Google Git
Sign in
gnu / gcc / dc9b9e310659bc1320d94355d18ea0fe64b13df6 / . / gcc / cpplex.c
blob: 7db6b24b253812bf65fa0110fcc634cdea28bd2d [file] [log] [blame]
/* CPP Library - lexical analysis.
Copyright (C) 2000, 2001, 2002 Free Software Foundation, Inc.
Contributed by Per Bothner, 1994-95.
Based on CCCP program by Paul Rubin, June 1986
Adapted to ANSI C, Richard Stallman, Jan 1987
Broken out to separate file, Zack Weinberg, Mar 2000
Single-pass line tokenization by Neil Booth, April 2000
This program is free software; you can redistribute it and/or modify it
under the terms of the GNU General Public License as published by the
Free Software Foundation; either version 2, or (at your option) any
later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */
#include "config.h"
#include "system.h"
#include "cpplib.h"
#include "cpphash.h"
#ifdef MULTIBYTE_CHARS
#include "mbchar.h"
#include <locale.h>
#endif
/* Tokens with SPELL_STRING store their spelling in the token list,
and it's length in the token->val.name.len. */
enum spell_type
{
SPELL_OPERATOR = 0,
SPELL_CHAR,
SPELL_IDENT,
SPELL_NUMBER,
SPELL_STRING,
SPELL_NONE
};
struct token_spelling
{
enum spell_type category;
const unsigned char *name;
};
static const unsigned char *const digraph_spellings[] =
{ U"%:", U"%:%:", U"<:", U":>", U"<%", U"%>" };
#define OP(e, s) { SPELL_OPERATOR, U s },
#define TK(e, s) { s, U STRINGX (e) },
static const struct token_spelling token_spellings[N_TTYPES] = { TTYPE_TABLE };
#undef OP
#undef TK
#define TOKEN_SPELL(token) (token_spellings[(token)->type].category)
#define TOKEN_NAME(token) (token_spellings[(token)->type].name)
#define BACKUP() do {buffer->cur = buffer->backup_to;} while (0)
static void handle_newline PARAMS ((cpp_reader *));
static cppchar_t skip_escaped_newlines PARAMS ((cpp_reader *));
static cppchar_t get_effective_char PARAMS ((cpp_reader *));
static int skip_block_comment PARAMS ((cpp_reader *));
static int skip_line_comment PARAMS ((cpp_reader *));
static void adjust_column PARAMS ((cpp_reader *));
static int skip_whitespace PARAMS ((cpp_reader *, cppchar_t));
static cpp_hashnode *parse_identifier PARAMS ((cpp_reader *));
static uchar *parse_slow PARAMS ((cpp_reader *, const uchar *, int,
unsigned int *));
static void parse_number PARAMS ((cpp_reader *, cpp_string *, int));
static int unescaped_terminator_p PARAMS ((cpp_reader *, const uchar *));
static void parse_string PARAMS ((cpp_reader *, cpp_token *, cppchar_t));
static bool trigraph_p PARAMS ((cpp_reader *));
static void save_comment PARAMS ((cpp_reader *, cpp_token *, const uchar *,
cppchar_t));
static bool continue_after_nul PARAMS ((cpp_reader *));
static int name_p PARAMS ((cpp_reader *, const cpp_string *));
static int maybe_read_ucs PARAMS ((cpp_reader *, const unsigned char **,
const unsigned char *, cppchar_t *));
static tokenrun *next_tokenrun PARAMS ((tokenrun *));
static unsigned int hex_digit_value PARAMS ((unsigned int));
static _cpp_buff *new_buff PARAMS ((size_t));
/* Utility routine:
Compares, the token TOKEN to the NUL-terminated string STRING.
TOKEN must be a CPP_NAME. Returns 1 for equal, 0 for unequal. */
int
cpp_ideq (token, string)
const cpp_token *token;
const char *string;
{
if (token->type != CPP_NAME)
return 0;
return !ustrcmp (NODE_NAME (token->val.node), (const uchar *) string);
}
/* Call when meeting a newline, assumed to be in buffer->cur[-1].
Returns with buffer->cur pointing to the character immediately
following the newline (combination). */
static void
handle_newline (pfile)
cpp_reader *pfile;
{
cpp_buffer *buffer = pfile->buffer;
/* Handle CR-LF and LF-CR. Most other implementations (e.g. java)
only accept CR-LF; maybe we should fall back to that behavior? */
if (buffer->cur[-1] + buffer->cur[0] == '\r' + '\n')
buffer->cur++;
buffer->line_base = buffer->cur;
buffer->col_adjust = 0;
pfile->line++;
}
/* Subroutine of skip_escaped_newlines; called when a 3-character
sequence beginning with "??" is encountered. buffer->cur points to
the second '?'.
Warn if necessary, and returns true if the sequence forms a
trigraph and the trigraph should be honored. */
static bool
trigraph_p (pfile)
cpp_reader *pfile;
{
cpp_buffer *buffer = pfile->buffer;
cppchar_t from_char = buffer->cur[1];
bool accept;
if (!_cpp_trigraph_map[from_char])
return false;
accept = CPP_OPTION (pfile, trigraphs);
/* Don't warn about trigraphs in comments. */
if (CPP_OPTION (pfile, warn_trigraphs) && !pfile->state.lexing_comment)
{
if (accept)
cpp_error_with_line (pfile, DL_WARNING,
pfile->line, CPP_BUF_COL (buffer) - 1,
"trigraph ??%c converted to %c",
(int) from_char,
(int) _cpp_trigraph_map[from_char]);
else if (buffer->cur != buffer->last_Wtrigraphs)
{
buffer->last_Wtrigraphs = buffer->cur;
cpp_error_with_line (pfile, DL_WARNING,
pfile->line, CPP_BUF_COL (buffer) - 1,
"trigraph ??%c ignored", (int) from_char);
}
}
return accept;
}
/* Skips any escaped newlines introduced by '?' or a '\\', assumed to
lie in buffer->cur[-1]. Returns the next byte, which will be in
buffer->cur[-1]. This routine performs preprocessing stages 1 and
2 of the ISO C standard. */
static cppchar_t
skip_escaped_newlines (pfile)
cpp_reader *pfile;
{
cpp_buffer *buffer = pfile->buffer;
cppchar_t next = buffer->cur[-1];
/* Only do this if we apply stages 1 and 2. */
if (!buffer->from_stage3)
{
const unsigned char *saved_cur;
cppchar_t next1;
do
{
if (next == '?')
{
if (buffer->cur[0] != '?' || !trigraph_p (pfile))
break;
/* Translate the trigraph. */
next = _cpp_trigraph_map[buffer->cur[1]];
buffer->cur += 2;
if (next != '\\')
break;
}
if (buffer->cur == buffer->rlimit)
break;
/* We have a backslash, and room for at least one more
character. Skip horizontal whitespace. */
saved_cur = buffer->cur;
do
next1 = *buffer->cur++;
while (is_nvspace (next1) && buffer->cur < buffer->rlimit);
if (!is_vspace (next1))
{
buffer->cur = saved_cur;
break;
}
if (saved_cur != buffer->cur - 1
&& !pfile->state.lexing_comment)
cpp_error (pfile, DL_WARNING,
"backslash and newline separated by space");
handle_newline (pfile);
buffer->backup_to = buffer->cur;
if (buffer->cur == buffer->rlimit)
{
cpp_error (pfile, DL_PEDWARN,
"backslash-newline at end of file");
next = EOF;
}
else
next = *buffer->cur++;
}
while (next == '\\' || next == '?');
}
return next;
}
/* Obtain the next character, after trigraph conversion and skipping
an arbitrarily long string of escaped newlines. The common case of
no trigraphs or escaped newlines falls through quickly. On return,
buffer->backup_to points to where to return to if the character is
not to be processed. */
static cppchar_t
get_effective_char (pfile)
cpp_reader *pfile;
{
cppchar_t next;
cpp_buffer *buffer = pfile->buffer;
buffer->backup_to = buffer->cur;
next = *buffer->cur++;
if (__builtin_expect (next == '?' || next == '\\', 0))
next = skip_escaped_newlines (pfile);
return next;
}
/* Skip a C-style block comment. We find the end of the comment by
seeing if an asterisk is before every '/' we encounter. Returns
nonzero if comment terminated by EOF, zero otherwise. */
static int
skip_block_comment (pfile)
cpp_reader *pfile;
{
cpp_buffer *buffer = pfile->buffer;
cppchar_t c = EOF, prevc = EOF;
pfile->state.lexing_comment = 1;
while (buffer->cur != buffer->rlimit)
{
prevc = c, c = *buffer->cur++;
/* FIXME: For speed, create a new character class of characters
of interest inside block comments. */
if (c == '?' || c == '\\')
c = skip_escaped_newlines (pfile);
/* People like decorating comments with '*', so check for '/'
instead for efficiency. */
if (c == '/')
{
if (prevc == '*')
break;
/* Warn about potential nested comments, but not if the '/'
comes immediately before the true comment delimiter.
Don't bother to get it right across escaped newlines. */
if (CPP_OPTION (pfile, warn_comments)
&& buffer->cur[0] == '*' && buffer->cur[1] != '/')
cpp_error_with_line (pfile, DL_WARNING,
pfile->line, CPP_BUF_COL (buffer),
"\"/*\" within comment");
}
else if (is_vspace (c))
handle_newline (pfile);
else if (c == '\t')
adjust_column (pfile);
}
pfile->state.lexing_comment = 0;
return c != '/' || prevc != '*';
}
/* Skip a C++ line comment, leaving buffer->cur pointing to the
terminating newline. Handles escaped newlines. Returns nonzero
if a multiline comment. */
static int
skip_line_comment (pfile)
cpp_reader *pfile;
{
cpp_buffer *buffer = pfile->buffer;
unsigned int orig_line = pfile->line;
cppchar_t c;
#ifdef MULTIBYTE_CHARS
wchar_t wc;
int char_len;
#endif
pfile->state.lexing_comment = 1;
#ifdef MULTIBYTE_CHARS
/* Reset multibyte conversion state. */
(void) local_mbtowc (NULL, NULL, 0);
#endif
do
{
if (buffer->cur == buffer->rlimit)
goto at_eof;
#ifdef MULTIBYTE_CHARS
char_len = local_mbtowc (&wc, (const char *) buffer->cur,
buffer->rlimit - buffer->cur);
if (char_len == -1)
{
cpp_error (pfile, DL_WARNING,
"ignoring invalid multibyte character");
char_len = 1;
c = *buffer->cur++;
}
else
{
buffer->cur += char_len;
c = wc;
}
#else
c = *buffer->cur++;
#endif
if (c == '?' || c == '\\')
c = skip_escaped_newlines (pfile);
}
while (!is_vspace (c));
/* Step back over the newline, except at EOF. */
buffer->cur--;
at_eof:
pfile->state.lexing_comment = 0;
return orig_line != pfile->line;
}
/* pfile->buffer->cur is one beyond the \t character. Update
col_adjust so we track the column correctly. */
static void
adjust_column (pfile)
cpp_reader *pfile;
{
cpp_buffer *buffer = pfile->buffer;
unsigned int col = CPP_BUF_COL (buffer) - 1; /* Zero-based column. */
/* Round it up to multiple of the tabstop, but subtract 1 since the
tab itself occupies a character position. */
buffer->col_adjust += (CPP_OPTION (pfile, tabstop)
- col % CPP_OPTION (pfile, tabstop)) - 1;
}
/* Skips whitespace, saving the next non-whitespace character.
Adjusts pfile->col_adjust to account for tabs. Without this,
tokens might be assigned an incorrect column. */
static int
skip_whitespace (pfile, c)
cpp_reader *pfile;
cppchar_t c;
{
cpp_buffer *buffer = pfile->buffer;
unsigned int warned = 0;
do
{
/* Horizontal space always OK. */
if (c == ' ')
;
else if (c == '\t')
adjust_column (pfile);
/* Just \f \v or \0 left. */
else if (c == '\0')
{
if (buffer->cur - 1 == buffer->rlimit)
return 0;
if (!warned)
{
cpp_error (pfile, DL_WARNING, "null character(s) ignored");
warned = 1;
}
}
else if (pfile->state.in_directive && CPP_PEDANTIC (pfile))
cpp_error_with_line (pfile, DL_PEDWARN, pfile->line,
CPP_BUF_COL (buffer),
"%s in preprocessing directive",
c == '\f' ? "form feed" : "vertical tab");
c = *buffer->cur++;
}
/* We only want non-vertical space, i.e. ' ' \t \f \v \0. */
while (is_nvspace (c));
buffer->cur--;
return 1;
}
/* See if the characters of a number token are valid in a name (no
'.', '+' or '-'). */
static int
name_p (pfile, string)
cpp_reader *pfile;
const cpp_string *string;
{
unsigned int i;
for (i = 0; i < string->len; i++)
if (!is_idchar (string->text[i]))
return 0;
return 1;
}
/* Parse an identifier, skipping embedded backslash-newlines. This is
a critical inner loop. The common case is an identifier which has
not been split by backslash-newline, does not contain a dollar
sign, and has already been scanned (roughly 10:1 ratio of
seen:unseen identifiers in normal code; the distribution is
Poisson-like). Second most common case is a new identifier, not
split and no dollar sign. The other possibilities are rare and
have been relegated to parse_slow. */
static cpp_hashnode *
parse_identifier (pfile)
cpp_reader *pfile;
{
cpp_hashnode *result;
const uchar *cur, *base;
/* Fast-path loop. Skim over a normal identifier.
N.B. ISIDNUM does not include $. */
cur = pfile->buffer->cur;
while (ISIDNUM (*cur))
cur++;
/* Check for slow-path cases. */
if (*cur == '?' || *cur == '\\' || *cur == '$')
{
unsigned int len;
base = parse_slow (pfile, cur, 0, &len);
result = (cpp_hashnode *)
ht_lookup (pfile->hash_table, base, len, HT_ALLOCED);
}
else
{
base = pfile->buffer->cur - 1;
pfile->buffer->cur = cur;
result = (cpp_hashnode *)
ht_lookup (pfile->hash_table, base, cur - base, HT_ALLOC);
}
/* Rarely, identifiers require diagnostics when lexed.
XXX Has to be forced out of the fast path. */
if (__builtin_expect ((result->flags & NODE_DIAGNOSTIC)
&& !pfile->state.skipping, 0))
{
/* It is allowed to poison the same identifier twice. */
if ((result->flags & NODE_POISONED) && !pfile->state.poisoned_ok)
cpp_error (pfile, DL_ERROR, "attempt to use poisoned \"%s\"",
NODE_NAME (result));
/* Constraint 6.10.3.5: __VA_ARGS__ should only appear in the
replacement list of a variadic macro. */
if (result == pfile->spec_nodes.n__VA_ARGS__
&& !pfile->state.va_args_ok)
cpp_error (pfile, DL_PEDWARN,
"__VA_ARGS__ can only appear in the expansion of a C99 variadic macro");
}
return result;
}
/* Slow path. This handles numbers and identifiers which have been
split, or contain dollar signs. The part of the token from
PFILE->buffer->cur-1 to CUR has already been scanned. NUMBER_P is
1 if it's a number, and 2 if it has a leading period. Returns a
pointer to the token's NUL-terminated spelling in permanent
storage, and sets PLEN to its length. */
static uchar *
parse_slow (pfile, cur, number_p, plen)
cpp_reader *pfile;
const uchar *cur;
int number_p;
unsigned int *plen;
{
cpp_buffer *buffer = pfile->buffer;
const uchar *base = buffer->cur - 1;
struct obstack *stack = &pfile->hash_table->stack;
unsigned int c, prevc, saw_dollar = 0;
/* Place any leading period. */
if (number_p == 2)
obstack_1grow (stack, '.');
/* Copy the part of the token which is known to be okay. */
obstack_grow (stack, base, cur - base);
/* Now process the part which isn't. We are looking at one of
'$', '\\', or '?' on entry to this loop. */
prevc = cur[-1];
c = *cur++;
buffer->cur = cur;
for (;;)
{
/* Potential escaped newline? */
buffer->backup_to = buffer->cur - 1;
if (c == '?' || c == '\\')
c = skip_escaped_newlines (pfile);
if (!is_idchar (c))
{
if (!number_p)
break;
if (c != '.' && !VALID_SIGN (c, prevc))
break;
}
/* Handle normal identifier characters in this loop. */
do
{
prevc = c;
obstack_1grow (stack, c);
if (c == '$')
saw_dollar++;
c = *buffer->cur++;
}
while (is_idchar (c));
}
/* Step back over the unwanted char. */
BACKUP ();
/* $ is not an identifier character in the standard, but is commonly
accepted as an extension. Don't warn about it in skipped
conditional blocks. */
if (saw_dollar && CPP_PEDANTIC (pfile) && ! pfile->state.skipping)
cpp_error (pfile, DL_PEDWARN, "'$' character(s) in identifier or number");
/* Identifiers and numbers are null-terminated. */
*plen = obstack_object_size (stack);
obstack_1grow (stack, '\0');
return obstack_finish (stack);
}
/* Parse a number, beginning with character C, skipping embedded
backslash-newlines. LEADING_PERIOD is nonzero if there was a "."
before C. Place the result in NUMBER. */
static void
parse_number (pfile, number, leading_period)
cpp_reader *pfile;
cpp_string *number;
int leading_period;
{
const uchar *cur;
/* Fast-path loop. Skim over a normal number.
N.B. ISIDNUM does not include $. */
cur = pfile->buffer->cur;
while (ISIDNUM (*cur) || *cur == '.' || VALID_SIGN (*cur, cur[-1]))
cur++;
/* Check for slow-path cases. */
if (*cur == '?' || *cur == '\\' || *cur == '$')
number->text = parse_slow (pfile, cur, 1 + leading_period, &number->len);
else
{
const uchar *base = pfile->buffer->cur - 1;
uchar *dest;
number->len = cur - base + leading_period;
dest = _cpp_unaligned_alloc (pfile, number->len + 1);
dest[number->len] = '\0';
number->text = dest;
if (leading_period)
*dest++ = '.';
memcpy (dest, base, cur - base);
pfile->buffer->cur = cur;
}
}
/* Subroutine of parse_string. */
static int
unescaped_terminator_p (pfile, dest)
cpp_reader *pfile;
const unsigned char *dest;
{
const unsigned char *start, *temp;
/* In #include-style directives, terminators are not escapeable. */
if (pfile->state.angled_headers)
return 1;
start = BUFF_FRONT (pfile->u_buff);
/* An odd number of consecutive backslashes represents an escaped
terminator. */
for (temp = dest; temp > start && temp[-1] == '\\'; temp--)
;
return ((dest - temp) & 1) == 0;
}
/* Parses a string, character constant, or angle-bracketed header file
name. Handles embedded trigraphs and escaped newlines. The stored
string is guaranteed NUL-terminated, but it is not guaranteed that
this is the first NUL since embedded NULs are preserved.
When this function returns, buffer->cur points to the next
character to be processed. */
static void
parse_string (pfile, token, terminator)
cpp_reader *pfile;
cpp_token *token;
cppchar_t terminator;
{
cpp_buffer *buffer = pfile->buffer;
unsigned char *dest, *limit;
cppchar_t c;
bool warned_nulls = false;
#ifdef MULTIBYTE_CHARS
wchar_t wc;
int char_len;
#endif
dest = BUFF_FRONT (pfile->u_buff);
limit = BUFF_LIMIT (pfile->u_buff);
#ifdef MULTIBYTE_CHARS
/* Reset multibyte conversion state. */
(void) local_mbtowc (NULL, NULL, 0);
#endif
for (;;)
{
/* We need room for another char, possibly the terminating NUL. */
if ((size_t) (limit - dest) < 1)
{
size_t len_so_far = dest - BUFF_FRONT (pfile->u_buff);
_cpp_extend_buff (pfile, &pfile->u_buff, 2);
dest = BUFF_FRONT (pfile->u_buff) + len_so_far;
limit = BUFF_LIMIT (pfile->u_buff);
}
#ifdef MULTIBYTE_CHARS
char_len = local_mbtowc (&wc, (const char *) buffer->cur,
buffer->rlimit - buffer->cur);
if (char_len == -1)
{
cpp_error (pfile, DL_WARNING,
"ignoring invalid multibyte character");
char_len = 1;
c = *buffer->cur++;
}
else
{
buffer->cur += char_len;
c = wc;
}
#else
c = *buffer->cur++;
#endif
/* Handle trigraphs, escaped newlines etc. */
if (c == '?' || c == '\\')
c = skip_escaped_newlines (pfile);
if (c == terminator)
{
if (unescaped_terminator_p (pfile, dest))
break;
}
else if (is_vspace (c))
{
/* No string literal may extend over multiple lines. In
assembly language, suppress the error except for <>
includes. This is a kludge around not knowing where
comments are. */
unterminated:
if (CPP_OPTION (pfile, lang) != CLK_ASM || terminator == '>')
cpp_error (pfile, DL_ERROR, "missing terminating %c character",
(int) terminator);
buffer->cur--;
break;
}
else if (c == '\0')
{
if (buffer->cur - 1 == buffer->rlimit)
goto unterminated;
if (!warned_nulls)
{
warned_nulls = true;
cpp_error (pfile, DL_WARNING,
"null character(s) preserved in literal");
}
}
#ifdef MULTIBYTE_CHARS
if (char_len > 1)
{
for ( ; char_len > 0; --char_len)
*dest++ = (*buffer->cur - char_len);
}
else
#endif
*dest++ = c;
}
*dest = '\0';
token->val.str.text = BUFF_FRONT (pfile->u_buff);
token->val.str.len = dest - BUFF_FRONT (pfile->u_buff);
BUFF_FRONT (pfile->u_buff) = dest + 1;
}
/* The stored comment includes the comment start and any terminator. */
static void
save_comment (pfile, token, from, type)
cpp_reader *pfile;
cpp_token *token;
const unsigned char *from;
cppchar_t type;
{
unsigned char *buffer;
unsigned int len, clen;
len = pfile->buffer->cur - from + 1; /* + 1 for the initial '/'. */
/* C++ comments probably (not definitely) have moved past a new
line, which we don't want to save in the comment. */
if (is_vspace (pfile->buffer->cur[-1]))
len--;
/* If we are currently in a directive, then we need to store all
C++ comments as C comments internally, and so we need to
allocate a little extra space in that case.
Note that the only time we encounter a directive here is
when we are saving comments in a "#define". */
clen = (pfile->state.in_directive && type == '/') ? len + 2 : len;
buffer = _cpp_unaligned_alloc (pfile, clen);
token->type = CPP_COMMENT;
token->val.str.len = clen;
token->val.str.text = buffer;
buffer[0] = '/';
memcpy (buffer + 1, from, len - 1);
/* Finish conversion to a C comment, if necessary. */
if (pfile->state.in_directive && type == '/')
{
buffer[1] = '*';
buffer[clen - 2] = '*';
buffer[clen - 1] = '/';
}
}
/* Allocate COUNT tokens for RUN. */
void
_cpp_init_tokenrun (run, count)
tokenrun *run;
unsigned int count;
{
run->base = xnewvec (cpp_token, count);
run->limit = run->base + count;
run->next = NULL;
}
/* Returns the next tokenrun, or creates one if there is none. */
static tokenrun *
next_tokenrun (run)
tokenrun *run;
{
if (run->next == NULL)
{
run->next = xnew (tokenrun);
run->next->prev = run;
_cpp_init_tokenrun (run->next, 250);
}
return run->next;
}
/* Allocate a single token that is invalidated at the same time as the
rest of the tokens on the line. Has its line and col set to the
same as the last lexed token, so that diagnostics appear in the
right place. */
cpp_token *
_cpp_temp_token (pfile)
cpp_reader *pfile;
{
cpp_token *old, *result;
old = pfile->cur_token - 1;
if (pfile->cur_token == pfile->cur_run->limit)
{
pfile->cur_run = next_tokenrun (pfile->cur_run);
pfile->cur_token = pfile->cur_run->base;
}
result = pfile->cur_token++;
result->line = old->line;
result->col = old->col;
return result;
}
/* Lex a token into RESULT (external interface). Takes care of issues
like directive handling, token lookahead, multiple include
optimization and skipping. */
const cpp_token *
_cpp_lex_token (pfile)
cpp_reader *pfile;
{
cpp_token *result;
for (;;)
{
if (pfile->cur_token == pfile->cur_run->limit)
{
pfile->cur_run = next_tokenrun (pfile->cur_run);
pfile->cur_token = pfile->cur_run->base;
}
if (pfile->lookaheads)
{
pfile->lookaheads--;
result = pfile->cur_token++;
}
else
result = _cpp_lex_direct (pfile);
if (result->flags & BOL)
{
/* Is this a directive. If _cpp_handle_directive returns
false, it is an assembler #. */
if (result->type == CPP_HASH
/* 6.10.3 p 11: Directives in a list of macro arguments
gives undefined behavior. This implementation
handles the directive as normal. */
&& pfile->state.parsing_args != 1
&& _cpp_handle_directive (pfile, result->flags & PREV_WHITE))
continue;
if (pfile->cb.line_change && !pfile->state.skipping)
(*pfile->cb.line_change)(pfile, result, pfile->state.parsing_args);
}
/* We don't skip tokens in directives. */
if (pfile->state.in_directive)
break;
/* Outside a directive, invalidate controlling macros. At file
EOF, _cpp_lex_direct takes care of popping the buffer, so we never
get here and MI optimisation works. */
pfile->mi_valid = false;
if (!pfile->state.skipping || result->type == CPP_EOF)
break;
}
return result;
}
/* A NUL terminates the current buffer. For ISO preprocessing this is
EOF, but for traditional preprocessing it indicates we need a line
refill. Returns TRUE to continue preprocessing a new buffer, FALSE
to return a CPP_EOF to the caller. */
static bool
continue_after_nul (pfile)
cpp_reader *pfile;
{
cpp_buffer *buffer = pfile->buffer;
bool more = false;
buffer->saved_flags = BOL;
if (CPP_OPTION (pfile, traditional))
{
if (pfile->state.in_directive)
return false;
_cpp_remove_overlay (pfile);
more = _cpp_read_logical_line_trad (pfile);
_cpp_overlay_buffer (pfile, pfile->out.base,
pfile->out.cur - pfile->out.base);
pfile->line = pfile->out.first_line;
}
else
{
/* Stop parsing arguments with a CPP_EOF. When we finally come
back here, do the work of popping the buffer. */
if (!pfile->state.parsing_args)
{
if (buffer->cur != buffer->line_base)
{
/* Non-empty files should end in a newline. Don't warn
for command line and _Pragma buffers. */
if (!buffer->from_stage3)
cpp_error (pfile, DL_PEDWARN, "no newline at end of file");
handle_newline (pfile);
}
/* Similarly, finish an in-progress directive with CPP_EOF
before popping the buffer. */
if (!pfile->state.in_directive && buffer->prev)
{
more = !buffer->return_at_eof;
_cpp_pop_buffer (pfile);
}
}
}
return more;
}
#define IF_NEXT_IS(CHAR, THEN_TYPE, ELSE_TYPE) \
do { \
if (get_effective_char (pfile) == CHAR) \
result->type = THEN_TYPE; \
else \
{ \
BACKUP (); \
result->type = ELSE_TYPE; \
} \
} while (0)
/* Lex a token into pfile->cur_token, which is also incremented, to
get diagnostics pointing to the correct location.
Does not handle issues such as token lookahead, multiple-include
optimisation, directives, skipping etc. This function is only
suitable for use by _cpp_lex_token, and in special cases like
lex_expansion_token which doesn't care for any of these issues.
When meeting a newline, returns CPP_EOF if parsing a directive,
otherwise returns to the start of the token buffer if permissible.
Returns the location of the lexed token. */
cpp_token *
_cpp_lex_direct (pfile)
cpp_reader *pfile;
{
cppchar_t c;
cpp_buffer *buffer;
const unsigned char *comment_start;
cpp_token *result = pfile->cur_token++;
fresh_line:
buffer = pfile->buffer;
result->flags = buffer->saved_flags;
buffer->saved_flags = 0;
update_tokens_line:
result->line = pfile->line;
skipped_white:
c = *buffer->cur++;
result->col = CPP_BUF_COLUMN (buffer, buffer->cur);
trigraph:
switch (c)
{
case ' ': case '\t': case '\f': case '\v': case '\0':
result->flags |= PREV_WHITE;
if (skip_whitespace (pfile, c))
goto skipped_white;
/* End of buffer. */
buffer->cur--;
if (continue_after_nul (pfile))
goto fresh_line;
result->type = CPP_EOF;
break;
case '\n': case '\r':
handle_newline (pfile);
buffer->saved_flags = BOL;
if (! pfile->state.in_directive)
{
if (pfile->state.parsing_args == 2)
buffer->saved_flags |= PREV_WHITE;
if (!pfile->keep_tokens)
{
pfile->cur_run = &pfile->base_run;
result = pfile->base_run.base;
pfile->cur_token = result + 1;
}
goto fresh_line;
}
result->type = CPP_EOF;
break;
case '?':
case '\\':
/* These could start an escaped newline, or '?' a trigraph. Let
skip_escaped_newlines do all the work. */
{
unsigned int line = pfile->line;
c = skip_escaped_newlines (pfile);
if (line != pfile->line)
{
buffer->cur--;
/* We had at least one escaped newline of some sort.
Update the token's line and column. */
goto update_tokens_line;
}
}
/* We are either the original '?' or '\\', or a trigraph. */
if (c == '?')
result->type = CPP_QUERY;
else if (c == '\\')
goto random_char;
else
goto trigraph;
break;
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9':
result->type = CPP_NUMBER;
parse_number (pfile, &result->val.str, 0);
break;
case 'L':
/* 'L' may introduce wide characters or strings. */
{
const unsigned char *pos = buffer->cur;
c = get_effective_char (pfile);
if (c == '\'' || c == '"')
{
result->type = (c == '"' ? CPP_WSTRING: CPP_WCHAR);
parse_string (pfile, result, c);
break;
}
buffer->cur = pos;
}
/* Fall through. */
start_ident:
case '_':
case 'a': case 'b': case 'c': case 'd': case 'e': case 'f':
case 'g': case 'h': case 'i': case 'j': case 'k': case 'l':
case 'm': case 'n': case 'o': case 'p': case 'q': case 'r':
case 's': case 't': case 'u': case 'v': case 'w': case 'x':
case 'y': case 'z':
case 'A': case 'B': case 'C': case 'D': case 'E': case 'F':
case 'G': case 'H': case 'I': case 'J': case 'K':
case 'M': case 'N': case 'O': case 'P': case 'Q': case 'R':
case 'S': case 'T': case 'U': case 'V': case 'W': case 'X':
case 'Y': case 'Z':
result->type = CPP_NAME;
result->val.node = parse_identifier (pfile);
/* Convert named operators to their proper types. */
if (result->val.node->flags & NODE_OPERATOR)
{
result->flags |= NAMED_OP;
result->type = result->val.node->value.operator;
}
break;
case '\'':
case '"':
result->type = c == '"' ? CPP_STRING: CPP_CHAR;
parse_string (pfile, result, c);
break;
case '/':
/* A potential block or line comment. */
comment_start = buffer->cur;
c = get_effective_char (pfile);
if (c == '*')
{
if (skip_block_comment (pfile))
cpp_error (pfile, DL_ERROR, "unterminated comment");
}
else if (c == '/' && (CPP_OPTION (pfile, cplusplus_comments)
|| CPP_IN_SYSTEM_HEADER (pfile)))
{
/* Warn about comments only if pedantically GNUC89, and not
in system headers. */
if (CPP_OPTION (pfile, lang) == CLK_GNUC89 && CPP_PEDANTIC (pfile)
&& ! buffer->warned_cplusplus_comments)
{
cpp_error (pfile, DL_PEDWARN,
"C++ style comments are not allowed in ISO C90");
cpp_error (pfile, DL_PEDWARN,
"(this will be reported only once per input file)");
buffer->warned_cplusplus_comments = 1;
}
if (skip_line_comment (pfile) && CPP_OPTION (pfile, warn_comments))
cpp_error (pfile, DL_WARNING, "multi-line comment");
}
else if (c == '=')
{
result->type = CPP_DIV_EQ;
break;
}
else
{
BACKUP ();
result->type = CPP_DIV;
break;
}
if (!pfile->state.save_comments)
{
result->flags |= PREV_WHITE;
goto update_tokens_line;
}
/* Save the comment as a token in its own right. */
save_comment (pfile, result, comment_start, c);
break;
case '<':
if (pfile->state.angled_headers)
{
result->type = CPP_HEADER_NAME;
parse_string (pfile, result, '>');
break;
}
c = get_effective_char (pfile);
if (c == '=')
result->type = CPP_LESS_EQ;
else if (c == '<')
IF_NEXT_IS ('=', CPP_LSHIFT_EQ, CPP_LSHIFT);
else if (c == '?' && CPP_OPTION (pfile, cplusplus))
IF_NEXT_IS ('=', CPP_MIN_EQ, CPP_MIN);
else if (c == ':' && CPP_OPTION (pfile, digraphs))
{
result->type = CPP_OPEN_SQUARE;
result->flags |= DIGRAPH;
}
else if (c == '%' && CPP_OPTION (pfile, digraphs))
{
result->type = CPP_OPEN_BRACE;
result->flags |= DIGRAPH;
}
else
{
BACKUP ();
result->type = CPP_LESS;
}
break;
case '>':
c = get_effective_char (pfile);
if (c == '=')
result->type = CPP_GREATER_EQ;
else if (c == '>')
IF_NEXT_IS ('=', CPP_RSHIFT_EQ, CPP_RSHIFT);
else if (c == '?' && CPP_OPTION (pfile, cplusplus))
IF_NEXT_IS ('=', CPP_MAX_EQ, CPP_MAX);
else
{
BACKUP ();
result->type = CPP_GREATER;
}
break;
case '%':
c = get_effective_char (pfile);
if (c == '=')
result->type = CPP_MOD_EQ;
else if (CPP_OPTION (pfile, digraphs) && c == ':')
{
result->flags |= DIGRAPH;
result->type = CPP_HASH;
if (get_effective_char (pfile) == '%')
{
const unsigned char *pos = buffer->cur;
if (get_effective_char (pfile) == ':')
result->type = CPP_PASTE;
else
buffer->cur = pos - 1;
}
else
BACKUP ();
}
else if (CPP_OPTION (pfile, digraphs) && c == '>')
{
result->flags |= DIGRAPH;
result->type = CPP_CLOSE_BRACE;
}
else
{
BACKUP ();
result->type = CPP_MOD;
}
break;
case '.':
result->type = CPP_DOT;
c = get_effective_char (pfile);
if (c == '.')
{
const unsigned char *pos = buffer->cur;
if (get_effective_char (pfile) == '.')
result->type = CPP_ELLIPSIS;
else
buffer->cur = pos - 1;
}
/* All known character sets have 0...9 contiguous. */
else if (ISDIGIT (c))
{
result->type = CPP_NUMBER;
parse_number (pfile, &result->val.str, 1);
}
else if (c == '*' && CPP_OPTION (pfile, cplusplus))
result->type = CPP_DOT_STAR;
else
BACKUP ();
break;
case '+':
c = get_effective_char (pfile);
if (c == '+')
result->type = CPP_PLUS_PLUS;
else if (c == '=')
result->type = CPP_PLUS_EQ;
else
{
BACKUP ();
result->type = CPP_PLUS;
}
break;
case '-':
c = get_effective_char (pfile);
if (c == '>')
{
result->type = CPP_DEREF;
if (CPP_OPTION (pfile, cplusplus))
{
if (get_effective_char (pfile) == '*')
result->type = CPP_DEREF_STAR;
else
BACKUP ();
}
}
else if (c == '-')
result->type = CPP_MINUS_MINUS;
else if (c == '=')
result->type = CPP_MINUS_EQ;
else
{
BACKUP ();
result->type = CPP_MINUS;
}
break;
case '&':
c = get_effective_char (pfile);
if (c == '&')
result->type = CPP_AND_AND;
else if (c == '=')
result->type = CPP_AND_EQ;
else
{
BACKUP ();
result->type = CPP_AND;
}
break;
case '|':
c = get_effective_char (pfile);
if (c == '|')
result->type = CPP_OR_OR;
else if (c == '=')
result->type = CPP_OR_EQ;
else
{
BACKUP ();
result->type = CPP_OR;
}
break;
case ':':
c = get_effective_char (pfile);
if (c == ':' && CPP_OPTION (pfile, cplusplus))
result->type = CPP_SCOPE;
else if (c == '>' && CPP_OPTION (pfile, digraphs))
{
result->flags |= DIGRAPH;
result->type = CPP_CLOSE_SQUARE;
}
else
{
BACKUP ();
result->type = CPP_COLON;
}
break;
case '*': IF_NEXT_IS ('=', CPP_MULT_EQ, CPP_MULT); break;
case '=': IF_NEXT_IS ('=', CPP_EQ_EQ, CPP_EQ); break;
case '!': IF_NEXT_IS ('=', CPP_NOT_EQ, CPP_NOT); break;
case '^': IF_NEXT_IS ('=', CPP_XOR_EQ, CPP_XOR); break;
case '#': IF_NEXT_IS ('#', CPP_PASTE, CPP_HASH); break;
case '~': result->type = CPP_COMPL; break;
case ',': result->type = CPP_COMMA; break;
case '(': result->type = CPP_OPEN_PAREN; break;
case ')': result->type = CPP_CLOSE_PAREN; break;
case '[': result->type = CPP_OPEN_SQUARE; break;
case ']': result->type = CPP_CLOSE_SQUARE; break;
case '{': result->type = CPP_OPEN_BRACE; break;
case '}': result->type = CPP_CLOSE_BRACE; break;
case ';': result->type = CPP_SEMICOLON; break;
/* @ is a punctuator in Objective-C. */
case '@': result->type = CPP_ATSIGN; break;
case '$':
if (CPP_OPTION (pfile, dollars_in_ident))
goto start_ident;
/* Fall through... */
random_char:
default:
result->type = CPP_OTHER;
result->val.c = c;
break;
}
return result;
}
/* An upper bound on the number of bytes needed to spell TOKEN,
including preceding whitespace. */
unsigned int
cpp_token_len (token)
const cpp_token *token;
{
unsigned int len;
switch (TOKEN_SPELL (token))
{
default: len = 0; break;
case SPELL_NUMBER:
case SPELL_STRING: len = token->val.str.len; break;
case SPELL_IDENT: len = NODE_LEN (token->val.node); break;
}
/* 1 for whitespace, 4 for comment delimiters. */
return len + 5;
}
/* Write the spelling of a token TOKEN to BUFFER. The buffer must
already contain the enough space to hold the token's spelling.
Returns a pointer to the character after the last character
written. */
unsigned char *
cpp_spell_token (pfile, token, buffer)
cpp_reader *pfile; /* Would be nice to be rid of this... */
const cpp_token *token;
unsigned char *buffer;
{
switch (TOKEN_SPELL (token))
{
case SPELL_OPERATOR:
{
const unsigned char *spelling;
unsigned char c;
if (token->flags & DIGRAPH)
spelling
= digraph_spellings[(int) token->type - (int) CPP_FIRST_DIGRAPH];
else if (token->flags & NAMED_OP)
goto spell_ident;
else
spelling = TOKEN_NAME (token);
while ((c = *spelling++) != '\0')
*buffer++ = c;
}
break;
case SPELL_CHAR:
*buffer++ = token->val.c;
break;
spell_ident:
case SPELL_IDENT:
memcpy (buffer, NODE_NAME (token->val.node), NODE_LEN (token->val.node));
buffer += NODE_LEN (token->val.node);
break;
case SPELL_NUMBER:
memcpy (buffer, token->val.str.text, token->val.str.len);
buffer += token->val.str.len;
break;
case SPELL_STRING:
{
int left, right, tag;
switch (token->type)
{
case CPP_STRING: left = '"'; right = '"'; tag = '\0'; break;
case CPP_WSTRING: left = '"'; right = '"'; tag = 'L'; break;
case CPP_CHAR: left = '\''; right = '\''; tag = '\0'; break;
case CPP_WCHAR: left = '\''; right = '\''; tag = 'L'; break;
case CPP_HEADER_NAME: left = '<'; right = '>'; tag = '\0'; break;
default:
cpp_error (pfile, DL_ICE, "unknown string token %s\n",
TOKEN_NAME (token));
return buffer;
}
if (tag) *buffer++ = tag;
*buffer++ = left;
memcpy (buffer, token->val.str.text, token->val.str.len);
buffer += token->val.str.len;
*buffer++ = right;
}
break;
case SPELL_NONE:
cpp_error (pfile, DL_ICE, "unspellable token %s", TOKEN_NAME (token));
break;
}
return buffer;
}
/* Returns TOKEN spelt as a null-terminated string. The string is
freed when the reader is destroyed. Useful for diagnostics. */
unsigned char *
cpp_token_as_text (pfile, token)
cpp_reader *pfile;
const cpp_token *token;
{
unsigned int len = cpp_token_len (token);
unsigned char *start = _cpp_unaligned_alloc (pfile, len), *end;
end = cpp_spell_token (pfile, token, start);
end[0] = '\0';
return start;
}
/* Used by C front ends, which really should move to using
cpp_token_as_text. */
const char *
cpp_type2name (type)
enum cpp_ttype type;
{
return (const char *) token_spellings[type].name;
}
/* Writes the spelling of token to FP, without any preceding space.
Separated from cpp_spell_token for efficiency - to avoid stdio
double-buffering. */
void
cpp_output_token (token, fp)
const cpp_token *token;
FILE *fp;
{
switch (TOKEN_SPELL (token))
{
case SPELL_OPERATOR:
{
const unsigned char *spelling;
int c;
if (token->flags & DIGRAPH)
spelling
= digraph_spellings[(int) token->type - (int) CPP_FIRST_DIGRAPH];
else if (token->flags & NAMED_OP)
goto spell_ident;
else
spelling = TOKEN_NAME (token);
c = *spelling;
do
putc (c, fp);
while ((c = *++spelling) != '\0');
}
break;
case SPELL_CHAR:
putc (token->val.c, fp);
break;
spell_ident:
case SPELL_IDENT:
fwrite (NODE_NAME (token->val.node), 1, NODE_LEN (token->val.node), fp);
break;
case SPELL_NUMBER:
fwrite (token->val.str.text, 1, token->val.str.len, fp);
break;
case SPELL_STRING:
{
int left, right, tag;
switch (token->type)
{
case CPP_STRING: left = '"'; right = '"'; tag = '\0'; break;
case CPP_WSTRING: left = '"'; right = '"'; tag = 'L'; break;
case CPP_CHAR: left = '\''; right = '\''; tag = '\0'; break;
case CPP_WCHAR: left = '\''; right = '\''; tag = 'L'; break;
case CPP_HEADER_NAME: left = '<'; right = '>'; tag = '\0'; break;
default:
fprintf (stderr, "impossible STRING token %s\n", TOKEN_NAME (token));
return;
}
if (tag) putc (tag, fp);
putc (left, fp);
fwrite (token->val.str.text, 1, token->val.str.len, fp);
putc (right, fp);
}
break;
case SPELL_NONE:
/* An error, most probably. */
break;
}
}
/* Compare two tokens. */
int
_cpp_equiv_tokens (a, b)
const cpp_token *a, *b;
{
if (a->type == b->type && a->flags == b->flags)
switch (TOKEN_SPELL (a))
{
default: /* Keep compiler happy. */
case SPELL_OPERATOR:
return 1;
case SPELL_CHAR:
return a->val.c == b->val.c; /* Character. */
case SPELL_NONE:
return (a->type != CPP_MACRO_ARG || a->val.arg_no == b->val.arg_no);
case SPELL_IDENT:
return a->val.node == b->val.node;
case SPELL_NUMBER:
case SPELL_STRING:
return (a->val.str.len == b->val.str.len
&& !memcmp (a->val.str.text, b->val.str.text,
a->val.str.len));
}
return 0;
}
/* Returns nonzero if a space should be inserted to avoid an
accidental token paste for output. For simplicity, it is
conservative, and occasionally advises a space where one is not
needed, e.g. "." and ".2". */
int
cpp_avoid_paste (pfile, token1, token2)
cpp_reader *pfile;
const cpp_token *token1, *token2;
{
enum cpp_ttype a = token1->type, b = token2->type;
cppchar_t c;
if (token1->flags & NAMED_OP)
a = CPP_NAME;
if (token2->flags & NAMED_OP)
b = CPP_NAME;
c = EOF;
if (token2->flags & DIGRAPH)
c = digraph_spellings[(int) b - (int) CPP_FIRST_DIGRAPH][0];
else if (token_spellings[b].category == SPELL_OPERATOR)
c = token_spellings[b].name[0];
/* Quickly get everything that can paste with an '='. */
if ((int) a <= (int) CPP_LAST_EQ && c == '=')
return 1;
switch (a)
{
case CPP_GREATER: return c == '>' || c == '?';
case CPP_LESS: return c == '<' || c == '?' || c == '%' || c == ':';
case CPP_PLUS: return c == '+';
case CPP_MINUS: return c == '-' || c == '>';
case CPP_DIV: return c == '/' || c == '*'; /* Comments. */
case CPP_MOD: return c == ':' || c == '>';
case CPP_AND: return c == '&';
case CPP_OR: return c == '|';
case CPP_COLON: return c == ':' || c == '>';
case CPP_DEREF: return c == '*';
case CPP_DOT: return c == '.' || c == '%' || b == CPP_NUMBER;
case CPP_HASH: return c == '#' || c == '%'; /* Digraph form. */
case CPP_NAME: return ((b == CPP_NUMBER
&& name_p (pfile, &token2->val.str))
|| b == CPP_NAME
|| b == CPP_CHAR || b == CPP_STRING); /* L */
case CPP_NUMBER: return (b == CPP_NUMBER || b == CPP_NAME
|| c == '.' || c == '+' || c == '-');
case CPP_OTHER: return (CPP_OPTION (pfile, objc)
&& token1->val.c == '@'
&& (b == CPP_NAME || b == CPP_STRING));
default: break;
}
return 0;
}
/* Output all the remaining tokens on the current line, and a newline
character, to FP. Leading whitespace is removed. If there are
macros, special token padding is not performed. */
void
cpp_output_line (pfile, fp)
cpp_reader *pfile;
FILE *fp;
{
const cpp_token *token;
token = cpp_get_token (pfile);
while (token->type != CPP_EOF)
{
cpp_output_token (token, fp);
token = cpp_get_token (pfile);
if (token->flags & PREV_WHITE)
putc (' ', fp);
}
putc ('\n', fp);
}
/* Returns the value of a hexadecimal digit. */
static unsigned int
hex_digit_value (c)
unsigned int c;
{
if (hex_p (c))
return hex_value (c);
else
abort ();
}
/* Parse a '\uNNNN' or '\UNNNNNNNN' sequence. Returns 1 to indicate
failure if cpplib is not parsing C++ or C99. Such failure is
silent, and no variables are updated. Otherwise returns 0, and
warns if -Wtraditional.
[lex.charset]: The character designated by the universal character
name \UNNNNNNNN is that character whose character short name in
ISO/IEC 10646 is NNNNNNNN; the character designated by the
universal character name \uNNNN is that character whose character
short name in ISO/IEC 10646 is 0000NNNN. If the hexadecimal value
for a universal character name is less than 0x20 or in the range
0x7F-0x9F (inclusive), or if the universal character name
designates a character in the basic source character set, then the
program is ill-formed.
We assume that wchar_t is Unicode, so we don't need to do any
mapping. Is this ever wrong?
PC points to the 'u' or 'U', PSTR is points to the byte after PC,
LIMIT is the end of the string or charconst. PSTR is updated to
point after the UCS on return, and the UCS is written into PC. */
static int
maybe_read_ucs (pfile, pstr, limit, pc)
cpp_reader *pfile;
const unsigned char **pstr;
const unsigned char *limit;
cppchar_t *pc;
{
const unsigned char *p = *pstr;
unsigned int code = 0;
unsigned int c = *pc, length;
/* Only attempt to interpret a UCS for C++ and C99. */
if (! (CPP_OPTION (pfile, cplusplus) || CPP_OPTION (pfile, c99)))
return 1;
if (CPP_WTRADITIONAL (pfile))
cpp_error (pfile, DL_WARNING,
"the meaning of '\\%c' is different in traditional C", c);
length = (c == 'u' ? 4: 8);
if ((size_t) (limit - p) < length)
{
cpp_error (pfile, DL_ERROR, "incomplete universal-character-name");
/* Skip to the end to avoid more diagnostics. */
p = limit;
}
else
{
for (; length; length--, p++)
{
c = *p;
if (ISXDIGIT (c))
code = (code << 4) + hex_digit_value (c);
else
{
cpp_error (pfile, DL_ERROR,
"non-hex digit '%c' in universal-character-name", c);
/* We shouldn't skip in case there are multibyte chars. */
break;
}
}
}
#ifdef TARGET_EBCDIC
cpp_error (pfile, DL_ERROR, "universal-character-name on EBCDIC target");
code = 0x3f; /* EBCDIC invalid character */
#else
/* True extended characters are OK. */
if (code >= 0xa0
&& !(code & 0x80000000)
&& !(code >= 0xD800 && code <= 0xDFFF))
;
/* The standard permits $, @ and ` to be specified as UCNs. We use
hex escapes so that this also works with EBCDIC hosts. */
else if (code == 0x24 || code == 0x40 || code == 0x60)
;
/* Don't give another error if one occurred above. */
else if (length == 0)
cpp_error (pfile, DL_ERROR, "universal-character-name out of range");
#endif
*pstr = p;
*pc = code;
return 0;
}
/* Returns the value of an escape sequence, truncated to the correct
target precision. PSTR points to the input pointer, which is just
after the backslash. LIMIT is how much text we have. WIDE is true
if the escape sequence is part of a wide character constant or
string literal. Handles all relevant diagnostics. */
cppchar_t
cpp_parse_escape (pfile, pstr, limit, wide)
cpp_reader *pfile;
const unsigned char **pstr;
const unsigned char *limit;
int wide;
{
int unknown = 0;
const unsigned char *str = *pstr;
cppchar_t c, mask;
unsigned int width;
if (wide)
width = CPP_OPTION (pfile, wchar_precision);
else
width = CPP_OPTION (pfile, char_precision);
if (width < BITS_PER_CPPCHAR_T)
mask = ((cppchar_t) 1 << width) - 1;
else
mask = ~0;
c = *str++;
switch (c)
{
case '\\': case '\'': case '"': case '?': break;
case 'b': c = TARGET_BS; break;
case 'f': c = TARGET_FF; break;
case 'n': c = TARGET_NEWLINE; break;
case 'r': c = TARGET_CR; break;
case 't': c = TARGET_TAB; break;
case 'v': c = TARGET_VT; break;
case '(': case '{': case '[': case '%':
/* '\(', etc, are used at beginning of line to avoid confusing Emacs.
'\%' is used to prevent SCCS from getting confused. */
unknown = CPP_PEDANTIC (pfile);
break;
case 'a':
if (CPP_WTRADITIONAL (pfile))
cpp_error (pfile, DL_WARNING,
"the meaning of '\\a' is different in traditional C");
c = TARGET_BELL;
break;
case 'e': case 'E':
if (CPP_PEDANTIC (pfile))
cpp_error (pfile, DL_PEDWARN,
"non-ISO-standard escape sequence, '\\%c'", (int) c);
c = TARGET_ESC;
break;
case 'u': case 'U':
unknown = maybe_read_ucs (pfile, &str, limit, &c);
break;
case 'x':
if (CPP_WTRADITIONAL (pfile))
cpp_error (pfile, DL_WARNING,
"the meaning of '\\x' is different in traditional C");
{
cppchar_t i = 0, overflow = 0;
int digits_found = 0;
while (str < limit)
{
c = *str;
if (! ISXDIGIT (c))
break;
str++;
overflow |= i ^ (i << 4 >> 4);
i = (i << 4) + hex_digit_value (c);
digits_found = 1;
}
if (!digits_found)
cpp_error (pfile, DL_ERROR,
"\\x used with no following hex digits");
if (overflow | (i != (i & mask)))
{
cpp_error (pfile, DL_PEDWARN,
"hex escape sequence out of range");
i &= mask;
}
c = i;
}
break;
case '0': case '1': case '2': case '3':
case '4': case '5': case '6': case '7':
{
size_t count = 0;
cppchar_t i = c - '0';
while (str < limit && ++count < 3)
{
c = *str;
if (c < '0' || c > '7')
break;
str++;
i = (i << 3) + c - '0';
}
if (i != (i & mask))
{
cpp_error (pfile, DL_PEDWARN,
"octal escape sequence out of range");
i &= mask;
}
c = i;
}
break;
default:
unknown = 1;
break;
}
if (unknown)
{
if (ISGRAPH (c))
cpp_error (pfile, DL_PEDWARN,
"unknown escape sequence '\\%c'", (int) c);
else
cpp_error (pfile, DL_PEDWARN,
"unknown escape sequence: '\\%03o'", (int) c);
}
if (c > mask)
{
cpp_error (pfile, DL_PEDWARN, "escape sequence out of range for its type");
c &= mask;
}
*pstr = str;
return c;
}
/* Interpret a (possibly wide) character constant in TOKEN.
WARN_MULTI warns about multi-character charconsts. PCHARS_SEEN
points to a variable that is filled in with the number of
characters seen, and UNSIGNEDP to a variable that indicates whether
the result has signed type. */
cppchar_t
cpp_interpret_charconst (pfile, token, pchars_seen, unsignedp)
cpp_reader *pfile;
const cpp_token *token;
unsigned int *pchars_seen;
int *unsignedp;
{
const unsigned char *str = token->val.str.text;
const unsigned char *limit = str + token->val.str.len;
unsigned int chars_seen = 0;
size_t width, max_chars;
cppchar_t c, mask, result = 0;
bool unsigned_p;
#ifdef MULTIBYTE_CHARS
(void) local_mbtowc (NULL, NULL, 0);
#endif
/* Width in bits. */
if (token->type == CPP_CHAR)
{
width = CPP_OPTION (pfile, char_precision);
max_chars = CPP_OPTION (pfile, int_precision) / width;
unsigned_p = CPP_OPTION (pfile, unsigned_char);
}
else
{
width = CPP_OPTION (pfile, wchar_precision);
max_chars = 1;
unsigned_p = CPP_OPTION (pfile, unsigned_wchar);
}
if (width < BITS_PER_CPPCHAR_T)
mask = ((cppchar_t) 1 << width) - 1;
else
mask = ~0;
while (str < limit)
{
#ifdef MULTIBYTE_CHARS
wchar_t wc;
int char_len;
char_len = local_mbtowc (&wc, str, limit - str);
if (char_len == -1)
{
cpp_error (pfile, DL_WARNING,
"ignoring invalid multibyte character");
c = *str++;
}
else
{
str += char_len;
c = wc;
}
#else
c = *str++;
#endif
if (c == '\\')
c = cpp_parse_escape (pfile, &str, limit, token->type == CPP_WCHAR);
#ifdef MAP_CHARACTER
if (ISPRINT (c))
c = MAP_CHARACTER (c);
#endif
chars_seen++;
/* Truncate the character, scale the result and merge the two. */
c &= mask;
if (width < BITS_PER_CPPCHAR_T)
result = (result << width) | c;
else
result = c;
}
if (chars_seen == 0)
cpp_error (pfile, DL_ERROR, "empty character constant");
else if (chars_seen > 1)
{
/* Multichar charconsts are of type int and therefore signed. */
unsigned_p = 0;
if (chars_seen > max_chars)
{
chars_seen = max_chars;
cpp_error (pfile, DL_WARNING,
"character constant too long for its type");
}
else if (CPP_OPTION (pfile, warn_multichar))
cpp_error (pfile, DL_WARNING, "multi-character character constant");
}
/* Sign-extend or truncate the constant to cppchar_t. The value is
in WIDTH bits, but for multi-char charconsts it's value is the
full target type's width. */
if (chars_seen > 1)
width *= max_chars;
if (width < BITS_PER_CPPCHAR_T)
{
mask = ((cppchar_t) 1 << width) - 1;
if (unsigned_p || !(result & (1 << (width - 1))))
result &= mask;
else
result |= ~mask;
}
*pchars_seen = chars_seen;
*unsignedp = unsigned_p;
return result;
}
/* Memory buffers. Changing these three constants can have a dramatic
effect on performance. The values here are reasonable defaults,
but might be tuned. If you adjust them, be sure to test across a
range of uses of cpplib, including heavy nested function-like macro
expansion. Also check the change in peak memory usage (NJAMD is a
good tool for this). */
#define MIN_BUFF_SIZE 8000
#define BUFF_SIZE_UPPER_BOUND(MIN_SIZE) (MIN_BUFF_SIZE + (MIN_SIZE) * 3 / 2)
#define EXTENDED_BUFF_SIZE(BUFF, MIN_EXTRA) \
(MIN_EXTRA + ((BUFF)->limit - (BUFF)->cur) * 2)
#if MIN_BUFF_SIZE > BUFF_SIZE_UPPER_BOUND (0)
#error BUFF_SIZE_UPPER_BOUND must be at least as large as MIN_BUFF_SIZE!
#endif
/* Create a new allocation buffer. Place the control block at the end
of the buffer, so that buffer overflows will cause immediate chaos. */
static _cpp_buff *
new_buff (len)
size_t len;
{
_cpp_buff *result;
unsigned char *base;
if (len < MIN_BUFF_SIZE)
len = MIN_BUFF_SIZE;
len = CPP_ALIGN (len);
base = xmalloc (len + sizeof (_cpp_buff));
result = (_cpp_buff *) (base + len);
result->base = base;
result->cur = base;
result->limit = base + len;
result->next = NULL;
return result;
}
/* Place a chain of unwanted allocation buffers on the free list. */
void
_cpp_release_buff (pfile, buff)
cpp_reader *pfile;
_cpp_buff *buff;
{
_cpp_buff *end = buff;
while (end->next)
end = end->next;
end->next = pfile->free_buffs;
pfile->free_buffs = buff;
}
/* Return a free buffer of size at least MIN_SIZE. */
_cpp_buff *
_cpp_get_buff (pfile, min_size)
cpp_reader *pfile;
size_t min_size;
{
_cpp_buff *result, **p;
for (p = &pfile->free_buffs;; p = &(*p)->next)
{
size_t size;
if (*p == NULL)
return new_buff (min_size);
result = *p;
size = result->limit - result->base;
/* Return a buffer that's big enough, but don't waste one that's
way too big. */
if (size >= min_size && size <= BUFF_SIZE_UPPER_BOUND (min_size))
break;
}
*p = result->next;
result->next = NULL;
result->cur = result->base;
return result;
}
/* Creates a new buffer with enough space to hold the uncommitted
remaining bytes of BUFF, and at least MIN_EXTRA more bytes. Copies
the excess bytes to the new buffer. Chains the new buffer after
BUFF, and returns the new buffer. */
_cpp_buff *
_cpp_append_extend_buff (pfile, buff, min_extra)
cpp_reader *pfile;
_cpp_buff *buff;
size_t min_extra;
{
size_t size = EXTENDED_BUFF_SIZE (buff, min_extra);
_cpp_buff *new_buff = _cpp_get_buff (pfile, size);
buff->next = new_buff;
memcpy (new_buff->base, buff->cur, BUFF_ROOM (buff));
return new_buff;
}
/* Creates a new buffer with enough space to hold the uncommitted
remaining bytes of the buffer pointed to by BUFF, and at least
MIN_EXTRA more bytes. Copies the excess bytes to the new buffer.
Chains the new buffer before the buffer pointed to by BUFF, and
updates the pointer to point to the new buffer. */
void
_cpp_extend_buff (pfile, pbuff, min_extra)
cpp_reader *pfile;
_cpp_buff **pbuff;
size_t min_extra;
{
_cpp_buff *new_buff, *old_buff = *pbuff;
size_t size = EXTENDED_BUFF_SIZE (old_buff, min_extra);
new_buff = _cpp_get_buff (pfile, size);
memcpy (new_buff->base, old_buff->cur, BUFF_ROOM (old_buff));
new_buff->next = old_buff;
*pbuff = new_buff;
}
/* Free a chain of buffers starting at BUFF. */
void
_cpp_free_buff (buff)
_cpp_buff *buff;
{
_cpp_buff *next;
for (; buff; buff = next)
{
next = buff->next;
free (buff->base);
}
}
/* Allocate permanent, unaligned storage of length LEN. */
unsigned char *
_cpp_unaligned_alloc (pfile, len)
cpp_reader *pfile;
size_t len;
{
_cpp_buff *buff = pfile->u_buff;
unsigned char *result = buff->cur;
if (len > (size_t) (buff->limit - result))
{
buff = _cpp_get_buff (pfile, len);
buff->next = pfile->u_buff;
pfile->u_buff = buff;
result = buff->cur;
}
buff->cur = result + len;
return result;
}
/* Allocate permanent, unaligned storage of length LEN from a_buff.
That buffer is used for growing allocations when saving macro
replacement lists in a #define, and when parsing an answer to an
assertion in #assert, #unassert or #if (and therefore possibly
whilst expanding macros). It therefore must not be used by any
code that they might call: specifically the lexer and the guts of
the macro expander.
All existing other uses clearly fit this restriction: storing
registered pragmas during initialization. */
unsigned char *
_cpp_aligned_alloc (pfile, len)
cpp_reader *pfile;
size_t len;
{
_cpp_buff *buff = pfile->a_buff;
unsigned char *result = buff->cur;
if (len > (size_t) (buff->limit - result))
{
buff = _cpp_get_buff (pfile, len);
buff->next = pfile->a_buff;
pfile->a_buff = buff;
result = buff->cur;
}
buff->cur = result + len;
return result;
}