[gforth] / gforth / prim

gforth: gforth/prim

1 :	anton	1.1	\ Gforth primitives
2 :
3 :	anton	1.257	\ Copyright (C) 1995,1996,1997,1998,2000,2003,2004,2005,2006,2007,2008,2009,2010 Free Software Foundation, Inc.
4 :	anton	1.1
5 :			\ This file is part of Gforth.
6 :
7 :			\ Gforth is free software; you can redistribute it and/or
8 :			\ modify it under the terms of the GNU General Public License
9 :	anton	1.222	\ as published by the Free Software Foundation, either version 3
10 :	anton	1.1	\ of the License, or (at your option) any later version.
11 :
12 :			\ This program is distributed in the hope that it will be useful,
13 :			\ but WITHOUT ANY WARRANTY; without even the implied warranty of
14 :			\ MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 :			\ GNU General Public License for more details.
16 :
17 :			\ You should have received a copy of the GNU General Public License
18 :	anton	1.222	\ along with this program. If not, see http://www.gnu.org/licenses/.
19 :	anton	1.1
20 :
21 :			\ WARNING: This file is processed by m4. Make sure your identifiers
22 :			\ don't collide with m4's (e.g. by undefining them).
23 :			\
24 :			\
25 :			\
26 :			\ This file contains primitive specifications in the following format:
27 :			\
28 :	anton	1.47	\ forth name ( stack effect ) category [pronunciation]
29 :	anton	1.1	\ [""glossary entry""]
30 :			\ C code
31 :			\ [:
32 :			\ Forth code]
33 :			\
34 :	anton	1.47	\ Note: Fields in brackets are optional. Word specifications have to
35 :			\ be separated by at least one empty line
36 :	anton	1.1	\
37 :			\ Both pronounciation and stack items (in the stack effect) must
38 :	anton	1.48	\ conform to the C identifier syntax or the C compiler will complain.
39 :			\ If you don't have a pronounciation field, the Forth name is used,
40 :			\ and has to conform to the C identifier syntax.
41 :	anton	1.1	\
42 :			\ These specifications are automatically translated into C-code for the
43 :			\ interpreter and into some other files. I hope that your C compiler has
44 :			\ decent optimization, otherwise the automatically generated code will
45 :			\ be somewhat slow. The Forth version of the code is included for manual
46 :			\ compilers, so they will need to compile only the important words.
47 :			\
48 :			\ Note that stack pointer adjustment is performed according to stack
49 :			\ effect by automatically generated code and NEXT is automatically
50 :			\ appended to the C code. Also, you can use the names in the stack
51 :			\ effect in the C code. Stack access is automatic. One exception: if
52 :			\ your code does not fall through, the results are not stored into the
53 :			\ stack. Use different names on both sides of the '--', if you change a
54 :			\ value (some stores to the stack are optimized away).
55 :	anton	1.93	\
56 :			\ For superinstructions the syntax is:
57 :			\
58 :			\ forth-name [/ c-name] = forth-name forth-name ...
59 :			\
60 :	anton	1.1	\
61 :			\ The stack variables have the following types:
62 :			\
63 :			\ name matches type
64 :			\ f.* Bool
65 :			\ c.* Char
66 :	anton	1.93	\ [nw].* Cell
67 :	anton	1.1	\ u.* UCell
68 :			\ d.* DCell
69 :			\ ud.* UDCell
70 :			\ r.* Float
71 :			\ a_.* Cell *
72 :			\ c_.* Char *
73 :			\ f_.* Float *
74 :			\ df_.* DFloat *
75 :			\ sf_.* SFloat *
76 :			\ xt.* XT
77 :			\ f83name.* F83Name *
78 :	anton	1.67
79 :	anton	1.79	\E stack data-stack sp Cell
80 :			\E stack fp-stack fp Float
81 :			\E stack return-stack rp Cell
82 :			\E
83 :	anton	1.67	\E get-current prefixes set-current
84 :			\E
85 :			\E s" Bool" single data-stack type-prefix f
86 :			\E s" Char" single data-stack type-prefix c
87 :			\E s" Cell" single data-stack type-prefix n
88 :			\E s" Cell" single data-stack type-prefix w
89 :			\E s" UCell" single data-stack type-prefix u
90 :			\E s" DCell" double data-stack type-prefix d
91 :			\E s" UDCell" double data-stack type-prefix ud
92 :			\E s" Float" single fp-stack type-prefix r
93 :			\E s" Cell *" single data-stack type-prefix a_
94 :			\E s" Char *" single data-stack type-prefix c_
95 :			\E s" Float *" single data-stack type-prefix f_
96 :			\E s" DFloat *" single data-stack type-prefix df_
97 :			\E s" SFloat *" single data-stack type-prefix sf_
98 :			\E s" Xt" single data-stack type-prefix xt
99 :			\E s" struct F83Name *" single data-stack type-prefix f83name
100 :	anton	1.71	\E s" struct Longname *" single data-stack type-prefix longname
101 :	anton	1.67	\E
102 :	anton	1.172	\E data-stack stack-prefix S:
103 :			\E fp-stack stack-prefix F:
104 :	anton	1.67	\E return-stack stack-prefix R:
105 :			\E inst-stream stack-prefix #
106 :			\E
107 :			\E set-current
108 :	anton	1.97	\E store-optimization on
109 :	anton	1.109	\E ' noop tail-nextp2 ! \ now INST_TAIL just stores, but does not jump
110 :	anton	1.128	\E
111 :	anton	1.218	\E `include-skipped-insts' on \ static superinsts include cells for components
112 :			\E \ useful for dynamic programming and
113 :			\E \ superinsts across entry points
114 :	anton	1.67
115 :	anton	1.1	\
116 :			\
117 :			\
118 :			\ In addition the following names can be used:
119 :			\ ip the instruction pointer
120 :			\ sp the data stack pointer
121 :			\ rp the parameter stack pointer
122 :			\ lp the locals stack pointer
123 :			\ NEXT executes NEXT
124 :			\ cfa
125 :			\ NEXT1 executes NEXT1
126 :			\ FLAG(x) makes a Forth flag from a C flag
127 :			\
128 :			\
129 :			\
130 :			\ Percentages in comments are from Koopmans book: average/maximum use
131 :			\ (taken from four, not very representative benchmarks)
132 :			\
133 :			\
134 :			\
135 :			\ To do:
136 :			\
137 :			\ throw execute, cfa and NEXT1 out?
138 :			\ macroize ip, ip++, ip++ (pipelining)?
139 :
140 :	anton	1.145	\ Stack caching setup
141 :
142 :	anton	1.173	ifdef(`STACK_CACHE_FILE', `include(STACK_CACHE_FILE)', `include(cache0.vmg)')
143 :	anton	1.145
144 :	anton	1.1	\ these m4 macros would collide with identifiers
145 :			undefine(`index')
146 :			undefine(`shift')
147 :	pazsan	1.78	undefine(`symbols')
148 :	anton	1.1
149 :	anton	1.140	\F 0 [if]
150 :
151 :	anton	1.139	\ run-time routines for non-primitives. They are defined as
152 :			\ primitives, because that simplifies things.
153 :
154 :			(docol) ( -- R:a_retaddr ) gforth-internal paren_docol
155 :			""run-time routine for colon definitions""
156 :	anton	1.148	#ifdef NO_IP
157 :			a_retaddr = next_code;
158 :			INST_TAIL;
159 :			goto *(Label )PFA(CFA);
160 :			#else /* !defined(NO_IP) */
161 :	anton	1.141	a_retaddr = (Cell *)IP;
162 :	anton	1.139	SET_IP((Xt *)PFA(CFA));
163 :	anton	1.148	#endif /* !defined(NO_IP) */
164 :	anton	1.139
165 :			(docon) ( -- w ) gforth-internal paren_docon
166 :			""run-time routine for constants""
167 :			w = (Cell )PFA(CFA);
168 :	anton	1.148	#ifdef NO_IP
169 :			INST_TAIL;
170 :			goto *next_code;
171 :			#endif /* defined(NO_IP) */
172 :	anton	1.139
173 :			(dovar) ( -- a_body ) gforth-internal paren_dovar
174 :			""run-time routine for variables and CREATEd words""
175 :			a_body = PFA(CFA);
176 :	anton	1.148	#ifdef NO_IP
177 :			INST_TAIL;
178 :			goto *next_code;
179 :			#endif /* defined(NO_IP) */
180 :	anton	1.139
181 :			(douser) ( -- a_user ) gforth-internal paren_douser
182 :			""run-time routine for constants""
183 :			a_user = (Cell )(up+(Cell *)PFA(CFA));
184 :	anton	1.148	#ifdef NO_IP
185 :			INST_TAIL;
186 :			goto *next_code;
187 :			#endif /* defined(NO_IP) */
188 :	anton	1.139
189 :			(dodefer) ( -- ) gforth-internal paren_dodefer
190 :			""run-time routine for deferred words""
191 :	anton	1.148	#ifndef NO_IP
192 :	anton	1.141	ip=IP; /* undo any ip updating that may have been performed by NEXT_P0 */
193 :	anton	1.148	#endif /* !defined(NO_IP) */
194 :	anton	1.141	SUPER_END; /* !! probably unnecessary and may lead to measurement errors */
195 :	anton	1.161	VM_JUMP(EXEC1((Xt )PFA(CFA)));
196 :	anton	1.139
197 :			(dofield) ( n1 -- n2 ) gforth-internal paren_field
198 :			""run-time routine for fields""
199 :			n2 = n1 + (Cell )PFA(CFA);
200 :	anton	1.148	#ifdef NO_IP
201 :			INST_TAIL;
202 :			goto *next_code;
203 :			#endif /* defined(NO_IP) */
204 :	anton	1.139
205 :	pazsan	1.219	(dovalue) ( -- w ) gforth-internal paren_doval
206 :			""run-time routine for constants""
207 :			w = (Cell )PFA(CFA);
208 :			#ifdef NO_IP
209 :			INST_TAIL;
210 :			goto *next_code;
211 :			#endif /* defined(NO_IP) */
212 :
213 :	anton	1.139	(dodoes) ( -- a_body R:a_retaddr ) gforth-internal paren_dodoes
214 :			""run-time routine for @code{does>}-defined words""
215 :	anton	1.148	#ifdef NO_IP
216 :			a_retaddr = next_code;
217 :			a_body = PFA(CFA);
218 :			INST_TAIL;
219 :	pazsan	1.211	#ifdef DEBUG
220 :			fprintf(stderr, "dodoes to %x, push %x\n", a_retaddr, a_body);
221 :			#endif
222 :	anton	1.148	goto *(Label )DOES_CODE1(CFA);
223 :			#else /* !defined(NO_IP) */
224 :	anton	1.141	a_retaddr = (Cell *)IP;
225 :	anton	1.139	a_body = PFA(CFA);
226 :	pazsan	1.211	#ifdef DEBUG
227 :			fprintf(stderr, "dodoes to %x, push %x\n", a_retaddr, a_body);
228 :			#endif
229 :	anton	1.139	SET_IP(DOES_CODE1(CFA));
230 :	anton	1.148	#endif /* !defined(NO_IP) */
231 :	anton	1.139
232 :	anton	1.247	(doabicode) ( ... -- ...) gforth-internal paren_doabicode
233 :	anton	1.248	""run-time routine for @code{ABI-code} definitions""
234 :	anton	1.247	abifunc f = (abifunc )PFA(CFA);
235 :			Float *fp_mem = fp;
236 :			sp = (*f)(sp, &fp_mem);
237 :			fp = fp_mem;
238 :	dvdkhlng	1.246	#ifdef NO_IP
239 :			INST_TAIL;
240 :			goto *next_code;
241 :			#endif /* defined(NO_IP) */
242 :
243 :	anton	1.248	(do;abicode) ( ... -- ... ) gforth-internal paren_do_semicolon_abi_code
244 :			""run-time routine for @code{;abi-code}-defined words""
245 :			Float *fp_mem = fp;
246 :			Address body = (Address)PFA(CFA);
247 :			semiabifunc f = (semiabifunc )DOES_CODE1(CFA);
248 :			sp = (*f)(sp, &fp_mem, body);
249 :			fp = fp_mem;
250 :			#ifdef NO_IP
251 :			INST_TAIL;
252 :			goto *next_code;
253 :			#endif /* defined(NO_IP) */
254 :
255 :	anton	1.140	\F [endif]
256 :	anton	1.139
257 :	pazsan	1.83	\g control
258 :
259 :	anton	1.47	noop ( -- ) gforth
260 :	anton	1.1	:
261 :			;
262 :
263 :	pazsan	1.112	call ( #a_callee -- R:a_retaddr ) new
264 :			""Call callee (a variant of docol with inline argument).""
265 :			#ifdef NO_IP
266 :	anton	1.148	assert(0);
267 :	pazsan	1.112	INST_TAIL;
268 :			JUMP(a_callee);
269 :			#else
270 :			#ifdef DEBUG
271 :			{
272 :			CFA_TO_NAME((((Cell *)a_callee)-2));
273 :			fprintf(stderr,"%08lx: call %08lx %.*s\n",(Cell)ip,(Cell)a_callee,
274 :			len,name);
275 :			}
276 :			#endif
277 :			a_retaddr = (Cell *)IP;
278 :			SET_IP((Xt *)a_callee);
279 :			#endif
280 :	anton	1.1
281 :	anton	1.47	execute ( xt -- ) core
282 :	crook	1.29	""Perform the semantics represented by the execution token, @i{xt}.""
283 :	pazsan	1.210	#ifdef DEBUG
284 :			fprintf(stderr, "execute %08x\n", xt);
285 :			#endif
286 :	anton	1.102	#ifndef NO_IP
287 :	anton	1.1	ip=IP;
288 :	anton	1.102	#endif
289 :	anton	1.76	SUPER_END;
290 :	anton	1.161	VM_JUMP(EXEC1(xt));
291 :	anton	1.1
292 :	anton	1.47	perform ( a_addr -- ) gforth
293 :	anton	1.55	""@code{@@ execute}.""
294 :	anton	1.1	/* and pfe */
295 :	anton	1.102	#ifndef NO_IP
296 :	anton	1.1	ip=IP;
297 :	anton	1.102	#endif
298 :	anton	1.76	SUPER_END;
299 :	anton	1.161	VM_JUMP(EXEC1((Xt )a_addr));
300 :	anton	1.1	:
301 :			@ execute ;
302 :
303 :	pazsan	1.112	;s ( R:w -- ) gforth semis
304 :			""The primitive compiled by @code{EXIT}.""
305 :			#ifdef NO_IP
306 :			INST_TAIL;
307 :			goto (void )w;
308 :			#else
309 :			SET_IP((Xt *)w);
310 :			#endif
311 :
312 :			unloop ( R:w1 R:w2 -- ) core
313 :			/* !! alias for 2rdrop */
314 :			:
315 :			r> rdrop rdrop >r ;
316 :
317 :			lit-perform ( #a_addr -- ) new lit_perform
318 :			#ifndef NO_IP
319 :			ip=IP;
320 :			#endif
321 :			SUPER_END;
322 :	anton	1.161	VM_JUMP(EXEC1((Xt )a_addr));
323 :	pazsan	1.112
324 :			does-exec ( #a_cfa -- R:nest a_pfa ) new does_exec
325 :			#ifdef NO_IP
326 :			/* compiled to LIT CALL by compile_prim */
327 :			assert(0);
328 :			#else
329 :			a_pfa = PFA(a_cfa);
330 :			nest = (Cell)IP;
331 :			#ifdef DEBUG
332 :			{
333 :			CFA_TO_NAME(a_cfa);
334 :			fprintf(stderr,"%08lx: does %08lx %.*s\n",
335 :			(Cell)ip,(Cell)a_cfa,len,name);
336 :			}
337 :			#endif
338 :			SET_IP(DOES_CODE1(a_cfa));
339 :			#endif
340 :
341 :	pazsan	1.15	\+glocals
342 :	anton	1.1
343 :	pazsan	1.112	branch-lp+!# ( #a_target #nlocals -- ) gforth branch_lp_plus_store_number
344 :	anton	1.1	/* this will probably not be used */
345 :	anton	1.68	lp += nlocals;
346 :	pazsan	1.112	#ifdef NO_IP
347 :			INST_TAIL;
348 :			JUMP(a_target);
349 :			#else
350 :			SET_IP((Xt *)a_target);
351 :			#endif
352 :	anton	1.1
353 :	pazsan	1.15	\+
354 :	anton	1.1
355 :	pazsan	1.112	branch ( #a_target -- ) gforth
356 :			#ifdef NO_IP
357 :			INST_TAIL;
358 :			JUMP(a_target);
359 :			#else
360 :			SET_IP((Xt *)a_target);
361 :			#endif
362 :	anton	1.1	:
363 :	pazsan	1.112	r> @ >r ;
364 :	anton	1.1
365 :	pazsan	1.112	\ condbranch(forthname,stackeffect,restline,code1,code2,forthcode)
366 :	anton	1.1	\ this is non-syntactical: code must open a brace that is closed by the macro
367 :			define(condbranch,
368 :	anton	1.159	$1 ( `#'a_target $2 ) $3
369 :			$4 #ifdef NO_IP
370 :			INST_TAIL;
371 :			#endif
372 :			$5 #ifdef NO_IP
373 :			JUMP(a_target);
374 :			#else
375 :			SET_IP((Xt *)a_target);
376 :	anton	1.214	ifelse(condbranch_opt,`1',`INST_TAIL; NEXT_P2;',`/* condbranch_opt=0 */')
377 :	anton	1.159	#endif
378 :			}
379 :	anton	1.214	ifelse(condbranch_opt,`1',`SUPER_CONTINUE;',`/* condbranch_opt=0 */')
380 :	anton	1.159	$6
381 :
382 :			\+glocals
383 :
384 :			$1-lp+!`#' ( `#'a_target `#'nlocals $2 ) $3_lp_plus_store_number
385 :			$4 #ifdef NO_IP
386 :			INST_TAIL;
387 :			#endif
388 :			$5 lp += nlocals;
389 :			#ifdef NO_IP
390 :			JUMP(a_target);
391 :			#else
392 :			SET_IP((Xt *)a_target);
393 :	anton	1.214	ifelse(condbranch_opt,`1',`INST_TAIL; NEXT_P2;',`/* condbranch_opt=0 */')
394 :	anton	1.159	#endif
395 :			}
396 :	anton	1.214	ifelse(condbranch_opt,`1',`SUPER_CONTINUE;',`/* condbranch_opt=0 */')
397 :	anton	1.1
398 :	pazsan	1.15	\+
399 :	anton	1.1	)
400 :
401 :	anton	1.68	condbranch(?branch,f --,f83 question_branch,
402 :	pazsan	1.112	,if (f==0) {
403 :	jwilke	1.5	,:
404 :	pazsan	1.112	0= dup 0= \ !f f
405 :			r> tuck cell+ \ !f branchoffset f IP+
406 :			and -rot @ and or \ f&IP+\|!f&branch
407 :	jwilke	1.5	>r ;)
408 :	anton	1.1
409 :			\ we don't need an lp_plus_store version of the ?dup-stuff, because it
410 :			\ is only used in if's (yet)
411 :
412 :	pazsan	1.15	\+xconds
413 :	anton	1.1
414 :	anton	1.172	?dup-?branch ( #a_target f -- S:... ) new question_dupe_question_branch
415 :	anton	1.1	""The run-time procedure compiled by @code{?DUP-IF}.""
416 :			if (f==0) {
417 :	pazsan	1.112	#ifdef NO_IP
418 :			INST_TAIL;
419 :			JUMP(a_target);
420 :			#else
421 :			SET_IP((Xt *)a_target);
422 :			#endif
423 :	anton	1.174	} else {
424 :	anton	1.172	sp--;
425 :			sp[0]=f;
426 :	anton	1.174	}
427 :	anton	1.1
428 :	anton	1.172	?dup-0=-?branch ( #a_target f -- S:... ) new question_dupe_zero_equals_question_branch
429 :	anton	1.1	""The run-time procedure compiled by @code{?DUP-0=-IF}.""
430 :			if (f!=0) {
431 :			sp--;
432 :	anton	1.172	sp[0]=f;
433 :	pazsan	1.112	#ifdef NO_IP
434 :			JUMP(a_target);
435 :			#else
436 :			SET_IP((Xt *)a_target);
437 :			#endif
438 :	anton	1.1	}
439 :
440 :	pazsan	1.15	\+
441 :	jwilke	1.31	\fhas? skiploopprims 0= [IF]
442 :	anton	1.1
443 :	anton	1.68	condbranch((next),R:n1 -- R:n2,cmFORTH paren_next,
444 :	anton	1.65	n2=n1-1;
445 :	pazsan	1.112	,if (n1) {
446 :	anton	1.1	,:
447 :			r> r> dup 1- >r
448 :	pazsan	1.112	IF @ >r ELSE cell+ >r THEN ;)
449 :	anton	1.1
450 :	anton	1.68	condbranch((loop),R:nlimit R:n1 -- R:nlimit R:n2,gforth paren_loop,
451 :	anton	1.65	n2=n1+1;
452 :	pazsan	1.112	,if (n2 != nlimit) {
453 :	anton	1.1	,:
454 :			r> r> 1+ r> 2dup =
455 :			IF >r 1- >r cell+ >r
456 :	pazsan	1.112	ELSE >r >r @ >r THEN ;)
457 :	anton	1.1
458 :	anton	1.68	condbranch((+loop),n R:nlimit R:n1 -- R:nlimit R:n2,gforth paren_plus_loop,
459 :	anton	1.1	/* !! check this thoroughly */
460 :			/* sign bit manipulation and test: (x^y)<0 is equivalent to (x<0) != (y<0) */
461 :			/* dependent upon two's complement arithmetic */
462 :	anton	1.65	Cell olddiff = n1-nlimit;
463 :			n2=n1+n;
464 :	anton	1.149	,if (((olddiff^(olddiff+n)) /* the limit is not crossed */
465 :			&(olddiff^n)) /* OR it is a wrap-around effect */
466 :			>=0) { /* & is used to avoid having two branches for gforth-native */
467 :	anton	1.1	,:
468 :			r> swap
469 :			r> r> 2dup - >r
470 :			2 pick r@ + r@ xor 0< 0=
471 :			3 pick r> xor 0< 0= or
472 :	pazsan	1.112	IF >r + >r @ >r
473 :	anton	1.1	ELSE >r >r drop cell+ >r THEN ;)
474 :
475 :	pazsan	1.15	\+xconds
476 :	anton	1.1
477 :	anton	1.68	condbranch((-loop),u R:nlimit R:n1 -- R:nlimit R:n2,gforth paren_minus_loop,
478 :	anton	1.65	UCell olddiff = n1-nlimit;
479 :			n2=n1-u;
480 :	pazsan	1.112	,if (olddiff>u) {
481 :	anton	1.1	,)
482 :
483 :	anton	1.68	condbranch((s+loop),n R:nlimit R:n1 -- R:nlimit R:n2,gforth paren_symmetric_plus_loop,
484 :	anton	1.1	""The run-time procedure compiled by S+LOOP. It loops until the index
485 :			crosses the boundary between limit and limit-sign(n). I.e. a symmetric
486 :			version of (+LOOP).""
487 :			/* !! check this thoroughly */
488 :	anton	1.65	Cell diff = n1-nlimit;
489 :	anton	1.1	Cell newdiff = diff+n;
490 :			if (n<0) {
491 :			diff = -diff;
492 :			newdiff = -newdiff;
493 :			}
494 :	anton	1.65	n2=n1+n;
495 :	anton	1.149	,if (((~diff)\|newdiff)<0) { /* use \| to avoid two branches for gforth-native */
496 :	anton	1.1	,)
497 :
498 :	pazsan	1.15	\+
499 :	anton	1.1
500 :	pazsan	1.112	(for) ( ncount -- R:nlimit R:ncount ) cmFORTH paren_for
501 :	anton	1.1	/* or (for) = >r -- collides with unloop! */
502 :	anton	1.65	nlimit=0;
503 :	anton	1.1	:
504 :			r> swap 0 >r >r >r ;
505 :
506 :	pazsan	1.112	(do) ( nlimit nstart -- R:nlimit R:nstart ) gforth paren_do
507 :	anton	1.1	:
508 :			r> swap rot >r >r >r ;
509 :
510 :	pazsan	1.112	(?do) ( #a_target nlimit nstart -- R:nlimit R:nstart ) gforth paren_question_do
511 :			#ifdef NO_IP
512 :			INST_TAIL;
513 :			#endif
514 :	anton	1.1	if (nstart == nlimit) {
515 :	pazsan	1.112	#ifdef NO_IP
516 :			JUMP(a_target);
517 :			#else
518 :			SET_IP((Xt *)a_target);
519 :			#endif
520 :	anton	1.1	}
521 :			:
522 :			2dup =
523 :			IF r> swap rot >r >r
524 :	pazsan	1.112	@ >r
525 :	anton	1.1	ELSE r> swap rot >r >r
526 :			cell+ >r
527 :			THEN ; \ --> CORE-EXT
528 :
529 :	pazsan	1.15	\+xconds
530 :	anton	1.1
531 :	pazsan	1.112	(+do) ( #a_target nlimit nstart -- R:nlimit R:nstart ) gforth paren_plus_do
532 :			#ifdef NO_IP
533 :			INST_TAIL;
534 :			#endif
535 :	anton	1.1	if (nstart >= nlimit) {
536 :	pazsan	1.112	#ifdef NO_IP
537 :			JUMP(a_target);
538 :			#else
539 :			SET_IP((Xt *)a_target);
540 :			#endif
541 :	anton	1.1	}
542 :			:
543 :			swap 2dup
544 :			r> swap >r swap >r
545 :			>=
546 :			IF
547 :	pazsan	1.112	@
548 :	anton	1.1	ELSE
549 :			cell+
550 :			THEN >r ;
551 :
552 :	pazsan	1.112	(u+do) ( #a_target ulimit ustart -- R:ulimit R:ustart ) gforth paren_u_plus_do
553 :			#ifdef NO_IP
554 :			INST_TAIL;
555 :			#endif
556 :	anton	1.1	if (ustart >= ulimit) {
557 :	pazsan	1.112	#ifdef NO_IP
558 :			JUMP(a_target);
559 :			#else
560 :			SET_IP((Xt *)a_target);
561 :			#endif
562 :	anton	1.1	}
563 :			:
564 :			swap 2dup
565 :			r> swap >r swap >r
566 :			u>=
567 :			IF
568 :	pazsan	1.112	@
569 :	anton	1.1	ELSE
570 :			cell+
571 :			THEN >r ;
572 :
573 :	pazsan	1.112	(-do) ( #a_target nlimit nstart -- R:nlimit R:nstart ) gforth paren_minus_do
574 :			#ifdef NO_IP
575 :			INST_TAIL;
576 :			#endif
577 :	anton	1.1	if (nstart <= nlimit) {
578 :	pazsan	1.112	#ifdef NO_IP
579 :			JUMP(a_target);
580 :			#else
581 :			SET_IP((Xt *)a_target);
582 :			#endif
583 :	anton	1.1	}
584 :			:
585 :			swap 2dup
586 :			r> swap >r swap >r
587 :			<=
588 :			IF
589 :	pazsan	1.112	@
590 :	anton	1.1	ELSE
591 :			cell+
592 :			THEN >r ;
593 :
594 :	pazsan	1.112	(u-do) ( #a_target ulimit ustart -- R:ulimit R:ustart ) gforth paren_u_minus_do
595 :			#ifdef NO_IP
596 :			INST_TAIL;
597 :			#endif
598 :	anton	1.1	if (ustart <= ulimit) {
599 :	pazsan	1.112	#ifdef NO_IP
600 :			JUMP(a_target);
601 :			#else
602 :			SET_IP((Xt *)a_target);
603 :			#endif
604 :	anton	1.1	}
605 :			:
606 :			swap 2dup
607 :			r> swap >r swap >r
608 :			u<=
609 :			IF
610 :	pazsan	1.112	@
611 :	anton	1.1	ELSE
612 :			cell+
613 :			THEN >r ;
614 :
615 :	anton	1.255	(try1) ( ... a_oldhandler a_recovery -- R:a_recovery R:a_sp R:f_fp R:c_lp R:a_oldhandler a_newhandler ) gforth paren_try1
616 :			a_sp = sp-1;
617 :			f_fp = fp;
618 :			c_lp = lp;
619 :			a_newhandler = rp-5;
620 :
621 :	anton	1.256	(throw1) ( ... wball a_handler -- ... wball ) gforth paren_throw1
622 :			rp = a_handler;
623 :			lp = (Address)rp[1];
624 :			fp = (Float *)rp[2];
625 :			sp = (Cell *)rp[3];
626 :			#ifndef NO_IP
627 :			ip=IP;
628 :			#endif
629 :			SUPER_END;
630 :			VM_JUMP(EXEC1((Xt )rp[4]));
631 :
632 :
633 :	pazsan	1.15	\+
634 :	anton	1.1
635 :	jwilke	1.5	\ don't make any assumptions where the return stack is!!
636 :			\ implement this in machine code if it should run quickly!
637 :
638 :	anton	1.65	i ( R:n -- R:n n ) core
639 :	anton	1.1	:
640 :	jwilke	1.5	\ rp@ cell+ @ ;
641 :			r> r> tuck >r >r ;
642 :	anton	1.1
643 :	anton	1.65	i' ( R:w R:w2 -- R:w R:w2 w ) gforth i_tick
644 :	anton	1.1	:
645 :	jwilke	1.5	\ rp@ cell+ cell+ @ ;
646 :			r> r> r> dup itmp ! >r >r >r itmp @ ;
647 :			variable itmp
648 :	anton	1.1
649 :	anton	1.215	j ( R:w R:w1 R:w2 -- w R:w R:w1 R:w2 ) core
650 :	anton	1.1	:
651 :	jwilke	1.5	\ rp@ cell+ cell+ cell+ @ ;
652 :			r> r> r> r> dup itmp ! >r >r >r >r itmp @ ;
653 :			[IFUNDEF] itmp variable itmp [THEN]
654 :	anton	1.1
655 :	anton	1.215	k ( R:w R:w1 R:w2 R:w3 R:w4 -- w R:w R:w1 R:w2 R:w3 R:w4 ) gforth
656 :	anton	1.1	:
657 :	jwilke	1.5	\ rp@ [ 5 cells ] Literal + @ ;
658 :			r> r> r> r> r> r> dup itmp ! >r >r >r >r >r >r itmp @ ;
659 :			[IFUNDEF] itmp variable itmp [THEN]
660 :	jwilke	1.31
661 :			\f[THEN]
662 :	anton	1.1
663 :			\ digit is high-level: 0/0%
664 :
665 :	pazsan	1.83	\g strings
666 :
667 :	anton	1.47	move ( c_from c_to ucount -- ) core
668 :	anton	1.52	""Copy the contents of @i{ucount} aus at @i{c-from} to
669 :	anton	1.33	@i{c-to}. @code{move} works correctly even if the two areas overlap.""
670 :	anton	1.52	/* !! note that the standard specifies addr, not c-addr */
671 :	anton	1.1	memmove(c_to,c_from,ucount);
672 :			/* make an Ifdef for bsd and others? */
673 :			:
674 :			>r 2dup u< IF r> cmove> ELSE r> cmove THEN ;
675 :
676 :	anton	1.47	cmove ( c_from c_to u -- ) string c_move
677 :	anton	1.33	""Copy the contents of @i{ucount} characters from data space at
678 :			@i{c-from} to @i{c-to}. The copy proceeds @code{char}-by-@code{char}
679 :			from low address to high address; i.e., for overlapping areas it is
680 :			safe if @i{c-to}=<@i{c-from}.""
681 :	anton	1.125	cmove(c_from,c_to,u);
682 :	anton	1.1	:
683 :			bounds ?DO dup c@ I c! 1+ LOOP drop ;
684 :
685 :	anton	1.47	cmove> ( c_from c_to u -- ) string c_move_up
686 :	anton	1.33	""Copy the contents of @i{ucount} characters from data space at
687 :			@i{c-from} to @i{c-to}. The copy proceeds @code{char}-by-@code{char}
688 :			from high address to low address; i.e., for overlapping areas it is
689 :			safe if @i{c-to}>=@i{c-from}.""
690 :	anton	1.125	cmove_up(c_from,c_to,u);
691 :	anton	1.1	:
692 :			dup 0= IF drop 2drop exit THEN
693 :			rot over + -rot bounds swap 1-
694 :			DO 1- dup c@ I c! -1 +LOOP drop ;
695 :
696 :	anton	1.47	fill ( c_addr u c -- ) core
697 :	anton	1.52	""Store @i{c} in @i{u} chars starting at @i{c-addr}.""
698 :	anton	1.1	memset(c_addr,c,u);
699 :			:
700 :			-rot bounds
701 :			?DO dup I c! LOOP drop ;
702 :
703 :	anton	1.47	compare ( c_addr1 u1 c_addr2 u2 -- n ) string
704 :	crook	1.29	""Compare two strings lexicographically. If they are equal, @i{n} is 0; if
705 :			the first string is smaller, @i{n} is -1; if the first string is larger, @i{n}
706 :	anton	1.1	is 1. Currently this is based on the machine's character
707 :	crook	1.26	comparison. In the future, this may change to consider the current
708 :	anton	1.1	locale and its collation order.""
709 :	pazsan	1.46	/* close ' to keep fontify happy */
710 :	anton	1.125	n = compare(c_addr1, u1, c_addr2, u2);
711 :	anton	1.1	:
712 :	pazsan	1.43	rot 2dup swap - >r min swap -text dup
713 :			IF rdrop ELSE drop r> sgn THEN ;
714 :	pazsan	1.143	: -text ( c_addr1 u c_addr2 -- n )
715 :			swap bounds
716 :			?DO dup c@ I c@ = WHILE 1+ LOOP drop 0
717 :			ELSE c@ I c@ - unloop THEN sgn ;
718 :	pazsan	1.43	: sgn ( n -- -1/0/1 )
719 :			dup 0= IF EXIT THEN 0< 2* 1+ ;
720 :	anton	1.1
721 :	anton	1.125	\ -text is only used by replaced primitives now; move it elsewhere
722 :			\ -text ( c_addr1 u c_addr2 -- n ) new dash_text
723 :			\ n = memcmp(c_addr1, c_addr2, u);
724 :			\ if (n<0)
725 :			\ n = -1;
726 :			\ else if (n>0)
727 :			\ n = 1;
728 :			\ :
729 :			\ swap bounds
730 :			\ ?DO dup c@ I c@ = WHILE 1+ LOOP drop 0
731 :			\ ELSE c@ I c@ - unloop THEN sgn ;
732 :			\ : sgn ( n -- -1/0/1 )
733 :			\ dup 0= IF EXIT THEN 0< 2* 1+ ;
734 :	anton	1.1
735 :	anton	1.47	toupper ( c1 -- c2 ) gforth
736 :	crook	1.29	""If @i{c1} is a lower-case character (in the current locale), @i{c2}
737 :	anton	1.25	is the equivalent upper-case character. All other characters are unchanged.""
738 :	anton	1.1	c2 = toupper(c1);
739 :			:
740 :			dup [char] a - [ char z char a - 1 + ] Literal u< bl and - ;
741 :
742 :	anton	1.223	capscompare ( c_addr1 u1 c_addr2 u2 -- n ) gforth
743 :	pazsan	1.188	""Compare two strings lexicographically. If they are equal, @i{n} is 0; if
744 :			the first string is smaller, @i{n} is -1; if the first string is larger, @i{n}
745 :			is 1. Currently this is based on the machine's character
746 :			comparison. In the future, this may change to consider the current
747 :			locale and its collation order.""
748 :			/* close ' to keep fontify happy */
749 :			n = capscompare(c_addr1, u1, c_addr2, u2);
750 :
751 :	anton	1.47	/string ( c_addr1 u1 n -- c_addr2 u2 ) string slash_string
752 :	crook	1.29	""Adjust the string specified by @i{c-addr1, u1} to remove @i{n}
753 :	crook	1.27	characters from the start of the string.""
754 :	anton	1.1	c_addr2 = c_addr1+n;
755 :			u2 = u1-n;
756 :			:
757 :			tuck - >r + r> dup 0< IF - 0 THEN ;
758 :
759 :	pazsan	1.83	\g arith
760 :
761 :	pazsan	1.112	lit ( #w -- w ) gforth
762 :			:
763 :			r> dup @ swap cell+ >r ;
764 :
765 :	anton	1.47	+ ( n1 n2 -- n ) core plus
766 :	anton	1.1	n = n1+n2;
767 :
768 :	pazsan	1.112	\ lit+ / lit_plus = lit +
769 :
770 :			lit+ ( n1 #n2 -- n ) new lit_plus
771 :	pazsan	1.211	#ifdef DEBUG
772 :			fprintf(stderr, "lit+ %08x\n", n2);
773 :			#endif
774 :	pazsan	1.112	n=n1+n2;
775 :
776 :	anton	1.1	\ PFE-0.9.14 has it differently, but the next release will have it as follows
777 :	anton	1.47	under+ ( n1 n2 n3 -- n n2 ) gforth under_plus
778 :	crook	1.29	""add @i{n3} to @i{n1} (giving @i{n})""
779 :	anton	1.1	n = n1+n3;
780 :			:
781 :			rot + swap ;
782 :
783 :	anton	1.47	- ( n1 n2 -- n ) core minus
784 :	anton	1.1	n = n1-n2;
785 :			:
786 :			negate + ;
787 :
788 :	anton	1.47	negate ( n1 -- n2 ) core
789 :	anton	1.1	/* use minus as alias */
790 :			n2 = -n1;
791 :			:
792 :			invert 1+ ;
793 :
794 :	anton	1.47	1+ ( n1 -- n2 ) core one_plus
795 :	anton	1.1	n2 = n1+1;
796 :			:
797 :			1 + ;
798 :
799 :	anton	1.47	1- ( n1 -- n2 ) core one_minus
800 :	anton	1.1	n2 = n1-1;
801 :			:
802 :			1 - ;
803 :
804 :	anton	1.47	max ( n1 n2 -- n ) core
805 :	anton	1.1	if (n1<n2)
806 :			n = n2;
807 :			else
808 :			n = n1;
809 :			:
810 :			2dup < IF swap THEN drop ;
811 :
812 :	anton	1.47	min ( n1 n2 -- n ) core
813 :	anton	1.1	if (n1<n2)
814 :			n = n1;
815 :			else
816 :			n = n2;
817 :			:
818 :			2dup > IF swap THEN drop ;
819 :
820 :	anton	1.52	abs ( n -- u ) core
821 :			if (n<0)
822 :			u = -n;
823 :	anton	1.1	else
824 :	anton	1.52	u = n;
825 :	anton	1.1	:
826 :			dup 0< IF negate THEN ;
827 :
828 :	anton	1.47	* ( n1 n2 -- n ) core star
829 :	anton	1.1	n = n1*n2;
830 :			:
831 :			um* drop ;
832 :
833 :	anton	1.47	/ ( n1 n2 -- n ) core slash
834 :	anton	1.1	n = n1/n2;
835 :	anton	1.200	if (CHECK_DIVISION_SW && n2 == 0)
836 :	anton	1.198	throw(BALL_DIVZERO);
837 :	anton	1.200	if (CHECK_DIVISION_SW && n2 == -1 && n1 == CELL_MIN)
838 :	anton	1.198	throw(BALL_RESULTRANGE);
839 :	anton	1.197	if (FLOORED_DIV && ((n1^n2) < 0) && (n1%n2 != 0))
840 :			n--;
841 :	anton	1.1	:
842 :			/mod nip ;
843 :
844 :	anton	1.47	mod ( n1 n2 -- n ) core
845 :	anton	1.1	n = n1%n2;
846 :	anton	1.200	if (CHECK_DIVISION_SW && n2 == 0)
847 :	anton	1.198	throw(BALL_DIVZERO);
848 :	anton	1.200	if (CHECK_DIVISION_SW && n2 == -1 && n1 == CELL_MIN)
849 :	anton	1.198	throw(BALL_RESULTRANGE);
850 :	pazsan	1.169	if(FLOORED_DIV && ((n1^n2) < 0) && n!=0) n += n2;
851 :	anton	1.1	:
852 :			/mod drop ;
853 :
854 :	anton	1.47	/mod ( n1 n2 -- n3 n4 ) core slash_mod
855 :	anton	1.1	n4 = n1/n2;
856 :			n3 = n1%n2; /* !! is this correct? look into C standard! */
857 :	anton	1.200	if (CHECK_DIVISION_SW && n2 == 0)
858 :	anton	1.198	throw(BALL_DIVZERO);
859 :	anton	1.200	if (CHECK_DIVISION_SW && n2 == -1 && n1 == CELL_MIN)
860 :	anton	1.198	throw(BALL_RESULTRANGE);
861 :	pazsan	1.169	if (FLOORED_DIV && ((n1^n2) < 0) && n3!=0) {
862 :	pazsan	1.162	n4--;
863 :			n3+=n2;
864 :			}
865 :	anton	1.1	:
866 :			>r s>d r> fm/mod ;
867 :
868 :	pazsan	1.162	*/mod ( n1 n2 n3 -- n4 n5 ) core star_slash_mod
869 :			""n1n2=n3n5+n4, with the intermediate result (n1*n2) being double.""
870 :			#ifdef BUGGY_LL_MUL
871 :			DCell d = mmul(n1,n2);
872 :			#else
873 :			DCell d = (DCell)n1 * (DCell)n2;
874 :			#endif
875 :	anton	1.202	#ifdef ASM_SM_SLASH_REM
876 :			ASM_SM_SLASH_REM(DLO(d), DHI(d), n3, n4, n5);
877 :	anton	1.207	if (FLOORED_DIV && ((DHI(d)^n3)<0) && n4!=0) {
878 :	anton	1.202	if (CHECK_DIVISION && n5 == CELL_MIN)
879 :			throw(BALL_RESULTRANGE);
880 :			n5--;
881 :			n4+=n3;
882 :			}
883 :			#else
884 :	anton	1.207	DCell r = FLOORED_DIV ? fmdiv(d,n3) : smdiv(d,n3);
885 :	pazsan	1.162	n4=DHI(r);
886 :			n5=DLO(r);
887 :			#endif
888 :			:
889 :			>r m* r> fm/mod ;
890 :
891 :			*/ ( n1 n2 n3 -- n4 ) core star_slash
892 :			""n4=(n1*n2)/n3, with the intermediate result being double.""
893 :			#ifdef BUGGY_LL_MUL
894 :			DCell d = mmul(n1,n2);
895 :			#else
896 :			DCell d = (DCell)n1 * (DCell)n2;
897 :			#endif
898 :	anton	1.202	#ifdef ASM_SM_SLASH_REM
899 :			Cell remainder;
900 :			ASM_SM_SLASH_REM(DLO(d), DHI(d), n3, remainder, n4);
901 :	anton	1.207	if (FLOORED_DIV && ((DHI(d)^n3)<0) && remainder!=0) {
902 :	anton	1.202	if (CHECK_DIVISION && n4 == CELL_MIN)
903 :			throw(BALL_RESULTRANGE);
904 :			n4--;
905 :			}
906 :			#else
907 :	anton	1.207	DCell r = FLOORED_DIV ? fmdiv(d,n3) : smdiv(d,n3);
908 :	pazsan	1.168	n4=DLO(r);
909 :	pazsan	1.162	#endif
910 :			:
911 :			*/mod nip ;
912 :
913 :	anton	1.47	2* ( n1 -- n2 ) core two_star
914 :	anton	1.52	""Shift left by 1; also works on unsigned numbers""
915 :	anton	1.1	n2 = 2*n1;
916 :			:
917 :			dup + ;
918 :
919 :	anton	1.47	2/ ( n1 -- n2 ) core two_slash
920 :	anton	1.52	""Arithmetic shift right by 1. For signed numbers this is a floored
921 :			division by 2 (note that @code{/} not necessarily floors).""
922 :	anton	1.1	n2 = n1>>1;
923 :			:
924 :			dup MINI and IF 1 ELSE 0 THEN
925 :	pazsan	1.187	[ bits/char cell * 1- ] literal
926 :	jwilke	1.5	0 DO 2* swap dup 2* >r MINI and
927 :	anton	1.1	IF 1 ELSE 0 THEN or r> swap
928 :			LOOP nip ;
929 :
930 :	anton	1.47	fm/mod ( d1 n1 -- n2 n3 ) core f_m_slash_mod
931 :	crook	1.29	""Floored division: @i{d1} = @i{n3}*@i{n1}+@i{n2}, @i{n1}>@i{n2}>=0 or 0>=@i{n2}>@i{n1}.""
932 :	anton	1.201	#ifdef ASM_SM_SLASH_REM
933 :	anton	1.203	ASM_SM_SLASH_REM(DLO(d1), DHI(d1), n1, n2, n3);
934 :	pazsan	1.169	if (((DHI(d1)^n1)<0) && n2!=0) {
935 :	anton	1.200	if (CHECK_DIVISION && n3 == CELL_MIN)
936 :	anton	1.198	throw(BALL_RESULTRANGE);
937 :	anton	1.165	n3--;
938 :			n2+=n1;
939 :			}
940 :	anton	1.201	#else /* !defined(ASM_SM_SLASH_REM) */
941 :			DCell r = fmdiv(d1,n1);
942 :			n2=DHI(r);
943 :			n3=DLO(r);
944 :	anton	1.203	#endif /* !defined(ASM_SM_SLASH_REM) */
945 :	anton	1.1	:
946 :			dup >r dup 0< IF negate >r dnegate r> THEN
947 :			over 0< IF tuck + swap THEN
948 :			um/mod
949 :			r> 0< IF swap negate swap THEN ;
950 :
951 :	anton	1.47	sm/rem ( d1 n1 -- n2 n3 ) core s_m_slash_rem
952 :	crook	1.29	""Symmetric division: @i{d1} = @i{n3}*@i{n1}+@i{n2}, sign(@i{n2})=sign(@i{d1}) or 0.""
953 :	anton	1.165	#ifdef ASM_SM_SLASH_REM
954 :	anton	1.203	ASM_SM_SLASH_REM(DLO(d1), DHI(d1), n1, n2, n3);
955 :	anton	1.165	#else /* !defined(ASM_SM_SLASH_REM) */
956 :	anton	1.1	DCell r = smdiv(d1,n1);
957 :	pazsan	1.162	n2=DHI(r);
958 :			n3=DLO(r);
959 :	anton	1.165	#endif /* !defined(ASM_SM_SLASH_REM) */
960 :	anton	1.1	:
961 :			over >r dup >r abs -rot
962 :			dabs rot um/mod
963 :			r> r@ xor 0< IF negate THEN
964 :			r> 0< IF swap negate swap THEN ;
965 :
966 :	anton	1.47	m* ( n1 n2 -- d ) core m_star
967 :	pazsan	1.158	#ifdef BUGGY_LL_MUL
968 :	anton	1.1	d = mmul(n1,n2);
969 :			#else
970 :			d = (DCell)n1 * (DCell)n2;
971 :			#endif
972 :			:
973 :			2dup 0< and >r
974 :			2dup swap 0< and >r
975 :			um* r> - r> - ;
976 :
977 :	anton	1.47	um* ( u1 u2 -- ud ) core u_m_star
978 :	anton	1.1	/* use u* as alias */
979 :	pazsan	1.158	#ifdef BUGGY_LL_MUL
980 :	anton	1.1	ud = ummul(u1,u2);
981 :			#else
982 :			ud = (UDCell)u1 * (UDCell)u2;
983 :			#endif
984 :			:
985 :	pazsan	1.137	0 -rot dup [ 8 cells ] literal -
986 :	anton	1.1	DO
987 :	pazsan	1.137	dup 0< I' and d2*+ drop
988 :			LOOP ;
989 :	anton	1.1	: d2*+ ( ud n -- ud+n c )
990 :			over MINI
991 :			and >r >r 2dup d+ swap r> + swap r> ;
992 :
993 :	anton	1.47	um/mod ( ud u1 -- u2 u3 ) core u_m_slash_mod
994 :	anton	1.32	""ud=u3*u1+u2, u1>u2>=0""
995 :	anton	1.165	#ifdef ASM_UM_SLASH_MOD
996 :	anton	1.203	ASM_UM_SLASH_MOD(DLO(ud), DHI(ud), u1, u2, u3);
997 :	anton	1.165	#else /* !defined(ASM_UM_SLASH_MOD) */
998 :	anton	1.1	UDCell r = umdiv(ud,u1);
999 :	pazsan	1.162	u2=DHI(r);
1000 :			u3=DLO(r);
1001 :	anton	1.165	#endif /* !defined(ASM_UM_SLASH_MOD) */
1002 :	anton	1.1	:
1003 :			0 swap [ 8 cells 1 + ] literal 0
1004 :	jwilke	1.5	?DO /modstep
1005 :	anton	1.1	LOOP drop swap 1 rshift or swap ;
1006 :			: /modstep ( ud c R: u -- ud-?u c R: u )
1007 :	jwilke	1.5	>r over r@ u< 0= or IF r@ - 1 ELSE 0 THEN d2*+ r> ;
1008 :	anton	1.1	: d2*+ ( ud n -- ud+n c )
1009 :			over MINI
1010 :			and >r >r 2dup d+ swap r> + swap r> ;
1011 :
1012 :	anton	1.47	m+ ( d1 n -- d2 ) double m_plus
1013 :	pazsan	1.158	#ifdef BUGGY_LL_ADD
1014 :			DLO_IS(d2, DLO(d1)+n);
1015 :			DHI_IS(d2, DHI(d1) - (n<0) + (DLO(d2)<DLO(d1)));
1016 :	anton	1.1	#else
1017 :			d2 = d1+n;
1018 :			#endif
1019 :			:
1020 :			s>d d+ ;
1021 :
1022 :	anton	1.47	d+ ( d1 d2 -- d ) double d_plus
1023 :	pazsan	1.158	#ifdef BUGGY_LL_ADD
1024 :			DLO_IS(d, DLO(d1) + DLO(d2));
1025 :			DHI_IS(d, DHI(d1) + DHI(d2) + (d.lo<DLO(d1)));
1026 :	anton	1.1	#else
1027 :			d = d1+d2;
1028 :			#endif
1029 :			:
1030 :			rot + >r tuck + swap over u> r> swap - ;
1031 :
1032 :	anton	1.47	d- ( d1 d2 -- d ) double d_minus
1033 :	pazsan	1.158	#ifdef BUGGY_LL_ADD
1034 :			DLO_IS(d, DLO(d1) - DLO(d2));
1035 :			DHI_IS(d, DHI(d1)-DHI(d2)-(DLO(d1)<DLO(d2)));
1036 :	anton	1.1	#else
1037 :			d = d1-d2;
1038 :			#endif
1039 :			:
1040 :			dnegate d+ ;
1041 :
1042 :	anton	1.47	dnegate ( d1 -- d2 ) double d_negate
1043 :	anton	1.1	/* use dminus as alias */
1044 :	pazsan	1.158	#ifdef BUGGY_LL_ADD
1045 :	anton	1.1	d2 = dnegate(d1);
1046 :			#else
1047 :			d2 = -d1;
1048 :			#endif
1049 :			:
1050 :			invert swap negate tuck 0= - ;
1051 :
1052 :	anton	1.47	d2* ( d1 -- d2 ) double d_two_star
1053 :	anton	1.52	""Shift left by 1; also works on unsigned numbers""
1054 :	anton	1.205	d2 = DLSHIFT(d1,1);
1055 :	anton	1.1	:
1056 :			2dup d+ ;
1057 :
1058 :	anton	1.47	d2/ ( d1 -- d2 ) double d_two_slash
1059 :	anton	1.52	""Arithmetic shift right by 1. For signed numbers this is a floored
1060 :			division by 2.""
1061 :	pazsan	1.158	#ifdef BUGGY_LL_SHIFT
1062 :			DHI_IS(d2, DHI(d1)>>1);
1063 :			DLO_IS(d2, (DLO(d1)>>1) \| (DHI(d1)<<(CELL_BITS-1)));
1064 :	anton	1.1	#else
1065 :			d2 = d1>>1;
1066 :			#endif
1067 :			:
1068 :			dup 1 and >r 2/ swap 2/ [ 1 8 cells 1- lshift 1- ] Literal and
1069 :			r> IF [ 1 8 cells 1- lshift ] Literal + THEN swap ;
1070 :
1071 :	anton	1.47	and ( w1 w2 -- w ) core
1072 :	anton	1.1	w = w1&w2;
1073 :
1074 :	anton	1.47	or ( w1 w2 -- w ) core
1075 :	anton	1.1	w = w1\|w2;
1076 :			:
1077 :			invert swap invert and invert ;
1078 :
1079 :	anton	1.47	xor ( w1 w2 -- w ) core x_or
1080 :	anton	1.1	w = w1^w2;
1081 :
1082 :	anton	1.47	invert ( w1 -- w2 ) core
1083 :	anton	1.1	w2 = ~w1;
1084 :			:
1085 :			MAXU xor ;
1086 :
1087 :	anton	1.47	rshift ( u1 n -- u2 ) core r_shift
1088 :	anton	1.53	""Logical shift right by @i{n} bits.""
1089 :	pazsan	1.154	#ifdef BROKEN_SHIFT
1090 :			u2 = rshift(u1, n);
1091 :			#else
1092 :			u2 = u1 >> n;
1093 :			#endif
1094 :	anton	1.1	:
1095 :			0 ?DO 2/ MAXI and LOOP ;
1096 :
1097 :	anton	1.47	lshift ( u1 n -- u2 ) core l_shift
1098 :	pazsan	1.154	#ifdef BROKEN_SHIFT
1099 :			u2 = lshift(u1, n);
1100 :			#else
1101 :			u2 = u1 << n;
1102 :			#endif
1103 :	anton	1.1	:
1104 :			0 ?DO 2* LOOP ;
1105 :
1106 :	pazsan	1.110	\g compare
1107 :
1108 :	anton	1.1	\ comparisons(prefix, args, prefix, arg1, arg2, wordsets...)
1109 :			define(comparisons,
1110 :	anton	1.47	$1= ( $2 -- f ) $6 $3equals
1111 :	anton	1.1	f = FLAG($4==$5);
1112 :			:
1113 :			[ char $1x char 0 = [IF]
1114 :			] IF false ELSE true THEN [
1115 :			[ELSE]
1116 :			] xor 0= [
1117 :			[THEN] ] ;
1118 :
1119 :	anton	1.47	$1<> ( $2 -- f ) $7 $3not_equals
1120 :	anton	1.1	f = FLAG($4!=$5);
1121 :			:
1122 :			[ char $1x char 0 = [IF]
1123 :			] IF true ELSE false THEN [
1124 :			[ELSE]
1125 :			] xor 0<> [
1126 :			[THEN] ] ;
1127 :
1128 :	anton	1.47	$1< ( $2 -- f ) $8 $3less_than
1129 :	anton	1.1	f = FLAG($4<$5);
1130 :			:
1131 :			[ char $1x char 0 = [IF]
1132 :			] MINI and 0<> [
1133 :			[ELSE] char $1x char u = [IF]
1134 :			] 2dup xor 0< IF nip ELSE - THEN 0< [
1135 :			[ELSE]
1136 :			] MINI xor >r MINI xor r> u< [
1137 :			[THEN]
1138 :			[THEN] ] ;
1139 :
1140 :	anton	1.47	$1> ( $2 -- f ) $9 $3greater_than
1141 :	anton	1.1	f = FLAG($4>$5);
1142 :			:
1143 :			[ char $1x char 0 = [IF] ] negate [ [ELSE] ] swap [ [THEN] ]
1144 :			$1< ;
1145 :
1146 :	anton	1.47	$1<= ( $2 -- f ) gforth $3less_or_equal
1147 :	anton	1.1	f = FLAG($4<=$5);
1148 :			:
1149 :			$1> 0= ;
1150 :
1151 :	anton	1.47	$1>= ( $2 -- f ) gforth $3greater_or_equal
1152 :	anton	1.1	f = FLAG($4>=$5);
1153 :			:
1154 :			[ char $1x char 0 = [IF] ] negate [ [ELSE] ] swap [ [THEN] ]
1155 :			$1<= ;
1156 :
1157 :			)
1158 :
1159 :			comparisons(0, n, zero_, n, 0, core, core-ext, core, core-ext)
1160 :			comparisons(, n1 n2, , n1, n2, core, core-ext, core, core)
1161 :			comparisons(u, u1 u2, u_, u1, u2, gforth, gforth, core, core-ext)
1162 :
1163 :			\ dcomparisons(prefix, args, prefix, arg1, arg2, wordsets...)
1164 :			define(dcomparisons,
1165 :	anton	1.47	$1= ( $2 -- f ) $6 $3equals
1166 :	pazsan	1.158	#ifdef BUGGY_LL_CMP
1167 :	anton	1.1	f = FLAG($4.lo==$5.lo && $4.hi==$5.hi);
1168 :			#else
1169 :			f = FLAG($4==$5);
1170 :			#endif
1171 :
1172 :	anton	1.47	$1<> ( $2 -- f ) $7 $3not_equals
1173 :	pazsan	1.158	#ifdef BUGGY_LL_CMP
1174 :	anton	1.1	f = FLAG($4.lo!=$5.lo \|\| $4.hi!=$5.hi);
1175 :			#else
1176 :			f = FLAG($4!=$5);
1177 :			#endif
1178 :
1179 :	anton	1.47	$1< ( $2 -- f ) $8 $3less_than
1180 :	pazsan	1.158	#ifdef BUGGY_LL_CMP
1181 :	anton	1.1	f = FLAG($4.hi==$5.hi ? $4.lo<$5.lo : $4.hi<$5.hi);
1182 :			#else
1183 :			f = FLAG($4<$5);
1184 :			#endif
1185 :
1186 :	anton	1.47	$1> ( $2 -- f ) $9 $3greater_than
1187 :	pazsan	1.158	#ifdef BUGGY_LL_CMP
1188 :	anton	1.1	f = FLAG($4.hi==$5.hi ? $4.lo>$5.lo : $4.hi>$5.hi);
1189 :			#else
1190 :			f = FLAG($4>$5);
1191 :			#endif
1192 :
1193 :	anton	1.47	$1<= ( $2 -- f ) gforth $3less_or_equal
1194 :	pazsan	1.158	#ifdef BUGGY_LL_CMP
1195 :	anton	1.1	f = FLAG($4.hi==$5.hi ? $4.lo<=$5.lo : $4.hi<=$5.hi);
1196 :			#else
1197 :			f = FLAG($4<=$5);
1198 :			#endif
1199 :
1200 :	anton	1.47	$1>= ( $2 -- f ) gforth $3greater_or_equal
1201 :	pazsan	1.158	#ifdef BUGGY_LL_CMP
1202 :	anton	1.1	f = FLAG($4.hi==$5.hi ? $4.lo>=$5.lo : $4.hi>=$5.hi);
1203 :			#else
1204 :			f = FLAG($4>=$5);
1205 :			#endif
1206 :
1207 :			)
1208 :
1209 :	pazsan	1.15	\+dcomps
1210 :	anton	1.1
1211 :			dcomparisons(d, d1 d2, d_, d1, d2, double, gforth, double, gforth)
1212 :			dcomparisons(d0, d, d_zero_, d, DZERO, double, gforth, double, gforth)
1213 :			dcomparisons(du, ud1 ud2, d_u_, ud1, ud2, gforth, gforth, double-ext, gforth)
1214 :
1215 :	pazsan	1.15	\+
1216 :	anton	1.1
1217 :	anton	1.47	within ( u1 u2 u3 -- f ) core-ext
1218 :	anton	1.32	""u2=<u1<u3 or: u3=<u2 and u1 is not in [u3,u2). This works for
1219 :			unsigned and signed numbers (but not a mixture). Another way to think
1220 :			about this word is to consider the numbers as a circle (wrapping
1221 :			around from @code{max-u} to 0 for unsigned, and from @code{max-n} to
1222 :			min-n for signed numbers); now consider the range from u2 towards
1223 :			increasing numbers up to and excluding u3 (giving an empty range if
1224 :	anton	1.52	u2=u3); if u1 is in this range, @code{within} returns true.""
1225 :	anton	1.1	f = FLAG(u1-u2 < u3-u2);
1226 :			:
1227 :			over - >r - r> u< ;
1228 :
1229 :	pazsan	1.112	\g stack
1230 :
1231 :			useraddr ( #u -- a_addr ) new
1232 :			a_addr = (Cell *)(up+u);
1233 :
1234 :			up! ( a_addr -- ) gforth up_store
1235 :	pazsan	1.190	gforth_UP=up=(Address)a_addr;
1236 :	pazsan	1.112	:
1237 :			up ! ;
1238 :			Variable UP
1239 :
1240 :	anton	1.172	sp@ ( S:... -- a_addr ) gforth sp_fetch
1241 :			a_addr = sp;
1242 :	anton	1.1
1243 :	anton	1.172	sp! ( a_addr -- S:... ) gforth sp_store
1244 :	anton	1.1	sp = a_addr;
1245 :
1246 :	anton	1.47	rp@ ( -- a_addr ) gforth rp_fetch
1247 :	anton	1.1	a_addr = rp;
1248 :
1249 :	anton	1.47	rp! ( a_addr -- ) gforth rp_store
1250 :	anton	1.1	rp = a_addr;
1251 :
1252 :	pazsan	1.15	\+floating
1253 :	anton	1.1
1254 :	anton	1.172	fp@ ( f:... -- f_addr ) gforth fp_fetch
1255 :	anton	1.1	f_addr = fp;
1256 :
1257 :	anton	1.172	fp! ( f_addr -- f:... ) gforth fp_store
1258 :	anton	1.1	fp = f_addr;
1259 :
1260 :	pazsan	1.15	\+
1261 :	anton	1.1
1262 :	anton	1.65	>r ( w -- R:w ) core to_r
1263 :	anton	1.1	:
1264 :			(>r) ;
1265 :			: (>r) rp@ cell+ @ rp@ ! rp@ cell+ ! ;
1266 :
1267 :	anton	1.65	r> ( R:w -- w ) core r_from
1268 :	anton	1.1	:
1269 :			rp@ cell+ @ rp@ @ rp@ cell+ ! (rdrop) rp@ ! ;
1270 :			Create (rdrop) ' ;s A,
1271 :
1272 :	anton	1.65	rdrop ( R:w -- ) gforth
1273 :	anton	1.1	:
1274 :			r> r> drop >r ;
1275 :
1276 :	pazsan	1.136	2>r ( d -- R:d ) core-ext two_to_r
1277 :	anton	1.1	:
1278 :			swap r> swap >r swap >r >r ;
1279 :
1280 :	pazsan	1.136	2r> ( R:d -- d ) core-ext two_r_from
1281 :	anton	1.1	:
1282 :			r> r> swap r> swap >r swap ;
1283 :
1284 :	pazsan	1.136	2r@ ( R:d -- R:d d ) core-ext two_r_fetch
1285 :	anton	1.1	:
1286 :			i' j ;
1287 :
1288 :	pazsan	1.136	2rdrop ( R:d -- ) gforth two_r_drop
1289 :	anton	1.1	:
1290 :			r> r> drop r> drop >r ;
1291 :
1292 :	anton	1.47	over ( w1 w2 -- w1 w2 w1 ) core
1293 :	anton	1.1	:
1294 :			sp@ cell+ @ ;
1295 :
1296 :	anton	1.47	drop ( w -- ) core
1297 :	anton	1.1	:
1298 :			IF THEN ;
1299 :
1300 :	anton	1.47	swap ( w1 w2 -- w2 w1 ) core
1301 :	anton	1.1	:
1302 :			>r (swap) ! r> (swap) @ ;
1303 :			Variable (swap)
1304 :
1305 :	anton	1.47	dup ( w -- w w ) core dupe
1306 :	anton	1.1	:
1307 :			sp@ @ ;
1308 :
1309 :	anton	1.47	rot ( w1 w2 w3 -- w2 w3 w1 ) core rote
1310 :	anton	1.1	:
1311 :			[ defined? (swap) [IF] ]
1312 :			(swap) ! (rot) ! >r (rot) @ (swap) @ r> ;
1313 :			Variable (rot)
1314 :			[ELSE] ]
1315 :			>r swap r> swap ;
1316 :			[THEN]
1317 :
1318 :	anton	1.47	-rot ( w1 w2 w3 -- w3 w1 w2 ) gforth not_rote
1319 :	anton	1.1	:
1320 :			rot rot ;
1321 :
1322 :	anton	1.47	nip ( w1 w2 -- w2 ) core-ext
1323 :	anton	1.1	:
1324 :	jwilke	1.6	swap drop ;
1325 :	anton	1.1
1326 :	anton	1.47	tuck ( w1 w2 -- w2 w1 w2 ) core-ext
1327 :	anton	1.1	:
1328 :			swap over ;
1329 :
1330 :	anton	1.172	?dup ( w -- S:... w ) core question_dupe
1331 :	anton	1.52	""Actually the stack effect is: @code{( w -- 0 \| w w )}. It performs a
1332 :			@code{dup} if w is nonzero.""
1333 :	anton	1.1	if (w!=0) {
1334 :			*--sp = w;
1335 :			}
1336 :			:
1337 :			dup IF dup THEN ;
1338 :
1339 :	anton	1.172	pick ( S:... u -- S:... w ) core-ext
1340 :	anton	1.52	""Actually the stack effect is @code{ x0 ... xu u -- x0 ... xu x0 }.""
1341 :	anton	1.172	w = sp[u];
1342 :	anton	1.1	:
1343 :			1+ cells sp@ + @ ;
1344 :
1345 :	anton	1.47	2drop ( w1 w2 -- ) core two_drop
1346 :	anton	1.1	:
1347 :			drop drop ;
1348 :
1349 :	anton	1.47	2dup ( w1 w2 -- w1 w2 w1 w2 ) core two_dupe
1350 :	anton	1.1	:
1351 :			over over ;
1352 :
1353 :	anton	1.47	2over ( w1 w2 w3 w4 -- w1 w2 w3 w4 w1 w2 ) core two_over
1354 :	anton	1.1	:
1355 :			3 pick 3 pick ;
1356 :
1357 :	anton	1.47	2swap ( w1 w2 w3 w4 -- w3 w4 w1 w2 ) core two_swap
1358 :	anton	1.1	:
1359 :			rot >r rot r> ;
1360 :
1361 :	anton	1.47	2rot ( w1 w2 w3 w4 w5 w6 -- w3 w4 w5 w6 w1 w2 ) double-ext two_rote
1362 :	anton	1.1	:
1363 :			>r >r 2swap r> r> 2swap ;
1364 :
1365 :	anton	1.47	2nip ( w1 w2 w3 w4 -- w3 w4 ) gforth two_nip
1366 :	anton	1.1	:
1367 :			2swap 2drop ;
1368 :
1369 :	anton	1.47	2tuck ( w1 w2 w3 w4 -- w3 w4 w1 w2 w3 w4 ) gforth two_tuck
1370 :	anton	1.1	:
1371 :			2swap 2over ;
1372 :
1373 :			\ toggle is high-level: 0.11/0.42%
1374 :
1375 :	pazsan	1.110	\g memory
1376 :
1377 :	anton	1.47	@ ( a_addr -- w ) core fetch
1378 :	anton	1.52	""@i{w} is the cell stored at @i{a_addr}.""
1379 :	anton	1.1	w = *a_addr;
1380 :
1381 :	pazsan	1.112	\ lit@ / lit_fetch = lit @
1382 :
1383 :			lit@ ( #a_addr -- w ) new lit_fetch
1384 :			w = *a_addr;
1385 :
1386 :	anton	1.47	! ( w a_addr -- ) core store
1387 :	anton	1.52	""Store @i{w} into the cell at @i{a-addr}.""
1388 :	anton	1.1	*a_addr = w;
1389 :
1390 :	anton	1.47	+! ( n a_addr -- ) core plus_store
1391 :	anton	1.52	""Add @i{n} to the cell at @i{a-addr}.""
1392 :	anton	1.1	*a_addr += n;
1393 :			:
1394 :			tuck @ + swap ! ;
1395 :
1396 :	anton	1.47	c@ ( c_addr -- c ) core c_fetch
1397 :	anton	1.52	""@i{c} is the char stored at @i{c_addr}.""
1398 :	anton	1.1	c = *c_addr;
1399 :			:
1400 :			[ bigendian [IF] ]
1401 :			[ cell>bit 4 = [IF] ]
1402 :			dup [ 0 cell - ] Literal and @ swap 1 and
1403 :			IF $FF and ELSE 8>> THEN ;
1404 :			[ [ELSE] ]
1405 :			dup [ cell 1- ] literal and
1406 :			tuck - @ swap [ cell 1- ] literal xor
1407 :			0 ?DO 8>> LOOP $FF and
1408 :			[ [THEN] ]
1409 :			[ [ELSE] ]
1410 :			[ cell>bit 4 = [IF] ]
1411 :			dup [ 0 cell - ] Literal and @ swap 1 and
1412 :			IF 8>> ELSE $FF and THEN
1413 :			[ [ELSE] ]
1414 :			dup [ cell 1- ] literal and
1415 :			tuck - @ swap
1416 :			0 ?DO 8>> LOOP 255 and
1417 :			[ [THEN] ]
1418 :			[ [THEN] ]
1419 :			;
1420 :			: 8>> 2/ 2/ 2/ 2/ 2/ 2/ 2/ 2/ ;
1421 :
1422 :	anton	1.47	c! ( c c_addr -- ) core c_store
1423 :	anton	1.52	""Store @i{c} into the char at @i{c-addr}.""
1424 :	anton	1.1	*c_addr = c;
1425 :			:
1426 :			[ bigendian [IF] ]
1427 :			[ cell>bit 4 = [IF] ]
1428 :			tuck 1 and IF $FF and ELSE 8<< THEN >r
1429 :			dup -2 and @ over 1 and cells masks + @ and
1430 :			r> or swap -2 and ! ;
1431 :			Create masks $00FF , $FF00 ,
1432 :			[ELSE] ]
1433 :			dup [ cell 1- ] literal and dup
1434 :			[ cell 1- ] literal xor >r
1435 :			- dup @ $FF r@ 0 ?DO 8<< LOOP invert and
1436 :			rot $FF and r> 0 ?DO 8<< LOOP or swap ! ;
1437 :			[THEN]
1438 :			[ELSE] ]
1439 :			[ cell>bit 4 = [IF] ]
1440 :			tuck 1 and IF 8<< ELSE $FF and THEN >r
1441 :			dup -2 and @ over 1 and cells masks + @ and
1442 :			r> or swap -2 and ! ;
1443 :			Create masks $FF00 , $00FF ,
1444 :			[ELSE] ]
1445 :			dup [ cell 1- ] literal and dup >r
1446 :			- dup @ $FF r@ 0 ?DO 8<< LOOP invert and
1447 :			rot $FF and r> 0 ?DO 8<< LOOP or swap ! ;
1448 :			[THEN]
1449 :			[THEN]
1450 :			: 8<< 2* 2* 2* 2* 2* 2* 2* 2* ;
1451 :
1452 :	anton	1.47	2! ( w1 w2 a_addr -- ) core two_store
1453 :	anton	1.52	""Store @i{w2} into the cell at @i{c-addr} and @i{w1} into the next cell.""
1454 :	anton	1.1	a_addr[0] = w2;
1455 :			a_addr[1] = w1;
1456 :			:
1457 :			tuck ! cell+ ! ;
1458 :
1459 :	anton	1.47	2@ ( a_addr -- w1 w2 ) core two_fetch
1460 :	anton	1.52	""@i{w2} is the content of the cell stored at @i{a-addr}, @i{w1} is
1461 :			the content of the next cell.""
1462 :	anton	1.1	w2 = a_addr[0];
1463 :			w1 = a_addr[1];
1464 :			:
1465 :			dup cell+ @ swap @ ;
1466 :
1467 :	anton	1.47	cell+ ( a_addr1 -- a_addr2 ) core cell_plus
1468 :	anton	1.52	""@code{1 cells +}""
1469 :	anton	1.1	a_addr2 = a_addr1+1;
1470 :			:
1471 :			cell + ;
1472 :
1473 :	anton	1.47	cells ( n1 -- n2 ) core
1474 :	anton	1.52	"" @i{n2} is the number of address units of @i{n1} cells.""
1475 :	anton	1.1	n2 = n1 * sizeof(Cell);
1476 :			:
1477 :			[ cell
1478 :			2/ dup [IF] ] 2* [ [THEN]
1479 :			2/ dup [IF] ] 2* [ [THEN]
1480 :			2/ dup [IF] ] 2* [ [THEN]
1481 :			2/ dup [IF] ] 2* [ [THEN]
1482 :			drop ] ;
1483 :
1484 :	anton	1.47	char+ ( c_addr1 -- c_addr2 ) core char_plus
1485 :	anton	1.52	""@code{1 chars +}.""
1486 :	anton	1.1	c_addr2 = c_addr1 + 1;
1487 :			:
1488 :			1+ ;
1489 :
1490 :	anton	1.47	(chars) ( n1 -- n2 ) gforth paren_chars
1491 :	anton	1.1	n2 = n1 * sizeof(Char);
1492 :			:
1493 :			;
1494 :
1495 :	anton	1.47	count ( c_addr1 -- c_addr2 u ) core
1496 :	anton	1.56	""@i{c-addr2} is the first character and @i{u} the length of the
1497 :			counted string at @i{c-addr1}.""
1498 :	anton	1.1	u = *c_addr1;
1499 :			c_addr2 = c_addr1+1;
1500 :			:
1501 :			dup 1+ swap c@ ;
1502 :
1503 :	pazsan	1.110	\g compiler
1504 :
1505 :	pazsan	1.138	\+f83headerstring
1506 :
1507 :			(f83find) ( c_addr u f83name1 -- f83name2 ) new paren_f83find
1508 :			for (; f83name1 != NULL; f83name1 = (struct F83Name *)(f83name1->next))
1509 :			if ((UCell)F83NAME_COUNT(f83name1)==u &&
1510 :			memcasecmp(c_addr, f83name1->name, u)== 0 /* or inline? */)
1511 :			break;
1512 :			f83name2=f83name1;
1513 :	pazsan	1.210	#ifdef DEBUG
1514 :			fprintf(stderr, "F83find ");
1515 :			fwrite(c_addr, u, 1, stderr);
1516 :			fprintf(stderr, " found %08x\n", f83name2);
1517 :			#endif
1518 :	pazsan	1.138	:
1519 :			BEGIN dup WHILE (find-samelen) dup WHILE
1520 :			>r 2dup r@ cell+ char+ capscomp 0=
1521 :			IF 2drop r> EXIT THEN
1522 :			r> @
1523 :			REPEAT THEN nip nip ;
1524 :			: (find-samelen) ( u f83name1 -- u f83name2/0 )
1525 :			BEGIN 2dup cell+ c@ $1F and <> WHILE @ dup 0= UNTIL THEN ;
1526 :			: capscomp ( c_addr1 u c_addr2 -- n )
1527 :			swap bounds
1528 :			?DO dup c@ I c@ <>
1529 :			IF dup c@ toupper I c@ toupper =
1530 :			ELSE true THEN WHILE 1+ LOOP drop 0
1531 :			ELSE c@ toupper I c@ toupper - unloop THEN sgn ;
1532 :			: sgn ( n -- -1/0/1 )
1533 :			dup 0= IF EXIT THEN 0< 2* 1+ ;
1534 :
1535 :			\-
1536 :
1537 :	pazsan	1.112	(listlfind) ( c_addr u longname1 -- longname2 ) new paren_listlfind
1538 :	anton	1.125	longname2=listlfind(c_addr, u, longname1);
1539 :	anton	1.1	:
1540 :	pazsan	1.112	BEGIN dup WHILE (findl-samelen) dup WHILE
1541 :			>r 2dup r@ cell+ cell+ capscomp 0=
1542 :	anton	1.1	IF 2drop r> EXIT THEN
1543 :			r> @
1544 :			REPEAT THEN nip nip ;
1545 :	pazsan	1.112	: (findl-samelen) ( u longname1 -- u longname2/0 )
1546 :			BEGIN 2dup cell+ @ lcount-mask and <> WHILE @ dup 0= UNTIL THEN ;
1547 :	pazsan	1.144	: capscomp ( c_addr1 u c_addr2 -- n )
1548 :			swap bounds
1549 :			?DO dup c@ I c@ <>
1550 :			IF dup c@ toupper I c@ toupper =
1551 :			ELSE true THEN WHILE 1+ LOOP drop 0
1552 :			ELSE c@ toupper I c@ toupper - unloop THEN sgn ;
1553 :			: sgn ( n -- -1/0/1 )
1554 :			dup 0= IF EXIT THEN 0< 2* 1+ ;
1555 :	anton	1.1
1556 :	pazsan	1.15	\+hash
1557 :	anton	1.1
1558 :	pazsan	1.112	(hashlfind) ( c_addr u a_addr -- longname2 ) new paren_hashlfind
1559 :	anton	1.125	longname2 = hashlfind(c_addr, u, a_addr);
1560 :	anton	1.1	:
1561 :			BEGIN dup WHILE
1562 :	pazsan	1.112	2@ >r >r dup r@ cell+ @ lcount-mask and =
1563 :			IF 2dup r@ cell+ cell+ capscomp 0=
1564 :	anton	1.1	IF 2drop r> rdrop EXIT THEN THEN
1565 :			rdrop r>
1566 :			REPEAT nip nip ;
1567 :
1568 :	pazsan	1.112	(tablelfind) ( c_addr u a_addr -- longname2 ) new paren_tablelfind
1569 :	anton	1.1	""A case-sensitive variant of @code{(hashfind)}""
1570 :	anton	1.125	longname2 = tablelfind(c_addr, u, a_addr);
1571 :	anton	1.1	:
1572 :			BEGIN dup WHILE
1573 :	pazsan	1.112	2@ >r >r dup r@ cell+ @ lcount-mask and =
1574 :			IF 2dup r@ cell+ cell+ -text 0=
1575 :	anton	1.1	IF 2drop r> rdrop EXIT THEN THEN
1576 :			rdrop r>
1577 :			REPEAT nip nip ;
1578 :	pazsan	1.138	: -text ( c_addr1 u c_addr2 -- n )
1579 :			swap bounds
1580 :			?DO dup c@ I c@ = WHILE 1+ LOOP drop 0
1581 :			ELSE c@ I c@ - unloop THEN sgn ;
1582 :			: sgn ( n -- -1/0/1 )
1583 :			dup 0= IF EXIT THEN 0< 2* 1+ ;
1584 :	anton	1.1
1585 :	anton	1.47	(hashkey1) ( c_addr u ubits -- ukey ) gforth paren_hashkey1
1586 :	anton	1.1	""ukey is the hash key for the string c_addr u fitting in ubits bits""
1587 :	anton	1.125	ukey = hashkey1(c_addr, u, ubits);
1588 :	anton	1.1	:
1589 :			dup rot-values + c@ over 1 swap lshift 1- >r
1590 :			tuck - 2swap r> 0 2swap bounds
1591 :			?DO dup 4 pick lshift swap 3 pick rshift or
1592 :			I c@ toupper xor
1593 :			over and LOOP
1594 :			nip nip nip ;
1595 :			Create rot-values
1596 :			5 c, 0 c, 1 c, 2 c, 3 c, 4 c, 5 c, 5 c, 5 c, 5 c,
1597 :			3 c, 5 c, 5 c, 5 c, 5 c, 7 c, 5 c, 5 c, 5 c, 5 c,
1598 :			7 c, 5 c, 5 c, 5 c, 5 c, 6 c, 5 c, 5 c, 5 c, 5 c,
1599 :			7 c, 5 c, 5 c,
1600 :	pazsan	1.138
1601 :			\+
1602 :	anton	1.1
1603 :	pazsan	1.15	\+
1604 :	anton	1.1
1605 :	anton	1.47	(parse-white) ( c_addr1 u1 -- c_addr2 u2 ) gforth paren_parse_white
1606 :	anton	1.125	struct Cellpair r=parse_white(c_addr1, u1);
1607 :			c_addr2 = (Char *)(r.n1);
1608 :			u2 = r.n2;
1609 :	anton	1.1	:
1610 :			BEGIN dup WHILE over c@ bl <= WHILE 1 /string
1611 :			REPEAT THEN 2dup
1612 :			BEGIN dup WHILE over c@ bl > WHILE 1 /string
1613 :			REPEAT THEN nip - ;
1614 :
1615 :	anton	1.47	aligned ( c_addr -- a_addr ) core
1616 :	crook	1.29	"" @i{a-addr} is the first aligned address greater than or equal to @i{c-addr}.""
1617 :	anton	1.1	a_addr = (Cell *)((((Cell)c_addr)+(sizeof(Cell)-1))&(-sizeof(Cell)));
1618 :			:
1619 :			[ cell 1- ] Literal + [ -1 cells ] Literal and ;
1620 :
1621 :	anton	1.47	faligned ( c_addr -- f_addr ) float f_aligned
1622 :	crook	1.29	"" @i{f-addr} is the first float-aligned address greater than or equal to @i{c-addr}.""
1623 :	anton	1.1	f_addr = (Float *)((((Cell)c_addr)+(sizeof(Float)-1))&(-sizeof(Float)));
1624 :			:
1625 :			[ 1 floats 1- ] Literal + [ -1 floats ] Literal and ;
1626 :
1627 :	jwilke	1.35	\ threading stuff is currently only interesting if we have a compiler
1628 :			\fhas? standardthreading has? compiler and [IF]
1629 :	anton	1.47	threading-method ( -- n ) gforth threading_method
1630 :	anton	1.1	""0 if the engine is direct threaded. Note that this may change during
1631 :			the lifetime of an image.""
1632 :			#if defined(DOUBLY_INDIRECT)
1633 :			n=2;
1634 :			#else
1635 :			# if defined(DIRECT_THREADED)
1636 :			n=0;
1637 :			# else
1638 :			n=1;
1639 :			# endif
1640 :			#endif
1641 :			:
1642 :			1 ;
1643 :	jwilke	1.28
1644 :	jwilke	1.35	\f[THEN]
1645 :	anton	1.1
1646 :	pazsan	1.83	\g hostos
1647 :
1648 :	anton	1.192	key-file ( wfileid -- c ) gforth paren_key_file
1649 :	anton	1.193	""Read one character @i{c} from @i{wfileid}. This word disables
1650 :			buffering for @i{wfileid}. If you want to read characters from a
1651 :			terminal in non-canonical (raw) mode, you have to put the terminal in
1652 :			non-canonical mode yourself (using the C interface); the exception is
1653 :			@code{stdin}: Gforth automatically puts it into non-canonical mode.""
1654 :	pazsan	1.17	#ifdef HAS_FILE
1655 :	anton	1.1	fflush(stdout);
1656 :	anton	1.192	c = key((FILE*)wfileid);
1657 :	pazsan	1.17	#else
1658 :	anton	1.192	c = key(stdin);
1659 :	pazsan	1.17	#endif
1660 :	anton	1.1
1661 :	anton	1.192	key?-file ( wfileid -- f ) gforth key_q_file
1662 :			""@i{f} is true if at least one character can be read from @i{wfileid}
1663 :	anton	1.193	without blocking. If you also want to use @code{read-file} or
1664 :			@code{read-line} on the file, you have to call @code{key?-file} or
1665 :			@code{key-file} first (these two words disable buffering).""
1666 :	pazsan	1.17	#ifdef HAS_FILE
1667 :	anton	1.1	fflush(stdout);
1668 :	anton	1.192	f = key_query((FILE*)wfileid);
1669 :	pazsan	1.17	#else
1670 :	anton	1.192	f = key_query(stdin);
1671 :	pazsan	1.17	#endif
1672 :
1673 :	anton	1.47	stdin ( -- wfileid ) gforth
1674 :	anton	1.193	""The standard input file of the Gforth process.""
1675 :	pazsan	1.12	wfileid = (Cell)stdin;
1676 :	anton	1.1
1677 :	anton	1.47	stdout ( -- wfileid ) gforth
1678 :	anton	1.193	""The standard output file of the Gforth process.""
1679 :	anton	1.1	wfileid = (Cell)stdout;
1680 :
1681 :	anton	1.47	stderr ( -- wfileid ) gforth
1682 :	anton	1.193	""The standard error output file of the Gforth process.""
1683 :	anton	1.1	wfileid = (Cell)stderr;
1684 :
1685 :	pazsan	1.208	\+os
1686 :
1687 :	anton	1.47	form ( -- urows ucols ) gforth
1688 :	anton	1.209	""The number of lines and columns in the terminal. These numbers may
1689 :			change with the window size. Note that it depends on the OS whether
1690 :			this reflects the actual size and changes with the window size
1691 :			(currently only on Unix-like OSs). On other OSs you just get a
1692 :			default, and can tell Gforth the terminal size by setting the
1693 :			environment variables @code{COLUMNS} and @code{LINES} before starting
1694 :			Gforth.""
1695 :	anton	1.1	/* we could block SIGWINCH here to get a consistent size, but I don't
1696 :			think this is necessary or always beneficial */
1697 :			urows=rows;
1698 :			ucols=cols;
1699 :
1700 :	pazsan	1.189	wcwidth ( u -- n ) gforth
1701 :			""The number of fixed-width characters per unicode character u""
1702 :	anton	1.238	#ifdef HAVE_WCWIDTH
1703 :	pazsan	1.189	n = wcwidth(u);
1704 :	anton	1.238	#else
1705 :			n = 1;
1706 :			#endif
1707 :	pazsan	1.189
1708 :	anton	1.47	flush-icache ( c_addr u -- ) gforth flush_icache
1709 :	anton	1.1	""Make sure that the instruction cache of the processor (if there is
1710 :	crook	1.29	one) does not contain stale data at @i{c-addr} and @i{u} bytes
1711 :	anton	1.1	afterwards. @code{END-CODE} performs a @code{flush-icache}
1712 :			automatically. Caveat: @code{flush-icache} might not work on your
1713 :			installation; this is usually the case if direct threading is not
1714 :			supported on your machine (take a look at your @file{machine.h}) and
1715 :			your machine has a separate instruction cache. In such cases,
1716 :			@code{flush-icache} does nothing instead of flushing the instruction
1717 :			cache.""
1718 :	anton	1.233	FLUSH_ICACHE((caddr_t)c_addr,u);
1719 :	anton	1.1
1720 :	anton	1.47	(bye) ( n -- ) gforth paren_bye
1721 :	anton	1.77	SUPER_END;
1722 :	anton	1.1	return (Label *)n;
1723 :
1724 :	anton	1.125	(system) ( c_addr u -- wretval wior ) gforth paren_system
1725 :	anton	1.155	wretval = gforth_system(c_addr, u);
1726 :	anton	1.1	wior = IOR(wretval==-1 \|\| (wretval==127 && errno != 0));
1727 :
1728 :	anton	1.47	getenv ( c_addr1 u1 -- c_addr2 u2 ) gforth
1729 :	crook	1.29	""The string @i{c-addr1 u1} specifies an environment variable. The string @i{c-addr2 u2}
1730 :	crook	1.24	is the host operating system's expansion of that environment variable. If the
1731 :	crook	1.29	environment variable does not exist, @i{c-addr2 u2} specifies a string 0 characters
1732 :	crook	1.24	in length.""
1733 :	pazsan	1.46	/* close ' to keep fontify happy */
1734 :	pazsan	1.190	c_addr2 = (Char *)getenv(cstr(c_addr1,u1,1));
1735 :			u2 = (c_addr2 == NULL ? 0 : strlen((char *)c_addr2));
1736 :	anton	1.1
1737 :	anton	1.56	open-pipe ( c_addr u wfam -- wfileid wior ) gforth open_pipe
1738 :	anton	1.239	fflush(stdout);
1739 :	pazsan	1.84	wfileid=(Cell)popen(cstr(c_addr,u,1),pfileattr[wfam]); /* ~ expansion of 1st arg? */
1740 :	anton	1.1	wior = IOR(wfileid==0); /* !! the man page says that errno is not set reliably */
1741 :
1742 :	anton	1.47	close-pipe ( wfileid -- wretval wior ) gforth close_pipe
1743 :	anton	1.1	wretval = pclose((FILE *)wfileid);
1744 :			wior = IOR(wretval==-1);
1745 :
1746 :	anton	1.47	time&date ( -- nsec nmin nhour nday nmonth nyear ) facility-ext time_and_date
1747 :	crook	1.44	""Report the current time of day. Seconds, minutes and hours are numbered from 0.
1748 :			Months are numbered from 1.""
1749 :	anton	1.127	#if 1
1750 :			time_t now;
1751 :			struct tm *ltime;
1752 :			time(&now);
1753 :			ltime=localtime(&now);
1754 :			#else
1755 :	anton	1.1	struct timeval time1;
1756 :			struct timezone zone1;
1757 :			struct tm *ltime;
1758 :			gettimeofday(&time1,&zone1);
1759 :	anton	1.51	/* !! Single Unix specification:
1760 :			If tzp is not a null pointer, the behaviour is unspecified. */
1761 :	anton	1.1	ltime=localtime((time_t *)&time1.tv_sec);
1762 :	anton	1.127	#endif
1763 :	anton	1.1	nyear =ltime->tm_year+1900;
1764 :			nmonth=ltime->tm_mon+1;
1765 :			nday =ltime->tm_mday;
1766 :			nhour =ltime->tm_hour;
1767 :			nmin =ltime->tm_min;
1768 :			nsec =ltime->tm_sec;
1769 :
1770 :	anton	1.212	ms ( u -- ) facility-ext
1771 :	crook	1.44	""Wait at least @i{n} milli-second.""
1772 :	anton	1.212	gforth_ms(u);
1773 :	anton	1.1
1774 :	anton	1.47	allocate ( u -- a_addr wior ) memory
1775 :	crook	1.29	""Allocate @i{u} address units of contiguous data space. The initial
1776 :	crook	1.27	contents of the data space is undefined. If the allocation is successful,
1777 :	crook	1.29	@i{a-addr} is the start address of the allocated region and @i{wior}
1778 :			is 0. If the allocation fails, @i{a-addr} is undefined and @i{wior}
1779 :	anton	1.52	is a non-zero I/O result code.""
1780 :	anton	1.1	a_addr = (Cell *)malloc(u?u:1);
1781 :			wior = IOR(a_addr==NULL);
1782 :
1783 :	anton	1.47	free ( a_addr -- wior ) memory
1784 :	crook	1.29	""Return the region of data space starting at @i{a-addr} to the system.
1785 :	anton	1.52	The region must originally have been obtained using @code{allocate} or
1786 :	crook	1.29	@code{resize}. If the operational is successful, @i{wior} is 0.
1787 :	anton	1.52	If the operation fails, @i{wior} is a non-zero I/O result code.""
1788 :	anton	1.1	free(a_addr);
1789 :			wior = 0;
1790 :
1791 :	anton	1.47	resize ( a_addr1 u -- a_addr2 wior ) memory
1792 :	crook	1.26	""Change the size of the allocated area at @i{a-addr1} to @i{u}
1793 :	anton	1.1	address units, possibly moving the contents to a different
1794 :	crook	1.27	area. @i{a-addr2} is the address of the resulting area.
1795 :	anton	1.52	If the operation is successful, @i{wior} is 0.
1796 :			If the operation fails, @i{wior} is a non-zero
1797 :	crook	1.29	I/O result code. If @i{a-addr1} is 0, Gforth's (but not the Standard)
1798 :	crook	1.27	@code{resize} @code{allocate}s @i{u} address units.""
1799 :	anton	1.1	/* the following check is not necessary on most OSs, but it is needed
1800 :			on SunOS 4.1.2. */
1801 :	pazsan	1.46	/* close ' to keep fontify happy */
1802 :	anton	1.1	if (a_addr1==NULL)
1803 :			a_addr2 = (Cell *)malloc(u);
1804 :			else
1805 :			a_addr2 = (Cell *)realloc(a_addr1, u);
1806 :			wior = IOR(a_addr2==NULL); /* !! Define a return code */
1807 :	anton	1.258	if (a_addr2==NULL)
1808 :			a_addr2 = a_addr1;
1809 :	anton	1.1
1810 :	anton	1.47	strerror ( n -- c_addr u ) gforth
1811 :	pazsan	1.190	c_addr = (Char *)strerror(n);
1812 :			u = strlen((char *)c_addr);
1813 :	anton	1.1
1814 :	anton	1.47	strsignal ( n -- c_addr u ) gforth
1815 :	pazsan	1.190	c_addr = (Char *)strsignal(n);
1816 :			u = strlen((char *)c_addr);
1817 :	anton	1.1
1818 :	anton	1.172	call-c ( ... w -- ... ) gforth call_c
1819 :	anton	1.1	""Call the C function pointed to by @i{w}. The C function has to
1820 :			access the stack itself. The stack pointers are exported in the global
1821 :	anton	1.213	variables @code{gforth_SP} and @code{gforth_FP}.""
1822 :	anton	1.1	/* This is a first attempt at support for calls to C. This may change in
1823 :			the future */
1824 :	pazsan	1.231	IF_fpTOS(fp[0]=fpTOS);
1825 :	pazsan	1.185	gforth_FP=fp;
1826 :			gforth_SP=sp;
1827 :	pazsan	1.231	gforth_RP=rp;
1828 :			gforth_LP=lp;
1829 :	pazsan	1.235	#ifdef HAS_LINKBACK
1830 :	anton	1.1	((void (*)())w)();
1831 :	pazsan	1.235	#else
1832 :			((void ()(void ))w)(gforth_pointers);
1833 :			#endif
1834 :	pazsan	1.185	sp=gforth_SP;
1835 :			fp=gforth_FP;
1836 :	pazsan	1.231	rp=gforth_RP;
1837 :			lp=gforth_LP;
1838 :			IF_fpTOS(fpTOS=fp[0]);
1839 :	anton	1.1
1840 :	pazsan	1.15	\+
1841 :			\+file
1842 :	anton	1.1
1843 :	anton	1.47	close-file ( wfileid -- wior ) file close_file
1844 :	anton	1.1	wior = IOR(fclose((FILE *)wfileid)==EOF);
1845 :
1846 :	anton	1.56	open-file ( c_addr u wfam -- wfileid wior ) file open_file
1847 :	anton	1.217	wfileid = opencreate_file(tilde_cstr(c_addr,u,1), wfam, 0, &wior);
1848 :	anton	1.1
1849 :	anton	1.56	create-file ( c_addr u wfam -- wfileid wior ) file create_file
1850 :	anton	1.217	wfileid = opencreate_file(tilde_cstr(c_addr,u,1), wfam, O_CREAT\|O_TRUNC, &wior);
1851 :	anton	1.1
1852 :	anton	1.47	delete-file ( c_addr u -- wior ) file delete_file
1853 :	anton	1.1	wior = IOR(unlink(tilde_cstr(c_addr, u, 1))==-1);
1854 :
1855 :	anton	1.47	rename-file ( c_addr1 u1 c_addr2 u2 -- wior ) file-ext rename_file
1856 :	crook	1.29	""Rename file @i{c_addr1 u1} to new name @i{c_addr2 u2}""
1857 :	anton	1.125	wior = rename_file(c_addr1, u1, c_addr2, u2);
1858 :	anton	1.1
1859 :	anton	1.47	file-position ( wfileid -- ud wior ) file file_position
1860 :	anton	1.1	/* !! use tell and lseek? */
1861 :	anton	1.108	ud = OFF2UD(ftello((FILE *)wfileid));
1862 :			wior = IOR(UD2OFF(ud)==-1);
1863 :	anton	1.1
1864 :	anton	1.47	reposition-file ( ud wfileid -- wior ) file reposition_file
1865 :	anton	1.108	wior = IOR(fseeko((FILE *)wfileid, UD2OFF(ud), SEEK_SET)==-1);
1866 :	anton	1.1
1867 :	anton	1.47	file-size ( wfileid -- ud wior ) file file_size
1868 :	anton	1.1	struct stat buf;
1869 :			wior = IOR(fstat(fileno((FILE *)wfileid), &buf)==-1);
1870 :	anton	1.108	ud = OFF2UD(buf.st_size);
1871 :	anton	1.1
1872 :	anton	1.47	resize-file ( ud wfileid -- wior ) file resize_file
1873 :	anton	1.108	wior = IOR(ftruncate(fileno((FILE *)wfileid), UD2OFF(ud))==-1);
1874 :	anton	1.1
1875 :	anton	1.47	read-file ( c_addr u1 wfileid -- u2 wior ) file read_file
1876 :	anton	1.1	/* !! fread does not guarantee enough */
1877 :			u2 = fread(c_addr, sizeof(Char), u1, (FILE *)wfileid);
1878 :	anton	1.243	if (u2>0)
1879 :			gf_regetc((FILE *)wfileid);
1880 :	anton	1.1	wior = FILEIO(u2<u1 && ferror((FILE *)wfileid));
1881 :			/* !! is the value of ferror errno-compatible? */
1882 :			if (wior)
1883 :			clearerr((FILE *)wfileid);
1884 :
1885 :	anton	1.125	(read-line) ( c_addr u1 wfileid -- u2 flag u3 wior ) file paren_read_line
1886 :	anton	1.243	struct Cellquad r = read_line(c_addr, u1, (FILE *)wfileid);
1887 :	anton	1.125	u2 = r.n1;
1888 :			flag = r.n2;
1889 :			u3 = r.n3;
1890 :			wior = r.n4;
1891 :	anton	1.1
1892 :	pazsan	1.15	\+
1893 :	anton	1.1
1894 :	anton	1.47	write-file ( c_addr u1 wfileid -- wior ) file write_file
1895 :	anton	1.1	/* !! fwrite does not guarantee enough */
1896 :	pazsan	1.39	#ifdef HAS_FILE
1897 :	anton	1.1	{
1898 :			UCell u2 = fwrite(c_addr, sizeof(Char), u1, (FILE *)wfileid);
1899 :			wior = FILEIO(u2<u1 && ferror((FILE *)wfileid));
1900 :			if (wior)
1901 :			clearerr((FILE *)wfileid);
1902 :			}
1903 :	pazsan	1.39	#else
1904 :			TYPE(c_addr, u1);
1905 :			#endif
1906 :	pazsan	1.17
1907 :	anton	1.47	emit-file ( c wfileid -- wior ) gforth emit_file
1908 :	pazsan	1.17	#ifdef HAS_FILE
1909 :	anton	1.1	wior = FILEIO(putc(c, (FILE *)wfileid)==EOF);
1910 :			if (wior)
1911 :			clearerr((FILE *)wfileid);
1912 :	pazsan	1.17	#else
1913 :	pazsan	1.36	PUTC(c);
1914 :	pazsan	1.17	#endif
1915 :	anton	1.1
1916 :	pazsan	1.15	\+file
1917 :	anton	1.1
1918 :	anton	1.47	flush-file ( wfileid -- wior ) file-ext flush_file
1919 :	anton	1.1	wior = IOR(fflush((FILE *) wfileid)==EOF);
1920 :
1921 :	anton	1.56	file-status ( c_addr u -- wfam wior ) file-ext file_status
1922 :	anton	1.125	struct Cellpair r = file_status(c_addr, u);
1923 :			wfam = r.n1;
1924 :			wior = r.n2;
1925 :	anton	1.1
1926 :	pazsan	1.112	file-eof? ( wfileid -- flag ) gforth file_eof_query
1927 :			flag = FLAG(feof((FILE *) wfileid));
1928 :	anton	1.1
1929 :	pazsan	1.112	open-dir ( c_addr u -- wdirid wior ) gforth open_dir
1930 :			""Open the directory specified by @i{c-addr, u}
1931 :			and return @i{dir-id} for futher access to it.""
1932 :			wdirid = (Cell)opendir(tilde_cstr(c_addr, u, 1));
1933 :			wior = IOR(wdirid == 0);
1934 :
1935 :			read-dir ( c_addr u1 wdirid -- u2 flag wior ) gforth read_dir
1936 :			""Attempt to read the next entry from the directory specified
1937 :			by @i{dir-id} to the buffer of length @i{u1} at address @i{c-addr}.
1938 :			If the attempt fails because there is no more entries,
1939 :			@i{ior}=0, @i{flag}=0, @i{u2}=0, and the buffer is unmodified.
1940 :			If the attempt to read the next entry fails because of any other reason,
1941 :			return @i{ior}<>0.
1942 :			If the attempt succeeds, store file name to the buffer at @i{c-addr}
1943 :			and return @i{ior}=0, @i{flag}=true and @i{u2} equal to the size of the file name.
1944 :			If the length of the file name is greater than @i{u1},
1945 :			store first @i{u1} characters from file name into the buffer and
1946 :			indicate "name too long" with @i{ior}, @i{flag}=true, and @i{u2}=@i{u1}.""
1947 :			struct dirent * dent;
1948 :			dent = readdir((DIR *)wdirid);
1949 :			wior = 0;
1950 :			flag = -1;
1951 :			if(dent == NULL) {
1952 :			u2 = 0;
1953 :			flag = 0;
1954 :			} else {
1955 :	pazsan	1.190	u2 = strlen((char *)dent->d_name);
1956 :	pazsan	1.112	if(u2 > u1) {
1957 :			u2 = u1;
1958 :			wior = -512-ENAMETOOLONG;
1959 :			}
1960 :			memmove(c_addr, dent->d_name, u2);
1961 :			}
1962 :
1963 :			close-dir ( wdirid -- wior ) gforth close_dir
1964 :			""Close the directory specified by @i{dir-id}.""
1965 :			wior = IOR(closedir((DIR *)wdirid));
1966 :
1967 :			filename-match ( c_addr1 u1 c_addr2 u2 -- flag ) gforth match_file
1968 :			char * string = cstr(c_addr1, u1, 1);
1969 :			char * pattern = cstr(c_addr2, u2, 0);
1970 :			flag = FLAG(!fnmatch(pattern, string, 0));
1971 :
1972 :	pazsan	1.157	set-dir ( c_addr u -- wior ) gforth set_dir
1973 :			""Change the current directory to @i{c-addr, u}.
1974 :			Return an error if this is not possible""
1975 :			wior = IOR(chdir(tilde_cstr(c_addr, u, 1)));
1976 :
1977 :			get-dir ( c_addr1 u1 -- c_addr2 u2 ) gforth get_dir
1978 :	anton	1.236	""Store the current directory in the buffer specified by @i{c-addr1, u1}.
1979 :	pazsan	1.157	If the buffer size is not sufficient, return 0 0""
1980 :	pazsan	1.190	c_addr2 = (Char )getcwd((char )c_addr1, u1);
1981 :	pazsan	1.157	if(c_addr2 != NULL) {
1982 :	pazsan	1.190	u2 = strlen((char *)c_addr2);
1983 :	pazsan	1.157	} else {
1984 :			u2 = 0;
1985 :			}
1986 :
1987 :	anton	1.236	=mkdir ( c_addr u wmode -- wior ) gforth equals_mkdir
1988 :			""Create directory @i{c-addr u} with mode @i{wmode}.""
1989 :			wior = IOR(mkdir(tilde_cstr(c_addr,u,1),wmode));
1990 :
1991 :	pazsan	1.112	\+
1992 :
1993 :			newline ( -- c_addr u ) gforth
1994 :			""String containing the newline sequence of the host OS""
1995 :			char newline[] = {
1996 :	anton	1.115	#if DIRSEP=='/'
1997 :			/* Unix */
1998 :	pazsan	1.112	'\n'
1999 :			#else
2000 :	anton	1.115	/* DOS, Win, OS/2 */
2001 :	pazsan	1.112	'\r','\n'
2002 :			#endif
2003 :			};
2004 :	pazsan	1.190	c_addr=(Char *)newline;
2005 :	pazsan	1.112	u=sizeof(newline);
2006 :			:
2007 :			"newline count ;
2008 :			Create "newline e? crlf [IF] 2 c, $0D c, [ELSE] 1 c, [THEN] $0A c,
2009 :
2010 :			\+os
2011 :
2012 :			utime ( -- dtime ) gforth
2013 :			""Report the current time in microseconds since some epoch.""
2014 :			struct timeval time1;
2015 :			gettimeofday(&time1,NULL);
2016 :			dtime = timeval2us(&time1);
2017 :
2018 :			cputime ( -- duser dsystem ) gforth
2019 :			""duser and dsystem are the respective user- and system-level CPU
2020 :			times used since the start of the Forth system (excluding child
2021 :			processes), in microseconds (the granularity may be much larger,
2022 :			however). On platforms without the getrusage call, it reports elapsed
2023 :			time (since some epoch) for duser and 0 for dsystem.""
2024 :			#ifdef HAVE_GETRUSAGE
2025 :			struct rusage usage;
2026 :			getrusage(RUSAGE_SELF, &usage);
2027 :			duser = timeval2us(&usage.ru_utime);
2028 :			dsystem = timeval2us(&usage.ru_stime);
2029 :			#else
2030 :			struct timeval time1;
2031 :			gettimeofday(&time1,NULL);
2032 :			duser = timeval2us(&time1);
2033 :	pazsan	1.158	dsystem = DZERO;
2034 :	pazsan	1.112	#endif
2035 :
2036 :	pazsan	1.259	ntime ( -- dtime ) gforth
2037 :			""Report the current time in nanoseconds since some epoch.""
2038 :			struct timespec t;
2039 :			clock_gettime(CLOCK_REALTIME,&t);
2040 :			dtime = timespec2ns(&t);
2041 :
2042 :	pazsan	1.112	\+
2043 :
2044 :			\+floating
2045 :
2046 :			\g floating
2047 :	pazsan	1.83
2048 :	anton	1.1	comparisons(f, r1 r2, f_, r1, r2, gforth, gforth, float, gforth)
2049 :			comparisons(f0, r, f_zero_, r, 0., float, gforth, float, gforth)
2050 :
2051 :	pazsan	1.177	s>f ( n -- r ) float s_to_f
2052 :			r = n;
2053 :
2054 :	anton	1.47	d>f ( d -- r ) float d_to_f
2055 :	pazsan	1.158	#ifdef BUGGY_LL_D2F
2056 :	anton	1.1	extern double ldexp(double x, int exp);
2057 :	pazsan	1.158	if (DHI(d)<0) {
2058 :			#ifdef BUGGY_LL_ADD
2059 :	anton	1.113	DCell d2=dnegate(d);
2060 :	pazsan	1.158	#else
2061 :			DCell d2=-d;
2062 :			#endif
2063 :			r = -(ldexp((Float)DHI(d2),CELL_BITS) + (Float)DLO(d2));
2064 :	anton	1.113	} else
2065 :	pazsan	1.158	r = ldexp((Float)DHI(d),CELL_BITS) + (Float)DLO(d);
2066 :	anton	1.1	#else
2067 :			r = d;
2068 :			#endif
2069 :
2070 :	anton	1.47	f>d ( r -- d ) float f_to_d
2071 :	pazsan	1.100	extern DCell double2ll(Float r);
2072 :			d = double2ll(r);
2073 :	anton	1.1
2074 :	pazsan	1.177	f>s ( r -- n ) float f_to_s
2075 :			n = (Cell)r;
2076 :
2077 :	anton	1.47	f! ( r f_addr -- ) float f_store
2078 :	anton	1.52	""Store @i{r} into the float at address @i{f-addr}.""
2079 :	anton	1.1	*f_addr = r;
2080 :
2081 :	anton	1.47	f@ ( f_addr -- r ) float f_fetch
2082 :	anton	1.52	""@i{r} is the float at address @i{f-addr}.""
2083 :	anton	1.1	r = *f_addr;
2084 :
2085 :	anton	1.47	df@ ( df_addr -- r ) float-ext d_f_fetch
2086 :	anton	1.52	""Fetch the double-precision IEEE floating-point value @i{r} from the address @i{df-addr}.""
2087 :	anton	1.1	#ifdef IEEE_FP
2088 :			r = *df_addr;
2089 :			#else
2090 :			!! df@
2091 :			#endif
2092 :
2093 :	anton	1.47	df! ( r df_addr -- ) float-ext d_f_store
2094 :	anton	1.52	""Store @i{r} as double-precision IEEE floating-point value to the
2095 :			address @i{df-addr}.""
2096 :	anton	1.1	#ifdef IEEE_FP
2097 :			*df_addr = r;
2098 :			#else
2099 :			!! df!
2100 :			#endif
2101 :
2102 :	anton	1.47	sf@ ( sf_addr -- r ) float-ext s_f_fetch
2103 :	anton	1.52	""Fetch the single-precision IEEE floating-point value @i{r} from the address @i{sf-addr}.""
2104 :	anton	1.1	#ifdef IEEE_FP
2105 :			r = *sf_addr;
2106 :			#else
2107 :			!! sf@
2108 :			#endif
2109 :
2110 :	anton	1.47	sf! ( r sf_addr -- ) float-ext s_f_store
2111 :	anton	1.52	""Store @i{r} as single-precision IEEE floating-point value to the
2112 :			address @i{sf-addr}.""
2113 :	anton	1.1	#ifdef IEEE_FP
2114 :			*sf_addr = r;
2115 :			#else
2116 :			!! sf!
2117 :			#endif
2118 :
2119 :	anton	1.47	f+ ( r1 r2 -- r3 ) float f_plus
2120 :	anton	1.1	r3 = r1+r2;
2121 :
2122 :	anton	1.47	f- ( r1 r2 -- r3 ) float f_minus
2123 :	anton	1.1	r3 = r1-r2;
2124 :
2125 :	anton	1.47	f* ( r1 r2 -- r3 ) float f_star
2126 :	anton	1.1	r3 = r1*r2;
2127 :
2128 :	anton	1.47	f/ ( r1 r2 -- r3 ) float f_slash
2129 :	anton	1.1	r3 = r1/r2;
2130 :
2131 :	anton	1.47	f** ( r1 r2 -- r3 ) float-ext f_star_star
2132 :	crook	1.26	""@i{r3} is @i{r1} raised to the @i{r2}th power.""
2133 :	anton	1.1	r3 = pow(r1,r2);
2134 :	pazsan	1.177
2135 :			fm* ( r1 n -- r2 ) gforth fm_star
2136 :			r2 = r1*n;
2137 :
2138 :			fm/ ( r1 n -- r2 ) gforth fm_slash
2139 :			r2 = r1/n;
2140 :
2141 :			fm*/ ( r1 n1 n2 -- r2 ) gforth fm_star_slash
2142 :			r2 = (r1*n1)/n2;
2143 :
2144 :			f**2 ( r1 -- r2 ) gforth fm_square
2145 :			r2 = r1*r1;
2146 :	anton	1.1
2147 :	anton	1.47	fnegate ( r1 -- r2 ) float f_negate
2148 :	anton	1.1	r2 = - r1;
2149 :
2150 :	anton	1.47	fdrop ( r -- ) float f_drop
2151 :	anton	1.1
2152 :	anton	1.47	fdup ( r -- r r ) float f_dupe
2153 :	anton	1.1
2154 :	anton	1.47	fswap ( r1 r2 -- r2 r1 ) float f_swap
2155 :	anton	1.1
2156 :	anton	1.47	fover ( r1 r2 -- r1 r2 r1 ) float f_over
2157 :	anton	1.1
2158 :	anton	1.47	frot ( r1 r2 r3 -- r2 r3 r1 ) float f_rote
2159 :	anton	1.1
2160 :	anton	1.47	fnip ( r1 r2 -- r2 ) gforth f_nip
2161 :	anton	1.1
2162 :	anton	1.47	ftuck ( r1 r2 -- r2 r1 r2 ) gforth f_tuck
2163 :	anton	1.1
2164 :	anton	1.47	float+ ( f_addr1 -- f_addr2 ) float float_plus
2165 :	anton	1.52	""@code{1 floats +}.""
2166 :	anton	1.1	f_addr2 = f_addr1+1;
2167 :
2168 :	anton	1.47	floats ( n1 -- n2 ) float
2169 :	anton	1.52	""@i{n2} is the number of address units of @i{n1} floats.""
2170 :	anton	1.1	n2 = n1*sizeof(Float);
2171 :
2172 :	anton	1.47	floor ( r1 -- r2 ) float
2173 :	crook	1.26	""Round towards the next smaller integral value, i.e., round toward negative infinity.""
2174 :	anton	1.1	/* !! unclear wording */
2175 :			r2 = floor(r1);
2176 :
2177 :	anton	1.216	fround ( r1 -- r2 ) float f_round
2178 :	anton	1.105	""Round to the nearest integral value.""
2179 :	anton	1.1	r2 = rint(r1);
2180 :
2181 :	anton	1.47	fmax ( r1 r2 -- r3 ) float f_max
2182 :	anton	1.1	if (r1<r2)
2183 :			r3 = r2;
2184 :			else
2185 :			r3 = r1;
2186 :
2187 :	anton	1.47	fmin ( r1 r2 -- r3 ) float f_min
2188 :	anton	1.1	if (r1<r2)
2189 :			r3 = r1;
2190 :			else
2191 :			r3 = r2;
2192 :
2193 :	anton	1.47	represent ( r c_addr u -- n f1 f2 ) float
2194 :	anton	1.1	char *sig;
2195 :	anton	1.122	size_t siglen;
2196 :	anton	1.1	int flag;
2197 :			int decpt;
2198 :			sig=ecvt(r, u, &decpt, &flag);
2199 :	anton	1.122	n=(r==0. ? 1 : decpt);
2200 :	anton	1.242	flag=signbit(r); /* not all ecvt()s do this as desired */
2201 :	anton	1.1	f1=FLAG(flag!=0);
2202 :	anton	1.21	f2=FLAG(isdigit((unsigned)(sig[0]))!=0);
2203 :	pazsan	1.190	siglen=strlen((char *)sig);
2204 :	anton	1.124	if (siglen>u) /* happens in glibc-2.1.3 if 999.. is rounded up */
2205 :			siglen=u;
2206 :	anton	1.170	if (!f2) /* workaround Cygwin trailing 0s for Inf and Nan */
2207 :			for (; sig[siglen-1]=='0'; siglen--);
2208 :			;
2209 :	anton	1.122	memcpy(c_addr,sig,siglen);
2210 :	anton	1.123	memset(c_addr+siglen,f2?'0':' ',u-siglen);
2211 :	anton	1.1
2212 :	anton	1.172	>float ( c_addr u -- f:... flag ) float to_float
2213 :	anton	1.56	""Actual stack effect: ( c_addr u -- r t \| f ). Attempt to convert the
2214 :			character string @i{c-addr u} to internal floating-point
2215 :			representation. If the string represents a valid floating-point number
2216 :			@i{r} is placed on the floating-point stack and @i{flag} is
2217 :			true. Otherwise, @i{flag} is false. A string of blanks is a special
2218 :			case and represents the floating-point number 0.""
2219 :	anton	1.1	Float r;
2220 :	anton	1.125	flag = to_float(c_addr, u, &r);
2221 :			if (flag) {
2222 :	anton	1.172	fp--;
2223 :			fp[0]=r;
2224 :	anton	1.1	}
2225 :
2226 :	anton	1.47	fabs ( r1 -- r2 ) float-ext f_abs
2227 :	anton	1.1	r2 = fabs(r1);
2228 :
2229 :	anton	1.47	facos ( r1 -- r2 ) float-ext f_a_cos
2230 :	anton	1.1	r2 = acos(r1);
2231 :
2232 :	anton	1.47	fasin ( r1 -- r2 ) float-ext f_a_sine
2233 :	anton	1.1	r2 = asin(r1);
2234 :
2235 :	anton	1.47	fatan ( r1 -- r2 ) float-ext f_a_tan
2236 :	anton	1.1	r2 = atan(r1);
2237 :
2238 :	anton	1.47	fatan2 ( r1 r2 -- r3 ) float-ext f_a_tan_two
2239 :	crook	1.26	""@i{r1/r2}=tan(@i{r3}). ANS Forth does not require, but probably
2240 :	anton	1.1	intends this to be the inverse of @code{fsincos}. In gforth it is.""
2241 :			r3 = atan2(r1,r2);
2242 :
2243 :	anton	1.47	fcos ( r1 -- r2 ) float-ext f_cos
2244 :	anton	1.1	r2 = cos(r1);
2245 :
2246 :	anton	1.47	fexp ( r1 -- r2 ) float-ext f_e_x_p
2247 :	anton	1.1	r2 = exp(r1);
2248 :
2249 :	anton	1.47	fexpm1 ( r1 -- r2 ) float-ext f_e_x_p_m_one
2250 :	anton	1.1	""@i{r2}=@i{e}**@i{r1}@minus{}1""
2251 :			#ifdef HAVE_EXPM1
2252 :	pazsan	1.3	extern double
2253 :			#ifdef NeXT
2254 :			const
2255 :			#endif
2256 :			expm1(double);
2257 :	anton	1.1	r2 = expm1(r1);
2258 :			#else
2259 :			r2 = exp(r1)-1.;
2260 :			#endif
2261 :
2262 :	anton	1.47	fln ( r1 -- r2 ) float-ext f_l_n
2263 :	anton	1.1	r2 = log(r1);
2264 :
2265 :	anton	1.47	flnp1 ( r1 -- r2 ) float-ext f_l_n_p_one
2266 :	anton	1.1	""@i{r2}=ln(@i{r1}+1)""
2267 :			#ifdef HAVE_LOG1P
2268 :	pazsan	1.3	extern double
2269 :			#ifdef NeXT
2270 :			const
2271 :			#endif
2272 :			log1p(double);
2273 :	anton	1.1	r2 = log1p(r1);
2274 :			#else
2275 :			r2 = log(r1+1.);
2276 :			#endif
2277 :
2278 :	anton	1.47	flog ( r1 -- r2 ) float-ext f_log
2279 :	crook	1.26	""The decimal logarithm.""
2280 :	anton	1.1	r2 = log10(r1);
2281 :
2282 :	anton	1.47	falog ( r1 -- r2 ) float-ext f_a_log
2283 :	anton	1.1	""@i{r2}=10**@i{r1}""
2284 :			extern double pow10(double);
2285 :			r2 = pow10(r1);
2286 :
2287 :	anton	1.47	fsin ( r1 -- r2 ) float-ext f_sine
2288 :	anton	1.1	r2 = sin(r1);
2289 :
2290 :	anton	1.47	fsincos ( r1 -- r2 r3 ) float-ext f_sine_cos
2291 :	anton	1.1	""@i{r2}=sin(@i{r1}), @i{r3}=cos(@i{r1})""
2292 :			r2 = sin(r1);
2293 :			r3 = cos(r1);
2294 :
2295 :	anton	1.47	fsqrt ( r1 -- r2 ) float-ext f_square_root
2296 :	anton	1.1	r2 = sqrt(r1);
2297 :
2298 :	anton	1.47	ftan ( r1 -- r2 ) float-ext f_tan
2299 :	anton	1.1	r2 = tan(r1);
2300 :			:
2301 :			fsincos f/ ;
2302 :
2303 :	anton	1.47	fsinh ( r1 -- r2 ) float-ext f_cinch
2304 :	anton	1.1	r2 = sinh(r1);
2305 :			:
2306 :			fexpm1 fdup fdup 1. d>f f+ f/ f+ f2/ ;
2307 :
2308 :	anton	1.47	fcosh ( r1 -- r2 ) float-ext f_cosh
2309 :	anton	1.1	r2 = cosh(r1);
2310 :			:
2311 :			fexp fdup 1/f f+ f2/ ;
2312 :
2313 :	anton	1.47	ftanh ( r1 -- r2 ) float-ext f_tan_h
2314 :	anton	1.1	r2 = tanh(r1);
2315 :			:
2316 :			f2* fexpm1 fdup 2. d>f f+ f/ ;
2317 :
2318 :	anton	1.47	fasinh ( r1 -- r2 ) float-ext f_a_cinch
2319 :	anton	1.1	r2 = asinh(r1);
2320 :			:
2321 :			fdup fdup f* 1. d>f f+ fsqrt f/ fatanh ;
2322 :
2323 :	anton	1.47	facosh ( r1 -- r2 ) float-ext f_a_cosh
2324 :	anton	1.1	r2 = acosh(r1);
2325 :			:
2326 :			fdup fdup f* 1. d>f f- fsqrt f+ fln ;
2327 :
2328 :	anton	1.47	fatanh ( r1 -- r2 ) float-ext f_a_tan_h
2329 :	anton	1.1	r2 = atanh(r1);
2330 :			:
2331 :			fdup f0< >r fabs 1. d>f fover f- f/ f2* flnp1 f2/
2332 :			r> IF fnegate THEN ;
2333 :
2334 :	anton	1.47	sfloats ( n1 -- n2 ) float-ext s_floats
2335 :	anton	1.52	""@i{n2} is the number of address units of @i{n1}
2336 :	crook	1.29	single-precision IEEE floating-point numbers.""
2337 :	anton	1.1	n2 = n1*sizeof(SFloat);
2338 :
2339 :	anton	1.47	dfloats ( n1 -- n2 ) float-ext d_floats
2340 :	anton	1.52	""@i{n2} is the number of address units of @i{n1}
2341 :	crook	1.29	double-precision IEEE floating-point numbers.""
2342 :	anton	1.1	n2 = n1*sizeof(DFloat);
2343 :
2344 :	anton	1.47	sfaligned ( c_addr -- sf_addr ) float-ext s_f_aligned
2345 :	anton	1.52	""@i{sf-addr} is the first single-float-aligned address greater
2346 :	crook	1.29	than or equal to @i{c-addr}.""
2347 :	anton	1.1	sf_addr = (SFloat *)((((Cell)c_addr)+(sizeof(SFloat)-1))&(-sizeof(SFloat)));
2348 :			:
2349 :			[ 1 sfloats 1- ] Literal + [ -1 sfloats ] Literal and ;
2350 :
2351 :	anton	1.47	dfaligned ( c_addr -- df_addr ) float-ext d_f_aligned
2352 :	anton	1.52	""@i{df-addr} is the first double-float-aligned address greater
2353 :	crook	1.29	than or equal to @i{c-addr}.""
2354 :	anton	1.1	df_addr = (DFloat *)((((Cell)c_addr)+(sizeof(DFloat)-1))&(-sizeof(DFloat)));
2355 :			:
2356 :			[ 1 dfloats 1- ] Literal + [ -1 dfloats ] Literal and ;
2357 :
2358 :	pazsan	1.112	v* ( f_addr1 nstride1 f_addr2 nstride2 ucount -- r ) gforth v_star
2359 :			""dot-product: r=v1*v2. The first element of v1 is at f_addr1, the
2360 :			next at f_addr1+nstride1 and so on (similar for v2). Both vectors have
2361 :			ucount elements.""
2362 :	anton	1.125	r = v_star(f_addr1, nstride1, f_addr2, nstride2, ucount);
2363 :	pazsan	1.112	:
2364 :			>r swap 2swap swap 0e r> 0 ?DO
2365 :			dup f@ over + 2swap dup f@ f* f+ over + 2swap
2366 :			LOOP 2drop 2drop ;
2367 :
2368 :			faxpy ( ra f_x nstridex f_y nstridey ucount -- ) gforth
2369 :			""vy=ra*vx+vy""
2370 :	anton	1.125	faxpy(ra, f_x, nstridex, f_y, nstridey, ucount);
2371 :	pazsan	1.112	:
2372 :			>r swap 2swap swap r> 0 ?DO
2373 :			fdup dup f@ f* over + 2swap dup f@ f+ dup f! over + 2swap
2374 :			LOOP 2drop 2drop fdrop ;
2375 :
2376 :			\+
2377 :
2378 :	anton	1.1	\ The following words access machine/OS/installation-dependent
2379 :			\ Gforth internals
2380 :			\ !! how about environmental queries DIRECT-THREADED,
2381 :			\ INDIRECT-THREADED, TOS-CACHED, FTOS-CACHED, CODEFIELD-DOES */
2382 :
2383 :			\ local variable implementation primitives
2384 :	pazsan	1.112
2385 :	pazsan	1.15	\+glocals
2386 :	anton	1.1
2387 :	pazsan	1.110	\g locals
2388 :
2389 :	anton	1.68	@local# ( #noffset -- w ) gforth fetch_local_number
2390 :			w = (Cell )(lp+noffset);
2391 :	anton	1.1
2392 :	anton	1.47	@local0 ( -- w ) new fetch_local_zero
2393 :	pazsan	1.112	w = ((Cell *)lp)[0];
2394 :	anton	1.1
2395 :	anton	1.47	@local1 ( -- w ) new fetch_local_four
2396 :	pazsan	1.112	w = ((Cell *)lp)[1];
2397 :	anton	1.1
2398 :	anton	1.47	@local2 ( -- w ) new fetch_local_eight
2399 :	pazsan	1.112	w = ((Cell *)lp)[2];
2400 :	anton	1.1
2401 :	anton	1.47	@local3 ( -- w ) new fetch_local_twelve
2402 :	pazsan	1.112	w = ((Cell *)lp)[3];
2403 :	anton	1.1
2404 :	pazsan	1.15	\+floating
2405 :	anton	1.1
2406 :	anton	1.68	f@local# ( #noffset -- r ) gforth f_fetch_local_number
2407 :			r = (Float )(lp+noffset);
2408 :	anton	1.1
2409 :	anton	1.47	f@local0 ( -- r ) new f_fetch_local_zero
2410 :	pazsan	1.112	r = ((Float *)lp)[0];
2411 :	anton	1.1
2412 :	anton	1.47	f@local1 ( -- r ) new f_fetch_local_eight
2413 :	pazsan	1.112	r = ((Float *)lp)[1];
2414 :	anton	1.1
2415 :	pazsan	1.15	\+
2416 :	anton	1.1
2417 :	anton	1.68	laddr# ( #noffset -- c_addr ) gforth laddr_number
2418 :	anton	1.1	/* this can also be used to implement lp@ */
2419 :	anton	1.68	c_addr = (Char *)(lp+noffset);
2420 :	anton	1.1
2421 :	anton	1.68	lp+!# ( #noffset -- ) gforth lp_plus_store_number
2422 :	anton	1.1	""used with negative immediate values it allocates memory on the
2423 :			local stack, a positive immediate argument drops memory from the local
2424 :			stack""
2425 :	anton	1.68	lp += noffset;
2426 :	anton	1.1
2427 :	anton	1.47	lp- ( -- ) new minus_four_lp_plus_store
2428 :	anton	1.1	lp += -sizeof(Cell);
2429 :
2430 :	anton	1.47	lp+ ( -- ) new eight_lp_plus_store
2431 :	anton	1.1	lp += sizeof(Float);
2432 :
2433 :	anton	1.47	lp+2 ( -- ) new sixteen_lp_plus_store
2434 :	anton	1.1	lp += 2*sizeof(Float);
2435 :
2436 :	anton	1.47	lp! ( c_addr -- ) gforth lp_store
2437 :	anton	1.1	lp = (Address)c_addr;
2438 :
2439 :	anton	1.47	>l ( w -- ) gforth to_l
2440 :	anton	1.1	lp -= sizeof(Cell);
2441 :			(Cell )lp = w;
2442 :
2443 :	pazsan	1.15	\+floating
2444 :	anton	1.1
2445 :	anton	1.47	f>l ( r -- ) gforth f_to_l
2446 :	anton	1.1	lp -= sizeof(Float);
2447 :			(Float )lp = r;
2448 :
2449 :	anton	1.172	fpick ( f:... u -- f:... r ) gforth
2450 :	anton	1.52	""Actually the stack effect is @code{ r0 ... ru u -- r0 ... ru r0 }.""
2451 :	anton	1.172	r = fp[u];
2452 :	anton	1.11	:
2453 :			floats fp@ + f@ ;
2454 :
2455 :	pazsan	1.15	\+
2456 :			\+
2457 :	anton	1.1
2458 :	pazsan	1.15	\+OS
2459 :	anton	1.1
2460 :	pazsan	1.110	\g syslib
2461 :
2462 :	pazsan	1.131	open-lib ( c_addr1 u1 -- u2 ) gforth open_lib
2463 :	pazsan	1.237	u2 = gforth_dlopen(c_addr1, u1);
2464 :	pazsan	1.131
2465 :			lib-sym ( c_addr1 u1 u2 -- u3 ) gforth lib_sym
2466 :	anton	1.234	#ifdef HAVE_LIBLTDL
2467 :	anton	1.220	u3 = (UCell) lt_dlsym((lt_dlhandle)u2, cstr(c_addr1, u1, 1));
2468 :			#elif defined(HAVE_LIBDL) \|\| defined(HAVE_DLOPEN)
2469 :	pazsan	1.131	u3 = (UCell) dlsym((void*)u2,cstr(c_addr1, u1, 1));
2470 :			#else
2471 :			# ifdef _WIN32
2472 :			u3 = (Cell) GetProcAddress((HMODULE)u2, cstr(c_addr1, u1, 1));
2473 :			# else
2474 :			#warning Define lib-sym!
2475 :			u3 = 0;
2476 :			# endif
2477 :			#endif
2478 :
2479 :	anton	1.172	wcall ( ... u -- ... ) gforth
2480 :	pazsan	1.185	gforth_FP=fp;
2481 :			sp=(Cell)(SYSCALL(Cell()(Cell , void *))u)(sp, &gforth_FP);
2482 :			fp=gforth_FP;
2483 :	pazsan	1.142
2484 :	anton	1.186	uw@ ( c_addr -- u ) gforth u_w_fetch
2485 :			""@i{u} is the zero-extended 16-bit value stored at @i{c_addr}.""
2486 :			u = (UWyde)(c_addr);
2487 :	pazsan	1.180
2488 :	anton	1.186	sw@ ( c_addr -- n ) gforth s_w_fetch
2489 :			""@i{n} is the sign-extended 16-bit value stored at @i{c_addr}.""
2490 :			n = (Wyde)(c_addr);
2491 :	pazsan	1.180
2492 :	anton	1.186	w! ( w c_addr -- ) gforth w_store
2493 :			""Store the bottom 16 bits of @i{w} at @i{c_addr}.""
2494 :			(Wyde)(c_addr) = w;
2495 :	pazsan	1.180
2496 :	anton	1.186	ul@ ( c_addr -- u ) gforth u_l_fetch
2497 :			""@i{u} is the zero-extended 32-bit value stored at @i{c_addr}.""
2498 :			u = (UTetrabyte)(c_addr);
2499 :	pazsan	1.181
2500 :	anton	1.186	sl@ ( c_addr -- n ) gforth s_l_fetch
2501 :			""@i{n} is the sign-extended 32-bit value stored at @i{c_addr}.""
2502 :			n = (Tetrabyte)(c_addr);
2503 :	pazsan	1.181
2504 :	anton	1.186	l! ( w c_addr -- ) gforth l_store
2505 :			""Store the bottom 32 bits of @i{w} at @i{c_addr}.""
2506 :			(Tetrabyte)(c_addr) = w;
2507 :	pazsan	1.180
2508 :	anton	1.220	lib-error ( -- c_addr u ) gforth lib_error
2509 :	anton	1.228	""Error message for last failed @code{open-lib} or @code{lib-sym}.""
2510 :	anton	1.234	#ifdef HAVE_LIBLTDL
2511 :	anton	1.232	c_addr = (Char *)lt_dlerror();
2512 :			u = (c_addr == NULL) ? 0 : strlen((char *)c_addr);
2513 :	pazsan	1.244	#elif defined(HAVE_LIBDL) \|\| defined(HAVE_DLOPEN)
2514 :			c_addr = dlerror();
2515 :			u = strlen(c_addr);
2516 :	anton	1.234	#else
2517 :			c_addr = "libltdl is not configured";
2518 :			u = strlen(c_addr);
2519 :			#endif
2520 :	anton	1.220
2521 :	pazsan	1.252	be-w! ( w c_addr -- ) gforth w_store_be
2522 :			""Store the bottom 16 bits of @i{w} at @i{c_addr} in big endian format.""
2523 :			c_addr[0] = w >> 8;
2524 :			c_addr[1] = w;
2525 :
2526 :			be-l! ( w c_addr -- ) gforth l_store_be
2527 :			""Store the bottom 32 bits of @i{w} at @i{c_addr} in big endian format.""
2528 :			c_addr[0] = w >> 24;
2529 :			c_addr[1] = w >> 16;
2530 :			c_addr[2] = w >> 8;
2531 :			c_addr[3] = w;
2532 :
2533 :			le-w! ( w c_addr -- ) gforth w_store_le
2534 :			""Store the bottom 16 bits of @i{w} at @i{c_addr} in big endian format.""
2535 :			c_addr[1] = w >> 8;
2536 :			c_addr[0] = w;
2537 :
2538 :			le-l! ( w c_addr -- ) gforth l_store_le
2539 :			""Store the bottom 32 bits of @i{w} at @i{c_addr} in big endian format.""
2540 :			c_addr[3] = w >> 24;
2541 :			c_addr[2] = w >> 16;
2542 :			c_addr[1] = w >> 8;
2543 :			c_addr[0] = w;
2544 :
2545 :	anton	1.254	be-uw@ ( c_addr -- u ) gforth w_fetch_be
2546 :			""@i{u} is the zero-extended 16-bit big endian value stored at @i{c_addr}.""
2547 :			u = (c_addr[0] << 8) \| (c_addr[1]);
2548 :
2549 :			be-ul@ ( c_addr -- u ) gforth l_fetch_be
2550 :			""@i{u} is the zero-extended 32-bit big endian value stored at @i{c_addr}.""
2551 :			u = (c_addr[0] << 24) \| (c_addr[1] << 16) \| (c_addr[2] << 8) \| (c_addr[3]);
2552 :
2553 :			le-uw@ ( c_addr -- u ) gforth w_fetch_le
2554 :			""@i{u} is the zero-extended 16-bit little endian value stored at @i{c_addr}.""
2555 :			u = (c_addr[1] << 8) \| (c_addr[0]);
2556 :
2557 :			le-ul@ ( c_addr -- u ) gforth l_fetch_le
2558 :			""@i{u} is the zero-extended 32-bit little endian value stored at @i{c_addr}.""
2559 :			u = (c_addr[3] << 24) \| (c_addr[2] << 16) \| (c_addr[1] << 8) \| (c_addr[0]);
2560 :
2561 :			\+64bit
2562 :
2563 :			x! ( w c_addr -- ) gforth x_store
2564 :			""Store the bottom 64 bits of @i{w} at 64-bit-aligned @i{c_addr}.""
2565 :			(UOctabyte )c_addr = w;
2566 :
2567 :			ux@ ( c_addr -- u ) gforth u_x_fetch
2568 :			""@i{u} is the zero-extended 64-bit value stored at 64-bit-aligned @i{c_addr}.""
2569 :			u = (UOctabyte )c_addr;
2570 :
2571 :			sx@ ( c_addr -- n ) gforth s_x_fetch
2572 :			""@i{u} is the sign-extended 64-bit value stored at 64-bit-aligned @i{c_addr}.""
2573 :			n = (Octabyte )c_addr;
2574 :
2575 :			be-x! ( w c_addr -- ) gforth b_e_x_store
2576 :			""Store the bottom 64 bits of @i{w} at @i{c_addr} in big endian format.""
2577 :			c_addr[0] = w >> 56;
2578 :			c_addr[1] = w >> 48;
2579 :			c_addr[2] = w >> 40;
2580 :			c_addr[3] = w >> 32;
2581 :			c_addr[4] = w >> 24;
2582 :			c_addr[5] = w >> 16;
2583 :			c_addr[6] = w >> 8;
2584 :			c_addr[7] = w;
2585 :
2586 :			le-x! ( w c_addr -- ) gforth l_e_x_store
2587 :	pazsan	1.252	""Store the bottom 64 bits of @i{w} at @i{c_addr} in big endian format.""
2588 :			c_addr[7] = w >> 56;
2589 :			c_addr[6] = w >> 48;
2590 :			c_addr[5] = w >> 40;
2591 :			c_addr[4] = w >> 32;
2592 :			c_addr[3] = w >> 24;
2593 :			c_addr[2] = w >> 16;
2594 :			c_addr[1] = w >> 8;
2595 :			c_addr[0] = w;
2596 :
2597 :	anton	1.254	be-ux@ ( c_addr -- u ) gforth b_e_u_x_fetch
2598 :	pazsan	1.252	""@i{u} is the zero-extended 64-bit big endian value stored at @i{c_addr}.""
2599 :			u = (((Cell)(c_addr[0]) << 56) \|
2600 :			((Cell)(c_addr[1]) << 48) \|
2601 :			((Cell)(c_addr[2]) << 40) \|
2602 :			((Cell)(c_addr[3]) << 32) \|
2603 :			((Cell)(c_addr[4]) << 24) \|
2604 :			((Cell)(c_addr[5]) << 16) \|
2605 :			((Cell)(c_addr[6]) << 8) \|
2606 :			((Cell)(c_addr[7])));
2607 :
2608 :	anton	1.254	le-ux@ ( c_addr -- u ) gforth l_e_u_x_fetch
2609 :	pazsan	1.252	""@i{u} is the zero-extended 64-bit little endian value stored at @i{c_addr}.""
2610 :			u = (((Cell)(c_addr[7]) << 56) \|
2611 :			((Cell)(c_addr[6]) << 48) \|
2612 :			((Cell)(c_addr[5]) << 40) \|
2613 :			((Cell)(c_addr[4]) << 32) \|
2614 :			((Cell)(c_addr[3]) << 24) \|
2615 :			((Cell)(c_addr[2]) << 16) \|
2616 :			((Cell)(c_addr[1]) << 8) \|
2617 :			((Cell)(c_addr[0])));
2618 :	pazsan	1.250
2619 :	pazsan	1.224	\+
2620 :	anton	1.254	\+
2621 :	pazsan	1.142	\g peephole
2622 :	pazsan	1.46
2623 :	pazsan	1.112	\+peephole
2624 :
2625 :	anton	1.119	compile-prim1 ( a_prim -- ) gforth compile_prim1
2626 :			""compile prim (incl. immargs) at @var{a_prim}""
2627 :			compile_prim1(a_prim);
2628 :
2629 :	anton	1.172	finish-code ( ... -- ... ) gforth finish_code
2630 :	anton	1.119	""Perform delayed steps in code generation (branch resolution, I-cache
2631 :			flushing).""
2632 :	anton	1.172	/* The ... above are a workaround for a bug in gcc-2.95, which fails
2633 :			to save spTOS (gforth-fast --enable-force-reg) */
2634 :	anton	1.119	finish_code();
2635 :
2636 :			forget-dyncode ( c_code -- f ) gforth-internal forget_dyncode
2637 :			f = forget_dyncode(c_code);
2638 :
2639 :			decompile-prim ( a_code -- a_prim ) gforth-internal decompile_prim
2640 :			""a_prim is the code address of the primitive that has been
2641 :			compile_prim1ed to a_code""
2642 :	anton	1.121	a_prim = (Cell *)decompile_code((Label)a_code);
2643 :	anton	1.119
2644 :	pazsan	1.112	\ set-next-code and call2 do not appear in images and can be
2645 :			\ renumbered arbitrarily
2646 :	pazsan	1.46
2647 :	pazsan	1.112	set-next-code ( #w -- ) gforth set_next_code
2648 :			#ifdef NO_IP
2649 :			next_code = (Label)w;
2650 :			#endif
2651 :	jwilke	1.34
2652 :	pazsan	1.112	call2 ( #a_callee #a_ret_addr -- R:a_ret_addr ) gforth
2653 :			/* call with explicit return address */
2654 :			#ifdef NO_IP
2655 :			INST_TAIL;
2656 :			JUMP(a_callee);
2657 :	anton	1.45	#else
2658 :	pazsan	1.112	assert(0);
2659 :	anton	1.45	#endif
2660 :	pazsan	1.131
2661 :			tag-offsets ( -- a_addr ) gforth tag_offsets
2662 :			extern Cell groups[32];
2663 :			a_addr = groups;
2664 :	anton	1.51
2665 :	pazsan	1.54	\+
2666 :	anton	1.128
2667 :	anton	1.248	\g primitive_centric
2668 :
2669 :			\ primitives for primitive-centric code
2670 :			\ another one is does-exec
2671 :
2672 :			abi-call ( #a_callee ... -- ... ) gforth-internal abi_call
2673 :			/* primitive for compiled ABI-CODE words */
2674 :			abifunc f = (abifunc )a_callee;
2675 :			Float *fp_mem = fp;
2676 :			sp = (*f)(sp, &fp_mem);
2677 :			fp = fp_mem;
2678 :
2679 :			;abi-code-exec ( #a_cfa ... -- ... ) gforth-internal semi_abi_code_exec
2680 :			/* primitive for performing ;ABI-CODE words */
2681 :			Float *fp_mem = fp;
2682 :			semiabifunc f = (semiabifunc )DOES_CODE1(a_cfa);
2683 :			Address body = (Address)PFA(a_cfa);
2684 :			sp = (*f)(sp, &fp_mem, body);
2685 :			fp = fp_mem;
2686 :
2687 :	anton	1.249	lit-execute ( #a_addr -- ) new lit_execute
2688 :			/* for ;code and code words; a static superinstruction would be more general,
2689 :			but VM_JUMP is currently not supported there */
2690 :			#ifndef NO_IP
2691 :			ip=IP;
2692 :			#endif
2693 :	anton	1.248	SUPER_END;
2694 :	anton	1.249	VM_JUMP(EXEC1((Xt)a_addr));
2695 :	anton	1.248
2696 :
2697 :	anton	1.128	\g static_super
2698 :
2699 :	anton	1.173	ifdef(`STACK_CACHE_FILE',
2700 :	anton	1.147	`include(peeprules.vmg)')
2701 :	pazsan	1.54
2702 :	pazsan	1.112	\g end

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