dist/libdecnumber/decCommon.c

     1.1  mrg /* Common code for fixed-size types in the decNumber C Library.
1.1.1.12  mrg    Copyright (C) 2007-2024 Free Software Foundation, Inc.
     1.1  mrg    Contributed by IBM Corporation.  Author Mike Cowlishaw.
     1.1  mrg
     1.1  mrg    This file is part of GCC.
     1.1  mrg
     1.1  mrg    GCC is free software; you can redistribute it and/or modify it under
     1.1  mrg    the terms of the GNU General Public License as published by the Free
     1.1  mrg    Software Foundation; either version 3, or (at your option) any later
     1.1  mrg    version.
     1.1  mrg
     1.1  mrg    GCC is distributed in the hope that it will be useful, but WITHOUT ANY
     1.1  mrg    WARRANTY; without even the implied warranty of MERCHANTABILITY or
     1.1  mrg    FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
     1.1  mrg    for more details.
     1.1  mrg
     1.1  mrg Under Section 7 of GPL version 3, you are granted additional
     1.1  mrg permissions described in the GCC Runtime Library Exception, version
     1.1  mrg 3.1, as published by the Free Software Foundation.
     1.1  mrg
     1.1  mrg You should have received a copy of the GNU General Public License and
     1.1  mrg a copy of the GCC Runtime Library Exception along with this program;
     1.1  mrg see the files COPYING3 and COPYING.RUNTIME respectively.  If not, see
     1.1  mrg <http://www.gnu.org/licenses/>.  */
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* decCommon.c -- common code for all three fixed-size types	      */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* This module comprises code that is shared between all the formats  */
     1.1  mrg /* (decSingle, decDouble, and decQuad); it includes set and extract   */
     1.1  mrg /* of format components, widening, narrowing, and string conversions. */
     1.1  mrg /*								      */
     1.1  mrg /* Unlike decNumber, parameterization takes place at compile time     */
     1.1  mrg /* rather than at runtime.  The parameters are set in the decDouble.c */
     1.1  mrg /* (etc.) files, which then include this one to produce the compiled  */
     1.1  mrg /* code.  The functions here, therefore, are code shared between      */
     1.1  mrg /* multiple formats.						      */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* Names here refer to decFloat rather than to decDouble, etc., and */
     1.1  mrg /* the functions are in strict alphabetical order. */
     1.1  mrg /* Constants, tables, and debug function(s) are included only for QUAD */
     1.1  mrg /* (which will always be compiled if DOUBLE or SINGLE are used). */
     1.1  mrg /* */
     1.1  mrg /* Whenever a decContext is used, only the status may be set (using */
     1.1  mrg /* OR) or the rounding mode read; all other fields are ignored and */
     1.1  mrg /* untouched. */
     1.1  mrg
     1.1  mrg #include "decCommonSymbols.h"
     1.1  mrg
     1.1  mrg /* names for simpler testing and default context */
     1.1  mrg #if DECPMAX==7
     1.1  mrg   #define SINGLE     1
     1.1  mrg   #define DOUBLE     0
     1.1  mrg   #define QUAD	     0
     1.1  mrg   #define DEFCONTEXT DEC_INIT_DECIMAL32
     1.1  mrg #elif DECPMAX==16
     1.1  mrg   #define SINGLE     0
     1.1  mrg   #define DOUBLE     1
     1.1  mrg   #define QUAD	     0
     1.1  mrg   #define DEFCONTEXT DEC_INIT_DECIMAL64
     1.1  mrg #elif DECPMAX==34
     1.1  mrg   #define SINGLE     0
     1.1  mrg   #define DOUBLE     0
     1.1  mrg   #define QUAD	     1
     1.1  mrg   #define DEFCONTEXT DEC_INIT_DECIMAL128
     1.1  mrg #else
     1.1  mrg   #error Unexpected DECPMAX value
     1.1  mrg #endif
     1.1  mrg
     1.1  mrg /* Assertions */
     1.1  mrg
     1.1  mrg #if DECPMAX!=7 && DECPMAX!=16 && DECPMAX!=34
     1.1  mrg   #error Unexpected Pmax (DECPMAX) value for this module
     1.1  mrg #endif
     1.1  mrg
     1.1  mrg /* Assert facts about digit characters, etc. */
     1.1  mrg #if ('9'&0x0f)!=9
     1.1  mrg   #error This module assumes characters are of the form 0b....nnnn
     1.1  mrg   /* where .... are don't care 4 bits and nnnn is 0000 through 1001 */
     1.1  mrg #endif
     1.1  mrg #if ('9'&0xf0)==('.'&0xf0)
     1.1  mrg   #error This module assumes '.' has a different mask than a digit
     1.1  mrg #endif
     1.1  mrg
     1.1  mrg /* Assert ToString lay-out conditions */
     1.1  mrg #if DECSTRING<DECPMAX+9
     1.1  mrg   #error ToString needs at least 8 characters for lead-in and dot
     1.1  mrg #endif
     1.1  mrg #if DECPMAX+DECEMAXD+5 > DECSTRING
     1.1  mrg   #error Exponent form can be too long for ToString to lay out safely
     1.1  mrg #endif
     1.1  mrg #if DECEMAXD > 4
     1.1  mrg   #error Exponent form is too long for ToString to lay out
     1.1  mrg   /* Note: code for up to 9 digits exists in archives [decOct] */
     1.1  mrg #endif
     1.1  mrg
     1.1  mrg /* Private functions used here and possibly in decBasic.c, etc. */
     1.1  mrg static decFloat * decFinalize(decFloat *, bcdnum *, decContext *);
     1.1  mrg static Flag decBiStr(const char *, const char *, const char *);
     1.1  mrg
     1.1  mrg /* Macros and private tables; those which are not format-dependent    */
     1.1  mrg /* are only included if decQuad is being built. 		      */
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* Combination field lookup tables (uInts to save measurable work)    */
     1.1  mrg /*								      */
     1.1  mrg /*   DECCOMBEXP  - 2 most-significant-bits of exponent (00, 01, or    */
     1.1  mrg /*		   10), shifted left for format, or DECFLOAT_Inf/NaN  */
     1.1  mrg /*   DECCOMBWEXP - The same, for the next-wider format (unless QUAD)  */
     1.1  mrg /*   DECCOMBMSD  - 4-bit most-significant-digit 		      */
     1.1  mrg /*		   [0 if the index is a special (Infinity or NaN)]    */
     1.1  mrg /*   DECCOMBFROM - 5-bit combination field from EXP top bits and MSD  */
     1.1  mrg /*		   (placed in uInt so no shift is needed)	      */
     1.1  mrg /*								      */
     1.1  mrg /* DECCOMBEXP, DECCOMBWEXP, and DECCOMBMSD are indexed by the sign    */
     1.1  mrg /*   and 5-bit combination field (0-63, the second half of the table  */
     1.1  mrg /*   identical to the first half)				      */
     1.1  mrg /* DECCOMBFROM is indexed by expTopTwoBits*16 + msd		      */
     1.1  mrg /*								      */
     1.1  mrg /* DECCOMBMSD and DECCOMBFROM are not format-dependent and so are     */
     1.1  mrg /* only included once, when QUAD is being built 		      */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg static const uInt DECCOMBEXP[64]={
     1.1  mrg   0, 0, 0, 0, 0, 0, 0, 0,
     1.1  mrg   1<<DECECONL, 1<<DECECONL, 1<<DECECONL, 1<<DECECONL,
     1.1  mrg   1<<DECECONL, 1<<DECECONL, 1<<DECECONL, 1<<DECECONL,
     1.1  mrg   2<<DECECONL, 2<<DECECONL, 2<<DECECONL, 2<<DECECONL,
     1.1  mrg   2<<DECECONL, 2<<DECECONL, 2<<DECECONL, 2<<DECECONL,
     1.1  mrg   0,	       0,	    1<<DECECONL, 1<<DECECONL,
     1.1  mrg   2<<DECECONL, 2<<DECECONL, DECFLOAT_Inf, DECFLOAT_NaN,
     1.1  mrg   0, 0, 0, 0, 0, 0, 0, 0,
     1.1  mrg   1<<DECECONL, 1<<DECECONL, 1<<DECECONL, 1<<DECECONL,
     1.1  mrg   1<<DECECONL, 1<<DECECONL, 1<<DECECONL, 1<<DECECONL,
     1.1  mrg   2<<DECECONL, 2<<DECECONL, 2<<DECECONL, 2<<DECECONL,
     1.1  mrg   2<<DECECONL, 2<<DECECONL, 2<<DECECONL, 2<<DECECONL,
     1.1  mrg   0,	       0,	    1<<DECECONL, 1<<DECECONL,
     1.1  mrg   2<<DECECONL, 2<<DECECONL, DECFLOAT_Inf, DECFLOAT_NaN};
     1.1  mrg #if !QUAD
     1.1  mrg static const uInt DECCOMBWEXP[64]={
     1.1  mrg   0, 0, 0, 0, 0, 0, 0, 0,
     1.1  mrg   1<<DECWECONL, 1<<DECWECONL, 1<<DECWECONL, 1<<DECWECONL,
     1.1  mrg   1<<DECWECONL, 1<<DECWECONL, 1<<DECWECONL, 1<<DECWECONL,
     1.1  mrg   2<<DECWECONL, 2<<DECWECONL, 2<<DECWECONL, 2<<DECWECONL,
     1.1  mrg   2<<DECWECONL, 2<<DECWECONL, 2<<DECWECONL, 2<<DECWECONL,
     1.1  mrg   0,		0,	      1<<DECWECONL, 1<<DECWECONL,
     1.1  mrg   2<<DECWECONL, 2<<DECWECONL, DECFLOAT_Inf, DECFLOAT_NaN,
     1.1  mrg   0, 0, 0, 0, 0, 0, 0, 0,
     1.1  mrg   1<<DECWECONL, 1<<DECWECONL, 1<<DECWECONL, 1<<DECWECONL,
     1.1  mrg   1<<DECWECONL, 1<<DECWECONL, 1<<DECWECONL, 1<<DECWECONL,
     1.1  mrg   2<<DECWECONL, 2<<DECWECONL, 2<<DECWECONL, 2<<DECWECONL,
     1.1  mrg   2<<DECWECONL, 2<<DECWECONL, 2<<DECWECONL, 2<<DECWECONL,
     1.1  mrg   0,		0,	      1<<DECWECONL, 1<<DECWECONL,
     1.1  mrg   2<<DECWECONL, 2<<DECWECONL, DECFLOAT_Inf, DECFLOAT_NaN};
     1.1  mrg #endif
     1.1  mrg
     1.1  mrg #if QUAD
     1.1  mrg const uInt DECCOMBMSD[64]={
     1.1  mrg   0, 1, 2, 3, 4, 5, 6, 7, 0, 1, 2, 3, 4, 5, 6, 7,
     1.1  mrg   0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 8, 9, 8, 9, 0, 0,
     1.1  mrg   0, 1, 2, 3, 4, 5, 6, 7, 0, 1, 2, 3, 4, 5, 6, 7,
     1.1  mrg   0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 8, 9, 8, 9, 0, 0};
     1.1  mrg
     1.1  mrg const uInt DECCOMBFROM[48]={
     1.1  mrg   0x00000000, 0x04000000, 0x08000000, 0x0C000000, 0x10000000, 0x14000000,
     1.1  mrg   0x18000000, 0x1C000000, 0x60000000, 0x64000000, 0x00000000, 0x00000000,
     1.1  mrg   0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x20000000, 0x24000000,
     1.1  mrg   0x28000000, 0x2C000000, 0x30000000, 0x34000000, 0x38000000, 0x3C000000,
     1.1  mrg   0x68000000, 0x6C000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000,
     1.1  mrg   0x00000000, 0x00000000, 0x40000000, 0x44000000, 0x48000000, 0x4C000000,
     1.1  mrg   0x50000000, 0x54000000, 0x58000000, 0x5C000000, 0x70000000, 0x74000000,
     1.1  mrg   0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000, 0x00000000};
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* Request and include the tables to use for conversions	      */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg #define DEC_BCD2DPD  1	      /* 0-0x999 -> DPD */
     1.1  mrg #define DEC_BIN2DPD  1	      /* 0-999 -> DPD */
     1.1  mrg #define DEC_BIN2BCD8 1	      /* 0-999 -> ddd, len */
     1.1  mrg #define DEC_DPD2BCD8 1	      /* DPD -> ddd, len */
     1.1  mrg #define DEC_DPD2BIN  1	      /* DPD -> 0-999 */
     1.1  mrg #define DEC_DPD2BINK 1	      /* DPD -> 0-999000 */
     1.1  mrg #define DEC_DPD2BINM 1	      /* DPD -> 0-999000000 */
     1.1  mrg #include "decDPD.h"	      /* source of the lookup tables */
     1.1  mrg
     1.1  mrg #endif
     1.1  mrg
     1.1  mrg /* ----------------------------------------------------------------- */
     1.1  mrg /* decBiStr -- compare string with pairwise options		     */
     1.1  mrg /*								     */
     1.1  mrg /*   targ is the string to compare				     */
     1.1  mrg /*   str1 is one of the strings to compare against (length may be 0) */
     1.1  mrg /*   str2 is the other; it must be the same length as str1	     */
     1.1  mrg /*								     */
     1.1  mrg /*   returns 1 if strings compare equal, (that is, targ is the same  */
     1.1  mrg /*   length as str1 and str2, and each character of targ is in one   */
     1.1  mrg /*   of str1 or str2 in the corresponding position), or 0 otherwise  */
     1.1  mrg /*								     */
     1.1  mrg /* This is used for generic caseless compare, including the awkward  */
     1.1  mrg /* case of the Turkish dotted and dotless Is.  Use as (for example): */
     1.1  mrg /*   if (decBiStr(test, "mike", "MIKE")) ...			     */
     1.1  mrg /* ----------------------------------------------------------------- */
     1.1  mrg static Flag decBiStr(const char *targ, const char *str1, const char *str2) {
     1.1  mrg   for (;;targ++, str1++, str2++) {
     1.1  mrg     if (*targ!=*str1 && *targ!=*str2) return 0;
     1.1  mrg     /* *targ has a match in one (or both, if terminator) */
     1.1  mrg     if (*targ=='\0') break;
     1.1  mrg     } /* forever */
     1.1  mrg   return 1;
     1.1  mrg   } /* decBiStr */
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* decFinalize -- adjust and store a final result		      */
     1.1  mrg /*								      */
     1.1  mrg /*  df	is the decFloat format number which gets the final result     */
     1.1  mrg /*  num is the descriptor of the number to be checked and encoded     */
     1.1  mrg /*	   [its values, including the coefficient, may be modified]   */
     1.1  mrg /*  set is the context to use					      */
     1.1  mrg /*  returns df							      */
     1.1  mrg /*								      */
     1.1  mrg /* The num descriptor may point to a bcd8 string of any length; this  */
     1.1  mrg /* string may have leading insignificant zeros.  If it has more than  */
     1.1  mrg /* DECPMAX digits then the final digit can be a round-for-reround     */
     1.1  mrg /* digit (i.e., it may include a sticky bit residue).		      */
     1.1  mrg /*								      */
     1.1  mrg /* The exponent (q) may be one of the codes for a special value and   */
     1.1  mrg /* can be up to 999999999 for conversion from string.		      */
     1.1  mrg /*								      */
     1.1  mrg /* No error is possible, but Inexact, Underflow, and/or Overflow may  */
     1.1  mrg /* be set.							      */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* Constant whose size varies with format; also the check for surprises */
     1.1  mrg static uByte allnines[DECPMAX]=
     1.1  mrg #if SINGLE
     1.1  mrg   {9, 9, 9, 9, 9, 9, 9};
     1.1  mrg #elif DOUBLE
     1.1  mrg   {9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9};
     1.1  mrg #elif QUAD
     1.1  mrg   {9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9,
     1.1  mrg    9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9, 9};
     1.1  mrg #endif
     1.1  mrg
     1.1  mrg static decFloat * decFinalize(decFloat *df, bcdnum *num,
     1.1  mrg 			      decContext *set) {
     1.1  mrg   uByte *ub;		      /* work */
     1.1  mrg   uInt	 dpd;		      /* .. */
     1.1  mrg   uInt	 uiwork;	      /* for macros */
     1.1  mrg   uByte *umsd=num->msd;       /* local copy */
     1.1  mrg   uByte *ulsd=num->lsd;       /* .. */
     1.1  mrg   uInt	 encode;	      /* encoding accumulator */
     1.1  mrg   Int	 length;	      /* coefficient length */
     1.1  mrg
     1.1  mrg   #if DECCHECK
     1.1  mrg   Int clen=ulsd-umsd+1;
     1.1  mrg   #if QUAD
     1.1  mrg     #define COEXTRA 2			     /* extra-long coefficent */
     1.1  mrg   #else
     1.1  mrg     #define COEXTRA 0
     1.1  mrg   #endif
     1.1  mrg   if (clen<1 || clen>DECPMAX*3+2+COEXTRA)
     1.1  mrg     printf("decFinalize: suspect coefficient [length=%ld]\n", (LI)clen);
     1.1  mrg   if (num->sign!=0 && num->sign!=DECFLOAT_Sign)
     1.1  mrg     printf("decFinalize: bad sign [%08lx]\n", (LI)num->sign);
     1.1  mrg   if (!EXPISSPECIAL(num->exponent)
     1.1  mrg       && (num->exponent>1999999999 || num->exponent<-1999999999))
     1.1  mrg     printf("decFinalize: improbable exponent [%ld]\n", (LI)num->exponent);
     1.1  mrg   /* decShowNum(num, "final"); */
     1.1  mrg   #endif
     1.1  mrg
     1.1  mrg   /* A special will have an 'exponent' which is very positive and a */
     1.1  mrg   /* coefficient < DECPMAX */
     1.1  mrg   length=(uInt)(ulsd-umsd+1);		     /* coefficient length */
     1.1  mrg
     1.1  mrg   if (!NUMISSPECIAL(num)) {
     1.1  mrg     Int   drop; 			     /* digits to be dropped */
     1.1  mrg     /* skip leading insignificant zeros to calculate an exact length */
     1.1  mrg     /* [this is quite expensive] */
     1.1  mrg     if (*umsd==0) {
     1.1  mrg       for (; umsd+3<ulsd && UBTOUI(umsd)==0;) umsd+=4;
     1.1  mrg       for (; *umsd==0 && umsd<ulsd;) umsd++;
     1.1  mrg       length=ulsd-umsd+1;		     /* recalculate */
     1.1  mrg       }
     1.1  mrg     drop=MAXI(length-DECPMAX, DECQTINY-num->exponent);
     1.1  mrg     /* drop can now be > digits for bottom-clamp (subnormal) cases */
     1.1  mrg     if (drop>0) {			     /* rounding needed */
     1.1  mrg       /* (decFloatQuantize has very similar code to this, so any */
     1.1  mrg       /* changes may need to be made there, too) */
     1.1  mrg       uByte *roundat;			     /* -> re-round digit */
     1.1  mrg       uByte reround;			     /* reround value */
     1.1  mrg       /* printf("Rounding; drop=%ld\n", (LI)drop); */
     1.1  mrg
     1.1  mrg       num->exponent+=drop;		     /* always update exponent */
     1.1  mrg
     1.1  mrg       /* Three cases here: */
     1.1  mrg       /*   1. new LSD is in coefficient (almost always) */
     1.1  mrg       /*   2. new LSD is digit to left of coefficient (so MSD is */
     1.1  mrg       /*      round-for-reround digit) */
     1.1  mrg       /*   3. new LSD is to left of case 2 (whole coefficient is sticky) */
     1.1  mrg       /* [duplicate check-stickies code to save a test] */
     1.1  mrg       /* [by-digit check for stickies as runs of zeros are rare] */
     1.1  mrg       if (drop<length) {		     /* NB lengths not addresses */
     1.1  mrg 	roundat=umsd+length-drop;
     1.1  mrg 	reround=*roundat;
     1.1  mrg 	for (ub=roundat+1; ub<=ulsd; ub++) {
     1.1  mrg 	  if (*ub!=0) { 		     /* non-zero to be discarded */
     1.1  mrg 	    reround=DECSTICKYTAB[reround];   /* apply sticky bit */
     1.1  mrg 	    break;			     /* [remainder don't-care] */
     1.1  mrg 	    }
     1.1  mrg 	  } /* check stickies */
     1.1  mrg 	ulsd=roundat-1; 		     /* new LSD */
     1.1  mrg 	}
     1.1  mrg        else {				     /* edge case */
     1.1  mrg 	if (drop==length) {
     1.1  mrg 	  roundat=umsd;
     1.1  mrg 	  reround=*roundat;
     1.1  mrg 	  }
     1.1  mrg 	 else {
     1.1  mrg 	  roundat=umsd-1;
     1.1  mrg 	  reround=0;
     1.1  mrg 	  }
     1.1  mrg 	for (ub=roundat+1; ub<=ulsd; ub++) {
     1.1  mrg 	  if (*ub!=0) { 		     /* non-zero to be discarded */
     1.1  mrg 	    reround=DECSTICKYTAB[reround];   /* apply sticky bit */
     1.1  mrg 	    break;			     /* [remainder don't-care] */
     1.1  mrg 	    }
     1.1  mrg 	  } /* check stickies */
     1.1  mrg 	*umsd=0;			     /* coefficient is a 0 */
     1.1  mrg 	ulsd=umsd;			     /* .. */
     1.1  mrg 	}
     1.1  mrg
     1.1  mrg       if (reround!=0) { 		     /* discarding non-zero */
     1.1  mrg 	uInt bump=0;
     1.1  mrg 	set->status|=DEC_Inexact;
     1.1  mrg 	/* if adjusted exponent [exp+digits-1] is < EMIN then num is */
     1.1  mrg 	/* subnormal -- so raise Underflow */
     1.1  mrg 	if (num->exponent<DECEMIN && (num->exponent+(ulsd-umsd+1)-1)<DECEMIN)
     1.1  mrg 	  set->status|=DEC_Underflow;
     1.1  mrg
     1.1  mrg 	/* next decide whether increment of the coefficient is needed */
     1.1  mrg 	if (set->round==DEC_ROUND_HALF_EVEN) {	  /* fastpath slowest case */
     1.1  mrg 	  if (reround>5) bump=1;		  /* >0.5 goes up */
     1.1  mrg 	   else if (reround==5) 		  /* exactly 0.5000 .. */
     1.1  mrg 	    bump=*ulsd & 0x01;			  /* .. up iff [new] lsd is odd */
     1.1  mrg 	  } /* r-h-e */
     1.1  mrg 	 else switch (set->round) {
     1.1  mrg 	  case DEC_ROUND_DOWN: {
     1.1  mrg 	    /* no change */
     1.1  mrg 	    break;} /* r-d */
     1.1  mrg 	  case DEC_ROUND_HALF_DOWN: {
     1.1  mrg 	    if (reround>5) bump=1;
     1.1  mrg 	    break;} /* r-h-d */
     1.1  mrg 	  case DEC_ROUND_HALF_UP: {
     1.1  mrg 	    if (reround>=5) bump=1;
     1.1  mrg 	    break;} /* r-h-u */
     1.1  mrg 	  case DEC_ROUND_UP: {
     1.1  mrg 	    if (reround>0) bump=1;
     1.1  mrg 	    break;} /* r-u */
     1.1  mrg 	  case DEC_ROUND_CEILING: {
     1.1  mrg 	    /* same as _UP for positive numbers, and as _DOWN for negatives */
     1.1  mrg 	    if (!num->sign && reround>0) bump=1;
     1.1  mrg 	    break;} /* r-c */
     1.1  mrg 	  case DEC_ROUND_FLOOR: {
     1.1  mrg 	    /* same as _UP for negative numbers, and as _DOWN for positive */
     1.1  mrg 	    /* [negative reround cannot occur on 0] */
     1.1  mrg 	    if (num->sign && reround>0) bump=1;
     1.1  mrg 	    break;} /* r-f */
     1.1  mrg 	  case DEC_ROUND_05UP: {
     1.1  mrg 	    if (reround>0) { /* anything out there is 'sticky' */
     1.1  mrg 	      /* bump iff lsd=0 or 5; this cannot carry so it could be */
     1.1  mrg 	      /* effected immediately with no bump -- but the code */
     1.1  mrg 	      /* is clearer if this is done the same way as the others */
     1.1  mrg 	      if (*ulsd==0 || *ulsd==5) bump=1;
     1.1  mrg 	      }
     1.1  mrg 	    break;} /* r-r */
     1.1  mrg 	  default: {	  /* e.g., DEC_ROUND_MAX */
     1.1  mrg 	    set->status|=DEC_Invalid_context;
     1.1  mrg 	    #if DECCHECK
     1.1  mrg 	    printf("Unknown rounding mode: %ld\n", (LI)set->round);
     1.1  mrg 	    #endif
     1.1  mrg 	    break;}
     1.1  mrg 	  } /* switch (not r-h-e) */
     1.1  mrg 	/* printf("ReRound: %ld  bump: %ld\n", (LI)reround, (LI)bump); */
     1.1  mrg
     1.1  mrg 	if (bump!=0) {			     /* need increment */
     1.1  mrg 	  /* increment the coefficient; this might end up with 1000... */
     1.1  mrg 	  /* (after the all nines case) */
     1.1  mrg 	  ub=ulsd;
     1.1  mrg 	  for(; ub-3>=umsd && UBTOUI(ub-3)==0x09090909; ub-=4)	{
     1.1  mrg 	    UBFROMUI(ub-3, 0);		     /* to 00000000 */
     1.1  mrg 	    }
     1.1  mrg 	  /* [note ub could now be to left of msd, and it is not safe */
1.1.1.12  mrg 	  /* to write to the left of the msd] */
     1.1  mrg 	  /* now at most 3 digits left to non-9 (usually just the one) */
     1.1  mrg 	  for (; ub>=umsd; *ub=0, ub--) {
     1.1  mrg 	    if (*ub==9) continue;	     /* carry */
     1.1  mrg 	    *ub+=1;
     1.1  mrg 	    break;
     1.1  mrg 	    }
     1.1  mrg 	  if (ub<umsd) {		     /* had all-nines */
     1.1  mrg 	    *umsd=1;			     /* coefficient to 1000... */
     1.1  mrg 	    /* usually the 1000... coefficient can be used as-is */
     1.1  mrg 	    if ((ulsd-umsd+1)==DECPMAX) {
     1.1  mrg 	      num->exponent++;
     1.1  mrg 	      }
     1.1  mrg 	     else {
     1.1  mrg 	      /* if coefficient is shorter than Pmax then num is */
     1.1  mrg 	      /* subnormal, so extend it; this is safe as drop>0 */
     1.1  mrg 	      /* (or, if the coefficient was supplied above, it could */
     1.1  mrg 	      /* not be 9); this may make the result normal. */
     1.1  mrg 	      ulsd++;
     1.1  mrg 	      *ulsd=0;
     1.1  mrg 	      /* [exponent unchanged] */
     1.1  mrg 	      #if DECCHECK
     1.1  mrg 	      if (num->exponent!=DECQTINY) /* sanity check */
     1.1  mrg 		printf("decFinalize: bad all-nines extend [^%ld, %ld]\n",
     1.1  mrg 		       (LI)num->exponent, (LI)(ulsd-umsd+1));
     1.1  mrg 	      #endif
     1.1  mrg 	      } /* subnormal extend */
     1.1  mrg 	    } /* had all-nines */
     1.1  mrg 	  } /* bump needed */
     1.1  mrg 	} /* inexact rounding */
     1.1  mrg
     1.1  mrg       length=ulsd-umsd+1;		/* recalculate (may be <DECPMAX) */
     1.1  mrg       } /* need round (drop>0) */
     1.1  mrg
     1.1  mrg     /* The coefficient will now fit and has final length unless overflow */
     1.1  mrg     /* decShowNum(num, "rounded"); */
     1.1  mrg
     1.1  mrg     /* if exponent is >=emax may have to clamp, overflow, or fold-down */
     1.1  mrg     if (num->exponent>DECEMAX-(DECPMAX-1)) { /* is edge case */
     1.1  mrg       /* printf("overflow checks...\n"); */
     1.1  mrg       if (*ulsd==0 && ulsd==umsd) {	/* have zero */
     1.1  mrg 	num->exponent=DECEMAX-(DECPMAX-1); /* clamp to max */
     1.1  mrg 	}
     1.1  mrg        else if ((num->exponent+length-1)>DECEMAX) { /* > Nmax */
     1.1  mrg 	/* Overflow -- these could go straight to encoding, here, but */
     1.1  mrg 	/* instead num is adjusted to keep the code cleaner */
     1.1  mrg 	Flag needmax=0; 		/* 1 for finite result */
     1.1  mrg 	set->status|=(DEC_Overflow | DEC_Inexact);
     1.1  mrg 	switch (set->round) {
     1.1  mrg 	  case DEC_ROUND_DOWN: {
     1.1  mrg 	    needmax=1;			/* never Infinity */
     1.1  mrg 	    break;} /* r-d */
     1.1  mrg 	  case DEC_ROUND_05UP: {
     1.1  mrg 	    needmax=1;			/* never Infinity */
     1.1  mrg 	    break;} /* r-05 */
     1.1  mrg 	  case DEC_ROUND_CEILING: {
     1.1  mrg 	    if (num->sign) needmax=1;	/* Infinity iff non-negative */
     1.1  mrg 	    break;} /* r-c */
     1.1  mrg 	  case DEC_ROUND_FLOOR: {
     1.1  mrg 	    if (!num->sign) needmax=1;	/* Infinity iff negative */
     1.1  mrg 	    break;} /* r-f */
     1.1  mrg 	  default: break;		/* Infinity in all other cases */
     1.1  mrg 	  }
     1.1  mrg 	if (!needmax) { 		/* easy .. set Infinity */
     1.1  mrg 	  num->exponent=DECFLOAT_Inf;
     1.1  mrg 	  *umsd=0;			/* be clean: coefficient to 0 */
     1.1  mrg 	  ulsd=umsd;			/* .. */
     1.1  mrg 	  }
     1.1  mrg 	 else { 			/* return Nmax */
     1.1  mrg 	  umsd=allnines;		/* use constant array */
     1.1  mrg 	  ulsd=allnines+DECPMAX-1;
     1.1  mrg 	  num->exponent=DECEMAX-(DECPMAX-1);
     1.1  mrg 	  }
     1.1  mrg 	}
     1.1  mrg        else { /* no overflow but non-zero and may have to fold-down */
     1.1  mrg 	Int shift=num->exponent-(DECEMAX-(DECPMAX-1));
     1.1  mrg 	if (shift>0) {			/* fold-down needed */
     1.1  mrg 	  /* fold down needed; must copy to buffer in order to pad */
     1.1  mrg 	  /* with zeros safely; fortunately this is not the worst case */
     1.1  mrg 	  /* path because cannot have had a round */
     1.1  mrg 	  uByte buffer[ROUNDUP(DECPMAX+3, 4)]; /* [+3 allows uInt padding] */
     1.1  mrg 	  uByte *s=umsd;		/* source */
     1.1  mrg 	  uByte *t=buffer;		/* safe target */
     1.1  mrg 	  uByte *tlsd=buffer+(ulsd-umsd)+shift; /* target LSD */
     1.1  mrg 	  /* printf("folddown shift=%ld\n", (LI)shift); */
     1.1  mrg 	  for (; s<=ulsd; s+=4, t+=4) UBFROMUI(t, UBTOUI(s));
     1.1  mrg 	  for (t=tlsd-shift+1; t<=tlsd; t+=4) UBFROMUI(t, 0);  /* pad 0s */
     1.1  mrg 	  num->exponent-=shift;
     1.1  mrg 	  umsd=buffer;
     1.1  mrg 	  ulsd=tlsd;
     1.1  mrg 	  }
     1.1  mrg 	} /* fold-down? */
     1.1  mrg       length=ulsd-umsd+1;		/* recalculate length */
     1.1  mrg       } /* high-end edge case */
     1.1  mrg     } /* finite number */
     1.1  mrg
     1.1  mrg   /*------------------------------------------------------------------*/
     1.1  mrg   /* At this point the result will properly fit the decFloat	      */
     1.1  mrg   /* encoding, and it can be encoded with no possibility of error     */
     1.1  mrg   /*------------------------------------------------------------------*/
     1.1  mrg   /* Following code does not alter coefficient (could be allnines array) */
     1.1  mrg
     1.1  mrg   /* fast path possible when DECPMAX digits */
     1.1  mrg   if (length==DECPMAX) {
     1.1  mrg     return decFloatFromBCD(df, num->exponent, umsd, num->sign);
     1.1  mrg     } /* full-length */
     1.1  mrg
     1.1  mrg   /* slower path when not a full-length number; must care about length */
     1.1  mrg   /* [coefficient length here will be < DECPMAX] */
     1.1  mrg   if (!NUMISSPECIAL(num)) {		/* is still finite */
     1.1  mrg     /* encode the combination field and exponent continuation */
     1.1  mrg     uInt uexp=(uInt)(num->exponent+DECBIAS); /* biased exponent */
     1.1  mrg     uInt code=(uexp>>DECECONL)<<4;	/* top two bits of exp */
     1.1  mrg     /* [msd==0] */
     1.1  mrg     /* look up the combination field and make high word */
     1.1  mrg     encode=DECCOMBFROM[code];		/* indexed by (0-2)*16+msd */
     1.1  mrg     encode|=(uexp<<(32-6-DECECONL)) & 0x03ffffff; /* exponent continuation */
     1.1  mrg     }
     1.1  mrg    else encode=num->exponent;		/* special [already in word] */
     1.1  mrg   encode|=num->sign;			/* add sign */
     1.1  mrg
     1.1  mrg   /* private macro to extract a declet, n (where 0<=n<DECLETS and 0 */
     1.1  mrg   /* refers to the declet from the least significant three digits) */
     1.1  mrg   /* and put the corresponding DPD code into dpd.  Access to umsd and */
     1.1  mrg   /* ulsd (pointers to the most and least significant digit of the */
     1.1  mrg   /* variable-length coefficient) is assumed, along with use of a */
     1.1  mrg   /* working pointer, uInt *ub. */
     1.1  mrg   /* As not full-length then chances are there are many leading zeros */
     1.1  mrg   /* [and there may be a partial triad] */
     1.1  mrg   #define getDPDt(dpd, n) ub=ulsd-(3*(n))-2;			      \
     1.1  mrg     if (ub<umsd-2) dpd=0;					      \
     1.1  mrg      else if (ub>=umsd) dpd=BCD2DPD[(*ub*256)+(*(ub+1)*16)+*(ub+2)];  \
     1.1  mrg      else {dpd=*(ub+2); if (ub+1==umsd) dpd+=*(ub+1)*16; dpd=BCD2DPD[dpd];}
     1.1  mrg
     1.1  mrg   /* place the declets in the encoding words and copy to result (df), */
     1.1  mrg   /* according to endianness; in all cases complete the sign word */
     1.1  mrg   /* first */
     1.1  mrg   #if DECPMAX==7
     1.1  mrg     getDPDt(dpd, 1);
     1.1  mrg     encode|=dpd<<10;
     1.1  mrg     getDPDt(dpd, 0);
     1.1  mrg     encode|=dpd;
     1.1  mrg     DFWORD(df, 0)=encode;     /* just the one word */
     1.1  mrg
     1.1  mrg   #elif DECPMAX==16
     1.1  mrg     getDPDt(dpd, 4); encode|=dpd<<8;
     1.1  mrg     getDPDt(dpd, 3); encode|=dpd>>2;
     1.1  mrg     DFWORD(df, 0)=encode;
     1.1  mrg     encode=dpd<<30;
     1.1  mrg     getDPDt(dpd, 2); encode|=dpd<<20;
     1.1  mrg     getDPDt(dpd, 1); encode|=dpd<<10;
     1.1  mrg     getDPDt(dpd, 0); encode|=dpd;
     1.1  mrg     DFWORD(df, 1)=encode;
     1.1  mrg
     1.1  mrg   #elif DECPMAX==34
     1.1  mrg     getDPDt(dpd,10); encode|=dpd<<4;
     1.1  mrg     getDPDt(dpd, 9); encode|=dpd>>6;
     1.1  mrg     DFWORD(df, 0)=encode;
     1.1  mrg
     1.1  mrg     encode=dpd<<26;
     1.1  mrg     getDPDt(dpd, 8); encode|=dpd<<16;
     1.1  mrg     getDPDt(dpd, 7); encode|=dpd<<6;
     1.1  mrg     getDPDt(dpd, 6); encode|=dpd>>4;
     1.1  mrg     DFWORD(df, 1)=encode;
     1.1  mrg
     1.1  mrg     encode=dpd<<28;
     1.1  mrg     getDPDt(dpd, 5); encode|=dpd<<18;
     1.1  mrg     getDPDt(dpd, 4); encode|=dpd<<8;
     1.1  mrg     getDPDt(dpd, 3); encode|=dpd>>2;
     1.1  mrg     DFWORD(df, 2)=encode;
     1.1  mrg
     1.1  mrg     encode=dpd<<30;
     1.1  mrg     getDPDt(dpd, 2); encode|=dpd<<20;
     1.1  mrg     getDPDt(dpd, 1); encode|=dpd<<10;
     1.1  mrg     getDPDt(dpd, 0); encode|=dpd;
     1.1  mrg     DFWORD(df, 3)=encode;
     1.1  mrg   #endif
     1.1  mrg
     1.1  mrg   /* printf("Status: %08lx\n", (LI)set->status); */
     1.1  mrg   /* decFloatShow(df, "final2"); */
     1.1  mrg   return df;
     1.1  mrg   } /* decFinalize */
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* decFloatFromBCD -- set decFloat from exponent, BCD8, and sign      */
     1.1  mrg /*								      */
     1.1  mrg /*  df is the target decFloat					      */
     1.1  mrg /*  exp is the in-range unbiased exponent, q, or a special value in   */
     1.1  mrg /*    the form returned by decFloatGetExponent			      */
     1.1  mrg /*  bcdar holds DECPMAX digits to set the coefficient from, one       */
     1.1  mrg /*    digit in each byte (BCD8 encoding); the first (MSD) is ignored  */
     1.1  mrg /*    if df is a NaN; all are ignored if df is infinite.	      */
     1.1  mrg /*    All bytes must be in 0-9; results are undefined otherwise.      */
     1.1  mrg /*  sig is DECFLOAT_Sign to set the sign bit, 0 otherwise	      */
     1.1  mrg /*  returns df, which will be canonical 			      */
     1.1  mrg /*								      */
     1.1  mrg /* No error is possible, and no status will be set.		      */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg decFloat * decFloatFromBCD(decFloat *df, Int exp, const uByte *bcdar,
     1.1  mrg 			   Int sig) {
     1.1  mrg   uInt encode, dpd;			/* work */
     1.1  mrg   const uByte *ub;			/* .. */
     1.1  mrg
     1.1  mrg   if (EXPISSPECIAL(exp)) encode=exp|sig;/* specials already encoded */
     1.1  mrg    else {				/* is finite */
     1.1  mrg     /* encode the combination field and exponent continuation */
     1.1  mrg     uInt uexp=(uInt)(exp+DECBIAS);	/* biased exponent */
     1.1  mrg     uInt code=(uexp>>DECECONL)<<4;	/* top two bits of exp */
     1.1  mrg     code+=bcdar[0];			/* add msd */
     1.1  mrg     /* look up the combination field and make high word */
     1.1  mrg     encode=DECCOMBFROM[code]|sig;	/* indexed by (0-2)*16+msd */
     1.1  mrg     encode|=(uexp<<(32-6-DECECONL)) & 0x03ffffff; /* exponent continuation */
     1.1  mrg     }
     1.1  mrg
     1.1  mrg   /* private macro to extract a declet, n (where 0<=n<DECLETS and 0 */
     1.1  mrg   /* refers to the declet from the least significant three digits) */
     1.1  mrg   /* and put the corresponding DPD code into dpd. */
     1.1  mrg   /* Use of a working pointer, uInt *ub, is assumed. */
     1.1  mrg
     1.1  mrg   #define getDPDb(dpd, n) ub=bcdar+DECPMAX-1-(3*(n))-2;     \
     1.1  mrg     dpd=BCD2DPD[(*ub*256)+(*(ub+1)*16)+*(ub+2)];
     1.1  mrg
     1.1  mrg   /* place the declets in the encoding words and copy to result (df), */
     1.1  mrg   /* according to endianness; in all cases complete the sign word */
     1.1  mrg   /* first */
     1.1  mrg   #if DECPMAX==7
     1.1  mrg     getDPDb(dpd, 1);
     1.1  mrg     encode|=dpd<<10;
     1.1  mrg     getDPDb(dpd, 0);
     1.1  mrg     encode|=dpd;
     1.1  mrg     DFWORD(df, 0)=encode;     /* just the one word */
     1.1  mrg
     1.1  mrg   #elif DECPMAX==16
     1.1  mrg     getDPDb(dpd, 4); encode|=dpd<<8;
     1.1  mrg     getDPDb(dpd, 3); encode|=dpd>>2;
     1.1  mrg     DFWORD(df, 0)=encode;
     1.1  mrg     encode=dpd<<30;
     1.1  mrg     getDPDb(dpd, 2); encode|=dpd<<20;
     1.1  mrg     getDPDb(dpd, 1); encode|=dpd<<10;
     1.1  mrg     getDPDb(dpd, 0); encode|=dpd;
     1.1  mrg     DFWORD(df, 1)=encode;
     1.1  mrg
     1.1  mrg   #elif DECPMAX==34
     1.1  mrg     getDPDb(dpd,10); encode|=dpd<<4;
     1.1  mrg     getDPDb(dpd, 9); encode|=dpd>>6;
     1.1  mrg     DFWORD(df, 0)=encode;
     1.1  mrg
     1.1  mrg     encode=dpd<<26;
     1.1  mrg     getDPDb(dpd, 8); encode|=dpd<<16;
     1.1  mrg     getDPDb(dpd, 7); encode|=dpd<<6;
     1.1  mrg     getDPDb(dpd, 6); encode|=dpd>>4;
     1.1  mrg     DFWORD(df, 1)=encode;
     1.1  mrg
     1.1  mrg     encode=dpd<<28;
     1.1  mrg     getDPDb(dpd, 5); encode|=dpd<<18;
     1.1  mrg     getDPDb(dpd, 4); encode|=dpd<<8;
     1.1  mrg     getDPDb(dpd, 3); encode|=dpd>>2;
     1.1  mrg     DFWORD(df, 2)=encode;
     1.1  mrg
     1.1  mrg     encode=dpd<<30;
     1.1  mrg     getDPDb(dpd, 2); encode|=dpd<<20;
     1.1  mrg     getDPDb(dpd, 1); encode|=dpd<<10;
     1.1  mrg     getDPDb(dpd, 0); encode|=dpd;
     1.1  mrg     DFWORD(df, 3)=encode;
     1.1  mrg   #endif
     1.1  mrg   /* decFloatShow(df, "fromB"); */
     1.1  mrg   return df;
     1.1  mrg   } /* decFloatFromBCD */
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* decFloatFromPacked -- set decFloat from exponent and packed BCD    */
     1.1  mrg /*								      */
     1.1  mrg /*  df is the target decFloat					      */
     1.1  mrg /*  exp is the in-range unbiased exponent, q, or a special value in   */
     1.1  mrg /*    the form returned by decFloatGetExponent			      */
     1.1  mrg /*  packed holds DECPMAX packed decimal digits plus a sign nibble     */
     1.1  mrg /*    (all 6 codes are OK); the first (MSD) is ignored if df is a NaN */
     1.1  mrg /*    and all except sign are ignored if df is infinite.  For DOUBLE  */
     1.1  mrg /*    and QUAD the first (pad) nibble is also ignored in all cases.   */
     1.1  mrg /*    All coefficient nibbles must be in 0-9 and sign in A-F; results */
     1.1  mrg /*    are undefined otherwise.					      */
     1.1  mrg /*  returns df, which will be canonical 			      */
     1.1  mrg /*								      */
     1.1  mrg /* No error is possible, and no status will be set.		      */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg decFloat * decFloatFromPacked(decFloat *df, Int exp, const uByte *packed) {
     1.1  mrg   uByte bcdar[DECPMAX+2];		/* work [+1 for pad, +1 for sign] */
     1.1  mrg   const uByte *ip;			/* .. */
     1.1  mrg   uByte *op;				/* .. */
     1.1  mrg   Int	sig=0;				/* sign */
     1.1  mrg
     1.1  mrg   /* expand coefficient and sign to BCDAR */
     1.1  mrg   #if SINGLE
     1.1  mrg   op=bcdar+1;				/* no pad digit */
     1.1  mrg   #else
     1.1  mrg   op=bcdar;				/* first (pad) digit ignored */
     1.1  mrg   #endif
     1.1  mrg   for (ip=packed; ip<packed+((DECPMAX+2)/2); ip++) {
     1.1  mrg     *op++=*ip>>4;
     1.1  mrg     *op++=(uByte)(*ip&0x0f);		/* [final nibble is sign] */
     1.1  mrg     }
     1.1  mrg   op--; 				/* -> sign byte */
     1.1  mrg   if (*op==DECPMINUS || *op==DECPMINUSALT) sig=DECFLOAT_Sign;
     1.1  mrg
     1.1  mrg   if (EXPISSPECIAL(exp)) {		/* Infinity or NaN */
     1.1  mrg     if (!EXPISINF(exp)) bcdar[1]=0;	/* a NaN: ignore MSD */
     1.1  mrg      else memset(bcdar+1, 0, DECPMAX);	/* Infinite: coefficient to 0 */
     1.1  mrg     }
     1.1  mrg   return decFloatFromBCD(df, exp, bcdar+1, sig);
     1.1  mrg   } /* decFloatFromPacked */
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* decFloatFromPackedChecked -- set from exponent and packed; checked */
     1.1  mrg /*								      */
     1.1  mrg /*  df is the target decFloat					      */
     1.1  mrg /*  exp is the in-range unbiased exponent, q, or a special value in   */
     1.1  mrg /*    the form returned by decFloatGetExponent			      */
     1.1  mrg /*  packed holds DECPMAX packed decimal digits plus a sign nibble     */
     1.1  mrg /*    (all 6 codes are OK); the first (MSD) must be 0 if df is a NaN  */
     1.1  mrg /*    and all digits must be 0 if df is infinite.  For DOUBLE and     */
     1.1  mrg /*    QUAD the first (pad) nibble must be 0.			      */
     1.1  mrg /*    All coefficient nibbles must be in 0-9 and sign in A-F.	      */
     1.1  mrg /*  returns df, which will be canonical or NULL if any of the	      */
     1.1  mrg /*    requirements are not met (if this case df is unchanged); that   */
     1.1  mrg /*    is, the input data must be as returned by decFloatToPacked,     */
 1.1.1.5  mrg /*    except that all six sign codes are accepted.		      */
     1.1  mrg /*								      */
     1.1  mrg /* No status will be set.					      */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg decFloat * decFloatFromPackedChecked(decFloat *df, Int exp,
     1.1  mrg 				     const uByte *packed) {
     1.1  mrg   uByte bcdar[DECPMAX+2];		/* work [+1 for pad, +1 for sign] */
     1.1  mrg   const uByte *ip;			/* .. */
     1.1  mrg   uByte *op;				/* .. */
     1.1  mrg   Int	sig=0;				/* sign */
     1.1  mrg
     1.1  mrg   /* expand coefficient and sign to BCDAR */
     1.1  mrg   #if SINGLE
     1.1  mrg   op=bcdar+1;				/* no pad digit */
     1.1  mrg   #else
     1.1  mrg   op=bcdar;				/* first (pad) digit here */
     1.1  mrg   #endif
     1.1  mrg   for (ip=packed; ip<packed+((DECPMAX+2)/2); ip++) {
     1.1  mrg     *op=*ip>>4;
     1.1  mrg     if (*op>9) return NULL;
     1.1  mrg     op++;
     1.1  mrg     *op=(uByte)(*ip&0x0f);		/* [final nibble is sign] */
     1.1  mrg     if (*op>9 && ip<packed+((DECPMAX+2)/2)-1) return NULL;
     1.1  mrg     op++;
     1.1  mrg     }
     1.1  mrg   op--; 				/* -> sign byte */
     1.1  mrg   if (*op<=9) return NULL;		/* bad sign */
     1.1  mrg   if (*op==DECPMINUS || *op==DECPMINUSALT) sig=DECFLOAT_Sign;
     1.1  mrg
     1.1  mrg   #if !SINGLE
     1.1  mrg   if (bcdar[0]!=0) return NULL; 	/* bad pad nibble */
     1.1  mrg   #endif
     1.1  mrg
     1.1  mrg   if (EXPISNAN(exp)) {			/* a NaN */
     1.1  mrg     if (bcdar[1]!=0) return NULL;	/* bad msd */
     1.1  mrg     } /* NaN */
     1.1  mrg    else if (EXPISINF(exp)) {		/* is infinite */
     1.1  mrg     Int i;
     1.1  mrg     for (i=0; i<DECPMAX; i++) {
     1.1  mrg       if (bcdar[i+1]!=0) return NULL;	/* should be all zeros */
     1.1  mrg       }
     1.1  mrg     } /* infinity */
     1.1  mrg    else {				/* finite */
     1.1  mrg     /* check the exponent is in range */
     1.1  mrg     if (exp>DECEMAX-DECPMAX+1) return NULL;
     1.1  mrg     if (exp<DECEMIN-DECPMAX+1) return NULL;
     1.1  mrg     }
     1.1  mrg   return decFloatFromBCD(df, exp, bcdar+1, sig);
     1.1  mrg   } /* decFloatFromPacked */
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* decFloatFromString -- conversion from numeric string 	      */
     1.1  mrg /*								      */
     1.1  mrg /*  result  is the decFloat format number which gets the result of    */
     1.1  mrg /*	    the conversion					      */
     1.1  mrg /*  *string is the character string which should contain a valid      */
     1.1  mrg /*	    number (which may be a special value), \0-terminated      */
     1.1  mrg /*	    If there are too many significant digits in the	      */
     1.1  mrg /*	    coefficient it will be rounded.			      */
     1.1  mrg /*  set     is the context					      */
     1.1  mrg /*  returns result						      */
     1.1  mrg /*								      */
     1.1  mrg /* The length of the coefficient and the size of the exponent are     */
     1.1  mrg /* checked by this routine, so the correct error (Underflow or	      */
     1.1  mrg /* Overflow) can be reported or rounding applied, as necessary.       */
     1.1  mrg /*								      */
     1.1  mrg /* There is no limit to the coefficient length for finite inputs;     */
     1.1  mrg /* NaN payloads must be integers with no more than DECPMAX-1 digits.  */
     1.1  mrg /* Exponents may have up to nine significant digits.		      */
     1.1  mrg /*								      */
     1.1  mrg /* If bad syntax is detected, the result will be a quiet NaN.	      */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg decFloat * decFloatFromString(decFloat *result, const char *string,
     1.1  mrg 			      decContext *set) {
     1.1  mrg   Int	 digits;		   /* count of digits in coefficient */
     1.1  mrg   const  char *dotchar=NULL;	   /* where dot was found [NULL if none] */
     1.1  mrg   const  char *cfirst=string;	   /* -> first character of decimal part */
     1.1  mrg   const  char *c;		   /* work */
     1.1  mrg   uByte *ub;			   /* .. */
     1.1  mrg   uInt	 uiwork;		   /* for macros */
     1.1  mrg   bcdnum num;			   /* collects data for finishing */
     1.1  mrg   uInt	 error=DEC_Conversion_syntax;	/* assume the worst */
     1.1  mrg   uByte  buffer[ROUNDUP(DECSTRING+11, 8)]; /* room for most coefficents, */
     1.1  mrg 				   /* some common rounding, +3, & pad */
     1.1  mrg   #if DECTRACE
     1.1  mrg   /* printf("FromString %s ...\n", string); */
     1.1  mrg   #endif
     1.1  mrg
     1.1  mrg   for(;;) {				/* once-only 'loop' */
     1.1  mrg     num.sign=0; 			/* assume non-negative */
     1.1  mrg     num.msd=buffer;			/* MSD is here always */
     1.1  mrg
     1.1  mrg     /* detect and validate the coefficient, including any leading, */
     1.1  mrg     /* trailing, or embedded '.' */
     1.1  mrg     /* [could test four-at-a-time here (saving 10% for decQuads), */
     1.1  mrg     /* but that risks storage violation because the position of the */
     1.1  mrg     /* terminator is unknown] */
     1.1  mrg     for (c=string;; c++) {		/* -> input character */
     1.1  mrg       if (((unsigned)(*c-'0'))<=9) continue; /* '0' through '9' is good */
     1.1  mrg       if (*c=='\0') break;		/* most common non-digit */
     1.1  mrg       if (*c=='.') {
     1.1  mrg 	if (dotchar!=NULL) break;	/* not first '.' */
     1.1  mrg 	dotchar=c;			/* record offset into decimal part */
     1.1  mrg 	continue;}
     1.1  mrg       if (c==string) {			/* first in string... */
     1.1  mrg 	if (*c=='-') {			/* valid - sign */
     1.1  mrg 	  cfirst++;
     1.1  mrg 	  num.sign=DECFLOAT_Sign;
     1.1  mrg 	  continue;}
     1.1  mrg 	if (*c=='+') {			/* valid + sign */
     1.1  mrg 	  cfirst++;
     1.1  mrg 	  continue;}
     1.1  mrg 	}
     1.1  mrg       /* *c is not a digit, terminator, or a valid +, -, or '.' */
     1.1  mrg       break;
     1.1  mrg       } /* c loop */
     1.1  mrg
     1.1  mrg     digits=(uInt)(c-cfirst);		/* digits (+1 if a dot) */
     1.1  mrg
     1.1  mrg     if (digits>0) {			/* had digits and/or dot */
     1.1  mrg       const char *clast=c-1;		/* note last coefficient char position */
     1.1  mrg       Int exp=0;			/* exponent accumulator */
     1.1  mrg       if (*c!='\0') {			/* something follows the coefficient */
     1.1  mrg 	uInt edig;			/* unsigned work */
     1.1  mrg 	/* had some digits and more to come; expect E[+|-]nnn now */
     1.1  mrg 	const char *firstexp;		/* exponent first non-zero */
     1.1  mrg 	if (*c!='E' && *c!='e') break;
     1.1  mrg 	c++;				/* to (optional) sign */
     1.1  mrg 	if (*c=='-' || *c=='+') c++;	/* step over sign (c=clast+2) */
     1.1  mrg 	if (*c=='\0') break;		/* no digits!  (e.g., '1.2E') */
     1.1  mrg 	for (; *c=='0';) c++;		/* skip leading zeros [even last] */
     1.1  mrg 	firstexp=c;			/* remember start [maybe '\0'] */
     1.1  mrg 	/* gather exponent digits */
     1.1  mrg 	edig=(uInt)*c-(uInt)'0';
     1.1  mrg 	if (edig<=9) {			/* [check not bad or terminator] */
     1.1  mrg 	  exp+=edig;			/* avoid initial X10 */
     1.1  mrg 	  c++;
     1.1  mrg 	  for (;; c++) {
     1.1  mrg 	    edig=(uInt)*c-(uInt)'0';
     1.1  mrg 	    if (edig>9) break;
     1.1  mrg 	    exp=exp*10+edig;
     1.1  mrg 	    }
     1.1  mrg 	  }
     1.1  mrg 	/* if not now on the '\0', *c must not be a digit */
     1.1  mrg 	if (*c!='\0') break;
     1.1  mrg
     1.1  mrg 	/* (this next test must be after the syntax checks) */
     1.1  mrg 	/* if definitely more than the possible digits for format then */
     1.1  mrg 	/* the exponent may have wrapped, so simply set it to a certain */
     1.1  mrg 	/* over/underflow value */
     1.1  mrg 	if (c>firstexp+DECEMAXD) exp=DECEMAX*2;
     1.1  mrg 	if (*(clast+2)=='-') exp=-exp;	/* was negative */
     1.1  mrg 	} /* digits>0 */
     1.1  mrg
     1.1  mrg       if (dotchar!=NULL) {		/* had a '.' */
     1.1  mrg 	digits--;			/* remove from digits count */
     1.1  mrg 	if (digits==0) break;		/* was dot alone: bad syntax */
     1.1  mrg 	exp-=(Int)(clast-dotchar);	/* adjust exponent */
     1.1  mrg 	/* [the '.' can now be ignored] */
     1.1  mrg 	}
     1.1  mrg       num.exponent=exp; 		/* exponent is good; store it */
     1.1  mrg
     1.1  mrg       /* Here when whole string has been inspected and syntax is good */
     1.1  mrg       /* cfirst->first digit or dot, clast->last digit or dot */
     1.1  mrg       error=0;				/* no error possible now */
     1.1  mrg
     1.1  mrg       /* if the number of digits in the coefficient will fit in buffer */
     1.1  mrg       /* then it can simply be converted to bcd8 and copied -- decFinalize */
     1.1  mrg       /* will take care of leading zeros and rounding; the buffer is big */
     1.1  mrg       /* enough for all canonical coefficients, including 0.00000nn... */
     1.1  mrg       ub=buffer;
     1.1  mrg       if (digits<=(Int)(sizeof(buffer)-3)) { /* [-3 allows by-4s copy] */
     1.1  mrg 	c=cfirst;
     1.1  mrg 	if (dotchar!=NULL) {		     /* a dot to worry about */
     1.1  mrg 	  if (*(c+1)=='.') {		     /* common canonical case */
     1.1  mrg 	    *ub++=(uByte)(*c-'0');	     /* copy leading digit */
     1.1  mrg 	    c+=2;			     /* prepare to handle rest */
     1.1  mrg 	    }
     1.1  mrg 	   else for (; c<=clast;) {	     /* '.' could be anywhere */
     1.1  mrg 	    /* as usual, go by fours when safe; NB it has been asserted */
     1.1  mrg 	    /* that a '.' does not have the same mask as a digit */
     1.1  mrg 	    if (c<=clast-3			       /* safe for four */
     1.1  mrg 	     && (UBTOUI(c)&0xf0f0f0f0)==CHARMASK) {    /* test four */
     1.1  mrg 	      UBFROMUI(ub, UBTOUI(c)&0x0f0f0f0f);      /* to BCD8 */
     1.1  mrg 	      ub+=4;
     1.1  mrg 	      c+=4;
     1.1  mrg 	      continue;
     1.1  mrg 	      }
     1.1  mrg 	    if (*c=='.') {		     /* found the dot */
     1.1  mrg 	      c++;			     /* step over it .. */
     1.1  mrg 	      break;			     /* .. and handle the rest */
     1.1  mrg 	      }
     1.1  mrg 	    *ub++=(uByte)(*c++-'0');
     1.1  mrg 	    }
     1.1  mrg 	  } /* had dot */
     1.1  mrg 	/* Now no dot; do this by fours (where safe) */
     1.1  mrg 	for (; c<=clast-3; c+=4, ub+=4) UBFROMUI(ub, UBTOUI(c)&0x0f0f0f0f);
     1.1  mrg 	for (; c<=clast; c++, ub++) *ub=(uByte)(*c-'0');
     1.1  mrg 	num.lsd=buffer+digits-1;	     /* record new LSD */
     1.1  mrg 	} /* fits */
     1.1  mrg
     1.1  mrg        else {				     /* too long for buffer */
     1.1  mrg 	/* [This is a rare and unusual case; arbitrary-length input] */
     1.1  mrg 	/* strip leading zeros [but leave final 0 if all 0's] */
     1.1  mrg 	if (*cfirst=='.') cfirst++;	     /* step past dot at start */
     1.1  mrg 	if (*cfirst=='0') {		     /* [cfirst always -> digit] */
     1.1  mrg 	  for (; cfirst<clast; cfirst++) {
     1.1  mrg 	    if (*cfirst!='0') { 	     /* non-zero found */
     1.1  mrg 	      if (*cfirst=='.') continue;    /* [ignore] */
     1.1  mrg 	      break;			     /* done */
     1.1  mrg 	      }
     1.1  mrg 	    digits--;			     /* 0 stripped */
     1.1  mrg 	    } /* cfirst */
     1.1  mrg 	  } /* at least one leading 0 */
     1.1  mrg
     1.1  mrg 	/* the coefficient is now as short as possible, but may still */
     1.1  mrg 	/* be too long; copy up to Pmax+1 digits to the buffer, then */
     1.1  mrg 	/* just record any non-zeros (set round-for-reround digit) */
     1.1  mrg 	for (c=cfirst; c<=clast && ub<=buffer+DECPMAX; c++) {
     1.1  mrg 	  /* (see commentary just above) */
     1.1  mrg 	  if (c<=clast-3			  /* safe for four */
     1.1  mrg 	   && (UBTOUI(c)&0xf0f0f0f0)==CHARMASK) { /* four digits */
     1.1  mrg 	    UBFROMUI(ub, UBTOUI(c)&0x0f0f0f0f);   /* to BCD8 */
     1.1  mrg 	    ub+=4;
     1.1  mrg 	    c+=3;			     /* [will become 4] */
     1.1  mrg 	    continue;
     1.1  mrg 	    }
     1.1  mrg 	  if (*c=='.') continue;	     /* [ignore] */
     1.1  mrg 	  *ub++=(uByte)(*c-'0');
     1.1  mrg 	  }
     1.1  mrg 	ub--;				     /* -> LSD */
     1.1  mrg 	for (; c<=clast; c++) { 	     /* inspect remaining chars */
     1.1  mrg 	  if (*c!='0') {		     /* sticky bit needed */
     1.1  mrg 	    if (*c=='.') continue;	     /* [ignore] */
     1.1  mrg 	    *ub=DECSTICKYTAB[*ub];	     /* update round-for-reround */
     1.1  mrg 	    break;			     /* no need to look at more */
     1.1  mrg 	    }
     1.1  mrg 	  }
     1.1  mrg 	num.lsd=ub;			     /* record LSD */
     1.1  mrg 	/* adjust exponent for dropped digits */
     1.1  mrg 	num.exponent+=digits-(Int)(ub-buffer+1);
     1.1  mrg 	} /* too long for buffer */
     1.1  mrg       } /* digits or dot */
     1.1  mrg
     1.1  mrg      else {				/* no digits or dot were found */
     1.1  mrg       if (*c=='\0') break;		/* nothing to come is bad */
     1.1  mrg       /* only Infinities and NaNs are allowed, here */
     1.1  mrg       buffer[0]=0;			/* default a coefficient of 0 */
     1.1  mrg       num.lsd=buffer;			/* .. */
     1.1  mrg       if (decBiStr(c, "infinity", "INFINITY")
     1.1  mrg        || decBiStr(c, "inf", "INF")) num.exponent=DECFLOAT_Inf;
     1.1  mrg        else {				/* should be a NaN */
     1.1  mrg 	num.exponent=DECFLOAT_qNaN;	/* assume quiet NaN */
     1.1  mrg 	if (*c=='s' || *c=='S') {	/* probably an sNaN */
     1.1  mrg 	  c++;
     1.1  mrg 	  num.exponent=DECFLOAT_sNaN;	/* assume is in fact sNaN */
     1.1  mrg 	  }
     1.1  mrg 	if (*c!='N' && *c!='n') break;	/* check caseless "NaN" */
     1.1  mrg 	c++;
     1.1  mrg 	if (*c!='a' && *c!='A') break;	/* .. */
     1.1  mrg 	c++;
     1.1  mrg 	if (*c!='N' && *c!='n') break;	/* .. */
     1.1  mrg 	c++;
     1.1  mrg 	/* now either nothing, or nnnn payload (no dots), expected */
     1.1  mrg 	/* -> start of integer, and skip leading 0s [including plain 0] */
     1.1  mrg 	for (cfirst=c; *cfirst=='0';) cfirst++;
     1.1  mrg 	if (*cfirst!='\0') {		/* not empty or all-0, payload */
     1.1  mrg 	  /* payload found; check all valid digits and copy to buffer as bcd8 */
     1.1  mrg 	  ub=buffer;
     1.1  mrg 	  for (c=cfirst;; c++, ub++) {
     1.1  mrg 	    if ((unsigned)(*c-'0')>9) break; /* quit if not 0-9 */
     1.1  mrg 	    if (c-cfirst==DECPMAX-1) break;  /* too many digits */
     1.1  mrg 	    *ub=(uByte)(*c-'0');	/* good bcd8 */
     1.1  mrg 	    }
     1.1  mrg 	  if (*c!='\0') break;		/* not all digits, or too many */
     1.1  mrg 	  num.lsd=ub-1; 		/* record new LSD */
     1.1  mrg 	  }
     1.1  mrg 	} /* NaN or sNaN */
     1.1  mrg       error=0;				/* syntax is OK */
     1.1  mrg       break;				/* done with specials */
     1.1  mrg       } /* digits=0 (special expected) */
     1.1  mrg     break;
     1.1  mrg     }					/* [for(;;) break] */
     1.1  mrg
     1.1  mrg   /* decShowNum(&num, "fromStr"); */
     1.1  mrg
     1.1  mrg   if (error!=0) {
     1.1  mrg     set->status|=error;
     1.1  mrg     num.exponent=DECFLOAT_qNaN; 	/* set up quiet NaN */
     1.1  mrg     num.sign=0; 			/* .. with 0 sign */
     1.1  mrg     buffer[0]=0;			/* .. and coefficient */
     1.1  mrg     num.lsd=buffer;			/* .. */
     1.1  mrg     /* decShowNum(&num, "oops"); */
     1.1  mrg     }
     1.1  mrg
     1.1  mrg   /* decShowNum(&num, "dffs"); */
     1.1  mrg   decFinalize(result, &num, set);	/* round, check, and lay out */
     1.1  mrg   /* decFloatShow(result, "fromString"); */
     1.1  mrg   return result;
     1.1  mrg   } /* decFloatFromString */
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* decFloatFromWider -- conversion from next-wider format	      */
     1.1  mrg /*								      */
     1.1  mrg /*  result  is the decFloat format number which gets the result of    */
     1.1  mrg /*	    the conversion					      */
     1.1  mrg /*  wider   is the decFloatWider format number which will be narrowed */
     1.1  mrg /*  set     is the context					      */
     1.1  mrg /*  returns result						      */
     1.1  mrg /*								      */
     1.1  mrg /* Narrowing can cause rounding, overflow, etc., but not Invalid      */
     1.1  mrg /* operation (sNaNs are copied and do not signal).		      */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* narrow-to is not possible for decQuad format numbers; simply omit */
     1.1  mrg #if !QUAD
     1.1  mrg decFloat * decFloatFromWider(decFloat *result, const decFloatWider *wider,
     1.1  mrg 			     decContext *set) {
     1.1  mrg   bcdnum num;				/* collects data for finishing */
     1.1  mrg   uByte  bcdar[DECWPMAX];		/* room for wider coefficient */
     1.1  mrg   uInt	 widerhi=DFWWORD(wider, 0);	/* top word */
     1.1  mrg   Int	 exp;
     1.1  mrg
     1.1  mrg   GETWCOEFF(wider, bcdar);
     1.1  mrg
     1.1  mrg   num.msd=bcdar;			/* MSD is here always */
     1.1  mrg   num.lsd=bcdar+DECWPMAX-1;		/* LSD is here always */
     1.1  mrg   num.sign=widerhi&0x80000000;		/* extract sign [DECFLOAT_Sign=Neg] */
     1.1  mrg
     1.1  mrg   /* decode the wider combination field to exponent */
     1.1  mrg   exp=DECCOMBWEXP[widerhi>>26]; 	/* decode from wider combination field */
     1.1  mrg   /* if it is a special there's nothing to do unless sNaN; if it's */
     1.1  mrg   /* finite then add the (wider) exponent continuation and unbias */
     1.1  mrg   if (EXPISSPECIAL(exp)) exp=widerhi&0x7e000000; /* include sNaN selector */
     1.1  mrg    else exp+=GETWECON(wider)-DECWBIAS;
     1.1  mrg   num.exponent=exp;
     1.1  mrg
     1.1  mrg   /* decShowNum(&num, "dffw"); */
     1.1  mrg   return decFinalize(result, &num, set);/* round, check, and lay out */
     1.1  mrg   } /* decFloatFromWider */
     1.1  mrg #endif
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* decFloatGetCoefficient -- get coefficient as BCD8		      */
     1.1  mrg /*								      */
     1.1  mrg /*  df is the decFloat from which to extract the coefficient	      */
     1.1  mrg /*  bcdar is where DECPMAX bytes will be written, one BCD digit in    */
     1.1  mrg /*    each byte (BCD8 encoding); if df is a NaN the first byte will   */
     1.1  mrg /*    be zero, and if it is infinite they will all be zero	      */
     1.1  mrg /*  returns the sign of the coefficient (DECFLOAT_Sign if negative,   */
     1.1  mrg /*    0 otherwise)						      */
     1.1  mrg /*								      */
     1.1  mrg /* No error is possible, and no status will be set.  If df is a       */
     1.1  mrg /* special value the array is set to zeros (for Infinity) or to the   */
     1.1  mrg /* payload of a qNaN or sNaN.					      */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg Int decFloatGetCoefficient(const decFloat *df, uByte *bcdar) {
     1.1  mrg   if (DFISINF(df)) memset(bcdar, 0, DECPMAX);
     1.1  mrg    else {
     1.1  mrg     GETCOEFF(df, bcdar);	   /* use macro */
     1.1  mrg     if (DFISNAN(df)) bcdar[0]=0;   /* MSD needs correcting */
     1.1  mrg     }
     1.1  mrg   return DFISSIGNED(df);
     1.1  mrg   } /* decFloatGetCoefficient */
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* decFloatGetExponent -- get unbiased exponent 		      */
     1.1  mrg /*								      */
     1.1  mrg /*  df is the decFloat from which to extract the exponent	      */
     1.1  mrg /*  returns the exponent, q.					      */
     1.1  mrg /*								      */
     1.1  mrg /* No error is possible, and no status will be set.  If df is a       */
     1.1  mrg /* special value the first seven bits of the decFloat are returned,   */
     1.1  mrg /* left adjusted and with the first (sign) bit set to 0 (followed by  */
     1.1  mrg /* 25 0 bits).	e.g., -sNaN would return 0x7e000000 (DECFLOAT_sNaN).  */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg Int decFloatGetExponent(const decFloat *df) {
     1.1  mrg   if (DFISSPECIAL(df)) return DFWORD(df, 0)&0x7e000000;
     1.1  mrg   return GETEXPUN(df);
     1.1  mrg   } /* decFloatGetExponent */
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* decFloatSetCoefficient -- set coefficient from BCD8		      */
     1.1  mrg /*								      */
     1.1  mrg /*  df is the target decFloat (and source of exponent/special value)  */
     1.1  mrg /*  bcdar holds DECPMAX digits to set the coefficient from, one       */
     1.1  mrg /*    digit in each byte (BCD8 encoding); the first (MSD) is ignored  */
     1.1  mrg /*    if df is a NaN; all are ignored if df is infinite.	      */
     1.1  mrg /*  sig is DECFLOAT_Sign to set the sign bit, 0 otherwise	      */
     1.1  mrg /*  returns df, which will be canonical 			      */
     1.1  mrg /*								      */
     1.1  mrg /* No error is possible, and no status will be set.		      */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg decFloat * decFloatSetCoefficient(decFloat *df, const uByte *bcdar,
     1.1  mrg 				  Int sig) {
     1.1  mrg   uInt exp;			   /* for exponent */
     1.1  mrg   uByte bcdzero[DECPMAX];	   /* for infinities */
     1.1  mrg
     1.1  mrg   /* Exponent/special code is extracted from df */
     1.1  mrg   if (DFISSPECIAL(df)) {
     1.1  mrg     exp=DFWORD(df, 0)&0x7e000000;
     1.1  mrg     if (DFISINF(df)) {
     1.1  mrg       memset(bcdzero, 0, DECPMAX);
     1.1  mrg       return decFloatFromBCD(df, exp, bcdzero, sig);
     1.1  mrg       }
     1.1  mrg     }
     1.1  mrg    else exp=GETEXPUN(df);
     1.1  mrg   return decFloatFromBCD(df, exp, bcdar, sig);
     1.1  mrg   } /* decFloatSetCoefficient */
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* decFloatSetExponent -- set exponent or special value 	      */
     1.1  mrg /*								      */
     1.1  mrg /*  df	is the target decFloat (and source of coefficient/payload)    */
     1.1  mrg /*  set is the context for reporting status			      */
     1.1  mrg /*  exp is the unbiased exponent, q, or a special value in the form   */
     1.1  mrg /*    returned by decFloatGetExponent				      */
     1.1  mrg /*  returns df, which will be canonical 			      */
     1.1  mrg /*								      */
     1.1  mrg /* No error is possible, but Overflow or Underflow might occur.       */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg decFloat * decFloatSetExponent(decFloat *df, decContext *set, Int exp) {
     1.1  mrg   uByte  bcdcopy[DECPMAX];	   /* for coefficient */
     1.1  mrg   bcdnum num;			   /* work */
     1.1  mrg   num.exponent=exp;
     1.1  mrg   num.sign=decFloatGetCoefficient(df, bcdcopy); /* extract coefficient */
     1.1  mrg   if (DFISSPECIAL(df)) {	   /* MSD or more needs correcting */
     1.1  mrg     if (DFISINF(df)) memset(bcdcopy, 0, DECPMAX);
     1.1  mrg     bcdcopy[0]=0;
     1.1  mrg     }
     1.1  mrg   num.msd=bcdcopy;
     1.1  mrg   num.lsd=bcdcopy+DECPMAX-1;
     1.1  mrg   return decFinalize(df, &num, set);
     1.1  mrg   } /* decFloatSetExponent */
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* decFloatRadix -- returns the base (10)			      */
     1.1  mrg /*								      */
     1.1  mrg /*   df is any decFloat of this format				      */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg uInt decFloatRadix(const decFloat *df) {
     1.1  mrg   if (df) return 10;			     /* to placate compiler */
     1.1  mrg   return 10;
     1.1  mrg   } /* decFloatRadix */
     1.1  mrg
     1.1  mrg #if (DECCHECK || DECTRACE)
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* decFloatShow -- printf a decFloat in hexadecimal and decimal       */
     1.1  mrg /*   df  is the decFloat to show				      */
     1.1  mrg /*   tag is a tag string displayed with the number		      */
     1.1  mrg /*								      */
     1.1  mrg /* This is a debug aid; the precise format of the string may change.  */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg void decFloatShow(const decFloat *df, const char *tag) {
     1.1  mrg   char hexbuf[DECBYTES*2+DECBYTES/4+1]; /* NB blank after every fourth */
     1.1  mrg   char buff[DECSTRING]; 		/* for value in decimal */
     1.1  mrg   Int i, j=0;
     1.1  mrg
     1.1  mrg   for (i=0; i<DECBYTES; i++) {
     1.1  mrg     #if DECLITEND
     1.1  mrg       sprintf(&hexbuf[j], "%02x", df->bytes[DECBYTES-1-i]);
     1.1  mrg     #else
     1.1  mrg       sprintf(&hexbuf[j], "%02x", df->bytes[i]);
     1.1  mrg     #endif
     1.1  mrg     j+=2;
     1.1  mrg     /* the next line adds blank (and terminator) after final pair, too */
     1.1  mrg     if ((i+1)%4==0) {strcpy(&hexbuf[j], " "); j++;}
     1.1  mrg     }
     1.1  mrg   decFloatToString(df, buff);
     1.1  mrg   printf(">%s> %s [big-endian]	%s\n", tag, hexbuf, buff);
     1.1  mrg   return;
     1.1  mrg   } /* decFloatShow */
     1.1  mrg #endif
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* decFloatToBCD -- get sign, exponent, and BCD8 from a decFloat      */
     1.1  mrg /*								      */
     1.1  mrg /*  df is the source decFloat					      */
     1.1  mrg /*  exp will be set to the unbiased exponent, q, or to a special      */
     1.1  mrg /*    value in the form returned by decFloatGetExponent 	      */
     1.1  mrg /*  bcdar is where DECPMAX bytes will be written, one BCD digit in    */
     1.1  mrg /*    each byte (BCD8 encoding); if df is a NaN the first byte will   */
     1.1  mrg /*    be zero, and if it is infinite they will all be zero	      */
     1.1  mrg /*  returns the sign of the coefficient (DECFLOAT_Sign if negative,   */
     1.1  mrg /*    0 otherwise)						      */
     1.1  mrg /*								      */
     1.1  mrg /* No error is possible, and no status will be set.		      */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg Int decFloatToBCD(const decFloat *df, Int *exp, uByte *bcdar) {
     1.1  mrg   if (DFISINF(df)) {
     1.1  mrg     memset(bcdar, 0, DECPMAX);
     1.1  mrg     *exp=DFWORD(df, 0)&0x7e000000;
     1.1  mrg     }
     1.1  mrg    else {
     1.1  mrg     GETCOEFF(df, bcdar);	   /* use macro */
     1.1  mrg     if (DFISNAN(df)) {
     1.1  mrg       bcdar[0]=0;		   /* MSD needs correcting */
     1.1  mrg       *exp=DFWORD(df, 0)&0x7e000000;
     1.1  mrg       }
     1.1  mrg      else {			   /* finite */
     1.1  mrg       *exp=GETEXPUN(df);
     1.1  mrg       }
     1.1  mrg     }
     1.1  mrg   return DFISSIGNED(df);
     1.1  mrg   } /* decFloatToBCD */
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* decFloatToEngString -- conversion to numeric string, engineering   */
     1.1  mrg /*								      */
     1.1  mrg /*  df is the decFloat format number to convert 		      */
     1.1  mrg /*  string is the string where the result will be laid out	      */
     1.1  mrg /*								      */
     1.1  mrg /* string must be at least DECPMAX+9 characters (the worst case is    */
     1.1  mrg /* "-0.00000nnn...nnn\0", which is as long as the exponent form when  */
     1.1  mrg /* DECEMAXD<=4); this condition is asserted above		      */
     1.1  mrg /*								      */
     1.1  mrg /* No error is possible, and no status will be set		      */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg char * decFloatToEngString(const decFloat *df, char *string){
     1.1  mrg   uInt msd;			   /* coefficient MSD */
     1.1  mrg   Int  exp;			   /* exponent top two bits or full */
     1.1  mrg   uInt comb;			   /* combination field */
     1.1  mrg   char *cstart; 		   /* coefficient start */
     1.1  mrg   char *c;			   /* output pointer in string */
     1.1  mrg   char *s, *t;			   /* .. (source, target) */
     1.1  mrg   Int  pre, e;			   /* work */
     1.1  mrg   const uByte *u;		   /* .. */
     1.1  mrg   uInt	uiwork; 		   /* for macros [one compiler needs */
     1.1  mrg 				   /* volatile here to avoid bug, but */
     1.1  mrg 				   /* that doubles execution time] */
     1.1  mrg
     1.1  mrg   /* Source words; macro handles endianness */
     1.1  mrg   uInt sourhi=DFWORD(df, 0);	   /* word with sign */
     1.1  mrg   #if DECPMAX==16
     1.1  mrg   uInt sourlo=DFWORD(df, 1);
     1.1  mrg   #elif DECPMAX==34
     1.1  mrg   uInt sourmh=DFWORD(df, 1);
     1.1  mrg   uInt sourml=DFWORD(df, 2);
     1.1  mrg   uInt sourlo=DFWORD(df, 3);
     1.1  mrg   #endif
     1.1  mrg
     1.1  mrg   c=string;			   /* where result will go */
     1.1  mrg   if (((Int)sourhi)<0) *c++='-';   /* handle sign */
     1.1  mrg   comb=sourhi>>26;		   /* sign+combination field */
     1.1  mrg   msd=DECCOMBMSD[comb]; 	   /* decode the combination field */
     1.1  mrg   exp=DECCOMBEXP[comb]; 	   /* .. */
     1.1  mrg
     1.1  mrg   if (EXPISSPECIAL(exp)) {	   /* special */
     1.1  mrg     if (exp==DECFLOAT_Inf) {	   /* infinity */
     1.1  mrg       strcpy(c,   "Inf");
     1.1  mrg       strcpy(c+3, "inity");
     1.1  mrg       return string;		   /* easy */
     1.1  mrg       }
     1.1  mrg     if (sourhi&0x02000000) *c++='s'; /* sNaN */
     1.1  mrg     strcpy(c, "NaN");		   /* complete word */
     1.1  mrg     c+=3;			   /* step past */
     1.1  mrg     /* quick exit if the payload is zero */
     1.1  mrg     #if DECPMAX==7
     1.1  mrg     if ((sourhi&0x000fffff)==0) return string;
     1.1  mrg     #elif DECPMAX==16
     1.1  mrg     if (sourlo==0 && (sourhi&0x0003ffff)==0) return string;
     1.1  mrg     #elif DECPMAX==34
     1.1  mrg     if (sourlo==0 && sourml==0 && sourmh==0
     1.1  mrg      && (sourhi&0x00003fff)==0) return string;
     1.1  mrg     #endif
     1.1  mrg     /* otherwise drop through to add integer; set correct exp etc. */
     1.1  mrg     exp=0; msd=0;		   /* setup for following code */
     1.1  mrg     }
     1.1  mrg    else { /* complete exponent; top two bits are in place */
     1.1  mrg     exp+=GETECON(df)-DECBIAS;	   /* .. + continuation and unbias */
     1.1  mrg     }
     1.1  mrg
     1.1  mrg   /* convert the digits of the significand to characters */
     1.1  mrg   cstart=c;			   /* save start of coefficient */
     1.1  mrg   if (msd) *c++=(char)('0'+(char)msd);	/* non-zero most significant digit */
     1.1  mrg
     1.1  mrg   /* Decode the declets.  After extracting each declet, it is */
     1.1  mrg   /* decoded to a 4-uByte sequence by table lookup; the four uBytes */
     1.1  mrg   /* are the three encoded BCD8 digits followed by a 1-byte length */
     1.1  mrg   /* (significant digits, except that 000 has length 0).  This allows */
     1.1  mrg   /* us to left-align the first declet with non-zero content, then */
     1.1  mrg   /* the remaining ones are full 3-char length.  Fixed-length copies */
     1.1  mrg   /* are used because variable-length memcpy causes a subroutine call */
     1.1  mrg   /* in at least two compilers.  (The copies are length 4 for speed */
     1.1  mrg   /* and are safe because the last item in the array is of length */
     1.1  mrg   /* three and has the length byte following.) */
     1.1  mrg   #define dpd2char(dpdin) u=&DPD2BCD8[((dpdin)&0x3ff)*4];	 \
     1.1  mrg 	 if (c!=cstart) {UBFROMUI(c, UBTOUI(u)|CHARMASK); c+=3;} \
     1.1  mrg 	  else if (*(u+3)) {					 \
     1.1  mrg 	   UBFROMUI(c, UBTOUI(u+3-*(u+3))|CHARMASK); c+=*(u+3);}
     1.1  mrg
     1.1  mrg   #if DECPMAX==7
     1.1  mrg   dpd2char(sourhi>>10); 		/* declet 1 */
     1.1  mrg   dpd2char(sourhi);			/* declet 2 */
     1.1  mrg
     1.1  mrg   #elif DECPMAX==16
     1.1  mrg   dpd2char(sourhi>>8);			/* declet 1 */
     1.1  mrg   dpd2char((sourhi<<2) | (sourlo>>30)); /* declet 2 */
     1.1  mrg   dpd2char(sourlo>>20); 		/* declet 3 */
     1.1  mrg   dpd2char(sourlo>>10); 		/* declet 4 */
     1.1  mrg   dpd2char(sourlo);			/* declet 5 */
     1.1  mrg
     1.1  mrg   #elif DECPMAX==34
     1.1  mrg   dpd2char(sourhi>>4);			/* declet 1 */
     1.1  mrg   dpd2char((sourhi<<6) | (sourmh>>26)); /* declet 2 */
     1.1  mrg   dpd2char(sourmh>>16); 		/* declet 3 */
     1.1  mrg   dpd2char(sourmh>>6);			/* declet 4 */
     1.1  mrg   dpd2char((sourmh<<4) | (sourml>>28)); /* declet 5 */
     1.1  mrg   dpd2char(sourml>>18); 		/* declet 6 */
     1.1  mrg   dpd2char(sourml>>8);			/* declet 7 */
     1.1  mrg   dpd2char((sourml<<2) | (sourlo>>30)); /* declet 8 */
     1.1  mrg   dpd2char(sourlo>>20); 		/* declet 9 */
     1.1  mrg   dpd2char(sourlo>>10); 		/* declet 10 */
     1.1  mrg   dpd2char(sourlo);			/* declet 11 */
     1.1  mrg   #endif
     1.1  mrg
     1.1  mrg   if (c==cstart) *c++='0';	   /* all zeros, empty -- make "0" */
     1.1  mrg
     1.1  mrg   if (exp==0) { 		   /* integer or NaN case -- easy */
     1.1  mrg     *c='\0';			   /* terminate */
     1.1  mrg     return string;
     1.1  mrg     }
     1.1  mrg   /* non-0 exponent */
     1.1  mrg
     1.1  mrg   e=0;				   /* assume no E */
     1.1  mrg   pre=(Int)(c-cstart)+exp;	   /* length+exp  [c->LSD+1] */
     1.1  mrg   /* [here, pre-exp is the digits count (==1 for zero)] */
     1.1  mrg
     1.1  mrg   if (exp>0 || pre<-5) {	   /* need exponential form */
     1.1  mrg     e=pre-1;			   /* calculate E value */
     1.1  mrg     pre=1;			   /* assume one digit before '.' */
     1.1  mrg     if (e!=0) { 		   /* engineering: may need to adjust */
     1.1  mrg       Int adj;			   /* adjustment */
     1.1  mrg       /* The C remainder operator is undefined for negative numbers, so */
     1.1  mrg       /* a positive remainder calculation must be used here */
     1.1  mrg       if (e<0) {
     1.1  mrg 	adj=(-e)%3;
     1.1  mrg 	if (adj!=0) adj=3-adj;
     1.1  mrg 	}
     1.1  mrg        else { /* e>0 */
     1.1  mrg 	adj=e%3;
     1.1  mrg 	}
     1.1  mrg       e=e-adj;
     1.1  mrg       /* if dealing with zero still produce an exponent which is a */
     1.1  mrg       /* multiple of three, as expected, but there will only be the */
     1.1  mrg       /* one zero before the E, still.	Otherwise note the padding. */
     1.1  mrg       if (!DFISZERO(df)) pre+=adj;
     1.1  mrg        else {  /* is zero */
     1.1  mrg 	if (adj!=0) {		   /* 0.00Esnn needed */
     1.1  mrg 	  e=e+3;
     1.1  mrg 	  pre=-(2-adj);
     1.1  mrg 	  }
     1.1  mrg 	} /* zero */
     1.1  mrg       } /* engineering adjustment */
     1.1  mrg     } /* exponential form */
     1.1  mrg   /* printf("e=%ld pre=%ld exp=%ld\n", (LI)e, (LI)pre, (LI)exp); */
     1.1  mrg
     1.1  mrg   /* modify the coefficient, adding 0s, '.', and E+nn as needed */
     1.1  mrg   if (pre>0) {			   /* ddd.ddd (plain), perhaps with E */
     1.1  mrg 				   /* or dd00 padding for engineering */
     1.1  mrg     char *dotat=cstart+pre;
     1.1  mrg     if (dotat<c) {			/* if embedded dot needed... */
     1.1  mrg       /* move by fours; there must be space for junk at the end */
     1.1  mrg       /* because there is still space for exponent */
     1.1  mrg       s=dotat+ROUNDDOWN4(c-dotat);	/* source */
     1.1  mrg       t=s+1;				/* target */
     1.1  mrg       /* open the gap [cannot use memcpy] */
     1.1  mrg       for (; s>=dotat; s-=4, t-=4) UBFROMUI(t, UBTOUI(s));
     1.1  mrg       *dotat='.';
     1.1  mrg       c++;				/* length increased by one */
     1.1  mrg       } /* need dot? */
     1.1  mrg      else for (; c<dotat; c++) *c='0';	/* pad for engineering */
     1.1  mrg     } /* pre>0 */
     1.1  mrg    else {
     1.1  mrg     /* -5<=pre<=0: here for plain 0.ddd or 0.000ddd forms (may have
     1.1  mrg        E, but only for 0.00E+3 kind of case -- with plenty of spare
     1.1  mrg        space in this case */
     1.1  mrg     pre=-pre+2; 			/* gap width, including "0." */
     1.1  mrg     t=cstart+ROUNDDOWN4(c-cstart)+pre;	/* preferred first target point */
     1.1  mrg     /* backoff if too far to the right */
     1.1  mrg     if (t>string+DECSTRING-5) t=string+DECSTRING-5; /* adjust to fit */
     1.1  mrg     /* now shift the entire coefficient to the right, being careful not */
     1.1  mrg     /* to access to the left of string [cannot use memcpy] */
     1.1  mrg     for (s=t-pre; s>=string; s-=4, t-=4) UBFROMUI(t, UBTOUI(s));
     1.1  mrg     /* for Quads and Singles there may be a character or two left... */
     1.1  mrg     s+=3;				/* where next would come from */
     1.1  mrg     for(; s>=cstart; s--, t--) *(t+3)=*(s);
     1.1  mrg     /* now have fill 0. through 0.00000; use overlaps to avoid tests */
     1.1  mrg     if (pre>=4) {
     1.1  mrg       memcpy(cstart+pre-4, "0000", 4);
     1.1  mrg       memcpy(cstart, "0.00", 4);
     1.1  mrg       }
     1.1  mrg      else { /* 2 or 3 */
     1.1  mrg       *(cstart+pre-1)='0';
     1.1  mrg       memcpy(cstart, "0.", 2);
     1.1  mrg       }
     1.1  mrg     c+=pre;				/* to end */
     1.1  mrg     }
     1.1  mrg
     1.1  mrg   /* finally add the E-part, if needed; it will never be 0, and has */
     1.1  mrg   /* a maximum length of 3 or 4 digits (asserted above) */
     1.1  mrg   if (e!=0) {
     1.1  mrg     memcpy(c, "E+", 2); 		/* starts with E, assume + */
     1.1  mrg     c++;
     1.1  mrg     if (e<0) {
     1.1  mrg       *c='-';				/* oops, need '-' */
     1.1  mrg       e=-e;				/* uInt, please */
     1.1  mrg       }
     1.1  mrg     c++;
     1.1  mrg     /* Three-character exponents are easy; 4-character a little trickier */
     1.1  mrg     #if DECEMAXD<=3
     1.1  mrg       u=&BIN2BCD8[e*4]; 		/* -> 3 digits + length byte */
     1.1  mrg       /* copy fixed 4 characters [is safe], starting at non-zero */
     1.1  mrg       /* and with character mask to convert BCD to char */
     1.1  mrg       UBFROMUI(c, UBTOUI(u+3-*(u+3))|CHARMASK);
     1.1  mrg       c+=*(u+3);			/* bump pointer appropriately */
     1.1  mrg     #elif DECEMAXD==4
     1.1  mrg       if (e<1000) {			/* 3 (or fewer) digits case */
     1.1  mrg 	u=&BIN2BCD8[e*4];		/* -> 3 digits + length byte */
     1.1  mrg 	UBFROMUI(c, UBTOUI(u+3-*(u+3))|CHARMASK); /* [as above] */
     1.1  mrg 	c+=*(u+3);			/* bump pointer appropriately */
     1.1  mrg 	}
     1.1  mrg        else {				/* 4-digits */
     1.1  mrg 	Int thou=((e>>3)*1049)>>17;	/* e/1000 */
     1.1  mrg 	Int rem=e-(1000*thou);		/* e%1000 */
     1.1  mrg 	*c++=(char)('0'+(char)thou);	/* the thousands digit */
     1.1  mrg 	u=&BIN2BCD8[rem*4];		/* -> 3 digits + length byte */
     1.1  mrg 	UBFROMUI(c, UBTOUI(u)|CHARMASK);/* copy fixed 3+1 characters [is safe] */
     1.1  mrg 	c+=3;				/* bump pointer, always 3 digits */
     1.1  mrg 	}
     1.1  mrg     #endif
     1.1  mrg     }
     1.1  mrg   *c='\0';				/* terminate */
     1.1  mrg   /*printf("res %s\n", string); */
     1.1  mrg   return string;
     1.1  mrg   } /* decFloatToEngString */
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* decFloatToPacked -- convert decFloat to Packed decimal + exponent  */
     1.1  mrg /*								      */
     1.1  mrg /*  df is the source decFloat					      */
     1.1  mrg /*  exp will be set to the unbiased exponent, q, or to a special      */
     1.1  mrg /*    value in the form returned by decFloatGetExponent 	      */
     1.1  mrg /*  packed is where DECPMAX nibbles will be written with the sign as  */
     1.1  mrg /*    final nibble (0x0c for +, 0x0d for -); a NaN has a first nibble */
     1.1  mrg /*    of zero, and an infinity is all zeros. decDouble and decQuad    */
     1.1  mrg /*    have a additional leading zero nibble, leading to result	      */
     1.1  mrg /*    lengths of 4, 9, and 18 bytes.				      */
     1.1  mrg /*  returns the sign of the coefficient (DECFLOAT_Sign if negative,   */
     1.1  mrg /*    0 otherwise)						      */
     1.1  mrg /*								      */
     1.1  mrg /* No error is possible, and no status will be set.		      */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg Int decFloatToPacked(const decFloat *df, Int *exp, uByte *packed) {
     1.1  mrg   uByte bcdar[DECPMAX+2];	   /* work buffer */
     1.1  mrg   uByte *ip=bcdar, *op=packed;	   /* work pointers */
     1.1  mrg   if (DFISINF(df)) {
     1.1  mrg     memset(bcdar, 0, DECPMAX+2);
     1.1  mrg     *exp=DECFLOAT_Inf;
     1.1  mrg     }
     1.1  mrg    else {
     1.1  mrg     GETCOEFF(df, bcdar+1);	   /* use macro */
     1.1  mrg     if (DFISNAN(df)) {
     1.1  mrg       bcdar[1]=0;		   /* MSD needs clearing */
     1.1  mrg       *exp=DFWORD(df, 0)&0x7e000000;
     1.1  mrg       }
     1.1  mrg      else {			   /* finite */
     1.1  mrg       *exp=GETEXPUN(df);
     1.1  mrg       }
     1.1  mrg     }
     1.1  mrg   /* now pack; coefficient currently at bcdar+1 */
     1.1  mrg   #if SINGLE
     1.1  mrg     ip++;			   /* ignore first byte */
     1.1  mrg   #else
     1.1  mrg     *ip=0;			   /* need leading zero */
     1.1  mrg   #endif
     1.1  mrg   /* set final byte to Packed BCD sign value */
     1.1  mrg   bcdar[DECPMAX+1]=(DFISSIGNED(df) ? DECPMINUS : DECPPLUS);
     1.1  mrg   /* pack an even number of bytes... */
     1.1  mrg   for (; op<packed+((DECPMAX+2)/2); op++, ip+=2) {
     1.1  mrg     *op=(uByte)((*ip<<4)+*(ip+1));
     1.1  mrg     }
     1.1  mrg   return (bcdar[DECPMAX+1]==DECPMINUS ? DECFLOAT_Sign : 0);
     1.1  mrg   } /* decFloatToPacked */
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* decFloatToString -- conversion to numeric string		      */
     1.1  mrg /*								      */
     1.1  mrg /*  df is the decFloat format number to convert 		      */
     1.1  mrg /*  string is the string where the result will be laid out	      */
     1.1  mrg /*								      */
     1.1  mrg /* string must be at least DECPMAX+9 characters (the worst case is    */
     1.1  mrg /* "-0.00000nnn...nnn\0", which is as long as the exponent form when  */
     1.1  mrg /* DECEMAXD<=4); this condition is asserted above		      */
     1.1  mrg /*								      */
     1.1  mrg /* No error is possible, and no status will be set		      */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg char * decFloatToString(const decFloat *df, char *string){
     1.1  mrg   uInt msd;			   /* coefficient MSD */
     1.1  mrg   Int  exp;			   /* exponent top two bits or full */
     1.1  mrg   uInt comb;			   /* combination field */
     1.1  mrg   char *cstart; 		   /* coefficient start */
     1.1  mrg   char *c;			   /* output pointer in string */
     1.1  mrg   char *s, *t;			   /* .. (source, target) */
     1.1  mrg   Int  pre, e;			   /* work */
     1.1  mrg   const uByte *u;		   /* .. */
     1.1  mrg   uInt	uiwork; 		   /* for macros [one compiler needs */
     1.1  mrg 				   /* volatile here to avoid bug, but */
     1.1  mrg 				   /* that doubles execution time] */
     1.1  mrg
     1.1  mrg   /* Source words; macro handles endianness */
     1.1  mrg   uInt sourhi=DFWORD(df, 0);	   /* word with sign */
     1.1  mrg   #if DECPMAX==16
     1.1  mrg   uInt sourlo=DFWORD(df, 1);
     1.1  mrg   #elif DECPMAX==34
     1.1  mrg   uInt sourmh=DFWORD(df, 1);
     1.1  mrg   uInt sourml=DFWORD(df, 2);
     1.1  mrg   uInt sourlo=DFWORD(df, 3);
     1.1  mrg   #endif
     1.1  mrg
     1.1  mrg   c=string;			   /* where result will go */
     1.1  mrg   if (((Int)sourhi)<0) *c++='-';   /* handle sign */
     1.1  mrg   comb=sourhi>>26;		   /* sign+combination field */
     1.1  mrg   msd=DECCOMBMSD[comb]; 	   /* decode the combination field */
     1.1  mrg   exp=DECCOMBEXP[comb]; 	   /* .. */
     1.1  mrg
     1.1  mrg   if (!EXPISSPECIAL(exp)) {	   /* finite */
     1.1  mrg     /* complete exponent; top two bits are in place */
     1.1  mrg     exp+=GETECON(df)-DECBIAS;	   /* .. + continuation and unbias */
     1.1  mrg     }
     1.1  mrg    else {			   /* IS special */
     1.1  mrg     if (exp==DECFLOAT_Inf) {	   /* infinity */
     1.1  mrg       strcpy(c, "Infinity");
     1.1  mrg       return string;		   /* easy */
     1.1  mrg       }
     1.1  mrg     if (sourhi&0x02000000) *c++='s'; /* sNaN */
     1.1  mrg     strcpy(c, "NaN");		   /* complete word */
     1.1  mrg     c+=3;			   /* step past */
     1.1  mrg     /* quick exit if the payload is zero */
     1.1  mrg     #if DECPMAX==7
     1.1  mrg     if ((sourhi&0x000fffff)==0) return string;
     1.1  mrg     #elif DECPMAX==16
     1.1  mrg     if (sourlo==0 && (sourhi&0x0003ffff)==0) return string;
     1.1  mrg     #elif DECPMAX==34
     1.1  mrg     if (sourlo==0 && sourml==0 && sourmh==0
     1.1  mrg      && (sourhi&0x00003fff)==0) return string;
     1.1  mrg     #endif
     1.1  mrg     /* otherwise drop through to add integer; set correct exp etc. */
     1.1  mrg     exp=0; msd=0;		   /* setup for following code */
     1.1  mrg     }
     1.1  mrg
     1.1  mrg   /* convert the digits of the significand to characters */
     1.1  mrg   cstart=c;			   /* save start of coefficient */
     1.1  mrg   if (msd) *c++=(char)('0'+(char)msd);	/* non-zero most significant digit */
     1.1  mrg
     1.1  mrg   /* Decode the declets.  After extracting each declet, it is */
     1.1  mrg   /* decoded to a 4-uByte sequence by table lookup; the four uBytes */
     1.1  mrg   /* are the three encoded BCD8 digits followed by a 1-byte length */
     1.1  mrg   /* (significant digits, except that 000 has length 0).  This allows */
     1.1  mrg   /* us to left-align the first declet with non-zero content, then */
     1.1  mrg   /* the remaining ones are full 3-char length.  Fixed-length copies */
     1.1  mrg   /* are used because variable-length memcpy causes a subroutine call */
     1.1  mrg   /* in at least two compilers.  (The copies are length 4 for speed */
     1.1  mrg   /* and are safe because the last item in the array is of length */
     1.1  mrg   /* three and has the length byte following.) */
     1.1  mrg   #define dpd2char(dpdin) u=&DPD2BCD8[((dpdin)&0x3ff)*4];	 \
     1.1  mrg 	 if (c!=cstart) {UBFROMUI(c, UBTOUI(u)|CHARMASK); c+=3;} \
     1.1  mrg 	  else if (*(u+3)) {					 \
     1.1  mrg 	   UBFROMUI(c, UBTOUI(u+3-*(u+3))|CHARMASK); c+=*(u+3);}
     1.1  mrg
     1.1  mrg   #if DECPMAX==7
     1.1  mrg   dpd2char(sourhi>>10); 		/* declet 1 */
     1.1  mrg   dpd2char(sourhi);			/* declet 2 */
     1.1  mrg
     1.1  mrg   #elif DECPMAX==16
     1.1  mrg   dpd2char(sourhi>>8);			/* declet 1 */
     1.1  mrg   dpd2char((sourhi<<2) | (sourlo>>30)); /* declet 2 */
     1.1  mrg   dpd2char(sourlo>>20); 		/* declet 3 */
     1.1  mrg   dpd2char(sourlo>>10); 		/* declet 4 */
     1.1  mrg   dpd2char(sourlo);			/* declet 5 */
     1.1  mrg
     1.1  mrg   #elif DECPMAX==34
     1.1  mrg   dpd2char(sourhi>>4);			/* declet 1 */
     1.1  mrg   dpd2char((sourhi<<6) | (sourmh>>26)); /* declet 2 */
     1.1  mrg   dpd2char(sourmh>>16); 		/* declet 3 */
     1.1  mrg   dpd2char(sourmh>>6);			/* declet 4 */
     1.1  mrg   dpd2char((sourmh<<4) | (sourml>>28)); /* declet 5 */
     1.1  mrg   dpd2char(sourml>>18); 		/* declet 6 */
     1.1  mrg   dpd2char(sourml>>8);			/* declet 7 */
     1.1  mrg   dpd2char((sourml<<2) | (sourlo>>30)); /* declet 8 */
     1.1  mrg   dpd2char(sourlo>>20); 		/* declet 9 */
     1.1  mrg   dpd2char(sourlo>>10); 		/* declet 10 */
     1.1  mrg   dpd2char(sourlo);			/* declet 11 */
     1.1  mrg   #endif
     1.1  mrg
     1.1  mrg   if (c==cstart) *c++='0';	   /* all zeros, empty -- make "0" */
     1.1  mrg
     1.1  mrg   /*[This fast path is valid but adds 3-5 cycles to worst case length] */
     1.1  mrg   /*if (exp==0) {		   // integer or NaN case -- easy */
     1.1  mrg   /*  *c='\0';			   // terminate */
     1.1  mrg   /*  return string; */
     1.1  mrg   /*  } */
     1.1  mrg
     1.1  mrg   e=0;				   /* assume no E */
     1.1  mrg   pre=(Int)(c-cstart)+exp;	   /* length+exp  [c->LSD+1] */
     1.1  mrg   /* [here, pre-exp is the digits count (==1 for zero)] */
     1.1  mrg
     1.1  mrg   if (exp>0 || pre<-5) {	   /* need exponential form */
     1.1  mrg     e=pre-1;			   /* calculate E value */
     1.1  mrg     pre=1;			   /* assume one digit before '.' */
     1.1  mrg     } /* exponential form */
     1.1  mrg
     1.1  mrg   /* modify the coefficient, adding 0s, '.', and E+nn as needed */
     1.1  mrg   if (pre>0) {			   /* ddd.ddd (plain), perhaps with E */
     1.1  mrg     char *dotat=cstart+pre;
     1.1  mrg     if (dotat<c) {			/* if embedded dot needed... */
     1.1  mrg       /* [memmove is a disaster, here] */
     1.1  mrg       /* move by fours; there must be space for junk at the end */
     1.1  mrg       /* because exponent is still possible */
     1.1  mrg       s=dotat+ROUNDDOWN4(c-dotat);	/* source */
     1.1  mrg       t=s+1;				/* target */
     1.1  mrg       /* open the gap [cannot use memcpy] */
     1.1  mrg       for (; s>=dotat; s-=4, t-=4) UBFROMUI(t, UBTOUI(s));
     1.1  mrg       *dotat='.';
     1.1  mrg       c++;				/* length increased by one */
     1.1  mrg       } /* need dot? */
     1.1  mrg
     1.1  mrg     /* finally add the E-part, if needed; it will never be 0, and has */
     1.1  mrg     /* a maximum length of 3 or 4 digits (asserted above) */
     1.1  mrg     if (e!=0) {
     1.1  mrg       memcpy(c, "E+", 2);		/* starts with E, assume + */
     1.1  mrg       c++;
     1.1  mrg       if (e<0) {
     1.1  mrg 	*c='-'; 			/* oops, need '-' */
     1.1  mrg 	e=-e;				/* uInt, please */
     1.1  mrg 	}
     1.1  mrg       c++;
     1.1  mrg       /* Three-character exponents are easy; 4-character a little trickier */
     1.1  mrg       #if DECEMAXD<=3
     1.1  mrg 	u=&BIN2BCD8[e*4];		/* -> 3 digits + length byte */
     1.1  mrg 	/* copy fixed 4 characters [is safe], starting at non-zero */
     1.1  mrg 	/* and with character mask to convert BCD to char */
     1.1  mrg 	UBFROMUI(c, UBTOUI(u+3-*(u+3))|CHARMASK);
     1.1  mrg 	c+=*(u+3);			/* bump pointer appropriately */
     1.1  mrg       #elif DECEMAXD==4
     1.1  mrg 	if (e<1000) {			/* 3 (or fewer) digits case */
     1.1  mrg 	  u=&BIN2BCD8[e*4];		/* -> 3 digits + length byte */
     1.1  mrg 	  UBFROMUI(c, UBTOUI(u+3-*(u+3))|CHARMASK); /* [as above] */
     1.1  mrg 	  c+=*(u+3);			/* bump pointer appropriately */
     1.1  mrg 	  }
     1.1  mrg 	 else { 			/* 4-digits */
     1.1  mrg 	  Int thou=((e>>3)*1049)>>17;	/* e/1000 */
     1.1  mrg 	  Int rem=e-(1000*thou);	/* e%1000 */
     1.1  mrg 	  *c++=(char)('0'+(char)thou);	/* the thousands digit */
     1.1  mrg 	  u=&BIN2BCD8[rem*4];		/* -> 3 digits + length byte */
     1.1  mrg 	  UBFROMUI(c, UBTOUI(u)|CHARMASK); /* copy fixed 3+1 characters [is safe] */
     1.1  mrg 	  c+=3; 			/* bump pointer, always 3 digits */
     1.1  mrg 	  }
     1.1  mrg       #endif
     1.1  mrg       }
     1.1  mrg     *c='\0';				/* add terminator */
     1.1  mrg     /*printf("res %s\n", string); */
     1.1  mrg     return string;
     1.1  mrg     } /* pre>0 */
     1.1  mrg
     1.1  mrg   /* -5<=pre<=0: here for plain 0.ddd or 0.000ddd forms (can never have E) */
     1.1  mrg   /* Surprisingly, this is close to being the worst-case path, so the */
     1.1  mrg   /* shift is done by fours; this is a little tricky because the */
     1.1  mrg   /* rightmost character to be written must not be beyond where the */
     1.1  mrg   /* rightmost terminator could be -- so backoff to not touch */
     1.1  mrg   /* terminator position if need be (this can make exact alignments */
     1.1  mrg   /* for full Doubles, but in some cases needs care not to access too */
     1.1  mrg   /* far to the left) */
     1.1  mrg
     1.1  mrg   pre=-pre+2;				/* gap width, including "0." */
     1.1  mrg   t=cstart+ROUNDDOWN4(c-cstart)+pre;	/* preferred first target point */
     1.1  mrg   /* backoff if too far to the right */
     1.1  mrg   if (t>string+DECSTRING-5) t=string+DECSTRING-5; /* adjust to fit */
     1.1  mrg   /* now shift the entire coefficient to the right, being careful not */
     1.1  mrg   /* to access to the left of string [cannot use memcpy] */
     1.1  mrg   for (s=t-pre; s>=string; s-=4, t-=4) UBFROMUI(t, UBTOUI(s));
     1.1  mrg   /* for Quads and Singles there may be a character or two left... */
     1.1  mrg   s+=3; 				/* where next would come from */
     1.1  mrg   for(; s>=cstart; s--, t--) *(t+3)=*(s);
     1.1  mrg   /* now have fill 0. through 0.00000; use overlaps to avoid tests */
     1.1  mrg   if (pre>=4) {
     1.1  mrg     memcpy(cstart+pre-4, "0000", 4);
     1.1  mrg     memcpy(cstart, "0.00", 4);
     1.1  mrg     }
     1.1  mrg    else { /* 2 or 3 */
     1.1  mrg     *(cstart+pre-1)='0';
     1.1  mrg     memcpy(cstart, "0.", 2);
     1.1  mrg     }
     1.1  mrg   *(c+pre)='\0';			/* terminate */
     1.1  mrg   return string;
     1.1  mrg   } /* decFloatToString */
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* decFloatToWider -- conversion to next-wider format		      */
     1.1  mrg /*								      */
     1.1  mrg /*  source  is the decFloat format number which gets the result of    */
     1.1  mrg /*	    the conversion					      */
     1.1  mrg /*  wider   is the decFloatWider format number which will be narrowed */
     1.1  mrg /*  returns wider						      */
     1.1  mrg /*								      */
     1.1  mrg /* Widening is always exact; no status is set (sNaNs are copied and   */
     1.1  mrg /* do not signal).  The result will be canonical if the source is,    */
     1.1  mrg /* and may or may not be if the source is not.			      */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* widening is not possible for decQuad format numbers; simply omit */
     1.1  mrg #if !QUAD
     1.1  mrg decFloatWider * decFloatToWider(const decFloat *source, decFloatWider *wider) {
     1.1  mrg   uInt msd;
     1.1  mrg
     1.1  mrg   /* Construct and copy the sign word */
     1.1  mrg   if (DFISSPECIAL(source)) {
     1.1  mrg     /* copy sign, combination, and first bit of exponent (sNaN selector) */
     1.1  mrg     DFWWORD(wider, 0)=DFWORD(source, 0)&0xfe000000;
     1.1  mrg     msd=0;
     1.1  mrg     }
     1.1  mrg    else { /* is finite number */
     1.1  mrg     uInt exp=GETEXPUN(source)+DECWBIAS; /* get unbiased exponent and rebias */
     1.1  mrg     uInt code=(exp>>DECWECONL)<<29;	/* set two bits of exp [msd=0] */
     1.1  mrg     code|=(exp<<(32-6-DECWECONL)) & 0x03ffffff; /* add exponent continuation */
     1.1  mrg     code|=DFWORD(source, 0)&0x80000000; /* add sign */
     1.1  mrg     DFWWORD(wider, 0)=code;		/* .. and place top word in wider */
     1.1  mrg     msd=GETMSD(source); 		/* get source coefficient MSD [0-9] */
     1.1  mrg     }
     1.1  mrg   /* Copy the coefficient and clear any 'unused' words to left */
     1.1  mrg   #if SINGLE
     1.1  mrg     DFWWORD(wider, 1)=(DFWORD(source, 0)&0x000fffff)|(msd<<20);
     1.1  mrg   #elif DOUBLE
     1.1  mrg     DFWWORD(wider, 2)=(DFWORD(source, 0)&0x0003ffff)|(msd<<18);
     1.1  mrg     DFWWORD(wider, 3)=DFWORD(source, 1);
     1.1  mrg     DFWWORD(wider, 1)=0;
     1.1  mrg   #endif
     1.1  mrg   return wider;
     1.1  mrg   } /* decFloatToWider */
     1.1  mrg #endif
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* decFloatVersion -- return package version string		      */
     1.1  mrg /*								      */
     1.1  mrg /*  returns a constant string describing this package		      */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg const char *decFloatVersion(void) {
     1.1  mrg   return DECVERSION;
     1.1  mrg   } /* decFloatVersion */
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* decFloatZero -- set to canonical (integer) zero		      */
     1.1  mrg /*								      */
     1.1  mrg /*  df is the decFloat format number to integer +0 (q=0, c=+0)	      */
     1.1  mrg /*  returns df							      */
     1.1  mrg /*								      */
     1.1  mrg /* No error is possible, and no status can be set.		      */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg decFloat * decFloatZero(decFloat *df){
     1.1  mrg   DFWORD(df, 0)=ZEROWORD;     /* set appropriate top word */
     1.1  mrg   #if DOUBLE || QUAD
     1.1  mrg     DFWORD(df, 1)=0;
     1.1  mrg     #if QUAD
     1.1  mrg       DFWORD(df, 2)=0;
     1.1  mrg       DFWORD(df, 3)=0;
     1.1  mrg     #endif
     1.1  mrg   #endif
     1.1  mrg   /* decFloatShow(df, "zero"); */
     1.1  mrg   return df;
     1.1  mrg   } /* decFloatZero */
     1.1  mrg
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* Private generic function (not format-specific) for development use */
     1.1  mrg /* ------------------------------------------------------------------ */
     1.1  mrg /* This is included once only, for all to use */
     1.1  mrg #if QUAD && (DECCHECK || DECTRACE)
     1.1  mrg   /* ---------------------------------------------------------------- */
     1.1  mrg   /* decShowNum -- display bcd8 number in debug form		      */
     1.1  mrg   /*								      */
     1.1  mrg   /*   num is the bcdnum to display				      */
     1.1  mrg   /*   tag is a string to label the display			      */
     1.1  mrg   /* ---------------------------------------------------------------- */
     1.1  mrg   void decShowNum(const bcdnum *num, const char *tag) {
     1.1  mrg     const char *csign="+";		/* sign character */
     1.1  mrg     uByte *ub;				/* work */
     1.1  mrg     uInt  uiwork;			/* for macros */
     1.1  mrg     if (num->sign==DECFLOAT_Sign) csign="-";
     1.1  mrg
     1.1  mrg     printf(">%s> ", tag);
     1.1  mrg     if (num->exponent==DECFLOAT_Inf) printf("%sInfinity", csign);
     1.1  mrg     else if (num->exponent==DECFLOAT_qNaN) printf("%sqNaN", csign);
     1.1  mrg     else if (num->exponent==DECFLOAT_sNaN) printf("%ssNaN", csign);
     1.1  mrg     else {				/* finite */
     1.1  mrg      char qbuf[10];			/* for right-aligned q */
     1.1  mrg      char *c;				/* work */
     1.1  mrg      const uByte *u;			/* .. */
     1.1  mrg      Int e=num->exponent;		/* .. exponent */
     1.1  mrg      strcpy(qbuf, "q=");
     1.1  mrg      c=&qbuf[2];			/* where exponent will go */
     1.1  mrg      /* lay out the exponent */
     1.1  mrg      if (e<0) {
     1.1  mrg        *c++='-';			/* add '-' */
     1.1  mrg        e=-e;				/* uInt, please */
     1.1  mrg        }
     1.1  mrg      #if DECEMAXD>4
     1.1  mrg        #error Exponent form is too long for ShowNum to lay out
     1.1  mrg      #endif
     1.1  mrg      if (e==0) *c++='0';		/* 0-length case */
     1.1  mrg       else if (e<1000) {		/* 3 (or fewer) digits case */
     1.1  mrg        u=&BIN2BCD8[e*4];		/* -> 3 digits + length byte */
     1.1  mrg        UBFROMUI(c, UBTOUI(u+3-*(u+3))|CHARMASK); /* [as above] */
     1.1  mrg        c+=*(u+3);			/* bump pointer appropriately */
     1.1  mrg        }
     1.1  mrg       else {				/* 4-digits */
     1.1  mrg        Int thou=((e>>3)*1049)>>17;	/* e/1000 */
     1.1  mrg        Int rem=e-(1000*thou);		/* e%1000 */
     1.1  mrg        *c++=(char)('0'+(char)thou);	/* the thousands digit */
     1.1  mrg        u=&BIN2BCD8[rem*4];		/* -> 3 digits + length byte */
     1.1  mrg        UBFROMUI(c, UBTOUI(u)|CHARMASK); /* copy fixed 3+1 characters [is safe] */
     1.1  mrg        c+=3;				/* bump pointer, always 3 digits */
     1.1  mrg        }
     1.1  mrg      *c='\0';				/* add terminator */
     1.1  mrg      printf("%7s c=%s", qbuf, csign);
     1.1  mrg      }
     1.1  mrg
     1.1  mrg     if (!EXPISSPECIAL(num->exponent) || num->msd!=num->lsd || *num->lsd!=0) {
     1.1  mrg       for (ub=num->msd; ub<=num->lsd; ub++) { /* coefficient... */
     1.1  mrg 	printf("%1x", *ub);
     1.1  mrg 	if ((num->lsd-ub)%3==0 && ub!=num->lsd) printf(" "); /* 4-space */
     1.1  mrg 	}
     1.1  mrg       }
     1.1  mrg     printf("\n");
     1.1  mrg     } /* decShowNum */
     1.1  mrg #endif