/* Copyright (C) 1991-2008, 2009, 2010, 2011 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
. */
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include "_itoa.h"
#include
#include
/* 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
#define FILE _IO_FILE
#undef va_list
#define va_list _IO_va_list
#undef BUFSIZ
#define BUFSIZ _IO_BUFSIZ
#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) \
{ \
MAYBE_SET_EINVAL; \
return -1; \
} \
} while (0)
#define UNBUFFERED_P(S) ((S)->_IO_file_flags & _IO_UNBUFFERED)
#define done_add(val) \
do { \
unsigned int _val = val; \
assert ((unsigned int) done < (unsigned int) INT_MAX); \
if (__builtin_expect ((unsigned int) INT_MAX - (unsigned int) done \
< _val, 0)) \
{ \
done = -1; \
goto all_done; \
} \
done += _val; \
} while (0)
#ifndef COMPILE_WPRINTF
# define vfprintf _IO_vfprintf_internal
# define CHAR_T char
# define UCHAR_T unsigned char
# define INT_T int
# define L_(Str) Str
# define ISDIGIT(Ch) ((unsigned int) ((Ch) - '0') < 10)
# define STR_LEN(Str) strlen (Str)
# define PUT(F, S, N) _IO_sputn ((F), (S), (N))
# define PAD(Padchar) \
if (width > 0) \
done_add (INTUSE(_IO_padn) (s, (Padchar), width))
# define PUTC(C, F) _IO_putc_unlocked (C, F)
# define ORIENT if (_IO_vtable_offset (s) == 0 && _IO_fwide (s, -1) != -1)\
return -1
#else
# define vfprintf _IO_vfwprintf
# define CHAR_T wchar_t
/* This is a hack!!! There should be a type uwchar_t. */
# define UCHAR_T unsigned int /* uwchar_t */
# define INT_T wint_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 PUT(F, S, N) _IO_sputn ((F), (S), (N))
# define PAD(Padchar) \
if (width > 0) \
done_add (_IO_wpadn (s, (Padchar), width))
# define PUTC(C, F) _IO_putwc_unlocked (C, F)
# define ORIENT if (_IO_fwide (s, 1) != 1) return -1
# 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 "_i18n_number.h"
/* Include the shared code for parsing the format string. */
#include "printf-parse.h"
#define outchar(Ch) \
do \
{ \
register const INT_T outc = (Ch); \
if (PUTC (outc, s) == EOF || done == INT_MAX) \
{ \
done = -1; \
goto all_done; \
} \
++done; \
} \
while (0)
#define outstring(String, Len) \
do \
{ \
assert ((size_t) done <= (size_t) INT_MAX); \
if ((size_t) PUT (s, (String), (Len)) != (size_t) (Len) \
|| (size_t) INT_MAX - (size_t) done < (size_t) (Len)) \
{ \
done = -1; \
goto all_done; \
} \
done += (Len); \
} \
while (0)
/* 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 variables. */
static const CHAR_T null[] = L_("(null)");
/* Helper function to provide temporary buffering for unbuffered streams. */
static int buffered_vfprintf (FILE *stream, const CHAR_T *fmt, va_list)
__THROW __attribute__ ((noinline)) internal_function;
/* Handle unknown format specifier. */
static int printf_unknown (FILE *, const struct printf_info *,
const void *const *) __THROW;
/* Group digits of number string. */
#ifdef COMPILE_WPRINTF
static CHAR_T *group_number (CHAR_T *, CHAR_T *, const char *, wchar_t)
__THROW internal_function;
#else
static CHAR_T *group_number (CHAR_T *, CHAR_T *, const char *, const char *)
__THROW internal_function;
#endif
/* The function itself. */
int
vfprintf (FILE *s, const CHAR_T *format, va_list ap)
{
/* The character used as thousands separator. */
#ifdef COMPILE_WPRINTF
wchar_t thousands_sep = L'\0';
#else
const char *thousands_sep = NULL;
#endif
/* The string describing the size of groups of digits. */
const char *grouping;
/* Place to accumulate the result. */
int done;
/* 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[1000];
CHAR_T *workstart = NULL;
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;
/* For the argument descriptions, which may be allocated on the heap. */
void *args_malloced = NULL;
/* 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, 0, /* '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, 0, /* '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, 0,
/* '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_(' ')])
#ifdef SHARED
/* 'int' is enough and it saves some space on 64 bit systems. */
# define JUMP_TABLE_TYPE const int
# define JUMP(ChExpr, table) \
do \
{ \
int offset; \
void *__unbounded ptr; \
spec = (ChExpr); \
offset = NOT_IN_JUMP_RANGE (spec) ? REF (form_unknown) \
: table[CHAR_CLASS (spec)]; \
ptr = &&do_form_unknown + offset; \
goto *ptr; \
} \
while (0)
#else
# define JUMP_TABLE_TYPE const void *const
# define JUMP(ChExpr, table) \
do \
{ \
const void *__unbounded 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[30] = \
{ \
REF (form_unknown), \
REF (flag_space), /* for ' ' */ \
REF (flag_plus), /* for '+' */ \
REF (flag_minus), /* for '-' */ \
REF (flag_hash), /* for '' */ \
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' */ \
}; \
/* Step 1: after processing width. */ \
static JUMP_TABLE_TYPE step1_jumps[30] = \
{ \
REF (form_unknown), \
REF (form_unknown), /* for ' ' */ \
REF (form_unknown), /* for '+' */ \
REF (form_unknown), /* for '-' */ \
REF (form_unknown), /* for '' */ \
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' */ \
}; \
/* Step 2: after processing precision. */ \
static JUMP_TABLE_TYPE step2_jumps[30] = \
{ \
REF (form_unknown), \
REF (form_unknown), /* for ' ' */ \
REF (form_unknown), /* for '+' */ \
REF (form_unknown), /* for '-' */ \
REF (form_unknown), /* for '' */ \
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' */ \
}; \
/* Step 3a: after processing first 'h' modifier. */ \
static JUMP_TABLE_TYPE step3a_jumps[30] = \
{ \
REF (form_unknown), \
REF (form_unknown), /* for ' ' */ \
REF (form_unknown), /* for '+' */ \
REF (form_unknown), /* for '-' */ \
REF (form_unknown), /* for '' */ \
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' */ \
}; \
/* Step 3b: after processing first 'l' modifier. */ \
static JUMP_TABLE_TYPE step3b_jumps[30] = \
{ \
REF (form_unknown), \
REF (form_unknown), /* for ' ' */ \
REF (form_unknown), /* for '+' */ \
REF (form_unknown), /* for '-' */ \
REF (form_unknown), /* for '' */ \
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' */ \
}
#define STEP4_TABLE \
/* Step 4: processing format specifier. */ \
static JUMP_TABLE_TYPE step4_jumps[30] = \
{ \
REF (form_unknown), \
REF (form_unknown), /* for ' ' */ \
REF (form_unknown), /* for '+' */ \
REF (form_unknown), /* for '-' */ \
REF (form_unknown), /* for '' */ \
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' */ \
}
#define process_arg(fspec) \
/* Start real work. We know about all flags and modifiers and \
now process the wanted format specifier. */ \
LABEL (form_percent): \
/* Write a literal "%". */ \
outchar (L_('%')); \
break; \
\
LABEL (form_integer): \
/* Signed decimal integer. */ \
base = 10; \
\
if (is_longlong) \
{ \
long long int signed_number; \
\
if (fspec == NULL) \
signed_number = va_arg (ap, long long int); \
else \
signed_number = args_value[fspec->data_arg].pa_long_long_int; \
\
is_negative = signed_number < 0; \
number.longlong = is_negative ? (- signed_number) : signed_number; \
\
goto LABEL (longlong_number); \
} \
else \
{ \
long int signed_number; \
\
if (fspec == NULL) \
{ \
if (is_long_num) \
signed_number = va_arg (ap, long int); \
else if (is_char) \
signed_number = (signed char) va_arg (ap, unsigned int); \
else if (!is_short) \
signed_number = va_arg (ap, int); \
else \
signed_number = (short int) va_arg (ap, unsigned int); \
} \
else \
if (is_long_num) \
signed_number = args_value[fspec->data_arg].pa_long_int; \
else if (is_char) \
signed_number = (signed char) \
args_value[fspec->data_arg].pa_u_int; \
else if (!is_short) \
signed_number = args_value[fspec->data_arg].pa_int; \
else \
signed_number = (short int) \
args_value[fspec->data_arg].pa_u_int; \
\
is_negative = signed_number < 0; \
number.word = is_negative ? (- signed_number) : signed_number; \
\
goto LABEL (number); \
} \
/* NOTREACHED */ \
\
LABEL (form_unsigned): \
/* Unsigned decimal integer. */ \
base = 10; \
goto LABEL (unsigned_number); \
/* NOTREACHED */ \
\
LABEL (form_octal): \
/* Unsigned octal integer. */ \
base = 8; \
goto LABEL (unsigned_number); \
/* NOTREACHED */ \
\
LABEL (form_hexa): \
/* Unsigned hexadecimal integer. */ \
base = 16; \
\
LABEL (unsigned_number): /* Unsigned number of base BASE. */ \
\
/* ISO specifies the `+' and ` ' flags only for signed \
conversions. */ \
is_negative = 0; \
showsign = 0; \
space = 0; \
\
if (is_longlong) \
{ \
if (fspec == NULL) \
number.longlong = va_arg (ap, unsigned long long int); \
else \
number.longlong = args_value[fspec->data_arg].pa_u_long_long_int; \
\
LABEL (longlong_number): \
if (prec < 0) \
/* Supply a default precision if none was given. */ \
prec = 1; \
else \
/* We have to take care for the '0' flag. If a precision \
is given it must be ignored. */ \
pad = L_(' '); \
\
/* If the precision is 0 and the number is 0 nothing has to \
be written for the number, except for the 'o' format in \
alternate form. */ \
if (prec == 0 && number.longlong == 0) \
{ \
string = workend; \
if (base == 8 && alt) \
*--string = L_('0'); \
} \
else \
{ \
/* Put the number in WORK. */ \
string = _itoa (number.longlong, workend, base, \
spec == L_('X')); \
if (group && grouping) \
string = group_number (string, workend, grouping, \
thousands_sep); \
\
if (use_outdigits && base == 10) \
string = _i18n_number_rewrite (string, workend, workend); \
} \
/* Simplify further test for num != 0. */ \
number.word = number.longlong != 0; \
} \
else \
{ \
if (fspec == NULL) \
{ \
if (is_long_num) \
number.word = va_arg (ap, unsigned long int); \
else if (is_char) \
number.word = (unsigned char) va_arg (ap, unsigned int); \
else if (!is_short) \
number.word = va_arg (ap, unsigned int); \
else \
number.word = (unsigned short int) va_arg (ap, unsigned int); \
} \
else \
if (is_long_num) \
number.word = args_value[fspec->data_arg].pa_u_long_int; \
else if (is_char) \
number.word = (unsigned char) \
args_value[fspec->data_arg].pa_u_int; \
else if (!is_short) \
number.word = args_value[fspec->data_arg].pa_u_int; \
else \
number.word = (unsigned short int) \
args_value[fspec->data_arg].pa_u_int; \
\
LABEL (number): \
if (prec < 0) \
/* Supply a default precision if none was given. */ \
prec = 1; \
else \
/* We have to take care for the '0' flag. If a precision \
is given it must be ignored. */ \
pad = L_(' '); \
\
/* If the precision is 0 and the number is 0 nothing has to \
be written for the number, except for the 'o' format in \
alternate form. */ \
if (prec == 0 && number.word == 0) \
{ \
string = workend; \
if (base == 8 && alt) \
*--string = L_('0'); \
} \
else \
{ \
/* Put the number in WORK. */ \
string = _itoa_word (number.word, workend, base, \
spec == L_('X')); \
if (group && grouping) \
string = group_number (string, workend, grouping, \
thousands_sep); \
\
if (use_outdigits && base == 10) \
string = _i18n_number_rewrite (string, workend, workend); \
} \
} \
\
if (prec <= workend - string && number.word != 0 && alt && base == 8) \
/* Add octal marker. */ \
*--string = L_('0'); \
\
prec = MAX (0, prec - (workend - string)); \
\
if (!left) \
{ \
width -= workend - string + prec; \
\
if (number.word != 0 && alt && base == 16) \
/* Account for 0X hex marker. */ \
width -= 2; \
\
if (is_negative || showsign || space) \
--width; \
\
if (pad == L_(' ')) \
{ \
PAD (L_(' ')); \
width = 0; \
} \
\
if (is_negative) \
outchar (L_('-')); \
else if (showsign) \
outchar (L_('+')); \
else if (space) \
outchar (L_(' ')); \
\
if (number.word != 0 && alt && base == 16) \
{ \
outchar (L_('0')); \
outchar (spec); \
} \
\
width += prec; \
PAD (L_('0')); \
\
outstring (string, workend - string); \
\
break; \
} \
else \
{ \
if (is_negative) \
{ \
outchar (L_('-')); \
--width; \
} \
else if (showsign) \
{ \
outchar (L_('+')); \
--width; \
} \
else if (space) \
{ \
outchar (L_(' ')); \
--width; \
} \
\
if (number.word != 0 && alt && base == 16) \
{ \
outchar (L_('0')); \
outchar (spec); \
width -= 2; \
} \
\
width -= workend - string + prec; \
\
if (prec > 0) \
{ \
int temp = width; \
width = prec; \
PAD (L_('0')); \
width = temp; \
} \
\
outstring (string, workend - string); \
\
PAD (L_(' ')); \
break; \
} \
\
LABEL (form_float): \
{ \
/* Floating-point number. This is handled by printf_fp.c. */ \
const void *ptr; \
int function_done; \
\
if (fspec == NULL) \
{ \
if (__ldbl_is_dbl) \
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 }; \
\
if (is_long_double) \
the_arg.pa_long_double = va_arg (ap, long double); \
else \
the_arg.pa_double = va_arg (ap, double); \
ptr = (const void *) &the_arg; \
\
function_done = __printf_fp (s, &info, &ptr); \
} \
else \
{ \
ptr = (const void *) &args_value[fspec->data_arg]; \
if (__ldbl_is_dbl) \
{ \
fspec->data_arg_type = PA_DOUBLE; \
fspec->info.is_long_double = 0; \
} \
\
function_done = __printf_fp (s, &fspec->info, &ptr); \
} \
\
if (function_done < 0) \
{ \
/* Error in print handler. */ \
done = -1; \
goto all_done; \
} \
\
done_add (function_done); \
} \
break; \
\
LABEL (form_floathex): \
{ \
/* Floating point number printed as hexadecimal number. */ \
const void *ptr; \
int function_done; \
\
if (fspec == NULL) \
{ \
if (__ldbl_is_dbl) \
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, \
.wide = sizeof (CHAR_T) != 1 }; \
\
if (is_long_double) \
the_arg.pa_long_double = va_arg (ap, long double); \
else \
the_arg.pa_double = va_arg (ap, double); \
ptr = (const void *) &the_arg; \
\
function_done = __printf_fphex (s, &info, &ptr); \
} \
else \
{ \
ptr = (const void *) &args_value[fspec->data_arg]; \
if (__ldbl_is_dbl) \
fspec->info.is_long_double = 0; \
\
function_done = __printf_fphex (s, &fspec->info, &ptr); \
} \
\
if (function_done < 0) \
{ \
/* Error in print handler. */ \
done = -1; \
goto all_done; \
} \
\
done_add (function_done); \
} \
break; \
\
LABEL (form_pointer): \
/* Generic pointer. */ \
{ \
const void *ptr; \
if (fspec == NULL) \
ptr = va_arg (ap, void *); \
else \
ptr = args_value[fspec->data_arg].pa_pointer; \
if (ptr != NULL) \
{ \
/* If the pointer is not NULL, write it as a %#x spec. */ \
base = 16; \
number.word = (unsigned long int) ptr; \
is_negative = 0; \
alt = 1; \
group = 0; \
spec = L_('x'); \
goto LABEL (number); \
} \
else \
{ \
/* Write "(nil)" for a nil pointer. */ \
string = (CHAR_T *) L_("(nil)"); \
/* Make sure the full string "(nil)" is printed. */ \
if (prec < 5) \
prec = 5; \
is_long = 0; /* This is no wide-char string. */ \
goto LABEL (print_string); \
} \
} \
/* NOTREACHED */ \
\
LABEL (form_number): \
if (s->_flags2 & _IO_FLAGS2_FORTIFY) \
{ \
if (! readonly_format) \
{ \
extern int __readonly_area (const void *, size_t) \
attribute_hidden; \
readonly_format \
= __readonly_area (format, ((STR_LEN (format) + 1) \
* sizeof (CHAR_T))); \
} \
if (readonly_format < 0) \
__libc_fatal ("*** %n in writable segment detected ***\n"); \
} \
/* Answer the count of characters written. */ \
if (fspec == NULL) \
{ \
if (is_longlong) \
*(long long int *) va_arg (ap, void *) = done; \
else if (is_long_num) \
*(long int *) va_arg (ap, void *) = done; \
else if (is_char) \
*(char *) va_arg (ap, void *) = done; \
else if (!is_short) \
*(int *) va_arg (ap, void *) = done; \
else \
*(short int *) va_arg (ap, void *) = done; \
} \
else \
if (is_longlong) \
*(long long int *) args_value[fspec->data_arg].pa_pointer = done; \
else if (is_long_num) \
*(long int *) args_value[fspec->data_arg].pa_pointer = done; \
else if (is_char) \
*(char *) args_value[fspec->data_arg].pa_pointer = done; \
else if (!is_short) \
*(int *) args_value[fspec->data_arg].pa_pointer = done; \
else \
*(short int *) args_value[fspec->data_arg].pa_pointer = done; \
break; \
\
LABEL (form_strerror): \
/* Print description of error ERRNO. */ \
string = \
(CHAR_T *) __strerror_r (save_errno, (char *) work_buffer, \
sizeof work_buffer); \
is_long = 0; /* This is no wide-char string. */ \
goto LABEL (print_string)
#ifdef COMPILE_WPRINTF
# define process_string_arg(fspec) \
LABEL (form_character): \
/* Character. */ \
if (is_long) \
goto LABEL (form_wcharacter); \
--width; /* Account for the character itself. */ \
if (!left) \
PAD (L' '); \
if (fspec == NULL) \
outchar (__btowc ((unsigned char) va_arg (ap, int))); /* Promoted. */ \
else \
outchar (__btowc ((unsigned char) \
args_value[fspec->data_arg].pa_int)); \
if (left) \
PAD (L' '); \
break; \
\
LABEL (form_wcharacter): \
{ \
/* Wide character. */ \
--width; \
if (!left) \
PAD (L' '); \
if (fspec == NULL) \
outchar (va_arg (ap, wchar_t)); \
else \
outchar (args_value[fspec->data_arg].pa_wchar); \
if (left) \
PAD (L' '); \
} \
break; \
\
LABEL (form_string): \
{ \
size_t len; \
int string_malloced; \
\
/* The string argument could in fact be `char *' or `wchar_t *'. \
But this should not make a difference here. */ \
if (fspec == NULL) \
string = (CHAR_T *) va_arg (ap, const wchar_t *); \
else \
string = (CHAR_T *) args_value[fspec->data_arg].pa_wstring; \
\
/* Entry point for printing other strings. */ \
LABEL (print_string): \
\
string_malloced = 0; \
if (string == NULL) \
{ \
/* Write "(null)" if there's space. */ \
if (prec == -1 \
|| prec >= (int) (sizeof (null) / sizeof (null[0])) - 1) \
{ \
string = (CHAR_T *) null; \
len = (sizeof (null) / sizeof (null[0])) - 1; \
} \
else \
{ \
string = (CHAR_T *) L""; \
len = 0; \
} \
} \
else if (!is_long && spec != L_('S')) \
{ \
/* This is complicated. We have to transform the multibyte \
string into a wide character string. */ \
const char *mbs = (const char *) string; \
mbstate_t mbstate; \
\
len = prec != -1 ? __strnlen (mbs, (size_t) prec) : strlen (mbs); \
\
/* Allocate dynamically an array which definitely is long \
enough for the wide character version. Each byte in the \
multi-byte string can produce at most one wide character. */ \
if (__libc_use_alloca (len * sizeof (wchar_t))) \
string = (CHAR_T *) alloca (len * sizeof (wchar_t)); \
else if ((string = (CHAR_T *) malloc (len * sizeof (wchar_t))) \
== NULL) \
{ \
done = -1; \
goto all_done; \
} \
else \
string_malloced = 1; \
\
memset (&mbstate, '\0', sizeof (mbstate_t)); \
len = __mbsrtowcs (string, &mbs, len, &mbstate); \
if (len == (size_t) -1) \
{ \
/* Illegal multibyte character. */ \
done = -1; \
goto all_done; \
} \
} \
else \
{ \
if (prec != -1) \
/* Search for the end of the string, but don't search past \
the length specified by the precision. */ \
len = __wcsnlen (string, prec); \
else \
len = __wcslen (string); \
} \
\
if ((width -= len) < 0) \
{ \
outstring (string, len); \
break; \
} \
\
if (!left) \
PAD (L' '); \
outstring (string, len); \
if (left) \
PAD (L' '); \
if (__builtin_expect (string_malloced, 0)) \
free (string); \
} \
break;
#else
# define process_string_arg(fspec) \
LABEL (form_character): \
/* Character. */ \
if (is_long) \
goto LABEL (form_wcharacter); \
--width; /* Account for the character itself. */ \
if (!left) \
PAD (' '); \
if (fspec == NULL) \
outchar ((unsigned char) va_arg (ap, int)); /* Promoted. */ \
else \
outchar ((unsigned char) args_value[fspec->data_arg].pa_int); \
if (left) \
PAD (' '); \
break; \
\
LABEL (form_wcharacter): \
{ \
/* Wide character. */ \
char buf[MB_CUR_MAX]; \
mbstate_t mbstate; \
size_t len; \
\
memset (&mbstate, '\0', sizeof (mbstate_t)); \
len = __wcrtomb (buf, (fspec == NULL ? va_arg (ap, wchar_t) \
: args_value[fspec->data_arg].pa_wchar), \
&mbstate); \
if (len == (size_t) -1) \
{ \
/* Something went wron gduring the conversion. Bail out. */ \
done = -1; \
goto all_done; \
} \
width -= len; \
if (!left) \
PAD (' '); \
outstring (buf, len); \
if (left) \
PAD (' '); \
} \
break; \
\
LABEL (form_string): \
{ \
size_t len; \
int string_malloced; \
\
/* The string argument could in fact be `char *' or `wchar_t *'. \
But this should not make a difference here. */ \
if (fspec == NULL) \
string = (char *) va_arg (ap, const char *); \
else \
string = (char *) args_value[fspec->data_arg].pa_string; \
\
/* Entry point for printing other strings. */ \
LABEL (print_string): \
\
string_malloced = 0; \
if (string == NULL) \
{ \
/* Write "(null)" if there's space. */ \
if (prec == -1 || prec >= (int) sizeof (null) - 1) \
{ \
string = (char *) null; \
len = sizeof (null) - 1; \
} \
else \
{ \
string = (char *) ""; \
len = 0; \
} \
} \
else if (!is_long && spec != L_('S')) \
{ \
if (prec != -1) \
{ \
/* Search for the end of the string, but don't search past \
the length (in bytes) specified by the precision. Also \
don't use incomplete characters. */ \
if (_NL_CURRENT_WORD (LC_CTYPE, _NL_CTYPE_MB_CUR_MAX) == 1) \
len = __strnlen (string, prec); \
else \
{ \
/* In case we have a multibyte character set the \
situation is more complicated. We must not copy \
bytes at the end which form an incomplete character. */\
size_t ignore_size = (unsigned) prec > 1024 ? 1024 : prec;\
wchar_t ignore[ignore_size]; \
const char *str2 = string; \
const char *strend = string + prec; \
if (strend < string) \
strend = (const char *) UINTPTR_MAX; \
\
mbstate_t ps; \
memset (&ps, '\0', sizeof (ps)); \
\
while (str2 != NULL && str2 < strend) \
if (__mbsnrtowcs (ignore, &str2, strend - str2, \
ignore_size, &ps) == (size_t) -1) \
{ \
done = -1; \
goto all_done; \
} \
\
if (str2 == NULL) \
len = strlen (string); \
else \
len = str2 - string - (ps.__count & 7); \
} \
} \
else \
len = strlen (string); \
} \
else \
{ \
const wchar_t *s2 = (const wchar_t *) string; \
mbstate_t mbstate; \
\
memset (&mbstate, '\0', sizeof (mbstate_t)); \
\
if (prec >= 0) \
{ \
/* The string `s2' might not be NUL terminated. */ \
if (__libc_use_alloca (prec)) \
string = (char *) alloca (prec); \
else if ((string = (char *) malloc (prec)) == NULL) \
{ \
done = -1; \
goto all_done; \
} \
else \
string_malloced = 1; \
len = __wcsrtombs (string, &s2, prec, &mbstate); \
} \
else \
{ \
len = __wcsrtombs (NULL, &s2, 0, &mbstate); \
if (len != (size_t) -1) \
{ \
assert (__mbsinit (&mbstate)); \
s2 = (const wchar_t *) string; \
if (__libc_use_alloca (len + 1)) \
string = (char *) alloca (len + 1); \
else if ((string = (char *) malloc (len + 1)) == NULL) \
{ \
done = -1; \
goto all_done; \
} \
else \
string_malloced = 1; \
(void) __wcsrtombs (string, &s2, len + 1, &mbstate); \
} \
} \
\
if (len == (size_t) -1) \
{ \
/* Illegal wide-character string. */ \
done = -1; \
goto all_done; \
} \
} \
\
if ((width -= len) < 0) \
{ \
outstring (string, len); \
break; \
} \
\
if (!left) \
PAD (' '); \
outstring (string, len); \
if (left) \
PAD (' '); \
if (__builtin_expect (string_malloced, 0)) \
free (string); \
} \
break;
#endif
/* 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 (UNBUFFERED_P (s))
/* Use a helper function which will allocate a local temporary buffer
for the stream and then call us again. */
return buffered_vfprintf (s, format, ap);
/* Initialize local variables. */
done = 0;
grouping = (const char *) -1;
#ifdef __va_copy
/* This macro will be available soon in gcc's . 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
/* Lock stream. */
_IO_cleanup_region_start ((void (*) (void *)) &_IO_funlockfile, s);
_IO_flockfile (s);
/* Write the literal text before the first format. */
outstring ((const UCHAR_T *) format,
lead_str_end - (const UCHAR_T *) format);
/* If we only have to print a simple string, return now. */
if (*f == L_('\0'))
goto all_done;
/* Use the slow path in case any printf handler is registered. */
if (__builtin_expect (__printf_function_table != NULL
|| __printf_modifier_table != NULL
|| __printf_va_arg_table != NULL, 0))
goto do_positional;
/* Process whole format string. */
do
{
#ifdef SHARED
# define REF(Name) &&do_##Name - &&do_form_unknown
#else
# define REF(Name) &&do_##Name
#endif
#define LABEL(Name) do_##Name
STEP0_3_TABLE;
STEP4_TABLE;
union printf_arg *args_value; /* This is not used here but ... */
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. */
int is_long_double = 0; /* Argument is long double/ long long int. */
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;
workstart = NULL;
workend = &work_buffer[sizeof (work_buffer) / sizeof (CHAR_T)];
/* 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) && read_int (&tmp) && *tmp == L_('$'))
/* The width comes from a positional parameter. */
goto do_positional;
width = va_arg (ap, int);
/* Negative width means left justified. */
if (width < 0)
{
width = -width;
pad = L_(' ');
left = 1;
}
if (__builtin_expect (width >= (size_t) -1 / sizeof (CHAR_T) - 32, 0))
{
__set_errno (ERANGE);
done = -1;
goto all_done;
}
if (width >= sizeof (work_buffer) / sizeof (work_buffer[0]) - 32)
{
/* We have to use a special buffer. The "32" is just a safe
bet for all the output which is not counted in the width. */
size_t needed = ((size_t) width + 32) * sizeof (CHAR_T);
if (__libc_use_alloca (needed))
workend = (CHAR_T *) alloca (needed) + width + 32;
else
{
workstart = (CHAR_T *) malloc (needed);
if (workstart == NULL)
{
done = -1;
goto all_done;
}
workend = workstart + width + 32;
}
}
}
JUMP (*f, step1_jumps);
/* Given width in format string. */
LABEL (width):
width = read_int (&f);
if (__builtin_expect (width >= (size_t) -1 / sizeof (CHAR_T) - 32, 0))
{
__set_errno (ERANGE);
done = -1;
goto all_done;
}
if (width >= sizeof (work_buffer) / sizeof (work_buffer[0]) - 32)
{
/* We have to use a special buffer. The "32" is just a safe
bet for all the output which is not counted in the width. */
size_t needed = ((size_t) width + 32) * sizeof (CHAR_T);
if (__libc_use_alloca (needed))
workend = (CHAR_T *) alloca (needed) + width + 32;
else
{
workstart = (CHAR_T *) malloc (needed);
if (workstart == NULL)
{
done = -1;
goto all_done;
}
workend = workstart + width + 32;
}
}
if (*f == L_('$'))
/* 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) && read_int (&tmp) > 0 && *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);
else
prec = 0;
if (prec > width
&& prec > sizeof (work_buffer) / sizeof (work_buffer[0]) - 32)
{
if (__builtin_expect (prec >= (size_t) -1 / sizeof (CHAR_T) - 32, 0))
{
__set_errno (ERANGE);
done = -1;
goto all_done;
}
size_t needed = ((size_t) prec + 32) * sizeof (CHAR_T);
if (__libc_use_alloca (needed))
workend = (CHAR_T *) alloca (needed) + prec + 32;
else
{
workstart = (CHAR_T *) malloc (needed);
if (workstart == NULL)
{
done = -1;
goto all_done;
}
workend = workstart + prec + 32;
}
}
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 current format. */
while (1)
{
process_arg (((struct printf_spec *) NULL));
process_string_arg (((struct printf_spec *) NULL));
LABEL (form_unknown):
if (spec == L_('\0'))
{
/* The format string ended before the specifier is complete. */
done = -1;
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;
if (__builtin_expect (workstart != NULL, 0))
free (workstart);
workstart = NULL;
/* 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. */
outstring (end_of_spec, f - end_of_spec);
}
while (*f != L_('\0'));
/* Unlock stream and return. */
goto all_done;
/* Here starts the more complex loop to handle positional parameters. */
do_positional:
{
/* Array with information about the needed arguments. This has to
be dynamically extensible. */
size_t nspecs = 0;
/* A more or less arbitrary start value. */
size_t nspecs_size = 32 * sizeof (struct printf_spec);
struct printf_spec *specs = alloca (nspecs_size);
/* 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;
size_t bytes_per_arg;
union printf_arg *args_value;
int *args_size;
int *args_type;
/* 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;
free (workstart);
workstart = NULL;
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 (f = lead_str_end; *f != L_('\0'); f = specs[nspecs++].next_fmt)
{
if (nspecs * sizeof (*specs) >= nspecs_size)
{
/* Extend the array of format specifiers. */
struct printf_spec *old = specs;
specs = extend_alloca (specs, nspecs_size, 2 * nspecs_size);
/* Copy the old array's elements to the new space. */
memmove (specs, old, nspecs * sizeof (*specs));
}
/* Parse the format specifier. */
#ifdef COMPILE_WPRINTF
nargs += __parse_one_specwc (f, nargs, &specs[nspecs], &max_ref_arg);
#else
nargs += __parse_one_specmb (f, nargs, &specs[nspecs], &max_ref_arg);
#endif
}
/* Determine the number of arguments the format string consumes. */
nargs = MAX (nargs, max_ref_arg);
/* Calculate total size needed to represent a single argument across
all three argument-related arrays. */
bytes_per_arg = sizeof (*args_value) + sizeof (*args_size)
+ sizeof (*args_type);
/* Check for potential integer overflow. */
if (__builtin_expect (nargs > SIZE_MAX / bytes_per_arg, 0))
{
__set_errno (ERANGE);
done = -1;
goto all_done;
}
/* Allocate memory for all three argument arrays. */
if (__libc_use_alloca (nargs * bytes_per_arg))
args_value = alloca (nargs * bytes_per_arg);
else
{
args_value = args_malloced = malloc (nargs * bytes_per_arg);
if (args_value == NULL)
{
done = -1;
goto all_done;
}
}
/* 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, s->_flags2 & _IO_FLAGS2_FORTIFY ? '\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_save, 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 (__ldbl_is_dbl)
{
args_value[cnt].pa_double = va_arg (ap_save, double);
args_type[cnt] &= ~PA_FLAG_LONG_DOUBLE;
}
else
args_value[cnt].pa_long_double = va_arg (ap_save, 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_save, void *);
else if (__builtin_expect (__printf_va_arg_table != NULL, 0)
&& __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_save);
}
else
args_value[cnt].pa_long_double = 0.0;
break;
case -1:
/* Error case. Not all parameters appear in N$ format
strings. We have no way to determine their type. */
assert (s->_flags2 & _IO_FLAGS2_FORTIFY);
__libc_fatal ("*** invalid %N$ use detected ***\n");
}
/* Now walk through all format specifiers and process them. */
for (; (size_t) nspecs_done < nspecs; ++nspecs_done)
{
#undef REF
#ifdef SHARED
# define REF(Name) &&do2_##Name - &&do_form_unknown
#else
# define REF(Name) &&do2_##Name
#endif
#undef LABEL
#define LABEL(Name) do2_##Name
STEP4_TABLE;
int is_negative;
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. */
/* 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 = 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;
workstart = NULL;
workend = &work_buffer[sizeof (work_buffer) / sizeof (CHAR_T)];
/* 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;
}
/* Maybe the buffer is too small. */
if (MAX (prec, width) + 32 > (int) (sizeof (work_buffer)
/ sizeof (CHAR_T)))
{
if (__libc_use_alloca ((MAX (prec, width) + 32)
* sizeof (CHAR_T)))
workend = ((CHAR_T *) alloca ((MAX (prec, width) + 32)
* sizeof (CHAR_T))
+ (MAX (prec, width) + 32));
else
{
workstart = (CHAR_T *) malloc ((MAX (prec, width) + 32)
* sizeof (CHAR_T));
workend = workstart + (MAX (prec, width) + 32);
}
}
/* Process format specifiers. */
while (1)
{
extern printf_function **__printf_function_table;
int function_done;
if (spec <= UCHAR_MAX
&& __printf_function_table != NULL
&& __printf_function_table[(size_t) spec] != NULL)
{
const void **ptr = alloca (specs[nspecs_done].ndata_args
* sizeof (const void *));
/* Fill in an array of pointers to the argument values. */
for (unsigned int i = 0; i < specs[nspecs_done].ndata_args;
++i)
ptr[i] = &args_value[specs[nspecs_done].data_arg + i];
/* Call the function. */
function_done = __printf_function_table[(size_t) spec]
(s, &specs[nspecs_done].info, ptr);
if (function_done != -2)
{
/* If an error occurred we don't have information
about # of chars. */
if (function_done < 0)
{
done = -1;
goto all_done;
}
done_add (function_done);
break;
}
}
JUMP (spec, step4_jumps);
process_arg ((&specs[nspecs_done]));
process_string_arg ((&specs[nspecs_done]));
LABEL (form_unknown):
{
unsigned int i;
const void **ptr;
ptr = alloca (specs[nspecs_done].ndata_args
* sizeof (const void *));
/* Fill in an array of pointers to the argument values. */
for (i = 0; i < specs[nspecs_done].ndata_args; ++i)
ptr[i] = &args_value[specs[nspecs_done].data_arg + i];
/* Call the function. */
function_done = printf_unknown (s, &specs[nspecs_done].info,
ptr);
/* If an error occurred we don't have information about #
of chars. */
if (function_done < 0)
{
done = -1;
goto all_done;
}
done_add (function_done);
}
break;
}
free (workstart);
workstart = NULL;
/* Write the following constant string. */
outstring (specs[nspecs_done].end_of_fmt,
specs[nspecs_done].next_fmt
- specs[nspecs_done].end_of_fmt);
}
}
all_done:
free (args_malloced);
free (workstart);
/* Unlock the stream. */
_IO_funlockfile (s);
_IO_cleanup_region_end (0);
return done;
}
/* Handle an unknown format specifier. This prints out a canonicalized
representation of the format spec itself. */
static int
printf_unknown (FILE *s, const struct printf_info *info,
const void *const *args)
{
int done = 0;
CHAR_T work_buffer[MAX (sizeof (info->width), sizeof (info->prec)) * 3];
CHAR_T *const workend
= &work_buffer[sizeof (work_buffer) / sizeof (CHAR_T)];
register CHAR_T *w;
outchar (L_('%'));
if (info->alt)
outchar (L_('#'));
if (info->group)
outchar (L_('\''));
if (info->showsign)
outchar (L_('+'));
else if (info->space)
outchar (L_(' '));
if (info->left)
outchar (L_('-'));
if (info->pad == L_('0'))
outchar (L_('0'));
if (info->i18n)
outchar (L_('I'));
if (info->width != 0)
{
w = _itoa_word (info->width, workend, 10, 0);
while (w < workend)
outchar (*w++);
}
if (info->prec != -1)
{
outchar (L_('.'));
w = _itoa_word (info->prec, workend, 10, 0);
while (w < workend)
outchar (*w++);
}
if (info->spec != L_('\0'))
outchar (info->spec);
all_done:
return done;
}
/* Group the digits according to the grouping rules of the current locale.
The interpretation of GROUPING is as in `struct lconv' from . */
static CHAR_T *
internal_function
group_number (CHAR_T *w, CHAR_T *rear_ptr, const char *grouping,
#ifdef COMPILE_WPRINTF
wchar_t thousands_sep
#else
const char *thousands_sep
#endif
)
{
int len;
CHAR_T *src, *s;
#ifndef COMPILE_WPRINTF
int tlen = strlen (thousands_sep);
#endif
/* We treat all negative values like CHAR_MAX. */
if (*grouping == CHAR_MAX || *grouping <= 0)
/* No grouping should be done. */
return w;
len = *grouping++;
/* Copy existing string so that nothing gets overwritten. */
src = (CHAR_T *) alloca ((rear_ptr - w) * sizeof (CHAR_T));
s = (CHAR_T *) __mempcpy (src, w,
(rear_ptr - w) * sizeof (CHAR_T));
w = rear_ptr;
/* Process all characters in the string. */
while (s > src)
{
*--w = *--s;
if (--len == 0 && s > src)
{
/* A new group begins. */
#ifdef COMPILE_WPRINTF
*--w = thousands_sep;
#else
int cnt = tlen;
do
*--w = thousands_sep[--cnt];
while (cnt > 0);
#endif
if (*grouping == CHAR_MAX
#if CHAR_MIN < 0
|| *grouping < 0
#endif
)
{
/* No further grouping to be done.
Copy the rest of the number. */
do
*--w = *--s;
while (s > src);
break;
}
else if (*grouping != '\0')
/* The previous grouping repeats ad infinitum. */
len = *grouping++;
else
len = grouping[-1];
}
}
return w;
}
/* Helper "class" for `fprintf to unbuffered': creates a temporary buffer. */
struct helper_file
{
struct _IO_FILE_plus _f;
#ifdef COMPILE_WPRINTF
struct _IO_wide_data _wide_data;
#endif
_IO_FILE *_put_stream;
#ifdef _IO_MTSAFE_IO
_IO_lock_t lock;
#endif
};
static int
_IO_helper_overflow (_IO_FILE *s, int c)
{
_IO_FILE *target = ((struct helper_file*) s)->_put_stream;
#ifdef COMPILE_WPRINTF
int used = s->_wide_data->_IO_write_ptr - s->_wide_data->_IO_write_base;
if (used)
{
_IO_size_t written = _IO_sputn (target, s->_wide_data->_IO_write_base,
used);
if (written == 0 || written == WEOF)
return WEOF;
__wmemmove (s->_wide_data->_IO_write_base,
s->_wide_data->_IO_write_base + written,
used - written);
s->_wide_data->_IO_write_ptr -= written;
}
#else
int used = s->_IO_write_ptr - s->_IO_write_base;
if (used)
{
_IO_size_t written = _IO_sputn (target, s->_IO_write_base, used);
if (written == 0 || written == EOF)
return EOF;
memmove (s->_IO_write_base, s->_IO_write_base + written,
used - written);
s->_IO_write_ptr -= written;
}
#endif
return PUTC (c, s);
}
#ifdef COMPILE_WPRINTF
static const struct _IO_jump_t _IO_helper_jumps =
{
JUMP_INIT_DUMMY,
JUMP_INIT (finish, INTUSE(_IO_wdefault_finish)),
JUMP_INIT (overflow, _IO_helper_overflow),
JUMP_INIT (underflow, _IO_default_underflow),
JUMP_INIT (uflow, INTUSE(_IO_default_uflow)),
JUMP_INIT (pbackfail, (_IO_pbackfail_t) INTUSE(_IO_wdefault_pbackfail)),
JUMP_INIT (xsputn, INTUSE(_IO_wdefault_xsputn)),
JUMP_INIT (xsgetn, INTUSE(_IO_wdefault_xsgetn)),
JUMP_INIT (seekoff, _IO_default_seekoff),
JUMP_INIT (seekpos, _IO_default_seekpos),
JUMP_INIT (setbuf, _IO_default_setbuf),
JUMP_INIT (sync, _IO_default_sync),
JUMP_INIT (doallocate, INTUSE(_IO_wdefault_doallocate)),
JUMP_INIT (read, _IO_default_read),
JUMP_INIT (write, _IO_default_write),
JUMP_INIT (seek, _IO_default_seek),
JUMP_INIT (close, _IO_default_close),
JUMP_INIT (stat, _IO_default_stat)
};
#else
static const struct _IO_jump_t _IO_helper_jumps =
{
JUMP_INIT_DUMMY,
JUMP_INIT (finish, INTUSE(_IO_default_finish)),
JUMP_INIT (overflow, _IO_helper_overflow),
JUMP_INIT (underflow, _IO_default_underflow),
JUMP_INIT (uflow, INTUSE(_IO_default_uflow)),
JUMP_INIT (pbackfail, INTUSE(_IO_default_pbackfail)),
JUMP_INIT (xsputn, INTUSE(_IO_default_xsputn)),
JUMP_INIT (xsgetn, INTUSE(_IO_default_xsgetn)),
JUMP_INIT (seekoff, _IO_default_seekoff),
JUMP_INIT (seekpos, _IO_default_seekpos),
JUMP_INIT (setbuf, _IO_default_setbuf),
JUMP_INIT (sync, _IO_default_sync),
JUMP_INIT (doallocate, INTUSE(_IO_default_doallocate)),
JUMP_INIT (read, _IO_default_read),
JUMP_INIT (write, _IO_default_write),
JUMP_INIT (seek, _IO_default_seek),
JUMP_INIT (close, _IO_default_close),
JUMP_INIT (stat, _IO_default_stat)
};
#endif
static int
internal_function
buffered_vfprintf (register _IO_FILE *s, const CHAR_T *format,
_IO_va_list args)
{
CHAR_T buf[_IO_BUFSIZ];
struct helper_file helper;
register _IO_FILE *hp = (_IO_FILE *) &helper._f;
int result, to_flush;
/* Orient the stream. */
#ifdef ORIENT
ORIENT;
#endif
/* Initialize helper. */
helper._put_stream = s;
#ifdef COMPILE_WPRINTF
hp->_wide_data = &helper._wide_data;
_IO_wsetp (hp, buf, buf + sizeof buf / sizeof (CHAR_T));
hp->_mode = 1;
#else
_IO_setp (hp, buf, buf + sizeof buf);
hp->_mode = -1;
#endif
hp->_IO_file_flags = _IO_MAGIC|_IO_NO_READS|_IO_USER_LOCK;
#if _IO_JUMPS_OFFSET
hp->_vtable_offset = 0;
#endif
#ifdef _IO_MTSAFE_IO
hp->_lock = NULL;
#endif
hp->_flags2 = s->_flags2;
_IO_JUMPS (&helper._f) = (struct _IO_jump_t *) &_IO_helper_jumps;
/* Now print to helper instead. */
#ifndef COMPILE_WPRINTF
result = INTUSE(_IO_vfprintf) (hp, format, args);
#else
result = vfprintf (hp, format, args);
#endif
/* Lock stream. */
__libc_cleanup_region_start (1, (void (*) (void *)) &_IO_funlockfile, s);
_IO_flockfile (s);
/* Now flush anything from the helper to the S. */
#ifdef COMPILE_WPRINTF
if ((to_flush = (hp->_wide_data->_IO_write_ptr
- hp->_wide_data->_IO_write_base)) > 0)
{
if ((int) _IO_sputn (s, hp->_wide_data->_IO_write_base, to_flush)
!= to_flush)
result = -1;
}
#else
if ((to_flush = hp->_IO_write_ptr - hp->_IO_write_base) > 0)
{
if ((int) _IO_sputn (s, hp->_IO_write_base, to_flush) != to_flush)
result = -1;
}
#endif
/* Unlock the stream. */
_IO_funlockfile (s);
__libc_cleanup_region_end (0);
return result;
}
#undef vfprintf
#ifdef COMPILE_WPRINTF
strong_alias (_IO_vfwprintf, __vfwprintf);
ldbl_weak_alias (_IO_vfwprintf, vfwprintf);
#else
ldbl_strong_alias (_IO_vfprintf_internal, vfprintf);
ldbl_hidden_def (_IO_vfprintf_internal, vfprintf)
ldbl_strong_alias (_IO_vfprintf_internal, _IO_vfprintf);
#endif