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view lib/vasnprintf.c @ 436:4c272633fce2 3.0 3.0
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author | lost@l-w.ca |
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date | Fri, 29 Oct 2010 19:28:54 -0600 |
parents | b8bf63962a99 |
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/* vsprintf with automatic memory allocation. Copyright (C) 1999, 2002-2010 Free Software Foundation, Inc. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ /* This file can be parametrized with the following macros: VASNPRINTF The name of the function being defined. FCHAR_T The element type of the format string. DCHAR_T The element type of the destination (result) string. FCHAR_T_ONLY_ASCII Set to 1 to enable verification that all characters in the format string are ASCII. MUST be set if FCHAR_T and DCHAR_T are not the same type. DIRECTIVE Structure denoting a format directive. Depends on FCHAR_T. DIRECTIVES Structure denoting the set of format directives of a format string. Depends on FCHAR_T. PRINTF_PARSE Function that parses a format string. Depends on FCHAR_T. DCHAR_CPY memcpy like function for DCHAR_T[] arrays. DCHAR_SET memset like function for DCHAR_T[] arrays. DCHAR_MBSNLEN mbsnlen like function for DCHAR_T[] arrays. SNPRINTF The system's snprintf (or similar) function. This may be either snprintf or swprintf. TCHAR_T The element type of the argument and result string of the said SNPRINTF function. This may be either char or wchar_t. The code exploits that sizeof (TCHAR_T) | sizeof (DCHAR_T) and alignof (TCHAR_T) <= alignof (DCHAR_T). DCHAR_IS_TCHAR Set to 1 if DCHAR_T and TCHAR_T are the same type. DCHAR_CONV_FROM_ENCODING A function to convert from char[] to DCHAR[]. DCHAR_IS_UINT8_T Set to 1 if DCHAR_T is uint8_t. DCHAR_IS_UINT16_T Set to 1 if DCHAR_T is uint16_t. DCHAR_IS_UINT32_T Set to 1 if DCHAR_T is uint32_t. */ /* Tell glibc's <stdio.h> to provide a prototype for snprintf(). This must come before <config.h> because <config.h> may include <features.h>, and once <features.h> has been included, it's too late. */ #ifndef _GNU_SOURCE # define _GNU_SOURCE 1 #endif #ifndef VASNPRINTF # include <config.h> #endif #ifndef IN_LIBINTL # include <alloca.h> #endif /* Specification. */ #ifndef VASNPRINTF # if WIDE_CHAR_VERSION # include "vasnwprintf.h" # else # include "vasnprintf.h" # endif #endif #include <locale.h> /* localeconv() */ #include <stdio.h> /* snprintf(), sprintf() */ #include <stdlib.h> /* abort(), malloc(), realloc(), free() */ #include <string.h> /* memcpy(), strlen() */ #include <errno.h> /* errno */ #include <limits.h> /* CHAR_BIT */ #include <float.h> /* DBL_MAX_EXP, LDBL_MAX_EXP */ #if HAVE_NL_LANGINFO # include <langinfo.h> #endif #ifndef VASNPRINTF # if WIDE_CHAR_VERSION # include "wprintf-parse.h" # else # include "printf-parse.h" # endif #endif /* Checked size_t computations. */ #include "xsize.h" #if (NEED_PRINTF_DOUBLE || NEED_PRINTF_LONG_DOUBLE) && !defined IN_LIBINTL # include <math.h> # include "float+.h" #endif #if (NEED_PRINTF_DOUBLE || NEED_PRINTF_INFINITE_DOUBLE) && !defined IN_LIBINTL # include <math.h> # include "isnand-nolibm.h" #endif #if (NEED_PRINTF_LONG_DOUBLE || NEED_PRINTF_INFINITE_LONG_DOUBLE) && !defined IN_LIBINTL # include <math.h> # include "isnanl-nolibm.h" # include "fpucw.h" #endif #if (NEED_PRINTF_DIRECTIVE_A || NEED_PRINTF_DOUBLE) && !defined IN_LIBINTL # include <math.h> # include "isnand-nolibm.h" # include "printf-frexp.h" #endif #if (NEED_PRINTF_DIRECTIVE_A || NEED_PRINTF_LONG_DOUBLE) && !defined IN_LIBINTL # include <math.h> # include "isnanl-nolibm.h" # include "printf-frexpl.h" # include "fpucw.h" #endif /* Default parameters. */ #ifndef VASNPRINTF # if WIDE_CHAR_VERSION # define VASNPRINTF vasnwprintf # define FCHAR_T wchar_t # define DCHAR_T wchar_t # define TCHAR_T wchar_t # define DCHAR_IS_TCHAR 1 # define DIRECTIVE wchar_t_directive # define DIRECTIVES wchar_t_directives # define PRINTF_PARSE wprintf_parse # define DCHAR_CPY wmemcpy # define DCHAR_SET wmemset # else # define VASNPRINTF vasnprintf # define FCHAR_T char # define DCHAR_T char # define TCHAR_T char # define DCHAR_IS_TCHAR 1 # define DIRECTIVE char_directive # define DIRECTIVES char_directives # define PRINTF_PARSE printf_parse # define DCHAR_CPY memcpy # define DCHAR_SET memset # endif #endif #if WIDE_CHAR_VERSION /* TCHAR_T is wchar_t. */ # define USE_SNPRINTF 1 # if HAVE_DECL__SNWPRINTF /* On Windows, the function swprintf() has a different signature than on Unix; we use the _snwprintf() function instead. */ # define SNPRINTF _snwprintf # else /* Unix. */ # define SNPRINTF swprintf # endif #else /* TCHAR_T is char. */ /* Use snprintf if it exists under the name 'snprintf' or '_snprintf'. But don't use it on BeOS, since BeOS snprintf produces no output if the size argument is >= 0x3000000. Also don't use it on Linux libc5, since there snprintf with size = 1 writes any output without bounds, like sprintf. */ # if (HAVE_DECL__SNPRINTF || HAVE_SNPRINTF) && !defined __BEOS__ && !(__GNU_LIBRARY__ == 1) # define USE_SNPRINTF 1 # else # define USE_SNPRINTF 0 # endif # if HAVE_DECL__SNPRINTF /* Windows. */ # define SNPRINTF _snprintf # else /* Unix. */ # define SNPRINTF snprintf /* Here we need to call the native snprintf, not rpl_snprintf. */ # undef snprintf # endif #endif /* Here we need to call the native sprintf, not rpl_sprintf. */ #undef sprintf /* GCC >= 4.0 with -Wall emits unjustified "... may be used uninitialized" warnings in this file. Use -Dlint to suppress them. */ #ifdef lint # define IF_LINT(Code) Code #else # define IF_LINT(Code) /* empty */ #endif /* Avoid some warnings from "gcc -Wshadow". This file doesn't use the exp() and remainder() functions. */ #undef exp #define exp expo #undef remainder #define remainder rem #if !USE_SNPRINTF && !WIDE_CHAR_VERSION # if (HAVE_STRNLEN && !defined _AIX) # define local_strnlen strnlen # else # ifndef local_strnlen_defined # define local_strnlen_defined 1 static size_t local_strnlen (const char *string, size_t maxlen) { const char *end = memchr (string, '\0', maxlen); return end ? (size_t) (end - string) : maxlen; } # endif # endif #endif #if (!USE_SNPRINTF || (NEED_PRINTF_DIRECTIVE_LS && !defined IN_LIBINTL)) && HAVE_WCHAR_T && (WIDE_CHAR_VERSION || DCHAR_IS_TCHAR) # if HAVE_WCSLEN # define local_wcslen wcslen # else /* Solaris 2.5.1 has wcslen() in a separate library libw.so. To avoid a dependency towards this library, here is a local substitute. Define this substitute only once, even if this file is included twice in the same compilation unit. */ # ifndef local_wcslen_defined # define local_wcslen_defined 1 static size_t local_wcslen (const wchar_t *s) { const wchar_t *ptr; for (ptr = s; *ptr != (wchar_t) 0; ptr++) ; return ptr - s; } # endif # endif #endif #if !USE_SNPRINTF && HAVE_WCHAR_T && WIDE_CHAR_VERSION # if HAVE_WCSNLEN # define local_wcsnlen wcsnlen # else # ifndef local_wcsnlen_defined # define local_wcsnlen_defined 1 static size_t local_wcsnlen (const wchar_t *s, size_t maxlen) { const wchar_t *ptr; for (ptr = s; maxlen > 0 && *ptr != (wchar_t) 0; ptr++, maxlen--) ; return ptr - s; } # endif # endif #endif #if (NEED_PRINTF_DIRECTIVE_A || NEED_PRINTF_LONG_DOUBLE || NEED_PRINTF_INFINITE_LONG_DOUBLE || NEED_PRINTF_DOUBLE || NEED_PRINTF_INFINITE_DOUBLE) && !defined IN_LIBINTL /* Determine the decimal-point character according to the current locale. */ # ifndef decimal_point_char_defined # define decimal_point_char_defined 1 static char decimal_point_char (void) { const char *point; /* Determine it in a multithread-safe way. We know nl_langinfo is multithread-safe on glibc systems and MacOS X systems, but is not required to be multithread-safe by POSIX. sprintf(), however, is multithread-safe. localeconv() is rarely multithread-safe. */ # if HAVE_NL_LANGINFO && (__GLIBC__ || (defined __APPLE__ && defined __MACH__)) point = nl_langinfo (RADIXCHAR); # elif 1 char pointbuf[5]; sprintf (pointbuf, "%#.0f", 1.0); point = &pointbuf[1]; # else point = localeconv () -> decimal_point; # endif /* The decimal point is always a single byte: either '.' or ','. */ return (point[0] != '\0' ? point[0] : '.'); } # endif #endif #if NEED_PRINTF_INFINITE_DOUBLE && !NEED_PRINTF_DOUBLE && !defined IN_LIBINTL /* Equivalent to !isfinite(x) || x == 0, but does not require libm. */ static int is_infinite_or_zero (double x) { return isnand (x) || x + x == x; } #endif #if NEED_PRINTF_INFINITE_LONG_DOUBLE && !NEED_PRINTF_LONG_DOUBLE && !defined IN_LIBINTL /* Equivalent to !isfinite(x) || x == 0, but does not require libm. */ static int is_infinite_or_zerol (long double x) { return isnanl (x) || x + x == x; } #endif #if (NEED_PRINTF_LONG_DOUBLE || NEED_PRINTF_DOUBLE) && !defined IN_LIBINTL /* Converting 'long double' to decimal without rare rounding bugs requires real bignums. We use the naming conventions of GNU gmp, but vastly simpler (and slower) algorithms. */ typedef unsigned int mp_limb_t; # define GMP_LIMB_BITS 32 typedef int mp_limb_verify[2 * (sizeof (mp_limb_t) * CHAR_BIT == GMP_LIMB_BITS) - 1]; typedef unsigned long long mp_twolimb_t; # define GMP_TWOLIMB_BITS 64 typedef int mp_twolimb_verify[2 * (sizeof (mp_twolimb_t) * CHAR_BIT == GMP_TWOLIMB_BITS) - 1]; /* Representation of a bignum >= 0. */ typedef struct { size_t nlimbs; mp_limb_t *limbs; /* Bits in little-endian order, allocated with malloc(). */ } mpn_t; /* Compute the product of two bignums >= 0. Return the allocated memory in case of success, NULL in case of memory allocation failure. */ static void * multiply (mpn_t src1, mpn_t src2, mpn_t *dest) { const mp_limb_t *p1; const mp_limb_t *p2; size_t len1; size_t len2; if (src1.nlimbs <= src2.nlimbs) { len1 = src1.nlimbs; p1 = src1.limbs; len2 = src2.nlimbs; p2 = src2.limbs; } else { len1 = src2.nlimbs; p1 = src2.limbs; len2 = src1.nlimbs; p2 = src1.limbs; } /* Now 0 <= len1 <= len2. */ if (len1 == 0) { /* src1 or src2 is zero. */ dest->nlimbs = 0; dest->limbs = (mp_limb_t *) malloc (1); } else { /* Here 1 <= len1 <= len2. */ size_t dlen; mp_limb_t *dp; size_t k, i, j; dlen = len1 + len2; dp = (mp_limb_t *) malloc (dlen * sizeof (mp_limb_t)); if (dp == NULL) return NULL; for (k = len2; k > 0; ) dp[--k] = 0; for (i = 0; i < len1; i++) { mp_limb_t digit1 = p1[i]; mp_twolimb_t carry = 0; for (j = 0; j < len2; j++) { mp_limb_t digit2 = p2[j]; carry += (mp_twolimb_t) digit1 * (mp_twolimb_t) digit2; carry += dp[i + j]; dp[i + j] = (mp_limb_t) carry; carry = carry >> GMP_LIMB_BITS; } dp[i + len2] = (mp_limb_t) carry; } /* Normalise. */ while (dlen > 0 && dp[dlen - 1] == 0) dlen--; dest->nlimbs = dlen; dest->limbs = dp; } return dest->limbs; } /* Compute the quotient of a bignum a >= 0 and a bignum b > 0. a is written as a = q * b + r with 0 <= r < b. q is the quotient, r the remainder. Finally, round-to-even is performed: If r > b/2 or if r = b/2 and q is odd, q is incremented. Return the allocated memory in case of success, NULL in case of memory allocation failure. */ static void * divide (mpn_t a, mpn_t b, mpn_t *q) { /* Algorithm: First normalise a and b: a=[a[m-1],...,a[0]], b=[b[n-1],...,b[0]] with m>=0 and n>0 (in base beta = 2^GMP_LIMB_BITS). If m<n, then q:=0 and r:=a. If m>=n=1, perform a single-precision division: r:=0, j:=m, while j>0 do {Here (q[m-1]*beta^(m-1)+...+q[j]*beta^j) * b[0] + r*beta^j = = a[m-1]*beta^(m-1)+...+a[j]*beta^j und 0<=r<b[0]<beta} j:=j-1, r:=r*beta+a[j], q[j]:=floor(r/b[0]), r:=r-b[0]*q[j]. Normalise [q[m-1],...,q[0]], yields q. If m>=n>1, perform a multiple-precision division: We have a/b < beta^(m-n+1). s:=intDsize-1-(highest bit in b[n-1]), 0<=s<intDsize. Shift a and b left by s bits, copying them. r:=a. r=[r[m],...,r[0]], b=[b[n-1],...,b[0]] with b[n-1]>=beta/2. For j=m-n,...,0: {Here 0 <= r < b*beta^(j+1).} Compute q* : q* := floor((r[j+n]*beta+r[j+n-1])/b[n-1]). In case of overflow (q* >= beta) set q* := beta-1. Compute c2 := ((r[j+n]*beta+r[j+n-1]) - q* * b[n-1])*beta + r[j+n-2] and c3 := b[n-2] * q*. {We have 0 <= c2 < 2*beta^2, even 0 <= c2 < beta^2 if no overflow occurred. Furthermore 0 <= c3 < beta^2. If there was overflow and r[j+n]*beta+r[j+n-1] - q* * b[n-1] >= beta, i.e. c2 >= beta^2, the next test can be skipped.} While c3 > c2, {Here 0 <= c2 < c3 < beta^2} Put q* := q* - 1, c2 := c2 + b[n-1]*beta, c3 := c3 - b[n-2]. If q* > 0: Put r := r - b * q* * beta^j. In detail: [r[n+j],...,r[j]] := [r[n+j],...,r[j]] - q* * [b[n-1],...,b[0]]. hence: u:=0, for i:=0 to n-1 do u := u + q* * b[i], r[j+i]:=r[j+i]-(u mod beta) (+ beta, if carry), u:=u div beta (+ 1, if carry in subtraction) r[n+j]:=r[n+j]-u. {Since always u = (q* * [b[i-1],...,b[0]] div beta^i) + 1 < q* + 1 <= beta, the carry u does not overflow.} If a negative carry occurs, put q* := q* - 1 and [r[n+j],...,r[j]] := [r[n+j],...,r[j]] + [0,b[n-1],...,b[0]]. Set q[j] := q*. Normalise [q[m-n],..,q[0]]; this yields the quotient q. Shift [r[n-1],...,r[0]] right by s bits and normalise; this yields the rest r. The room for q[j] can be allocated at the memory location of r[n+j]. Finally, round-to-even: Shift r left by 1 bit. If r > b or if r = b and q[0] is odd, q := q+1. */ const mp_limb_t *a_ptr = a.limbs; size_t a_len = a.nlimbs; const mp_limb_t *b_ptr = b.limbs; size_t b_len = b.nlimbs; mp_limb_t *roomptr; mp_limb_t *tmp_roomptr = NULL; mp_limb_t *q_ptr; size_t q_len; mp_limb_t *r_ptr; size_t r_len; /* Allocate room for a_len+2 digits. (Need a_len+1 digits for the real division and 1 more digit for the final rounding of q.) */ roomptr = (mp_limb_t *) malloc ((a_len + 2) * sizeof (mp_limb_t)); if (roomptr == NULL) return NULL; /* Normalise a. */ while (a_len > 0 && a_ptr[a_len - 1] == 0) a_len--; /* Normalise b. */ for (;;) { if (b_len == 0) /* Division by zero. */ abort (); if (b_ptr[b_len - 1] == 0) b_len--; else break; } /* Here m = a_len >= 0 and n = b_len > 0. */ if (a_len < b_len) { /* m<n: trivial case. q=0, r := copy of a. */ r_ptr = roomptr; r_len = a_len; memcpy (r_ptr, a_ptr, a_len * sizeof (mp_limb_t)); q_ptr = roomptr + a_len; q_len = 0; } else if (b_len == 1) { /* n=1: single precision division. beta^(m-1) <= a < beta^m ==> beta^(m-2) <= a/b < beta^m */ r_ptr = roomptr; q_ptr = roomptr + 1; { mp_limb_t den = b_ptr[0]; mp_limb_t remainder = 0; const mp_limb_t *sourceptr = a_ptr + a_len; mp_limb_t *destptr = q_ptr + a_len; size_t count; for (count = a_len; count > 0; count--) { mp_twolimb_t num = ((mp_twolimb_t) remainder << GMP_LIMB_BITS) | *--sourceptr; *--destptr = num / den; remainder = num % den; } /* Normalise and store r. */ if (remainder > 0) { r_ptr[0] = remainder; r_len = 1; } else r_len = 0; /* Normalise q. */ q_len = a_len; if (q_ptr[q_len - 1] == 0) q_len--; } } else { /* n>1: multiple precision division. beta^(m-1) <= a < beta^m, beta^(n-1) <= b < beta^n ==> beta^(m-n-1) <= a/b < beta^(m-n+1). */ /* Determine s. */ size_t s; { mp_limb_t msd = b_ptr[b_len - 1]; /* = b[n-1], > 0 */ s = 31; if (msd >= 0x10000) { msd = msd >> 16; s -= 16; } if (msd >= 0x100) { msd = msd >> 8; s -= 8; } if (msd >= 0x10) { msd = msd >> 4; s -= 4; } if (msd >= 0x4) { msd = msd >> 2; s -= 2; } if (msd >= 0x2) { msd = msd >> 1; s -= 1; } } /* 0 <= s < GMP_LIMB_BITS. Copy b, shifting it left by s bits. */ if (s > 0) { tmp_roomptr = (mp_limb_t *) malloc (b_len * sizeof (mp_limb_t)); if (tmp_roomptr == NULL) { free (roomptr); return NULL; } { const mp_limb_t *sourceptr = b_ptr; mp_limb_t *destptr = tmp_roomptr; mp_twolimb_t accu = 0; size_t count; for (count = b_len; count > 0; count--) { accu += (mp_twolimb_t) *sourceptr++ << s; *destptr++ = (mp_limb_t) accu; accu = accu >> GMP_LIMB_BITS; } /* accu must be zero, since that was how s was determined. */ if (accu != 0) abort (); } b_ptr = tmp_roomptr; } /* Copy a, shifting it left by s bits, yields r. Memory layout: At the beginning: r = roomptr[0..a_len], at the end: r = roomptr[0..b_len-1], q = roomptr[b_len..a_len] */ r_ptr = roomptr; if (s == 0) { memcpy (r_ptr, a_ptr, a_len * sizeof (mp_limb_t)); r_ptr[a_len] = 0; } else { const mp_limb_t *sourceptr = a_ptr; mp_limb_t *destptr = r_ptr; mp_twolimb_t accu = 0; size_t count; for (count = a_len; count > 0; count--) { accu += (mp_twolimb_t) *sourceptr++ << s; *destptr++ = (mp_limb_t) accu; accu = accu >> GMP_LIMB_BITS; } *destptr++ = (mp_limb_t) accu; } q_ptr = roomptr + b_len; q_len = a_len - b_len + 1; /* q will have m-n+1 limbs */ { size_t j = a_len - b_len; /* m-n */ mp_limb_t b_msd = b_ptr[b_len - 1]; /* b[n-1] */ mp_limb_t b_2msd = b_ptr[b_len - 2]; /* b[n-2] */ mp_twolimb_t b_msdd = /* b[n-1]*beta+b[n-2] */ ((mp_twolimb_t) b_msd << GMP_LIMB_BITS) | b_2msd; /* Division loop, traversed m-n+1 times. j counts down, b is unchanged, beta/2 <= b[n-1] < beta. */ for (;;) { mp_limb_t q_star; mp_limb_t c1; if (r_ptr[j + b_len] < b_msd) /* r[j+n] < b[n-1] ? */ { /* Divide r[j+n]*beta+r[j+n-1] by b[n-1], no overflow. */ mp_twolimb_t num = ((mp_twolimb_t) r_ptr[j + b_len] << GMP_LIMB_BITS) | r_ptr[j + b_len - 1]; q_star = num / b_msd; c1 = num % b_msd; } else { /* Overflow, hence r[j+n]*beta+r[j+n-1] >= beta*b[n-1]. */ q_star = (mp_limb_t)~(mp_limb_t)0; /* q* = beta-1 */ /* Test whether r[j+n]*beta+r[j+n-1] - (beta-1)*b[n-1] >= beta <==> r[j+n]*beta+r[j+n-1] + b[n-1] >= beta*b[n-1]+beta <==> b[n-1] < floor((r[j+n]*beta+r[j+n-1]+b[n-1])/beta) {<= beta !}. If yes, jump directly to the subtraction loop. (Otherwise, r[j+n]*beta+r[j+n-1] - (beta-1)*b[n-1] < beta <==> floor((r[j+n]*beta+r[j+n-1]+b[n-1])/beta) = b[n-1] ) */ if (r_ptr[j + b_len] > b_msd || (c1 = r_ptr[j + b_len - 1] + b_msd) < b_msd) /* r[j+n] >= b[n-1]+1 or r[j+n] = b[n-1] and the addition r[j+n-1]+b[n-1] gives a carry. */ goto subtract; } /* q_star = q*, c1 = (r[j+n]*beta+r[j+n-1]) - q* * b[n-1] (>=0, <beta). */ { mp_twolimb_t c2 = /* c1*beta+r[j+n-2] */ ((mp_twolimb_t) c1 << GMP_LIMB_BITS) | r_ptr[j + b_len - 2]; mp_twolimb_t c3 = /* b[n-2] * q* */ (mp_twolimb_t) b_2msd * (mp_twolimb_t) q_star; /* While c2 < c3, increase c2 and decrease c3. Consider c3-c2. While it is > 0, decrease it by b[n-1]*beta+b[n-2]. Because of b[n-1]*beta+b[n-2] >= beta^2/2 this can happen only twice. */ if (c3 > c2) { q_star = q_star - 1; /* q* := q* - 1 */ if (c3 - c2 > b_msdd) q_star = q_star - 1; /* q* := q* - 1 */ } } if (q_star > 0) subtract: { /* Subtract r := r - b * q* * beta^j. */ mp_limb_t cr; { const mp_limb_t *sourceptr = b_ptr; mp_limb_t *destptr = r_ptr + j; mp_twolimb_t carry = 0; size_t count; for (count = b_len; count > 0; count--) { /* Here 0 <= carry <= q*. */ carry = carry + (mp_twolimb_t) q_star * (mp_twolimb_t) *sourceptr++ + (mp_limb_t) ~(*destptr); /* Here 0 <= carry <= beta*q* + beta-1. */ *destptr++ = ~(mp_limb_t) carry; carry = carry >> GMP_LIMB_BITS; /* <= q* */ } cr = (mp_limb_t) carry; } /* Subtract cr from r_ptr[j + b_len], then forget about r_ptr[j + b_len]. */ if (cr > r_ptr[j + b_len]) { /* Subtraction gave a carry. */ q_star = q_star - 1; /* q* := q* - 1 */ /* Add b back. */ { const mp_limb_t *sourceptr = b_ptr; mp_limb_t *destptr = r_ptr + j; mp_limb_t carry = 0; size_t count; for (count = b_len; count > 0; count--) { mp_limb_t source1 = *sourceptr++; mp_limb_t source2 = *destptr; *destptr++ = source1 + source2 + carry; carry = (carry ? source1 >= (mp_limb_t) ~source2 : source1 > (mp_limb_t) ~source2); } } /* Forget about the carry and about r[j+n]. */ } } /* q* is determined. Store it as q[j]. */ q_ptr[j] = q_star; if (j == 0) break; j--; } } r_len = b_len; /* Normalise q. */ if (q_ptr[q_len - 1] == 0) q_len--; # if 0 /* Not needed here, since we need r only to compare it with b/2, and b is shifted left by s bits. */ /* Shift r right by s bits. */ if (s > 0) { mp_limb_t ptr = r_ptr + r_len; mp_twolimb_t accu = 0; size_t count; for (count = r_len; count > 0; count--) { accu = (mp_twolimb_t) (mp_limb_t) accu << GMP_LIMB_BITS; accu += (mp_twolimb_t) *--ptr << (GMP_LIMB_BITS - s); *ptr = (mp_limb_t) (accu >> GMP_LIMB_BITS); } } # endif /* Normalise r. */ while (r_len > 0 && r_ptr[r_len - 1] == 0) r_len--; } /* Compare r << 1 with b. */ if (r_len > b_len) goto increment_q; { size_t i; for (i = b_len;;) { mp_limb_t r_i = (i <= r_len && i > 0 ? r_ptr[i - 1] >> (GMP_LIMB_BITS - 1) : 0) | (i < r_len ? r_ptr[i] << 1 : 0); mp_limb_t b_i = (i < b_len ? b_ptr[i] : 0); if (r_i > b_i) goto increment_q; if (r_i < b_i) goto keep_q; if (i == 0) break; i--; } } if (q_len > 0 && ((q_ptr[0] & 1) != 0)) /* q is odd. */ increment_q: { size_t i; for (i = 0; i < q_len; i++) if (++(q_ptr[i]) != 0) goto keep_q; q_ptr[q_len++] = 1; } keep_q: if (tmp_roomptr != NULL) free (tmp_roomptr); q->limbs = q_ptr; q->nlimbs = q_len; return roomptr; } /* Convert a bignum a >= 0, multiplied with 10^extra_zeroes, to decimal representation. Destroys the contents of a. Return the allocated memory - containing the decimal digits in low-to-high order, terminated with a NUL character - in case of success, NULL in case of memory allocation failure. */ static char * convert_to_decimal (mpn_t a, size_t extra_zeroes) { mp_limb_t *a_ptr = a.limbs; size_t a_len = a.nlimbs; /* 0.03345 is slightly larger than log(2)/(9*log(10)). */ size_t c_len = 9 * ((size_t)(a_len * (GMP_LIMB_BITS * 0.03345f)) + 1); char *c_ptr = (char *) malloc (xsum (c_len, extra_zeroes)); if (c_ptr != NULL) { char *d_ptr = c_ptr; for (; extra_zeroes > 0; extra_zeroes--) *d_ptr++ = '0'; while (a_len > 0) { /* Divide a by 10^9, in-place. */ mp_limb_t remainder = 0; mp_limb_t *ptr = a_ptr + a_len; size_t count; for (count = a_len; count > 0; count--) { mp_twolimb_t num = ((mp_twolimb_t) remainder << GMP_LIMB_BITS) | *--ptr; *ptr = num / 1000000000; remainder = num % 1000000000; } /* Store the remainder as 9 decimal digits. */ for (count = 9; count > 0; count--) { *d_ptr++ = '0' + (remainder % 10); remainder = remainder / 10; } /* Normalize a. */ if (a_ptr[a_len - 1] == 0) a_len--; } /* Remove leading zeroes. */ while (d_ptr > c_ptr && d_ptr[-1] == '0') d_ptr--; /* But keep at least one zero. */ if (d_ptr == c_ptr) *d_ptr++ = '0'; /* Terminate the string. */ *d_ptr = '\0'; } return c_ptr; } # if NEED_PRINTF_LONG_DOUBLE /* Assuming x is finite and >= 0: write x as x = 2^e * m, where m is a bignum. Return the allocated memory in case of success, NULL in case of memory allocation failure. */ static void * decode_long_double (long double x, int *ep, mpn_t *mp) { mpn_t m; int exp; long double y; size_t i; /* Allocate memory for result. */ m.nlimbs = (LDBL_MANT_BIT + GMP_LIMB_BITS - 1) / GMP_LIMB_BITS; m.limbs = (mp_limb_t *) malloc (m.nlimbs * sizeof (mp_limb_t)); if (m.limbs == NULL) return NULL; /* Split into exponential part and mantissa. */ y = frexpl (x, &exp); if (!(y >= 0.0L && y < 1.0L)) abort (); /* x = 2^exp * y = 2^(exp - LDBL_MANT_BIT) * (y * LDBL_MANT_BIT), and the latter is an integer. */ /* Convert the mantissa (y * LDBL_MANT_BIT) to a sequence of limbs. I'm not sure whether it's safe to cast a 'long double' value between 2^31 and 2^32 to 'unsigned int', therefore play safe and cast only 'long double' values between 0 and 2^16 (to 'unsigned int' or 'int', doesn't matter). */ # if (LDBL_MANT_BIT % GMP_LIMB_BITS) != 0 # if (LDBL_MANT_BIT % GMP_LIMB_BITS) > GMP_LIMB_BITS / 2 { mp_limb_t hi, lo; y *= (mp_limb_t) 1 << (LDBL_MANT_BIT % (GMP_LIMB_BITS / 2)); hi = (int) y; y -= hi; if (!(y >= 0.0L && y < 1.0L)) abort (); y *= (mp_limb_t) 1 << (GMP_LIMB_BITS / 2); lo = (int) y; y -= lo; if (!(y >= 0.0L && y < 1.0L)) abort (); m.limbs[LDBL_MANT_BIT / GMP_LIMB_BITS] = (hi << (GMP_LIMB_BITS / 2)) | lo; } # else { mp_limb_t d; y *= (mp_limb_t) 1 << (LDBL_MANT_BIT % GMP_LIMB_BITS); d = (int) y; y -= d; if (!(y >= 0.0L && y < 1.0L)) abort (); m.limbs[LDBL_MANT_BIT / GMP_LIMB_BITS] = d; } # endif # endif for (i = LDBL_MANT_BIT / GMP_LIMB_BITS; i > 0; ) { mp_limb_t hi, lo; y *= (mp_limb_t) 1 << (GMP_LIMB_BITS / 2); hi = (int) y; y -= hi; if (!(y >= 0.0L && y < 1.0L)) abort (); y *= (mp_limb_t) 1 << (GMP_LIMB_BITS / 2); lo = (int) y; y -= lo; if (!(y >= 0.0L && y < 1.0L)) abort (); m.limbs[--i] = (hi << (GMP_LIMB_BITS / 2)) | lo; } #if 0 /* On FreeBSD 6.1/x86, 'long double' numbers sometimes have excess precision. */ if (!(y == 0.0L)) abort (); #endif /* Normalise. */ while (m.nlimbs > 0 && m.limbs[m.nlimbs - 1] == 0) m.nlimbs--; *mp = m; *ep = exp - LDBL_MANT_BIT; return m.limbs; } # endif # if NEED_PRINTF_DOUBLE /* Assuming x is finite and >= 0: write x as x = 2^e * m, where m is a bignum. Return the allocated memory in case of success, NULL in case of memory allocation failure. */ static void * decode_double (double x, int *ep, mpn_t *mp) { mpn_t m; int exp; double y; size_t i; /* Allocate memory for result. */ m.nlimbs = (DBL_MANT_BIT + GMP_LIMB_BITS - 1) / GMP_LIMB_BITS; m.limbs = (mp_limb_t *) malloc (m.nlimbs * sizeof (mp_limb_t)); if (m.limbs == NULL) return NULL; /* Split into exponential part and mantissa. */ y = frexp (x, &exp); if (!(y >= 0.0 && y < 1.0)) abort (); /* x = 2^exp * y = 2^(exp - DBL_MANT_BIT) * (y * DBL_MANT_BIT), and the latter is an integer. */ /* Convert the mantissa (y * DBL_MANT_BIT) to a sequence of limbs. I'm not sure whether it's safe to cast a 'double' value between 2^31 and 2^32 to 'unsigned int', therefore play safe and cast only 'double' values between 0 and 2^16 (to 'unsigned int' or 'int', doesn't matter). */ # if (DBL_MANT_BIT % GMP_LIMB_BITS) != 0 # if (DBL_MANT_BIT % GMP_LIMB_BITS) > GMP_LIMB_BITS / 2 { mp_limb_t hi, lo; y *= (mp_limb_t) 1 << (DBL_MANT_BIT % (GMP_LIMB_BITS / 2)); hi = (int) y; y -= hi; if (!(y >= 0.0 && y < 1.0)) abort (); y *= (mp_limb_t) 1 << (GMP_LIMB_BITS / 2); lo = (int) y; y -= lo; if (!(y >= 0.0 && y < 1.0)) abort (); m.limbs[DBL_MANT_BIT / GMP_LIMB_BITS] = (hi << (GMP_LIMB_BITS / 2)) | lo; } # else { mp_limb_t d; y *= (mp_limb_t) 1 << (DBL_MANT_BIT % GMP_LIMB_BITS); d = (int) y; y -= d; if (!(y >= 0.0 && y < 1.0)) abort (); m.limbs[DBL_MANT_BIT / GMP_LIMB_BITS] = d; } # endif # endif for (i = DBL_MANT_BIT / GMP_LIMB_BITS; i > 0; ) { mp_limb_t hi, lo; y *= (mp_limb_t) 1 << (GMP_LIMB_BITS / 2); hi = (int) y; y -= hi; if (!(y >= 0.0 && y < 1.0)) abort (); y *= (mp_limb_t) 1 << (GMP_LIMB_BITS / 2); lo = (int) y; y -= lo; if (!(y >= 0.0 && y < 1.0)) abort (); m.limbs[--i] = (hi << (GMP_LIMB_BITS / 2)) | lo; } if (!(y == 0.0)) abort (); /* Normalise. */ while (m.nlimbs > 0 && m.limbs[m.nlimbs - 1] == 0) m.nlimbs--; *mp = m; *ep = exp - DBL_MANT_BIT; return m.limbs; } # endif /* Assuming x = 2^e * m is finite and >= 0, and n is an integer: Returns the decimal representation of round (x * 10^n). Return the allocated memory - containing the decimal digits in low-to-high order, terminated with a NUL character - in case of success, NULL in case of memory allocation failure. */ static char * scale10_round_decimal_decoded (int e, mpn_t m, void *memory, int n) { int s; size_t extra_zeroes; unsigned int abs_n; unsigned int abs_s; mp_limb_t *pow5_ptr; size_t pow5_len; unsigned int s_limbs; unsigned int s_bits; mpn_t pow5; mpn_t z; void *z_memory; char *digits; if (memory == NULL) return NULL; /* x = 2^e * m, hence y = round (2^e * 10^n * m) = round (2^(e+n) * 5^n * m) = round (2^s * 5^n * m). */ s = e + n; extra_zeroes = 0; /* Factor out a common power of 10 if possible. */ if (s > 0 && n > 0) { extra_zeroes = (s < n ? s : n); s -= extra_zeroes; n -= extra_zeroes; } /* Here y = round (2^s * 5^n * m) * 10^extra_zeroes. Before converting to decimal, we need to compute z = round (2^s * 5^n * m). */ /* Compute 5^|n|, possibly shifted by |s| bits if n and s have the same sign. 2.322 is slightly larger than log(5)/log(2). */ abs_n = (n >= 0 ? n : -n); abs_s = (s >= 0 ? s : -s); pow5_ptr = (mp_limb_t *) malloc (((int)(abs_n * (2.322f / GMP_LIMB_BITS)) + 1 + abs_s / GMP_LIMB_BITS + 1) * sizeof (mp_limb_t)); if (pow5_ptr == NULL) { free (memory); return NULL; } /* Initialize with 1. */ pow5_ptr[0] = 1; pow5_len = 1; /* Multiply with 5^|n|. */ if (abs_n > 0) { static mp_limb_t const small_pow5[13 + 1] = { 1, 5, 25, 125, 625, 3125, 15625, 78125, 390625, 1953125, 9765625, 48828125, 244140625, 1220703125 }; unsigned int n13; for (n13 = 0; n13 <= abs_n; n13 += 13) { mp_limb_t digit1 = small_pow5[n13 + 13 <= abs_n ? 13 : abs_n - n13]; size_t j; mp_twolimb_t carry = 0; for (j = 0; j < pow5_len; j++) { mp_limb_t digit2 = pow5_ptr[j]; carry += (mp_twolimb_t) digit1 * (mp_twolimb_t) digit2; pow5_ptr[j] = (mp_limb_t) carry; carry = carry >> GMP_LIMB_BITS; } if (carry > 0) pow5_ptr[pow5_len++] = (mp_limb_t) carry; } } s_limbs = abs_s / GMP_LIMB_BITS; s_bits = abs_s % GMP_LIMB_BITS; if (n >= 0 ? s >= 0 : s <= 0) { /* Multiply with 2^|s|. */ if (s_bits > 0) { mp_limb_t *ptr = pow5_ptr; mp_twolimb_t accu = 0; size_t count; for (count = pow5_len; count > 0; count--) { accu += (mp_twolimb_t) *ptr << s_bits; *ptr++ = (mp_limb_t) accu; accu = accu >> GMP_LIMB_BITS; } if (accu > 0) { *ptr = (mp_limb_t) accu; pow5_len++; } } if (s_limbs > 0) { size_t count; for (count = pow5_len; count > 0;) { count--; pow5_ptr[s_limbs + count] = pow5_ptr[count]; } for (count = s_limbs; count > 0;) { count--; pow5_ptr[count] = 0; } pow5_len += s_limbs; } pow5.limbs = pow5_ptr; pow5.nlimbs = pow5_len; if (n >= 0) { /* Multiply m with pow5. No division needed. */ z_memory = multiply (m, pow5, &z); } else { /* Divide m by pow5 and round. */ z_memory = divide (m, pow5, &z); } } else { pow5.limbs = pow5_ptr; pow5.nlimbs = pow5_len; if (n >= 0) { /* n >= 0, s < 0. Multiply m with pow5, then divide by 2^|s|. */ mpn_t numerator; mpn_t denominator; void *tmp_memory; tmp_memory = multiply (m, pow5, &numerator); if (tmp_memory == NULL) { free (pow5_ptr); free (memory); return NULL; } /* Construct 2^|s|. */ { mp_limb_t *ptr = pow5_ptr + pow5_len; size_t i; for (i = 0; i < s_limbs; i++) ptr[i] = 0; ptr[s_limbs] = (mp_limb_t) 1 << s_bits; denominator.limbs = ptr; denominator.nlimbs = s_limbs + 1; } z_memory = divide (numerator, denominator, &z); free (tmp_memory); } else { /* n < 0, s > 0. Multiply m with 2^s, then divide by pow5. */ mpn_t numerator; mp_limb_t *num_ptr; num_ptr = (mp_limb_t *) malloc ((m.nlimbs + s_limbs + 1) * sizeof (mp_limb_t)); if (num_ptr == NULL) { free (pow5_ptr); free (memory); return NULL; } { mp_limb_t *destptr = num_ptr; { size_t i; for (i = 0; i < s_limbs; i++) *destptr++ = 0; } if (s_bits > 0) { const mp_limb_t *sourceptr = m.limbs; mp_twolimb_t accu = 0; size_t count; for (count = m.nlimbs; count > 0; count--) { accu += (mp_twolimb_t) *sourceptr++ << s_bits; *destptr++ = (mp_limb_t) accu; accu = accu >> GMP_LIMB_BITS; } if (accu > 0) *destptr++ = (mp_limb_t) accu; } else { const mp_limb_t *sourceptr = m.limbs; size_t count; for (count = m.nlimbs; count > 0; count--) *destptr++ = *sourceptr++; } numerator.limbs = num_ptr; numerator.nlimbs = destptr - num_ptr; } z_memory = divide (numerator, pow5, &z); free (num_ptr); } } free (pow5_ptr); free (memory); /* Here y = round (x * 10^n) = z * 10^extra_zeroes. */ if (z_memory == NULL) return NULL; digits = convert_to_decimal (z, extra_zeroes); free (z_memory); return digits; } # if NEED_PRINTF_LONG_DOUBLE /* Assuming x is finite and >= 0, and n is an integer: Returns the decimal representation of round (x * 10^n). Return the allocated memory - containing the decimal digits in low-to-high order, terminated with a NUL character - in case of success, NULL in case of memory allocation failure. */ static char * scale10_round_decimal_long_double (long double x, int n) { int e IF_LINT(= 0); mpn_t m; void *memory = decode_long_double (x, &e, &m); return scale10_round_decimal_decoded (e, m, memory, n); } # endif # if NEED_PRINTF_DOUBLE /* Assuming x is finite and >= 0, and n is an integer: Returns the decimal representation of round (x * 10^n). Return the allocated memory - containing the decimal digits in low-to-high order, terminated with a NUL character - in case of success, NULL in case of memory allocation failure. */ static char * scale10_round_decimal_double (double x, int n) { int e IF_LINT(= 0); mpn_t m; void *memory = decode_double (x, &e, &m); return scale10_round_decimal_decoded (e, m, memory, n); } # endif # if NEED_PRINTF_LONG_DOUBLE /* Assuming x is finite and > 0: Return an approximation for n with 10^n <= x < 10^(n+1). The approximation is usually the right n, but may be off by 1 sometimes. */ static int floorlog10l (long double x) { int exp; long double y; double z; double l; /* Split into exponential part and mantissa. */ y = frexpl (x, &exp); if (!(y >= 0.0L && y < 1.0L)) abort (); if (y == 0.0L) return INT_MIN; if (y < 0.5L) { while (y < (1.0L / (1 << (GMP_LIMB_BITS / 2)) / (1 << (GMP_LIMB_BITS / 2)))) { y *= 1.0L * (1 << (GMP_LIMB_BITS / 2)) * (1 << (GMP_LIMB_BITS / 2)); exp -= GMP_LIMB_BITS; } if (y < (1.0L / (1 << 16))) { y *= 1.0L * (1 << 16); exp -= 16; } if (y < (1.0L / (1 << 8))) { y *= 1.0L * (1 << 8); exp -= 8; } if (y < (1.0L / (1 << 4))) { y *= 1.0L * (1 << 4); exp -= 4; } if (y < (1.0L / (1 << 2))) { y *= 1.0L * (1 << 2); exp -= 2; } if (y < (1.0L / (1 << 1))) { y *= 1.0L * (1 << 1); exp -= 1; } } if (!(y >= 0.5L && y < 1.0L)) abort (); /* Compute an approximation for l = log2(x) = exp + log2(y). */ l = exp; z = y; if (z < 0.70710678118654752444) { z *= 1.4142135623730950488; l -= 0.5; } if (z < 0.8408964152537145431) { z *= 1.1892071150027210667; l -= 0.25; } if (z < 0.91700404320467123175) { z *= 1.0905077326652576592; l -= 0.125; } if (z < 0.9576032806985736469) { z *= 1.0442737824274138403; l -= 0.0625; } /* Now 0.95 <= z <= 1.01. */ z = 1 - z; /* log2(1-z) = 1/log(2) * (- z - z^2/2 - z^3/3 - z^4/4 - ...) Four terms are enough to get an approximation with error < 10^-7. */ l -= 1.4426950408889634074 * z * (1.0 + z * (0.5 + z * ((1.0 / 3) + z * 0.25))); /* Finally multiply with log(2)/log(10), yields an approximation for log10(x). */ l *= 0.30102999566398119523; /* Round down to the next integer. */ return (int) l + (l < 0 ? -1 : 0); } # endif # if NEED_PRINTF_DOUBLE /* Assuming x is finite and > 0: Return an approximation for n with 10^n <= x < 10^(n+1). The approximation is usually the right n, but may be off by 1 sometimes. */ static int floorlog10 (double x) { int exp; double y; double z; double l; /* Split into exponential part and mantissa. */ y = frexp (x, &exp); if (!(y >= 0.0 && y < 1.0)) abort (); if (y == 0.0) return INT_MIN; if (y < 0.5) { while (y < (1.0 / (1 << (GMP_LIMB_BITS / 2)) / (1 << (GMP_LIMB_BITS / 2)))) { y *= 1.0 * (1 << (GMP_LIMB_BITS / 2)) * (1 << (GMP_LIMB_BITS / 2)); exp -= GMP_LIMB_BITS; } if (y < (1.0 / (1 << 16))) { y *= 1.0 * (1 << 16); exp -= 16; } if (y < (1.0 / (1 << 8))) { y *= 1.0 * (1 << 8); exp -= 8; } if (y < (1.0 / (1 << 4))) { y *= 1.0 * (1 << 4); exp -= 4; } if (y < (1.0 / (1 << 2))) { y *= 1.0 * (1 << 2); exp -= 2; } if (y < (1.0 / (1 << 1))) { y *= 1.0 * (1 << 1); exp -= 1; } } if (!(y >= 0.5 && y < 1.0)) abort (); /* Compute an approximation for l = log2(x) = exp + log2(y). */ l = exp; z = y; if (z < 0.70710678118654752444) { z *= 1.4142135623730950488; l -= 0.5; } if (z < 0.8408964152537145431) { z *= 1.1892071150027210667; l -= 0.25; } if (z < 0.91700404320467123175) { z *= 1.0905077326652576592; l -= 0.125; } if (z < 0.9576032806985736469) { z *= 1.0442737824274138403; l -= 0.0625; } /* Now 0.95 <= z <= 1.01. */ z = 1 - z; /* log2(1-z) = 1/log(2) * (- z - z^2/2 - z^3/3 - z^4/4 - ...) Four terms are enough to get an approximation with error < 10^-7. */ l -= 1.4426950408889634074 * z * (1.0 + z * (0.5 + z * ((1.0 / 3) + z * 0.25))); /* Finally multiply with log(2)/log(10), yields an approximation for log10(x). */ l *= 0.30102999566398119523; /* Round down to the next integer. */ return (int) l + (l < 0 ? -1 : 0); } # endif /* Tests whether a string of digits consists of exactly PRECISION zeroes and a single '1' digit. */ static int is_borderline (const char *digits, size_t precision) { for (; precision > 0; precision--, digits++) if (*digits != '0') return 0; if (*digits != '1') return 0; digits++; return *digits == '\0'; } #endif DCHAR_T * VASNPRINTF (DCHAR_T *resultbuf, size_t *lengthp, const FCHAR_T *format, va_list args) { DIRECTIVES d; arguments a; if (PRINTF_PARSE (format, &d, &a) < 0) /* errno is already set. */ return NULL; #define CLEANUP() \ free (d.dir); \ if (a.arg) \ free (a.arg); if (PRINTF_FETCHARGS (args, &a) < 0) { CLEANUP (); errno = EINVAL; return NULL; } { size_t buf_neededlength; TCHAR_T *buf; TCHAR_T *buf_malloced; const FCHAR_T *cp; size_t i; DIRECTIVE *dp; /* Output string accumulator. */ DCHAR_T *result; size_t allocated; size_t length; /* Allocate a small buffer that will hold a directive passed to sprintf or snprintf. */ buf_neededlength = xsum4 (7, d.max_width_length, d.max_precision_length, 6); #if HAVE_ALLOCA if (buf_neededlength < 4000 / sizeof (TCHAR_T)) { buf = (TCHAR_T *) alloca (buf_neededlength * sizeof (TCHAR_T)); buf_malloced = NULL; } else #endif { size_t buf_memsize = xtimes (buf_neededlength, sizeof (TCHAR_T)); if (size_overflow_p (buf_memsize)) goto out_of_memory_1; buf = (TCHAR_T *) malloc (buf_memsize); if (buf == NULL) goto out_of_memory_1; buf_malloced = buf; } if (resultbuf != NULL) { result = resultbuf; allocated = *lengthp; } else { result = NULL; allocated = 0; } length = 0; /* Invariants: result is either == resultbuf or == NULL or malloc-allocated. If length > 0, then result != NULL. */ /* Ensures that allocated >= needed. Aborts through a jump to out_of_memory if needed is SIZE_MAX or otherwise too big. */ #define ENSURE_ALLOCATION(needed) \ if ((needed) > allocated) \ { \ size_t memory_size; \ DCHAR_T *memory; \ \ allocated = (allocated > 0 ? xtimes (allocated, 2) : 12); \ if ((needed) > allocated) \ allocated = (needed); \ memory_size = xtimes (allocated, sizeof (DCHAR_T)); \ if (size_overflow_p (memory_size)) \ goto out_of_memory; \ if (result == resultbuf || result == NULL) \ memory = (DCHAR_T *) malloc (memory_size); \ else \ memory = (DCHAR_T *) realloc (result, memory_size); \ if (memory == NULL) \ goto out_of_memory; \ if (result == resultbuf && length > 0) \ DCHAR_CPY (memory, result, length); \ result = memory; \ } for (cp = format, i = 0, dp = &d.dir[0]; ; cp = dp->dir_end, i++, dp++) { if (cp != dp->dir_start) { size_t n = dp->dir_start - cp; size_t augmented_length = xsum (length, n); ENSURE_ALLOCATION (augmented_length); /* This copies a piece of FCHAR_T[] into a DCHAR_T[]. Here we need that the format string contains only ASCII characters if FCHAR_T and DCHAR_T are not the same type. */ if (sizeof (FCHAR_T) == sizeof (DCHAR_T)) { DCHAR_CPY (result + length, (const DCHAR_T *) cp, n); length = augmented_length; } else { do result[length++] = (unsigned char) *cp++; while (--n > 0); } } if (i == d.count) break; /* Execute a single directive. */ if (dp->conversion == '%') { size_t augmented_length; if (!(dp->arg_index == ARG_NONE)) abort (); augmented_length = xsum (length, 1); ENSURE_ALLOCATION (augmented_length); result[length] = '%'; length = augmented_length; } else { if (!(dp->arg_index != ARG_NONE)) abort (); if (dp->conversion == 'n') { switch (a.arg[dp->arg_index].type) { case TYPE_COUNT_SCHAR_POINTER: *a.arg[dp->arg_index].a.a_count_schar_pointer = length; break; case TYPE_COUNT_SHORT_POINTER: *a.arg[dp->arg_index].a.a_count_short_pointer = length; break; case TYPE_COUNT_INT_POINTER: *a.arg[dp->arg_index].a.a_count_int_pointer = length; break; case TYPE_COUNT_LONGINT_POINTER: *a.arg[dp->arg_index].a.a_count_longint_pointer = length; break; #if HAVE_LONG_LONG_INT case TYPE_COUNT_LONGLONGINT_POINTER: *a.arg[dp->arg_index].a.a_count_longlongint_pointer = length; break; #endif default: abort (); } } #if ENABLE_UNISTDIO /* The unistdio extensions. */ else if (dp->conversion == 'U') { arg_type type = a.arg[dp->arg_index].type; int flags = dp->flags; int has_width; size_t width; int has_precision; size_t precision; has_width = 0; width = 0; if (dp->width_start != dp->width_end) { if (dp->width_arg_index != ARG_NONE) { int arg; if (!(a.arg[dp->width_arg_index].type == TYPE_INT)) abort (); arg = a.arg[dp->width_arg_index].a.a_int; if (arg < 0) { /* "A negative field width is taken as a '-' flag followed by a positive field width." */ flags |= FLAG_LEFT; width = (unsigned int) (-arg); } else width = arg; } else { const FCHAR_T *digitp = dp->width_start; do width = xsum (xtimes (width, 10), *digitp++ - '0'); while (digitp != dp->width_end); } has_width = 1; } has_precision = 0; precision = 0; if (dp->precision_start != dp->precision_end) { if (dp->precision_arg_index != ARG_NONE) { int arg; if (!(a.arg[dp->precision_arg_index].type == TYPE_INT)) abort (); arg = a.arg[dp->precision_arg_index].a.a_int; /* "A negative precision is taken as if the precision were omitted." */ if (arg >= 0) { precision = arg; has_precision = 1; } } else { const FCHAR_T *digitp = dp->precision_start + 1; precision = 0; while (digitp != dp->precision_end) precision = xsum (xtimes (precision, 10), *digitp++ - '0'); has_precision = 1; } } switch (type) { case TYPE_U8_STRING: { const uint8_t *arg = a.arg[dp->arg_index].a.a_u8_string; const uint8_t *arg_end; size_t characters; if (has_precision) { /* Use only PRECISION characters, from the left. */ arg_end = arg; characters = 0; for (; precision > 0; precision--) { int count = u8_strmblen (arg_end); if (count == 0) break; if (count < 0) { if (!(result == resultbuf || result == NULL)) free (result); if (buf_malloced != NULL) free (buf_malloced); CLEANUP (); errno = EILSEQ; return NULL; } arg_end += count; characters++; } } else if (has_width) { /* Use the entire string, and count the number of characters. */ arg_end = arg; characters = 0; for (;;) { int count = u8_strmblen (arg_end); if (count == 0) break; if (count < 0) { if (!(result == resultbuf || result == NULL)) free (result); if (buf_malloced != NULL) free (buf_malloced); CLEANUP (); errno = EILSEQ; return NULL; } arg_end += count; characters++; } } else { /* Use the entire string. */ arg_end = arg + u8_strlen (arg); /* The number of characters doesn't matter. */ characters = 0; } if (has_width && width > characters && !(dp->flags & FLAG_LEFT)) { size_t n = width - characters; ENSURE_ALLOCATION (xsum (length, n)); DCHAR_SET (result + length, ' ', n); length += n; } # if DCHAR_IS_UINT8_T { size_t n = arg_end - arg; ENSURE_ALLOCATION (xsum (length, n)); DCHAR_CPY (result + length, arg, n); length += n; } # else { /* Convert. */ DCHAR_T *converted = result + length; size_t converted_len = allocated - length; # if DCHAR_IS_TCHAR /* Convert from UTF-8 to locale encoding. */ converted = u8_conv_to_encoding (locale_charset (), iconveh_question_mark, arg, arg_end - arg, NULL, converted, &converted_len); # else /* Convert from UTF-8 to UTF-16/UTF-32. */ converted = U8_TO_DCHAR (arg, arg_end - arg, converted, &converted_len); # endif if (converted == NULL) { int saved_errno = errno; if (!(result == resultbuf || result == NULL)) free (result); if (buf_malloced != NULL) free (buf_malloced); CLEANUP (); errno = saved_errno; return NULL; } if (converted != result + length) { ENSURE_ALLOCATION (xsum (length, converted_len)); DCHAR_CPY (result + length, converted, converted_len); free (converted); } length += converted_len; } # endif if (has_width && width > characters && (dp->flags & FLAG_LEFT)) { size_t n = width - characters; ENSURE_ALLOCATION (xsum (length, n)); DCHAR_SET (result + length, ' ', n); length += n; } } break; case TYPE_U16_STRING: { const uint16_t *arg = a.arg[dp->arg_index].a.a_u16_string; const uint16_t *arg_end; size_t characters; if (has_precision) { /* Use only PRECISION characters, from the left. */ arg_end = arg; characters = 0; for (; precision > 0; precision--) { int count = u16_strmblen (arg_end); if (count == 0) break; if (count < 0) { if (!(result == resultbuf || result == NULL)) free (result); if (buf_malloced != NULL) free (buf_malloced); CLEANUP (); errno = EILSEQ; return NULL; } arg_end += count; characters++; } } else if (has_width) { /* Use the entire string, and count the number of characters. */ arg_end = arg; characters = 0; for (;;) { int count = u16_strmblen (arg_end); if (count == 0) break; if (count < 0) { if (!(result == resultbuf || result == NULL)) free (result); if (buf_malloced != NULL) free (buf_malloced); CLEANUP (); errno = EILSEQ; return NULL; } arg_end += count; characters++; } } else { /* Use the entire string. */ arg_end = arg + u16_strlen (arg); /* The number of characters doesn't matter. */ characters = 0; } if (has_width && width > characters && !(dp->flags & FLAG_LEFT)) { size_t n = width - characters; ENSURE_ALLOCATION (xsum (length, n)); DCHAR_SET (result + length, ' ', n); length += n; } # if DCHAR_IS_UINT16_T { size_t n = arg_end - arg; ENSURE_ALLOCATION (xsum (length, n)); DCHAR_CPY (result + length, arg, n); length += n; } # else { /* Convert. */ DCHAR_T *converted = result + length; size_t converted_len = allocated - length; # if DCHAR_IS_TCHAR /* Convert from UTF-16 to locale encoding. */ converted = u16_conv_to_encoding (locale_charset (), iconveh_question_mark, arg, arg_end - arg, NULL, converted, &converted_len); # else /* Convert from UTF-16 to UTF-8/UTF-32. */ converted = U16_TO_DCHAR (arg, arg_end - arg, converted, &converted_len); # endif if (converted == NULL) { int saved_errno = errno; if (!(result == resultbuf || result == NULL)) free (result); if (buf_malloced != NULL) free (buf_malloced); CLEANUP (); errno = saved_errno; return NULL; } if (converted != result + length) { ENSURE_ALLOCATION (xsum (length, converted_len)); DCHAR_CPY (result + length, converted, converted_len); free (converted); } length += converted_len; } # endif if (has_width && width > characters && (dp->flags & FLAG_LEFT)) { size_t n = width - characters; ENSURE_ALLOCATION (xsum (length, n)); DCHAR_SET (result + length, ' ', n); length += n; } } break; case TYPE_U32_STRING: { const uint32_t *arg = a.arg[dp->arg_index].a.a_u32_string; const uint32_t *arg_end; size_t characters; if (has_precision) { /* Use only PRECISION characters, from the left. */ arg_end = arg; characters = 0; for (; precision > 0; precision--) { int count = u32_strmblen (arg_end); if (count == 0) break; if (count < 0) { if (!(result == resultbuf || result == NULL)) free (result); if (buf_malloced != NULL) free (buf_malloced); CLEANUP (); errno = EILSEQ; return NULL; } arg_end += count; characters++; } } else if (has_width) { /* Use the entire string, and count the number of characters. */ arg_end = arg; characters = 0; for (;;) { int count = u32_strmblen (arg_end); if (count == 0) break; if (count < 0) { if (!(result == resultbuf || result == NULL)) free (result); if (buf_malloced != NULL) free (buf_malloced); CLEANUP (); errno = EILSEQ; return NULL; } arg_end += count; characters++; } } else { /* Use the entire string. */ arg_end = arg + u32_strlen (arg); /* The number of characters doesn't matter. */ characters = 0; } if (has_width && width > characters && !(dp->flags & FLAG_LEFT)) { size_t n = width - characters; ENSURE_ALLOCATION (xsum (length, n)); DCHAR_SET (result + length, ' ', n); length += n; } # if DCHAR_IS_UINT32_T { size_t n = arg_end - arg; ENSURE_ALLOCATION (xsum (length, n)); DCHAR_CPY (result + length, arg, n); length += n; } # else { /* Convert. */ DCHAR_T *converted = result + length; size_t converted_len = allocated - length; # if DCHAR_IS_TCHAR /* Convert from UTF-32 to locale encoding. */ converted = u32_conv_to_encoding (locale_charset (), iconveh_question_mark, arg, arg_end - arg, NULL, converted, &converted_len); # else /* Convert from UTF-32 to UTF-8/UTF-16. */ converted = U32_TO_DCHAR (arg, arg_end - arg, converted, &converted_len); # endif if (converted == NULL) { int saved_errno = errno; if (!(result == resultbuf || result == NULL)) free (result); if (buf_malloced != NULL) free (buf_malloced); CLEANUP (); errno = saved_errno; return NULL; } if (converted != result + length) { ENSURE_ALLOCATION (xsum (length, converted_len)); DCHAR_CPY (result + length, converted, converted_len); free (converted); } length += converted_len; } # endif if (has_width && width > characters && (dp->flags & FLAG_LEFT)) { size_t n = width - characters; ENSURE_ALLOCATION (xsum (length, n)); DCHAR_SET (result + length, ' ', n); length += n; } } break; default: abort (); } } #endif #if (!USE_SNPRINTF || (NEED_PRINTF_DIRECTIVE_LS && !defined IN_LIBINTL)) && HAVE_WCHAR_T else if (dp->conversion == 's' # if WIDE_CHAR_VERSION && a.arg[dp->arg_index].type != TYPE_WIDE_STRING # else && a.arg[dp->arg_index].type == TYPE_WIDE_STRING # endif ) { /* The normal handling of the 's' directive below requires allocating a temporary buffer. The determination of its length (tmp_length), in the case when a precision is specified, below requires a conversion between a char[] string and a wchar_t[] wide string. It could be done, but we have no guarantee that the implementation of sprintf will use the exactly same algorithm. Without this guarantee, it is possible to have buffer overrun bugs. In order to avoid such bugs, we implement the entire processing of the 's' directive ourselves. */ int flags = dp->flags; int has_width; size_t width; int has_precision; size_t precision; has_width = 0; width = 0; if (dp->width_start != dp->width_end) { if (dp->width_arg_index != ARG_NONE) { int arg; if (!(a.arg[dp->width_arg_index].type == TYPE_INT)) abort (); arg = a.arg[dp->width_arg_index].a.a_int; if (arg < 0) { /* "A negative field width is taken as a '-' flag followed by a positive field width." */ flags |= FLAG_LEFT; width = (unsigned int) (-arg); } else width = arg; } else { const FCHAR_T *digitp = dp->width_start; do width = xsum (xtimes (width, 10), *digitp++ - '0'); while (digitp != dp->width_end); } has_width = 1; } has_precision = 0; precision = 6; if (dp->precision_start != dp->precision_end) { if (dp->precision_arg_index != ARG_NONE) { int arg; if (!(a.arg[dp->precision_arg_index].type == TYPE_INT)) abort (); arg = a.arg[dp->precision_arg_index].a.a_int; /* "A negative precision is taken as if the precision were omitted." */ if (arg >= 0) { precision = arg; has_precision = 1; } } else { const FCHAR_T *digitp = dp->precision_start + 1; precision = 0; while (digitp != dp->precision_end) precision = xsum (xtimes (precision, 10), *digitp++ - '0'); has_precision = 1; } } # if WIDE_CHAR_VERSION /* %s in vasnwprintf. See the specification of fwprintf. */ { const char *arg = a.arg[dp->arg_index].a.a_string; const char *arg_end; size_t characters; if (has_precision) { /* Use only as many bytes as needed to produce PRECISION wide characters, from the left. */ # if HAVE_MBRTOWC mbstate_t state; memset (&state, '\0', sizeof (mbstate_t)); # endif arg_end = arg; characters = 0; for (; precision > 0; precision--) { int count; # if HAVE_MBRTOWC count = mbrlen (arg_end, MB_CUR_MAX, &state); # else count = mblen (arg_end, MB_CUR_MAX); # endif if (count == 0) /* Found the terminating NUL. */ break; if (count < 0) { /* Invalid or incomplete multibyte character. */ if (!(result == resultbuf || result == NULL)) free (result); if (buf_malloced != NULL) free (buf_malloced); CLEANUP (); errno = EILSEQ; return NULL; } arg_end += count; characters++; } } else if (has_width) { /* Use the entire string, and count the number of wide characters. */ # if HAVE_MBRTOWC mbstate_t state; memset (&state, '\0', sizeof (mbstate_t)); # endif arg_end = arg; characters = 0; for (;;) { int count; # if HAVE_MBRTOWC count = mbrlen (arg_end, MB_CUR_MAX, &state); # else count = mblen (arg_end, MB_CUR_MAX); # endif if (count == 0) /* Found the terminating NUL. */ break; if (count < 0) { /* Invalid or incomplete multibyte character. */ if (!(result == resultbuf || result == NULL)) free (result); if (buf_malloced != NULL) free (buf_malloced); CLEANUP (); errno = EILSEQ; return NULL; } arg_end += count; characters++; } } else { /* Use the entire string. */ arg_end = arg + strlen (arg); /* The number of characters doesn't matter. */ characters = 0; } if (has_width && width > characters && !(dp->flags & FLAG_LEFT)) { size_t n = width - characters; ENSURE_ALLOCATION (xsum (length, n)); DCHAR_SET (result + length, ' ', n); length += n; } if (has_precision || has_width) { /* We know the number of wide characters in advance. */ size_t remaining; # if HAVE_MBRTOWC mbstate_t state; memset (&state, '\0', sizeof (mbstate_t)); # endif ENSURE_ALLOCATION (xsum (length, characters)); for (remaining = characters; remaining > 0; remaining--) { wchar_t wc; int count; # if HAVE_MBRTOWC count = mbrtowc (&wc, arg, arg_end - arg, &state); # else count = mbtowc (&wc, arg, arg_end - arg); # endif if (count <= 0) /* mbrtowc not consistent with mbrlen, or mbtowc not consistent with mblen. */ abort (); result[length++] = wc; arg += count; } if (!(arg == arg_end)) abort (); } else { # if HAVE_MBRTOWC mbstate_t state; memset (&state, '\0', sizeof (mbstate_t)); # endif while (arg < arg_end) { wchar_t wc; int count; # if HAVE_MBRTOWC count = mbrtowc (&wc, arg, arg_end - arg, &state); # else count = mbtowc (&wc, arg, arg_end - arg); # endif if (count <= 0) /* mbrtowc not consistent with mbrlen, or mbtowc not consistent with mblen. */ abort (); ENSURE_ALLOCATION (xsum (length, 1)); result[length++] = wc; arg += count; } } if (has_width && width > characters && (dp->flags & FLAG_LEFT)) { size_t n = width - characters; ENSURE_ALLOCATION (xsum (length, n)); DCHAR_SET (result + length, ' ', n); length += n; } } # else /* %ls in vasnprintf. See the specification of fprintf. */ { const wchar_t *arg = a.arg[dp->arg_index].a.a_wide_string; const wchar_t *arg_end; size_t characters; # if !DCHAR_IS_TCHAR /* This code assumes that TCHAR_T is 'char'. */ typedef int TCHAR_T_verify[2 * (sizeof (TCHAR_T) == 1) - 1]; TCHAR_T *tmpsrc; DCHAR_T *tmpdst; size_t tmpdst_len; # endif size_t w; if (has_precision) { /* Use only as many wide characters as needed to produce at most PRECISION bytes, from the left. */ # if HAVE_WCRTOMB && !defined GNULIB_defined_mbstate_t mbstate_t state; memset (&state, '\0', sizeof (mbstate_t)); # endif arg_end = arg; characters = 0; while (precision > 0) { char cbuf[64]; /* Assume MB_CUR_MAX <= 64. */ int count; if (*arg_end == 0) /* Found the terminating null wide character. */ break; # if HAVE_WCRTOMB && !defined GNULIB_defined_mbstate_t count = wcrtomb (cbuf, *arg_end, &state); # else count = wctomb (cbuf, *arg_end); # endif if (count < 0) { /* Cannot convert. */ if (!(result == resultbuf || result == NULL)) free (result); if (buf_malloced != NULL) free (buf_malloced); CLEANUP (); errno = EILSEQ; return NULL; } if (precision < count) break; arg_end++; characters += count; precision -= count; } } # if DCHAR_IS_TCHAR else if (has_width) # else else # endif { /* Use the entire string, and count the number of bytes. */ # if HAVE_WCRTOMB && !defined GNULIB_defined_mbstate_t mbstate_t state; memset (&state, '\0', sizeof (mbstate_t)); # endif arg_end = arg; characters = 0; for (;;) { char cbuf[64]; /* Assume MB_CUR_MAX <= 64. */ int count; if (*arg_end == 0) /* Found the terminating null wide character. */ break; # if HAVE_WCRTOMB && !defined GNULIB_defined_mbstate_t count = wcrtomb (cbuf, *arg_end, &state); # else count = wctomb (cbuf, *arg_end); # endif if (count < 0) { /* Cannot convert. */ if (!(result == resultbuf || result == NULL)) free (result); if (buf_malloced != NULL) free (buf_malloced); CLEANUP (); errno = EILSEQ; return NULL; } arg_end++; characters += count; } } # if DCHAR_IS_TCHAR else { /* Use the entire string. */ arg_end = arg + local_wcslen (arg); /* The number of bytes doesn't matter. */ characters = 0; } # endif # if !DCHAR_IS_TCHAR /* Convert the string into a piece of temporary memory. */ tmpsrc = (TCHAR_T *) malloc (characters * sizeof (TCHAR_T)); if (tmpsrc == NULL) goto out_of_memory; { TCHAR_T *tmpptr = tmpsrc; size_t remaining; # if HAVE_WCRTOMB && !defined GNULIB_defined_mbstate_t mbstate_t state; memset (&state, '\0', sizeof (mbstate_t)); # endif for (remaining = characters; remaining > 0; ) { char cbuf[64]; /* Assume MB_CUR_MAX <= 64. */ int count; if (*arg == 0) abort (); # if HAVE_WCRTOMB && !defined GNULIB_defined_mbstate_t count = wcrtomb (cbuf, *arg, &state); # else count = wctomb (cbuf, *arg); # endif if (count <= 0) /* Inconsistency. */ abort (); memcpy (tmpptr, cbuf, count); tmpptr += count; arg++; remaining -= count; } if (!(arg == arg_end)) abort (); } /* Convert from TCHAR_T[] to DCHAR_T[]. */ tmpdst = DCHAR_CONV_FROM_ENCODING (locale_charset (), iconveh_question_mark, tmpsrc, characters, NULL, NULL, &tmpdst_len); if (tmpdst == NULL) { int saved_errno = errno; free (tmpsrc); if (!(result == resultbuf || result == NULL)) free (result); if (buf_malloced != NULL) free (buf_malloced); CLEANUP (); errno = saved_errno; return NULL; } free (tmpsrc); # endif if (has_width) { # if ENABLE_UNISTDIO /* Outside POSIX, it's preferrable to compare the width against the number of _characters_ of the converted value. */ w = DCHAR_MBSNLEN (result + length, characters); # else /* The width is compared against the number of _bytes_ of the converted value, says POSIX. */ w = characters; # endif } else /* w doesn't matter. */ w = 0; if (has_width && width > w && !(dp->flags & FLAG_LEFT)) { size_t n = width - w; ENSURE_ALLOCATION (xsum (length, n)); DCHAR_SET (result + length, ' ', n); length += n; } # if DCHAR_IS_TCHAR if (has_precision || has_width) { /* We know the number of bytes in advance. */ size_t remaining; # if HAVE_WCRTOMB && !defined GNULIB_defined_mbstate_t mbstate_t state; memset (&state, '\0', sizeof (mbstate_t)); # endif ENSURE_ALLOCATION (xsum (length, characters)); for (remaining = characters; remaining > 0; ) { char cbuf[64]; /* Assume MB_CUR_MAX <= 64. */ int count; if (*arg == 0) abort (); # if HAVE_WCRTOMB && !defined GNULIB_defined_mbstate_t count = wcrtomb (cbuf, *arg, &state); # else count = wctomb (cbuf, *arg); # endif if (count <= 0) /* Inconsistency. */ abort (); memcpy (result + length, cbuf, count); length += count; arg++; remaining -= count; } if (!(arg == arg_end)) abort (); } else { # if HAVE_WCRTOMB && !defined GNULIB_defined_mbstate_t mbstate_t state; memset (&state, '\0', sizeof (mbstate_t)); # endif while (arg < arg_end) { char cbuf[64]; /* Assume MB_CUR_MAX <= 64. */ int count; if (*arg == 0) abort (); # if HAVE_WCRTOMB && !defined GNULIB_defined_mbstate_t count = wcrtomb (cbuf, *arg, &state); # else count = wctomb (cbuf, *arg); # endif if (count <= 0) /* Inconsistency. */ abort (); ENSURE_ALLOCATION (xsum (length, count)); memcpy (result + length, cbuf, count); length += count; arg++; } } # else ENSURE_ALLOCATION (xsum (length, tmpdst_len)); DCHAR_CPY (result + length, tmpdst, tmpdst_len); free (tmpdst); length += tmpdst_len; # endif if (has_width && width > w && (dp->flags & FLAG_LEFT)) { size_t n = width - w; ENSURE_ALLOCATION (xsum (length, n)); DCHAR_SET (result + length, ' ', n); length += n; } } } # endif #endif #if (NEED_PRINTF_DIRECTIVE_A || NEED_PRINTF_LONG_DOUBLE || NEED_PRINTF_DOUBLE) && !defined IN_LIBINTL else if ((dp->conversion == 'a' || dp->conversion == 'A') # if !(NEED_PRINTF_DIRECTIVE_A || (NEED_PRINTF_LONG_DOUBLE && NEED_PRINTF_DOUBLE)) && (0 # if NEED_PRINTF_DOUBLE || a.arg[dp->arg_index].type == TYPE_DOUBLE # endif # if NEED_PRINTF_LONG_DOUBLE || a.arg[dp->arg_index].type == TYPE_LONGDOUBLE # endif ) # endif ) { arg_type type = a.arg[dp->arg_index].type; int flags = dp->flags; int has_width; size_t width; int has_precision; size_t precision; size_t tmp_length; DCHAR_T tmpbuf[700]; DCHAR_T *tmp; DCHAR_T *pad_ptr; DCHAR_T *p; has_width = 0; width = 0; if (dp->width_start != dp->width_end) { if (dp->width_arg_index != ARG_NONE) { int arg; if (!(a.arg[dp->width_arg_index].type == TYPE_INT)) abort (); arg = a.arg[dp->width_arg_index].a.a_int; if (arg < 0) { /* "A negative field width is taken as a '-' flag followed by a positive field width." */ flags |= FLAG_LEFT; width = (unsigned int) (-arg); } else width = arg; } else { const FCHAR_T *digitp = dp->width_start; do width = xsum (xtimes (width, 10), *digitp++ - '0'); while (digitp != dp->width_end); } has_width = 1; } has_precision = 0; precision = 0; if (dp->precision_start != dp->precision_end) { if (dp->precision_arg_index != ARG_NONE) { int arg; if (!(a.arg[dp->precision_arg_index].type == TYPE_INT)) abort (); arg = a.arg[dp->precision_arg_index].a.a_int; /* "A negative precision is taken as if the precision were omitted." */ if (arg >= 0) { precision = arg; has_precision = 1; } } else { const FCHAR_T *digitp = dp->precision_start + 1; precision = 0; while (digitp != dp->precision_end) precision = xsum (xtimes (precision, 10), *digitp++ - '0'); has_precision = 1; } } /* Allocate a temporary buffer of sufficient size. */ if (type == TYPE_LONGDOUBLE) tmp_length = (unsigned int) ((LDBL_DIG + 1) * 0.831 /* decimal -> hexadecimal */ ) + 1; /* turn floor into ceil */ else tmp_length = (unsigned int) ((DBL_DIG + 1) * 0.831 /* decimal -> hexadecimal */ ) + 1; /* turn floor into ceil */ if (tmp_length < precision) tmp_length = precision; /* Account for sign, decimal point etc. */ tmp_length = xsum (tmp_length, 12); if (tmp_length < width) tmp_length = width; tmp_length = xsum (tmp_length, 1); /* account for trailing NUL */ if (tmp_length <= sizeof (tmpbuf) / sizeof (DCHAR_T)) tmp = tmpbuf; else { size_t tmp_memsize = xtimes (tmp_length, sizeof (DCHAR_T)); if (size_overflow_p (tmp_memsize)) /* Overflow, would lead to out of memory. */ goto out_of_memory; tmp = (DCHAR_T *) malloc (tmp_memsize); if (tmp == NULL) /* Out of memory. */ goto out_of_memory; } pad_ptr = NULL; p = tmp; if (type == TYPE_LONGDOUBLE) { # if NEED_PRINTF_DIRECTIVE_A || NEED_PRINTF_LONG_DOUBLE long double arg = a.arg[dp->arg_index].a.a_longdouble; if (isnanl (arg)) { if (dp->conversion == 'A') { *p++ = 'N'; *p++ = 'A'; *p++ = 'N'; } else { *p++ = 'n'; *p++ = 'a'; *p++ = 'n'; } } else { int sign = 0; DECL_LONG_DOUBLE_ROUNDING BEGIN_LONG_DOUBLE_ROUNDING (); if (signbit (arg)) /* arg < 0.0L or negative zero */ { sign = -1; arg = -arg; } if (sign < 0) *p++ = '-'; else if (flags & FLAG_SHOWSIGN) *p++ = '+'; else if (flags & FLAG_SPACE) *p++ = ' '; if (arg > 0.0L && arg + arg == arg) { if (dp->conversion == 'A') { *p++ = 'I'; *p++ = 'N'; *p++ = 'F'; } else { *p++ = 'i'; *p++ = 'n'; *p++ = 'f'; } } else { int exponent; long double mantissa; if (arg > 0.0L) mantissa = printf_frexpl (arg, &exponent); else { exponent = 0; mantissa = 0.0L; } if (has_precision && precision < (unsigned int) ((LDBL_DIG + 1) * 0.831) + 1) { /* Round the mantissa. */ long double tail = mantissa; size_t q; for (q = precision; ; q--) { int digit = (int) tail; tail -= digit; if (q == 0) { if (digit & 1 ? tail >= 0.5L : tail > 0.5L) tail = 1 - tail; else tail = - tail; break; } tail *= 16.0L; } if (tail != 0.0L) for (q = precision; q > 0; q--) tail *= 0.0625L; mantissa += tail; } *p++ = '0'; *p++ = dp->conversion - 'A' + 'X'; pad_ptr = p; { int digit; digit = (int) mantissa; mantissa -= digit; *p++ = '0' + digit; if ((flags & FLAG_ALT) || mantissa > 0.0L || precision > 0) { *p++ = decimal_point_char (); /* This loop terminates because we assume that FLT_RADIX is a power of 2. */ while (mantissa > 0.0L) { mantissa *= 16.0L; digit = (int) mantissa; mantissa -= digit; *p++ = digit + (digit < 10 ? '0' : dp->conversion - 10); if (precision > 0) precision--; } while (precision > 0) { *p++ = '0'; precision--; } } } *p++ = dp->conversion - 'A' + 'P'; # if WIDE_CHAR_VERSION { static const wchar_t decimal_format[] = { '%', '+', 'd', '\0' }; SNPRINTF (p, 6 + 1, decimal_format, exponent); } while (*p != '\0') p++; # else if (sizeof (DCHAR_T) == 1) { sprintf ((char *) p, "%+d", exponent); while (*p != '\0') p++; } else { char expbuf[6 + 1]; const char *ep; sprintf (expbuf, "%+d", exponent); for (ep = expbuf; (*p = *ep) != '\0'; ep++) p++; } # endif } END_LONG_DOUBLE_ROUNDING (); } # else abort (); # endif } else { # if NEED_PRINTF_DIRECTIVE_A || NEED_PRINTF_DOUBLE double arg = a.arg[dp->arg_index].a.a_double; if (isnand (arg)) { if (dp->conversion == 'A') { *p++ = 'N'; *p++ = 'A'; *p++ = 'N'; } else { *p++ = 'n'; *p++ = 'a'; *p++ = 'n'; } } else { int sign = 0; if (signbit (arg)) /* arg < 0.0 or negative zero */ { sign = -1; arg = -arg; } if (sign < 0) *p++ = '-'; else if (flags & FLAG_SHOWSIGN) *p++ = '+'; else if (flags & FLAG_SPACE) *p++ = ' '; if (arg > 0.0 && arg + arg == arg) { if (dp->conversion == 'A') { *p++ = 'I'; *p++ = 'N'; *p++ = 'F'; } else { *p++ = 'i'; *p++ = 'n'; *p++ = 'f'; } } else { int exponent; double mantissa; if (arg > 0.0) mantissa = printf_frexp (arg, &exponent); else { exponent = 0; mantissa = 0.0; } if (has_precision && precision < (unsigned int) ((DBL_DIG + 1) * 0.831) + 1) { /* Round the mantissa. */ double tail = mantissa; size_t q; for (q = precision; ; q--) { int digit = (int) tail; tail -= digit; if (q == 0) { if (digit & 1 ? tail >= 0.5 : tail > 0.5) tail = 1 - tail; else tail = - tail; break; } tail *= 16.0; } if (tail != 0.0) for (q = precision; q > 0; q--) tail *= 0.0625; mantissa += tail; } *p++ = '0'; *p++ = dp->conversion - 'A' + 'X'; pad_ptr = p; { int digit; digit = (int) mantissa; mantissa -= digit; *p++ = '0' + digit; if ((flags & FLAG_ALT) || mantissa > 0.0 || precision > 0) { *p++ = decimal_point_char (); /* This loop terminates because we assume that FLT_RADIX is a power of 2. */ while (mantissa > 0.0) { mantissa *= 16.0; digit = (int) mantissa; mantissa -= digit; *p++ = digit + (digit < 10 ? '0' : dp->conversion - 10); if (precision > 0) precision--; } while (precision > 0) { *p++ = '0'; precision--; } } } *p++ = dp->conversion - 'A' + 'P'; # if WIDE_CHAR_VERSION { static const wchar_t decimal_format[] = { '%', '+', 'd', '\0' }; SNPRINTF (p, 6 + 1, decimal_format, exponent); } while (*p != '\0') p++; # else if (sizeof (DCHAR_T) == 1) { sprintf ((char *) p, "%+d", exponent); while (*p != '\0') p++; } else { char expbuf[6 + 1]; const char *ep; sprintf (expbuf, "%+d", exponent); for (ep = expbuf; (*p = *ep) != '\0'; ep++) p++; } # endif } } # else abort (); # endif } /* The generated string now extends from tmp to p, with the zero padding insertion point being at pad_ptr. */ if (has_width && p - tmp < width) { size_t pad = width - (p - tmp); DCHAR_T *end = p + pad; if (flags & FLAG_LEFT) { /* Pad with spaces on the right. */ for (; pad > 0; pad--) *p++ = ' '; } else if ((flags & FLAG_ZERO) && pad_ptr != NULL) { /* Pad with zeroes. */ DCHAR_T *q = end; while (p > pad_ptr) *--q = *--p; for (; pad > 0; pad--) *p++ = '0'; } else { /* Pad with spaces on the left. */ DCHAR_T *q = end; while (p > tmp) *--q = *--p; for (; pad > 0; pad--) *p++ = ' '; } p = end; } { size_t count = p - tmp; if (count >= tmp_length) /* tmp_length was incorrectly calculated - fix the code above! */ abort (); /* Make room for the result. */ if (count >= allocated - length) { size_t n = xsum (length, count); ENSURE_ALLOCATION (n); } /* Append the result. */ memcpy (result + length, tmp, count * sizeof (DCHAR_T)); if (tmp != tmpbuf) free (tmp); length += count; } } #endif #if (NEED_PRINTF_INFINITE_DOUBLE || NEED_PRINTF_DOUBLE || NEED_PRINTF_INFINITE_LONG_DOUBLE || NEED_PRINTF_LONG_DOUBLE) && !defined IN_LIBINTL else if ((dp->conversion == 'f' || dp->conversion == 'F' || dp->conversion == 'e' || dp->conversion == 'E' || dp->conversion == 'g' || dp->conversion == 'G' || dp->conversion == 'a' || dp->conversion == 'A') && (0 # if NEED_PRINTF_DOUBLE || a.arg[dp->arg_index].type == TYPE_DOUBLE # elif NEED_PRINTF_INFINITE_DOUBLE || (a.arg[dp->arg_index].type == TYPE_DOUBLE /* The systems (mingw) which produce wrong output for Inf, -Inf, and NaN also do so for -0.0. Therefore we treat this case here as well. */ && is_infinite_or_zero (a.arg[dp->arg_index].a.a_double)) # endif # if NEED_PRINTF_LONG_DOUBLE || a.arg[dp->arg_index].type == TYPE_LONGDOUBLE # elif NEED_PRINTF_INFINITE_LONG_DOUBLE || (a.arg[dp->arg_index].type == TYPE_LONGDOUBLE /* Some systems produce wrong output for Inf, -Inf, and NaN. Some systems in this category (IRIX 5.3) also do so for -0.0. Therefore we treat this case here as well. */ && is_infinite_or_zerol (a.arg[dp->arg_index].a.a_longdouble)) # endif )) { # if (NEED_PRINTF_DOUBLE || NEED_PRINTF_INFINITE_DOUBLE) && (NEED_PRINTF_LONG_DOUBLE || NEED_PRINTF_INFINITE_LONG_DOUBLE) arg_type type = a.arg[dp->arg_index].type; # endif int flags = dp->flags; int has_width; size_t width; int has_precision; size_t precision; size_t tmp_length; DCHAR_T tmpbuf[700]; DCHAR_T *tmp; DCHAR_T *pad_ptr; DCHAR_T *p; has_width = 0; width = 0; if (dp->width_start != dp->width_end) { if (dp->width_arg_index != ARG_NONE) { int arg; if (!(a.arg[dp->width_arg_index].type == TYPE_INT)) abort (); arg = a.arg[dp->width_arg_index].a.a_int; if (arg < 0) { /* "A negative field width is taken as a '-' flag followed by a positive field width." */ flags |= FLAG_LEFT; width = (unsigned int) (-arg); } else width = arg; } else { const FCHAR_T *digitp = dp->width_start; do width = xsum (xtimes (width, 10), *digitp++ - '0'); while (digitp != dp->width_end); } has_width = 1; } has_precision = 0; precision = 0; if (dp->precision_start != dp->precision_end) { if (dp->precision_arg_index != ARG_NONE) { int arg; if (!(a.arg[dp->precision_arg_index].type == TYPE_INT)) abort (); arg = a.arg[dp->precision_arg_index].a.a_int; /* "A negative precision is taken as if the precision were omitted." */ if (arg >= 0) { precision = arg; has_precision = 1; } } else { const FCHAR_T *digitp = dp->precision_start + 1; precision = 0; while (digitp != dp->precision_end) precision = xsum (xtimes (precision, 10), *digitp++ - '0'); has_precision = 1; } } /* POSIX specifies the default precision to be 6 for %f, %F, %e, %E, but not for %g, %G. Implementations appear to use the same default precision also for %g, %G. But for %a, %A, the default precision is 0. */ if (!has_precision) if (!(dp->conversion == 'a' || dp->conversion == 'A')) precision = 6; /* Allocate a temporary buffer of sufficient size. */ # if NEED_PRINTF_DOUBLE && NEED_PRINTF_LONG_DOUBLE tmp_length = (type == TYPE_LONGDOUBLE ? LDBL_DIG + 1 : DBL_DIG + 1); # elif NEED_PRINTF_INFINITE_DOUBLE && NEED_PRINTF_LONG_DOUBLE tmp_length = (type == TYPE_LONGDOUBLE ? LDBL_DIG + 1 : 0); # elif NEED_PRINTF_LONG_DOUBLE tmp_length = LDBL_DIG + 1; # elif NEED_PRINTF_DOUBLE tmp_length = DBL_DIG + 1; # else tmp_length = 0; # endif if (tmp_length < precision) tmp_length = precision; # if NEED_PRINTF_LONG_DOUBLE # if NEED_PRINTF_DOUBLE || NEED_PRINTF_INFINITE_DOUBLE if (type == TYPE_LONGDOUBLE) # endif if (dp->conversion == 'f' || dp->conversion == 'F') { long double arg = a.arg[dp->arg_index].a.a_longdouble; if (!(isnanl (arg) || arg + arg == arg)) { /* arg is finite and nonzero. */ int exponent = floorlog10l (arg < 0 ? -arg : arg); if (exponent >= 0 && tmp_length < exponent + precision) tmp_length = exponent + precision; } } # endif # if NEED_PRINTF_DOUBLE # if NEED_PRINTF_LONG_DOUBLE || NEED_PRINTF_INFINITE_LONG_DOUBLE if (type == TYPE_DOUBLE) # endif if (dp->conversion == 'f' || dp->conversion == 'F') { double arg = a.arg[dp->arg_index].a.a_double; if (!(isnand (arg) || arg + arg == arg)) { /* arg is finite and nonzero. */ int exponent = floorlog10 (arg < 0 ? -arg : arg); if (exponent >= 0 && tmp_length < exponent + precision) tmp_length = exponent + precision; } } # endif /* Account for sign, decimal point etc. */ tmp_length = xsum (tmp_length, 12); if (tmp_length < width) tmp_length = width; tmp_length = xsum (tmp_length, 1); /* account for trailing NUL */ if (tmp_length <= sizeof (tmpbuf) / sizeof (DCHAR_T)) tmp = tmpbuf; else { size_t tmp_memsize = xtimes (tmp_length, sizeof (DCHAR_T)); if (size_overflow_p (tmp_memsize)) /* Overflow, would lead to out of memory. */ goto out_of_memory; tmp = (DCHAR_T *) malloc (tmp_memsize); if (tmp == NULL) /* Out of memory. */ goto out_of_memory; } pad_ptr = NULL; p = tmp; # if NEED_PRINTF_LONG_DOUBLE || NEED_PRINTF_INFINITE_LONG_DOUBLE # if NEED_PRINTF_DOUBLE || NEED_PRINTF_INFINITE_DOUBLE if (type == TYPE_LONGDOUBLE) # endif { long double arg = a.arg[dp->arg_index].a.a_longdouble; if (isnanl (arg)) { if (dp->conversion >= 'A' && dp->conversion <= 'Z') { *p++ = 'N'; *p++ = 'A'; *p++ = 'N'; } else { *p++ = 'n'; *p++ = 'a'; *p++ = 'n'; } } else { int sign = 0; DECL_LONG_DOUBLE_ROUNDING BEGIN_LONG_DOUBLE_ROUNDING (); if (signbit (arg)) /* arg < 0.0L or negative zero */ { sign = -1; arg = -arg; } if (sign < 0) *p++ = '-'; else if (flags & FLAG_SHOWSIGN) *p++ = '+'; else if (flags & FLAG_SPACE) *p++ = ' '; if (arg > 0.0L && arg + arg == arg) { if (dp->conversion >= 'A' && dp->conversion <= 'Z') { *p++ = 'I'; *p++ = 'N'; *p++ = 'F'; } else { *p++ = 'i'; *p++ = 'n'; *p++ = 'f'; } } else { # if NEED_PRINTF_LONG_DOUBLE pad_ptr = p; if (dp->conversion == 'f' || dp->conversion == 'F') { char *digits; size_t ndigits; digits = scale10_round_decimal_long_double (arg, precision); if (digits == NULL) { END_LONG_DOUBLE_ROUNDING (); goto out_of_memory; } ndigits = strlen (digits); if (ndigits > precision) do { --ndigits; *p++ = digits[ndigits]; } while (ndigits > precision); else *p++ = '0'; /* Here ndigits <= precision. */ if ((flags & FLAG_ALT) || precision > 0) { *p++ = decimal_point_char (); for (; precision > ndigits; precision--) *p++ = '0'; while (ndigits > 0) { --ndigits; *p++ = digits[ndigits]; } } free (digits); } else if (dp->conversion == 'e' || dp->conversion == 'E') { int exponent; if (arg == 0.0L) { exponent = 0; *p++ = '0'; if ((flags & FLAG_ALT) || precision > 0) { *p++ = decimal_point_char (); for (; precision > 0; precision--) *p++ = '0'; } } else { /* arg > 0.0L. */ int adjusted; char *digits; size_t ndigits; exponent = floorlog10l (arg); adjusted = 0; for (;;) { digits = scale10_round_decimal_long_double (arg, (int)precision - exponent); if (digits == NULL) { END_LONG_DOUBLE_ROUNDING (); goto out_of_memory; } ndigits = strlen (digits); if (ndigits == precision + 1) break; if (ndigits < precision || ndigits > precision + 2) /* The exponent was not guessed precisely enough. */ abort (); if (adjusted) /* None of two values of exponent is the right one. Prevent an endless loop. */ abort (); free (digits); if (ndigits == precision) exponent -= 1; else exponent += 1; adjusted = 1; } /* Here ndigits = precision+1. */ if (is_borderline (digits, precision)) { /* Maybe the exponent guess was too high and a smaller exponent can be reached by turning a 10...0 into 9...9x. */ char *digits2 = scale10_round_decimal_long_double (arg, (int)precision - exponent + 1); if (digits2 == NULL) { free (digits); END_LONG_DOUBLE_ROUNDING (); goto out_of_memory; } if (strlen (digits2) == precision + 1) { free (digits); digits = digits2; exponent -= 1; } else free (digits2); } /* Here ndigits = precision+1. */ *p++ = digits[--ndigits]; if ((flags & FLAG_ALT) || precision > 0) { *p++ = decimal_point_char (); while (ndigits > 0) { --ndigits; *p++ = digits[ndigits]; } } free (digits); } *p++ = dp->conversion; /* 'e' or 'E' */ # if WIDE_CHAR_VERSION { static const wchar_t decimal_format[] = { '%', '+', '.', '2', 'd', '\0' }; SNPRINTF (p, 6 + 1, decimal_format, exponent); } while (*p != '\0') p++; # else if (sizeof (DCHAR_T) == 1) { sprintf ((char *) p, "%+.2d", exponent); while (*p != '\0') p++; } else { char expbuf[6 + 1]; const char *ep; sprintf (expbuf, "%+.2d", exponent); for (ep = expbuf; (*p = *ep) != '\0'; ep++) p++; } # endif } else if (dp->conversion == 'g' || dp->conversion == 'G') { if (precision == 0) precision = 1; /* precision >= 1. */ if (arg == 0.0L) /* The exponent is 0, >= -4, < precision. Use fixed-point notation. */ { size_t ndigits = precision; /* Number of trailing zeroes that have to be dropped. */ size_t nzeroes = (flags & FLAG_ALT ? 0 : precision - 1); --ndigits; *p++ = '0'; if ((flags & FLAG_ALT) || ndigits > nzeroes) { *p++ = decimal_point_char (); while (ndigits > nzeroes) { --ndigits; *p++ = '0'; } } } else { /* arg > 0.0L. */ int exponent; int adjusted; char *digits; size_t ndigits; size_t nzeroes; exponent = floorlog10l (arg); adjusted = 0; for (;;) { digits = scale10_round_decimal_long_double (arg, (int)(precision - 1) - exponent); if (digits == NULL) { END_LONG_DOUBLE_ROUNDING (); goto out_of_memory; } ndigits = strlen (digits); if (ndigits == precision) break; if (ndigits < precision - 1 || ndigits > precision + 1) /* The exponent was not guessed precisely enough. */ abort (); if (adjusted) /* None of two values of exponent is the right one. Prevent an endless loop. */ abort (); free (digits); if (ndigits < precision) exponent -= 1; else exponent += 1; adjusted = 1; } /* Here ndigits = precision. */ if (is_borderline (digits, precision - 1)) { /* Maybe the exponent guess was too high and a smaller exponent can be reached by turning a 10...0 into 9...9x. */ char *digits2 = scale10_round_decimal_long_double (arg, (int)(precision - 1) - exponent + 1); if (digits2 == NULL) { free (digits); END_LONG_DOUBLE_ROUNDING (); goto out_of_memory; } if (strlen (digits2) == precision) { free (digits); digits = digits2; exponent -= 1; } else free (digits2); } /* Here ndigits = precision. */ /* Determine the number of trailing zeroes that have to be dropped. */ nzeroes = 0; if ((flags & FLAG_ALT) == 0) while (nzeroes < ndigits && digits[nzeroes] == '0') nzeroes++; /* The exponent is now determined. */ if (exponent >= -4 && exponent < (long)precision) { /* Fixed-point notation: max(exponent,0)+1 digits, then the decimal point, then the remaining digits without trailing zeroes. */ if (exponent >= 0) { size_t count = exponent + 1; /* Note: count <= precision = ndigits. */ for (; count > 0; count--) *p++ = digits[--ndigits]; if ((flags & FLAG_ALT) || ndigits > nzeroes) { *p++ = decimal_point_char (); while (ndigits > nzeroes) { --ndigits; *p++ = digits[ndigits]; } } } else { size_t count = -exponent - 1; *p++ = '0'; *p++ = decimal_point_char (); for (; count > 0; count--) *p++ = '0'; while (ndigits > nzeroes) { --ndigits; *p++ = digits[ndigits]; } } } else { /* Exponential notation. */ *p++ = digits[--ndigits]; if ((flags & FLAG_ALT) || ndigits > nzeroes) { *p++ = decimal_point_char (); while (ndigits > nzeroes) { --ndigits; *p++ = digits[ndigits]; } } *p++ = dp->conversion - 'G' + 'E'; /* 'e' or 'E' */ # if WIDE_CHAR_VERSION { static const wchar_t decimal_format[] = { '%', '+', '.', '2', 'd', '\0' }; SNPRINTF (p, 6 + 1, decimal_format, exponent); } while (*p != '\0') p++; # else if (sizeof (DCHAR_T) == 1) { sprintf ((char *) p, "%+.2d", exponent); while (*p != '\0') p++; } else { char expbuf[6 + 1]; const char *ep; sprintf (expbuf, "%+.2d", exponent); for (ep = expbuf; (*p = *ep) != '\0'; ep++) p++; } # endif } free (digits); } } else abort (); # else /* arg is finite. */ if (!(arg == 0.0L)) abort (); pad_ptr = p; if (dp->conversion == 'f' || dp->conversion == 'F') { *p++ = '0'; if ((flags & FLAG_ALT) || precision > 0) { *p++ = decimal_point_char (); for (; precision > 0; precision--) *p++ = '0'; } } else if (dp->conversion == 'e' || dp->conversion == 'E') { *p++ = '0'; if ((flags & FLAG_ALT) || precision > 0) { *p++ = decimal_point_char (); for (; precision > 0; precision--) *p++ = '0'; } *p++ = dp->conversion; /* 'e' or 'E' */ *p++ = '+'; *p++ = '0'; *p++ = '0'; } else if (dp->conversion == 'g' || dp->conversion == 'G') { *p++ = '0'; if (flags & FLAG_ALT) { size_t ndigits = (precision > 0 ? precision - 1 : 0); *p++ = decimal_point_char (); for (; ndigits > 0; --ndigits) *p++ = '0'; } } else if (dp->conversion == 'a' || dp->conversion == 'A') { *p++ = '0'; *p++ = dp->conversion - 'A' + 'X'; pad_ptr = p; *p++ = '0'; if ((flags & FLAG_ALT) || precision > 0) { *p++ = decimal_point_char (); for (; precision > 0; precision--) *p++ = '0'; } *p++ = dp->conversion - 'A' + 'P'; *p++ = '+'; *p++ = '0'; } else abort (); # endif } END_LONG_DOUBLE_ROUNDING (); } } # if NEED_PRINTF_DOUBLE || NEED_PRINTF_INFINITE_DOUBLE else # endif # endif # if NEED_PRINTF_DOUBLE || NEED_PRINTF_INFINITE_DOUBLE { double arg = a.arg[dp->arg_index].a.a_double; if (isnand (arg)) { if (dp->conversion >= 'A' && dp->conversion <= 'Z') { *p++ = 'N'; *p++ = 'A'; *p++ = 'N'; } else { *p++ = 'n'; *p++ = 'a'; *p++ = 'n'; } } else { int sign = 0; if (signbit (arg)) /* arg < 0.0 or negative zero */ { sign = -1; arg = -arg; } if (sign < 0) *p++ = '-'; else if (flags & FLAG_SHOWSIGN) *p++ = '+'; else if (flags & FLAG_SPACE) *p++ = ' '; if (arg > 0.0 && arg + arg == arg) { if (dp->conversion >= 'A' && dp->conversion <= 'Z') { *p++ = 'I'; *p++ = 'N'; *p++ = 'F'; } else { *p++ = 'i'; *p++ = 'n'; *p++ = 'f'; } } else { # if NEED_PRINTF_DOUBLE pad_ptr = p; if (dp->conversion == 'f' || dp->conversion == 'F') { char *digits; size_t ndigits; digits = scale10_round_decimal_double (arg, precision); if (digits == NULL) goto out_of_memory; ndigits = strlen (digits); if (ndigits > precision) do { --ndigits; *p++ = digits[ndigits]; } while (ndigits > precision); else *p++ = '0'; /* Here ndigits <= precision. */ if ((flags & FLAG_ALT) || precision > 0) { *p++ = decimal_point_char (); for (; precision > ndigits; precision--) *p++ = '0'; while (ndigits > 0) { --ndigits; *p++ = digits[ndigits]; } } free (digits); } else if (dp->conversion == 'e' || dp->conversion == 'E') { int exponent; if (arg == 0.0) { exponent = 0; *p++ = '0'; if ((flags & FLAG_ALT) || precision > 0) { *p++ = decimal_point_char (); for (; precision > 0; precision--) *p++ = '0'; } } else { /* arg > 0.0. */ int adjusted; char *digits; size_t ndigits; exponent = floorlog10 (arg); adjusted = 0; for (;;) { digits = scale10_round_decimal_double (arg, (int)precision - exponent); if (digits == NULL) goto out_of_memory; ndigits = strlen (digits); if (ndigits == precision + 1) break; if (ndigits < precision || ndigits > precision + 2) /* The exponent was not guessed precisely enough. */ abort (); if (adjusted) /* None of two values of exponent is the right one. Prevent an endless loop. */ abort (); free (digits); if (ndigits == precision) exponent -= 1; else exponent += 1; adjusted = 1; } /* Here ndigits = precision+1. */ if (is_borderline (digits, precision)) { /* Maybe the exponent guess was too high and a smaller exponent can be reached by turning a 10...0 into 9...9x. */ char *digits2 = scale10_round_decimal_double (arg, (int)precision - exponent + 1); if (digits2 == NULL) { free (digits); goto out_of_memory; } if (strlen (digits2) == precision + 1) { free (digits); digits = digits2; exponent -= 1; } else free (digits2); } /* Here ndigits = precision+1. */ *p++ = digits[--ndigits]; if ((flags & FLAG_ALT) || precision > 0) { *p++ = decimal_point_char (); while (ndigits > 0) { --ndigits; *p++ = digits[ndigits]; } } free (digits); } *p++ = dp->conversion; /* 'e' or 'E' */ # if WIDE_CHAR_VERSION { static const wchar_t decimal_format[] = /* Produce the same number of exponent digits as the native printf implementation. */ # if (defined _WIN32 || defined __WIN32__) && ! defined __CYGWIN__ { '%', '+', '.', '3', 'd', '\0' }; # else { '%', '+', '.', '2', 'd', '\0' }; # endif SNPRINTF (p, 6 + 1, decimal_format, exponent); } while (*p != '\0') p++; # else { static const char decimal_format[] = /* Produce the same number of exponent digits as the native printf implementation. */ # if (defined _WIN32 || defined __WIN32__) && ! defined __CYGWIN__ "%+.3d"; # else "%+.2d"; # endif if (sizeof (DCHAR_T) == 1) { sprintf ((char *) p, decimal_format, exponent); while (*p != '\0') p++; } else { char expbuf[6 + 1]; const char *ep; sprintf (expbuf, decimal_format, exponent); for (ep = expbuf; (*p = *ep) != '\0'; ep++) p++; } } # endif } else if (dp->conversion == 'g' || dp->conversion == 'G') { if (precision == 0) precision = 1; /* precision >= 1. */ if (arg == 0.0) /* The exponent is 0, >= -4, < precision. Use fixed-point notation. */ { size_t ndigits = precision; /* Number of trailing zeroes that have to be dropped. */ size_t nzeroes = (flags & FLAG_ALT ? 0 : precision - 1); --ndigits; *p++ = '0'; if ((flags & FLAG_ALT) || ndigits > nzeroes) { *p++ = decimal_point_char (); while (ndigits > nzeroes) { --ndigits; *p++ = '0'; } } } else { /* arg > 0.0. */ int exponent; int adjusted; char *digits; size_t ndigits; size_t nzeroes; exponent = floorlog10 (arg); adjusted = 0; for (;;) { digits = scale10_round_decimal_double (arg, (int)(precision - 1) - exponent); if (digits == NULL) goto out_of_memory; ndigits = strlen (digits); if (ndigits == precision) break; if (ndigits < precision - 1 || ndigits > precision + 1) /* The exponent was not guessed precisely enough. */ abort (); if (adjusted) /* None of two values of exponent is the right one. Prevent an endless loop. */ abort (); free (digits); if (ndigits < precision) exponent -= 1; else exponent += 1; adjusted = 1; } /* Here ndigits = precision. */ if (is_borderline (digits, precision - 1)) { /* Maybe the exponent guess was too high and a smaller exponent can be reached by turning a 10...0 into 9...9x. */ char *digits2 = scale10_round_decimal_double (arg, (int)(precision - 1) - exponent + 1); if (digits2 == NULL) { free (digits); goto out_of_memory; } if (strlen (digits2) == precision) { free (digits); digits = digits2; exponent -= 1; } else free (digits2); } /* Here ndigits = precision. */ /* Determine the number of trailing zeroes that have to be dropped. */ nzeroes = 0; if ((flags & FLAG_ALT) == 0) while (nzeroes < ndigits && digits[nzeroes] == '0') nzeroes++; /* The exponent is now determined. */ if (exponent >= -4 && exponent < (long)precision) { /* Fixed-point notation: max(exponent,0)+1 digits, then the decimal point, then the remaining digits without trailing zeroes. */ if (exponent >= 0) { size_t count = exponent + 1; /* Note: count <= precision = ndigits. */ for (; count > 0; count--) *p++ = digits[--ndigits]; if ((flags & FLAG_ALT) || ndigits > nzeroes) { *p++ = decimal_point_char (); while (ndigits > nzeroes) { --ndigits; *p++ = digits[ndigits]; } } } else { size_t count = -exponent - 1; *p++ = '0'; *p++ = decimal_point_char (); for (; count > 0; count--) *p++ = '0'; while (ndigits > nzeroes) { --ndigits; *p++ = digits[ndigits]; } } } else { /* Exponential notation. */ *p++ = digits[--ndigits]; if ((flags & FLAG_ALT) || ndigits > nzeroes) { *p++ = decimal_point_char (); while (ndigits > nzeroes) { --ndigits; *p++ = digits[ndigits]; } } *p++ = dp->conversion - 'G' + 'E'; /* 'e' or 'E' */ # if WIDE_CHAR_VERSION { static const wchar_t decimal_format[] = /* Produce the same number of exponent digits as the native printf implementation. */ # if (defined _WIN32 || defined __WIN32__) && ! defined __CYGWIN__ { '%', '+', '.', '3', 'd', '\0' }; # else { '%', '+', '.', '2', 'd', '\0' }; # endif SNPRINTF (p, 6 + 1, decimal_format, exponent); } while (*p != '\0') p++; # else { static const char decimal_format[] = /* Produce the same number of exponent digits as the native printf implementation. */ # if (defined _WIN32 || defined __WIN32__) && ! defined __CYGWIN__ "%+.3d"; # else "%+.2d"; # endif if (sizeof (DCHAR_T) == 1) { sprintf ((char *) p, decimal_format, exponent); while (*p != '\0') p++; } else { char expbuf[6 + 1]; const char *ep; sprintf (expbuf, decimal_format, exponent); for (ep = expbuf; (*p = *ep) != '\0'; ep++) p++; } } # endif } free (digits); } } else abort (); # else /* arg is finite. */ if (!(arg == 0.0)) abort (); pad_ptr = p; if (dp->conversion == 'f' || dp->conversion == 'F') { *p++ = '0'; if ((flags & FLAG_ALT) || precision > 0) { *p++ = decimal_point_char (); for (; precision > 0; precision--) *p++ = '0'; } } else if (dp->conversion == 'e' || dp->conversion == 'E') { *p++ = '0'; if ((flags & FLAG_ALT) || precision > 0) { *p++ = decimal_point_char (); for (; precision > 0; precision--) *p++ = '0'; } *p++ = dp->conversion; /* 'e' or 'E' */ *p++ = '+'; /* Produce the same number of exponent digits as the native printf implementation. */ # if (defined _WIN32 || defined __WIN32__) && ! defined __CYGWIN__ *p++ = '0'; # endif *p++ = '0'; *p++ = '0'; } else if (dp->conversion == 'g' || dp->conversion == 'G') { *p++ = '0'; if (flags & FLAG_ALT) { size_t ndigits = (precision > 0 ? precision - 1 : 0); *p++ = decimal_point_char (); for (; ndigits > 0; --ndigits) *p++ = '0'; } } else abort (); # endif } } } # endif /* The generated string now extends from tmp to p, with the zero padding insertion point being at pad_ptr. */ if (has_width && p - tmp < width) { size_t pad = width - (p - tmp); DCHAR_T *end = p + pad; if (flags & FLAG_LEFT) { /* Pad with spaces on the right. */ for (; pad > 0; pad--) *p++ = ' '; } else if ((flags & FLAG_ZERO) && pad_ptr != NULL) { /* Pad with zeroes. */ DCHAR_T *q = end; while (p > pad_ptr) *--q = *--p; for (; pad > 0; pad--) *p++ = '0'; } else { /* Pad with spaces on the left. */ DCHAR_T *q = end; while (p > tmp) *--q = *--p; for (; pad > 0; pad--) *p++ = ' '; } p = end; } { size_t count = p - tmp; if (count >= tmp_length) /* tmp_length was incorrectly calculated - fix the code above! */ abort (); /* Make room for the result. */ if (count >= allocated - length) { size_t n = xsum (length, count); ENSURE_ALLOCATION (n); } /* Append the result. */ memcpy (result + length, tmp, count * sizeof (DCHAR_T)); if (tmp != tmpbuf) free (tmp); length += count; } } #endif else { arg_type type = a.arg[dp->arg_index].type; int flags = dp->flags; #if !USE_SNPRINTF || !DCHAR_IS_TCHAR || ENABLE_UNISTDIO || NEED_PRINTF_FLAG_LEFTADJUST || NEED_PRINTF_FLAG_ZERO || NEED_PRINTF_UNBOUNDED_PRECISION int has_width; size_t width; #endif #if !USE_SNPRINTF || NEED_PRINTF_UNBOUNDED_PRECISION int has_precision; size_t precision; #endif #if NEED_PRINTF_UNBOUNDED_PRECISION int prec_ourselves; #else # define prec_ourselves 0 #endif #if NEED_PRINTF_FLAG_LEFTADJUST # define pad_ourselves 1 #elif !DCHAR_IS_TCHAR || ENABLE_UNISTDIO || NEED_PRINTF_FLAG_ZERO || NEED_PRINTF_UNBOUNDED_PRECISION int pad_ourselves; #else # define pad_ourselves 0 #endif TCHAR_T *fbp; unsigned int prefix_count; int prefixes[2] IF_LINT (= { 0 }); #if !USE_SNPRINTF size_t tmp_length; TCHAR_T tmpbuf[700]; TCHAR_T *tmp; #endif #if !USE_SNPRINTF || !DCHAR_IS_TCHAR || ENABLE_UNISTDIO || NEED_PRINTF_FLAG_LEFTADJUST || NEED_PRINTF_FLAG_ZERO || NEED_PRINTF_UNBOUNDED_PRECISION has_width = 0; width = 0; if (dp->width_start != dp->width_end) { if (dp->width_arg_index != ARG_NONE) { int arg; if (!(a.arg[dp->width_arg_index].type == TYPE_INT)) abort (); arg = a.arg[dp->width_arg_index].a.a_int; if (arg < 0) { /* "A negative field width is taken as a '-' flag followed by a positive field width." */ flags |= FLAG_LEFT; width = (unsigned int) (-arg); } else width = arg; } else { const FCHAR_T *digitp = dp->width_start; do width = xsum (xtimes (width, 10), *digitp++ - '0'); while (digitp != dp->width_end); } has_width = 1; } #endif #if !USE_SNPRINTF || NEED_PRINTF_UNBOUNDED_PRECISION has_precision = 0; precision = 6; if (dp->precision_start != dp->precision_end) { if (dp->precision_arg_index != ARG_NONE) { int arg; if (!(a.arg[dp->precision_arg_index].type == TYPE_INT)) abort (); arg = a.arg[dp->precision_arg_index].a.a_int; /* "A negative precision is taken as if the precision were omitted." */ if (arg >= 0) { precision = arg; has_precision = 1; } } else { const FCHAR_T *digitp = dp->precision_start + 1; precision = 0; while (digitp != dp->precision_end) precision = xsum (xtimes (precision, 10), *digitp++ - '0'); has_precision = 1; } } #endif /* Decide whether to handle the precision ourselves. */ #if NEED_PRINTF_UNBOUNDED_PRECISION switch (dp->conversion) { case 'd': case 'i': case 'u': case 'o': case 'x': case 'X': case 'p': prec_ourselves = has_precision && (precision > 0); break; default: prec_ourselves = 0; break; } #endif /* Decide whether to perform the padding ourselves. */ #if !NEED_PRINTF_FLAG_LEFTADJUST && (!DCHAR_IS_TCHAR || ENABLE_UNISTDIO || NEED_PRINTF_FLAG_ZERO || NEED_PRINTF_UNBOUNDED_PRECISION) switch (dp->conversion) { # if !DCHAR_IS_TCHAR || ENABLE_UNISTDIO /* If we need conversion from TCHAR_T[] to DCHAR_T[], we need to perform the padding after this conversion. Functions with unistdio extensions perform the padding based on character count rather than element count. */ case 'c': case 's': # endif # if NEED_PRINTF_FLAG_ZERO case 'f': case 'F': case 'e': case 'E': case 'g': case 'G': case 'a': case 'A': # endif pad_ourselves = 1; break; default: pad_ourselves = prec_ourselves; break; } #endif #if !USE_SNPRINTF /* Allocate a temporary buffer of sufficient size for calling sprintf. */ { switch (dp->conversion) { case 'd': case 'i': case 'u': # if HAVE_LONG_LONG_INT if (type == TYPE_LONGLONGINT || type == TYPE_ULONGLONGINT) tmp_length = (unsigned int) (sizeof (unsigned long long) * CHAR_BIT * 0.30103 /* binary -> decimal */ ) + 1; /* turn floor into ceil */ else # endif if (type == TYPE_LONGINT || type == TYPE_ULONGINT) tmp_length = (unsigned int) (sizeof (unsigned long) * CHAR_BIT * 0.30103 /* binary -> decimal */ ) + 1; /* turn floor into ceil */ else tmp_length = (unsigned int) (sizeof (unsigned int) * CHAR_BIT * 0.30103 /* binary -> decimal */ ) + 1; /* turn floor into ceil */ if (tmp_length < precision) tmp_length = precision; /* Multiply by 2, as an estimate for FLAG_GROUP. */ tmp_length = xsum (tmp_length, tmp_length); /* Add 1, to account for a leading sign. */ tmp_length = xsum (tmp_length, 1); break; case 'o': # if HAVE_LONG_LONG_INT if (type == TYPE_LONGLONGINT || type == TYPE_ULONGLONGINT) tmp_length = (unsigned int) (sizeof (unsigned long long) * CHAR_BIT * 0.333334 /* binary -> octal */ ) + 1; /* turn floor into ceil */ else # endif if (type == TYPE_LONGINT || type == TYPE_ULONGINT) tmp_length = (unsigned int) (sizeof (unsigned long) * CHAR_BIT * 0.333334 /* binary -> octal */ ) + 1; /* turn floor into ceil */ else tmp_length = (unsigned int) (sizeof (unsigned int) * CHAR_BIT * 0.333334 /* binary -> octal */ ) + 1; /* turn floor into ceil */ if (tmp_length < precision) tmp_length = precision; /* Add 1, to account for a leading sign. */ tmp_length = xsum (tmp_length, 1); break; case 'x': case 'X': # if HAVE_LONG_LONG_INT if (type == TYPE_LONGLONGINT || type == TYPE_ULONGLONGINT) tmp_length = (unsigned int) (sizeof (unsigned long long) * CHAR_BIT * 0.25 /* binary -> hexadecimal */ ) + 1; /* turn floor into ceil */ else # endif if (type == TYPE_LONGINT || type == TYPE_ULONGINT) tmp_length = (unsigned int) (sizeof (unsigned long) * CHAR_BIT * 0.25 /* binary -> hexadecimal */ ) + 1; /* turn floor into ceil */ else tmp_length = (unsigned int) (sizeof (unsigned int) * CHAR_BIT * 0.25 /* binary -> hexadecimal */ ) + 1; /* turn floor into ceil */ if (tmp_length < precision) tmp_length = precision; /* Add 2, to account for a leading sign or alternate form. */ tmp_length = xsum (tmp_length, 2); break; case 'f': case 'F': if (type == TYPE_LONGDOUBLE) tmp_length = (unsigned int) (LDBL_MAX_EXP * 0.30103 /* binary -> decimal */ * 2 /* estimate for FLAG_GROUP */ ) + 1 /* turn floor into ceil */ + 10; /* sign, decimal point etc. */ else tmp_length = (unsigned int) (DBL_MAX_EXP * 0.30103 /* binary -> decimal */ * 2 /* estimate for FLAG_GROUP */ ) + 1 /* turn floor into ceil */ + 10; /* sign, decimal point etc. */ tmp_length = xsum (tmp_length, precision); break; case 'e': case 'E': case 'g': case 'G': tmp_length = 12; /* sign, decimal point, exponent etc. */ tmp_length = xsum (tmp_length, precision); break; case 'a': case 'A': if (type == TYPE_LONGDOUBLE) tmp_length = (unsigned int) (LDBL_DIG * 0.831 /* decimal -> hexadecimal */ ) + 1; /* turn floor into ceil */ else tmp_length = (unsigned int) (DBL_DIG * 0.831 /* decimal -> hexadecimal */ ) + 1; /* turn floor into ceil */ if (tmp_length < precision) tmp_length = precision; /* Account for sign, decimal point etc. */ tmp_length = xsum (tmp_length, 12); break; case 'c': # if HAVE_WINT_T && !WIDE_CHAR_VERSION if (type == TYPE_WIDE_CHAR) tmp_length = MB_CUR_MAX; else # endif tmp_length = 1; break; case 's': # if HAVE_WCHAR_T if (type == TYPE_WIDE_STRING) { # if WIDE_CHAR_VERSION /* ISO C says about %ls in fwprintf: "If the precision is not specified or is greater than the size of the array, the array shall contain a null wide character." So if there is a precision, we must not use wcslen. */ const wchar_t *arg = a.arg[dp->arg_index].a.a_wide_string; if (has_precision) tmp_length = local_wcsnlen (arg, precision); else tmp_length = local_wcslen (arg); # else /* ISO C says about %ls in fprintf: "If a precision is specified, no more than that many bytes are written (including shift sequences, if any), and the array shall contain a null wide character if, to equal the multibyte character sequence length given by the precision, the function would need to access a wide character one past the end of the array." So if there is a precision, we must not use wcslen. */ /* This case has already been handled above. */ abort (); # endif } else # endif { # if WIDE_CHAR_VERSION /* ISO C says about %s in fwprintf: "If the precision is not specified or is greater than the size of the converted array, the converted array shall contain a null wide character." So if there is a precision, we must not use strlen. */ /* This case has already been handled above. */ abort (); # else /* ISO C says about %s in fprintf: "If the precision is not specified or greater than the size of the array, the array shall contain a null character." So if there is a precision, we must not use strlen. */ const char *arg = a.arg[dp->arg_index].a.a_string; if (has_precision) tmp_length = local_strnlen (arg, precision); else tmp_length = strlen (arg); # endif } break; case 'p': tmp_length = (unsigned int) (sizeof (void *) * CHAR_BIT * 0.25 /* binary -> hexadecimal */ ) + 1 /* turn floor into ceil */ + 2; /* account for leading 0x */ break; default: abort (); } if (!pad_ourselves) { # if ENABLE_UNISTDIO /* Padding considers the number of characters, therefore the number of elements after padding may be > max (tmp_length, width) but is certainly <= tmp_length + width. */ tmp_length = xsum (tmp_length, width); # else /* Padding considers the number of elements, says POSIX. */ if (tmp_length < width) tmp_length = width; # endif } tmp_length = xsum (tmp_length, 1); /* account for trailing NUL */ } if (tmp_length <= sizeof (tmpbuf) / sizeof (TCHAR_T)) tmp = tmpbuf; else { size_t tmp_memsize = xtimes (tmp_length, sizeof (TCHAR_T)); if (size_overflow_p (tmp_memsize)) /* Overflow, would lead to out of memory. */ goto out_of_memory; tmp = (TCHAR_T *) malloc (tmp_memsize); if (tmp == NULL) /* Out of memory. */ goto out_of_memory; } #endif /* Construct the format string for calling snprintf or sprintf. */ fbp = buf; *fbp++ = '%'; #if NEED_PRINTF_FLAG_GROUPING /* The underlying implementation doesn't support the ' flag. Produce no grouping characters in this case; this is acceptable because the grouping is locale dependent. */ #else if (flags & FLAG_GROUP) *fbp++ = '\''; #endif if (flags & FLAG_LEFT) *fbp++ = '-'; if (flags & FLAG_SHOWSIGN) *fbp++ = '+'; if (flags & FLAG_SPACE) *fbp++ = ' '; if (flags & FLAG_ALT) *fbp++ = '#'; if (!pad_ourselves) { if (flags & FLAG_ZERO) *fbp++ = '0'; if (dp->width_start != dp->width_end) { size_t n = dp->width_end - dp->width_start; /* The width specification is known to consist only of standard ASCII characters. */ if (sizeof (FCHAR_T) == sizeof (TCHAR_T)) { memcpy (fbp, dp->width_start, n * sizeof (TCHAR_T)); fbp += n; } else { const FCHAR_T *mp = dp->width_start; do *fbp++ = (unsigned char) *mp++; while (--n > 0); } } } if (!prec_ourselves) { if (dp->precision_start != dp->precision_end) { size_t n = dp->precision_end - dp->precision_start; /* The precision specification is known to consist only of standard ASCII characters. */ if (sizeof (FCHAR_T) == sizeof (TCHAR_T)) { memcpy (fbp, dp->precision_start, n * sizeof (TCHAR_T)); fbp += n; } else { const FCHAR_T *mp = dp->precision_start; do *fbp++ = (unsigned char) *mp++; while (--n > 0); } } } switch (type) { #if HAVE_LONG_LONG_INT case TYPE_LONGLONGINT: case TYPE_ULONGLONGINT: # if (defined _WIN32 || defined __WIN32__) && ! defined __CYGWIN__ *fbp++ = 'I'; *fbp++ = '6'; *fbp++ = '4'; break; # else *fbp++ = 'l'; /*FALLTHROUGH*/ # endif #endif case TYPE_LONGINT: case TYPE_ULONGINT: #if HAVE_WINT_T case TYPE_WIDE_CHAR: #endif #if HAVE_WCHAR_T case TYPE_WIDE_STRING: #endif *fbp++ = 'l'; break; case TYPE_LONGDOUBLE: *fbp++ = 'L'; break; default: break; } #if NEED_PRINTF_DIRECTIVE_F if (dp->conversion == 'F') *fbp = 'f'; else #endif *fbp = dp->conversion; #if USE_SNPRINTF # if !(__GLIBC__ > 2 || (__GLIBC__ == 2 && __GLIBC_MINOR__ >= 3) || ((defined _WIN32 || defined __WIN32__) && ! defined __CYGWIN__)) fbp[1] = '%'; fbp[2] = 'n'; fbp[3] = '\0'; # else /* On glibc2 systems from glibc >= 2.3 - probably also older ones - we know that snprintf's returns value conforms to ISO C 99: the gl_SNPRINTF_DIRECTIVE_N test passes. Therefore we can avoid using %n in this situation. On glibc2 systems from 2004-10-18 or newer, the use of %n in format strings in writable memory may crash the program (if compiled with _FORTIFY_SOURCE=2), so we should avoid it in this situation. */ /* On native Win32 systems (such as mingw), we can avoid using %n because: - Although the gl_SNPRINTF_TRUNCATION_C99 test fails, snprintf does not write more than the specified number of bytes. (snprintf (buf, 3, "%d %d", 4567, 89) writes '4', '5', '6' into buf, not '4', '5', '\0'.) - Although the gl_SNPRINTF_RETVAL_C99 test fails, snprintf allows us to recognize the case of an insufficient buffer size: it returns -1 in this case. On native Win32 systems (such as mingw) where the OS is Windows Vista, the use of %n in format strings by default crashes the program. See <http://gcc.gnu.org/ml/gcc/2007-06/msg00122.html> and <http://msdn2.microsoft.com/en-us/library/ms175782(VS.80).aspx> So we should avoid %n in this situation. */ fbp[1] = '\0'; # endif #else fbp[1] = '\0'; #endif /* Construct the arguments for calling snprintf or sprintf. */ prefix_count = 0; if (!pad_ourselves && dp->width_arg_index != ARG_NONE) { if (!(a.arg[dp->width_arg_index].type == TYPE_INT)) abort (); prefixes[prefix_count++] = a.arg[dp->width_arg_index].a.a_int; } if (!prec_ourselves && dp->precision_arg_index != ARG_NONE) { if (!(a.arg[dp->precision_arg_index].type == TYPE_INT)) abort (); prefixes[prefix_count++] = a.arg[dp->precision_arg_index].a.a_int; } #if USE_SNPRINTF /* The SNPRINTF result is appended after result[0..length]. The latter is an array of DCHAR_T; SNPRINTF appends an array of TCHAR_T to it. This is possible because sizeof (TCHAR_T) divides sizeof (DCHAR_T) and alignof (TCHAR_T) <= alignof (DCHAR_T). */ # define TCHARS_PER_DCHAR (sizeof (DCHAR_T) / sizeof (TCHAR_T)) /* Ensure that maxlen below will be >= 2. Needed on BeOS, where an snprintf() with maxlen==1 acts like sprintf(). */ ENSURE_ALLOCATION (xsum (length, (2 + TCHARS_PER_DCHAR - 1) / TCHARS_PER_DCHAR)); /* Prepare checking whether snprintf returns the count via %n. */ *(TCHAR_T *) (result + length) = '\0'; #endif for (;;) { int count = -1; #if USE_SNPRINTF int retcount = 0; size_t maxlen = allocated - length; /* SNPRINTF can fail if its second argument is > INT_MAX. */ if (maxlen > INT_MAX / TCHARS_PER_DCHAR) maxlen = INT_MAX / TCHARS_PER_DCHAR; maxlen = maxlen * TCHARS_PER_DCHAR; # define SNPRINTF_BUF(arg) \ switch (prefix_count) \ { \ case 0: \ retcount = SNPRINTF ((TCHAR_T *) (result + length), \ maxlen, buf, \ arg, &count); \ break; \ case 1: \ retcount = SNPRINTF ((TCHAR_T *) (result + length), \ maxlen, buf, \ prefixes[0], arg, &count); \ break; \ case 2: \ retcount = SNPRINTF ((TCHAR_T *) (result + length), \ maxlen, buf, \ prefixes[0], prefixes[1], arg, \ &count); \ break; \ default: \ abort (); \ } #else # define SNPRINTF_BUF(arg) \ switch (prefix_count) \ { \ case 0: \ count = sprintf (tmp, buf, arg); \ break; \ case 1: \ count = sprintf (tmp, buf, prefixes[0], arg); \ break; \ case 2: \ count = sprintf (tmp, buf, prefixes[0], prefixes[1],\ arg); \ break; \ default: \ abort (); \ } #endif switch (type) { case TYPE_SCHAR: { int arg = a.arg[dp->arg_index].a.a_schar; SNPRINTF_BUF (arg); } break; case TYPE_UCHAR: { unsigned int arg = a.arg[dp->arg_index].a.a_uchar; SNPRINTF_BUF (arg); } break; case TYPE_SHORT: { int arg = a.arg[dp->arg_index].a.a_short; SNPRINTF_BUF (arg); } break; case TYPE_USHORT: { unsigned int arg = a.arg[dp->arg_index].a.a_ushort; SNPRINTF_BUF (arg); } break; case TYPE_INT: { int arg = a.arg[dp->arg_index].a.a_int; SNPRINTF_BUF (arg); } break; case TYPE_UINT: { unsigned int arg = a.arg[dp->arg_index].a.a_uint; SNPRINTF_BUF (arg); } break; case TYPE_LONGINT: { long int arg = a.arg[dp->arg_index].a.a_longint; SNPRINTF_BUF (arg); } break; case TYPE_ULONGINT: { unsigned long int arg = a.arg[dp->arg_index].a.a_ulongint; SNPRINTF_BUF (arg); } break; #if HAVE_LONG_LONG_INT case TYPE_LONGLONGINT: { long long int arg = a.arg[dp->arg_index].a.a_longlongint; SNPRINTF_BUF (arg); } break; case TYPE_ULONGLONGINT: { unsigned long long int arg = a.arg[dp->arg_index].a.a_ulonglongint; SNPRINTF_BUF (arg); } break; #endif case TYPE_DOUBLE: { double arg = a.arg[dp->arg_index].a.a_double; SNPRINTF_BUF (arg); } break; case TYPE_LONGDOUBLE: { long double arg = a.arg[dp->arg_index].a.a_longdouble; SNPRINTF_BUF (arg); } break; case TYPE_CHAR: { int arg = a.arg[dp->arg_index].a.a_char; SNPRINTF_BUF (arg); } break; #if HAVE_WINT_T case TYPE_WIDE_CHAR: { wint_t arg = a.arg[dp->arg_index].a.a_wide_char; SNPRINTF_BUF (arg); } break; #endif case TYPE_STRING: { const char *arg = a.arg[dp->arg_index].a.a_string; SNPRINTF_BUF (arg); } break; #if HAVE_WCHAR_T case TYPE_WIDE_STRING: { const wchar_t *arg = a.arg[dp->arg_index].a.a_wide_string; SNPRINTF_BUF (arg); } break; #endif case TYPE_POINTER: { void *arg = a.arg[dp->arg_index].a.a_pointer; SNPRINTF_BUF (arg); } break; default: abort (); } #if USE_SNPRINTF /* Portability: Not all implementations of snprintf() are ISO C 99 compliant. Determine the number of bytes that snprintf() has produced or would have produced. */ if (count >= 0) { /* Verify that snprintf() has NUL-terminated its result. */ if (count < maxlen && ((TCHAR_T *) (result + length)) [count] != '\0') abort (); /* Portability hack. */ if (retcount > count) count = retcount; } else { /* snprintf() doesn't understand the '%n' directive. */ if (fbp[1] != '\0') { /* Don't use the '%n' directive; instead, look at the snprintf() return value. */ fbp[1] = '\0'; continue; } else { /* Look at the snprintf() return value. */ if (retcount < 0) { /* HP-UX 10.20 snprintf() is doubly deficient: It doesn't understand the '%n' directive, *and* it returns -1 (rather than the length that would have been required) when the buffer is too small. */ size_t bigger_need = xsum (xtimes (allocated, 2), 12); ENSURE_ALLOCATION (bigger_need); continue; } else count = retcount; } } #endif /* Attempt to handle failure. */ if (count < 0) { if (!(result == resultbuf || result == NULL)) free (result); if (buf_malloced != NULL) free (buf_malloced); CLEANUP (); errno = EINVAL; return NULL; } #if USE_SNPRINTF /* Handle overflow of the allocated buffer. If such an overflow occurs, a C99 compliant snprintf() returns a count >= maxlen. However, a non-compliant snprintf() function returns only count = maxlen - 1. To cover both cases, test whether count >= maxlen - 1. */ if ((unsigned int) count + 1 >= maxlen) { /* If maxlen already has attained its allowed maximum, allocating more memory will not increase maxlen. Instead of looping, bail out. */ if (maxlen == INT_MAX / TCHARS_PER_DCHAR) goto overflow; else { /* Need at least (count + 1) * sizeof (TCHAR_T) bytes. (The +1 is for the trailing NUL.) But ask for (count + 2) * sizeof (TCHAR_T) bytes, so that in the next round, we likely get maxlen > (unsigned int) count + 1 and so we don't get here again. And allocate proportionally, to avoid looping eternally if snprintf() reports a too small count. */ size_t n = xmax (xsum (length, ((unsigned int) count + 2 + TCHARS_PER_DCHAR - 1) / TCHARS_PER_DCHAR), xtimes (allocated, 2)); ENSURE_ALLOCATION (n); continue; } } #endif #if NEED_PRINTF_UNBOUNDED_PRECISION if (prec_ourselves) { /* Handle the precision. */ TCHAR_T *prec_ptr = # if USE_SNPRINTF (TCHAR_T *) (result + length); # else tmp; # endif size_t prefix_count; size_t move; prefix_count = 0; /* Put the additional zeroes after the sign. */ if (count >= 1 && (*prec_ptr == '-' || *prec_ptr == '+' || *prec_ptr == ' ')) prefix_count = 1; /* Put the additional zeroes after the 0x prefix if (flags & FLAG_ALT) || (dp->conversion == 'p'). */ else if (count >= 2 && prec_ptr[0] == '0' && (prec_ptr[1] == 'x' || prec_ptr[1] == 'X')) prefix_count = 2; move = count - prefix_count; if (precision > move) { /* Insert zeroes. */ size_t insert = precision - move; TCHAR_T *prec_end; # if USE_SNPRINTF size_t n = xsum (length, (count + insert + TCHARS_PER_DCHAR - 1) / TCHARS_PER_DCHAR); length += (count + TCHARS_PER_DCHAR - 1) / TCHARS_PER_DCHAR; ENSURE_ALLOCATION (n); length -= (count + TCHARS_PER_DCHAR - 1) / TCHARS_PER_DCHAR; prec_ptr = (TCHAR_T *) (result + length); # endif prec_end = prec_ptr + count; prec_ptr += prefix_count; while (prec_end > prec_ptr) { prec_end--; prec_end[insert] = prec_end[0]; } prec_end += insert; do *--prec_end = '0'; while (prec_end > prec_ptr); count += insert; } } #endif #if !USE_SNPRINTF if (count >= tmp_length) /* tmp_length was incorrectly calculated - fix the code above! */ abort (); #endif #if !DCHAR_IS_TCHAR /* Convert from TCHAR_T[] to DCHAR_T[]. */ if (dp->conversion == 'c' || dp->conversion == 's') { /* type = TYPE_CHAR or TYPE_WIDE_CHAR or TYPE_STRING TYPE_WIDE_STRING. The result string is not certainly ASCII. */ const TCHAR_T *tmpsrc; DCHAR_T *tmpdst; size_t tmpdst_len; /* This code assumes that TCHAR_T is 'char'. */ typedef int TCHAR_T_verify [2 * (sizeof (TCHAR_T) == 1) - 1]; # if USE_SNPRINTF tmpsrc = (TCHAR_T *) (result + length); # else tmpsrc = tmp; # endif tmpdst = DCHAR_CONV_FROM_ENCODING (locale_charset (), iconveh_question_mark, tmpsrc, count, NULL, NULL, &tmpdst_len); if (tmpdst == NULL) { int saved_errno = errno; if (!(result == resultbuf || result == NULL)) free (result); if (buf_malloced != NULL) free (buf_malloced); CLEANUP (); errno = saved_errno; return NULL; } ENSURE_ALLOCATION (xsum (length, tmpdst_len)); DCHAR_CPY (result + length, tmpdst, tmpdst_len); free (tmpdst); count = tmpdst_len; } else { /* The result string is ASCII. Simple 1:1 conversion. */ # if USE_SNPRINTF /* If sizeof (DCHAR_T) == sizeof (TCHAR_T), it's a no-op conversion, in-place on the array starting at (result + length). */ if (sizeof (DCHAR_T) != sizeof (TCHAR_T)) # endif { const TCHAR_T *tmpsrc; DCHAR_T *tmpdst; size_t n; # if USE_SNPRINTF if (result == resultbuf) { tmpsrc = (TCHAR_T *) (result + length); /* ENSURE_ALLOCATION will not move tmpsrc (because it's part of resultbuf). */ ENSURE_ALLOCATION (xsum (length, count)); } else { /* ENSURE_ALLOCATION will move the array (because it uses realloc(). */ ENSURE_ALLOCATION (xsum (length, count)); tmpsrc = (TCHAR_T *) (result + length); } # else tmpsrc = tmp; ENSURE_ALLOCATION (xsum (length, count)); # endif tmpdst = result + length; /* Copy backwards, because of overlapping. */ tmpsrc += count; tmpdst += count; for (n = count; n > 0; n--) *--tmpdst = (unsigned char) *--tmpsrc; } } #endif #if DCHAR_IS_TCHAR && !USE_SNPRINTF /* Make room for the result. */ if (count > allocated - length) { /* Need at least count elements. But allocate proportionally. */ size_t n = xmax (xsum (length, count), xtimes (allocated, 2)); ENSURE_ALLOCATION (n); } #endif /* Here count <= allocated - length. */ /* Perform padding. */ #if !DCHAR_IS_TCHAR || ENABLE_UNISTDIO || NEED_PRINTF_FLAG_LEFTADJUST || NEED_PRINTF_FLAG_ZERO || NEED_PRINTF_UNBOUNDED_PRECISION if (pad_ourselves && has_width) { size_t w; # if ENABLE_UNISTDIO /* Outside POSIX, it's preferrable to compare the width against the number of _characters_ of the converted value. */ w = DCHAR_MBSNLEN (result + length, count); # else /* The width is compared against the number of _bytes_ of the converted value, says POSIX. */ w = count; # endif if (w < width) { size_t pad = width - w; /* Make room for the result. */ if (xsum (count, pad) > allocated - length) { /* Need at least count + pad elements. But allocate proportionally. */ size_t n = xmax (xsum3 (length, count, pad), xtimes (allocated, 2)); # if USE_SNPRINTF length += count; ENSURE_ALLOCATION (n); length -= count; # else ENSURE_ALLOCATION (n); # endif } /* Here count + pad <= allocated - length. */ { # if !DCHAR_IS_TCHAR || USE_SNPRINTF DCHAR_T * const rp = result + length; # else DCHAR_T * const rp = tmp; # endif DCHAR_T *p = rp + count; DCHAR_T *end = p + pad; DCHAR_T *pad_ptr; # if !DCHAR_IS_TCHAR || ENABLE_UNISTDIO if (dp->conversion == 'c' || dp->conversion == 's') /* No zero-padding for string directives. */ pad_ptr = NULL; else # endif { pad_ptr = (*rp == '-' ? rp + 1 : rp); /* No zero-padding of "inf" and "nan". */ if ((*pad_ptr >= 'A' && *pad_ptr <= 'Z') || (*pad_ptr >= 'a' && *pad_ptr <= 'z')) pad_ptr = NULL; } /* The generated string now extends from rp to p, with the zero padding insertion point being at pad_ptr. */ count = count + pad; /* = end - rp */ if (flags & FLAG_LEFT) { /* Pad with spaces on the right. */ for (; pad > 0; pad--) *p++ = ' '; } else if ((flags & FLAG_ZERO) && pad_ptr != NULL) { /* Pad with zeroes. */ DCHAR_T *q = end; while (p > pad_ptr) *--q = *--p; for (; pad > 0; pad--) *p++ = '0'; } else { /* Pad with spaces on the left. */ DCHAR_T *q = end; while (p > rp) *--q = *--p; for (; pad > 0; pad--) *p++ = ' '; } } } } #endif /* Here still count <= allocated - length. */ #if !DCHAR_IS_TCHAR || USE_SNPRINTF /* The snprintf() result did fit. */ #else /* Append the sprintf() result. */ memcpy (result + length, tmp, count * sizeof (DCHAR_T)); #endif #if !USE_SNPRINTF if (tmp != tmpbuf) free (tmp); #endif #if NEED_PRINTF_DIRECTIVE_F if (dp->conversion == 'F') { /* Convert the %f result to upper case for %F. */ DCHAR_T *rp = result + length; size_t rc; for (rc = count; rc > 0; rc--, rp++) if (*rp >= 'a' && *rp <= 'z') *rp = *rp - 'a' + 'A'; } #endif length += count; break; } } } } /* Add the final NUL. */ ENSURE_ALLOCATION (xsum (length, 1)); result[length] = '\0'; if (result != resultbuf && length + 1 < allocated) { /* Shrink the allocated memory if possible. */ DCHAR_T *memory; memory = (DCHAR_T *) realloc (result, (length + 1) * sizeof (DCHAR_T)); if (memory != NULL) result = memory; } if (buf_malloced != NULL) free (buf_malloced); CLEANUP (); *lengthp = length; /* Note that we can produce a big string of a length > INT_MAX. POSIX says that snprintf() fails with errno = EOVERFLOW in this case, but that's only because snprintf() returns an 'int'. This function does not have this limitation. */ return result; #if USE_SNPRINTF overflow: if (!(result == resultbuf || result == NULL)) free (result); if (buf_malloced != NULL) free (buf_malloced); CLEANUP (); errno = EOVERFLOW; return NULL; #endif out_of_memory: if (!(result == resultbuf || result == NULL)) free (result); if (buf_malloced != NULL) free (buf_malloced); out_of_memory_1: CLEANUP (); errno = ENOMEM; return NULL; } } #undef TCHARS_PER_DCHAR #undef SNPRINTF #undef USE_SNPRINTF #undef DCHAR_SET #undef DCHAR_CPY #undef PRINTF_PARSE #undef DIRECTIVES #undef DIRECTIVE #undef DCHAR_IS_TCHAR #undef TCHAR_T #undef DCHAR_T #undef FCHAR_T #undef VASNPRINTF