ; RUN-TIME U1 U2 -- | LOOP-SYS ) gforth-0.2: Counted Loops.
                                                            (line  6560)
* u. ( U -- ) core:                      Simple numeric output.
                                                            (line 12237)
* u.r ( U N -- ) core-ext:               Simple numeric output.
                                                            (line 12247)
* u*/ ( U1 U2 U3 -- U4 ) gforth-1.0:     Integer division.  (line  4185)
* u*/mod ( U1 U2 U3 -- U4 U5 ) gforth-1.0: Integer division.
                                                            (line  4200)
* u/ ( U1 U2 -- U ) gforth-1.0:          Integer division.  (line  4136)
* u/-stage1m ( U A-RECI -- ) gforth-1.0: Two-stage integer division.
                                                            (line  4314)
* u/-stage2m ( U1 A-RECI -- UQUOTIENT ) gforth-1.0: Two-stage integer division.
                                                            (line  4318)
* u/mod ( U1 U2 -- U3 U4 ) gforth-1.0:   Integer division.  (line  4156)
* u/mod-stage2m ( U1 A-RECI -- UMODULUS UQUOTIENT ) gforth-1.0: Two-stage integer division.
                                                            (line  4326)
* U+DO ( COMPILATION -- DO-SYS ; RUN-TIME U1 U2 -- | LOOP-SYS ) gforth-0.2: Counted Loops.
                                                            (line  6539)
* u< ( U1 U2 -- F ) core:                Numeric comparison.
                                                            (line  4496)
* u<= ( U1 U2 -- F ) gforth-0.2:         Numeric comparison.
                                                            (line  4498)
* u> ( U1 U2 -- F ) core-ext:            Numeric comparison.
                                                            (line  4500)
* u>= ( U1 U2 -- F ) gforth-0.2:         Numeric comparison.
                                                            (line  4502)
* uallot ( N1 -- N2 ) gforth-0.3:        Task-local data.   (line 16525)
* ud. ( UD -- ) gforth-0.2:              Simple numeric output.
                                                            (line 12258)
* ud.r ( UD N -- ) gforth-0.2:           Simple numeric output.
                                                            (line 12267)
* ud/mod ( UD1 U2 -- UREM UDQUOT ) gforth-0.2: Integer division.
                                                            (line  4206)
* UDefer ( "NAME" -- ) gforth-1.0:       Task-local data.   (line 16533)
* ukeyed ( ADDR U -- ) minos2:           actor methods.     (line 20777)
* um* ( U1 U2 -- UD ) core:              Mixed precision.   (line  4082)
* um/mod ( UD U1 -- U2 U3 ) core:        Integer division.  (line  4170)
* umax ( U1 U2 -- U ) gforth-1.0:        Single precision.  (line  4036)
* umin ( U1 U2 -- U ) gforth-0.5:        Single precision.  (line  4034)
* umod ( U1 U2 -- U ) gforth-1.0:        Integer division.  (line  4145)
* umod-stage2m ( U1 A-RECI -- UMODULUS ) gforth-1.0: Two-stage integer division.
                                                            (line  4322)
* uncolored-mode ( -- ) gforth-1.0:      Terminal output.   (line 12684)
* under+ ( N1 N2 N3 -- N N2 ) gforth-0.3: Single precision. (line  4017)
* unescape ( ADDR1 U1 DEST -- DEST U2 ) string-ext: Substitute.
                                                            (line 13206)
* unlock ( SEMAPHORE -- ) gforth-experimental: Semaphores.  (line 16572)
* unloop ( R:W1 R:W2 -- ) core:          Counted Loops.     (line  6618)
* UNREACHABLE ( -- ) gforth-0.2:         Where are locals visible by name?.
                                                            (line 13528)
* UNTIL ( COMPILATION DEST -- ; RUN-TIME F -- ) core: Arbitrary control structures.
                                                            (line  6832)
* unused ( -- U ) core-ext:              Dictionary allocation.
                                                            (line  5041)
* unused-words ( -- ) gforth-1.0:        Locating uses of a word.
                                                            (line 15848)
* up@ ( -- A-ADDR ) new:                 Task-local data.   (line 16539)
* update ( -- ) block:                   Blocks.            (line 12158)
* updated? ( N -- F ) gforth-0.2:        Blocks.            (line 12161)
* use ( "FILE" -- ) gforth-0.2:          Blocks.            (line 12112)
* User ( "NAME" -- ) gforth-0.2:         Task-local data.   (line 16516)
* user' ( "NAME" -- U ) gforth-experimental: Task-local data.
                                                            (line 16543)
* utime ( -- DTIME ) gforth-0.5:         Keeping track of Time.
                                                            (line 18300)
* UValue ( "NAME" -- ) gforth-1.0:       Task-local data.   (line 16529)
* v* ( F-ADDR1 NSTRIDE1 F-ADDR2 NSTRIDE2 UCOUNT -- R ) gforth-0.5: Floating Point.
                                                            (line  4639)
* Value ( W "NAME" -- ) core-ext:        Values.            (line  7415)
* value: ( U1 "NAME" -- U2 ) gforth-experimental: Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8838)
* value[]: ( U1 "NAME" -- U2 ) gforth-experimental: Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8922)
* var ( M V SIZE "NAME" -- M V' ) mini-oof2: Basic Mini-OOF Usage.
                                                            (line 14884)
* var ( SIZE -- ) oof:                   Class Declaration. (line 14824)
* Variable ( "NAME" -- ) core:           Variables.         (line  7333)
* vglue ( -- RTYP RSUB RADD ) minos2:    widget methods.    (line 20885)
* vglue@ ( -- RTYP RSUB RADD ) minos2:   widget methods.    (line 20894)
* vlist ( -- ) gforth-0.2:               Word Lists.        (line 11257)
* Vocabulary ( "NAME" -- ) gforth-0.2:   Word Lists.        (line 11274)
* vocs ( -- ) gforth-0.2:                Word Lists.        (line 11283)
* vp-bottom ( O:VP -- ) minos2:          widget methods.    (line 20992)
* vp-left ( O:VP -- ) minos2:            widget methods.    (line 20995)
* vp-needed ( XT -- ) minos2:            widget methods.    (line 21004)
* vp-reslide ( O:VP -- ) minos2:         widget methods.    (line 21001)
* vp-right ( O:VP -- ) minos2:           widget methods.    (line 20998)
* vp-top ( O:VP -- ) minos2:             widget methods.    (line 20989)
* w ( -- R ) minos2:                     widget methods.    (line 20831)
* w-color ( -- R ) minos2:               widget methods.    (line 20864)
* w, ( X -- ) gforth-1.0:                Dictionary allocation.
                                                            (line  5069)
* W: ( COMPILATION "NAME" -- A-ADDR XT; RUN-TIME X -- ) gforth-0.2: Locals definition words.
                                                            (line 13446)
* w! ( W C-ADDR -- ) gforth-0.7:         Special Memory Accesses.
                                                            (line  5442)
* w@ ( C-ADDR -- U ) gforth-0.5:         Special Memory Accesses.
                                                            (line  5439)
* w/o ( -- FAM ) file:                   General files.     (line 11706)
* W^ ( COMPILATION "NAME" -- A-ADDR XT; RUN-TIME X -- ) gforth-0.2: Locals definition words.
                                                            (line 13449)
* w>s ( X -- N ) gforth-1.0:             Special Memory Accesses.
                                                            (line  5507)
* wake ( TASK -- ) gforth-experimental:  Basic multi-tasking.
                                                            (line 16492)
* walign ( -- ) gforth-1.0:              Address arithmetic.
                                                            (line  5658)
* waligned ( ADDR -- ADDR' ) gforth-1.0: Address arithmetic.
                                                            (line  5655)
* warning-color ( -- ) gforth-1.0:       Terminal output.   (line 12654)
* WARNING" ( COMPILATION 'CCC"' -- ; RUN-TIME F -- ) gforth-1.0: Exception Handling.
                                                            (line  7234)
* warnings ( -- ADDR ) gforth-0.2:       Exception Handling.
                                                            (line  7237)
* wbe ( U1 -- U2 ) gforth-1.0:           Special Memory Accesses.
                                                            (line  5468)
* wfield: ( U1 "NAME" -- U2 ) gforth-1.0: Standard Structures.
                                                            (line  8745)
* where ( "NAME" -- ) gforth-1.0:        Locating uses of a word.
                                                            (line 15800)
* whereg ( "NAME" -- ) gforth-1.0:       Locating uses of a word.
                                                            (line 15829)
* WHILE ( COMPILATION DEST -- ORIG DEST ; RUN-TIME F -- ) core: Arbitrary control structures.
                                                            (line  6864)
* widget ( -- CLASS ) minos2:            MINOS2 object framework.
                                                            (line 20750)
* within ( U1 U2 U3 -- F ) core-ext:     Numeric comparison.
                                                            (line  4504)
* wle ( U1 -- U2 ) gforth-1.0:           Special Memory Accesses.
                                                            (line  5472)
* word ( CHAR "<CHARS>CCC<CHAR>-- C-ADDR ) core: The Input Stream.
                                                            (line 11075)
* wordlist ( -- WID ) search:            Word Lists.        (line 11187)
* wordlist-words ( WID -- ) gforth-0.6:  Word Lists.        (line 11260)
* wordlists ( -- N ) environment:        Environmental Queries.
                                                            (line 11468)
* words ( -- ) tools:                    Word Lists.        (line 11253)
* wrap-xt ( ... XT1 XT2 XT3 -- ... ) gforth-1.0: Deferred Words.
                                                            (line  8566)
* write-file ( C-ADDR U1 WFILEID -- WIOR ) file: General files.
                                                            (line 11763)
* write-line ( C-ADDR U WFILEID -- IOR ) file: General files.
                                                            (line 11765)
* wrol ( U1 U -- U2 ) gforth-1.0:        Bitwise operations.
                                                            (line  4437)
* wror ( U1 U -- U2 ) gforth-1.0:        Bitwise operations.
                                                            (line  4441)
* WTF?? ( -- ) gforth-1.0:               Debugging.         (line 16130)
* wvalue: ( U1 "NAME" -- U2 ) gforth-experimental: Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8845)
* ww ( U -- ) gforth-1.0:                Locating uses of a word.
                                                            (line 15806)
* x ( -- R ) minos2:                     widget methods.    (line 20825)
* x-size ( XC-ADDR U1 -- U2 ) xchar:     Xchars and Unicode.
                                                            (line 13032)
* x-width ( XC-ADDR U -- N ) xchar-ext:  Xchars and Unicode.
                                                            (line 13086)
* x, ( X -- ) gforth-1.0:                Dictionary allocation.
                                                            (line  5077)
* x! ( W C-ADDR -- ) gforth-1.0:         Special Memory Accesses.
                                                            (line  5454)
* x@ ( C-ADDR -- U ) gforth-1.0:         Special Memory Accesses.
                                                            (line  5451)
* x\string- ( XC-ADDR U1 -- XC-ADDR U2 ) xchar-ext: Xchars and Unicode.
                                                            (line 13075)
* x>s ( X -- N ) gforth-1.0:             Special Memory Accesses.
                                                            (line  5513)
* xalign ( -- ) gforth-1.0:              Address arithmetic.
                                                            (line  5670)
* xaligned ( ADDR -- ADDR' ) gforth-1.0: Address arithmetic.
                                                            (line  5667)
* xbe ( U1 -- U2 ) gforth-1.0:           Special Memory Accesses.
                                                            (line  5484)
* xc-size ( XC -- U ) xchar:             Xchars and Unicode.
                                                            (line 13029)
* xc-width ( XC -- N ) xchar-ext:        Xchars and Unicode.
                                                            (line 13096)
* xc, ( XCHAR -- ) xchar:                Xchars and Unicode.
                                                            (line 13103)
* xc!+ ( XC XC-ADDR1 -- XC-ADDR2 ) xchar: Xchars and Unicode.
                                                            (line 13055)
* xc!+? ( XC XC-ADDR1 U1 -- XC-ADDR2 U2 F ) xchar: Xchars and Unicode.
                                                            (line 13047)
* xc@ ( XC-ADDR -- XC ) xchar-ext:       Xchars and Unicode.
                                                            (line 13036)
* xc@+ ( XC-ADDR1 -- XC-ADDR2 XC ) xchar: Xchars and Unicode.
                                                            (line 13039)
* xc@+? ( XC-ADDR1 U1 -- XC-ADDR2 U2 XC ) gforth-experimental: Xchars and Unicode.
                                                            (line 13043)
* xchar- ( XC-ADDR1 -- XC-ADDR2 ) xchar-ext: Xchars and Unicode.
                                                            (line 13066)
* XCHAR-ENCODING ( -- ADDR U ) environment: Environmental Queries.
                                                            (line 11475)
* XCHAR-MAXMEM ( -- U ) environment:     Environmental Queries.
                                                            (line 11485)
* xchar+ ( XC-ADDR1 -- XC-ADDR2 ) xchar: Xchars and Unicode.
                                                            (line 13062)
* xd, ( XD -- ) gforth-1.0:              Dictionary allocation.
                                                            (line  5081)
* xd! ( UD C-ADDR -- ) gforth-1.0:       Special Memory Accesses.
                                                            (line  5460)
* xd@ ( C-ADDR -- UD ) gforth-1.0:       Special Memory Accesses.
                                                            (line  5457)
* xd>s ( XD -- D ) gforth-1.0:           Special Memory Accesses.
                                                            (line  5516)
* xdbe ( UD1 -- UD2 ) gforth-1.0:        Special Memory Accesses.
                                                            (line  5492)
* xdle ( UD1 -- UD2 ) gforth-1.0:        Special Memory Accesses.
                                                            (line  5496)
* xemit ( XC -- ) xchar:                 Displaying characters and strings.
                                                            (line 12599)
* xfield: ( U1 "NAME" -- U2 ) gforth-1.0: Standard Structures.
                                                            (line  8751)
* xhold ( XC -- ) xchar-ext:             Xchars and Unicode.
                                                            (line 13099)
* xkey ( -- XC ) xchar:                  Xchars and Unicode.
                                                            (line 13092)
* xkey? ( -- FLAG ) xchar:               Single-key input.  (line 12718)
* xle ( U1 -- U2 ) gforth-1.0:           Special Memory Accesses.
                                                            (line  5488)
* xor ( W1 W2 -- W ) core:               Bitwise operations.
                                                            (line  4371)
* xt-locate ( NT/XT -- ) gforth-1.0:     Locating source code definitions.
                                                            (line 15749)
* xt-new ( ... CLASS XT -- OBJECT ) objects: Objects Glossary.
                                                            (line 14633)
* xt-see ( XT -- ) gforth-0.2:           Examining compiled code.
                                                            (line 15874)
* xt-see-code ( XT -- ) gforth-1.0:      Examining compiled code.
                                                            (line 15898)
* xt-simple-see ( XT -- ) gforth-1.0:    Examining compiled code.
                                                            (line 15881)
* XT: ( COMPILATION "NAME" -- A-ADDR XT; RUN-TIME XT1 -- ) gforth-1.0: Locals definition words.
                                                            (line 13473)
* xt>name ( XT -- NT ) gforth-1.0:       Name token.        (line  9676)
* xywh ( -- RX0 RY0 RW RH ) minos2:      widget methods.    (line 20897)
* xywhd ( -- RX RY RW RH RD ) minos2:    widget methods.    (line 20900)
* y ( -- R ) minos2:                     widget methods.    (line 20828)
* z: ( COMPILATION "NAME" -- A-ADDR XT; RUN-TIME Z -- ) gforth-1.0: Locals definition words.
                                                            (line 13470)
* zvalue: ( U1 "NAME" -- U2 ) gforth-experimental: Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8881)

Concept and Word Index
**********************

Not all entries listed in this index are present verbatim in the text.
This index also duplicates, in abbreviated form, all of the words listed
in the Word Index (only the names are listed for the words here).

* Menu:

* -:                                     Single precision.  (line  4020)
* --:                                    Locals definition words.
                                                            (line 13421)
* -->:                                   Blocks.            (line 12188)
* -, tutorial:                           Stack-Effect Comments Tutorial.
                                                            (line  1398)
* -[do:                                  Counted Loops.     (line  6547)
* -\d:                                   Regular Expressions.
                                                            (line 15605)
* -\s:                                   Regular Expressions.
                                                            (line 15608)
* -`:                                    Regular Expressions.
                                                            (line 15616)
* ->here:                                Dictionary allocation.
                                                            (line  5052)
* -appl-image, command-line option:      Invoking Gforth.   (line   547)
* -application, gforthmi option:         gforthmi.          (line 19895)
* -c?:                                   Regular Expressions.
                                                            (line 15593)
* -char:                                 Regular Expressions.
                                                            (line 15571)
* -class:                                Regular Expressions.
                                                            (line 15583)
* -clear-dictionary, command-line option: Invoking Gforth.  (line   643)
* -code-block-size, command-line option: Invoking Gforth.   (line   729)
* -d, command-line option:               Invoking Gforth.   (line   578)
* -D, command-line option:               Invoking Gforth.   (line   624)
* -data-stack-size, command-line option: Invoking Gforth.   (line   578)
* -debug-mcheck, command-line option:    Invoking Gforth.   (line   631)
* -debug, command-line option:           Invoking Gforth.   (line   628)
* -DFORCE_REG:                           Portability.       (line 20137)
* -diag, command-line option:            Invoking Gforth.   (line   624)
* -dictionary-size, command-line option: Invoking Gforth.   (line   568)
* -die-on-signal, command-line-option:   Invoking Gforth.   (line   647)
* -DO:                                   Counted Loops.     (line  6557)
* -DUSE_FTOS:                            TOS Optimization.  (line 20498)
* -DUSE_NO_FTOS:                         TOS Optimization.  (line 20498)
* -DUSE_NO_TOS:                          TOS Optimization.  (line 20486)
* -DUSE_TOS:                             TOS Optimization.  (line 20486)
* -dynamic command-line option:          Dynamic Superinstructions.
                                                            (line 20369)
* -dynamic, command-line option:         Invoking Gforth.   (line   665)
* -enable-force-reg, configuration flag: Portability.       (line 20137)
* -f, command-line option:               Invoking Gforth.   (line   588)
* -fp-stack-size, command-line option:   Invoking Gforth.   (line   588)
* -h, command-line option:               Invoking Gforth.   (line   616)
* -help, command-line option:            Invoking Gforth.   (line   616)
* -i, command-line option:               Invoking Gforth.   (line   542)
* -i, invoke image file:                 Running Image Files.
                                                            (line 19955)
* -ignore-async-signals, command-line-option: Invoking Gforth.
                                                            (line   658)
* -image file, invoke image file:        Running Image Files.
                                                            (line 19955)
* -image-file, command-line option:      Invoking Gforth.   (line   542)
* -inf:                                  Floating Point.    (line  4701)
* -infinity:                             Floating Point.    (line  4698)
* -l, command-line option:               Invoking Gforth.   (line   594)
* -locals-stack-size, command-line option: Invoking Gforth. (line   594)
* -LOOP:                                 Counted Loops.     (line  6591)
* -ltrace:                               Debugging.         (line 16148)
* -m, command-line option:               Invoking Gforth.   (line   568)
* -map_32bit, command-line option:       Invoking Gforth.   (line   599)
* -no-0rc, command-line option:          Invoking Gforth.   (line   553)
* -no-dynamic command-line option:       Dynamic Superinstructions.
                                                            (line 20357)
* -no-dynamic-image, command-line option: Invoking Gforth.  (line   670)
* -no-dynamic, command-line option:      Invoking Gforth.   (line   665)
* -no-offset-im, command-line option:    Invoking Gforth.   (line   640)
* -no-super command-line option:         Dynamic Superinstructions.
                                                            (line 20357)
* -no-super, command-line option:        Invoking Gforth.   (line   675)
* -offset-image, command-line option:    Invoking Gforth.   (line   635)
* -opt-ip-updates, command-line option:  Invoking Gforth.   (line   713)
* -p, command-line option:               Invoking Gforth.   (line   557)
* -path, command-line option:            Invoking Gforth.   (line   557)
* -print-metrics, command-line option:   Invoking Gforth.   (line   733)
* -print-nonreloc, command-line option:  Invoking Gforth.   (line   762)
* -print-prims, command-line option:     Invoking Gforth.   (line   744)
* -print-sequences, command-line option: Invoking Gforth.   (line   765)
* -r, command-line option:               Invoking Gforth.   (line   583)
* -return-stack-size, command-line option: Invoking Gforth. (line   583)
* -rot:                                  Data stack.        (line  4791)
* -ss-greedy, command-line option:       Invoking Gforth.   (line   700)
* -ss-min-..., command-line options:     Invoking Gforth.   (line   686)
* -ss-number, command-line option:       Invoking Gforth.   (line   680)
* -stack:                                User-defined Stacks.
                                                            (line  9156)
* -tpa-noautomaton, command-line option: Invoking Gforth.   (line   769)
* -tpa-noequiv, command-line option:     Invoking Gforth.   (line   769)
* -tpa-trace, command-line option:       Invoking Gforth.   (line   806)
* -trailing:                             String words.      (line  5997)
* -trailing-garbage:                     Xchars and Unicode.
                                                            (line 13081)
* -v, command-line option:               Invoking Gforth.   (line   620)
* -version, command-line option:         Invoking Gforth.   (line   620)
* -vm-commit, command-line option:       Invoking Gforth.   (line   604)
* -W, command-line option:               Invoking Gforth.   (line   844)
* -Wall, command-line option:            Invoking Gforth.   (line   850)
* -Werror, command-line option:          Invoking Gforth.   (line   856)
* -Won, command-line option:             Invoking Gforth.   (line   847)
* -Wpedantic, command-line option:       Invoking Gforth.   (line   853)
* ,:                                     Dictionary allocation.
                                                            (line  5062)
* ;:                                     Colon Definitions. (line  7505)
* ;]:                                    Quotations.        (line  7643)
* ;>:                                    How do I write outer locals?.
                                                            (line 15525)
* ;abi-code:                             Assembler Definitions.
                                                            (line 17216)
* ;code:                                 Assembler Definitions.
                                                            (line 17239)
* ;CODE ending sequence:                 programming-idef.  (line 19282)
* ;CODE, name not defined via CREATE:    programming-ambcond.
                                                            (line 19314)
* ;CODE, processing input:               programming-idef.  (line 19285)
* ;inline:                               Inline Definitions.
                                                            (line  7521)
* ;m:                                    Objects Glossary.  (line 14583)
* ;m usage:                              Method conveniences.
                                                            (line 14199)
* ::                                     Colon Definitions. (line  7503)
* :, passing data across:                Literals.          (line  9902)
* :::                                    Basic Mini-OOF Usage.
                                                            (line 14902)
* :}:                                    Locals definition words.
                                                            (line 13430)
* :}d:                                   Closures.          (line 15315)
* :}h:                                   Closures.          (line 15319)
* :}h1:                                  Closures.          (line 15324)
* :}l:                                   Closures.          (line 15311)
* :}xt:                                  Closures.          (line 15329)
* :is:                                   Deferred Words.    (line  8520)
* :m:                                    Objects Glossary.  (line 14579)
* :method:                               Mini-OOF2.         (line 15097)
* :noname:                               Anonymous Definitions.
                                                            (line  7576)
* !:                                     Memory Access.     (line  5357)
* !!FIXME!!:                             Debugging.         (line 16133)
* !@:                                    Memory Access.     (line  5363)
* !localn:                               Locals implementation.
                                                            (line 13758)
* !resize:                               widget methods.    (line 20903)
* !size:                                 widget methods.    (line 20906)
* ?:                                     Examining data.    (line 16030)
* ???:                                   Debugging.         (line 16127)
* ?cov+:                                 Code Coverage.     (line 16322)
* ?DO:                                   Counted Loops.     (line  6533)
* ?dup:                                  Data stack.        (line  4800)
* ?DUP-0=-IF:                            Arbitrary control structures.
                                                            (line  6884)
* ?dup-IF:                               Arbitrary control structures.
                                                            (line  6879)
* ?errno-throw:                          Exception Handling.
                                                            (line  7028)
* ?events:                               Message queues.    (line 16651)
* ?EXIT:                                 Calls and returns. (line  6960)
* ?found:                                Performing translator actions.
                                                            (line 10995)
* ?inside:                               actor methods.     (line 20783)
* ?ior:                                  Exception Handling.
                                                            (line  7031)
* ?LEAVE:                                Counted Loops.     (line  6615)
* ?of:                                   General control structures with CASE.
                                                            (line  6782)
* .:                                     Simple numeric output.
                                                            (line 12221)
* .?:                                    Regular Expressions.
                                                            (line 15602)
* ...:                                   Examining data.    (line 15984)
* ..char:                                Regular Expressions.
                                                            (line 15574)
* .":                                    Miscellaneous output.
                                                            (line 12546)
* .", how it works:                      How does that work?.
                                                            (line  3462)
* .(:                                    Miscellaneous output.
                                                            (line 12552)
* .\":                                   Miscellaneous output.
                                                            (line 12543)
* .cover-raw:                            Code Coverage.     (line 16342)
* .coverage:                             Code Coverage.     (line 16329)
* .debugline:                            Debugging.         (line 16105)
* .emacs:                                Installing gforth.el.
                                                            (line 19567)
* .fi files:                             Image Files.       (line 19704)
* .fpath:                                Source Search Paths.
                                                            (line 11935)
* .gforth-history:                       Command-line editing.
                                                            (line   929)
* .hm:                                   Header methods.    (line 18018)
* .id:                                   Name token.        (line  9703)
* .included:                             Forth source files.
                                                            (line 11678)
* .locale-csv:                           i18n and l10n.     (line 13164)
* .path:                                 General Search Paths.
                                                            (line 11975)
* .quoted-csv:                           CSV reading and writing.
                                                            (line 13238)
* .r:                                    Simple numeric output.
                                                            (line 12241)
* .recognizers:                          Default Recognizers.
                                                            (line 10660)
* .s:                                    Examining data.    (line 15987)
* .sections:                             Sections.          (line  5230)
* .substitute:                           Substitute.        (line 13193)
* .unresolved:                           Calls and returns. (line  6934)
* .voc:                                  Word Lists.        (line 11224)
* .widget:                               widget methods.    (line 20912)
* ':                                     Execution token.   (line  9574)
* '-prefix for characters/code points:   Integer and character literals.
                                                            (line  3640)
* ', stack item type:                    Notation.          (line  3918)
* 'cold:                                 Modifying the Startup Sequence.
                                                            (line 20073)
* 's:                                    Task-local data.   (line 16547)
* ", stack item type:                    Notation.          (line  3915)
* (:                                     Comments.          (line  3950)
* ((:                                    Regular Expressions.
                                                            (line 15554)
* (local):                               Standard Forth locals.
                                                            (line 13894)
* ):                                     Assertions.        (line 16197)
* )):                                    Regular Expressions.
                                                            (line 15557)
* [:                                     Literals.          (line  9848)
* [::                                    Quotations.        (line  7640)
* [?DO]:                                 Interpreter Directives.
                                                            (line 10438)
* [']:                                   Execution token.   (line  9577)
* [{::                                   Closures.          (line 15297)
* [+LOOP]:                               Interpreter Directives.
                                                            (line 10444)
* [AGAIN]:                               Interpreter Directives.
                                                            (line 10464)
* [BEGIN]:                               Interpreter Directives.
                                                            (line 10460)
* [bind]:                                Objects Glossary.  (line 14491)
* [bind] usage:                          Class Binding.     (line 14154)
* [char]:                                String and character literals.
                                                            (line  5889)
* [COMP']:                               Compilation token. (line  9781)
* [compile]:                             Macros.            (line 10153)
* [current]:                             Objects Glossary.  (line 14524)
* [d:d:                                  Closures.          (line 15258)
* [d:h:                                  Closures.          (line 15264)
* [d:h1:                                 Closures.          (line 15270)
* [d:l:                                  Closures.          (line 15252)
* [defined]:                             Interpreter Directives.
                                                            (line 10420)
* [DO]:                                  Interpreter Directives.
                                                            (line 10440)
* [ELSE]:                                Interpreter Directives.
                                                            (line 10404)
* [ENDIF]:                               Interpreter Directives.
                                                            (line 10417)
* [f:d:                                  Closures.          (line 15260)
* [f:h:                                  Closures.          (line 15266)
* [f:h1:                                 Closures.          (line 15272)
* [f:l:                                  Closures.          (line 15254)
* [FOR]:                                 Interpreter Directives.
                                                            (line 10446)
* [I]:                                   Interpreter Directives.
                                                            (line 10450)
* [IF]:                                  Interpreter Directives.
                                                            (line 10396)
* [IF] and POSTPONE:                     programming-ambcond.
                                                            (line 19319)
* [IF], end of the input source before matching [ELSE] or [THEN]: programming-ambcond.
                                                            (line 19323)
* [IFDEF]:                               Interpreter Directives.
                                                            (line 10428)
* [IFUNDEF]:                             Interpreter Directives.
                                                            (line 10433)
* [LOOP]:                                Interpreter Directives.
                                                            (line 10442)
* [n:d:                                  Closures.          (line 15256)
* [n:h:                                  Closures.          (line 15262)
* [n:h1:                                 Closures.          (line 15268)
* [n:l:                                  Closures.          (line 15250)
* [NEXT]:                                Interpreter Directives.
                                                            (line 10448)
* [noop]:                                Execution token.   (line  9634)
* [parent]:                              Objects Glossary.  (line 14602)
* [parent] usage:                        Class Binding.     (line 14173)
* [REPEAT]:                              Interpreter Directives.
                                                            (line 10468)
* [THEN]:                                Interpreter Directives.
                                                            (line 10413)
* [to-inst]:                             Objects Glossary.  (line 14627)
* [undefined]:                           Interpreter Directives.
                                                            (line 10424)
* [UNTIL]:                               Interpreter Directives.
                                                            (line 10462)
* [WHILE]:                               Interpreter Directives.
                                                            (line 10466)
* ]:                                     Literals.          (line  9851)
* ]]:                                    Macros.            (line  9970)
* ]L:                                    Literals.          (line  9868)
* ]nocov:                                Code Coverage.     (line 16313)
* {:                                     Locals definition words.
                                                            (line 13433)
* {::                                    Locals definition words.
                                                            (line 13418)
* {{:                                    Regular Expressions.
                                                            (line 15669)
* {*:                                    Regular Expressions.
                                                            (line 15649)
* {**:                                   Regular Expressions.
                                                            (line 15637)
* {+:                                    Regular Expressions.
                                                            (line 15655)
* {++:                                   Regular Expressions.
                                                            (line 15643)
* }:                                     Locals definition words.
                                                            (line 13437)
* }}:                                    Regular Expressions.
                                                            (line 15675)
* @:                                     Memory Access.     (line  5354)
* @localn:                               Locals implementation.
                                                            (line 13754)
* *:                                     Single precision.  (line  4024)
* *}:                                    Regular Expressions.
                                                            (line 15652)
* **}:                                   Regular Expressions.
                                                            (line 15640)
* */:                                    Integer division.  (line  4176)
* */f:                                   Integer division.  (line  4182)
* */mod:                                 Integer division.  (line  4188)
* */modf:                                Integer division.  (line  4196)
* */mods:                                Integer division.  (line  4192)
* */s:                                   Integer division.  (line  4179)
* *align:                                Address arithmetic.
                                                            (line  5652)
* *aligned:                              Address arithmetic.
                                                            (line  5648)
* /:                                     Integer division.  (line  4129)
* //:                                    Regular Expressions.
                                                            (line 15664)
* //g:                                   Regular Expressions.
                                                            (line 15714)
* //o:                                   Regular Expressions.
                                                            (line 15711)
* //s:                                   Regular Expressions.
                                                            (line 15708)
* /COUNTED-STRING:                       Environmental Queries.
                                                            (line 11423)
* /f:                                    Integer division.  (line  4134)
* /f-stage1m:                            Two-stage integer division.
                                                            (line  4297)
* /f-stage2m:                            Two-stage integer division.
                                                            (line  4301)
* /HOLD:                                 Environmental Queries.
                                                            (line 11426)
* /l:                                    Address arithmetic.
                                                            (line  5680)
* /mod:                                  Integer division.  (line  4147)
* /modf:                                 Integer division.  (line  4153)
* /modf-stage2m:                         Two-stage integer division.
                                                            (line  4309)
* /mods:                                 Integer division.  (line  4150)
* /PAD:                                  Environmental Queries.
                                                            (line 11429)
* /s:                                    Integer division.  (line  4132)
* /string:                               String words.      (line  6001)
* /w:                                    Address arithmetic.
                                                            (line  5677)
* /x:                                    Address arithmetic.
                                                            (line  5683)
* \:                                     Comments.          (line  3957)
* \, editing with Emacs:                 Emacs and Gforth.  (line 19536)
* \, line length in blocks:              block-idef.        (line 18957)
* \(:                                    Regular Expressions.
                                                            (line 15681)
* \):                                    Regular Expressions.
                                                            (line 15684)
* \\\:                                   Forth source files.
                                                            (line 11675)
* \^:                                    Regular Expressions.
                                                            (line 15622)
* \$:                                    Regular Expressions.
                                                            (line 15625)
* \0:                                    Regular Expressions.
                                                            (line 15687)
* \c:                                    Declaring C Functions.
                                                            (line 16862)
* \d:                                    Regular Expressions.
                                                            (line 15596)
* \G:                                    Comments.          (line  3963)
* \s:                                    Regular Expressions.
                                                            (line 15599)
* &-prefix for decimal numbers:          Integer and character literals.
                                                            (line  3612)
* #:                                     Formatted numeric output.
                                                            (line 12319)
* #-prefix for decimal numbers:          Integer and character literals.
                                                            (line  3612)
* #!:                                    Running Image Files.
                                                            (line 20017)
* #>:                                    Formatted numeric output.
                                                            (line 12342)
* #>>:                                   Formatted numeric output.
                                                            (line 12349)
* #bell:                                 String and character literals.
                                                            (line  5931)
* #bs:                                   String and character literals.
                                                            (line  5927)
* #cr:                                   String and character literals.
                                                            (line  5923)
* #del:                                  String and character literals.
                                                            (line  5929)
* #eof:                                  String and character literals.
                                                            (line  5935)
* #esc:                                  String and character literals.
                                                            (line  5933)
* #ff:                                   String and character literals.
                                                            (line  5925)
* #lf:                                   String and character literals.
                                                            (line  5921)
* #line:                                 Interpreter Directives.
                                                            (line 10477)
* #loc:                                  Debugging.         (line 16151)
* #locals:                               Environmental Queries.
                                                            (line 11465)
* #s:                                    Formatted numeric output.
                                                            (line 12324)
* #tab:                                  String and character literals.
                                                            (line  5919)
* #tib:                                  The Text Interpreter.
                                                            (line 10241)
* %-prefix for binary numbers:           Integer and character literals.
                                                            (line  3612)
* %align:                                Gforth structs.    (line  9070)
* %alignment:                            Gforth structs.    (line  9073)
* %alloc:                                Gforth structs.    (line  9076)
* %allocate:                             Gforth structs.    (line  9080)
* %allot:                                Gforth structs.    (line  9084)
* %size:                                 Gforth structs.    (line  9112)
* `:                                     Regular Expressions.
                                                            (line 15611)
* ` prefix:                              Execution token.   (line  9564)
* ` prefix of word:                      Literals for tokens and addresses.
                                                            (line  3727)
* `?:                                    Regular Expressions.
                                                            (line 15614)
* `` prefix of word:                     Literals for tokens and addresses.
                                                            (line  3733)
* +:                                     Single precision.  (line  4013)
* +!:                                    Memory Access.     (line  5360)
* +!@:                                   Memory Access.     (line  5367)
* +}:                                    Regular Expressions.
                                                            (line 15658)
* ++}:                                   Regular Expressions.
                                                            (line 15646)
* +after:                                User-defined Stacks.
                                                            (line  9153)
* +char:                                 Regular Expressions.
                                                            (line 15568)
* +chars:                                Regular Expressions.
                                                            (line 15577)
* +class:                                Regular Expressions.
                                                            (line 15580)
* +DO:                                   Counted Loops.     (line  6536)
* +field:                                Standard Structures.
                                                            (line  8774)
* +fmode:                                General files.     (line 11710)
* +load:                                 Blocks.            (line 12180)
* +LOOP:                                 Counted Loops.     (line  6588)
* +ltrace:                               Debugging.         (line 16145)
* +thru:                                 Blocks.            (line 12184)
* +TO:                                   Values.            (line  7445)
* +to _name_ semantics, changing them:   Words with user-defined TO etc..
                                                            (line  8092)
* +x/string:                             Xchars and Unicode.
                                                            (line 13070)
* <:                                     Numeric comparison.
                                                            (line  4472)
* <{::                                   How do I write outer locals?.
                                                            (line 15522)
* <#:                                    Formatted numeric output.
                                                            (line 12310)
* <<:                                    Regular Expressions.
                                                            (line 15699)
* <<":                                   Regular Expressions.
                                                            (line 15702)
* <<#:                                   Formatted numeric output.
                                                            (line 12313)
* <=:                                    Numeric comparison.
                                                            (line  4474)
* <>:                                    Numeric comparison.
                                                            (line  4476)
* <bind>:                                Objects Glossary.  (line 14485)
* <to-inst>:                             Objects Glossary.  (line 14624)
* =:                                     Numeric comparison.
                                                            (line  4478)
* =":                                    Regular Expressions.
                                                            (line 15631)
* =mkdir:                                Directories.       (line 11885)
* >:                                     Numeric comparison.
                                                            (line  4480)
* >=:                                    Numeric comparison.
                                                            (line  4482)
* >>:                                    Regular Expressions.
                                                            (line 15695)
* >addr:                                 Closures.          (line 15334)
* >animate:                              widget methods.    (line 20930)
* >back:                                 User-defined Stacks.
                                                            (line  9147)
* >body:                                 CREATE..DOES> details.
                                                            (line  7943)
* >BODY of non-CREATEd words:            core-ambcond.      (line 18906)
* >code-address:                         Threading Words.   (line 18177)
* >definer:                              Threading Words.   (line 18238)
* >does-code:                            Threading Words.   (line 18220)
* >float:                                Line input and conversion.
                                                            (line 12923)
* >float1:                               Line input and conversion.
                                                            (line 12931)
* >in:                                   The Text Interpreter.
                                                            (line 10234)
* >IN greater than input buffer:         core-ambcond.      (line 18838)
* >l:                                    Locals implementation.
                                                            (line 13766)
* >name:                                 Name token.        (line  9668)
* >number:                               Line input and conversion.
                                                            (line 12910)
* >o:                                    Mini-OOF2.         (line 15077)
* >order:                                Word Lists.        (line 11199)
* >pow2:                                 Bitwise operations.
                                                            (line  4417)
* >r:                                    Return stack.      (line  4876)
* >stack:                                User-defined Stacks.
                                                            (line  9144)
* >string-execute:                       String words.      (line  6054)
* >time&date&tz:                         Keeping track of Time.
                                                            (line 18295)
* >uvalue:                               Words with user-defined TO etc..
                                                            (line  8200)
* |:                                     Locals definition words.
                                                            (line 13426)
* ||:                                    Regular Expressions.
                                                            (line 15672)
* ~~:                                    Debugging.         (line 16099)
* ~~, removal with Emacs:                Emacs and Gforth.  (line 19536)
* ~~1bt:                                 Debugging.         (line 16124)
* ~~bt:                                  Debugging.         (line 16121)
* ~~Value:                               Debugging.         (line 16142)
* ~~Variable:                            Debugging.         (line 16139)
* $-prefix for hexadecimal numbers:      Integer and character literals.
                                                            (line  3612)
* $!:                                    $tring words.      (line  6094)
* $!len:                                 $tring words.      (line  6104)
* $?:                                    Passing Commands to the OS.
                                                            (line 18274)
* $.:                                    $tring words.      (line  6143)
* $[]:                                   $tring words.      (line  6161)
* $[]!:                                  $tring words.      (line  6165)
* $[].:                                  $tring words.      (line  6194)
* $[]@:                                  $tring words.      (line  6177)
* $[]#:                                  $tring words.      (line  6181)
* $[]+!:                                 $tring words.      (line  6169)
* $[]free:                               $tring words.      (line  6197)
* $[]map:                                $tring words.      (line  6184)
* $[]slurp:                              $tring words.      (line  6188)
* $[]slurp-file:                         $tring words.      (line  6191)
* $[]Variable:                           $tring words.      (line  6206)
* $@:                                    $tring words.      (line  6098)
* $@len:                                 $tring words.      (line  6101)
* $+!:                                   $tring words.      (line  6118)
* $+!len:                                $tring words.      (line  6108)
* $+[]!:                                 $tring words.      (line  6173)
* $+slurp:                               $tring words.      (line  6153)
* $+slurp-file:                          $tring words.      (line  6157)
* $del:                                  $tring words.      (line  6112)
* $exec:                                 $tring words.      (line  6139)
* $free:                                 $tring words.      (line  6124)
* $init:                                 $tring words.      (line  6127)
* $ins:                                  $tring words.      (line  6115)
* $iter:                                 $tring words.      (line  6130)
* $over:                                 $tring words.      (line  6135)
* $slurp:                                $tring words.      (line  6146)
* $slurp-file:                           $tring words.      (line  6150)
* $split:                                String words.      (line  5986)
* $substitute:                           Substitute.        (line 13197)
* $tmp:                                  String words.      (line  6060)
* $unescape:                             Substitute.        (line 13212)
* $value::                               Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8885)
* $value[]::                             Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8926)
* $Variable:                             $tring words.      (line  6202)
* 0<:                                    Numeric comparison.
                                                            (line  4484)
* 0<=:                                   Numeric comparison.
                                                            (line  4486)
* 0<>:                                   Numeric comparison.
                                                            (line  4488)
* 0=:                                    Numeric comparison.
                                                            (line  4490)
* 0>:                                    Numeric comparison.
                                                            (line  4492)
* 0>=:                                   Numeric comparison.
                                                            (line  4494)
* 0x-prefix for hexadecimal numbers:     Integer and character literals.
                                                            (line  3612)
* 1-:                                    Single precision.  (line  4022)
* 1/f:                                   Floating Point.    (line  4634)
* 1+:                                    Single precision.  (line  4015)
* 2,:                                    Dictionary allocation.
                                                            (line  5065)
* 2!:                                    Memory Access.     (line  5381)
* 2@:                                    Memory Access.     (line  5377)
* 2*:                                    Bitwise operations.
                                                            (line  4402)
* 2/:                                    Bitwise operations.
                                                            (line  4405)
* 2>r:                                   Return stack.      (line  4891)
* 2Constant:                             Constants.         (line  7385)
* 2drop:                                 Data stack.        (line  4804)
* 2dup:                                  Data stack.        (line  4808)
* 2field::                               Standard Structures.
                                                            (line  8733)
* 2Literal:                              Literals.          (line  9874)
* 2nip:                                  Data stack.        (line  4806)
* 2over:                                 Data stack.        (line  4810)
* 2r@:                                   Return stack.      (line  4895)
* 2r>:                                   Return stack.      (line  4893)
* 2rdrop:                                Return stack.      (line  4897)
* 2rot:                                  Data stack.        (line  4814)
* 2swap:                                 Data stack.        (line  4812)
* 2tuck:                                 Data stack.        (line  4816)
* 2Value:                                Values.            (line  7425)
* 2value::                               Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8865)
* 2Variable:                             Variables.         (line  7341)
* a_, stack item type:                   Notation.          (line  3896)
* A,:                                    Dictionary allocation.
                                                            (line  5085)
* abi-code:                              Assembler Definitions.
                                                            (line 17208)
* abort:                                 Exception Handling.
                                                            (line  7227)
* ABORT":                                Exception Handling.
                                                            (line  7222)
* ABORT", exception abort sequence:      core-idef.         (line 18610)
* abs:                                   Single precision.  (line  4028)
* absolute-file?:                        Search Paths.      (line 11920)
* abstract class:                        Basic Objects Usage.
                                                            (line 14054)
* abstract class <1>:                    Basic OOF Usage.   (line 14692)
* accept:                                Line input and conversion.
                                                            (line 12891)
* ACCEPT, display after end of input:    core-idef.         (line 18606)
* ACCEPT, editing:                       core-idef.         (line 18552)
* AConstant:                             Constants.         (line  7381)
* act:                                   widget methods.    (line 20819)
* act-name$:                             actor methods.     (line 20762)
* action-of:                             Deferred Words.    (line  8491)
* action-of _name_ semantics, changing them: Words with user-defined TO etc..
                                                            (line  8092)
* activate:                              Basic multi-tasking.
                                                            (line 16435)
* active-w:                              actor methods.     (line 20759)
* actor:                                 MINOS2 object framework.
                                                            (line 20747)
* add-cflags:                            Declaring OS-level libraries.
                                                            (line 17021)
* add-framework:                         Declaring OS-level libraries.
                                                            (line 17014)
* add-incdir:                            Declaring OS-level libraries.
                                                            (line 17018)
* add-ldflags:                           Declaring OS-level libraries.
                                                            (line 17024)
* add-lib:                               Declaring OS-level libraries.
                                                            (line 17006)
* add-libpath:                           Declaring OS-level libraries.
                                                            (line 17010)
* addr:                                  Values.            (line  7477)
* addr _name_ semantics, changing them:  Words with user-defined TO etc..
                                                            (line  8092)
* address alignment exception:           core-ambcond.      (line 18859)
* address alignment exception, stack overflow: core-ambcond.
                                                            (line 18761)
* address arithmetic words:              Address arithmetic.
                                                            (line  5527)
* address unit:                          Address arithmetic.
                                                            (line  5535)
* address unit, size in bits:            core-idef.         (line 18646)
* ADDRESS-UNIT-BITS:                     Environmental Queries.
                                                            (line 11417)
* addressable::                          Values.            (line  7472)
* adjust-buffer:                         Growable memory buffers.
                                                            (line  5336)
* after-locate:                          Locating source code definitions.
                                                            (line 15780)
* AGAIN:                                 Arbitrary control structures.
                                                            (line  6837)
* AHEAD:                                 Arbitrary control structures.
                                                            (line  6820)
* Alias:                                 Synonyms.          (line  8631)
* aliases:                               Synonyms.          (line  8610)
* align:                                 Dictionary allocation.
                                                            (line  5109)
* aligned:                               Address arithmetic.
                                                            (line  5592)
* aligned addresses:                     core-idef.         (line 18542)
* alignment faults:                      core-ambcond.      (line 18859)
* alignment of addresses for types:      Address arithmetic.
                                                            (line  5547)
* alignment tutorial:                    Alignment Tutorial.
                                                            (line  2134)
* ALiteral:                              Literals.          (line  9864)
* allocate:                              Heap Allocation.   (line  5269)
* allot:                                 Dictionary allocation.
                                                            (line  5045)
* also:                                  Word Lists.        (line 11205)
* also-path:                             General Search Paths.
                                                            (line 11972)
* also, too many word lists in search order: search-ambcond.
                                                            (line 19357)
* ambiguous conditions, block words:     block-ambcond.     (line 18962)
* ambiguous conditions, core words:      core-ambcond.      (line 18726)
* ambiguous conditions, double words:    double-ambcond.    (line 18998)
* ambiguous conditions, facility words:  facility-ambcond.  (line 19043)
* ambiguous conditions, file words:      file-ambcond.      (line 19110)
* ambiguous conditions, floating-point words: floating-ambcond.
                                                            (line 19169)
* ambiguous conditions, locals words:    locals-ambcond.    (line 19255)
* ambiguous conditions, programming-tools words: programming-ambcond.
                                                            (line 19301)
* ambiguous conditions, search-order words: search-ambcond. (line 19345)
* and:                                   Bitwise operations.
                                                            (line  4367)
* angles in trigonometric operations:    Floating Point.    (line  4649)
* annotate-cov:                          Code Coverage.     (line 16332)
* ans-report.fs:                         Standard Report.   (line 18400)
* append:                                String words.      (line  6049)
* arg:                                   OS command line arguments.
                                                            (line 13280)
* argc:                                  OS command line arguments.
                                                            (line 13294)
* argument input source different than current input source for RESTORE-INPUT: core-ambcond.
                                                            (line 18845)
* argument type mismatch:                core-ambcond.      (line 18739)
* argument type mismatch, RESTORE-INPUT: core-ambcond.      (line 18845)
* arguments, OS command line:            OS command line arguments.
                                                            (line 13245)
* argv:                                  OS command line arguments.
                                                            (line 13298)
* arithmetic words:                      Arithmetic.        (line  3994)
* arithmetics tutorial:                  Arithmetics Tutorial.
                                                            (line  1194)
* array, iterating over:                 Counted Loops.     (line  6480)
* array>mem:                             Counted Loops.     (line  6563)
* arrays:                                CREATE.            (line  7293)
* arrays tutorial:                       Arrays and Records Tutorial.
                                                            (line  2649)
* arshift:                               Bitwise operations.
                                                            (line  4387)
* asptr:                                 Class Declaration. (line 14832)
* assembler:                             Assembler and Code Words.
                                                            (line 17172)
* assembler <1>:                         Assembler Definitions.
                                                            (line 17201)
* ASSEMBLER, search order capability:    programming-idef.  (line 19290)
* assert-level:                          Assertions.        (line 16213)
* assert(:                               Assertions.        (line 16194)
* assert0(:                              Assertions.        (line 16181)
* assert1(:                              Assertions.        (line 16184)
* assert2(:                              Assertions.        (line 16187)
* assert3(:                              Assertions.        (line 16190)
* assertions:                            Assertions.        (line 16157)
* assignment conversion:                 How do I write outer locals?.
                                                            (line 15400)
* ASSUME-LIVE:                           Where are locals visible by name?.
                                                            (line 13620)
* at-deltaxy:                            Terminal output.   (line 12619)
* at-xy:                                 Terminal output.   (line 12615)
* AT-XY can't be performed on user output device: facility-ambcond.
                                                            (line 19044)
* atomic operations:                     Hardware operations for multi-tasking.
                                                            (line 16588)
* atomic!@:                              Hardware operations for multi-tasking.
                                                            (line 16595)
* atomic?!@:                             Hardware operations for multi-tasking.
                                                            (line 16603)
* atomic+!@:                             Hardware operations for multi-tasking.
                                                            (line 16599)
* Attempt to use zero-length string as a name: core-ambcond.
                                                            (line 18832)
* au (address unit):                     Address arithmetic.
                                                            (line  5535)
* AUser:                                 Task-local data.   (line 16521)
* authors:                               Help on Gforth.    (line   885)
* authors of Gforth:                     Origin.            (line 21061)
* auto-indentation of Forth code in Emacs: Auto-Indentation.
                                                            (line 19640)
* AValue:                                Values.            (line  7421)
* AVariable:                             Variables.         (line  7337)
* b:                                     Locating source code definitions.
                                                            (line 15766)
* back>:                                 User-defined Stacks.
                                                            (line  9150)
* backtrace:                             Error messages.    (line 18332)
* backtrace examination:                 Locating exception source.
                                                            (line 15854)
* backtraces with gforth-fast:           Error messages.    (line 18379)
* barrier:                               Hardware operations for multi-tasking.
                                                            (line 16615)
* base:                                  Number Conversion. (line 10330)
* base is not decimal (REPRESENT, F., FE., FS.): floating-ambcond.
                                                            (line 19189)
* base-execute:                          Number Conversion. (line 10326)
* baseline:                              widget methods.    (line 20843)
* basename:                              Directories.       (line 11842)
* basic objects usage:                   Basic Objects Usage.
                                                            (line 14040)
* batch processing with Gforth:          Invoking Gforth.   (line   813)
* before-line:                           Text Interpreter Hooks.
                                                            (line 11024)
* before-locate:                         Locating source code definitions.
                                                            (line 15777)
* before-word:                           Text Interpreter Hooks.
                                                            (line 11027)
* BEGIN:                                 Arbitrary control structures.
                                                            (line  6828)
* begin-structure:                       Standard Structures.
                                                            (line  8722)
* benchmarking Forth systems:            Performance.       (line 20531)
* Benchres:                              Performance.       (line 20611)
* big-endian:                            Special Memory Accesses.
                                                            (line  5409)
* bin:                                   General files.     (line 11708)
* bind:                                  Objects Glossary.  (line 14482)
* bind usage:                            Class Binding.     (line 14158)
* bind':                                 Objects Glossary.  (line 14488)
* bitwise operation words:               Bitwise operations.
                                                            (line  4367)
* bl:                                    String and character literals.
                                                            (line  5916)
* blank:                                 Memory Blocks.     (line  5730)
* blk:                                   Input Sources.     (line 10285)
* BLK, altering BLK:                     block-ambcond.     (line 18975)
* block:                                 Blocks.            (line 12136)
* block buffers:                         Blocks.            (line 12030)
* block number invalid:                  block-ambcond.     (line 18972)
* block read not possible:               block-ambcond.     (line 18963)
* block transfer, I/O exception:         block-ambcond.     (line 18968)
* block words, ambiguous conditions:     block-ambcond.     (line 18962)
* block words, implementation-defined options: block-idef.  (line 18952)
* block words, other system documentation: block-other.     (line 18986)
* block words, system documentation:     The optional Block word set.
                                                            (line 18949)
* block-included:                        Blocks.            (line 12195)
* block-offset:                          Blocks.            (line 12115)
* block-position:                        Blocks.            (line 12125)
* blocks:                                Blocks.            (line 11996)
* blocks file:                           Blocks.            (line 12019)
* blocks files, use with Emacs:          Blocks Files.      (line 19676)
* blocks in files:                       file-idef.         (line 19097)
* blocks.fb:                             Blocks.            (line 12025)
* body-relative address input format:    Literals for tokens and addresses.
                                                            (line  3736)
* Boolean flags:                         Boolean Flags.     (line  3971)
* bootmessage:                           Modifying the Startup Sequence.
                                                            (line 20078)
* border:                                widget methods.    (line 20852)
* borderl:                               widget methods.    (line 20861)
* bordert:                               widget methods.    (line 20858)
* borderv:                               widget methods.    (line 20855)
* bounds:                                Counted Loops.     (line  6542)
* break::                                Singlestep Debugger.
                                                            (line 16292)
* break":                                Singlestep Debugger.
                                                            (line 16294)
* broken-pipe-error:                     Pipes.             (line 12980)
* browse:                                Locating source code definitions.
                                                            (line 15791)
* bt:                                    Locating exception source.
                                                            (line 15858)
* buffer:                                Blocks.            (line 12143)
* buffer::                               Variables.         (line  7351)
* buffer%:                               Growable memory buffers.
                                                            (line  5331)
* bug reporting:                         Bugs.              (line 21034)
* bw:                                    Locating uses of a word.
                                                            (line 15814)
* bw-cover:                              Code Coverage.     (line 16349)
* bye:                                   Leaving Gforth.    (line   868)
* bye during gforthmi:                   gforthmi.          (line 19905)
* byte order:                            Special Memory Accesses.
                                                            (line  5409)
* C function pointers to Forth words:    Callbacks.         (line 17030)
* C function pointers, calling from Forth: Calling C function pointers.
                                                            (line 16887)
* C functions, calls to:                 Calling C Functions.
                                                            (line 16732)
* C functions, declarations:             Declaring C Functions.
                                                            (line 16792)
* C interface:                           C Interface.       (line 16716)
* c_, stack item type:                   Notation.          (line  3898)
* c-callback:                            Callbacks.         (line 17040)
* c-callback-thread:                     Callbacks.         (line 17045)
* c-function:                            Declaring C Functions.
                                                            (line 16865)
* c-funptr:                              Calling C function pointers.
                                                            (line 16892)
* c-library:                             Defining library interfaces.
                                                            (line 16967)
* c-library-name:                        Defining library interfaces.
                                                            (line 16961)
* c-value:                               Declaring C Functions.
                                                            (line 16869)
* c-variable:                            Declaring C Functions.
                                                            (line 16873)
* c,:                                    Dictionary allocation.
                                                            (line  5055)
* c, stack item type:                    Notation.          (line  3879)
* C, using C for the engine:             Portability.       (line 20110)
* C::                                    Locals definition words.
                                                            (line 13458)
* c!:                                    Memory Access.     (line  5374)
* c?:                                    Regular Expressions.
                                                            (line 15590)
* C":                                    Counted string words.
                                                            (line  6228)
* c@:                                    Memory Access.     (line  5371)
* C^:                                    Locals definition words.
                                                            (line 13461)
* c++-library:                           Defining library interfaces.
                                                            (line 16970)
* c++-library-name:                      Defining library interfaces.
                                                            (line 16964)
* c>s:                                   Special Memory Accesses.
                                                            (line  5504)
* c$+!:                                  $tring words.      (line  6121)
* call-c:                                Low-Level C Interface Words.
                                                            (line 17095)
* Callback functions written in Forth:   Callbacks.         (line 17030)
* caller-w:                              actor methods.     (line 20756)
* calling a definition:                  Calls and returns. (line  6889)
* calling C functions:                   Calling C Functions.
                                                            (line 16732)
* capscompare:                           String words.      (line  6028)
* capssearch:                            String words.      (line  6039)
* capsstring-prefix?:                    String words.      (line  6035)
* case:                                  General control structures with CASE.
                                                            (line  6765)
* case as generalized control structure: General control structures with CASE.
                                                            (line  6695)
* CASE control structure:                Selection.         (line  6295)
* case sensitivity:                      Case insensitivity.
                                                            (line  3930)
* case-sensitivity characteristics:      core-idef.         (line 18691)
* case-sensitivity for name lookup:      core-idef.         (line 18569)
* catch:                                 Exception Handling.
                                                            (line  7057)
* catch and backtraces:                  Error messages.    (line 18368)
* catch and this:                        Objects Implementation.
                                                            (line 14405)
* catch in m: ... ;m:                    Method conveniences.
                                                            (line 14202)
* catch-nobt:                            Exception Handling.
                                                            (line  7063)
* cell:                                  Address arithmetic.
                                                            (line  5589)
* cell size:                             core-idef.         (line 18671)
* cell-:                                 Address arithmetic.
                                                            (line  5582)
* cell-aligned addresses:                core-idef.         (line 18542)
* cell/:                                 Address arithmetic.
                                                            (line  5585)
* cell%:                                 Gforth structs.    (line  9088)
* cell+:                                 Address arithmetic.
                                                            (line  5579)
* cells:                                 Address arithmetic.
                                                            (line  5576)
* CFA:                                   Threading Words.   (line 18143)
* cfield::                               Standard Structures.
                                                            (line  8727)
* changing the compilation word list (during compilation): search-ambcond.
                                                            (line 19346)
* char:                                  String and character literals.
                                                            (line  5885)
* char size:                             core-idef.         (line 18674)
* char-:                                 Address arithmetic.
                                                            (line  5573)
* char%:                                 Gforth structs.    (line  9090)
* char+:                                 Address arithmetic.
                                                            (line  5570)
* character editing of ACCEPT and EXPECT: core-idef.        (line 18552)
* character encoding:                    Characters.        (line  5743)
* character literals:                    String and character literals.
                                                            (line  5796)
* character set:                         core-idef.         (line 18559)
* character strings - displaying:        Displaying characters and strings.
                                                            (line 12595)
* character strings - moving and copying: Memory Blocks.    (line  5696)
* character strings - representations:   String representations.
                                                            (line  5773)
* character-aligned address requirements: core-idef.        (line 18564)
* character-set extensions and matching of names: core-idef.
                                                            (line 18569)
* Characters - chars/bytes vs. extended characters: Characters.
                                                            (line  5743)
* characters - displaying:               Displaying characters and strings.
                                                            (line 12595)
* characters tutorial:                   Characters and Strings Tutorial.
                                                            (line  2085)
* charclass:                             Regular Expressions.
                                                            (line 15565)
* chars:                                 Address arithmetic.
                                                            (line  5567)
* child class:                           Object-Oriented Terminology.
                                                            (line 13980)
* child words:                           User-defined defining words using CREATE.
                                                            (line  7747)
* cilk-bye:                              Cilk.              (line 16710)
* cilk-init:                             Cilk.              (line 16692)
* cilk-sync:                             Cilk.              (line 16707)
* class:                                 Object-Oriented Terminology.
                                                            (line 13947)
* class <1>:                             Objects Glossary.  (line 14494)
* class <2>:                             Basic Mini-OOF Usage.
                                                            (line 14888)
* class binding:                         Class Binding.     (line 14145)
* class binding as optimization:         Class Binding.     (line 14178)
* class binding, alternative to:         Class Binding.     (line 14160)
* class binding, implementation:         Objects Implementation.
                                                            (line 14401)
* class declaration:                     Class Declaration. (line 14822)
* class definition, restrictions:        Basic Objects Usage.
                                                            (line 14092)
* class definition, restrictions <1>:    Basic OOF Usage.   (line 14725)
* class implementation and representation: Objects Implementation.
                                                            (line 14386)
* class scoping implementation:          Objects Implementation.
                                                            (line 14420)
* class usage:                           Basic Objects Usage.
                                                            (line 14042)
* class usage <1>:                       Basic OOF Usage.   (line 14680)
* class->map:                            Objects Glossary.  (line 14498)
* class-inst-size:                       Objects Glossary.  (line 14503)
* class-inst-size discussion:            Creating objects.  (line 14117)
* class-override!:                       Objects Glossary.  (line 14507)
* class-previous:                        Objects Glossary.  (line 14510)
* class;:                                Class Declaration. (line 14858)
* class; usage:                          Basic OOF Usage.   (line 14680)
* class>order:                           Objects Glossary.  (line 14514)
* classes and scoping:                   Classes and Scoping.
                                                            (line 14258)
* clear screen:                          Terminal output.   (line 12627)
* clear-libs:                            Declaring OS-level libraries.
                                                            (line 17003)
* clear-path:                            General Search Paths.
                                                            (line 11969)
* clearstack:                            Examining data.    (line 16019)
* clearstacks:                           Examining data.    (line 16025)
* clicked:                               actor methods.     (line 20765)
* clock tick duration:                   facility-idef.     (line 19030)
* close-dir:                             Directories.       (line 11869)
* close-file:                            General files.     (line 11722)
* close-pipe:                            Pipes.             (line 12970)
* closure conversion:                    How do I read outer locals?.
                                                            (line 15363)
* closures:                              Closures.          (line 15174)
* cmove:                                 Memory Blocks.     (line  5714)
* cmove>:                                Memory Blocks.     (line  5719)
* code:                                  Assembler Definitions.
                                                            (line 17232)
* code address:                          Threading Words.   (line 18143)
* code coverage:                         Code Coverage.     (line 16299)
* CODE ending sequence:                  programming-idef.  (line 19282)
* code field:                            Threading Words.   (line 18143)
* code space:                            Memory model.      (line  4973)
* code words:                            Assembler and Code Words.
                                                            (line 17172)
* code-address!:                         Threading Words.   (line 18180)
* CODE, processing input:                programming-idef.  (line 19285)
* colon definitions:                     Colon Definitions. (line  7492)
* colon definitions <1>:                 Anonymous Definitions.
                                                            (line  7573)
* colon definitions, nesting:            Quotations.        (line  7619)
* colon definitions, tutorial:           Colon Definitions Tutorial.
                                                            (line  1349)
* colon-sys, passing data across ::      Literals.          (line  9902)
* color-cover:                           Code Coverage.     (line 16352)
* color::                                widget methods.    (line 20938)
* combined word:                         How to define combined words.
                                                            (line  9415)
* command line arguments, OS:            OS command line arguments.
                                                            (line 13245)
* command-line editing:                  Command-line editing.
                                                            (line   894)
* command-line options:                  Invoking Gforth.   (line   516)
* comment editing commands:              Emacs and Gforth.  (line 19536)
* comments:                              Comments.          (line  3946)
* comments tutorial:                     Comments Tutorial. (line  1320)
* common-list:                           Locals implementation.
                                                            (line 13840)
* comp-i.fs:                             gforthmi.          (line 19867)
* comp.lang.forth:                       Forth-related information.
                                                            (line 21122)
* COMP':                                 Compilation token. (line  9784)
* compare:                               String words.      (line  5948)
* compare and swap:                      Hardware operations for multi-tasking.
                                                            (line 16603)
* comparison of object models:           Comparison with other object models.
                                                            (line 15104)
* comparison tutorial:                   Flags and Comparisons Tutorial.
                                                            (line  1673)
* compilation and interpretation semantics, arbitrary combination: How to define combined words.
                                                            (line  9415)
* compilation semantics:                 How does that work?.
                                                            (line  3375)
* compilation semantics tutorial:        Interpretation and Compilation Semantics and Immediacy Tutorial.
                                                            (line  2342)
* compilation semantics, default:        What semantics do normal definitions have?.
                                                            (line  9321)
* compilation semantics, usage:          Where are compilation semantics used?.
                                                            (line  9223)
* compilation token:                     Compilation token. (line  9764)
* compilation tokens, tutorial:          Compilation Tokens Tutorial.
                                                            (line  2812)
* compilation word list:                 Word Lists.        (line 11134)
* compilation word list, change before definition ends: search-ambcond.
                                                            (line 19346)
* compile state:                         The Text Interpreter.
                                                            (line 10167)
* compile-color:                         Terminal output.   (line 12669)
* compile-only:                          How to define immediate words.
                                                            (line  9361)
* compile-only warning, for ' etc.:      core-ambcond.      (line 18744)
* compile-only words:                    How to define immediate words.
                                                            (line  9358)
* compile-only?:                         Name token.        (line  9706)
* compile,:                              Macros.            (line 10093)
* compiled code examination:             Examining compiled code.
                                                            (line 15863)
* compiling:                             Performing translator actions.
                                                            (line 10978)
* compiling compilation semantics:       Macros.            (line  9930)
* compiling words:                       Compiling words.   (line  9806)
* complex numbers, input format:         Floating-point number and complex literals.
                                                            (line  3697)
* compsem::                              How to define combined words.
                                                            (line  9523)
* conditional compilation:               Interpreter Directives.
                                                            (line 10382)
* conditionals, tutorial:                Conditional execution Tutorial.
                                                            (line  1627)
* const-does>:                           Const-does>.       (line  8393)
* Constant:                              Constants.         (line  7377)
* constants:                             Constants.         (line  7359)
* construct:                             Objects Glossary.  (line 14517)
* construct discussion:                  Creating objects.  (line 14111)
* context:                               Word Lists.        (line 11289)
* context-sensitive help:                Emacs and Gforth.  (line 19559)
* contiguous region:                     Memory model.      (line  4991)
* contiguous regions and heap allocation: Heap Allocation.  (line  5259)
* contiguous regions in dictionary allocation: Dictionary allocation.
                                                            (line  5022)
* contiguous regioons and sections:      Sections.          (line  5131)
* contof:                                General control structures with CASE.
                                                            (line  6789)
* contributors to Gforth:                Origin.            (line 21061)
* control characters as delimiters:      core-idef.         (line 18585)
* control structures:                    Control Structures.
                                                            (line  6247)
* control structures for selection:      Selection.         (line  6262)
* control structures, user-defined:      Arbitrary control structures.
                                                            (line  6805)
* control-flow stack:                    Arbitrary control structures.
                                                            (line  6805)
* control-flow stack items, locals information: Locals implementation.
                                                            (line 13830)
* control-flow stack underflow:          programming-ambcond.
                                                            (line 19305)
* control-flow stack, format:            core-idef.         (line 18593)
* convert:                               Line input and conversion.
                                                            (line 12941)
* converting strings to numbers:         Line input and conversion.
                                                            (line 12886)
* CORE:                                  Environmental Queries.
                                                            (line 11432)
* core words, ambiguous conditions:      core-ambcond.      (line 18726)
* core words, implementation-defined options: core-idef.    (line 18541)
* core words, other system documentation: core-other.       (line 18918)
* core words, system documentation:      The Core Words.    (line 18538)
* CORE-EXT:                              Environmental Queries.
                                                            (line 11436)
* cores:                                 Cilk.              (line 16686)
* count:                                 Counted string words.
                                                            (line  6220)
* counted loops:                         Counted Loops.     (line  6362)
* counted loops with negative increment: Counted Loops.     (line  6433)
* counted string, maximum size:          core-idef.         (line 18619)
* counted strings:                       String representations.
                                                            (line  5773)
* Country:                               i18n and l10n.     (line 13142)
* cov%:                                  Code Coverage.     (line 16338)
* cov+:                                  Code Coverage.     (line 16319)
* cover-filename:                        Code Coverage.     (line 16365)
* coverage?:                             Code Coverage.     (line 16316)
* cputime:                               Keeping track of Time.
                                                            (line 18307)
* cr:                                    Miscellaneous output.
                                                            (line 12523)
* Create:                                CREATE.            (line  7271)
* CREATE ... DOES>:                      User-defined defining words using CREATE.
                                                            (line  7736)
* CREATE ... DOES>, applications:        CREATE..DOES> applications.
                                                            (line  7833)
* CREATE ... DOES>, details:             CREATE..DOES> details.
                                                            (line  7870)
* CREATE ... SET-DOES>:                  User-defined defining words using CREATE.
                                                            (line  7794)
* CREATE and alignment:                  Address arithmetic.
                                                            (line  5560)
* create-file:                           General files.     (line 11720)
* create-from:                           Creating from a prototype.
                                                            (line  8332)
* create...does> tutorial:               Defining Words Tutorial.
                                                            (line  2560)
* creating objects:                      Creating objects.  (line 14111)
* critical-section:                      Semaphores.        (line 16581)
* cross-compiler:                        cross.fs.          (line 19920)
* cross-compiler <1>:                    Cross Compiler.    (line 20624)
* cross.fs:                              cross.fs.          (line 19920)
* cross.fs <1>:                          Cross Compiler.    (line 20624)
* CS-DROP:                               Arbitrary control structures.
                                                            (line  6845)
* CS-PICK:                               Arbitrary control structures.
                                                            (line  6841)
* CS-PICK, fewer than u+1 items on the control flow-stack: programming-ambcond.
                                                            (line 19305)
* CS-ROLL:                               Arbitrary control structures.
                                                            (line  6843)
* CS-ROLL, fewer than u+1 items on the control flow-stack: programming-ambcond.
                                                            (line 19305)
* cs-vocabulary:                         Word Lists.        (line 11196)
* cs-wordlist:                           Word Lists.        (line 11193)
* cstring>sstring:                       String words.      (line  6020)
* csv-quote:                             CSV reading and writing.
                                                            (line 13234)
* csv-separator:                         CSV reading and writing.
                                                            (line 13229)
* ct (compilation token):                Compilation token. (line  9764)
* CT, tutorial:                          Compilation Tokens Tutorial.
                                                            (line  2812)
* ctz:                                   Bitwise operations.
                                                            (line  4428)
* current:                               Word Lists.        (line 11286)
* current-interface:                     Objects Glossary.  (line 14527)
* current-interface discussion:          Objects Implementation.
                                                            (line 14386)
* current':                              Objects Glossary.  (line 14521)
* currying:                              CREATE..DOES> applications.
                                                            (line  7854)
* cursor positioning:                    Terminal output.   (line 12613)
* cvalue::                               Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8841)
* d:                                     widget methods.    (line 20837)
* d-:                                    Double precision.  (line  4065)
* d, stack item type:                    Notation.          (line  3888)
* D::                                    Locals definition words.
                                                            (line 13452)
* d.:                                    Simple numeric output.
                                                            (line 12254)
* d.r:                                   Simple numeric output.
                                                            (line 12262)
* D^:                                    Locals definition words.
                                                            (line 13455)
* d+:                                    Double precision.  (line  4063)
* d<:                                    Numeric comparison.
                                                            (line  4513)
* d<=:                                   Numeric comparison.
                                                            (line  4515)
* d<>:                                   Numeric comparison.
                                                            (line  4517)
* d=:                                    Numeric comparison.
                                                            (line  4519)
* d>:                                    Numeric comparison.
                                                            (line  4521)
* d>=:                                   Numeric comparison.
                                                            (line  4523)
* d>f:                                   Floating Point.    (line  4568)
* D>F, d cannot be presented precisely as a float: floating-ambcond.
                                                            (line 19201)
* d>s:                                   Double precision.  (line  4061)
* D>S, d out of range of n:              double-ambcond.    (line 18999)
* d0<:                                   Numeric comparison.
                                                            (line  4525)
* d0<=:                                  Numeric comparison.
                                                            (line  4527)
* d0<>:                                  Numeric comparison.
                                                            (line  4529)
* d0=:                                   Numeric comparison.
                                                            (line  4531)
* d0>:                                   Numeric comparison.
                                                            (line  4533)
* d0>=:                                  Numeric comparison.
                                                            (line  4535)
* d2*:                                   Bitwise operations.
                                                            (line  4410)
* d2/:                                   Bitwise operations.
                                                            (line  4413)
* dabs:                                  Double precision.  (line  4069)
* dark-mode:                             Terminal output.   (line 12681)
* darshift:                              Bitwise operations.
                                                            (line  4398)
* data space:                            Memory model.      (line  4973)
* data space - reserving some:           Dictionary allocation.
                                                            (line  5018)
* data space available:                  core-other.        (line 18928)
* data space containing definitions gets de-allocated: core-ambcond.
                                                            (line 18855)
* data space pointer not properly aligned, ,, C,: core-ambcond.
                                                            (line 18867)
* data space read/write with incorrect alignment: core-ambcond.
                                                            (line 18859)
* data stack:                            Stack Manipulation.
                                                            (line  4762)
* data stack manipulation words:         Data stack.        (line  4775)
* data structure locals:                 Gforth locals.     (line 13384)
* data-relocatable image files:          Data-Relocatable Image Files.
                                                            (line 19837)
* data-space, read-only regions:         core-idef.         (line 18661)
* dbg:                                   Singlestep Debugger.
                                                            (line 16290)
* debug tracer editing commands:         Emacs and Gforth.  (line 19536)
* debug-fid:                             Debugging.         (line 16110)
* debugging:                             Debugging.         (line 16077)
* debugging output, finding the source location in Emacs: Emacs and Gforth.
                                                            (line 19551)
* debugging Singlestep:                  Singlestep Debugger.
                                                            (line 16233)
* dec.:                                  Simple numeric output.
                                                            (line 12225)
* dec.r:                                 Simple numeric output.
                                                            (line 12251)
* decimal:                               Number Conversion. (line 10339)
* declaring C functions:                 Declaring C Functions.
                                                            (line 16792)
* decompilation tutorial:                Decompilation Tutorial.
                                                            (line  1381)
* default type of locals:                Gforth locals.     (line 13376)
* default-color:                         Terminal output.   (line 12642)
* default-input:                         Terminal output.   (line 12690)
* Defer:                                 Deferred Words.    (line  8474)
* defer:                                 Class Declaration. (line 14837)
* defer::                                Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8947)
* defer!:                                Deferred Words.    (line  8574)
* defer@:                                Deferred Words.    (line  8583)
* deferred words:                        Deferred Words.    (line  8429)
* defers:                                Deferred Words.    (line  8523)
* definer:                               Threading Words.   (line 18235)
* definer!:                              Threading Words.   (line 18243)
* defines:                               Basic Mini-OOF Usage.
                                                            (line 14896)
* defining defining words:               User-defined Defining Words.
                                                            (line  7672)
* defining words:                        Defining Words.    (line  7253)
* defining words tutorial:               Defining Words Tutorial.
                                                            (line  2560)
* defining words without name:           Anonymous Definitions.
                                                            (line  7573)
* defining words, name given in a string: Supplying names.  (line  7651)
* defining words, simple:                CREATE.            (line  7259)
* defining words, user-defined:          User-defined Defining Words.
                                                            (line  7672)
* definition:                            Introducing the Text Interpreter.
                                                            (line  2982)
* definitions:                           Word Lists.        (line 11153)
* definitions, tutorial:                 Colon Definitions Tutorial.
                                                            (line  1349)
* defocus:                               actor methods.     (line 20789)
* delete:                                String words.      (line  6015)
* delete-file:                           General files.     (line 11724)
* delta-i:                               Counted Loops.     (line  6609)
* depth:                                 Examining data.    (line 16011)
* depth changes during interpretation:   Stack depth changes.
                                                            (line 18443)
* depth-changes.fs:                      Stack depth changes.
                                                            (line 18443)
* deque:                                 User-defined Stacks.
                                                            (line  9121)
* design of stack effects, tutorial:     Designing the stack effect Tutorial.
                                                            (line  1545)
* dest, control-flow stack item:         Arbitrary control structures.
                                                            (line  6810)
* df_, stack item type:                  Notation.          (line  3903)
* df!:                                   Memory Access.     (line  5402)
* df@:                                   Memory Access.     (line  5398)
* df@ or df! used with an address that is not double-float aligned: floating-ambcond.
                                                            (line 19170)
* dfalign:                               Dictionary allocation.
                                                            (line  5121)
* dfaligned:                             Address arithmetic.
                                                            (line  5640)
* dffield::                              Standard Structures.
                                                            (line  8742)
* dfloat/:                               Address arithmetic.
                                                            (line  5636)
* dfloat%:                               Gforth structs.    (line  9092)
* dfloat+:                               Address arithmetic.
                                                            (line  5633)
* dfloats:                               Address arithmetic.
                                                            (line  5629)
* dfvalue::                              Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8877)
* dglue:                                 widget methods.    (line 20882)
* dglue@:                                widget methods.    (line 20891)
* dict-new:                              Objects Glossary.  (line 14530)
* dict-new discussion:                   Creating objects.  (line 14111)
* dictionary allocation direction:       Memory model.      (line  5000)
* dictionary in persistent form:         Image Files.       (line 19704)
* dictionary memory:                     Memory model.      (line  4983)
* dictionary overflow:                   core-ambcond.      (line 18777)
* dictionary size default:               Stack and Dictionary Sizes.
                                                            (line 19934)
* digits > 35:                           core-idef.         (line 18602)
* direct threaded inner interpreter:     Threading.         (line 20168)
* Directories:                           Directories.       (line 11840)
* dirname:                               Directories.       (line 11846)
* disassembler, general:                 Common Disassembler.
                                                            (line 17374)
* discode:                               Common Disassembler.
                                                            (line 17377)
* dispose-widget:                        widget methods.    (line 20909)
* dividing by zero:                      core-ambcond.      (line 18756)
* dividing by zero, floating-point:      floating-ambcond.  (line 19204)
* Dividing classes:                      Dividing classes.  (line 14284)
* dividing integers:                     Integer division.  (line  4087)
* dividing many integers with the same divisor: Two-stage integer division.
                                                            (line  4236)
* Division by zero:                      Integer division.  (line  4087)
* Division by zero <1>:                  Integer division.  (line  4221)
* division rounding:                     core-idef.         (line 18701)
* division with potentially negative operands: Arithmetic.  (line  3994)
* dlshift:                               Bitwise operations.
                                                            (line  4391)
* dmax:                                  Double precision.  (line  4073)
* dmin:                                  Double precision.  (line  4071)
* dnegate:                               Double precision.  (line  4067)
* DO:                                    Counted Loops.     (line  6576)
* DO loops:                              Counted Loops.     (line  6362)
* doabicode::                            Threading Words.   (line 18210)
* docol::                                Threading Words.   (line 18186)
* docon::                                Threading Words.   (line 18189)
* dodefer::                              Threading Words.   (line 18198)
* dodoes routine:                        DOES>.             (line 20376)
* dodoes::                               Threading Words.   (line 18207)
* does-code!:                            Threading Words.   (line 18230)
* DOES>:                                 CREATE..DOES> details.
                                                            (line  7870)
* DOES> implementation:                  DOES>.             (line 20376)
* DOES> in a separate definition:        CREATE..DOES> details.
                                                            (line  7876)
* DOES> in interpretation state:         CREATE..DOES> details.
                                                            (line  7917)
* DOES> of non-CREATEd words:            core-ambcond.      (line 18908)
* does> tutorial:                        Defining Words Tutorial.
                                                            (line  2560)
* does>-code:                            Threading Words.   (line 18213)
* DOES>-code:                            DOES>.             (line 20376)
* DOES>-parts, stack effect:             User-defined defining words using CREATE.
                                                            (line  7790)
* DOES>, visibility of current definition: core-idef.       (line 18721)
* dofield::                              Threading Words.   (line 18201)
* DONE:                                  Counted Loops.     (line  6620)
* double precision arithmetic words:     Double precision.  (line  4041)
* double words, ambiguous conditions:    double-ambcond.    (line 18998)
* double words, system documentation:    The optional Double Number word set.
                                                            (line 18995)
* double-cell numbers, input format:     Integer and character literals.
                                                            (line  3624)
* double-ended queue:                    User-defined Stacks.
                                                            (line  9121)
* double%:                               Gforth structs.    (line  9094)
* doubly indirect threaded code:         gforthmi.          (line 19905)
* douser::                               Threading Words.   (line 18195)
* dovalue::                              Threading Words.   (line 18204)
* dovar::                                Threading Words.   (line 18192)
* dpl:                                   Number Conversion. (line 10343)
* draw:                                  widget methods.    (line 20870)
* draw-init:                             widget methods.    (line 20867)
* drol:                                  Bitwise operations.
                                                            (line  4459)
* drop:                                  Data stack.        (line  4775)
* dror:                                  Bitwise operations.
                                                            (line  4462)
* drshift:                               Bitwise operations.
                                                            (line  4394)
* du/mod:                                Integer division.  (line  4173)
* du<:                                   Numeric comparison.
                                                            (line  4537)
* du<=:                                  Numeric comparison.
                                                            (line  4539)
* du>:                                   Numeric comparison.
                                                            (line  4541)
* du>=:                                  Numeric comparison.
                                                            (line  4543)
* dump:                                  Examining data.    (line 16033)
* dup:                                   Data stack.        (line  4779)
* duration of a system clock tick:       facility-idef.     (line 19030)
* dynamic allocation of memory:          Heap Allocation.   (line  5259)
* Dynamic superinstructions with replication: Dynamic Superinstructions.
                                                            (line 20265)
* Dynamically linked libraries in C interface: Declaring OS-level libraries.
                                                            (line 16979)
* early:                                 Class Declaration. (line 14842)
* early binding:                         Class Binding.     (line 14145)
* edit:                                  Locating source code definitions.
                                                            (line 15786)
* edit-line:                             Line input and conversion.
                                                            (line 12898)
* editing in ACCEPT and EXPECT:          core-idef.         (line 18552)
* eforth performance:                    Performance.       (line 20547)
* ekey:                                  Single-key input.  (line 12740)
* EKEY, encoding of keyboard events:     facility-idef.     (line 19023)
* ekey?:                                 Single-key input.  (line 12755)
* ekey>char:                             Single-key input.  (line 12746)
* ekey>fkey:                             Single-key input.  (line 12751)
* ekey>xchar:                            Single-key input.  (line 12743)
* ekeyed:                                actor methods.     (line 20780)
* elements of a Forth system:            Review - elements of a Forth system.
                                                            (line  3524)
* ELSE:                                  Arbitrary control structures.
                                                            (line  6859)
* Emacs and Gforth:                      Emacs and Gforth.  (line 19536)
* emit:                                  Displaying characters and strings.
                                                            (line 12602)
* EMIT and non-graphic characters:       core-idef.         (line 18548)
* emit-file:                             General files.     (line 11767)
* empty-buffer:                          Blocks.            (line 12156)
* empty-buffers:                         Blocks.            (line 12152)
* end-c-library:                         Defining library interfaces.
                                                            (line 16973)
* end-class:                             Objects Glossary.  (line 14533)
* end-class <1>:                         Basic Mini-OOF Usage.
                                                            (line 14892)
* end-class usage:                       Basic Objects Usage.
                                                            (line 14042)
* end-class-noname:                      Objects Glossary.  (line 14537)
* end-code:                              Assembler Definitions.
                                                            (line 17227)
* end-interface:                         Objects Glossary.  (line 14540)
* end-interface usage:                   Object Interfaces. (line 14341)
* end-interface-noname:                  Objects Glossary.  (line 14544)
* end-methods:                           Objects Glossary.  (line 14547)
* end-struct:                            Gforth structs.    (line  9096)
* end-struct usage:                      Gforth structs.    (line  9036)
* end-structure:                         Standard Structures.
                                                            (line  8724)
* endcase:                               General control structures with CASE.
                                                            (line  6768)
* ENDIF:                                 Arbitrary control structures.
                                                            (line  6876)
* endless loop:                          General Loops.     (line  6351)
* endof:                                 General control structures with CASE.
                                                            (line  6785)
* endscope:                              Where are locals visible by name?.
                                                            (line 13491)
* endtry:                                Exception Handling.
                                                            (line  7109)
* endtry-iferror:                        Exception Handling.
                                                            (line  7188)
* engine:                                Engine.            (line 20089)
* engine performance:                    Performance.       (line 20531)
* engine portability:                    Portability.       (line 20103)
* engine.s:                              Produced code.     (line 20523)
* engines, gforth vs. gforth-fast vs. gforth-itc: Direct or Indirect Threaded?.
                                                            (line 20249)
* entered:                               actor methods.     (line 20792)
* environment:                           Environmental Queries.
                                                            (line 11554)
* environment variable input format:     String and environment variable literals.
                                                            (line  3716)
* environment variables:                 Environment variables.
                                                            (line   952)
* environment variables <1>:             gforthmi.          (line 19905)
* environment wordset:                   Notation.          (line  3824)
* environment-wordlist:                  Environmental Queries.
                                                            (line 11550)
* environment?:                          Environmental Queries.
                                                            (line 11403)
* ENVIRONMENT? string length, maximum:   core-idef.         (line 18629)
* environmental queries:                 Environmental Queries.
                                                            (line 11398)
* environmental restrictions:            Standard conformance.
                                                            (line 18515)
* equality of floats:                    Floating-point comparisons.
                                                            (line  4717)
* erase:                                 Memory Blocks.     (line  5727)
* error messages:                        Error messages.    (line 18332)
* error output, finding the source location in Emacs: Emacs and Gforth.
                                                            (line 19551)
* error-color:                           Terminal output.   (line 12645)
* error-hl-inv:                          Terminal output.   (line 12648)
* error-hl-ul:                           Terminal output.   (line 12651)
* etags.fs:                              Emacs Tags.        (line 19587)
* evaluate:                              Input Sources.     (line 10274)
* event-loop:                            Message queues.    (line 16655)
* examining data:                        Examining data.    (line 15982)
* exception:                             Exception Handling.
                                                            (line  6995)
* exception abort sequence of ABORT":    core-idef.         (line 18610)
* exception source code:                 Locating exception source.
                                                            (line 15854)
* exception when including source:       file-idef.         (line 19081)
* exception words, implementation-defined options: exception-idef.
                                                            (line 19007)
* exception words, system documentation: The optional Exception word set.
                                                            (line 19004)
* exceptions:                            Exception Handling.
                                                            (line  6966)
* exceptions <1>:                        Exception Handling.
                                                            (line  7005)
* exceptions tutorial:                   Exceptions Tutorial.
                                                            (line  2501)
* executable image file:                 Running Image Files.
                                                            (line 19959)
* execute:                               Execution token.   (line  9621)
* execute-exit:                          Execution token.   (line  9624)
* execute-parsing:                       The Input Stream.  (line 11102)
* execute-parsing-file:                  The Input Stream.  (line 11118)
* execute-task:                          Basic multi-tasking.
                                                            (line 16448)
* executing code on startup:             Invoking Gforth.   (line   813)
* execution frequency:                   Code Coverage.     (line 16299)
* execution semantics (aka interpretation semantics): Interpretation and Compilation Semantics.
                                                            (line  9180)
* execution token:                       Introducing the Text Interpreter.
                                                            (line  2982)
* execution token <1>:                   Execution token.   (line  9555)
* execution token input format:          Literals for tokens and addresses.
                                                            (line  3727)
* execution token of last defined word:  Anonymous Definitions.
                                                            (line  7595)
* execution token of words with undefined execution semantics: core-ambcond.
                                                            (line 18744)
* execution tokens tutorial:             Execution Tokens Tutorial.
                                                            (line  2415)
* exercises:                             Exercises.         (line  3593)
* EXIT:                                  Calls and returns. (line  6955)
* exit in m: ... ;m:                     Method conveniences.
                                                            (line 14202)
* exitm:                                 Objects Glossary.  (line 14551)
* exitm discussion:                      Method conveniences.
                                                            (line 14202)
* expand-where:                          Locating uses of a word.
                                                            (line 15837)
* expect:                                Line input and conversion.
                                                            (line 12944)
* EXPECT, display after end of input:    core-idef.         (line 18606)
* EXPECT, editing:                       core-idef.         (line 18552)
* explicit register declarations:        Portability.       (line 20137)
* exponent too big for conversion (DF!, DF@, SF!, SF@): floating-ambcond.
                                                            (line 19209)
* extend-mem:                            Memory blocks and heap allocation.
                                                            (line  5301)
* extend-structure:                      Structure Extension.
                                                            (line  8997)
* extended records:                      Structure Extension.
                                                            (line  8958)
* extra-section:                         Sections.          (line  5210)
* f_, stack item type:                   Notation.          (line  3901)
* f-:                                    Floating Point.    (line  4578)
* f-rot:                                 Floating point stack.
                                                            (line  4837)
* f,:                                    Dictionary allocation.
                                                            (line  5058)
* f, stack item type:                    Notation.          (line  3877)
* F::                                    Locals definition words.
                                                            (line 13464)
* f!:                                    Memory Access.     (line  5387)
* f! used with an address that is not float aligned: floating-ambcond.
                                                            (line 19174)
* f.:                                    Floating-point output.
                                                            (line 12427)
* f.rdp:                                 Floating-point output.
                                                            (line 12463)
* f.s:                                   Examining data.    (line 15992)
* f.s-precision:                         Examining data.    (line 15997)
* f@:                                    Memory Access.     (line  5384)
* f@ used with an address that is not float aligned: floating-ambcond.
                                                            (line 19174)
* f@localn:                              Locals implementation.
                                                            (line 13756)
* f*:                                    Floating Point.    (line  4580)
* f**:                                   Floating Point.    (line  4605)
* f/:                                    Floating Point.    (line  4582)
* F^:                                    Locals definition words.
                                                            (line 13467)
* f+:                                    Floating Point.    (line  4576)
* f<:                                    Floating-point comparisons.
                                                            (line  4737)
* f<=:                                   Floating-point comparisons.
                                                            (line  4739)
* f<>:                                   Floating-point comparisons.
                                                            (line  4735)
* f=:                                    Floating-point comparisons.
                                                            (line  4733)
* f>:                                    Floating-point comparisons.
                                                            (line  4741)
* f>=:                                   Floating-point comparisons.
                                                            (line  4743)
* f>buf-rdp:                             Floating-point output.
                                                            (line 12508)
* f>d:                                   Floating Point.    (line  4572)
* F>D, integer part of float cannot be represented by d: floating-ambcond.
                                                            (line 19232)
* f>l:                                   Locals implementation.
                                                            (line 13768)
* f>r:                                   Return stack.      (line  4913)
* f>s:                                   Floating Point.    (line  4570)
* f>str-rdp:                             Floating-point output.
                                                            (line 12502)
* f~:                                    Floating-point comparisons.
                                                            (line  4729)
* f~abs:                                 Floating-point comparisons.
                                                            (line  4726)
* f~rel:                                 Floating-point comparisons.
                                                            (line  4723)
* f0<:                                   Floating-point comparisons.
                                                            (line  4745)
* f0<=:                                  Floating-point comparisons.
                                                            (line  4747)
* f0<>:                                  Floating-point comparisons.
                                                            (line  4749)
* f0=:                                   Floating-point comparisons.
                                                            (line  4751)
* f0>:                                   Floating-point comparisons.
                                                            (line  4753)
* f0>=:                                  Floating-point comparisons.
                                                            (line  4755)
* f2*:                                   Floating Point.    (line  4628)
* f2/:                                   Floating Point.    (line  4631)
* fabs:                                  Floating Point.    (line  4586)
* facility words, ambiguous conditions:  facility-ambcond.  (line 19043)
* facility words, implementation-defined options: facility-idef.
                                                            (line 19022)
* facility words, system documentation:  The optional Facility word set.
                                                            (line 19019)
* facos:                                 Floating Point.    (line  4663)
* FACOS, |float|>1:                      floating-ambcond.  (line 19229)
* facosh:                                Floating Point.    (line  4679)
* FACOSH, float<1:                       floating-ambcond.  (line 19213)
* factoring:                             Introduction.      (line  2932)
* factoring similar colon definitions:   CREATE..DOES> applications.
                                                            (line  7835)
* factoring tutorial:                    Factoring Tutorial.
                                                            (line  1521)
* fade-color::                           widget methods.    (line 20952)
* falign:                                Dictionary allocation.
                                                            (line  5113)
* faligned:                              Address arithmetic.
                                                            (line  5610)
* falog:                                 Floating Point.    (line  4625)
* false:                                 Boolean Flags.     (line  3979)
* fam (file access method):              General files.     (line 11702)
* fasin:                                 Floating Point.    (line  4661)
* FASIN, |float|>1:                      floating-ambcond.  (line 19229)
* fasinh:                                Floating Point.    (line  4677)
* FASINH, float<0:                       floating-ambcond.  (line 19224)
* fast-throw:                            Exception Handling.
                                                            (line  6975)
* fatan:                                 Floating Point.    (line  4665)
* fatan2:                                Floating Point.    (line  4667)
* FATAN2, both arguments are equal to zero: floating-ambcond.
                                                            (line 19192)
* fatanh:                                Floating Point.    (line  4681)
* FATANH, |float|>1:                     floating-ambcond.  (line 19229)
* faxpy:                                 Floating Point.    (line  4644)
* fclearstack:                           Examining data.    (line 16022)
* fconstant:                             Constants.         (line  7389)
* fcopysign:                             Floating Point.    (line  4588)
* fcos:                                  Floating Point.    (line  4654)
* fcosh:                                 Floating Point.    (line  4673)
* fdepth:                                Examining data.    (line 16015)
* FDL, GNU Free Documentation License:   GNU Free Documentation License.
                                                            (line 21138)
* fdrop:                                 Floating point stack.
                                                            (line  4821)
* fdup:                                  Floating point stack.
                                                            (line  4825)
* fe.:                                   Floating-point output.
                                                            (line 12431)
* fetch and add:                         Hardware operations for multi-tasking.
                                                            (line 16599)
* fexp:                                  Floating Point.    (line  4610)
* fexpm1:                                Floating Point.    (line  4613)
* ffield::                               Standard Structures.
                                                            (line  8736)
* ffourth:                               Floating point stack.
                                                            (line  4831)
* field:                                 Gforth structs.    (line  9101)
* field usage:                           Gforth structs.    (line  9036)
* field usage in class definition:       Basic Objects Usage.
                                                            (line 14063)
* field::                                Standard Structures.
                                                            (line  8730)
* file access methods used:              file-idef.         (line 19055)
* file exceptions:                       file-idef.         (line 19062)
* file input nesting, maximum depth:     file-idef.         (line 19090)
* file line terminator:                  file-idef.         (line 19066)
* file name format:                      file-idef.         (line 19071)
* file search path:                      Search Paths.      (line 11895)
* file words, ambiguous conditions:      file-ambcond.      (line 19110)
* file words, implementation-defined options: file-idef.    (line 19054)
* file words, system documentation:      The optional File-Access word set.
                                                            (line 19051)
* file-eof?:                             General files.     (line 11760)
* file-handling:                         General files.     (line 11699)
* file-position:                         General files.     (line 11773)
* file-size:                             General files.     (line 11777)
* file-status:                           General files.     (line 11771)
* FILE-STATUS, returned information:     file-idef.         (line 19075)
* file>fpath:                            Source Search Paths.
                                                            (line 11938)
* file>path:                             General Search Paths.
                                                            (line 11963)
* filename-match:                        Directories.       (line 11872)
* filenames in ~~ output:                Debugging.         (line 16113)
* filenames in assertion output:         Assertions.        (line 16222)
* files:                                 Files.             (line 11609)
* files containing blocks:               file-idef.         (line 19097)
* files containing Forth code, tutorial: Using files for Forth code Tutorial.
                                                            (line  1281)
* files tutorial:                        Files Tutorial.    (line  2238)
* fill:                                  Memory Blocks.     (line  5724)
* find:                                  Word Lists.        (line 11229)
* find-name:                             Name token.        (line  9652)
* find-name-in:                          Name token.        (line  9656)
* first definition:                      Your first definition.
                                                            (line  3234)
* first field optimization:              Standard Structures.
                                                            (line  8778)
* fkey.:                                 Single-key input.  (line 12873)
* flags on the command line:             Invoking Gforth.   (line   516)
* flags tutorial:                        Flags and Comparisons Tutorial.
                                                            (line  1673)
* flat address space:                    Memory model.      (line  5000)
* flat closures:                         Closures.          (line 15174)
* flavours of locals:                    Gforth locals.     (line 13344)
* flit,:                                 Literals.          (line  9885)
* FLiteral:                              Literals.          (line  9879)
* fln:                                   Floating Point.    (line  4616)
* FLN, float<=0:                         floating-ambcond.  (line 19220)
* flnp1:                                 Floating Point.    (line  4619)
* FLNP1, float<=-1:                      floating-ambcond.  (line 19216)
* float:                                 Address arithmetic.
                                                            (line  5602)
* float/:                                Address arithmetic.
                                                            (line  5606)
* float%:                                Gforth structs.    (line  9108)
* float+:                                Address arithmetic.
                                                            (line  5599)
* floating point arithmetic words:       Floating Point.    (line  4548)
* floating point numbers, format and range: floating-idef.  (line 19145)
* floating point tutorial:               Floating Point Tutorial.
                                                            (line  2166)
* floating point unidentified fault, integer division: core-ambcond.
                                                            (line 18756)
* floating-point arithmetic, pitfalls:   Floating Point.    (line  4554)
* floating-point comparisons:            Floating-point comparisons.
                                                            (line  4717)
* floating-point constants:              Floating Point.    (line  4687)
* floating-point dividing by zero:       floating-ambcond.  (line 19204)
* floating-point numbers, input format:  Floating-point number and complex literals.
                                                            (line  3650)
* floating-point numbers, rounding or truncation: floating-idef.
                                                            (line 19152)
* floating-point output:                 Floating-point output.
                                                            (line 12425)
* floating-point result out of range:    floating-ambcond.  (line 19178)
* floating-point stack:                  Stack Manipulation.
                                                            (line  4765)
* floating-point stack in the standard:  Stack Manipulation.
                                                            (line  4760)
* floating-point stack manipulation words: Floating point stack.
                                                            (line  4821)
* floating-point stack size:             floating-idef.     (line 19158)
* floating-point stack width:            floating-idef.     (line 19164)
* Floating-point unidentified fault:     Integer division.  (line  4087)
* Floating-point unidentified fault (on integer division): Integer division.
                                                            (line  4221)
* floating-point unidentified fault, F>D: floating-ambcond. (line 19232)
* floating-point unidentified fault, FACOS, FASIN or FATANH: floating-ambcond.
                                                            (line 19229)
* floating-point unidentified fault, FACOSH: floating-ambcond.
                                                            (line 19213)
* floating-point unidentified fault, FASINH or FSQRT: floating-ambcond.
                                                            (line 19224)
* floating-point unidentified fault, FLN or FLOG: floating-ambcond.
                                                            (line 19220)
* floating-point unidentified fault, FLNP1: floating-ambcond.
                                                            (line 19216)
* floating-point unidentified fault, FP divide-by-zero: floating-ambcond.
                                                            (line 19204)
* floating-point words, ambiguous conditions: floating-ambcond.
                                                            (line 19169)
* floating-point words, implementation-defined options: floating-idef.
                                                            (line 19144)
* floating-point words, system documentation: The optional Floating-Point word set.
                                                            (line 19141)
* floating-stack:                        Environmental Queries.
                                                            (line 11461)
* floats:                                Address arithmetic.
                                                            (line  5596)
* flog:                                  Floating Point.    (line  4622)
* FLOG, float<=0:                        floating-ambcond.  (line 19220)
* floor:                                 Floating Point.    (line  4595)
* FLOORED:                               Environmental Queries.
                                                            (line 11440)
* floored division:                      Integer division.  (line  4092)
* flush:                                 Blocks.            (line 12171)
* flush-file:                            General files.     (line 11769)
* flush-icache:                          Assembler Definitions.
                                                            (line 17244)
* fm/mod:                                Integer division.  (line  4164)
* fmax:                                  Floating Point.    (line  4591)
* fmin:                                  Floating Point.    (line  4593)
* fnegate:                               Floating Point.    (line  4584)
* fnip:                                  Floating point stack.
                                                            (line  4823)
* focus:                                 actor methods.     (line 20786)
* FOR:                                   Counted Loops.     (line  6579)
* FOR loops:                             Counted Loops.     (line  6519)
* foreign language interface:            C Interface.       (line 16716)
* FORGET, deleting the compilation word list: programming-ambcond.
                                                            (line 19302)
* FORGET, name can't be found:           programming-ambcond.
                                                            (line 19311)
* FORGET, removing a needed definition:  programming-ambcond.
                                                            (line 19328)
* forgeting words:                       Forgetting words.  (line 16042)
* FORK:                                  Regular Expressions.
                                                            (line 15544)
* form:                                  Terminal output.   (line 12625)
* format and range of floating point numbers: floating-idef.
                                                            (line 19145)
* format of glossary entries:            Notation.          (line  3766)
* formatted numeric output:              Formatted numeric output.
                                                            (line 12274)
* Forth:                                 Word Lists.        (line 11210)
* Forth - an introduction:               Introduction.      (line  2908)
* Forth mode in Emacs:                   Emacs and Gforth.  (line 19536)
* Forth source files:                    Forth source files.
                                                            (line 11620)
* Forth Tutorial:                        Tutorial.          (line  1090)
* forth-recognize:                       Recognizer order.  (line 10727)
* forth-recognize-nt?:                   Define recognizers with existing translators.
                                                            (line 10888)
* Forth-related information:             Forth-related information.
                                                            (line 21122)
* forth-wordlist:                        Word Lists.        (line 11148)
* forth.el:                              Emacs and Gforth.  (line 19536)
* forward:                               Calls and returns. (line  6928)
* fourth:                                Data stack.        (line  4785)
* fover:                                 Floating point stack.
                                                            (line  4827)
* FP output:                             Floating-point output.
                                                            (line 12425)
* FP tutorial:                           Floating Point Tutorial.
                                                            (line  2166)
* fp!:                                   Stack pointer manipulation.
                                                            (line  4946)
* fp.:                                   Floating-point output.
                                                            (line 12439)
* fp@:                                   Stack pointer manipulation.
                                                            (line  4944)
* fp0:                                   Stack pointer manipulation.
                                                            (line  4941)
* fpath:                                 Source Search Paths.
                                                            (line 11933)
* fpick:                                 Floating point stack.
                                                            (line  4841)
* fr@:                                   Return stack.      (line  4919)
* fr>:                                   Return stack.      (line  4916)
* free:                                  Heap Allocation.   (line  5275)
* free-closure:                          Closures.          (line 15242)
* free-mem-var:                          Memory blocks and heap allocation.
                                                            (line  5307)
* frequently asked questions:            Forth-related information.
                                                            (line 21122)
* frot:                                  Floating point stack.
                                                            (line  4835)
* fround:                                Floating Point.    (line  4599)
* fs.:                                   Floating-point output.
                                                            (line 12435)
* fsin:                                  Floating Point.    (line  4652)
* fsincos:                               Floating Point.    (line  4656)
* fsinh:                                 Floating Point.    (line  4671)
* fsqrt:                                 Floating Point.    (line  4608)
* FSQRT, float<0:                        floating-ambcond.  (line 19224)
* fswap:                                 Floating point stack.
                                                            (line  4833)
* ftan:                                  Floating Point.    (line  4659)
* FTAN on an argument r1 where cos(r1) is zero: floating-ambcond.
                                                            (line 19196)
* ftanh:                                 Floating Point.    (line  4675)
* fthird:                                Floating point stack.
                                                            (line  4829)
* ftrunc:                                Floating Point.    (line  4602)
* ftuck:                                 Floating point stack.
                                                            (line  4839)
* fully relocatable image files:         Fully Relocatable Image Files.
                                                            (line 19854)
* functions, tutorial:                   Colon Definitions Tutorial.
                                                            (line  1349)
* fvalue:                                Values.            (line  7431)
* fvalue::                               Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8869)
* fvariable:                             Variables.         (line  7345)
* g:                                     Locating source code definitions.
                                                            (line 15770)
* gap:                                   widget methods.    (line 20840)
* gdb disassembler:                      Common Disassembler.
                                                            (line 17374)
* general control structures (case):     General control structures with CASE.
                                                            (line  6695)
* general files:                         General files.     (line 11699)
* get:                                   actor methods.     (line 20804)
* get-block-fid:                         Blocks.            (line 12121)
* get-current:                           Word Lists.        (line 11157)
* get-dir:                               Directories.       (line 11877)
* get-order:                             Word Lists.        (line 11173)
* get-stack:                             User-defined Stacks.
                                                            (line  9163)
* getenv:                                Passing Commands to the OS.
                                                            (line 18278)
* gforth:                                Environmental Queries.
                                                            (line 11527)
* GFORTH - environment variable:         Environment variables.
                                                            (line   980)
* GFORTH - environment variable <1>:     gforthmi.          (line 19905)
* Gforth - leaving:                      Leaving Gforth.    (line   862)
* gforth engine:                         Direct or Indirect Threaded?.
                                                            (line 20249)
* Gforth environment:                    Gforth Environment.
                                                            (line   507)
* Gforth extensions:                     Standard vs Extensions.
                                                            (line 19362)
* Gforth files:                          Gforth Files.      (line   993)
* Gforth locals:                         Gforth locals.     (line 13315)
* Gforth performance:                    Performance.       (line 20531)
* Gforth stability:                      Stability Goals.   (line   471)
* gforth-ditc:                           gforthmi.          (line 19905)
* gforth-fast and backtraces:            Error messages.    (line 18379)
* gforth-fast engine:                    Direct or Indirect Threaded?.
                                                            (line 20249)
* gforth-fast, difference from gforth:   Error messages.    (line 18379)
* gforth-itc engine:                     Direct or Indirect Threaded?.
                                                            (line 20253)
* gforth.el:                             Emacs and Gforth.  (line 19536)
* gforth.el, installation:               Installing gforth.el.
                                                            (line 19567)
* gforth.fi, relocatability:             Fully Relocatable Image Files.
                                                            (line 19854)
* GFORTHD - environment variable:        Environment variables.
                                                            (line   982)
* GFORTHD - environment variable <1>:    gforthmi.          (line 19905)
* GFORTHHIST - environment variable:     Environment variables.
                                                            (line   954)
* gforthmi:                              gforthmi.          (line 19867)
* GFORTHPATH - environment variable:     Environment variables.
                                                            (line   958)
* GFORTHSYSTEMPREFIX - environment variable: Environment variables.
                                                            (line   974)
* gg:                                    Locating uses of a word.
                                                            (line 15819)
* giving a name to a library interface:  Defining library interfaces.
                                                            (line 16919)
* glossary notation format:              Notation.          (line  3766)
* GNU C for the engine:                  Portability.       (line 20120)
* goals of the Gforth project:           Goals.             (line   419)
* h:                                     widget methods.    (line 20834)
* h.:                                    Simple numeric output.
                                                            (line 12228)
* halt:                                  Basic multi-tasking.
                                                            (line 16464)
* header fields:                         Header fields.     (line 17932)
* header methods:                        Header methods.    (line 18000)
* header space:                          Word Lists.        (line 11125)
* heap allocation:                       Heap Allocation.   (line  5259)
* heap memory:                           Memory model.      (line  4983)
* heap-new:                              Objects Glossary.  (line 14554)
* heap-new discussion:                   Creating objects.  (line 14111)
* heap-new usage:                        Basic Objects Usage.
                                                            (line 14085)
* help:                                  Help on Gforth.    (line   874)
* help <1>:                              Help on Gforth.    (line   876)
* here:                                  Dictionary allocation.
                                                            (line  5038)
* hex:                                   Number Conversion. (line 10335)
* hex.:                                  Simple numeric output.
                                                            (line 12232)
* hglue:                                 widget methods.    (line 20879)
* hglue@:                                widget methods.    (line 20888)
* hide:                                  actor methods.     (line 20801)
* highlighting Forth code in Emacs:      Hilighting.        (line 19602)
* hilighting Forth code in Emacs:        Hilighting.        (line 19602)
* history file:                          Command-line editing.
                                                            (line   929)
* hold:                                  Formatted numeric output.
                                                            (line 12330)
* holds:                                 Formatted numeric output.
                                                            (line 12334)
* hooks in the text interpreter:         Text Interpreter Hooks.
                                                            (line 11024)
* how::                                  Class Declaration. (line 14855)
* hybrid direct/indirect threaded code:  Direct or Indirect Threaded?.
                                                            (line 20241)
* i:                                     Counted Loops.     (line  6597)
* i':                                    Counted Loops.     (line  6606)
* I/O - blocks:                          Blocks.            (line 11996)
* I/O - file-handling:                   Files.             (line 11609)
* I/O - keyboard and display:            Other I/O.         (line 12214)
* I/O - see input:                       Line input and conversion.
                                                            (line 12886)
* I/O exception in block transfer:       block-ambcond.     (line 18968)
* id.:                                   Name token.        (line  9700)
* IDE (integrated development environment): Locating source code definitions.
                                                            (line 15725)
* IF:                                    Arbitrary control structures.
                                                            (line  6815)
* IF control structure:                  Selection.         (line  6262)
* if, tutorial:                          Conditional execution Tutorial.
                                                            (line  1627)
* iferror:                               Exception Handling.
                                                            (line  7112)
* image file:                            Image Files.       (line 19704)
* image file background:                 Image File Background.
                                                            (line 19732)
* image file initialization sequence:    Modifying the Startup Sequence.
                                                            (line 20032)
* image file invocation:                 Running Image Files.
                                                            (line 19955)
* image file loader:                     Image File Background.
                                                            (line 19767)
* image file, data-relocatable:          Data-Relocatable Image Files.
                                                            (line 19837)
* image file, executable:                Running Image Files.
                                                            (line 19959)
* image file, fully relocatable:         Fully Relocatable Image Files.
                                                            (line 19854)
* image file, non-relocatable:           Non-Relocatable Image Files.
                                                            (line 19818)
* image file, stack and dictionary sizes: Stack and Dictionary Sizes.
                                                            (line 19934)
* image file, turnkey applications:      Modifying the Startup Sequence.
                                                            (line 20048)
* image license:                         Image Licensing Issues.
                                                            (line 19711)
* immediate:                             How to define immediate words.
                                                            (line  9338)
* immediate words:                       How does that work?.
                                                            (line  3399)
* immediate words <1>:                   How to define immediate words.
                                                            (line  9335)
* immediate, tutorial:                   Interpretation and Compilation Semantics and Immediacy Tutorial.
                                                            (line  2342)
* immediate?:                            Header methods.    (line 18121)
* implementation:                        Objects Glossary.  (line 14557)
* implementation of locals:              Locals implementation.
                                                            (line 13746)
* implementation usage:                  Object Interfaces. (line 14341)
* implementation-defined options, block words: block-idef.  (line 18952)
* implementation-defined options, core words: core-idef.    (line 18541)
* implementation-defined options, exception words: exception-idef.
                                                            (line 19007)
* implementation-defined options, facility words: facility-idef.
                                                            (line 19022)
* implementation-defined options, file words: file-idef.    (line 19054)
* implementation-defined options, floating-point words: floating-idef.
                                                            (line 19144)
* implementation-defined options, locals words: locals-idef.
                                                            (line 19246)
* implementation-defined options, memory-allocation words: memory-idef.
                                                            (line 19269)
* implementation-defined options, programming-tools words: programming-idef.
                                                            (line 19281)
* implementation-defined options, search-order words: search-idef.
                                                            (line 19336)
* in:                                    Word Lists.        (line 11168)
* in-colon-def?:                         Macros.            (line 10160)
* in-wordlist:                           Word Lists.        (line 11163)
* include:                               Forth source files.
                                                            (line 11660)
* include search path:                   Search Paths.      (line 11895)
* include-file:                          Forth source files.
                                                            (line 11646)
* INCLUDE-FILE, file-id is invalid:      file-ambcond.      (line 19119)
* INCLUDE-FILE, I/O exception reading or closing file-id: file-ambcond.
                                                            (line 19123)
* include-locale:                        i18n and l10n.     (line 13154)
* include, placement in files:           Emacs Tags.        (line 19587)
* included:                              Forth source files.
                                                            (line 11650)
* included-locale:                       i18n and l10n.     (line 13151)
* INCLUDED, I/O exception reading or closing file-id: file-ambcond.
                                                            (line 19123)
* INCLUDED, named file cannot be opened: file-ambcond.      (line 19127)
* included?:                             Forth source files.
                                                            (line 11653)
* including files:                       Forth source files.
                                                            (line 11620)
* including files, stack effect:         Forth source files.
                                                            (line 11634)
* indentation of Forth code in Emacs:    Auto-Indentation.  (line 19640)
* indirect threaded inner interpreter:   Threading.         (line 20157)
* inf:                                   Floating Point.    (line  4694)
* infile-execute:                        Redirection.       (line 11822)
* infile-id:                             Redirection.       (line 11825)
* infinity:                              Floating Point.    (line  4691)
* info-color:                            Terminal output.   (line 12657)
* inheritance:                           Object-Oriented Terminology.
                                                            (line 13980)
* init-asm:                              Assembler Definitions.
                                                            (line 17205)
* init-buffer:                           Growable memory buffers.
                                                            (line  5334)
* init-object:                           Objects Glossary.  (line 14561)
* init-object discussion:                Creating objects.  (line 14117)
* initialization of locals:              Gforth locals.     (line 13379)
* initialization sequence of image file: Modifying the Startup Sequence.
                                                            (line 20032)
* initiate:                              Basic multi-tasking.
                                                            (line 16423)
* inline::                               Inline Definitions.
                                                            (line  7513)
* inner interpreter and text interpreter: The Text Interpreter.
                                                            (line 10173)
* inner interpreter implementation:      Threading.         (line 20151)
* inner interpreter optimization:        Scheduling.        (line 20178)
* inner interpreter, direct threaded:    Threading.         (line 20168)
* inner interpreter, indirect threaded:  Threading.         (line 20157)
* input format for body-relative addresses: Literals for tokens and addresses.
                                                            (line  3736)
* input format for characters/code points: Integer and character literals.
                                                            (line  3640)
* input format for double-cell numbers:  Integer and character literals.
                                                            (line  3624)
* input format for environment variables: String and environment variable literals.
                                                            (line  3716)
* input format for execution tokens:     Literals for tokens and addresses.
                                                            (line  3727)
* input format for floating-point numbers: Floating-point number and complex literals.
                                                            (line  3650)
* input format for name tokens:          Literals for tokens and addresses.
                                                            (line  3733)
* input format for single-cell numbers:  Integer and character literals.
                                                            (line  3603)
* input format for strings:              String and environment variable literals.
                                                            (line  3706)
* input from pipes:                      Gforth in pipes.   (line  1014)
* input line size, maximum:              file-idef.         (line 19094)
* input line terminator:                 core-idef.         (line 18614)
* Input Redirection:                     Redirection.       (line 11799)
* input sources:                         Input Sources.     (line 10261)
* input stream:                          The Input Stream.  (line 11036)
* input-color:                           Terminal output.   (line 12663)
* input, linewise from terminal:         Line input and conversion.
                                                            (line 12886)
* input, single-key:                     Single-key input.  (line 12702)
* insert:                                String words.      (line  6010)
* inst-value:                            Objects Glossary.  (line 14565)
* inst-value usage:                      Method conveniences.
                                                            (line 14231)
* inst-value visibility:                 Classes and Scoping.
                                                            (line 14264)
* inst-var:                              Objects Glossary.  (line 14569)
* inst-var implementation:               Objects Implementation.
                                                            (line 14415)
* inst-var usage:                        Method conveniences.
                                                            (line 14209)
* inst-var visibility:                   Classes and Scoping.
                                                            (line 14264)
* instance variables:                    Object-Oriented Terminology.
                                                            (line 13954)
* instruction pointer:                   Threading.         (line 20161)
* insufficient data stack or return stack space: core-ambcond.
                                                            (line 18761)
* insufficient space for loop control parameters: core-ambcond.
                                                            (line 18774)
* insufficient space in the dictionary:  core-ambcond.      (line 18777)
* INT-[I]:                               Interpreter Directives.
                                                            (line 10456)
* integer types, ranges:                 core-idef.         (line 18654)
* integrated development environment:    Locating source code definitions.
                                                            (line 15725)
* interface:                             Objects Glossary.  (line 14573)
* interface implementation:              Objects Implementation.
                                                            (line 14426)
* interface to C functions:              C Interface.       (line 16716)
* interface usage:                       Object Interfaces. (line 14341)
* interfaces for objects:                Object Interfaces. (line 14320)
* interpret state:                       The Text Interpreter.
                                                            (line 10167)
* Interpret/Compile states:              Interpret/Compile states.
                                                            (line 10368)
* interpret/compile::                    How to define combined words.
                                                            (line  9428)
* interpretation and compilation semantics, arbitrary combination: How to define combined words.
                                                            (line  9415)
* interpretation semantics:              How does that work?.
                                                            (line  3371)
* interpretation semantics (aka execution semantics): Interpretation and Compilation Semantics.
                                                            (line  9180)
* interpretation semantics tutorial:     Interpretation and Compilation Semantics and Immediacy Tutorial.
                                                            (line  2342)
* interpretation semantics, default:     What semantics do normal definitions have?.
                                                            (line  9313)
* interpretation semantics, usage:       Where are interpretation semantics used?.
                                                            (line  9198)
* interpreter - outer:                   The Text Interpreter.
                                                            (line 10167)
* interpreter directives:                Interpreter Directives.
                                                            (line 10382)
* interpreting:                          Performing translator actions.
                                                            (line 10970)
* Interpreting a compile-only word:      core-ambcond.      (line 18784)
* Interpreting a compile-only word, for a local: locals-ambcond.
                                                            (line 19256)
* interpreting a word with undefined interpretation semantics: core-ambcond.
                                                            (line 18784)
* intsem::                               How to define combined words.
                                                            (line  9527)
* invalid block number:                  block-ambcond.     (line 18972)
* Invalid memory address:                core-ambcond.      (line 18733)
* Invalid memory address, stack overflow: core-ambcond.     (line 18761)
* Invalid name argument, TO:             core-ambcond.      (line 18881)
* Invalid name argument, TO <1>:         locals-ambcond.    (line 19261)
* invert:                                Bitwise operations.
                                                            (line  4373)
* invoking a selector:                   Object-Oriented Terminology.
                                                            (line 13968)
* invoking Gforth:                       Invoking Gforth.   (line   516)
* invoking image files:                  Running Image Files.
                                                            (line 19955)
* ior type description:                  Notation.          (line  3913)
* ior values and meaning:                file-idef.         (line 19084)
* ior values and meaning <1>:            memory-idef.       (line 19270)
* IS:                                    Deferred Words.    (line  8481)
* is _name_ semantics, changing them:    Words with user-defined TO etc..
                                                            (line  8092)
* items on the stack after interpretation: Stack depth changes.
                                                            (line 18443)
* iterate over array:                    Counted Loops.     (line  6480)
* j:                                     Counted Loops.     (line  6600)
* JOIN:                                  Regular Expressions.
                                                            (line 15547)
* k:                                     Counted Loops.     (line  6603)
* k-alt-mask:                            Single-key input.  (line 12819)
* k-backspace:                           Single-key input.  (line 12827)
* k-ctrl-mask:                           Single-key input.  (line 12817)
* k-delete:                              Single-key input.  (line 12781)
* k-down:                                Single-key input.  (line 12766)
* k-end:                                 Single-key input.  (line 12771)
* k-enter:                               Single-key input.  (line 12825)
* k-eof:                                 Single-key input.  (line 12847)
* k-f1:                                  Single-key input.  (line 12786)
* k-f10:                                 Single-key input.  (line 12804)
* k-f11:                                 Single-key input.  (line 12806)
* k-f12:                                 Single-key input.  (line 12808)
* k-f2:                                  Single-key input.  (line 12788)
* k-f3:                                  Single-key input.  (line 12790)
* k-f4:                                  Single-key input.  (line 12792)
* k-f5:                                  Single-key input.  (line 12794)
* k-f6:                                  Single-key input.  (line 12796)
* k-f7:                                  Single-key input.  (line 12798)
* k-f8:                                  Single-key input.  (line 12800)
* k-f9:                                  Single-key input.  (line 12802)
* k-home:                                Single-key input.  (line 12768)
* k-insert:                              Single-key input.  (line 12779)
* k-left:                                Single-key input.  (line 12760)
* k-mute:                                Single-key input.  (line 12839)
* k-next:                                Single-key input.  (line 12776)
* k-pause:                               Single-key input.  (line 12837)
* k-prior:                               Single-key input.  (line 12773)
* k-right:                               Single-key input.  (line 12762)
* k-sel:                                 Single-key input.  (line 12845)
* k-shift-mask:                          Single-key input.  (line 12815)
* k-tab:                                 Single-key input.  (line 12829)
* k-up:                                  Single-key input.  (line 12764)
* k-voldown:                             Single-key input.  (line 12843)
* k-volup:                               Single-key input.  (line 12841)
* k-winch:                               Single-key input.  (line 12833)
* kern*.fi, relocatability:              Fully Relocatable Image Files.
                                                            (line 19854)
* kerning:                               widget methods.    (line 20846)
* key:                                   Single-key input.  (line 12705)
* key-file:                              General files.     (line 11747)
* key-ior:                               Single-key input.  (line 12708)
* key?:                                  Single-key input.  (line 12712)
* key?-file:                             General files.     (line 11754)
* keyboard events, encoding in EKEY:     facility-idef.     (line 19023)
* kill:                                  Basic multi-tasking.
                                                            (line 16459)
* kill-task:                             Basic multi-tasking.
                                                            (line 16456)
* Kuehling, David:                       Emacs and Gforth.  (line 19536)
* l:                                     Locating source code definitions.
                                                            (line 15759)
* l,:                                    Dictionary allocation.
                                                            (line  5073)
* l!:                                    Special Memory Accesses.
                                                            (line  5448)
* L":                                    i18n and l10n.     (line 13120)
* l@:                                    Special Memory Accesses.
                                                            (line  5445)
* l>s:                                   Special Memory Accesses.
                                                            (line  5510)
* labels as values:                      Threading.         (line 20151)
* lalign:                                Address arithmetic.
                                                            (line  5664)
* laligned:                              Address arithmetic.
                                                            (line  5661)
* LANG - environment variable:           Environment variables.
                                                            (line   963)
* Language:                              i18n and l10n.     (line 13139)
* last word was headerless:              core-ambcond.      (line 18878)
* lastfit:                               widget methods.    (line 20876)
* late binding:                          Class Binding.     (line 14145)
* latest:                                Name token.        (line  9660)
* latestnt:                              Name token.        (line  9664)
* latestxt:                              Anonymous Definitions.
                                                            (line  7595)
* lbe:                                   Special Memory Accesses.
                                                            (line  5476)
* LC_ALL - environment variable:         Environment variables.
                                                            (line   965)
* LC_CTYPE - environment variable:       Environment variables.
                                                            (line   967)
* LEAVE:                                 Counted Loops.     (line  6612)
* leaving definitions, tutorial:         Leaving definitions or loops Tutorial.
                                                            (line  1914)
* leaving Gforth:                        Leaving Gforth.    (line   862)
* leaving loops, tutorial:               Leaving definitions or loops Tutorial.
                                                            (line  1914)
* left:                                  actor methods.     (line 20795)
* length of a line affected by \:        block-idef.        (line 18957)
* lfield::                               Standard Structures.
                                                            (line  8748)
* lib-error:                             Low-Level C Interface Words.
                                                            (line 17092)
* lib-sym:                               Low-Level C Interface Words.
                                                            (line 17090)
* Libraries in C interface:              Declaring OS-level libraries.
                                                            (line 16979)
* library interface names:               Defining library interfaces.
                                                            (line 16919)
* license:                               Help on Gforth.    (line   888)
* license for images:                    Image Licensing Issues.
                                                            (line 19711)
* lifetime of locals:                    How long do locals live?.
                                                            (line 13668)
* light-mode:                            Terminal output.   (line 12678)
* line input from terminal:              Line input and conversion.
                                                            (line 12886)
* line terminator on input:              core-idef.         (line 18614)
* line-end-hook:                         Text Interpreter Hooks.
                                                            (line 11030)
* lines and the text interpreter:        The Text Interpreter.
                                                            (line 10180)
* list:                                  Blocks.            (line 12128)
* LIST display format:                   block-idef.        (line 18953)
* list-size:                             Locals implementation.
                                                            (line 13844)
* lit,:                                  Literals.          (line  9859)
* Literal:                               Literals.          (line  9854)
* literal tutorial:                      Literal Tutorial.  (line  2729)
* Literals:                              Literals.          (line  9818)
* Literals (in source code):             Literals in source code.
                                                            (line  3600)
* literals for characters and strings:   String and character literals.
                                                            (line  5796)
* little-endian:                         Special Memory Accesses.
                                                            (line  5409)
* ll:                                    Locating uses of a word.
                                                            (line 15824)
* lle:                                   Special Memory Accesses.
                                                            (line  5480)
* load:                                  Blocks.            (line 12174)
* load-cov:                              Code Coverage.     (line 16362)
* loader for image files:                Image File Background.
                                                            (line 19767)
* loading files at startup:              Invoking Gforth.   (line   813)
* loading Forth code, tutorial:          Using files for Forth code Tutorial.
                                                            (line  1281)
* local in interpretation state:         locals-ambcond.    (line 19256)
* local variables, tutorial:             Local Variables Tutorial.
                                                            (line  1592)
* locale and case-sensitivity:           core-idef.         (line 18569)
* locale-csv:                            i18n and l10n.     (line 13157)
* locale-csv-out:                        i18n and l10n.     (line 13167)
* locale-file:                           i18n and l10n.     (line 13148)
* locale!:                               i18n and l10n.     (line 13135)
* locale@:                               i18n and l10n.     (line 13132)
* locals:                                Locals.            (line 13307)
* locals and return stack:               Return stack.      (line  4847)
* locals flavours:                       Gforth locals.     (line 13344)
* locals implementation:                 Locals implementation.
                                                            (line 13746)
* locals information on the control-flow stack: Locals implementation.
                                                            (line 13830)
* locals initialization:                 Gforth locals.     (line 13379)
* locals lifetime:                       How long do locals live?.
                                                            (line 13668)
* locals programming style:              Locals programming style.
                                                            (line 13683)
* locals stack:                          Stack Manipulation.
                                                            (line  4770)
* locals stack <1>:                      Locals implementation.
                                                            (line 13746)
* locals types:                          Gforth locals.     (line 13336)
* locals visibility:                     Where are locals visible by name?.
                                                            (line 13484)
* locals words, ambiguous conditions:    locals-ambcond.    (line 19255)
* locals words, implementation-defined options: locals-idef.
                                                            (line 19246)
* locals words, system documentation:    The optional Locals word set.
                                                            (line 19243)
* locals, default type:                  Gforth locals.     (line 13376)
* locals, Gforth style:                  Gforth locals.     (line 13315)
* locals, maximum number in a definition: locals-idef.      (line 19247)
* locals, Standard Forth style:          Standard Forth locals.
                                                            (line 13877)
* locals|:                               Locals definition words.
                                                            (line 13441)
* locate:                                Locating source code definitions.
                                                            (line 15745)
* lock:                                  Semaphores.        (line 16569)
* log2:                                  Bitwise operations.
                                                            (line  4420)
* long long:                             Portability.       (line 20120)
* LOOP:                                  Counted Loops.     (line  6582)
* loop control parameters not available: core-ambcond.      (line 18873)
* loops without count:                   General Loops.     (line  6329)
* loops, counted:                        Counted Loops.     (line  6362)
* loops, counted, tutorial:              Counted loops Tutorial.
                                                            (line  1822)
* loops, endless:                        General Loops.     (line  6351)
* loops, indefinite, tutorial:           General Loops Tutorial.
                                                            (line  1757)
* lp!:                                   Stack pointer manipulation.
                                                            (line  4961)
* lp@:                                   Stack pointer manipulation.
                                                            (line  4958)
* lp+!:                                  Locals implementation.
                                                            (line 13762)
* lp+n:                                  Locals implementation.
                                                            (line 13760)
* lp0:                                   Stack pointer manipulation.
                                                            (line  4955)
* lrol:                                  Bitwise operations.
                                                            (line  4445)
* lror:                                  Bitwise operations.
                                                            (line  4449)
* lshift:                                Bitwise operations.
                                                            (line  4380)
* LSHIFT, large shift counts:            core-ambcond.      (line 18902)
* LU":                                   i18n and l10n.     (line 13125)
* lvalue::                               Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8849)
* m::                                    Objects Glossary.  (line 14576)
* m: usage:                              Method conveniences.
                                                            (line 14199)
* m*:                                    Mixed precision.   (line  4080)
* m*/:                                   Integer division.  (line  4210)
* m+:                                    Mixed precision.   (line  4078)
* macros:                                Compiling words.   (line  9806)
* Macros:                                Macros.            (line  9930)
* macros-wordlist:                       Substitute.        (line 13182)
* macros, advanced tutorial:             Advanced macros Tutorial.
                                                            (line  2757)
* magenta-input:                         Terminal output.   (line 12687)
* make-latest:                           Making a word current.
                                                            (line  8376)
* map-vocs:                              Word Lists.        (line 11293)
* mapping block ranges to files:         file-idef.         (line 19097)
* marker:                                Forgetting words.  (line 16045)
* max:                                   Single precision.  (line  4032)
* MAX-CHAR:                              Environmental Queries.
                                                            (line 11420)
* MAX-D:                                 Environmental Queries.
                                                            (line 11449)
* max-float:                             Environmental Queries.
                                                            (line 11471)
* MAX-N:                                 Environmental Queries.
                                                            (line 11443)
* MAX-U:                                 Environmental Queries.
                                                            (line 11446)
* MAX-UD:                                Environmental Queries.
                                                            (line 11452)
* MAX-XCHAR:                             Environmental Queries.
                                                            (line 11482)
* maxalign:                              Dictionary allocation.
                                                            (line  5125)
* maxaligned:                            Address arithmetic.
                                                            (line  5644)
* maxdepth-.s:                           Examining data.    (line 16001)
* maximum depth of file input nesting:   file-idef.         (line 19090)
* maximum number of locals in a definition: locals-idef.    (line 19247)
* maximum number of word lists in search order: search-idef.
                                                            (line 19337)
* maximum size of a counted string:      core-idef.         (line 18619)
* maximum size of a definition name, in characters: core-idef.
                                                            (line 18626)
* maximum size of a parsed string:       core-idef.         (line 18623)
* maximum size of input line:            file-idef.         (line 19094)
* maximum string length for ENVIRONMENT?, in characters: core-idef.
                                                            (line 18629)
* mem-do:                                Counted Loops.     (line  6571)
* mem,:                                  Dictionary allocation.
                                                            (line  5090)
* mem+do:                                Counted Loops.     (line  6566)
* memory access words:                   Memory Access.     (line  5354)
* memory access/allocation tutorial:     Memory Tutorial.   (line  1995)
* memory alignment tutorial:             Alignment Tutorial.
                                                            (line  2134)
* memory barrier:                        Hardware operations for multi-tasking.
                                                            (line 16613)
* memory block words:                    Memory Blocks.     (line  5696)
* memory overcommit for dictionary and stacks: Invoking Gforth.
                                                            (line   604)
* memory words:                          Memory.            (line  4966)
* memory-allocation word set:            Heap Allocation.   (line  5259)
* memory-allocation words, implementation-defined options: memory-idef.
                                                            (line 19269)
* memory-allocation words, system documentation: The optional Memory-Allocation word set.
                                                            (line 19266)
* message send:                          Object-Oriented Terminology.
                                                            (line 13968)
* meta recognizer:                       Disambiguating recognizers.
                                                            (line  3752)
* metacompiler:                          cross.fs.          (line 19920)
* metacompiler <1>:                      Cross Compiler.    (line 20624)
* method:                                Object-Oriented Terminology.
                                                            (line 13963)
* method <1>:                            Objects Glossary.  (line 14586)
* method <2>:                            Class Declaration. (line 14845)
* method <3>:                            Basic Mini-OOF Usage.
                                                            (line 14880)
* method conveniences:                   Method conveniences.
                                                            (line 14193)
* method map:                            Objects Implementation.
                                                            (line 14372)
* method selector:                       Object-Oriented Terminology.
                                                            (line 13957)
* method usage:                          Basic OOF Usage.   (line 14680)
* methods:                               Objects Glossary.  (line 14590)
* methods...end-methods:                 Dividing classes.  (line 14284)
* min:                                   Single precision.  (line  4030)
* mini-oof:                              Mini-OOF.          (line 14864)
* mini-oof example:                      Mini-OOF Example.  (line 14909)
* mini-oof usage:                        Basic Mini-OOF Usage.
                                                            (line 14872)
* mini-oof.fs, differences to other models: Comparison with other object models.
                                                            (line 15161)
* minimum search order:                  search-idef.       (line 19340)
* miscellaneous words:                   Miscellaneous Words.
                                                            (line 18317)
* mixed precision arithmetic words:      Mixed precision.   (line  4078)
* mkdir-parents:                         Directories.       (line 11888)
* mod:                                   Integer division.  (line  4138)
* modf:                                  Integer division.  (line  4143)
* modf-stage2m:                          Two-stage integer division.
                                                            (line  4305)
* modifying >IN:                         How does that work?.
                                                            (line  3326)
* Modifying a word defined earlier:      Making a word current.
                                                            (line  8372)
* modifying the contents of the input buffer or a string literal: core-ambcond.
                                                            (line 18794)
* mods:                                  Integer division.  (line  4141)
* modulus:                               Integer division.  (line  4087)
* most recent definition does not have a name (IMMEDIATE): core-ambcond.
                                                            (line 18878)
* motivation for object-oriented programming: Why object-oriented programming?.
                                                            (line 13918)
* move:                                  Memory Blocks.     (line  5710)
* ms:                                    Keeping track of Time.
                                                            (line 18287)
* MS, repeatability to be expected:      facility-idef.     (line 19035)
* Multiple exits from begin:             General loops with multiple exits.
                                                            (line  6638)
* multitasker:                           Multitasker.       (line 16373)
* Must now be used inside C-LIBRARY, see C interface doc: Migrating the C interface from earlier Gforth.
                                                            (line 17159)
* mux:                                   Bitwise operations.
                                                            (line  4375)
* mwords:                                Word Lists.        (line 11263)
* n:                                     Locating source code definitions.
                                                            (line 15762)
* n, stack item type:                    Notation.          (line  3884)
* n/a:                                   Words with user-defined TO etc..
                                                            (line  8190)
* n>r:                                   Return stack.      (line  4899)
* name:                                  The Input Stream.  (line 11072)
* name dictionary:                       Introducing the Text Interpreter.
                                                            (line  2978)
* name field address:                    Name token.        (line  9744)
* name lookup, case-sensitivity:         core-idef.         (line 18569)
* name not defined by VALUE or (LOCAL) used by TO: locals-ambcond.
                                                            (line 19261)
* name not defined by VALUE used by TO:  core-ambcond.      (line 18881)
* name not found:                        core-ambcond.      (line 18727)
* name not found (', POSTPONE, ['], [COMPILE]): core-ambcond.
                                                            (line 18886)
* name space:                            Memory model.      (line  4973)
* name token (nt):                       Name token.        (line  9644)
* name, maximum length:                  core-idef.         (line 18626)
* name>compile:                          Name token.        (line  9693)
* name>interpret:                        Name token.        (line  9690)
* name>link:                             Name token.        (line  9713)
* name>string:                           Name token.        (line  9697)
* name$:                                 widget methods.    (line 20822)
* names for defined words:               Supplying names.   (line  7651)
* NaN:                                   Floating Point.    (line  4705)
* native@:                               i18n and l10n.     (line 13129)
* NDCS word:                             How to define combined words.
                                                            (line  9415)
* needs:                                 Forth source files.
                                                            (line 11672)
* negate:                                Single precision.  (line  4026)
* negative increment for counted loops:  Counted Loops.     (line  6433)
* Neon model:                            Comparison with other object models.
                                                            (line 15111)
* nested colon definitions:              Quotations.        (line  7619)
* new:                                   Basic Mini-OOF Usage.
                                                            (line 14899)
* new-color::                            widget methods.    (line 20941)
* newline:                               String and character literals.
                                                            (line  5913)
* newline character on input:            core-idef.         (line 18614)
* newtask:                               Basic multi-tasking.
                                                            (line 16398)
* newtask4:                              Basic multi-tasking.
                                                            (line 16407)
* NEXT:                                  Counted Loops.     (line  6594)
* next-arg:                              OS command line arguments.
                                                            (line 13254)
* next-case:                             General control structures with CASE.
                                                            (line  6774)
* next-section:                          Sections.          (line  5194)
* NEXT, direct threaded:                 Threading.         (line 20168)
* NEXT, indirect threaded:               Threading.         (line 20157)
* nextname:                              Supplying names.   (line  7655)
* NFA:                                   Name token.        (line  9744)
* nip:                                   Data stack.        (line  4777)
* nocov[:                                Code Coverage.     (line 16310)
* non-graphic characters and EMIT:       core-idef.         (line 18548)
* non-relocatable image files:           Non-Relocatable Image Files.
                                                            (line 19818)
* noname:                                Anonymous Definitions.
                                                            (line  7590)
* noname-from:                           Creating from a prototype.
                                                            (line  8350)
* noop:                                  Execution token.   (line  9637)
* nosplit?:                              String words.      (line  5993)
* notation of glossary entries:          Notation.          (line  3766)
* nothrow:                               Exception Handling.
                                                            (line  7066)
* nr>:                                   Return stack.      (line  4904)
* ns:                                    Keeping track of Time.
                                                            (line 18289)
* nt:                                    Locating exception source.
                                                            (line 15856)
* nt (name token):                       Name token.        (line  9644)
* NT Forth performance:                  Performance.       (line 20547)
* nt input format:                       Literals for tokens and addresses.
                                                            (line  3733)
* nt token input format:                 Literals for tokens and addresses.
                                                            (line  3733)
* nt, stack item type:                   Notation.          (line  3907)
* ntime:                                 Keeping track of Time.
                                                            (line 18304)
* number conversion:                     Number Conversion. (line 10313)
* number conversion - traps for the unwary: Number Conversion.
                                                            (line 10350)
* number of bits in one address unit:    core-idef.         (line 18646)
* number representation and arithmetic:  core-idef.         (line 18650)
* numeric comparison words:              Numeric comparison.
                                                            (line  4468)
* numeric output - formatted:            Formatted numeric output.
                                                            (line 12274)
* numeric output - simple/free-format:   Simple numeric output.
                                                            (line 12217)
* numeric output, FP:                    Floating-point output.
                                                            (line 12425)
* nw:                                    Locating uses of a word.
                                                            (line 15809)
* o>:                                    Mini-OOF2.         (line 15081)
* object:                                Object-Oriented Terminology.
                                                            (line 13950)
* object <1>:                            Objects Glossary.  (line 14595)
* object <2>:                            Basic Mini-OOF Usage.
                                                            (line 14877)
* object allocation options:             Creating objects.  (line 14111)
* object class:                          The Objects base class.
                                                            (line 14102)
* object creation:                       Creating objects.  (line 14111)
* object interfaces:                     Object Interfaces. (line 14320)
* object models, comparison:             Comparison with other object models.
                                                            (line 15104)
* object-::                              The OOF base class.
                                                            (line 14772)
* object-:::                             The OOF base class.
                                                            (line 14784)
* object-':                              The OOF base class.
                                                            (line 14806)
* object-[]:                             The OOF base class.
                                                            (line 14778)
* object-asptr:                          The OOF base class.
                                                            (line 14776)
* object-bind:                           The OOF base class.
                                                            (line 14795)
* object-bound:                          The OOF base class.
                                                            (line 14797)
* object-class:                          The OOF base class.
                                                            (line 14749)
* object-class?:                         The OOF base class.
                                                            (line 14753)
* object-definitions:                    The OOF base class.
                                                            (line 14751)
* object-dispose:                        The OOF base class.
                                                            (line 14763)
* object-endwith:                        The OOF base class.
                                                            (line 14817)
* object-init:                           The OOF base class.
                                                            (line 14761)
* object-is:                             The OOF base class.
                                                            (line 14801)
* object-link:                           The OOF base class.
                                                            (line 14799)
* object-map discussion:                 Objects Implementation.
                                                            (line 14368)
* object-new:                            The OOF base class.
                                                            (line 14768)
* object-new[]:                          The OOF base class.
                                                            (line 14770)
* object-oriented programming:           Objects.           (line 13989)
* object-oriented programming <1>:       OOF.               (line 14639)
* object-oriented programming motivation: Why object-oriented programming?.
                                                            (line 13918)
* object-oriented programming style:     Object-Oriented Programming Style.
                                                            (line 14126)
* object-oriented terminology:           Object-Oriented Terminology.
                                                            (line 13943)
* object-postpone:                       The OOF base class.
                                                            (line 14808)
* object-ptr:                            The OOF base class.
                                                            (line 14774)
* object-self:                           The OOF base class.
                                                            (line 14790)
* object-super:                          The OOF base class.
                                                            (line 14786)
* object-with:                           The OOF base class.
                                                            (line 14815)
* objects:                               Objects.           (line 13989)
* objects, basic usage:                  Basic Objects Usage.
                                                            (line 14040)
* objects.fs:                            Objects.           (line 13989)
* objects.fs <1>:                        OOF.               (line 14639)
* objects.fs Glossary:                   Objects Glossary.  (line 14482)
* objects.fs implementation:             Objects Implementation.
                                                            (line 14368)
* objects.fs properties:                 Properties of the Objects model.
                                                            (line 14006)
* obsolete?:                             Name token.        (line  9709)
* of:                                    General control structures with CASE.
                                                            (line  6778)
* off:                                   Boolean Flags.     (line  3985)
* on:                                    Boolean Flags.     (line  3982)
* once:                                  Debugging.         (line 16118)
* Only:                                  Word Lists.        (line 11214)
* oof:                                   OOF.               (line 14639)
* oof.fs:                                Objects.           (line 13989)
* oof.fs <1>:                            OOF.               (line 14639)
* oof.fs base class:                     The OOF base class.
                                                            (line 14735)
* oof.fs properties:                     Properties of the OOF model.
                                                            (line 14652)
* oof.fs usage:                          Basic OOF Usage.   (line 14675)
* oof.fs, differences to other models:   Comparison with other object models.
                                                            (line 15146)
* open-blocks:                           Blocks.            (line 12109)
* open-dir:                              Directories.       (line 11854)
* open-file:                             General files.     (line 11718)
* open-lib:                              Low-Level C Interface Words.
                                                            (line 17088)
* open-path-file:                        General Search Paths.
                                                            (line 11957)
* open-pipe:                             Pipes.             (line 12963)
* operating system - passing commands:   Passing Commands to the OS.
                                                            (line 18255)
* operator's terminal facilities available: core-other.     (line 18922)
* opt::                                  User-defined compile-comma.
                                                            (line  8230)
* options on the command line:           Invoking Gforth.   (line   516)
* or:                                    Bitwise operations.
                                                            (line  4369)
* order:                                 Word Lists.        (line 11218)
* orig, control-flow stack item:         Arbitrary control structures.
                                                            (line  6810)
* OS command line arguments:             OS command line arguments.
                                                            (line 13245)
* os-class:                              Environmental Queries.
                                                            (line 11532)
* os-type:                               Environmental Queries.
                                                            (line 11536)
* other system documentation, block words: block-other.     (line 18986)
* other system documentation, core words: core-other.       (line 18918)
* out:                                   Miscellaneous output.
                                                            (line 12535)
* outer interpreter:                     Introducing the Text Interpreter.
                                                            (line  2941)
* outer interpreter <1>:                 Stacks and Postfix notation.
                                                            (line  3049)
* outer interpreter <2>:                 The Text Interpreter.
                                                            (line 10173)
* outfile-execute:                       Redirection.       (line 11814)
* outfile-id:                            Redirection.       (line 11817)
* output in pipes:                       Gforth in pipes.   (line  1022)
* Output Redirection:                    Redirection.       (line 11799)
* output to terminal:                    Terminal output.   (line 12612)
* over:                                  Data stack.        (line  4781)
* overcommit memory for dictionary and stacks: Invoking Gforth.
                                                            (line   604)
* overflow of the pictured numeric output string: core-ambcond.
                                                            (line 18797)
* overrides:                             Objects Glossary.  (line 14598)
* overrides usage:                       Basic Objects Usage.
                                                            (line 14063)
* pad:                                   Memory Blocks.     (line  5733)
* PAD size:                              core-idef.         (line 18688)
* PAD use by nonstandard words:          core-other.        (line 18919)
* page:                                  Terminal output.   (line 12629)
* par-split:                             widget methods.    (line 20915)
* parameter stack:                       Stack Manipulation.
                                                            (line  4762)
* parameters are not of the same type (DO, ?DO, WITHIN): core-ambcond.
                                                            (line 18889)
* parent class:                          Object-Oriented Terminology.
                                                            (line 13980)
* parent class binding:                  Class Binding.     (line 14166)
* parent-w:                              widget methods.    (line 20816)
* parse:                                 The Input Stream.  (line 11055)
* parse-name:                            The Input Stream.  (line 11065)
* parse-word:                            The Input Stream.  (line 11068)
* parsed string overflow:                core-ambcond.      (line 18800)
* parsed string, maximum size:           core-idef.         (line 18623)
* parsing words:                         How does that work?.
                                                            (line  3314)
* parsing words <1>:                     How does that work?.
                                                            (line  3338)
* pass:                                  Basic multi-tasking.
                                                            (line 16440)
* patching threaded code:                Dynamic Superinstructions.
                                                            (line 20364)
* path for included:                     Search Paths.      (line 11895)
* path+:                                 General Search Paths.
                                                            (line 11978)
* path=:                                 General Search Paths.
                                                            (line 11981)
* pause:                                 Basic multi-tasking.
                                                            (line 16500)
* pedigree of Gforth:                    Origin.            (line 21084)
* perform:                               Execution token.   (line  9629)
* performance of some Forth interpreters: Performance.      (line 20531)
* persistent form of dictionary:         Image Files.       (line 19704)
* PFE performance:                       Performance.       (line 20547)
* pi:                                    Floating Point.    (line  4683)
* pick:                                  Data stack.        (line  4795)
* pictured numeric output:               Formatted numeric output.
                                                            (line 12274)
* pictured numeric output buffer, size:  core-idef.         (line 18684)
* pictured numeric output string, overflow: core-ambcond.   (line 18797)
* pipes, creating your own:              Pipes.             (line 12959)
* pipes, Gforth as part of:              Gforth in pipes.   (line  1011)
* place:                                 Counted string words.
                                                            (line  6233)
* postpone:                              Macros.            (line  9947)
* POSTPONE applied to [IF]:              programming-ambcond.
                                                            (line 19319)
* POSTPONE or [COMPILE] applied to TO:   core-ambcond.      (line 18894)
* postpone tutorial:                     POSTPONE Tutorial. (line  2674)
* postpone,:                             Compilation token. (line  9792)
* postponing:                            Performing translator actions.
                                                            (line 10987)
* Pountain's object-oriented model:      Comparison with other object models.
                                                            (line 15126)
* pow2?:                                 Bitwise operations.
                                                            (line  4424)
* precision:                             Floating-point output.
                                                            (line 12453)
* precompiled Forth code:                Image Files.       (line 19704)
* prefix `:                              Execution token.   (line  9564)
* prepend-where:                         Locating uses of a word.
                                                            (line 15841)
* preserve:                              Deferred Words.    (line  8547)
* previous:                              Word Lists.        (line 11202)
* previous-section:                      Sections.          (line  5199)
* previous, search order empty:          search-ambcond.    (line 19354)
* primitive source format:               Automatic Generation.
                                                            (line 20407)
* primitive-centric threaded code:       Direct or Indirect Threaded?.
                                                            (line 20226)
* primitives, assembly code listing:     Produced code.     (line 20523)
* primitives, automatic generation:      Automatic Generation.
                                                            (line 20398)
* primitives, implementation:            Primitives.        (line 20395)
* primitives, keeping the TOS in a register: TOS Optimization.
                                                            (line 20477)
* prims2x.fs:                            Automatic Generation.
                                                            (line 20398)
* print:                                 Objects Glossary.  (line 14605)
* printdebugdata:                        Debugging.         (line 16103)
* private discussion:                    Classes and Scoping.
                                                            (line 14273)
* procedures, tutorial:                  Colon Definitions Tutorial.
                                                            (line  1349)
* process-option:                        Modifying the Startup Sequence.
                                                            (line 20082)
* program data space available:          core-other.        (line 18928)
* programming style, locals:             Locals programming style.
                                                            (line 13683)
* programming style, object-oriented:    Object-Oriented Programming Style.
                                                            (line 14126)
* programming tools:                     Programming Tools. (line 15722)
* programming-tools words, ambiguous conditions: programming-ambcond.
                                                            (line 19301)
* programming-tools words, implementation-defined options: programming-idef.
                                                            (line 19281)
* programming-tools words, system documentation: The optional Programming-Tools word set.
                                                            (line 19278)
* prompt:                                core-idef.         (line 18698)
* pronunciation of words:                Notation.          (line  3821)
* protected:                             Objects Glossary.  (line 14609)
* protected discussion:                  Classes and Scoping.
                                                            (line 14273)
* pthread:                               Pthreads.          (line 16382)
* ptr:                                   Class Declaration. (line 14829)
* public:                                Objects Glossary.  (line 14612)
* query:                                 Input Sources.     (line 10305)
* quit:                                  Miscellaneous Words.
                                                            (line 18320)
* quotations:                            Quotations.        (line  7619)
* r, stack item type:                    Notation.          (line  3892)
* r'@:                                   Return stack.      (line  4882)
* r@:                                    Return stack.      (line  4880)
* r/o:                                   General files.     (line 11702)
* r/w:                                   General files.     (line 11704)
* r>:                                    Return stack.      (line  4878)
* raise:                                 widget methods.    (line 20849)
* ranges for integer types:              core-idef.         (line 18654)
* rdrop:                                 Return stack.      (line  4889)
* re-color:                              widget methods.    (line 20964)
* re-emoji-color:                        widget methods.    (line 20972)
* re-fade-color:                         widget methods.    (line 20976)
* re-text-color:                         widget methods.    (line 20968)
* re-text-emoji-fade-color:              widget methods.    (line 20980)
* read-csv:                              CSV reading and writing.
                                                            (line 13223)
* read-dir:                              Directories.       (line 11858)
* read-file:                             General files.     (line 11729)
* read-line:                             General files.     (line 11735)
* read-only data space regions:          core-idef.         (line 18661)
* reading from file positions not yet written: file-ambcond.
                                                            (line 19115)
* rec-body:                              Default Recognizers.
                                                            (line 10707)
* rec-complex:                           Default Recognizers.
                                                            (line 10686)
* rec-dtick:                             Default Recognizers.
                                                            (line 10699)
* rec-env:                               Default Recognizers.
                                                            (line 10711)
* rec-float:                             Default Recognizers.
                                                            (line 10683)
* rec-locals:                            Default Recognizers.
                                                            (line 10667)
* rec-meta:                              Default Recognizers.
                                                            (line 10716)
* rec-moof2:                             Mini-OOF2.         (line 15087)
* rec-nothing:                           Recognizer order.  (line 10753)
* rec-nt:                                Default Recognizers.
                                                            (line 10664)
* rec-num:                               Default Recognizers.
                                                            (line 10680)
* rec-scope:                             Default Recognizers.
                                                            (line 10671)
* rec-string:                            Default Recognizers.
                                                            (line 10690)
* rec-tick:                              Default Recognizers.
                                                            (line 10703)
* rec-to:                                Default Recognizers.
                                                            (line 10694)
* receiving object:                      Object-Oriented Terminology.
                                                            (line 13974)
* reciprocal of integer:                 Two-stage integer division.
                                                            (line  4236)
* recognizer-sequence::                  Recognizer order.  (line 10732)
* Recognizers normal usage:              Default Recognizers.
                                                            (line 10508)
* recongizers:                           Recognizers.       (line 10484)
* records:                               Structures.        (line  8656)
* records tutorial:                      Arrays and Records Tutorial.
                                                            (line  2649)
* recover (old Gforth versions):         Exception Handling.
                                                            (line  7151)
* recurse:                               Calls and returns. (line  6899)
* RECURSE appears after DOES>:           core-ambcond.      (line 18842)
* recursion tutorial:                    Recursion Tutorial.
                                                            (line  1875)
* recursive:                             Calls and returns. (line  6895)
* recursive definitions:                 Calls and returns. (line  6889)
* Redirection:                           Redirection.       (line 11799)
* refill:                                The Input Stream.  (line 11085)
* regexps:                               Regular Expressions.
                                                            (line 15532)
* relocating loader:                     Image File Background.
                                                            (line 19767)
* relocation at load-time:               Image File Background.
                                                            (line 19758)
* relocation at run-time:                Image File Background.
                                                            (line 19752)
* remainder:                             Integer division.  (line  4087)
* rename-file:                           General files.     (line 11726)
* REPEAT:                                Arbitrary control structures.
                                                            (line  6869)
* repeatability to be expected from the execution of MS: facility-idef.
                                                            (line 19035)
* replace-word:                          Debugging.         (line 16136)
* replacer::                             Substitute.        (line 13189)
* replaces:                              Substitute.        (line 13185)
* Replication:                           Dynamic Superinstructions.
                                                            (line 20265)
* report the words used in your program: Standard Report.   (line 18400)
* reposition-file:                       General files.     (line 11775)
* REPOSITION-FILE, outside the file's boundaries: file-ambcond.
                                                            (line 19111)
* represent:                             Floating-point output.
                                                            (line 12515)
* REPRESENT, results when float is out of range: floating-idef.
                                                            (line 19148)
* require:                               Forth source files.
                                                            (line 11669)
* require, placement in files:           Emacs Tags.        (line 19587)
* required:                              Forth source files.
                                                            (line 11663)
* reserving data space:                  Dictionary allocation.
                                                            (line  5018)
* resize:                                Heap Allocation.   (line  5282)
* resize-file:                           General files.     (line 11779)
* resized:                               widget methods.    (line 20918)
* restart:                               Basic multi-tasking.
                                                            (line 16495)
* restore:                               Exception Handling.
                                                            (line  7184)
* restore-input:                         Input Sources.     (line 10294)
* RESTORE-INPUT, Argument type mismatch: core-ambcond.      (line 18845)
* restrict:                              How to define immediate words.
                                                            (line  9409)
* Result out of range:                   Integer division.  (line  4087)
* result out of range:                   core-ambcond.      (line 18803)
* Result out of range (on integer division): Integer division.
                                                            (line  4221)
* return stack:                          Stack Manipulation.
                                                            (line  4767)
* return stack and locals:               Return stack.      (line  4847)
* return stack dump with gforth-fast:    Error messages.    (line 18379)
* return stack manipulation words:       Return stack.      (line  4847)
* return stack space available:          core-other.        (line 18933)
* return stack tutorial:                 Return Stack Tutorial.
                                                            (line  1943)
* return stack underflow:                core-ambcond.      (line 18814)
* return-stack-cells:                    Environmental Queries.
                                                            (line 11455)
* returning from a definition:           Calls and returns. (line  6889)
* reveal:                                Creating from a prototype.
                                                            (line  8340)
* reveal!:                               Creating from a prototype.
                                                            (line  8344)
* rol:                                   Bitwise operations.
                                                            (line  4453)
* roll:                                  Data stack.        (line  4798)
* Root:                                  Word Lists.        (line 11269)
* ror:                                   Bitwise operations.
                                                            (line  4456)
* rot:                                   Data stack.        (line  4789)
* rounding of floating-point numbers:    floating-idef.     (line 19152)
* rp!:                                   Stack pointer manipulation.
                                                            (line  4953)
* rp@:                                   Stack pointer manipulation.
                                                            (line  4951)
* rp0:                                   Stack pointer manipulation.
                                                            (line  4948)
* rpick:                                 Return stack.      (line  4885)
* rshift:                                Bitwise operations.
                                                            (line  4383)
* RSHIFT, large shift counts:            core-ambcond.      (line 18902)
* run-time code generation, tutorial:    Advanced macros Tutorial.
                                                            (line  2757)
* run-time semantics:                    Which semantics do existing words have?.
                                                            (line  9275)
* running Gforth:                        Invoking Gforth.   (line   516)
* running image files:                   Running Image Files.
                                                            (line 19955)
* Rydqvist, Goran:                       Emacs and Gforth.  (line 19536)
* S":                                    String and character literals.
                                                            (line  5860)
* S", number of string buffers:          file-idef.         (line 19101)
* S", size of string buffer:             file-idef.         (line 19105)
* s//:                                   Regular Expressions.
                                                            (line 15705)
* s\":                                   String and character literals.
                                                            (line  5850)
* s+:                                    String words.      (line  6045)
* s>>:                                   Regular Expressions.
                                                            (line 15692)
* s>d:                                   Double precision.  (line  4059)
* s>f:                                   Floating Point.    (line  4566)
* s>number?:                             Line input and conversion.
                                                            (line 12904)
* s>unumber?:                            Line input and conversion.
                                                            (line 12907)
* safe/string:                           String words.      (line  6005)
* save-buffer:                           Blocks.            (line 12169)
* save-buffers:                          Blocks.            (line 12165)
* save-cov:                              Code Coverage.     (line 16359)
* save-input:                            Input Sources.     (line 10289)
* save-mem:                              Memory blocks and heap allocation.
                                                            (line  5297)
* save-mem-dict:                         Dictionary allocation.
                                                            (line  5095)
* savesystem:                            Non-Relocatable Image Files.
                                                            (line 19832)
* savesystem during gforthmi:            gforthmi.          (line 19905)
* scan:                                  String words.      (line  5972)
* scan-back:                             String words.      (line  5977)
* scan-translate-string:                 Define recognizers with existing translators.
                                                            (line 10850)
* scope:                                 Where are locals visible by name?.
                                                            (line 13489)
* scope of locals:                       Where are locals visible by name?.
                                                            (line 13484)
* scoping and classes:                   Classes and Scoping.
                                                            (line 14258)
* scr:                                   Blocks.            (line 12132)
* scripting with Gforth:                 Invoking Gforth.   (line   813)
* scrolled:                              actor methods.     (line 20768)
* scvalue::                              Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8853)
* seal:                                  Word Lists.        (line 11279)
* search:                                String words.      (line  5966)
* search order stack:                    Word Lists.        (line 11129)
* search order, maximum depth:           search-idef.       (line 19337)
* search order, minimum:                 search-idef.       (line 19340)
* search order, tutorial:                Wordlists and Search Order Tutorial.
                                                            (line  2844)
* search path control, source files:     Source Search Paths.
                                                            (line 11929)
* search path control, source files <1>: General Search Paths.
                                                            (line 11952)
* search path for files:                 Search Paths.      (line 11895)
* search-order words, ambiguous conditions: search-ambcond. (line 19345)
* search-order words, implementation-defined options: search-idef.
                                                            (line 19336)
* search-order words, system documentation: The optional Search-Order word set.
                                                            (line 19333)
* search-wordlist:                       Word Lists.        (line 11245)
* sections and contiguous regions:       Sections.          (line  5131)
* see:                                   Examining compiled code.
                                                            (line 15868)
* see tutorial:                          Decompilation Tutorial.
                                                            (line  1381)
* see-code:                              Examining compiled code.
                                                            (line 15887)
* see-code-range:                        Examining compiled code.
                                                            (line 15901)
* SEE, source and format of output:      programming-idef.  (line 19293)
* select:                                Boolean Flags.     (line  3988)
* selection control structures:          Selection.         (line  6262)
* selector:                              Object-Oriented Terminology.
                                                            (line 13957)
* selector <1>:                          Objects Glossary.  (line 14616)
* selector implementation, class:        Objects Implementation.
                                                            (line 14376)
* selector invocation:                   Object-Oriented Terminology.
                                                            (line 13968)
* selector invocation, restrictions:     Basic Objects Usage.
                                                            (line 14092)
* selector invocation, restrictions <1>: Basic OOF Usage.   (line 14725)
* selector usage:                        Basic Objects Usage.
                                                            (line 14042)
* selectors and stack effects:           Object-Oriented Programming Style.
                                                            (line 14128)
* selectors common to hardly-related classes: Object Interfaces.
                                                            (line 14325)
* semantics tutorial:                    Interpretation and Compilation Semantics and Immediacy Tutorial.
                                                            (line  2342)
* semantics, arbitrary combination of interpretation and compilation: How to define combined words.
                                                            (line  9415)
* semantics, changing the to/+to/action-of/is/addr _name_ semantics: Words with user-defined TO etc..
                                                            (line  8092)
* semantics, interpretation and compilation: Interpretation and Compilation Semantics.
                                                            (line  9170)
* semantics, interpretation/execution:   Interpretation and Compilation Semantics.
                                                            (line  9180)
* semantics, run-time:                   Which semantics do existing words have?.
                                                            (line  9275)
* semaphore:                             Semaphores.        (line 16565)
* send-event:                            Message queues.    (line 16642)
* set:                                   actor methods.     (line 20807)
* set->comp:                             Header methods.    (line 18117)
* set->int:                              Header methods.    (line 18105)
* set-compsem:                           How to define combined words.
                                                            (line  9520)
* set-current:                           Word Lists.        (line 11160)
* set-dir:                               Directories.       (line 11881)
* set-does>:                             CREATE..DOES> details.
                                                            (line  7911)
* set-execute:                           Header methods.    (line 18035)
* set-name>link:                         Header methods.    (line 18136)
* set-name>string:                       Header methods.    (line 18132)
* set-optimizer:                         User-defined compile-comma.
                                                            (line  8224)
* set-order:                             Word Lists.        (line 11179)
* set-precision:                         Floating-point output.
                                                            (line 12457)
* set-stack:                             User-defined Stacks.
                                                            (line  9159)
* set-to:                                Words with user-defined TO etc..
                                                            (line  8208)
* sf_, stack item type:                  Notation.          (line  3905)
* sf!:                                   Memory Access.     (line  5394)
* sf@:                                   Memory Access.     (line  5390)
* sf@ or sf! used with an address that is not single-float aligned: floating-ambcond.
                                                            (line 19185)
* sfalign:                               Dictionary allocation.
                                                            (line  5117)
* sfaligned:                             Address arithmetic.
                                                            (line  5625)
* sffield::                              Standard Structures.
                                                            (line  8739)
* sfloat/:                               Address arithmetic.
                                                            (line  5621)
* sfloat%:                               Gforth structs.    (line  9110)
* sfloat+:                               Address arithmetic.
                                                            (line  5618)
* sfloats:                               Address arithmetic.
                                                            (line  5614)
* sfvalue::                              Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8873)
* sh:                                    Passing Commands to the OS.
                                                            (line 18258)
* sh-get:                                Passing Commands to the OS.
                                                            (line 18270)
* Shared libraries in C interface:       Declaring OS-level libraries.
                                                            (line 16979)
* shell commands:                        Passing Commands to the OS.
                                                            (line 18255)
* shift-args:                            OS command line arguments.
                                                            (line 13288)
* short-where:                           Locating uses of a word.
                                                            (line 15834)
* show:                                  actor methods.     (line 20798)
* show-you:                              actor methods.     (line 20810)
* sign:                                  Formatted numeric output.
                                                            (line 12338)
* sign extension:                        Special Memory Accesses.
                                                            (line  5409)
* silent exiting from Gforth:            Gforth in pipes.   (line  1024)
* simple defining words:                 CREATE.            (line  7259)
* simple loops:                          General Loops.     (line  6329)
* simple-fkey-string:                    Single-key input.  (line 12878)
* simple-see:                            Examining compiled code.
                                                            (line 15877)
* simple-see-range:                      Examining compiled code.
                                                            (line 15884)
* single precision arithmetic words:     Single precision.  (line  4003)
* single-assignment style for locals:    Locals programming style.
                                                            (line 13702)
* single-cell numbers, input format:     Integer and character literals.
                                                            (line  3603)
* single-key input:                      Single-key input.  (line 12702)
* singlestep Debugger:                   Singlestep Debugger.
                                                            (line 16233)
* size of buffer at WORD:                core-idef.         (line 18664)
* size of the dictionary and the stacks: Invoking Gforth.   (line   568)
* size of the keyboard terminal buffer:  core-idef.         (line 18677)
* size of the pictured numeric output buffer: core-idef.    (line 18684)
* size of the scratch area returned by PAD: core-idef.      (line 18688)
* size parameters for command-line options: Invoking Gforth.
                                                            (line   568)
* skip:                                  String words.      (line  5981)
* sleep:                                 Basic multi-tasking.
                                                            (line 16467)
* slit,:                                 Literals.          (line  9896)
* SLiteral:                              Literals.          (line  9890)
* slurp-fid:                             General files.     (line 11784)
* slurp-file:                            General files.     (line 11781)
* slvalue::                              Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8861)
* sm/rem:                                Integer division.  (line  4167)
* source:                                The Text Interpreter.
                                                            (line 10230)
* source code for exception:             Locating exception source.
                                                            (line 15854)
* source code of a word:                 Locating source code definitions.
                                                            (line 15725)
* source location of error or debugging output in Emacs: Emacs and Gforth.
                                                            (line 19551)
* source-id:                             Input Sources.     (line 10280)
* SOURCE-ID, behaviour when BLK is non-zero: file-ambcond.  (line 19135)
* sourcefilename:                        Forth source files.
                                                            (line 11681)
* sourceline#:                           Forth source files.
                                                            (line 11688)
* sp!:                                   Stack pointer manipulation.
                                                            (line  4939)
* sp@:                                   Stack pointer manipulation.
                                                            (line  4937)
* sp0:                                   Stack pointer manipulation.
                                                            (line  4934)
* space:                                 Miscellaneous output.
                                                            (line 12529)
* space delimiters:                      core-idef.         (line 18585)
* spaces:                                Miscellaneous output.
                                                            (line 12532)
* span:                                  Line input and conversion.
                                                            (line 12952)
* spawn:                                 Cilk.              (line 16695)
* spawn1:                                Cilk.              (line 16701)
* spawn2:                                Cilk.              (line 16704)
* speed, startup:                        Startup speed.     (line  1054)
* split:                                 widget methods.    (line 20873)
* stability of Gforth:                   Stability Goals.   (line   471)
* stack:                                 User-defined Stacks.
                                                            (line  9135)
* stack depth changes during interpretation: Stack depth changes.
                                                            (line 18443)
* stack effect:                          Notation.          (line  3776)
* Stack effect design, tutorial:         Designing the stack effect Tutorial.
                                                            (line  1545)
* stack effect of DOES>-parts:           User-defined defining words using CREATE.
                                                            (line  7790)
* stack effect of included files:        Forth source files.
                                                            (line 11634)
* stack effects of selectors:            Object-Oriented Programming Style.
                                                            (line 14128)
* stack empty:                           core-ambcond.      (line 18814)
* stack item types:                      Notation.          (line  3874)
* stack manipulation tutorial:           Stack Manipulation Tutorial.
                                                            (line  1236)
* stack manipulation words:              Stack Manipulation.
                                                            (line  4760)
* stack manipulation words, floating-point stack: Floating point stack.
                                                            (line  4821)
* stack manipulation words, return stack: Return stack.     (line  4847)
* stack manipulations words, data stack: Data stack.        (line  4775)
* stack overflow:                        core-ambcond.      (line 18761)
* stack pointer manipulation words:      Stack pointer manipulation.
                                                            (line  4931)
* stack size default:                    Stack and Dictionary Sizes.
                                                            (line 19934)
* stack size, cache-friendly:            Stack and Dictionary Sizes.
                                                            (line 19947)
* stack space available:                 core-other.        (line 18938)
* stack tutorial:                        Stack Tutorial.    (line  1172)
* stack underflow:                       core-ambcond.      (line 18814)
* stack-cells:                           Environmental Queries.
                                                            (line 11458)
* stack-effect comments, tutorial:       Stack-Effect Comments Tutorial.
                                                            (line  1398)
* stack, user-defined:                   User-defined Stacks.
                                                            (line  9121)
* stack::                                User-defined Stacks.
                                                            (line  9138)
* stack>:                                User-defined Stacks.
                                                            (line  9141)
* stacksize:                             Basic multi-tasking.
                                                            (line 16414)
* stacksize4:                            Basic multi-tasking.
                                                            (line 16417)
* staged/-divisor:                       Two-stage integer division.
                                                            (line  4336)
* staged/-size:                          Two-stage integer division.
                                                            (line  4294)
* Standard conformance of Gforth:        Standard conformance.
                                                            (line 18484)
* starting Gforth tutorial:              Starting Gforth Tutorial.
                                                            (line  1115)
* startup sequence for image file:       Modifying the Startup Sequence.
                                                            (line 20032)
* Startup speed:                         Startup speed.     (line  1054)
* state:                                 The Text Interpreter.
                                                            (line 10247)
* state - effect on the text interpreter: How does that work?.
                                                            (line  3342)
* STATE values:                          core-idef.         (line 18708)
* state-smart words (are a bad idea):    How to define combined words.
                                                            (line  9463)
* static:                                Class Declaration. (line 14850)
* status-color:                          Terminal output.   (line 12666)
* stderr:                                General files.     (line 11793)
* stderr and pipes:                      Gforth in pipes.   (line  1049)
* stdin:                                 General files.     (line 11787)
* stdout:                                General files.     (line 11790)
* stop:                                  Basic multi-tasking.
                                                            (line 16470)
* stop-dns:                              Basic multi-tasking.
                                                            (line 16476)
* stop-ns:                               Basic multi-tasking.
                                                            (line 16473)
* str<:                                  String words.      (line  5957)
* str=:                                  String words.      (line  5954)
* str=?:                                 Regular Expressions.
                                                            (line 15628)
* String input format:                   String and environment variable literals.
                                                            (line  3706)
* string larger than pictured numeric output area (f., fe., fs.): floating-ambcond.
                                                            (line 19236)
* string literals:                       String and character literals.
                                                            (line  5796)
* string longer than a counted string returned by WORD: core-ambcond.
                                                            (line 18898)
* string words with $:                   $tring words.      (line  6076)
* string-parse:                          The Input Stream.  (line 11060)
* string-prefix?:                        String words.      (line  5960)
* string-suffix?:                        String words.      (line  5963)
* string,:                               Counted string words.
                                                            (line  6240)
* strings - see character strings:       String representations.
                                                            (line  5773)
* strings tutorial:                      Characters and Strings Tutorial.
                                                            (line  2085)
* struct:                                Gforth structs.    (line  9115)
* struct usage:                          Gforth structs.    (line  9036)
* structs tutorial:                      Arrays and Records Tutorial.
                                                            (line  2649)
* structure extension:                   Structure Extension.
                                                            (line  8958)
* structure of Forth programs:           Forth is written in Forth.
                                                            (line  3485)
* structures:                            Structures.        (line  8656)
* Structures in Forth200x:               Standard Structures.
                                                            (line  8669)
* sub-list?:                             Locals implementation.
                                                            (line 13842)
* substitute:                            Substitute.        (line 13201)
* success-color:                         Terminal output.   (line 12660)
* superclass binding:                    Class Binding.     (line 14166)
* Superinstructions:                     Dynamic Superinstructions.
                                                            (line 20265)
* swap:                                  Data stack.        (line  4787)
* swvalue::                              Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8857)
* symmetric division:                    Integer division.  (line  4092)
* Synonym:                               Synonyms.          (line  8621)
* synonyms:                              Synonyms.          (line  8610)
* syntax tutorial:                       Syntax Tutorial.   (line  1126)
* system:                                Passing Commands to the OS.
                                                            (line 18262)
* system dictionary space required, in address units: core-other.
                                                            (line 18943)
* system documentation:                  Standard conformance.
                                                            (line 18523)
* system documentation, block words:     The optional Block word set.
                                                            (line 18949)
* system documentation, core words:      The Core Words.    (line 18538)
* system documentation, double words:    The optional Double Number word set.
                                                            (line 18995)
* system documentation, exception words: The optional Exception word set.
                                                            (line 19004)
* system documentation, facility words:  The optional Facility word set.
                                                            (line 19019)
* system documentation, file words:      The optional File-Access word set.
                                                            (line 19051)
* system documentation, floating-point words: The optional Floating-Point word set.
                                                            (line 19141)
* system documentation, locals words:    The optional Locals word set.
                                                            (line 19243)
* system documentation, memory-allocation words: The optional Memory-Allocation word set.
                                                            (line 19266)
* system documentation, programming-tools words: The optional Programming-Tools word set.
                                                            (line 19278)
* system documentation, search-order words: The optional Search-Order word set.
                                                            (line 19333)
* system prompt:                         core-idef.         (line 18698)
* table:                                 Word Lists.        (line 11190)
* TAGS file:                             Emacs Tags.        (line 19587)
* target compiler:                       cross.fs.          (line 19920)
* target compiler <1>:                   Cross Compiler.    (line 20624)
* task:                                  Basic multi-tasking.
                                                            (line 16402)
* task-local data:                       Task-local data.   (line 16510)
* terminal buffer, size:                 core-idef.         (line 18677)
* terminal output:                       Terminal output.   (line 12612)
* terminal size:                         Terminal output.   (line 12623)
* terminology for object-oriented programming: Object-Oriented Terminology.
                                                            (line 13943)
* text interpreter:                      Introducing the Text Interpreter.
                                                            (line  2941)
* text interpreter <1>:                  Stacks and Postfix notation.
                                                            (line  3049)
* text interpreter <2>:                  The Text Interpreter.
                                                            (line 10167)
* text interpreter - effect of state:    How does that work?.
                                                            (line  3342)
* text interpreter - input sources:      Input Sources.     (line 10261)
* text-color::                           widget methods.    (line 20944)
* text-emoji-color::                     widget methods.    (line 20948)
* text-emoji-fade-color::                widget methods.    (line 20958)
* THEN:                                  Arbitrary control structures.
                                                            (line  6824)
* third:                                 Data stack.        (line  4783)
* this:                                  Objects Glossary.  (line 14621)
* this and catch:                        Objects Implementation.
                                                            (line 14405)
* this implementation:                   Objects Implementation.
                                                            (line 14405)
* this usage:                            Method conveniences.
                                                            (line 14199)
* ThisForth performance:                 Performance.       (line 20547)
* thread-deadline:                       Basic multi-tasking.
                                                            (line 16480)
* threaded code implementation:          Threading.         (line 20151)
* threading words:                       Threading Words.   (line 18143)
* threading-method:                      Threading Words.   (line 18173)
* threading, direct or indirect?:        Direct or Indirect Threaded?.
                                                            (line 20216)
* throw:                                 Exception Handling.
                                                            (line  6970)
* THROW-codes used in the system:        exception-idef.    (line 19008)
* thru:                                  Blocks.            (line 12177)
* tib:                                   The Text Interpreter.
                                                            (line 10239)
* tick ('):                              Execution token.   (line  9571)
* TILE performance:                      Performance.       (line 20547)
* time-related words:                    Keeping track of Time.
                                                            (line 18287)
* time&date:                             Keeping track of Time.
                                                            (line 18291)
* TMP, TEMP - environment variable:      Environment variables.
                                                            (line   984)
* TO:                                    Values.            (line  7437)
* to _name_ semantics, changing them:    Words with user-defined TO etc..
                                                            (line  8092)
* TO on non-VALUEs:                      core-ambcond.      (line 18881)
* TO on non-VALUEs and non-locals:       locals-ambcond.    (line 19261)
* to-class::                             Words with user-defined TO etc..
                                                            (line  8195)
* to-table::                             Words with user-defined TO etc..
                                                            (line  8162)
* to-this:                               Objects Glossary.  (line 14630)
* tokens for words:                      Tokens for Words.  (line  9549)
* TOS definition:                        Stacks and Postfix notation.
                                                            (line  3084)
* TOS optimization for primitives:       TOS Optimization.  (line 20477)
* touchdown:                             actor methods.     (line 20771)
* touchup:                               actor methods.     (line 20774)
* toupper:                               Characters.        (line  5766)
* translate-complex:                     Define recognizers with existing translators.
                                                            (line 10841)
* translate-dnum:                        Define recognizers with existing translators.
                                                            (line 10833)
* translate-env:                         Define recognizers with existing translators.
                                                            (line 10857)
* translate-float:                       Define recognizers with existing translators.
                                                            (line 10837)
* translate-nt:                          Define recognizers with existing translators.
                                                            (line 10822)
* translate-num:                         Define recognizers with existing translators.
                                                            (line 10829)
* translate-string:                      Define recognizers with existing translators.
                                                            (line 10845)
* translate-to:                          Define recognizers with existing translators.
                                                            (line 10863)
* translate::                            Defining translators.
                                                            (line 10907)
* traverse-wordlist:                     Name token.        (line  9682)
* trigonometric operations:              Floating Point.    (line  4649)
* true:                                  Boolean Flags.     (line  3976)
* truncation of floating-point numbers:  floating-idef.     (line 19152)
* try:                                   Exception Handling.
                                                            (line  7106)
* try-recognize:                         Define recognizers with existing translators.
                                                            (line 10882)
* tt:                                    Locating exception source.
                                                            (line 15854)
* tuck:                                  Data stack.        (line  4793)
* turnkey image files:                   Modifying the Startup Sequence.
                                                            (line 20048)
* Tutorial:                              Tutorial.          (line  1090)
* type:                                  Displaying characters and strings.
                                                            (line 12595)
* types of locals:                       Gforth locals.     (line 13336)
* types of stack items:                  Notation.          (line  3874)
* types tutorial:                        Types Tutorial.    (line  1474)
* typewhite:                             Displaying characters and strings.
                                                            (line 12606)
* u-[do:                                 Counted Loops.     (line  6552)
* U-DO:                                  Counted Loops.     (line  6560)
* u, stack item type:                    Notation.          (line  3886)
* u.:                                    Simple numeric output.
                                                            (line 12237)
* u.r:                                   Simple numeric output.
                                                            (line 12247)
* u*/:                                   Integer division.  (line  4185)
* u*/mod:                                Integer division.  (line  4200)
* u/:                                    Integer division.  (line  4136)
* u/-stage1m:                            Two-stage integer division.
                                                            (line  4314)
* u/-stage2m:                            Two-stage integer division.
                                                            (line  4318)
* u/mod:                                 Integer division.  (line  4156)
* u/mod-stage2m:                         Two-stage integer division.
                                                            (line  4326)
* U+DO:                                  Counted Loops.     (line  6539)
* u<:                                    Numeric comparison.
                                                            (line  4496)
* u<=:                                   Numeric comparison.
                                                            (line  4498)
* u>:                                    Numeric comparison.
                                                            (line  4500)
* u>=:                                   Numeric comparison.
                                                            (line  4502)
* uallot:                                Task-local data.   (line 16525)
* ud, stack item type:                   Notation.          (line  3890)
* ud.:                                   Simple numeric output.
                                                            (line 12258)
* ud.r:                                  Simple numeric output.
                                                            (line 12267)
* ud/mod:                                Integer division.  (line  4206)
* UDefer:                                Task-local data.   (line 16533)
* ukeyed:                                actor methods.     (line 20777)
* um*:                                   Mixed precision.   (line  4082)
* um/mod:                                Integer division.  (line  4170)
* umax:                                  Single precision.  (line  4036)
* umin:                                  Single precision.  (line  4034)
* umod:                                  Integer division.  (line  4145)
* umod-stage2m:                          Two-stage integer division.
                                                            (line  4322)
* unaligned memory access:               Special Memory Accesses.
                                                            (line  5409)
* uncolored-mode:                        Terminal output.   (line 12684)
* undefined word:                        core-ambcond.      (line 18727)
* undefined word, ', POSTPONE, ['], [COMPILE]: core-ambcond.
                                                            (line 18886)
* under+:                                Single precision.  (line  4017)
* unescape:                              Substitute.        (line 13206)
* unexpected end of the input buffer:    core-ambcond.      (line 18832)
* unlock:                                Semaphores.        (line 16572)
* unloop:                                Counted Loops.     (line  6618)
* unmapped block numbers:                file-ambcond.      (line 19130)
* UNREACHABLE:                           Where are locals visible by name?.
                                                            (line 13528)
* UNTIL:                                 Arbitrary control structures.
                                                            (line  6832)
* UNTIL loop:                            General Loops.     (line  6339)
* unused:                                Dictionary allocation.
                                                            (line  5041)
* unused-words:                          Locating uses of a word.
                                                            (line 15848)
* unwind-protect:                        Exception Handling.
                                                            (line  7125)
* up@:                                   Task-local data.   (line 16539)
* update:                                Blocks.            (line 12158)
* UPDATE, no current block buffer:       block-ambcond.     (line 18981)
* updated?:                              Blocks.            (line 12161)
* upper and lower case:                  Case insensitivity.
                                                            (line  3930)
* use:                                   Blocks.            (line 12112)
* User:                                  Task-local data.   (line 16516)
* user input device, method of selecting: core-idef.        (line 18632)
* user output device, method of selecting: core-idef.       (line 18637)
* user space:                            Task-local data.   (line 16510)
* user variables:                        Task-local data.   (line 16510)
* user-defined defining words:           User-defined Defining Words.
                                                            (line  7672)
* user':                                 Task-local data.   (line 16543)
* Uses of a word:                        Locating uses of a word.
                                                            (line 15800)
* utime:                                 Keeping track of Time.
                                                            (line 18300)
* UValue:                                Task-local data.   (line 16529)
* v*:                                    Floating Point.    (line  4639)
* Value:                                 Values.            (line  7415)
* value-flavoured locals:                Gforth locals.     (line 13344)
* value-flavoured words:                 Values.            (line  7454)
* value::                                Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8838)
* value[]::                              Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8922)
* values:                                Values.            (line  7401)
* var:                                   Class Declaration. (line 14824)
* var <1>:                               Basic Mini-OOF Usage.
                                                            (line 14884)
* Variable:                              Variables.         (line  7333)
* variable-flavoured locals:             Gforth locals.     (line 13344)
* variable-flavoured words:              Values.            (line  7454)
* variables:                             Variables.         (line  7308)
* variadic C functions:                  Declaring C Functions.
                                                            (line 16842)
* versions, invoking other versions of Gforth: Invoking Gforth.
                                                            (line   826)
* vglue:                                 widget methods.    (line 20885)
* vglue@:                                widget methods.    (line 20894)
* view (called locate in Gforth):        Locating source code definitions.
                                                            (line 15725)
* viewing the documentation of a word in Emacs: Emacs and Gforth.
                                                            (line 19559)
* viewing the source of a word in Emacs: Emacs Tags.        (line 19587)
* virtual function:                      Object-Oriented Terminology.
                                                            (line 13957)
* virtual function table:                Objects Implementation.
                                                            (line 14372)
* virtual machine:                       Engine.            (line 20089)
* virtual machine instructions, implementation: Primitives. (line 20395)
* visibility of locals:                  Where are locals visible by name?.
                                                            (line 13484)
* vlist:                                 Word Lists.        (line 11257)
* Vocabularies, detailed explanation:    Vocabularies.      (line 11300)
* Vocabulary:                            Word Lists.        (line 11274)
* vocs:                                  Word Lists.        (line 11283)
* vocstack empty, previous:              search-ambcond.    (line 19354)
* vocstack full, also:                   search-ambcond.    (line 19357)
* vp-bottom:                             widget methods.    (line 20992)
* vp-left:                               widget methods.    (line 20995)
* vp-needed:                             widget methods.    (line 21004)
* vp-reslide:                            widget methods.    (line 21001)
* vp-right:                              widget methods.    (line 20998)
* vp-top:                                widget methods.    (line 20989)
* w:                                     widget methods.    (line 20831)
* w-color:                               widget methods.    (line 20864)
* w,:                                    Dictionary allocation.
                                                            (line  5069)
* w, stack item type:                    Notation.          (line  3882)
* W::                                    Locals definition words.
                                                            (line 13446)
* w!:                                    Special Memory Accesses.
                                                            (line  5442)
* w@:                                    Special Memory Accesses.
                                                            (line  5439)
* w/o:                                   General files.     (line 11706)
* W^:                                    Locals definition words.
                                                            (line 13449)
* w>s:                                   Special Memory Accesses.
                                                            (line  5507)
* wake:                                  Basic multi-tasking.
                                                            (line 16492)
* walign:                                Address arithmetic.
                                                            (line  5658)
* waligned:                              Address arithmetic.
                                                            (line  5655)
* warning-color:                         Terminal output.   (line 12654)
* WARNING":                              Exception Handling.
                                                            (line  7234)
* warnings:                              Exception Handling.
                                                            (line  7237)
* wbe:                                   Special Memory Accesses.
                                                            (line  5468)
* wfield::                               Standard Structures.
                                                            (line  8745)
* where:                                 Locating uses of a word.
                                                            (line 15800)
* where to go next:                      Where to go next.  (line  3556)
* whereg:                                Locating uses of a word.
                                                            (line 15829)
* WHILE:                                 Arbitrary control structures.
                                                            (line  6864)
* WHILE loop:                            General Loops.     (line  6329)
* wid:                                   Word Lists.        (line 11137)
* wid, stack item type:                  Notation.          (line  3911)
* widget:                                MINOS2 object framework.
                                                            (line 20750)
* Win32Forth performance:                Performance.       (line 20547)
* wior type description:                 Notation.          (line  3913)
* wior values and meaning:               file-idef.         (line 19084)
* within:                                Numeric comparison.
                                                            (line  4504)
* wle:                                   Special Memory Accesses.
                                                            (line  5472)
* word:                                  Introducing the Text Interpreter.
                                                            (line  2982)
* word <1>:                              The Input Stream.  (line 11075)
* WORD buffer size:                      core-idef.         (line 18664)
* word glossary entry format:            Notation.          (line  3766)
* word list for defining locals:         Locals implementation.
                                                            (line 13786)
* word lists:                            Word Lists.        (line 11125)
* word lists - example:                  Word list example. (line 11383)
* word lists - why use them?:            Why use word lists?.
                                                            (line 11335)
* word name too long:                    core-ambcond.      (line 18730)
* WORD, string overflow:                 core-ambcond.      (line 18898)
* wordlist:                              Word Lists.        (line 11187)
* wordlist-words:                        Word Lists.        (line 11260)
* wordlists:                             Environmental Queries.
                                                            (line 11468)
* wordlists tutorial:                    Wordlists and Search Order Tutorial.
                                                            (line  2844)
* words:                                 Words.             (line  3763)
* words <1>:                             Word Lists.        (line 11253)
* words used in your program:            Standard Report.   (line 18400)
* words, forgetting:                     Forgetting words.  (line 16042)
* wordset:                               Notation.          (line  3824)
* wrap-xt:                               Deferred Words.    (line  8566)
* write-file:                            General files.     (line 11763)
* write-line:                            General files.     (line 11765)
* wrol:                                  Bitwise operations.
                                                            (line  4437)
* wror:                                  Bitwise operations.
                                                            (line  4441)
* WTF??:                                 Debugging.         (line 16130)
* wvalue::                               Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8845)
* ww:                                    Locating uses of a word.
                                                            (line 15806)
* x:                                     widget methods.    (line 20825)
* x-size:                                Xchars and Unicode.
                                                            (line 13032)
* x-width:                               Xchars and Unicode.
                                                            (line 13086)
* x,:                                    Dictionary allocation.
                                                            (line  5077)
* x, stack item type:                    Notation.          (line  3882)
* x!:                                    Special Memory Accesses.
                                                            (line  5454)
* x@:                                    Special Memory Accesses.
                                                            (line  5451)
* x\string-:                             Xchars and Unicode.
                                                            (line 13075)
* x>s:                                   Special Memory Accesses.
                                                            (line  5513)
* xalign:                                Address arithmetic.
                                                            (line  5670)
* xaligned:                              Address arithmetic.
                                                            (line  5667)
* xbe:                                   Special Memory Accesses.
                                                            (line  5484)
* xc-size:                               Xchars and Unicode.
                                                            (line 13029)
* xc-width:                              Xchars and Unicode.
                                                            (line 13096)
* xc,:                                   Xchars and Unicode.
                                                            (line 13103)
* xc!+:                                  Xchars and Unicode.
                                                            (line 13055)
* xc!+?:                                 Xchars and Unicode.
                                                            (line 13047)
* xc@:                                   Xchars and Unicode.
                                                            (line 13036)
* xc@+:                                  Xchars and Unicode.
                                                            (line 13039)
* xc@+?:                                 Xchars and Unicode.
                                                            (line 13043)
* xchar-:                                Xchars and Unicode.
                                                            (line 13066)
* XCHAR-ENCODING:                        Environmental Queries.
                                                            (line 11475)
* XCHAR-MAXMEM:                          Environmental Queries.
                                                            (line 11485)
* xchar+:                                Xchars and Unicode.
                                                            (line 13062)
* xd,:                                   Dictionary allocation.
                                                            (line  5081)
* xd!:                                   Special Memory Accesses.
                                                            (line  5460)
* xd@:                                   Special Memory Accesses.
                                                            (line  5457)
* xd>s:                                  Special Memory Accesses.
                                                            (line  5516)
* xdbe:                                  Special Memory Accesses.
                                                            (line  5492)
* xdle:                                  Special Memory Accesses.
                                                            (line  5496)
* xemit:                                 Displaying characters and strings.
                                                            (line 12599)
* xfield::                               Standard Structures.
                                                            (line  8751)
* xhold:                                 Xchars and Unicode.
                                                            (line 13099)
* xkey:                                  Xchars and Unicode.
                                                            (line 13092)
* xkey?:                                 Single-key input.  (line 12718)
* xle:                                   Special Memory Accesses.
                                                            (line  5488)
* xor:                                   Bitwise operations.
                                                            (line  4371)
* xt:                                    Introducing the Text Interpreter.
                                                            (line  2982)
* xt <1>:                                Execution token.   (line  9555)
* xt input format:                       Literals for tokens and addresses.
                                                            (line  3727)
* XT tutorial:                           Execution Tokens Tutorial.
                                                            (line  2415)
* xt-locate:                             Locating source code definitions.
                                                            (line 15749)
* xt-new:                                Objects Glossary.  (line 14633)
* xt-see:                                Examining compiled code.
                                                            (line 15874)
* xt-see-code:                           Examining compiled code.
                                                            (line 15898)
* xt-simple-see:                         Examining compiled code.
                                                            (line 15881)
* xt, stack item type:                   Notation.          (line  3907)
* XT::                                   Locals definition words.
                                                            (line 13473)
* xt>name:                               Name token.        (line  9676)
* xywh:                                  widget methods.    (line 20897)
* xywhd:                                 widget methods.    (line 20900)
* y:                                     widget methods.    (line 20828)
* z::                                    Locals definition words.
                                                            (line 13470)
* zero-length string as a name:          core-ambcond.      (line 18832)
* Zsoter's object-oriented model:        Comparison with other object models.
                                                            (line 15132)
* zvalue::                               Value-Flavoured and Defer-Flavoured Fields.
                                                            (line  8881)

