/* * The authors of this software are Rob Pike and Ken Thompson, * with contributions from Mike Burrows and Sean Dorward. * * Copyright (c) 2002-2006 by Lucent Technologies. * Portions Copyright (c) 2004 Google Inc. * * Permission to use, copy, modify, and distribute this software for any * purpose without fee is hereby granted, provided that this entire notice * is included in all copies of any software which is or includes a copy * or modification of this software and in all copies of the supporting * documentation for such software. * THIS SOFTWARE IS BEING PROVIDED "AS IS", WITHOUT ANY EXPRESS OR IMPLIED * WARRANTY. IN PARTICULAR, NEITHER THE AUTHORS NOR LUCENT TECHNOLOGIES * NOR GOOGLE INC MAKE ANY REPRESENTATION OR WARRANTY OF ANY KIND CONCERNING * THE MERCHANTABILITY OF THIS SOFTWARE OR ITS FITNESS FOR ANY PARTICULAR PURPOSE. */ /* Copyright (c) 2002-2006 Lucent Technologies; see LICENSE */ #include #include #include #include "fmtdef.h" enum { FDIGIT = 30, FDEFLT = 6, NSIGNIF = 17 }; /* * first few powers of 10, enough for about 1/2 of the * total space for doubles. */ static double pows10[] = { 1e0, 1e1, 1e2, 1e3, 1e4, 1e5, 1e6, 1e7, 1e8, 1e9, 1e10, 1e11, 1e12, 1e13, 1e14, 1e15, 1e16, 1e17, 1e18, 1e19, 1e20, 1e21, 1e22, 1e23, 1e24, 1e25, 1e26, 1e27, 1e28, 1e29, 1e30, 1e31, 1e32, 1e33, 1e34, 1e35, 1e36, 1e37, 1e38, 1e39, 1e40, 1e41, 1e42, 1e43, 1e44, 1e45, 1e46, 1e47, 1e48, 1e49, 1e50, 1e51, 1e52, 1e53, 1e54, 1e55, 1e56, 1e57, 1e58, 1e59, 1e60, 1e61, 1e62, 1e63, 1e64, 1e65, 1e66, 1e67, 1e68, 1e69, 1e70, 1e71, 1e72, 1e73, 1e74, 1e75, 1e76, 1e77, 1e78, 1e79, 1e80, 1e81, 1e82, 1e83, 1e84, 1e85, 1e86, 1e87, 1e88, 1e89, 1e90, 1e91, 1e92, 1e93, 1e94, 1e95, 1e96, 1e97, 1e98, 1e99, 1e100, 1e101, 1e102, 1e103, 1e104, 1e105, 1e106, 1e107, 1e108, 1e109, 1e110, 1e111, 1e112, 1e113, 1e114, 1e115, 1e116, 1e117, 1e118, 1e119, 1e120, 1e121, 1e122, 1e123, 1e124, 1e125, 1e126, 1e127, 1e128, 1e129, 1e130, 1e131, 1e132, 1e133, 1e134, 1e135, 1e136, 1e137, 1e138, 1e139, 1e140, 1e141, 1e142, 1e143, 1e144, 1e145, 1e146, 1e147, 1e148, 1e149, 1e150, 1e151, 1e152, 1e153, 1e154, 1e155, 1e156, 1e157, 1e158, 1e159, }; #undef pow10 #define npows10 ((int)(sizeof(pows10)/sizeof(pows10[0]))) #define pow10(x) fmtpow10(x) static double pow10(int n) { double d; int neg; neg = 0; if(n < 0){ neg = 1; n = -n; } if(n < npows10) d = pows10[n]; else{ d = pows10[npows10-1]; for(;;){ n -= npows10 - 1; if(n < npows10){ d *= pows10[n]; break; } d *= pows10[npows10 - 1]; } } if(neg) return 1./d; return d; } /* * add 1 to the decimal integer string a of length n. * if 99999 overflows into 10000, return 1 to tell caller * to move the virtual decimal point. */ static int xadd1(char *a, int n) { char *b; int c; if(n < 0 || n > NSIGNIF) return 0; for(b = a+n-1; b >= a; b--) { c = *b + 1; if(c <= '9') { *b = c; return 0; } *b = '0'; } /* * need to overflow adding digit. * shift number down and insert 1 at beginning. * decimal is known to be 0s or we wouldn't * have gotten this far. (e.g., 99999+1 => 00000) */ a[0] = '1'; return 1; } /* * subtract 1 from the decimal integer string a. * if 10000 underflows into 09999, make it 99999 * and return 1 to tell caller to move the virtual * decimal point. this way, xsub1 is inverse of xadd1. */ static int xsub1(char *a, int n) { char *b; int c; if(n < 0 || n > NSIGNIF) return 0; for(b = a+n-1; b >= a; b--) { c = *b - 1; if(c >= '0') { if(c == '0' && b == a) { /* * just zeroed the top digit; shift everyone up. * decimal is known to be 9s or we wouldn't * have gotten this far. (e.g., 10000-1 => 09999) */ *b = '9'; return 1; } *b = c; return 0; } *b = '9'; } /* * can't get here. the number a is always normalized * so that it has a nonzero first digit. */ abort(); } /* * format exponent like sprintf(p, "e%+02d", e) */ static void xfmtexp(char *p, int e, int ucase) { char se[9]; int i; *p++ = ucase ? 'E' : 'e'; if(e < 0) { *p++ = '-'; e = -e; } else *p++ = '+'; i = 0; while(e) { se[i++] = e % 10 + '0'; e /= 10; } while(i < 2) se[i++] = '0'; while(i > 0) *p++ = se[--i]; *p++ = '\0'; } /* * compute decimal integer m, exp such that: * f = m*10^exp * m is as short as possible with losing exactness * assumes special cases (NaN, +Inf, -Inf) have been handled. */ static void xdtoa(double f, char *s, int *exp, int *neg, int *ns) { int c, d, e2, e, ee, i, ndigit, oerrno; char tmp[NSIGNIF+10]; double g; oerrno = errno; /* in case strtod smashes errno */ /* * make f non-negative. */ *neg = 0; if(f < 0) { f = -f; *neg = 1; } /* * must handle zero specially. */ if(f == 0){ *exp = 0; s[0] = '0'; s[1] = '\0'; *ns = 1; return; } /* * find g,e such that f = g*10^e. * guess 10-exponent using 2-exponent, then fine tune. */ frexp(f, &e2); e = (int)(e2 * .301029995664); g = f * pow10(-e); while(g < 1) { e--; g = f * pow10(-e); } while(g >= 10) { e++; g = f * pow10(-e); } /* * convert NSIGNIF digits as a first approximation. */ for(i=0; i g) { if(xadd1(s, NSIGNIF)) { /* gained a digit */ e--; xfmtexp(s+NSIGNIF, e, 0); } continue; } if(f < g) { if(xsub1(s, NSIGNIF)) { /* lost a digit */ e++; xfmtexp(s+NSIGNIF, e, 0); } continue; } break; } /* * play with the decimal to try to simplify. */ /* * bump last few digits up to 9 if we can */ for(i=NSIGNIF-1; i>=NSIGNIF-3; i--) { c = s[i]; if(c != '9') { s[i] = '9'; g = strtod(s, nil); if(g != f) { s[i] = c; break; } } } /* * add 1 in hopes of turning 9s to 0s */ if(s[NSIGNIF-1] == '9') { strcpy(tmp, s); ee = e; if(xadd1(tmp, NSIGNIF)) { ee--; xfmtexp(tmp+NSIGNIF, ee, 0); } g = strtod(tmp, nil); if(g == f) { strcpy(s, tmp); e = ee; } } /* * bump last few digits down to 0 as we can. */ for(i=NSIGNIF-1; i>=NSIGNIF-3; i--) { c = s[i]; if(c != '0') { s[i] = '0'; g = strtod(s, nil); if(g != f) { s[i] = c; break; } } } /* * remove trailing zeros. */ ndigit = NSIGNIF; while(ndigit > 1 && s[ndigit-1] == '0'){ e++; --ndigit; } s[ndigit] = 0; *exp = e; *ns = ndigit; errno = oerrno; } #ifdef PLAN9PORT static char *special[] = { "NaN", "NaN", "+Inf", "+Inf", "-Inf", "-Inf" }; #else static char *special[] = { "nan", "NAN", "inf", "INF", "-inf", "-INF" }; #endif int __efgfmt(Fmt *fmt) { char buf[NSIGNIF+10], *dot, *digits, *p, *s, suf[10], *t; double f; int c, chr, dotwid, e, exp, fl, ndigits, neg, newndigits; int pad, point, prec, realchr, sign, sufwid, ucase, wid, z1, z2; Rune r, *rs, *rt; if(fmt->flags&FmtLong) f = va_arg(fmt->args, long double); else f = va_arg(fmt->args, double); /* * extract formatting flags */ fl = fmt->flags; fmt->flags = 0; prec = FDEFLT; if(fl & FmtPrec) prec = fmt->prec; chr = fmt->r; ucase = 0; switch(chr) { case 'A': case 'E': case 'F': case 'G': chr += 'a'-'A'; ucase = 1; break; } /* * pick off special numbers. */ if(__isNaN(f)) { s = special[0+ucase]; special: fmt->flags = fl & (FmtWidth|FmtLeft); return __fmtcpy(fmt, s, strlen(s), strlen(s)); } if(__isInf(f, 1)) { s = special[2+ucase]; goto special; } if(__isInf(f, -1)) { s = special[4+ucase]; goto special; } /* * get exact representation. */ digits = buf; xdtoa(f, digits, &exp, &neg, &ndigits); /* * get locale's decimal point. */ dot = fmt->decimal; if(dot == nil) dot = "."; dotwid = utflen(dot); /* * now the formatting fun begins. * compute parameters for actual fmt: * * pad: number of spaces to insert before/after field. * z1: number of zeros to insert before digits * z2: number of zeros to insert after digits * point: number of digits to print before decimal point * ndigits: number of digits to use from digits[] * suf: trailing suffix, like "e-5" */ realchr = chr; switch(chr){ case 'g': /* * convert to at most prec significant digits. (prec=0 means 1) */ if(prec == 0) prec = 1; if(ndigits > prec) { if(digits[prec] >= '5' && xadd1(digits, prec)) exp++; exp += ndigits-prec; ndigits = prec; } /* * extra rules for %g (implemented below): * trailing zeros removed after decimal unless FmtSharp. * decimal point only if digit follows. */ /* fall through to %e */ default: case 'e': /* * one significant digit before decimal, no leading zeros. */ point = 1; z1 = 0; /* * decimal point is after ndigits digits right now. * slide to be after first. */ e = exp + (ndigits-1); /* * if this is %g, check exponent and convert prec */ if(realchr == 'g') { if(-4 <= e && e < prec) goto casef; prec--; /* one digit before decimal; rest after */ } /* * compute trailing zero padding or truncate digits. */ if(1+prec >= ndigits) z2 = 1+prec - ndigits; else { /* * truncate digits */ assert(realchr != 'g'); newndigits = 1+prec; if(digits[newndigits] >= '5' && xadd1(digits, newndigits)) { /* * had 999e4, now have 100e5 */ e++; } ndigits = newndigits; z2 = 0; } xfmtexp(suf, e, ucase); sufwid = strlen(suf); break; casef: case 'f': /* * determine where digits go with respect to decimal point */ if(ndigits+exp > 0) { point = ndigits+exp; z1 = 0; } else { point = 1; z1 = 1 + -(ndigits+exp); } /* * %g specifies prec = number of significant digits * convert to number of digits after decimal point */ if(realchr == 'g') prec += z1 - point; /* * compute trailing zero padding or truncate digits. */ if(point+prec >= z1+ndigits) z2 = point+prec - (z1+ndigits); else { /* * truncate digits */ assert(realchr != 'g'); newndigits = point+prec - z1; if(newndigits < 0) { z1 += newndigits; newndigits = 0; } else if(newndigits == 0) { /* perhaps round up */ if(digits[0] >= '5'){ digits[0] = '1'; newndigits = 1; goto newdigit; } } else if(digits[newndigits] >= '5' && xadd1(digits, newndigits)) { /* * digits was 999, is now 100; make it 1000 */ digits[newndigits++] = '0'; newdigit: /* * account for new digit */ if(z1) /* 0.099 => 0.100 or 0.99 => 1.00*/ z1--; else /* 9.99 => 10.00 */ point++; } z2 = 0; ndigits = newndigits; } sufwid = 0; break; } /* * if %g is given without FmtSharp, remove trailing zeros. * must do after truncation, so that e.g. print %.3g 1.001 * produces 1, not 1.00. sorry, but them's the rules. */ if(realchr == 'g' && !(fl & FmtSharp)) { if(z1+ndigits+z2 >= point) { if(z1+ndigits < point) z2 = point - (z1+ndigits); else{ z2 = 0; while(z1+ndigits > point && digits[ndigits-1] == '0') ndigits--; } } } /* * compute width of all digits and decimal point and suffix if any */ wid = z1+ndigits+z2; if(wid > point) wid += dotwid; else if(wid == point){ if(fl & FmtSharp) wid += dotwid; else point++; /* do not print any decimal point */ } wid += sufwid; /* * determine sign */ sign = 0; if(neg) sign = '-'; else if(fl & FmtSign) sign = '+'; else if(fl & FmtSpace) sign = ' '; if(sign) wid++; /* * compute padding */ pad = 0; if((fl & FmtWidth) && fmt->width > wid) pad = fmt->width - wid; if(pad && !(fl & FmtLeft) && (fl & FmtZero)){ z1 += pad; point += pad; pad = 0; } /* * format the actual field. too bad about doing this twice. */ if(fmt->runes){ if(pad && !(fl & FmtLeft) && __rfmtpad(fmt, pad) < 0) return -1; rt = (Rune*)fmt->to; rs = (Rune*)fmt->stop; if(sign) FMTRCHAR(fmt, rt, rs, sign); while(z1>0 || ndigits>0 || z2>0) { if(z1 > 0){ z1--; c = '0'; }else if(ndigits > 0){ ndigits--; c = *digits++; }else{ z2--; c = '0'; } FMTRCHAR(fmt, rt, rs, c); if(--point == 0) { for(p = dot; *p; ){ p += chartorune(&r, p); FMTRCHAR(fmt, rt, rs, r); } } } fmt->nfmt += rt - (Rune*)fmt->to; fmt->to = rt; if(sufwid && __fmtcpy(fmt, suf, sufwid, sufwid) < 0) return -1; if(pad && (fl & FmtLeft) && __rfmtpad(fmt, pad) < 0) return -1; }else{ if(pad && !(fl & FmtLeft) && __fmtpad(fmt, pad) < 0) return -1; t = (char*)fmt->to; s = (char*)fmt->stop; if(sign) FMTCHAR(fmt, t, s, sign); while(z1>0 || ndigits>0 || z2>0) { if(z1 > 0){ z1--; c = '0'; }else if(ndigits > 0){ ndigits--; c = *digits++; }else{ z2--; c = '0'; } FMTCHAR(fmt, t, s, c); if(--point == 0) for(p=dot; *p; p++) FMTCHAR(fmt, t, s, *p); } fmt->nfmt += t - (char*)fmt->to; fmt->to = t; if(sufwid && __fmtcpy(fmt, suf, sufwid, sufwid) < 0) return -1; if(pad && (fl & FmtLeft) && __fmtpad(fmt, pad) < 0) return -1; } return 0; }