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/******************************************************************* ** f l o a t . c ** Forth Inspired Command Language ** ANS Forth FLOAT word-set written in C ** Author: Guy Carver & John Sadler (john_sadler@alum.mit.edu) ** Created: Apr 2001 ** $Id: float.c,v 1.8 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: release/9.1.0/sys/boot/ficl/float.c 167850 2007-03-23 22:26:01Z jkim $ */ #include <stdlib.h> #include <stdio.h> #include <string.h> #include <ctype.h> #include <math.h> #include "ficl.h" #if FICL_WANT_FLOAT /******************************************************************* ** Do float addition r1 + r2. ** f+ ( r1 r2 -- r ) *******************************************************************/ static void Fadd(FICL_VM *pVM) { FICL_FLOAT f; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 2, 1); #endif f = POPFLOAT(); f += GETTOPF().f; SETTOPF(f); } /******************************************************************* ** Do float subtraction r1 - r2. ** f- ( r1 r2 -- r ) *******************************************************************/ static void Fsub(FICL_VM *pVM) { FICL_FLOAT f; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 2, 1); #endif f = POPFLOAT(); f = GETTOPF().f - f; SETTOPF(f); } /******************************************************************* ** Do float multiplication r1 * r2. ** f* ( r1 r2 -- r ) *******************************************************************/ static void Fmul(FICL_VM *pVM) { FICL_FLOAT f; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 2, 1); #endif f = POPFLOAT(); f *= GETTOPF().f; SETTOPF(f); } /******************************************************************* ** Do float negation. ** fnegate ( r -- r ) *******************************************************************/ static void Fnegate(FICL_VM *pVM) { FICL_FLOAT f; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 1, 1); #endif f = -GETTOPF().f; SETTOPF(f); } /******************************************************************* ** Do float division r1 / r2. ** f/ ( r1 r2 -- r ) *******************************************************************/ static void Fdiv(FICL_VM *pVM) { FICL_FLOAT f; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 2, 1); #endif f = POPFLOAT(); f = GETTOPF().f / f; SETTOPF(f); } /******************************************************************* ** Do float + integer r + n. ** f+i ( r n -- r ) *******************************************************************/ static void Faddi(FICL_VM *pVM) { FICL_FLOAT f; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 1, 1); vmCheckStack(pVM, 1, 0); #endif f = (FICL_FLOAT)POPINT(); f += GETTOPF().f; SETTOPF(f); } /******************************************************************* ** Do float - integer r - n. ** f-i ( r n -- r ) *******************************************************************/ static void Fsubi(FICL_VM *pVM) { FICL_FLOAT f; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 1, 1); vmCheckStack(pVM, 1, 0); #endif f = GETTOPF().f; f -= (FICL_FLOAT)POPINT(); SETTOPF(f); } /******************************************************************* ** Do float * integer r * n. ** f*i ( r n -- r ) *******************************************************************/ static void Fmuli(FICL_VM *pVM) { FICL_FLOAT f; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 1, 1); vmCheckStack(pVM, 1, 0); #endif f = (FICL_FLOAT)POPINT(); f *= GETTOPF().f; SETTOPF(f); } /******************************************************************* ** Do float / integer r / n. ** f/i ( r n -- r ) *******************************************************************/ static void Fdivi(FICL_VM *pVM) { FICL_FLOAT f; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 1, 1); vmCheckStack(pVM, 1, 0); #endif f = GETTOPF().f; f /= (FICL_FLOAT)POPINT(); SETTOPF(f); } /******************************************************************* ** Do integer - float n - r. ** i-f ( n r -- r ) *******************************************************************/ static void isubf(FICL_VM *pVM) { FICL_FLOAT f; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 1, 1); vmCheckStack(pVM, 1, 0); #endif f = (FICL_FLOAT)POPINT(); f -= GETTOPF().f; SETTOPF(f); } /******************************************************************* ** Do integer / float n / r. ** i/f ( n r -- r ) *******************************************************************/ static void idivf(FICL_VM *pVM) { FICL_FLOAT f; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 1,1); vmCheckStack(pVM, 1, 0); #endif f = (FICL_FLOAT)POPINT(); f /= GETTOPF().f; SETTOPF(f); } /******************************************************************* ** Do integer to float conversion. ** int>float ( n -- r ) *******************************************************************/ static void itof(FICL_VM *pVM) { float f; #if FICL_ROBUST > 1 vmCheckStack(pVM, 1, 0); vmCheckFStack(pVM, 0, 1); #endif f = (float)POPINT(); PUSHFLOAT(f); } /******************************************************************* ** Do float to integer conversion. ** float>int ( r -- n ) *******************************************************************/ static void Ftoi(FICL_VM *pVM) { FICL_INT i; #if FICL_ROBUST > 1 vmCheckStack(pVM, 0, 1); vmCheckFStack(pVM, 1, 0); #endif i = (FICL_INT)POPFLOAT(); PUSHINT(i); } /******************************************************************* ** Floating point constant execution word. *******************************************************************/ void FconstantParen(FICL_VM *pVM) { FICL_WORD *pFW = pVM->runningWord; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 0, 1); #endif PUSHFLOAT(pFW->param[0].f); } /******************************************************************* ** Create a floating point constant. ** fconstant ( r -"name"- ) *******************************************************************/ static void Fconstant(FICL_VM *pVM) { FICL_DICT *dp = vmGetDict(pVM); STRINGINFO si = vmGetWord(pVM); #if FICL_ROBUST > 1 vmCheckFStack(pVM, 1, 0); #endif dictAppendWord2(dp, si, FconstantParen, FW_DEFAULT); dictAppendCell(dp, stackPop(pVM->fStack)); } /******************************************************************* ** Display a float in decimal format. ** f. ( r -- ) *******************************************************************/ static void FDot(FICL_VM *pVM) { float f; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 1, 0); #endif f = POPFLOAT(); sprintf(pVM->pad,"%#f ",f); vmTextOut(pVM, pVM->pad, 0); } /******************************************************************* ** Display a float in engineering format. ** fe. ( r -- ) *******************************************************************/ static void EDot(FICL_VM *pVM) { float f; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 1, 0); #endif f = POPFLOAT(); sprintf(pVM->pad,"%#e ",f); vmTextOut(pVM, pVM->pad, 0); } /************************************************************************** d i s p l a y FS t a c k ** Display the parameter stack (code for "f.s") ** f.s ( -- ) **************************************************************************/ static void displayFStack(FICL_VM *pVM) { int d = stackDepth(pVM->fStack); int i; CELL *pCell; vmCheckFStack(pVM, 0, 0); vmTextOut(pVM, "F:", 0); if (d == 0) vmTextOut(pVM, "[0]", 0); else { ltoa(d, &pVM->pad[1], pVM->base); pVM->pad[0] = '['; strcat(pVM->pad,"] "); vmTextOut(pVM,pVM->pad,0); pCell = pVM->fStack->sp - d; for (i = 0; i < d; i++) { sprintf(pVM->pad,"%#f ",(*pCell++).f); vmTextOut(pVM,pVM->pad,0); } } } /******************************************************************* ** Do float stack depth. ** fdepth ( -- n ) *******************************************************************/ static void Fdepth(FICL_VM *pVM) { int i; #if FICL_ROBUST > 1 vmCheckStack(pVM, 0, 1); #endif i = stackDepth(pVM->fStack); PUSHINT(i); } /******************************************************************* ** Do float stack drop. ** fdrop ( r -- ) *******************************************************************/ static void Fdrop(FICL_VM *pVM) { #if FICL_ROBUST > 1 vmCheckFStack(pVM, 1, 0); #endif DROPF(1); } /******************************************************************* ** Do float stack 2drop. ** f2drop ( r r -- ) *******************************************************************/ static void FtwoDrop(FICL_VM *pVM) { #if FICL_ROBUST > 1 vmCheckFStack(pVM, 2, 0); #endif DROPF(2); } /******************************************************************* ** Do float stack dup. ** fdup ( r -- r r ) *******************************************************************/ static void Fdup(FICL_VM *pVM) { #if FICL_ROBUST > 1 vmCheckFStack(pVM, 1, 2); #endif PICKF(0); } /******************************************************************* ** Do float stack 2dup. ** f2dup ( r1 r2 -- r1 r2 r1 r2 ) *******************************************************************/ static void FtwoDup(FICL_VM *pVM) { #if FICL_ROBUST > 1 vmCheckFStack(pVM, 2, 4); #endif PICKF(1); PICKF(1); } /******************************************************************* ** Do float stack over. ** fover ( r1 r2 -- r1 r2 r1 ) *******************************************************************/ static void Fover(FICL_VM *pVM) { #if FICL_ROBUST > 1 vmCheckFStack(pVM, 2, 3); #endif PICKF(1); } /******************************************************************* ** Do float stack 2over. ** f2over ( r1 r2 r3 -- r1 r2 r3 r1 r2 ) *******************************************************************/ static void FtwoOver(FICL_VM *pVM) { #if FICL_ROBUST > 1 vmCheckFStack(pVM, 4, 6); #endif PICKF(3); PICKF(3); } /******************************************************************* ** Do float stack pick. ** fpick ( n -- r ) *******************************************************************/ static void Fpick(FICL_VM *pVM) { CELL c = POP(); #if FICL_ROBUST > 1 vmCheckFStack(pVM, c.i+1, c.i+2); #endif PICKF(c.i); } /******************************************************************* ** Do float stack ?dup. ** f?dup ( r -- r ) *******************************************************************/ static void FquestionDup(FICL_VM *pVM) { CELL c; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 1, 2); #endif c = GETTOPF(); if (c.f != 0) PICKF(0); } /******************************************************************* ** Do float stack roll. ** froll ( n -- ) *******************************************************************/ static void Froll(FICL_VM *pVM) { int i = POP().i; i = (i > 0) ? i : 0; #if FICL_ROBUST > 1 vmCheckFStack(pVM, i+1, i+1); #endif ROLLF(i); } /******************************************************************* ** Do float stack -roll. ** f-roll ( n -- ) *******************************************************************/ static void FminusRoll(FICL_VM *pVM) { int i = POP().i; i = (i > 0) ? i : 0; #if FICL_ROBUST > 1 vmCheckFStack(pVM, i+1, i+1); #endif ROLLF(-i); } /******************************************************************* ** Do float stack rot. ** frot ( r1 r2 r3 -- r2 r3 r1 ) *******************************************************************/ static void Frot(FICL_VM *pVM) { #if FICL_ROBUST > 1 vmCheckFStack(pVM, 3, 3); #endif ROLLF(2); } /******************************************************************* ** Do float stack -rot. ** f-rot ( r1 r2 r3 -- r3 r1 r2 ) *******************************************************************/ static void Fminusrot(FICL_VM *pVM) { #if FICL_ROBUST > 1 vmCheckFStack(pVM, 3, 3); #endif ROLLF(-2); } /******************************************************************* ** Do float stack swap. ** fswap ( r1 r2 -- r2 r1 ) *******************************************************************/ static void Fswap(FICL_VM *pVM) { #if FICL_ROBUST > 1 vmCheckFStack(pVM, 2, 2); #endif ROLLF(1); } /******************************************************************* ** Do float stack 2swap ** f2swap ( r1 r2 r3 r4 -- r3 r4 r1 r2 ) *******************************************************************/ static void FtwoSwap(FICL_VM *pVM) { #if FICL_ROBUST > 1 vmCheckFStack(pVM, 4, 4); #endif ROLLF(3); ROLLF(3); } /******************************************************************* ** Get a floating point number from a variable. ** f@ ( n -- r ) *******************************************************************/ static void Ffetch(FICL_VM *pVM) { CELL *pCell; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 0, 1); vmCheckStack(pVM, 1, 0); #endif pCell = (CELL *)POPPTR(); PUSHFLOAT(pCell->f); } /******************************************************************* ** Store a floating point number into a variable. ** f! ( r n -- ) *******************************************************************/ static void Fstore(FICL_VM *pVM) { CELL *pCell; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 1, 0); vmCheckStack(pVM, 1, 0); #endif pCell = (CELL *)POPPTR(); pCell->f = POPFLOAT(); } /******************************************************************* ** Add a floating point number to contents of a variable. ** f+! ( r n -- ) *******************************************************************/ static void FplusStore(FICL_VM *pVM) { CELL *pCell; #if FICL_ROBUST > 1 vmCheckStack(pVM, 1, 0); vmCheckFStack(pVM, 1, 0); #endif pCell = (CELL *)POPPTR(); pCell->f += POPFLOAT(); } /******************************************************************* ** Floating point literal execution word. *******************************************************************/ static void fliteralParen(FICL_VM *pVM) { #if FICL_ROBUST > 1 vmCheckStack(pVM, 0, 1); #endif PUSHFLOAT(*(float*)(pVM->ip)); vmBranchRelative(pVM, 1); } /******************************************************************* ** Compile a floating point literal. *******************************************************************/ static void fliteralIm(FICL_VM *pVM) { FICL_DICT *dp = vmGetDict(pVM); FICL_WORD *pfLitParen = ficlLookup(pVM->pSys, "(fliteral)"); #if FICL_ROBUST > 1 vmCheckFStack(pVM, 1, 0); #endif dictAppendCell(dp, LVALUEtoCELL(pfLitParen)); dictAppendCell(dp, stackPop(pVM->fStack)); } /******************************************************************* ** Do float 0= comparison r = 0.0. ** f0= ( r -- T/F ) *******************************************************************/ static void FzeroEquals(FICL_VM *pVM) { CELL c; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 1, 0); /* Make sure something on float stack. */ vmCheckStack(pVM, 0, 1); /* Make sure room for result. */ #endif c.i = FICL_BOOL(POPFLOAT() == 0); PUSH(c); } /******************************************************************* ** Do float 0< comparison r < 0.0. ** f0< ( r -- T/F ) *******************************************************************/ static void FzeroLess(FICL_VM *pVM) { CELL c; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 1, 0); /* Make sure something on float stack. */ vmCheckStack(pVM, 0, 1); /* Make sure room for result. */ #endif c.i = FICL_BOOL(POPFLOAT() < 0); PUSH(c); } /******************************************************************* ** Do float 0> comparison r > 0.0. ** f0> ( r -- T/F ) *******************************************************************/ static void FzeroGreater(FICL_VM *pVM) { CELL c; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 1, 0); vmCheckStack(pVM, 0, 1); #endif c.i = FICL_BOOL(POPFLOAT() > 0); PUSH(c); } /******************************************************************* ** Do float = comparison r1 = r2. ** f= ( r1 r2 -- T/F ) *******************************************************************/ static void FisEqual(FICL_VM *pVM) { float x, y; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 2, 0); vmCheckStack(pVM, 0, 1); #endif x = POPFLOAT(); y = POPFLOAT(); PUSHINT(FICL_BOOL(x == y)); } /******************************************************************* ** Do float < comparison r1 < r2. ** f< ( r1 r2 -- T/F ) *******************************************************************/ static void FisLess(FICL_VM *pVM) { float x, y; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 2, 0); vmCheckStack(pVM, 0, 1); #endif y = POPFLOAT(); x = POPFLOAT(); PUSHINT(FICL_BOOL(x < y)); } /******************************************************************* ** Do float > comparison r1 > r2. ** f> ( r1 r2 -- T/F ) *******************************************************************/ static void FisGreater(FICL_VM *pVM) { float x, y; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 2, 0); vmCheckStack(pVM, 0, 1); #endif y = POPFLOAT(); x = POPFLOAT(); PUSHINT(FICL_BOOL(x > y)); } /******************************************************************* ** Move float to param stack (assumes they both fit in a single CELL) ** f>s *******************************************************************/ static void FFrom(FICL_VM *pVM) { CELL c; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 1, 0); vmCheckStack(pVM, 0, 1); #endif c = stackPop(pVM->fStack); stackPush(pVM->pStack, c); return; } static void ToF(FICL_VM *pVM) { CELL c; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 0, 1); vmCheckStack(pVM, 1, 0); #endif c = stackPop(pVM->pStack); stackPush(pVM->fStack, c); return; } /************************************************************************** F l o a t P a r s e S t a t e ** Enum to determine the current segement of a floating point number ** being parsed. **************************************************************************/ #define NUMISNEG 1 #define EXPISNEG 2 typedef enum _floatParseState { FPS_START, FPS_ININT, FPS_INMANT, FPS_STARTEXP, FPS_INEXP } FloatParseState; /************************************************************************** f i c l P a r s e F l o a t N u m b e r ** pVM -- Virtual Machine pointer. ** si -- String to parse. ** Returns 1 if successful, 0 if not. **************************************************************************/ int ficlParseFloatNumber( FICL_VM *pVM, STRINGINFO si ) { unsigned char ch, digit; char *cp; FICL_COUNT count; float power; float accum = 0.0f; float mant = 0.1f; FICL_INT exponent = 0; char flag = 0; FloatParseState estate = FPS_START; #if FICL_ROBUST > 1 vmCheckFStack(pVM, 0, 1); #endif /* ** floating point numbers only allowed in base 10 */ if (pVM->base != 10) return(0); cp = SI_PTR(si); count = (FICL_COUNT)SI_COUNT(si); /* Loop through the string's characters. */ while ((count--) && ((ch = *cp++) != 0)) { switch (estate) { /* At start of the number so look for a sign. */ case FPS_START: { estate = FPS_ININT; if (ch == '-') { flag |= NUMISNEG; break; } if (ch == '+') { break; } } /* Note! Drop through to FPS_ININT */ /* **Converting integer part of number. ** Only allow digits, decimal and 'E'. */ case FPS_ININT: { if (ch == '.') { estate = FPS_INMANT; } else if ((ch == 'e') || (ch == 'E')) { estate = FPS_STARTEXP; } else { digit = (unsigned char)(ch - '0'); if (digit > 9) return(0); accum = accum * 10 + digit; } break; } /* ** Processing the fraction part of number. ** Only allow digits and 'E' */ case FPS_INMANT: { if ((ch == 'e') || (ch == 'E')) { estate = FPS_STARTEXP; } else { digit = (unsigned char)(ch - '0'); if (digit > 9) return(0); accum += digit * mant; mant *= 0.1f; } break; } /* Start processing the exponent part of number. */ /* Look for sign. */ case FPS_STARTEXP: { estate = FPS_INEXP; if (ch == '-') { flag |= EXPISNEG; break; } else if (ch == '+') { break; } } /* Note! Drop through to FPS_INEXP */ /* ** Processing the exponent part of number. ** Only allow digits. */ case FPS_INEXP: { digit = (unsigned char)(ch - '0'); if (digit > 9) return(0); exponent = exponent * 10 + digit; break; } } } /* If parser never made it to the exponent this is not a float. */ if (estate < FPS_STARTEXP) return(0); /* Set the sign of the number. */ if (flag & NUMISNEG) accum = -accum; /* If exponent is not 0 then adjust number by it. */ if (exponent != 0) { /* Determine if exponent is negative. */ if (flag & EXPISNEG) { exponent = -exponent; } /* power = 10^x */ power = (float)pow(10.0, exponent); accum *= power; } PUSHFLOAT(accum); if (pVM->state == COMPILE) fliteralIm(pVM); return(1); } #endif /* FICL_WANT_FLOAT */ /************************************************************************** ** Add float words to a system's dictionary. ** pSys -- Pointer to the FICL sytem to add float words to. **************************************************************************/ void ficlCompileFloat(FICL_SYSTEM *pSys) { FICL_DICT *dp = pSys->dp; assert(dp); #if FICL_WANT_FLOAT dictAppendWord(dp, ">float", ToF, FW_DEFAULT); /* d>f */ dictAppendWord(dp, "f!", Fstore, FW_DEFAULT); dictAppendWord(dp, "f*", Fmul, FW_DEFAULT); dictAppendWord(dp, "f+", Fadd, FW_DEFAULT); dictAppendWord(dp, "f-", Fsub, FW_DEFAULT); dictAppendWord(dp, "f/", Fdiv, FW_DEFAULT); dictAppendWord(dp, "f0<", FzeroLess, FW_DEFAULT); dictAppendWord(dp, "f0=", FzeroEquals, FW_DEFAULT); dictAppendWord(dp, "f<", FisLess, FW_DEFAULT); /* f>d */ dictAppendWord(dp, "f@", Ffetch, FW_DEFAULT); /* falign faligned */ dictAppendWord(dp, "fconstant", Fconstant, FW_DEFAULT); dictAppendWord(dp, "fdepth", Fdepth, FW_DEFAULT); dictAppendWord(dp, "fdrop", Fdrop, FW_DEFAULT); dictAppendWord(dp, "fdup", Fdup, FW_DEFAULT); dictAppendWord(dp, "fliteral", fliteralIm, FW_IMMEDIATE); /* float+ floats floor fmax fmin */ dictAppendWord(dp, "f?dup", FquestionDup, FW_DEFAULT); dictAppendWord(dp, "f=", FisEqual, FW_DEFAULT); dictAppendWord(dp, "f>", FisGreater, FW_DEFAULT); dictAppendWord(dp, "f0>", FzeroGreater, FW_DEFAULT); dictAppendWord(dp, "f2drop", FtwoDrop, FW_DEFAULT); dictAppendWord(dp, "f2dup", FtwoDup, FW_DEFAULT); dictAppendWord(dp, "f2over", FtwoOver, FW_DEFAULT); dictAppendWord(dp, "f2swap", FtwoSwap, FW_DEFAULT); dictAppendWord(dp, "f+!", FplusStore, FW_DEFAULT); dictAppendWord(dp, "f+i", Faddi, FW_DEFAULT); dictAppendWord(dp, "f-i", Fsubi, FW_DEFAULT); dictAppendWord(dp, "f*i", Fmuli, FW_DEFAULT); dictAppendWord(dp, "f/i", Fdivi, FW_DEFAULT); dictAppendWord(dp, "int>float", itof, FW_DEFAULT); dictAppendWord(dp, "float>int", Ftoi, FW_DEFAULT); dictAppendWord(dp, "f.", FDot, FW_DEFAULT); dictAppendWord(dp, "f.s", displayFStack, FW_DEFAULT); dictAppendWord(dp, "fe.", EDot, FW_DEFAULT); dictAppendWord(dp, "fover", Fover, FW_DEFAULT); dictAppendWord(dp, "fnegate", Fnegate, FW_DEFAULT); dictAppendWord(dp, "fpick", Fpick, FW_DEFAULT); dictAppendWord(dp, "froll", Froll, FW_DEFAULT); dictAppendWord(dp, "frot", Frot, FW_DEFAULT); dictAppendWord(dp, "fswap", Fswap, FW_DEFAULT); dictAppendWord(dp, "i-f", isubf, FW_DEFAULT); dictAppendWord(dp, "i/f", idivf, FW_DEFAULT); dictAppendWord(dp, "float>", FFrom, FW_DEFAULT); dictAppendWord(dp, "f-roll", FminusRoll, FW_DEFAULT); dictAppendWord(dp, "f-rot", Fminusrot, FW_DEFAULT); dictAppendWord(dp, "(fliteral)", fliteralParen, FW_COMPILE); ficlSetEnv(pSys, "floating", FICL_FALSE); /* not all required words are present */ ficlSetEnv(pSys, "floating-ext", FICL_FALSE); ficlSetEnv(pSys, "floating-stack", FICL_DEFAULT_STACK); #endif return; }