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freebsd-dev/stand/ficl/words.c
Toomas Soome dba7640e44 ficl: instead of pad, emit can use local variable 
Pad in forth is used as "scratchpad" and internal implementations
should not use it. Ficl does not really follow this rule and this can fire back.
emit has no need to use pad, we can use local variable instead.
2020-12-01 22:28:02 +00:00

5222 lines
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/*******************************************************************
** w o r d s . c
** Forth Inspired Command Language
** ANS Forth CORE word-set written in C
** Author: John Sadler (john_sadler@alum.mit.edu)
** Created: 19 July 1997
** $Id: words.c,v 1.17 2001/12/05 07:21:34 jsadler Exp $
*******************************************************************/
/*
** Copyright (c) 1997-2001 John Sadler (john_sadler@alum.mit.edu)
** All rights reserved.
**
** Get the latest Ficl release at http://ficl.sourceforge.net
**
** I am interested in hearing from anyone who uses ficl. If you have
** a problem, a success story, a defect, an enhancement request, or
** if you would like to contribute to the ficl release, please
** contact me by email at the address above.
**
** L I C E N S E and D I S C L A I M E R
**
** Redistribution and use in source and binary forms, with or without
** modification, are permitted provided that the following conditions
** are met:
** 1. Redistributions of source code must retain the above copyright
** notice, this list of conditions and the following disclaimer.
** 2. Redistributions in binary form must reproduce the above copyright
** notice, this list of conditions and the following disclaimer in the
** documentation and/or other materials provided with the distribution.
**
** THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
** ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
** IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
** ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
** FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
** DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
** OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
** HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
** LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
** OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
** SUCH DAMAGE.
*/
/* $FreeBSD$ */
#ifdef TESTMAIN
#include <stdlib.h>
#include <stdio.h>
#include <ctype.h>
#include <fcntl.h>
#else
#include <stand.h>
#endif
#include <string.h>
#include "ficl.h"
#include "math64.h"
static void colonParen(FICL_VM *pVM);
static void literalIm(FICL_VM *pVM);
static int ficlParseWord(FICL_VM *pVM, STRINGINFO si);
/*
** Control structure building words use these
** strings' addresses as markers on the stack to
** check for structure completion.
*/
static char doTag[] = "do";
static char colonTag[] = "colon";
static char leaveTag[] = "leave";
static char destTag[] = "target";
static char origTag[] = "origin";
static char caseTag[] = "case";
static char ofTag[] = "of";
static char fallthroughTag[] = "fallthrough";
#if FICL_WANT_LOCALS
static void doLocalIm(FICL_VM *pVM);
static void do2LocalIm(FICL_VM *pVM);
#endif
/*
** C O N T R O L S T R U C T U R E B U I L D E R S
**
** Push current dict location for later branch resolution.
** The location may be either a branch target or a patch address...
*/
static void markBranch(FICL_DICT *dp, FICL_VM *pVM, char *tag)
{
PUSHPTR(dp->here);
PUSHPTR(tag);
return;
}
static void markControlTag(FICL_VM *pVM, char *tag)
{
PUSHPTR(tag);
return;
}
static void matchControlTag(FICL_VM *pVM, char *tag)
{
char *cp;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 0);
#endif
cp = (char *)stackPopPtr(pVM->pStack);
/*
** Changed the code below to compare the pointers first (by popular demand)
*/
if ( (cp != tag) && strcmp(cp, tag) )
{
vmThrowErr(pVM, "Error -- unmatched control structure \"%s\"", tag);
}
return;
}
/*
** Expect a branch target address on the param stack,
** compile a literal offset from the current dict location
** to the target address
*/
static void resolveBackBranch(FICL_DICT *dp, FICL_VM *pVM, char *tag)
{
FICL_INT offset;
CELL *patchAddr;
matchControlTag(pVM, tag);
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 0);
#endif
patchAddr = (CELL *)stackPopPtr(pVM->pStack);
offset = patchAddr - dp->here;
dictAppendCell(dp, LVALUEtoCELL(offset));
return;
}
/*
** Expect a branch patch address on the param stack,
** compile a literal offset from the patch location
** to the current dict location
*/
static void resolveForwardBranch(FICL_DICT *dp, FICL_VM *pVM, char *tag)
{
FICL_INT offset;
CELL *patchAddr;
matchControlTag(pVM, tag);
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 0);
#endif
patchAddr = (CELL *)stackPopPtr(pVM->pStack);
offset = dp->here - patchAddr;
*patchAddr = LVALUEtoCELL(offset);
return;
}
/*
** Match the tag to the top of the stack. If success,
** sopy "here" address into the cell whose address is next
** on the stack. Used by do..leave..loop.
*/
static void resolveAbsBranch(FICL_DICT *dp, FICL_VM *pVM, char *tag)
{
CELL *patchAddr;
char *cp;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 0);
#endif
cp = stackPopPtr(pVM->pStack);
/*
** Changed the comparison below to compare the pointers first (by popular demand)
*/
if ((cp != tag) && strcmp(cp, tag))
{
vmTextOut(pVM, "Warning -- Unmatched control word: ", 0);
vmTextOut(pVM, tag, 1);
}
patchAddr = (CELL *)stackPopPtr(pVM->pStack);
*patchAddr = LVALUEtoCELL(dp->here);
return;
}
/**************************************************************************
f i c l P a r s e N u m b e r
** Attempts to convert the NULL terminated string in the VM's pad to
** a number using the VM's current base. If successful, pushes the number
** onto the param stack and returns TRUE. Otherwise, returns FALSE.
** (jws 8/01) Trailing decimal point causes a zero cell to be pushed. (See
** the standard for DOUBLE wordset.
**************************************************************************/
int ficlParseNumber(FICL_VM *pVM, STRINGINFO si)
{
FICL_INT accum = 0;
char isNeg = FALSE;
char hasDP = FALSE;
unsigned base = pVM->base;
char *cp = SI_PTR(si);
FICL_COUNT count= (FICL_COUNT)SI_COUNT(si);
unsigned ch;
unsigned digit;
if (count > 1)
{
switch (*cp)
{
case '-':
cp++;
count--;
isNeg = TRUE;
break;
case '+':
cp++;
count--;
isNeg = FALSE;
break;
default:
break;
}
}
if ((count > 0) && (cp[count-1] == '.')) /* detect & remove trailing decimal */
{
hasDP = TRUE;
count--;
}
if (count == 0) /* detect "+", "-", ".", "+." etc */
return FALSE;
while ((count--) && ((ch = *cp++) != '\0'))
{
if (!isalnum(ch))
return FALSE;
digit = ch - '0';
if (digit > 9)
digit = tolower(ch) - 'a' + 10;
if (digit >= base)
return FALSE;
accum = accum * base + digit;
}
if (hasDP) /* simple (required) DOUBLE support */
PUSHINT(0);
if (isNeg)
accum = -accum;
PUSHINT(accum);
if (pVM->state == COMPILE)
literalIm(pVM);
return TRUE;
}
/**************************************************************************
a d d & f r i e n d s
**
**************************************************************************/
static void add(FICL_VM *pVM)
{
FICL_INT i;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 1);
#endif
i = stackPopINT(pVM->pStack);
i += stackGetTop(pVM->pStack).i;
stackSetTop(pVM->pStack, LVALUEtoCELL(i));
return;
}
static void sub(FICL_VM *pVM)
{
FICL_INT i;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 1);
#endif
i = stackPopINT(pVM->pStack);
i = stackGetTop(pVM->pStack).i - i;
stackSetTop(pVM->pStack, LVALUEtoCELL(i));
return;
}
static void mul(FICL_VM *pVM)
{
FICL_INT i;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 1);
#endif
i = stackPopINT(pVM->pStack);
i *= stackGetTop(pVM->pStack).i;
stackSetTop(pVM->pStack, LVALUEtoCELL(i));
return;
}
static void negate(FICL_VM *pVM)
{
FICL_INT i;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 1);
#endif
i = -stackPopINT(pVM->pStack);
PUSHINT(i);
return;
}
static void ficlDiv(FICL_VM *pVM)
{
FICL_INT i;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 1);
#endif
i = stackPopINT(pVM->pStack);
i = stackGetTop(pVM->pStack).i / i;
stackSetTop(pVM->pStack, LVALUEtoCELL(i));
return;
}
/*
** slash-mod CORE ( n1 n2 -- n3 n4 )
** Divide n1 by n2, giving the single-cell remainder n3 and the single-cell
** quotient n4. An ambiguous condition exists if n2 is zero. If n1 and n2
** differ in sign, the implementation-defined result returned will be the
** same as that returned by either the phrase
** >R S>D R> FM/MOD or the phrase >R S>D R> SM/REM .
** NOTE: Ficl complies with the second phrase (symmetric division)
*/
static void slashMod(FICL_VM *pVM)
{
DPINT n1;
FICL_INT n2;
INTQR qr;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 2);
#endif
n2 = stackPopINT(pVM->pStack);
n1.lo = stackPopINT(pVM->pStack);
i64Extend(n1);
qr = m64SymmetricDivI(n1, n2);
PUSHINT(qr.rem);
PUSHINT(qr.quot);
return;
}
static void onePlus(FICL_VM *pVM)
{
FICL_INT i;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 1);
#endif
i = stackGetTop(pVM->pStack).i;
i += 1;
stackSetTop(pVM->pStack, LVALUEtoCELL(i));
return;
}
static void oneMinus(FICL_VM *pVM)
{
FICL_INT i;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 1);
#endif
i = stackGetTop(pVM->pStack).i;
i -= 1;
stackSetTop(pVM->pStack, LVALUEtoCELL(i));
return;
}
static void twoMul(FICL_VM *pVM)
{
FICL_INT i;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 1);
#endif
i = stackGetTop(pVM->pStack).i;
i *= 2;
stackSetTop(pVM->pStack, LVALUEtoCELL(i));
return;
}
static void twoDiv(FICL_VM *pVM)
{
FICL_INT i;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 1);
#endif
i = stackGetTop(pVM->pStack).i;
i >>= 1;
stackSetTop(pVM->pStack, LVALUEtoCELL(i));
return;
}
static void mulDiv(FICL_VM *pVM)
{
FICL_INT x, y, z;
DPINT prod;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 3, 1);
#endif
z = stackPopINT(pVM->pStack);
y = stackPopINT(pVM->pStack);
x = stackPopINT(pVM->pStack);
prod = m64MulI(x,y);
x = m64SymmetricDivI(prod, z).quot;
PUSHINT(x);
return;
}
static void mulDivRem(FICL_VM *pVM)
{
FICL_INT x, y, z;
DPINT prod;
INTQR qr;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 3, 2);
#endif
z = stackPopINT(pVM->pStack);
y = stackPopINT(pVM->pStack);
x = stackPopINT(pVM->pStack);
prod = m64MulI(x,y);
qr = m64SymmetricDivI(prod, z);
PUSHINT(qr.rem);
PUSHINT(qr.quot);
return;
}
/**************************************************************************
c o l o n d e f i n i t i o n s
** Code to begin compiling a colon definition
** This function sets the state to COMPILE, then creates a
** new word whose name is the next word in the input stream
** and whose code is colonParen.
**************************************************************************/
static void colon(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
STRINGINFO si = vmGetWord(pVM);
dictCheckThreshold(dp);
pVM->state = COMPILE;
markControlTag(pVM, colonTag);
dictAppendWord2(dp, si, colonParen, FW_DEFAULT | FW_SMUDGE);
#if FICL_WANT_LOCALS
pVM->pSys->nLocals = 0;
#endif
return;
}
/**************************************************************************
c o l o n P a r e n
** This is the code that executes a colon definition. It assumes that the
** virtual machine is running a "next" loop (See the vm.c
** for its implementation of member function vmExecute()). The colon
** code simply copies the address of the first word in the list of words
** to interpret into IP after saving its old value. When we return to the
** "next" loop, the virtual machine will call the code for each word in
** turn.
**
**************************************************************************/
static void colonParen(FICL_VM *pVM)
{
IPTYPE tempIP = (IPTYPE) (pVM->runningWord->param);
vmPushIP(pVM, tempIP);
return;
}
/**************************************************************************
s e m i c o l o n C o I m
**
** IMMEDIATE code for ";". This function sets the state to INTERPRET and
** terminates a word under compilation by appending code for "(;)" to
** the definition. TO DO: checks for leftover branch target tags on the
** return stack and complains if any are found.
**************************************************************************/
static void semiParen(FICL_VM *pVM)
{
vmPopIP(pVM);
return;
}
static void semicolonCoIm(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
assert(pVM->pSys->pSemiParen);
matchControlTag(pVM, colonTag);
#if FICL_WANT_LOCALS
assert(pVM->pSys->pUnLinkParen);
if (pVM->pSys->nLocals > 0)
{
FICL_DICT *pLoc = ficlGetLoc(pVM->pSys);
dictEmpty(pLoc, pLoc->pForthWords->size);
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pUnLinkParen));
}
pVM->pSys->nLocals = 0;
#endif
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pSemiParen));
pVM->state = INTERPRET;
dictUnsmudge(dp);
return;
}
/**************************************************************************
e x i t
** CORE
** This function simply pops the previous instruction
** pointer and returns to the "next" loop. Used for exiting from within
** a definition. Note that exitParen is identical to semiParen - they
** are in two different functions so that "see" can correctly identify
** the end of a colon definition, even if it uses "exit".
**************************************************************************/
static void exitParen(FICL_VM *pVM)
{
vmPopIP(pVM);
return;
}
static void exitCoIm(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
assert(pVM->pSys->pExitParen);
IGNORE(pVM);
#if FICL_WANT_LOCALS
if (pVM->pSys->nLocals > 0)
{
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pUnLinkParen));
}
#endif
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pExitParen));
return;
}
/**************************************************************************
c o n s t a n t P a r e n
** This is the run-time code for "constant". It simply returns the
** contents of its word's first data cell.
**
**************************************************************************/
void constantParen(FICL_VM *pVM)
{
FICL_WORD *pFW = pVM->runningWord;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 0, 1);
#endif
stackPush(pVM->pStack, pFW->param[0]);
return;
}
void twoConstParen(FICL_VM *pVM)
{
FICL_WORD *pFW = pVM->runningWord;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 0, 2);
#endif
stackPush(pVM->pStack, pFW->param[0]); /* lo */
stackPush(pVM->pStack, pFW->param[1]); /* hi */
return;
}
/**************************************************************************
c o n s t a n t
** IMMEDIATE
** Compiles a constant into the dictionary. Constants return their
** value when invoked. Expects a value on top of the parm stack.
**************************************************************************/
static void constant(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
STRINGINFO si = vmGetWord(pVM);
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 0);
#endif
dictAppendWord2(dp, si, constantParen, FW_DEFAULT);
dictAppendCell(dp, stackPop(pVM->pStack));
return;
}
static void twoConstant(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
STRINGINFO si = vmGetWord(pVM);
CELL c;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 0);
#endif
c = stackPop(pVM->pStack);
dictAppendWord2(dp, si, twoConstParen, FW_DEFAULT);
dictAppendCell(dp, stackPop(pVM->pStack));
dictAppendCell(dp, c);
return;
}
/**************************************************************************
d i s p l a y C e l l
** Drop and print the contents of the cell at the top of the param
** stack
**************************************************************************/
static void displayCell(FICL_VM *pVM)
{
CELL c;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 0);
#endif
c = stackPop(pVM->pStack);
ltoa((c).i, pVM->pad, pVM->base);
strcat(pVM->pad, " ");
vmTextOut(pVM, pVM->pad, 0);
return;
}
static void uDot(FICL_VM *pVM)
{
FICL_UNS u;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 0);
#endif
u = stackPopUNS(pVM->pStack);
ultoa(u, pVM->pad, pVM->base);
strcat(pVM->pad, " ");
vmTextOut(pVM, pVM->pad, 0);
return;
}
static void hexDot(FICL_VM *pVM)
{
FICL_UNS u;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 0);
#endif
u = stackPopUNS(pVM->pStack);
ultoa(u, pVM->pad, 16);
strcat(pVM->pad, " ");
vmTextOut(pVM, pVM->pad, 0);
return;
}
/**************************************************************************
s t r l e n
** FICL ( c-string -- length )
**
** Returns the length of a C-style (zero-terminated) string.
**
** --lch
**/
static void ficlStrlen(FICL_VM *ficlVM)
{
char *address = (char *)stackPopPtr(ficlVM->pStack);
stackPushINT(ficlVM->pStack, strlen(address));
}
/**************************************************************************
s p r i n t f
** FICL ( i*x c-addr-fmt u-fmt c-addr-buffer u-buffer -- c-addr-buffer u-written success-flag )
** Similar to the C sprintf() function. It formats into a buffer based on
** a "format" string. Each character in the format string is copied verbatim
** to the output buffer, until SPRINTF encounters a percent sign ("%").
** SPRINTF then skips the percent sign, and examines the next character
** (the "format character"). Here are the valid format characters:
** s - read a C-ADDR U-LENGTH string from the stack and copy it to
** the buffer
** d - read a cell from the stack, format it as a string (base-10,
** signed), and copy it to the buffer
** x - same as d, except in base-16
** u - same as d, but unsigned
** % - output a literal percent-sign to the buffer
** SPRINTF returns the c-addr-buffer argument unchanged, the number of bytes
** written, and a flag indicating whether or not it ran out of space while
** writing to the output buffer (TRUE if it ran out of space).
**
** If SPRINTF runs out of space in the buffer to store the formatted string,
** it still continues parsing, in an effort to preserve your stack (otherwise
** it might leave uneaten arguments behind).
**
** --lch
**************************************************************************/
static void ficlSprintf(FICL_VM *pVM) /* */
{
int bufferLength = stackPopINT(pVM->pStack);
char *buffer = (char *)stackPopPtr(pVM->pStack);
char *bufferStart = buffer;
int formatLength = stackPopINT(pVM->pStack);
char *format = (char *)stackPopPtr(pVM->pStack);
char *formatStop = format + formatLength;
int base = 10;
int unsignedInteger = FALSE;
FICL_INT append = FICL_TRUE;
while (format < formatStop)
{
char scratch[64];
char *source;
int actualLength;
int desiredLength;
int leadingZeroes;
if (*format != '%')
{
source = format;
actualLength = desiredLength = 1;
leadingZeroes = 0;
}
else
{
format++;
if (format == formatStop)
break;
leadingZeroes = (*format == '0');
if (leadingZeroes)
{
format++;
if (format == formatStop)
break;
}
desiredLength = isdigit(*format);
if (desiredLength)
{
desiredLength = strtol(format, &format, 10);
if (format == formatStop)
break;
}
else if (*format == '*')
{
desiredLength = stackPopINT(pVM->pStack);
format++;
if (format == formatStop)
break;
}
switch (*format)
{
case 's':
case 'S':
{
actualLength = stackPopINT(pVM->pStack);
source = (char *)stackPopPtr(pVM->pStack);
break;
}
case 'x':
case 'X':
base = 16;
case 'u':
case 'U':
unsignedInteger = TRUE;
case 'd':
case 'D':
{
int integer = stackPopINT(pVM->pStack);
if (unsignedInteger)
ultoa(integer, scratch, base);
else
ltoa(integer, scratch, base);
base = 10;
unsignedInteger = FALSE;
source = scratch;
actualLength = strlen(scratch);
break;
}
case '%':
source = format;
actualLength = 1;
default:
continue;
}
}
if (append != FICL_FALSE)
{
if (!desiredLength)
desiredLength = actualLength;
if (desiredLength > bufferLength)
{
append = FICL_FALSE;
desiredLength = bufferLength;
}
while (desiredLength > actualLength)
{
*buffer++ = (char)((leadingZeroes) ? '0' : ' ');
bufferLength--;
desiredLength--;
}
memcpy(buffer, source, actualLength);
buffer += actualLength;
bufferLength -= actualLength;
}
format++;
}
stackPushPtr(pVM->pStack, bufferStart);
stackPushINT(pVM->pStack, buffer - bufferStart);
stackPushINT(pVM->pStack, append);
}
/**************************************************************************
d u p & f r i e n d s
**
**************************************************************************/
static void depth(FICL_VM *pVM)
{
int i;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 0, 1);
#endif
i = stackDepth(pVM->pStack);
PUSHINT(i);
return;
}
static void drop(FICL_VM *pVM)
{
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 0);
#endif
stackDrop(pVM->pStack, 1);
return;
}
static void twoDrop(FICL_VM *pVM)
{
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 0);
#endif
stackDrop(pVM->pStack, 2);
return;
}
static void dup(FICL_VM *pVM)
{
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 2);
#endif
stackPick(pVM->pStack, 0);
return;
}
static void twoDup(FICL_VM *pVM)
{
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 4);
#endif
stackPick(pVM->pStack, 1);
stackPick(pVM->pStack, 1);
return;
}
static void over(FICL_VM *pVM)
{
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 3);
#endif
stackPick(pVM->pStack, 1);
return;
}
static void twoOver(FICL_VM *pVM)
{
#if FICL_ROBUST > 1
vmCheckStack(pVM, 4, 6);
#endif
stackPick(pVM->pStack, 3);
stackPick(pVM->pStack, 3);
return;
}
static void pick(FICL_VM *pVM)
{
CELL c = stackPop(pVM->pStack);
#if FICL_ROBUST > 1
vmCheckStack(pVM, c.i+1, c.i+2);
#endif
stackPick(pVM->pStack, c.i);
return;
}
static void questionDup(FICL_VM *pVM)
{
CELL c;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 2);
#endif
c = stackGetTop(pVM->pStack);
if (c.i != 0)
stackPick(pVM->pStack, 0);
return;
}
static void roll(FICL_VM *pVM)
{
int i = stackPop(pVM->pStack).i;
i = (i > 0) ? i : 0;
#if FICL_ROBUST > 1
vmCheckStack(pVM, i+1, i+1);
#endif
stackRoll(pVM->pStack, i);
return;
}
static void minusRoll(FICL_VM *pVM)
{
int i = stackPop(pVM->pStack).i;
i = (i > 0) ? i : 0;
#if FICL_ROBUST > 1
vmCheckStack(pVM, i+1, i+1);
#endif
stackRoll(pVM->pStack, -i);
return;
}
static void rot(FICL_VM *pVM)
{
#if FICL_ROBUST > 1
vmCheckStack(pVM, 3, 3);
#endif
stackRoll(pVM->pStack, 2);
return;
}
static void swap(FICL_VM *pVM)
{
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 2);
#endif
stackRoll(pVM->pStack, 1);
return;
}
static void twoSwap(FICL_VM *pVM)
{
#if FICL_ROBUST > 1
vmCheckStack(pVM, 4, 4);
#endif
stackRoll(pVM->pStack, 3);
stackRoll(pVM->pStack, 3);
return;
}
/**************************************************************************
e m i t & f r i e n d s
**
**************************************************************************/
static void emit(FICL_VM *pVM)
{
char cp[2];
int i;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 0);
#endif
i = stackPopINT(pVM->pStack);
cp[0] = (char)i;
cp[1] = '\0';
vmTextOut(pVM, cp, 0);
return;
}
static void cr(FICL_VM *pVM)
{
vmTextOut(pVM, "", 1);
return;
}
static void commentLine(FICL_VM *pVM)
{
char *cp = vmGetInBuf(pVM);
char *pEnd = vmGetInBufEnd(pVM);
char ch = *cp;
while ((cp != pEnd) && (ch != '\r') && (ch != '\n'))
{
ch = *++cp;
}
/*
** Cope with DOS or UNIX-style EOLs -
** Check for /r, /n, /r/n, or /n/r end-of-line sequences,
** and point cp to next char. If EOL is \0, we're done.
*/
if (cp != pEnd)
{
cp++;
if ( (cp != pEnd) && (ch != *cp)
&& ((*cp == '\r') || (*cp == '\n')) )
cp++;
}
vmUpdateTib(pVM, cp);
return;
}
/*
** paren CORE
** Compilation: Perform the execution semantics given below.
** Execution: ( "ccc<paren>" -- )
** Parse ccc delimited by ) (right parenthesis). ( is an immediate word.
** The number of characters in ccc may be zero to the number of characters
** in the parse area.
**
*/
static void commentHang(FICL_VM *pVM)
{
vmParseStringEx(pVM, ')', 0);
return;
}
/**************************************************************************
F E T C H & S T O R E
**
**************************************************************************/
static void fetch(FICL_VM *pVM)
{
CELL *pCell;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 1);
#endif
pCell = (CELL *)stackPopPtr(pVM->pStack);
stackPush(pVM->pStack, *pCell);
return;
}
/*
** two-fetch CORE ( a-addr -- x1 x2 )
** Fetch the cell pair x1 x2 stored at a-addr. x2 is stored at a-addr and
** x1 at the next consecutive cell. It is equivalent to the sequence
** DUP CELL+ @ SWAP @ .
*/
static void twoFetch(FICL_VM *pVM)
{
CELL *pCell;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 2);
#endif
pCell = (CELL *)stackPopPtr(pVM->pStack);
stackPush(pVM->pStack, *pCell++);
stackPush(pVM->pStack, *pCell);
swap(pVM);
return;
}
/*
** store CORE ( x a-addr -- )
** Store x at a-addr.
*/
static void store(FICL_VM *pVM)
{
CELL *pCell;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 0);
#endif
pCell = (CELL *)stackPopPtr(pVM->pStack);
*pCell = stackPop(pVM->pStack);
}
/*
** two-store CORE ( x1 x2 a-addr -- )
** Store the cell pair x1 x2 at a-addr, with x2 at a-addr and x1 at the
** next consecutive cell. It is equivalent to the sequence
** SWAP OVER ! CELL+ ! .
*/
static void twoStore(FICL_VM *pVM)
{
CELL *pCell;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 3, 0);
#endif
pCell = (CELL *)stackPopPtr(pVM->pStack);
*pCell++ = stackPop(pVM->pStack);
*pCell = stackPop(pVM->pStack);
}
static void plusStore(FICL_VM *pVM)
{
CELL *pCell;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 0);
#endif
pCell = (CELL *)stackPopPtr(pVM->pStack);
pCell->i += stackPop(pVM->pStack).i;
}
static void quadFetch(FICL_VM *pVM)
{
UNS32 *pw;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 1);
#endif
pw = (UNS32 *)stackPopPtr(pVM->pStack);
PUSHUNS((FICL_UNS)*pw);
return;
}
static void quadStore(FICL_VM *pVM)
{
UNS32 *pw;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 0);
#endif
pw = (UNS32 *)stackPopPtr(pVM->pStack);
*pw = (UNS32)(stackPop(pVM->pStack).u);
}
static void wFetch(FICL_VM *pVM)
{
UNS16 *pw;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 1);
#endif
pw = (UNS16 *)stackPopPtr(pVM->pStack);
PUSHUNS((FICL_UNS)*pw);
return;
}
static void wStore(FICL_VM *pVM)
{
UNS16 *pw;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 0);
#endif
pw = (UNS16 *)stackPopPtr(pVM->pStack);
*pw = (UNS16)(stackPop(pVM->pStack).u);
}
static void cFetch(FICL_VM *pVM)
{
UNS8 *pc;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 1);
#endif
pc = (UNS8 *)stackPopPtr(pVM->pStack);
PUSHUNS((FICL_UNS)*pc);
return;
}
static void cStore(FICL_VM *pVM)
{
UNS8 *pc;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 0);
#endif
pc = (UNS8 *)stackPopPtr(pVM->pStack);
*pc = (UNS8)(stackPop(pVM->pStack).u);
}
/**************************************************************************
b r a n c h P a r e n
**
** Runtime for "(branch)" -- expects a literal offset in the next
** compilation address, and branches to that location.
**************************************************************************/
static void branchParen(FICL_VM *pVM)
{
vmBranchRelative(pVM, (uintptr_t)*(pVM->ip));
return;
}
/**************************************************************************
b r a n c h 0
** Runtime code for "(branch0)"; pop a flag from the stack,
** branch if 0. fall through otherwise. The heart of "if" and "until".
**************************************************************************/
static void branch0(FICL_VM *pVM)
{
FICL_UNS flag;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 0);
#endif
flag = stackPopUNS(pVM->pStack);
if (flag)
{ /* fall through */
vmBranchRelative(pVM, 1);
}
else
{ /* take branch (to else/endif/begin) */
vmBranchRelative(pVM, (uintptr_t)*(pVM->ip));
}
return;
}
/**************************************************************************
i f C o I m
** IMMEDIATE COMPILE-ONLY
** Compiles code for a conditional branch into the dictionary
** and pushes the branch patch address on the stack for later
** patching by ELSE or THEN/ENDIF.
**************************************************************************/
static void ifCoIm(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
assert(pVM->pSys->pBranch0);
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pBranch0));
markBranch(dp, pVM, origTag);
dictAppendUNS(dp, 1);
return;
}
/**************************************************************************
e l s e C o I m
**
** IMMEDIATE COMPILE-ONLY
** compiles an "else"...
** 1) Compile a branch and a patch address; the address gets patched
** by "endif" to point past the "else" code.
** 2) Pop the "if" patch address
** 3) Patch the "if" branch to point to the current compile address.
** 4) Push the "else" patch address. ("endif" patches this to jump past
** the "else" code.
**************************************************************************/
static void elseCoIm(FICL_VM *pVM)
{
CELL *patchAddr;
FICL_INT offset;
FICL_DICT *dp = vmGetDict(pVM);
assert(pVM->pSys->pBranchParen);
/* (1) compile branch runtime */
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pBranchParen));
matchControlTag(pVM, origTag);
patchAddr =
(CELL *)stackPopPtr(pVM->pStack); /* (2) pop "if" patch addr */
markBranch(dp, pVM, origTag); /* (4) push "else" patch addr */
dictAppendUNS(dp, 1); /* (1) compile patch placeholder */
offset = dp->here - patchAddr;
*patchAddr = LVALUEtoCELL(offset); /* (3) Patch "if" */
return;
}
/**************************************************************************
e n d i f C o I m
** IMMEDIATE COMPILE-ONLY
**************************************************************************/
static void endifCoIm(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
resolveForwardBranch(dp, pVM, origTag);
return;
}
/**************************************************************************
c a s e C o I m
** IMMEDIATE COMPILE-ONLY
**
**
** At compile-time, a CASE-SYS (see DPANS94 6.2.0873) looks like this:
** i*addr i caseTag
** and an OF-SYS (see DPANS94 6.2.1950) looks like this:
** i*addr i caseTag addr ofTag
** The integer under caseTag is the count of fixup addresses that branch
** to ENDCASE.
**************************************************************************/
static void caseCoIm(FICL_VM *pVM)
{
#if FICL_ROBUST > 1
vmCheckStack(pVM, 0, 2);
#endif
PUSHUNS(0);
markControlTag(pVM, caseTag);
return;
}
/**************************************************************************
e n d c a s eC o I m
** IMMEDIATE COMPILE-ONLY
**************************************************************************/
static void endcaseCoIm(FICL_VM *pVM)
{
FICL_UNS fixupCount;
FICL_DICT *dp;
CELL *patchAddr;
FICL_INT offset;
assert(pVM->pSys->pDrop);
/*
** if the last OF ended with FALLTHROUGH,
** just add the FALLTHROUGH fixup to the
** ENDOF fixups
*/
if (stackGetTop(pVM->pStack).p == fallthroughTag)
{
matchControlTag(pVM, fallthroughTag);
patchAddr = POPPTR();
matchControlTag(pVM, caseTag);
fixupCount = POPUNS();
PUSHPTR(patchAddr);
PUSHUNS(fixupCount + 1);
markControlTag(pVM, caseTag);
}
matchControlTag(pVM, caseTag);
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 0);
#endif
fixupCount = POPUNS();
#if FICL_ROBUST > 1
vmCheckStack(pVM, fixupCount, 0);
#endif
dp = vmGetDict(pVM);
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pDrop));
while (fixupCount--)
{
patchAddr = (CELL *)stackPopPtr(pVM->pStack);
offset = dp->here - patchAddr;
*patchAddr = LVALUEtoCELL(offset);
}
return;
}
static void ofParen(FICL_VM *pVM)
{
FICL_UNS a, b;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 1);
#endif
a = POPUNS();
b = stackGetTop(pVM->pStack).u;
if (a == b)
{ /* fall through */
stackDrop(pVM->pStack, 1);
vmBranchRelative(pVM, 1);
}
else
{ /* take branch to next of or endswitch */
vmBranchRelative(pVM, *(int *)(pVM->ip));
}
return;
}
/**************************************************************************
o f C o I m
** IMMEDIATE COMPILE-ONLY
**************************************************************************/
static void ofCoIm(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
CELL *fallthroughFixup = NULL;
assert(pVM->pSys->pBranch0);
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 3);
#endif
if (stackGetTop(pVM->pStack).p == fallthroughTag)
{
matchControlTag(pVM, fallthroughTag);
fallthroughFixup = POPPTR();
}
matchControlTag(pVM, caseTag);
markControlTag(pVM, caseTag);
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pOfParen));
markBranch(dp, pVM, ofTag);
dictAppendUNS(dp, 2);
if (fallthroughFixup != NULL)
{
FICL_INT offset = dp->here - fallthroughFixup;
*fallthroughFixup = LVALUEtoCELL(offset);
}
return;
}
/**************************************************************************
e n d o f C o I m
** IMMEDIATE COMPILE-ONLY
**************************************************************************/
static void endofCoIm(FICL_VM *pVM)
{
CELL *patchAddr;
FICL_UNS fixupCount;
FICL_INT offset;
FICL_DICT *dp = vmGetDict(pVM);
#if FICL_ROBUST > 1
vmCheckStack(pVM, 4, 3);
#endif
assert(pVM->pSys->pBranchParen);
/* ensure we're in an OF, */
matchControlTag(pVM, ofTag);
/* grab the address of the branch location after the OF */
patchAddr = (CELL *)stackPopPtr(pVM->pStack);
/* ensure we're also in a "case" */
matchControlTag(pVM, caseTag);
/* grab the current number of ENDOF fixups */
fixupCount = POPUNS();
/* compile branch runtime */
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pBranchParen));
/* push a new ENDOF fixup, the updated count of ENDOF fixups, and the caseTag */
PUSHPTR(dp->here);
PUSHUNS(fixupCount + 1);
markControlTag(pVM, caseTag);
/* reserve space for the ENDOF fixup */
dictAppendUNS(dp, 2);
/* and patch the original OF */
offset = dp->here - patchAddr;
*patchAddr = LVALUEtoCELL(offset);
}
/**************************************************************************
f a l l t h r o u g h C o I m
** IMMEDIATE COMPILE-ONLY
**************************************************************************/
static void fallthroughCoIm(FICL_VM *pVM)
{
CELL *patchAddr;
FICL_INT offset;
FICL_DICT *dp = vmGetDict(pVM);
#if FICL_ROBUST > 1
vmCheckStack(pVM, 4, 3);
#endif
/* ensure we're in an OF, */
matchControlTag(pVM, ofTag);
/* grab the address of the branch location after the OF */
patchAddr = (CELL *)stackPopPtr(pVM->pStack);
/* ensure we're also in a "case" */
matchControlTag(pVM, caseTag);
/* okay, here we go. put the case tag back. */
markControlTag(pVM, caseTag);
/* compile branch runtime */
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pBranchParen));
/* push a new FALLTHROUGH fixup and the fallthroughTag */
PUSHPTR(dp->here);
markControlTag(pVM, fallthroughTag);
/* reserve space for the FALLTHROUGH fixup */
dictAppendUNS(dp, 2);
/* and patch the original OF */
offset = dp->here - patchAddr;
*patchAddr = LVALUEtoCELL(offset);
}
/**************************************************************************
h a s h
** hash ( c-addr u -- code)
** calculates hashcode of specified string and leaves it on the stack
**************************************************************************/
static void hash(FICL_VM *pVM)
{
STRINGINFO si;
SI_SETLEN(si, stackPopUNS(pVM->pStack));
SI_SETPTR(si, stackPopPtr(pVM->pStack));
PUSHUNS(hashHashCode(si));
return;
}
/**************************************************************************
i n t e r p r e t
** This is the "user interface" of a Forth. It does the following:
** while there are words in the VM's Text Input Buffer
** Copy next word into the pad (vmGetWord)
** Attempt to find the word in the dictionary (dictLookup)
** If successful, execute the word.
** Otherwise, attempt to convert the word to a number (isNumber)
** If successful, push the number onto the parameter stack.
** Otherwise, print an error message and exit loop...
** End Loop
**
** From the standard, section 3.4
** Text interpretation (see 6.1.1360 EVALUATE and 6.1.2050 QUIT) shall
** repeat the following steps until either the parse area is empty or an
** ambiguous condition exists:
** a) Skip leading spaces and parse a name (see 3.4.1);
**************************************************************************/
static void interpret(FICL_VM *pVM)
{
STRINGINFO si;
int i;
FICL_SYSTEM *pSys;
assert(pVM);
pSys = pVM->pSys;
si = vmGetWord0(pVM);
/*
** Get next word...if out of text, we're done.
*/
if (si.count == 0)
{
vmThrow(pVM, VM_OUTOFTEXT);
}
/*
** Attempt to find the incoming token in the dictionary. If that fails...
** run the parse chain against the incoming token until somebody eats it.
** Otherwise emit an error message and give up.
** Although ficlParseWord could be part of the parse list, I've hard coded it
** in for robustness. ficlInitSystem adds the other default steps to the list.
*/
if (ficlParseWord(pVM, si))
return;
for (i=0; i < FICL_MAX_PARSE_STEPS; i++)
{
FICL_WORD *pFW = pSys->parseList[i];
if (pFW == NULL)
break;
if (pFW->code == parseStepParen)
{
FICL_PARSE_STEP pStep;
pStep = (FICL_PARSE_STEP)(pFW->param->fn);
if ((*pStep)(pVM, si))
return;
}
else
{
stackPushPtr(pVM->pStack, SI_PTR(si));
stackPushUNS(pVM->pStack, SI_COUNT(si));
ficlExecXT(pVM, pFW);
if (stackPopINT(pVM->pStack))
return;
}
}
i = SI_COUNT(si);
vmThrowErr(pVM, "%.*s not found", i, SI_PTR(si));
return; /* back to inner interpreter */
}
/**************************************************************************
f i c l P a r s e W o r d
** From the standard, section 3.4
** b) Search the dictionary name space (see 3.4.2). If a definition name
** matching the string is found:
** 1.if interpreting, perform the interpretation semantics of the definition
** (see 3.4.3.2), and continue at a);
** 2.if compiling, perform the compilation semantics of the definition
** (see 3.4.3.3), and continue at a).
**
** c) If a definition name matching the string is not found, attempt to
** convert the string to a number (see 3.4.1.3). If successful:
** 1.if interpreting, place the number on the data stack, and continue at a);
** 2.if compiling, compile code that when executed will place the number on
** the stack (see 6.1.1780 LITERAL), and continue at a);
**
** d) If unsuccessful, an ambiguous condition exists (see 3.4.4).
**
** (jws 4/01) Modified to be a FICL_PARSE_STEP
**************************************************************************/
static int ficlParseWord(FICL_VM *pVM, STRINGINFO si)
{
FICL_DICT *dp = vmGetDict(pVM);
FICL_WORD *tempFW;
#if FICL_ROBUST
dictCheck(dp, pVM, 0);
vmCheckStack(pVM, 0, 0);
#endif
#if FICL_WANT_LOCALS
if (pVM->pSys->nLocals > 0)
{
tempFW = ficlLookupLoc(pVM->pSys, si);
}
else
#endif
tempFW = dictLookup(dp, si);
if (pVM->state == INTERPRET)
{
if (tempFW != NULL)
{
if (wordIsCompileOnly(tempFW))
{
vmThrowErr(pVM, "Error: Compile only!");
}
vmExecute(pVM, tempFW);
return (int)FICL_TRUE;
}
}
else /* (pVM->state == COMPILE) */
{
if (tempFW != NULL)
{
if (wordIsImmediate(tempFW))
{
vmExecute(pVM, tempFW);
}
else
{
dictAppendCell(dp, LVALUEtoCELL(tempFW));
}
return (int)FICL_TRUE;
}
}
return FICL_FALSE;
}
/*
** Surrogate precompiled parse step for ficlParseWord (this step is hard coded in
** INTERPRET)
*/
static void lookup(FICL_VM *pVM)
{
STRINGINFO si;
SI_SETLEN(si, stackPopUNS(pVM->pStack));
SI_SETPTR(si, stackPopPtr(pVM->pStack));
stackPushINT(pVM->pStack, ficlParseWord(pVM, si));
return;
}
/**************************************************************************
p a r e n P a r s e S t e p
** (parse-step) ( c-addr u -- flag )
** runtime for a precompiled parse step - pop a counted string off the
** stack, run the parse step against it, and push the result flag (FICL_TRUE
** if success, FICL_FALSE otherwise).
**************************************************************************/
void parseStepParen(FICL_VM *pVM)
{
STRINGINFO si;
FICL_WORD *pFW = pVM->runningWord;
FICL_PARSE_STEP pStep = (FICL_PARSE_STEP)(pFW->param->fn);
SI_SETLEN(si, stackPopINT(pVM->pStack));
SI_SETPTR(si, stackPopPtr(pVM->pStack));
PUSHINT((*pStep)(pVM, si));
return;
}
static void addParseStep(FICL_VM *pVM)
{
FICL_WORD *pStep;
FICL_DICT *pd = vmGetDict(pVM);
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 0);
#endif
pStep = (FICL_WORD *)(stackPop(pVM->pStack).p);
if ((pStep != NULL) && isAFiclWord(pd, pStep))
ficlAddParseStep(pVM->pSys, pStep);
return;
}
/**************************************************************************
l i t e r a l P a r e n
**
** This is the runtime for (literal). It assumes that it is part of a colon
** definition, and that the next CELL contains a value to be pushed on the
** parameter stack at runtime. This code is compiled by "literal".
**
**************************************************************************/
static void literalParen(FICL_VM *pVM)
{
#if FICL_ROBUST > 1
vmCheckStack(pVM, 0, 1);
#endif
PUSHINT(*(FICL_INT *)(pVM->ip));
vmBranchRelative(pVM, 1);
return;
}
static void twoLitParen(FICL_VM *pVM)
{
#if FICL_ROBUST > 1
vmCheckStack(pVM, 0, 2);
#endif
PUSHINT(*((FICL_INT *)(pVM->ip)+1));
PUSHINT(*(FICL_INT *)(pVM->ip));
vmBranchRelative(pVM, 2);
return;
}
/**************************************************************************
l i t e r a l I m
**
** IMMEDIATE code for "literal". This function gets a value from the stack
** and compiles it into the dictionary preceded by the code for "(literal)".
** IMMEDIATE
**************************************************************************/
static void literalIm(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
assert(pVM->pSys->pLitParen);
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pLitParen));
dictAppendCell(dp, stackPop(pVM->pStack));
return;
}
static void twoLiteralIm(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
assert(pVM->pSys->pTwoLitParen);
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pTwoLitParen));
dictAppendCell(dp, stackPop(pVM->pStack));
dictAppendCell(dp, stackPop(pVM->pStack));
return;
}
/**************************************************************************
l o g i c a n d c o m p a r i s o n s
**
**************************************************************************/
static void zeroEquals(FICL_VM *pVM)
{
CELL c;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 1);
#endif
c.i = FICL_BOOL(stackPopINT(pVM->pStack) == 0);
stackPush(pVM->pStack, c);
return;
}
static void zeroLess(FICL_VM *pVM)
{
CELL c;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 1);
#endif
c.i = FICL_BOOL(stackPopINT(pVM->pStack) < 0);
stackPush(pVM->pStack, c);
return;
}
static void zeroGreater(FICL_VM *pVM)
{
CELL c;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 1);
#endif
c.i = FICL_BOOL(stackPopINT(pVM->pStack) > 0);
stackPush(pVM->pStack, c);
return;
}
static void isEqual(FICL_VM *pVM)
{
CELL x, y;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 1);
#endif
x = stackPop(pVM->pStack);
y = stackPop(pVM->pStack);
PUSHINT(FICL_BOOL(x.i == y.i));
return;
}
static void isLess(FICL_VM *pVM)
{
CELL x, y;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 1);
#endif
y = stackPop(pVM->pStack);
x = stackPop(pVM->pStack);
PUSHINT(FICL_BOOL(x.i < y.i));
return;
}
static void uIsLess(FICL_VM *pVM)
{
FICL_UNS u1, u2;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 1);
#endif
u2 = stackPopUNS(pVM->pStack);
u1 = stackPopUNS(pVM->pStack);
PUSHINT(FICL_BOOL(u1 < u2));
return;
}
static void isGreater(FICL_VM *pVM)
{
CELL x, y;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 1);
#endif
y = stackPop(pVM->pStack);
x = stackPop(pVM->pStack);
PUSHINT(FICL_BOOL(x.i > y.i));
return;
}
static void uIsGreater(FICL_VM *pVM)
{
FICL_UNS u1, u2;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 1);
#endif
u2 = stackPopUNS(pVM->pStack);
u1 = stackPopUNS(pVM->pStack);
PUSHINT(FICL_BOOL(u1 > u2));
return;
}
static void bitwiseAnd(FICL_VM *pVM)
{
CELL x, y;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 1);
#endif
x = stackPop(pVM->pStack);
y = stackPop(pVM->pStack);
PUSHINT(x.i & y.i);
return;
}
static void bitwiseOr(FICL_VM *pVM)
{
CELL x, y;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 1);
#endif
x = stackPop(pVM->pStack);
y = stackPop(pVM->pStack);
PUSHINT(x.i | y.i);
return;
}
static void bitwiseXor(FICL_VM *pVM)
{
CELL x, y;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 1);
#endif
x = stackPop(pVM->pStack);
y = stackPop(pVM->pStack);
PUSHINT(x.i ^ y.i);
return;
}
static void bitwiseNot(FICL_VM *pVM)
{
CELL x;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 1);
#endif
x = stackPop(pVM->pStack);
PUSHINT(~x.i);
return;
}
/**************************************************************************
D o / L o o p
** do -- IMMEDIATE COMPILE ONLY
** Compiles code to initialize a loop: compile (do),
** allot space to hold the "leave" address, push a branch
** target address for the loop.
** (do) -- runtime for "do"
** pops index and limit from the p stack and moves them
** to the r stack, then skips to the loop body.
** loop -- IMMEDIATE COMPILE ONLY
** +loop
** Compiles code for the test part of a loop:
** compile (loop), resolve forward branch from "do", and
** copy "here" address to the "leave" address allotted by "do"
** i,j,k -- COMPILE ONLY
** Runtime: Push loop indices on param stack (i is innermost loop...)
** Note: each loop has three values on the return stack:
** ( R: leave limit index )
** "leave" is the absolute address of the next cell after the loop
** limit and index are the loop control variables.
** leave -- COMPILE ONLY
** Runtime: pop the loop control variables, then pop the
** "leave" address and jump (absolute) there.
**************************************************************************/
static void doCoIm(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
assert(pVM->pSys->pDoParen);
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pDoParen));
/*
** Allot space for a pointer to the end
** of the loop - "leave" uses this...
*/
markBranch(dp, pVM, leaveTag);
dictAppendUNS(dp, 0);
/*
** Mark location of head of loop...
*/
markBranch(dp, pVM, doTag);
return;
}
static void doParen(FICL_VM *pVM)
{
CELL index, limit;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 0);
#endif
index = stackPop(pVM->pStack);
limit = stackPop(pVM->pStack);
/* copy "leave" target addr to stack */
stackPushPtr(pVM->rStack, *(pVM->ip++));
stackPush(pVM->rStack, limit);
stackPush(pVM->rStack, index);
return;
}
static void qDoCoIm(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
assert(pVM->pSys->pQDoParen);
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pQDoParen));
/*
** Allot space for a pointer to the end
** of the loop - "leave" uses this...
*/
markBranch(dp, pVM, leaveTag);
dictAppendUNS(dp, 0);
/*
** Mark location of head of loop...
*/
markBranch(dp, pVM, doTag);
return;
}
static void qDoParen(FICL_VM *pVM)
{
CELL index, limit;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 0);
#endif
index = stackPop(pVM->pStack);
limit = stackPop(pVM->pStack);
/* copy "leave" target addr to stack */
stackPushPtr(pVM->rStack, *(pVM->ip++));
if (limit.u == index.u)
{
vmPopIP(pVM);
}
else
{
stackPush(pVM->rStack, limit);
stackPush(pVM->rStack, index);
}
return;
}
/*
** Runtime code to break out of a do..loop construct
** Drop the loop control variables; the branch address
** past "loop" is next on the return stack.
*/
static void leaveCo(FICL_VM *pVM)
{
/* almost unloop */
stackDrop(pVM->rStack, 2);
/* exit */
vmPopIP(pVM);
return;
}
static void unloopCo(FICL_VM *pVM)
{
stackDrop(pVM->rStack, 3);
return;
}
static void loopCoIm(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
assert(pVM->pSys->pLoopParen);
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pLoopParen));
resolveBackBranch(dp, pVM, doTag);
resolveAbsBranch(dp, pVM, leaveTag);
return;
}
static void plusLoopCoIm(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
assert(pVM->pSys->pPLoopParen);
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pPLoopParen));
resolveBackBranch(dp, pVM, doTag);
resolveAbsBranch(dp, pVM, leaveTag);
return;
}
static void loopParen(FICL_VM *pVM)
{
FICL_INT index = stackGetTop(pVM->rStack).i;
FICL_INT limit = stackFetch(pVM->rStack, 1).i;
index++;
if (index >= limit)
{
stackDrop(pVM->rStack, 3); /* nuke the loop indices & "leave" addr */
vmBranchRelative(pVM, 1); /* fall through the loop */
}
else
{ /* update index, branch to loop head */
stackSetTop(pVM->rStack, LVALUEtoCELL(index));
vmBranchRelative(pVM, (uintptr_t)*(pVM->ip));
}
return;
}
static void plusLoopParen(FICL_VM *pVM)
{
FICL_INT index,limit,increment;
int flag;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 0);
#endif
index = stackGetTop(pVM->rStack).i;
limit = stackFetch(pVM->rStack, 1).i;
increment = POP().i;
index += increment;
if (increment < 0)
flag = (index < limit);
else
flag = (index >= limit);
if (flag)
{
stackDrop(pVM->rStack, 3); /* nuke the loop indices & "leave" addr */
vmBranchRelative(pVM, 1); /* fall through the loop */
}
else
{ /* update index, branch to loop head */
stackSetTop(pVM->rStack, LVALUEtoCELL(index));
vmBranchRelative(pVM, (uintptr_t)*(pVM->ip));
}
return;
}
static void loopICo(FICL_VM *pVM)
{
CELL index = stackGetTop(pVM->rStack);
stackPush(pVM->pStack, index);
return;
}
static void loopJCo(FICL_VM *pVM)
{
CELL index = stackFetch(pVM->rStack, 3);
stackPush(pVM->pStack, index);
return;
}
static void loopKCo(FICL_VM *pVM)
{
CELL index = stackFetch(pVM->rStack, 6);
stackPush(pVM->pStack, index);
return;
}
/**************************************************************************
r e t u r n s t a c k
**
**************************************************************************/
static void toRStack(FICL_VM *pVM)
{
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 0);
#endif
stackPush(pVM->rStack, POP());
}
static void fromRStack(FICL_VM *pVM)
{
#if FICL_ROBUST > 1
vmCheckStack(pVM, 0, 1);
#endif
PUSH(stackPop(pVM->rStack));
}
static void fetchRStack(FICL_VM *pVM)
{
#if FICL_ROBUST > 1
vmCheckStack(pVM, 0, 1);
#endif
PUSH(stackGetTop(pVM->rStack));
}
static void twoToR(FICL_VM *pVM)
{
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 0);
#endif
stackRoll(pVM->pStack, 1);
stackPush(pVM->rStack, stackPop(pVM->pStack));
stackPush(pVM->rStack, stackPop(pVM->pStack));
return;
}
static void twoRFrom(FICL_VM *pVM)
{
#if FICL_ROBUST > 1
vmCheckStack(pVM, 0, 2);
#endif
stackPush(pVM->pStack, stackPop(pVM->rStack));
stackPush(pVM->pStack, stackPop(pVM->rStack));
stackRoll(pVM->pStack, 1);
return;
}
static void twoRFetch(FICL_VM *pVM)
{
#if FICL_ROBUST > 1
vmCheckStack(pVM, 0, 2);
#endif
stackPush(pVM->pStack, stackFetch(pVM->rStack, 1));
stackPush(pVM->pStack, stackFetch(pVM->rStack, 0));
return;
}
/**************************************************************************
v a r i a b l e
**
**************************************************************************/
static void variableParen(FICL_VM *pVM)
{
FICL_WORD *fw;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 0, 1);
#endif
fw = pVM->runningWord;
PUSHPTR(fw->param);
}
static void variable(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
STRINGINFO si = vmGetWord(pVM);
dictAppendWord2(dp, si, variableParen, FW_DEFAULT);
dictAllotCells(dp, 1);
return;
}
static void twoVariable(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
STRINGINFO si = vmGetWord(pVM);
dictAppendWord2(dp, si, variableParen, FW_DEFAULT);
dictAllotCells(dp, 2);
return;
}
/**************************************************************************
b a s e & f r i e n d s
**
**************************************************************************/
static void base(FICL_VM *pVM)
{
CELL *pBase;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 0, 1);
#endif
pBase = (CELL *)(&pVM->base);
stackPush(pVM->pStack, LVALUEtoCELL(pBase));
return;
}
static void decimal(FICL_VM *pVM)
{
pVM->base = 10;
return;
}
static void hex(FICL_VM *pVM)
{
pVM->base = 16;
return;
}
/**************************************************************************
a l l o t & f r i e n d s
**
**************************************************************************/
static void allot(FICL_VM *pVM)
{
FICL_DICT *dp;
FICL_INT i;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 0);
#endif
dp = vmGetDict(pVM);
i = POPINT();
#if FICL_ROBUST
dictCheck(dp, pVM, i);
#endif
dictAllot(dp, i);
return;
}
static void here(FICL_VM *pVM)
{
FICL_DICT *dp;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 0, 1);
#endif
dp = vmGetDict(pVM);
PUSHPTR(dp->here);
return;
}
static void comma(FICL_VM *pVM)
{
FICL_DICT *dp;
CELL c;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 0);
#endif
dp = vmGetDict(pVM);
c = POP();
dictAppendCell(dp, c);
return;
}
static void cComma(FICL_VM *pVM)
{
FICL_DICT *dp;
char c;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 0);
#endif
dp = vmGetDict(pVM);
c = (char)POPINT();
dictAppendChar(dp, c);
return;
}
static void cells(FICL_VM *pVM)
{
FICL_INT i;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 1);
#endif
i = POPINT();
PUSHINT(i * (FICL_INT)sizeof (CELL));
return;
}
static void cellPlus(FICL_VM *pVM)
{
char *cp;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 1);
#endif
cp = POPPTR();
PUSHPTR(cp + sizeof (CELL));
return;
}
/**************************************************************************
t i c k
** tick CORE ( "<spaces>name" -- xt )
** Skip leading space delimiters. Parse name delimited by a space. Find
** name and return xt, the execution token for name. An ambiguous condition
** exists if name is not found.
**************************************************************************/
void ficlTick(FICL_VM *pVM)
{
FICL_WORD *pFW = NULL;
STRINGINFO si = vmGetWord(pVM);
#if FICL_ROBUST > 1
vmCheckStack(pVM, 0, 1);
#endif
pFW = dictLookup(vmGetDict(pVM), si);
if (!pFW)
{
int i = SI_COUNT(si);
vmThrowErr(pVM, "%.*s not found", i, SI_PTR(si));
}
PUSHPTR(pFW);
return;
}
static void bracketTickCoIm(FICL_VM *pVM)
{
ficlTick(pVM);
literalIm(pVM);
return;
}
/**************************************************************************
p o s t p o n e
** Lookup the next word in the input stream and compile code to
** insert it into definitions created by the resulting word
** (defers compilation, even of immediate words)
**************************************************************************/
static void postponeCoIm(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
FICL_WORD *pFW;
FICL_WORD *pComma = ficlLookup(pVM->pSys, ",");
assert(pComma);
ficlTick(pVM);
pFW = stackGetTop(pVM->pStack).p;
if (wordIsImmediate(pFW))
{
dictAppendCell(dp, stackPop(pVM->pStack));
}
else
{
literalIm(pVM);
dictAppendCell(dp, LVALUEtoCELL(pComma));
}
return;
}
/**************************************************************************
e x e c u t e
** Pop an execution token (pointer to a word) off the stack and
** run it
**************************************************************************/
static void execute(FICL_VM *pVM)
{
FICL_WORD *pFW;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 0);
#endif
pFW = stackPopPtr(pVM->pStack);
vmExecute(pVM, pFW);
return;
}
/**************************************************************************
i m m e d i a t e
** Make the most recently compiled word IMMEDIATE -- it executes even
** in compile state (most often used for control compiling words
** such as IF, THEN, etc)
**************************************************************************/
static void immediate(FICL_VM *pVM)
{
IGNORE(pVM);
dictSetImmediate(vmGetDict(pVM));
return;
}
static void compileOnly(FICL_VM *pVM)
{
IGNORE(pVM);
dictSetFlags(vmGetDict(pVM), FW_COMPILE, 0);
return;
}
static void setObjectFlag(FICL_VM *pVM)
{
IGNORE(pVM);
dictSetFlags(vmGetDict(pVM), FW_ISOBJECT, 0);
return;
}
static void isObject(FICL_VM *pVM)
{
FICL_INT flag;
FICL_WORD *pFW = (FICL_WORD *)stackPopPtr(pVM->pStack);
flag = ((pFW != NULL) && (pFW->flags & FW_ISOBJECT)) ? FICL_TRUE : FICL_FALSE;
stackPushINT(pVM->pStack, flag);
return;
}
static void cstringLit(FICL_VM *pVM)
{
FICL_STRING *sp = (FICL_STRING *)(pVM->ip);
char *cp = sp->text;
cp += sp->count + 1;
cp = alignPtr(cp);
pVM->ip = (IPTYPE)(void *)cp;
stackPushPtr(pVM->pStack, sp);
return;
}
static void cstringQuoteIm(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
if (pVM->state == INTERPRET)
{
FICL_STRING *sp = (FICL_STRING *) dp->here;
vmGetString(pVM, sp, '\"');
stackPushPtr(pVM->pStack, sp);
/* move HERE past string so it doesn't get overwritten. --lch */
dictAllot(dp, sp->count + sizeof(FICL_COUNT));
}
else /* COMPILE state */
{
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pCStringLit));
dp->here = PTRtoCELL vmGetString(pVM, (FICL_STRING *)dp->here, '\"');
dictAlign(dp);
}
return;
}
/**************************************************************************
d o t Q u o t e
** IMMEDIATE word that compiles a string literal for later display
** Compile stringLit, then copy the bytes of the string from the TIB
** to the dictionary. Backpatch the count byte and align the dictionary.
**
** stringlit: Fetch the count from the dictionary, then push the address
** and count on the stack. Finally, update ip to point to the first
** aligned address after the string text.
**************************************************************************/
static void stringLit(FICL_VM *pVM)
{
FICL_STRING *sp;
FICL_COUNT count;
char *cp;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 0, 2);
#endif
sp = (FICL_STRING *)(pVM->ip);
count = sp->count;
cp = sp->text;
PUSHPTR(cp);
PUSHUNS(count);
cp += count + 1;
cp = alignPtr(cp);
pVM->ip = (IPTYPE)(void *)cp;
}
static void dotQuoteCoIm(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
FICL_WORD *pType = ficlLookup(pVM->pSys, "type");
assert(pType);
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pStringLit));
dp->here = PTRtoCELL vmGetString(pVM, (FICL_STRING *)dp->here, '\"');
dictAlign(dp);
dictAppendCell(dp, LVALUEtoCELL(pType));
return;
}
static void dotParen(FICL_VM *pVM)
{
char *pSrc = vmGetInBuf(pVM);
char *pEnd = vmGetInBufEnd(pVM);
char *pDest = pVM->pad;
char ch;
/*
** Note: the standard does not want leading spaces skipped (apparently)
*/
for (ch = *pSrc; (pEnd != pSrc) && (ch != ')'); ch = *++pSrc)
*pDest++ = ch;
*pDest = '\0';
if ((pEnd != pSrc) && (ch == ')'))
pSrc++;
vmTextOut(pVM, pVM->pad, 0);
vmUpdateTib(pVM, pSrc);
return;
}
/**************************************************************************
s l i t e r a l
** STRING
** Interpretation: Interpretation semantics for this word are undefined.
** Compilation: ( c-addr1 u -- )
** Append the run-time semantics given below to the current definition.
** Run-time: ( -- c-addr2 u )
** Return c-addr2 u describing a string consisting of the characters
** specified by c-addr1 u during compilation. A program shall not alter
** the returned string.
**************************************************************************/
static void sLiteralCoIm(FICL_VM *pVM)
{
FICL_DICT *dp;
char *cp, *cpDest;
FICL_UNS u;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 0);
#endif
dp = vmGetDict(pVM);
u = POPUNS();
cp = POPPTR();
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pStringLit));
cpDest = (char *) dp->here;
*cpDest++ = (char) u;
for (; u > 0; --u)
{
*cpDest++ = *cp++;
}
*cpDest++ = 0;
dp->here = PTRtoCELL alignPtr(cpDest);
return;
}
/**************************************************************************
s t a t e
** Return the address of the VM's state member (must be sized the
** same as a CELL for this reason)
**************************************************************************/
static void state(FICL_VM *pVM)
{
#if FICL_ROBUST > 1
vmCheckStack(pVM, 0, 1);
#endif
PUSHPTR(&pVM->state);
return;
}
/**************************************************************************
c r e a t e . . . d o e s >
** Make a new word in the dictionary with the run-time effect of
** a variable (push my address), but with extra space allotted
** for use by does> .
**************************************************************************/
static void createParen(FICL_VM *pVM)
{
CELL *pCell;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 0, 1);
#endif
pCell = pVM->runningWord->param;
PUSHPTR(pCell+1);
return;
}
static void create(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
STRINGINFO si = vmGetWord(pVM);
dictCheckThreshold(dp);
dictAppendWord2(dp, si, createParen, FW_DEFAULT);
dictAllotCells(dp, 1);
return;
}
static void doDoes(FICL_VM *pVM)
{
CELL *pCell;
IPTYPE tempIP;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 0, 1);
#endif
pCell = pVM->runningWord->param;
tempIP = (IPTYPE)((*pCell).p);
PUSHPTR(pCell+1);
vmPushIP(pVM, tempIP);
return;
}
static void doesParen(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
dp->smudge->code = doDoes;
dp->smudge->param[0] = LVALUEtoCELL(pVM->ip);
vmPopIP(pVM);
return;
}
static void doesCoIm(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
#if FICL_WANT_LOCALS
assert(pVM->pSys->pUnLinkParen);
if (pVM->pSys->nLocals > 0)
{
FICL_DICT *pLoc = ficlGetLoc(pVM->pSys);
dictEmpty(pLoc, pLoc->pForthWords->size);
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pUnLinkParen));
}
pVM->pSys->nLocals = 0;
#endif
IGNORE(pVM);
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pDoesParen));
return;
}
/**************************************************************************
t o b o d y
** to-body CORE ( xt -- a-addr )
** a-addr is the data-field address corresponding to xt. An ambiguous
** condition exists if xt is not for a word defined via CREATE.
**************************************************************************/
static void toBody(FICL_VM *pVM)
{
FICL_WORD *pFW;
/*#$-GUY CHANGE: Added robustness.-$#*/
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 1);
#endif
pFW = POPPTR();
PUSHPTR(pFW->param + 1);
return;
}
/*
** from-body ficl ( a-addr -- xt )
** Reverse effect of >body
*/
static void fromBody(FICL_VM *pVM)
{
char *ptr;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 1);
#endif
ptr = (char *)POPPTR() - sizeof (FICL_WORD);
PUSHPTR(ptr);
return;
}
/*
** >name ficl ( xt -- c-addr u )
** Push the address and length of a word's name given its address
** xt.
*/
static void toName(FICL_VM *pVM)
{
FICL_WORD *pFW;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 2);
#endif
pFW = POPPTR();
PUSHPTR(pFW->name);
PUSHUNS(pFW->nName);
return;
}
static void getLastWord(FICL_VM *pVM)
{
FICL_DICT *pDict = vmGetDict(pVM);
FICL_WORD *wp = pDict->smudge;
assert(wp);
vmPush(pVM, LVALUEtoCELL(wp));
return;
}
/**************************************************************************
l b r a c k e t e t c
**
**************************************************************************/
static void lbracketCoIm(FICL_VM *pVM)
{
pVM->state = INTERPRET;
return;
}
static void rbracket(FICL_VM *pVM)
{
pVM->state = COMPILE;
return;
}
/**************************************************************************
p i c t u r e d n u m e r i c w o r d s
**
** less-number-sign CORE ( -- )
** Initialize the pictured numeric output conversion process.
** (clear the pad)
**************************************************************************/
static void lessNumberSign(FICL_VM *pVM)
{
FICL_STRING *sp = PTRtoSTRING pVM->pad;
sp->count = 0;
return;
}
/*
** number-sign CORE ( ud1 -- ud2 )
** Divide ud1 by the number in BASE giving the quotient ud2 and the remainder
** n. (n is the least-significant digit of ud1.) Convert n to external form
** and add the resulting character to the beginning of the pictured numeric
** output string. An ambiguous condition exists if # executes outside of a
** <# #> delimited number conversion.
*/
static void numberSign(FICL_VM *pVM)
{
FICL_STRING *sp;
DPUNS u;
UNS16 rem;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 2);
#endif
sp = PTRtoSTRING pVM->pad;
u = u64Pop(pVM->pStack);
rem = m64UMod(&u, (UNS16)(pVM->base));
sp->text[sp->count++] = digit_to_char(rem);
u64Push(pVM->pStack, u);
return;
}
/*
** number-sign-greater CORE ( xd -- c-addr u )
** Drop xd. Make the pictured numeric output string available as a character
** string. c-addr and u specify the resulting character string. A program
** may replace characters within the string.
*/
static void numberSignGreater(FICL_VM *pVM)
{
FICL_STRING *sp;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 2);
#endif
sp = PTRtoSTRING pVM->pad;
sp->text[sp->count] = 0;
strrev(sp->text);
DROP(2);
PUSHPTR(sp->text);
PUSHUNS(sp->count);
return;
}
/*
** number-sign-s CORE ( ud1 -- ud2 )
** Convert one digit of ud1 according to the rule for #. Continue conversion
** until the quotient is zero. ud2 is zero. An ambiguous condition exists if
** #S executes outside of a <# #> delimited number conversion.
** TO DO: presently does not use ud1 hi cell - use it!
*/
static void numberSignS(FICL_VM *pVM)
{
FICL_STRING *sp;
DPUNS u;
UNS16 rem;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 2, 2);
#endif
sp = PTRtoSTRING pVM->pad;
u = u64Pop(pVM->pStack);
do
{
rem = m64UMod(&u, (UNS16)(pVM->base));
sp->text[sp->count++] = digit_to_char(rem);
}
while (u.hi || u.lo);
u64Push(pVM->pStack, u);
return;
}
/*
** HOLD CORE ( char -- )
** Add char to the beginning of the pictured numeric output string. An ambiguous
** condition exists if HOLD executes outside of a <# #> delimited number conversion.
*/
static void hold(FICL_VM *pVM)
{
FICL_STRING *sp;
int i;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 0);
#endif
sp = PTRtoSTRING pVM->pad;
i = POPINT();
sp->text[sp->count++] = (char) i;
return;
}
/*
** SIGN CORE ( n -- )
** If n is negative, add a minus sign to the beginning of the pictured
** numeric output string. An ambiguous condition exists if SIGN
** executes outside of a <# #> delimited number conversion.
*/
static void sign(FICL_VM *pVM)
{
FICL_STRING *sp;
int i;
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 0);
#endif
sp = PTRtoSTRING pVM->pad;
i = POPINT();
if (i < 0)
sp->text[sp->count++] = '-';
return;
}
/**************************************************************************
t o N u m b e r
** to-number CORE ( ud1 c-addr1 u1 -- ud2 c-addr2 u2 )
** ud2 is the unsigned result of converting the characters within the
** string specified by c-addr1 u1 into digits, using the number in BASE,
** and adding each into ud1 after multiplying ud1 by the number in BASE.
** Conversion continues left-to-right until a character that is not
** convertible, including any + or -, is encountered or the string is
** entirely converted. c-addr2 is the location of the first unconverted
** character or the first character past the end of the string if the string
** was entirely converted. u2 is the number of unconverted characters in the
** string. An ambiguous condition exists if ud2 overflows during the
** conversion.
**************************************************************************/
static void toNumber(FICL_VM *pVM)
{
FICL_UNS count;
char *cp;
DPUNS accum;
FICL_UNS base = pVM->base;
FICL_UNS ch;
FICL_UNS digit;
#if FICL_ROBUST > 1
vmCheckStack(pVM,4,4);
#endif
count = POPUNS();
cp = (char *)POPPTR();
accum = u64Pop(pVM->pStack);
for (ch = *cp; count > 0; ch = *++cp, count--)
{
if (ch < '0')
break;
digit = ch - '0';
if (digit > 9)
digit = tolower(ch) - 'a' + 10;
/*
** Note: following test also catches chars between 9 and a
** because 'digit' is unsigned!
*/
if (digit >= base)
break;
accum = m64Mac(accum, base, digit);
}
u64Push(pVM->pStack, accum);
PUSHPTR(cp);
PUSHUNS(count);
return;
}
/**************************************************************************
q u i t & a b o r t
** quit CORE ( -- ) ( R: i*x -- )
** Empty the return stack, store zero in SOURCE-ID if it is present, make
** the user input device the input source, and enter interpretation state.
** Do not display a message. Repeat the following:
**
** Accept a line from the input source into the input buffer, set >IN to
** zero, and interpret.
** Display the implementation-defined system prompt if in
** interpretation state, all processing has been completed, and no
** ambiguous condition exists.
**************************************************************************/
static void quit(FICL_VM *pVM)
{
vmThrow(pVM, VM_QUIT);
return;
}
static void ficlAbort(FICL_VM *pVM)
{
vmThrow(pVM, VM_ABORT);
return;
}
/**************************************************************************
a c c e p t
** accept CORE ( c-addr +n1 -- +n2 )
** Receive a string of at most +n1 characters. An ambiguous condition
** exists if +n1 is zero or greater than 32,767. Display graphic characters
** as they are received. A program that depends on the presence or absence
** of non-graphic characters in the string has an environmental dependency.
** The editing functions, if any, that the system performs in order to
** construct the string are implementation-defined.
**
** (Although the standard text doesn't say so, I assume that the intent
** of 'accept' is to store the string at the address specified on
** the stack.)
** Implementation: if there's more text in the TIB, use it. Otherwise
** throw out for more text. Copy characters up to the max count into the
** address given, and return the number of actual characters copied.
**
** Note (sobral) this may not be the behavior you'd expect if you're
** trying to get user input at load time!
**************************************************************************/
static void accept(FICL_VM *pVM)
{
FICL_UNS count, len;
char *cp;
char *pBuf, *pEnd;
#if FICL_ROBUST > 1
vmCheckStack(pVM,2,1);
#endif
pBuf = vmGetInBuf(pVM);
pEnd = vmGetInBufEnd(pVM);
len = pEnd - pBuf;
if (len == 0)
vmThrow(pVM, VM_RESTART);
/*
** Now we have something in the text buffer - use it
*/
count = stackPopINT(pVM->pStack);
cp = stackPopPtr(pVM->pStack);
len = (count < len) ? count : len;
strncpy(cp, vmGetInBuf(pVM), len);
pBuf += len;
vmUpdateTib(pVM, pBuf);
PUSHINT(len);
return;
}
/**************************************************************************
a l i g n
** 6.1.0705 ALIGN CORE ( -- )
** If the data-space pointer is not aligned, reserve enough space to
** align it.
**************************************************************************/
static void align(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
IGNORE(pVM);
dictAlign(dp);
return;
}
/**************************************************************************
a l i g n e d
**
**************************************************************************/
static void aligned(FICL_VM *pVM)
{
void *addr;
#if FICL_ROBUST > 1
vmCheckStack(pVM,1,1);
#endif
addr = POPPTR();
PUSHPTR(alignPtr(addr));
return;
}
/**************************************************************************
b e g i n & f r i e n d s
** Indefinite loop control structures
** A.6.1.0760 BEGIN
** Typical use:
** : X ... BEGIN ... test UNTIL ;
** or
** : X ... BEGIN ... test WHILE ... REPEAT ;
**************************************************************************/
static void beginCoIm(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
markBranch(dp, pVM, destTag);
return;
}
static void untilCoIm(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
assert(pVM->pSys->pBranch0);
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pBranch0));
resolveBackBranch(dp, pVM, destTag);
return;
}
static void whileCoIm(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
assert(pVM->pSys->pBranch0);
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pBranch0));
markBranch(dp, pVM, origTag);
twoSwap(pVM);
dictAppendUNS(dp, 1);
return;
}
static void repeatCoIm(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
assert(pVM->pSys->pBranchParen);
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pBranchParen));
/* expect "begin" branch marker */
resolveBackBranch(dp, pVM, destTag);
/* expect "while" branch marker */
resolveForwardBranch(dp, pVM, origTag);
return;
}
static void againCoIm(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
assert(pVM->pSys->pBranchParen);
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pBranchParen));
/* expect "begin" branch marker */
resolveBackBranch(dp, pVM, destTag);
return;
}
/**************************************************************************
c h a r & f r i e n d s
** 6.1.0895 CHAR CORE ( "<spaces>name" -- char )
** Skip leading space delimiters. Parse name delimited by a space.
** Put the value of its first character onto the stack.
**
** bracket-char CORE
** Interpretation: Interpretation semantics for this word are undefined.
** Compilation: ( "<spaces>name" -- )
** Skip leading space delimiters. Parse name delimited by a space.
** Append the run-time semantics given below to the current definition.
** Run-time: ( -- char )
** Place char, the value of the first character of name, on the stack.
**************************************************************************/
static void ficlChar(FICL_VM *pVM)
{
STRINGINFO si;
#if FICL_ROBUST > 1
vmCheckStack(pVM,0,1);
#endif
si = vmGetWord(pVM);
PUSHUNS((FICL_UNS)(si.cp[0]));
return;
}
static void charCoIm(FICL_VM *pVM)
{
ficlChar(pVM);
literalIm(pVM);
return;
}
/**************************************************************************
c h a r P l u s
** char-plus CORE ( c-addr1 -- c-addr2 )
** Add the size in address units of a character to c-addr1, giving c-addr2.
**************************************************************************/
static void charPlus(FICL_VM *pVM)
{
char *cp;
#if FICL_ROBUST > 1
vmCheckStack(pVM,1,1);
#endif
cp = POPPTR();
PUSHPTR(cp + 1);
return;
}
/**************************************************************************
c h a r s
** chars CORE ( n1 -- n2 )
** n2 is the size in address units of n1 characters.
** For most processors, this function can be a no-op. To guarantee
** portability, we'll multiply by sizeof (char).
**************************************************************************/
#if defined (_M_IX86)
#pragma warning(disable: 4127)
#endif
static void ficlChars(FICL_VM *pVM)
{
if (sizeof (char) > 1)
{
FICL_INT i;
#if FICL_ROBUST > 1
vmCheckStack(pVM,1,1);
#endif
i = POPINT();
PUSHINT(i * sizeof (char));
}
/* otherwise no-op! */
return;
}
#if defined (_M_IX86)
#pragma warning(default: 4127)
#endif
/**************************************************************************
c o u n t
** COUNT CORE ( c-addr1 -- c-addr2 u )
** Return the character string specification for the counted string stored
** at c-addr1. c-addr2 is the address of the first character after c-addr1.
** u is the contents of the character at c-addr1, which is the length in
** characters of the string at c-addr2.
**************************************************************************/
static void count(FICL_VM *pVM)
{
FICL_STRING *sp;
#if FICL_ROBUST > 1
vmCheckStack(pVM,1,2);
#endif
sp = POPPTR();
PUSHPTR(sp->text);
PUSHUNS(sp->count);
return;
}
/**************************************************************************
e n v i r o n m e n t ?
** environment-query CORE ( c-addr u -- false | i*x true )
** c-addr is the address of a character string and u is the string's
** character count. u may have a value in the range from zero to an
** implementation-defined maximum which shall not be less than 31. The
** character string should contain a keyword from 3.2.6 Environmental
** queries or the optional word sets to be checked for correspondence
** with an attribute of the present environment. If the system treats the
** attribute as unknown, the returned flag is false; otherwise, the flag
** is true and the i*x returned is of the type specified in the table for
** the attribute queried.
**************************************************************************/
static void environmentQ(FICL_VM *pVM)
{
FICL_DICT *envp;
FICL_WORD *pFW;
STRINGINFO si;
#if FICL_ROBUST > 1
vmCheckStack(pVM,2,1);
#endif
envp = pVM->pSys->envp;
si.count = (FICL_COUNT)stackPopUNS(pVM->pStack);
si.cp = stackPopPtr(pVM->pStack);
pFW = dictLookup(envp, si);
if (pFW != NULL)
{
vmExecute(pVM, pFW);
PUSHINT(FICL_TRUE);
}
else
{
PUSHINT(FICL_FALSE);
}
return;
}
/**************************************************************************
e v a l u a t e
** EVALUATE CORE ( i*x c-addr u -- j*x )
** Save the current input source specification. Store minus-one (-1) in
** SOURCE-ID if it is present. Make the string described by c-addr and u
** both the input source and input buffer, set >IN to zero, and interpret.
** When the parse area is empty, restore the prior input source
** specification. Other stack effects are due to the words EVALUATEd.
**
**************************************************************************/
static void evaluate(FICL_VM *pVM)
{
FICL_UNS count;
char *cp;
CELL id;
int result;
#if FICL_ROBUST > 1
vmCheckStack(pVM,2,0);
#endif
count = POPUNS();
cp = POPPTR();
IGNORE(count);
id = pVM->sourceID;
pVM->sourceID.i = -1;
result = ficlExecC(pVM, cp, count);
pVM->sourceID = id;
if (result != VM_OUTOFTEXT)
vmThrow(pVM, result);
return;
}
/**************************************************************************
s t r i n g q u o t e
** Interpreting: get string delimited by a quote from the input stream,
** copy to a scratch area, and put its count and address on the stack.
** Compiling: compile code to push the address and count of a string
** literal, compile the string from the input stream, and align the dict
** pointer.
**************************************************************************/
static void stringQuoteIm(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
if (pVM->state == INTERPRET)
{
FICL_STRING *sp = (FICL_STRING *) dp->here;
vmGetString(pVM, sp, '\"');
PUSHPTR(sp->text);
PUSHUNS(sp->count);
}
else /* COMPILE state */
{
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pStringLit));
dp->here = PTRtoCELL vmGetString(pVM, (FICL_STRING *)dp->here, '\"');
dictAlign(dp);
}
return;
}
/**************************************************************************
t y p e
** Pop count and char address from stack and print the designated string.
**************************************************************************/
static void type(FICL_VM *pVM)
{
FICL_UNS count = stackPopUNS(pVM->pStack);
char *cp = stackPopPtr(pVM->pStack);
char *pDest = (char *)ficlMalloc(count + 1);
/*
** Since we don't have an output primitive for a counted string
** (oops), make sure the string is null terminated. If not, copy
** and terminate it.
*/
if (!pDest)
vmThrowErr(pVM, "Error: out of memory");
strncpy(pDest, cp, count);
pDest[count] = '\0';
vmTextOut(pVM, pDest, 0);
ficlFree(pDest);
return;
}
/**************************************************************************
w o r d
** word CORE ( char "<chars>ccc<char>" -- c-addr )
** Skip leading delimiters. Parse characters ccc delimited by char. An
** ambiguous condition exists if the length of the parsed string is greater
** than the implementation-defined length of a counted string.
**
** c-addr is the address of a transient region containing the parsed word
** as a counted string. If the parse area was empty or contained no
** characters other than the delimiter, the resulting string has a zero
** length. A space, not included in the length, follows the string. A
** program may replace characters within the string.
** NOTE! Ficl also NULL-terminates the dest string.
**************************************************************************/
static void ficlWord(FICL_VM *pVM)
{
FICL_STRING *sp;
char delim;
STRINGINFO si;
#if FICL_ROBUST > 1
vmCheckStack(pVM,1,1);
#endif
sp = (FICL_STRING *)pVM->pad;
delim = (char)POPINT();
si = vmParseStringEx(pVM, delim, 1);
if (SI_COUNT(si) > nPAD-1)
SI_SETLEN(si, nPAD-1);
sp->count = (FICL_COUNT)SI_COUNT(si);
strncpy(sp->text, SI_PTR(si), SI_COUNT(si));
/*#$-GUY CHANGE: I added this.-$#*/
sp->text[sp->count] = 0;
strcat(sp->text, " ");
PUSHPTR(sp);
return;
}
/**************************************************************************
p a r s e - w o r d
** ficl PARSE-WORD ( <spaces>name -- c-addr u )
** Skip leading spaces and parse name delimited by a space. c-addr is the
** address within the input buffer and u is the length of the selected
** string. If the parse area is empty, the resulting string has a zero length.
**************************************************************************/
static void parseNoCopy(FICL_VM *pVM)
{
STRINGINFO si;
#if FICL_ROBUST > 1
vmCheckStack(pVM,0,2);
#endif
si = vmGetWord0(pVM);
PUSHPTR(SI_PTR(si));
PUSHUNS(SI_COUNT(si));
return;
}
/**************************************************************************
p a r s e
** CORE EXT ( char "ccc<char>" -- c-addr u )
** Parse ccc delimited by the delimiter char.
** c-addr is the address (within the input buffer) and u is the length of
** the parsed string. If the parse area was empty, the resulting string has
** a zero length.
** NOTE! PARSE differs from WORD: it does not skip leading delimiters.
**************************************************************************/
static void parse(FICL_VM *pVM)
{
STRINGINFO si;
char delim;
#if FICL_ROBUST > 1
vmCheckStack(pVM,1,2);
#endif
delim = (char)POPINT();
si = vmParseStringEx(pVM, delim, 0);
PUSHPTR(SI_PTR(si));
PUSHUNS(SI_COUNT(si));
return;
}
/**************************************************************************
f i l l
** CORE ( c-addr u char -- )
** If u is greater than zero, store char in each of u consecutive
** characters of memory beginning at c-addr.
**************************************************************************/
static void fill(FICL_VM *pVM)
{
char ch;
FICL_UNS u;
char *cp;
#if FICL_ROBUST > 1
vmCheckStack(pVM,3,0);
#endif
ch = (char)POPINT();
u = POPUNS();
cp = (char *)POPPTR();
while (u > 0)
{
*cp++ = ch;
u--;
}
return;
}
/**************************************************************************
f i n d
** FIND CORE ( c-addr -- c-addr 0 | xt 1 | xt -1 )
** Find the definition named in the counted string at c-addr. If the
** definition is not found, return c-addr and zero. If the definition is
** found, return its execution token xt. If the definition is immediate,
** also return one (1), otherwise also return minus-one (-1). For a given
** string, the values returned by FIND while compiling may differ from
** those returned while not compiling.
**************************************************************************/
static void do_find(FICL_VM *pVM, STRINGINFO si, void *returnForFailure)
{
FICL_WORD *pFW;
pFW = dictLookup(vmGetDict(pVM), si);
if (pFW)
{
PUSHPTR(pFW);
PUSHINT((wordIsImmediate(pFW) ? 1 : -1));
}
else
{
PUSHPTR(returnForFailure);
PUSHUNS(0);
}
return;
}
/**************************************************************************
f i n d
** FIND CORE ( c-addr -- c-addr 0 | xt 1 | xt -1 )
** Find the definition named in the counted string at c-addr. If the
** definition is not found, return c-addr and zero. If the definition is
** found, return its execution token xt. If the definition is immediate,
** also return one (1), otherwise also return minus-one (-1). For a given
** string, the values returned by FIND while compiling may differ from
** those returned while not compiling.
**************************************************************************/
static void cFind(FICL_VM *pVM)
{
FICL_STRING *sp;
STRINGINFO si;
#if FICL_ROBUST > 1
vmCheckStack(pVM,1,2);
#endif
sp = POPPTR();
SI_PFS(si, sp);
do_find(pVM, si, sp);
}
/**************************************************************************
s f i n d
** FICL ( c-addr u -- 0 0 | xt 1 | xt -1 )
** Like FIND, but takes "c-addr u" for the string.
**************************************************************************/
static void sFind(FICL_VM *pVM)
{
STRINGINFO si;
#if FICL_ROBUST > 1
vmCheckStack(pVM,2,2);
#endif
si.count = stackPopINT(pVM->pStack);
si.cp = stackPopPtr(pVM->pStack);
do_find(pVM, si, NULL);
}
/**************************************************************************
f m S l a s h M o d
** f-m-slash-mod CORE ( d1 n1 -- n2 n3 )
** Divide d1 by n1, giving the floored quotient n3 and the remainder n2.
** Input and output stack arguments are signed. An ambiguous condition
** exists if n1 is zero or if the quotient lies outside the range of a
** single-cell signed integer.
**************************************************************************/
static void fmSlashMod(FICL_VM *pVM)
{
DPINT d1;
FICL_INT n1;
INTQR qr;
#if FICL_ROBUST > 1
vmCheckStack(pVM,3,2);
#endif
n1 = POPINT();
d1 = i64Pop(pVM->pStack);
qr = m64FlooredDivI(d1, n1);
PUSHINT(qr.rem);
PUSHINT(qr.quot);
return;
}
/**************************************************************************
s m S l a s h R e m
** s-m-slash-rem CORE ( d1 n1 -- n2 n3 )
** Divide d1 by n1, giving the symmetric quotient n3 and the remainder n2.
** Input and output stack arguments are signed. An ambiguous condition
** exists if n1 is zero or if the quotient lies outside the range of a
** single-cell signed integer.
**************************************************************************/
static void smSlashRem(FICL_VM *pVM)
{
DPINT d1;
FICL_INT n1;
INTQR qr;
#if FICL_ROBUST > 1
vmCheckStack(pVM,3,2);
#endif
n1 = POPINT();
d1 = i64Pop(pVM->pStack);
qr = m64SymmetricDivI(d1, n1);
PUSHINT(qr.rem);
PUSHINT(qr.quot);
return;
}
static void ficlMod(FICL_VM *pVM)
{
DPINT d1;
FICL_INT n1;
INTQR qr;
#if FICL_ROBUST > 1
vmCheckStack(pVM,2,1);
#endif
n1 = POPINT();
d1.lo = POPINT();
i64Extend(d1);
qr = m64SymmetricDivI(d1, n1);
PUSHINT(qr.rem);
return;
}
/**************************************************************************
u m S l a s h M o d
** u-m-slash-mod CORE ( ud u1 -- u2 u3 )
** Divide ud by u1, giving the quotient u3 and the remainder u2.
** All values and arithmetic are unsigned. An ambiguous condition
** exists if u1 is zero or if the quotient lies outside the range of a
** single-cell unsigned integer.
*************************************************************************/
static void umSlashMod(FICL_VM *pVM)
{
DPUNS ud;
FICL_UNS u1;
UNSQR qr;
u1 = stackPopUNS(pVM->pStack);
ud = u64Pop(pVM->pStack);
qr = ficlLongDiv(ud, u1);
PUSHUNS(qr.rem);
PUSHUNS(qr.quot);
return;
}
/**************************************************************************
l s h i f t
** l-shift CORE ( x1 u -- x2 )
** Perform a logical left shift of u bit-places on x1, giving x2.
** Put zeroes into the least significant bits vacated by the shift.
** An ambiguous condition exists if u is greater than or equal to the
** number of bits in a cell.
**
** r-shift CORE ( x1 u -- x2 )
** Perform a logical right shift of u bit-places on x1, giving x2.
** Put zeroes into the most significant bits vacated by the shift. An
** ambiguous condition exists if u is greater than or equal to the
** number of bits in a cell.
**************************************************************************/
static void lshift(FICL_VM *pVM)
{
FICL_UNS nBits;
FICL_UNS x1;
#if FICL_ROBUST > 1
vmCheckStack(pVM,2,1);
#endif
nBits = POPUNS();
x1 = POPUNS();
PUSHUNS(x1 << nBits);
return;
}
static void rshift(FICL_VM *pVM)
{
FICL_UNS nBits;
FICL_UNS x1;
#if FICL_ROBUST > 1
vmCheckStack(pVM,2,1);
#endif
nBits = POPUNS();
x1 = POPUNS();
PUSHUNS(x1 >> nBits);
return;
}
/**************************************************************************
m S t a r
** m-star CORE ( n1 n2 -- d )
** d is the signed product of n1 times n2.
**************************************************************************/
static void mStar(FICL_VM *pVM)
{
FICL_INT n2;
FICL_INT n1;
DPINT d;
#if FICL_ROBUST > 1
vmCheckStack(pVM,2,2);
#endif
n2 = POPINT();
n1 = POPINT();
d = m64MulI(n1, n2);
i64Push(pVM->pStack, d);
return;
}
static void umStar(FICL_VM *pVM)
{
FICL_UNS u2;
FICL_UNS u1;
DPUNS ud;
#if FICL_ROBUST > 1
vmCheckStack(pVM,2,2);
#endif
u2 = POPUNS();
u1 = POPUNS();
ud = ficlLongMul(u1, u2);
u64Push(pVM->pStack, ud);
return;
}
/**************************************************************************
m a x & m i n
**
**************************************************************************/
static void ficlMax(FICL_VM *pVM)
{
FICL_INT n2;
FICL_INT n1;
#if FICL_ROBUST > 1
vmCheckStack(pVM,2,1);
#endif
n2 = POPINT();
n1 = POPINT();
PUSHINT((n1 > n2) ? n1 : n2);
return;
}
static void ficlMin(FICL_VM *pVM)
{
FICL_INT n2;
FICL_INT n1;
#if FICL_ROBUST > 1
vmCheckStack(pVM,2,1);
#endif
n2 = POPINT();
n1 = POPINT();
PUSHINT((n1 < n2) ? n1 : n2);
return;
}
/**************************************************************************
m o v e
** CORE ( addr1 addr2 u -- )
** If u is greater than zero, copy the contents of u consecutive address
** units at addr1 to the u consecutive address units at addr2. After MOVE
** completes, the u consecutive address units at addr2 contain exactly
** what the u consecutive address units at addr1 contained before the move.
** NOTE! This implementation assumes that a char is the same size as
** an address unit.
**************************************************************************/
static void move(FICL_VM *pVM)
{
FICL_UNS u;
char *addr2;
char *addr1;
#if FICL_ROBUST > 1
vmCheckStack(pVM,3,0);
#endif
u = POPUNS();
addr2 = POPPTR();
addr1 = POPPTR();
if (u == 0)
return;
/*
** Do the copy carefully, so as to be
** correct even if the two ranges overlap
*/
if (addr1 >= addr2)
{
for (; u > 0; u--)
*addr2++ = *addr1++;
}
else
{
addr2 += u-1;
addr1 += u-1;
for (; u > 0; u--)
*addr2-- = *addr1--;
}
return;
}
/**************************************************************************
r e c u r s e
**
**************************************************************************/
static void recurseCoIm(FICL_VM *pVM)
{
FICL_DICT *pDict = vmGetDict(pVM);
IGNORE(pVM);
dictAppendCell(pDict, LVALUEtoCELL(pDict->smudge));
return;
}
/**************************************************************************
s t o d
** s-to-d CORE ( n -- d )
** Convert the number n to the double-cell number d with the same
** numerical value.
**************************************************************************/
static void sToD(FICL_VM *pVM)
{
FICL_INT s;
#if FICL_ROBUST > 1
vmCheckStack(pVM,1,2);
#endif
s = POPINT();
/* sign extend to 64 bits.. */
PUSHINT(s);
PUSHINT((s < 0) ? -1 : 0);
return;
}
/**************************************************************************
s o u r c e
** CORE ( -- c-addr u )
** c-addr is the address of, and u is the number of characters in, the
** input buffer.
**************************************************************************/
static void source(FICL_VM *pVM)
{
#if FICL_ROBUST > 1
vmCheckStack(pVM,0,2);
#endif
PUSHPTR(pVM->tib.cp);
PUSHINT(vmGetInBufLen(pVM));
return;
}
/**************************************************************************
v e r s i o n
** non-standard...
**************************************************************************/
static void ficlVersion(FICL_VM *pVM)
{
vmTextOut(pVM, "ficl Version " FICL_VER, 1);
return;
}
/**************************************************************************
t o I n
** to-in CORE
**************************************************************************/
static void toIn(FICL_VM *pVM)
{
#if FICL_ROBUST > 1
vmCheckStack(pVM,0,1);
#endif
PUSHPTR(&pVM->tib.index);
return;
}
/**************************************************************************
c o l o n N o N a m e
** CORE EXT ( C: -- colon-sys ) ( S: -- xt )
** Create an unnamed colon definition and push its address.
** Change state to compile.
**************************************************************************/
static void colonNoName(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
FICL_WORD *pFW;
STRINGINFO si;
SI_SETLEN(si, 0);
SI_SETPTR(si, NULL);
pVM->state = COMPILE;
pFW = dictAppendWord2(dp, si, colonParen, FW_DEFAULT | FW_SMUDGE);
PUSHPTR(pFW);
markControlTag(pVM, colonTag);
return;
}
/**************************************************************************
u s e r V a r i a b l e
** user ( u -- ) "<spaces>name"
** Get a name from the input stream and create a user variable
** with the name and the index supplied. The run-time effect
** of a user variable is to push the address of the indexed cell
** in the running vm's user array.
**
** User variables are vm local cells. Each vm has an array of
** FICL_USER_CELLS of them when FICL_WANT_USER is nonzero.
** Ficl's user facility is implemented with two primitives,
** "user" and "(user)", a variable ("nUser") (in softcore.c) that
** holds the index of the next free user cell, and a redefinition
** (also in softcore) of "user" that defines a user word and increments
** nUser.
**************************************************************************/
#if FICL_WANT_USER
static void userParen(FICL_VM *pVM)
{
FICL_INT i = pVM->runningWord->param[0].i;
PUSHPTR(&pVM->user[i]);
return;
}
static void userVariable(FICL_VM *pVM)
{
FICL_DICT *dp = vmGetDict(pVM);
STRINGINFO si = vmGetWord(pVM);
CELL c;
c = stackPop(pVM->pStack);
if (c.i >= FICL_USER_CELLS)
{
vmThrowErr(pVM, "Error - out of user space");
}
dictAppendWord2(dp, si, userParen, FW_DEFAULT);
dictAppendCell(dp, c);
return;
}
#endif
/**************************************************************************
t o V a l u e
** CORE EXT
** Interpretation: ( x "<spaces>name" -- )
** Skip leading spaces and parse name delimited by a space. Store x in
** name. An ambiguous condition exists if name was not defined by VALUE.
** NOTE: In ficl, VALUE is an alias of CONSTANT
**************************************************************************/
static void toValue(FICL_VM *pVM)
{
STRINGINFO si = vmGetWord(pVM);
FICL_DICT *dp = vmGetDict(pVM);
FICL_WORD *pFW;
#if FICL_WANT_LOCALS
if ((pVM->pSys->nLocals > 0) && (pVM->state == COMPILE))
{
FICL_DICT *pLoc = ficlGetLoc(pVM->pSys);
pFW = dictLookup(pLoc, si);
if (pFW && (pFW->code == doLocalIm))
{
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pToLocalParen));
dictAppendCell(dp, LVALUEtoCELL(pFW->param[0]));
return;
}
else if (pFW && pFW->code == do2LocalIm)
{
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pTo2LocalParen));
dictAppendCell(dp, LVALUEtoCELL(pFW->param[0]));
return;
}
}
#endif
assert(pVM->pSys->pStore);
pFW = dictLookup(dp, si);
if (!pFW)
{
int i = SI_COUNT(si);
vmThrowErr(pVM, "%.*s not found", i, SI_PTR(si));
}
if (pVM->state == INTERPRET)
pFW->param[0] = stackPop(pVM->pStack);
else /* compile code to store to word's param */
{
PUSHPTR(&pFW->param[0]);
literalIm(pVM);
dictAppendCell(dp, LVALUEtoCELL(pVM->pSys->pStore));
}
return;
}
#if FICL_WANT_LOCALS
/**************************************************************************
l i n k P a r e n
** ( -- )
** Link a frame on the return stack, reserving nCells of space for
** locals - the value of nCells is the next cell in the instruction
** stream.
**************************************************************************/
static void linkParen(FICL_VM *pVM)
{
FICL_INT nLink = *(FICL_INT *)(pVM->ip);
vmBranchRelative(pVM, 1);
stackLink(pVM->rStack, nLink);
return;
}
static void unlinkParen(FICL_VM *pVM)
{
stackUnlink(pVM->rStack);
return;
}
/**************************************************************************
d o L o c a l I m
** Immediate - cfa of a local while compiling - when executed, compiles
** code to fetch the value of a local given the local's index in the
** word's pfa
**************************************************************************/
static void getLocalParen(FICL_VM *pVM)
{
FICL_INT nLocal = *(FICL_INT *)(pVM->ip++);
stackPush(pVM->pStack, pVM->rStack->pFrame[nLocal]);
return;
}
static void toLocalParen(FICL_VM *pVM)
{
FICL_INT nLocal = *(FICL_INT *)(pVM->ip++);
pVM->rStack->pFrame[nLocal] = stackPop(pVM->pStack);
return;
}
static void getLocal0(FICL_VM *pVM)
{
stackPush(pVM->pStack, pVM->rStack->pFrame[0]);
return;
}
static void toLocal0(FICL_VM *pVM)
{
pVM->rStack->pFrame[0] = stackPop(pVM->pStack);
return;
}
static void getLocal1(FICL_VM *pVM)
{
stackPush(pVM->pStack, pVM->rStack->pFrame[1]);
return;
}
static void toLocal1(FICL_VM *pVM)
{
pVM->rStack->pFrame[1] = stackPop(pVM->pStack);
return;
}
/*
** Each local is recorded in a private locals dictionary as a
** word that does doLocalIm at runtime. DoLocalIm compiles code
** into the client definition to fetch the value of the
** corresponding local variable from the return stack.
** The private dictionary gets initialized at the end of each block
** that uses locals (in ; and does> for example).
*/
static void doLocalIm(FICL_VM *pVM)
{
FICL_DICT *pDict = vmGetDict(pVM);
FICL_INT nLocal = pVM->runningWord->param[0].i;
if (pVM->state == INTERPRET)
{
stackPush(pVM->pStack, pVM->rStack->pFrame[nLocal]);
}
else
{
if (nLocal == 0)
{
dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->pGetLocal0));
}
else if (nLocal == 1)
{
dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->pGetLocal1));
}
else
{
dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->pGetLocalParen));
dictAppendCell(pDict, LVALUEtoCELL(nLocal));
}
}
return;
}
/**************************************************************************
l o c a l P a r e n
** paren-local-paren LOCAL
** Interpretation: Interpretation semantics for this word are undefined.
** Execution: ( c-addr u -- )
** When executed during compilation, (LOCAL) passes a message to the
** system that has one of two meanings. If u is non-zero,
** the message identifies a new local whose definition name is given by
** the string of characters identified by c-addr u. If u is zero,
** the message is last local and c-addr has no significance.
**
** The result of executing (LOCAL) during compilation of a definition is
** to create a set of named local identifiers, each of which is
** a definition name, that only have execution semantics within the scope
** of that definition's source.
**
** local Execution: ( -- x )
**
** Push the local's value, x, onto the stack. The local's value is
** initialized as described in 13.3.3 Processing locals and may be
** changed by preceding the local's name with TO. An ambiguous condition
** exists when local is executed while in interpretation state.
**************************************************************************/
static void localParen(FICL_VM *pVM)
{
FICL_DICT *pDict;
STRINGINFO si;
#if FICL_ROBUST > 1
vmCheckStack(pVM,2,0);
#endif
pDict = vmGetDict(pVM);
SI_SETLEN(si, POPUNS());
SI_SETPTR(si, (char *)POPPTR());
if (SI_COUNT(si) > 0)
{ /* add a local to the **locals** dict and update nLocals */
FICL_DICT *pLoc = ficlGetLoc(pVM->pSys);
if (pVM->pSys->nLocals >= FICL_MAX_LOCALS)
{
vmThrowErr(pVM, "Error: out of local space");
}
dictAppendWord2(pLoc, si, doLocalIm, FW_COMPIMMED);
dictAppendCell(pLoc, LVALUEtoCELL(pVM->pSys->nLocals));
if (pVM->pSys->nLocals == 0)
{ /* compile code to create a local stack frame */
dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->pLinkParen));
/* save location in dictionary for #locals */
pVM->pSys->pMarkLocals = pDict->here;
dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->nLocals));
/* compile code to initialize first local */
dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->pToLocal0));
}
else if (pVM->pSys->nLocals == 1)
{
dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->pToLocal1));
}
else
{
dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->pToLocalParen));
dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->nLocals));
}
(pVM->pSys->nLocals)++;
}
else if (pVM->pSys->nLocals > 0)
{ /* write nLocals to (link) param area in dictionary */
*(FICL_INT *)(pVM->pSys->pMarkLocals) = pVM->pSys->nLocals;
}
return;
}
static void get2LocalParen(FICL_VM *pVM)
{
FICL_INT nLocal = *(FICL_INT *)(pVM->ip++);
stackPush(pVM->pStack, pVM->rStack->pFrame[nLocal]);
stackPush(pVM->pStack, pVM->rStack->pFrame[nLocal+1]);
return;
}
static void do2LocalIm(FICL_VM *pVM)
{
FICL_DICT *pDict = vmGetDict(pVM);
FICL_INT nLocal = pVM->runningWord->param[0].i;
if (pVM->state == INTERPRET)
{
stackPush(pVM->pStack, pVM->rStack->pFrame[nLocal]);
stackPush(pVM->pStack, pVM->rStack->pFrame[nLocal+1]);
}
else
{
dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->pGet2LocalParen));
dictAppendCell(pDict, LVALUEtoCELL(nLocal));
}
return;
}
static void to2LocalParen(FICL_VM *pVM)
{
FICL_INT nLocal = *(FICL_INT *)(pVM->ip++);
pVM->rStack->pFrame[nLocal+1] = stackPop(pVM->pStack);
pVM->rStack->pFrame[nLocal] = stackPop(pVM->pStack);
return;
}
static void twoLocalParen(FICL_VM *pVM)
{
FICL_DICT *pDict = vmGetDict(pVM);
STRINGINFO si;
SI_SETLEN(si, stackPopUNS(pVM->pStack));
SI_SETPTR(si, (char *)stackPopPtr(pVM->pStack));
if (SI_COUNT(si) > 0)
{ /* add a local to the **locals** dict and update nLocals */
FICL_DICT *pLoc = ficlGetLoc(pVM->pSys);
if (pVM->pSys->nLocals >= FICL_MAX_LOCALS)
{
vmThrowErr(pVM, "Error: out of local space");
}
dictAppendWord2(pLoc, si, do2LocalIm, FW_COMPIMMED);
dictAppendCell(pLoc, LVALUEtoCELL(pVM->pSys->nLocals));
if (pVM->pSys->nLocals == 0)
{ /* compile code to create a local stack frame */
dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->pLinkParen));
/* save location in dictionary for #locals */
pVM->pSys->pMarkLocals = pDict->here;
dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->nLocals));
}
dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->pTo2LocalParen));
dictAppendCell(pDict, LVALUEtoCELL(pVM->pSys->nLocals));
pVM->pSys->nLocals += 2;
}
else if (pVM->pSys->nLocals > 0)
{ /* write nLocals to (link) param area in dictionary */
*(FICL_INT *)(pVM->pSys->pMarkLocals) = pVM->pSys->nLocals;
}
return;
}
#endif
/**************************************************************************
c o m p a r e
** STRING ( c-addr1 u1 c-addr2 u2 -- n )
** Compare the string specified by c-addr1 u1 to the string specified by
** c-addr2 u2. The strings are compared, beginning at the given addresses,
** character by character, up to the length of the shorter string or until a
** difference is found. If the two strings are identical, n is zero. If the two
** strings are identical up to the length of the shorter string, n is minus-one
** (-1) if u1 is less than u2 and one (1) otherwise. If the two strings are not
** identical up to the length of the shorter string, n is minus-one (-1) if the
** first non-matching character in the string specified by c-addr1 u1 has a
** lesser numeric value than the corresponding character in the string specified
** by c-addr2 u2 and one (1) otherwise.
**************************************************************************/
static void compareInternal(FICL_VM *pVM, int caseInsensitive)
{
char *cp1, *cp2;
FICL_UNS u1, u2, uMin;
int n = 0;
vmCheckStack(pVM, 4, 1);
u2 = stackPopUNS(pVM->pStack);
cp2 = (char *)stackPopPtr(pVM->pStack);
u1 = stackPopUNS(pVM->pStack);
cp1 = (char *)stackPopPtr(pVM->pStack);
uMin = (u1 < u2)? u1 : u2;
for ( ; (uMin > 0) && (n == 0); uMin--)
{
char c1 = *cp1++;
char c2 = *cp2++;
if (caseInsensitive)
{
c1 = (char)tolower(c1);
c2 = (char)tolower(c2);
}
n = (int)(c1 - c2);
}
if (n == 0)
n = (int)(u1 - u2);
if (n < 0)
n = -1;
else if (n > 0)
n = 1;
PUSHINT(n);
return;
}
static void compareString(FICL_VM *pVM)
{
compareInternal(pVM, FALSE);
}
static void compareStringInsensitive(FICL_VM *pVM)
{
compareInternal(pVM, TRUE);
}
/**************************************************************************
p a d
** CORE EXT ( -- c-addr )
** c-addr is the address of a transient region that can be used to hold
** data for intermediate processing.
**************************************************************************/
static void pad(FICL_VM *pVM)
{
stackPushPtr(pVM->pStack, pVM->pad);
}
/**************************************************************************
s o u r c e - i d
** CORE EXT, FILE ( -- 0 | -1 | fileid )
** Identifies the input source as follows:
**
** SOURCE-ID Input source
** --------- ------------
** fileid Text file fileid
** -1 String (via EVALUATE)
** 0 User input device
**************************************************************************/
static void sourceid(FICL_VM *pVM)
{
PUSHINT(pVM->sourceID.i);
return;
}
/**************************************************************************
r e f i l l
** CORE EXT ( -- flag )
** Attempt to fill the input buffer from the input source, returning a true
** flag if successful.
** When the input source is the user input device, attempt to receive input
** into the terminal input buffer. If successful, make the result the input
** buffer, set >IN to zero, and return true. Receipt of a line containing no
** characters is considered successful. If there is no input available from
** the current input source, return false.
** When the input source is a string from EVALUATE, return false and
** perform no other action.
**************************************************************************/
static void refill(FICL_VM *pVM)
{
FICL_INT ret = (pVM->sourceID.i == -1) ? FICL_FALSE : FICL_TRUE;
if (ret && (pVM->fRestart == 0))
vmThrow(pVM, VM_RESTART);
PUSHINT(ret);
return;
}
/**************************************************************************
freebsd exception handling words
** Catch, from ANS Forth standard. Installs a safety net, then EXECUTE
** the word in ToS. If an exception happens, restore the state to what
** it was before, and pushes the exception value on the stack. If not,
** push zero.
**
** Notice that Catch implements an inner interpreter. This is ugly,
** but given how ficl works, it cannot be helped. The problem is that
** colon definitions will be executed *after* the function returns,
** while "code" definitions will be executed immediately. I considered
** other solutions to this problem, but all of them shared the same
** basic problem (with added disadvantages): if ficl ever changes it's
** inner thread modus operandi, one would have to fix this word.
**
** More comments can be found throughout catch's code.
**
** Daniel C. Sobral Jan 09/1999
** sadler may 2000 -- revised to follow ficl.c:ficlExecXT.
**************************************************************************/
static void ficlCatch(FICL_VM *pVM)
{
int except;
jmp_buf vmState;
FICL_VM VM;
FICL_STACK pStack;
FICL_STACK rStack;
FICL_WORD *pFW;
assert(pVM);
assert(pVM->pSys->pExitInner);
/*
** Get xt.
** We need this *before* we save the stack pointer, or
** we'll have to pop one element out of the stack after
** an exception. I prefer to get done with it up front. :-)
*/
#if FICL_ROBUST > 1
vmCheckStack(pVM, 1, 0);
#endif
pFW = stackPopPtr(pVM->pStack);
/*
** Save vm's state -- a catch will not back out environmental
** changes.
**
** We are *not* saving dictionary state, since it is
** global instead of per vm, and we are not saving
** stack contents, since we are not required to (and,
** thus, it would be useless). We save pVM, and pVM
** "stacks" (a structure containing general information
** about it, including the current stack pointer).
*/
memcpy((void*)&VM, (void*)pVM, sizeof(FICL_VM));
memcpy((void*)&pStack, (void*)pVM->pStack, sizeof(FICL_STACK));
memcpy((void*)&rStack, (void*)pVM->rStack, sizeof(FICL_STACK));
/*
** Give pVM a jmp_buf
*/
pVM->pState = &vmState;
/*
** Safety net
*/
except = setjmp(vmState);
switch (except)
{
/*
** Setup condition - push poison pill so that the VM throws
** VM_INNEREXIT if the XT terminates normally, then execute
** the XT
*/
case 0:
vmPushIP(pVM, &(pVM->pSys->pExitInner)); /* Open mouth, insert emetic */
vmExecute(pVM, pFW);
vmInnerLoop(pVM);
break;
/*
** Normal exit from XT - lose the poison pill,
** restore old setjmp vector and push a zero.
*/
case VM_INNEREXIT:
vmPopIP(pVM); /* Gack - hurl poison pill */
pVM->pState = VM.pState; /* Restore just the setjmp vector */
PUSHINT(0); /* Push 0 -- everything is ok */
break;
/*
** Some other exception got thrown - restore pre-existing VM state
** and push the exception code
*/
default:
/* Restore vm's state */
memcpy((void*)pVM, (void*)&VM, sizeof(FICL_VM));
memcpy((void*)pVM->pStack, (void*)&pStack, sizeof(FICL_STACK));
memcpy((void*)pVM->rStack, (void*)&rStack, sizeof(FICL_STACK));
PUSHINT(except);/* Push error */
break;
}
}
/**************************************************************************
** t h r o w
** EXCEPTION
** Throw -- From ANS Forth standard.
**
** Throw takes the ToS and, if that's different from zero,
** returns to the last executed catch context. Further throws will
** unstack previously executed "catches", in LIFO mode.
**
** Daniel C. Sobral Jan 09/1999
**************************************************************************/
static void ficlThrow(FICL_VM *pVM)
{
int except;
except = stackPopINT(pVM->pStack);
if (except)
vmThrow(pVM, except);
}
/**************************************************************************
** a l l o c a t e
** MEMORY
**************************************************************************/
static void ansAllocate(FICL_VM *pVM)
{
size_t size;
void *p;
size = stackPopINT(pVM->pStack);
p = ficlMalloc(size);
PUSHPTR(p);
if (p)
PUSHINT(0);
else
PUSHINT(1);
}
/**************************************************************************
** f r e e
** MEMORY
**************************************************************************/
static void ansFree(FICL_VM *pVM)
{
void *p;
p = stackPopPtr(pVM->pStack);
ficlFree(p);
PUSHINT(0);
}
/**************************************************************************
** r e s i z e
** MEMORY
**************************************************************************/
static void ansResize(FICL_VM *pVM)
{
size_t size;
void *new, *old;
size = stackPopINT(pVM->pStack);
old = stackPopPtr(pVM->pStack);
new = ficlRealloc(old, size);
if (new)
{
PUSHPTR(new);
PUSHINT(0);
}
else
{
PUSHPTR(old);
PUSHINT(1);
}
}
/**************************************************************************
** e x i t - i n n e r
** Signals execXT that an inner loop has completed
**************************************************************************/
static void ficlExitInner(FICL_VM *pVM)
{
vmThrow(pVM, VM_INNEREXIT);
}
/**************************************************************************
d n e g a t e
** DOUBLE ( d1 -- d2 )
** d2 is the negation of d1.
**************************************************************************/
static void dnegate(FICL_VM *pVM)
{
DPINT i = i64Pop(pVM->pStack);
i = m64Negate(i);
i64Push(pVM->pStack, i);
return;
}
#if 0
/**************************************************************************
**
**************************************************************************/
static void funcname(FICL_VM *pVM)
{
IGNORE(pVM);
return;
}
#endif
/**************************************************************************
f i c l W o r d C l a s s i f y
** This public function helps to classify word types for SEE
** and the deugger in tools.c. Given a pointer to a word, it returns
** a member of WOR
**************************************************************************/
WORDKIND ficlWordClassify(FICL_WORD *pFW)
{
typedef struct
{
WORDKIND kind;
FICL_CODE code;
} CODEtoKIND;
static CODEtoKIND codeMap[] =
{
{BRANCH, branchParen},
{COLON, colonParen},
{CONSTANT, constantParen},
{CREATE, createParen},
{DO, doParen},
{DOES, doDoes},
{IF, branch0},
{LITERAL, literalParen},
{LOOP, loopParen},
{OF, ofParen},
{PLOOP, plusLoopParen},
{QDO, qDoParen},
{CSTRINGLIT, cstringLit},
{STRINGLIT, stringLit},
#if FICL_WANT_USER
{USER, userParen},
#endif
{VARIABLE, variableParen},
};
#define nMAP (sizeof(codeMap) / sizeof(CODEtoKIND))
FICL_CODE code = pFW->code;
int i;
for (i=0; i < nMAP; i++)
{
if (codeMap[i].code == code)
return codeMap[i].kind;
}
return PRIMITIVE;
}
#ifdef TESTMAIN
/**************************************************************************
** r a n d o m
** FICL-specific
**************************************************************************/
static void ficlRandom(FICL_VM *pVM)
{
PUSHUNS(random());
}
/**************************************************************************
** s e e d - r a n d o m
** FICL-specific
**************************************************************************/
static void ficlSeedRandom(FICL_VM *pVM)
{
srandom(POPUNS());
}
#endif
/**************************************************************************
f i c l C o m p i l e C o r e
** Builds the primitive wordset and the environment-query namespace.
**************************************************************************/
void ficlCompileCore(FICL_SYSTEM *pSys)
{
FICL_DICT *dp = pSys->dp;
assert (dp);
/*
** CORE word set
** see softcore.c for definitions of: abs bl space spaces abort"
*/
pSys->pStore =
dictAppendWord(dp, "!", store, FW_DEFAULT);
dictAppendWord(dp, "#", numberSign, FW_DEFAULT);
dictAppendWord(dp, "#>", numberSignGreater,FW_DEFAULT);
dictAppendWord(dp, "#s", numberSignS, FW_DEFAULT);
dictAppendWord(dp, "\'", ficlTick, FW_DEFAULT);
dictAppendWord(dp, "(", commentHang, FW_IMMEDIATE);
dictAppendWord(dp, "*", mul, FW_DEFAULT);
dictAppendWord(dp, "*/", mulDiv, FW_DEFAULT);
dictAppendWord(dp, "*/mod", mulDivRem, FW_DEFAULT);
dictAppendWord(dp, "+", add, FW_DEFAULT);
dictAppendWord(dp, "+!", plusStore, FW_DEFAULT);
dictAppendWord(dp, "+loop", plusLoopCoIm, FW_COMPIMMED);
dictAppendWord(dp, ",", comma, FW_DEFAULT);
dictAppendWord(dp, "-", sub, FW_DEFAULT);
dictAppendWord(dp, ".", displayCell, FW_DEFAULT);
dictAppendWord(dp, ".\"", dotQuoteCoIm, FW_COMPIMMED);
dictAppendWord(dp, "/", ficlDiv, FW_DEFAULT);
dictAppendWord(dp, "/mod", slashMod, FW_DEFAULT);
dictAppendWord(dp, "0<", zeroLess, FW_DEFAULT);
dictAppendWord(dp, "0=", zeroEquals, FW_DEFAULT);
dictAppendWord(dp, "1+", onePlus, FW_DEFAULT);
dictAppendWord(dp, "1-", oneMinus, FW_DEFAULT);
dictAppendWord(dp, "2!", twoStore, FW_DEFAULT);
dictAppendWord(dp, "2*", twoMul, FW_DEFAULT);
dictAppendWord(dp, "2/", twoDiv, FW_DEFAULT);
dictAppendWord(dp, "2@", twoFetch, FW_DEFAULT);
dictAppendWord(dp, "2drop", twoDrop, FW_DEFAULT);
dictAppendWord(dp, "2dup", twoDup, FW_DEFAULT);
dictAppendWord(dp, "2over", twoOver, FW_DEFAULT);
dictAppendWord(dp, "2swap", twoSwap, FW_DEFAULT);
dictAppendWord(dp, ":", colon, FW_DEFAULT);
dictAppendWord(dp, ";", semicolonCoIm, FW_COMPIMMED);
dictAppendWord(dp, "<", isLess, FW_DEFAULT);
dictAppendWord(dp, "<#", lessNumberSign, FW_DEFAULT);
dictAppendWord(dp, "=", isEqual, FW_DEFAULT);
dictAppendWord(dp, ">", isGreater, FW_DEFAULT);
dictAppendWord(dp, ">body", toBody, FW_DEFAULT);
dictAppendWord(dp, ">in", toIn, FW_DEFAULT);
dictAppendWord(dp, ">number", toNumber, FW_DEFAULT);
dictAppendWord(dp, ">r", toRStack, FW_COMPILE);
dictAppendWord(dp, "?dup", questionDup, FW_DEFAULT);
dictAppendWord(dp, "@", fetch, FW_DEFAULT);
dictAppendWord(dp, "abort", ficlAbort, FW_DEFAULT);
dictAppendWord(dp, "accept", accept, FW_DEFAULT);
dictAppendWord(dp, "align", align, FW_DEFAULT);
dictAppendWord(dp, "aligned", aligned, FW_DEFAULT);
dictAppendWord(dp, "allot", allot, FW_DEFAULT);
dictAppendWord(dp, "and", bitwiseAnd, FW_DEFAULT);
dictAppendWord(dp, "base", base, FW_DEFAULT);
dictAppendWord(dp, "begin", beginCoIm, FW_COMPIMMED);
dictAppendWord(dp, "c!", cStore, FW_DEFAULT);
dictAppendWord(dp, "c,", cComma, FW_DEFAULT);
dictAppendWord(dp, "c@", cFetch, FW_DEFAULT);
dictAppendWord(dp, "case", caseCoIm, FW_COMPIMMED);
dictAppendWord(dp, "cell+", cellPlus, FW_DEFAULT);
dictAppendWord(dp, "cells", cells, FW_DEFAULT);
dictAppendWord(dp, "char", ficlChar, FW_DEFAULT);
dictAppendWord(dp, "char+", charPlus, FW_DEFAULT);
dictAppendWord(dp, "chars", ficlChars, FW_DEFAULT);
dictAppendWord(dp, "constant", constant, FW_DEFAULT);
dictAppendWord(dp, "count", count, FW_DEFAULT);
dictAppendWord(dp, "cr", cr, FW_DEFAULT);
dictAppendWord(dp, "create", create, FW_DEFAULT);
dictAppendWord(dp, "decimal", decimal, FW_DEFAULT);
dictAppendWord(dp, "depth", depth, FW_DEFAULT);
dictAppendWord(dp, "do", doCoIm, FW_COMPIMMED);
dictAppendWord(dp, "does>", doesCoIm, FW_COMPIMMED);
pSys->pDrop =
dictAppendWord(dp, "drop", drop, FW_DEFAULT);
dictAppendWord(dp, "dup", dup, FW_DEFAULT);
dictAppendWord(dp, "else", elseCoIm, FW_COMPIMMED);
dictAppendWord(dp, "emit", emit, FW_DEFAULT);
dictAppendWord(dp, "endcase", endcaseCoIm, FW_COMPIMMED);
dictAppendWord(dp, "endof", endofCoIm, FW_COMPIMMED);
dictAppendWord(dp, "environment?", environmentQ,FW_DEFAULT);
dictAppendWord(dp, "evaluate", evaluate, FW_DEFAULT);
dictAppendWord(dp, "execute", execute, FW_DEFAULT);
dictAppendWord(dp, "exit", exitCoIm, FW_COMPIMMED);
dictAppendWord(dp, "fallthrough",fallthroughCoIm,FW_COMPIMMED);
dictAppendWord(dp, "fill", fill, FW_DEFAULT);
dictAppendWord(dp, "find", cFind, FW_DEFAULT);
dictAppendWord(dp, "fm/mod", fmSlashMod, FW_DEFAULT);
dictAppendWord(dp, "here", here, FW_DEFAULT);
dictAppendWord(dp, "hold", hold, FW_DEFAULT);
dictAppendWord(dp, "i", loopICo, FW_COMPILE);
dictAppendWord(dp, "if", ifCoIm, FW_COMPIMMED);
dictAppendWord(dp, "immediate", immediate, FW_DEFAULT);
dictAppendWord(dp, "invert", bitwiseNot, FW_DEFAULT);
dictAppendWord(dp, "j", loopJCo, FW_COMPILE);
dictAppendWord(dp, "k", loopKCo, FW_COMPILE);
dictAppendWord(dp, "leave", leaveCo, FW_COMPILE);
dictAppendWord(dp, "literal", literalIm, FW_IMMEDIATE);
dictAppendWord(dp, "loop", loopCoIm, FW_COMPIMMED);
dictAppendWord(dp, "lshift", lshift, FW_DEFAULT);
dictAppendWord(dp, "m*", mStar, FW_DEFAULT);
dictAppendWord(dp, "max", ficlMax, FW_DEFAULT);
dictAppendWord(dp, "min", ficlMin, FW_DEFAULT);
dictAppendWord(dp, "mod", ficlMod, FW_DEFAULT);
dictAppendWord(dp, "move", move, FW_DEFAULT);
dictAppendWord(dp, "negate", negate, FW_DEFAULT);
dictAppendWord(dp, "of", ofCoIm, FW_COMPIMMED);
dictAppendWord(dp, "or", bitwiseOr, FW_DEFAULT);
dictAppendWord(dp, "over", over, FW_DEFAULT);
dictAppendWord(dp, "postpone", postponeCoIm, FW_COMPIMMED);
dictAppendWord(dp, "quit", quit, FW_DEFAULT);
dictAppendWord(dp, "r>", fromRStack, FW_COMPILE);
dictAppendWord(dp, "r@", fetchRStack, FW_COMPILE);
dictAppendWord(dp, "recurse", recurseCoIm, FW_COMPIMMED);
dictAppendWord(dp, "repeat", repeatCoIm, FW_COMPIMMED);
dictAppendWord(dp, "rot", rot, FW_DEFAULT);
dictAppendWord(dp, "rshift", rshift, FW_DEFAULT);
dictAppendWord(dp, "s\"", stringQuoteIm, FW_IMMEDIATE);
dictAppendWord(dp, "s>d", sToD, FW_DEFAULT);
dictAppendWord(dp, "sign", sign, FW_DEFAULT);
dictAppendWord(dp, "sm/rem", smSlashRem, FW_DEFAULT);
dictAppendWord(dp, "source", source, FW_DEFAULT);
dictAppendWord(dp, "state", state, FW_DEFAULT);
dictAppendWord(dp, "swap", swap, FW_DEFAULT);
dictAppendWord(dp, "then", endifCoIm, FW_COMPIMMED);
dictAppendWord(dp, "type", type, FW_DEFAULT);
dictAppendWord(dp, "u.", uDot, FW_DEFAULT);
dictAppendWord(dp, "u<", uIsLess, FW_DEFAULT);
dictAppendWord(dp, "u>", uIsGreater, FW_DEFAULT);
dictAppendWord(dp, "um*", umStar, FW_DEFAULT);
dictAppendWord(dp, "um/mod", umSlashMod, FW_DEFAULT);
dictAppendWord(dp, "unloop", unloopCo, FW_COMPILE);
dictAppendWord(dp, "until", untilCoIm, FW_COMPIMMED);
dictAppendWord(dp, "variable", variable, FW_DEFAULT);
dictAppendWord(dp, "while", whileCoIm, FW_COMPIMMED);
dictAppendWord(dp, "word", ficlWord, FW_DEFAULT);
dictAppendWord(dp, "xor", bitwiseXor, FW_DEFAULT);
dictAppendWord(dp, "[", lbracketCoIm, FW_COMPIMMED);
dictAppendWord(dp, "[\']", bracketTickCoIm,FW_COMPIMMED);
dictAppendWord(dp, "[char]", charCoIm, FW_COMPIMMED);
dictAppendWord(dp, "]", rbracket, FW_DEFAULT);
/*
** CORE EXT word set...
** see softcore.fr for other definitions
*/
/* "#tib" */
dictAppendWord(dp, ".(", dotParen, FW_IMMEDIATE);
/* ".r" */
dictAppendWord(dp, "0>", zeroGreater, FW_DEFAULT);
dictAppendWord(dp, "2>r", twoToR, FW_COMPILE);
dictAppendWord(dp, "2r>", twoRFrom, FW_COMPILE);
dictAppendWord(dp, "2r@", twoRFetch, FW_COMPILE);
dictAppendWord(dp, ":noname", colonNoName, FW_DEFAULT);
dictAppendWord(dp, "?do", qDoCoIm, FW_COMPIMMED);
dictAppendWord(dp, "again", againCoIm, FW_COMPIMMED);
dictAppendWord(dp, "c\"", cstringQuoteIm, FW_IMMEDIATE);
dictAppendWord(dp, "hex", hex, FW_DEFAULT);
dictAppendWord(dp, "pad", pad, FW_DEFAULT);
dictAppendWord(dp, "parse", parse, FW_DEFAULT);
dictAppendWord(dp, "pick", pick, FW_DEFAULT);
/* query restore-input save-input tib u.r u> unused [compile] */
dictAppendWord(dp, "roll", roll, FW_DEFAULT);
dictAppendWord(dp, "refill", refill, FW_DEFAULT);
dictAppendWord(dp, "source-id", sourceid, FW_DEFAULT);
dictAppendWord(dp, "to", toValue, FW_IMMEDIATE);
dictAppendWord(dp, "value", constant, FW_DEFAULT);
dictAppendWord(dp, "\\", commentLine, FW_IMMEDIATE);
/*
** Set CORE environment query values
*/
ficlSetEnv(pSys, "/counted-string", FICL_STRING_MAX);
ficlSetEnv(pSys, "/hold", nPAD);
ficlSetEnv(pSys, "/pad", nPAD);
ficlSetEnv(pSys, "address-unit-bits", 8);
ficlSetEnv(pSys, "core", FICL_TRUE);
ficlSetEnv(pSys, "core-ext", FICL_FALSE);
ficlSetEnv(pSys, "floored", FICL_FALSE);
ficlSetEnv(pSys, "max-char", UCHAR_MAX);
ficlSetEnvD(pSys,"max-d", 0x7fffffff, 0xffffffff);
ficlSetEnv(pSys, "max-n", 0x7fffffff);
ficlSetEnv(pSys, "max-u", 0xffffffff);
ficlSetEnvD(pSys,"max-ud", 0xffffffff, 0xffffffff);
ficlSetEnv(pSys, "return-stack-cells",FICL_DEFAULT_STACK);
ficlSetEnv(pSys, "stack-cells", FICL_DEFAULT_STACK);
/*
** DOUBLE word set (partial)
*/
dictAppendWord(dp, "2constant", twoConstant, FW_IMMEDIATE);
dictAppendWord(dp, "2literal", twoLiteralIm, FW_IMMEDIATE);
dictAppendWord(dp, "2variable", twoVariable, FW_IMMEDIATE);
dictAppendWord(dp, "dnegate", dnegate, FW_DEFAULT);
/*
** EXCEPTION word set
*/
dictAppendWord(dp, "catch", ficlCatch, FW_DEFAULT);
dictAppendWord(dp, "throw", ficlThrow, FW_DEFAULT);
ficlSetEnv(pSys, "exception", FICL_TRUE);
ficlSetEnv(pSys, "exception-ext", FICL_TRUE);
/*
** LOCAL and LOCAL EXT
** see softcore.c for implementation of locals|
*/
#if FICL_WANT_LOCALS
pSys->pLinkParen =
dictAppendWord(dp, "(link)", linkParen, FW_COMPILE);
pSys->pUnLinkParen =
dictAppendWord(dp, "(unlink)", unlinkParen, FW_COMPILE);
dictAppendWord(dp, "doLocal", doLocalIm, FW_COMPIMMED);
pSys->pGetLocalParen =
dictAppendWord(dp, "(@local)", getLocalParen, FW_COMPILE);
pSys->pToLocalParen =
dictAppendWord(dp, "(toLocal)", toLocalParen, FW_COMPILE);
pSys->pGetLocal0 =
dictAppendWord(dp, "(@local0)", getLocal0, FW_COMPILE);
pSys->pToLocal0 =
dictAppendWord(dp, "(toLocal0)",toLocal0, FW_COMPILE);
pSys->pGetLocal1 =
dictAppendWord(dp, "(@local1)", getLocal1, FW_COMPILE);
pSys->pToLocal1 =
dictAppendWord(dp, "(toLocal1)",toLocal1, FW_COMPILE);
dictAppendWord(dp, "(local)", localParen, FW_COMPILE);
pSys->pGet2LocalParen =
dictAppendWord(dp, "(@2local)", get2LocalParen, FW_COMPILE);
pSys->pTo2LocalParen =
dictAppendWord(dp, "(to2Local)",to2LocalParen, FW_COMPILE);
dictAppendWord(dp, "(2local)", twoLocalParen, FW_COMPILE);
ficlSetEnv(pSys, "locals", FICL_TRUE);
ficlSetEnv(pSys, "locals-ext", FICL_TRUE);
ficlSetEnv(pSys, "#locals", FICL_MAX_LOCALS);
#endif
/*
** Optional MEMORY-ALLOC word set
*/
dictAppendWord(dp, "allocate", ansAllocate, FW_DEFAULT);
dictAppendWord(dp, "free", ansFree, FW_DEFAULT);
dictAppendWord(dp, "resize", ansResize, FW_DEFAULT);
ficlSetEnv(pSys, "memory-alloc", FICL_TRUE);
/*
** optional SEARCH-ORDER word set
*/
ficlCompileSearch(pSys);
/*
** TOOLS and TOOLS EXT
*/
ficlCompileTools(pSys);
/*
** FILE and FILE EXT
*/
#if FICL_WANT_FILE
ficlCompileFile(pSys);
#endif
/*
** Ficl extras
*/
#if FICL_WANT_FLOAT
dictAppendWord(dp, ".hash", dictHashSummary,FW_DEFAULT);
#endif
dictAppendWord(dp, ".ver", ficlVersion, FW_DEFAULT);
dictAppendWord(dp, "-roll", minusRoll, FW_DEFAULT);
dictAppendWord(dp, ">name", toName, FW_DEFAULT);
dictAppendWord(dp, "add-parse-step",
addParseStep, FW_DEFAULT);
dictAppendWord(dp, "body>", fromBody, FW_DEFAULT);
dictAppendWord(dp, "compare", compareString, FW_DEFAULT); /* STRING */
dictAppendWord(dp, "compare-insensitive", compareStringInsensitive, FW_DEFAULT); /* STRING */
dictAppendWord(dp, "compile-only",
compileOnly, FW_DEFAULT);
dictAppendWord(dp, "endif", endifCoIm, FW_COMPIMMED);
dictAppendWord(dp, "last-word", getLastWord, FW_DEFAULT);
dictAppendWord(dp, "hash", hash, FW_DEFAULT);
dictAppendWord(dp, "objectify", setObjectFlag, FW_DEFAULT);
dictAppendWord(dp, "?object", isObject, FW_DEFAULT);
dictAppendWord(dp, "parse-word",parseNoCopy, FW_DEFAULT);
dictAppendWord(dp, "sfind", sFind, FW_DEFAULT);
dictAppendWord(dp, "sliteral", sLiteralCoIm, FW_COMPIMMED); /* STRING */
dictAppendWord(dp, "sprintf", ficlSprintf, FW_DEFAULT);
dictAppendWord(dp, "strlen", ficlStrlen, FW_DEFAULT);
dictAppendWord(dp, "q@", quadFetch, FW_DEFAULT);
dictAppendWord(dp, "q!", quadStore, FW_DEFAULT);
dictAppendWord(dp, "w@", wFetch, FW_DEFAULT);
dictAppendWord(dp, "w!", wStore, FW_DEFAULT);
dictAppendWord(dp, "x.", hexDot, FW_DEFAULT);
#if FICL_WANT_USER
dictAppendWord(dp, "(user)", userParen, FW_DEFAULT);
dictAppendWord(dp, "user", userVariable, FW_DEFAULT);
#endif
#ifdef TESTMAIN
dictAppendWord(dp, "random", ficlRandom, FW_DEFAULT);
dictAppendWord(dp, "seed-random",ficlSeedRandom,FW_DEFAULT);
#endif
/*
** internal support words
*/
dictAppendWord(dp, "(create)", createParen, FW_COMPILE);
pSys->pExitParen =
dictAppendWord(dp, "(exit)", exitParen, FW_COMPILE);
pSys->pSemiParen =
dictAppendWord(dp, "(;)", semiParen, FW_COMPILE);
pSys->pLitParen =
dictAppendWord(dp, "(literal)", literalParen, FW_COMPILE);
pSys->pTwoLitParen =
dictAppendWord(dp, "(2literal)",twoLitParen, FW_COMPILE);
pSys->pStringLit =
dictAppendWord(dp, "(.\")", stringLit, FW_COMPILE);
pSys->pCStringLit =
dictAppendWord(dp, "(c\")", cstringLit, FW_COMPILE);
pSys->pBranch0 =
dictAppendWord(dp, "(branch0)", branch0, FW_COMPILE);
pSys->pBranchParen =
dictAppendWord(dp, "(branch)", branchParen, FW_COMPILE);
pSys->pDoParen =
dictAppendWord(dp, "(do)", doParen, FW_COMPILE);
pSys->pDoesParen =
dictAppendWord(dp, "(does>)", doesParen, FW_COMPILE);
pSys->pQDoParen =
dictAppendWord(dp, "(?do)", qDoParen, FW_COMPILE);
pSys->pLoopParen =
dictAppendWord(dp, "(loop)", loopParen, FW_COMPILE);
pSys->pPLoopParen =
dictAppendWord(dp, "(+loop)", plusLoopParen, FW_COMPILE);
pSys->pInterpret =
dictAppendWord(dp, "interpret", interpret, FW_DEFAULT);
dictAppendWord(dp, "lookup", lookup, FW_DEFAULT);
pSys->pOfParen =
dictAppendWord(dp, "(of)", ofParen, FW_DEFAULT);
dictAppendWord(dp, "(variable)",variableParen, FW_COMPILE);
dictAppendWord(dp, "(constant)",constantParen, FW_COMPILE);
dictAppendWord(dp, "(parse-step)",
parseStepParen, FW_DEFAULT);
pSys->pExitInner =
dictAppendWord(dp, "exit-inner",ficlExitInner, FW_DEFAULT);
/*
** Set up system's outer interpreter loop - maybe this should be in initSystem?
*/
pSys->pInterp[0] = pSys->pInterpret;
pSys->pInterp[1] = pSys->pBranchParen;
pSys->pInterp[2] = (FICL_WORD *)(void *)(-2);
assert(dictCellsAvail(dp) > 0);
return;
}
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