freebsd-skq/contrib/gcc/c-format.c

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/* Check calls to formatted I/O functions (-Wformat).
Copyright (C) 1992, 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000,
2001, 2002, 2003 Free Software Foundation, Inc.
This file is part of GCC.
GCC is free software; you can redistribute it and/or modify it under
the terms of the GNU General Public License as published by the Free
Software Foundation; either version 2, or (at your option) any later
version.
GCC is distributed in the hope that it will be useful, but WITHOUT ANY
WARRANTY; without even the implied warranty of MERCHANTABILITY or
FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
for more details.
You should have received a copy of the GNU General Public License
along with GCC; see the file COPYING. If not, write to the Free
Software Foundation, 59 Temple Place - Suite 330, Boston, MA
02111-1307, USA. */
/* $FreeBSD$ */
#include "config.h"
#include "system.h"
#include "coretypes.h"
#include "tm.h"
#include "tree.h"
#include "flags.h"
#include "toplev.h"
#include "c-common.h"
#include "intl.h"
#include "diagnostic.h"
#include "langhooks.h"
/* Set format warning options according to a -Wformat=n option. */
void
set_Wformat (int setting)
{
warn_format = setting;
warn_format_extra_args = setting;
warn_format_zero_length = setting;
if (setting != 1)
{
warn_format_nonliteral = setting;
warn_format_security = setting;
warn_format_y2k = setting;
}
/* Make sure not to disable -Wnonnull if -Wformat=0 is specified. */
if (setting)
warn_nonnull = setting;
}
/* Handle attributes associated with format checking. */
/* This must be in the same order as format_types, with format_type_error
last. */
enum format_type { printf_format_type, asm_fprintf_format_type,
gcc_diag_format_type, gcc_cdiag_format_type,
gcc_cxxdiag_format_type,
scanf_format_type, strftime_format_type,
strfmon_format_type, rintf0_format_type,
format_type_error };
typedef struct function_format_info
{
enum format_type format_type; /* type of format (printf, scanf, etc.) */
unsigned HOST_WIDE_INT format_num; /* number of format argument */
unsigned HOST_WIDE_INT first_arg_num; /* number of first arg (zero for varargs) */
} function_format_info;
static bool decode_format_attr (tree, function_format_info *, int);
static enum format_type decode_format_type (const char *);
static bool check_format_string (tree argument,
unsigned HOST_WIDE_INT format_num,
int flags, bool *no_add_attrs);
static bool get_constant (tree expr, unsigned HOST_WIDE_INT *value,
int validated_p);
/* Handle a "format_arg" attribute; arguments as in
struct attribute_spec.handler. */
tree
handle_format_arg_attribute (tree *node, tree name ATTRIBUTE_UNUSED,
tree args, int flags, bool *no_add_attrs)
{
tree type = *node;
tree format_num_expr = TREE_VALUE (args);
unsigned HOST_WIDE_INT format_num;
tree argument;
if (!get_constant (format_num_expr, &format_num, 0))
{
error ("format string has invalid operand number");
*no_add_attrs = true;
return NULL_TREE;
}
argument = TYPE_ARG_TYPES (type);
if (argument)
{
if (!check_format_string (argument, format_num, flags, no_add_attrs))
return NULL_TREE;
}
if (TREE_CODE (TREE_TYPE (type)) != POINTER_TYPE
|| (TYPE_MAIN_VARIANT (TREE_TYPE (TREE_TYPE (type)))
!= char_type_node))
{
if (!(flags & (int) ATTR_FLAG_BUILT_IN))
error ("function does not return string type");
*no_add_attrs = true;
return NULL_TREE;
}
return NULL_TREE;
}
/* Verify that the format_num argument is actually a string, in case
the format attribute is in error. */
static bool
check_format_string (tree argument, unsigned HOST_WIDE_INT format_num,
int flags, bool *no_add_attrs)
{
unsigned HOST_WIDE_INT i;
for (i = 1; i != format_num; i++)
{
if (argument == 0)
break;
argument = TREE_CHAIN (argument);
}
if (!argument
|| TREE_CODE (TREE_VALUE (argument)) != POINTER_TYPE
|| (TYPE_MAIN_VARIANT (TREE_TYPE (TREE_VALUE (argument)))
!= char_type_node))
{
if (!(flags & (int) ATTR_FLAG_BUILT_IN))
error ("format string arg not a string type");
*no_add_attrs = true;
return false;
}
return true;
}
/* Strip any conversions from the expression, verify it is a constant,
and store its value. If validated_p is true, abort on errors.
Returns true on success, false otherwise. */
static bool
get_constant(tree expr, unsigned HOST_WIDE_INT *value, int validated_p)
{
while (TREE_CODE (expr) == NOP_EXPR
|| TREE_CODE (expr) == CONVERT_EXPR
|| TREE_CODE (expr) == NON_LVALUE_EXPR)
expr = TREE_OPERAND (expr, 0);
if (TREE_CODE (expr) != INTEGER_CST || TREE_INT_CST_HIGH (expr) != 0)
{
if (validated_p)
abort ();
return false;
}
*value = TREE_INT_CST_LOW (expr);
return true;
}
/* Decode the arguments to a "format" attribute into a function_format_info
structure. It is already known that the list is of the right length.
If VALIDATED_P is true, then these attributes have already been validated
and this function will abort if they are erroneous; if false, it
will give an error message. Returns true if the attributes are
successfully decoded, false otherwise. */
static bool
decode_format_attr (tree args, function_format_info *info, int validated_p)
{
tree format_type_id = TREE_VALUE (args);
tree format_num_expr = TREE_VALUE (TREE_CHAIN (args));
tree first_arg_num_expr
= TREE_VALUE (TREE_CHAIN (TREE_CHAIN (args)));
if (TREE_CODE (format_type_id) != IDENTIFIER_NODE)
{
if (validated_p)
abort ();
error("%Junrecognized format specifier", getdecls());
return false;
}
else
{
const char *p = IDENTIFIER_POINTER (format_type_id);
info->format_type = decode_format_type (p);
if (info->format_type == format_type_error)
{
if (validated_p)
abort ();
warning ("`%s' is an unrecognized format function type", p);
return false;
}
}
if (!get_constant (format_num_expr, &info->format_num, validated_p))
{
error ("format string has invalid operand number");
return false;
}
if (!get_constant (first_arg_num_expr, &info->first_arg_num, validated_p))
{
error ("'...' has invalid operand number");
return false;
}
if (info->first_arg_num != 0 && info->first_arg_num <= info->format_num)
{
if (validated_p)
abort ();
error ("format string arg follows the args to be formatted");
return false;
}
return true;
}
/* Check a call to a format function against a parameter list. */
/* The meaningfully distinct length modifiers for format checking recognized
by GCC. */
enum format_lengths
{
FMT_LEN_none,
FMT_LEN_hh,
FMT_LEN_h,
FMT_LEN_l,
FMT_LEN_ll,
FMT_LEN_L,
FMT_LEN_z,
FMT_LEN_t,
FMT_LEN_j,
FMT_LEN_MAX
};
/* The standard versions in which various format features appeared. */
enum format_std_version
{
STD_C89,
STD_C94,
STD_C9L, /* C99, but treat as C89 if -Wno-long-long. */
STD_C99,
STD_EXT
};
/* The C standard version C++ is treated as equivalent to
or inheriting from, for the purpose of format features supported. */
#define CPLUSPLUS_STD_VER STD_C94
/* The C standard version we are checking formats against when pedantic. */
#define C_STD_VER ((int)(c_dialect_cxx () \
? CPLUSPLUS_STD_VER \
: (flag_isoc99 \
? STD_C99 \
: (flag_isoc94 ? STD_C94 : STD_C89))))
/* The name to give to the standard version we are warning about when
pedantic. FEATURE_VER is the version in which the feature warned out
appeared, which is higher than C_STD_VER. */
#define C_STD_NAME(FEATURE_VER) (c_dialect_cxx () \
? "ISO C++" \
: ((FEATURE_VER) == STD_EXT \
? "ISO C" \
: "ISO C90"))
/* Adjust a C standard version, which may be STD_C9L, to account for
-Wno-long-long. Returns other standard versions unchanged. */
#define ADJ_STD(VER) ((int)((VER) == STD_C9L \
? (warn_long_long ? STD_C99 : STD_C89) \
: (VER)))
/* Flags that may apply to a particular kind of format checked by GCC. */
enum
{
/* This format converts arguments of types determined by the
format string. */
FMT_FLAG_ARG_CONVERT = 1,
/* The scanf allocation 'a' kludge applies to this format kind. */
FMT_FLAG_SCANF_A_KLUDGE = 2,
/* A % during parsing a specifier is allowed to be a modified % rather
that indicating the format is broken and we are out-of-sync. */
FMT_FLAG_FANCY_PERCENT_OK = 4,
/* With $ operand numbers, it is OK to reference the same argument more
than once. */
FMT_FLAG_DOLLAR_MULTIPLE = 8,
/* This format type uses $ operand numbers (strfmon doesn't). */
FMT_FLAG_USE_DOLLAR = 16,
/* Zero width is bad in this type of format (scanf). */
FMT_FLAG_ZERO_WIDTH_BAD = 32,
/* Empty precision specification is OK in this type of format (printf). */
FMT_FLAG_EMPTY_PREC_OK = 64,
/* Gaps are allowed in the arguments with $ operand numbers if all
arguments are pointers (scanf). */
FMT_FLAG_DOLLAR_GAP_POINTER_OK = 128
/* Not included here: details of whether width or precision may occur
(controlled by width_char and precision_char); details of whether
'*' can be used for these (width_type and precision_type); details
of whether length modifiers can occur (length_char_specs). */
};
/* Structure describing a length modifier supported in format checking, and
possibly a doubled version such as "hh". */
typedef struct
{
/* Name of the single-character length modifier. */
const char *name;
/* Index into a format_char_info.types array. */
enum format_lengths index;
/* Standard version this length appears in. */
enum format_std_version std;
/* Same, if the modifier can be repeated, or NULL if it can't. */
const char *double_name;
enum format_lengths double_index;
enum format_std_version double_std;
} format_length_info;
/* Structure describing the combination of a conversion specifier
(or a set of specifiers which act identically) and a length modifier. */
typedef struct
{
/* The standard version this combination of length and type appeared in.
This is only relevant if greater than those for length and type
individually; otherwise it is ignored. */
enum format_std_version std;
/* The name to use for the type, if different from that generated internally
(e.g., "signed size_t"). */
const char *name;
/* The type itself. */
tree *type;
} format_type_detail;
/* Macros to fill out tables of these. */
#define NOARGUMENTS { T89_V, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }
#define BADLEN { 0, NULL, NULL }
#define NOLENGTHS { BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }
/* Structure describing a format conversion specifier (or a set of specifiers
which act identically), and the length modifiers used with it. */
typedef struct
{
const char *format_chars;
int pointer_count;
enum format_std_version std;
/* Types accepted for each length modifier. */
format_type_detail types[FMT_LEN_MAX];
/* List of other modifier characters allowed with these specifiers.
This lists flags, and additionally "w" for width, "p" for precision
(right precision, for strfmon), "#" for left precision (strfmon),
"a" for scanf "a" allocation extension (not applicable in C99 mode),
"*" for scanf suppression, and "E" and "O" for those strftime
modifiers. */
const char *flag_chars;
/* List of additional flags describing these conversion specifiers.
"c" for generic character pointers being allowed, "2" for strftime
two digit year formats, "3" for strftime formats giving two digit
years in some locales, "4" for "2" which becomes "3" with an "E" modifier,
"o" if use of strftime "O" is a GNU extension beyond C99,
"W" if the argument is a pointer which is dereferenced and written into,
"R" if the argument is a pointer which is dereferenced and read from,
"i" for printf integer formats where the '0' flag is ignored with
precision, and "[" for the starting character of a scanf scanset. */
const char *flags2;
} format_char_info;
/* Structure describing a flag accepted by some kind of format. */
typedef struct
{
/* The flag character in question (0 for end of array). */
int flag_char;
/* Zero if this entry describes the flag character in general, or a
nonzero character that may be found in flags2 if it describes the
flag when used with certain formats only. If the latter, only
the first such entry found that applies to the current conversion
specifier is used; the values of `name' and `long_name' it supplies
will be used, if non-NULL and the standard version is higher than
the unpredicated one, for any pedantic warning. For example, 'o'
for strftime formats (meaning 'O' is an extension over C99). */
int predicate;
/* Nonzero if the next character after this flag in the format should
be skipped ('=' in strfmon), zero otherwise. */
int skip_next_char;
/* The name to use for this flag in diagnostic messages. For example,
N_("`0' flag"), N_("field width"). */
const char *name;
/* Long name for this flag in diagnostic messages; currently only used for
"ISO C does not support ...". For example, N_("the `I' printf flag"). */
const char *long_name;
/* The standard version in which it appeared. */
enum format_std_version std;
} format_flag_spec;
/* Structure describing a combination of flags that is bad for some kind
of format. */
typedef struct
{
/* The first flag character in question (0 for end of array). */
int flag_char1;
/* The second flag character. */
int flag_char2;
/* Nonzero if the message should say that the first flag is ignored with
the second, zero if the combination should simply be objected to. */
int ignored;
/* Zero if this entry applies whenever this flag combination occurs,
a nonzero character from flags2 if it only applies in some
circumstances (e.g. 'i' for printf formats ignoring 0 with precision). */
int predicate;
} format_flag_pair;
/* Structure describing a particular kind of format processed by GCC. */
typedef struct
{
/* The name of this kind of format, for use in diagnostics. Also
the name of the attribute (without preceding and following __). */
const char *name;
/* Specifications of the length modifiers accepted; possibly NULL. */
const format_length_info *length_char_specs;
/* Details of the conversion specification characters accepted. */
const format_char_info *conversion_specs;
/* String listing the flag characters that are accepted. */
const char *flag_chars;
/* String listing modifier characters (strftime) accepted. May be NULL. */
const char *modifier_chars;
/* Details of the flag characters, including pseudo-flags. */
const format_flag_spec *flag_specs;
/* Details of bad combinations of flags. */
const format_flag_pair *bad_flag_pairs;
/* Flags applicable to this kind of format. */
int flags;
/* Flag character to treat a width as, or 0 if width not used. */
int width_char;
/* Flag character to treat a left precision (strfmon) as,
or 0 if left precision not used. */
int left_precision_char;
/* Flag character to treat a precision (for strfmon, right precision) as,
or 0 if precision not used. */
int precision_char;
/* If a flag character has the effect of suppressing the conversion of
an argument ('*' in scanf), that flag character, otherwise 0. */
int suppression_char;
/* Flag character to treat a length modifier as (ignored if length
modifiers not used). Need not be placed in flag_chars for conversion
specifiers, but is used to check for bad combinations such as length
modifier with assignment suppression in scanf. */
int length_code_char;
/* Pointer to type of argument expected if '*' is used for a width,
or NULL if '*' not used for widths. */
tree *width_type;
/* Pointer to type of argument expected if '*' is used for a precision,
or NULL if '*' not used for precisions. */
tree *precision_type;
const int null_format_ok;
} format_kind_info;
/* Structure describing details of a type expected in format checking,
and the type to check against it. */
typedef struct format_wanted_type
{
/* The type wanted. */
tree wanted_type;
/* The name of this type to use in diagnostics. */
const char *wanted_type_name;
/* The level of indirection through pointers at which this type occurs. */
int pointer_count;
/* Whether, when pointer_count is 1, to allow any character type when
pedantic, rather than just the character or void type specified. */
int char_lenient_flag;
/* Whether the argument, dereferenced once, is written into and so the
argument must not be a pointer to a const-qualified type. */
int writing_in_flag;
/* Whether the argument, dereferenced once, is read from and so
must not be a NULL pointer. */
int reading_from_flag;
/* If warnings should be of the form "field precision is not type int",
the name to use (in this case "field precision"), otherwise NULL,
for "%s format, %s arg" type messages. If (in an extension), this
is a pointer type, wanted_type_name should be set to include the
terminating '*' characters of the type name to give a correct
message. */
const char *name;
/* The actual parameter to check against the wanted type. */
tree param;
/* The argument number of that parameter. */
int arg_num;
/* The next type to check for this format conversion, or NULL if none. */
struct format_wanted_type *next;
} format_wanted_type;
static const format_length_info printf_length_specs[] =
{
{ "h", FMT_LEN_h, STD_C89, "hh", FMT_LEN_hh, STD_C99 },
{ "l", FMT_LEN_l, STD_C89, "ll", FMT_LEN_ll, STD_C9L },
{ "q", FMT_LEN_ll, STD_EXT, NULL, 0, 0 },
{ "L", FMT_LEN_L, STD_C89, NULL, 0, 0 },
{ "z", FMT_LEN_z, STD_C99, NULL, 0, 0 },
{ "Z", FMT_LEN_z, STD_EXT, NULL, 0, 0 },
{ "t", FMT_LEN_t, STD_C99, NULL, 0, 0 },
{ "j", FMT_LEN_j, STD_C99, NULL, 0, 0 },
{ NULL, 0, 0, NULL, 0, 0 }
};
/* Length specifiers valid for asm_fprintf. */
static const format_length_info asm_fprintf_length_specs[] =
{
{ "l", FMT_LEN_l, STD_C89, "ll", FMT_LEN_ll, STD_C89 },
{ "w", FMT_LEN_none, STD_C89, NULL, 0, 0 },
{ NULL, 0, 0, NULL, 0, 0 }
};
/* Length specifiers valid for GCC diagnostics. */
static const format_length_info gcc_diag_length_specs[] =
{
{ "l", FMT_LEN_l, STD_C89, "ll", FMT_LEN_ll, STD_C89 },
{ "w", FMT_LEN_none, STD_C89, NULL, 0, 0 },
{ NULL, 0, 0, NULL, 0, 0 }
};
/* The custom diagnostics all accept the same length specifiers. */
#define gcc_cdiag_length_specs gcc_diag_length_specs
#define gcc_cxxdiag_length_specs gcc_diag_length_specs
/* This differs from printf_length_specs only in that "Z" is not accepted. */
static const format_length_info scanf_length_specs[] =
{
{ "h", FMT_LEN_h, STD_C89, "hh", FMT_LEN_hh, STD_C99 },
{ "l", FMT_LEN_l, STD_C89, "ll", FMT_LEN_ll, STD_C9L },
{ "q", FMT_LEN_ll, STD_EXT, NULL, 0, 0 },
{ "L", FMT_LEN_L, STD_C89, NULL, 0, 0 },
{ "z", FMT_LEN_z, STD_C99, NULL, 0, 0 },
{ "t", FMT_LEN_t, STD_C99, NULL, 0, 0 },
{ "j", FMT_LEN_j, STD_C99, NULL, 0, 0 },
{ NULL, 0, 0, NULL, 0, 0 }
};
/* All tables for strfmon use STD_C89 everywhere, since -pedantic warnings
make no sense for a format type not part of any C standard version. */
static const format_length_info strfmon_length_specs[] =
{
/* A GNU extension. */
{ "L", FMT_LEN_L, STD_C89, NULL, 0, 0 },
{ NULL, 0, 0, NULL, 0, 0 }
};
static const format_flag_spec printf_flag_specs[] =
{
{ ' ', 0, 0, N_("` ' flag"), N_("the ` ' printf flag"), STD_C89 },
{ '+', 0, 0, N_("`+' flag"), N_("the `+' printf flag"), STD_C89 },
{ '#', 0, 0, N_("`#' flag"), N_("the `#' printf flag"), STD_C89 },
{ '0', 0, 0, N_("`0' flag"), N_("the `0' printf flag"), STD_C89 },
{ '-', 0, 0, N_("`-' flag"), N_("the `-' printf flag"), STD_C89 },
{ '\'', 0, 0, N_("`'' flag"), N_("the `'' printf flag"), STD_EXT },
{ 'I', 0, 0, N_("`I' flag"), N_("the `I' printf flag"), STD_EXT },
{ 'w', 0, 0, N_("field width"), N_("field width in printf format"), STD_C89 },
{ 'p', 0, 0, N_("precision"), N_("precision in printf format"), STD_C89 },
{ 'L', 0, 0, N_("length modifier"), N_("length modifier in printf format"), STD_C89 },
{ 0, 0, 0, NULL, NULL, 0 }
};
static const format_flag_pair printf_flag_pairs[] =
{
{ ' ', '+', 1, 0 },
{ '0', '-', 1, 0 },
{ '0', 'p', 1, 'i' },
{ 0, 0, 0, 0 }
};
static const format_flag_spec asm_fprintf_flag_specs[] =
{
{ ' ', 0, 0, N_("` ' flag"), N_("the ` ' printf flag"), STD_C89 },
{ '+', 0, 0, N_("`+' flag"), N_("the `+' printf flag"), STD_C89 },
{ '#', 0, 0, N_("`#' flag"), N_("the `#' printf flag"), STD_C89 },
{ '0', 0, 0, N_("`0' flag"), N_("the `0' printf flag"), STD_C89 },
{ '-', 0, 0, N_("`-' flag"), N_("the `-' printf flag"), STD_C89 },
{ 'w', 0, 0, N_("field width"), N_("field width in printf format"), STD_C89 },
{ 'p', 0, 0, N_("precision"), N_("precision in printf format"), STD_C89 },
{ 'L', 0, 0, N_("length modifier"), N_("length modifier in printf format"), STD_C89 },
{ 0, 0, 0, NULL, NULL, 0 }
};
static const format_flag_pair asm_fprintf_flag_pairs[] =
{
{ ' ', '+', 1, 0 },
{ '0', '-', 1, 0 },
{ '0', 'p', 1, 'i' },
{ 0, 0, 0, 0 }
};
static const format_flag_pair gcc_diag_flag_pairs[] =
{
{ 0, 0, 0, 0 }
};
#define gcc_cdiag_flag_pairs gcc_diag_flag_pairs
#define gcc_cxxdiag_flag_pairs gcc_diag_flag_pairs
static const format_flag_spec gcc_diag_flag_specs[] =
{
{ 'p', 0, 0, N_("precision"), N_("precision in printf format"), STD_C89 },
{ 'L', 0, 0, N_("length modifier"), N_("length modifier in printf format"), STD_C89 },
{ 0, 0, 0, NULL, NULL, 0 }
};
#define gcc_cdiag_flag_specs gcc_diag_flag_specs
static const format_flag_spec gcc_cxxdiag_flag_specs[] =
{
{ '+', 0, 0, N_("`+' flag"), N_("the `+' printf flag"), STD_C89 },
{ '#', 0, 0, N_("`#' flag"), N_("the `#' printf flag"), STD_C89 },
{ 'p', 0, 0, N_("precision"), N_("precision in printf format"), STD_C89 },
{ 'L', 0, 0, N_("length modifier"), N_("length modifier in printf format"), STD_C89 },
{ 0, 0, 0, NULL, NULL, 0 }
};
static const format_flag_spec scanf_flag_specs[] =
{
{ '*', 0, 0, N_("assignment suppression"), N_("the assignment suppression scanf feature"), STD_C89 },
{ 'a', 0, 0, N_("`a' flag"), N_("the `a' scanf flag"), STD_EXT },
{ 'w', 0, 0, N_("field width"), N_("field width in scanf format"), STD_C89 },
{ 'L', 0, 0, N_("length modifier"), N_("length modifier in scanf format"), STD_C89 },
{ '\'', 0, 0, N_("`'' flag"), N_("the `'' scanf flag"), STD_EXT },
{ 'I', 0, 0, N_("`I' flag"), N_("the `I' scanf flag"), STD_EXT },
{ 0, 0, 0, NULL, NULL, 0 }
};
static const format_flag_pair scanf_flag_pairs[] =
{
{ '*', 'L', 0, 0 },
{ 0, 0, 0, 0 }
};
static const format_flag_spec strftime_flag_specs[] =
{
{ '_', 0, 0, N_("`_' flag"), N_("the `_' strftime flag"), STD_EXT },
{ '-', 0, 0, N_("`-' flag"), N_("the `-' strftime flag"), STD_EXT },
{ '0', 0, 0, N_("`0' flag"), N_("the `0' strftime flag"), STD_EXT },
{ '^', 0, 0, N_("`^' flag"), N_("the `^' strftime flag"), STD_EXT },
{ '#', 0, 0, N_("`#' flag"), N_("the `#' strftime flag"), STD_EXT },
{ 'w', 0, 0, N_("field width"), N_("field width in strftime format"), STD_EXT },
{ 'E', 0, 0, N_("`E' modifier"), N_("the `E' strftime modifier"), STD_C99 },
{ 'O', 0, 0, N_("`O' modifier"), N_("the `O' strftime modifier"), STD_C99 },
{ 'O', 'o', 0, NULL, N_("the `O' modifier"), STD_EXT },
{ 0, 0, 0, NULL, NULL, 0 }
};
static const format_flag_pair strftime_flag_pairs[] =
{
{ 'E', 'O', 0, 0 },
{ '_', '-', 0, 0 },
{ '_', '0', 0, 0 },
{ '-', '0', 0, 0 },
{ '^', '#', 0, 0 },
{ 0, 0, 0, 0 }
};
static const format_flag_spec strfmon_flag_specs[] =
{
{ '=', 0, 1, N_("fill character"), N_("fill character in strfmon format"), STD_C89 },
{ '^', 0, 0, N_("`^' flag"), N_("the `^' strfmon flag"), STD_C89 },
{ '+', 0, 0, N_("`+' flag"), N_("the `+' strfmon flag"), STD_C89 },
{ '(', 0, 0, N_("`(' flag"), N_("the `(' strfmon flag"), STD_C89 },
{ '!', 0, 0, N_("`!' flag"), N_("the `!' strfmon flag"), STD_C89 },
{ '-', 0, 0, N_("`-' flag"), N_("the `-' strfmon flag"), STD_C89 },
{ 'w', 0, 0, N_("field width"), N_("field width in strfmon format"), STD_C89 },
{ '#', 0, 0, N_("left precision"), N_("left precision in strfmon format"), STD_C89 },
{ 'p', 0, 0, N_("right precision"), N_("right precision in strfmon format"), STD_C89 },
{ 'L', 0, 0, N_("length modifier"), N_("length modifier in strfmon format"), STD_C89 },
{ 0, 0, 0, NULL, NULL, 0 }
};
static const format_flag_pair strfmon_flag_pairs[] =
{
{ '+', '(', 0, 0 },
{ 0, 0, 0, 0 }
};
#define T_I &integer_type_node
#define T89_I { STD_C89, NULL, T_I }
#define T_L &long_integer_type_node
#define T89_L { STD_C89, NULL, T_L }
#define T_LL &long_long_integer_type_node
#define T9L_LL { STD_C9L, NULL, T_LL }
#define TEX_LL { STD_EXT, NULL, T_LL }
#define T_S &short_integer_type_node
#define T89_S { STD_C89, NULL, T_S }
#define T_UI &unsigned_type_node
#define T89_UI { STD_C89, NULL, T_UI }
#define T_UL &long_unsigned_type_node
#define T89_UL { STD_C89, NULL, T_UL }
#define T_ULL &long_long_unsigned_type_node
#define T9L_ULL { STD_C9L, NULL, T_ULL }
#define TEX_ULL { STD_EXT, NULL, T_ULL }
#define T_US &short_unsigned_type_node
#define T89_US { STD_C89, NULL, T_US }
#define T_F &float_type_node
#define T89_F { STD_C89, NULL, T_F }
#define T99_F { STD_C99, NULL, T_F }
#define T_D &double_type_node
#define T89_D { STD_C89, NULL, T_D }
#define T99_D { STD_C99, NULL, T_D }
#define T_LD &long_double_type_node
#define T89_LD { STD_C89, NULL, T_LD }
#define T99_LD { STD_C99, NULL, T_LD }
#define T_C &char_type_node
#define T89_C { STD_C89, NULL, T_C }
#define T_SC &signed_char_type_node
#define T99_SC { STD_C99, NULL, T_SC }
#define T_UC &unsigned_char_type_node
#define T99_UC { STD_C99, NULL, T_UC }
#define T_V &void_type_node
#define T89_V { STD_C89, NULL, T_V }
#define T_W &wchar_type_node
#define T94_W { STD_C94, "wchar_t", T_W }
#define TEX_W { STD_EXT, "wchar_t", T_W }
#define T_WI &wint_type_node
#define T94_WI { STD_C94, "wint_t", T_WI }
#define TEX_WI { STD_EXT, "wint_t", T_WI }
#define T_ST &size_type_node
#define T99_ST { STD_C99, "size_t", T_ST }
#define T_SST &signed_size_type_node
#define T99_SST { STD_C99, "signed size_t", T_SST }
#define T_PD &ptrdiff_type_node
#define T99_PD { STD_C99, "ptrdiff_t", T_PD }
#define T_UPD &unsigned_ptrdiff_type_node
#define T99_UPD { STD_C99, "unsigned ptrdiff_t", T_UPD }
#define T_IM &intmax_type_node
#define T99_IM { STD_C99, "intmax_t", T_IM }
#define T_UIM &uintmax_type_node
#define T99_UIM { STD_C99, "uintmax_t", T_UIM }
static const format_char_info print_char_table[] =
{
/* C89 conversion specifiers. */
{ "di", 0, STD_C89, { T89_I, T99_SC, T89_S, T89_L, T9L_LL, TEX_LL, T99_SST, T99_PD, T99_IM }, "-wp0 +'I", "i" },
{ "oxX", 0, STD_C89, { T89_UI, T99_UC, T89_US, T89_UL, T9L_ULL, TEX_ULL, T99_ST, T99_UPD, T99_UIM }, "-wp0#", "i" },
{ "u", 0, STD_C89, { T89_UI, T99_UC, T89_US, T89_UL, T9L_ULL, TEX_ULL, T99_ST, T99_UPD, T99_UIM }, "-wp0'I", "i" },
{ "fgG", 0, STD_C89, { T89_D, BADLEN, BADLEN, T99_D, BADLEN, T89_LD, BADLEN, BADLEN, BADLEN }, "-wp0 +#'I", "" },
{ "eE", 0, STD_C89, { T89_D, BADLEN, BADLEN, T99_D, BADLEN, T89_LD, BADLEN, BADLEN, BADLEN }, "-wp0 +#I", "" },
{ "c", 0, STD_C89, { T89_I, BADLEN, BADLEN, T94_WI, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "-w", "" },
{ "s", 1, STD_C89, { T89_C, BADLEN, BADLEN, T94_W, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "-wp", "cR" },
{ "p", 1, STD_C89, { T89_V, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "-w", "c" },
{ "n", 1, STD_C89, { T89_I, T99_SC, T89_S, T89_L, T9L_LL, BADLEN, T99_SST, T99_PD, T99_IM }, "", "W" },
/* C99 conversion specifiers. */
{ "F", 0, STD_C99, { T99_D, BADLEN, BADLEN, T99_D, BADLEN, T99_LD, BADLEN, BADLEN, BADLEN }, "-wp0 +#'I", "" },
{ "aA", 0, STD_C99, { T99_D, BADLEN, BADLEN, T99_D, BADLEN, T99_LD, BADLEN, BADLEN, BADLEN }, "-wp0 +#", "" },
/* X/Open conversion specifiers. */
{ "C", 0, STD_EXT, { TEX_WI, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "-w", "" },
{ "S", 1, STD_EXT, { TEX_W, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "-wp", "R" },
/* GNU conversion specifiers. */
{ "m", 0, STD_EXT, { T89_V, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "-wp", "" },
/* BSD conversion specifiers. */
/* FreeBSD kernel extensions (src/sys/kern/subr_prf.c).
The format %b is supported to decode error registers.
Its usage is: printf("reg=%b\n", regval, "<base><arg>*");
which produces: reg=3<BITTWO,BITONE>
The format %D provides a hexdump given a pointer and separator string:
("%6D", ptr, ":") -> XX:XX:XX:XX:XX:XX
("%*D", len, ptr, " ") -> XX XX XX XX ...
*/
{ "D", 1, STD_EXT, { T89_C, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "-wp", "cR" },
{ "b", 1, STD_EXT, { T89_C, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "-wp", "" },
{ "ry", 0, STD_EXT, { T89_I, BADLEN, BADLEN, T89_L, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "-wp0 +#", "i" },
{ NULL, 0, 0, NOLENGTHS, NULL, NULL }
};
static const format_char_info asm_fprintf_char_table[] =
{
/* C89 conversion specifiers. */
{ "di", 0, STD_C89, { T89_I, BADLEN, BADLEN, T89_L, T9L_LL, BADLEN, BADLEN, BADLEN, BADLEN }, "-wp0 +", "i" },
{ "oxX", 0, STD_C89, { T89_UI, BADLEN, BADLEN, T89_UL, T9L_ULL, BADLEN, BADLEN, BADLEN, BADLEN }, "-wp0#", "i" },
{ "u", 0, STD_C89, { T89_UI, BADLEN, BADLEN, T89_UL, T9L_ULL, BADLEN, BADLEN, BADLEN, BADLEN }, "-wp0", "i" },
{ "c", 0, STD_C89, { T89_I, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "-w", "" },
{ "s", 1, STD_C89, { T89_C, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "-wp", "cR" },
/* asm_fprintf conversion specifiers. */
{ "O", 0, STD_C89, NOARGUMENTS, "", "" },
{ "R", 0, STD_C89, NOARGUMENTS, "", "" },
{ "I", 0, STD_C89, NOARGUMENTS, "", "" },
{ "L", 0, STD_C89, NOARGUMENTS, "", "" },
{ "U", 0, STD_C89, NOARGUMENTS, "", "" },
{ "r", 0, STD_C89, { T89_I, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "", "" },
{ "@", 0, STD_C89, NOARGUMENTS, "", "" },
{ NULL, 0, 0, NOLENGTHS, NULL, NULL }
};
static const format_char_info gcc_diag_char_table[] =
{
/* C89 conversion specifiers. */
{ "di", 0, STD_C89, { T89_I, BADLEN, BADLEN, T89_L, T9L_LL, BADLEN, BADLEN, BADLEN, BADLEN }, "", "" },
{ "ox", 0, STD_C89, { T89_UI, BADLEN, BADLEN, T89_UL, T9L_ULL, BADLEN, BADLEN, BADLEN, BADLEN }, "", "" },
{ "u", 0, STD_C89, { T89_UI, BADLEN, BADLEN, T89_UL, T9L_ULL, BADLEN, BADLEN, BADLEN, BADLEN }, "", "" },
{ "c", 0, STD_C89, { T89_I, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "", "" },
{ "s", 1, STD_C89, { T89_C, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "p", "cR" },
{ "p", 1, STD_C89, { T89_V, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "", "c" },
/* Custom conversion specifiers. */
/* %H will require "location_t" at runtime. */
{ "H", 0, STD_C89, { T89_V, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "", "" },
/* These will require a "tree" at runtime. */
{ "J", 0, STD_C89, { T89_V, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "", "" },
{ "m", 0, STD_C89, NOARGUMENTS, "", "" },
{ NULL, 0, 0, NOLENGTHS, NULL, NULL }
};
static const format_char_info gcc_cdiag_char_table[] =
{
/* C89 conversion specifiers. */
{ "di", 0, STD_C89, { T89_I, BADLEN, BADLEN, T89_L, T9L_LL, BADLEN, BADLEN, BADLEN, BADLEN }, "", "" },
{ "ox", 0, STD_C89, { T89_UI, BADLEN, BADLEN, T89_UL, T9L_ULL, BADLEN, BADLEN, BADLEN, BADLEN }, "", "" },
{ "u", 0, STD_C89, { T89_UI, BADLEN, BADLEN, T89_UL, T9L_ULL, BADLEN, BADLEN, BADLEN, BADLEN }, "", "" },
{ "c", 0, STD_C89, { T89_I, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "", "" },
{ "s", 1, STD_C89, { T89_C, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "p", "cR" },
{ "p", 1, STD_C89, { T89_V, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "", "c" },
/* Custom conversion specifiers. */
/* %H will require "location_t" at runtime. */
{ "H", 0, STD_C89, { T89_V, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "", "" },
/* These will require a "tree" at runtime. */
{ "DEFJT", 0, STD_C89, { T89_V, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "", "" },
{ "m", 0, STD_C89, NOARGUMENTS, "", "" },
{ NULL, 0, 0, NOLENGTHS, NULL, NULL }
};
static const format_char_info gcc_cxxdiag_char_table[] =
{
/* C89 conversion specifiers. */
{ "di", 0, STD_C89, { T89_I, BADLEN, BADLEN, T89_L, T9L_LL, BADLEN, BADLEN, BADLEN, BADLEN }, "", "" },
{ "ox", 0, STD_C89, { T89_UI, BADLEN, BADLEN, T89_UL, T9L_ULL, BADLEN, BADLEN, BADLEN, BADLEN }, "", "" },
{ "u", 0, STD_C89, { T89_UI, BADLEN, BADLEN, T89_UL, T9L_ULL, BADLEN, BADLEN, BADLEN, BADLEN }, "", "" },
{ "c", 0, STD_C89, { T89_I, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "", "" },
{ "s", 1, STD_C89, { T89_C, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "p", "cR" },
{ "p", 1, STD_C89, { T89_V, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "", "c" },
/* Custom conversion specifiers. */
/* %H will require "location_t" at runtime. */
{ "H", 0, STD_C89, { T89_V, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "", "" },
/* These will require a "tree" at runtime. */
{ "ADEFJTV",0,STD_C89,{ T89_V, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "+#", "" },
/* These accept either an `int' or an `enum tree_code' (which is handled as an `int'.) */
{ "CLOPQ",0,STD_C89, { T89_I, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "", "" },
{ "m", 0, STD_C89, NOARGUMENTS, "", "" },
{ NULL, 0, 0, NOLENGTHS, NULL, NULL }
};
static const format_char_info scan_char_table[] =
{
/* C89 conversion specifiers. */
{ "di", 1, STD_C89, { T89_I, T99_SC, T89_S, T89_L, T9L_LL, TEX_LL, T99_SST, T99_PD, T99_IM }, "*w'I", "W" },
{ "u", 1, STD_C89, { T89_UI, T99_UC, T89_US, T89_UL, T9L_ULL, TEX_ULL, T99_ST, T99_UPD, T99_UIM }, "*w'I", "W" },
{ "oxX", 1, STD_C89, { T89_UI, T99_UC, T89_US, T89_UL, T9L_ULL, TEX_ULL, T99_ST, T99_UPD, T99_UIM }, "*w", "W" },
{ "efgEG", 1, STD_C89, { T89_F, BADLEN, BADLEN, T89_D, BADLEN, T89_LD, BADLEN, BADLEN, BADLEN }, "*w'", "W" },
{ "c", 1, STD_C89, { T89_C, BADLEN, BADLEN, T94_W, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "*w", "cW" },
{ "s", 1, STD_C89, { T89_C, BADLEN, BADLEN, T94_W, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "*aw", "cW" },
{ "[", 1, STD_C89, { T89_C, BADLEN, BADLEN, T94_W, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "*aw", "cW[" },
{ "p", 2, STD_C89, { T89_V, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "*w", "W" },
{ "n", 1, STD_C89, { T89_I, T99_SC, T89_S, T89_L, T9L_LL, BADLEN, T99_SST, T99_PD, T99_IM }, "", "W" },
/* C99 conversion specifiers. */
{ "FaA", 1, STD_C99, { T99_F, BADLEN, BADLEN, T99_D, BADLEN, T99_LD, BADLEN, BADLEN, BADLEN }, "*w'", "W" },
/* X/Open conversion specifiers. */
{ "C", 1, STD_EXT, { TEX_W, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "*w", "W" },
{ "S", 1, STD_EXT, { TEX_W, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN, BADLEN }, "*aw", "W" },
{ NULL, 0, 0, NOLENGTHS, NULL, NULL }
};
static const format_char_info time_char_table[] =
{
/* C89 conversion specifiers. */
{ "ABZab", 0, STD_C89, NOLENGTHS, "^#", "" },
{ "cx", 0, STD_C89, NOLENGTHS, "E", "3" },
{ "HIMSUWdmw", 0, STD_C89, NOLENGTHS, "-_0Ow", "" },
{ "j", 0, STD_C89, NOLENGTHS, "-_0Ow", "o" },
{ "p", 0, STD_C89, NOLENGTHS, "#", "" },
{ "X", 0, STD_C89, NOLENGTHS, "E", "" },
{ "y", 0, STD_C89, NOLENGTHS, "EO-_0w", "4" },
{ "Y", 0, STD_C89, NOLENGTHS, "-_0EOw", "o" },
{ "%", 0, STD_C89, NOLENGTHS, "", "" },
/* C99 conversion specifiers. */
{ "C", 0, STD_C99, NOLENGTHS, "-_0EOw", "o" },
{ "D", 0, STD_C99, NOLENGTHS, "", "2" },
{ "eVu", 0, STD_C99, NOLENGTHS, "-_0Ow", "" },
{ "FRTnrt", 0, STD_C99, NOLENGTHS, "", "" },
{ "g", 0, STD_C99, NOLENGTHS, "O-_0w", "2o" },
{ "G", 0, STD_C99, NOLENGTHS, "-_0Ow", "o" },
{ "h", 0, STD_C99, NOLENGTHS, "^#", "" },
{ "z", 0, STD_C99, NOLENGTHS, "O", "o" },
/* GNU conversion specifiers. */
{ "kls", 0, STD_EXT, NOLENGTHS, "-_0Ow", "" },
{ "P", 0, STD_EXT, NOLENGTHS, "", "" },
{ NULL, 0, 0, NOLENGTHS, NULL, NULL }
};
static const format_char_info monetary_char_table[] =
{
{ "in", 0, STD_C89, { T89_D, BADLEN, BADLEN, BADLEN, BADLEN, T89_LD, BADLEN, BADLEN, BADLEN }, "=^+(!-w#p", "" },
{ NULL, 0, 0, NOLENGTHS, NULL, NULL }
};
/* This must be in the same order as enum format_type. */
static const format_kind_info format_types_orig[] =
{
{ "printf", printf_length_specs, print_char_table, " +#0-'I", NULL,
printf_flag_specs, printf_flag_pairs,
FMT_FLAG_ARG_CONVERT|FMT_FLAG_DOLLAR_MULTIPLE|FMT_FLAG_USE_DOLLAR|FMT_FLAG_EMPTY_PREC_OK,
'w', 0, 'p', 0, 'L',
&integer_type_node, &integer_type_node, 0
},
{ "asm_fprintf", asm_fprintf_length_specs, asm_fprintf_char_table, " +#0-", NULL,
asm_fprintf_flag_specs, asm_fprintf_flag_pairs,
FMT_FLAG_ARG_CONVERT|FMT_FLAG_EMPTY_PREC_OK,
'w', 0, 'p', 0, 'L',
NULL, NULL
},
{ "gcc_diag", gcc_diag_length_specs, gcc_diag_char_table, "", NULL,
gcc_diag_flag_specs, gcc_diag_flag_pairs,
FMT_FLAG_ARG_CONVERT,
0, 0, 'p', 0, 'L',
NULL, &integer_type_node
},
{ "gcc_cdiag", gcc_cdiag_length_specs, gcc_cdiag_char_table, "", NULL,
gcc_cdiag_flag_specs, gcc_cdiag_flag_pairs,
FMT_FLAG_ARG_CONVERT,
0, 0, 'p', 0, 'L',
NULL, &integer_type_node
},
{ "gcc_cxxdiag", gcc_cxxdiag_length_specs, gcc_cxxdiag_char_table, "+#", NULL,
gcc_cxxdiag_flag_specs, gcc_cxxdiag_flag_pairs,
FMT_FLAG_ARG_CONVERT,
0, 0, 'p', 0, 'L',
NULL, &integer_type_node
},
{ "scanf", scanf_length_specs, scan_char_table, "*'I", NULL,
scanf_flag_specs, scanf_flag_pairs,
FMT_FLAG_ARG_CONVERT|FMT_FLAG_SCANF_A_KLUDGE|FMT_FLAG_USE_DOLLAR|FMT_FLAG_ZERO_WIDTH_BAD|FMT_FLAG_DOLLAR_GAP_POINTER_OK,
'w', 0, 0, '*', 'L',
NULL, NULL, 0
},
{ "strftime", NULL, time_char_table, "_-0^#", "EO",
strftime_flag_specs, strftime_flag_pairs,
FMT_FLAG_FANCY_PERCENT_OK, 'w', 0, 0, 0, 0,
NULL, NULL, 0
},
{ "strfmon", strfmon_length_specs, monetary_char_table, "=^+(!-", NULL,
strfmon_flag_specs, strfmon_flag_pairs,
FMT_FLAG_ARG_CONVERT, 'w', '#', 'p', 0, 'L',
NULL, NULL, 0
},
{ "printf0", printf_length_specs, print_char_table, " +#0-'I", NULL,
printf_flag_specs, printf_flag_pairs,
FMT_FLAG_ARG_CONVERT|FMT_FLAG_DOLLAR_MULTIPLE|FMT_FLAG_USE_DOLLAR|FMT_FLAG_EMPTY_PREC_OK,
'w', 0, 'p', 0, 'L',
&integer_type_node, &integer_type_node, 1
}
};
/* This layer of indirection allows GCC to reassign format_types with
new data if necessary, while still allowing the original data to be
const. */
static const format_kind_info *format_types = format_types_orig;
/* We can modify this one. */
static format_kind_info *dynamic_format_types;
/* Structure detailing the results of checking a format function call
where the format expression may be a conditional expression with
many leaves resulting from nested conditional expressions. */
typedef struct
{
/* Number of leaves of the format argument that could not be checked
as they were not string literals. */
int number_non_literal;
/* Number of leaves of the format argument that were null pointers or
string literals, but had extra format arguments. */
int number_extra_args;
/* Number of leaves of the format argument that were null pointers or
string literals, but had extra format arguments and used $ operand
numbers. */
int number_dollar_extra_args;
/* Number of leaves of the format argument that were wide string
literals. */
int number_wide;
/* Number of leaves of the format argument that were empty strings. */
int number_empty;
/* Number of leaves of the format argument that were unterminated
strings. */
int number_unterminated;
/* Number of leaves of the format argument that were not counted above. */
int number_other;
} format_check_results;
typedef struct
{
format_check_results *res;
function_format_info *info;
tree params;
int *status;
} format_check_context;
static void check_format_info (int *, function_format_info *, tree);
static void check_format_arg (void *, tree, unsigned HOST_WIDE_INT);
static void check_format_info_main (int *, format_check_results *,
function_format_info *,
const char *, int, tree,
unsigned HOST_WIDE_INT);
static void status_warning (int *, const char *, ...)
ATTRIBUTE_PRINTF_2;
static void init_dollar_format_checking (int, tree);
static int maybe_read_dollar_number (int *, const char **, int,
tree, tree *, const format_kind_info *);
static void finish_dollar_format_checking (int *, format_check_results *, int);
static const format_flag_spec *get_flag_spec (const format_flag_spec *,
int, const char *);
static void check_format_types (int *, format_wanted_type *);
/* Decode a format type from a string, returning the type, or
format_type_error if not valid, in which case the caller should print an
error message. */
static enum format_type
decode_format_type (const char *s)
{
int i;
int slen;
slen = strlen (s);
for (i = 0; i < (int) format_type_error; i++)
{
int alen;
if (!strcmp (s, format_types[i].name))
break;
alen = strlen (format_types[i].name);
if (slen == alen + 4 && s[0] == '_' && s[1] == '_'
&& s[slen - 1] == '_' && s[slen - 2] == '_'
&& !strncmp (s + 2, format_types[i].name, alen))
break;
}
return ((enum format_type) i);
}
/* Check the argument list of a call to printf, scanf, etc.
ATTRS are the attributes on the function type.
PARAMS is the list of argument values. Also, if -Wmissing-format-attribute,
warn for calls to vprintf or vscanf in functions with no such format
attribute themselves. */
void
check_function_format (int *status, tree attrs, tree params)
{
tree a;
/* See if this function has any format attributes. */
for (a = attrs; a; a = TREE_CHAIN (a))
{
if (is_attribute_p ("format", TREE_PURPOSE (a)))
{
/* Yup; check it. */
function_format_info info;
decode_format_attr (TREE_VALUE (a), &info, 1);
check_format_info (status, &info, params);
if (warn_missing_format_attribute && info.first_arg_num == 0
&& (format_types[info.format_type].flags
& (int) FMT_FLAG_ARG_CONVERT))
{
tree c;
for (c = TYPE_ATTRIBUTES (TREE_TYPE (current_function_decl));
c;
c = TREE_CHAIN (c))
if (is_attribute_p ("format", TREE_PURPOSE (c))
&& (decode_format_type (IDENTIFIER_POINTER
(TREE_VALUE (TREE_VALUE (c))))
== info.format_type))
break;
if (c == NULL_TREE)
{
/* Check if the current function has a parameter to which
the format attribute could be attached; if not, it
can't be a candidate for a format attribute, despite
the vprintf-like or vscanf-like call. */
tree args;
for (args = DECL_ARGUMENTS (current_function_decl);
args != 0;
args = TREE_CHAIN (args))
{
if (TREE_CODE (TREE_TYPE (args)) == POINTER_TYPE
&& (TYPE_MAIN_VARIANT (TREE_TYPE (TREE_TYPE (args)))
== char_type_node))
break;
}
if (args != 0)
warning ("function might be possible candidate for `%s' format attribute",
format_types[info.format_type].name);
}
}
}
}
}
/* This function replaces `warning' inside the printf format checking
functions. If the `status' parameter is non-NULL, then it is
dereferenced and set to 1 whenever a warning is caught. Otherwise
it warns as usual by replicating the innards of the warning
function from diagnostic.c. */
static void
status_warning (int *status, const char *msgid, ...)
{
diagnostic_info diagnostic ;
va_list ap;
va_start (ap, msgid);
if (status)
*status = 1;
else
{
/* This duplicates the warning function behavior. */
diagnostic_set_info (&diagnostic, _(msgid), &ap,
input_location, DK_WARNING);
report_diagnostic (&diagnostic);
}
va_end (ap);
}
/* Variables used by the checking of $ operand number formats. */
static char *dollar_arguments_used = NULL;
static char *dollar_arguments_pointer_p = NULL;
static int dollar_arguments_alloc = 0;
static int dollar_arguments_count;
static int dollar_first_arg_num;
static int dollar_max_arg_used;
static int dollar_format_warned;
/* Initialize the checking for a format string that may contain $
parameter number specifications; we will need to keep track of whether
each parameter has been used. FIRST_ARG_NUM is the number of the first
argument that is a parameter to the format, or 0 for a vprintf-style
function; PARAMS is the list of arguments starting at this argument. */
static void
init_dollar_format_checking (int first_arg_num, tree params)
{
tree oparams = params;
dollar_first_arg_num = first_arg_num;
dollar_arguments_count = 0;
dollar_max_arg_used = 0;
dollar_format_warned = 0;
if (first_arg_num > 0)
{
while (params)
{
dollar_arguments_count++;
params = TREE_CHAIN (params);
}
}
if (dollar_arguments_alloc < dollar_arguments_count)
{
if (dollar_arguments_used)
free (dollar_arguments_used);
if (dollar_arguments_pointer_p)
free (dollar_arguments_pointer_p);
dollar_arguments_alloc = dollar_arguments_count;
dollar_arguments_used = xmalloc (dollar_arguments_alloc);
dollar_arguments_pointer_p = xmalloc (dollar_arguments_alloc);
}
if (dollar_arguments_alloc)
{
memset (dollar_arguments_used, 0, dollar_arguments_alloc);
if (first_arg_num > 0)
{
int i = 0;
params = oparams;
while (params)
{
dollar_arguments_pointer_p[i] = (TREE_CODE (TREE_TYPE (TREE_VALUE (params)))
== POINTER_TYPE);
params = TREE_CHAIN (params);
i++;
}
}
}
}
/* Look for a decimal number followed by a $ in *FORMAT. If DOLLAR_NEEDED
is set, it is an error if one is not found; otherwise, it is OK. If
such a number is found, check whether it is within range and mark that
numbered operand as being used for later checking. Returns the operand
number if found and within range, zero if no such number was found and
this is OK, or -1 on error. PARAMS points to the first operand of the
format; PARAM_PTR is made to point to the parameter referred to. If
a $ format is found, *FORMAT is updated to point just after it. */
static int
maybe_read_dollar_number (int *status, const char **format,
int dollar_needed, tree params, tree *param_ptr,
const format_kind_info *fki)
{
int argnum;
int overflow_flag;
const char *fcp = *format;
if (! ISDIGIT (*fcp))
{
if (dollar_needed)
{
status_warning (status, "missing $ operand number in format");
return -1;
}
else
return 0;
}
argnum = 0;
overflow_flag = 0;
while (ISDIGIT (*fcp))
{
int nargnum;
nargnum = 10 * argnum + (*fcp - '0');
if (nargnum < 0 || nargnum / 10 != argnum)
overflow_flag = 1;
argnum = nargnum;
fcp++;
}
if (*fcp != '$')
{
if (dollar_needed)
{
status_warning (status, "missing $ operand number in format");
return -1;
}
else
return 0;
}
*format = fcp + 1;
if (pedantic && !dollar_format_warned)
{
status_warning (status,
"%s does not support %%n$ operand number formats",
C_STD_NAME (STD_EXT));
dollar_format_warned = 1;
}
if (overflow_flag || argnum == 0
|| (dollar_first_arg_num && argnum > dollar_arguments_count))
{
status_warning (status, "operand number out of range in format");
return -1;
}
if (argnum > dollar_max_arg_used)
dollar_max_arg_used = argnum;
/* For vprintf-style functions we may need to allocate more memory to
track which arguments are used. */
while (dollar_arguments_alloc < dollar_max_arg_used)
{
int nalloc;
nalloc = 2 * dollar_arguments_alloc + 16;
dollar_arguments_used = xrealloc (dollar_arguments_used, nalloc);
dollar_arguments_pointer_p = xrealloc (dollar_arguments_pointer_p,
nalloc);
memset (dollar_arguments_used + dollar_arguments_alloc, 0,
nalloc - dollar_arguments_alloc);
dollar_arguments_alloc = nalloc;
}
if (!(fki->flags & (int) FMT_FLAG_DOLLAR_MULTIPLE)
&& dollar_arguments_used[argnum - 1] == 1)
{
dollar_arguments_used[argnum - 1] = 2;
status_warning (status,
"format argument %d used more than once in %s format",
argnum, fki->name);
}
else
dollar_arguments_used[argnum - 1] = 1;
if (dollar_first_arg_num)
{
int i;
*param_ptr = params;
for (i = 1; i < argnum && *param_ptr != 0; i++)
*param_ptr = TREE_CHAIN (*param_ptr);
if (*param_ptr == 0)
{
/* This case shouldn't be caught here. */
abort ();
}
}
else
*param_ptr = 0;
return argnum;
}
/* Finish the checking for a format string that used $ operand number formats
instead of non-$ formats. We check for unused operands before used ones
(a serious error, since the implementation of the format function
can't know what types to pass to va_arg to find the later arguments).
and for unused operands at the end of the format (if we know how many
arguments the format had, so not for vprintf). If there were operand
numbers out of range on a non-vprintf-style format, we won't have reached
here. If POINTER_GAP_OK, unused arguments are OK if all arguments are
pointers. */
static void
finish_dollar_format_checking (int *status, format_check_results *res, int pointer_gap_ok)
{
int i;
bool found_pointer_gap = false;
for (i = 0; i < dollar_max_arg_used; i++)
{
if (!dollar_arguments_used[i])
{
if (pointer_gap_ok && (dollar_first_arg_num == 0
|| dollar_arguments_pointer_p[i]))
found_pointer_gap = true;
else
status_warning (status, "format argument %d unused before used argument %d in $-style format",
i + 1, dollar_max_arg_used);
}
}
if (found_pointer_gap
|| (dollar_first_arg_num
&& dollar_max_arg_used < dollar_arguments_count))
{
res->number_other--;
res->number_dollar_extra_args++;
}
}
/* Retrieve the specification for a format flag. SPEC contains the
specifications for format flags for the applicable kind of format.
FLAG is the flag in question. If PREDICATES is NULL, the basic
spec for that flag must be retrieved and this function aborts if
it cannot be found. If PREDICATES is not NULL, it is a string listing
possible predicates for the spec entry; if an entry predicated on any
of these is found, it is returned, otherwise NULL is returned. */
static const format_flag_spec *
get_flag_spec (const format_flag_spec *spec, int flag, const char *predicates)
{
int i;
for (i = 0; spec[i].flag_char != 0; i++)
{
if (spec[i].flag_char != flag)
continue;
if (predicates != NULL)
{
if (spec[i].predicate != 0
&& strchr (predicates, spec[i].predicate) != 0)
return &spec[i];
}
else if (spec[i].predicate == 0)
return &spec[i];
}
if (predicates == NULL)
abort ();
else
return NULL;
}
/* Check the argument list of a call to printf, scanf, etc.
INFO points to the function_format_info structure.
PARAMS is the list of argument values. */
static void
check_format_info (int *status, function_format_info *info, tree params)
{
format_check_context format_ctx;
unsigned HOST_WIDE_INT arg_num;
tree format_tree;
format_check_results res;
/* Skip to format argument. If the argument isn't available, there's
no work for us to do; prototype checking will catch the problem. */
for (arg_num = 1; ; ++arg_num)
{
if (params == 0)
return;
if (arg_num == info->format_num)
break;
params = TREE_CHAIN (params);
}
format_tree = TREE_VALUE (params);
params = TREE_CHAIN (params);
if (format_tree == 0)
return;
res.number_non_literal = 0;
res.number_extra_args = 0;
res.number_dollar_extra_args = 0;
res.number_wide = 0;
res.number_empty = 0;
res.number_unterminated = 0;
res.number_other = 0;
format_ctx.res = &res;
format_ctx.info = info;
format_ctx.params = params;
format_ctx.status = status;
check_function_arguments_recurse (check_format_arg, &format_ctx,
format_tree, arg_num);
if (res.number_non_literal > 0)
{
/* Functions taking a va_list normally pass a non-literal format
string. These functions typically are declared with
first_arg_num == 0, so avoid warning in those cases. */
if (!(format_types[info->format_type].flags & (int) FMT_FLAG_ARG_CONVERT))
{
/* For strftime-like formats, warn for not checking the format
string; but there are no arguments to check. */
if (warn_format_nonliteral)
status_warning (status, "format not a string literal, format string not checked");
}
else if (info->first_arg_num != 0)
{
/* If there are no arguments for the format at all, we may have
printf (foo) which is likely to be a security hole. */
while (arg_num + 1 < info->first_arg_num)
{
if (params == 0)
break;
params = TREE_CHAIN (params);
++arg_num;
}
if (params == 0 && (warn_format_nonliteral || warn_format_security))
status_warning (status, "format not a string literal and no format arguments");
else if (warn_format_nonliteral)
status_warning (status, "format not a string literal, argument types not checked");
}
}
/* If there were extra arguments to the format, normally warn. However,
the standard does say extra arguments are ignored, so in the specific
case where we have multiple leaves (conditional expressions or
ngettext) allow extra arguments if at least one leaf didn't have extra
arguments, but was otherwise OK (either non-literal or checked OK).
If the format is an empty string, this should be counted similarly to the
case of extra format arguments. */
if (res.number_extra_args > 0 && res.number_non_literal == 0
&& res.number_other == 0 && warn_format_extra_args)
status_warning (status, "too many arguments for format");
if (res.number_dollar_extra_args > 0 && res.number_non_literal == 0
&& res.number_other == 0 && warn_format_extra_args)
status_warning (status, "unused arguments in $-style format");
if (res.number_empty > 0 && res.number_non_literal == 0
&& res.number_other == 0 && warn_format_zero_length)
status_warning (status, "zero-length %s format string",
format_types[info->format_type].name);
if (res.number_wide > 0)
status_warning (status, "format is a wide character string");
if (res.number_unterminated > 0)
status_warning (status, "unterminated format string");
}
/* Callback from check_function_arguments_recurse to check a
format string. FORMAT_TREE is the format parameter. ARG_NUM
is the number of the format argument. CTX points to a
format_check_context. */
static void
check_format_arg (void *ctx, tree format_tree,
unsigned HOST_WIDE_INT arg_num)
{
format_check_context *format_ctx = ctx;
format_check_results *res = format_ctx->res;
function_format_info *info = format_ctx->info;
tree params = format_ctx->params;
int *status = format_ctx->status;
int format_length;
HOST_WIDE_INT offset;
const char *format_chars;
tree array_size = 0;
tree array_init;
if (integer_zerop (format_tree))
{
/* FIXME: this warning should go away once Marc Espie's
__attribute__((nonnull)) patch is in. Instead, checking for
nonnull attributes should probably change this function to act
specially if info == NULL and add a res->number_null entry for
that case, or maybe add a function pointer to be called at
the end instead of hardcoding check_format_info_main. */
if (!format_types[info->format_type].null_format_ok)
status_warning (status, "null format string");
/* Skip to first argument to check, so we can see if this format
has any arguments (it shouldn't). */
while (arg_num + 1 < info->first_arg_num)
{
if (params == 0)
return;
params = TREE_CHAIN (params);
++arg_num;
}
if (params == 0)
res->number_other++;
else
res->number_extra_args++;
return;
}
offset = 0;
if (TREE_CODE (format_tree) == PLUS_EXPR)
{
tree arg0, arg1;
arg0 = TREE_OPERAND (format_tree, 0);
arg1 = TREE_OPERAND (format_tree, 1);
STRIP_NOPS (arg0);
STRIP_NOPS (arg1);
if (TREE_CODE (arg1) == INTEGER_CST)
format_tree = arg0;
else if (TREE_CODE (arg0) == INTEGER_CST)
{
format_tree = arg1;
arg1 = arg0;
}
else
{
res->number_non_literal++;
return;
}
if (!host_integerp (arg1, 0)
|| (offset = tree_low_cst (arg1, 0)) < 0)
{
res->number_non_literal++;
return;
}
}
if (TREE_CODE (format_tree) != ADDR_EXPR)
{
res->number_non_literal++;
return;
}
format_tree = TREE_OPERAND (format_tree, 0);
if (TREE_CODE (format_tree) == VAR_DECL
&& TREE_CODE (TREE_TYPE (format_tree)) == ARRAY_TYPE
&& (array_init = decl_constant_value (format_tree)) != format_tree
&& TREE_CODE (array_init) == STRING_CST)
{
/* Extract the string constant initializer. Note that this may include
a trailing NUL character that is not in the array (e.g.
const char a[3] = "foo";). */
array_size = DECL_SIZE_UNIT (format_tree);
format_tree = array_init;
}
if (TREE_CODE (format_tree) != STRING_CST)
{
res->number_non_literal++;
return;
}
if (TYPE_MAIN_VARIANT (TREE_TYPE (TREE_TYPE (format_tree))) != char_type_node)
{
res->number_wide++;
return;
}
format_chars = TREE_STRING_POINTER (format_tree);
format_length = TREE_STRING_LENGTH (format_tree);
if (array_size != 0)
{
/* Variable length arrays can't be initialized. */
if (TREE_CODE (array_size) != INTEGER_CST)
abort ();
if (host_integerp (array_size, 0))
{
HOST_WIDE_INT array_size_value = TREE_INT_CST_LOW (array_size);
if (array_size_value > 0
&& array_size_value == (int) array_size_value
&& format_length > array_size_value)
format_length = array_size_value;
}
}
if (offset)
{
if (offset >= format_length)
{
res->number_non_literal++;
return;
}
format_chars += offset;
format_length -= offset;
}
if (format_length < 1)
{
res->number_unterminated++;
return;
}
if (format_length == 1)
{
res->number_empty++;
return;
}
if (format_chars[--format_length] != 0)
{
res->number_unterminated++;
return;
}
/* Skip to first argument to check. */
while (arg_num + 1 < info->first_arg_num)
{
if (params == 0)
return;
params = TREE_CHAIN (params);
++arg_num;
}
/* Provisionally increment res->number_other; check_format_info_main
will decrement it if it finds there are extra arguments, but this way
need not adjust it for every return. */
res->number_other++;
check_format_info_main (status, res, info, format_chars, format_length,
params, arg_num);
}
/* Do the main part of checking a call to a format function. FORMAT_CHARS
is the NUL-terminated format string (which at this point may contain
internal NUL characters); FORMAT_LENGTH is its length (excluding the
terminating NUL character). ARG_NUM is one less than the number of
the first format argument to check; PARAMS points to that format
argument in the list of arguments. */
static void
check_format_info_main (int *status, format_check_results *res,
function_format_info *info, const char *format_chars,
int format_length, tree params,
unsigned HOST_WIDE_INT arg_num)
{
const char *orig_format_chars = format_chars;
tree first_fillin_param = params;
const format_kind_info *fki = &format_types[info->format_type];
const format_flag_spec *flag_specs = fki->flag_specs;
const format_flag_pair *bad_flag_pairs = fki->bad_flag_pairs;
/* -1 if no conversions taking an operand have been found; 0 if one has
and it didn't use $; 1 if $ formats are in use. */
int has_operand_number = -1;
init_dollar_format_checking (info->first_arg_num, first_fillin_param);
while (1)
{
int i;
int suppressed = FALSE;
const char *length_chars = NULL;
enum format_lengths length_chars_val = FMT_LEN_none;
enum format_std_version length_chars_std = STD_C89;
int format_char;
tree cur_param;
tree wanted_type;
int main_arg_num = 0;
tree main_arg_params = 0;
enum format_std_version wanted_type_std;
const char *wanted_type_name;
format_wanted_type width_wanted_type;
format_wanted_type precision_wanted_type;
format_wanted_type main_wanted_type;
format_wanted_type *first_wanted_type = NULL;
format_wanted_type *last_wanted_type = NULL;
const format_length_info *fli = NULL;
const format_char_info *fci = NULL;
char flag_chars[256];
int aflag = 0;
if (*format_chars == 0)
{
if (format_chars - orig_format_chars != format_length)
status_warning (status, "embedded `\\0' in format");
if (info->first_arg_num != 0 && params != 0
&& has_operand_number <= 0)
{
res->number_other--;
res->number_extra_args++;
}
if (has_operand_number > 0)
finish_dollar_format_checking (status, res, fki->flags & (int) FMT_FLAG_DOLLAR_GAP_POINTER_OK);
return;
}
if (*format_chars++ != '%')
continue;
if (*format_chars == 0)
{
status_warning (status, "spurious trailing `%%' in format");
continue;
}
if (*format_chars == '%')
{
++format_chars;
continue;
}
flag_chars[0] = 0;
if ((fki->flags & (int) FMT_FLAG_USE_DOLLAR) && has_operand_number != 0)
{
/* Possibly read a $ operand number at the start of the format.
If one was previously used, one is required here. If one
is not used here, we can't immediately conclude this is a
format without them, since it could be printf %m or scanf %*. */
int opnum;
opnum = maybe_read_dollar_number (status, &format_chars, 0,
first_fillin_param,
&main_arg_params, fki);
if (opnum == -1)
return;
else if (opnum > 0)
{
has_operand_number = 1;
main_arg_num = opnum + info->first_arg_num - 1;
}
}
/* Read any format flags, but do not yet validate them beyond removing
duplicates, since in general validation depends on the rest of
the format. */
while (*format_chars != 0
&& strchr (fki->flag_chars, *format_chars) != 0)
{
const format_flag_spec *s = get_flag_spec (flag_specs,
*format_chars, NULL);
if (strchr (flag_chars, *format_chars) != 0)
{
status_warning (status, "repeated %s in format", _(s->name));
}
else
{
i = strlen (flag_chars);
flag_chars[i++] = *format_chars;
flag_chars[i] = 0;
}
if (s->skip_next_char)
{
++format_chars;
if (*format_chars == 0)
{
status_warning (status, "missing fill character at end of strfmon format");
return;
}
}
++format_chars;
}
/* Read any format width, possibly * or *m$. */
if (fki->width_char != 0)
{
if (fki->width_type != NULL && *format_chars == '*')
{
i = strlen (flag_chars);
flag_chars[i++] = fki->width_char;
flag_chars[i] = 0;
/* "...a field width...may be indicated by an asterisk.
In this case, an int argument supplies the field width..." */
++format_chars;
if (has_operand_number != 0)
{
int opnum;
opnum = maybe_read_dollar_number (status, &format_chars,
has_operand_number == 1,
first_fillin_param,
&params, fki);
if (opnum == -1)
return;
else if (opnum > 0)
{
has_operand_number = 1;
arg_num = opnum + info->first_arg_num - 1;
}
else
has_operand_number = 0;
}
if (info->first_arg_num != 0)
{
if (params == 0)
{
status_warning (status, "too few arguments for format");
return;
}
cur_param = TREE_VALUE (params);
if (has_operand_number <= 0)
{
params = TREE_CHAIN (params);
++arg_num;
}
width_wanted_type.wanted_type = *fki->width_type;
width_wanted_type.wanted_type_name = NULL;
width_wanted_type.pointer_count = 0;
width_wanted_type.char_lenient_flag = 0;
width_wanted_type.writing_in_flag = 0;
width_wanted_type.reading_from_flag = 0;
width_wanted_type.name = _("field width");
width_wanted_type.param = cur_param;
width_wanted_type.arg_num = arg_num;
width_wanted_type.next = NULL;
if (last_wanted_type != 0)
last_wanted_type->next = &width_wanted_type;
if (first_wanted_type == 0)
first_wanted_type = &width_wanted_type;
last_wanted_type = &width_wanted_type;
}
}
else
{
/* Possibly read a numeric width. If the width is zero,
we complain if appropriate. */
int non_zero_width_char = FALSE;
int found_width = FALSE;
while (ISDIGIT (*format_chars))
{
found_width = TRUE;
if (*format_chars != '0')
non_zero_width_char = TRUE;
++format_chars;
}
if (found_width && !non_zero_width_char &&
(fki->flags & (int) FMT_FLAG_ZERO_WIDTH_BAD))
status_warning (status, "zero width in %s format",
fki->name);
if (found_width)
{
i = strlen (flag_chars);
flag_chars[i++] = fki->width_char;
flag_chars[i] = 0;
}
}
}
/* Read any format left precision (must be a number, not *). */
if (fki->left_precision_char != 0 && *format_chars == '#')
{
++format_chars;
i = strlen (flag_chars);
flag_chars[i++] = fki->left_precision_char;
flag_chars[i] = 0;
if (!ISDIGIT (*format_chars))
status_warning (status, "empty left precision in %s format",
fki->name);
while (ISDIGIT (*format_chars))
++format_chars;
}
/* Read any format precision, possibly * or *m$. */
if (fki->precision_char != 0 && *format_chars == '.')
{
++format_chars;
i = strlen (flag_chars);
flag_chars[i++] = fki->precision_char;
flag_chars[i] = 0;
if (fki->precision_type != NULL && *format_chars == '*')
{
/* "...a...precision...may be indicated by an asterisk.
In this case, an int argument supplies the...precision." */
++format_chars;
if (has_operand_number != 0)
{
int opnum;
opnum = maybe_read_dollar_number (status, &format_chars,
has_operand_number == 1,
first_fillin_param,
&params, fki);
if (opnum == -1)
return;
else if (opnum > 0)
{
has_operand_number = 1;
arg_num = opnum + info->first_arg_num - 1;
}
else
has_operand_number = 0;
}
if (info->first_arg_num != 0)
{
if (params == 0)
{
status_warning (status, "too few arguments for format");
return;
}
cur_param = TREE_VALUE (params);
if (has_operand_number <= 0)
{
params = TREE_CHAIN (params);
++arg_num;
}
precision_wanted_type.wanted_type = *fki->precision_type;
precision_wanted_type.wanted_type_name = NULL;
precision_wanted_type.pointer_count = 0;
precision_wanted_type.char_lenient_flag = 0;
precision_wanted_type.writing_in_flag = 0;
precision_wanted_type.reading_from_flag = 0;
precision_wanted_type.name = _("field precision");
precision_wanted_type.param = cur_param;
precision_wanted_type.arg_num = arg_num;
precision_wanted_type.next = NULL;
if (last_wanted_type != 0)
last_wanted_type->next = &precision_wanted_type;
if (first_wanted_type == 0)
first_wanted_type = &precision_wanted_type;
last_wanted_type = &precision_wanted_type;
}
}
else
{
if (!(fki->flags & (int) FMT_FLAG_EMPTY_PREC_OK)
&& !ISDIGIT (*format_chars))
status_warning (status, "empty precision in %s format",
fki->name);
while (ISDIGIT (*format_chars))
++format_chars;
}
}
/* Read any length modifier, if this kind of format has them. */
fli = fki->length_char_specs;
length_chars = NULL;
length_chars_val = FMT_LEN_none;
length_chars_std = STD_C89;
if (fli)
{
while (fli->name != 0 && fli->name[0] != *format_chars)
fli++;
if (fli->name != 0)
{
format_chars++;
if (fli->double_name != 0 && fli->name[0] == *format_chars)
{
format_chars++;
length_chars = fli->double_name;
length_chars_val = fli->double_index;
length_chars_std = fli->double_std;
}
else
{
length_chars = fli->name;
length_chars_val = fli->index;
length_chars_std = fli->std;
}
i = strlen (flag_chars);
flag_chars[i++] = fki->length_code_char;
flag_chars[i] = 0;
}
if (pedantic)
{
/* Warn if the length modifier is non-standard. */
if (ADJ_STD (length_chars_std) > C_STD_VER)
status_warning (status, "%s does not support the `%s' %s length modifier",
C_STD_NAME (length_chars_std), length_chars,
fki->name);
}
}
/* Read any modifier (strftime E/O). */
if (fki->modifier_chars != NULL)
{
while (*format_chars != 0
&& strchr (fki->modifier_chars, *format_chars) != 0)
{
if (strchr (flag_chars, *format_chars) != 0)
{
const format_flag_spec *s = get_flag_spec (flag_specs,
*format_chars, NULL);
status_warning (status, "repeated %s in format", _(s->name));
}
else
{
i = strlen (flag_chars);
flag_chars[i++] = *format_chars;
flag_chars[i] = 0;
}
++format_chars;
}
}
/* Handle the scanf allocation kludge. */
if (fki->flags & (int) FMT_FLAG_SCANF_A_KLUDGE)
{
if (*format_chars == 'a' && !flag_isoc99)
{
if (format_chars[1] == 's' || format_chars[1] == 'S'
|| format_chars[1] == '[')
{
/* `a' is used as a flag. */
i = strlen (flag_chars);
flag_chars[i++] = 'a';
flag_chars[i] = 0;
format_chars++;
}
}
}
if (*format_chars == 'b')
{
/* There should be an int arg to control the string arg. */
if (params == 0)
{
status_warning (status, "too few arguments for format");
return;
}
if (info->first_arg_num != 0)
{
cur_param = TREE_VALUE (params);
params = TREE_CHAIN (params);
++arg_num;
if ((TYPE_MAIN_VARIANT (TREE_TYPE (cur_param))
!= integer_type_node)
&&
(TYPE_MAIN_VARIANT (TREE_TYPE (cur_param))
!= unsigned_type_node))
{
status_warning (status, "bitmap is not type int (arg %d)",
arg_num);
}
}
}
if (*format_chars == 'D')
{
/* There should be an unsigned char * arg before the string arg. */
if (params == 0)
{
status_warning (status, "too few arguments for format");
return;
}
if (info->first_arg_num != 0)
{
tree cur_type;
cur_param = TREE_VALUE (params);
params = TREE_CHAIN (params);
++arg_num;
cur_type = TREE_TYPE (cur_param);
if (TREE_CODE (cur_type) != POINTER_TYPE
|| TYPE_MAIN_VARIANT (TREE_TYPE (cur_type))
!= unsigned_char_type_node)
{
status_warning (status,
"ethernet address is not type unsigned char * (arg %d)",
arg_num);
}
}
}
format_char = *format_chars;
if (format_char == 0
|| (!(fki->flags & (int) FMT_FLAG_FANCY_PERCENT_OK)
&& format_char == '%'))
{
status_warning (status, "conversion lacks type at end of format");
continue;
}
format_chars++;
fci = fki->conversion_specs;
while (fci->format_chars != 0
&& strchr (fci->format_chars, format_char) == 0)
++fci;
if (fci->format_chars == 0)
{
if (ISGRAPH(format_char))
status_warning (status, "unknown conversion type character `%c' in format",
format_char);
else
status_warning (status, "unknown conversion type character 0x%x in format",
format_char);
continue;
}
if (pedantic)
{
if (ADJ_STD (fci->std) > C_STD_VER)
status_warning (status, "%s does not support the `%%%c' %s format",
C_STD_NAME (fci->std), format_char, fki->name);
}
/* Validate the individual flags used, removing any that are invalid. */
{
int d = 0;
for (i = 0; flag_chars[i] != 0; i++)
{
const format_flag_spec *s = get_flag_spec (flag_specs,
flag_chars[i], NULL);
flag_chars[i - d] = flag_chars[i];
if (flag_chars[i] == fki->length_code_char)
continue;
if (strchr (fci->flag_chars, flag_chars[i]) == 0)
{
status_warning (status, "%s used with `%%%c' %s format",
_(s->name), format_char, fki->name);
d++;
continue;
}
if (pedantic)
{
const format_flag_spec *t;
if (ADJ_STD (s->std) > C_STD_VER)
status_warning (status, "%s does not support %s",
C_STD_NAME (s->std), _(s->long_name));
t = get_flag_spec (flag_specs, flag_chars[i], fci->flags2);
if (t != NULL && ADJ_STD (t->std) > ADJ_STD (s->std))
{
const char *long_name = (t->long_name != NULL
? t->long_name
: s->long_name);
if (ADJ_STD (t->std) > C_STD_VER)
status_warning (status, "%s does not support %s with the `%%%c' %s format",
C_STD_NAME (t->std), _(long_name),
format_char, fki->name);
}
}
}
flag_chars[i - d] = 0;
}
if ((fki->flags & (int) FMT_FLAG_SCANF_A_KLUDGE)
&& strchr (flag_chars, 'a') != 0)
aflag = 1;
if (fki->suppression_char
&& strchr (flag_chars, fki->suppression_char) != 0)
suppressed = 1;
/* Validate the pairs of flags used. */
for (i = 0; bad_flag_pairs[i].flag_char1 != 0; i++)
{
const format_flag_spec *s, *t;
if (strchr (flag_chars, bad_flag_pairs[i].flag_char1) == 0)
continue;
if (strchr (flag_chars, bad_flag_pairs[i].flag_char2) == 0)
continue;
if (bad_flag_pairs[i].predicate != 0
&& strchr (fci->flags2, bad_flag_pairs[i].predicate) == 0)
continue;
s = get_flag_spec (flag_specs, bad_flag_pairs[i].flag_char1, NULL);
t = get_flag_spec (flag_specs, bad_flag_pairs[i].flag_char2, NULL);
if (bad_flag_pairs[i].ignored)
{
if (bad_flag_pairs[i].predicate != 0)
status_warning (status, "%s ignored with %s and `%%%c' %s format",
_(s->name), _(t->name), format_char,
fki->name);
else
status_warning (status, "%s ignored with %s in %s format",
_(s->name), _(t->name), fki->name);
}
else
{
if (bad_flag_pairs[i].predicate != 0)
status_warning (status, "use of %s and %s together with `%%%c' %s format",
_(s->name), _(t->name), format_char,
fki->name);
else
status_warning (status, "use of %s and %s together in %s format",
_(s->name), _(t->name), fki->name);
}
}
/* Give Y2K warnings. */
if (warn_format_y2k)
{
int y2k_level = 0;
if (strchr (fci->flags2, '4') != 0)
if (strchr (flag_chars, 'E') != 0)
y2k_level = 3;
else
y2k_level = 2;
else if (strchr (fci->flags2, '3') != 0)
y2k_level = 3;
else if (strchr (fci->flags2, '2') != 0)
y2k_level = 2;
if (y2k_level == 3)
status_warning (status, "`%%%c' yields only last 2 digits of year in some locales on non-BSD systems",
format_char);
else if (y2k_level == 2)
status_warning (status, "`%%%c' yields only last 2 digits of year", format_char);
}
if (strchr (fci->flags2, '[') != 0)
{
/* Skip over scan set, in case it happens to have '%' in it. */
if (*format_chars == '^')
++format_chars;
/* Find closing bracket; if one is hit immediately, then
it's part of the scan set rather than a terminator. */
if (*format_chars == ']')
++format_chars;
while (*format_chars && *format_chars != ']')
++format_chars;
if (*format_chars != ']')
/* The end of the format string was reached. */
status_warning (status, "no closing `]' for `%%[' format");
}
wanted_type = 0;
wanted_type_name = 0;
if (fki->flags & (int) FMT_FLAG_ARG_CONVERT)
{
wanted_type = (fci->types[length_chars_val].type
? *fci->types[length_chars_val].type : 0);
wanted_type_name = fci->types[length_chars_val].name;
wanted_type_std = fci->types[length_chars_val].std;
if (wanted_type == 0)
{
status_warning (status, "use of `%s' length modifier with `%c' type character",
length_chars, format_char);
/* Heuristic: skip one argument when an invalid length/type
combination is encountered. */
arg_num++;
if (params == 0)
{
status_warning (status, "too few arguments for format");
return;
}
params = TREE_CHAIN (params);
continue;
}
else if (pedantic
/* Warn if non-standard, provided it is more non-standard
than the length and type characters that may already
have been warned for. */
&& ADJ_STD (wanted_type_std) > ADJ_STD (length_chars_std)
&& ADJ_STD (wanted_type_std) > ADJ_STD (fci->std))
{
if (ADJ_STD (wanted_type_std) > C_STD_VER)
status_warning (status, "%s does not support the `%%%s%c' %s format",
C_STD_NAME (wanted_type_std), length_chars,
format_char, fki->name);
}
}
/* Finally. . .check type of argument against desired type! */
if (info->first_arg_num == 0)
continue;
if ((fci->pointer_count == 0 && wanted_type == void_type_node)
|| suppressed)
{
if (main_arg_num != 0)
{
if (suppressed)
status_warning (status, "operand number specified with suppressed assignment");
else
status_warning (status, "operand number specified for format taking no argument");
}
}
else
{
if (main_arg_num != 0)
{
arg_num = main_arg_num;
params = main_arg_params;
}
else
{
++arg_num;
if (has_operand_number > 0)
{
status_warning (status, "missing $ operand number in format");
return;
}
else
has_operand_number = 0;
if (params == 0)
{
status_warning (status, "too few arguments for format");
return;
}
}
cur_param = TREE_VALUE (params);
params = TREE_CHAIN (params);
main_wanted_type.wanted_type = wanted_type;
main_wanted_type.wanted_type_name = wanted_type_name;
main_wanted_type.pointer_count = fci->pointer_count + aflag;
main_wanted_type.char_lenient_flag = 0;
if (strchr (fci->flags2, 'c') != 0)
main_wanted_type.char_lenient_flag = 1;
main_wanted_type.writing_in_flag = 0;
main_wanted_type.reading_from_flag = 0;
if (aflag)
main_wanted_type.writing_in_flag = 1;
else
{
if (strchr (fci->flags2, 'W') != 0)
main_wanted_type.writing_in_flag = 1;
if (strchr (fci->flags2, 'R') != 0)
main_wanted_type.reading_from_flag = 1;
}
main_wanted_type.name = NULL;
main_wanted_type.param = cur_param;
main_wanted_type.arg_num = arg_num;
main_wanted_type.next = NULL;
if (last_wanted_type != 0)
last_wanted_type->next = &main_wanted_type;
if (first_wanted_type == 0)
first_wanted_type = &main_wanted_type;
last_wanted_type = &main_wanted_type;
}
if (first_wanted_type != 0)
check_format_types (status, first_wanted_type);
}
}
/* Check the argument types from a single format conversion (possibly
including width and precision arguments). */
static void
check_format_types (int *status, format_wanted_type *types)
{
for (; types != 0; types = types->next)
{
tree cur_param;
tree cur_type;
tree orig_cur_type;
tree wanted_type;
int arg_num;
int i;
int char_type_flag;
cur_param = types->param;
cur_type = TREE_TYPE (cur_param);
if (cur_type == error_mark_node)
continue;
char_type_flag = 0;
wanted_type = types->wanted_type;
arg_num = types->arg_num;
/* The following should not occur here. */
if (wanted_type == 0)
abort ();
if (wanted_type == void_type_node && types->pointer_count == 0)
abort ();
if (types->pointer_count == 0)
wanted_type = (*lang_hooks.types.type_promotes_to) (wanted_type);
STRIP_NOPS (cur_param);
/* Check the types of any additional pointer arguments
that precede the "real" argument. */
for (i = 0; i < types->pointer_count; ++i)
{
if (TREE_CODE (cur_type) == POINTER_TYPE)
{
cur_type = TREE_TYPE (cur_type);
if (cur_type == error_mark_node)
break;
/* Check for writing through a NULL pointer. */
if (types->writing_in_flag
&& i == 0
&& cur_param != 0
&& integer_zerop (cur_param))
status_warning (status,
"writing through null pointer (arg %d)",
arg_num);
/* Check for reading through a NULL pointer. */
if (types->reading_from_flag
&& i == 0
&& cur_param != 0
&& integer_zerop (cur_param))
status_warning (status,
"reading through null pointer (arg %d)",
arg_num);
if (cur_param != 0 && TREE_CODE (cur_param) == ADDR_EXPR)
cur_param = TREE_OPERAND (cur_param, 0);
else
cur_param = 0;
/* See if this is an attempt to write into a const type with
scanf or with printf "%n". Note: the writing in happens
at the first indirection only, if for example
void * const * is passed to scanf %p; passing
const void ** is simply passing an incompatible type. */
if (types->writing_in_flag
&& i == 0
&& (TYPE_READONLY (cur_type)
|| (cur_param != 0
&& (TREE_CODE_CLASS (TREE_CODE (cur_param)) == 'c'
|| (DECL_P (cur_param)
&& TREE_READONLY (cur_param))))))
status_warning (status, "writing into constant object (arg %d)", arg_num);
/* If there are extra type qualifiers beyond the first
indirection, then this makes the types technically
incompatible. */
if (i > 0
&& pedantic
&& (TYPE_READONLY (cur_type)
|| TYPE_VOLATILE (cur_type)
|| TYPE_RESTRICT (cur_type)))
status_warning (status, "extra type qualifiers in format argument (arg %d)",
arg_num);
}
else
{
if (types->pointer_count == 1)
status_warning (status, "format argument is not a pointer (arg %d)", arg_num);
else
status_warning (status, "format argument is not a pointer to a pointer (arg %d)", arg_num);
break;
}
}
if (i < types->pointer_count)
continue;
orig_cur_type = cur_type;
cur_type = TYPE_MAIN_VARIANT (cur_type);
/* Check whether the argument type is a character type. This leniency
only applies to certain formats, flagged with 'c'.
*/
if (types->char_lenient_flag)
char_type_flag = (cur_type == char_type_node
|| cur_type == signed_char_type_node
|| cur_type == unsigned_char_type_node);
/* Check the type of the "real" argument, if there's a type we want. */
if (wanted_type == cur_type)
continue;
/* If we want `void *', allow any pointer type.
(Anything else would already have got a warning.)
With -pedantic, only allow pointers to void and to character
types. */
if (wanted_type == void_type_node
&& (!pedantic || (i == 1 && char_type_flag)))
continue;
/* Don't warn about differences merely in signedness, unless
-pedantic. With -pedantic, warn if the type is a pointer
target and not a character type, and for character types at
a second level of indirection. */
if (TREE_CODE (wanted_type) == INTEGER_TYPE
&& TREE_CODE (cur_type) == INTEGER_TYPE
&& (! pedantic || i == 0 || (i == 1 && char_type_flag))
&& (TREE_UNSIGNED (wanted_type)
? wanted_type == c_common_unsigned_type (cur_type)
: wanted_type == c_common_signed_type (cur_type)))
continue;
/* Likewise, "signed char", "unsigned char" and "char" are
equivalent but the above test won't consider them equivalent. */
if (wanted_type == char_type_node
&& (! pedantic || i < 2)
&& char_type_flag)
continue;
/* Now we have a type mismatch. */
{
const char *this;
const char *that;
tree tmp;
tmp = TYPE_NAME (wanted_type);
if (TREE_CODE (tmp) == TYPE_DECL)
tmp = DECL_NAME (tmp);
this = IDENTIFIER_POINTER (tmp);
that = 0;
if (TYPE_NAME (orig_cur_type) != 0
&& TREE_CODE (orig_cur_type) != INTEGER_TYPE
&& !(TREE_CODE (orig_cur_type) == POINTER_TYPE
&& TREE_CODE (TREE_TYPE (orig_cur_type)) == INTEGER_TYPE))
{
tmp = TYPE_NAME (orig_cur_type);
if (TREE_CODE (tmp) == TYPE_DECL)
tmp = DECL_NAME (tmp);
if (tmp)
that = IDENTIFIER_POINTER (tmp);
}
/* A nameless type can't possibly match what the format wants.
So there will be a warning for it.
Make up a string to describe vaguely what it is. */
if (that == 0)
{
if (TREE_CODE (orig_cur_type) == POINTER_TYPE)
that = _("pointer");
else
that = _("different type");
}
/* Make the warning better in case of mismatch of int vs long. */
if (TREE_CODE (orig_cur_type) == INTEGER_TYPE
&& TREE_CODE (wanted_type) == INTEGER_TYPE
&& TYPE_PRECISION (orig_cur_type) == TYPE_PRECISION (wanted_type)
&& TYPE_NAME (orig_cur_type) != 0
&& TREE_CODE (TYPE_NAME (orig_cur_type)) == TYPE_DECL)
that = IDENTIFIER_POINTER (DECL_NAME (TYPE_NAME (orig_cur_type)));
if (strcmp (this, that) != 0)
{
/* There may be a better name for the format, e.g. size_t,
but we should allow for programs with a perverse typedef
making size_t something other than what the compiler
thinks. */
if (types->wanted_type_name != 0
&& strcmp (types->wanted_type_name, that) != 0)
this = types->wanted_type_name;
if (types->name != 0)
status_warning (status, "%s is not type %s (arg %d)", types->name, this,
arg_num);
else
status_warning (status, "%s format, %s arg (arg %d)", this, that, arg_num);
}
}
}
}
/* Given a format_char_info array FCI, and a character C, this function
returns the index into the conversion_specs where that specifier's
data is located. If the character isn't found it aborts. */
static unsigned int
find_char_info_specifier_index (const format_char_info *fci, int c)
{
unsigned int i = 0;
while (fci->format_chars)
{
if (strchr (fci->format_chars, c))
return i;
i++; fci++;
}
/* We shouldn't be looking for a non-existent specifier. */
abort ();
}
/* Given a format_length_info array FLI, and a character C, this
function returns the index into the conversion_specs where that
modifier's data is located. If the character isn't found it
aborts. */
static unsigned int
find_length_info_modifier_index (const format_length_info *fli, int c)
{
unsigned int i = 0;
while (fli->name)
{
if (strchr (fli->name, c))
return i;
i++; fli++;
}
/* We shouldn't be looking for a non-existent modifier. */
abort ();
}
/* Determine the type of HOST_WIDE_INT in the code being compiled for
use in GCC's __asm_fprintf__ custom format attribute. You must
have set dynamic_format_types before calling this function. */
static void
init_dynamic_asm_fprintf_info (void)
{
static tree hwi;
if (!hwi)
{
format_length_info *new_asm_fprintf_length_specs;
unsigned int i;
/* Find the underlying type for HOST_WIDE_INT. For the %w
length modifier to work, one must have issued: "typedef
HOST_WIDE_INT __gcc_host_wide_int__;" in one's source code
prior to using that modifier. */
2005-06-03 04:02:20 +00:00
hwi = maybe_get_identifier ("__gcc_host_wide_int__");
if (!hwi)
{
error ("'__gcc_host_wide_int__' is not defined as a type");
return;
}
hwi = identifier_global_value (hwi);
if (!hwi || TREE_CODE (hwi) != TYPE_DECL)
{
error ("'__gcc_host_wide_int__' is not defined as a type");
return;
}
hwi = DECL_ORIGINAL_TYPE (hwi);
if (!hwi)
abort ();
2005-06-03 04:02:20 +00:00
if (hwi != long_integer_type_node && hwi != long_long_integer_type_node)
{
error ("'__gcc_host_wide_int__' is not defined as 'long'"
" or 'long long'");
return;
}
/* Create a new (writable) copy of asm_fprintf_length_specs. */
new_asm_fprintf_length_specs = xmemdup (asm_fprintf_length_specs,
sizeof (asm_fprintf_length_specs),
sizeof (asm_fprintf_length_specs));
/* HOST_WIDE_INT must be one of 'long' or 'long long'. */
i = find_length_info_modifier_index (new_asm_fprintf_length_specs, 'w');
if (hwi == long_integer_type_node)
new_asm_fprintf_length_specs[i].index = FMT_LEN_l;
else if (hwi == long_long_integer_type_node)
new_asm_fprintf_length_specs[i].index = FMT_LEN_ll;
else
abort ();
/* Assign the new data for use. */
dynamic_format_types[asm_fprintf_format_type].length_char_specs =
new_asm_fprintf_length_specs;
}
}
/* Determine the types of "tree" and "location_t" in the code being
compiled for use in GCC's diagnostic custom format attributes. You
must have set dynamic_format_types before calling this function. */
static void
init_dynamic_diag_info (void)
{
static tree t, loc, hwi;
if (!loc || !t || !hwi)
{
static format_char_info *diag_fci, *cdiag_fci, *cxxdiag_fci;
static format_length_info *diag_ls;
unsigned int i;
/* For the GCC-diagnostics custom format specifiers to work, one
must have declared `tree' and/or `location_t' prior to using
those attributes. If we haven't seen these declarations then
you shouldn't use the specifiers requiring these types.
However we don't force a hard ICE because we may see only one
or the other type. */
if ((loc = maybe_get_identifier ("location_t")))
2005-06-03 04:02:20 +00:00
{
loc = identifier_global_value (loc);
if (loc)
{
if (TREE_CODE (loc) != TYPE_DECL)
{
error ("'location_t' is not defined as a type");
loc = 0;
}
else
loc = TREE_TYPE (loc);
}
}
/* We need to grab the underlying `union tree_node' so peek into
an extra type level. */
if ((t = maybe_get_identifier ("tree")))
2005-06-03 04:02:20 +00:00
{
t = identifier_global_value (t);
if (t)
{
if (TREE_CODE (t) != TYPE_DECL)
{
error ("'tree' is not defined as a type");
t = 0;
}
else if (TREE_CODE (TREE_TYPE (t)) != POINTER_TYPE)
{
error ("'tree' is not defined as a pointer type");
t = 0;
}
else
t = TREE_TYPE (TREE_TYPE (t));
}
}
/* Find the underlying type for HOST_WIDE_INT. For the %w
length modifier to work, one must have issued: "typedef
HOST_WIDE_INT __gcc_host_wide_int__;" in one's source code
prior to using that modifier. */
if ((hwi = maybe_get_identifier ("__gcc_host_wide_int__")))
2005-06-03 04:02:20 +00:00
{
hwi = identifier_global_value (hwi);
if (hwi)
{
if (TREE_CODE (hwi) != TYPE_DECL)
{
error ("'__gcc_host_wide_int__' is not defined as a type");
hwi = 0;
}
else
{
hwi = DECL_ORIGINAL_TYPE (hwi);
if (!hwi)
abort ();
if (hwi != long_integer_type_node
&& hwi != long_long_integer_type_node)
{
error ("'__gcc_host_wide_int__' is not defined"
" as 'long' or 'long long'");
hwi = 0;
}
}
}
}
/* Assign the new data for use. */
/* All the GCC diag formats use the same length specs. */
if (! diag_ls)
dynamic_format_types[gcc_diag_format_type].length_char_specs =
dynamic_format_types[gcc_cdiag_format_type].length_char_specs =
dynamic_format_types[gcc_cxxdiag_format_type].length_char_specs =
diag_ls = xmemdup (gcc_diag_length_specs,
sizeof (gcc_diag_length_specs),
sizeof (gcc_diag_length_specs));
if (hwi)
{
/* HOST_WIDE_INT must be one of 'long' or 'long long'. */
i = find_length_info_modifier_index (diag_ls, 'w');
if (hwi == long_integer_type_node)
diag_ls[i].index = FMT_LEN_l;
else if (hwi == long_long_integer_type_node)
diag_ls[i].index = FMT_LEN_ll;
else
abort ();
}
/* Handle the __gcc_diag__ format specifics. */
if (! diag_fci)
dynamic_format_types[gcc_diag_format_type].conversion_specs =
diag_fci = xmemdup (gcc_diag_char_table,
sizeof(gcc_diag_char_table),
sizeof(gcc_diag_char_table));
if (loc)
{
i = find_char_info_specifier_index (diag_fci, 'H');
diag_fci[i].types[0].type = &loc;
diag_fci[i].pointer_count = 1;
}
if (t)
{
i = find_char_info_specifier_index (diag_fci, 'J');
diag_fci[i].types[0].type = &t;
diag_fci[i].pointer_count = 1;
}
/* Handle the __gcc_cdiag__ format specifics. */
if (! cdiag_fci)
dynamic_format_types[gcc_cdiag_format_type].conversion_specs =
cdiag_fci = xmemdup (gcc_cdiag_char_table,
sizeof(gcc_cdiag_char_table),
sizeof(gcc_cdiag_char_table));
if (loc)
{
i = find_char_info_specifier_index (cdiag_fci, 'H');
cdiag_fci[i].types[0].type = &loc;
cdiag_fci[i].pointer_count = 1;
}
if (t)
{
/* All specifiers taking a tree share the same struct. */
i = find_char_info_specifier_index (cdiag_fci, 'D');
cdiag_fci[i].types[0].type = &t;
cdiag_fci[i].pointer_count = 1;
i = find_char_info_specifier_index (cdiag_fci, 'J');
cdiag_fci[i].types[0].type = &t;
cdiag_fci[i].pointer_count = 1;
}
/* Handle the __gcc_cxxdiag__ format specifics. */
if (! cxxdiag_fci)
dynamic_format_types[gcc_cxxdiag_format_type].conversion_specs =
cxxdiag_fci = xmemdup (gcc_cxxdiag_char_table,
sizeof(gcc_cxxdiag_char_table),
sizeof(gcc_cxxdiag_char_table));
if (loc)
{
i = find_char_info_specifier_index (cxxdiag_fci, 'H');
cxxdiag_fci[i].types[0].type = &loc;
cxxdiag_fci[i].pointer_count = 1;
}
if (t)
{
/* All specifiers taking a tree share the same struct. */
i = find_char_info_specifier_index (cxxdiag_fci, 'D');
cxxdiag_fci[i].types[0].type = &t;
cxxdiag_fci[i].pointer_count = 1;
i = find_char_info_specifier_index (cxxdiag_fci, 'J');
cxxdiag_fci[i].types[0].type = &t;
cxxdiag_fci[i].pointer_count = 1;
}
}
}
/* Handle a "format" attribute; arguments as in
struct attribute_spec.handler. */
tree
handle_format_attribute (tree *node, tree name ATTRIBUTE_UNUSED, tree args,
int flags, bool *no_add_attrs)
{
tree type = *node;
function_format_info info;
tree argument;
if (!decode_format_attr (args, &info, 0))
{
*no_add_attrs = true;
return NULL_TREE;
}
argument = TYPE_ARG_TYPES (type);
if (argument)
{
if (!check_format_string (argument, info.format_num, flags,
no_add_attrs))
return NULL_TREE;
if (info.first_arg_num != 0)
{
unsigned HOST_WIDE_INT arg_num = 1;
/* Verify that first_arg_num points to the last arg,
the ... */
while (argument)
arg_num++, argument = TREE_CHAIN (argument);
if (arg_num != info.first_arg_num)
{
if (!(flags & (int) ATTR_FLAG_BUILT_IN))
error ("args to be formatted is not '...'");
*no_add_attrs = true;
return NULL_TREE;
}
}
}
if (info.format_type == strftime_format_type && info.first_arg_num != 0)
{
error ("strftime formats cannot format arguments");
*no_add_attrs = true;
return NULL_TREE;
}
/* If this is a custom GCC-internal format type, we have to
initialize certain bits a runtime. */
if (info.format_type == asm_fprintf_format_type
|| info.format_type == gcc_diag_format_type
|| info.format_type == gcc_cdiag_format_type
|| info.format_type == gcc_cxxdiag_format_type)
{
/* Our first time through, we have to make sure that our
format_type data is allocated dynamically and is modifiable. */
if (!dynamic_format_types)
format_types = dynamic_format_types =
xmemdup (format_types_orig, sizeof (format_types_orig),
sizeof (format_types_orig));
/* If this is format __asm_fprintf__, we have to initialize
GCC's notion of HOST_WIDE_INT for checking %wd. */
if (info.format_type == asm_fprintf_format_type)
init_dynamic_asm_fprintf_info();
/* If this is one of the diagnostic attributes, then we have to
initialize `location_t' and `tree' at runtime. */
else if (info.format_type == gcc_diag_format_type
|| info.format_type == gcc_cdiag_format_type
|| info.format_type == gcc_cxxdiag_format_type)
init_dynamic_diag_info();
else
abort();
}
return NULL_TREE;
}