glibc/stdio-common/vfprintf-internal.c
Joseph Myers 5f83b2674e C2x printf %wN, %wfN support (bug 24466)
ISO C2x defines printf length modifiers wN (for intN_t / int_leastN_t
/ uintN_t / uint_leastN_t) and wfN (for int_fastN_t / uint_fastN_t).
Add support for those length modifiers (such a feature was previously
requested in bug 24466).  scanf support is to be added separately.
GCC 13 has format checking support for these modifiers.

When used with the support for registering format specifiers, these
modifiers are translated to existing flags in struct printf_info,
rather than trying to add some way of distinguishing them without
breaking the printf_info ABI.  C2x requires an error to be returned
for unsupported values of N; this is implemented for printf-family
functions, but the parse_printf_format interface doesn't support error
returns, so such an error gets discarded by that function.

Tested for x86_64 and x86.
2023-06-19 18:52:12 +00:00

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/* Copyright (C) 1991-2023 Free Software Foundation, Inc.
This file is part of the GNU C Library.
The GNU C Library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
The GNU C Library 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
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with the GNU C Library; if not, see
<https://www.gnu.org/licenses/>. */
#include <array_length.h>
#include <assert.h>
#include <ctype.h>
#include <limits.h>
#include <printf.h>
#include <stdarg.h>
#include <stdint.h>
#include <stdlib.h>
#include <string.h>
#include <errno.h>
#include <wchar.h>
#include <libc-lock.h>
#include <sys/param.h>
#include <_itoa.h>
#include <locale/localeinfo.h>
#include <grouping_iterator.h>
#include <stdio.h>
#include <scratch_buffer.h>
#include <intprops.h>
#include <printf_buffer.h>
#include <printf_buffer_to_file.h>
/* This code is shared between the standard stdio implementation found
in GNU C library and the libio implementation originally found in
GNU libg++.
Beside this it is also shared between the normal and wide character
implementation as defined in ISO/IEC 9899:1990/Amendment 1:1995. */
#include <libioP.h>
#ifdef COMPILE_WPRINTF
#include <wctype.h>
#endif
#define ARGCHECK(S, Format) \
do \
{ \
/* Check file argument for consistence. */ \
CHECK_FILE (S, -1); \
if (S->_flags & _IO_NO_WRITES) \
{ \
S->_flags |= _IO_ERR_SEEN; \
__set_errno (EBADF); \
return -1; \
} \
if (Format == NULL) \
{ \
__set_errno (EINVAL); \
return -1; \
} \
} while (0)
#define UNBUFFERED_P(S) ((S)->_flags & _IO_UNBUFFERED)
#if __HAVE_FLOAT128_UNLIKE_LDBL
# define PARSE_FLOAT_VA_ARG_EXTENDED(INFO) \
do \
{ \
if (is_long_double \
&& (mode_flags & PRINTF_LDBL_USES_FLOAT128) != 0) \
{ \
INFO.is_binary128 = 1; \
the_arg.pa_float128 = va_arg (ap, _Float128); \
} \
else \
{ \
PARSE_FLOAT_VA_ARG (INFO); \
} \
} \
while (0)
#else
# define PARSE_FLOAT_VA_ARG_EXTENDED(INFO) \
PARSE_FLOAT_VA_ARG (INFO);
#endif
#define PARSE_FLOAT_VA_ARG(INFO) \
do \
{ \
INFO.is_binary128 = 0; \
if (is_long_double) \
the_arg.pa_long_double = va_arg (ap, long double); \
else \
the_arg.pa_double = va_arg (ap, double); \
} \
while (0)
#if __HAVE_FLOAT128_UNLIKE_LDBL
# define SETUP_FLOAT128_INFO(INFO) \
do \
{ \
if ((mode_flags & PRINTF_LDBL_USES_FLOAT128) != 0) \
INFO.is_binary128 = is_long_double; \
else \
INFO.is_binary128 = 0; \
} \
while (0)
#else
# define SETUP_FLOAT128_INFO(INFO) \
do \
{ \
INFO.is_binary128 = 0; \
} \
while (0)
#endif
#ifndef COMPILE_WPRINTF
# include "printf_buffer-char.h"
# define vfprintf __vfprintf_internal
# define OTHER_CHAR_T wchar_t
# define UCHAR_T unsigned char
# define INT_T int
typedef const char *THOUSANDS_SEP_T;
# define L_(Str) Str
# define ISDIGIT(Ch) ((unsigned int) ((Ch) - '0') < 10)
# define STR_LEN(Str) strlen (Str)
# define ORIENT if (_IO_vtable_offset (s) == 0 && _IO_fwide (s, -1) != -1)\
return -1
# define CONVERT_FROM_OTHER_STRING __wcsrtombs
#else
# include "printf_buffer-wchar_t.h"
# define vfprintf __vfwprintf_internal
# define OTHER_CHAR_T char
/* This is a hack!!! There should be a type uwchar_t. */
# define UCHAR_T unsigned int /* uwchar_t */
# define INT_T wint_t
typedef wchar_t THOUSANDS_SEP_T;
# define L_(Str) L##Str
# define ISDIGIT(Ch) ((unsigned int) ((Ch) - L'0') < 10)
# define STR_LEN(Str) __wcslen (Str)
# include <_itowa.h>
# define ORIENT if (_IO_fwide (s, 1) != 1) return -1
# define CONVERT_FROM_OTHER_STRING __mbsrtowcs
# undef _itoa
# define _itoa(Val, Buf, Base, Case) _itowa (Val, Buf, Base, Case)
# define _itoa_word(Val, Buf, Base, Case) _itowa_word (Val, Buf, Base, Case)
# undef EOF
# define EOF WEOF
#endif
/* Include the shared code for parsing the format string. */
#include "printf-parse.h"
/* Write the string SRC to S. If PREC is non-negative, write at most
PREC bytes. If LEFT is true, perform left justification. */
static void
outstring_converted_wide_string (struct Xprintf_buffer *target,
const OTHER_CHAR_T *src, int prec,
int width, bool left)
{
/* Use a small buffer to combine processing of multiple characters.
CONVERT_FROM_OTHER_STRING expects the buffer size in (wide)
characters, and buf_length counts that. */
enum { buf_length = 256 / sizeof (CHAR_T) };
CHAR_T buf[buf_length];
_Static_assert (sizeof (buf) > MB_LEN_MAX,
"buffer is large enough for a single multi-byte character");
/* Add the initial padding if needed. */
if (width > 0 && !left)
{
/* Make a first pass to find the output width, so that we can
add the required padding. */
mbstate_t mbstate = { 0 };
const OTHER_CHAR_T *src_copy = src;
size_t total_written;
if (prec < 0)
total_written = CONVERT_FROM_OTHER_STRING
(NULL, &src_copy, 0, &mbstate);
else
{
/* The source might not be null-terminated. Enforce the
limit manually, based on the output length. */
total_written = 0;
size_t limit = prec;
while (limit > 0 && src_copy != NULL)
{
size_t write_limit = buf_length;
if (write_limit > limit)
write_limit = limit;
size_t written = CONVERT_FROM_OTHER_STRING
(buf, &src_copy, write_limit, &mbstate);
if (written == (size_t) -1)
{
Xprintf_buffer_mark_failed (target);
return;
}
if (written == 0)
break;
total_written += written;
limit -= written;
}
}
/* Output initial padding. */
Xprintf_buffer_pad (target, L_(' '), width - total_written);
if (Xprintf_buffer_has_failed (target))
return;
}
/* Convert the input string, piece by piece. */
size_t total_written = 0;
{
mbstate_t mbstate = { 0 };
/* If prec is negative, remaining is not decremented, otherwise,
it serves as the write limit. */
size_t remaining = -1;
if (prec >= 0)
remaining = prec;
while (remaining > 0 && src != NULL)
{
size_t write_limit = buf_length;
if (remaining < write_limit)
write_limit = remaining;
size_t written = CONVERT_FROM_OTHER_STRING
(buf, &src, write_limit, &mbstate);
if (written == (size_t) -1)
{
Xprintf_buffer_mark_failed (target);
return;
}
if (written == 0)
break;
Xprintf_buffer_write (target, buf, written);
total_written += written;
if (prec >= 0)
remaining -= written;
}
}
/* Add final padding. */
if (width > 0 && left)
Xprintf_buffer_pad (target, L_(' '), width - total_written);
}
/* Calls __printf_fp or __printf_fphex based on the value of the
format specifier INFO->spec. */
static inline void
__printf_fp_spec (struct Xprintf_buffer *target,
const struct printf_info *info, const void *const *args)
{
if (info->spec == 'a' || info->spec == 'A')
Xprintf (fphex_l_buffer) (target, _NL_CURRENT_LOCALE, info, args);
else
Xprintf (fp_l_buffer) (target, _NL_CURRENT_LOCALE, info, args);
}
/* For handling long_double and longlong we use the same flag. If
`long' and `long long' are effectively the same type define it to
zero. */
#if LONG_MAX == LONG_LONG_MAX
# define is_longlong 0
#else
# define is_longlong is_long_double
#endif
/* If `long' and `int' is effectively the same type we don't have to
handle `long separately. */
#if INT_MAX == LONG_MAX
# define is_long_num 0
#else
# define is_long_num is_long
#endif
/* Global constants. */
static const CHAR_T null[] = L_("(null)");
/* Size of the work_buffer variable (in characters, not bytes. */
enum { WORK_BUFFER_SIZE = 1000 / sizeof (CHAR_T) };
/* This table maps a character into a number representing a class. In
each step there is a destination label for each class. */
static const uint8_t jump_table[] =
{
/* ' ' */ 1, 0, 0, /* '#' */ 4,
0, /* '%' */ 14, 0, /* '\''*/ 6,
0, 0, /* '*' */ 7, /* '+' */ 2,
0, /* '-' */ 3, /* '.' */ 9, 0,
/* '0' */ 5, /* '1' */ 8, /* '2' */ 8, /* '3' */ 8,
/* '4' */ 8, /* '5' */ 8, /* '6' */ 8, /* '7' */ 8,
/* '8' */ 8, /* '9' */ 8, 0, 0,
0, 0, 0, 0,
0, /* 'A' */ 26, /* 'B' */ 30, /* 'C' */ 25,
0, /* 'E' */ 19, /* F */ 19, /* 'G' */ 19,
0, /* 'I' */ 29, 0, 0,
/* 'L' */ 12, 0, 0, 0,
0, 0, 0, /* 'S' */ 21,
0, 0, 0, 0,
/* 'X' */ 18, 0, /* 'Z' */ 13, 0,
0, 0, 0, 0,
0, /* 'a' */ 26, /* 'b' */ 30, /* 'c' */ 20,
/* 'd' */ 15, /* 'e' */ 19, /* 'f' */ 19, /* 'g' */ 19,
/* 'h' */ 10, /* 'i' */ 15, /* 'j' */ 28, 0,
/* 'l' */ 11, /* 'm' */ 24, /* 'n' */ 23, /* 'o' */ 17,
/* 'p' */ 22, /* 'q' */ 12, 0, /* 's' */ 21,
/* 't' */ 27, /* 'u' */ 16, 0, /* 'w' */ 31,
/* 'x' */ 18, 0, /* 'z' */ 13
};
#define NOT_IN_JUMP_RANGE(Ch) ((Ch) < L_(' ') || (Ch) > L_('z'))
#define CHAR_CLASS(Ch) (jump_table[(INT_T) (Ch) - L_(' ')])
#define LABEL(Name) do_##Name
#ifdef SHARED
/* 'int' is enough and it saves some space on 64 bit systems. */
# define JUMP_TABLE_TYPE const int
# define JUMP_TABLE_BASE_LABEL do_form_unknown
# define REF(Name) &&do_##Name - &&JUMP_TABLE_BASE_LABEL
# define JUMP(ChExpr, table) \
do \
{ \
int offset; \
void *ptr; \
spec = (ChExpr); \
offset = NOT_IN_JUMP_RANGE (spec) ? REF (form_unknown) \
: table[CHAR_CLASS (spec)]; \
ptr = &&JUMP_TABLE_BASE_LABEL + offset; \
goto *ptr; \
} \
while (0)
#else
# define JUMP_TABLE_TYPE const void *const
# define REF(Name) &&do_##Name
# define JUMP(ChExpr, table) \
do \
{ \
const void *ptr; \
spec = (ChExpr); \
ptr = NOT_IN_JUMP_RANGE (spec) ? REF (form_unknown) \
: table[CHAR_CLASS (spec)]; \
goto *ptr; \
} \
while (0)
#endif
#define STEP0_3_TABLE \
/* Step 0: at the beginning. */ \
static JUMP_TABLE_TYPE step0_jumps[32] = \
{ \
REF (form_unknown), \
REF (flag_space), /* for ' ' */ \
REF (flag_plus), /* for '+' */ \
REF (flag_minus), /* for '-' */ \
REF (flag_hash), /* for '<hash>' */ \
REF (flag_zero), /* for '0' */ \
REF (flag_quote), /* for '\'' */ \
REF (width_asterics), /* for '*' */ \
REF (width), /* for '1'...'9' */ \
REF (precision), /* for '.' */ \
REF (mod_half), /* for 'h' */ \
REF (mod_long), /* for 'l' */ \
REF (mod_longlong), /* for 'L', 'q' */ \
REF (mod_size_t), /* for 'z', 'Z' */ \
REF (form_percent), /* for '%' */ \
REF (form_integer), /* for 'd', 'i' */ \
REF (form_unsigned), /* for 'u' */ \
REF (form_octal), /* for 'o' */ \
REF (form_hexa), /* for 'X', 'x' */ \
REF (form_float), /* for 'E', 'e', 'F', 'f', 'G', 'g' */ \
REF (form_character), /* for 'c' */ \
REF (form_string), /* for 's', 'S' */ \
REF (form_pointer), /* for 'p' */ \
REF (form_number), /* for 'n' */ \
REF (form_strerror), /* for 'm' */ \
REF (form_wcharacter), /* for 'C' */ \
REF (form_floathex), /* for 'A', 'a' */ \
REF (mod_ptrdiff_t), /* for 't' */ \
REF (mod_intmax_t), /* for 'j' */ \
REF (flag_i18n), /* for 'I' */ \
REF (form_binary), /* for 'B', 'b' */ \
REF (mod_bitwidth), /* for 'w' */ \
}; \
/* Step 1: after processing width. */ \
static JUMP_TABLE_TYPE step1_jumps[32] = \
{ \
REF (form_unknown), \
REF (form_unknown), /* for ' ' */ \
REF (form_unknown), /* for '+' */ \
REF (form_unknown), /* for '-' */ \
REF (form_unknown), /* for '<hash>' */ \
REF (form_unknown), /* for '0' */ \
REF (form_unknown), /* for '\'' */ \
REF (form_unknown), /* for '*' */ \
REF (form_unknown), /* for '1'...'9' */ \
REF (precision), /* for '.' */ \
REF (mod_half), /* for 'h' */ \
REF (mod_long), /* for 'l' */ \
REF (mod_longlong), /* for 'L', 'q' */ \
REF (mod_size_t), /* for 'z', 'Z' */ \
REF (form_percent), /* for '%' */ \
REF (form_integer), /* for 'd', 'i' */ \
REF (form_unsigned), /* for 'u' */ \
REF (form_octal), /* for 'o' */ \
REF (form_hexa), /* for 'X', 'x' */ \
REF (form_float), /* for 'E', 'e', 'F', 'f', 'G', 'g' */ \
REF (form_character), /* for 'c' */ \
REF (form_string), /* for 's', 'S' */ \
REF (form_pointer), /* for 'p' */ \
REF (form_number), /* for 'n' */ \
REF (form_strerror), /* for 'm' */ \
REF (form_wcharacter), /* for 'C' */ \
REF (form_floathex), /* for 'A', 'a' */ \
REF (mod_ptrdiff_t), /* for 't' */ \
REF (mod_intmax_t), /* for 'j' */ \
REF (form_unknown), /* for 'I' */ \
REF (form_binary), /* for 'B', 'b' */ \
REF (mod_bitwidth), /* for 'w' */ \
}; \
/* Step 2: after processing precision. */ \
static JUMP_TABLE_TYPE step2_jumps[32] = \
{ \
REF (form_unknown), \
REF (form_unknown), /* for ' ' */ \
REF (form_unknown), /* for '+' */ \
REF (form_unknown), /* for '-' */ \
REF (form_unknown), /* for '<hash>' */ \
REF (form_unknown), /* for '0' */ \
REF (form_unknown), /* for '\'' */ \
REF (form_unknown), /* for '*' */ \
REF (form_unknown), /* for '1'...'9' */ \
REF (form_unknown), /* for '.' */ \
REF (mod_half), /* for 'h' */ \
REF (mod_long), /* for 'l' */ \
REF (mod_longlong), /* for 'L', 'q' */ \
REF (mod_size_t), /* for 'z', 'Z' */ \
REF (form_percent), /* for '%' */ \
REF (form_integer), /* for 'd', 'i' */ \
REF (form_unsigned), /* for 'u' */ \
REF (form_octal), /* for 'o' */ \
REF (form_hexa), /* for 'X', 'x' */ \
REF (form_float), /* for 'E', 'e', 'F', 'f', 'G', 'g' */ \
REF (form_character), /* for 'c' */ \
REF (form_string), /* for 's', 'S' */ \
REF (form_pointer), /* for 'p' */ \
REF (form_number), /* for 'n' */ \
REF (form_strerror), /* for 'm' */ \
REF (form_wcharacter), /* for 'C' */ \
REF (form_floathex), /* for 'A', 'a' */ \
REF (mod_ptrdiff_t), /* for 't' */ \
REF (mod_intmax_t), /* for 'j' */ \
REF (form_unknown), /* for 'I' */ \
REF (form_binary), /* for 'B', 'b' */ \
REF (mod_bitwidth), /* for 'w' */ \
}; \
/* Step 3a: after processing first 'h' modifier. */ \
static JUMP_TABLE_TYPE step3a_jumps[32] = \
{ \
REF (form_unknown), \
REF (form_unknown), /* for ' ' */ \
REF (form_unknown), /* for '+' */ \
REF (form_unknown), /* for '-' */ \
REF (form_unknown), /* for '<hash>' */ \
REF (form_unknown), /* for '0' */ \
REF (form_unknown), /* for '\'' */ \
REF (form_unknown), /* for '*' */ \
REF (form_unknown), /* for '1'...'9' */ \
REF (form_unknown), /* for '.' */ \
REF (mod_halfhalf), /* for 'h' */ \
REF (form_unknown), /* for 'l' */ \
REF (form_unknown), /* for 'L', 'q' */ \
REF (form_unknown), /* for 'z', 'Z' */ \
REF (form_percent), /* for '%' */ \
REF (form_integer), /* for 'd', 'i' */ \
REF (form_unsigned), /* for 'u' */ \
REF (form_octal), /* for 'o' */ \
REF (form_hexa), /* for 'X', 'x' */ \
REF (form_unknown), /* for 'E', 'e', 'F', 'f', 'G', 'g' */ \
REF (form_unknown), /* for 'c' */ \
REF (form_unknown), /* for 's', 'S' */ \
REF (form_unknown), /* for 'p' */ \
REF (form_number), /* for 'n' */ \
REF (form_unknown), /* for 'm' */ \
REF (form_unknown), /* for 'C' */ \
REF (form_unknown), /* for 'A', 'a' */ \
REF (form_unknown), /* for 't' */ \
REF (form_unknown), /* for 'j' */ \
REF (form_unknown), /* for 'I' */ \
REF (form_binary), /* for 'B', 'b' */ \
REF (form_unknown), /* for 'w' */ \
}; \
/* Step 3b: after processing first 'l' modifier. */ \
static JUMP_TABLE_TYPE step3b_jumps[32] = \
{ \
REF (form_unknown), \
REF (form_unknown), /* for ' ' */ \
REF (form_unknown), /* for '+' */ \
REF (form_unknown), /* for '-' */ \
REF (form_unknown), /* for '<hash>' */ \
REF (form_unknown), /* for '0' */ \
REF (form_unknown), /* for '\'' */ \
REF (form_unknown), /* for '*' */ \
REF (form_unknown), /* for '1'...'9' */ \
REF (form_unknown), /* for '.' */ \
REF (form_unknown), /* for 'h' */ \
REF (mod_longlong), /* for 'l' */ \
REF (form_unknown), /* for 'L', 'q' */ \
REF (form_unknown), /* for 'z', 'Z' */ \
REF (form_percent), /* for '%' */ \
REF (form_integer), /* for 'd', 'i' */ \
REF (form_unsigned), /* for 'u' */ \
REF (form_octal), /* for 'o' */ \
REF (form_hexa), /* for 'X', 'x' */ \
REF (form_float), /* for 'E', 'e', 'F', 'f', 'G', 'g' */ \
REF (form_character), /* for 'c' */ \
REF (form_string), /* for 's', 'S' */ \
REF (form_pointer), /* for 'p' */ \
REF (form_number), /* for 'n' */ \
REF (form_strerror), /* for 'm' */ \
REF (form_wcharacter), /* for 'C' */ \
REF (form_floathex), /* for 'A', 'a' */ \
REF (form_unknown), /* for 't' */ \
REF (form_unknown), /* for 'j' */ \
REF (form_unknown), /* for 'I' */ \
REF (form_binary), /* for 'B', 'b' */ \
REF (form_unknown), /* for 'w' */ \
}
#define STEP4_TABLE \
/* Step 4: processing format specifier. */ \
static JUMP_TABLE_TYPE step4_jumps[32] = \
{ \
REF (form_unknown), \
REF (form_unknown), /* for ' ' */ \
REF (form_unknown), /* for '+' */ \
REF (form_unknown), /* for '-' */ \
REF (form_unknown), /* for '<hash>' */ \
REF (form_unknown), /* for '0' */ \
REF (form_unknown), /* for '\'' */ \
REF (form_unknown), /* for '*' */ \
REF (form_unknown), /* for '1'...'9' */ \
REF (form_unknown), /* for '.' */ \
REF (form_unknown), /* for 'h' */ \
REF (form_unknown), /* for 'l' */ \
REF (form_unknown), /* for 'L', 'q' */ \
REF (form_unknown), /* for 'z', 'Z' */ \
REF (form_percent), /* for '%' */ \
REF (form_integer), /* for 'd', 'i' */ \
REF (form_unsigned), /* for 'u' */ \
REF (form_octal), /* for 'o' */ \
REF (form_hexa), /* for 'X', 'x' */ \
REF (form_float), /* for 'E', 'e', 'F', 'f', 'G', 'g' */ \
REF (form_character), /* for 'c' */ \
REF (form_string), /* for 's', 'S' */ \
REF (form_pointer), /* for 'p' */ \
REF (form_number), /* for 'n' */ \
REF (form_strerror), /* for 'm' */ \
REF (form_wcharacter), /* for 'C' */ \
REF (form_floathex), /* for 'A', 'a' */ \
REF (form_unknown), /* for 't' */ \
REF (form_unknown), /* for 'j' */ \
REF (form_unknown), /* for 'I' */ \
REF (form_binary), /* for 'B', 'b' */ \
REF (form_unknown), /* for 'w' */ \
}
/* Handle positional format specifiers. */
static void printf_positional (struct Xprintf_buffer *buf,
const CHAR_T *format, int readonly_format,
va_list ap, va_list *ap_savep,
int nspecs_done, const UCHAR_T *lead_str_end,
CHAR_T *work_buffer, int save_errno,
const char *grouping,
THOUSANDS_SEP_T thousands_sep,
unsigned int mode_flags);
/* Handle unknown format specifier. */
static void printf_unknown (struct Xprintf_buffer *,
const struct printf_info *) __THROW;
static void group_number (struct Xprintf_buffer *buf,
struct grouping_iterator *iter,
CHAR_T *from, CHAR_T *to,
THOUSANDS_SEP_T thousands_sep, bool i18n);
/* The buffer-based function itself. */
void
Xprintf_buffer (struct Xprintf_buffer *buf, const CHAR_T *format,
va_list ap, unsigned int mode_flags)
{
/* The character used as thousands separator. */
THOUSANDS_SEP_T thousands_sep = 0;
/* The string describing the size of groups of digits. */
const char *grouping;
/* Current character in format string. */
const UCHAR_T *f;
/* End of leading constant string. */
const UCHAR_T *lead_str_end;
/* Points to next format specifier. */
const UCHAR_T *end_of_spec;
/* Buffer intermediate results. */
CHAR_T work_buffer[WORK_BUFFER_SIZE];
CHAR_T *workend;
/* We have to save the original argument pointer. */
va_list ap_save;
/* Count number of specifiers we already processed. */
int nspecs_done;
/* For the %m format we may need the current `errno' value. */
int save_errno = errno;
/* 1 if format is in read-only memory, -1 if it is in writable memory,
0 if unknown. */
int readonly_format = 0;
/* Initialize local variables. */
grouping = (const char *) -1;
#ifdef __va_copy
/* This macro will be available soon in gcc's <stdarg.h>. We need it
since on some systems `va_list' is not an integral type. */
__va_copy (ap_save, ap);
#else
ap_save = ap;
#endif
nspecs_done = 0;
#ifdef COMPILE_WPRINTF
/* Find the first format specifier. */
f = lead_str_end = __find_specwc ((const UCHAR_T *) format);
#else
/* Find the first format specifier. */
f = lead_str_end = __find_specmb ((const UCHAR_T *) format);
#endif
/* Write the literal text before the first format. */
Xprintf_buffer_write (buf, format,
lead_str_end - (const UCHAR_T *) format);
if (Xprintf_buffer_has_failed (buf))
return;
/* If we only have to print a simple string, return now. */
if (*f == L_('\0'))
return;
/* Use the slow path in case any printf handler is registered. */
if (__glibc_unlikely (__printf_function_table != NULL
|| __printf_modifier_table != NULL
|| __printf_va_arg_table != NULL))
goto do_positional;
/* Process whole format string. */
do
{
STEP0_3_TABLE;
STEP4_TABLE;
int is_negative; /* Flag for negative number. */
union
{
unsigned long long int longlong;
unsigned long int word;
} number;
int base;
union printf_arg the_arg;
CHAR_T *string; /* Pointer to argument string. */
int alt = 0; /* Alternate format. */
int space = 0; /* Use space prefix if no sign is needed. */
int left = 0; /* Left-justify output. */
int showsign = 0; /* Always begin with plus or minus sign. */
int group = 0; /* Print numbers according grouping rules. */
/* Argument is long double/long long int. Only used if
double/long double or long int/long long int are distinct. */
int is_long_double __attribute__ ((unused)) = 0;
int is_short = 0; /* Argument is short int. */
int is_long = 0; /* Argument is long int. */
int is_char = 0; /* Argument is promoted (unsigned) char. */
int width = 0; /* Width of output; 0 means none specified. */
int prec = -1; /* Precision of output; -1 means none specified. */
/* This flag is set by the 'I' modifier and selects the use of the
`outdigits' as determined by the current locale. */
int use_outdigits = 0;
UCHAR_T pad = L_(' ');/* Padding character. */
CHAR_T spec;
workend = work_buffer + WORK_BUFFER_SIZE;
/* Get current character in format string. */
JUMP (*++f, step0_jumps);
/* ' ' flag. */
LABEL (flag_space):
space = 1;
JUMP (*++f, step0_jumps);
/* '+' flag. */
LABEL (flag_plus):
showsign = 1;
JUMP (*++f, step0_jumps);
/* The '-' flag. */
LABEL (flag_minus):
left = 1;
pad = L_(' ');
JUMP (*++f, step0_jumps);
/* The '#' flag. */
LABEL (flag_hash):
alt = 1;
JUMP (*++f, step0_jumps);
/* The '0' flag. */
LABEL (flag_zero):
if (!left)
pad = L_('0');
JUMP (*++f, step0_jumps);
/* The '\'' flag. */
LABEL (flag_quote):
group = 1;
if (grouping == (const char *) -1)
{
#ifdef COMPILE_WPRINTF
thousands_sep = _NL_CURRENT_WORD (LC_NUMERIC,
_NL_NUMERIC_THOUSANDS_SEP_WC);
#else
thousands_sep = _NL_CURRENT (LC_NUMERIC, THOUSANDS_SEP);
#endif
grouping = _NL_CURRENT (LC_NUMERIC, GROUPING);
if (*grouping == '\0' || *grouping == CHAR_MAX
#ifdef COMPILE_WPRINTF
|| thousands_sep == L'\0'
#else
|| *thousands_sep == '\0'
#endif
)
grouping = NULL;
}
JUMP (*++f, step0_jumps);
LABEL (flag_i18n):
use_outdigits = 1;
JUMP (*++f, step0_jumps);
/* Get width from argument. */
LABEL (width_asterics):
{
const UCHAR_T *tmp; /* Temporary value. */
tmp = ++f;
if (ISDIGIT (*tmp))
{
int pos = read_int (&tmp);
if (pos == -1)
{
__set_errno (EOVERFLOW);
Xprintf_buffer_mark_failed (buf);
goto all_done;
}
if (pos && *tmp == L_('$'))
/* The width comes from a positional parameter. */
goto do_positional;
}
width = va_arg (ap, int);
/* Negative width means left justified. */
if (width < 0)
{
width = -width;
pad = L_(' ');
left = 1;
}
}
JUMP (*f, step1_jumps);
/* Given width in format string. */
LABEL (width):
width = read_int (&f);
if (__glibc_unlikely (width == -1))
{
__set_errno (EOVERFLOW);
Xprintf_buffer_mark_failed (buf);
goto all_done;
}
if (*f == L_('$'))
/* Oh, oh. The argument comes from a positional parameter. */
goto do_positional;
JUMP (*f, step1_jumps);
LABEL (precision):
++f;
if (*f == L_('*'))
{
const UCHAR_T *tmp; /* Temporary value. */
tmp = ++f;
if (ISDIGIT (*tmp))
{
int pos = read_int (&tmp);
if (pos == -1)
{
__set_errno (EOVERFLOW);
Xprintf_buffer_mark_failed (buf);
goto all_done;
}
if (pos && *tmp == L_('$'))
/* The precision comes from a positional parameter. */
goto do_positional;
}
prec = va_arg (ap, int);
/* If the precision is negative the precision is omitted. */
if (prec < 0)
prec = -1;
}
else if (ISDIGIT (*f))
{
prec = read_int (&f);
/* The precision was specified in this case as an extremely
large positive value. */
if (prec == -1)
{
__set_errno (EOVERFLOW);
Xprintf_buffer_mark_failed (buf);
goto all_done;
}
}
else
prec = 0;
JUMP (*f, step2_jumps);
/* Process 'h' modifier. There might another 'h' following. */
LABEL (mod_half):
is_short = 1;
JUMP (*++f, step3a_jumps);
/* Process 'hh' modifier. */
LABEL (mod_halfhalf):
is_short = 0;
is_char = 1;
JUMP (*++f, step4_jumps);
/* Process 'l' modifier. There might another 'l' following. */
LABEL (mod_long):
is_long = 1;
JUMP (*++f, step3b_jumps);
/* Process 'L', 'q', or 'll' modifier. No other modifier is
allowed to follow. */
LABEL (mod_longlong):
is_long_double = 1;
is_long = 1;
JUMP (*++f, step4_jumps);
LABEL (mod_size_t):
is_long_double = sizeof (size_t) > sizeof (unsigned long int);
is_long = sizeof (size_t) > sizeof (unsigned int);
JUMP (*++f, step4_jumps);
LABEL (mod_ptrdiff_t):
is_long_double = sizeof (ptrdiff_t) > sizeof (unsigned long int);
is_long = sizeof (ptrdiff_t) > sizeof (unsigned int);
JUMP (*++f, step4_jumps);
LABEL (mod_intmax_t):
is_long_double = sizeof (intmax_t) > sizeof (unsigned long int);
is_long = sizeof (intmax_t) > sizeof (unsigned int);
JUMP (*++f, step4_jumps);
/* Process 'wN' or 'wfN' modifier. */
LABEL (mod_bitwidth):
++f;
bool is_fast = false;
if (*f == L_('f'))
{
++f;
is_fast = true;
}
int bitwidth = 0;
if (ISDIGIT (*f))
bitwidth = read_int (&f);
if (is_fast)
switch (bitwidth)
{
case 8:
bitwidth = INT_FAST8_WIDTH;
break;
case 16:
bitwidth = INT_FAST16_WIDTH;
break;
case 32:
bitwidth = INT_FAST32_WIDTH;
break;
case 64:
bitwidth = INT_FAST64_WIDTH;
break;
}
switch (bitwidth)
{
case 8:
is_char = 1;
break;
case 16:
is_short = 1;
break;
case 32:
break;
case 64:
is_long_double = 1;
is_long = 1;
break;
default:
/* ISO C requires this error to be detected. */
__set_errno (EINVAL);
Xprintf_buffer_mark_failed (buf);
goto all_done;
}
JUMP (*f, step4_jumps);
/* Process current format. */
while (1)
{
#define process_arg_int() va_arg (ap, int)
#define process_arg_long_int() va_arg (ap, long int)
#define process_arg_long_long_int() va_arg (ap, long long int)
#define process_arg_pointer() va_arg (ap, void *)
#define process_arg_string() va_arg (ap, const char *)
#define process_arg_unsigned_int() va_arg (ap, unsigned int)
#define process_arg_unsigned_long_int() va_arg (ap, unsigned long int)
#define process_arg_unsigned_long_long_int() va_arg (ap, unsigned long long int)
#define process_arg_wchar_t() va_arg (ap, wchar_t)
#define process_arg_wstring() va_arg (ap, const wchar_t *)
#include "vfprintf-process-arg.c"
#undef process_arg_int
#undef process_arg_long_int
#undef process_arg_long_long_int
#undef process_arg_pointer
#undef process_arg_string
#undef process_arg_unsigned_int
#undef process_arg_unsigned_long_int
#undef process_arg_unsigned_long_long_int
#undef process_arg_wchar_t
#undef process_arg_wstring
LABEL (form_float):
LABEL (form_floathex):
{
if (__glibc_unlikely ((mode_flags & PRINTF_LDBL_IS_DBL) != 0))
is_long_double = 0;
struct printf_info info =
{
.prec = prec,
.width = width,
.spec = spec,
.is_long_double = is_long_double,
.is_short = is_short,
.is_long = is_long,
.alt = alt,
.space = space,
.left = left,
.showsign = showsign,
.group = group,
.pad = pad,
.extra = 0,
.i18n = use_outdigits,
.wide = sizeof (CHAR_T) != 1,
.is_binary128 = 0
};
PARSE_FLOAT_VA_ARG_EXTENDED (info);
const void *ptr = &the_arg;
__printf_fp_spec (buf, &info, &ptr);
}
break;
LABEL (form_unknown):
if (spec == L_('\0'))
{
/* The format string ended before the specifier is complete. */
__set_errno (EINVAL);
Xprintf_buffer_mark_failed (buf);
goto all_done;
}
/* If we are in the fast loop force entering the complicated
one. */
goto do_positional;
}
/* The format is correctly handled. */
++nspecs_done;
/* Look for next format specifier. */
#ifdef COMPILE_WPRINTF
f = __find_specwc ((end_of_spec = ++f));
#else
f = __find_specmb ((end_of_spec = ++f));
#endif
/* Write the following constant string. */
Xprintf_buffer_write (buf, (const CHAR_T *) end_of_spec,
f - end_of_spec);
}
while (*f != L_('\0') && !Xprintf_buffer_has_failed (buf));
all_done:
/* printf_positional performs cleanup under its all_done label, so
vfprintf-process-arg.c uses it for this function and
printf_positional below. */
return;
/* Hand off processing for positional parameters. */
do_positional:
printf_positional (buf, format, readonly_format, ap, &ap_save,
nspecs_done, lead_str_end, work_buffer,
save_errno, grouping, thousands_sep, mode_flags);
}
static void
printf_positional (struct Xprintf_buffer * buf, const CHAR_T *format,
int readonly_format,
va_list ap, va_list *ap_savep, int nspecs_done,
const UCHAR_T *lead_str_end,
CHAR_T *work_buffer, int save_errno,
const char *grouping, THOUSANDS_SEP_T thousands_sep,
unsigned int mode_flags)
{
/* For positional argument handling. */
struct scratch_buffer specsbuf;
scratch_buffer_init (&specsbuf);
struct printf_spec *specs = specsbuf.data;
size_t specs_limit = specsbuf.length / sizeof (specs[0]);
/* Used as a backing store for args_value, args_size, args_type
below. */
struct scratch_buffer argsbuf;
scratch_buffer_init (&argsbuf);
/* Array with information about the needed arguments. This has to
be dynamically extensible. */
size_t nspecs = 0;
/* The number of arguments the format string requests. This will
determine the size of the array needed to store the argument
attributes. */
size_t nargs = 0;
/* Positional parameters refer to arguments directly. This could
also determine the maximum number of arguments. Track the
maximum number. */
size_t max_ref_arg = 0;
/* Just a counter. */
size_t cnt;
if (grouping == (const char *) -1)
{
#ifdef COMPILE_WPRINTF
thousands_sep = _NL_CURRENT_WORD (LC_NUMERIC,
_NL_NUMERIC_THOUSANDS_SEP_WC);
#else
thousands_sep = _NL_CURRENT (LC_NUMERIC, THOUSANDS_SEP);
#endif
grouping = _NL_CURRENT (LC_NUMERIC, GROUPING);
if (*grouping == '\0' || *grouping == CHAR_MAX)
grouping = NULL;
}
for (const UCHAR_T *f = lead_str_end; *f != L_('\0');
f = specs[nspecs++].next_fmt)
{
if (nspecs == specs_limit)
{
if (!scratch_buffer_grow_preserve (&specsbuf))
{
Xprintf_buffer_mark_failed (buf);
goto all_done;
}
specs = specsbuf.data;
specs_limit = specsbuf.length / sizeof (specs[0]);
}
/* Parse the format specifier. */
bool failed;
#ifdef COMPILE_WPRINTF
nargs += __parse_one_specwc (f, nargs, &specs[nspecs], &max_ref_arg,
&failed);
#else
nargs += __parse_one_specmb (f, nargs, &specs[nspecs], &max_ref_arg,
&failed);
#endif
if (failed)
{
Xprintf_buffer_mark_failed (buf);
goto all_done;
}
}
/* Determine the number of arguments the format string consumes. */
nargs = MAX (nargs, max_ref_arg);
union printf_arg *args_value;
int *args_size;
int *args_type;
{
/* Calculate total size needed to represent a single argument
across all three argument-related arrays. */
size_t bytes_per_arg
= sizeof (*args_value) + sizeof (*args_size) + sizeof (*args_type);
if (!scratch_buffer_set_array_size (&argsbuf, nargs, bytes_per_arg))
{
Xprintf_buffer_mark_failed (buf);
goto all_done;
}
args_value = argsbuf.data;
/* Set up the remaining two arrays to each point past the end of
the prior array, since space for all three has been allocated
now. */
args_size = &args_value[nargs].pa_int;
args_type = &args_size[nargs];
memset (args_type, (mode_flags & PRINTF_FORTIFY) != 0 ? '\xff' : '\0',
nargs * sizeof (*args_type));
}
/* XXX Could do sanity check here: If any element in ARGS_TYPE is
still zero after this loop, format is invalid. For now we
simply use 0 as the value. */
/* Fill in the types of all the arguments. */
for (cnt = 0; cnt < nspecs; ++cnt)
{
/* If the width is determined by an argument this is an int. */
if (specs[cnt].width_arg != -1)
args_type[specs[cnt].width_arg] = PA_INT;
/* If the precision is determined by an argument this is an int. */
if (specs[cnt].prec_arg != -1)
args_type[specs[cnt].prec_arg] = PA_INT;
switch (specs[cnt].ndata_args)
{
case 0: /* No arguments. */
break;
case 1: /* One argument; we already have the
type and size. */
args_type[specs[cnt].data_arg] = specs[cnt].data_arg_type;
args_size[specs[cnt].data_arg] = specs[cnt].size;
break;
default:
/* We have more than one argument for this format spec.
We must call the arginfo function again to determine
all the types. */
(void) (*__printf_arginfo_table[specs[cnt].info.spec])
(&specs[cnt].info,
specs[cnt].ndata_args, &args_type[specs[cnt].data_arg],
&args_size[specs[cnt].data_arg]);
break;
}
}
/* Now we know all the types and the order. Fill in the argument
values. */
for (cnt = 0; cnt < nargs; ++cnt)
switch (args_type[cnt])
{
#define T(tag, mem, type) \
case tag: \
args_value[cnt].mem = va_arg (*ap_savep, type); \
break
T (PA_WCHAR, pa_wchar, wint_t);
case PA_CHAR: /* Promoted. */
case PA_INT|PA_FLAG_SHORT: /* Promoted. */
#if LONG_MAX == INT_MAX
case PA_INT|PA_FLAG_LONG:
#endif
T (PA_INT, pa_int, int);
#if LONG_MAX == LONG_LONG_MAX
case PA_INT|PA_FLAG_LONG:
#endif
T (PA_INT|PA_FLAG_LONG_LONG, pa_long_long_int, long long int);
#if LONG_MAX != INT_MAX && LONG_MAX != LONG_LONG_MAX
# error "he?"
#endif
case PA_FLOAT: /* Promoted. */
T (PA_DOUBLE, pa_double, double);
case PA_DOUBLE|PA_FLAG_LONG_DOUBLE:
if (__glibc_unlikely ((mode_flags & PRINTF_LDBL_IS_DBL) != 0))
{
args_value[cnt].pa_double = va_arg (*ap_savep, double);
args_type[cnt] &= ~PA_FLAG_LONG_DOUBLE;
}
#if __HAVE_FLOAT128_UNLIKE_LDBL
else if ((mode_flags & PRINTF_LDBL_USES_FLOAT128) != 0)
args_value[cnt].pa_float128 = va_arg (*ap_savep, _Float128);
#endif
else
args_value[cnt].pa_long_double = va_arg (*ap_savep, long double);
break;
case PA_STRING: /* All pointers are the same */
case PA_WSTRING: /* All pointers are the same */
T (PA_POINTER, pa_pointer, void *);
#undef T
default:
if ((args_type[cnt] & PA_FLAG_PTR) != 0)
args_value[cnt].pa_pointer = va_arg (*ap_savep, void *);
else if (__glibc_unlikely (__printf_va_arg_table != NULL)
&& __printf_va_arg_table[args_type[cnt] - PA_LAST] != NULL)
{
args_value[cnt].pa_user = alloca (args_size[cnt]);
(*__printf_va_arg_table[args_type[cnt] - PA_LAST])
(args_value[cnt].pa_user, ap_savep);
}
else
memset (&args_value[cnt], 0, sizeof (args_value[cnt]));
break;
case -1:
/* Error case. Not all parameters appear in N$ format
strings. We have no way to determine their type. */
assert ((mode_flags & PRINTF_FORTIFY) != 0);
__libc_fatal ("*** invalid %N$ use detected ***\n");
}
/* Now walk through all format specifiers and process them. */
for (; (size_t) nspecs_done < nspecs && !Xprintf_buffer_has_failed (buf);
++nspecs_done)
{
STEP4_TABLE;
int is_negative;
union
{
unsigned long long int longlong;
unsigned long int word;
} number;
int base;
CHAR_T *string; /* Pointer to argument string. */
/* Fill variables from values in struct. */
int alt = specs[nspecs_done].info.alt;
int space = specs[nspecs_done].info.space;
int left = specs[nspecs_done].info.left;
int showsign = specs[nspecs_done].info.showsign;
int group = specs[nspecs_done].info.group;
int is_long_double __attribute__ ((unused))
= specs[nspecs_done].info.is_long_double;
int is_short = specs[nspecs_done].info.is_short;
int is_char = specs[nspecs_done].info.is_char;
int is_long = specs[nspecs_done].info.is_long;
int width = specs[nspecs_done].info.width;
int prec = specs[nspecs_done].info.prec;
int use_outdigits = specs[nspecs_done].info.i18n;
char pad = specs[nspecs_done].info.pad;
CHAR_T spec = specs[nspecs_done].info.spec;
CHAR_T *workend = work_buffer + WORK_BUFFER_SIZE;
/* Fill in last information. */
if (specs[nspecs_done].width_arg != -1)
{
/* Extract the field width from an argument. */
specs[nspecs_done].info.width =
args_value[specs[nspecs_done].width_arg].pa_int;
if (specs[nspecs_done].info.width < 0)
/* If the width value is negative left justification is
selected and the value is taken as being positive. */
{
specs[nspecs_done].info.width *= -1;
left = specs[nspecs_done].info.left = 1;
}
width = specs[nspecs_done].info.width;
}
if (specs[nspecs_done].prec_arg != -1)
{
/* Extract the precision from an argument. */
specs[nspecs_done].info.prec =
args_value[specs[nspecs_done].prec_arg].pa_int;
if (specs[nspecs_done].info.prec < 0)
/* If the precision is negative the precision is
omitted. */
specs[nspecs_done].info.prec = -1;
prec = specs[nspecs_done].info.prec;
}
/* Process format specifiers. */
do
{
if (spec <= UCHAR_MAX
&& __printf_function_table != NULL
&& __printf_function_table[(size_t) spec] != NULL)
{
int function_done
= Xprintf (function_invoke) (buf,
__printf_function_table[(size_t) spec],
&args_value[specs[nspecs_done]
.data_arg],
specs[nspecs_done].ndata_args,
&specs[nspecs_done].info);
if (function_done != -2)
{
/* If an error occurred we don't have information
about # of chars. */
if (function_done < 0)
{
/* Function has set errno. */
Xprintf_buffer_mark_failed (buf);
goto all_done;
}
break;
}
}
JUMP (spec, step4_jumps);
#define process_arg_data args_value[specs[nspecs_done].data_arg]
#define process_arg_int() process_arg_data.pa_int
#define process_arg_long_int() process_arg_data.pa_long_int
#define process_arg_long_long_int() process_arg_data.pa_long_long_int
#define process_arg_pointer() process_arg_data.pa_pointer
#define process_arg_string() process_arg_data.pa_string
#define process_arg_unsigned_int() process_arg_data.pa_u_int
#define process_arg_unsigned_long_int() process_arg_data.pa_u_long_int
#define process_arg_unsigned_long_long_int() process_arg_data.pa_u_long_long_int
#define process_arg_wchar_t() process_arg_data.pa_wchar
#define process_arg_wstring() process_arg_data.pa_wstring
#include "vfprintf-process-arg.c"
#undef process_arg_data
#undef process_arg_int
#undef process_arg_long_int
#undef process_arg_long_long_int
#undef process_arg_pointer
#undef process_arg_string
#undef process_arg_unsigned_int
#undef process_arg_unsigned_long_int
#undef process_arg_unsigned_long_long_int
#undef process_arg_wchar_t
#undef process_arg_wstring
LABEL (form_float):
LABEL (form_floathex):
{
const void *ptr
= (const void *) &args_value[specs[nspecs_done].data_arg];
if (__glibc_unlikely ((mode_flags & PRINTF_LDBL_IS_DBL) != 0))
{
specs[nspecs_done].data_arg_type = PA_DOUBLE;
specs[nspecs_done].info.is_long_double = 0;
}
SETUP_FLOAT128_INFO (specs[nspecs_done].info);
__printf_fp_spec (buf, &specs[nspecs_done].info, &ptr);
}
break;
LABEL (form_unknown):
{
printf_unknown (buf, &specs[nspecs_done].info);
}
break;
}
while (Xprintf_buffer_has_failed (buf));
/* Write the following constant string. */
Xprintf_buffer_write (buf,
(const CHAR_T *) specs[nspecs_done].end_of_fmt,
(specs[nspecs_done].next_fmt
- specs[nspecs_done].end_of_fmt));
}
all_done:
scratch_buffer_free (&argsbuf);
scratch_buffer_free (&specsbuf);
}
/* Handle an unknown format specifier. This prints out a canonicalized
representation of the format spec itself. */
static void
printf_unknown (struct Xprintf_buffer *buf, const struct printf_info *info)
{
CHAR_T work_buffer[MAX (sizeof (info->width), sizeof (info->prec)) * 3];
CHAR_T *const workend
= &work_buffer[sizeof (work_buffer) / sizeof (CHAR_T)];
CHAR_T *w;
Xprintf_buffer_putc (buf, L_('%'));
if (info->alt)
Xprintf_buffer_putc (buf, L_('#'));
if (info->group)
Xprintf_buffer_putc (buf, L_('\''));
if (info->showsign)
Xprintf_buffer_putc (buf, L_('+'));
else if (info->space)
Xprintf_buffer_putc (buf, L_(' '));
if (info->left)
Xprintf_buffer_putc (buf, L_('-'));
if (info->pad == L_('0'))
Xprintf_buffer_putc (buf, L_('0'));
if (info->i18n)
Xprintf_buffer_putc (buf, L_('I'));
if (info->width != 0)
{
w = _itoa_word (info->width, workend, 10, 0);
while (w < workend)
Xprintf_buffer_putc (buf, *w++);
}
if (info->prec != -1)
{
Xprintf_buffer_putc (buf, L_('.'));
w = _itoa_word (info->prec, workend, 10, 0);
while (w < workend)
Xprintf_buffer_putc (buf, *w++);
}
if (info->spec != L_('\0'))
Xprintf_buffer_putc (buf, info->spec);
}
static void
group_number (struct Xprintf_buffer *buf,
struct grouping_iterator *iter,
CHAR_T *from, CHAR_T *to, THOUSANDS_SEP_T thousands_sep,
bool i18n)
{
if (!i18n)
for (CHAR_T *cp = from; cp != to; ++cp)
{
if (__grouping_iterator_next (iter))
{
#ifdef COMPILE_WPRINTF
__wprintf_buffer_putc (buf, thousands_sep);
#else
__printf_buffer_puts (buf, thousands_sep);
#endif
}
Xprintf_buffer_putc (buf, *cp);
}
else
{
/* Apply digit translation and grouping. */
for (CHAR_T *cp = from; cp != to; ++cp)
{
if (__grouping_iterator_next (iter))
{
#ifdef COMPILE_WPRINTF
__wprintf_buffer_putc (buf, thousands_sep);
#else
__printf_buffer_puts (buf, thousands_sep);
#endif
}
int digit = *cp - '0';
#ifdef COMPILE_WPRINTF
__wprintf_buffer_putc
(buf, _NL_CURRENT_WORD (LC_CTYPE,
_NL_CTYPE_OUTDIGIT0_WC + digit));
#else
__printf_buffer_puts
(buf, _NL_CURRENT (LC_CTYPE, _NL_CTYPE_OUTDIGIT0_MB + digit));
#endif
}
}
}
/* The FILE-based function. */
int
vfprintf (FILE *s, const CHAR_T *format, va_list ap, unsigned int mode_flags)
{
/* Orient the stream. */
#ifdef ORIENT
ORIENT;
#endif
/* Sanity check of arguments. */
ARGCHECK (s, format);
#ifdef ORIENT
/* Check for correct orientation. */
if (_IO_vtable_offset (s) == 0
&& _IO_fwide (s, sizeof (CHAR_T) == 1 ? -1 : 1)
!= (sizeof (CHAR_T) == 1 ? -1 : 1))
/* The stream is already oriented otherwise. */
return EOF;
#endif
if (!_IO_need_lock (s))
{
struct Xprintf (buffer_to_file) wrap;
Xprintf (buffer_to_file_init) (&wrap, s);
Xprintf_buffer (&wrap.base, format, ap, mode_flags);
return Xprintf (buffer_to_file_done) (&wrap);
}
int done;
/* Lock stream. */
_IO_cleanup_region_start ((void (*) (void *)) &_IO_funlockfile, s);
_IO_flockfile (s);
/* Set up the wrapping buffer. */
struct Xprintf (buffer_to_file) wrap;
Xprintf (buffer_to_file_init) (&wrap, s);
/* Perform the printing operation on the buffer. */
Xprintf_buffer (&wrap.base, format, ap, mode_flags);
done = Xprintf (buffer_to_file_done) (&wrap);
/* Unlock the stream. */
_IO_funlockfile (s);
_IO_cleanup_region_end (0);
return done;
}