/* vsprintf with automatic memory allocation.
Copyright (C) 1999, 2002-2007 Free Software Foundation, Inc.
This program is free software; you can redistribute it and/or modify it
under the terms of the GNU Library General Public License as published
by the Free Software Foundation; either version 2, 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
Library General Public License for more details.
You should have received a copy of the GNU Library 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 "isnan.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 "isnan.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
/* Some systems, like OSF/1 4.0 and Woe32, don't have EOVERFLOW. */
#ifndef EOVERFLOW
# define EOVERFLOW E2BIG
#endif
#if HAVE_WCHAR_T
# 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
/* 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
# 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
# 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. */
# if (HAVE_DECL__SNPRINTF || HAVE_SNPRINTF) && !defined __BEOS__
# 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
#if (NEED_PRINTF_DIRECTIVE_A || NEED_PRINTF_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 ()
{
const char *point;
/* Determine it in a multithread-safe way. We know nl_langinfo is
multithread-safe on glibc 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__
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 isnan (x) || x + x == x;
}
#endif
#if NEED_PRINTF_INFINITE_LONG_DOUBLE && !NEED_PRINTF_LONG_DOUBLE && !defined IN_LIBINTL
/* Equivalent to !isfinite(x), but does not require libm. */
static int
is_infinitel (long double x)
{
return isnanl (x) || (x + x == x && x != 0.0L);
}
#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-(hightest 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 (!(y == 0.0L))
abort ();
/* 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;
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;
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;
/* log(1-z) = - z - z^2/2 - z^3/3 - z^4/4 - ...
Four terms are enough to get an approximation with error < 10^-7. */
l -= 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;
/* log(1-z) = - z - z^2/2 - z^3/3 - z^4/4 - ...
Four terms are enough to get an approximation with error < 10^-7. */
l -= 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
#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. */
if (u8_conv_to_encoding (locale_charset (),
iconveh_question_mark,
arg, arg_end - arg, NULL,
&converted, &converted_len)
< 0)
# else
/* Convert from UTF-8 to UTF-16/UTF-32. */
converted =
U8_TO_DCHAR (arg, arg_end - arg,
converted, &converted_len);
if (converted == NULL)
# endif
{
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. */
if (u16_conv_to_encoding (locale_charset (),
iconveh_question_mark,
arg, arg_end - arg, NULL,
&converted, &converted_len)
< 0)
# else
/* Convert from UTF-16 to UTF-8/UTF-32. */
converted =
U16_TO_DCHAR (arg, arg_end - arg,
converted, &converted_len);
if (converted == NULL)
# endif
{
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. */
if (u32_conv_to_encoding (locale_charset (),
iconveh_question_mark,
arg, arg_end - arg, NULL,
&converted, &converted_len)
< 0)
# else
/* Convert from UTF-32 to UTF-8/UTF-16. */
converted =
U32_TO_DCHAR (arg, arg_end - arg,
converted, &converted_len);
if (converted == NULL)
# endif
{
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 (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 (isnan (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. */
&& is_infinitel (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. */
if (!has_precision)
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 (!(isnan (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. */
*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. */
/* 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. */
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 (isnan (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. */
*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. */
/* 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_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 !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 !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_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
#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)
{
tmp_length =
local_wcslen (a.arg[dp->arg_index].a.a_wide_string);
# if !WIDE_CHAR_VERSION
tmp_length = xtimes (tmp_length, MB_CUR_MAX);
# endif
}
else
# endif
tmp_length = strlen (a.arg[dp->arg_index].a.a_string);
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 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
/* 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 !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
/* 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))
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. */
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 (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))
/* Prepare checking whether snprintf returns the count
via %n. */
ENSURE_ALLOCATION (xsum (length, 1));
*(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 * sizeof (TCHAR_T) bytes.
But allocate proportionally, to avoid looping
eternally if snprintf() reports a too small
count. */
size_t n =
xmax (xsum (length,
(count + 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 !DCHAR_IS_TCHAR
# if !USE_SNPRINTF
if (count >= tmp_length)
/* tmp_length was incorrectly calculated - fix the
code above! */
abort ();
# endif
/* 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 = NULL;
tmpdst_len = 0;
if (DCHAR_CONV_FROM_ENCODING (locale_charset (),
iconveh_question_mark,
tmpsrc, count,
NULL,
&tmpdst, &tmpdst_len)
< 0)
{
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_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;
# if USE_SNPRINTF
/* 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));
length += count;
ENSURE_ALLOCATION (n);
length -= count;
}
/* Here count + pad <= allocated - length. */
# endif
{
# 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;
# if NEED_PRINTF_FLAG_ZERO
DCHAR_T *pad_ptr;
# if !DCHAR_IS_TCHAR
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;
}
# endif
/* 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++ = ' ';
}
# if NEED_PRINTF_FLAG_ZERO
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';
}
# endif
else
{
/* Pad with spaces on the left. */
DCHAR_T *q = end;
while (p > rp)
*--q = *--p;
for (; pad > 0; pad--)
*p++ = ' ';
}
}
}
}
#endif
#if DCHAR_IS_TCHAR && !USE_SNPRINTF
if (count >= tmp_length)
/* tmp_length was incorrectly calculated - fix the
code above! */
abort ();
#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;
overflow:
if (!(result == resultbuf || result == NULL))
free (result);
if (buf_malloced != NULL)
free (buf_malloced);
CLEANUP ();
errno = EOVERFLOW;
return NULL;
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_CPY
#undef PRINTF_PARSE
#undef DIRECTIVES
#undef DIRECTIVE
#undef DCHAR_IS_TCHAR
#undef TCHAR_T
#undef DCHAR_T
#undef FCHAR_T
#undef VASNPRINTF
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