xref: /freebsd/stand/ficl/words.c (revision 6829dae12bb055451fa467da4589c43bd03b1e64)
1 /*******************************************************************
2 ** w o r d s . c
3 ** Forth Inspired Command Language
4 ** ANS Forth CORE word-set written in C
5 ** Author: John Sadler (john_sadler@alum.mit.edu)
6 ** Created: 19 July 1997
7 ** $Id: words.c,v 1.17 2001/12/05 07:21:34 jsadler Exp $
8 *******************************************************************/
9 /*
10 ** Copyright (c) 1997-2001 John Sadler (john_sadler@alum.mit.edu)
11 ** All rights reserved.
12 **
13 ** Get the latest Ficl release at http://ficl.sourceforge.net
14 **
15 ** I am interested in hearing from anyone who uses ficl. If you have
16 ** a problem, a success story, a defect, an enhancement request, or
17 ** if you would like to contribute to the ficl release, please
18 ** contact me by email at the address above.
19 **
20 ** L I C E N S E  and  D I S C L A I M E R
21 **
22 ** Redistribution and use in source and binary forms, with or without
23 ** modification, are permitted provided that the following conditions
24 ** are met:
25 ** 1. Redistributions of source code must retain the above copyright
26 **    notice, this list of conditions and the following disclaimer.
27 ** 2. Redistributions in binary form must reproduce the above copyright
28 **    notice, this list of conditions and the following disclaimer in the
29 **    documentation and/or other materials provided with the distribution.
30 **
31 ** THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
32 ** ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
33 ** IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
34 ** ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
35 ** FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
36 ** DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
37 ** OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
38 ** HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
39 ** LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
40 ** OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
41 ** SUCH DAMAGE.
42 */
43 
44 /* $FreeBSD$ */
45 
46 #ifdef TESTMAIN
47 #include <stdlib.h>
48 #include <stdio.h>
49 #include <ctype.h>
50 #include <fcntl.h>
51 #else
52 #include <stand.h>
53 #endif
54 #include <string.h>
55 #include "ficl.h"
56 #include "math64.h"
57 
58 static void colonParen(FICL_VM *pVM);
59 static void literalIm(FICL_VM *pVM);
60 static int  ficlParseWord(FICL_VM *pVM, STRINGINFO si);
61 
62 /*
63 ** Control structure building words use these
64 ** strings' addresses as markers on the stack to
65 ** check for structure completion.
66 */
67 static char doTag[]    = "do";
68 static char colonTag[] = "colon";
69 static char leaveTag[] = "leave";
70 
71 static char destTag[]  = "target";
72 static char origTag[]  = "origin";
73 
74 static char caseTag[]  = "case";
75 static char ofTag[]  = "of";
76 static char fallthroughTag[]  = "fallthrough";
77 
78 #if FICL_WANT_LOCALS
79 static void doLocalIm(FICL_VM *pVM);
80 static void do2LocalIm(FICL_VM *pVM);
81 #endif
82 
83 
84 /*
85 ** C O N T R O L   S T R U C T U R E   B U I L D E R S
86 **
87 ** Push current dict location for later branch resolution.
88 ** The location may be either a branch target or a patch address...
89 */
90 static void markBranch(FICL_DICT *dp, FICL_VM *pVM, char *tag)
91 {
92     PUSHPTR(dp->here);
93     PUSHPTR(tag);
94     return;
95 }
96 
97 static void markControlTag(FICL_VM *pVM, char *tag)
98 {
99     PUSHPTR(tag);
100     return;
101 }
102 
103 static void matchControlTag(FICL_VM *pVM, char *tag)
104 {
105     char *cp;
106 #if FICL_ROBUST > 1
107     vmCheckStack(pVM, 1, 0);
108 #endif
109     cp = (char *)stackPopPtr(pVM->pStack);
110     /*
111     ** Changed the code below to compare the pointers first (by popular demand)
112     */
113     if ( (cp != tag) && strcmp(cp, tag) )
114     {
115         vmThrowErr(pVM, "Error -- unmatched control structure \"%s\"", tag);
116     }
117 
118     return;
119 }
120 
121 /*
122 ** Expect a branch target address on the param stack,
123 ** compile a literal offset from the current dict location
124 ** to the target address
125 */
126 static void resolveBackBranch(FICL_DICT *dp, FICL_VM *pVM, char *tag)
127 {
128     FICL_INT offset;
129     CELL *patchAddr;
130 
131     matchControlTag(pVM, tag);
132 
133 #if FICL_ROBUST > 1
134     vmCheckStack(pVM, 1, 0);
135 #endif
136     patchAddr = (CELL *)stackPopPtr(pVM->pStack);
137     offset = patchAddr - dp->here;
138     dictAppendCell(dp, LVALUEtoCELL(offset));
139 
140     return;
141 }
142 
143 
144 /*
145 ** Expect a branch patch address on the param stack,
146 ** compile a literal offset from the patch location
147 ** to the current dict location
148 */
149 static void resolveForwardBranch(FICL_DICT *dp, FICL_VM *pVM, char *tag)
150 {
151     FICL_INT offset;
152     CELL *patchAddr;
153 
154     matchControlTag(pVM, tag);
155 
156 #if FICL_ROBUST > 1
157     vmCheckStack(pVM, 1, 0);
158 #endif
159     patchAddr = (CELL *)stackPopPtr(pVM->pStack);
160     offset = dp->here - patchAddr;
161     *patchAddr = LVALUEtoCELL(offset);
162 
163     return;
164 }
165 
166 /*
167 ** Match the tag to the top of the stack. If success,
168 ** sopy "here" address into the cell whose address is next
169 ** on the stack. Used by do..leave..loop.
170 */
171 static void resolveAbsBranch(FICL_DICT *dp, FICL_VM *pVM, char *tag)
172 {
173     CELL *patchAddr;
174     char *cp;
175 
176 #if FICL_ROBUST > 1
177     vmCheckStack(pVM, 2, 0);
178 #endif
179     cp = stackPopPtr(pVM->pStack);
180     /*
181     ** Changed the comparison below to compare the pointers first (by popular demand)
182     */
183     if ((cp != tag) && strcmp(cp, tag))
184     {
185         vmTextOut(pVM, "Warning -- Unmatched control word: ", 0);
186         vmTextOut(pVM, tag, 1);
187     }
188 
189     patchAddr = (CELL *)stackPopPtr(pVM->pStack);
190     *patchAddr = LVALUEtoCELL(dp->here);
191 
192     return;
193 }
194 
195 
196 /**************************************************************************
197                         f i c l P a r s e N u m b e r
198 ** Attempts to convert the NULL terminated string in the VM's pad to
199 ** a number using the VM's current base. If successful, pushes the number
200 ** onto the param stack and returns TRUE. Otherwise, returns FALSE.
201 ** (jws 8/01) Trailing decimal point causes a zero cell to be pushed. (See
202 ** the standard for DOUBLE wordset.
203 **************************************************************************/
204 
205 int ficlParseNumber(FICL_VM *pVM, STRINGINFO si)
206 {
207     FICL_INT accum  = 0;
208     char isNeg      = FALSE;
209 	char hasDP      = FALSE;
210     unsigned base   = pVM->base;
211     char *cp        = SI_PTR(si);
212     FICL_COUNT count= (FICL_COUNT)SI_COUNT(si);
213     unsigned ch;
214     unsigned digit;
215 
216     if (count > 1)
217     {
218         switch (*cp)
219         {
220         case '-':
221             cp++;
222             count--;
223             isNeg = TRUE;
224             break;
225         case '+':
226             cp++;
227             count--;
228             isNeg = FALSE;
229             break;
230         default:
231             break;
232         }
233     }
234 
235     if ((count > 0) && (cp[count-1] == '.')) /* detect & remove trailing decimal */
236     {
237         hasDP = TRUE;
238         count--;
239     }
240 
241     if (count == 0)        /* detect "+", "-", ".", "+." etc */
242         return FALSE;
243 
244     while ((count--) && ((ch = *cp++) != '\0'))
245     {
246         if (!isalnum(ch))
247             return FALSE;
248 
249         digit = ch - '0';
250 
251         if (digit > 9)
252             digit = tolower(ch) - 'a' + 10;
253 
254         if (digit >= base)
255             return FALSE;
256 
257         accum = accum * base + digit;
258     }
259 
260 	if (hasDP)		/* simple (required) DOUBLE support */
261 		PUSHINT(0);
262 
263     if (isNeg)
264         accum = -accum;
265 
266     PUSHINT(accum);
267     if (pVM->state == COMPILE)
268         literalIm(pVM);
269 
270     return TRUE;
271 }
272 
273 
274 /**************************************************************************
275                         a d d   &   f r i e n d s
276 **
277 **************************************************************************/
278 
279 static void add(FICL_VM *pVM)
280 {
281     FICL_INT i;
282 #if FICL_ROBUST > 1
283     vmCheckStack(pVM, 2, 1);
284 #endif
285     i = stackPopINT(pVM->pStack);
286     i += stackGetTop(pVM->pStack).i;
287     stackSetTop(pVM->pStack, LVALUEtoCELL(i));
288     return;
289 }
290 
291 static void sub(FICL_VM *pVM)
292 {
293     FICL_INT i;
294 #if FICL_ROBUST > 1
295     vmCheckStack(pVM, 2, 1);
296 #endif
297     i = stackPopINT(pVM->pStack);
298     i = stackGetTop(pVM->pStack).i - i;
299     stackSetTop(pVM->pStack, LVALUEtoCELL(i));
300     return;
301 }
302 
303 static void mul(FICL_VM *pVM)
304 {
305     FICL_INT i;
306 #if FICL_ROBUST > 1
307     vmCheckStack(pVM, 2, 1);
308 #endif
309     i = stackPopINT(pVM->pStack);
310     i *= stackGetTop(pVM->pStack).i;
311     stackSetTop(pVM->pStack, LVALUEtoCELL(i));
312     return;
313 }
314 
315 static void negate(FICL_VM *pVM)
316 {
317     FICL_INT i;
318 #if FICL_ROBUST > 1
319     vmCheckStack(pVM, 1, 1);
320 #endif
321     i = -stackPopINT(pVM->pStack);
322     PUSHINT(i);
323     return;
324 }
325 
326 static void ficlDiv(FICL_VM *pVM)
327 {
328     FICL_INT i;
329 #if FICL_ROBUST > 1
330     vmCheckStack(pVM, 2, 1);
331 #endif
332     i = stackPopINT(pVM->pStack);
333     i = stackGetTop(pVM->pStack).i / i;
334     stackSetTop(pVM->pStack, LVALUEtoCELL(i));
335     return;
336 }
337 
338 /*
339 ** slash-mod        CORE ( n1 n2 -- n3 n4 )
340 ** Divide n1 by n2, giving the single-cell remainder n3 and the single-cell
341 ** quotient n4. An ambiguous condition exists if n2 is zero. If n1 and n2
342 ** differ in sign, the implementation-defined result returned will be the
343 ** same as that returned by either the phrase
344 ** >R S>D R> FM/MOD or the phrase >R S>D R> SM/REM .
345 ** NOTE: Ficl complies with the second phrase (symmetric division)
346 */
347 static void slashMod(FICL_VM *pVM)
348 {
349     DPINT n1;
350     FICL_INT n2;
351     INTQR qr;
352 
353 #if FICL_ROBUST > 1
354     vmCheckStack(pVM, 2, 2);
355 #endif
356     n2    = stackPopINT(pVM->pStack);
357     n1.lo = stackPopINT(pVM->pStack);
358     i64Extend(n1);
359 
360     qr = m64SymmetricDivI(n1, n2);
361     PUSHINT(qr.rem);
362     PUSHINT(qr.quot);
363     return;
364 }
365 
366 static void onePlus(FICL_VM *pVM)
367 {
368     FICL_INT i;
369 #if FICL_ROBUST > 1
370     vmCheckStack(pVM, 1, 1);
371 #endif
372     i = stackGetTop(pVM->pStack).i;
373     i += 1;
374     stackSetTop(pVM->pStack, LVALUEtoCELL(i));
375     return;
376 }
377 
378 static void oneMinus(FICL_VM *pVM)
379 {
380     FICL_INT i;
381 #if FICL_ROBUST > 1
382     vmCheckStack(pVM, 1, 1);
383 #endif
384     i = stackGetTop(pVM->pStack).i;
385     i -= 1;
386     stackSetTop(pVM->pStack, LVALUEtoCELL(i));
387     return;
388 }
389 
390 static void twoMul(FICL_VM *pVM)
391 {
392     FICL_INT i;
393 #if FICL_ROBUST > 1
394     vmCheckStack(pVM, 1, 1);
395 #endif
396     i = stackGetTop(pVM->pStack).i;
397     i *= 2;
398     stackSetTop(pVM->pStack, LVALUEtoCELL(i));
399     return;
400 }
401 
402 static void twoDiv(FICL_VM *pVM)
403 {
404     FICL_INT i;
405 #if FICL_ROBUST > 1
406     vmCheckStack(pVM, 1, 1);
407 #endif
408     i = stackGetTop(pVM->pStack).i;
409     i >>= 1;
410     stackSetTop(pVM->pStack, LVALUEtoCELL(i));
411     return;
412 }
413 
414 static void mulDiv(FICL_VM *pVM)
415 {
416     FICL_INT x, y, z;
417     DPINT prod;
418 #if FICL_ROBUST > 1
419     vmCheckStack(pVM, 3, 1);
420 #endif
421     z = stackPopINT(pVM->pStack);
422     y = stackPopINT(pVM->pStack);
423     x = stackPopINT(pVM->pStack);
424 
425     prod = m64MulI(x,y);
426     x    = m64SymmetricDivI(prod, z).quot;
427 
428     PUSHINT(x);
429     return;
430 }
431 
432 
433 static void mulDivRem(FICL_VM *pVM)
434 {
435     FICL_INT x, y, z;
436     DPINT prod;
437     INTQR qr;
438 #if FICL_ROBUST > 1
439     vmCheckStack(pVM, 3, 2);
440 #endif
441     z = stackPopINT(pVM->pStack);
442     y = stackPopINT(pVM->pStack);
443     x = stackPopINT(pVM->pStack);
444 
445     prod = m64MulI(x,y);
446     qr   = m64SymmetricDivI(prod, z);
447 
448     PUSHINT(qr.rem);
449     PUSHINT(qr.quot);
450     return;
451 }
452 
453 
454 /**************************************************************************
455                         c o l o n   d e f i n i t i o n s
456 ** Code to begin compiling a colon definition
457 ** This function sets the state to COMPILE, then creates a
458 ** new word whose name is the next word in the input stream
459 ** and whose code is colonParen.
460 **************************************************************************/
461 
462 static void colon(FICL_VM *pVM)
463 {
464     FICL_DICT *dp = vmGetDict(pVM);
465     STRINGINFO si = vmGetWord(pVM);
466 
467     dictCheckThreshold(dp);
468 
469     pVM->state = COMPILE;
470     markControlTag(pVM, colonTag);
471     dictAppendWord2(dp, si, colonParen, FW_DEFAULT | FW_SMUDGE);
472 #if FICL_WANT_LOCALS
473     pVM->pSys->nLocals = 0;
474 #endif
475     return;
476 }
477 
478 
479 /**************************************************************************
480                         c o l o n P a r e n
481 ** This is the code that executes a colon definition. It assumes that the
482 ** virtual machine is running a "next" loop (See the vm.c
483 ** for its implementation of member function vmExecute()). The colon
484 ** code simply copies the address of the first word in the list of words
485 ** to interpret into IP after saving its old value. When we return to the
486 ** "next" loop, the virtual machine will call the code for each word in
487 ** turn.
488 **
489 **************************************************************************/
490 
491 static void colonParen(FICL_VM *pVM)
492 {
493     IPTYPE tempIP = (IPTYPE) (pVM->runningWord->param);
494     vmPushIP(pVM, tempIP);
495 
496     return;
497 }
498 
499 
500 /**************************************************************************
501                         s e m i c o l o n C o I m
502 **
503 ** IMMEDIATE code for ";". This function sets the state to INTERPRET and
504 ** terminates a word under compilation by appending code for "(;)" to
505 ** the definition. TO DO: checks for leftover branch target tags on the
506 ** return stack and complains if any are found.
507 **************************************************************************/
508 static void semiParen(FICL_VM *pVM)
509 {
510     vmPopIP(pVM);
511     return;
512 }
513 
514 
515 static void semicolonCoIm(FICL_VM *pVM)
516 {
517     FICL_DICT *dp = vmGetDict(pVM);
518 
519     assert(pVM->pSys->pSemiParen);
520     matchControlTag(pVM, colonTag);
521 
522 #if FICL_WANT_LOCALS
523     assert(pVM->pSys->pUnLinkParen);
524     if (pVM->pSys->nLocals > 0)
525     {
526         FICL_DICT *pLoc = ficlGetLoc(pVM->pSys);
527         dictEmpty(pLoc, pLoc->pForthWords->size);
528         dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pUnLinkParen));
529     }
530     pVM->pSys->nLocals = 0;
531 #endif
532 
533     dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pSemiParen));
534     pVM->state = INTERPRET;
535     dictUnsmudge(dp);
536     return;
537 }
538 
539 
540 /**************************************************************************
541                         e x i t
542 ** CORE
543 ** This function simply pops the previous instruction
544 ** pointer and returns to the "next" loop. Used for exiting from within
545 ** a definition. Note that exitParen is identical to semiParen - they
546 ** are in two different functions so that "see" can correctly identify
547 ** the end of a colon definition, even if it uses "exit".
548 **************************************************************************/
549 static void exitParen(FICL_VM *pVM)
550 {
551     vmPopIP(pVM);
552     return;
553 }
554 
555 static void exitCoIm(FICL_VM *pVM)
556 {
557     FICL_DICT *dp = vmGetDict(pVM);
558     assert(pVM->pSys->pExitParen);
559     IGNORE(pVM);
560 
561 #if FICL_WANT_LOCALS
562     if (pVM->pSys->nLocals > 0)
563     {
564         dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pUnLinkParen));
565     }
566 #endif
567     dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pExitParen));
568     return;
569 }
570 
571 
572 /**************************************************************************
573                         c o n s t a n t P a r e n
574 ** This is the run-time code for "constant". It simply returns the
575 ** contents of its word's first data cell.
576 **
577 **************************************************************************/
578 
579 void constantParen(FICL_VM *pVM)
580 {
581     FICL_WORD *pFW = pVM->runningWord;
582 #if FICL_ROBUST > 1
583     vmCheckStack(pVM, 0, 1);
584 #endif
585     stackPush(pVM->pStack, pFW->param[0]);
586     return;
587 }
588 
589 void twoConstParen(FICL_VM *pVM)
590 {
591     FICL_WORD *pFW = pVM->runningWord;
592 #if FICL_ROBUST > 1
593     vmCheckStack(pVM, 0, 2);
594 #endif
595     stackPush(pVM->pStack, pFW->param[0]); /* lo */
596     stackPush(pVM->pStack, pFW->param[1]); /* hi */
597     return;
598 }
599 
600 
601 /**************************************************************************
602                         c o n s t a n t
603 ** IMMEDIATE
604 ** Compiles a constant into the dictionary. Constants return their
605 ** value when invoked. Expects a value on top of the parm stack.
606 **************************************************************************/
607 
608 static void constant(FICL_VM *pVM)
609 {
610     FICL_DICT *dp = vmGetDict(pVM);
611     STRINGINFO si = vmGetWord(pVM);
612 
613 #if FICL_ROBUST > 1
614     vmCheckStack(pVM, 1, 0);
615 #endif
616     dictAppendWord2(dp, si, constantParen, FW_DEFAULT);
617     dictAppendCell(dp, stackPop(pVM->pStack));
618     return;
619 }
620 
621 
622 static void twoConstant(FICL_VM *pVM)
623 {
624     FICL_DICT *dp = vmGetDict(pVM);
625     STRINGINFO si = vmGetWord(pVM);
626     CELL c;
627 
628 #if FICL_ROBUST > 1
629     vmCheckStack(pVM, 2, 0);
630 #endif
631     c = stackPop(pVM->pStack);
632     dictAppendWord2(dp, si, twoConstParen, FW_DEFAULT);
633     dictAppendCell(dp, stackPop(pVM->pStack));
634     dictAppendCell(dp, c);
635     return;
636 }
637 
638 
639 /**************************************************************************
640                         d i s p l a y C e l l
641 ** Drop and print the contents of the cell at the top of the param
642 ** stack
643 **************************************************************************/
644 
645 static void displayCell(FICL_VM *pVM)
646 {
647     CELL c;
648 #if FICL_ROBUST > 1
649     vmCheckStack(pVM, 1, 0);
650 #endif
651     c = stackPop(pVM->pStack);
652     ltoa((c).i, pVM->pad, pVM->base);
653     strcat(pVM->pad, " ");
654     vmTextOut(pVM, pVM->pad, 0);
655     return;
656 }
657 
658 static void uDot(FICL_VM *pVM)
659 {
660     FICL_UNS u;
661 #if FICL_ROBUST > 1
662     vmCheckStack(pVM, 1, 0);
663 #endif
664     u = stackPopUNS(pVM->pStack);
665     ultoa(u, pVM->pad, pVM->base);
666     strcat(pVM->pad, " ");
667     vmTextOut(pVM, pVM->pad, 0);
668     return;
669 }
670 
671 
672 static void hexDot(FICL_VM *pVM)
673 {
674     FICL_UNS u;
675 #if FICL_ROBUST > 1
676     vmCheckStack(pVM, 1, 0);
677 #endif
678     u = stackPopUNS(pVM->pStack);
679     ultoa(u, pVM->pad, 16);
680     strcat(pVM->pad, " ");
681     vmTextOut(pVM, pVM->pad, 0);
682     return;
683 }
684 
685 
686 /**************************************************************************
687                         s t r l e n
688 ** FICL   ( c-string -- length )
689 **
690 ** Returns the length of a C-style (zero-terminated) string.
691 **
692 ** --lch
693 **/
694 static void ficlStrlen(FICL_VM *ficlVM)
695 	{
696 	char *address = (char *)stackPopPtr(ficlVM->pStack);
697 	stackPushINT(ficlVM->pStack, strlen(address));
698 	}
699 
700 
701 /**************************************************************************
702                         s p r i n t f
703 ** FICL   ( i*x c-addr-fmt u-fmt c-addr-buffer u-buffer -- c-addr-buffer u-written success-flag )
704 ** Similar to the C sprintf() function.  It formats into a buffer based on
705 ** a "format" string.  Each character in the format string is copied verbatim
706 ** to the output buffer, until SPRINTF encounters a percent sign ("%").
707 ** SPRINTF then skips the percent sign, and examines the next character
708 ** (the "format character").  Here are the valid format characters:
709 **    s - read a C-ADDR U-LENGTH string from the stack and copy it to
710 **        the buffer
711 **    d - read a cell from the stack, format it as a string (base-10,
712 **        signed), and copy it to the buffer
713 **    x - same as d, except in base-16
714 **    u - same as d, but unsigned
715 **    % - output a literal percent-sign to the buffer
716 ** SPRINTF returns the c-addr-buffer argument unchanged, the number of bytes
717 ** written, and a flag indicating whether or not it ran out of space while
718 ** writing to the output buffer (TRUE if it ran out of space).
719 **
720 ** If SPRINTF runs out of space in the buffer to store the formatted string,
721 ** it still continues parsing, in an effort to preserve your stack (otherwise
722 ** it might leave uneaten arguments behind).
723 **
724 ** --lch
725 **************************************************************************/
726 static void ficlSprintf(FICL_VM *pVM) /*  */
727 {
728 	int bufferLength = stackPopINT(pVM->pStack);
729 	char *buffer = (char *)stackPopPtr(pVM->pStack);
730 	char *bufferStart = buffer;
731 
732 	int formatLength = stackPopINT(pVM->pStack);
733 	char *format = (char *)stackPopPtr(pVM->pStack);
734 	char *formatStop = format + formatLength;
735 
736 	int base = 10;
737 	int unsignedInteger = FALSE;
738 
739 	FICL_INT append = FICL_TRUE;
740 
741 	while (format < formatStop)
742 	{
743 		char scratch[64];
744 		char *source;
745 		int actualLength;
746 		int desiredLength;
747 		int leadingZeroes;
748 
749 
750 		if (*format != '%')
751 		{
752 			source = format;
753 			actualLength = desiredLength = 1;
754 			leadingZeroes = 0;
755 		}
756 		else
757 		{
758 			format++;
759 			if (format == formatStop)
760 				break;
761 
762 			leadingZeroes = (*format == '0');
763 			if (leadingZeroes)
764 				{
765 				format++;
766 				if (format == formatStop)
767 					break;
768 				}
769 
770 			desiredLength = isdigit(*format);
771 			if (desiredLength)
772 				{
773 				desiredLength = strtol(format, &format, 10);
774 				if (format == formatStop)
775 					break;
776 				}
777 			else if (*format == '*')
778 				{
779 				desiredLength = stackPopINT(pVM->pStack);
780 				format++;
781 				if (format == formatStop)
782 					break;
783 				}
784 
785 
786 			switch (*format)
787 			{
788 				case 's':
789 				case 'S':
790 				{
791 					actualLength = stackPopINT(pVM->pStack);
792 					source = (char *)stackPopPtr(pVM->pStack);
793 					break;
794 				}
795 				case 'x':
796 				case 'X':
797 					base = 16;
798 				case 'u':
799 				case 'U':
800 					unsignedInteger = TRUE;
801 				case 'd':
802 				case 'D':
803 				{
804 					int integer = stackPopINT(pVM->pStack);
805 					if (unsignedInteger)
806 						ultoa(integer, scratch, base);
807 					else
808 						ltoa(integer, scratch, base);
809 					base = 10;
810 					unsignedInteger = FALSE;
811 					source = scratch;
812 					actualLength = strlen(scratch);
813 					break;
814 				}
815 				case '%':
816 					source = format;
817 					actualLength = 1;
818 				default:
819 					continue;
820 			}
821 		}
822 
823 		if (append != FICL_FALSE)
824 		{
825 			if (!desiredLength)
826 				desiredLength = actualLength;
827 			if (desiredLength > bufferLength)
828 			{
829 				append = FICL_FALSE;
830 				desiredLength = bufferLength;
831 			}
832 			while (desiredLength > actualLength)
833 				{
834 				*buffer++ = (char)((leadingZeroes) ? '0' : ' ');
835 				bufferLength--;
836 				desiredLength--;
837 				}
838 			memcpy(buffer, source, actualLength);
839 			buffer += actualLength;
840 			bufferLength -= actualLength;
841 		}
842 
843 		format++;
844 	}
845 
846 	stackPushPtr(pVM->pStack, bufferStart);
847 	stackPushINT(pVM->pStack, buffer - bufferStart);
848 	stackPushINT(pVM->pStack, append);
849 }
850 
851 
852 /**************************************************************************
853                         d u p   &   f r i e n d s
854 **
855 **************************************************************************/
856 
857 static void depth(FICL_VM *pVM)
858 {
859     int i;
860 #if FICL_ROBUST > 1
861     vmCheckStack(pVM, 0, 1);
862 #endif
863     i = stackDepth(pVM->pStack);
864     PUSHINT(i);
865     return;
866 }
867 
868 
869 static void drop(FICL_VM *pVM)
870 {
871 #if FICL_ROBUST > 1
872     vmCheckStack(pVM, 1, 0);
873 #endif
874     stackDrop(pVM->pStack, 1);
875     return;
876 }
877 
878 
879 static void twoDrop(FICL_VM *pVM)
880 {
881 #if FICL_ROBUST > 1
882     vmCheckStack(pVM, 2, 0);
883 #endif
884     stackDrop(pVM->pStack, 2);
885     return;
886 }
887 
888 
889 static void dup(FICL_VM *pVM)
890 {
891 #if FICL_ROBUST > 1
892     vmCheckStack(pVM, 1, 2);
893 #endif
894     stackPick(pVM->pStack, 0);
895     return;
896 }
897 
898 
899 static void twoDup(FICL_VM *pVM)
900 {
901 #if FICL_ROBUST > 1
902     vmCheckStack(pVM, 2, 4);
903 #endif
904     stackPick(pVM->pStack, 1);
905     stackPick(pVM->pStack, 1);
906     return;
907 }
908 
909 
910 static void over(FICL_VM *pVM)
911 {
912 #if FICL_ROBUST > 1
913     vmCheckStack(pVM, 2, 3);
914 #endif
915     stackPick(pVM->pStack, 1);
916     return;
917 }
918 
919 static void twoOver(FICL_VM *pVM)
920 {
921 #if FICL_ROBUST > 1
922     vmCheckStack(pVM, 4, 6);
923 #endif
924     stackPick(pVM->pStack, 3);
925     stackPick(pVM->pStack, 3);
926     return;
927 }
928 
929 
930 static void pick(FICL_VM *pVM)
931 {
932     CELL c = stackPop(pVM->pStack);
933 #if FICL_ROBUST > 1
934     vmCheckStack(pVM, c.i+1, c.i+2);
935 #endif
936     stackPick(pVM->pStack, c.i);
937     return;
938 }
939 
940 
941 static void questionDup(FICL_VM *pVM)
942 {
943     CELL c;
944 #if FICL_ROBUST > 1
945     vmCheckStack(pVM, 1, 2);
946 #endif
947     c = stackGetTop(pVM->pStack);
948 
949     if (c.i != 0)
950         stackPick(pVM->pStack, 0);
951 
952     return;
953 }
954 
955 
956 static void roll(FICL_VM *pVM)
957 {
958     int i = stackPop(pVM->pStack).i;
959     i = (i > 0) ? i : 0;
960 #if FICL_ROBUST > 1
961     vmCheckStack(pVM, i+1, i+1);
962 #endif
963     stackRoll(pVM->pStack, i);
964     return;
965 }
966 
967 
968 static void minusRoll(FICL_VM *pVM)
969 {
970     int i = stackPop(pVM->pStack).i;
971     i = (i > 0) ? i : 0;
972 #if FICL_ROBUST > 1
973     vmCheckStack(pVM, i+1, i+1);
974 #endif
975     stackRoll(pVM->pStack, -i);
976     return;
977 }
978 
979 
980 static void rot(FICL_VM *pVM)
981 {
982 #if FICL_ROBUST > 1
983     vmCheckStack(pVM, 3, 3);
984 #endif
985     stackRoll(pVM->pStack, 2);
986     return;
987 }
988 
989 
990 static void swap(FICL_VM *pVM)
991 {
992 #if FICL_ROBUST > 1
993     vmCheckStack(pVM, 2, 2);
994 #endif
995     stackRoll(pVM->pStack, 1);
996     return;
997 }
998 
999 
1000 static void twoSwap(FICL_VM *pVM)
1001 {
1002 #if FICL_ROBUST > 1
1003     vmCheckStack(pVM, 4, 4);
1004 #endif
1005     stackRoll(pVM->pStack, 3);
1006     stackRoll(pVM->pStack, 3);
1007     return;
1008 }
1009 
1010 
1011 /**************************************************************************
1012                         e m i t   &   f r i e n d s
1013 **
1014 **************************************************************************/
1015 
1016 static void emit(FICL_VM *pVM)
1017 {
1018     char *cp = pVM->pad;
1019     int i;
1020 
1021 #if FICL_ROBUST > 1
1022     vmCheckStack(pVM, 1, 0);
1023 #endif
1024     i = stackPopINT(pVM->pStack);
1025     cp[0] = (char)i;
1026     cp[1] = '\0';
1027     vmTextOut(pVM, cp, 0);
1028     return;
1029 }
1030 
1031 
1032 static void cr(FICL_VM *pVM)
1033 {
1034     vmTextOut(pVM, "", 1);
1035     return;
1036 }
1037 
1038 
1039 static void commentLine(FICL_VM *pVM)
1040 {
1041     char *cp        = vmGetInBuf(pVM);
1042     char *pEnd      = vmGetInBufEnd(pVM);
1043     char ch = *cp;
1044 
1045     while ((cp != pEnd) && (ch != '\r') && (ch != '\n'))
1046     {
1047         ch = *++cp;
1048     }
1049 
1050     /*
1051     ** Cope with DOS or UNIX-style EOLs -
1052     ** Check for /r, /n, /r/n, or /n/r end-of-line sequences,
1053     ** and point cp to next char. If EOL is \0, we're done.
1054     */
1055     if (cp != pEnd)
1056     {
1057         cp++;
1058 
1059         if ( (cp != pEnd) && (ch != *cp)
1060              && ((*cp == '\r') || (*cp == '\n')) )
1061             cp++;
1062     }
1063 
1064     vmUpdateTib(pVM, cp);
1065     return;
1066 }
1067 
1068 
1069 /*
1070 ** paren CORE
1071 ** Compilation: Perform the execution semantics given below.
1072 ** Execution: ( "ccc<paren>" -- )
1073 ** Parse ccc delimited by ) (right parenthesis). ( is an immediate word.
1074 ** The number of characters in ccc may be zero to the number of characters
1075 ** in the parse area.
1076 **
1077 */
1078 static void commentHang(FICL_VM *pVM)
1079 {
1080     vmParseStringEx(pVM, ')', 0);
1081     return;
1082 }
1083 
1084 
1085 /**************************************************************************
1086                         F E T C H   &   S T O R E
1087 **
1088 **************************************************************************/
1089 
1090 static void fetch(FICL_VM *pVM)
1091 {
1092     CELL *pCell;
1093 #if FICL_ROBUST > 1
1094     vmCheckStack(pVM, 1, 1);
1095 #endif
1096     pCell = (CELL *)stackPopPtr(pVM->pStack);
1097     stackPush(pVM->pStack, *pCell);
1098     return;
1099 }
1100 
1101 /*
1102 ** two-fetch    CORE ( a-addr -- x1 x2 )
1103 ** Fetch the cell pair x1 x2 stored at a-addr. x2 is stored at a-addr and
1104 ** x1 at the next consecutive cell. It is equivalent to the sequence
1105 ** DUP CELL+ @ SWAP @ .
1106 */
1107 static void twoFetch(FICL_VM *pVM)
1108 {
1109     CELL *pCell;
1110 #if FICL_ROBUST > 1
1111     vmCheckStack(pVM, 1, 2);
1112 #endif
1113     pCell = (CELL *)stackPopPtr(pVM->pStack);
1114     stackPush(pVM->pStack, *pCell++);
1115     stackPush(pVM->pStack, *pCell);
1116     swap(pVM);
1117     return;
1118 }
1119 
1120 /*
1121 ** store        CORE ( x a-addr -- )
1122 ** Store x at a-addr.
1123 */
1124 static void store(FICL_VM *pVM)
1125 {
1126     CELL *pCell;
1127 #if FICL_ROBUST > 1
1128     vmCheckStack(pVM, 2, 0);
1129 #endif
1130     pCell = (CELL *)stackPopPtr(pVM->pStack);
1131     *pCell = stackPop(pVM->pStack);
1132 }
1133 
1134 /*
1135 ** two-store    CORE ( x1 x2 a-addr -- )
1136 ** Store the cell pair x1 x2 at a-addr, with x2 at a-addr and x1 at the
1137 ** next consecutive cell. It is equivalent to the sequence
1138 ** SWAP OVER ! CELL+ ! .
1139 */
1140 static void twoStore(FICL_VM *pVM)
1141 {
1142     CELL *pCell;
1143 #if FICL_ROBUST > 1
1144     vmCheckStack(pVM, 3, 0);
1145 #endif
1146     pCell = (CELL *)stackPopPtr(pVM->pStack);
1147     *pCell++    = stackPop(pVM->pStack);
1148     *pCell      = stackPop(pVM->pStack);
1149 }
1150 
1151 static void plusStore(FICL_VM *pVM)
1152 {
1153     CELL *pCell;
1154 #if FICL_ROBUST > 1
1155     vmCheckStack(pVM, 2, 0);
1156 #endif
1157     pCell = (CELL *)stackPopPtr(pVM->pStack);
1158     pCell->i += stackPop(pVM->pStack).i;
1159 }
1160 
1161 
1162 static void quadFetch(FICL_VM *pVM)
1163 {
1164     UNS32 *pw;
1165 #if FICL_ROBUST > 1
1166     vmCheckStack(pVM, 1, 1);
1167 #endif
1168     pw = (UNS32 *)stackPopPtr(pVM->pStack);
1169     PUSHUNS((FICL_UNS)*pw);
1170     return;
1171 }
1172 
1173 static void quadStore(FICL_VM *pVM)
1174 {
1175     UNS32 *pw;
1176 #if FICL_ROBUST > 1
1177     vmCheckStack(pVM, 2, 0);
1178 #endif
1179     pw = (UNS32 *)stackPopPtr(pVM->pStack);
1180     *pw = (UNS32)(stackPop(pVM->pStack).u);
1181 }
1182 
1183 static void wFetch(FICL_VM *pVM)
1184 {
1185     UNS16 *pw;
1186 #if FICL_ROBUST > 1
1187     vmCheckStack(pVM, 1, 1);
1188 #endif
1189     pw = (UNS16 *)stackPopPtr(pVM->pStack);
1190     PUSHUNS((FICL_UNS)*pw);
1191     return;
1192 }
1193 
1194 static void wStore(FICL_VM *pVM)
1195 {
1196     UNS16 *pw;
1197 #if FICL_ROBUST > 1
1198     vmCheckStack(pVM, 2, 0);
1199 #endif
1200     pw = (UNS16 *)stackPopPtr(pVM->pStack);
1201     *pw = (UNS16)(stackPop(pVM->pStack).u);
1202 }
1203 
1204 static void cFetch(FICL_VM *pVM)
1205 {
1206     UNS8 *pc;
1207 #if FICL_ROBUST > 1
1208     vmCheckStack(pVM, 1, 1);
1209 #endif
1210     pc = (UNS8 *)stackPopPtr(pVM->pStack);
1211     PUSHUNS((FICL_UNS)*pc);
1212     return;
1213 }
1214 
1215 static void cStore(FICL_VM *pVM)
1216 {
1217     UNS8 *pc;
1218 #if FICL_ROBUST > 1
1219     vmCheckStack(pVM, 2, 0);
1220 #endif
1221     pc = (UNS8 *)stackPopPtr(pVM->pStack);
1222     *pc = (UNS8)(stackPop(pVM->pStack).u);
1223 }
1224 
1225 
1226 /**************************************************************************
1227                         b r a n c h P a r e n
1228 **
1229 ** Runtime for "(branch)" -- expects a literal offset in the next
1230 ** compilation address, and branches to that location.
1231 **************************************************************************/
1232 
1233 static void branchParen(FICL_VM *pVM)
1234 {
1235     vmBranchRelative(pVM, (uintptr_t)*(pVM->ip));
1236     return;
1237 }
1238 
1239 
1240 /**************************************************************************
1241                         b r a n c h 0
1242 ** Runtime code for "(branch0)"; pop a flag from the stack,
1243 ** branch if 0. fall through otherwise.  The heart of "if" and "until".
1244 **************************************************************************/
1245 
1246 static void branch0(FICL_VM *pVM)
1247 {
1248     FICL_UNS flag;
1249 
1250 #if FICL_ROBUST > 1
1251     vmCheckStack(pVM, 1, 0);
1252 #endif
1253     flag = stackPopUNS(pVM->pStack);
1254 
1255     if (flag)
1256     {                           /* fall through */
1257         vmBranchRelative(pVM, 1);
1258     }
1259     else
1260     {                           /* take branch (to else/endif/begin) */
1261         vmBranchRelative(pVM, (uintptr_t)*(pVM->ip));
1262     }
1263 
1264     return;
1265 }
1266 
1267 
1268 /**************************************************************************
1269                         i f C o I m
1270 ** IMMEDIATE COMPILE-ONLY
1271 ** Compiles code for a conditional branch into the dictionary
1272 ** and pushes the branch patch address on the stack for later
1273 ** patching by ELSE or THEN/ENDIF.
1274 **************************************************************************/
1275 
1276 static void ifCoIm(FICL_VM *pVM)
1277 {
1278     FICL_DICT *dp = vmGetDict(pVM);
1279 
1280     assert(pVM->pSys->pBranch0);
1281 
1282     dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pBranch0));
1283     markBranch(dp, pVM, origTag);
1284     dictAppendUNS(dp, 1);
1285     return;
1286 }
1287 
1288 
1289 /**************************************************************************
1290                         e l s e C o I m
1291 **
1292 ** IMMEDIATE COMPILE-ONLY
1293 ** compiles an "else"...
1294 ** 1) Compile a branch and a patch address; the address gets patched
1295 **    by "endif" to point past the "else" code.
1296 ** 2) Pop the "if" patch address
1297 ** 3) Patch the "if" branch to point to the current compile address.
1298 ** 4) Push the "else" patch address. ("endif" patches this to jump past
1299 **    the "else" code.
1300 **************************************************************************/
1301 
1302 static void elseCoIm(FICL_VM *pVM)
1303 {
1304     CELL *patchAddr;
1305     FICL_INT offset;
1306     FICL_DICT *dp = vmGetDict(pVM);
1307 
1308     assert(pVM->pSys->pBranchParen);
1309                                             /* (1) compile branch runtime */
1310     dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pBranchParen));
1311     matchControlTag(pVM, origTag);
1312     patchAddr =
1313         (CELL *)stackPopPtr(pVM->pStack);   /* (2) pop "if" patch addr */
1314     markBranch(dp, pVM, origTag);           /* (4) push "else" patch addr */
1315     dictAppendUNS(dp, 1);                 /* (1) compile patch placeholder */
1316     offset = dp->here - patchAddr;
1317     *patchAddr = LVALUEtoCELL(offset);      /* (3) Patch "if" */
1318 
1319     return;
1320 }
1321 
1322 
1323 /**************************************************************************
1324                         e n d i f C o I m
1325 ** IMMEDIATE COMPILE-ONLY
1326 **************************************************************************/
1327 
1328 static void endifCoIm(FICL_VM *pVM)
1329 {
1330     FICL_DICT *dp = vmGetDict(pVM);
1331     resolveForwardBranch(dp, pVM, origTag);
1332     return;
1333 }
1334 
1335 
1336 /**************************************************************************
1337                         c a s e C o I m
1338 ** IMMEDIATE COMPILE-ONLY
1339 **
1340 **
1341 ** At compile-time, a CASE-SYS (see DPANS94 6.2.0873) looks like this:
1342 **			i*addr i caseTag
1343 ** and an OF-SYS (see DPANS94 6.2.1950) looks like this:
1344 **			i*addr i caseTag addr ofTag
1345 ** The integer under caseTag is the count of fixup addresses that branch
1346 ** to ENDCASE.
1347 **************************************************************************/
1348 
1349 static void caseCoIm(FICL_VM *pVM)
1350 {
1351 #if FICL_ROBUST > 1
1352     vmCheckStack(pVM, 0, 2);
1353 #endif
1354 
1355 	PUSHUNS(0);
1356 	markControlTag(pVM, caseTag);
1357     return;
1358 }
1359 
1360 
1361 /**************************************************************************
1362                         e n d c a s eC o I m
1363 ** IMMEDIATE COMPILE-ONLY
1364 **************************************************************************/
1365 
1366 static void endcaseCoIm(FICL_VM *pVM)
1367 {
1368 	FICL_UNS fixupCount;
1369     FICL_DICT *dp;
1370     CELL *patchAddr;
1371     FICL_INT offset;
1372 
1373     assert(pVM->pSys->pDrop);
1374 
1375 	/*
1376 	** if the last OF ended with FALLTHROUGH,
1377 	** just add the FALLTHROUGH fixup to the
1378 	** ENDOF fixups
1379 	*/
1380 	if (stackGetTop(pVM->pStack).p == fallthroughTag)
1381 	{
1382 		matchControlTag(pVM, fallthroughTag);
1383 		patchAddr = POPPTR();
1384 	    matchControlTag(pVM, caseTag);
1385 		fixupCount = POPUNS();
1386 		PUSHPTR(patchAddr);
1387 		PUSHUNS(fixupCount + 1);
1388 		markControlTag(pVM, caseTag);
1389 	}
1390 
1391     matchControlTag(pVM, caseTag);
1392 
1393 #if FICL_ROBUST > 1
1394     vmCheckStack(pVM, 1, 0);
1395 #endif
1396 	fixupCount = POPUNS();
1397 #if FICL_ROBUST > 1
1398     vmCheckStack(pVM, fixupCount, 0);
1399 #endif
1400 
1401     dp = vmGetDict(pVM);
1402 
1403     dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pDrop));
1404 
1405 	while (fixupCount--)
1406 	{
1407 		patchAddr = (CELL *)stackPopPtr(pVM->pStack);
1408 		offset = dp->here - patchAddr;
1409 		*patchAddr = LVALUEtoCELL(offset);
1410 	}
1411     return;
1412 }
1413 
1414 
1415 static void ofParen(FICL_VM *pVM)
1416 {
1417 	FICL_UNS a, b;
1418 
1419 #if FICL_ROBUST > 1
1420     vmCheckStack(pVM, 2, 1);
1421 #endif
1422 
1423 	a = POPUNS();
1424 	b = stackGetTop(pVM->pStack).u;
1425 
1426     if (a == b)
1427     {                           /* fall through */
1428 		stackDrop(pVM->pStack, 1);
1429         vmBranchRelative(pVM, 1);
1430     }
1431     else
1432     {                           /* take branch to next of or endswitch */
1433         vmBranchRelative(pVM, *(int *)(pVM->ip));
1434     }
1435 
1436     return;
1437 }
1438 
1439 
1440 /**************************************************************************
1441                         o f C o I m
1442 ** IMMEDIATE COMPILE-ONLY
1443 **************************************************************************/
1444 
1445 static void ofCoIm(FICL_VM *pVM)
1446 {
1447     FICL_DICT *dp = vmGetDict(pVM);
1448 	CELL *fallthroughFixup = NULL;
1449 
1450     assert(pVM->pSys->pBranch0);
1451 
1452 #if FICL_ROBUST > 1
1453     vmCheckStack(pVM, 1, 3);
1454 #endif
1455 
1456 	if (stackGetTop(pVM->pStack).p == fallthroughTag)
1457 	{
1458 		matchControlTag(pVM, fallthroughTag);
1459 		fallthroughFixup = POPPTR();
1460 	}
1461 
1462 	matchControlTag(pVM, caseTag);
1463 
1464 	markControlTag(pVM, caseTag);
1465 
1466     dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pOfParen));
1467     markBranch(dp, pVM, ofTag);
1468     dictAppendUNS(dp, 2);
1469 
1470 	if (fallthroughFixup != NULL)
1471 	{
1472 		FICL_INT offset = dp->here - fallthroughFixup;
1473 		*fallthroughFixup = LVALUEtoCELL(offset);
1474 	}
1475 
1476     return;
1477 }
1478 
1479 
1480 /**************************************************************************
1481                     e n d o f C o I m
1482 ** IMMEDIATE COMPILE-ONLY
1483 **************************************************************************/
1484 
1485 static void endofCoIm(FICL_VM *pVM)
1486 {
1487     CELL *patchAddr;
1488     FICL_UNS fixupCount;
1489     FICL_INT offset;
1490     FICL_DICT *dp = vmGetDict(pVM);
1491 
1492 #if FICL_ROBUST > 1
1493     vmCheckStack(pVM, 4, 3);
1494 #endif
1495 
1496     assert(pVM->pSys->pBranchParen);
1497 
1498 	/* ensure we're in an OF, */
1499     matchControlTag(pVM, ofTag);
1500 	/* grab the address of the branch location after the OF */
1501     patchAddr = (CELL *)stackPopPtr(pVM->pStack);
1502 	/* ensure we're also in a "case" */
1503     matchControlTag(pVM, caseTag);
1504 	/* grab the current number of ENDOF fixups */
1505 	fixupCount = POPUNS();
1506 
1507     /* compile branch runtime */
1508     dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pBranchParen));
1509 
1510 	/* push a new ENDOF fixup, the updated count of ENDOF fixups, and the caseTag */
1511     PUSHPTR(dp->here);
1512     PUSHUNS(fixupCount + 1);
1513 	markControlTag(pVM, caseTag);
1514 
1515 	/* reserve space for the ENDOF fixup */
1516     dictAppendUNS(dp, 2);
1517 
1518 	/* and patch the original OF */
1519     offset = dp->here - patchAddr;
1520     *patchAddr = LVALUEtoCELL(offset);
1521 }
1522 
1523 
1524 /**************************************************************************
1525                     f a l l t h r o u g h C o I m
1526 ** IMMEDIATE COMPILE-ONLY
1527 **************************************************************************/
1528 
1529 static void fallthroughCoIm(FICL_VM *pVM)
1530 {
1531     CELL *patchAddr;
1532     FICL_INT offset;
1533     FICL_DICT *dp = vmGetDict(pVM);
1534 
1535 #if FICL_ROBUST > 1
1536     vmCheckStack(pVM, 4, 3);
1537 #endif
1538 
1539 	/* ensure we're in an OF, */
1540     matchControlTag(pVM, ofTag);
1541 	/* grab the address of the branch location after the OF */
1542     patchAddr = (CELL *)stackPopPtr(pVM->pStack);
1543 	/* ensure we're also in a "case" */
1544     matchControlTag(pVM, caseTag);
1545 
1546 	/* okay, here we go.  put the case tag back. */
1547 	markControlTag(pVM, caseTag);
1548 
1549     /* compile branch runtime */
1550     dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pBranchParen));
1551 
1552 	/* push a new FALLTHROUGH fixup and the fallthroughTag */
1553     PUSHPTR(dp->here);
1554 	markControlTag(pVM, fallthroughTag);
1555 
1556 	/* reserve space for the FALLTHROUGH fixup */
1557     dictAppendUNS(dp, 2);
1558 
1559 	/* and patch the original OF */
1560     offset = dp->here - patchAddr;
1561     *patchAddr = LVALUEtoCELL(offset);
1562 }
1563 
1564 /**************************************************************************
1565                         h a s h
1566 ** hash ( c-addr u -- code)
1567 ** calculates hashcode of specified string and leaves it on the stack
1568 **************************************************************************/
1569 
1570 static void hash(FICL_VM *pVM)
1571 {
1572     STRINGINFO si;
1573     SI_SETLEN(si, stackPopUNS(pVM->pStack));
1574     SI_SETPTR(si, stackPopPtr(pVM->pStack));
1575     PUSHUNS(hashHashCode(si));
1576     return;
1577 }
1578 
1579 
1580 /**************************************************************************
1581                         i n t e r p r e t
1582 ** This is the "user interface" of a Forth. It does the following:
1583 **   while there are words in the VM's Text Input Buffer
1584 **     Copy next word into the pad (vmGetWord)
1585 **     Attempt to find the word in the dictionary (dictLookup)
1586 **     If successful, execute the word.
1587 **     Otherwise, attempt to convert the word to a number (isNumber)
1588 **     If successful, push the number onto the parameter stack.
1589 **     Otherwise, print an error message and exit loop...
1590 **   End Loop
1591 **
1592 ** From the standard, section 3.4
1593 ** Text interpretation (see 6.1.1360 EVALUATE and 6.1.2050 QUIT) shall
1594 ** repeat the following steps until either the parse area is empty or an
1595 ** ambiguous condition exists:
1596 ** a) Skip leading spaces and parse a name (see 3.4.1);
1597 **************************************************************************/
1598 
1599 static void interpret(FICL_VM *pVM)
1600 {
1601     STRINGINFO si;
1602     int i;
1603     FICL_SYSTEM *pSys;
1604 
1605     assert(pVM);
1606 
1607     pSys = pVM->pSys;
1608     si   = vmGetWord0(pVM);
1609 
1610     /*
1611     ** Get next word...if out of text, we're done.
1612     */
1613     if (si.count == 0)
1614     {
1615         vmThrow(pVM, VM_OUTOFTEXT);
1616     }
1617 
1618     /*
1619     ** Attempt to find the incoming token in the dictionary. If that fails...
1620     ** run the parse chain against the incoming token until somebody eats it.
1621     ** Otherwise emit an error message and give up.
1622     ** Although ficlParseWord could be part of the parse list, I've hard coded it
1623     ** in for robustness. ficlInitSystem adds the other default steps to the list.
1624     */
1625     if (ficlParseWord(pVM, si))
1626         return;
1627 
1628     for (i=0; i < FICL_MAX_PARSE_STEPS; i++)
1629     {
1630         FICL_WORD *pFW = pSys->parseList[i];
1631 
1632         if (pFW == NULL)
1633             break;
1634 
1635         if (pFW->code == parseStepParen)
1636         {
1637             FICL_PARSE_STEP pStep;
1638             pStep = (FICL_PARSE_STEP)(pFW->param->fn);
1639             if ((*pStep)(pVM, si))
1640                 return;
1641         }
1642         else
1643         {
1644             stackPushPtr(pVM->pStack, SI_PTR(si));
1645             stackPushUNS(pVM->pStack, SI_COUNT(si));
1646             ficlExecXT(pVM, pFW);
1647             if (stackPopINT(pVM->pStack))
1648                 return;
1649         }
1650     }
1651 
1652     i = SI_COUNT(si);
1653     vmThrowErr(pVM, "%.*s not found", i, SI_PTR(si));
1654 
1655     return;                 /* back to inner interpreter */
1656 }
1657 
1658 
1659 /**************************************************************************
1660                         f i c l P a r s e W o r d
1661 ** From the standard, section 3.4
1662 ** b) Search the dictionary name space (see 3.4.2). If a definition name
1663 ** matching the string is found:
1664 **  1.if interpreting, perform the interpretation semantics of the definition
1665 **  (see 3.4.3.2), and continue at a);
1666 **  2.if compiling, perform the compilation semantics of the definition
1667 **  (see 3.4.3.3), and continue at a).
1668 **
1669 ** c) If a definition name matching the string is not found, attempt to
1670 ** convert the string to a number (see 3.4.1.3). If successful:
1671 **  1.if interpreting, place the number on the data stack, and continue at a);
1672 **  2.if compiling, compile code that when executed will place the number on
1673 **  the stack (see 6.1.1780 LITERAL), and continue at a);
1674 **
1675 ** d) If unsuccessful, an ambiguous condition exists (see 3.4.4).
1676 **
1677 ** (jws 4/01) Modified to be a FICL_PARSE_STEP
1678 **************************************************************************/
1679 static int ficlParseWord(FICL_VM *pVM, STRINGINFO si)
1680 {
1681     FICL_DICT *dp = vmGetDict(pVM);
1682     FICL_WORD *tempFW;
1683 
1684 #if FICL_ROBUST
1685     dictCheck(dp, pVM, 0);
1686     vmCheckStack(pVM, 0, 0);
1687 #endif
1688 
1689 #if FICL_WANT_LOCALS
1690     if (pVM->pSys->nLocals > 0)
1691     {
1692         tempFW = ficlLookupLoc(pVM->pSys, si);
1693     }
1694     else
1695 #endif
1696     tempFW = dictLookup(dp, si);
1697 
1698     if (pVM->state == INTERPRET)
1699     {
1700         if (tempFW != NULL)
1701         {
1702             if (wordIsCompileOnly(tempFW))
1703             {
1704                 vmThrowErr(pVM, "Error: Compile only!");
1705             }
1706 
1707             vmExecute(pVM, tempFW);
1708             return (int)FICL_TRUE;
1709         }
1710     }
1711 
1712     else /* (pVM->state == COMPILE) */
1713     {
1714         if (tempFW != NULL)
1715         {
1716             if (wordIsImmediate(tempFW))
1717             {
1718                 vmExecute(pVM, tempFW);
1719             }
1720             else
1721             {
1722                 dictAppendCell(dp, LVALUEtoCELL(tempFW));
1723             }
1724             return (int)FICL_TRUE;
1725         }
1726     }
1727 
1728     return FICL_FALSE;
1729 }
1730 
1731 
1732 /*
1733 ** Surrogate precompiled parse step for ficlParseWord (this step is hard coded in
1734 ** INTERPRET)
1735 */
1736 static void lookup(FICL_VM *pVM)
1737 {
1738     STRINGINFO si;
1739     SI_SETLEN(si, stackPopUNS(pVM->pStack));
1740     SI_SETPTR(si, stackPopPtr(pVM->pStack));
1741     stackPushINT(pVM->pStack, ficlParseWord(pVM, si));
1742     return;
1743 }
1744 
1745 
1746 /**************************************************************************
1747                         p a r e n P a r s e S t e p
1748 ** (parse-step)  ( c-addr u -- flag )
1749 ** runtime for a precompiled parse step - pop a counted string off the
1750 ** stack, run the parse step against it, and push the result flag (FICL_TRUE
1751 ** if success, FICL_FALSE otherwise).
1752 **************************************************************************/
1753 
1754 void parseStepParen(FICL_VM *pVM)
1755 {
1756     STRINGINFO si;
1757     FICL_WORD *pFW = pVM->runningWord;
1758     FICL_PARSE_STEP pStep = (FICL_PARSE_STEP)(pFW->param->fn);
1759 
1760     SI_SETLEN(si, stackPopINT(pVM->pStack));
1761     SI_SETPTR(si, stackPopPtr(pVM->pStack));
1762 
1763     PUSHINT((*pStep)(pVM, si));
1764 
1765     return;
1766 }
1767 
1768 
1769 static void addParseStep(FICL_VM *pVM)
1770 {
1771     FICL_WORD *pStep;
1772     FICL_DICT *pd = vmGetDict(pVM);
1773 #if FICL_ROBUST > 1
1774     vmCheckStack(pVM, 1, 0);
1775 #endif
1776     pStep = (FICL_WORD *)(stackPop(pVM->pStack).p);
1777     if ((pStep != NULL) && isAFiclWord(pd, pStep))
1778         ficlAddParseStep(pVM->pSys, pStep);
1779     return;
1780 }
1781 
1782 
1783 /**************************************************************************
1784                         l i t e r a l P a r e n
1785 **
1786 ** This is the runtime for (literal). It assumes that it is part of a colon
1787 ** definition, and that the next CELL contains a value to be pushed on the
1788 ** parameter stack at runtime. This code is compiled by "literal".
1789 **
1790 **************************************************************************/
1791 
1792 static void literalParen(FICL_VM *pVM)
1793 {
1794 #if FICL_ROBUST > 1
1795     vmCheckStack(pVM, 0, 1);
1796 #endif
1797     PUSHINT(*(FICL_INT *)(pVM->ip));
1798     vmBranchRelative(pVM, 1);
1799     return;
1800 }
1801 
1802 static void twoLitParen(FICL_VM *pVM)
1803 {
1804 #if FICL_ROBUST > 1
1805     vmCheckStack(pVM, 0, 2);
1806 #endif
1807     PUSHINT(*((FICL_INT *)(pVM->ip)+1));
1808     PUSHINT(*(FICL_INT *)(pVM->ip));
1809     vmBranchRelative(pVM, 2);
1810     return;
1811 }
1812 
1813 
1814 /**************************************************************************
1815                         l i t e r a l I m
1816 **
1817 ** IMMEDIATE code for "literal". This function gets a value from the stack
1818 ** and compiles it into the dictionary preceded by the code for "(literal)".
1819 ** IMMEDIATE
1820 **************************************************************************/
1821 
1822 static void literalIm(FICL_VM *pVM)
1823 {
1824     FICL_DICT *dp = vmGetDict(pVM);
1825     assert(pVM->pSys->pLitParen);
1826 
1827     dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pLitParen));
1828     dictAppendCell(dp, stackPop(pVM->pStack));
1829 
1830     return;
1831 }
1832 
1833 
1834 static void twoLiteralIm(FICL_VM *pVM)
1835 {
1836     FICL_DICT *dp = vmGetDict(pVM);
1837     assert(pVM->pSys->pTwoLitParen);
1838 
1839     dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pTwoLitParen));
1840     dictAppendCell(dp, stackPop(pVM->pStack));
1841     dictAppendCell(dp, stackPop(pVM->pStack));
1842 
1843     return;
1844 }
1845 
1846 /**************************************************************************
1847                         l o g i c   a n d   c o m p a r i s o n s
1848 **
1849 **************************************************************************/
1850 
1851 static void zeroEquals(FICL_VM *pVM)
1852 {
1853     CELL c;
1854 #if FICL_ROBUST > 1
1855     vmCheckStack(pVM, 1, 1);
1856 #endif
1857     c.i = FICL_BOOL(stackPopINT(pVM->pStack) == 0);
1858     stackPush(pVM->pStack, c);
1859     return;
1860 }
1861 
1862 static void zeroLess(FICL_VM *pVM)
1863 {
1864     CELL c;
1865 #if FICL_ROBUST > 1
1866     vmCheckStack(pVM, 1, 1);
1867 #endif
1868     c.i = FICL_BOOL(stackPopINT(pVM->pStack) < 0);
1869     stackPush(pVM->pStack, c);
1870     return;
1871 }
1872 
1873 static void zeroGreater(FICL_VM *pVM)
1874 {
1875     CELL c;
1876 #if FICL_ROBUST > 1
1877     vmCheckStack(pVM, 1, 1);
1878 #endif
1879     c.i = FICL_BOOL(stackPopINT(pVM->pStack) > 0);
1880     stackPush(pVM->pStack, c);
1881     return;
1882 }
1883 
1884 static void isEqual(FICL_VM *pVM)
1885 {
1886     CELL x, y;
1887 
1888 #if FICL_ROBUST > 1
1889     vmCheckStack(pVM, 2, 1);
1890 #endif
1891     x = stackPop(pVM->pStack);
1892     y = stackPop(pVM->pStack);
1893     PUSHINT(FICL_BOOL(x.i == y.i));
1894     return;
1895 }
1896 
1897 static void isLess(FICL_VM *pVM)
1898 {
1899     CELL x, y;
1900 #if FICL_ROBUST > 1
1901     vmCheckStack(pVM, 2, 1);
1902 #endif
1903     y = stackPop(pVM->pStack);
1904     x = stackPop(pVM->pStack);
1905     PUSHINT(FICL_BOOL(x.i < y.i));
1906     return;
1907 }
1908 
1909 static void uIsLess(FICL_VM *pVM)
1910 {
1911     FICL_UNS u1, u2;
1912 #if FICL_ROBUST > 1
1913     vmCheckStack(pVM, 2, 1);
1914 #endif
1915     u2 = stackPopUNS(pVM->pStack);
1916     u1 = stackPopUNS(pVM->pStack);
1917     PUSHINT(FICL_BOOL(u1 < u2));
1918     return;
1919 }
1920 
1921 static void isGreater(FICL_VM *pVM)
1922 {
1923     CELL x, y;
1924 #if FICL_ROBUST > 1
1925     vmCheckStack(pVM, 2, 1);
1926 #endif
1927     y = stackPop(pVM->pStack);
1928     x = stackPop(pVM->pStack);
1929     PUSHINT(FICL_BOOL(x.i > y.i));
1930     return;
1931 }
1932 
1933 static void bitwiseAnd(FICL_VM *pVM)
1934 {
1935     CELL x, y;
1936 #if FICL_ROBUST > 1
1937     vmCheckStack(pVM, 2, 1);
1938 #endif
1939     x = stackPop(pVM->pStack);
1940     y = stackPop(pVM->pStack);
1941     PUSHINT(x.i & y.i);
1942     return;
1943 }
1944 
1945 static void bitwiseOr(FICL_VM *pVM)
1946 {
1947     CELL x, y;
1948 #if FICL_ROBUST > 1
1949     vmCheckStack(pVM, 2, 1);
1950 #endif
1951     x = stackPop(pVM->pStack);
1952     y = stackPop(pVM->pStack);
1953     PUSHINT(x.i | y.i);
1954     return;
1955 }
1956 
1957 static void bitwiseXor(FICL_VM *pVM)
1958 {
1959     CELL x, y;
1960 #if FICL_ROBUST > 1
1961     vmCheckStack(pVM, 2, 1);
1962 #endif
1963     x = stackPop(pVM->pStack);
1964     y = stackPop(pVM->pStack);
1965     PUSHINT(x.i ^ y.i);
1966     return;
1967 }
1968 
1969 static void bitwiseNot(FICL_VM *pVM)
1970 {
1971     CELL x;
1972 #if FICL_ROBUST > 1
1973     vmCheckStack(pVM, 1, 1);
1974 #endif
1975     x = stackPop(pVM->pStack);
1976     PUSHINT(~x.i);
1977     return;
1978 }
1979 
1980 
1981 /**************************************************************************
1982                                D o  /  L o o p
1983 ** do -- IMMEDIATE COMPILE ONLY
1984 **    Compiles code to initialize a loop: compile (do),
1985 **    allot space to hold the "leave" address, push a branch
1986 **    target address for the loop.
1987 ** (do) -- runtime for "do"
1988 **    pops index and limit from the p stack and moves them
1989 **    to the r stack, then skips to the loop body.
1990 ** loop -- IMMEDIATE COMPILE ONLY
1991 ** +loop
1992 **    Compiles code for the test part of a loop:
1993 **    compile (loop), resolve forward branch from "do", and
1994 **    copy "here" address to the "leave" address allotted by "do"
1995 ** i,j,k -- COMPILE ONLY
1996 **    Runtime: Push loop indices on param stack (i is innermost loop...)
1997 **    Note: each loop has three values on the return stack:
1998 **    ( R: leave limit index )
1999 **    "leave" is the absolute address of the next cell after the loop
2000 **    limit and index are the loop control variables.
2001 ** leave -- COMPILE ONLY
2002 **    Runtime: pop the loop control variables, then pop the
2003 **    "leave" address and jump (absolute) there.
2004 **************************************************************************/
2005 
2006 static void doCoIm(FICL_VM *pVM)
2007 {
2008     FICL_DICT *dp = vmGetDict(pVM);
2009 
2010     assert(pVM->pSys->pDoParen);
2011 
2012     dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pDoParen));
2013     /*
2014     ** Allot space for a pointer to the end
2015     ** of the loop - "leave" uses this...
2016     */
2017     markBranch(dp, pVM, leaveTag);
2018     dictAppendUNS(dp, 0);
2019     /*
2020     ** Mark location of head of loop...
2021     */
2022     markBranch(dp, pVM, doTag);
2023 
2024     return;
2025 }
2026 
2027 
2028 static void doParen(FICL_VM *pVM)
2029 {
2030     CELL index, limit;
2031 #if FICL_ROBUST > 1
2032     vmCheckStack(pVM, 2, 0);
2033 #endif
2034     index = stackPop(pVM->pStack);
2035     limit = stackPop(pVM->pStack);
2036 
2037     /* copy "leave" target addr to stack */
2038     stackPushPtr(pVM->rStack, *(pVM->ip++));
2039     stackPush(pVM->rStack, limit);
2040     stackPush(pVM->rStack, index);
2041 
2042     return;
2043 }
2044 
2045 
2046 static void qDoCoIm(FICL_VM *pVM)
2047 {
2048     FICL_DICT *dp = vmGetDict(pVM);
2049 
2050     assert(pVM->pSys->pQDoParen);
2051 
2052     dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pQDoParen));
2053     /*
2054     ** Allot space for a pointer to the end
2055     ** of the loop - "leave" uses this...
2056     */
2057     markBranch(dp, pVM, leaveTag);
2058     dictAppendUNS(dp, 0);
2059     /*
2060     ** Mark location of head of loop...
2061     */
2062     markBranch(dp, pVM, doTag);
2063 
2064     return;
2065 }
2066 
2067 
2068 static void qDoParen(FICL_VM *pVM)
2069 {
2070     CELL index, limit;
2071 #if FICL_ROBUST > 1
2072     vmCheckStack(pVM, 2, 0);
2073 #endif
2074     index = stackPop(pVM->pStack);
2075     limit = stackPop(pVM->pStack);
2076 
2077     /* copy "leave" target addr to stack */
2078     stackPushPtr(pVM->rStack, *(pVM->ip++));
2079 
2080     if (limit.u == index.u)
2081     {
2082         vmPopIP(pVM);
2083     }
2084     else
2085     {
2086         stackPush(pVM->rStack, limit);
2087         stackPush(pVM->rStack, index);
2088     }
2089 
2090     return;
2091 }
2092 
2093 
2094 /*
2095 ** Runtime code to break out of a do..loop construct
2096 ** Drop the loop control variables; the branch address
2097 ** past "loop" is next on the return stack.
2098 */
2099 static void leaveCo(FICL_VM *pVM)
2100 {
2101     /* almost unloop */
2102     stackDrop(pVM->rStack, 2);
2103     /* exit */
2104     vmPopIP(pVM);
2105     return;
2106 }
2107 
2108 
2109 static void unloopCo(FICL_VM *pVM)
2110 {
2111     stackDrop(pVM->rStack, 3);
2112     return;
2113 }
2114 
2115 
2116 static void loopCoIm(FICL_VM *pVM)
2117 {
2118     FICL_DICT *dp = vmGetDict(pVM);
2119 
2120     assert(pVM->pSys->pLoopParen);
2121 
2122     dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pLoopParen));
2123     resolveBackBranch(dp, pVM, doTag);
2124     resolveAbsBranch(dp, pVM, leaveTag);
2125     return;
2126 }
2127 
2128 
2129 static void plusLoopCoIm(FICL_VM *pVM)
2130 {
2131     FICL_DICT *dp = vmGetDict(pVM);
2132 
2133     assert(pVM->pSys->pPLoopParen);
2134 
2135     dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pPLoopParen));
2136     resolveBackBranch(dp, pVM, doTag);
2137     resolveAbsBranch(dp, pVM, leaveTag);
2138     return;
2139 }
2140 
2141 
2142 static void loopParen(FICL_VM *pVM)
2143 {
2144     FICL_INT index = stackGetTop(pVM->rStack).i;
2145     FICL_INT limit = stackFetch(pVM->rStack, 1).i;
2146 
2147     index++;
2148 
2149     if (index >= limit)
2150     {
2151         stackDrop(pVM->rStack, 3); /* nuke the loop indices & "leave" addr */
2152         vmBranchRelative(pVM, 1);  /* fall through the loop */
2153     }
2154     else
2155     {                       /* update index, branch to loop head */
2156         stackSetTop(pVM->rStack, LVALUEtoCELL(index));
2157         vmBranchRelative(pVM, (uintptr_t)*(pVM->ip));
2158     }
2159 
2160     return;
2161 }
2162 
2163 
2164 static void plusLoopParen(FICL_VM *pVM)
2165 {
2166     FICL_INT index,limit,increment;
2167     int flag;
2168 
2169 #if FICL_ROBUST > 1
2170     vmCheckStack(pVM, 1, 0);
2171 #endif
2172 
2173     index = stackGetTop(pVM->rStack).i;
2174     limit = stackFetch(pVM->rStack, 1).i;
2175     increment = POP().i;
2176 
2177     index += increment;
2178 
2179     if (increment < 0)
2180         flag = (index < limit);
2181     else
2182         flag = (index >= limit);
2183 
2184     if (flag)
2185     {
2186         stackDrop(pVM->rStack, 3); /* nuke the loop indices & "leave" addr */
2187         vmBranchRelative(pVM, 1);  /* fall through the loop */
2188     }
2189     else
2190     {                       /* update index, branch to loop head */
2191         stackSetTop(pVM->rStack, LVALUEtoCELL(index));
2192         vmBranchRelative(pVM, (uintptr_t)*(pVM->ip));
2193     }
2194 
2195     return;
2196 }
2197 
2198 
2199 static void loopICo(FICL_VM *pVM)
2200 {
2201     CELL index = stackGetTop(pVM->rStack);
2202     stackPush(pVM->pStack, index);
2203 
2204     return;
2205 }
2206 
2207 
2208 static void loopJCo(FICL_VM *pVM)
2209 {
2210     CELL index = stackFetch(pVM->rStack, 3);
2211     stackPush(pVM->pStack, index);
2212 
2213     return;
2214 }
2215 
2216 
2217 static void loopKCo(FICL_VM *pVM)
2218 {
2219     CELL index = stackFetch(pVM->rStack, 6);
2220     stackPush(pVM->pStack, index);
2221 
2222     return;
2223 }
2224 
2225 
2226 /**************************************************************************
2227                         r e t u r n   s t a c k
2228 **
2229 **************************************************************************/
2230 static void toRStack(FICL_VM *pVM)
2231 {
2232 #if FICL_ROBUST > 1
2233     vmCheckStack(pVM, 1, 0);
2234 #endif
2235 
2236     stackPush(pVM->rStack, POP());
2237 }
2238 
2239 static void fromRStack(FICL_VM *pVM)
2240 {
2241 #if FICL_ROBUST > 1
2242     vmCheckStack(pVM, 0, 1);
2243 #endif
2244 
2245     PUSH(stackPop(pVM->rStack));
2246 }
2247 
2248 static void fetchRStack(FICL_VM *pVM)
2249 {
2250 #if FICL_ROBUST > 1
2251     vmCheckStack(pVM, 0, 1);
2252 #endif
2253 
2254     PUSH(stackGetTop(pVM->rStack));
2255 }
2256 
2257 static void twoToR(FICL_VM *pVM)
2258 {
2259 #if FICL_ROBUST > 1
2260     vmCheckStack(pVM, 2, 0);
2261 #endif
2262     stackRoll(pVM->pStack, 1);
2263     stackPush(pVM->rStack, stackPop(pVM->pStack));
2264     stackPush(pVM->rStack, stackPop(pVM->pStack));
2265     return;
2266 }
2267 
2268 static void twoRFrom(FICL_VM *pVM)
2269 {
2270 #if FICL_ROBUST > 1
2271     vmCheckStack(pVM, 0, 2);
2272 #endif
2273     stackPush(pVM->pStack, stackPop(pVM->rStack));
2274     stackPush(pVM->pStack, stackPop(pVM->rStack));
2275     stackRoll(pVM->pStack, 1);
2276     return;
2277 }
2278 
2279 static void twoRFetch(FICL_VM *pVM)
2280 {
2281 #if FICL_ROBUST > 1
2282     vmCheckStack(pVM, 0, 2);
2283 #endif
2284     stackPush(pVM->pStack, stackFetch(pVM->rStack, 1));
2285     stackPush(pVM->pStack, stackFetch(pVM->rStack, 0));
2286     return;
2287 }
2288 
2289 
2290 /**************************************************************************
2291                         v a r i a b l e
2292 **
2293 **************************************************************************/
2294 
2295 static void variableParen(FICL_VM *pVM)
2296 {
2297     FICL_WORD *fw;
2298 #if FICL_ROBUST > 1
2299     vmCheckStack(pVM, 0, 1);
2300 #endif
2301 
2302     fw = pVM->runningWord;
2303     PUSHPTR(fw->param);
2304 }
2305 
2306 
2307 static void variable(FICL_VM *pVM)
2308 {
2309     FICL_DICT *dp = vmGetDict(pVM);
2310     STRINGINFO si = vmGetWord(pVM);
2311 
2312     dictAppendWord2(dp, si, variableParen, FW_DEFAULT);
2313     dictAllotCells(dp, 1);
2314     return;
2315 }
2316 
2317 
2318 static void twoVariable(FICL_VM *pVM)
2319 {
2320     FICL_DICT *dp = vmGetDict(pVM);
2321     STRINGINFO si = vmGetWord(pVM);
2322 
2323     dictAppendWord2(dp, si, variableParen, FW_DEFAULT);
2324     dictAllotCells(dp, 2);
2325     return;
2326 }
2327 
2328 
2329 /**************************************************************************
2330                         b a s e   &   f r i e n d s
2331 **
2332 **************************************************************************/
2333 
2334 static void base(FICL_VM *pVM)
2335 {
2336     CELL *pBase;
2337 #if FICL_ROBUST > 1
2338     vmCheckStack(pVM, 0, 1);
2339 #endif
2340 
2341     pBase = (CELL *)(&pVM->base);
2342     stackPush(pVM->pStack, LVALUEtoCELL(pBase));
2343     return;
2344 }
2345 
2346 
2347 static void decimal(FICL_VM *pVM)
2348 {
2349     pVM->base = 10;
2350     return;
2351 }
2352 
2353 
2354 static void hex(FICL_VM *pVM)
2355 {
2356     pVM->base = 16;
2357     return;
2358 }
2359 
2360 
2361 /**************************************************************************
2362                         a l l o t   &   f r i e n d s
2363 **
2364 **************************************************************************/
2365 
2366 static void allot(FICL_VM *pVM)
2367 {
2368     FICL_DICT *dp;
2369     FICL_INT i;
2370 #if FICL_ROBUST > 1
2371     vmCheckStack(pVM, 1, 0);
2372 #endif
2373 
2374     dp = vmGetDict(pVM);
2375     i = POPINT();
2376 
2377 #if FICL_ROBUST
2378     dictCheck(dp, pVM, i);
2379 #endif
2380 
2381     dictAllot(dp, i);
2382     return;
2383 }
2384 
2385 
2386 static void here(FICL_VM *pVM)
2387 {
2388     FICL_DICT *dp;
2389 #if FICL_ROBUST > 1
2390     vmCheckStack(pVM, 0, 1);
2391 #endif
2392 
2393     dp = vmGetDict(pVM);
2394     PUSHPTR(dp->here);
2395     return;
2396 }
2397 
2398 static void comma(FICL_VM *pVM)
2399 {
2400     FICL_DICT *dp;
2401     CELL c;
2402 #if FICL_ROBUST > 1
2403     vmCheckStack(pVM, 1, 0);
2404 #endif
2405 
2406     dp = vmGetDict(pVM);
2407     c = POP();
2408     dictAppendCell(dp, c);
2409     return;
2410 }
2411 
2412 static void cComma(FICL_VM *pVM)
2413 {
2414     FICL_DICT *dp;
2415     char c;
2416 #if FICL_ROBUST > 1
2417     vmCheckStack(pVM, 1, 0);
2418 #endif
2419 
2420     dp = vmGetDict(pVM);
2421     c = (char)POPINT();
2422     dictAppendChar(dp, c);
2423     return;
2424 }
2425 
2426 static void cells(FICL_VM *pVM)
2427 {
2428     FICL_INT i;
2429 #if FICL_ROBUST > 1
2430     vmCheckStack(pVM, 1, 1);
2431 #endif
2432 
2433     i = POPINT();
2434     PUSHINT(i * (FICL_INT)sizeof (CELL));
2435     return;
2436 }
2437 
2438 static void cellPlus(FICL_VM *pVM)
2439 {
2440     char *cp;
2441 #if FICL_ROBUST > 1
2442     vmCheckStack(pVM, 1, 1);
2443 #endif
2444 
2445     cp = POPPTR();
2446     PUSHPTR(cp + sizeof (CELL));
2447     return;
2448 }
2449 
2450 
2451 
2452 /**************************************************************************
2453                         t i c k
2454 ** tick         CORE ( "<spaces>name" -- xt )
2455 ** Skip leading space delimiters. Parse name delimited by a space. Find
2456 ** name and return xt, the execution token for name. An ambiguous condition
2457 ** exists if name is not found.
2458 **************************************************************************/
2459 void ficlTick(FICL_VM *pVM)
2460 {
2461     FICL_WORD *pFW = NULL;
2462     STRINGINFO si = vmGetWord(pVM);
2463 #if FICL_ROBUST > 1
2464     vmCheckStack(pVM, 0, 1);
2465 #endif
2466 
2467     pFW = dictLookup(vmGetDict(pVM), si);
2468     if (!pFW)
2469     {
2470         int i = SI_COUNT(si);
2471         vmThrowErr(pVM, "%.*s not found", i, SI_PTR(si));
2472     }
2473     PUSHPTR(pFW);
2474     return;
2475 }
2476 
2477 
2478 static void bracketTickCoIm(FICL_VM *pVM)
2479 {
2480     ficlTick(pVM);
2481     literalIm(pVM);
2482 
2483     return;
2484 }
2485 
2486 
2487 /**************************************************************************
2488                         p o s t p o n e
2489 ** Lookup the next word in the input stream and compile code to
2490 ** insert it into definitions created by the resulting word
2491 ** (defers compilation, even of immediate words)
2492 **************************************************************************/
2493 
2494 static void postponeCoIm(FICL_VM *pVM)
2495 {
2496     FICL_DICT *dp  = vmGetDict(pVM);
2497     FICL_WORD *pFW;
2498     FICL_WORD *pComma = ficlLookup(pVM->pSys, ",");
2499     assert(pComma);
2500 
2501     ficlTick(pVM);
2502     pFW = stackGetTop(pVM->pStack).p;
2503     if (wordIsImmediate(pFW))
2504     {
2505         dictAppendCell(dp, stackPop(pVM->pStack));
2506     }
2507     else
2508     {
2509         literalIm(pVM);
2510         dictAppendCell(dp, LVALUEtoCELL(pComma));
2511     }
2512 
2513     return;
2514 }
2515 
2516 
2517 
2518 /**************************************************************************
2519                         e x e c u t e
2520 ** Pop an execution token (pointer to a word) off the stack and
2521 ** run it
2522 **************************************************************************/
2523 
2524 static void execute(FICL_VM *pVM)
2525 {
2526     FICL_WORD *pFW;
2527 #if FICL_ROBUST > 1
2528     vmCheckStack(pVM, 1, 0);
2529 #endif
2530 
2531     pFW = stackPopPtr(pVM->pStack);
2532     vmExecute(pVM, pFW);
2533 
2534     return;
2535 }
2536 
2537 
2538 /**************************************************************************
2539                         i m m e d i a t e
2540 ** Make the most recently compiled word IMMEDIATE -- it executes even
2541 ** in compile state (most often used for control compiling words
2542 ** such as IF, THEN, etc)
2543 **************************************************************************/
2544 
2545 static void immediate(FICL_VM *pVM)
2546 {
2547     IGNORE(pVM);
2548     dictSetImmediate(vmGetDict(pVM));
2549     return;
2550 }
2551 
2552 
2553 static void compileOnly(FICL_VM *pVM)
2554 {
2555     IGNORE(pVM);
2556     dictSetFlags(vmGetDict(pVM), FW_COMPILE, 0);
2557     return;
2558 }
2559 
2560 
2561 static void setObjectFlag(FICL_VM *pVM)
2562 {
2563     IGNORE(pVM);
2564     dictSetFlags(vmGetDict(pVM), FW_ISOBJECT, 0);
2565     return;
2566 }
2567 
2568 static void isObject(FICL_VM *pVM)
2569 {
2570     FICL_INT flag;
2571     FICL_WORD *pFW = (FICL_WORD *)stackPopPtr(pVM->pStack);
2572 
2573     flag = ((pFW != NULL) && (pFW->flags & FW_ISOBJECT)) ? FICL_TRUE : FICL_FALSE;
2574     stackPushINT(pVM->pStack, flag);
2575     return;
2576 }
2577 
2578 static void cstringLit(FICL_VM *pVM)
2579 {
2580     FICL_STRING *sp = (FICL_STRING *)(pVM->ip);
2581 
2582     char *cp = sp->text;
2583     cp += sp->count + 1;
2584     cp = alignPtr(cp);
2585     pVM->ip = (IPTYPE)(void *)cp;
2586 
2587     stackPushPtr(pVM->pStack, sp);
2588     return;
2589 }
2590 
2591 
2592 static void cstringQuoteIm(FICL_VM *pVM)
2593 {
2594     FICL_DICT *dp = vmGetDict(pVM);
2595 
2596     if (pVM->state == INTERPRET)
2597     {
2598         FICL_STRING *sp = (FICL_STRING *) dp->here;
2599         vmGetString(pVM, sp, '\"');
2600         stackPushPtr(pVM->pStack, sp);
2601 		/* move HERE past string so it doesn't get overwritten.  --lch */
2602 		dictAllot(dp, sp->count + sizeof(FICL_COUNT));
2603     }
2604     else    /* COMPILE state */
2605     {
2606         dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pCStringLit));
2607         dp->here = PTRtoCELL vmGetString(pVM, (FICL_STRING *)dp->here, '\"');
2608         dictAlign(dp);
2609     }
2610 
2611     return;
2612 }
2613 
2614 /**************************************************************************
2615                         d o t Q u o t e
2616 ** IMMEDIATE word that compiles a string literal for later display
2617 ** Compile stringLit, then copy the bytes of the string from the TIB
2618 ** to the dictionary. Backpatch the count byte and align the dictionary.
2619 **
2620 ** stringlit: Fetch the count from the dictionary, then push the address
2621 ** and count on the stack. Finally, update ip to point to the first
2622 ** aligned address after the string text.
2623 **************************************************************************/
2624 
2625 static void stringLit(FICL_VM *pVM)
2626 {
2627     FICL_STRING *sp;
2628     FICL_COUNT count;
2629     char *cp;
2630 #if FICL_ROBUST > 1
2631     vmCheckStack(pVM, 0, 2);
2632 #endif
2633 
2634     sp = (FICL_STRING *)(pVM->ip);
2635     count = sp->count;
2636     cp = sp->text;
2637     PUSHPTR(cp);
2638     PUSHUNS(count);
2639     cp += count + 1;
2640     cp = alignPtr(cp);
2641     pVM->ip = (IPTYPE)(void *)cp;
2642 }
2643 
2644 static void dotQuoteCoIm(FICL_VM *pVM)
2645 {
2646     FICL_DICT *dp = vmGetDict(pVM);
2647     FICL_WORD *pType = ficlLookup(pVM->pSys, "type");
2648     assert(pType);
2649     dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pStringLit));
2650     dp->here = PTRtoCELL vmGetString(pVM, (FICL_STRING *)dp->here, '\"');
2651     dictAlign(dp);
2652     dictAppendCell(dp, LVALUEtoCELL(pType));
2653     return;
2654 }
2655 
2656 
2657 static void dotParen(FICL_VM *pVM)
2658 {
2659     char *pSrc      = vmGetInBuf(pVM);
2660     char *pEnd      = vmGetInBufEnd(pVM);
2661     char *pDest     = pVM->pad;
2662     char ch;
2663 
2664     /*
2665     ** Note: the standard does not want leading spaces skipped (apparently)
2666     */
2667     for (ch = *pSrc; (pEnd != pSrc) && (ch != ')'); ch = *++pSrc)
2668         *pDest++ = ch;
2669 
2670     *pDest = '\0';
2671     if ((pEnd != pSrc) && (ch == ')'))
2672         pSrc++;
2673 
2674     vmTextOut(pVM, pVM->pad, 0);
2675     vmUpdateTib(pVM, pSrc);
2676 
2677     return;
2678 }
2679 
2680 
2681 /**************************************************************************
2682                         s l i t e r a l
2683 ** STRING
2684 ** Interpretation: Interpretation semantics for this word are undefined.
2685 ** Compilation: ( c-addr1 u -- )
2686 ** Append the run-time semantics given below to the current definition.
2687 ** Run-time:       ( -- c-addr2 u )
2688 ** Return c-addr2 u describing a string consisting of the characters
2689 ** specified by c-addr1 u during compilation. A program shall not alter
2690 ** the returned string.
2691 **************************************************************************/
2692 static void sLiteralCoIm(FICL_VM *pVM)
2693 {
2694     FICL_DICT *dp;
2695     char *cp, *cpDest;
2696     FICL_UNS u;
2697 
2698 #if FICL_ROBUST > 1
2699     vmCheckStack(pVM, 2, 0);
2700 #endif
2701 
2702     dp = vmGetDict(pVM);
2703     u  = POPUNS();
2704     cp = POPPTR();
2705 
2706     dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pStringLit));
2707     cpDest    = (char *) dp->here;
2708     *cpDest++ = (char)   u;
2709 
2710     for (; u > 0; --u)
2711     {
2712         *cpDest++ = *cp++;
2713     }
2714 
2715     *cpDest++ = 0;
2716     dp->here = PTRtoCELL alignPtr(cpDest);
2717     return;
2718 }
2719 
2720 
2721 /**************************************************************************
2722                         s t a t e
2723 ** Return the address of the VM's state member (must be sized the
2724 ** same as a CELL for this reason)
2725 **************************************************************************/
2726 static void state(FICL_VM *pVM)
2727 {
2728 #if FICL_ROBUST > 1
2729     vmCheckStack(pVM, 0, 1);
2730 #endif
2731     PUSHPTR(&pVM->state);
2732     return;
2733 }
2734 
2735 
2736 /**************************************************************************
2737                         c r e a t e . . . d o e s >
2738 ** Make a new word in the dictionary with the run-time effect of
2739 ** a variable (push my address), but with extra space allotted
2740 ** for use by does> .
2741 **************************************************************************/
2742 
2743 static void createParen(FICL_VM *pVM)
2744 {
2745     CELL *pCell;
2746 
2747 #if FICL_ROBUST > 1
2748     vmCheckStack(pVM, 0, 1);
2749 #endif
2750 
2751     pCell = pVM->runningWord->param;
2752     PUSHPTR(pCell+1);
2753     return;
2754 }
2755 
2756 
2757 static void create(FICL_VM *pVM)
2758 {
2759     FICL_DICT *dp = vmGetDict(pVM);
2760     STRINGINFO si = vmGetWord(pVM);
2761 
2762     dictCheckThreshold(dp);
2763 
2764     dictAppendWord2(dp, si, createParen, FW_DEFAULT);
2765     dictAllotCells(dp, 1);
2766     return;
2767 }
2768 
2769 
2770 static void doDoes(FICL_VM *pVM)
2771 {
2772     CELL *pCell;
2773     IPTYPE tempIP;
2774 #if FICL_ROBUST > 1
2775     vmCheckStack(pVM, 0, 1);
2776 #endif
2777 
2778     pCell = pVM->runningWord->param;
2779     tempIP = (IPTYPE)((*pCell).p);
2780     PUSHPTR(pCell+1);
2781     vmPushIP(pVM, tempIP);
2782     return;
2783 }
2784 
2785 
2786 static void doesParen(FICL_VM *pVM)
2787 {
2788     FICL_DICT *dp = vmGetDict(pVM);
2789     dp->smudge->code = doDoes;
2790     dp->smudge->param[0] = LVALUEtoCELL(pVM->ip);
2791     vmPopIP(pVM);
2792     return;
2793 }
2794 
2795 
2796 static void doesCoIm(FICL_VM *pVM)
2797 {
2798     FICL_DICT *dp = vmGetDict(pVM);
2799 #if FICL_WANT_LOCALS
2800     assert(pVM->pSys->pUnLinkParen);
2801     if (pVM->pSys->nLocals > 0)
2802     {
2803         FICL_DICT *pLoc = ficlGetLoc(pVM->pSys);
2804         dictEmpty(pLoc, pLoc->pForthWords->size);
2805         dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pUnLinkParen));
2806     }
2807 
2808     pVM->pSys->nLocals = 0;
2809 #endif
2810     IGNORE(pVM);
2811 
2812     dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pDoesParen));
2813     return;
2814 }
2815 
2816 
2817 /**************************************************************************
2818                         t o   b o d y
2819 ** to-body      CORE ( xt -- a-addr )
2820 ** a-addr is the data-field address corresponding to xt. An ambiguous
2821 ** condition exists if xt is not for a word defined via CREATE.
2822 **************************************************************************/
2823 static void toBody(FICL_VM *pVM)
2824 {
2825     FICL_WORD *pFW;
2826 /*#$-GUY CHANGE: Added robustness.-$#*/
2827 #if FICL_ROBUST > 1
2828     vmCheckStack(pVM, 1, 1);
2829 #endif
2830 
2831     pFW = POPPTR();
2832     PUSHPTR(pFW->param + 1);
2833     return;
2834 }
2835 
2836 
2837 /*
2838 ** from-body       ficl ( a-addr -- xt )
2839 ** Reverse effect of >body
2840 */
2841 static void fromBody(FICL_VM *pVM)
2842 {
2843     char *ptr;
2844 #if FICL_ROBUST > 1
2845     vmCheckStack(pVM, 1, 1);
2846 #endif
2847 
2848     ptr = (char *)POPPTR() - sizeof (FICL_WORD);
2849     PUSHPTR(ptr);
2850     return;
2851 }
2852 
2853 
2854 /*
2855 ** >name        ficl ( xt -- c-addr u )
2856 ** Push the address and length of a word's name given its address
2857 ** xt.
2858 */
2859 static void toName(FICL_VM *pVM)
2860 {
2861     FICL_WORD *pFW;
2862 #if FICL_ROBUST > 1
2863     vmCheckStack(pVM, 1, 2);
2864 #endif
2865 
2866     pFW = POPPTR();
2867     PUSHPTR(pFW->name);
2868     PUSHUNS(pFW->nName);
2869     return;
2870 }
2871 
2872 
2873 static void getLastWord(FICL_VM *pVM)
2874 {
2875     FICL_DICT *pDict = vmGetDict(pVM);
2876     FICL_WORD *wp = pDict->smudge;
2877     assert(wp);
2878     vmPush(pVM, LVALUEtoCELL(wp));
2879     return;
2880 }
2881 
2882 
2883 /**************************************************************************
2884                         l b r a c k e t   e t c
2885 **
2886 **************************************************************************/
2887 
2888 static void lbracketCoIm(FICL_VM *pVM)
2889 {
2890     pVM->state = INTERPRET;
2891     return;
2892 }
2893 
2894 
2895 static void rbracket(FICL_VM *pVM)
2896 {
2897     pVM->state = COMPILE;
2898     return;
2899 }
2900 
2901 
2902 /**************************************************************************
2903                         p i c t u r e d   n u m e r i c   w o r d s
2904 **
2905 ** less-number-sign CORE ( -- )
2906 ** Initialize the pictured numeric output conversion process.
2907 ** (clear the pad)
2908 **************************************************************************/
2909 static void lessNumberSign(FICL_VM *pVM)
2910 {
2911     FICL_STRING *sp = PTRtoSTRING pVM->pad;
2912     sp->count = 0;
2913     return;
2914 }
2915 
2916 /*
2917 ** number-sign      CORE ( ud1 -- ud2 )
2918 ** Divide ud1 by the number in BASE giving the quotient ud2 and the remainder
2919 ** n. (n is the least-significant digit of ud1.) Convert n to external form
2920 ** and add the resulting character to the beginning of the pictured numeric
2921 ** output  string. An ambiguous condition exists if # executes outside of a
2922 ** <# #> delimited number conversion.
2923 */
2924 static void numberSign(FICL_VM *pVM)
2925 {
2926     FICL_STRING *sp;
2927     DPUNS u;
2928     UNS16 rem;
2929 #if FICL_ROBUST > 1
2930     vmCheckStack(pVM, 2, 2);
2931 #endif
2932 
2933     sp = PTRtoSTRING pVM->pad;
2934     u = u64Pop(pVM->pStack);
2935     rem = m64UMod(&u, (UNS16)(pVM->base));
2936     sp->text[sp->count++] = digit_to_char(rem);
2937     u64Push(pVM->pStack, u);
2938     return;
2939 }
2940 
2941 /*
2942 ** number-sign-greater CORE ( xd -- c-addr u )
2943 ** Drop xd. Make the pictured numeric output string available as a character
2944 ** string. c-addr and u specify the resulting character string. A program
2945 ** may replace characters within the string.
2946 */
2947 static void numberSignGreater(FICL_VM *pVM)
2948 {
2949     FICL_STRING *sp;
2950 #if FICL_ROBUST > 1
2951     vmCheckStack(pVM, 2, 2);
2952 #endif
2953 
2954     sp = PTRtoSTRING pVM->pad;
2955     sp->text[sp->count] = 0;
2956     strrev(sp->text);
2957     DROP(2);
2958     PUSHPTR(sp->text);
2959     PUSHUNS(sp->count);
2960     return;
2961 }
2962 
2963 /*
2964 ** number-sign-s    CORE ( ud1 -- ud2 )
2965 ** Convert one digit of ud1 according to the rule for #. Continue conversion
2966 ** until the quotient is zero. ud2 is zero. An ambiguous condition exists if
2967 ** #S executes outside of a <# #> delimited number conversion.
2968 ** TO DO: presently does not use ud1 hi cell - use it!
2969 */
2970 static void numberSignS(FICL_VM *pVM)
2971 {
2972     FICL_STRING *sp;
2973     DPUNS u;
2974     UNS16 rem;
2975 #if FICL_ROBUST > 1
2976     vmCheckStack(pVM, 2, 2);
2977 #endif
2978 
2979     sp = PTRtoSTRING pVM->pad;
2980     u = u64Pop(pVM->pStack);
2981 
2982     do
2983     {
2984         rem = m64UMod(&u, (UNS16)(pVM->base));
2985         sp->text[sp->count++] = digit_to_char(rem);
2986     }
2987     while (u.hi || u.lo);
2988 
2989     u64Push(pVM->pStack, u);
2990     return;
2991 }
2992 
2993 /*
2994 ** HOLD             CORE ( char -- )
2995 ** Add char to the beginning of the pictured numeric output string. An ambiguous
2996 ** condition exists if HOLD executes outside of a <# #> delimited number conversion.
2997 */
2998 static void hold(FICL_VM *pVM)
2999 {
3000     FICL_STRING *sp;
3001     int i;
3002 #if FICL_ROBUST > 1
3003     vmCheckStack(pVM, 1, 0);
3004 #endif
3005 
3006     sp = PTRtoSTRING pVM->pad;
3007     i = POPINT();
3008     sp->text[sp->count++] = (char) i;
3009     return;
3010 }
3011 
3012 /*
3013 ** SIGN             CORE ( n -- )
3014 ** If n is negative, add a minus sign to the beginning of the pictured
3015 ** numeric output string. An ambiguous condition exists if SIGN
3016 ** executes outside of a <# #> delimited number conversion.
3017 */
3018 static void sign(FICL_VM *pVM)
3019 {
3020     FICL_STRING *sp;
3021     int i;
3022 #if FICL_ROBUST > 1
3023     vmCheckStack(pVM, 1, 0);
3024 #endif
3025 
3026     sp = PTRtoSTRING pVM->pad;
3027     i = POPINT();
3028     if (i < 0)
3029         sp->text[sp->count++] = '-';
3030     return;
3031 }
3032 
3033 
3034 /**************************************************************************
3035                         t o   N u m b e r
3036 ** to-number CORE ( ud1 c-addr1 u1 -- ud2 c-addr2 u2 )
3037 ** ud2 is the unsigned result of converting the characters within the
3038 ** string specified by c-addr1 u1 into digits, using the number in BASE,
3039 ** and adding each into ud1 after multiplying ud1 by the number in BASE.
3040 ** Conversion continues left-to-right until a character that is not
3041 ** convertible, including any + or -, is encountered or the string is
3042 ** entirely converted. c-addr2 is the location of the first unconverted
3043 ** character or the first character past the end of the string if the string
3044 ** was entirely converted. u2 is the number of unconverted characters in the
3045 ** string. An ambiguous condition exists if ud2 overflows during the
3046 ** conversion.
3047 **************************************************************************/
3048 static void toNumber(FICL_VM *pVM)
3049 {
3050     FICL_UNS count;
3051     char *cp;
3052     DPUNS accum;
3053     FICL_UNS base = pVM->base;
3054     FICL_UNS ch;
3055     FICL_UNS digit;
3056 
3057 #if FICL_ROBUST > 1
3058     vmCheckStack(pVM,4,4);
3059 #endif
3060 
3061     count = POPUNS();
3062     cp = (char *)POPPTR();
3063     accum = u64Pop(pVM->pStack);
3064 
3065     for (ch = *cp; count > 0; ch = *++cp, count--)
3066     {
3067         if (ch < '0')
3068             break;
3069 
3070         digit = ch - '0';
3071 
3072         if (digit > 9)
3073             digit = tolower(ch) - 'a' + 10;
3074         /*
3075         ** Note: following test also catches chars between 9 and a
3076         ** because 'digit' is unsigned!
3077         */
3078         if (digit >= base)
3079             break;
3080 
3081         accum = m64Mac(accum, base, digit);
3082     }
3083 
3084     u64Push(pVM->pStack, accum);
3085     PUSHPTR(cp);
3086     PUSHUNS(count);
3087 
3088     return;
3089 }
3090 
3091 
3092 
3093 /**************************************************************************
3094                         q u i t   &   a b o r t
3095 ** quit CORE   ( -- )  ( R:  i*x -- )
3096 ** Empty the return stack, store zero in SOURCE-ID if it is present, make
3097 ** the user input device the input source, and enter interpretation state.
3098 ** Do not display a message. Repeat the following:
3099 **
3100 **   Accept a line from the input source into the input buffer, set >IN to
3101 **   zero, and interpret.
3102 **   Display the implementation-defined system prompt if in
3103 **   interpretation state, all processing has been completed, and no
3104 **   ambiguous condition exists.
3105 **************************************************************************/
3106 
3107 static void quit(FICL_VM *pVM)
3108 {
3109     vmThrow(pVM, VM_QUIT);
3110     return;
3111 }
3112 
3113 
3114 static void ficlAbort(FICL_VM *pVM)
3115 {
3116     vmThrow(pVM, VM_ABORT);
3117     return;
3118 }
3119 
3120 
3121 /**************************************************************************
3122                         a c c e p t
3123 ** accept       CORE ( c-addr +n1 -- +n2 )
3124 ** Receive a string of at most +n1 characters. An ambiguous condition
3125 ** exists if +n1 is zero or greater than 32,767. Display graphic characters
3126 ** as they are received. A program that depends on the presence or absence
3127 ** of non-graphic characters in the string has an environmental dependency.
3128 ** The editing functions, if any, that the system performs in order to
3129 ** construct the string are implementation-defined.
3130 **
3131 ** (Although the standard text doesn't say so, I assume that the intent
3132 ** of 'accept' is to store the string at the address specified on
3133 ** the stack.)
3134 ** Implementation: if there's more text in the TIB, use it. Otherwise
3135 ** throw out for more text. Copy characters up to the max count into the
3136 ** address given, and return the number of actual characters copied.
3137 **
3138 ** Note (sobral) this may not be the behavior you'd expect if you're
3139 ** trying to get user input at load time!
3140 **************************************************************************/
3141 static void accept(FICL_VM *pVM)
3142 {
3143     FICL_UNS count, len;
3144     char *cp;
3145     char *pBuf, *pEnd;
3146 
3147 #if FICL_ROBUST > 1
3148     vmCheckStack(pVM,2,1);
3149 #endif
3150 
3151     pBuf = vmGetInBuf(pVM);
3152     pEnd = vmGetInBufEnd(pVM);
3153     len = pEnd - pBuf;
3154     if (len == 0)
3155         vmThrow(pVM, VM_RESTART);
3156 
3157     /*
3158     ** Now we have something in the text buffer - use it
3159     */
3160     count = stackPopINT(pVM->pStack);
3161     cp    = stackPopPtr(pVM->pStack);
3162 
3163     len = (count < len) ? count : len;
3164     strncpy(cp, vmGetInBuf(pVM), len);
3165     pBuf += len;
3166     vmUpdateTib(pVM, pBuf);
3167     PUSHINT(len);
3168 
3169     return;
3170 }
3171 
3172 
3173 /**************************************************************************
3174                         a l i g n
3175 ** 6.1.0705 ALIGN       CORE ( -- )
3176 ** If the data-space pointer is not aligned, reserve enough space to
3177 ** align it.
3178 **************************************************************************/
3179 static void align(FICL_VM *pVM)
3180 {
3181     FICL_DICT *dp = vmGetDict(pVM);
3182     IGNORE(pVM);
3183     dictAlign(dp);
3184     return;
3185 }
3186 
3187 
3188 /**************************************************************************
3189                         a l i g n e d
3190 **
3191 **************************************************************************/
3192 static void aligned(FICL_VM *pVM)
3193 {
3194     void *addr;
3195 #if FICL_ROBUST > 1
3196     vmCheckStack(pVM,1,1);
3197 #endif
3198 
3199     addr = POPPTR();
3200     PUSHPTR(alignPtr(addr));
3201     return;
3202 }
3203 
3204 
3205 /**************************************************************************
3206                         b e g i n   &   f r i e n d s
3207 ** Indefinite loop control structures
3208 ** A.6.1.0760 BEGIN
3209 ** Typical use:
3210 **      : X ... BEGIN ... test UNTIL ;
3211 ** or
3212 **      : X ... BEGIN ... test WHILE ... REPEAT ;
3213 **************************************************************************/
3214 static void beginCoIm(FICL_VM *pVM)
3215 {
3216     FICL_DICT *dp = vmGetDict(pVM);
3217     markBranch(dp, pVM, destTag);
3218     return;
3219 }
3220 
3221 static void untilCoIm(FICL_VM *pVM)
3222 {
3223     FICL_DICT *dp = vmGetDict(pVM);
3224 
3225     assert(pVM->pSys->pBranch0);
3226 
3227     dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pBranch0));
3228     resolveBackBranch(dp, pVM, destTag);
3229     return;
3230 }
3231 
3232 static void whileCoIm(FICL_VM *pVM)
3233 {
3234     FICL_DICT *dp = vmGetDict(pVM);
3235 
3236     assert(pVM->pSys->pBranch0);
3237 
3238     dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pBranch0));
3239     markBranch(dp, pVM, origTag);
3240     twoSwap(pVM);
3241     dictAppendUNS(dp, 1);
3242     return;
3243 }
3244 
3245 static void repeatCoIm(FICL_VM *pVM)
3246 {
3247     FICL_DICT *dp = vmGetDict(pVM);
3248 
3249     assert(pVM->pSys->pBranchParen);
3250     dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pBranchParen));
3251 
3252     /* expect "begin" branch marker */
3253     resolveBackBranch(dp, pVM, destTag);
3254     /* expect "while" branch marker */
3255     resolveForwardBranch(dp, pVM, origTag);
3256     return;
3257 }
3258 
3259 
3260 static void againCoIm(FICL_VM *pVM)
3261 {
3262     FICL_DICT *dp = vmGetDict(pVM);
3263 
3264     assert(pVM->pSys->pBranchParen);
3265     dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pBranchParen));
3266 
3267     /* expect "begin" branch marker */
3268     resolveBackBranch(dp, pVM, destTag);
3269     return;
3270 }
3271 
3272 
3273 /**************************************************************************
3274                         c h a r   &   f r i e n d s
3275 ** 6.1.0895 CHAR    CORE ( "<spaces>name" -- char )
3276 ** Skip leading space delimiters. Parse name delimited by a space.
3277 ** Put the value of its first character onto the stack.
3278 **
3279 ** bracket-char     CORE
3280 ** Interpretation: Interpretation semantics for this word are undefined.
3281 ** Compilation: ( "<spaces>name" -- )
3282 ** Skip leading space delimiters. Parse name delimited by a space.
3283 ** Append the run-time semantics given below to the current definition.
3284 ** Run-time: ( -- char )
3285 ** Place char, the value of the first character of name, on the stack.
3286 **************************************************************************/
3287 static void ficlChar(FICL_VM *pVM)
3288 {
3289     STRINGINFO si;
3290 #if FICL_ROBUST > 1
3291     vmCheckStack(pVM,0,1);
3292 #endif
3293 
3294     si = vmGetWord(pVM);
3295     PUSHUNS((FICL_UNS)(si.cp[0]));
3296     return;
3297 }
3298 
3299 static void charCoIm(FICL_VM *pVM)
3300 {
3301     ficlChar(pVM);
3302     literalIm(pVM);
3303     return;
3304 }
3305 
3306 /**************************************************************************
3307                         c h a r P l u s
3308 ** char-plus        CORE ( c-addr1 -- c-addr2 )
3309 ** Add the size in address units of a character to c-addr1, giving c-addr2.
3310 **************************************************************************/
3311 static void charPlus(FICL_VM *pVM)
3312 {
3313     char *cp;
3314 #if FICL_ROBUST > 1
3315     vmCheckStack(pVM,1,1);
3316 #endif
3317 
3318     cp = POPPTR();
3319     PUSHPTR(cp + 1);
3320     return;
3321 }
3322 
3323 /**************************************************************************
3324                         c h a r s
3325 ** chars        CORE ( n1 -- n2 )
3326 ** n2 is the size in address units of n1 characters.
3327 ** For most processors, this function can be a no-op. To guarantee
3328 ** portability, we'll multiply by sizeof (char).
3329 **************************************************************************/
3330 #if defined (_M_IX86)
3331 #pragma warning(disable: 4127)
3332 #endif
3333 static void ficlChars(FICL_VM *pVM)
3334 {
3335     if (sizeof (char) > 1)
3336     {
3337         FICL_INT i;
3338 #if FICL_ROBUST > 1
3339         vmCheckStack(pVM,1,1);
3340 #endif
3341         i = POPINT();
3342         PUSHINT(i * sizeof (char));
3343     }
3344     /* otherwise no-op! */
3345     return;
3346 }
3347 #if defined (_M_IX86)
3348 #pragma warning(default: 4127)
3349 #endif
3350 
3351 
3352 /**************************************************************************
3353                         c o u n t
3354 ** COUNT    CORE ( c-addr1 -- c-addr2 u )
3355 ** Return the character string specification for the counted string stored
3356 ** at c-addr1. c-addr2 is the address of the first character after c-addr1.
3357 ** u is the contents of the character at c-addr1, which is the length in
3358 ** characters of the string at c-addr2.
3359 **************************************************************************/
3360 static void count(FICL_VM *pVM)
3361 {
3362     FICL_STRING *sp;
3363 #if FICL_ROBUST > 1
3364     vmCheckStack(pVM,1,2);
3365 #endif
3366 
3367     sp = POPPTR();
3368     PUSHPTR(sp->text);
3369     PUSHUNS(sp->count);
3370     return;
3371 }
3372 
3373 /**************************************************************************
3374                         e n v i r o n m e n t ?
3375 ** environment-query CORE ( c-addr u -- false | i*x true )
3376 ** c-addr is the address of a character string and u is the string's
3377 ** character count. u may have a value in the range from zero to an
3378 ** implementation-defined maximum which shall not be less than 31. The
3379 ** character string should contain a keyword from 3.2.6 Environmental
3380 ** queries or the optional word sets to be checked for correspondence
3381 ** with an attribute of the present environment. If the system treats the
3382 ** attribute as unknown, the returned flag is false; otherwise, the flag
3383 ** is true and the i*x returned is of the type specified in the table for
3384 ** the attribute queried.
3385 **************************************************************************/
3386 static void environmentQ(FICL_VM *pVM)
3387 {
3388     FICL_DICT *envp;
3389     FICL_WORD *pFW;
3390     STRINGINFO si;
3391 #if FICL_ROBUST > 1
3392     vmCheckStack(pVM,2,1);
3393 #endif
3394 
3395     envp = pVM->pSys->envp;
3396     si.count = (FICL_COUNT)stackPopUNS(pVM->pStack);
3397     si.cp    = stackPopPtr(pVM->pStack);
3398 
3399     pFW = dictLookup(envp, si);
3400 
3401     if (pFW != NULL)
3402     {
3403         vmExecute(pVM, pFW);
3404         PUSHINT(FICL_TRUE);
3405     }
3406     else
3407     {
3408         PUSHINT(FICL_FALSE);
3409     }
3410     return;
3411 }
3412 
3413 /**************************************************************************
3414                         e v a l u a t e
3415 ** EVALUATE CORE ( i*x c-addr u -- j*x )
3416 ** Save the current input source specification. Store minus-one (-1) in
3417 ** SOURCE-ID if it is present. Make the string described by c-addr and u
3418 ** both the input source and input buffer, set >IN to zero, and interpret.
3419 ** When the parse area is empty, restore the prior input source
3420 ** specification. Other stack effects are due to the words EVALUATEd.
3421 **
3422 **************************************************************************/
3423 static void evaluate(FICL_VM *pVM)
3424 {
3425     FICL_UNS count;
3426     char *cp;
3427     CELL id;
3428     int result;
3429 #if FICL_ROBUST > 1
3430     vmCheckStack(pVM,2,0);
3431 #endif
3432 
3433     count = POPUNS();
3434     cp = POPPTR();
3435 
3436     IGNORE(count);
3437     id = pVM->sourceID;
3438     pVM->sourceID.i = -1;
3439     result = ficlExecC(pVM, cp, count);
3440     pVM->sourceID = id;
3441     if (result != VM_OUTOFTEXT)
3442         vmThrow(pVM, result);
3443 
3444     return;
3445 }
3446 
3447 
3448 /**************************************************************************
3449                         s t r i n g   q u o t e
3450 ** Interpreting: get string delimited by a quote from the input stream,
3451 ** copy to a scratch area, and put its count and address on the stack.
3452 ** Compiling: compile code to push the address and count of a string
3453 ** literal, compile the string from the input stream, and align the dict
3454 ** pointer.
3455 **************************************************************************/
3456 static void stringQuoteIm(FICL_VM *pVM)
3457 {
3458     FICL_DICT *dp = vmGetDict(pVM);
3459 
3460     if (pVM->state == INTERPRET)
3461     {
3462         FICL_STRING *sp = (FICL_STRING *) dp->here;
3463         vmGetString(pVM, sp, '\"');
3464         PUSHPTR(sp->text);
3465         PUSHUNS(sp->count);
3466     }
3467     else    /* COMPILE state */
3468     {
3469         dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pStringLit));
3470         dp->here = PTRtoCELL vmGetString(pVM, (FICL_STRING *)dp->here, '\"');
3471         dictAlign(dp);
3472     }
3473 
3474     return;
3475 }
3476 
3477 
3478 /**************************************************************************
3479                         t y p e
3480 ** Pop count and char address from stack and print the designated string.
3481 **************************************************************************/
3482 static void type(FICL_VM *pVM)
3483 {
3484     FICL_UNS count = stackPopUNS(pVM->pStack);
3485     char *cp    = stackPopPtr(pVM->pStack);
3486     char *pDest = (char *)ficlMalloc(count + 1);
3487 
3488     /*
3489     ** Since we don't have an output primitive for a counted string
3490     ** (oops), make sure the string is null terminated. If not, copy
3491     ** and terminate it.
3492     */
3493     if (!pDest)
3494 	vmThrowErr(pVM, "Error: out of memory");
3495 
3496     strncpy(pDest, cp, count);
3497     pDest[count] = '\0';
3498 
3499     vmTextOut(pVM, pDest, 0);
3500 
3501     ficlFree(pDest);
3502     return;
3503 }
3504 
3505 /**************************************************************************
3506                         w o r d
3507 ** word CORE ( char "<chars>ccc<char>" -- c-addr )
3508 ** Skip leading delimiters. Parse characters ccc delimited by char. An
3509 ** ambiguous condition exists if the length of the parsed string is greater
3510 ** than the implementation-defined length of a counted string.
3511 **
3512 ** c-addr is the address of a transient region containing the parsed word
3513 ** as a counted string. If the parse area was empty or contained no
3514 ** characters other than the delimiter, the resulting string has a zero
3515 ** length. A space, not included in the length, follows the string. A
3516 ** program may replace characters within the string.
3517 ** NOTE! Ficl also NULL-terminates the dest string.
3518 **************************************************************************/
3519 static void ficlWord(FICL_VM *pVM)
3520 {
3521     FICL_STRING *sp;
3522     char delim;
3523     STRINGINFO   si;
3524 #if FICL_ROBUST > 1
3525     vmCheckStack(pVM,1,1);
3526 #endif
3527 
3528     sp = (FICL_STRING *)pVM->pad;
3529     delim = (char)POPINT();
3530     si = vmParseStringEx(pVM, delim, 1);
3531 
3532     if (SI_COUNT(si) > nPAD-1)
3533         SI_SETLEN(si, nPAD-1);
3534 
3535     sp->count = (FICL_COUNT)SI_COUNT(si);
3536     strncpy(sp->text, SI_PTR(si), SI_COUNT(si));
3537     /*#$-GUY CHANGE: I added this.-$#*/
3538     sp->text[sp->count] = 0;
3539     strcat(sp->text, " ");
3540 
3541     PUSHPTR(sp);
3542     return;
3543 }
3544 
3545 
3546 /**************************************************************************
3547                         p a r s e - w o r d
3548 ** ficl   PARSE-WORD  ( <spaces>name -- c-addr u )
3549 ** Skip leading spaces and parse name delimited by a space. c-addr is the
3550 ** address within the input buffer and u is the length of the selected
3551 ** string. If the parse area is empty, the resulting string has a zero length.
3552 **************************************************************************/
3553 static void parseNoCopy(FICL_VM *pVM)
3554 {
3555     STRINGINFO si;
3556 #if FICL_ROBUST > 1
3557     vmCheckStack(pVM,0,2);
3558 #endif
3559 
3560     si = vmGetWord0(pVM);
3561     PUSHPTR(SI_PTR(si));
3562     PUSHUNS(SI_COUNT(si));
3563     return;
3564 }
3565 
3566 
3567 /**************************************************************************
3568                         p a r s e
3569 ** CORE EXT  ( char "ccc<char>" -- c-addr u )
3570 ** Parse ccc delimited by the delimiter char.
3571 ** c-addr is the address (within the input buffer) and u is the length of
3572 ** the parsed string. If the parse area was empty, the resulting string has
3573 ** a zero length.
3574 ** NOTE! PARSE differs from WORD: it does not skip leading delimiters.
3575 **************************************************************************/
3576 static void parse(FICL_VM *pVM)
3577 {
3578     STRINGINFO si;
3579     char delim;
3580 
3581 #if FICL_ROBUST > 1
3582     vmCheckStack(pVM,1,2);
3583 #endif
3584 
3585     delim = (char)POPINT();
3586 
3587     si = vmParseStringEx(pVM, delim, 0);
3588     PUSHPTR(SI_PTR(si));
3589     PUSHUNS(SI_COUNT(si));
3590     return;
3591 }
3592 
3593 
3594 /**************************************************************************
3595                         f i l l
3596 ** CORE ( c-addr u char -- )
3597 ** If u is greater than zero, store char in each of u consecutive
3598 ** characters of memory beginning at c-addr.
3599 **************************************************************************/
3600 static void fill(FICL_VM *pVM)
3601 {
3602     char ch;
3603     FICL_UNS u;
3604     char *cp;
3605 #if FICL_ROBUST > 1
3606     vmCheckStack(pVM,3,0);
3607 #endif
3608     ch = (char)POPINT();
3609     u = POPUNS();
3610     cp = (char *)POPPTR();
3611 
3612     while (u > 0)
3613     {
3614         *cp++ = ch;
3615         u--;
3616     }
3617     return;
3618 }
3619 
3620 
3621 /**************************************************************************
3622                         f i n d
3623 ** FIND CORE ( c-addr -- c-addr 0  |  xt 1  |  xt -1 )
3624 ** Find the definition named in the counted string at c-addr. If the
3625 ** definition is not found, return c-addr and zero. If the definition is
3626 ** found, return its execution token xt. If the definition is immediate,
3627 ** also return one (1), otherwise also return minus-one (-1). For a given
3628 ** string, the values returned by FIND while compiling may differ from
3629 ** those returned while not compiling.
3630 **************************************************************************/
3631 static void do_find(FICL_VM *pVM, STRINGINFO si, void *returnForFailure)
3632 {
3633     FICL_WORD *pFW;
3634 
3635     pFW = dictLookup(vmGetDict(pVM), si);
3636     if (pFW)
3637     {
3638         PUSHPTR(pFW);
3639         PUSHINT((wordIsImmediate(pFW) ? 1 : -1));
3640     }
3641     else
3642     {
3643         PUSHPTR(returnForFailure);
3644         PUSHUNS(0);
3645     }
3646     return;
3647 }
3648 
3649 
3650 
3651 /**************************************************************************
3652                         f i n d
3653 ** FIND CORE ( c-addr -- c-addr 0  |  xt 1  |  xt -1 )
3654 ** Find the definition named in the counted string at c-addr. If the
3655 ** definition is not found, return c-addr and zero. If the definition is
3656 ** found, return its execution token xt. If the definition is immediate,
3657 ** also return one (1), otherwise also return minus-one (-1). For a given
3658 ** string, the values returned by FIND while compiling may differ from
3659 ** those returned while not compiling.
3660 **************************************************************************/
3661 static void cFind(FICL_VM *pVM)
3662 {
3663     FICL_STRING *sp;
3664     STRINGINFO si;
3665 
3666 #if FICL_ROBUST > 1
3667     vmCheckStack(pVM,1,2);
3668 #endif
3669     sp = POPPTR();
3670     SI_PFS(si, sp);
3671     do_find(pVM, si, sp);
3672 }
3673 
3674 
3675 
3676 /**************************************************************************
3677                         s f i n d
3678 ** FICL   ( c-addr u -- 0 0  |  xt 1  |  xt -1 )
3679 ** Like FIND, but takes "c-addr u" for the string.
3680 **************************************************************************/
3681 static void sFind(FICL_VM *pVM)
3682 {
3683     STRINGINFO si;
3684 
3685 #if FICL_ROBUST > 1
3686     vmCheckStack(pVM,2,2);
3687 #endif
3688 
3689     si.count = stackPopINT(pVM->pStack);
3690     si.cp = stackPopPtr(pVM->pStack);
3691 
3692     do_find(pVM, si, NULL);
3693 }
3694 
3695 
3696 
3697 /**************************************************************************
3698                         f m S l a s h M o d
3699 ** f-m-slash-mod CORE ( d1 n1 -- n2 n3 )
3700 ** Divide d1 by n1, giving the floored quotient n3 and the remainder n2.
3701 ** Input and output stack arguments are signed. An ambiguous condition
3702 ** exists if n1 is zero or if the quotient lies outside the range of a
3703 ** single-cell signed integer.
3704 **************************************************************************/
3705 static void fmSlashMod(FICL_VM *pVM)
3706 {
3707     DPINT d1;
3708     FICL_INT n1;
3709     INTQR qr;
3710 #if FICL_ROBUST > 1
3711     vmCheckStack(pVM,3,2);
3712 #endif
3713 
3714     n1 = POPINT();
3715     d1 = i64Pop(pVM->pStack);
3716     qr = m64FlooredDivI(d1, n1);
3717     PUSHINT(qr.rem);
3718     PUSHINT(qr.quot);
3719     return;
3720 }
3721 
3722 
3723 /**************************************************************************
3724                         s m S l a s h R e m
3725 ** s-m-slash-rem CORE ( d1 n1 -- n2 n3 )
3726 ** Divide d1 by n1, giving the symmetric quotient n3 and the remainder n2.
3727 ** Input and output stack arguments are signed. An ambiguous condition
3728 ** exists if n1 is zero or if the quotient lies outside the range of a
3729 ** single-cell signed integer.
3730 **************************************************************************/
3731 static void smSlashRem(FICL_VM *pVM)
3732 {
3733     DPINT d1;
3734     FICL_INT n1;
3735     INTQR qr;
3736 #if FICL_ROBUST > 1
3737     vmCheckStack(pVM,3,2);
3738 #endif
3739 
3740     n1 = POPINT();
3741     d1 = i64Pop(pVM->pStack);
3742     qr = m64SymmetricDivI(d1, n1);
3743     PUSHINT(qr.rem);
3744     PUSHINT(qr.quot);
3745     return;
3746 }
3747 
3748 
3749 static void ficlMod(FICL_VM *pVM)
3750 {
3751     DPINT d1;
3752     FICL_INT n1;
3753     INTQR qr;
3754 #if FICL_ROBUST > 1
3755     vmCheckStack(pVM,2,1);
3756 #endif
3757 
3758     n1 = POPINT();
3759     d1.lo = POPINT();
3760     i64Extend(d1);
3761     qr = m64SymmetricDivI(d1, n1);
3762     PUSHINT(qr.rem);
3763     return;
3764 }
3765 
3766 
3767 /**************************************************************************
3768                         u m S l a s h M o d
3769 ** u-m-slash-mod CORE ( ud u1 -- u2 u3 )
3770 ** Divide ud by u1, giving the quotient u3 and the remainder u2.
3771 ** All values and arithmetic are unsigned. An ambiguous condition
3772 ** exists if u1 is zero or if the quotient lies outside the range of a
3773 ** single-cell unsigned integer.
3774 *************************************************************************/
3775 static void umSlashMod(FICL_VM *pVM)
3776 {
3777     DPUNS ud;
3778     FICL_UNS u1;
3779     UNSQR qr;
3780 
3781     u1    = stackPopUNS(pVM->pStack);
3782     ud    = u64Pop(pVM->pStack);
3783     qr    = ficlLongDiv(ud, u1);
3784     PUSHUNS(qr.rem);
3785     PUSHUNS(qr.quot);
3786     return;
3787 }
3788 
3789 
3790 /**************************************************************************
3791                         l s h i f t
3792 ** l-shift CORE ( x1 u -- x2 )
3793 ** Perform a logical left shift of u bit-places on x1, giving x2.
3794 ** Put zeroes into the least significant bits vacated by the shift.
3795 ** An ambiguous condition exists if u is greater than or equal to the
3796 ** number of bits in a cell.
3797 **
3798 ** r-shift CORE ( x1 u -- x2 )
3799 ** Perform a logical right shift of u bit-places on x1, giving x2.
3800 ** Put zeroes into the most significant bits vacated by the shift. An
3801 ** ambiguous condition exists if u is greater than or equal to the
3802 ** number of bits in a cell.
3803 **************************************************************************/
3804 static void lshift(FICL_VM *pVM)
3805 {
3806     FICL_UNS nBits;
3807     FICL_UNS x1;
3808 #if FICL_ROBUST > 1
3809     vmCheckStack(pVM,2,1);
3810 #endif
3811 
3812     nBits = POPUNS();
3813     x1 = POPUNS();
3814     PUSHUNS(x1 << nBits);
3815     return;
3816 }
3817 
3818 
3819 static void rshift(FICL_VM *pVM)
3820 {
3821     FICL_UNS nBits;
3822     FICL_UNS x1;
3823 #if FICL_ROBUST > 1
3824     vmCheckStack(pVM,2,1);
3825 #endif
3826 
3827     nBits = POPUNS();
3828     x1 = POPUNS();
3829 
3830     PUSHUNS(x1 >> nBits);
3831     return;
3832 }
3833 
3834 
3835 /**************************************************************************
3836                         m S t a r
3837 ** m-star CORE ( n1 n2 -- d )
3838 ** d is the signed product of n1 times n2.
3839 **************************************************************************/
3840 static void mStar(FICL_VM *pVM)
3841 {
3842     FICL_INT n2;
3843     FICL_INT n1;
3844     DPINT d;
3845 #if FICL_ROBUST > 1
3846     vmCheckStack(pVM,2,2);
3847 #endif
3848 
3849     n2 = POPINT();
3850     n1 = POPINT();
3851 
3852     d = m64MulI(n1, n2);
3853     i64Push(pVM->pStack, d);
3854     return;
3855 }
3856 
3857 
3858 static void umStar(FICL_VM *pVM)
3859 {
3860     FICL_UNS u2;
3861     FICL_UNS u1;
3862     DPUNS ud;
3863 #if FICL_ROBUST > 1
3864     vmCheckStack(pVM,2,2);
3865 #endif
3866 
3867     u2 = POPUNS();
3868     u1 = POPUNS();
3869 
3870     ud = ficlLongMul(u1, u2);
3871     u64Push(pVM->pStack, ud);
3872     return;
3873 }
3874 
3875 
3876 /**************************************************************************
3877                         m a x   &   m i n
3878 **
3879 **************************************************************************/
3880 static void ficlMax(FICL_VM *pVM)
3881 {
3882     FICL_INT n2;
3883     FICL_INT n1;
3884 #if FICL_ROBUST > 1
3885     vmCheckStack(pVM,2,1);
3886 #endif
3887 
3888     n2 = POPINT();
3889     n1 = POPINT();
3890 
3891     PUSHINT((n1 > n2) ? n1 : n2);
3892     return;
3893 }
3894 
3895 static void ficlMin(FICL_VM *pVM)
3896 {
3897     FICL_INT n2;
3898     FICL_INT n1;
3899 #if FICL_ROBUST > 1
3900     vmCheckStack(pVM,2,1);
3901 #endif
3902 
3903     n2 = POPINT();
3904     n1 = POPINT();
3905 
3906     PUSHINT((n1 < n2) ? n1 : n2);
3907     return;
3908 }
3909 
3910 
3911 /**************************************************************************
3912                         m o v e
3913 ** CORE ( addr1 addr2 u -- )
3914 ** If u is greater than zero, copy the contents of u consecutive address
3915 ** units at addr1 to the u consecutive address units at addr2. After MOVE
3916 ** completes, the u consecutive address units at addr2 contain exactly
3917 ** what the u consecutive address units at addr1 contained before the move.
3918 ** NOTE! This implementation assumes that a char is the same size as
3919 **       an address unit.
3920 **************************************************************************/
3921 static void move(FICL_VM *pVM)
3922 {
3923     FICL_UNS u;
3924     char *addr2;
3925     char *addr1;
3926 #if FICL_ROBUST > 1
3927     vmCheckStack(pVM,3,0);
3928 #endif
3929 
3930     u = POPUNS();
3931     addr2 = POPPTR();
3932     addr1 = POPPTR();
3933 
3934     if (u == 0)
3935         return;
3936     /*
3937     ** Do the copy carefully, so as to be
3938     ** correct even if the two ranges overlap
3939     */
3940     if (addr1 >= addr2)
3941     {
3942         for (; u > 0; u--)
3943             *addr2++ = *addr1++;
3944     }
3945     else
3946     {
3947         addr2 += u-1;
3948         addr1 += u-1;
3949         for (; u > 0; u--)
3950             *addr2-- = *addr1--;
3951     }
3952 
3953     return;
3954 }
3955 
3956 
3957 /**************************************************************************
3958                         r e c u r s e
3959 **
3960 **************************************************************************/
3961 static void recurseCoIm(FICL_VM *pVM)
3962 {
3963     FICL_DICT *pDict = vmGetDict(pVM);
3964 
3965     IGNORE(pVM);
3966     dictAppendCell(pDict, LVALUEtoCELL(pDict->smudge));
3967     return;
3968 }
3969 
3970 
3971 /**************************************************************************
3972                         s t o d
3973 ** s-to-d CORE ( n -- d )
3974 ** Convert the number n to the double-cell number d with the same
3975 ** numerical value.
3976 **************************************************************************/
3977 static void sToD(FICL_VM *pVM)
3978 {
3979     FICL_INT s;
3980 #if FICL_ROBUST > 1
3981     vmCheckStack(pVM,1,2);
3982 #endif
3983 
3984     s = POPINT();
3985 
3986     /* sign extend to 64 bits.. */
3987     PUSHINT(s);
3988     PUSHINT((s < 0) ? -1 : 0);
3989     return;
3990 }
3991 
3992 
3993 /**************************************************************************
3994                         s o u r c e
3995 ** CORE ( -- c-addr u )
3996 ** c-addr is the address of, and u is the number of characters in, the
3997 ** input buffer.
3998 **************************************************************************/
3999 static void source(FICL_VM *pVM)
4000 {
4001 #if FICL_ROBUST > 1
4002     vmCheckStack(pVM,0,2);
4003 #endif
4004     PUSHPTR(pVM->tib.cp);
4005     PUSHINT(vmGetInBufLen(pVM));
4006     return;
4007 }
4008 
4009 
4010 /**************************************************************************
4011                         v e r s i o n
4012 ** non-standard...
4013 **************************************************************************/
4014 static void ficlVersion(FICL_VM *pVM)
4015 {
4016     vmTextOut(pVM, "ficl Version " FICL_VER, 1);
4017     return;
4018 }
4019 
4020 
4021 /**************************************************************************
4022                         t o I n
4023 ** to-in CORE
4024 **************************************************************************/
4025 static void toIn(FICL_VM *pVM)
4026 {
4027 #if FICL_ROBUST > 1
4028     vmCheckStack(pVM,0,1);
4029 #endif
4030     PUSHPTR(&pVM->tib.index);
4031     return;
4032 }
4033 
4034 
4035 /**************************************************************************
4036                         c o l o n N o N a m e
4037 ** CORE EXT ( C:  -- colon-sys )  ( S:  -- xt )
4038 ** Create an unnamed colon definition and push its address.
4039 ** Change state to compile.
4040 **************************************************************************/
4041 static void colonNoName(FICL_VM *pVM)
4042 {
4043     FICL_DICT *dp = vmGetDict(pVM);
4044     FICL_WORD *pFW;
4045     STRINGINFO si;
4046 
4047     SI_SETLEN(si, 0);
4048     SI_SETPTR(si, NULL);
4049 
4050     pVM->state = COMPILE;
4051     pFW = dictAppendWord2(dp, si, colonParen, FW_DEFAULT | FW_SMUDGE);
4052     PUSHPTR(pFW);
4053     markControlTag(pVM, colonTag);
4054     return;
4055 }
4056 
4057 
4058 /**************************************************************************
4059                         u s e r   V a r i a b l e
4060 ** user  ( u -- )  "<spaces>name"
4061 ** Get a name from the input stream and create a user variable
4062 ** with the name and the index supplied. The run-time effect
4063 ** of a user variable is to push the address of the indexed cell
4064 ** in the running vm's user array.
4065 **
4066 ** User variables are vm local cells. Each vm has an array of
4067 ** FICL_USER_CELLS of them when FICL_WANT_USER is nonzero.
4068 ** Ficl's user facility is implemented with two primitives,
4069 ** "user" and "(user)", a variable ("nUser") (in softcore.c) that
4070 ** holds the index of the next free user cell, and a redefinition
4071 ** (also in softcore) of "user" that defines a user word and increments
4072 ** nUser.
4073 **************************************************************************/
4074 #if FICL_WANT_USER
4075 static void userParen(FICL_VM *pVM)
4076 {
4077     FICL_INT i = pVM->runningWord->param[0].i;
4078     PUSHPTR(&pVM->user[i]);
4079     return;
4080 }
4081 
4082 
4083 static void userVariable(FICL_VM *pVM)
4084 {
4085     FICL_DICT *dp = vmGetDict(pVM);
4086     STRINGINFO si = vmGetWord(pVM);
4087     CELL c;
4088 
4089     c = stackPop(pVM->pStack);
4090     if (c.i >= FICL_USER_CELLS)
4091     {
4092         vmThrowErr(pVM, "Error - out of user space");
4093     }
4094 
4095     dictAppendWord2(dp, si, userParen, FW_DEFAULT);
4096     dictAppendCell(dp, c);
4097     return;
4098 }
4099 #endif
4100 
4101 
4102 /**************************************************************************
4103                         t o V a l u e
4104 ** CORE EXT
4105 ** Interpretation: ( x "<spaces>name" -- )
4106 ** Skip leading spaces and parse name delimited by a space. Store x in
4107 ** name. An ambiguous condition exists if name was not defined by VALUE.
4108 ** NOTE: In ficl, VALUE is an alias of CONSTANT
4109 **************************************************************************/
4110 static void toValue(FICL_VM *pVM)
4111 {
4112     STRINGINFO si = vmGetWord(pVM);
4113     FICL_DICT *dp = vmGetDict(pVM);
4114     FICL_WORD *pFW;
4115 
4116 #if FICL_WANT_LOCALS
4117     if ((pVM->pSys->nLocals > 0) && (pVM->state == COMPILE))
4118     {
4119         FICL_DICT *pLoc = ficlGetLoc(pVM->pSys);
4120         pFW = dictLookup(pLoc, si);
4121         if (pFW && (pFW->code == doLocalIm))
4122         {
4123             dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pToLocalParen));
4124             dictAppendCell(dp, LVALUEtoCELL(pFW->param[0]));
4125             return;
4126         }
4127         else if (pFW && pFW->code == do2LocalIm)
4128         {
4129             dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pTo2LocalParen));
4130             dictAppendCell(dp, LVALUEtoCELL(pFW->param[0]));
4131             return;
4132         }
4133     }
4134 #endif
4135 
4136     assert(pVM->pSys->pStore);
4137 
4138     pFW = dictLookup(dp, si);
4139     if (!pFW)
4140     {
4141         int i = SI_COUNT(si);
4142         vmThrowErr(pVM, "%.*s not found", i, SI_PTR(si));
4143     }
4144 
4145     if (pVM->state == INTERPRET)
4146         pFW->param[0] = stackPop(pVM->pStack);
4147     else        /* compile code to store to word's param */
4148     {
4149         PUSHPTR(&pFW->param[0]);
4150         literalIm(pVM);
4151         dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pStore));
4152     }
4153     return;
4154 }
4155 
4156 
4157 #if FICL_WANT_LOCALS
4158 /**************************************************************************
4159                         l i n k P a r e n
4160 ** ( -- )
4161 ** Link a frame on the return stack, reserving nCells of space for
4162 ** locals - the value of nCells is the next cell in the instruction
4163 ** stream.
4164 **************************************************************************/
4165 static void linkParen(FICL_VM *pVM)
4166 {
4167     FICL_INT nLink = *(FICL_INT *)(pVM->ip);
4168     vmBranchRelative(pVM, 1);
4169     stackLink(pVM->rStack, nLink);
4170     return;
4171 }
4172 
4173 
4174 static void unlinkParen(FICL_VM *pVM)
4175 {
4176     stackUnlink(pVM->rStack);
4177     return;
4178 }
4179 
4180 
4181 /**************************************************************************
4182                         d o L o c a l I m
4183 ** Immediate - cfa of a local while compiling - when executed, compiles
4184 ** code to fetch the value of a local given the local's index in the
4185 ** word's pfa
4186 **************************************************************************/
4187 static void getLocalParen(FICL_VM *pVM)
4188 {
4189     FICL_INT nLocal = *(FICL_INT *)(pVM->ip++);
4190     stackPush(pVM->pStack, pVM->rStack->pFrame[nLocal]);
4191     return;
4192 }
4193 
4194 
4195 static void toLocalParen(FICL_VM *pVM)
4196 {
4197     FICL_INT nLocal = *(FICL_INT *)(pVM->ip++);
4198     pVM->rStack->pFrame[nLocal] = stackPop(pVM->pStack);
4199     return;
4200 }
4201 
4202 
4203 static void getLocal0(FICL_VM *pVM)
4204 {
4205     stackPush(pVM->pStack, pVM->rStack->pFrame[0]);
4206     return;
4207 }
4208 
4209 
4210 static void toLocal0(FICL_VM *pVM)
4211 {
4212     pVM->rStack->pFrame[0] = stackPop(pVM->pStack);
4213     return;
4214 }
4215 
4216 
4217 static void getLocal1(FICL_VM *pVM)
4218 {
4219     stackPush(pVM->pStack, pVM->rStack->pFrame[1]);
4220     return;
4221 }
4222 
4223 
4224 static void toLocal1(FICL_VM *pVM)
4225 {
4226     pVM->rStack->pFrame[1] = stackPop(pVM->pStack);
4227     return;
4228 }
4229 
4230 
4231 /*
4232 ** Each local is recorded in a private locals dictionary as a
4233 ** word that does doLocalIm at runtime. DoLocalIm compiles code
4234 ** into the client definition to fetch the value of the
4235 ** corresponding local variable from the return stack.
4236 ** The private dictionary gets initialized at the end of each block
4237 ** that uses locals (in ; and does> for example).
4238 */
4239 static void doLocalIm(FICL_VM *pVM)
4240 {
4241     FICL_DICT *pDict = vmGetDict(pVM);
4242     FICL_INT nLocal = pVM->runningWord->param[0].i;
4243 
4244     if (pVM->state == INTERPRET)
4245     {
4246         stackPush(pVM->pStack, pVM->rStack->pFrame[nLocal]);
4247     }
4248     else
4249     {
4250 
4251         if (nLocal == 0)
4252         {
4253             dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->pGetLocal0));
4254         }
4255         else if (nLocal == 1)
4256         {
4257             dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->pGetLocal1));
4258         }
4259         else
4260         {
4261             dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->pGetLocalParen));
4262             dictAppendCell(pDict, LVALUEtoCELL(nLocal));
4263         }
4264     }
4265     return;
4266 }
4267 
4268 
4269 /**************************************************************************
4270                         l o c a l P a r e n
4271 ** paren-local-paren LOCAL
4272 ** Interpretation: Interpretation semantics for this word are undefined.
4273 ** Execution: ( c-addr u -- )
4274 ** When executed during compilation, (LOCAL) passes a message to the
4275 ** system that has one of two meanings. If u is non-zero,
4276 ** the message identifies a new local whose definition name is given by
4277 ** the string of characters identified by c-addr u. If u is zero,
4278 ** the message is last local and c-addr has no significance.
4279 **
4280 ** The result of executing (LOCAL) during compilation of a definition is
4281 ** to create a set of named local identifiers, each of which is
4282 ** a definition name, that only have execution semantics within the scope
4283 ** of that definition's source.
4284 **
4285 ** local Execution: ( -- x )
4286 **
4287 ** Push the local's value, x, onto the stack. The local's value is
4288 ** initialized as described in 13.3.3 Processing locals and may be
4289 ** changed by preceding the local's name with TO. An ambiguous condition
4290 ** exists when local is executed while in interpretation state.
4291 **************************************************************************/
4292 static void localParen(FICL_VM *pVM)
4293 {
4294     FICL_DICT *pDict;
4295     STRINGINFO si;
4296 #if FICL_ROBUST > 1
4297     vmCheckStack(pVM,2,0);
4298 #endif
4299 
4300     pDict = vmGetDict(pVM);
4301     SI_SETLEN(si, POPUNS());
4302     SI_SETPTR(si, (char *)POPPTR());
4303 
4304     if (SI_COUNT(si) > 0)
4305     {   /* add a local to the **locals** dict and update nLocals */
4306         FICL_DICT *pLoc = ficlGetLoc(pVM->pSys);
4307         if (pVM->pSys->nLocals >= FICL_MAX_LOCALS)
4308         {
4309             vmThrowErr(pVM, "Error: out of local space");
4310         }
4311 
4312         dictAppendWord2(pLoc, si, doLocalIm, FW_COMPIMMED);
4313         dictAppendCell(pLoc,  LVALUEtoCELL(pVM->pSys->nLocals));
4314 
4315         if (pVM->pSys->nLocals == 0)
4316         {   /* compile code to create a local stack frame */
4317             dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->pLinkParen));
4318             /* save location in dictionary for #locals */
4319             pVM->pSys->pMarkLocals = pDict->here;
4320             dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->nLocals));
4321             /* compile code to initialize first local */
4322             dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->pToLocal0));
4323         }
4324         else if (pVM->pSys->nLocals == 1)
4325         {
4326             dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->pToLocal1));
4327         }
4328         else
4329         {
4330             dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->pToLocalParen));
4331             dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->nLocals));
4332         }
4333 
4334         (pVM->pSys->nLocals)++;
4335     }
4336     else if (pVM->pSys->nLocals > 0)
4337     {       /* write nLocals to (link) param area in dictionary */
4338         *(FICL_INT *)(pVM->pSys->pMarkLocals) = pVM->pSys->nLocals;
4339     }
4340 
4341     return;
4342 }
4343 
4344 
4345 static void get2LocalParen(FICL_VM *pVM)
4346 {
4347     FICL_INT nLocal = *(FICL_INT *)(pVM->ip++);
4348     stackPush(pVM->pStack, pVM->rStack->pFrame[nLocal]);
4349     stackPush(pVM->pStack, pVM->rStack->pFrame[nLocal+1]);
4350     return;
4351 }
4352 
4353 
4354 static void do2LocalIm(FICL_VM *pVM)
4355 {
4356     FICL_DICT *pDict = vmGetDict(pVM);
4357     FICL_INT nLocal = pVM->runningWord->param[0].i;
4358 
4359     if (pVM->state == INTERPRET)
4360     {
4361         stackPush(pVM->pStack, pVM->rStack->pFrame[nLocal]);
4362         stackPush(pVM->pStack, pVM->rStack->pFrame[nLocal+1]);
4363     }
4364     else
4365     {
4366         dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->pGet2LocalParen));
4367         dictAppendCell(pDict, LVALUEtoCELL(nLocal));
4368     }
4369     return;
4370 }
4371 
4372 
4373 static void to2LocalParen(FICL_VM *pVM)
4374 {
4375     FICL_INT nLocal = *(FICL_INT *)(pVM->ip++);
4376     pVM->rStack->pFrame[nLocal+1] = stackPop(pVM->pStack);
4377     pVM->rStack->pFrame[nLocal]   = stackPop(pVM->pStack);
4378     return;
4379 }
4380 
4381 
4382 static void twoLocalParen(FICL_VM *pVM)
4383 {
4384     FICL_DICT *pDict = vmGetDict(pVM);
4385     STRINGINFO si;
4386     SI_SETLEN(si, stackPopUNS(pVM->pStack));
4387     SI_SETPTR(si, (char *)stackPopPtr(pVM->pStack));
4388 
4389     if (SI_COUNT(si) > 0)
4390     {   /* add a local to the **locals** dict and update nLocals */
4391         FICL_DICT *pLoc = ficlGetLoc(pVM->pSys);
4392         if (pVM->pSys->nLocals >= FICL_MAX_LOCALS)
4393         {
4394             vmThrowErr(pVM, "Error: out of local space");
4395         }
4396 
4397         dictAppendWord2(pLoc, si, do2LocalIm, FW_COMPIMMED);
4398         dictAppendCell(pLoc,  LVALUEtoCELL(pVM->pSys->nLocals));
4399 
4400         if (pVM->pSys->nLocals == 0)
4401         {   /* compile code to create a local stack frame */
4402             dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->pLinkParen));
4403             /* save location in dictionary for #locals */
4404             pVM->pSys->pMarkLocals = pDict->here;
4405             dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->nLocals));
4406         }
4407 
4408         dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->pTo2LocalParen));
4409         dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->nLocals));
4410 
4411         pVM->pSys->nLocals += 2;
4412     }
4413     else if (pVM->pSys->nLocals > 0)
4414     {       /* write nLocals to (link) param area in dictionary */
4415         *(FICL_INT *)(pVM->pSys->pMarkLocals) = pVM->pSys->nLocals;
4416     }
4417 
4418     return;
4419 }
4420 
4421 
4422 #endif
4423 /**************************************************************************
4424                         c o m p a r e
4425 ** STRING ( c-addr1 u1 c-addr2 u2 -- n )
4426 ** Compare the string specified by c-addr1 u1 to the string specified by
4427 ** c-addr2 u2. The strings are compared, beginning at the given addresses,
4428 ** character by character, up to the length of the shorter string or until a
4429 ** difference is found. If the two strings are identical, n is zero. If the two
4430 ** strings are identical up to the length of the shorter string, n is minus-one
4431 ** (-1) if u1 is less than u2 and one (1) otherwise. If the two strings are not
4432 ** identical up to the length of the shorter string, n is minus-one (-1) if the
4433 ** first non-matching character in the string specified by c-addr1 u1 has a
4434 ** lesser numeric value than the corresponding character in the string specified
4435 ** by c-addr2 u2 and one (1) otherwise.
4436 **************************************************************************/
4437 static void compareInternal(FICL_VM *pVM, int caseInsensitive)
4438 {
4439     char *cp1, *cp2;
4440     FICL_UNS u1, u2, uMin;
4441     int n = 0;
4442 
4443     vmCheckStack(pVM, 4, 1);
4444     u2  = stackPopUNS(pVM->pStack);
4445     cp2 = (char *)stackPopPtr(pVM->pStack);
4446     u1  = stackPopUNS(pVM->pStack);
4447     cp1 = (char *)stackPopPtr(pVM->pStack);
4448 
4449     uMin = (u1 < u2)? u1 : u2;
4450     for ( ; (uMin > 0) && (n == 0); uMin--)
4451     {
4452 		char c1 = *cp1++;
4453 		char c2 = *cp2++;
4454 		if (caseInsensitive)
4455 		{
4456 			c1 = (char)tolower(c1);
4457 			c2 = (char)tolower(c2);
4458 		}
4459         n = (int)(c1 - c2);
4460     }
4461 
4462     if (n == 0)
4463         n = (int)(u1 - u2);
4464 
4465     if (n < 0)
4466         n = -1;
4467     else if (n > 0)
4468         n = 1;
4469 
4470     PUSHINT(n);
4471     return;
4472 }
4473 
4474 
4475 static void compareString(FICL_VM *pVM)
4476 {
4477 	compareInternal(pVM, FALSE);
4478 }
4479 
4480 
4481 static void compareStringInsensitive(FICL_VM *pVM)
4482 {
4483 	compareInternal(pVM, TRUE);
4484 }
4485 
4486 
4487 /**************************************************************************
4488                         p a d
4489 ** CORE EXT  ( -- c-addr )
4490 ** c-addr is the address of a transient region that can be used to hold
4491 ** data for intermediate processing.
4492 **************************************************************************/
4493 static void pad(FICL_VM *pVM)
4494 {
4495     stackPushPtr(pVM->pStack, pVM->pad);
4496 }
4497 
4498 
4499 /**************************************************************************
4500                         s o u r c e - i d
4501 ** CORE EXT, FILE   ( -- 0 | -1 | fileid )
4502 **    Identifies the input source as follows:
4503 **
4504 ** SOURCE-ID       Input source
4505 ** ---------       ------------
4506 ** fileid          Text file fileid
4507 ** -1              String (via EVALUATE)
4508 ** 0               User input device
4509 **************************************************************************/
4510 static void sourceid(FICL_VM *pVM)
4511 {
4512     PUSHINT(pVM->sourceID.i);
4513     return;
4514 }
4515 
4516 
4517 /**************************************************************************
4518                         r e f i l l
4519 ** CORE EXT   ( -- flag )
4520 ** Attempt to fill the input buffer from the input source, returning a true
4521 ** flag if successful.
4522 ** When the input source is the user input device, attempt to receive input
4523 ** into the terminal input buffer. If successful, make the result the input
4524 ** buffer, set >IN to zero, and return true. Receipt of a line containing no
4525 ** characters is considered successful. If there is no input available from
4526 ** the current input source, return false.
4527 ** When the input source is a string from EVALUATE, return false and
4528 ** perform no other action.
4529 **************************************************************************/
4530 static void refill(FICL_VM *pVM)
4531 {
4532     FICL_INT ret = (pVM->sourceID.i == -1) ? FICL_FALSE : FICL_TRUE;
4533     if (ret && (pVM->fRestart == 0))
4534         vmThrow(pVM, VM_RESTART);
4535 
4536     PUSHINT(ret);
4537     return;
4538 }
4539 
4540 
4541 /**************************************************************************
4542                         freebsd exception handling words
4543 ** Catch, from ANS Forth standard. Installs a safety net, then EXECUTE
4544 ** the word in ToS. If an exception happens, restore the state to what
4545 ** it was before, and pushes the exception value on the stack. If not,
4546 ** push zero.
4547 **
4548 ** Notice that Catch implements an inner interpreter. This is ugly,
4549 ** but given how ficl works, it cannot be helped. The problem is that
4550 ** colon definitions will be executed *after* the function returns,
4551 ** while "code" definitions will be executed immediately. I considered
4552 ** other solutions to this problem, but all of them shared the same
4553 ** basic problem (with added disadvantages): if ficl ever changes it's
4554 ** inner thread modus operandi, one would have to fix this word.
4555 **
4556 ** More comments can be found throughout catch's code.
4557 **
4558 ** Daniel C. Sobral Jan 09/1999
4559 ** sadler may 2000 -- revised to follow ficl.c:ficlExecXT.
4560 **************************************************************************/
4561 
4562 static void ficlCatch(FICL_VM *pVM)
4563 {
4564     int         except;
4565     jmp_buf     vmState;
4566     FICL_VM     VM;
4567     FICL_STACK  pStack;
4568     FICL_STACK  rStack;
4569     FICL_WORD   *pFW;
4570 
4571     assert(pVM);
4572     assert(pVM->pSys->pExitInner);
4573 
4574 
4575     /*
4576     ** Get xt.
4577     ** We need this *before* we save the stack pointer, or
4578     ** we'll have to pop one element out of the stack after
4579     ** an exception. I prefer to get done with it up front. :-)
4580     */
4581 #if FICL_ROBUST > 1
4582     vmCheckStack(pVM, 1, 0);
4583 #endif
4584     pFW = stackPopPtr(pVM->pStack);
4585 
4586     /*
4587     ** Save vm's state -- a catch will not back out environmental
4588     ** changes.
4589     **
4590     ** We are *not* saving dictionary state, since it is
4591     ** global instead of per vm, and we are not saving
4592     ** stack contents, since we are not required to (and,
4593     ** thus, it would be useless). We save pVM, and pVM
4594     ** "stacks" (a structure containing general information
4595     ** about it, including the current stack pointer).
4596     */
4597     memcpy((void*)&VM, (void*)pVM, sizeof(FICL_VM));
4598     memcpy((void*)&pStack, (void*)pVM->pStack, sizeof(FICL_STACK));
4599     memcpy((void*)&rStack, (void*)pVM->rStack, sizeof(FICL_STACK));
4600 
4601     /*
4602     ** Give pVM a jmp_buf
4603     */
4604     pVM->pState = &vmState;
4605 
4606     /*
4607     ** Safety net
4608     */
4609     except = setjmp(vmState);
4610 
4611     switch (except)
4612     {
4613         /*
4614         ** Setup condition - push poison pill so that the VM throws
4615         ** VM_INNEREXIT if the XT terminates normally, then execute
4616         ** the XT
4617         */
4618     case 0:
4619         vmPushIP(pVM, &(pVM->pSys->pExitInner));          /* Open mouth, insert emetic */
4620         vmExecute(pVM, pFW);
4621         vmInnerLoop(pVM);
4622         break;
4623 
4624         /*
4625         ** Normal exit from XT - lose the poison pill,
4626         ** restore old setjmp vector and push a zero.
4627         */
4628     case VM_INNEREXIT:
4629         vmPopIP(pVM);                   /* Gack - hurl poison pill */
4630         pVM->pState = VM.pState;        /* Restore just the setjmp vector */
4631         PUSHINT(0);   /* Push 0 -- everything is ok */
4632         break;
4633 
4634         /*
4635         ** Some other exception got thrown - restore pre-existing VM state
4636         ** and push the exception code
4637         */
4638     default:
4639         /* Restore vm's state */
4640         memcpy((void*)pVM, (void*)&VM, sizeof(FICL_VM));
4641         memcpy((void*)pVM->pStack, (void*)&pStack, sizeof(FICL_STACK));
4642         memcpy((void*)pVM->rStack, (void*)&rStack, sizeof(FICL_STACK));
4643 
4644         PUSHINT(except);/* Push error */
4645         break;
4646     }
4647 }
4648 
4649 /**************************************************************************
4650 **                     t h r o w
4651 ** EXCEPTION
4652 ** Throw --  From ANS Forth standard.
4653 **
4654 ** Throw takes the ToS and, if that's different from zero,
4655 ** returns to the last executed catch context. Further throws will
4656 ** unstack previously executed "catches", in LIFO mode.
4657 **
4658 ** Daniel C. Sobral Jan 09/1999
4659 **************************************************************************/
4660 static void ficlThrow(FICL_VM *pVM)
4661 {
4662     int except;
4663 
4664     except = stackPopINT(pVM->pStack);
4665 
4666     if (except)
4667         vmThrow(pVM, except);
4668 }
4669 
4670 
4671 /**************************************************************************
4672 **                     a l l o c a t e
4673 ** MEMORY
4674 **************************************************************************/
4675 static void ansAllocate(FICL_VM *pVM)
4676 {
4677     size_t size;
4678     void *p;
4679 
4680     size = stackPopINT(pVM->pStack);
4681     p = ficlMalloc(size);
4682     PUSHPTR(p);
4683     if (p)
4684         PUSHINT(0);
4685     else
4686         PUSHINT(1);
4687 }
4688 
4689 
4690 /**************************************************************************
4691 **                     f r e e
4692 ** MEMORY
4693 **************************************************************************/
4694 static void ansFree(FICL_VM *pVM)
4695 {
4696     void *p;
4697 
4698     p = stackPopPtr(pVM->pStack);
4699     ficlFree(p);
4700     PUSHINT(0);
4701 }
4702 
4703 
4704 /**************************************************************************
4705 **                     r e s i z e
4706 ** MEMORY
4707 **************************************************************************/
4708 static void ansResize(FICL_VM *pVM)
4709 {
4710     size_t size;
4711     void *new, *old;
4712 
4713     size = stackPopINT(pVM->pStack);
4714     old = stackPopPtr(pVM->pStack);
4715     new = ficlRealloc(old, size);
4716     if (new)
4717     {
4718         PUSHPTR(new);
4719         PUSHINT(0);
4720     }
4721     else
4722     {
4723         PUSHPTR(old);
4724         PUSHINT(1);
4725     }
4726 }
4727 
4728 
4729 /**************************************************************************
4730 **                     e x i t - i n n e r
4731 ** Signals execXT that an inner loop has completed
4732 **************************************************************************/
4733 static void ficlExitInner(FICL_VM *pVM)
4734 {
4735     vmThrow(pVM, VM_INNEREXIT);
4736 }
4737 
4738 
4739 /**************************************************************************
4740                         d n e g a t e
4741 ** DOUBLE   ( d1 -- d2 )
4742 ** d2 is the negation of d1.
4743 **************************************************************************/
4744 static void dnegate(FICL_VM *pVM)
4745 {
4746     DPINT i = i64Pop(pVM->pStack);
4747     i = m64Negate(i);
4748     i64Push(pVM->pStack, i);
4749 
4750     return;
4751 }
4752 
4753 
4754 #if 0
4755 /**************************************************************************
4756 
4757 **
4758 **************************************************************************/
4759 static void funcname(FICL_VM *pVM)
4760 {
4761     IGNORE(pVM);
4762     return;
4763 }
4764 
4765 
4766 #endif
4767 /**************************************************************************
4768                         f i c l W o r d C l a s s i f y
4769 ** This public function helps to classify word types for SEE
4770 ** and the deugger in tools.c. Given a pointer to a word, it returns
4771 ** a member of WOR
4772 **************************************************************************/
4773 WORDKIND ficlWordClassify(FICL_WORD *pFW)
4774 {
4775     typedef struct
4776     {
4777         WORDKIND kind;
4778         FICL_CODE code;
4779     } CODEtoKIND;
4780 
4781     static CODEtoKIND codeMap[] =
4782     {
4783         {BRANCH,     branchParen},
4784         {COLON,       colonParen},
4785         {CONSTANT, constantParen},
4786         {CREATE,     createParen},
4787         {DO,             doParen},
4788         {DOES,            doDoes},
4789         {IF,             branch0},
4790         {LITERAL,   literalParen},
4791         {LOOP,         loopParen},
4792         {OF,             ofParen},
4793         {PLOOP,    plusLoopParen},
4794         {QDO,           qDoParen},
4795         {CSTRINGLIT,  cstringLit},
4796         {STRINGLIT,    stringLit},
4797 #if FICL_WANT_USER
4798         {USER,         userParen},
4799 #endif
4800         {VARIABLE, variableParen},
4801     };
4802 
4803 #define nMAP (sizeof(codeMap) / sizeof(CODEtoKIND))
4804 
4805     FICL_CODE code = pFW->code;
4806     int i;
4807 
4808     for (i=0; i < nMAP; i++)
4809     {
4810         if (codeMap[i].code == code)
4811             return codeMap[i].kind;
4812     }
4813 
4814     return PRIMITIVE;
4815 }
4816 
4817 
4818 #ifdef TESTMAIN
4819 /**************************************************************************
4820 **                     r a n d o m
4821 ** FICL-specific
4822 **************************************************************************/
4823 static void ficlRandom(FICL_VM *pVM)
4824 {
4825     PUSHUNS(random());
4826 }
4827 
4828 
4829 /**************************************************************************
4830 **                     s e e d - r a n d o m
4831 ** FICL-specific
4832 **************************************************************************/
4833 static void ficlSeedRandom(FICL_VM *pVM)
4834 {
4835     srandom(POPUNS());
4836 }
4837 #endif
4838 
4839 
4840 /**************************************************************************
4841                         f i c l C o m p i l e C o r e
4842 ** Builds the primitive wordset and the environment-query namespace.
4843 **************************************************************************/
4844 
4845 void ficlCompileCore(FICL_SYSTEM *pSys)
4846 {
4847     FICL_DICT *dp = pSys->dp;
4848     assert (dp);
4849 
4850 
4851     /*
4852     ** CORE word set
4853     ** see softcore.c for definitions of: abs bl space spaces abort"
4854     */
4855     pSys->pStore =
4856     dictAppendWord(dp, "!",         store,          FW_DEFAULT);
4857     dictAppendWord(dp, "#",         numberSign,     FW_DEFAULT);
4858     dictAppendWord(dp, "#>",        numberSignGreater,FW_DEFAULT);
4859     dictAppendWord(dp, "#s",        numberSignS,    FW_DEFAULT);
4860     dictAppendWord(dp, "\'",        ficlTick,       FW_DEFAULT);
4861     dictAppendWord(dp, "(",         commentHang,    FW_IMMEDIATE);
4862     dictAppendWord(dp, "*",         mul,            FW_DEFAULT);
4863     dictAppendWord(dp, "*/",        mulDiv,         FW_DEFAULT);
4864     dictAppendWord(dp, "*/mod",     mulDivRem,      FW_DEFAULT);
4865     dictAppendWord(dp, "+",         add,            FW_DEFAULT);
4866     dictAppendWord(dp, "+!",        plusStore,      FW_DEFAULT);
4867     dictAppendWord(dp, "+loop",     plusLoopCoIm,   FW_COMPIMMED);
4868     dictAppendWord(dp, ",",         comma,          FW_DEFAULT);
4869     dictAppendWord(dp, "-",         sub,            FW_DEFAULT);
4870     dictAppendWord(dp, ".",         displayCell,    FW_DEFAULT);
4871     dictAppendWord(dp, ".\"",       dotQuoteCoIm,   FW_COMPIMMED);
4872     dictAppendWord(dp, "/",         ficlDiv,        FW_DEFAULT);
4873     dictAppendWord(dp, "/mod",      slashMod,       FW_DEFAULT);
4874     dictAppendWord(dp, "0<",        zeroLess,       FW_DEFAULT);
4875     dictAppendWord(dp, "0=",        zeroEquals,     FW_DEFAULT);
4876     dictAppendWord(dp, "1+",        onePlus,        FW_DEFAULT);
4877     dictAppendWord(dp, "1-",        oneMinus,       FW_DEFAULT);
4878     dictAppendWord(dp, "2!",        twoStore,       FW_DEFAULT);
4879     dictAppendWord(dp, "2*",        twoMul,         FW_DEFAULT);
4880     dictAppendWord(dp, "2/",        twoDiv,         FW_DEFAULT);
4881     dictAppendWord(dp, "2@",        twoFetch,       FW_DEFAULT);
4882     dictAppendWord(dp, "2drop",     twoDrop,        FW_DEFAULT);
4883     dictAppendWord(dp, "2dup",      twoDup,         FW_DEFAULT);
4884     dictAppendWord(dp, "2over",     twoOver,        FW_DEFAULT);
4885     dictAppendWord(dp, "2swap",     twoSwap,        FW_DEFAULT);
4886     dictAppendWord(dp, ":",         colon,          FW_DEFAULT);
4887     dictAppendWord(dp, ";",         semicolonCoIm,  FW_COMPIMMED);
4888     dictAppendWord(dp, "<",         isLess,         FW_DEFAULT);
4889     dictAppendWord(dp, "<#",        lessNumberSign, FW_DEFAULT);
4890     dictAppendWord(dp, "=",         isEqual,        FW_DEFAULT);
4891     dictAppendWord(dp, ">",         isGreater,      FW_DEFAULT);
4892     dictAppendWord(dp, ">body",     toBody,         FW_DEFAULT);
4893     dictAppendWord(dp, ">in",       toIn,           FW_DEFAULT);
4894     dictAppendWord(dp, ">number",   toNumber,       FW_DEFAULT);
4895     dictAppendWord(dp, ">r",        toRStack,       FW_COMPILE);
4896     dictAppendWord(dp, "?dup",      questionDup,    FW_DEFAULT);
4897     dictAppendWord(dp, "@",         fetch,          FW_DEFAULT);
4898     dictAppendWord(dp, "abort",     ficlAbort,      FW_DEFAULT);
4899     dictAppendWord(dp, "accept",    accept,         FW_DEFAULT);
4900     dictAppendWord(dp, "align",     align,          FW_DEFAULT);
4901     dictAppendWord(dp, "aligned",   aligned,        FW_DEFAULT);
4902     dictAppendWord(dp, "allot",     allot,          FW_DEFAULT);
4903     dictAppendWord(dp, "and",       bitwiseAnd,     FW_DEFAULT);
4904     dictAppendWord(dp, "base",      base,           FW_DEFAULT);
4905     dictAppendWord(dp, "begin",     beginCoIm,      FW_COMPIMMED);
4906     dictAppendWord(dp, "c!",        cStore,         FW_DEFAULT);
4907     dictAppendWord(dp, "c,",        cComma,         FW_DEFAULT);
4908     dictAppendWord(dp, "c@",        cFetch,         FW_DEFAULT);
4909     dictAppendWord(dp, "case",      caseCoIm,       FW_COMPIMMED);
4910     dictAppendWord(dp, "cell+",     cellPlus,       FW_DEFAULT);
4911     dictAppendWord(dp, "cells",     cells,          FW_DEFAULT);
4912     dictAppendWord(dp, "char",      ficlChar,       FW_DEFAULT);
4913     dictAppendWord(dp, "char+",     charPlus,       FW_DEFAULT);
4914     dictAppendWord(dp, "chars",     ficlChars,      FW_DEFAULT);
4915     dictAppendWord(dp, "constant",  constant,       FW_DEFAULT);
4916     dictAppendWord(dp, "count",     count,          FW_DEFAULT);
4917     dictAppendWord(dp, "cr",        cr,             FW_DEFAULT);
4918     dictAppendWord(dp, "create",    create,         FW_DEFAULT);
4919     dictAppendWord(dp, "decimal",   decimal,        FW_DEFAULT);
4920     dictAppendWord(dp, "depth",     depth,          FW_DEFAULT);
4921     dictAppendWord(dp, "do",        doCoIm,         FW_COMPIMMED);
4922     dictAppendWord(dp, "does>",     doesCoIm,       FW_COMPIMMED);
4923     pSys->pDrop =
4924     dictAppendWord(dp, "drop",      drop,           FW_DEFAULT);
4925     dictAppendWord(dp, "dup",       dup,            FW_DEFAULT);
4926     dictAppendWord(dp, "else",      elseCoIm,       FW_COMPIMMED);
4927     dictAppendWord(dp, "emit",      emit,           FW_DEFAULT);
4928     dictAppendWord(dp, "endcase",   endcaseCoIm,    FW_COMPIMMED);
4929     dictAppendWord(dp, "endof",     endofCoIm,      FW_COMPIMMED);
4930     dictAppendWord(dp, "environment?", environmentQ,FW_DEFAULT);
4931     dictAppendWord(dp, "evaluate",  evaluate,       FW_DEFAULT);
4932     dictAppendWord(dp, "execute",   execute,        FW_DEFAULT);
4933     dictAppendWord(dp, "exit",      exitCoIm,       FW_COMPIMMED);
4934     dictAppendWord(dp, "fallthrough",fallthroughCoIm,FW_COMPIMMED);
4935     dictAppendWord(dp, "fill",      fill,           FW_DEFAULT);
4936     dictAppendWord(dp, "find",      cFind,          FW_DEFAULT);
4937     dictAppendWord(dp, "fm/mod",    fmSlashMod,     FW_DEFAULT);
4938     dictAppendWord(dp, "here",      here,           FW_DEFAULT);
4939     dictAppendWord(dp, "hold",      hold,           FW_DEFAULT);
4940     dictAppendWord(dp, "i",         loopICo,        FW_COMPILE);
4941     dictAppendWord(dp, "if",        ifCoIm,         FW_COMPIMMED);
4942     dictAppendWord(dp, "immediate", immediate,      FW_DEFAULT);
4943     dictAppendWord(dp, "invert",    bitwiseNot,     FW_DEFAULT);
4944     dictAppendWord(dp, "j",         loopJCo,        FW_COMPILE);
4945     dictAppendWord(dp, "k",         loopKCo,        FW_COMPILE);
4946     dictAppendWord(dp, "leave",     leaveCo,        FW_COMPILE);
4947     dictAppendWord(dp, "literal",   literalIm,      FW_IMMEDIATE);
4948     dictAppendWord(dp, "loop",      loopCoIm,       FW_COMPIMMED);
4949     dictAppendWord(dp, "lshift",    lshift,         FW_DEFAULT);
4950     dictAppendWord(dp, "m*",        mStar,          FW_DEFAULT);
4951     dictAppendWord(dp, "max",       ficlMax,        FW_DEFAULT);
4952     dictAppendWord(dp, "min",       ficlMin,        FW_DEFAULT);
4953     dictAppendWord(dp, "mod",       ficlMod,        FW_DEFAULT);
4954     dictAppendWord(dp, "move",      move,           FW_DEFAULT);
4955     dictAppendWord(dp, "negate",    negate,         FW_DEFAULT);
4956     dictAppendWord(dp, "of",        ofCoIm,         FW_COMPIMMED);
4957     dictAppendWord(dp, "or",        bitwiseOr,      FW_DEFAULT);
4958     dictAppendWord(dp, "over",      over,           FW_DEFAULT);
4959     dictAppendWord(dp, "postpone",  postponeCoIm,   FW_COMPIMMED);
4960     dictAppendWord(dp, "quit",      quit,           FW_DEFAULT);
4961     dictAppendWord(dp, "r>",        fromRStack,     FW_COMPILE);
4962     dictAppendWord(dp, "r@",        fetchRStack,    FW_COMPILE);
4963     dictAppendWord(dp, "recurse",   recurseCoIm,    FW_COMPIMMED);
4964     dictAppendWord(dp, "repeat",    repeatCoIm,     FW_COMPIMMED);
4965     dictAppendWord(dp, "rot",       rot,            FW_DEFAULT);
4966     dictAppendWord(dp, "rshift",    rshift,         FW_DEFAULT);
4967     dictAppendWord(dp, "s\"",       stringQuoteIm,  FW_IMMEDIATE);
4968     dictAppendWord(dp, "s>d",       sToD,           FW_DEFAULT);
4969     dictAppendWord(dp, "sign",      sign,           FW_DEFAULT);
4970     dictAppendWord(dp, "sm/rem",    smSlashRem,     FW_DEFAULT);
4971     dictAppendWord(dp, "source",    source,         FW_DEFAULT);
4972     dictAppendWord(dp, "state",     state,          FW_DEFAULT);
4973     dictAppendWord(dp, "swap",      swap,           FW_DEFAULT);
4974     dictAppendWord(dp, "then",      endifCoIm,      FW_COMPIMMED);
4975     dictAppendWord(dp, "type",      type,           FW_DEFAULT);
4976     dictAppendWord(dp, "u.",        uDot,           FW_DEFAULT);
4977     dictAppendWord(dp, "u<",        uIsLess,        FW_DEFAULT);
4978     dictAppendWord(dp, "um*",       umStar,         FW_DEFAULT);
4979     dictAppendWord(dp, "um/mod",    umSlashMod,     FW_DEFAULT);
4980     dictAppendWord(dp, "unloop",    unloopCo,       FW_COMPILE);
4981     dictAppendWord(dp, "until",     untilCoIm,      FW_COMPIMMED);
4982     dictAppendWord(dp, "variable",  variable,       FW_DEFAULT);
4983     dictAppendWord(dp, "while",     whileCoIm,      FW_COMPIMMED);
4984     dictAppendWord(dp, "word",      ficlWord,       FW_DEFAULT);
4985     dictAppendWord(dp, "xor",       bitwiseXor,     FW_DEFAULT);
4986     dictAppendWord(dp, "[",         lbracketCoIm,   FW_COMPIMMED);
4987     dictAppendWord(dp, "[\']",      bracketTickCoIm,FW_COMPIMMED);
4988     dictAppendWord(dp, "[char]",    charCoIm,       FW_COMPIMMED);
4989     dictAppendWord(dp, "]",         rbracket,       FW_DEFAULT);
4990     /*
4991     ** CORE EXT word set...
4992     ** see softcore.fr for other definitions
4993     */
4994     /* "#tib" */
4995     dictAppendWord(dp, ".(",        dotParen,       FW_IMMEDIATE);
4996     /* ".r" */
4997     dictAppendWord(dp, "0>",        zeroGreater,    FW_DEFAULT);
4998     dictAppendWord(dp, "2>r",       twoToR,         FW_COMPILE);
4999     dictAppendWord(dp, "2r>",       twoRFrom,       FW_COMPILE);
5000     dictAppendWord(dp, "2r@",       twoRFetch,      FW_COMPILE);
5001     dictAppendWord(dp, ":noname",   colonNoName,    FW_DEFAULT);
5002     dictAppendWord(dp, "?do",       qDoCoIm,        FW_COMPIMMED);
5003     dictAppendWord(dp, "again",     againCoIm,      FW_COMPIMMED);
5004     dictAppendWord(dp, "c\"",       cstringQuoteIm, FW_IMMEDIATE);
5005     dictAppendWord(dp, "hex",       hex,            FW_DEFAULT);
5006     dictAppendWord(dp, "pad",       pad,            FW_DEFAULT);
5007     dictAppendWord(dp, "parse",     parse,          FW_DEFAULT);
5008     dictAppendWord(dp, "pick",      pick,           FW_DEFAULT);
5009     /* query restore-input save-input tib u.r u> unused [compile] */
5010     dictAppendWord(dp, "roll",      roll,           FW_DEFAULT);
5011     dictAppendWord(dp, "refill",    refill,         FW_DEFAULT);
5012     dictAppendWord(dp, "source-id", sourceid,       FW_DEFAULT);
5013     dictAppendWord(dp, "to",        toValue,        FW_IMMEDIATE);
5014     dictAppendWord(dp, "value",     constant,       FW_DEFAULT);
5015     dictAppendWord(dp, "\\",        commentLine,    FW_IMMEDIATE);
5016 
5017 
5018     /*
5019     ** Set CORE environment query values
5020     */
5021     ficlSetEnv(pSys, "/counted-string",   FICL_STRING_MAX);
5022     ficlSetEnv(pSys, "/hold",             nPAD);
5023     ficlSetEnv(pSys, "/pad",              nPAD);
5024     ficlSetEnv(pSys, "address-unit-bits", 8);
5025     ficlSetEnv(pSys, "core",              FICL_TRUE);
5026     ficlSetEnv(pSys, "core-ext",          FICL_FALSE);
5027     ficlSetEnv(pSys, "floored",           FICL_FALSE);
5028     ficlSetEnv(pSys, "max-char",          UCHAR_MAX);
5029     ficlSetEnvD(pSys,"max-d",             0x7fffffff, 0xffffffff);
5030     ficlSetEnv(pSys, "max-n",             0x7fffffff);
5031     ficlSetEnv(pSys, "max-u",             0xffffffff);
5032     ficlSetEnvD(pSys,"max-ud",            0xffffffff, 0xffffffff);
5033     ficlSetEnv(pSys, "return-stack-cells",FICL_DEFAULT_STACK);
5034     ficlSetEnv(pSys, "stack-cells",       FICL_DEFAULT_STACK);
5035 
5036     /*
5037     ** DOUBLE word set (partial)
5038     */
5039     dictAppendWord(dp, "2constant", twoConstant,    FW_IMMEDIATE);
5040     dictAppendWord(dp, "2literal",  twoLiteralIm,   FW_IMMEDIATE);
5041     dictAppendWord(dp, "2variable", twoVariable,    FW_IMMEDIATE);
5042     dictAppendWord(dp, "dnegate",   dnegate,        FW_DEFAULT);
5043 
5044 
5045     /*
5046     ** EXCEPTION word set
5047     */
5048     dictAppendWord(dp, "catch",     ficlCatch,      FW_DEFAULT);
5049     dictAppendWord(dp, "throw",     ficlThrow,      FW_DEFAULT);
5050 
5051     ficlSetEnv(pSys, "exception",         FICL_TRUE);
5052     ficlSetEnv(pSys, "exception-ext",     FICL_TRUE);
5053 
5054     /*
5055     ** LOCAL and LOCAL EXT
5056     ** see softcore.c for implementation of locals|
5057     */
5058 #if FICL_WANT_LOCALS
5059     pSys->pLinkParen =
5060     dictAppendWord(dp, "(link)",    linkParen,      FW_COMPILE);
5061     pSys->pUnLinkParen =
5062     dictAppendWord(dp, "(unlink)",  unlinkParen,    FW_COMPILE);
5063     dictAppendWord(dp, "doLocal",   doLocalIm,      FW_COMPIMMED);
5064     pSys->pGetLocalParen =
5065     dictAppendWord(dp, "(@local)",  getLocalParen,  FW_COMPILE);
5066     pSys->pToLocalParen =
5067     dictAppendWord(dp, "(toLocal)", toLocalParen,   FW_COMPILE);
5068     pSys->pGetLocal0 =
5069     dictAppendWord(dp, "(@local0)", getLocal0,      FW_COMPILE);
5070     pSys->pToLocal0 =
5071     dictAppendWord(dp, "(toLocal0)",toLocal0,       FW_COMPILE);
5072     pSys->pGetLocal1 =
5073     dictAppendWord(dp, "(@local1)", getLocal1,      FW_COMPILE);
5074     pSys->pToLocal1 =
5075     dictAppendWord(dp, "(toLocal1)",toLocal1,       FW_COMPILE);
5076     dictAppendWord(dp, "(local)",   localParen,     FW_COMPILE);
5077 
5078     pSys->pGet2LocalParen =
5079     dictAppendWord(dp, "(@2local)", get2LocalParen, FW_COMPILE);
5080     pSys->pTo2LocalParen =
5081     dictAppendWord(dp, "(to2Local)",to2LocalParen,  FW_COMPILE);
5082     dictAppendWord(dp, "(2local)",  twoLocalParen,  FW_COMPILE);
5083 
5084     ficlSetEnv(pSys, "locals",            FICL_TRUE);
5085     ficlSetEnv(pSys, "locals-ext",        FICL_TRUE);
5086     ficlSetEnv(pSys, "#locals",           FICL_MAX_LOCALS);
5087 #endif
5088 
5089     /*
5090     ** Optional MEMORY-ALLOC word set
5091     */
5092 
5093     dictAppendWord(dp, "allocate",  ansAllocate,    FW_DEFAULT);
5094     dictAppendWord(dp, "free",      ansFree,        FW_DEFAULT);
5095     dictAppendWord(dp, "resize",    ansResize,      FW_DEFAULT);
5096 
5097     ficlSetEnv(pSys, "memory-alloc",      FICL_TRUE);
5098 
5099     /*
5100     ** optional SEARCH-ORDER word set
5101     */
5102     ficlCompileSearch(pSys);
5103 
5104     /*
5105     ** TOOLS and TOOLS EXT
5106     */
5107     ficlCompileTools(pSys);
5108 
5109     /*
5110     ** FILE and FILE EXT
5111     */
5112 #if FICL_WANT_FILE
5113     ficlCompileFile(pSys);
5114 #endif
5115 
5116     /*
5117     ** Ficl extras
5118     */
5119 #if FICL_WANT_FLOAT
5120     dictAppendWord(dp, ".hash",     dictHashSummary,FW_DEFAULT);
5121 #endif
5122     dictAppendWord(dp, ".ver",      ficlVersion,    FW_DEFAULT);
5123     dictAppendWord(dp, "-roll",     minusRoll,      FW_DEFAULT);
5124     dictAppendWord(dp, ">name",     toName,         FW_DEFAULT);
5125     dictAppendWord(dp, "add-parse-step",
5126                                     addParseStep,   FW_DEFAULT);
5127     dictAppendWord(dp, "body>",     fromBody,       FW_DEFAULT);
5128     dictAppendWord(dp, "compare",   compareString,  FW_DEFAULT);   /* STRING */
5129     dictAppendWord(dp, "compare-insensitive",   compareStringInsensitive,  FW_DEFAULT);   /* STRING */
5130     dictAppendWord(dp, "compile-only",
5131                                     compileOnly,    FW_DEFAULT);
5132     dictAppendWord(dp, "endif",     endifCoIm,      FW_COMPIMMED);
5133     dictAppendWord(dp, "last-word", getLastWord,    FW_DEFAULT);
5134     dictAppendWord(dp, "hash",      hash,           FW_DEFAULT);
5135     dictAppendWord(dp, "objectify", setObjectFlag,  FW_DEFAULT);
5136     dictAppendWord(dp, "?object",   isObject,       FW_DEFAULT);
5137     dictAppendWord(dp, "parse-word",parseNoCopy,    FW_DEFAULT);
5138     dictAppendWord(dp, "sfind",     sFind,          FW_DEFAULT);
5139     dictAppendWord(dp, "sliteral",  sLiteralCoIm,   FW_COMPIMMED); /* STRING */
5140     dictAppendWord(dp, "sprintf",   ficlSprintf,    FW_DEFAULT);
5141     dictAppendWord(dp, "strlen",    ficlStrlen,     FW_DEFAULT);
5142     dictAppendWord(dp, "q@",        quadFetch,      FW_DEFAULT);
5143     dictAppendWord(dp, "q!",        quadStore,      FW_DEFAULT);
5144     dictAppendWord(dp, "w@",        wFetch,         FW_DEFAULT);
5145     dictAppendWord(dp, "w!",        wStore,         FW_DEFAULT);
5146     dictAppendWord(dp, "x.",        hexDot,         FW_DEFAULT);
5147 #if FICL_WANT_USER
5148     dictAppendWord(dp, "(user)",    userParen,      FW_DEFAULT);
5149     dictAppendWord(dp, "user",      userVariable,   FW_DEFAULT);
5150 #endif
5151 #ifdef TESTMAIN
5152     dictAppendWord(dp, "random",    ficlRandom,     FW_DEFAULT);
5153     dictAppendWord(dp, "seed-random",ficlSeedRandom,FW_DEFAULT);
5154 #endif
5155 
5156     /*
5157     ** internal support words
5158     */
5159     dictAppendWord(dp, "(create)",  createParen,    FW_COMPILE);
5160     pSys->pExitParen =
5161     dictAppendWord(dp, "(exit)",    exitParen,      FW_COMPILE);
5162     pSys->pSemiParen =
5163     dictAppendWord(dp, "(;)",       semiParen,      FW_COMPILE);
5164     pSys->pLitParen =
5165     dictAppendWord(dp, "(literal)", literalParen,   FW_COMPILE);
5166     pSys->pTwoLitParen =
5167     dictAppendWord(dp, "(2literal)",twoLitParen,    FW_COMPILE);
5168     pSys->pStringLit =
5169     dictAppendWord(dp, "(.\")",     stringLit,      FW_COMPILE);
5170     pSys->pCStringLit =
5171     dictAppendWord(dp, "(c\")",     cstringLit,     FW_COMPILE);
5172     pSys->pBranch0 =
5173     dictAppendWord(dp, "(branch0)",      branch0,        FW_COMPILE);
5174     pSys->pBranchParen =
5175     dictAppendWord(dp, "(branch)",  branchParen,    FW_COMPILE);
5176     pSys->pDoParen =
5177     dictAppendWord(dp, "(do)",      doParen,        FW_COMPILE);
5178     pSys->pDoesParen =
5179     dictAppendWord(dp, "(does>)",   doesParen,      FW_COMPILE);
5180     pSys->pQDoParen =
5181     dictAppendWord(dp, "(?do)",     qDoParen,       FW_COMPILE);
5182     pSys->pLoopParen =
5183     dictAppendWord(dp, "(loop)",    loopParen,      FW_COMPILE);
5184     pSys->pPLoopParen =
5185     dictAppendWord(dp, "(+loop)",   plusLoopParen,  FW_COMPILE);
5186     pSys->pInterpret =
5187     dictAppendWord(dp, "interpret", interpret,      FW_DEFAULT);
5188     dictAppendWord(dp, "lookup",    lookup,         FW_DEFAULT);
5189     pSys->pOfParen =
5190     dictAppendWord(dp, "(of)",      ofParen,        FW_DEFAULT);
5191     dictAppendWord(dp, "(variable)",variableParen,  FW_COMPILE);
5192     dictAppendWord(dp, "(constant)",constantParen,  FW_COMPILE);
5193     dictAppendWord(dp, "(parse-step)",
5194                                     parseStepParen, FW_DEFAULT);
5195 	pSys->pExitInner =
5196     dictAppendWord(dp, "exit-inner",ficlExitInner,  FW_DEFAULT);
5197 
5198     /*
5199     ** Set up system's outer interpreter loop - maybe this should be in initSystem?
5200     */
5201     pSys->pInterp[0] = pSys->pInterpret;
5202     pSys->pInterp[1] = pSys->pBranchParen;
5203     pSys->pInterp[2] = (FICL_WORD *)(void *)(-2);
5204 
5205     assert(dictCellsAvail(dp) > 0);
5206 
5207     return;
5208 }
5209