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/* C++ Parser.
Copyright (C) 2000, 2001, 2002, 2003 Free Software Foundation, Inc.
Written by Mark Mitchell <mark@codesourcery.com>.
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. */
#include "config.h"
#include "system.h"
#include "coretypes.h"
#include "tm.h"
#include "dyn-string.h"
#include "varray.h"
#include "cpplib.h"
#include "tree.h"
#include "cp-tree.h"
#include "c-pragma.h"
#include "decl.h"
#include "flags.h"
#include "diagnostic.h"
#include "toplev.h"
#include "output.h"
/* The lexer. */
/* Overview
--------
A cp_lexer represents a stream of cp_tokens. It allows arbitrary
look-ahead.
Methodology
-----------
We use a circular buffer to store incoming tokens.
Some artifacts of the C++ language (such as the
expression/declaration ambiguity) require arbitrary look-ahead.
The strategy we adopt for dealing with these problems is to attempt
to parse one construct (e.g., the declaration) and fall back to the
other (e.g., the expression) if that attempt does not succeed.
Therefore, we must sometimes store an arbitrary number of tokens.
The parser routinely peeks at the next token, and then consumes it
later. That also requires a buffer in which to store the tokens.
In order to easily permit adding tokens to the end of the buffer,
while removing them from the beginning of the buffer, we use a
circular buffer. */
/* A C++ token. */
typedef struct cp_token GTY (())
{
/* The kind of token. */
enum cpp_ttype type;
/* The value associated with this token, if any. */
tree value;
/* If this token is a keyword, this value indicates which keyword.
Otherwise, this value is RID_MAX. */
enum rid keyword;
/* The location at which this token was found. */
location_t location;
} cp_token;
/* The number of tokens in a single token block. */
#define CP_TOKEN_BLOCK_NUM_TOKENS 32
/* A group of tokens. These groups are chained together to store
large numbers of tokens. (For example, a token block is created
when the body of an inline member function is first encountered;
the tokens are processed later after the class definition is
complete.)
This somewhat ungainly data structure (as opposed to, say, a
variable-length array), is used due to contraints imposed by the
current garbage-collection methodology. If it is made more
flexible, we could perhaps simplify the data structures involved. */
typedef struct cp_token_block GTY (())
{
/* The tokens. */
cp_token tokens[CP_TOKEN_BLOCK_NUM_TOKENS];
/* The number of tokens in this block. */
size_t num_tokens;
/* The next token block in the chain. */
struct cp_token_block *next;
/* The previous block in the chain. */
struct cp_token_block *prev;
} cp_token_block;
typedef struct cp_token_cache GTY (())
{
/* The first block in the cache. NULL if there are no tokens in the
cache. */
cp_token_block *first;
/* The last block in the cache. NULL If there are no tokens in the
cache. */
cp_token_block *last;
} cp_token_cache;
/* Prototypes. */
static cp_token_cache *cp_token_cache_new
(void);
static void cp_token_cache_push_token
(cp_token_cache *, cp_token *);
/* Create a new cp_token_cache. */
static cp_token_cache *
cp_token_cache_new ()
{
return (cp_token_cache *) ggc_alloc_cleared (sizeof (cp_token_cache));
}
/* Add *TOKEN to *CACHE. */
static void
cp_token_cache_push_token (cp_token_cache *cache,
cp_token *token)
{
cp_token_block *b = cache->last;
/* See if we need to allocate a new token block. */
if (!b || b->num_tokens == CP_TOKEN_BLOCK_NUM_TOKENS)
{
b = ((cp_token_block *) ggc_alloc_cleared (sizeof (cp_token_block)));
b->prev = cache->last;
if (cache->last)
{
cache->last->next = b;
cache->last = b;
}
else
cache->first = cache->last = b;
}
/* Add this token to the current token block. */
b->tokens[b->num_tokens++] = *token;
}
/* The cp_lexer structure represents the C++ lexer. It is responsible
for managing the token stream from the preprocessor and supplying
it to the parser. */
typedef struct cp_lexer GTY (())
{
/* The memory allocated for the buffer. Never NULL. */
cp_token * GTY ((length ("(%h.buffer_end - %h.buffer)"))) buffer;
/* A pointer just past the end of the memory allocated for the buffer. */
cp_token * GTY ((skip (""))) buffer_end;
/* The first valid token in the buffer, or NULL if none. */
cp_token * GTY ((skip (""))) first_token;
/* The next available token. If NEXT_TOKEN is NULL, then there are
no more available tokens. */
cp_token * GTY ((skip (""))) next_token;
/* A pointer just past the last available token. If FIRST_TOKEN is
NULL, however, there are no available tokens, and then this
location is simply the place in which the next token read will be
placed. If LAST_TOKEN == FIRST_TOKEN, then the buffer is full.
When the LAST_TOKEN == BUFFER, then the last token is at the
highest memory address in the BUFFER. */
cp_token * GTY ((skip (""))) last_token;
/* A stack indicating positions at which cp_lexer_save_tokens was
called. The top entry is the most recent position at which we
began saving tokens. The entries are differences in token
position between FIRST_TOKEN and the first saved token.
If the stack is non-empty, we are saving tokens. When a token is
consumed, the NEXT_TOKEN pointer will move, but the FIRST_TOKEN
pointer will not. The token stream will be preserved so that it
can be reexamined later.
If the stack is empty, then we are not saving tokens. Whenever a
token is consumed, the FIRST_TOKEN pointer will be moved, and the
consumed token will be gone forever. */
varray_type saved_tokens;
/* The STRING_CST tokens encountered while processing the current
string literal. */
varray_type string_tokens;
/* True if we should obtain more tokens from the preprocessor; false
if we are processing a saved token cache. */
bool main_lexer_p;
/* True if we should output debugging information. */
bool debugging_p;
/* The next lexer in a linked list of lexers. */
struct cp_lexer *next;
} cp_lexer;
/* Prototypes. */
static cp_lexer *cp_lexer_new_main
(void);
static cp_lexer *cp_lexer_new_from_tokens
(struct cp_token_cache *);
static int cp_lexer_saving_tokens
(const cp_lexer *);
static cp_token *cp_lexer_next_token
(cp_lexer *, cp_token *);
static ptrdiff_t cp_lexer_token_difference
(cp_lexer *, cp_token *, cp_token *);
static cp_token *cp_lexer_read_token
(cp_lexer *);
static void cp_lexer_maybe_grow_buffer
(cp_lexer *);
static void cp_lexer_get_preprocessor_token
(cp_lexer *, cp_token *);
static cp_token *cp_lexer_peek_token
(cp_lexer *);
static cp_token *cp_lexer_peek_nth_token
(cp_lexer *, size_t);
static inline bool cp_lexer_next_token_is
(cp_lexer *, enum cpp_ttype);
static bool cp_lexer_next_token_is_not
(cp_lexer *, enum cpp_ttype);
static bool cp_lexer_next_token_is_keyword
(cp_lexer *, enum rid);
static cp_token *cp_lexer_consume_token
(cp_lexer *);
static void cp_lexer_purge_token
(cp_lexer *);
static void cp_lexer_purge_tokens_after
(cp_lexer *, cp_token *);
static void cp_lexer_save_tokens
(cp_lexer *);
static void cp_lexer_commit_tokens
(cp_lexer *);
static void cp_lexer_rollback_tokens
(cp_lexer *);
static inline void cp_lexer_set_source_position_from_token
(cp_lexer *, const cp_token *);
static void cp_lexer_print_token
(FILE *, cp_token *);
static inline bool cp_lexer_debugging_p
(cp_lexer *);
static void cp_lexer_start_debugging
(cp_lexer *) ATTRIBUTE_UNUSED;
static void cp_lexer_stop_debugging
(cp_lexer *) ATTRIBUTE_UNUSED;
/* Manifest constants. */
#define CP_TOKEN_BUFFER_SIZE 5
#define CP_SAVED_TOKENS_SIZE 5
/* A token type for keywords, as opposed to ordinary identifiers. */
#define CPP_KEYWORD ((enum cpp_ttype) (N_TTYPES + 1))
/* A token type for template-ids. If a template-id is processed while
parsing tentatively, it is replaced with a CPP_TEMPLATE_ID token;
the value of the CPP_TEMPLATE_ID is whatever was returned by
cp_parser_template_id. */
#define CPP_TEMPLATE_ID ((enum cpp_ttype) (CPP_KEYWORD + 1))
/* A token type for nested-name-specifiers. If a
nested-name-specifier is processed while parsing tentatively, it is
replaced with a CPP_NESTED_NAME_SPECIFIER token; the value of the
CPP_NESTED_NAME_SPECIFIER is whatever was returned by
cp_parser_nested_name_specifier_opt. */
#define CPP_NESTED_NAME_SPECIFIER ((enum cpp_ttype) (CPP_TEMPLATE_ID + 1))
/* A token type for tokens that are not tokens at all; these are used
to mark the end of a token block. */
#define CPP_NONE (CPP_NESTED_NAME_SPECIFIER + 1)
/* Variables. */
/* The stream to which debugging output should be written. */
static FILE *cp_lexer_debug_stream;
/* Create a new main C++ lexer, the lexer that gets tokens from the
preprocessor. */
static cp_lexer *
cp_lexer_new_main (void)
{
cp_lexer *lexer;
cp_token first_token;
/* It's possible that lexing the first token will load a PCH file,
which is a GC collection point. So we have to grab the first
token before allocating any memory. */
cp_lexer_get_preprocessor_token (NULL, &first_token);
cpp_get_callbacks (parse_in)->valid_pch = NULL;
/* Allocate the memory. */
lexer = (cp_lexer *) ggc_alloc_cleared (sizeof (cp_lexer));
/* Create the circular buffer. */
lexer->buffer = ((cp_token *)
ggc_calloc (CP_TOKEN_BUFFER_SIZE, sizeof (cp_token)));
lexer->buffer_end = lexer->buffer + CP_TOKEN_BUFFER_SIZE;
/* There is one token in the buffer. */
lexer->last_token = lexer->buffer + 1;
lexer->first_token = lexer->buffer;
lexer->next_token = lexer->buffer;
memcpy (lexer->buffer, &first_token, sizeof (cp_token));
/* This lexer obtains more tokens by calling c_lex. */
lexer->main_lexer_p = true;
/* Create the SAVED_TOKENS stack. */
VARRAY_INT_INIT (lexer->saved_tokens, CP_SAVED_TOKENS_SIZE, "saved_tokens");
/* Create the STRINGS array. */
VARRAY_TREE_INIT (lexer->string_tokens, 32, "strings");
/* Assume we are not debugging. */
lexer->debugging_p = false;
return lexer;
}
/* Create a new lexer whose token stream is primed with the TOKENS.
When these tokens are exhausted, no new tokens will be read. */
static cp_lexer *
cp_lexer_new_from_tokens (cp_token_cache *tokens)
{
cp_lexer *lexer;
cp_token *token;
cp_token_block *block;
ptrdiff_t num_tokens;
/* Allocate the memory. */
lexer = (cp_lexer *) ggc_alloc_cleared (sizeof (cp_lexer));
/* Create a new buffer, appropriately sized. */
num_tokens = 0;
for (block = tokens->first; block != NULL; block = block->next)
num_tokens += block->num_tokens;
lexer->buffer = ((cp_token *) ggc_alloc (num_tokens * sizeof (cp_token)));
lexer->buffer_end = lexer->buffer + num_tokens;
/* Install the tokens. */
token = lexer->buffer;
for (block = tokens->first; block != NULL; block = block->next)
{
memcpy (token, block->tokens, block->num_tokens * sizeof (cp_token));
token += block->num_tokens;
}
/* The FIRST_TOKEN is the beginning of the buffer. */
lexer->first_token = lexer->buffer;
/* The next available token is also at the beginning of the buffer. */
lexer->next_token = lexer->buffer;
/* The buffer is full. */
lexer->last_token = lexer->first_token;
/* This lexer doesn't obtain more tokens. */
lexer->main_lexer_p = false;
/* Create the SAVED_TOKENS stack. */
VARRAY_INT_INIT (lexer->saved_tokens, CP_SAVED_TOKENS_SIZE, "saved_tokens");
/* Create the STRINGS array. */
VARRAY_TREE_INIT (lexer->string_tokens, 32, "strings");
/* Assume we are not debugging. */
lexer->debugging_p = false;
return lexer;
}
/* Returns non-zero if debugging information should be output. */
static inline bool
cp_lexer_debugging_p (cp_lexer *lexer)
{
return lexer->debugging_p;
}
/* Set the current source position from the information stored in
TOKEN. */
static inline void
cp_lexer_set_source_position_from_token (cp_lexer *lexer ATTRIBUTE_UNUSED ,
const cp_token *token)
{
/* Ideally, the source position information would not be a global
variable, but it is. */
/* Update the line number. */
if (token->type != CPP_EOF)
input_location = token->location;
}
/* TOKEN points into the circular token buffer. Return a pointer to
the next token in the buffer. */
static inline cp_token *
cp_lexer_next_token (cp_lexer* lexer, cp_token* token)
{
token++;
if (token == lexer->buffer_end)
token = lexer->buffer;
return token;
}
/* Non-zero if we are presently saving tokens. */
static int
cp_lexer_saving_tokens (const cp_lexer* lexer)
{
return VARRAY_ACTIVE_SIZE (lexer->saved_tokens) != 0;
}
/* Return a pointer to the token that is N tokens beyond TOKEN in the
buffer. */
static cp_token *
cp_lexer_advance_token (cp_lexer *lexer, cp_token *token, ptrdiff_t n)
{
token += n;
if (token >= lexer->buffer_end)
token = lexer->buffer + (token - lexer->buffer_end);
return token;
}
/* Returns the number of times that START would have to be incremented
to reach FINISH. If START and FINISH are the same, returns zero. */
static ptrdiff_t
cp_lexer_token_difference (cp_lexer* lexer, cp_token* start, cp_token* finish)
{
if (finish >= start)
return finish - start;
else
return ((lexer->buffer_end - lexer->buffer)
- (start - finish));
}
/* Obtain another token from the C preprocessor and add it to the
token buffer. Returns the newly read token. */
static cp_token *
cp_lexer_read_token (cp_lexer* lexer)
{
cp_token *token;
/* Make sure there is room in the buffer. */
cp_lexer_maybe_grow_buffer (lexer);
/* If there weren't any tokens, then this one will be the first. */
if (!lexer->first_token)
lexer->first_token = lexer->last_token;
/* Similarly, if there were no available tokens, there is one now. */
if (!lexer->next_token)
lexer->next_token = lexer->last_token;
/* Figure out where we're going to store the new token. */
token = lexer->last_token;
/* Get a new token from the preprocessor. */
cp_lexer_get_preprocessor_token (lexer, token);
/* Increment LAST_TOKEN. */
lexer->last_token = cp_lexer_next_token (lexer, token);
/* The preprocessor does not yet do translation phase six, i.e., the
combination of adjacent string literals. Therefore, we do it
here. */
if (token->type == CPP_STRING || token->type == CPP_WSTRING)
{
ptrdiff_t delta;
int i;
/* When we grow the buffer, we may invalidate TOKEN. So, save
the distance from the beginning of the BUFFER so that we can
recaulate it. */
delta = cp_lexer_token_difference (lexer, lexer->buffer, token);
/* Make sure there is room in the buffer for another token. */
cp_lexer_maybe_grow_buffer (lexer);
/* Restore TOKEN. */
token = lexer->buffer;
for (i = 0; i < delta; ++i)
token = cp_lexer_next_token (lexer, token);
VARRAY_PUSH_TREE (lexer->string_tokens, token->value);
while (true)
{
/* Read the token after TOKEN. */
cp_lexer_get_preprocessor_token (lexer, lexer->last_token);
/* See whether it's another string constant. */
if (lexer->last_token->type != token->type)
{
/* If not, then it will be the next real token. */
lexer->last_token = cp_lexer_next_token (lexer,
lexer->last_token);
break;
}
/* Chain the strings together. */
VARRAY_PUSH_TREE (lexer->string_tokens,
lexer->last_token->value);
}
/* Create a single STRING_CST. Curiously we have to call
combine_strings even if there is only a single string in
order to get the type set correctly. */
token->value = combine_strings (lexer->string_tokens);
VARRAY_CLEAR (lexer->string_tokens);
token->value = fix_string_type (token->value);
/* Strings should have type `const char []'. Right now, we will
have an ARRAY_TYPE that is constant rather than an array of
constant elements. */
if (flag_const_strings)
{
tree type;
/* Get the current type. It will be an ARRAY_TYPE. */
type = TREE_TYPE (token->value);
/* Use build_cplus_array_type to rebuild the array, thereby
getting the right type. */
type = build_cplus_array_type (TREE_TYPE (type),
TYPE_DOMAIN (type));
/* Reset the type of the token. */
TREE_TYPE (token->value) = type;
}
}
return token;
}
/* If the circular buffer is full, make it bigger. */
static void
cp_lexer_maybe_grow_buffer (cp_lexer* lexer)
{
/* If the buffer is full, enlarge it. */
if (lexer->last_token == lexer->first_token)
{
cp_token *new_buffer;
cp_token *old_buffer;
cp_token *new_first_token;
ptrdiff_t buffer_length;
size_t num_tokens_to_copy;
/* Remember the current buffer pointer. It will become invalid,
but we will need to do pointer arithmetic involving this
value. */
old_buffer = lexer->buffer;
/* Compute the current buffer size. */
buffer_length = lexer->buffer_end - lexer->buffer;
/* Allocate a buffer twice as big. */
new_buffer = ((cp_token *)
ggc_realloc (lexer->buffer,
2 * buffer_length * sizeof (cp_token)));
/* Because the buffer is circular, logically consecutive tokens
are not necessarily placed consecutively in memory.
Therefore, we must keep move the tokens that were before
FIRST_TOKEN to the second half of the newly allocated
buffer. */
num_tokens_to_copy = (lexer->first_token - old_buffer);
memcpy (new_buffer + buffer_length,
new_buffer,
num_tokens_to_copy * sizeof (cp_token));
/* Clear the rest of the buffer. We never look at this storage,
but the garbage collector may. */
memset (new_buffer + buffer_length + num_tokens_to_copy, 0,
(buffer_length - num_tokens_to_copy) * sizeof (cp_token));
/* Now recompute all of the buffer pointers. */
new_first_token
= new_buffer + (lexer->first_token - old_buffer);
if (lexer->next_token != NULL)
{
ptrdiff_t next_token_delta;
if (lexer->next_token > lexer->first_token)
next_token_delta = lexer->next_token - lexer->first_token;
else
next_token_delta =
buffer_length - (lexer->first_token - lexer->next_token);
lexer->next_token = new_first_token + next_token_delta;
}
lexer->last_token = new_first_token + buffer_length;
lexer->buffer = new_buffer;
lexer->buffer_end = new_buffer + buffer_length * 2;
lexer->first_token = new_first_token;
}
}
/* Store the next token from the preprocessor in *TOKEN. */
static void
cp_lexer_get_preprocessor_token (cp_lexer *lexer ATTRIBUTE_UNUSED ,
cp_token *token)
{
bool done;
/* If this not the main lexer, return a terminating CPP_EOF token. */
if (lexer != NULL && !lexer->main_lexer_p)
{
token->type = CPP_EOF;
token->location.line = 0;
token->location.file = NULL;
token->value = NULL_TREE;
token->keyword = RID_MAX;
return;
}
done = false;
/* Keep going until we get a token we like. */
while (!done)
{
/* Get a new token from the preprocessor. */
token->type = c_lex (&token->value);
/* Issue messages about tokens we cannot process. */
switch (token->type)
{
case CPP_ATSIGN:
case CPP_HASH:
case CPP_PASTE:
error ("invalid token");
break;
default:
/* This is a good token, so we exit the loop. */
done = true;
break;
}
}
/* Now we've got our token. */
token->location = input_location;
/* Check to see if this token is a keyword. */
if (token->type == CPP_NAME
&& C_IS_RESERVED_WORD (token->value))
{
/* Mark this token as a keyword. */
token->type = CPP_KEYWORD;
/* Record which keyword. */
token->keyword = C_RID_CODE (token->value);
/* Update the value. Some keywords are mapped to particular
entities, rather than simply having the value of the
corresponding IDENTIFIER_NODE. For example, `__const' is
mapped to `const'. */
token->value = ridpointers[token->keyword];
}
else
token->keyword = RID_MAX;
}
/* Return a pointer to the next token in the token stream, but do not
consume it. */
static cp_token *
cp_lexer_peek_token (cp_lexer* lexer)
{
cp_token *token;
/* If there are no tokens, read one now. */
if (!lexer->next_token)
cp_lexer_read_token (lexer);
/* Provide debugging output. */
if (cp_lexer_debugging_p (lexer))
{
fprintf (cp_lexer_debug_stream, "cp_lexer: peeking at token: ");
cp_lexer_print_token (cp_lexer_debug_stream, lexer->next_token);
fprintf (cp_lexer_debug_stream, "\n");
}
token = lexer->next_token;
cp_lexer_set_source_position_from_token (lexer, token);
return token;
}
/* Return true if the next token has the indicated TYPE. */
static bool
cp_lexer_next_token_is (cp_lexer* lexer, enum cpp_ttype type)
{
cp_token *token;
/* Peek at the next token. */
token = cp_lexer_peek_token (lexer);
/* Check to see if it has the indicated TYPE. */
return token->type == type;
}
/* Return true if the next token does not have the indicated TYPE. */
static bool
cp_lexer_next_token_is_not (cp_lexer* lexer, enum cpp_ttype type)
{
return !cp_lexer_next_token_is (lexer, type);
}
/* Return true if the next token is the indicated KEYWORD. */
static bool
cp_lexer_next_token_is_keyword (cp_lexer* lexer, enum rid keyword)
{
cp_token *token;
/* Peek at the next token. */
token = cp_lexer_peek_token (lexer);
/* Check to see if it is the indicated keyword. */
return token->keyword == keyword;
}
/* Return a pointer to the Nth token in the token stream. If N is 1,
then this is precisely equivalent to cp_lexer_peek_token. */
static cp_token *
cp_lexer_peek_nth_token (cp_lexer* lexer, size_t n)
{
cp_token *token;
/* N is 1-based, not zero-based. */
my_friendly_assert (n > 0, 20000224);
/* Skip ahead from NEXT_TOKEN, reading more tokens as necessary. */
token = lexer->next_token;
/* If there are no tokens in the buffer, get one now. */
if (!token)
{
cp_lexer_read_token (lexer);
token = lexer->next_token;
}
/* Now, read tokens until we have enough. */
while (--n > 0)
{
/* Advance to the next token. */
token = cp_lexer_next_token (lexer, token);
/* If that's all the tokens we have, read a new one. */
if (token == lexer->last_token)
token = cp_lexer_read_token (lexer);
}
return token;
}
/* Consume the next token. The pointer returned is valid only until
another token is read. Callers should preserve copy the token
explicitly if they will need its value for a longer period of
time. */
static cp_token *
cp_lexer_consume_token (cp_lexer* lexer)
{
cp_token *token;
/* If there are no tokens, read one now. */
if (!lexer->next_token)
cp_lexer_read_token (lexer);
/* Remember the token we'll be returning. */
token = lexer->next_token;
/* Increment NEXT_TOKEN. */
lexer->next_token = cp_lexer_next_token (lexer,
lexer->next_token);
/* Check to see if we're all out of tokens. */
if (lexer->next_token == lexer->last_token)
lexer->next_token = NULL;
/* If we're not saving tokens, then move FIRST_TOKEN too. */
if (!cp_lexer_saving_tokens (lexer))
{
/* If there are no tokens available, set FIRST_TOKEN to NULL. */
if (!lexer->next_token)
lexer->first_token = NULL;
else
lexer->first_token = lexer->next_token;
}
/* Provide debugging output. */
if (cp_lexer_debugging_p (lexer))
{
fprintf (cp_lexer_debug_stream, "cp_lexer: consuming token: ");
cp_lexer_print_token (cp_lexer_debug_stream, token);
fprintf (cp_lexer_debug_stream, "\n");
}
return token;
}
/* Permanently remove the next token from the token stream. There
must be a valid next token already; this token never reads
additional tokens from the preprocessor. */
static void
cp_lexer_purge_token (cp_lexer *lexer)
{
cp_token *token;
cp_token *next_token;
token = lexer->next_token;
while (true)
{
next_token = cp_lexer_next_token (lexer, token);
if (next_token == lexer->last_token)
break;
*token = *next_token;
token = next_token;
}
lexer->last_token = token;
/* The token purged may have been the only token remaining; if so,
clear NEXT_TOKEN. */
if (lexer->next_token == token)
lexer->next_token = NULL;
}
/* Permanently remove all tokens after TOKEN, up to, but not
including, the token that will be returned next by
cp_lexer_peek_token. */
static void
cp_lexer_purge_tokens_after (cp_lexer *lexer, cp_token *token)
{
cp_token *peek;
cp_token *t1;
cp_token *t2;
if (lexer->next_token)
{
/* Copy the tokens that have not yet been read to the location
immediately following TOKEN. */
t1 = cp_lexer_next_token (lexer, token);
t2 = peek = cp_lexer_peek_token (lexer);
/* Move tokens into the vacant area between TOKEN and PEEK. */
while (t2 != lexer->last_token)
{
*t1 = *t2;
t1 = cp_lexer_next_token (lexer, t1);
t2 = cp_lexer_next_token (lexer, t2);
}
/* Now, the next available token is right after TOKEN. */
lexer->next_token = cp_lexer_next_token (lexer, token);
/* And the last token is wherever we ended up. */
lexer->last_token = t1;
}
else
{
/* There are no tokens in the buffer, so there is nothing to
copy. The last token in the buffer is TOKEN itself. */
lexer->last_token = cp_lexer_next_token (lexer, token);
}
}
/* Begin saving tokens. All tokens consumed after this point will be
preserved. */
static void
cp_lexer_save_tokens (cp_lexer* lexer)
{
/* Provide debugging output. */
if (cp_lexer_debugging_p (lexer))
fprintf (cp_lexer_debug_stream, "cp_lexer: saving tokens\n");
/* Make sure that LEXER->NEXT_TOKEN is non-NULL so that we can
restore the tokens if required. */
if (!lexer->next_token)
cp_lexer_read_token (lexer);
VARRAY_PUSH_INT (lexer->saved_tokens,
cp_lexer_token_difference (lexer,
lexer->first_token,
lexer->next_token));
}
/* Commit to the portion of the token stream most recently saved. */
static void
cp_lexer_commit_tokens (cp_lexer* lexer)
{
/* Provide debugging output. */
if (cp_lexer_debugging_p (lexer))
fprintf (cp_lexer_debug_stream, "cp_lexer: committing tokens\n");
VARRAY_POP (lexer->saved_tokens);
}
/* Return all tokens saved since the last call to cp_lexer_save_tokens
to the token stream. Stop saving tokens. */
static void
cp_lexer_rollback_tokens (cp_lexer* lexer)
{
size_t delta;
/* Provide debugging output. */
if (cp_lexer_debugging_p (lexer))
fprintf (cp_lexer_debug_stream, "cp_lexer: restoring tokens\n");
/* Find the token that was the NEXT_TOKEN when we started saving
tokens. */
delta = VARRAY_TOP_INT(lexer->saved_tokens);
/* Make it the next token again now. */
lexer->next_token = cp_lexer_advance_token (lexer,
lexer->first_token,
delta);
/* It might be the case that there were no tokens when we started
saving tokens, but that there are some tokens now. */
if (!lexer->next_token && lexer->first_token)
lexer->next_token = lexer->first_token;
/* Stop saving tokens. */
VARRAY_POP (lexer->saved_tokens);
}
/* Print a representation of the TOKEN on the STREAM. */
static void
cp_lexer_print_token (FILE * stream, cp_token* token)
{
const char *token_type = NULL;
/* Figure out what kind of token this is. */
switch (token->type)
{
case CPP_EQ:
token_type = "EQ";
break;
case CPP_COMMA:
token_type = "COMMA";
break;
case CPP_OPEN_PAREN:
token_type = "OPEN_PAREN";
break;
case CPP_CLOSE_PAREN:
token_type = "CLOSE_PAREN";
break;
case CPP_OPEN_BRACE:
token_type = "OPEN_BRACE";
break;
case CPP_CLOSE_BRACE:
token_type = "CLOSE_BRACE";
break;
case CPP_SEMICOLON:
token_type = "SEMICOLON";
break;
case CPP_NAME:
token_type = "NAME";
break;
case CPP_EOF:
token_type = "EOF";
break;
case CPP_KEYWORD:
token_type = "keyword";
break;
/* This is not a token that we know how to handle yet. */
default:
break;
}
/* If we have a name for the token, print it out. Otherwise, we
simply give the numeric code. */
if (token_type)
fprintf (stream, "%s", token_type);
else
fprintf (stream, "%d", token->type);
/* And, for an identifier, print the identifier name. */
if (token->type == CPP_NAME
/* Some keywords have a value that is not an IDENTIFIER_NODE.
For example, `struct' is mapped to an INTEGER_CST. */
|| (token->type == CPP_KEYWORD
&& TREE_CODE (token->value) == IDENTIFIER_NODE))
fprintf (stream, " %s", IDENTIFIER_POINTER (token->value));
}
/* Start emitting debugging information. */
static void
cp_lexer_start_debugging (cp_lexer* lexer)
{
++lexer->debugging_p;
}
/* Stop emitting debugging information. */
static void
cp_lexer_stop_debugging (cp_lexer* lexer)
{
--lexer->debugging_p;
}
/* The parser. */
/* Overview
--------
A cp_parser parses the token stream as specified by the C++
grammar. Its job is purely parsing, not semantic analysis. For
example, the parser breaks the token stream into declarators,
expressions, statements, and other similar syntactic constructs.
It does not check that the types of the expressions on either side
of an assignment-statement are compatible, or that a function is
not declared with a parameter of type `void'.
The parser invokes routines elsewhere in the compiler to perform
semantic analysis and to build up the abstract syntax tree for the
code processed.
The parser (and the template instantiation code, which is, in a
way, a close relative of parsing) are the only parts of the
compiler that should be calling push_scope and pop_scope, or
related functions. The parser (and template instantiation code)
keeps track of what scope is presently active; everything else
should simply honor that. (The code that generates static
initializers may also need to set the scope, in order to check
access control correctly when emitting the initializers.)
Methodology
-----------
The parser is of the standard recursive-descent variety. Upcoming
tokens in the token stream are examined in order to determine which
production to use when parsing a non-terminal. Some C++ constructs
require arbitrary look ahead to disambiguate. For example, it is
impossible, in the general case, to tell whether a statement is an
expression or declaration without scanning the entire statement.
Therefore, the parser is capable of "parsing tentatively." When the
parser is not sure what construct comes next, it enters this mode.
Then, while we attempt to parse the construct, the parser queues up
error messages, rather than issuing them immediately, and saves the
tokens it consumes. If the construct is parsed successfully, the
parser "commits", i.e., it issues any queued error messages and
the tokens that were being preserved are permanently discarded.
If, however, the construct is not parsed successfully, the parser
rolls back its state completely so that it can resume parsing using
a different alternative.
Future Improvements
-------------------
The performance of the parser could probably be improved
substantially. Some possible improvements include:
- The expression parser recurses through the various levels of
precedence as specified in the grammar, rather than using an
operator-precedence technique. Therefore, parsing a simple
identifier requires multiple recursive calls.
- We could often eliminate the need to parse tentatively by
looking ahead a little bit. In some places, this approach
might not entirely eliminate the need to parse tentatively, but
it might still speed up the average case. */
/* Flags that are passed to some parsing functions. These values can
be bitwise-ored together. */
typedef enum cp_parser_flags
{
/* No flags. */
CP_PARSER_FLAGS_NONE = 0x0,
/* The construct is optional. If it is not present, then no error
should be issued. */
CP_PARSER_FLAGS_OPTIONAL = 0x1,
/* When parsing a type-specifier, do not allow user-defined types. */
CP_PARSER_FLAGS_NO_USER_DEFINED_TYPES = 0x2
} cp_parser_flags;
/* The different kinds of ids that we ecounter. */
typedef enum cp_parser_id_kind
{
/* Not an id at all. */
CP_PARSER_ID_KIND_NONE,
/* An unqualified-id that is not a template-id. */
CP_PARSER_ID_KIND_UNQUALIFIED,
/* An unqualified template-id. */
CP_PARSER_ID_KIND_TEMPLATE_ID,
/* A qualified-id. */
CP_PARSER_ID_KIND_QUALIFIED
} cp_parser_id_kind;
/* The different kinds of declarators we want to parse. */
typedef enum cp_parser_declarator_kind
{
/* We want an abstract declartor. */
CP_PARSER_DECLARATOR_ABSTRACT,
/* We want a named declarator. */
CP_PARSER_DECLARATOR_NAMED,
/* We don't mind, but the name must be an unqualified-id */
CP_PARSER_DECLARATOR_EITHER
} cp_parser_declarator_kind;
/* A mapping from a token type to a corresponding tree node type. */
typedef struct cp_parser_token_tree_map_node
{
/* The token type. */
enum cpp_ttype token_type;
/* The corresponding tree code. */
enum tree_code tree_type;
} cp_parser_token_tree_map_node;
/* A complete map consists of several ordinary entries, followed by a
terminator. The terminating entry has a token_type of CPP_EOF. */
typedef cp_parser_token_tree_map_node cp_parser_token_tree_map[];
/* The status of a tentative parse. */
typedef enum cp_parser_status_kind
{
/* No errors have occurred. */
CP_PARSER_STATUS_KIND_NO_ERROR,
/* An error has occurred. */
CP_PARSER_STATUS_KIND_ERROR,
/* We are committed to this tentative parse, whether or not an error
has occurred. */
CP_PARSER_STATUS_KIND_COMMITTED
} cp_parser_status_kind;
/* Context that is saved and restored when parsing tentatively. */
typedef struct cp_parser_context GTY (())
{
/* If this is a tentative parsing context, the status of the
tentative parse. */
enum cp_parser_status_kind status;
/* If non-NULL, we have just seen a `x->' or `x.' expression. Names
that are looked up in this context must be looked up both in the
scope given by OBJECT_TYPE (the type of `x' or `*x') and also in
the context of the containing expression. */
tree object_type;
/* The next parsing context in the stack. */
struct cp_parser_context *next;
} cp_parser_context;
/* Prototypes. */
/* Constructors and destructors. */
static cp_parser_context *cp_parser_context_new
(cp_parser_context *);
/* Class variables. */
static GTY((deletable (""))) cp_parser_context* cp_parser_context_free_list;
/* Constructors and destructors. */
/* Construct a new context. The context below this one on the stack
is given by NEXT. */
static cp_parser_context *
cp_parser_context_new (cp_parser_context* next)
{
cp_parser_context *context;
/* Allocate the storage. */
if (cp_parser_context_free_list != NULL)
{
/* Pull the first entry from the free list. */
context = cp_parser_context_free_list;
cp_parser_context_free_list = context->next;
memset ((char *)context, 0, sizeof (*context));
}
else
context = ((cp_parser_context *)
ggc_alloc_cleared (sizeof (cp_parser_context)));
/* No errors have occurred yet in this context. */
context->status = CP_PARSER_STATUS_KIND_NO_ERROR;
/* If this is not the bottomost context, copy information that we
need from the previous context. */
if (next)
{
/* If, in the NEXT context, we are parsing an `x->' or `x.'
expression, then we are parsing one in this context, too. */
context->object_type = next->object_type;
/* Thread the stack. */
context->next = next;
}
return context;
}
/* The cp_parser structure represents the C++ parser. */
typedef struct cp_parser GTY(())
{
/* The lexer from which we are obtaining tokens. */
cp_lexer *lexer;
/* The scope in which names should be looked up. If NULL_TREE, then
we look up names in the scope that is currently open in the
source program. If non-NULL, this is either a TYPE or
NAMESPACE_DECL for the scope in which we should look.
This value is not cleared automatically after a name is looked
up, so we must be careful to clear it before starting a new look
up sequence. (If it is not cleared, then `X::Y' followed by `Z'
will look up `Z' in the scope of `X', rather than the current
scope.) Unfortunately, it is difficult to tell when name lookup
is complete, because we sometimes peek at a token, look it up,
and then decide not to consume it. */
tree scope;
/* OBJECT_SCOPE and QUALIFYING_SCOPE give the scopes in which the
last lookup took place. OBJECT_SCOPE is used if an expression
like "x->y" or "x.y" was used; it gives the type of "*x" or "x",
respectively. QUALIFYING_SCOPE is used for an expression of the
form "X::Y"; it refers to X. */
tree object_scope;
tree qualifying_scope;
/* A stack of parsing contexts. All but the bottom entry on the
stack will be tentative contexts.
We parse tentatively in order to determine which construct is in
use in some situations. For example, in order to determine
whether a statement is an expression-statement or a
declaration-statement we parse it tentatively as a
declaration-statement. If that fails, we then reparse the same
token stream as an expression-statement. */
cp_parser_context *context;
/* True if we are parsing GNU C++. If this flag is not set, then
GNU extensions are not recognized. */
bool allow_gnu_extensions_p;
/* TRUE if the `>' token should be interpreted as the greater-than
operator. FALSE if it is the end of a template-id or
template-parameter-list. */
bool greater_than_is_operator_p;
/* TRUE if default arguments are allowed within a parameter list
that starts at this point. FALSE if only a gnu extension makes
them permissable. */
bool default_arg_ok_p;
/* TRUE if we are parsing an integral constant-expression. See
[expr.const] for a precise definition. */
bool constant_expression_p;
/* TRUE if we are parsing an integral constant-expression -- but a
non-constant expression should be permitted as well. This flag
is used when parsing an array bound so that GNU variable-length
arrays are tolerated. */
bool allow_non_constant_expression_p;
/* TRUE if ALLOW_NON_CONSTANT_EXPRESSION_P is TRUE and something has
been seen that makes the expression non-constant. */
bool non_constant_expression_p;
/* TRUE if local variable names and `this' are forbidden in the
current context. */
bool local_variables_forbidden_p;
/* TRUE if the declaration we are parsing is part of a
linkage-specification of the form `extern string-literal
declaration'. */
bool in_unbraced_linkage_specification_p;
/* TRUE if we are presently parsing a declarator, after the
direct-declarator. */
bool in_declarator_p;
/* If non-NULL, then we are parsing a construct where new type
definitions are not permitted. The string stored here will be
issued as an error message if a type is defined. */
const char *type_definition_forbidden_message;
/* A TREE_LIST of queues of functions whose bodies have been lexed,
but may not have been parsed. These functions are friends of
members defined within a class-specification; they are not
procssed until the class is complete. The active queue is at the
front of the list.
Within each queue, functions appear in the reverse order that
they appeared in the source. Each TREE_VALUE is a
FUNCTION_DECL of TEMPLATE_DECL corresponding to a member
function. */
tree unparsed_functions_queues;
/* The number of classes whose definitions are currently in
progress. */
unsigned num_classes_being_defined;
/* The number of template parameter lists that apply directly to the
current declaration. */
unsigned num_template_parameter_lists;
} cp_parser;
/* The type of a function that parses some kind of expression */
typedef tree (*cp_parser_expression_fn) (cp_parser *);
/* Prototypes. */
/* Constructors and destructors. */
static cp_parser *cp_parser_new
(void);
/* Routines to parse various constructs.
Those that return `tree' will return the error_mark_node (rather
than NULL_TREE) if a parse error occurs, unless otherwise noted.
Sometimes, they will return an ordinary node if error-recovery was
attempted, even though a parse error occurrred. So, to check
whether or not a parse error occurred, you should always use
cp_parser_error_occurred. If the construct is optional (indicated
either by an `_opt' in the name of the function that does the
parsing or via a FLAGS parameter), then NULL_TREE is returned if
the construct is not present. */
/* Lexical conventions [gram.lex] */
static tree cp_parser_identifier
(cp_parser *);
/* Basic concepts [gram.basic] */
static bool cp_parser_translation_unit
(cp_parser *);
/* Expressions [gram.expr] */
static tree cp_parser_primary_expression
(cp_parser *, cp_parser_id_kind *, tree *);
static tree cp_parser_id_expression
(cp_parser *, bool, bool, bool *);
static tree cp_parser_unqualified_id
(cp_parser *, bool, bool);
static tree cp_parser_nested_name_specifier_opt
(cp_parser *, bool, bool, bool);
static tree cp_parser_nested_name_specifier
(cp_parser *, bool, bool, bool);
static tree cp_parser_class_or_namespace_name
(cp_parser *, bool, bool, bool, bool);
static tree cp_parser_postfix_expression
(cp_parser *, bool);
static tree cp_parser_expression_list
(cp_parser *);
static void cp_parser_pseudo_destructor_name
(cp_parser *, tree *, tree *);
static tree cp_parser_unary_expression
(cp_parser *, bool);
static enum tree_code cp_parser_unary_operator
(cp_token *);
static tree cp_parser_new_expression
(cp_parser *);
static tree cp_parser_new_placement
(cp_parser *);
static tree cp_parser_new_type_id
(cp_parser *);
static tree cp_parser_new_declarator_opt
(cp_parser *);
static tree cp_parser_direct_new_declarator
(cp_parser *);
static tree cp_parser_new_initializer
(cp_parser *);
static tree cp_parser_delete_expression
(cp_parser *);
static tree cp_parser_cast_expression
(cp_parser *, bool);
static tree cp_parser_pm_expression
(cp_parser *);
static tree cp_parser_multiplicative_expression
(cp_parser *);
static tree cp_parser_additive_expression
(cp_parser *);
static tree cp_parser_shift_expression
(cp_parser *);
static tree cp_parser_relational_expression
(cp_parser *);
static tree cp_parser_equality_expression
(cp_parser *);
static tree cp_parser_and_expression
(cp_parser *);
static tree cp_parser_exclusive_or_expression
(cp_parser *);
static tree cp_parser_inclusive_or_expression
(cp_parser *);
static tree cp_parser_logical_and_expression
(cp_parser *);
static tree cp_parser_logical_or_expression
(cp_parser *);
static tree cp_parser_conditional_expression
(cp_parser *);
static tree cp_parser_question_colon_clause
(cp_parser *, tree);
static tree cp_parser_assignment_expression
(cp_parser *);
static enum tree_code cp_parser_assignment_operator_opt
(cp_parser *);
static tree cp_parser_expression
(cp_parser *);
static tree cp_parser_constant_expression
(cp_parser *, bool, bool *);
/* Statements [gram.stmt.stmt] */
static void cp_parser_statement
(cp_parser *);
static tree cp_parser_labeled_statement
(cp_parser *);
static tree cp_parser_expression_statement
(cp_parser *);
static tree cp_parser_compound_statement
(cp_parser *);
static void cp_parser_statement_seq_opt
(cp_parser *);
static tree cp_parser_selection_statement
(cp_parser *);
static tree cp_parser_condition
(cp_parser *);
static tree cp_parser_iteration_statement
(cp_parser *);
static void cp_parser_for_init_statement
(cp_parser *);
static tree cp_parser_jump_statement
(cp_parser *);
static void cp_parser_declaration_statement
(cp_parser *);
static tree cp_parser_implicitly_scoped_statement
(cp_parser *);
static void cp_parser_already_scoped_statement
(cp_parser *);
/* Declarations [gram.dcl.dcl] */
static void cp_parser_declaration_seq_opt
(cp_parser *);
static void cp_parser_declaration
(cp_parser *);
static void cp_parser_block_declaration
(cp_parser *, bool);
static void cp_parser_simple_declaration
(cp_parser *, bool);
static tree cp_parser_decl_specifier_seq
(cp_parser *, cp_parser_flags, tree *, bool *);
static tree cp_parser_storage_class_specifier_opt
(cp_parser *);
static tree cp_parser_function_specifier_opt
(cp_parser *);
static tree cp_parser_type_specifier
(cp_parser *, cp_parser_flags, bool, bool, bool *, bool *);
static tree cp_parser_simple_type_specifier
(cp_parser *, cp_parser_flags);
static tree cp_parser_type_name
(cp_parser *);
static tree cp_parser_elaborated_type_specifier
(cp_parser *, bool, bool);
static tree cp_parser_enum_specifier
(cp_parser *);
static void cp_parser_enumerator_list
(cp_parser *, tree);
static void cp_parser_enumerator_definition
(cp_parser *, tree);
static tree cp_parser_namespace_name
(cp_parser *);
static void cp_parser_namespace_definition
(cp_parser *);
static void cp_parser_namespace_body
(cp_parser *);
static tree cp_parser_qualified_namespace_specifier
(cp_parser *);
static void cp_parser_namespace_alias_definition
(cp_parser *);
static void cp_parser_using_declaration
(cp_parser *);
static void cp_parser_using_directive
(cp_parser *);
static void cp_parser_asm_definition
(cp_parser *);
static void cp_parser_linkage_specification
(cp_parser *);
/* Declarators [gram.dcl.decl] */
static tree cp_parser_init_declarator
(cp_parser *, tree, tree, bool, bool, bool *);
static tree cp_parser_declarator
(cp_parser *, cp_parser_declarator_kind, bool *);
static tree cp_parser_direct_declarator
(cp_parser *, cp_parser_declarator_kind, bool *);
static enum tree_code cp_parser_ptr_operator
(cp_parser *, tree *, tree *);
static tree cp_parser_cv_qualifier_seq_opt
(cp_parser *);
static tree cp_parser_cv_qualifier_opt
(cp_parser *);
static tree cp_parser_declarator_id
(cp_parser *);
static tree cp_parser_type_id
(cp_parser *);
static tree cp_parser_type_specifier_seq
(cp_parser *);
static tree cp_parser_parameter_declaration_clause
(cp_parser *);
static tree cp_parser_parameter_declaration_list
(cp_parser *);
static tree cp_parser_parameter_declaration
(cp_parser *, bool);
static tree cp_parser_function_definition
(cp_parser *, bool *);
static void cp_parser_function_body
(cp_parser *);
static tree cp_parser_initializer
(cp_parser *, bool *);
static tree cp_parser_initializer_clause
(cp_parser *);
static tree cp_parser_initializer_list
(cp_parser *);
static bool cp_parser_ctor_initializer_opt_and_function_body
(cp_parser *);
/* Classes [gram.class] */
static tree cp_parser_class_name
(cp_parser *, bool, bool, bool, bool, bool);
static tree cp_parser_class_specifier
(cp_parser *);
static tree cp_parser_class_head
(cp_parser *, bool *);
static enum tag_types cp_parser_class_key
(cp_parser *);
static void cp_parser_member_specification_opt
(cp_parser *);
static void cp_parser_member_declaration
(cp_parser *);
static tree cp_parser_pure_specifier
(cp_parser *);
static tree cp_parser_constant_initializer
(cp_parser *);
/* Derived classes [gram.class.derived] */
static tree cp_parser_base_clause
(cp_parser *);
static tree cp_parser_base_specifier
(cp_parser *);
/* Special member functions [gram.special] */
static tree cp_parser_conversion_function_id
(cp_parser *);
static tree cp_parser_conversion_type_id
(cp_parser *);
static tree cp_parser_conversion_declarator_opt
(cp_parser *);
static bool cp_parser_ctor_initializer_opt
(cp_parser *);
static void cp_parser_mem_initializer_list
(cp_parser *);
static tree cp_parser_mem_initializer
(cp_parser *);
static tree cp_parser_mem_initializer_id
(cp_parser *);
/* Overloading [gram.over] */
static tree cp_parser_operator_function_id
(cp_parser *);
static tree cp_parser_operator
(cp_parser *);
/* Templates [gram.temp] */
static void cp_parser_template_declaration
(cp_parser *, bool);
static tree cp_parser_template_parameter_list
(cp_parser *);
static tree cp_parser_template_parameter
(cp_parser *);
static tree cp_parser_type_parameter
(cp_parser *);
static tree cp_parser_template_id
(cp_parser *, bool, bool);
static tree cp_parser_template_name
(cp_parser *, bool, bool);
static tree cp_parser_template_argument_list
(cp_parser *);
static tree cp_parser_template_argument
(cp_parser *);
static void cp_parser_explicit_instantiation
(cp_parser *);
static void cp_parser_explicit_specialization
(cp_parser *);
/* Exception handling [gram.exception] */
static tree cp_parser_try_block
(cp_parser *);
static bool cp_parser_function_try_block
(cp_parser *);
static void cp_parser_handler_seq
(cp_parser *);
static void cp_parser_handler
(cp_parser *);
static tree cp_parser_exception_declaration
(cp_parser *);
static tree cp_parser_throw_expression
(cp_parser *);
static tree cp_parser_exception_specification_opt
(cp_parser *);
static tree cp_parser_type_id_list
(cp_parser *);
/* GNU Extensions */
static tree cp_parser_asm_specification_opt
(cp_parser *);
static tree cp_parser_asm_operand_list
(cp_parser *);
static tree cp_parser_asm_clobber_list
(cp_parser *);
static tree cp_parser_attributes_opt
(cp_parser *);
static tree cp_parser_attribute_list
(cp_parser *);
static bool cp_parser_extension_opt
(cp_parser *, int *);
static void cp_parser_label_declaration
(cp_parser *);
/* Utility Routines */
static tree cp_parser_lookup_name
(cp_parser *, tree, bool, bool, bool);
static tree cp_parser_lookup_name_simple
(cp_parser *, tree);
static tree cp_parser_maybe_treat_template_as_class
(tree, bool);
static bool cp_parser_check_declarator_template_parameters
(cp_parser *, tree);
static bool cp_parser_check_template_parameters
(cp_parser *, unsigned);
static tree cp_parser_binary_expression
(cp_parser *, const cp_parser_token_tree_map, cp_parser_expression_fn);
static tree cp_parser_global_scope_opt
(cp_parser *, bool);
static bool cp_parser_constructor_declarator_p
(cp_parser *, bool);
static tree cp_parser_function_definition_from_specifiers_and_declarator
(cp_parser *, tree, tree, tree);
static tree cp_parser_function_definition_after_declarator
(cp_parser *, bool);
static void cp_parser_template_declaration_after_export
(cp_parser *, bool);
static tree cp_parser_single_declaration
(cp_parser *, bool, bool *);
static tree cp_parser_functional_cast
(cp_parser *, tree);
static void cp_parser_late_parsing_for_member
(cp_parser *, tree);
static void cp_parser_late_parsing_default_args
(cp_parser *, tree);
static tree cp_parser_sizeof_operand
(cp_parser *, enum rid);
static bool cp_parser_declares_only_class_p
(cp_parser *);
static bool cp_parser_friend_p
(tree);
static cp_token *cp_parser_require
(cp_parser *, enum cpp_ttype, const char *);
static cp_token *cp_parser_require_keyword
(cp_parser *, enum rid, const char *);
static bool cp_parser_token_starts_function_definition_p
(cp_token *);
static bool cp_parser_next_token_starts_class_definition_p
(cp_parser *);
static enum tag_types cp_parser_token_is_class_key
(cp_token *);
static void cp_parser_check_class_key
(enum tag_types, tree type);
static bool cp_parser_optional_template_keyword
(cp_parser *);
static void cp_parser_pre_parsed_nested_name_specifier
(cp_parser *);
static void cp_parser_cache_group
(cp_parser *, cp_token_cache *, enum cpp_ttype, unsigned);
static void cp_parser_parse_tentatively
(cp_parser *);
static void cp_parser_commit_to_tentative_parse
(cp_parser *);
static void cp_parser_abort_tentative_parse
(cp_parser *);
static bool cp_parser_parse_definitely
(cp_parser *);
static inline bool cp_parser_parsing_tentatively
(cp_parser *);
static bool cp_parser_committed_to_tentative_parse
(cp_parser *);
static void cp_parser_error
(cp_parser *, const char *);
static bool cp_parser_simulate_error
(cp_parser *);
static void cp_parser_check_type_definition
(cp_parser *);
static tree cp_parser_non_constant_expression
(const char *);
static tree cp_parser_non_constant_id_expression
(tree);
static bool cp_parser_diagnose_invalid_type_name
(cp_parser *);
static bool cp_parser_skip_to_closing_parenthesis
(cp_parser *);
static bool cp_parser_skip_to_closing_parenthesis_or_comma
(cp_parser *);
static void cp_parser_skip_to_end_of_statement
(cp_parser *);
static void cp_parser_consume_semicolon_at_end_of_statement
(cp_parser *);
static void cp_parser_skip_to_end_of_block_or_statement
(cp_parser *);
static void cp_parser_skip_to_closing_brace
(cp_parser *);
static void cp_parser_skip_until_found
(cp_parser *, enum cpp_ttype, const char *);
static bool cp_parser_error_occurred
(cp_parser *);
static bool cp_parser_allow_gnu_extensions_p
(cp_parser *);
static bool cp_parser_is_string_literal
(cp_token *);
static bool cp_parser_is_keyword
(cp_token *, enum rid);
static tree cp_parser_scope_through_which_access_occurs
(tree, tree, tree);
/* Returns non-zero if we are parsing tentatively. */
static inline bool
cp_parser_parsing_tentatively (cp_parser* parser)
{
return parser->context->next != NULL;
}
/* Returns non-zero if TOKEN is a string literal. */
static bool
cp_parser_is_string_literal (cp_token* token)
{
return (token->type == CPP_STRING || token->type == CPP_WSTRING);
}
/* Returns non-zero if TOKEN is the indicated KEYWORD. */
static bool
cp_parser_is_keyword (cp_token* token, enum rid keyword)
{
return token->keyword == keyword;
}
/* Returns the scope through which DECL is being accessed, or
NULL_TREE if DECL is not a member. If OBJECT_TYPE is non-NULL, we
have just seen `x->' or `x.' and OBJECT_TYPE is the type of `*x',
or `x', respectively. If the DECL was named as `A::B' then
NESTED_NAME_SPECIFIER is `A'. */
tree
cp_parser_scope_through_which_access_occurs (tree decl,
tree object_type,
tree nested_name_specifier)
{
tree scope;
tree qualifying_type = NULL_TREE;
/* Determine the SCOPE of DECL. */
scope = context_for_name_lookup (decl);
/* If the SCOPE is not a type, then DECL is not a member. */
if (!TYPE_P (scope))
return NULL_TREE;
/* Figure out the type through which DECL is being accessed. */
if (object_type
/* OBJECT_TYPE might not be a class type; consider:
class A { typedef int I; };
I *p;
p->A::I::~I();
In this case, we will have "A::I" as the DECL, but "I" as the
OBJECT_TYPE. */
&& CLASS_TYPE_P (object_type)
&& DERIVED_FROM_P (scope, object_type))
/* If we are processing a `->' or `.' expression, use the type of the
left-hand side. */
qualifying_type = object_type;
else if (nested_name_specifier)
{
/* If the reference is to a non-static member of the
current class, treat it as if it were referenced through
`this'. */
if (DECL_NONSTATIC_MEMBER_P (decl)
&& current_class_ptr
&& DERIVED_FROM_P (scope, current_class_type))
qualifying_type = current_class_type;
/* Otherwise, use the type indicated by the
nested-name-specifier. */
else
qualifying_type = nested_name_specifier;
}
else
/* Otherwise, the name must be from the current class or one of
its bases. */
qualifying_type = currently_open_derived_class (scope);
return qualifying_type;
}
/* Issue the indicated error MESSAGE. */
static void
cp_parser_error (cp_parser* parser, const char* message)
{
/* Output the MESSAGE -- unless we're parsing tentatively. */
if (!cp_parser_simulate_error (parser))
error (message);
}
/* If we are parsing tentatively, remember that an error has occurred
during this tentative parse. Returns true if the error was
simulated; false if a messgae should be issued by the caller. */
static bool
cp_parser_simulate_error (cp_parser* parser)
{
if (cp_parser_parsing_tentatively (parser)
&& !cp_parser_committed_to_tentative_parse (parser))
{
parser->context->status = CP_PARSER_STATUS_KIND_ERROR;
return true;
}
return false;
}
/* This function is called when a type is defined. If type
definitions are forbidden at this point, an error message is
issued. */
static void
cp_parser_check_type_definition (cp_parser* parser)
{
/* If types are forbidden here, issue a message. */
if (parser->type_definition_forbidden_message)
/* Use `%s' to print the string in case there are any escape
characters in the message. */
error ("%s", parser->type_definition_forbidden_message);
}
/* Issue an eror message about the fact that THING appeared in a
constant-expression. Returns ERROR_MARK_NODE. */
static tree
cp_parser_non_constant_expression (const char *thing)
{
error ("%s cannot appear in a constant-expression", thing);
return error_mark_node;
}
/* Issue an eror message about the fact that DECL appeared in a
constant-expression. Returns ERROR_MARK_NODE. */
static tree
cp_parser_non_constant_id_expression (tree decl)
{
error ("`%D' cannot appear in a constant-expression", decl);
return error_mark_node;
}
/* Check for a common situation where a type-name should be present,
but is not, and issue a sensible error message. Returns true if an
invalid type-name was detected. */
static bool
cp_parser_diagnose_invalid_type_name (cp_parser *parser)
{
/* If the next two tokens are both identifiers, the code is
erroneous. The usual cause of this situation is code like:
T t;
where "T" should name a type -- but does not. */
if (cp_lexer_next_token_is (parser->lexer, CPP_NAME)
&& cp_lexer_peek_nth_token (parser->lexer, 2)->type == CPP_NAME)
{
tree name;
/* If parsing tentatively, we should commit; we really are
looking at a declaration. */
/* Consume the first identifier. */
name = cp_lexer_consume_token (parser->lexer)->value;
/* Issue an error message. */
error ("`%s' does not name a type", IDENTIFIER_POINTER (name));
/* If we're in a template class, it's possible that the user was
referring to a type from a base class. For example:
template <typename T> struct A { typedef T X; };
template <typename T> struct B : public A<T> { X x; };
The user should have said "typename A<T>::X". */
if (processing_template_decl && current_class_type)
{
tree b;
for (b = TREE_CHAIN (TYPE_BINFO (current_class_type));
b;
b = TREE_CHAIN (b))
{
tree base_type = BINFO_TYPE (b);
if (CLASS_TYPE_P (base_type)
&& dependent_type_p (base_type))
{
tree field;
/* Go from a particular instantiation of the
template (which will have an empty TYPE_FIELDs),
to the main version. */
base_type = CLASSTYPE_PRIMARY_TEMPLATE_TYPE (base_type);
for (field = TYPE_FIELDS (base_type);
field;
field = TREE_CHAIN (field))
if (TREE_CODE (field) == TYPE_DECL
&& DECL_NAME (field) == name)
{
error ("(perhaps `typename %T::%s' was intended)",
BINFO_TYPE (b), IDENTIFIER_POINTER (name));
break;
}
if (field)
break;
}
}
}
/* Skip to the end of the declaration; there's no point in
trying to process it. */
cp_parser_skip_to_end_of_statement (parser);
return true;
}
return false;
}
/* Consume tokens up to, and including, the next non-nested closing `)'.
Returns TRUE iff we found a closing `)'. */
static bool
cp_parser_skip_to_closing_parenthesis (cp_parser *parser)
{
unsigned nesting_depth = 0;
while (true)
{
cp_token *token;
/* If we've run out of tokens, then there is no closing `)'. */
if (cp_lexer_next_token_is (parser->lexer, CPP_EOF))
return false;
/* Consume the token. */
token = cp_lexer_consume_token (parser->lexer);
/* If it is an `(', we have entered another level of nesting. */
if (token->type == CPP_OPEN_PAREN)
++nesting_depth;
/* If it is a `)', then we might be done. */
else if (token->type == CPP_CLOSE_PAREN && nesting_depth-- == 0)
return true;
}
}
/* Consume tokens until the next token is a `)', or a `,'. Returns
TRUE if the next token is a `,'. */
static bool
cp_parser_skip_to_closing_parenthesis_or_comma (cp_parser *parser)
{
unsigned nesting_depth = 0;
while (true)
{
cp_token *token = cp_lexer_peek_token (parser->lexer);
/* If we've run out of tokens, then there is no closing `)'. */
if (token->type == CPP_EOF)
return false;
/* If it is a `,' stop. */
else if (token->type == CPP_COMMA && nesting_depth-- == 0)
return true;
/* If it is a `)', stop. */
else if (token->type == CPP_CLOSE_PAREN && nesting_depth-- == 0)
return false;
/* If it is an `(', we have entered another level of nesting. */
else if (token->type == CPP_OPEN_PAREN)
++nesting_depth;
/* Consume the token. */
token = cp_lexer_consume_token (parser->lexer);
}
}
/* Consume tokens until we reach the end of the current statement.
Normally, that will be just before consuming a `;'. However, if a
non-nested `}' comes first, then we stop before consuming that. */
static void
cp_parser_skip_to_end_of_statement (cp_parser* parser)
{
unsigned nesting_depth = 0;
while (true)
{
cp_token *token;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If we've run out of tokens, stop. */
if (token->type == CPP_EOF)
break;
/* If the next token is a `;', we have reached the end of the
statement. */
if (token->type == CPP_SEMICOLON && !nesting_depth)
break;
/* If the next token is a non-nested `}', then we have reached
the end of the current block. */
if (token->type == CPP_CLOSE_BRACE)
{
/* If this is a non-nested `}', stop before consuming it.
That way, when confronted with something like:
{ 3 + }
we stop before consuming the closing `}', even though we
have not yet reached a `;'. */
if (nesting_depth == 0)
break;
/* If it is the closing `}' for a block that we have
scanned, stop -- but only after consuming the token.
That way given:
void f g () { ... }
typedef int I;
we will stop after the body of the erroneously declared
function, but before consuming the following `typedef'
declaration. */
if (--nesting_depth == 0)
{
cp_lexer_consume_token (parser->lexer);
break;
}
}
/* If it the next token is a `{', then we are entering a new
block. Consume the entire block. */
else if (token->type == CPP_OPEN_BRACE)
++nesting_depth;
/* Consume the token. */
cp_lexer_consume_token (parser->lexer);
}
}
/* This function is called at the end of a statement or declaration.
If the next token is a semicolon, it is consumed; otherwise, error
recovery is attempted. */
static void
cp_parser_consume_semicolon_at_end_of_statement (cp_parser *parser)
{
/* Look for the trailing `;'. */
if (!cp_parser_require (parser, CPP_SEMICOLON, "`;'"))
{
/* If there is additional (erroneous) input, skip to the end of
the statement. */
cp_parser_skip_to_end_of_statement (parser);
/* If the next token is now a `;', consume it. */
if (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON))
cp_lexer_consume_token (parser->lexer);
}
}
/* Skip tokens until we have consumed an entire block, or until we
have consumed a non-nested `;'. */
static void
cp_parser_skip_to_end_of_block_or_statement (cp_parser* parser)
{
unsigned nesting_depth = 0;
while (true)
{
cp_token *token;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If we've run out of tokens, stop. */
if (token->type == CPP_EOF)
break;
/* If the next token is a `;', we have reached the end of the
statement. */
if (token->type == CPP_SEMICOLON && !nesting_depth)
{
/* Consume the `;'. */
cp_lexer_consume_token (parser->lexer);
break;
}
/* Consume the token. */
token = cp_lexer_consume_token (parser->lexer);
/* If the next token is a non-nested `}', then we have reached
the end of the current block. */
if (token->type == CPP_CLOSE_BRACE
&& (nesting_depth == 0 || --nesting_depth == 0))
break;
/* If it the next token is a `{', then we are entering a new
block. Consume the entire block. */
if (token->type == CPP_OPEN_BRACE)
++nesting_depth;
}
}
/* Skip tokens until a non-nested closing curly brace is the next
token. */
static void
cp_parser_skip_to_closing_brace (cp_parser *parser)
{
unsigned nesting_depth = 0;
while (true)
{
cp_token *token;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If we've run out of tokens, stop. */
if (token->type == CPP_EOF)
break;
/* If the next token is a non-nested `}', then we have reached
the end of the current block. */
if (token->type == CPP_CLOSE_BRACE && nesting_depth-- == 0)
break;
/* If it the next token is a `{', then we are entering a new
block. Consume the entire block. */
else if (token->type == CPP_OPEN_BRACE)
++nesting_depth;
/* Consume the token. */
cp_lexer_consume_token (parser->lexer);
}
}
/* Create a new C++ parser. */
static cp_parser *
cp_parser_new (void)
{
cp_parser *parser;
cp_lexer *lexer;
/* cp_lexer_new_main is called before calling ggc_alloc because
cp_lexer_new_main might load a PCH file. */
lexer = cp_lexer_new_main ();
parser = (cp_parser *) ggc_alloc_cleared (sizeof (cp_parser));
parser->lexer = lexer;
parser->context = cp_parser_context_new (NULL);
/* For now, we always accept GNU extensions. */
parser->allow_gnu_extensions_p = 1;
/* The `>' token is a greater-than operator, not the end of a
template-id. */
parser->greater_than_is_operator_p = true;
parser->default_arg_ok_p = true;
/* We are not parsing a constant-expression. */
parser->constant_expression_p = false;
parser->allow_non_constant_expression_p = false;
parser->non_constant_expression_p = false;
/* Local variable names are not forbidden. */
parser->local_variables_forbidden_p = false;
/* We are not procesing an `extern "C"' declaration. */
parser->in_unbraced_linkage_specification_p = false;
/* We are not processing a declarator. */
parser->in_declarator_p = false;
/* The unparsed function queue is empty. */
parser->unparsed_functions_queues = build_tree_list (NULL_TREE, NULL_TREE);
/* There are no classes being defined. */
parser->num_classes_being_defined = 0;
/* No template parameters apply. */
parser->num_template_parameter_lists = 0;
return parser;
}
/* Lexical conventions [gram.lex] */
/* Parse an identifier. Returns an IDENTIFIER_NODE representing the
identifier. */
static tree
cp_parser_identifier (cp_parser* parser)
{
cp_token *token;
/* Look for the identifier. */
token = cp_parser_require (parser, CPP_NAME, "identifier");
/* Return the value. */
return token ? token->value : error_mark_node;
}
/* Basic concepts [gram.basic] */
/* Parse a translation-unit.
translation-unit:
declaration-seq [opt]
Returns TRUE if all went well. */
static bool
cp_parser_translation_unit (cp_parser* parser)
{
while (true)
{
cp_parser_declaration_seq_opt (parser);
/* If there are no tokens left then all went well. */
if (cp_lexer_next_token_is (parser->lexer, CPP_EOF))
break;
/* Otherwise, issue an error message. */
cp_parser_error (parser, "expected declaration");
return false;
}
/* Consume the EOF token. */
cp_parser_require (parser, CPP_EOF, "end-of-file");
/* Finish up. */
finish_translation_unit ();
/* All went well. */
return true;
}
/* Expressions [gram.expr] */
/* Parse a primary-expression.
primary-expression:
literal
this
( expression )
id-expression
GNU Extensions:
primary-expression:
( compound-statement )
__builtin_va_arg ( assignment-expression , type-id )
literal:
__null
Returns a representation of the expression.
*IDK indicates what kind of id-expression (if any) was present.
*QUALIFYING_CLASS is set to a non-NULL value if the id-expression can be
used as the operand of a pointer-to-member. In that case,
*QUALIFYING_CLASS gives the class that is used as the qualifying
class in the pointer-to-member. */
static tree
cp_parser_primary_expression (cp_parser *parser,
cp_parser_id_kind *idk,
tree *qualifying_class)
{
cp_token *token;
/* Assume the primary expression is not an id-expression. */
*idk = CP_PARSER_ID_KIND_NONE;
/* And that it cannot be used as pointer-to-member. */
*qualifying_class = NULL_TREE;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
switch (token->type)
{
/* literal:
integer-literal
character-literal
floating-literal
string-literal
boolean-literal */
case CPP_CHAR:
case CPP_WCHAR:
case CPP_STRING:
case CPP_WSTRING:
case CPP_NUMBER:
token = cp_lexer_consume_token (parser->lexer);
return token->value;
case CPP_OPEN_PAREN:
{
tree expr;
bool saved_greater_than_is_operator_p;
/* Consume the `('. */
cp_lexer_consume_token (parser->lexer);
/* Within a parenthesized expression, a `>' token is always
the greater-than operator. */
saved_greater_than_is_operator_p
= parser->greater_than_is_operator_p;
parser->greater_than_is_operator_p = true;
/* If we see `( { ' then we are looking at the beginning of
a GNU statement-expression. */
if (cp_parser_allow_gnu_extensions_p (parser)
&& cp_lexer_next_token_is (parser->lexer, CPP_OPEN_BRACE))
{
/* Statement-expressions are not allowed by the standard. */
if (pedantic)
pedwarn ("ISO C++ forbids braced-groups within expressions");
/* And they're not allowed outside of a function-body; you
cannot, for example, write:
int i = ({ int j = 3; j + 1; });
at class or namespace scope. */
if (!at_function_scope_p ())
error ("statement-expressions are allowed only inside functions");
/* Start the statement-expression. */
expr = begin_stmt_expr ();
/* Parse the compound-statement. */
cp_parser_compound_statement (parser);
/* Finish up. */
expr = finish_stmt_expr (expr);
}
else
{
/* Parse the parenthesized expression. */
expr = cp_parser_expression (parser);
/* Let the front end know that this expression was
enclosed in parentheses. This matters in case, for
example, the expression is of the form `A::B', since
`&A::B' might be a pointer-to-member, but `&(A::B)' is
not. */
finish_parenthesized_expr (expr);
}
/* The `>' token might be the end of a template-id or
template-parameter-list now. */
parser->greater_than_is_operator_p
= saved_greater_than_is_operator_p;
/* Consume the `)'. */
if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"))
cp_parser_skip_to_end_of_statement (parser);
return expr;
}
case CPP_KEYWORD:
switch (token->keyword)
{
/* These two are the boolean literals. */
case RID_TRUE:
cp_lexer_consume_token (parser->lexer);
return boolean_true_node;
case RID_FALSE:
cp_lexer_consume_token (parser->lexer);
return boolean_false_node;
/* The `__null' literal. */
case RID_NULL:
cp_lexer_consume_token (parser->lexer);
return null_node;
/* Recognize the `this' keyword. */
case RID_THIS:
cp_lexer_consume_token (parser->lexer);
if (parser->local_variables_forbidden_p)
{
error ("`this' may not be used in this context");
return error_mark_node;
}
/* Pointers cannot appear in constant-expressions. */
if (parser->constant_expression_p)
{
if (!parser->allow_non_constant_expression_p)
return cp_parser_non_constant_expression ("`this'");
parser->non_constant_expression_p = true;
}
return finish_this_expr ();
/* The `operator' keyword can be the beginning of an
id-expression. */
case RID_OPERATOR:
goto id_expression;
case RID_FUNCTION_NAME:
case RID_PRETTY_FUNCTION_NAME:
case RID_C99_FUNCTION_NAME:
/* The symbols __FUNCTION__, __PRETTY_FUNCTION__, and
__func__ are the names of variables -- but they are
treated specially. Therefore, they are handled here,
rather than relying on the generic id-expression logic
below. Gramatically, these names are id-expressions.
Consume the token. */
token = cp_lexer_consume_token (parser->lexer);
/* Look up the name. */
return finish_fname (token->value);
case RID_VA_ARG:
{
tree expression;
tree type;
/* The `__builtin_va_arg' construct is used to handle
`va_arg'. Consume the `__builtin_va_arg' token. */
cp_lexer_consume_token (parser->lexer);
/* Look for the opening `('. */
cp_parser_require (parser, CPP_OPEN_PAREN, "`('");
/* Now, parse the assignment-expression. */
expression = cp_parser_assignment_expression (parser);
/* Look for the `,'. */
cp_parser_require (parser, CPP_COMMA, "`,'");
/* Parse the type-id. */
type = cp_parser_type_id (parser);
/* Look for the closing `)'. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
/* Using `va_arg' in a constant-expression is not
allowed. */
if (parser->constant_expression_p)
{
if (!parser->allow_non_constant_expression_p)
return cp_parser_non_constant_expression ("`va_arg'");
parser->non_constant_expression_p = true;
}
return build_x_va_arg (expression, type);
}
default:
cp_parser_error (parser, "expected primary-expression");
return error_mark_node;
}
/* Fall through. */
/* An id-expression can start with either an identifier, a
`::' as the beginning of a qualified-id, or the "operator"
keyword. */
case CPP_NAME:
case CPP_SCOPE:
case CPP_TEMPLATE_ID:
case CPP_NESTED_NAME_SPECIFIER:
{
tree id_expression;
tree decl;
id_expression:
/* Parse the id-expression. */
id_expression
= cp_parser_id_expression (parser,
/*template_keyword_p=*/false,
/*check_dependency_p=*/true,
/*template_p=*/NULL);
if (id_expression == error_mark_node)
return error_mark_node;
/* If we have a template-id, then no further lookup is
required. If the template-id was for a template-class, we
will sometimes have a TYPE_DECL at this point. */
else if (TREE_CODE (id_expression) == TEMPLATE_ID_EXPR
|| TREE_CODE (id_expression) == TYPE_DECL)
decl = id_expression;
/* Look up the name. */
else
{
decl = cp_parser_lookup_name_simple (parser, id_expression);
/* If name lookup gives us a SCOPE_REF, then the
qualifying scope was dependent. Just propagate the
name. */
if (TREE_CODE (decl) == SCOPE_REF)
{
if (TYPE_P (TREE_OPERAND (decl, 0)))
*qualifying_class = TREE_OPERAND (decl, 0);
/* Since this name was dependent, the expression isn't
constant -- yet. No error is issued because it
might be constant when things are instantiated. */
if (parser->constant_expression_p)
parser->non_constant_expression_p = true;
return decl;
}
/* Check to see if DECL is a local variable in a context
where that is forbidden. */
if (parser->local_variables_forbidden_p
&& local_variable_p (decl))
{
/* It might be that we only found DECL because we are
trying to be generous with pre-ISO scoping rules.
For example, consider:
int i;
void g() {
for (int i = 0; i < 10; ++i) {}
extern void f(int j = i);
}
Here, name look up will originally find the out
of scope `i'. We need to issue a warning message,
but then use the global `i'. */
decl = check_for_out_of_scope_variable (decl);
if (local_variable_p (decl))
{
error ("local variable `%D' may not appear in this context",
decl);
return error_mark_node;
}
}
if (decl == error_mark_node)
{
/* Name lookup failed. */
if (!parser->scope
&& processing_template_decl)
{
/* Unqualified name lookup failed while processing a
template. */
*idk = CP_PARSER_ID_KIND_UNQUALIFIED;
/* If the next token is a parenthesis, assume that
Koenig lookup will succeed when instantiating the
template. */
if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN))
return build_min_nt (LOOKUP_EXPR, id_expression);
/* If we're not doing Koenig lookup, issue an error. */
error ("`%D' has not been declared", id_expression);
return error_mark_node;
}
else if (parser->scope
&& (!TYPE_P (parser->scope)
|| !dependent_type_p (parser->scope)))
{
/* Qualified name lookup failed, and the
qualifying name was not a dependent type. That
is always an error. */
if (TYPE_P (parser->scope)
&& !COMPLETE_TYPE_P (parser->scope))
error ("incomplete type `%T' used in nested name "
"specifier",
parser->scope);
else if (parser->scope != global_namespace)
error ("`%D' is not a member of `%D'",
id_expression, parser->scope);
else
error ("`::%D' has not been declared", id_expression);
return error_mark_node;
}
else if (!parser->scope && !processing_template_decl)
{
/* It may be resolvable as a koenig lookup function
call. */
*idk = CP_PARSER_ID_KIND_UNQUALIFIED;
return id_expression;
}
}
/* If DECL is a variable that would be out of scope under
ANSI/ISO rules, but in scope in the ARM, name lookup
will succeed. Issue a diagnostic here. */
else
decl = check_for_out_of_scope_variable (decl);
/* Remember that the name was used in the definition of
the current class so that we can check later to see if
the meaning would have been different after the class
was entirely defined. */
if (!parser->scope && decl != error_mark_node)
maybe_note_name_used_in_class (id_expression, decl);
}
/* If we didn't find anything, or what we found was a type,
then this wasn't really an id-expression. */
if (TREE_CODE (decl) == TEMPLATE_DECL
&& !DECL_FUNCTION_TEMPLATE_P (decl))
{
cp_parser_error (parser, "missing template arguments");
return error_mark_node;
}
else if (TREE_CODE (decl) == TYPE_DECL
|| TREE_CODE (decl) == NAMESPACE_DECL)
{
cp_parser_error (parser,
"expected primary-expression");
return error_mark_node;
}
/* If the name resolved to a template parameter, there is no
need to look it up again later. Similarly, we resolve
enumeration constants to their underlying values. */
if (TREE_CODE (decl) == CONST_DECL)
{
*idk = CP_PARSER_ID_KIND_NONE;
if (DECL_TEMPLATE_PARM_P (decl) || !processing_template_decl)
return DECL_INITIAL (decl);
return decl;
}
else
{
bool dependent_p;
/* If the declaration was explicitly qualified indicate
that. The semantics of `A::f(3)' are different than
`f(3)' if `f' is virtual. */
*idk = (parser->scope
? CP_PARSER_ID_KIND_QUALIFIED
: (TREE_CODE (decl) == TEMPLATE_ID_EXPR
? CP_PARSER_ID_KIND_TEMPLATE_ID
: CP_PARSER_ID_KIND_UNQUALIFIED));
/* [temp.dep.expr]
An id-expression is type-dependent if it contains an
identifier that was declared with a dependent type.
As an optimization, we could choose not to create a
LOOKUP_EXPR for a name that resolved to a local
variable in the template function that we are currently
declaring; such a name cannot ever resolve to anything
else. If we did that we would not have to look up
these names at instantiation time.
The standard is not very specific about an
id-expression that names a set of overloaded functions.
What if some of them have dependent types and some of
them do not? Presumably, such a name should be treated
as a dependent name. */
/* Assume the name is not dependent. */
dependent_p = false;
if (!processing_template_decl)
/* No names are dependent outside a template. */
;
/* A template-id where the name of the template was not
resolved is definitely dependent. */
else if (TREE_CODE (decl) == TEMPLATE_ID_EXPR
&& (TREE_CODE (TREE_OPERAND (decl, 0))
== IDENTIFIER_NODE))
dependent_p = true;
/* For anything except an overloaded function, just check
its type. */
else if (!is_overloaded_fn (decl))
dependent_p
= dependent_type_p (TREE_TYPE (decl));
/* For a set of overloaded functions, check each of the
functions. */
else
{
tree fns = decl;
if (BASELINK_P (fns))
fns = BASELINK_FUNCTIONS (fns);
/* For a template-id, check to see if the template
arguments are dependent. */
if (TREE_CODE (fns) == TEMPLATE_ID_EXPR)
{
tree args = TREE_OPERAND (fns, 1);
if (args && TREE_CODE (args) == TREE_LIST)
{
while (args)
{
if (dependent_template_arg_p (TREE_VALUE (args)))
{
dependent_p = true;
break;
}
args = TREE_CHAIN (args);
}
}
else if (args && TREE_CODE (args) == TREE_VEC)
{
int i;
for (i = 0; i < TREE_VEC_LENGTH (args); ++i)
if (dependent_template_arg_p (TREE_VEC_ELT (args, i)))
{
dependent_p = true;
break;
}
}
/* The functions are those referred to by the
template-id. */
fns = TREE_OPERAND (fns, 0);
}
/* If there are no dependent template arguments, go
through the overlaoded functions. */
while (fns && !dependent_p)
{
tree fn = OVL_CURRENT (fns);
/* Member functions of dependent classes are
dependent. */
if (TREE_CODE (fn) == FUNCTION_DECL
&& type_dependent_expression_p (fn))
dependent_p = true;
else if (TREE_CODE (fn) == TEMPLATE_DECL
&& dependent_template_p (fn))
dependent_p = true;
fns = OVL_NEXT (fns);
}
}
/* If the name was dependent on a template parameter,
we will resolve the name at instantiation time. */
if (dependent_p)
{
/* Create a SCOPE_REF for qualified names. */
if (parser->scope)
{
if (TYPE_P (parser->scope))
*qualifying_class = parser->scope;
/* Since this name was dependent, the expression isn't
constant -- yet. No error is issued because it
might be constant when things are instantiated. */
if (parser->constant_expression_p)
parser->non_constant_expression_p = true;
return build_nt (SCOPE_REF,
parser->scope,
id_expression);
}
/* A TEMPLATE_ID already contains all the information
we need. */
if (TREE_CODE (id_expression) == TEMPLATE_ID_EXPR)
return id_expression;
/* Since this name was dependent, the expression isn't
constant -- yet. No error is issued because it
might be constant when things are instantiated. */
if (parser->constant_expression_p)
parser->non_constant_expression_p = true;
/* Create a LOOKUP_EXPR for other unqualified names. */
return build_min_nt (LOOKUP_EXPR, id_expression);
}
/* Only certain kinds of names are allowed in constant
expression. Enumerators have already been handled
above. */
if (parser->constant_expression_p
/* Non-type template parameters of integral or
enumeration type. */
&& !(TREE_CODE (decl) == TEMPLATE_PARM_INDEX
&& INTEGRAL_OR_ENUMERATION_TYPE_P (TREE_TYPE (decl)))
/* Const variables or static data members of integral
or enumeration types initialized with constant
expressions. */
&& !(TREE_CODE (decl) == VAR_DECL
&& INTEGRAL_OR_ENUMERATION_TYPE_P (TREE_TYPE (decl))
&& DECL_INITIAL (decl)
&& TREE_CONSTANT (DECL_INITIAL (decl))))
{
if (!parser->allow_non_constant_expression_p)
return cp_parser_non_constant_id_expression (decl);
parser->non_constant_expression_p = true;
}
if (parser->scope)
{
decl = (adjust_result_of_qualified_name_lookup
(decl, parser->scope, current_class_type));
if (TREE_CODE (decl) == FIELD_DECL || BASELINK_P (decl))
*qualifying_class = parser->scope;
else if (!processing_template_decl)
decl = convert_from_reference (decl);
}
else
/* Transform references to non-static data members into
COMPONENT_REFs. */
decl = hack_identifier (decl, id_expression);
/* Resolve references to variables of anonymous unions
into COMPONENT_REFs. */
if (TREE_CODE (decl) == ALIAS_DECL)
decl = DECL_INITIAL (decl);
}
if (TREE_DEPRECATED (decl))
warn_deprecated_use (decl);
return decl;
}
/* Anything else is an error. */
default:
cp_parser_error (parser, "expected primary-expression");
return error_mark_node;
}
}
/* Parse an id-expression.
id-expression:
unqualified-id
qualified-id
qualified-id:
:: [opt] nested-name-specifier template [opt] unqualified-id
:: identifier
:: operator-function-id
:: template-id
Return a representation of the unqualified portion of the
identifier. Sets PARSER->SCOPE to the qualifying scope if there is
a `::' or nested-name-specifier.
Often, if the id-expression was a qualified-id, the caller will
want to make a SCOPE_REF to represent the qualified-id. This
function does not do this in order to avoid wastefully creating
SCOPE_REFs when they are not required.
If TEMPLATE_KEYWORD_P is true, then we have just seen the
`template' keyword.
If CHECK_DEPENDENCY_P is false, then names are looked up inside
uninstantiated templates.
If *TEMPLATE_P is non-NULL, it is set to true iff the
`template' keyword is used to explicitly indicate that the entity
named is a template. */
static tree
cp_parser_id_expression (cp_parser *parser,
bool template_keyword_p,
bool check_dependency_p,
bool *template_p)
{
bool global_scope_p;
bool nested_name_specifier_p;
/* Assume the `template' keyword was not used. */
if (template_p)
*template_p = false;
/* Look for the optional `::' operator. */
global_scope_p
= (cp_parser_global_scope_opt (parser, /*current_scope_valid_p=*/false)
!= NULL_TREE);
/* Look for the optional nested-name-specifier. */
nested_name_specifier_p
= (cp_parser_nested_name_specifier_opt (parser,
/*typename_keyword_p=*/false,
check_dependency_p,
/*type_p=*/false)
!= NULL_TREE);
/* If there is a nested-name-specifier, then we are looking at
the first qualified-id production. */
if (nested_name_specifier_p)
{
tree saved_scope;
tree saved_object_scope;
tree saved_qualifying_scope;
tree unqualified_id;
bool is_template;
/* See if the next token is the `template' keyword. */
if (!template_p)
template_p = &is_template;
*template_p = cp_parser_optional_template_keyword (parser);
/* Name lookup we do during the processing of the
unqualified-id might obliterate SCOPE. */
saved_scope = parser->scope;
saved_object_scope = parser->object_scope;
saved_qualifying_scope = parser->qualifying_scope;
/* Process the final unqualified-id. */
unqualified_id = cp_parser_unqualified_id (parser, *template_p,
check_dependency_p);
/* Restore the SAVED_SCOPE for our caller. */
parser->scope = saved_scope;
parser->object_scope = saved_object_scope;
parser->qualifying_scope = saved_qualifying_scope;
return unqualified_id;
}
/* Otherwise, if we are in global scope, then we are looking at one
of the other qualified-id productions. */
else if (global_scope_p)
{
cp_token *token;
tree id;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If it's an identifier, and the next token is not a "<", then
we can avoid the template-id case. This is an optimization
for this common case. */
if (token->type == CPP_NAME
&& cp_lexer_peek_nth_token (parser->lexer, 2)->type != CPP_LESS)
return cp_parser_identifier (parser);
cp_parser_parse_tentatively (parser);
/* Try a template-id. */
id = cp_parser_template_id (parser,
/*template_keyword_p=*/false,
/*check_dependency_p=*/true);
/* If that worked, we're done. */
if (cp_parser_parse_definitely (parser))
return id;
/* Peek at the next token. (Changes in the token buffer may
have invalidated the pointer obtained above.) */
token = cp_lexer_peek_token (parser->lexer);
switch (token->type)
{
case CPP_NAME:
return cp_parser_identifier (parser);
case CPP_KEYWORD:
if (token->keyword == RID_OPERATOR)
return cp_parser_operator_function_id (parser);
/* Fall through. */
default:
cp_parser_error (parser, "expected id-expression");
return error_mark_node;
}
}
else
return cp_parser_unqualified_id (parser, template_keyword_p,
/*check_dependency_p=*/true);
}
/* Parse an unqualified-id.
unqualified-id:
identifier
operator-function-id
conversion-function-id
~ class-name
template-id
If TEMPLATE_KEYWORD_P is TRUE, we have just seen the `template'
keyword, in a construct like `A::template ...'.
Returns a representation of unqualified-id. For the `identifier'
production, an IDENTIFIER_NODE is returned. For the `~ class-name'
production a BIT_NOT_EXPR is returned; the operand of the
BIT_NOT_EXPR is an IDENTIFIER_NODE for the class-name. For the
other productions, see the documentation accompanying the
corresponding parsing functions. If CHECK_DEPENDENCY_P is false,
names are looked up in uninstantiated templates. */
static tree
cp_parser_unqualified_id (cp_parser* parser,
bool template_keyword_p,
bool check_dependency_p)
{
cp_token *token;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
switch (token->type)
{
case CPP_NAME:
{
tree id;
/* We don't know yet whether or not this will be a
template-id. */
cp_parser_parse_tentatively (parser);
/* Try a template-id. */
id = cp_parser_template_id (parser, template_keyword_p,
check_dependency_p);
/* If it worked, we're done. */
if (cp_parser_parse_definitely (parser))
return id;
/* Otherwise, it's an ordinary identifier. */
return cp_parser_identifier (parser);
}
case CPP_TEMPLATE_ID:
return cp_parser_template_id (parser, template_keyword_p,
check_dependency_p);
case CPP_COMPL:
{
tree type_decl;
tree qualifying_scope;
tree object_scope;
tree scope;
/* Consume the `~' token. */
cp_lexer_consume_token (parser->lexer);
/* Parse the class-name. The standard, as written, seems to
say that:
template <typename T> struct S { ~S (); };
template <typename T> S<T>::~S() {}
is invalid, since `~' must be followed by a class-name, but
`S<T>' is dependent, and so not known to be a class.
That's not right; we need to look in uninstantiated
templates. A further complication arises from:
template <typename T> void f(T t) {
t.T::~T();
}
Here, it is not possible to look up `T' in the scope of `T'
itself. We must look in both the current scope, and the
scope of the containing complete expression.
Yet another issue is:
struct S {
int S;
~S();
};
S::~S() {}
The standard does not seem to say that the `S' in `~S'
should refer to the type `S' and not the data member
`S::S'. */
/* DR 244 says that we look up the name after the "~" in the
same scope as we looked up the qualifying name. That idea
isn't fully worked out; it's more complicated than that. */
scope = parser->scope;
object_scope = parser->object_scope;
qualifying_scope = parser->qualifying_scope;
/* If the name is of the form "X::~X" it's OK. */
if (scope && TYPE_P (scope)
&& cp_lexer_next_token_is (parser->lexer, CPP_NAME)
&& (cp_lexer_peek_nth_token (parser->lexer, 2)->type
== CPP_OPEN_PAREN)
&& (cp_lexer_peek_token (parser->lexer)->value
== TYPE_IDENTIFIER (scope)))
{
cp_lexer_consume_token (parser->lexer);
return build_nt (BIT_NOT_EXPR, scope);
}
/* If there was an explicit qualification (S::~T), first look
in the scope given by the qualification (i.e., S). */
if (scope)
{
cp_parser_parse_tentatively (parser);
type_decl = cp_parser_class_name (parser,
/*typename_keyword_p=*/false,
/*template_keyword_p=*/false,
/*type_p=*/false,
/*check_dependency=*/false,
/*class_head_p=*/false);
if (cp_parser_parse_definitely (parser))
return build_nt (BIT_NOT_EXPR, TREE_TYPE (type_decl));
}
/* In "N::S::~S", look in "N" as well. */
if (scope && qualifying_scope)
{
cp_parser_parse_tentatively (parser);
parser->scope = qualifying_scope;
parser->object_scope = NULL_TREE;
parser->qualifying_scope = NULL_TREE;
type_decl
= cp_parser_class_name (parser,
/*typename_keyword_p=*/false,
/*template_keyword_p=*/false,
/*type_p=*/false,
/*check_dependency=*/false,
/*class_head_p=*/false);
if (cp_parser_parse_definitely (parser))
return build_nt (BIT_NOT_EXPR, TREE_TYPE (type_decl));
}
/* In "p->S::~T", look in the scope given by "*p" as well. */
else if (object_scope)
{
cp_parser_parse_tentatively (parser);
parser->scope = object_scope;
parser->object_scope = NULL_TREE;
parser->qualifying_scope = NULL_TREE;
type_decl
= cp_parser_class_name (parser,
/*typename_keyword_p=*/false,
/*template_keyword_p=*/false,
/*type_p=*/false,
/*check_dependency=*/false,
/*class_head_p=*/false);
if (cp_parser_parse_definitely (parser))
return build_nt (BIT_NOT_EXPR, TREE_TYPE (type_decl));
}
/* Look in the surrounding context. */
parser->scope = NULL_TREE;
parser->object_scope = NULL_TREE;
parser->qualifying_scope = NULL_TREE;
type_decl
= cp_parser_class_name (parser,
/*typename_keyword_p=*/false,
/*template_keyword_p=*/false,
/*type_p=*/false,
/*check_dependency=*/false,
/*class_head_p=*/false);
/* If an error occurred, assume that the name of the
destructor is the same as the name of the qualifying
class. That allows us to keep parsing after running
into ill-formed destructor names. */
if (type_decl == error_mark_node && scope && TYPE_P (scope))
return build_nt (BIT_NOT_EXPR, scope);
else if (type_decl == error_mark_node)
return error_mark_node;
return build_nt (BIT_NOT_EXPR, TREE_TYPE (type_decl));
}
case CPP_KEYWORD:
if (token->keyword == RID_OPERATOR)
{
tree id;
/* This could be a template-id, so we try that first. */
cp_parser_parse_tentatively (parser);
/* Try a template-id. */
id = cp_parser_template_id (parser, template_keyword_p,
/*check_dependency_p=*/true);
/* If that worked, we're done. */
if (cp_parser_parse_definitely (parser))
return id;
/* We still don't know whether we're looking at an
operator-function-id or a conversion-function-id. */
cp_parser_parse_tentatively (parser);
/* Try an operator-function-id. */
id = cp_parser_operator_function_id (parser);
/* If that didn't work, try a conversion-function-id. */
if (!cp_parser_parse_definitely (parser))
id = cp_parser_conversion_function_id (parser);
return id;
}
/* Fall through. */
default:
cp_parser_error (parser, "expected unqualified-id");
return error_mark_node;
}
}
/* Parse an (optional) nested-name-specifier.
nested-name-specifier:
class-or-namespace-name :: nested-name-specifier [opt]
class-or-namespace-name :: template nested-name-specifier [opt]
PARSER->SCOPE should be set appropriately before this function is
called. TYPENAME_KEYWORD_P is TRUE if the `typename' keyword is in
effect. TYPE_P is TRUE if we non-type bindings should be ignored
in name lookups.
Sets PARSER->SCOPE to the class (TYPE) or namespace
(NAMESPACE_DECL) specified by the nested-name-specifier, or leaves
it unchanged if there is no nested-name-specifier. Returns the new
scope iff there is a nested-name-specifier, or NULL_TREE otherwise. */
static tree
cp_parser_nested_name_specifier_opt (cp_parser *parser,
bool typename_keyword_p,
bool check_dependency_p,
bool type_p)
{
bool success = false;
tree access_check = NULL_TREE;
ptrdiff_t start;
cp_token* token;
/* If the next token corresponds to a nested name specifier, there
is no need to reparse it. However, if CHECK_DEPENDENCY_P is
false, it may have been true before, in which case something
like `A<X>::B<Y>::C' may have resulted in a nested-name-specifier
of `A<X>::', where it should now be `A<X>::B<Y>::'. So, when
CHECK_DEPENDENCY_P is false, we have to fall through into the
main loop. */
if (check_dependency_p
&& cp_lexer_next_token_is (parser->lexer, CPP_NESTED_NAME_SPECIFIER))
{
cp_parser_pre_parsed_nested_name_specifier (parser);
return parser->scope;
}
/* Remember where the nested-name-specifier starts. */
if (cp_parser_parsing_tentatively (parser)
&& !cp_parser_committed_to_tentative_parse (parser))
{
token = cp_lexer_peek_token (parser->lexer);
start = cp_lexer_token_difference (parser->lexer,
parser->lexer->first_token,
token);
}
else
start = -1;
push_deferring_access_checks (dk_deferred);
while (true)
{
tree new_scope;
tree old_scope;
tree saved_qualifying_scope;
bool template_keyword_p;
/* Spot cases that cannot be the beginning of a
nested-name-specifier. */
token = cp_lexer_peek_token (parser->lexer);
/* If the next token is CPP_NESTED_NAME_SPECIFIER, just process
the already parsed nested-name-specifier. */
if (token->type == CPP_NESTED_NAME_SPECIFIER)
{
/* Grab the nested-name-specifier and continue the loop. */
cp_parser_pre_parsed_nested_name_specifier (parser);
success = true;
continue;
}
/* Spot cases that cannot be the beginning of a
nested-name-specifier. On the second and subsequent times
through the loop, we look for the `template' keyword. */
if (success && token->keyword == RID_TEMPLATE)
;
/* A template-id can start a nested-name-specifier. */
else if (token->type == CPP_TEMPLATE_ID)
;
else
{
/* If the next token is not an identifier, then it is
definitely not a class-or-namespace-name. */
if (token->type != CPP_NAME)
break;
/* If the following token is neither a `<' (to begin a
template-id), nor a `::', then we are not looking at a
nested-name-specifier. */
token = cp_lexer_peek_nth_token (parser->lexer, 2);
if (token->type != CPP_LESS && token->type != CPP_SCOPE)
break;
}
/* The nested-name-specifier is optional, so we parse
tentatively. */
cp_parser_parse_tentatively (parser);
/* Look for the optional `template' keyword, if this isn't the
first time through the loop. */
if (success)
template_keyword_p = cp_parser_optional_template_keyword (parser);
else
template_keyword_p = false;
/* Save the old scope since the name lookup we are about to do
might destroy it. */
old_scope = parser->scope;
saved_qualifying_scope = parser->qualifying_scope;
/* Parse the qualifying entity. */
new_scope
= cp_parser_class_or_namespace_name (parser,
typename_keyword_p,
template_keyword_p,
check_dependency_p,
type_p);
/* Look for the `::' token. */
cp_parser_require (parser, CPP_SCOPE, "`::'");
/* If we found what we wanted, we keep going; otherwise, we're
done. */
if (!cp_parser_parse_definitely (parser))
{
bool error_p = false;
/* Restore the OLD_SCOPE since it was valid before the
failed attempt at finding the last
class-or-namespace-name. */
parser->scope = old_scope;
parser->qualifying_scope = saved_qualifying_scope;
/* If the next token is an identifier, and the one after
that is a `::', then any valid interpretation would have
found a class-or-namespace-name. */
while (cp_lexer_next_token_is (parser->lexer, CPP_NAME)
&& (cp_lexer_peek_nth_token (parser->lexer, 2)->type
== CPP_SCOPE)
&& (cp_lexer_peek_nth_token (parser->lexer, 3)->type
!= CPP_COMPL))
{
token = cp_lexer_consume_token (parser->lexer);
if (!error_p)
{
tree decl;
decl = cp_parser_lookup_name_simple (parser, token->value);
if (TREE_CODE (decl) == TEMPLATE_DECL)
error ("`%D' used without template parameters",
decl);
else if (parser->scope)
{
if (TYPE_P (parser->scope))
error ("`%T::%D' is not a class-name or "
"namespace-name",
parser->scope, token->value);
else
error ("`%D::%D' is not a class-name or "
"namespace-name",
parser->scope, token->value);
}
else
error ("`%D' is not a class-name or namespace-name",
token->value);
parser->scope = NULL_TREE;
error_p = true;
/* Treat this as a successful nested-name-specifier
due to:
[basic.lookup.qual]
If the name found is not a class-name (clause
_class_) or namespace-name (_namespace.def_), the
program is ill-formed. */
success = true;
}
cp_lexer_consume_token (parser->lexer);
}
break;
}
/* We've found one valid nested-name-specifier. */
success = true;
/* Make sure we look in the right scope the next time through
the loop. */
parser->scope = (TREE_CODE (new_scope) == TYPE_DECL
? TREE_TYPE (new_scope)
: new_scope);
/* If it is a class scope, try to complete it; we are about to
be looking up names inside the class. */
if (TYPE_P (parser->scope)
/* Since checking types for dependency can be expensive,
avoid doing it if the type is already complete. */
&& !COMPLETE_TYPE_P (parser->scope)
/* Do not try to complete dependent types. */
&& !dependent_type_p (parser->scope))
complete_type (parser->scope);
}
/* Retrieve any deferred checks. Do not pop this access checks yet
so the memory will not be reclaimed during token replacing below. */
access_check = get_deferred_access_checks ();
/* If parsing tentatively, replace the sequence of tokens that makes
up the nested-name-specifier with a CPP_NESTED_NAME_SPECIFIER
token. That way, should we re-parse the token stream, we will
not have to repeat the effort required to do the parse, nor will
we issue duplicate error messages. */
if (success && start >= 0)
{
/* Find the token that corresponds to the start of the
template-id. */
token = cp_lexer_advance_token (parser->lexer,
parser->lexer->first_token,
start);
/* Reset the contents of the START token. */
token->type = CPP_NESTED_NAME_SPECIFIER;
token->value = build_tree_list (access_check, parser->scope);
TREE_TYPE (token->value) = parser->qualifying_scope;
token->keyword = RID_MAX;
/* Purge all subsequent tokens. */
cp_lexer_purge_tokens_after (parser->lexer, token);
}
pop_deferring_access_checks ();
return success ? parser->scope : NULL_TREE;
}
/* Parse a nested-name-specifier. See
cp_parser_nested_name_specifier_opt for details. This function
behaves identically, except that it will an issue an error if no
nested-name-specifier is present, and it will return
ERROR_MARK_NODE, rather than NULL_TREE, if no nested-name-specifier
is present. */
static tree
cp_parser_nested_name_specifier (cp_parser *parser,
bool typename_keyword_p,
bool check_dependency_p,
bool type_p)
{
tree scope;
/* Look for the nested-name-specifier. */
scope = cp_parser_nested_name_specifier_opt (parser,
typename_keyword_p,
check_dependency_p,
type_p);
/* If it was not present, issue an error message. */
if (!scope)
{
cp_parser_error (parser, "expected nested-name-specifier");
return error_mark_node;
}
return scope;
}
/* Parse a class-or-namespace-name.
class-or-namespace-name:
class-name
namespace-name
TYPENAME_KEYWORD_P is TRUE iff the `typename' keyword is in effect.
TEMPLATE_KEYWORD_P is TRUE iff the `template' keyword is in effect.
CHECK_DEPENDENCY_P is FALSE iff dependent names should be looked up.
TYPE_P is TRUE iff the next name should be taken as a class-name,
even the same name is declared to be another entity in the same
scope.
Returns the class (TYPE_DECL) or namespace (NAMESPACE_DECL)
specified by the class-or-namespace-name. If neither is found the
ERROR_MARK_NODE is returned. */
static tree
cp_parser_class_or_namespace_name (cp_parser *parser,
bool typename_keyword_p,
bool template_keyword_p,
bool check_dependency_p,
bool type_p)
{
tree saved_scope;
tree saved_qualifying_scope;
tree saved_object_scope;
tree scope;
bool only_class_p;
/* Before we try to parse the class-name, we must save away the
current PARSER->SCOPE since cp_parser_class_name will destroy
it. */
saved_scope = parser->scope;
saved_qualifying_scope = parser->qualifying_scope;
saved_object_scope = parser->object_scope;
/* Try for a class-name first. If the SAVED_SCOPE is a type, then
there is no need to look for a namespace-name. */
only_class_p = template_keyword_p || (saved_scope && TYPE_P (saved_scope));
if (!only_class_p)
cp_parser_parse_tentatively (parser);
scope = cp_parser_class_name (parser,
typename_keyword_p,
template_keyword_p,
type_p,
check_dependency_p,
/*class_head_p=*/false);
/* If that didn't work, try for a namespace-name. */
if (!only_class_p && !cp_parser_parse_definitely (parser))
{
/* Restore the saved scope. */
parser->scope = saved_scope;
parser->qualifying_scope = saved_qualifying_scope;
parser->object_scope = saved_object_scope;
/* If we are not looking at an identifier followed by the scope
resolution operator, then this is not part of a
nested-name-specifier. (Note that this function is only used
to parse the components of a nested-name-specifier.) */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_NAME)
|| cp_lexer_peek_nth_token (parser->lexer, 2)->type != CPP_SCOPE)
return error_mark_node;
scope = cp_parser_namespace_name (parser);
}
return scope;
}
/* Parse a postfix-expression.
postfix-expression:
primary-expression
postfix-expression [ expression ]
postfix-expression ( expression-list [opt] )
simple-type-specifier ( expression-list [opt] )
typename :: [opt] nested-name-specifier identifier
( expression-list [opt] )
typename :: [opt] nested-name-specifier template [opt] template-id
( expression-list [opt] )
postfix-expression . template [opt] id-expression
postfix-expression -> template [opt] id-expression
postfix-expression . pseudo-destructor-name
postfix-expression -> pseudo-destructor-name
postfix-expression ++
postfix-expression --
dynamic_cast < type-id > ( expression )
static_cast < type-id > ( expression )
reinterpret_cast < type-id > ( expression )
const_cast < type-id > ( expression )
typeid ( expression )
typeid ( type-id )
GNU Extension:
postfix-expression:
( type-id ) { initializer-list , [opt] }
This extension is a GNU version of the C99 compound-literal
construct. (The C99 grammar uses `type-name' instead of `type-id',
but they are essentially the same concept.)
If ADDRESS_P is true, the postfix expression is the operand of the
`&' operator.
Returns a representation of the expression. */
static tree
cp_parser_postfix_expression (cp_parser *parser, bool address_p)
{
cp_token *token;
enum rid keyword;
cp_parser_id_kind idk = CP_PARSER_ID_KIND_NONE;
tree postfix_expression = NULL_TREE;
/* Non-NULL only if the current postfix-expression can be used to
form a pointer-to-member. In that case, QUALIFYING_CLASS is the
class used to qualify the member. */
tree qualifying_class = NULL_TREE;
bool done;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* Some of the productions are determined by keywords. */
keyword = token->keyword;
switch (keyword)
{
case RID_DYNCAST:
case RID_STATCAST:
case RID_REINTCAST:
case RID_CONSTCAST:
{
tree type;
tree expression;
const char *saved_message;
/* All of these can be handled in the same way from the point
of view of parsing. Begin by consuming the token
identifying the cast. */
cp_lexer_consume_token (parser->lexer);
/* New types cannot be defined in the cast. */
saved_message = parser->type_definition_forbidden_message;
parser->type_definition_forbidden_message
= "types may not be defined in casts";
/* Look for the opening `<'. */
cp_parser_require (parser, CPP_LESS, "`<'");
/* Parse the type to which we are casting. */
type = cp_parser_type_id (parser);
/* Look for the closing `>'. */
cp_parser_require (parser, CPP_GREATER, "`>'");
/* Restore the old message. */
parser->type_definition_forbidden_message = saved_message;
/* And the expression which is being cast. */
cp_parser_require (parser, CPP_OPEN_PAREN, "`('");
expression = cp_parser_expression (parser);
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
/* Only type conversions to integral or enumeration types
can be used in constant-expressions. */
if (parser->constant_expression_p
&& !dependent_type_p (type)
&& !INTEGRAL_OR_ENUMERATION_TYPE_P (type))
{
if (!parser->allow_non_constant_expression_p)
return (cp_parser_non_constant_expression
("a cast to a type other than an integral or "
"enumeration type"));
parser->non_constant_expression_p = true;
}
switch (keyword)
{
case RID_DYNCAST:
postfix_expression
= build_dynamic_cast (type, expression);
break;
case RID_STATCAST:
postfix_expression
= build_static_cast (type, expression);
break;
case RID_REINTCAST:
postfix_expression
= build_reinterpret_cast (type, expression);
break;
case RID_CONSTCAST:
postfix_expression
= build_const_cast (type, expression);
break;
default:
abort ();
}
}
break;
case RID_TYPEID:
{
tree type;
const char *saved_message;
/* Consume the `typeid' token. */
cp_lexer_consume_token (parser->lexer);
/* Look for the `(' token. */
cp_parser_require (parser, CPP_OPEN_PAREN, "`('");
/* Types cannot be defined in a `typeid' expression. */
saved_message = parser->type_definition_forbidden_message;
parser->type_definition_forbidden_message
= "types may not be defined in a `typeid\' expression";
/* We can't be sure yet whether we're looking at a type-id or an
expression. */
cp_parser_parse_tentatively (parser);
/* Try a type-id first. */
type = cp_parser_type_id (parser);
/* Look for the `)' token. Otherwise, we can't be sure that
we're not looking at an expression: consider `typeid (int
(3))', for example. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
/* If all went well, simply lookup the type-id. */
if (cp_parser_parse_definitely (parser))
postfix_expression = get_typeid (type);
/* Otherwise, fall back to the expression variant. */
else
{
tree expression;
/* Look for an expression. */
expression = cp_parser_expression (parser);
/* Compute its typeid. */
postfix_expression = build_typeid (expression);
/* Look for the `)' token. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
}
/* Restore the saved message. */
parser->type_definition_forbidden_message = saved_message;
}
break;
case RID_TYPENAME:
{
bool template_p = false;
tree id;
tree type;
/* Consume the `typename' token. */
cp_lexer_consume_token (parser->lexer);
/* Look for the optional `::' operator. */
cp_parser_global_scope_opt (parser,
/*current_scope_valid_p=*/false);
/* Look for the nested-name-specifier. */
cp_parser_nested_name_specifier (parser,
/*typename_keyword_p=*/true,
/*check_dependency_p=*/true,
/*type_p=*/true);
/* Look for the optional `template' keyword. */
template_p = cp_parser_optional_template_keyword (parser);
/* We don't know whether we're looking at a template-id or an
identifier. */
cp_parser_parse_tentatively (parser);
/* Try a template-id. */
id = cp_parser_template_id (parser, template_p,
/*check_dependency_p=*/true);
/* If that didn't work, try an identifier. */
if (!cp_parser_parse_definitely (parser))
id = cp_parser_identifier (parser);
/* Create a TYPENAME_TYPE to represent the type to which the
functional cast is being performed. */
type = make_typename_type (parser->scope, id,
/*complain=*/1);
postfix_expression = cp_parser_functional_cast (parser, type);
}
break;
default:
{
tree type;
/* If the next thing is a simple-type-specifier, we may be
looking at a functional cast. We could also be looking at
an id-expression. So, we try the functional cast, and if
that doesn't work we fall back to the primary-expression. */
cp_parser_parse_tentatively (parser);
/* Look for the simple-type-specifier. */
type = cp_parser_simple_type_specifier (parser,
CP_PARSER_FLAGS_NONE);
/* Parse the cast itself. */
if (!cp_parser_error_occurred (parser))
postfix_expression
= cp_parser_functional_cast (parser, type);
/* If that worked, we're done. */
if (cp_parser_parse_definitely (parser))
break;
/* If the functional-cast didn't work out, try a
compound-literal. */
if (cp_parser_allow_gnu_extensions_p (parser)
&& cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN))
{
tree initializer_list = NULL_TREE;
cp_parser_parse_tentatively (parser);
/* Consume the `('. */
cp_lexer_consume_token (parser->lexer);
/* Parse the type. */
type = cp_parser_type_id (parser);
/* Look for the `)'. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
/* Look for the `{'. */
cp_parser_require (parser, CPP_OPEN_BRACE, "`{'");
/* If things aren't going well, there's no need to
keep going. */
if (!cp_parser_error_occurred (parser))
{
/* Parse the initializer-list. */
initializer_list
= cp_parser_initializer_list (parser);
/* Allow a trailing `,'. */
if (cp_lexer_next_token_is (parser->lexer, CPP_COMMA))
cp_lexer_consume_token (parser->lexer);
/* Look for the final `}'. */
cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'");
}
/* If that worked, we're definitely looking at a
compound-literal expression. */
if (cp_parser_parse_definitely (parser))
{
/* Warn the user that a compound literal is not
allowed in standard C++. */
if (pedantic)
pedwarn ("ISO C++ forbids compound-literals");
/* Form the representation of the compound-literal. */
postfix_expression
= finish_compound_literal (type, initializer_list);
break;
}
}
/* It must be a primary-expression. */
postfix_expression = cp_parser_primary_expression (parser,
&idk,
&qualifying_class);
}
break;
}
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
done = (token->type != CPP_OPEN_SQUARE
&& token->type != CPP_OPEN_PAREN
&& token->type != CPP_DOT
&& token->type != CPP_DEREF
&& token->type != CPP_PLUS_PLUS
&& token->type != CPP_MINUS_MINUS);
/* If the postfix expression is complete, finish up. */
if (address_p && qualifying_class && done)
{
if (TREE_CODE (postfix_expression) == SCOPE_REF)
postfix_expression = TREE_OPERAND (postfix_expression, 1);
postfix_expression
= build_offset_ref (qualifying_class, postfix_expression);
return postfix_expression;
}
/* Otherwise, if we were avoiding committing until we knew
whether or not we had a pointer-to-member, we now know that
the expression is an ordinary reference to a qualified name. */
if (qualifying_class)
{
if (TREE_CODE (postfix_expression) == FIELD_DECL)
postfix_expression
= finish_non_static_data_member (postfix_expression,
qualifying_class);
else if (BASELINK_P (postfix_expression)
&& !processing_template_decl)
{
tree fn;
tree fns;
/* See if any of the functions are non-static members. */
fns = BASELINK_FUNCTIONS (postfix_expression);
if (TREE_CODE (fns) == TEMPLATE_ID_EXPR)
fns = TREE_OPERAND (fns, 0);
for (fn = fns; fn; fn = OVL_NEXT (fn))
if (DECL_NONSTATIC_MEMBER_FUNCTION_P (fn))
break;
/* If so, the expression may be relative to the current
class. */
if (fn && current_class_type
&& DERIVED_FROM_P (qualifying_class, current_class_type))
postfix_expression
= (build_class_member_access_expr
(maybe_dummy_object (qualifying_class, NULL),
postfix_expression,
BASELINK_ACCESS_BINFO (postfix_expression),
/*preserve_reference=*/false));
else if (done)
return build_offset_ref (qualifying_class,
postfix_expression);
}
}
/* Remember that there was a reference to this entity. */
if (DECL_P (postfix_expression))
mark_used (postfix_expression);
/* Keep looping until the postfix-expression is complete. */
while (true)
{
if (TREE_CODE (postfix_expression) == IDENTIFIER_NODE
&& cp_lexer_next_token_is_not (parser->lexer, CPP_OPEN_PAREN))
{
/* It is not a Koenig lookup function call. */
unqualified_name_lookup_error (postfix_expression);
postfix_expression = error_mark_node;
}
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
switch (token->type)
{
case CPP_OPEN_SQUARE:
/* postfix-expression [ expression ] */
{
tree index;
/* Consume the `[' token. */
cp_lexer_consume_token (parser->lexer);
/* Parse the index expression. */
index = cp_parser_expression (parser);
/* Look for the closing `]'. */
cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'");
/* Build the ARRAY_REF. */
postfix_expression
= grok_array_decl (postfix_expression, index);
idk = CP_PARSER_ID_KIND_NONE;
}
break;
case CPP_OPEN_PAREN:
/* postfix-expression ( expression-list [opt] ) */
{
tree args;
/* Consume the `(' token. */
cp_lexer_consume_token (parser->lexer);
/* If the next token is not a `)', then there are some
arguments. */
if (cp_lexer_next_token_is_not (parser->lexer,
CPP_CLOSE_PAREN))
args = cp_parser_expression_list (parser);
else
args = NULL_TREE;
/* Look for the closing `)'. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
/* Function calls are not permitted in
constant-expressions. */
if (parser->constant_expression_p)
{
if (!parser->allow_non_constant_expression_p)
return cp_parser_non_constant_expression ("a function call");
parser->non_constant_expression_p = true;
}
if (idk == CP_PARSER_ID_KIND_UNQUALIFIED
&& (is_overloaded_fn (postfix_expression)
|| DECL_P (postfix_expression)
|| TREE_CODE (postfix_expression) == IDENTIFIER_NODE)
&& args)
{
tree arg;
tree identifier = NULL_TREE;
tree functions = NULL_TREE;
/* Find the name of the overloaded function. */
if (TREE_CODE (postfix_expression) == IDENTIFIER_NODE)
identifier = postfix_expression;
else if (is_overloaded_fn (postfix_expression))
{
functions = postfix_expression;
identifier = DECL_NAME (get_first_fn (functions));
}
else if (DECL_P (postfix_expression))
{
functions = postfix_expression;
identifier = DECL_NAME (postfix_expression);
}
/* A call to a namespace-scope function using an
unqualified name.
Do Koenig lookup -- unless any of the arguments are
type-dependent. */
for (arg = args; arg; arg = TREE_CHAIN (arg))
if (type_dependent_expression_p (TREE_VALUE (arg)))
break;
if (!arg)
{
postfix_expression
= lookup_arg_dependent(identifier, functions, args);
if (!postfix_expression)
{
/* The unqualified name could not be resolved. */
unqualified_name_lookup_error (identifier);
postfix_expression = error_mark_node;
}
postfix_expression
= build_call_from_tree (postfix_expression, args,
/*diallow_virtual=*/false);
break;
}
postfix_expression = build_min_nt (LOOKUP_EXPR,
identifier);
}
else if (idk == CP_PARSER_ID_KIND_UNQUALIFIED
&& TREE_CODE (postfix_expression) == IDENTIFIER_NODE)
{
/* The unqualified name could not be resolved. */
unqualified_name_lookup_error (postfix_expression);
postfix_expression = error_mark_node;
break;
}
/* In the body of a template, no further processing is
required. */
if (processing_template_decl)
{
postfix_expression = build_nt (CALL_EXPR,
postfix_expression,
args);
break;
}
if (TREE_CODE (postfix_expression) == COMPONENT_REF)
postfix_expression
= (build_new_method_call
(TREE_OPERAND (postfix_expression, 0),
TREE_OPERAND (postfix_expression, 1),
args, NULL_TREE,
(idk == CP_PARSER_ID_KIND_QUALIFIED
? LOOKUP_NONVIRTUAL : LOOKUP_NORMAL)));
else if (TREE_CODE (postfix_expression) == OFFSET_REF)
postfix_expression = (build_offset_ref_call_from_tree
(postfix_expression, args));
else if (idk == CP_PARSER_ID_KIND_QUALIFIED)
/* A call to a static class member, or a namespace-scope
function. */
postfix_expression
= finish_call_expr (postfix_expression, args,
/*disallow_virtual=*/true);
else
/* All other function calls. */
postfix_expression
= finish_call_expr (postfix_expression, args,
/*disallow_virtual=*/false);
/* The POSTFIX_EXPRESSION is certainly no longer an id. */
idk = CP_PARSER_ID_KIND_NONE;
}
break;
case CPP_DOT:
case CPP_DEREF:
/* postfix-expression . template [opt] id-expression
postfix-expression . pseudo-destructor-name
postfix-expression -> template [opt] id-expression
postfix-expression -> pseudo-destructor-name */
{
tree name;
bool dependent_p;
bool template_p;
tree scope = NULL_TREE;
/* If this is a `->' operator, dereference the pointer. */
if (token->type == CPP_DEREF)
postfix_expression = build_x_arrow (postfix_expression);
/* Check to see whether or not the expression is
type-dependent. */
dependent_p = type_dependent_expression_p (postfix_expression);
/* The identifier following the `->' or `.' is not
qualified. */
parser->scope = NULL_TREE;
parser->qualifying_scope = NULL_TREE;
parser->object_scope = NULL_TREE;
idk = CP_PARSER_ID_KIND_NONE;
/* Enter the scope corresponding to the type of the object
given by the POSTFIX_EXPRESSION. */
if (!dependent_p
&& TREE_TYPE (postfix_expression) != NULL_TREE)
{
scope = TREE_TYPE (postfix_expression);
/* According to the standard, no expression should
ever have reference type. Unfortunately, we do not
currently match the standard in this respect in
that our internal representation of an expression
may have reference type even when the standard says
it does not. Therefore, we have to manually obtain
the underlying type here. */
if (TREE_CODE (scope) == REFERENCE_TYPE)
scope = TREE_TYPE (scope);
/* If the SCOPE is an OFFSET_TYPE, then we grab the
type of the field. We get an OFFSET_TYPE for
something like:
S::T.a ...
Probably, we should not get an OFFSET_TYPE here;
that transformation should be made only if `&S::T'
is written. */
if (TREE_CODE (scope) == OFFSET_TYPE)
scope = TREE_TYPE (scope);
/* The type of the POSTFIX_EXPRESSION must be
complete. */
scope = complete_type_or_else (scope, NULL_TREE);
/* Let the name lookup machinery know that we are
processing a class member access expression. */
parser->context->object_type = scope;
/* If something went wrong, we want to be able to
discern that case, as opposed to the case where
there was no SCOPE due to the type of expression
being dependent. */
if (!scope)
scope = error_mark_node;
}
/* Consume the `.' or `->' operator. */
cp_lexer_consume_token (parser->lexer);
/* If the SCOPE is not a scalar type, we are looking at an
ordinary class member access expression, rather than a
pseudo-destructor-name. */
if (!scope || !SCALAR_TYPE_P (scope))
{
template_p = cp_parser_optional_template_keyword (parser);
/* Parse the id-expression. */
name = cp_parser_id_expression (parser,
template_p,
/*check_dependency_p=*/true,
/*template_p=*/NULL);
/* In general, build a SCOPE_REF if the member name is
qualified. However, if the name was not dependent
and has already been resolved; there is no need to
build the SCOPE_REF. For example;
struct X { void f(); };
template <typename T> void f(T* t) { t->X::f(); }
Even though "t" is dependent, "X::f" is not and has
except that for a BASELINK there is no need to
include scope information. */
/* But we do need to remember that there was an explicit
scope for virtual function calls. */
if (parser->scope)
idk = CP_PARSER_ID_KIND_QUALIFIED;
if (name != error_mark_node
&& !BASELINK_P (name)
&& parser->scope)
{
name = build_nt (SCOPE_REF, parser->scope, name);
parser->scope = NULL_TREE;
parser->qualifying_scope = NULL_TREE;
parser->object_scope = NULL_TREE;
}
postfix_expression
= finish_class_member_access_expr (postfix_expression, name);
}
/* Otherwise, try the pseudo-destructor-name production. */
else
{
tree s;
tree type;
/* Parse the pseudo-destructor-name. */
cp_parser_pseudo_destructor_name (parser, &s, &type);
/* Form the call. */
postfix_expression
= finish_pseudo_destructor_expr (postfix_expression,
s, TREE_TYPE (type));
}
/* We no longer need to look up names in the scope of the
object on the left-hand side of the `.' or `->'
operator. */
parser->context->object_type = NULL_TREE;
}
break;
case CPP_PLUS_PLUS:
/* postfix-expression ++ */
/* Consume the `++' token. */
cp_lexer_consume_token (parser->lexer);
/* Increments may not appear in constant-expressions. */
if (parser->constant_expression_p)
{
if (!parser->allow_non_constant_expression_p)
return cp_parser_non_constant_expression ("an increment");
parser->non_constant_expression_p = true;
}
/* Generate a reprsentation for the complete expression. */
postfix_expression
= finish_increment_expr (postfix_expression,
POSTINCREMENT_EXPR);
idk = CP_PARSER_ID_KIND_NONE;
break;
case CPP_MINUS_MINUS:
/* postfix-expression -- */
/* Consume the `--' token. */
cp_lexer_consume_token (parser->lexer);
/* Decrements may not appear in constant-expressions. */
if (parser->constant_expression_p)
{
if (!parser->allow_non_constant_expression_p)
return cp_parser_non_constant_expression ("a decrement");
parser->non_constant_expression_p = true;
}
/* Generate a reprsentation for the complete expression. */
postfix_expression
= finish_increment_expr (postfix_expression,
POSTDECREMENT_EXPR);
idk = CP_PARSER_ID_KIND_NONE;
break;
default:
return postfix_expression;
}
}
/* We should never get here. */
abort ();
return error_mark_node;
}
/* Parse an expression-list.
expression-list:
assignment-expression
expression-list, assignment-expression
Returns a TREE_LIST. The TREE_VALUE of each node is a
representation of an assignment-expression. Note that a TREE_LIST
is returned even if there is only a single expression in the list. */
static tree
cp_parser_expression_list (cp_parser* parser)
{
tree expression_list = NULL_TREE;
/* Consume expressions until there are no more. */
while (true)
{
tree expr;
/* Parse the next assignment-expression. */
expr = cp_parser_assignment_expression (parser);
/* Add it to the list. */
expression_list = tree_cons (NULL_TREE, expr, expression_list);
/* If the next token isn't a `,', then we are done. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA))
{
/* All uses of expression-list in the grammar are followed
by a `)'. Therefore, if the next token is not a `)' an
error will be issued, unless we are parsing tentatively.
Skip ahead to see if there is another `,' before the `)';
if so, we can go there and recover. */
if (cp_parser_parsing_tentatively (parser)
|| cp_lexer_next_token_is (parser->lexer, CPP_CLOSE_PAREN)
|| !cp_parser_skip_to_closing_parenthesis_or_comma (parser))
break;
}
/* Otherwise, consume the `,' and keep going. */
cp_lexer_consume_token (parser->lexer);
}
/* We built up the list in reverse order so we must reverse it now. */
return nreverse (expression_list);
}
/* Parse a pseudo-destructor-name.
pseudo-destructor-name:
:: [opt] nested-name-specifier [opt] type-name :: ~ type-name
:: [opt] nested-name-specifier template template-id :: ~ type-name
:: [opt] nested-name-specifier [opt] ~ type-name
If either of the first two productions is used, sets *SCOPE to the
TYPE specified before the final `::'. Otherwise, *SCOPE is set to
NULL_TREE. *TYPE is set to the TYPE_DECL for the final type-name,
or ERROR_MARK_NODE if no type-name is present. */
static void
cp_parser_pseudo_destructor_name (cp_parser* parser,
tree* scope,
tree* type)
{
bool nested_name_specifier_p;
/* Look for the optional `::' operator. */
cp_parser_global_scope_opt (parser, /*current_scope_valid_p=*/true);
/* Look for the optional nested-name-specifier. */
nested_name_specifier_p
= (cp_parser_nested_name_specifier_opt (parser,
/*typename_keyword_p=*/false,
/*check_dependency_p=*/true,
/*type_p=*/false)
!= NULL_TREE);
/* Now, if we saw a nested-name-specifier, we might be doing the
second production. */
if (nested_name_specifier_p
&& cp_lexer_next_token_is_keyword (parser->lexer, RID_TEMPLATE))
{
/* Consume the `template' keyword. */
cp_lexer_consume_token (parser->lexer);
/* Parse the template-id. */
cp_parser_template_id (parser,
/*template_keyword_p=*/true,
/*check_dependency_p=*/false);
/* Look for the `::' token. */
cp_parser_require (parser, CPP_SCOPE, "`::'");
}
/* If the next token is not a `~', then there might be some
additional qualification. */
else if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMPL))
{
/* Look for the type-name. */
*scope = TREE_TYPE (cp_parser_type_name (parser));
/* Look for the `::' token. */
cp_parser_require (parser, CPP_SCOPE, "`::'");
}
else
*scope = NULL_TREE;
/* Look for the `~'. */
cp_parser_require (parser, CPP_COMPL, "`~'");
/* Look for the type-name again. We are not responsible for
checking that it matches the first type-name. */
*type = cp_parser_type_name (parser);
}
/* Parse a unary-expression.
unary-expression:
postfix-expression
++ cast-expression
-- cast-expression
unary-operator cast-expression
sizeof unary-expression
sizeof ( type-id )
new-expression
delete-expression
GNU Extensions:
unary-expression:
__extension__ cast-expression
__alignof__ unary-expression
__alignof__ ( type-id )
__real__ cast-expression
__imag__ cast-expression
&& identifier
ADDRESS_P is true iff the unary-expression is appearing as the
operand of the `&' operator.
Returns a representation of the expresion. */
static tree
cp_parser_unary_expression (cp_parser *parser, bool address_p)
{
cp_token *token;
enum tree_code unary_operator;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* Some keywords give away the kind of expression. */
if (token->type == CPP_KEYWORD)
{
enum rid keyword = token->keyword;
switch (keyword)
{
case RID_ALIGNOF:
{
/* Consume the `alignof' token. */
cp_lexer_consume_token (parser->lexer);
/* Parse the operand. */
return finish_alignof (cp_parser_sizeof_operand
(parser, keyword));
}
case RID_SIZEOF:
{
tree operand;
/* Consume the `sizeof' token. */
cp_lexer_consume_token (parser->lexer);
/* Parse the operand. */
operand = cp_parser_sizeof_operand (parser, keyword);
/* If the type of the operand cannot be determined build a
SIZEOF_EXPR. */
if (TYPE_P (operand)
? dependent_type_p (operand)
: type_dependent_expression_p (operand))
return build_min (SIZEOF_EXPR, size_type_node, operand);
/* Otherwise, compute the constant value. */
else
return finish_sizeof (operand);
}
case RID_NEW:
return cp_parser_new_expression (parser);
case RID_DELETE:
return cp_parser_delete_expression (parser);
case RID_EXTENSION:
{
/* The saved value of the PEDANTIC flag. */
int saved_pedantic;
tree expr;
/* Save away the PEDANTIC flag. */
cp_parser_extension_opt (parser, &saved_pedantic);
/* Parse the cast-expression. */
expr = cp_parser_cast_expression (parser, /*address_p=*/false);
/* Restore the PEDANTIC flag. */
pedantic = saved_pedantic;
return expr;
}
case RID_REALPART:
case RID_IMAGPART:
{
tree expression;
/* Consume the `__real__' or `__imag__' token. */
cp_lexer_consume_token (parser->lexer);
/* Parse the cast-expression. */
expression = cp_parser_cast_expression (parser,
/*address_p=*/false);
/* Create the complete representation. */
return build_x_unary_op ((keyword == RID_REALPART
? REALPART_EXPR : IMAGPART_EXPR),
expression);
}
break;
default:
break;
}
}
/* Look for the `:: new' and `:: delete', which also signal the
beginning of a new-expression, or delete-expression,
respectively. If the next token is `::', then it might be one of
these. */
if (cp_lexer_next_token_is (parser->lexer, CPP_SCOPE))
{
enum rid keyword;
/* See if the token after the `::' is one of the keywords in
which we're interested. */
keyword = cp_lexer_peek_nth_token (parser->lexer, 2)->keyword;
/* If it's `new', we have a new-expression. */
if (keyword == RID_NEW)
return cp_parser_new_expression (parser);
/* Similarly, for `delete'. */
else if (keyword == RID_DELETE)
return cp_parser_delete_expression (parser);
}
/* Look for a unary operator. */
unary_operator = cp_parser_unary_operator (token);
/* The `++' and `--' operators can be handled similarly, even though
they are not technically unary-operators in the grammar. */
if (unary_operator == ERROR_MARK)
{
if (token->type == CPP_PLUS_PLUS)
unary_operator = PREINCREMENT_EXPR;
else if (token->type == CPP_MINUS_MINUS)
unary_operator = PREDECREMENT_EXPR;
/* Handle the GNU address-of-label extension. */
else if (cp_parser_allow_gnu_extensions_p (parser)
&& token->type == CPP_AND_AND)
{
tree identifier;
/* Consume the '&&' token. */
cp_lexer_consume_token (parser->lexer);
/* Look for the identifier. */
identifier = cp_parser_identifier (parser);
/* Create an expression representing the address. */
return finish_label_address_expr (identifier);
}
}
if (unary_operator != ERROR_MARK)
{
tree cast_expression;
/* Consume the operator token. */
token = cp_lexer_consume_token (parser->lexer);
/* Parse the cast-expression. */
cast_expression
= cp_parser_cast_expression (parser, unary_operator == ADDR_EXPR);
/* Now, build an appropriate representation. */
switch (unary_operator)
{
case INDIRECT_REF:
return build_x_indirect_ref (cast_expression, "unary *");
case ADDR_EXPR:
return build_x_unary_op (ADDR_EXPR, cast_expression);
case PREINCREMENT_EXPR:
case PREDECREMENT_EXPR:
if (parser->constant_expression_p)
{
if (!parser->allow_non_constant_expression_p)
return cp_parser_non_constant_expression (PREINCREMENT_EXPR
? "an increment"
: "a decrement");
parser->non_constant_expression_p = true;
}
/* Fall through. */
case CONVERT_EXPR:
case NEGATE_EXPR:
case TRUTH_NOT_EXPR:
return finish_unary_op_expr (unary_operator, cast_expression);
case BIT_NOT_EXPR:
return build_x_unary_op (BIT_NOT_EXPR, cast_expression);
default:
abort ();
return error_mark_node;
}
}
return cp_parser_postfix_expression (parser, address_p);
}
/* Returns ERROR_MARK if TOKEN is not a unary-operator. If TOKEN is a
unary-operator, the corresponding tree code is returned. */
static enum tree_code
cp_parser_unary_operator (cp_token* token)
{
switch (token->type)
{
case CPP_MULT:
return INDIRECT_REF;
case CPP_AND:
return ADDR_EXPR;
case CPP_PLUS:
return CONVERT_EXPR;
case CPP_MINUS:
return NEGATE_EXPR;
case CPP_NOT:
return TRUTH_NOT_EXPR;
case CPP_COMPL:
return BIT_NOT_EXPR;
default:
return ERROR_MARK;
}
}
/* Parse a new-expression.
new-expression:
:: [opt] new new-placement [opt] new-type-id new-initializer [opt]
:: [opt] new new-placement [opt] ( type-id ) new-initializer [opt]
Returns a representation of the expression. */
static tree
cp_parser_new_expression (cp_parser* parser)
{
bool global_scope_p;
tree placement;
tree type;
tree initializer;
/* Look for the optional `::' operator. */
global_scope_p
= (cp_parser_global_scope_opt (parser,
/*current_scope_valid_p=*/false)
!= NULL_TREE);
/* Look for the `new' operator. */
cp_parser_require_keyword (parser, RID_NEW, "`new'");
/* There's no easy way to tell a new-placement from the
`( type-id )' construct. */
cp_parser_parse_tentatively (parser);
/* Look for a new-placement. */
placement = cp_parser_new_placement (parser);
/* If that didn't work out, there's no new-placement. */
if (!cp_parser_parse_definitely (parser))
placement = NULL_TREE;
/* If the next token is a `(', then we have a parenthesized
type-id. */
if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN))
{
/* Consume the `('. */
cp_lexer_consume_token (parser->lexer);
/* Parse the type-id. */
type = cp_parser_type_id (parser);
/* Look for the closing `)'. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
}
/* Otherwise, there must be a new-type-id. */
else
type = cp_parser_new_type_id (parser);
/* If the next token is a `(', then we have a new-initializer. */
if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN))
initializer = cp_parser_new_initializer (parser);
else
initializer = NULL_TREE;
/* Create a representation of the new-expression. */
return build_new (placement, type, initializer, global_scope_p);
}
/* Parse a new-placement.
new-placement:
( expression-list )
Returns the same representation as for an expression-list. */
static tree
cp_parser_new_placement (cp_parser* parser)
{
tree expression_list;
/* Look for the opening `('. */
if (!cp_parser_require (parser, CPP_OPEN_PAREN, "`('"))
return error_mark_node;
/* Parse the expression-list. */
expression_list = cp_parser_expression_list (parser);
/* Look for the closing `)'. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
return expression_list;
}
/* Parse a new-type-id.
new-type-id:
type-specifier-seq new-declarator [opt]
Returns a TREE_LIST whose TREE_PURPOSE is the type-specifier-seq,
and whose TREE_VALUE is the new-declarator. */
static tree
cp_parser_new_type_id (cp_parser* parser)
{
tree type_specifier_seq;
tree declarator;
const char *saved_message;
/* The type-specifier sequence must not contain type definitions.
(It cannot contain declarations of new types either, but if they
are not definitions we will catch that because they are not
complete.) */
saved_message = parser->type_definition_forbidden_message;
parser->type_definition_forbidden_message
= "types may not be defined in a new-type-id";
/* Parse the type-specifier-seq. */
type_specifier_seq = cp_parser_type_specifier_seq (parser);
/* Restore the old message. */
parser->type_definition_forbidden_message = saved_message;
/* Parse the new-declarator. */
declarator = cp_parser_new_declarator_opt (parser);
return build_tree_list (type_specifier_seq, declarator);
}
/* Parse an (optional) new-declarator.
new-declarator:
ptr-operator new-declarator [opt]
direct-new-declarator
Returns a representation of the declarator. See
cp_parser_declarator for the representations used. */
static tree
cp_parser_new_declarator_opt (cp_parser* parser)
{
enum tree_code code;
tree type;
tree cv_qualifier_seq;
/* We don't know if there's a ptr-operator next, or not. */
cp_parser_parse_tentatively (parser);
/* Look for a ptr-operator. */
code = cp_parser_ptr_operator (parser, &type, &cv_qualifier_seq);
/* If that worked, look for more new-declarators. */
if (cp_parser_parse_definitely (parser))
{
tree declarator;
/* Parse another optional declarator. */
declarator = cp_parser_new_declarator_opt (parser);
/* Create the representation of the declarator. */
if (code == INDIRECT_REF)
declarator = make_pointer_declarator (cv_qualifier_seq,
declarator);
else
declarator = make_reference_declarator (cv_qualifier_seq,
declarator);
/* Handle the pointer-to-member case. */
if (type)
declarator = build_nt (SCOPE_REF, type, declarator);
return declarator;
}
/* If the next token is a `[', there is a direct-new-declarator. */
if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_SQUARE))
return cp_parser_direct_new_declarator (parser);
return NULL_TREE;
}
/* Parse a direct-new-declarator.
direct-new-declarator:
[ expression ]
direct-new-declarator [constant-expression]
Returns an ARRAY_REF, following the same conventions as are
documented for cp_parser_direct_declarator. */
static tree
cp_parser_direct_new_declarator (cp_parser* parser)
{
tree declarator = NULL_TREE;
while (true)
{
tree expression;
/* Look for the opening `['. */
cp_parser_require (parser, CPP_OPEN_SQUARE, "`['");
/* The first expression is not required to be constant. */
if (!declarator)
{
expression = cp_parser_expression (parser);
/* The standard requires that the expression have integral
type. DR 74 adds enumeration types. We believe that the
real intent is that these expressions be handled like the
expression in a `switch' condition, which also allows
classes with a single conversion to integral or
enumeration type. */
if (!processing_template_decl)
{
expression
= build_expr_type_conversion (WANT_INT | WANT_ENUM,
expression,
/*complain=*/true);
if (!expression)
{
error ("expression in new-declarator must have integral or enumeration type");
expression = error_mark_node;
}
}
}
/* But all the other expressions must be. */
else
expression
= cp_parser_constant_expression (parser,
/*allow_non_constant=*/false,
NULL);
/* Look for the closing `]'. */
cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'");
/* Add this bound to the declarator. */
declarator = build_nt (ARRAY_REF, declarator, expression);
/* If the next token is not a `[', then there are no more
bounds. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_OPEN_SQUARE))
break;
}
return declarator;
}
/* Parse a new-initializer.
new-initializer:
( expression-list [opt] )
Returns a reprsentation of the expression-list. If there is no
expression-list, VOID_ZERO_NODE is returned. */
static tree
cp_parser_new_initializer (cp_parser* parser)
{
tree expression_list;
/* Look for the opening parenthesis. */
cp_parser_require (parser, CPP_OPEN_PAREN, "`('");
/* If the next token is not a `)', then there is an
expression-list. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_PAREN))
expression_list = cp_parser_expression_list (parser);
else
expression_list = void_zero_node;
/* Look for the closing parenthesis. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
return expression_list;
}
/* Parse a delete-expression.
delete-expression:
:: [opt] delete cast-expression
:: [opt] delete [ ] cast-expression
Returns a representation of the expression. */
static tree
cp_parser_delete_expression (cp_parser* parser)
{
bool global_scope_p;
bool array_p;
tree expression;
/* Look for the optional `::' operator. */
global_scope_p
= (cp_parser_global_scope_opt (parser,
/*current_scope_valid_p=*/false)
!= NULL_TREE);
/* Look for the `delete' keyword. */
cp_parser_require_keyword (parser, RID_DELETE, "`delete'");
/* See if the array syntax is in use. */
if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_SQUARE))
{
/* Consume the `[' token. */
cp_lexer_consume_token (parser->lexer);
/* Look for the `]' token. */
cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'");
/* Remember that this is the `[]' construct. */
array_p = true;
}
else
array_p = false;
/* Parse the cast-expression. */
expression = cp_parser_cast_expression (parser, /*address_p=*/false);
return delete_sanity (expression, NULL_TREE, array_p, global_scope_p);
}
/* Parse a cast-expression.
cast-expression:
unary-expression
( type-id ) cast-expression
Returns a representation of the expression. */
static tree
cp_parser_cast_expression (cp_parser *parser, bool address_p)
{
/* If it's a `(', then we might be looking at a cast. */
if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN))
{
tree type = NULL_TREE;
tree expr = NULL_TREE;
bool compound_literal_p;
const char *saved_message;
/* There's no way to know yet whether or not this is a cast.
For example, `(int (3))' is a unary-expression, while `(int)
3' is a cast. So, we resort to parsing tentatively. */
cp_parser_parse_tentatively (parser);
/* Types may not be defined in a cast. */
saved_message = parser->type_definition_forbidden_message;
parser->type_definition_forbidden_message
= "types may not be defined in casts";
/* Consume the `('. */
cp_lexer_consume_token (parser->lexer);
/* A very tricky bit is that `(struct S) { 3 }' is a
compound-literal (which we permit in C++ as an extension).
But, that construct is not a cast-expression -- it is a
postfix-expression. (The reason is that `(struct S) { 3 }.i'
is legal; if the compound-literal were a cast-expression,
you'd need an extra set of parentheses.) But, if we parse
the type-id, and it happens to be a class-specifier, then we
will commit to the parse at that point, because we cannot
undo the action that is done when creating a new class. So,
then we cannot back up and do a postfix-expression.
Therefore, we scan ahead to the closing `)', and check to see
if the token after the `)' is a `{'. If so, we are not
looking at a cast-expression.
Save tokens so that we can put them back. */
cp_lexer_save_tokens (parser->lexer);
/* Skip tokens until the next token is a closing parenthesis.
If we find the closing `)', and the next token is a `{', then
we are looking at a compound-literal. */
compound_literal_p
= (cp_parser_skip_to_closing_parenthesis (parser)
&& cp_lexer_next_token_is (parser->lexer, CPP_OPEN_BRACE));
/* Roll back the tokens we skipped. */
cp_lexer_rollback_tokens (parser->lexer);
/* If we were looking at a compound-literal, simulate an error
so that the call to cp_parser_parse_definitely below will
fail. */
if (compound_literal_p)
cp_parser_simulate_error (parser);
else
{
/* Look for the type-id. */
type = cp_parser_type_id (parser);
/* Look for the closing `)'. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
}
/* Restore the saved message. */
parser->type_definition_forbidden_message = saved_message;
/* If ok so far, parse the dependent expression. We cannot be
sure it is a cast. Consider `(T ())'. It is a parenthesized
ctor of T, but looks like a cast to function returning T
without a dependent expression. */
if (!cp_parser_error_occurred (parser))
expr = cp_parser_cast_expression (parser, /*address_p=*/false);
if (cp_parser_parse_definitely (parser))
{
/* Warn about old-style casts, if so requested. */
if (warn_old_style_cast
&& !in_system_header
&& !VOID_TYPE_P (type)
&& current_lang_name != lang_name_c)
warning ("use of old-style cast");
/* Only type conversions to integral or enumeration types
can be used in constant-expressions. */
if (parser->constant_expression_p
&& !dependent_type_p (type)
&& !INTEGRAL_OR_ENUMERATION_TYPE_P (type))
{
if (!parser->allow_non_constant_expression_p)
return (cp_parser_non_constant_expression
("a casts to a type other than an integral or "
"enumeration type"));
parser->non_constant_expression_p = true;
}
/* Perform the cast. */
expr = build_c_cast (type, expr);
return expr;
}
}
/* If we get here, then it's not a cast, so it must be a
unary-expression. */
return cp_parser_unary_expression (parser, address_p);
}
/* Parse a pm-expression.
pm-expression:
cast-expression
pm-expression .* cast-expression
pm-expression ->* cast-expression
Returns a representation of the expression. */
static tree
cp_parser_pm_expression (cp_parser* parser)
{
tree cast_expr;
tree pm_expr;
/* Parse the cast-expresion. */
cast_expr = cp_parser_cast_expression (parser, /*address_p=*/false);
pm_expr = cast_expr;
/* Now look for pointer-to-member operators. */
while (true)
{
cp_token *token;
enum cpp_ttype token_type;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
token_type = token->type;
/* If it's not `.*' or `->*' there's no pointer-to-member
operation. */
if (token_type != CPP_DOT_STAR
&& token_type != CPP_DEREF_STAR)
break;
/* Consume the token. */
cp_lexer_consume_token (parser->lexer);
/* Parse another cast-expression. */
cast_expr = cp_parser_cast_expression (parser, /*address_p=*/false);
/* Build the representation of the pointer-to-member
operation. */
if (token_type == CPP_DEREF_STAR)
pm_expr = build_x_binary_op (MEMBER_REF, pm_expr, cast_expr);
else
pm_expr = build_m_component_ref (pm_expr, cast_expr);
}
return pm_expr;
}
/* Parse a multiplicative-expression.
mulitplicative-expression:
pm-expression
multiplicative-expression * pm-expression
multiplicative-expression / pm-expression
multiplicative-expression % pm-expression
Returns a representation of the expression. */
static tree
cp_parser_multiplicative_expression (cp_parser* parser)
{
static const cp_parser_token_tree_map map = {
{ CPP_MULT, MULT_EXPR },
{ CPP_DIV, TRUNC_DIV_EXPR },
{ CPP_MOD, TRUNC_MOD_EXPR },
{ CPP_EOF, ERROR_MARK }
};
return cp_parser_binary_expression (parser,
map,
cp_parser_pm_expression);
}
/* Parse an additive-expression.
additive-expression:
multiplicative-expression
additive-expression + multiplicative-expression
additive-expression - multiplicative-expression
Returns a representation of the expression. */
static tree
cp_parser_additive_expression (cp_parser* parser)
{
static const cp_parser_token_tree_map map = {
{ CPP_PLUS, PLUS_EXPR },
{ CPP_MINUS, MINUS_EXPR },
{ CPP_EOF, ERROR_MARK }
};
return cp_parser_binary_expression (parser,
map,
cp_parser_multiplicative_expression);
}
/* Parse a shift-expression.
shift-expression:
additive-expression
shift-expression << additive-expression
shift-expression >> additive-expression
Returns a representation of the expression. */
static tree
cp_parser_shift_expression (cp_parser* parser)
{
static const cp_parser_token_tree_map map = {
{ CPP_LSHIFT, LSHIFT_EXPR },
{ CPP_RSHIFT, RSHIFT_EXPR },
{ CPP_EOF, ERROR_MARK }
};
return cp_parser_binary_expression (parser,
map,
cp_parser_additive_expression);
}
/* Parse a relational-expression.
relational-expression:
shift-expression
relational-expression < shift-expression
relational-expression > shift-expression
relational-expression <= shift-expression
relational-expression >= shift-expression
GNU Extension:
relational-expression:
relational-expression <? shift-expression
relational-expression >? shift-expression
Returns a representation of the expression. */
static tree
cp_parser_relational_expression (cp_parser* parser)
{
static const cp_parser_token_tree_map map = {
{ CPP_LESS, LT_EXPR },
{ CPP_GREATER, GT_EXPR },
{ CPP_LESS_EQ, LE_EXPR },
{ CPP_GREATER_EQ, GE_EXPR },
{ CPP_MIN, MIN_EXPR },
{ CPP_MAX, MAX_EXPR },
{ CPP_EOF, ERROR_MARK }
};
return cp_parser_binary_expression (parser,
map,
cp_parser_shift_expression);
}
/* Parse an equality-expression.
equality-expression:
relational-expression
equality-expression == relational-expression
equality-expression != relational-expression
Returns a representation of the expression. */
static tree
cp_parser_equality_expression (cp_parser* parser)
{
static const cp_parser_token_tree_map map = {
{ CPP_EQ_EQ, EQ_EXPR },
{ CPP_NOT_EQ, NE_EXPR },
{ CPP_EOF, ERROR_MARK }
};
return cp_parser_binary_expression (parser,
map,
cp_parser_relational_expression);
}
/* Parse an and-expression.
and-expression:
equality-expression
and-expression & equality-expression
Returns a representation of the expression. */
static tree
cp_parser_and_expression (cp_parser* parser)
{
static const cp_parser_token_tree_map map = {
{ CPP_AND, BIT_AND_EXPR },
{ CPP_EOF, ERROR_MARK }
};
return cp_parser_binary_expression (parser,
map,
cp_parser_equality_expression);
}
/* Parse an exclusive-or-expression.
exclusive-or-expression:
and-expression
exclusive-or-expression ^ and-expression
Returns a representation of the expression. */
static tree
cp_parser_exclusive_or_expression (cp_parser* parser)
{
static const cp_parser_token_tree_map map = {
{ CPP_XOR, BIT_XOR_EXPR },
{ CPP_EOF, ERROR_MARK }
};
return cp_parser_binary_expression (parser,
map,
cp_parser_and_expression);
}
/* Parse an inclusive-or-expression.
inclusive-or-expression:
exclusive-or-expression
inclusive-or-expression | exclusive-or-expression
Returns a representation of the expression. */
static tree
cp_parser_inclusive_or_expression (cp_parser* parser)
{
static const cp_parser_token_tree_map map = {
{ CPP_OR, BIT_IOR_EXPR },
{ CPP_EOF, ERROR_MARK }
};
return cp_parser_binary_expression (parser,
map,
cp_parser_exclusive_or_expression);
}
/* Parse a logical-and-expression.
logical-and-expression:
inclusive-or-expression
logical-and-expression && inclusive-or-expression
Returns a representation of the expression. */
static tree
cp_parser_logical_and_expression (cp_parser* parser)
{
static const cp_parser_token_tree_map map = {
{ CPP_AND_AND, TRUTH_ANDIF_EXPR },
{ CPP_EOF, ERROR_MARK }
};
return cp_parser_binary_expression (parser,
map,
cp_parser_inclusive_or_expression);
}
/* Parse a logical-or-expression.
logical-or-expression:
logical-and-expresion
logical-or-expression || logical-and-expression
Returns a representation of the expression. */
static tree
cp_parser_logical_or_expression (cp_parser* parser)
{
static const cp_parser_token_tree_map map = {
{ CPP_OR_OR, TRUTH_ORIF_EXPR },
{ CPP_EOF, ERROR_MARK }
};
return cp_parser_binary_expression (parser,
map,
cp_parser_logical_and_expression);
}
/* Parse a conditional-expression.
conditional-expression:
logical-or-expression
logical-or-expression ? expression : assignment-expression
GNU Extensions:
conditional-expression:
logical-or-expression ? : assignment-expression
Returns a representation of the expression. */
static tree
cp_parser_conditional_expression (cp_parser* parser)
{
tree logical_or_expr;
/* Parse the logical-or-expression. */
logical_or_expr = cp_parser_logical_or_expression (parser);
/* If the next token is a `?', then we have a real conditional
expression. */
if (cp_lexer_next_token_is (parser->lexer, CPP_QUERY))
return cp_parser_question_colon_clause (parser, logical_or_expr);
/* Otherwise, the value is simply the logical-or-expression. */
else
return logical_or_expr;
}
/* Parse the `? expression : assignment-expression' part of a
conditional-expression. The LOGICAL_OR_EXPR is the
logical-or-expression that started the conditional-expression.
Returns a representation of the entire conditional-expression.
This routine exists only so that it can be shared between
cp_parser_conditional_expression and
cp_parser_assignment_expression.
? expression : assignment-expression
GNU Extensions:
? : assignment-expression */
static tree
cp_parser_question_colon_clause (cp_parser* parser, tree logical_or_expr)
{
tree expr;
tree assignment_expr;
/* Consume the `?' token. */
cp_lexer_consume_token (parser->lexer);
if (cp_parser_allow_gnu_extensions_p (parser)
&& cp_lexer_next_token_is (parser->lexer, CPP_COLON))
/* Implicit true clause. */
expr = NULL_TREE;
else
/* Parse the expression. */
expr = cp_parser_expression (parser);
/* The next token should be a `:'. */
cp_parser_require (parser, CPP_COLON, "`:'");
/* Parse the assignment-expression. */
assignment_expr = cp_parser_assignment_expression (parser);
/* Build the conditional-expression. */
return build_x_conditional_expr (logical_or_expr,
expr,
assignment_expr);
}
/* Parse an assignment-expression.
assignment-expression:
conditional-expression
logical-or-expression assignment-operator assignment_expression
throw-expression
Returns a representation for the expression. */
static tree
cp_parser_assignment_expression (cp_parser* parser)
{
tree expr;
/* If the next token is the `throw' keyword, then we're looking at
a throw-expression. */
if (cp_lexer_next_token_is_keyword (parser->lexer, RID_THROW))
expr = cp_parser_throw_expression (parser);
/* Otherwise, it must be that we are looking at a
logical-or-expression. */
else
{
/* Parse the logical-or-expression. */
expr = cp_parser_logical_or_expression (parser);
/* If the next token is a `?' then we're actually looking at a
conditional-expression. */
if (cp_lexer_next_token_is (parser->lexer, CPP_QUERY))
return cp_parser_question_colon_clause (parser, expr);
else
{
enum tree_code assignment_operator;
/* If it's an assignment-operator, we're using the second
production. */
assignment_operator
= cp_parser_assignment_operator_opt (parser);
if (assignment_operator != ERROR_MARK)
{
tree rhs;
/* Parse the right-hand side of the assignment. */
rhs = cp_parser_assignment_expression (parser);
/* An assignment may not appear in a
constant-expression. */
if (parser->constant_expression_p)
{
if (!parser->allow_non_constant_expression_p)
return cp_parser_non_constant_expression ("an assignment");
parser->non_constant_expression_p = true;
}
/* Build the asignment expression. */
expr = build_x_modify_expr (expr,
assignment_operator,
rhs);
}
}
}
return expr;
}
/* Parse an (optional) assignment-operator.
assignment-operator: one of
= *= /= %= += -= >>= <<= &= ^= |=
GNU Extension:
assignment-operator: one of
<?= >?=
If the next token is an assignment operator, the corresponding tree
code is returned, and the token is consumed. For example, for
`+=', PLUS_EXPR is returned. For `=' itself, the code returned is
NOP_EXPR. For `/', TRUNC_DIV_EXPR is returned; for `%',
TRUNC_MOD_EXPR is returned. If TOKEN is not an assignment
operator, ERROR_MARK is returned. */
static enum tree_code
cp_parser_assignment_operator_opt (cp_parser* parser)
{
enum tree_code op;
cp_token *token;
/* Peek at the next toen. */
token = cp_lexer_peek_token (parser->lexer);
switch (token->type)
{
case CPP_EQ:
op = NOP_EXPR;
break;
case CPP_MULT_EQ:
op = MULT_EXPR;
break;
case CPP_DIV_EQ:
op = TRUNC_DIV_EXPR;
break;
case CPP_MOD_EQ:
op = TRUNC_MOD_EXPR;
break;
case CPP_PLUS_EQ:
op = PLUS_EXPR;
break;
case CPP_MINUS_EQ:
op = MINUS_EXPR;
break;
case CPP_RSHIFT_EQ:
op = RSHIFT_EXPR;
break;
case CPP_LSHIFT_EQ:
op = LSHIFT_EXPR;
break;
case CPP_AND_EQ:
op = BIT_AND_EXPR;
break;
case CPP_XOR_EQ:
op = BIT_XOR_EXPR;
break;
case CPP_OR_EQ:
op = BIT_IOR_EXPR;
break;
case CPP_MIN_EQ:
op = MIN_EXPR;
break;
case CPP_MAX_EQ:
op = MAX_EXPR;
break;
default:
/* Nothing else is an assignment operator. */
op = ERROR_MARK;
}
/* If it was an assignment operator, consume it. */
if (op != ERROR_MARK)
cp_lexer_consume_token (parser->lexer);
return op;
}
/* Parse an expression.
expression:
assignment-expression
expression , assignment-expression
Returns a representation of the expression. */
static tree
cp_parser_expression (cp_parser* parser)
{
tree expression = NULL_TREE;
bool saw_comma_p = false;
while (true)
{
tree assignment_expression;
/* Parse the next assignment-expression. */
assignment_expression
= cp_parser_assignment_expression (parser);
/* If this is the first assignment-expression, we can just
save it away. */
if (!expression)
expression = assignment_expression;
/* Otherwise, chain the expressions together. It is unclear why
we do not simply build COMPOUND_EXPRs as we go. */
else
expression = tree_cons (NULL_TREE,
assignment_expression,
expression);
/* If the next token is not a comma, then we are done with the
expression. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA))
break;
/* Consume the `,'. */
cp_lexer_consume_token (parser->lexer);
/* The first time we see a `,', we must take special action
because the representation used for a single expression is
different from that used for a list containing the single
expression. */
if (!saw_comma_p)
{
/* Remember that this expression has a `,' in it. */
saw_comma_p = true;
/* Turn the EXPRESSION into a TREE_LIST so that we can link
additional expressions to it. */
expression = build_tree_list (NULL_TREE, expression);
}
}
/* Build a COMPOUND_EXPR to represent the entire expression, if
necessary. We built up the list in reverse order, so we must
straighten it out here. */
if (saw_comma_p)
{
/* A comma operator cannot appear in a constant-expression. */
if (parser->constant_expression_p)
{
if (!parser->allow_non_constant_expression_p)
return cp_parser_non_constant_expression ("a comma operator");
parser->non_constant_expression_p = true;
}
expression = build_x_compound_expr (nreverse (expression));
}
return expression;
}
/* Parse a constant-expression.
constant-expression:
conditional-expression
If ALLOW_NON_CONSTANT_P a non-constant expression is silently
accepted. In that case *NON_CONSTANT_P is set to TRUE. If
ALLOW_NON_CONSTANT_P is false, NON_CONSTANT_P should be NULL. */
static tree
cp_parser_constant_expression (cp_parser* parser,
bool allow_non_constant_p,
bool *non_constant_p)
{
bool saved_constant_expression_p;
bool saved_allow_non_constant_expression_p;
bool saved_non_constant_expression_p;
tree expression;
/* It might seem that we could simply parse the
conditional-expression, and then check to see if it were
TREE_CONSTANT. However, an expression that is TREE_CONSTANT is
one that the compiler can figure out is constant, possibly after
doing some simplifications or optimizations. The standard has a
precise definition of constant-expression, and we must honor
that, even though it is somewhat more restrictive.
For example:
int i[(2, 3)];
is not a legal declaration, because `(2, 3)' is not a
constant-expression. The `,' operator is forbidden in a
constant-expression. However, GCC's constant-folding machinery
will fold this operation to an INTEGER_CST for `3'. */
/* Save the old settings. */
saved_constant_expression_p = parser->constant_expression_p;
saved_allow_non_constant_expression_p
= parser->allow_non_constant_expression_p;
saved_non_constant_expression_p = parser->non_constant_expression_p;
/* We are now parsing a constant-expression. */
parser->constant_expression_p = true;
parser->allow_non_constant_expression_p = allow_non_constant_p;
parser->non_constant_expression_p = false;
/* Parse the conditional-expression. */
expression = cp_parser_conditional_expression (parser);
/* Restore the old settings. */
parser->constant_expression_p = saved_constant_expression_p;
parser->allow_non_constant_expression_p
= saved_allow_non_constant_expression_p;
if (allow_non_constant_p)
*non_constant_p = parser->non_constant_expression_p;
parser->non_constant_expression_p = saved_non_constant_expression_p;
return expression;
}
/* Statements [gram.stmt.stmt] */
/* Parse a statement.
statement:
labeled-statement
expression-statement
compound-statement
selection-statement
iteration-statement
jump-statement
declaration-statement
try-block */
static void
cp_parser_statement (cp_parser* parser)
{
tree statement;
cp_token *token;
int statement_line_number;
/* There is no statement yet. */
statement = NULL_TREE;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* Remember the line number of the first token in the statement. */
statement_line_number = token->location.line;
/* If this is a keyword, then that will often determine what kind of
statement we have. */
if (token->type == CPP_KEYWORD)
{
enum rid keyword = token->keyword;
switch (keyword)
{
case RID_CASE:
case RID_DEFAULT:
statement = cp_parser_labeled_statement (parser);
break;
case RID_IF:
case RID_SWITCH:
statement = cp_parser_selection_statement (parser);
break;
case RID_WHILE:
case RID_DO:
case RID_FOR:
statement = cp_parser_iteration_statement (parser);
break;
case RID_BREAK:
case RID_CONTINUE:
case RID_RETURN:
case RID_GOTO:
statement = cp_parser_jump_statement (parser);
break;
case RID_TRY:
statement = cp_parser_try_block (parser);
break;
default:
/* It might be a keyword like `int' that can start a
declaration-statement. */
break;
}
}
else if (token->type == CPP_NAME)
{
/* If the next token is a `:', then we are looking at a
labeled-statement. */
token = cp_lexer_peek_nth_token (parser->lexer, 2);
if (token->type == CPP_COLON)
statement = cp_parser_labeled_statement (parser);
}
/* Anything that starts with a `{' must be a compound-statement. */
else if (token->type == CPP_OPEN_BRACE)
statement = cp_parser_compound_statement (parser);
/* Everything else must be a declaration-statement or an
expression-statement. Try for the declaration-statement
first, unless we are looking at a `;', in which case we know that
we have an expression-statement. */
if (!statement)
{
if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON))
{
cp_parser_parse_tentatively (parser);
/* Try to parse the declaration-statement. */
cp_parser_declaration_statement (parser);
/* If that worked, we're done. */
if (cp_parser_parse_definitely (parser))
return;
}
/* Look for an expression-statement instead. */
statement = cp_parser_expression_statement (parser);
}
/* Set the line number for the statement. */
if (statement && STATEMENT_CODE_P (TREE_CODE (statement)))
STMT_LINENO (statement) = statement_line_number;
}
/* Parse a labeled-statement.
labeled-statement:
identifier : statement
case constant-expression : statement
default : statement
Returns the new CASE_LABEL, for a `case' or `default' label. For
an ordinary label, returns a LABEL_STMT. */
static tree
cp_parser_labeled_statement (cp_parser* parser)
{
cp_token *token;
tree statement = NULL_TREE;
/* The next token should be an identifier. */
token = cp_lexer_peek_token (parser->lexer);
if (token->type != CPP_NAME
&& token->type != CPP_KEYWORD)
{
cp_parser_error (parser, "expected labeled-statement");
return error_mark_node;
}
switch (token->keyword)
{
case RID_CASE:
{
tree expr;
/* Consume the `case' token. */
cp_lexer_consume_token (parser->lexer);
/* Parse the constant-expression. */
expr = cp_parser_constant_expression (parser,
/*allow_non_constant=*/false,
NULL);
/* Create the label. */
statement = finish_case_label (expr, NULL_TREE);
}
break;
case RID_DEFAULT:
/* Consume the `default' token. */
cp_lexer_consume_token (parser->lexer);
/* Create the label. */
statement = finish_case_label (NULL_TREE, NULL_TREE);
break;
default:
/* Anything else must be an ordinary label. */
statement = finish_label_stmt (cp_parser_identifier (parser));
break;
}
/* Require the `:' token. */
cp_parser_require (parser, CPP_COLON, "`:'");
/* Parse the labeled statement. */
cp_parser_statement (parser);
/* Return the label, in the case of a `case' or `default' label. */
return statement;
}
/* Parse an expression-statement.
expression-statement:
expression [opt] ;
Returns the new EXPR_STMT -- or NULL_TREE if the expression
statement consists of nothing more than an `;'. */
static tree
cp_parser_expression_statement (cp_parser* parser)
{
tree statement;
/* If the next token is not a `;', then there is an expression to parse. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON))
statement = finish_expr_stmt (cp_parser_expression (parser));
/* Otherwise, we do not even bother to build an EXPR_STMT. */
else
{
finish_stmt ();
statement = NULL_TREE;
}
/* Consume the final `;'. */
cp_parser_consume_semicolon_at_end_of_statement (parser);
return statement;
}
/* Parse a compound-statement.
compound-statement:
{ statement-seq [opt] }
Returns a COMPOUND_STMT representing the statement. */
static tree
cp_parser_compound_statement (cp_parser *parser)
{
tree compound_stmt;
/* Consume the `{'. */
if (!cp_parser_require (parser, CPP_OPEN_BRACE, "`{'"))
return error_mark_node;
/* Begin the compound-statement. */
compound_stmt = begin_compound_stmt (/*has_no_scope=*/0);
/* Parse an (optional) statement-seq. */
cp_parser_statement_seq_opt (parser);
/* Finish the compound-statement. */
finish_compound_stmt (/*has_no_scope=*/0, compound_stmt);
/* Consume the `}'. */
cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'");
return compound_stmt;
}
/* Parse an (optional) statement-seq.
statement-seq:
statement
statement-seq [opt] statement */
static void
cp_parser_statement_seq_opt (cp_parser* parser)
{
/* Scan statements until there aren't any more. */
while (true)
{
/* If we're looking at a `}', then we've run out of statements. */
if (cp_lexer_next_token_is (parser->lexer, CPP_CLOSE_BRACE)
|| cp_lexer_next_token_is (parser->lexer, CPP_EOF))
break;
/* Parse the statement. */
cp_parser_statement (parser);
}
}
/* Parse a selection-statement.
selection-statement:
if ( condition ) statement
if ( condition ) statement else statement
switch ( condition ) statement
Returns the new IF_STMT or SWITCH_STMT. */
static tree
cp_parser_selection_statement (cp_parser* parser)
{
cp_token *token;
enum rid keyword;
/* Peek at the next token. */
token = cp_parser_require (parser, CPP_KEYWORD, "selection-statement");
/* See what kind of keyword it is. */
keyword = token->keyword;
switch (keyword)
{
case RID_IF:
case RID_SWITCH:
{
tree statement;
tree condition;
/* Look for the `('. */
if (!cp_parser_require (parser, CPP_OPEN_PAREN, "`('"))
{
cp_parser_skip_to_end_of_statement (parser);
return error_mark_node;
}
/* Begin the selection-statement. */
if (keyword == RID_IF)
statement = begin_if_stmt ();
else
statement = begin_switch_stmt ();
/* Parse the condition. */
condition = cp_parser_condition (parser);
/* Look for the `)'. */
if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"))
cp_parser_skip_to_closing_parenthesis (parser);
if (keyword == RID_IF)
{
tree then_stmt;
/* Add the condition. */
finish_if_stmt_cond (condition, statement);
/* Parse the then-clause. */
then_stmt = cp_parser_implicitly_scoped_statement (parser);
finish_then_clause (statement);
/* If the next token is `else', parse the else-clause. */
if (cp_lexer_next_token_is_keyword (parser->lexer,
RID_ELSE))
{
tree else_stmt;
/* Consume the `else' keyword. */
cp_lexer_consume_token (parser->lexer);
/* Parse the else-clause. */
else_stmt
= cp_parser_implicitly_scoped_statement (parser);
finish_else_clause (statement);
}
/* Now we're all done with the if-statement. */
finish_if_stmt ();
}
else
{
tree body;
/* Add the condition. */
finish_switch_cond (condition, statement);
/* Parse the body of the switch-statement. */
body = cp_parser_implicitly_scoped_statement (parser);
/* Now we're all done with the switch-statement. */
finish_switch_stmt (statement);
}
return statement;
}
break;
default:
cp_parser_error (parser, "expected selection-statement");
return error_mark_node;
}
}
/* Parse a condition.
condition:
expression
type-specifier-seq declarator = assignment-expression
GNU Extension:
condition:
type-specifier-seq declarator asm-specification [opt]
attributes [opt] = assignment-expression
Returns the expression that should be tested. */
static tree
cp_parser_condition (cp_parser* parser)
{
tree type_specifiers;
const char *saved_message;
/* Try the declaration first. */
cp_parser_parse_tentatively (parser);
/* New types are not allowed in the type-specifier-seq for a
condition. */
saved_message = parser->type_definition_forbidden_message;
parser->type_definition_forbidden_message
= "types may not be defined in conditions";
/* Parse the type-specifier-seq. */
type_specifiers = cp_parser_type_specifier_seq (parser);
/* Restore the saved message. */
parser->type_definition_forbidden_message = saved_message;
/* If all is well, we might be looking at a declaration. */
if (!cp_parser_error_occurred (parser))
{
tree decl;
tree asm_specification;
tree attributes;
tree declarator;
tree initializer = NULL_TREE;
/* Parse the declarator. */
declarator = cp_parser_declarator (parser, CP_PARSER_DECLARATOR_NAMED,
/*ctor_dtor_or_conv_p=*/NULL);
/* Parse the attributes. */
attributes = cp_parser_attributes_opt (parser);
/* Parse the asm-specification. */
asm_specification = cp_parser_asm_specification_opt (parser);
/* If the next token is not an `=', then we might still be
looking at an expression. For example:
if (A(a).x)
looks like a decl-specifier-seq and a declarator -- but then
there is no `=', so this is an expression. */
cp_parser_require (parser, CPP_EQ, "`='");
/* If we did see an `=', then we are looking at a declaration
for sure. */
if (cp_parser_parse_definitely (parser))
{
/* Create the declaration. */
decl = start_decl (declarator, type_specifiers,
/*initialized_p=*/true,
attributes, /*prefix_attributes=*/NULL_TREE);
/* Parse the assignment-expression. */
initializer = cp_parser_assignment_expression (parser);
/* Process the initializer. */
cp_finish_decl (decl,
initializer,
asm_specification,
LOOKUP_ONLYCONVERTING);
return convert_from_reference (decl);
}
}
/* If we didn't even get past the declarator successfully, we are
definitely not looking at a declaration. */
else
cp_parser_abort_tentative_parse (parser);
/* Otherwise, we are looking at an expression. */
return cp_parser_expression (parser);
}
/* Parse an iteration-statement.
iteration-statement:
while ( condition ) statement
do statement while ( expression ) ;
for ( for-init-statement condition [opt] ; expression [opt] )
statement
Returns the new WHILE_STMT, DO_STMT, or FOR_STMT. */
static tree
cp_parser_iteration_statement (cp_parser* parser)
{
cp_token *token;
enum rid keyword;
tree statement;
/* Peek at the next token. */
token = cp_parser_require (parser, CPP_KEYWORD, "iteration-statement");
if (!token)
return error_mark_node;
/* See what kind of keyword it is. */
keyword = token->keyword;
switch (keyword)
{
case RID_WHILE:
{
tree condition;
/* Begin the while-statement. */
statement = begin_while_stmt ();
/* Look for the `('. */
cp_parser_require (parser, CPP_OPEN_PAREN, "`('");
/* Parse the condition. */
condition = cp_parser_condition (parser);
finish_while_stmt_cond (condition, statement);
/* Look for the `)'. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
/* Parse the dependent statement. */
cp_parser_already_scoped_statement (parser);
/* We're done with the while-statement. */
finish_while_stmt (statement);
}
break;
case RID_DO:
{
tree expression;
/* Begin the do-statement. */
statement = begin_do_stmt ();
/* Parse the body of the do-statement. */
cp_parser_implicitly_scoped_statement (parser);
finish_do_body (statement);
/* Look for the `while' keyword. */
cp_parser_require_keyword (parser, RID_WHILE, "`while'");
/* Look for the `('. */
cp_parser_require (parser, CPP_OPEN_PAREN, "`('");
/* Parse the expression. */
expression = cp_parser_expression (parser);
/* We're done with the do-statement. */
finish_do_stmt (expression, statement);
/* Look for the `)'. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
/* Look for the `;'. */
cp_parser_require (parser, CPP_SEMICOLON, "`;'");
}
break;
case RID_FOR:
{
tree condition = NULL_TREE;
tree expression = NULL_TREE;
/* Begin the for-statement. */
statement = begin_for_stmt ();
/* Look for the `('. */
cp_parser_require (parser, CPP_OPEN_PAREN, "`('");
/* Parse the initialization. */
cp_parser_for_init_statement (parser);
finish_for_init_stmt (statement);
/* If there's a condition, process it. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON))
condition = cp_parser_condition (parser);
finish_for_cond (condition, statement);
/* Look for the `;'. */
cp_parser_require (parser, CPP_SEMICOLON, "`;'");
/* If there's an expression, process it. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_PAREN))
expression = cp_parser_expression (parser);
finish_for_expr (expression, statement);
/* Look for the `)'. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`;'");
/* Parse the body of the for-statement. */
cp_parser_already_scoped_statement (parser);
/* We're done with the for-statement. */
finish_for_stmt (statement);
}
break;
default:
cp_parser_error (parser, "expected iteration-statement");
statement = error_mark_node;
break;
}
return statement;
}
/* Parse a for-init-statement.
for-init-statement:
expression-statement
simple-declaration */
static void
cp_parser_for_init_statement (cp_parser* parser)
{
/* If the next token is a `;', then we have an empty
expression-statement. Gramatically, this is also a
simple-declaration, but an invalid one, because it does not
declare anything. Therefore, if we did not handle this case
specially, we would issue an error message about an invalid
declaration. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON))
{
/* We're going to speculatively look for a declaration, falling back
to an expression, if necessary. */
cp_parser_parse_tentatively (parser);
/* Parse the declaration. */
cp_parser_simple_declaration (parser,
/*function_definition_allowed_p=*/false);
/* If the tentative parse failed, then we shall need to look for an
expression-statement. */
if (cp_parser_parse_definitely (parser))
return;
}
cp_parser_expression_statement (parser);
}
/* Parse a jump-statement.
jump-statement:
break ;
continue ;
return expression [opt] ;
goto identifier ;
GNU extension:
jump-statement:
goto * expression ;
Returns the new BREAK_STMT, CONTINUE_STMT, RETURN_STMT, or
GOTO_STMT. */
static tree
cp_parser_jump_statement (cp_parser* parser)
{
tree statement = error_mark_node;
cp_token *token;
enum rid keyword;
/* Peek at the next token. */
token = cp_parser_require (parser, CPP_KEYWORD, "jump-statement");
if (!token)
return error_mark_node;
/* See what kind of keyword it is. */
keyword = token->keyword;
switch (keyword)
{
case RID_BREAK:
statement = finish_break_stmt ();
cp_parser_require (parser, CPP_SEMICOLON, "`;'");
break;
case RID_CONTINUE:
statement = finish_continue_stmt ();
cp_parser_require (parser, CPP_SEMICOLON, "`;'");
break;
case RID_RETURN:
{
tree expr;
/* If the next token is a `;', then there is no
expression. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON))
expr = cp_parser_expression (parser);
else
expr = NULL_TREE;
/* Build the return-statement. */
statement = finish_return_stmt (expr);
/* Look for the final `;'. */
cp_parser_require (parser, CPP_SEMICOLON, "`;'");
}
break;
case RID_GOTO:
/* Create the goto-statement. */
if (cp_lexer_next_token_is (parser->lexer, CPP_MULT))
{
/* Issue a warning about this use of a GNU extension. */
if (pedantic)
pedwarn ("ISO C++ forbids computed gotos");
/* Consume the '*' token. */
cp_lexer_consume_token (parser->lexer);
/* Parse the dependent expression. */
finish_goto_stmt (cp_parser_expression (parser));
}
else
finish_goto_stmt (cp_parser_identifier (parser));
/* Look for the final `;'. */
cp_parser_require (parser, CPP_SEMICOLON, "`;'");
break;
default:
cp_parser_error (parser, "expected jump-statement");
break;
}
return statement;
}
/* Parse a declaration-statement.
declaration-statement:
block-declaration */
static void
cp_parser_declaration_statement (cp_parser* parser)
{
/* Parse the block-declaration. */
cp_parser_block_declaration (parser, /*statement_p=*/true);
/* Finish off the statement. */
finish_stmt ();
}
/* Some dependent statements (like `if (cond) statement'), are
implicitly in their own scope. In other words, if the statement is
a single statement (as opposed to a compound-statement), it is
none-the-less treated as if it were enclosed in braces. Any
declarations appearing in the dependent statement are out of scope
after control passes that point. This function parses a statement,
but ensures that is in its own scope, even if it is not a
compound-statement.
Returns the new statement. */
static tree
cp_parser_implicitly_scoped_statement (cp_parser* parser)
{
tree statement;
/* If the token is not a `{', then we must take special action. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_OPEN_BRACE))
{
/* Create a compound-statement. */
statement = begin_compound_stmt (/*has_no_scope=*/0);
/* Parse the dependent-statement. */
cp_parser_statement (parser);
/* Finish the dummy compound-statement. */
finish_compound_stmt (/*has_no_scope=*/0, statement);
}
/* Otherwise, we simply parse the statement directly. */
else
statement = cp_parser_compound_statement (parser);
/* Return the statement. */
return statement;
}
/* For some dependent statements (like `while (cond) statement'), we
have already created a scope. Therefore, even if the dependent
statement is a compound-statement, we do not want to create another
scope. */
static void
cp_parser_already_scoped_statement (cp_parser* parser)
{
/* If the token is not a `{', then we must take special action. */
if (cp_lexer_next_token_is_not(parser->lexer, CPP_OPEN_BRACE))
{
tree statement;
/* Create a compound-statement. */
statement = begin_compound_stmt (/*has_no_scope=*/1);
/* Parse the dependent-statement. */
cp_parser_statement (parser);
/* Finish the dummy compound-statement. */
finish_compound_stmt (/*has_no_scope=*/1, statement);
}
/* Otherwise, we simply parse the statement directly. */
else
cp_parser_statement (parser);
}
/* Declarations [gram.dcl.dcl] */
/* Parse an optional declaration-sequence.
declaration-seq:
declaration
declaration-seq declaration */
static void
cp_parser_declaration_seq_opt (cp_parser* parser)
{
while (true)
{
cp_token *token;
token = cp_lexer_peek_token (parser->lexer);
if (token->type == CPP_CLOSE_BRACE
|| token->type == CPP_EOF)
break;
if (token->type == CPP_SEMICOLON)
{
/* A declaration consisting of a single semicolon is
invalid. Allow it unless we're being pedantic. */
if (pedantic)
pedwarn ("extra `;'");
cp_lexer_consume_token (parser->lexer);
continue;
}
/* The C lexer modifies PENDING_LANG_CHANGE when it wants the
parser to enter or exit implict `extern "C"' blocks. */
while (pending_lang_change > 0)
{
push_lang_context (lang_name_c);
--pending_lang_change;
}
while (pending_lang_change < 0)
{
pop_lang_context ();
++pending_lang_change;
}
/* Parse the declaration itself. */
cp_parser_declaration (parser);
}
}
/* Parse a declaration.
declaration:
block-declaration
function-definition
template-declaration
explicit-instantiation
explicit-specialization
linkage-specification
namespace-definition
GNU extension:
declaration:
__extension__ declaration */
static void
cp_parser_declaration (cp_parser* parser)
{
cp_token token1;
cp_token token2;
int saved_pedantic;
/* Check for the `__extension__' keyword. */
if (cp_parser_extension_opt (parser, &saved_pedantic))
{
/* Parse the qualified declaration. */
cp_parser_declaration (parser);
/* Restore the PEDANTIC flag. */
pedantic = saved_pedantic;
return;
}
/* Try to figure out what kind of declaration is present. */
token1 = *cp_lexer_peek_token (parser->lexer);
if (token1.type != CPP_EOF)
token2 = *cp_lexer_peek_nth_token (parser->lexer, 2);
/* If the next token is `extern' and the following token is a string
literal, then we have a linkage specification. */
if (token1.keyword == RID_EXTERN
&& cp_parser_is_string_literal (&token2))
cp_parser_linkage_specification (parser);
/* If the next token is `template', then we have either a template
declaration, an explicit instantiation, or an explicit
specialization. */
else if (token1.keyword == RID_TEMPLATE)
{
/* `template <>' indicates a template specialization. */
if (token2.type == CPP_LESS
&& cp_lexer_peek_nth_token (parser->lexer, 3)->type == CPP_GREATER)
cp_parser_explicit_specialization (parser);
/* `template <' indicates a template declaration. */
else if (token2.type == CPP_LESS)
cp_parser_template_declaration (parser, /*member_p=*/false);
/* Anything else must be an explicit instantiation. */
else
cp_parser_explicit_instantiation (parser);
}
/* If the next token is `export', then we have a template
declaration. */
else if (token1.keyword == RID_EXPORT)
cp_parser_template_declaration (parser, /*member_p=*/false);
/* If the next token is `extern', 'static' or 'inline' and the one
after that is `template', we have a GNU extended explicit
instantiation directive. */
else if (cp_parser_allow_gnu_extensions_p (parser)
&& (token1.keyword == RID_EXTERN
|| token1.keyword == RID_STATIC
|| token1.keyword == RID_INLINE)
&& token2.keyword == RID_TEMPLATE)
cp_parser_explicit_instantiation (parser);
/* If the next token is `namespace', check for a named or unnamed
namespace definition. */
else if (token1.keyword == RID_NAMESPACE
&& (/* A named namespace definition. */
(token2.type == CPP_NAME
&& (cp_lexer_peek_nth_token (parser->lexer, 3)->type
== CPP_OPEN_BRACE))
/* An unnamed namespace definition. */
|| token2.type == CPP_OPEN_BRACE))
cp_parser_namespace_definition (parser);
/* We must have either a block declaration or a function
definition. */
else
/* Try to parse a block-declaration, or a function-definition. */
cp_parser_block_declaration (parser, /*statement_p=*/false);
}
/* Parse a block-declaration.
block-declaration:
simple-declaration
asm-definition
namespace-alias-definition
using-declaration
using-directive
GNU Extension:
block-declaration:
__extension__ block-declaration
label-declaration
If STATEMENT_P is TRUE, then this block-declaration is ocurring as
part of a declaration-statement. */
static void
cp_parser_block_declaration (cp_parser *parser,
bool statement_p)
{
cp_token *token1;
int saved_pedantic;
/* Check for the `__extension__' keyword. */
if (cp_parser_extension_opt (parser, &saved_pedantic))
{
/* Parse the qualified declaration. */
cp_parser_block_declaration (parser, statement_p);
/* Restore the PEDANTIC flag. */
pedantic = saved_pedantic;
return;
}
/* Peek at the next token to figure out which kind of declaration is
present. */
token1 = cp_lexer_peek_token (parser->lexer);
/* If the next keyword is `asm', we have an asm-definition. */
if (token1->keyword == RID_ASM)
{
if (statement_p)
cp_parser_commit_to_tentative_parse (parser);
cp_parser_asm_definition (parser);
}
/* If the next keyword is `namespace', we have a
namespace-alias-definition. */
else if (token1->keyword == RID_NAMESPACE)
cp_parser_namespace_alias_definition (parser);
/* If the next keyword is `using', we have either a
using-declaration or a using-directive. */
else if (token1->keyword == RID_USING)
{
cp_token *token2;
if (statement_p)
cp_parser_commit_to_tentative_parse (parser);
/* If the token after `using' is `namespace', then we have a
using-directive. */
token2 = cp_lexer_peek_nth_token (parser->lexer, 2);
if (token2->keyword == RID_NAMESPACE)
cp_parser_using_directive (parser);
/* Otherwise, it's a using-declaration. */
else
cp_parser_using_declaration (parser);
}
/* If the next keyword is `__label__' we have a label declaration. */
else if (token1->keyword == RID_LABEL)
{
if (statement_p)
cp_parser_commit_to_tentative_parse (parser);
cp_parser_label_declaration (parser);
}
/* Anything else must be a simple-declaration. */
else
cp_parser_simple_declaration (parser, !statement_p);
}
/* Parse a simple-declaration.
simple-declaration:
decl-specifier-seq [opt] init-declarator-list [opt] ;
init-declarator-list:
init-declarator
init-declarator-list , init-declarator
If FUNCTION_DEFINTION_ALLOWED_P is TRUE, then we also recognize a
function-definition as a simple-declaration. */
static void
cp_parser_simple_declaration (cp_parser* parser,
bool function_definition_allowed_p)
{
tree decl_specifiers;
tree attributes;
bool declares_class_or_enum;
bool saw_declarator;
/* Defer access checks until we know what is being declared; the
checks for names appearing in the decl-specifier-seq should be
done as if we were in the scope of the thing being declared. */
push_deferring_access_checks (dk_deferred);
/* Parse the decl-specifier-seq. We have to keep track of whether
or not the decl-specifier-seq declares a named class or
enumeration type, since that is the only case in which the
init-declarator-list is allowed to be empty.
[dcl.dcl]
In a simple-declaration, the optional init-declarator-list can be
omitted only when declaring a class or enumeration, that is when
the decl-specifier-seq contains either a class-specifier, an
elaborated-type-specifier, or an enum-specifier. */
decl_specifiers
= cp_parser_decl_specifier_seq (parser,
CP_PARSER_FLAGS_OPTIONAL,
&attributes,
&declares_class_or_enum);
/* We no longer need to defer access checks. */
stop_deferring_access_checks ();
/* If the next two tokens are both identifiers, the code is
erroneous. The usual cause of this situation is code like:
T t;
where "T" should name a type -- but does not. */
if (cp_parser_diagnose_invalid_type_name (parser))
{
/* If parsing tentatively, we should commit; we really are
looking at a declaration. */
cp_parser_commit_to_tentative_parse (parser);
/* Give up. */
return;
}
/* Keep going until we hit the `;' at the end of the simple
declaration. */
saw_declarator = false;
while (cp_lexer_next_token_is_not (parser->lexer,
CPP_SEMICOLON))
{
cp_token *token;
bool function_definition_p;
saw_declarator = true;
/* Parse the init-declarator. */
cp_parser_init_declarator (parser, decl_specifiers, attributes,
function_definition_allowed_p,
/*member_p=*/false,
&function_definition_p);
/* If an error occurred while parsing tentatively, exit quickly.
(That usually happens when in the body of a function; each
statement is treated as a declaration-statement until proven
otherwise.) */
if (cp_parser_error_occurred (parser))
{
pop_deferring_access_checks ();
return;
}
/* Handle function definitions specially. */
if (function_definition_p)
{
/* If the next token is a `,', then we are probably
processing something like:
void f() {}, *p;
which is erroneous. */
if (cp_lexer_next_token_is (parser->lexer, CPP_COMMA))
error ("mixing declarations and function-definitions is forbidden");
/* Otherwise, we're done with the list of declarators. */
else
{
pop_deferring_access_checks ();
return;
}
}
/* The next token should be either a `,' or a `;'. */
token = cp_lexer_peek_token (parser->lexer);
/* If it's a `,', there are more declarators to come. */
if (token->type == CPP_COMMA)
cp_lexer_consume_token (parser->lexer);
/* If it's a `;', we are done. */
else if (token->type == CPP_SEMICOLON)
break;
/* Anything else is an error. */
else
{
cp_parser_error (parser, "expected `,' or `;'");
/* Skip tokens until we reach the end of the statement. */
cp_parser_skip_to_end_of_statement (parser);
pop_deferring_access_checks ();
return;
}
/* After the first time around, a function-definition is not
allowed -- even if it was OK at first. For example:
int i, f() {}
is not valid. */
function_definition_allowed_p = false;
}
/* Issue an error message if no declarators are present, and the
decl-specifier-seq does not itself declare a class or
enumeration. */
if (!saw_declarator)
{
if (cp_parser_declares_only_class_p (parser))
shadow_tag (decl_specifiers);
/* Perform any deferred access checks. */
perform_deferred_access_checks ();
}
pop_deferring_access_checks ();
/* Consume the `;'. */
cp_parser_require (parser, CPP_SEMICOLON, "`;'");
/* Mark all the classes that appeared in the decl-specifier-seq as
having received a `;'. */
note_list_got_semicolon (decl_specifiers);
}
/* Parse a decl-specifier-seq.
decl-specifier-seq:
decl-specifier-seq [opt] decl-specifier
decl-specifier:
storage-class-specifier
type-specifier
function-specifier
friend
typedef
GNU Extension:
decl-specifier-seq:
decl-specifier-seq [opt] attributes
Returns a TREE_LIST, giving the decl-specifiers in the order they
appear in the source code. The TREE_VALUE of each node is the
decl-specifier. For a keyword (such as `auto' or `friend'), the
TREE_VALUE is simply the correspoding TREE_IDENTIFIER. For the
representation of a type-specifier, see cp_parser_type_specifier.
If there are attributes, they will be stored in *ATTRIBUTES,
represented as described above cp_parser_attributes.
If FRIEND_IS_NOT_CLASS_P is non-NULL, and the `friend' specifier
appears, and the entity that will be a friend is not going to be a
class, then *FRIEND_IS_NOT_CLASS_P will be set to TRUE. Note that
even if *FRIEND_IS_NOT_CLASS_P is FALSE, the entity to which
friendship is granted might not be a class. */
static tree
cp_parser_decl_specifier_seq (cp_parser* parser,
cp_parser_flags flags,
tree* attributes,
bool* declares_class_or_enum)
{
tree decl_specs = NULL_TREE;
bool friend_p = false;
bool constructor_possible_p = !parser->in_declarator_p;
/* Assume no class or enumeration type is declared. */
*declares_class_or_enum = false;
/* Assume there are no attributes. */
*attributes = NULL_TREE;
/* Keep reading specifiers until there are no more to read. */
while (true)
{
tree decl_spec = NULL_TREE;
bool constructor_p;
cp_token *token;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* Handle attributes. */
if (token->keyword == RID_ATTRIBUTE)
{
/* Parse the attributes. */
decl_spec = cp_parser_attributes_opt (parser);
/* Add them to the list. */
*attributes = chainon (*attributes, decl_spec);
continue;
}
/* If the next token is an appropriate keyword, we can simply
add it to the list. */
switch (token->keyword)
{
case RID_FRIEND:
/* decl-specifier:
friend */
friend_p = true;
/* The representation of the specifier is simply the
appropriate TREE_IDENTIFIER node. */
decl_spec = token->value;
/* Consume the token. */
cp_lexer_consume_token (parser->lexer);
break;
/* function-specifier:
inline
virtual
explicit */
case RID_INLINE:
case RID_VIRTUAL:
case RID_EXPLICIT:
decl_spec = cp_parser_function_specifier_opt (parser);
break;
/* decl-specifier:
typedef */
case RID_TYPEDEF:
/* The representation of the specifier is simply the
appropriate TREE_IDENTIFIER node. */
decl_spec = token->value;
/* Consume the token. */
cp_lexer_consume_token (parser->lexer);
/* A constructor declarator cannot appear in a typedef. */
constructor_possible_p = false;
/* The "typedef" keyword can only occur in a declaration; we
may as well commit at this point. */
cp_parser_commit_to_tentative_parse (parser);
break;
/* storage-class-specifier:
auto
register
static
extern
mutable
GNU Extension:
thread */
case RID_AUTO:
case RID_REGISTER:
case RID_STATIC:
case RID_EXTERN:
case RID_MUTABLE:
case RID_THREAD:
decl_spec = cp_parser_storage_class_specifier_opt (parser);
break;
default:
break;
}
/* Constructors are a special case. The `S' in `S()' is not a
decl-specifier; it is the beginning of the declarator. */
constructor_p = (!decl_spec
&& constructor_possible_p
&& cp_parser_constructor_declarator_p (parser,
friend_p));
/* If we don't have a DECL_SPEC yet, then we must be looking at
a type-specifier. */
if (!decl_spec && !constructor_p)
{
bool decl_spec_declares_class_or_enum;
bool is_cv_qualifier;
decl_spec
= cp_parser_type_specifier (parser, flags,
friend_p,
/*is_declaration=*/true,
&decl_spec_declares_class_or_enum,
&is_cv_qualifier);
*declares_class_or_enum |= decl_spec_declares_class_or_enum;
/* If this type-specifier referenced a user-defined type
(a typedef, class-name, etc.), then we can't allow any
more such type-specifiers henceforth.
[dcl.spec]
The longest sequence of decl-specifiers that could
possibly be a type name is taken as the
decl-specifier-seq of a declaration. The sequence shall
be self-consistent as described below.
[dcl.type]
As a general rule, at most one type-specifier is allowed
in the complete decl-specifier-seq of a declaration. The
only exceptions are the following:
-- const or volatile can be combined with any other
type-specifier.
-- signed or unsigned can be combined with char, long,
short, or int.
-- ..
Example:
typedef char* Pc;
void g (const int Pc);
Here, Pc is *not* part of the decl-specifier seq; it's
the declarator. Therefore, once we see a type-specifier
(other than a cv-qualifier), we forbid any additional
user-defined types. We *do* still allow things like `int
int' to be considered a decl-specifier-seq, and issue the
error message later. */
if (decl_spec && !is_cv_qualifier)
flags |= CP_PARSER_FLAGS_NO_USER_DEFINED_TYPES;
/* A constructor declarator cannot follow a type-specifier. */
if (decl_spec)
constructor_possible_p = false;
}
/* If we still do not have a DECL_SPEC, then there are no more
decl-specifiers. */
if (!decl_spec)
{
/* Issue an error message, unless the entire construct was
optional. */
if (!(flags & CP_PARSER_FLAGS_OPTIONAL))
{
cp_parser_error (parser, "expected decl specifier");
return error_mark_node;
}
break;
}
/* Add the DECL_SPEC to the list of specifiers. */
decl_specs = tree_cons (NULL_TREE, decl_spec, decl_specs);
/* After we see one decl-specifier, further decl-specifiers are
always optional. */
flags |= CP_PARSER_FLAGS_OPTIONAL;
}
/* We have built up the DECL_SPECS in reverse order. Return them in
the correct order. */
return nreverse (decl_specs);
}
/* Parse an (optional) storage-class-specifier.
storage-class-specifier:
auto
register
static
extern
mutable
GNU Extension:
storage-class-specifier:
thread
Returns an IDENTIFIER_NODE corresponding to the keyword used. */
static tree
cp_parser_storage_class_specifier_opt (cp_parser* parser)
{
switch (cp_lexer_peek_token (parser->lexer)->keyword)
{
case RID_AUTO:
case RID_REGISTER:
case RID_STATIC:
case RID_EXTERN:
case RID_MUTABLE:
case RID_THREAD:
/* Consume the token. */
return cp_lexer_consume_token (parser->lexer)->value;
default:
return NULL_TREE;
}
}
/* Parse an (optional) function-specifier.
function-specifier:
inline
virtual
explicit
Returns an IDENTIFIER_NODE corresponding to the keyword used. */
static tree
cp_parser_function_specifier_opt (cp_parser* parser)
{
switch (cp_lexer_peek_token (parser->lexer)->keyword)
{
case RID_INLINE:
case RID_VIRTUAL:
case RID_EXPLICIT:
/* Consume the token. */
return cp_lexer_consume_token (parser->lexer)->value;
default:
return NULL_TREE;
}
}
/* Parse a linkage-specification.
linkage-specification:
extern string-literal { declaration-seq [opt] }
extern string-literal declaration */
static void
cp_parser_linkage_specification (cp_parser* parser)
{
cp_token *token;
tree linkage;
/* Look for the `extern' keyword. */
cp_parser_require_keyword (parser, RID_EXTERN, "`extern'");
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If it's not a string-literal, then there's a problem. */
if (!cp_parser_is_string_literal (token))
{
cp_parser_error (parser, "expected language-name");
return;
}
/* Consume the token. */
cp_lexer_consume_token (parser->lexer);
/* Transform the literal into an identifier. If the literal is a
wide-character string, or contains embedded NULs, then we can't
handle it as the user wants. */
if (token->type == CPP_WSTRING
|| (strlen (TREE_STRING_POINTER (token->value))
!= (size_t) (TREE_STRING_LENGTH (token->value) - 1)))
{
cp_parser_error (parser, "invalid linkage-specification");
/* Assume C++ linkage. */
linkage = get_identifier ("c++");
}
/* If it's a simple string constant, things are easier. */
else
linkage = get_identifier (TREE_STRING_POINTER (token->value));
/* We're now using the new linkage. */
push_lang_context (linkage);
/* If the next token is a `{', then we're using the first
production. */
if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_BRACE))
{
/* Consume the `{' token. */
cp_lexer_consume_token (parser->lexer);
/* Parse the declarations. */
cp_parser_declaration_seq_opt (parser);
/* Look for the closing `}'. */
cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'");
}
/* Otherwise, there's just one declaration. */
else
{
bool saved_in_unbraced_linkage_specification_p;
saved_in_unbraced_linkage_specification_p
= parser->in_unbraced_linkage_specification_p;
parser->in_unbraced_linkage_specification_p = true;
have_extern_spec = true;
cp_parser_declaration (parser);
have_extern_spec = false;
parser->in_unbraced_linkage_specification_p
= saved_in_unbraced_linkage_specification_p;
}
/* We're done with the linkage-specification. */
pop_lang_context ();
}
/* Special member functions [gram.special] */
/* Parse a conversion-function-id.
conversion-function-id:
operator conversion-type-id
Returns an IDENTIFIER_NODE representing the operator. */
static tree
cp_parser_conversion_function_id (cp_parser* parser)
{
tree type;
tree saved_scope;
tree saved_qualifying_scope;
tree saved_object_scope;
/* Look for the `operator' token. */
if (!cp_parser_require_keyword (parser, RID_OPERATOR, "`operator'"))
return error_mark_node;
/* When we parse the conversion-type-id, the current scope will be
reset. However, we need that information in able to look up the
conversion function later, so we save it here. */
saved_scope = parser->scope;
saved_qualifying_scope = parser->qualifying_scope;
saved_object_scope = parser->object_scope;
/* We must enter the scope of the class so that the names of
entities declared within the class are available in the
conversion-type-id. For example, consider:
struct S {
typedef int I;
operator I();
};
S::operator I() { ... }
In order to see that `I' is a type-name in the definition, we
must be in the scope of `S'. */
if (saved_scope)
push_scope (saved_scope);
/* Parse the conversion-type-id. */
type = cp_parser_conversion_type_id (parser);
/* Leave the scope of the class, if any. */
if (saved_scope)
pop_scope (saved_scope);
/* Restore the saved scope. */
parser->scope = saved_scope;
parser->qualifying_scope = saved_qualifying_scope;
parser->object_scope = saved_object_scope;
/* If the TYPE is invalid, indicate failure. */
if (type == error_mark_node)
return error_mark_node;
return mangle_conv_op_name_for_type (type);
}
/* Parse a conversion-type-id:
conversion-type-id:
type-specifier-seq conversion-declarator [opt]
Returns the TYPE specified. */
static tree
cp_parser_conversion_type_id (cp_parser* parser)
{
tree attributes;
tree type_specifiers;
tree declarator;
/* Parse the attributes. */
attributes = cp_parser_attributes_opt (parser);
/* Parse the type-specifiers. */
type_specifiers = cp_parser_type_specifier_seq (parser);
/* If that didn't work, stop. */
if (type_specifiers == error_mark_node)
return error_mark_node;
/* Parse the conversion-declarator. */
declarator = cp_parser_conversion_declarator_opt (parser);
return grokdeclarator (declarator, type_specifiers, TYPENAME,
/*initialized=*/0, &attributes);
}
/* Parse an (optional) conversion-declarator.
conversion-declarator:
ptr-operator conversion-declarator [opt]
Returns a representation of the declarator. See
cp_parser_declarator for details. */
static tree
cp_parser_conversion_declarator_opt (cp_parser* parser)
{
enum tree_code code;
tree class_type;
tree cv_qualifier_seq;
/* We don't know if there's a ptr-operator next, or not. */
cp_parser_parse_tentatively (parser);
/* Try the ptr-operator. */
code = cp_parser_ptr_operator (parser, &class_type,
&cv_qualifier_seq);
/* If it worked, look for more conversion-declarators. */
if (cp_parser_parse_definitely (parser))
{
tree declarator;
/* Parse another optional declarator. */
declarator = cp_parser_conversion_declarator_opt (parser);
/* Create the representation of the declarator. */
if (code == INDIRECT_REF)
declarator = make_pointer_declarator (cv_qualifier_seq,
declarator);
else
declarator = make_reference_declarator (cv_qualifier_seq,
declarator);
/* Handle the pointer-to-member case. */
if (class_type)
declarator = build_nt (SCOPE_REF, class_type, declarator);
return declarator;
}
return NULL_TREE;
}
/* Parse an (optional) ctor-initializer.
ctor-initializer:
: mem-initializer-list
Returns TRUE iff the ctor-initializer was actually present. */
static bool
cp_parser_ctor_initializer_opt (cp_parser* parser)
{
/* If the next token is not a `:', then there is no
ctor-initializer. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_COLON))
{
/* Do default initialization of any bases and members. */
if (DECL_CONSTRUCTOR_P (current_function_decl))
finish_mem_initializers (NULL_TREE);
return false;
}
/* Consume the `:' token. */
cp_lexer_consume_token (parser->lexer);
/* And the mem-initializer-list. */
cp_parser_mem_initializer_list (parser);
return true;
}
/* Parse a mem-initializer-list.
mem-initializer-list:
mem-initializer
mem-initializer , mem-initializer-list */
static void
cp_parser_mem_initializer_list (cp_parser* parser)
{
tree mem_initializer_list = NULL_TREE;
/* Let the semantic analysis code know that we are starting the
mem-initializer-list. */
if (!DECL_CONSTRUCTOR_P (current_function_decl))
error ("only constructors take base initializers");
/* Loop through the list. */
while (true)
{
tree mem_initializer;
/* Parse the mem-initializer. */
mem_initializer = cp_parser_mem_initializer (parser);
/* Add it to the list, unless it was erroneous. */
if (mem_initializer)
{
TREE_CHAIN (mem_initializer) = mem_initializer_list;
mem_initializer_list = mem_initializer;
}
/* If the next token is not a `,', we're done. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA))
break;
/* Consume the `,' token. */
cp_lexer_consume_token (parser->lexer);
}
/* Perform semantic analysis. */
if (DECL_CONSTRUCTOR_P (current_function_decl))
finish_mem_initializers (mem_initializer_list);
}
/* Parse a mem-initializer.
mem-initializer:
mem-initializer-id ( expression-list [opt] )
GNU extension:
mem-initializer:
( expresion-list [opt] )
Returns a TREE_LIST. The TREE_PURPOSE is the TYPE (for a base
class) or FIELD_DECL (for a non-static data member) to initialize;
the TREE_VALUE is the expression-list. */
static tree
cp_parser_mem_initializer (cp_parser* parser)
{
tree mem_initializer_id;
tree expression_list;
tree member;
/* Find out what is being initialized. */
if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN))
{
pedwarn ("anachronistic old-style base class initializer");
mem_initializer_id = NULL_TREE;
}
else
mem_initializer_id = cp_parser_mem_initializer_id (parser);
member = expand_member_init (mem_initializer_id);
if (member && !DECL_P (member))
in_base_initializer = 1;
/* Look for the opening `('. */
cp_parser_require (parser, CPP_OPEN_PAREN, "`('");
/* Parse the expression-list. */
if (cp_lexer_next_token_is_not (parser->lexer,
CPP_CLOSE_PAREN))
expression_list = cp_parser_expression_list (parser);
else
expression_list = void_type_node;
/* Look for the closing `)'. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
in_base_initializer = 0;
return member ? build_tree_list (member, expression_list) : NULL_TREE;
}
/* Parse a mem-initializer-id.
mem-initializer-id:
:: [opt] nested-name-specifier [opt] class-name
identifier
Returns a TYPE indicating the class to be initializer for the first
production. Returns an IDENTIFIER_NODE indicating the data member
to be initialized for the second production. */
static tree
cp_parser_mem_initializer_id (cp_parser* parser)
{
bool global_scope_p;
bool nested_name_specifier_p;
tree id;
/* Look for the optional `::' operator. */
global_scope_p
= (cp_parser_global_scope_opt (parser,
/*current_scope_valid_p=*/false)
!= NULL_TREE);
/* Look for the optional nested-name-specifier. The simplest way to
implement:
[temp.res]
The keyword `typename' is not permitted in a base-specifier or
mem-initializer; in these contexts a qualified name that
depends on a template-parameter is implicitly assumed to be a
type name.
is to assume that we have seen the `typename' keyword at this
point. */
nested_name_specifier_p
= (cp_parser_nested_name_specifier_opt (parser,
/*typename_keyword_p=*/true,
/*check_dependency_p=*/true,
/*type_p=*/true)
!= NULL_TREE);
/* If there is a `::' operator or a nested-name-specifier, then we
are definitely looking for a class-name. */
if (global_scope_p || nested_name_specifier_p)
return cp_parser_class_name (parser,
/*typename_keyword_p=*/true,
/*template_keyword_p=*/false,
/*type_p=*/false,
/*check_dependency_p=*/true,
/*class_head_p=*/false);
/* Otherwise, we could also be looking for an ordinary identifier. */
cp_parser_parse_tentatively (parser);
/* Try a class-name. */
id = cp_parser_class_name (parser,
/*typename_keyword_p=*/true,
/*template_keyword_p=*/false,
/*type_p=*/false,
/*check_dependency_p=*/true,
/*class_head_p=*/false);
/* If we found one, we're done. */
if (cp_parser_parse_definitely (parser))
return id;
/* Otherwise, look for an ordinary identifier. */
return cp_parser_identifier (parser);
}
/* Overloading [gram.over] */
/* Parse an operator-function-id.
operator-function-id:
operator operator
Returns an IDENTIFIER_NODE for the operator which is a
human-readable spelling of the identifier, e.g., `operator +'. */
static tree
cp_parser_operator_function_id (cp_parser* parser)
{
/* Look for the `operator' keyword. */
if (!cp_parser_require_keyword (parser, RID_OPERATOR, "`operator'"))
return error_mark_node;
/* And then the name of the operator itself. */
return cp_parser_operator (parser);
}
/* Parse an operator.
operator:
new delete new[] delete[] + - * / % ^ & | ~ ! = < >
+= -= *= /= %= ^= &= |= << >> >>= <<= == != <= >= &&
|| ++ -- , ->* -> () []
GNU Extensions:
operator:
<? >? <?= >?=
Returns an IDENTIFIER_NODE for the operator which is a
human-readable spelling of the identifier, e.g., `operator +'. */
static tree
cp_parser_operator (cp_parser* parser)
{
tree id = NULL_TREE;
cp_token *token;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* Figure out which operator we have. */
switch (token->type)
{
case CPP_KEYWORD:
{
enum tree_code op;
/* The keyword should be either `new' or `delete'. */
if (token->keyword == RID_NEW)
op = NEW_EXPR;
else if (token->keyword == RID_DELETE)
op = DELETE_EXPR;
else
break;
/* Consume the `new' or `delete' token. */
cp_lexer_consume_token (parser->lexer);
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If it's a `[' token then this is the array variant of the
operator. */
if (token->type == CPP_OPEN_SQUARE)
{
/* Consume the `[' token. */
cp_lexer_consume_token (parser->lexer);
/* Look for the `]' token. */
cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'");
id = ansi_opname (op == NEW_EXPR
? VEC_NEW_EXPR : VEC_DELETE_EXPR);
}
/* Otherwise, we have the non-array variant. */
else
id = ansi_opname (op);
return id;
}
case CPP_PLUS:
id = ansi_opname (PLUS_EXPR);
break;
case CPP_MINUS:
id = ansi_opname (MINUS_EXPR);
break;
case CPP_MULT:
id = ansi_opname (MULT_EXPR);
break;
case CPP_DIV:
id = ansi_opname (TRUNC_DIV_EXPR);
break;
case CPP_MOD:
id = ansi_opname (TRUNC_MOD_EXPR);
break;
case CPP_XOR:
id = ansi_opname (BIT_XOR_EXPR);
break;
case CPP_AND:
id = ansi_opname (BIT_AND_EXPR);
break;
case CPP_OR:
id = ansi_opname (BIT_IOR_EXPR);
break;
case CPP_COMPL:
id = ansi_opname (BIT_NOT_EXPR);
break;
case CPP_NOT:
id = ansi_opname (TRUTH_NOT_EXPR);
break;
case CPP_EQ:
id = ansi_assopname (NOP_EXPR);
break;
case CPP_LESS:
id = ansi_opname (LT_EXPR);
break;
case CPP_GREATER:
id = ansi_opname (GT_EXPR);
break;
case CPP_PLUS_EQ:
id = ansi_assopname (PLUS_EXPR);
break;
case CPP_MINUS_EQ:
id = ansi_assopname (MINUS_EXPR);
break;
case CPP_MULT_EQ:
id = ansi_assopname (MULT_EXPR);
break;
case CPP_DIV_EQ:
id = ansi_assopname (TRUNC_DIV_EXPR);
break;
case CPP_MOD_EQ:
id = ansi_assopname (TRUNC_MOD_EXPR);
break;
case CPP_XOR_EQ:
id = ansi_assopname (BIT_XOR_EXPR);
break;
case CPP_AND_EQ:
id = ansi_assopname (BIT_AND_EXPR);
break;
case CPP_OR_EQ:
id = ansi_assopname (BIT_IOR_EXPR);
break;
case CPP_LSHIFT:
id = ansi_opname (LSHIFT_EXPR);
break;
case CPP_RSHIFT:
id = ansi_opname (RSHIFT_EXPR);
break;
case CPP_LSHIFT_EQ:
id = ansi_assopname (LSHIFT_EXPR);
break;
case CPP_RSHIFT_EQ:
id = ansi_assopname (RSHIFT_EXPR);
break;
case CPP_EQ_EQ:
id = ansi_opname (EQ_EXPR);
break;
case CPP_NOT_EQ:
id = ansi_opname (NE_EXPR);
break;
case CPP_LESS_EQ:
id = ansi_opname (LE_EXPR);
break;
case CPP_GREATER_EQ:
id = ansi_opname (GE_EXPR);
break;
case CPP_AND_AND:
id = ansi_opname (TRUTH_ANDIF_EXPR);
break;
case CPP_OR_OR:
id = ansi_opname (TRUTH_ORIF_EXPR);
break;
case CPP_PLUS_PLUS:
id = ansi_opname (POSTINCREMENT_EXPR);
break;
case CPP_MINUS_MINUS:
id = ansi_opname (PREDECREMENT_EXPR);
break;
case CPP_COMMA:
id = ansi_opname (COMPOUND_EXPR);
break;
case CPP_DEREF_STAR:
id = ansi_opname (MEMBER_REF);
break;
case CPP_DEREF:
id = ansi_opname (COMPONENT_REF);
break;
case CPP_OPEN_PAREN:
/* Consume the `('. */
cp_lexer_consume_token (parser->lexer);
/* Look for the matching `)'. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
return ansi_opname (CALL_EXPR);
case CPP_OPEN_SQUARE:
/* Consume the `['. */
cp_lexer_consume_token (parser->lexer);
/* Look for the matching `]'. */
cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'");
return ansi_opname (ARRAY_REF);
/* Extensions. */
case CPP_MIN:
id = ansi_opname (MIN_EXPR);
break;
case CPP_MAX:
id = ansi_opname (MAX_EXPR);
break;
case CPP_MIN_EQ:
id = ansi_assopname (MIN_EXPR);
break;
case CPP_MAX_EQ:
id = ansi_assopname (MAX_EXPR);
break;
default:
/* Anything else is an error. */
break;
}
/* If we have selected an identifier, we need to consume the
operator token. */
if (id)
cp_lexer_consume_token (parser->lexer);
/* Otherwise, no valid operator name was present. */
else
{
cp_parser_error (parser, "expected operator");
id = error_mark_node;
}
return id;
}
/* Parse a template-declaration.
template-declaration:
export [opt] template < template-parameter-list > declaration
If MEMBER_P is TRUE, this template-declaration occurs within a
class-specifier.
The grammar rule given by the standard isn't correct. What
is really meant is:
template-declaration:
export [opt] template-parameter-list-seq
decl-specifier-seq [opt] init-declarator [opt] ;
export [opt] template-parameter-list-seq
function-definition
template-parameter-list-seq:
template-parameter-list-seq [opt]
template < template-parameter-list > */
static void
cp_parser_template_declaration (cp_parser* parser, bool member_p)
{
/* Check for `export'. */
if (cp_lexer_next_token_is_keyword (parser->lexer, RID_EXPORT))
{
/* Consume the `export' token. */
cp_lexer_consume_token (parser->lexer);
/* Warn that we do not support `export'. */
warning ("keyword `export' not implemented, and will be ignored");
}
cp_parser_template_declaration_after_export (parser, member_p);
}
/* Parse a template-parameter-list.
template-parameter-list:
template-parameter
template-parameter-list , template-parameter
Returns a TREE_LIST. Each node represents a template parameter.
The nodes are connected via their TREE_CHAINs. */
static tree
cp_parser_template_parameter_list (cp_parser* parser)
{
tree parameter_list = NULL_TREE;
while (true)
{
tree parameter;
cp_token *token;
/* Parse the template-parameter. */
parameter = cp_parser_template_parameter (parser);
/* Add it to the list. */
parameter_list = process_template_parm (parameter_list,
parameter);
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If it's not a `,', we're done. */
if (token->type != CPP_COMMA)
break;
/* Otherwise, consume the `,' token. */
cp_lexer_consume_token (parser->lexer);
}
return parameter_list;
}
/* Parse a template-parameter.
template-parameter:
type-parameter
parameter-declaration
Returns a TREE_LIST. The TREE_VALUE represents the parameter. The
TREE_PURPOSE is the default value, if any. */
static tree
cp_parser_template_parameter (cp_parser* parser)
{
cp_token *token;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If it is `class' or `template', we have a type-parameter. */
if (token->keyword == RID_TEMPLATE)
return cp_parser_type_parameter (parser);
/* If it is `class' or `typename' we do not know yet whether it is a
type parameter or a non-type parameter. Consider:
template <typename T, typename T::X X> ...
or:
template <class C, class D*> ...
Here, the first parameter is a type parameter, and the second is
a non-type parameter. We can tell by looking at the token after
the identifier -- if it is a `,', `=', or `>' then we have a type
parameter. */
if (token->keyword == RID_TYPENAME || token->keyword == RID_CLASS)
{
/* Peek at the token after `class' or `typename'. */
token = cp_lexer_peek_nth_token (parser->lexer, 2);
/* If it's an identifier, skip it. */
if (token->type == CPP_NAME)
token = cp_lexer_peek_nth_token (parser->lexer, 3);
/* Now, see if the token looks like the end of a template
parameter. */
if (token->type == CPP_COMMA
|| token->type == CPP_EQ
|| token->type == CPP_GREATER)
return cp_parser_type_parameter (parser);
}
/* Otherwise, it is a non-type parameter.
[temp.param]
When parsing a default template-argument for a non-type
template-parameter, the first non-nested `>' is taken as the end
of the template parameter-list rather than a greater-than
operator. */
return
cp_parser_parameter_declaration (parser, /*template_parm_p=*/true);
}
/* Parse a type-parameter.
type-parameter:
class identifier [opt]
class identifier [opt] = type-id
typename identifier [opt]
typename identifier [opt] = type-id
template < template-parameter-list > class identifier [opt]
template < template-parameter-list > class identifier [opt]
= id-expression
Returns a TREE_LIST. The TREE_VALUE is itself a TREE_LIST. The
TREE_PURPOSE is the default-argument, if any. The TREE_VALUE is
the declaration of the parameter. */
static tree
cp_parser_type_parameter (cp_parser* parser)
{
cp_token *token;
tree parameter;
/* Look for a keyword to tell us what kind of parameter this is. */
token = cp_parser_require (parser, CPP_KEYWORD,
"`class', `typename', or `template'");
if (!token)
return error_mark_node;
switch (token->keyword)
{
case RID_CLASS:
case RID_TYPENAME:
{
tree identifier;
tree default_argument;
/* If the next token is an identifier, then it names the
parameter. */
if (cp_lexer_next_token_is (parser->lexer, CPP_NAME))
identifier = cp_parser_identifier (parser);
else
identifier = NULL_TREE;
/* Create the parameter. */
parameter = finish_template_type_parm (class_type_node, identifier);
/* If the next token is an `=', we have a default argument. */
if (cp_lexer_next_token_is (parser->lexer, CPP_EQ))
{
/* Consume the `=' token. */
cp_lexer_consume_token (parser->lexer);
/* Parse the default-argumen. */
default_argument = cp_parser_type_id (parser);
}
else
default_argument = NULL_TREE;
/* Create the combined representation of the parameter and the
default argument. */
parameter = build_tree_list (default_argument,
parameter);
}
break;
case RID_TEMPLATE:
{
tree parameter_list;
tree identifier;
tree default_argument;
/* Look for the `<'. */
cp_parser_require (parser, CPP_LESS, "`<'");
/* Parse the template-parameter-list. */
begin_template_parm_list ();
parameter_list
= cp_parser_template_parameter_list (parser);
parameter_list = end_template_parm_list (parameter_list);
/* Look for the `>'. */
cp_parser_require (parser, CPP_GREATER, "`>'");
/* Look for the `class' keyword. */
cp_parser_require_keyword (parser, RID_CLASS, "`class'");
/* If the next token is an `=', then there is a
default-argument. If the next token is a `>', we are at
the end of the parameter-list. If the next token is a `,',
then we are at the end of this parameter. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_EQ)
&& cp_lexer_next_token_is_not (parser->lexer, CPP_GREATER)
&& cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA))
identifier = cp_parser_identifier (parser);
else
identifier = NULL_TREE;
/* Create the template parameter. */
parameter = finish_template_template_parm (class_type_node,
identifier);
/* If the next token is an `=', then there is a
default-argument. */
if (cp_lexer_next_token_is (parser->lexer, CPP_EQ))
{
/* Consume the `='. */
cp_lexer_consume_token (parser->lexer);
/* Parse the id-expression. */
default_argument
= cp_parser_id_expression (parser,
/*template_keyword_p=*/false,
/*check_dependency_p=*/true,
/*template_p=*/NULL);
/* Look up the name. */
default_argument
= cp_parser_lookup_name_simple (parser, default_argument);
/* See if the default argument is valid. */
default_argument
= check_template_template_default_arg (default_argument);
}
else
default_argument = NULL_TREE;
/* Create the combined representation of the parameter and the
default argument. */
parameter = build_tree_list (default_argument,
parameter);
}
break;
default:
/* Anything else is an error. */
cp_parser_error (parser,
"expected `class', `typename', or `template'");
parameter = error_mark_node;
}
return parameter;
}
/* Parse a template-id.
template-id:
template-name < template-argument-list [opt] >
If TEMPLATE_KEYWORD_P is TRUE, then we have just seen the
`template' keyword. In this case, a TEMPLATE_ID_EXPR will be
returned. Otherwise, if the template-name names a function, or set
of functions, returns a TEMPLATE_ID_EXPR. If the template-name
names a class, returns a TYPE_DECL for the specialization.
If CHECK_DEPENDENCY_P is FALSE, names are looked up in
uninstantiated templates. */
static tree
cp_parser_template_id (cp_parser *parser,
bool template_keyword_p,
bool check_dependency_p)
{
tree template;
tree arguments;
tree saved_scope;
tree saved_qualifying_scope;
tree saved_object_scope;
tree template_id;
bool saved_greater_than_is_operator_p;
ptrdiff_t start_of_id;
tree access_check = NULL_TREE;
cp_token *next_token;
/* If the next token corresponds to a template-id, there is no need
to reparse it. */
next_token = cp_lexer_peek_token (parser->lexer);
if (next_token->type == CPP_TEMPLATE_ID)
{
tree value;
tree check;
/* Get the stored value. */
value = cp_lexer_consume_token (parser->lexer)->value;
/* Perform any access checks that were deferred. */
for (check = TREE_PURPOSE (value); check; check = TREE_CHAIN (check))
perform_or_defer_access_check (TREE_PURPOSE (check),
TREE_VALUE (check));
/* Return the stored value. */
return TREE_VALUE (value);
}
/* Avoid performing name lookup if there is no possibility of
finding a template-id. */
if ((next_token->type != CPP_NAME && next_token->keyword != RID_OPERATOR)
|| (next_token->type == CPP_NAME
&& cp_lexer_peek_nth_token (parser->lexer, 2)->type != CPP_LESS))
{
cp_parser_error (parser, "expected template-id");
return error_mark_node;
}
/* Remember where the template-id starts. */
if (cp_parser_parsing_tentatively (parser)
&& !cp_parser_committed_to_tentative_parse (parser))
{
next_token = cp_lexer_peek_token (parser->lexer);
start_of_id = cp_lexer_token_difference (parser->lexer,
parser->lexer->first_token,
next_token);
}
else
start_of_id = -1;
push_deferring_access_checks (dk_deferred);
/* Parse the template-name. */
template = cp_parser_template_name (parser, template_keyword_p,
check_dependency_p);
if (template == error_mark_node)
{
pop_deferring_access_checks ();
return error_mark_node;
}
/* Look for the `<' that starts the template-argument-list. */
if (!cp_parser_require (parser, CPP_LESS, "`<'"))
{
pop_deferring_access_checks ();
return error_mark_node;
}
/* [temp.names]
When parsing a template-id, the first non-nested `>' is taken as
the end of the template-argument-list rather than a greater-than
operator. */
saved_greater_than_is_operator_p
= parser->greater_than_is_operator_p;
parser->greater_than_is_operator_p = false;
/* Parsing the argument list may modify SCOPE, so we save it
here. */
saved_scope = parser->scope;
saved_qualifying_scope = parser->qualifying_scope;
saved_object_scope = parser->object_scope;
/* Parse the template-argument-list itself. */
if (cp_lexer_next_token_is (parser->lexer, CPP_GREATER))
arguments = NULL_TREE;
else
arguments = cp_parser_template_argument_list (parser);
/* Look for the `>' that ends the template-argument-list. */
cp_parser_require (parser, CPP_GREATER, "`>'");
/* The `>' token might be a greater-than operator again now. */
parser->greater_than_is_operator_p
= saved_greater_than_is_operator_p;
/* Restore the SAVED_SCOPE. */
parser->scope = saved_scope;
parser->qualifying_scope = saved_qualifying_scope;
parser->object_scope = saved_object_scope;
/* Build a representation of the specialization. */
if (TREE_CODE (template) == IDENTIFIER_NODE)
template_id = build_min_nt (TEMPLATE_ID_EXPR, template, arguments);
else if (DECL_CLASS_TEMPLATE_P (template)
|| DECL_TEMPLATE_TEMPLATE_PARM_P (template))
template_id
= finish_template_type (template, arguments,
cp_lexer_next_token_is (parser->lexer,
CPP_SCOPE));
else
{
/* If it's not a class-template or a template-template, it should be
a function-template. */
my_friendly_assert ((DECL_FUNCTION_TEMPLATE_P (template)
|| TREE_CODE (template) == OVERLOAD
|| BASELINK_P (template)),
20010716);
template_id = lookup_template_function (template, arguments);
}
/* Retrieve any deferred checks. Do not pop this access checks yet
so the memory will not be reclaimed during token replacing below. */
access_check = get_deferred_access_checks ();
/* If parsing tentatively, replace the sequence of tokens that makes
up the template-id with a CPP_TEMPLATE_ID token. That way,
should we re-parse the token stream, we will not have to repeat
the effort required to do the parse, nor will we issue duplicate
error messages about problems during instantiation of the
template. */
if (start_of_id >= 0)
{
cp_token *token;
/* Find the token that corresponds to the start of the
template-id. */
token = cp_lexer_advance_token (parser->lexer,
parser->lexer->first_token,
start_of_id);
/* Reset the contents of the START_OF_ID token. */
token->type = CPP_TEMPLATE_ID;
token->value = build_tree_list (access_check, template_id);
token->keyword = RID_MAX;
/* Purge all subsequent tokens. */
cp_lexer_purge_tokens_after (parser->lexer, token);
}
pop_deferring_access_checks ();
return template_id;
}
/* Parse a template-name.
template-name:
identifier
The standard should actually say:
template-name:
identifier
operator-function-id
conversion-function-id
A defect report has been filed about this issue.
If TEMPLATE_KEYWORD_P is true, then we have just seen the
`template' keyword, in a construction like:
T::template f<3>()
In that case `f' is taken to be a template-name, even though there
is no way of knowing for sure.
Returns the TEMPLATE_DECL for the template, or an OVERLOAD if the
name refers to a set of overloaded functions, at least one of which
is a template, or an IDENTIFIER_NODE with the name of the template,
if TEMPLATE_KEYWORD_P is true. If CHECK_DEPENDENCY_P is FALSE,
names are looked up inside uninstantiated templates. */
static tree
cp_parser_template_name (cp_parser* parser,
bool template_keyword_p,
bool check_dependency_p)
{
tree identifier;
tree decl;
tree fns;
/* If the next token is `operator', then we have either an
operator-function-id or a conversion-function-id. */
if (cp_lexer_next_token_is_keyword (parser->lexer, RID_OPERATOR))
{
/* We don't know whether we're looking at an
operator-function-id or a conversion-function-id. */
cp_parser_parse_tentatively (parser);
/* Try an operator-function-id. */
identifier = cp_parser_operator_function_id (parser);
/* If that didn't work, try a conversion-function-id. */
if (!cp_parser_parse_definitely (parser))
identifier = cp_parser_conversion_function_id (parser);
}
/* Look for the identifier. */
else
identifier = cp_parser_identifier (parser);
/* If we didn't find an identifier, we don't have a template-id. */
if (identifier == error_mark_node)
return error_mark_node;
/* If the name immediately followed the `template' keyword, then it
is a template-name. However, if the next token is not `<', then
we do not treat it as a template-name, since it is not being used
as part of a template-id. This enables us to handle constructs
like:
template <typename T> struct S { S(); };
template <typename T> S<T>::S();
correctly. We would treat `S' as a template -- if it were `S<T>'
-- but we do not if there is no `<'. */
if (template_keyword_p && processing_template_decl
&& cp_lexer_next_token_is (parser->lexer, CPP_LESS))
return identifier;
/* Look up the name. */
decl = cp_parser_lookup_name (parser, identifier,
/*is_type=*/false,
/*is_namespace=*/false,
check_dependency_p);
decl = maybe_get_template_decl_from_type_decl (decl);
/* If DECL is a template, then the name was a template-name. */
if (TREE_CODE (decl) == TEMPLATE_DECL)
;
else
{
/* The standard does not explicitly indicate whether a name that
names a set of overloaded declarations, some of which are
templates, is a template-name. However, such a name should
be a template-name; otherwise, there is no way to form a
template-id for the overloaded templates. */
fns = BASELINK_P (decl) ? BASELINK_FUNCTIONS (decl) : decl;
if (TREE_CODE (fns) == OVERLOAD)
{
tree fn;
for (fn = fns; fn; fn = OVL_NEXT (fn))
if (TREE_CODE (OVL_CURRENT (fn)) == TEMPLATE_DECL)
break;
}
else
{
/* Otherwise, the name does not name a template. */
cp_parser_error (parser, "expected template-name");
return error_mark_node;
}
}
/* If DECL is dependent, and refers to a function, then just return
its name; we will look it up again during template instantiation. */
if (DECL_FUNCTION_TEMPLATE_P (decl) || !DECL_P (decl))
{
tree scope = CP_DECL_CONTEXT (get_first_fn (decl));
if (TYPE_P (scope) && dependent_type_p (scope))
return identifier;
}
return decl;
}
/* Parse a template-argument-list.
template-argument-list:
template-argument
template-argument-list , template-argument
Returns a TREE_LIST representing the arguments, in the order they
appeared. The TREE_VALUE of each node is a representation of the
argument. */
static tree
cp_parser_template_argument_list (cp_parser* parser)
{
tree arguments = NULL_TREE;
while (true)
{
tree argument;
/* Parse the template-argument. */
argument = cp_parser_template_argument (parser);
/* Add it to the list. */
arguments = tree_cons (NULL_TREE, argument, arguments);
/* If it is not a `,', then there are no more arguments. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA))
break;
/* Otherwise, consume the ','. */
cp_lexer_consume_token (parser->lexer);
}
/* We built up the arguments in reverse order. */
return nreverse (arguments);
}
/* Parse a template-argument.
template-argument:
assignment-expression
type-id
id-expression
The representation is that of an assignment-expression, type-id, or
id-expression -- except that the qualified id-expression is
evaluated, so that the value returned is either a DECL or an
OVERLOAD. */
static tree
cp_parser_template_argument (cp_parser* parser)
{
tree argument;
bool template_p;
/* There's really no way to know what we're looking at, so we just
try each alternative in order.
[temp.arg]
In a template-argument, an ambiguity between a type-id and an
expression is resolved to a type-id, regardless of the form of
the corresponding template-parameter.
Therefore, we try a type-id first. */
cp_parser_parse_tentatively (parser);
argument = cp_parser_type_id (parser);
/* If the next token isn't a `,' or a `>', then this argument wasn't
really finished. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA)
&& cp_lexer_next_token_is_not (parser->lexer, CPP_GREATER))
cp_parser_error (parser, "expected template-argument");
/* If that worked, we're done. */
if (cp_parser_parse_definitely (parser))
return argument;
/* We're still not sure what the argument will be. */
cp_parser_parse_tentatively (parser);
/* Try a template. */
argument = cp_parser_id_expression (parser,
/*template_keyword_p=*/false,
/*check_dependency_p=*/true,
&template_p);
/* If the next token isn't a `,' or a `>', then this argument wasn't
really finished. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA)
&& cp_lexer_next_token_is_not (parser->lexer, CPP_GREATER))
cp_parser_error (parser, "expected template-argument");
if (!cp_parser_error_occurred (parser))
{
/* Figure out what is being referred to. */
argument = cp_parser_lookup_name_simple (parser, argument);
if (template_p)
argument = make_unbound_class_template (TREE_OPERAND (argument, 0),
TREE_OPERAND (argument, 1),
tf_error);
else if (TREE_CODE (argument) != TEMPLATE_DECL)
cp_parser_error (parser, "expected template-name");
}
if (cp_parser_parse_definitely (parser))
return argument;
/* It must be an assignment-expression. */
return cp_parser_assignment_expression (parser);
}
/* Parse an explicit-instantiation.
explicit-instantiation:
template declaration
Although the standard says `declaration', what it really means is:
explicit-instantiation:
template decl-specifier-seq [opt] declarator [opt] ;
Things like `template int S<int>::i = 5, int S<double>::j;' are not
supposed to be allowed. A defect report has been filed about this
issue.
GNU Extension:
explicit-instantiation:
storage-class-specifier template
decl-specifier-seq [opt] declarator [opt] ;
function-specifier template
decl-specifier-seq [opt] declarator [opt] ; */
static void
cp_parser_explicit_instantiation (cp_parser* parser)
{
bool declares_class_or_enum;
tree decl_specifiers;
tree attributes;
tree extension_specifier = NULL_TREE;
/* Look for an (optional) storage-class-specifier or
function-specifier. */
if (cp_parser_allow_gnu_extensions_p (parser))
{
extension_specifier
= cp_parser_storage_class_specifier_opt (parser);
if (!extension_specifier)
extension_specifier = cp_parser_function_specifier_opt (parser);
}
/* Look for the `template' keyword. */
cp_parser_require_keyword (parser, RID_TEMPLATE, "`template'");
/* Let the front end know that we are processing an explicit
instantiation. */
begin_explicit_instantiation ();
/* [temp.explicit] says that we are supposed to ignore access
control while processing explicit instantiation directives. */
push_deferring_access_checks (dk_no_check);
/* Parse a decl-specifier-seq. */
decl_specifiers
= cp_parser_decl_specifier_seq (parser,
CP_PARSER_FLAGS_OPTIONAL,
&attributes,
&declares_class_or_enum);
/* If there was exactly one decl-specifier, and it declared a class,
and there's no declarator, then we have an explicit type
instantiation. */
if (declares_class_or_enum && cp_parser_declares_only_class_p (parser))
{
tree type;
type = check_tag_decl (decl_specifiers);
/* Turn access control back on for names used during
template instantiation. */
pop_deferring_access_checks ();
if (type)
do_type_instantiation (type, extension_specifier, /*complain=*/1);
}
else
{
tree declarator;
tree decl;
/* Parse the declarator. */
declarator
= cp_parser_declarator (parser, CP_PARSER_DECLARATOR_NAMED,
/*ctor_dtor_or_conv_p=*/NULL);
decl = grokdeclarator (declarator, decl_specifiers,
NORMAL, 0, NULL);
/* Turn access control back on for names used during
template instantiation. */
pop_deferring_access_checks ();
/* Do the explicit instantiation. */
do_decl_instantiation (decl, extension_specifier);
}
/* We're done with the instantiation. */
end_explicit_instantiation ();
cp_parser_consume_semicolon_at_end_of_statement (parser);
}
/* Parse an explicit-specialization.
explicit-specialization:
template < > declaration
Although the standard says `declaration', what it really means is:
explicit-specialization:
template <> decl-specifier [opt] init-declarator [opt] ;
template <> function-definition
template <> explicit-specialization
template <> template-declaration */
static void
cp_parser_explicit_specialization (cp_parser* parser)
{
/* Look for the `template' keyword. */
cp_parser_require_keyword (parser, RID_TEMPLATE, "`template'");
/* Look for the `<'. */
cp_parser_require (parser, CPP_LESS, "`<'");
/* Look for the `>'. */
cp_parser_require (parser, CPP_GREATER, "`>'");
/* We have processed another parameter list. */
++parser->num_template_parameter_lists;
/* Let the front end know that we are beginning a specialization. */
begin_specialization ();
/* If the next keyword is `template', we need to figure out whether
or not we're looking a template-declaration. */
if (cp_lexer_next_token_is_keyword (parser->lexer, RID_TEMPLATE))
{
if (cp_lexer_peek_nth_token (parser->lexer, 2)->type == CPP_LESS
&& cp_lexer_peek_nth_token (parser->lexer, 3)->type != CPP_GREATER)
cp_parser_template_declaration_after_export (parser,
/*member_p=*/false);
else
cp_parser_explicit_specialization (parser);
}
else
/* Parse the dependent declaration. */
cp_parser_single_declaration (parser,
/*member_p=*/false,
/*friend_p=*/NULL);
/* We're done with the specialization. */
end_specialization ();
/* We're done with this parameter list. */
--parser->num_template_parameter_lists;
}
/* Parse a type-specifier.
type-specifier:
simple-type-specifier
class-specifier
enum-specifier
elaborated-type-specifier
cv-qualifier
GNU Extension:
type-specifier:
__complex__
Returns a representation of the type-specifier. If the
type-specifier is a keyword (like `int' or `const', or
`__complex__') then the correspoding IDENTIFIER_NODE is returned.
For a class-specifier, enum-specifier, or elaborated-type-specifier
a TREE_TYPE is returned; otherwise, a TYPE_DECL is returned.
If IS_FRIEND is TRUE then this type-specifier is being declared a
`friend'. If IS_DECLARATION is TRUE, then this type-specifier is
appearing in a decl-specifier-seq.
If DECLARES_CLASS_OR_ENUM is non-NULL, and the type-specifier is a
class-specifier, enum-specifier, or elaborated-type-specifier, then
*DECLARES_CLASS_OR_ENUM is set to TRUE. Otherwise, it is set to
FALSE.
If IS_CV_QUALIFIER is non-NULL, and the type-specifier is a
cv-qualifier, then IS_CV_QUALIFIER is set to TRUE. Otherwise, it
is set to FALSE. */
static tree
cp_parser_type_specifier (cp_parser* parser,
cp_parser_flags flags,
bool is_friend,
bool is_declaration,
bool* declares_class_or_enum,
bool* is_cv_qualifier)
{
tree type_spec = NULL_TREE;
cp_token *token;
enum rid keyword;
/* Assume this type-specifier does not declare a new type. */
if (declares_class_or_enum)
*declares_class_or_enum = false;
/* And that it does not specify a cv-qualifier. */
if (is_cv_qualifier)
*is_cv_qualifier = false;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If we're looking at a keyword, we can use that to guide the
production we choose. */
keyword = token->keyword;
switch (keyword)
{
/* Any of these indicate either a class-specifier, or an
elaborated-type-specifier. */
case RID_CLASS:
case RID_STRUCT:
case RID_UNION:
case RID_ENUM:
/* Parse tentatively so that we can back up if we don't find a
class-specifier or enum-specifier. */
cp_parser_parse_tentatively (parser);
/* Look for the class-specifier or enum-specifier. */
if (keyword == RID_ENUM)
type_spec = cp_parser_enum_specifier (parser);
else
type_spec = cp_parser_class_specifier (parser);
/* If that worked, we're done. */
if (cp_parser_parse_definitely (parser))
{
if (declares_class_or_enum)
*declares_class_or_enum = true;
return type_spec;
}
/* Fall through. */
case RID_TYPENAME:
/* Look for an elaborated-type-specifier. */
type_spec = cp_parser_elaborated_type_specifier (parser,
is_friend,
is_declaration);
/* We're declaring a class or enum -- unless we're using
`typename'. */
if (declares_class_or_enum && keyword != RID_TYPENAME)
*declares_class_or_enum = true;
return type_spec;
case RID_CONST:
case RID_VOLATILE:
case RID_RESTRICT:
type_spec = cp_parser_cv_qualifier_opt (parser);
/* Even though we call a routine that looks for an optional
qualifier, we know that there should be one. */
my_friendly_assert (type_spec != NULL, 20000328);
/* This type-specifier was a cv-qualified. */
if (is_cv_qualifier)
*is_cv_qualifier = true;
return type_spec;
case RID_COMPLEX:
/* The `__complex__' keyword is a GNU extension. */
return cp_lexer_consume_token (parser->lexer)->value;
default:
break;
}
/* If we do not already have a type-specifier, assume we are looking
at a simple-type-specifier. */
type_spec = cp_parser_simple_type_specifier (parser, flags);
/* If we didn't find a type-specifier, and a type-specifier was not
optional in this context, issue an error message. */
if (!type_spec && !(flags & CP_PARSER_FLAGS_OPTIONAL))
{
cp_parser_error (parser, "expected type specifier");
return error_mark_node;
}
return type_spec;
}
/* Parse a simple-type-specifier.
simple-type-specifier:
:: [opt] nested-name-specifier [opt] type-name
:: [opt] nested-name-specifier template template-id
char
wchar_t
bool
short
int
long
signed
unsigned
float
double
void
GNU Extension:
simple-type-specifier:
__typeof__ unary-expression
__typeof__ ( type-id )
For the various keywords, the value returned is simply the
TREE_IDENTIFIER representing the keyword. For the first two
productions, the value returned is the indicated TYPE_DECL. */
static tree
cp_parser_simple_type_specifier (cp_parser* parser, cp_parser_flags flags)
{
tree type = NULL_TREE;
cp_token *token;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If we're looking at a keyword, things are easy. */
switch (token->keyword)
{
case RID_CHAR:
case RID_WCHAR:
case RID_BOOL:
case RID_SHORT:
case RID_INT:
case RID_LONG:
case RID_SIGNED:
case RID_UNSIGNED:
case RID_FLOAT:
case RID_DOUBLE:
case RID_VOID:
/* Consume the token. */
return cp_lexer_consume_token (parser->lexer)->value;
case RID_TYPEOF:
{
tree operand;
/* Consume the `typeof' token. */
cp_lexer_consume_token (parser->lexer);
/* Parse the operand to `typeof' */
operand = cp_parser_sizeof_operand (parser, RID_TYPEOF);
/* If it is not already a TYPE, take its type. */
if (!TYPE_P (operand))
operand = finish_typeof (operand);
return operand;
}
default:
break;
}
/* The type-specifier must be a user-defined type. */
if (!(flags & CP_PARSER_FLAGS_NO_USER_DEFINED_TYPES))
{
/* Don't gobble tokens or issue error messages if this is an
optional type-specifier. */
if (flags & CP_PARSER_FLAGS_OPTIONAL)
cp_parser_parse_tentatively (parser);
/* Look for the optional `::' operator. */
cp_parser_global_scope_opt (parser,
/*current_scope_valid_p=*/false);
/* Look for the nested-name specifier. */
cp_parser_nested_name_specifier_opt (parser,
/*typename_keyword_p=*/false,
/*check_dependency_p=*/true,
/*type_p=*/false);
/* If we have seen a nested-name-specifier, and the next token
is `template', then we are using the template-id production. */
if (parser->scope
&& cp_parser_optional_template_keyword (parser))
{
/* Look for the template-id. */
type = cp_parser_template_id (parser,
/*template_keyword_p=*/true,
/*check_dependency_p=*/true);
/* If the template-id did not name a type, we are out of
luck. */
if (TREE_CODE (type) != TYPE_DECL)
{
cp_parser_error (parser, "expected template-id for type");
type = NULL_TREE;
}
}
/* Otherwise, look for a type-name. */
else
{
type = cp_parser_type_name (parser);
if (type == error_mark_node)
type = NULL_TREE;
}
/* If it didn't work out, we don't have a TYPE. */
if ((flags & CP_PARSER_FLAGS_OPTIONAL)
&& !cp_parser_parse_definitely (parser))
type = NULL_TREE;
}
/* If we didn't get a type-name, issue an error message. */
if (!type && !(flags & CP_PARSER_FLAGS_OPTIONAL))
{
cp_parser_error (parser, "expected type-name");
return error_mark_node;
}
return type;
}
/* Parse a type-name.
type-name:
class-name
enum-name
typedef-name
enum-name:
identifier
typedef-name:
identifier
Returns a TYPE_DECL for the the type. */
static tree
cp_parser_type_name (cp_parser* parser)
{
tree type_decl;
tree identifier;
/* We can't know yet whether it is a class-name or not. */
cp_parser_parse_tentatively (parser);
/* Try a class-name. */
type_decl = cp_parser_class_name (parser,
/*typename_keyword_p=*/false,
/*template_keyword_p=*/false,
/*type_p=*/false,
/*check_dependency_p=*/true,
/*class_head_p=*/false);
/* If it's not a class-name, keep looking. */
if (!cp_parser_parse_definitely (parser))
{
/* It must be a typedef-name or an enum-name. */
identifier = cp_parser_identifier (parser);
if (identifier == error_mark_node)
return error_mark_node;
/* Look up the type-name. */
type_decl = cp_parser_lookup_name_simple (parser, identifier);
/* Issue an error if we did not find a type-name. */
if (TREE_CODE (type_decl) != TYPE_DECL)
{
cp_parser_error (parser, "expected type-name");
type_decl = error_mark_node;
}
/* Remember that the name was used in the definition of the
current class so that we can check later to see if the
meaning would have been different after the class was
entirely defined. */
else if (type_decl != error_mark_node
&& !parser->scope)
maybe_note_name_used_in_class (identifier, type_decl);
}
return type_decl;
}
/* Parse an elaborated-type-specifier. Note that the grammar given
here incorporates the resolution to DR68.
elaborated-type-specifier:
class-key :: [opt] nested-name-specifier [opt] identifier
class-key :: [opt] nested-name-specifier [opt] template [opt] template-id
enum :: [opt] nested-name-specifier [opt] identifier
typename :: [opt] nested-name-specifier identifier
typename :: [opt] nested-name-specifier template [opt]
template-id
If IS_FRIEND is TRUE, then this elaborated-type-specifier is being
declared `friend'. If IS_DECLARATION is TRUE, then this
elaborated-type-specifier appears in a decl-specifiers-seq, i.e.,
something is being declared.
Returns the TYPE specified. */
static tree
cp_parser_elaborated_type_specifier (cp_parser* parser,
bool is_friend,
bool is_declaration)
{
enum tag_types tag_type;
tree identifier;
tree type = NULL_TREE;
/* See if we're looking at the `enum' keyword. */
if (cp_lexer_next_token_is_keyword (parser->lexer, RID_ENUM))
{
/* Consume the `enum' token. */
cp_lexer_consume_token (parser->lexer);
/* Remember that it's an enumeration type. */
tag_type = enum_type;
}
/* Or, it might be `typename'. */
else if (cp_lexer_next_token_is_keyword (parser->lexer,
RID_TYPENAME))
{
/* Consume the `typename' token. */
cp_lexer_consume_token (parser->lexer);
/* Remember that it's a `typename' type. */
tag_type = typename_type;
/* The `typename' keyword is only allowed in templates. */
if (!processing_template_decl)
pedwarn ("using `typename' outside of template");
}
/* Otherwise it must be a class-key. */
else
{
tag_type = cp_parser_class_key (parser);
if (tag_type == none_type)
return error_mark_node;
}
/* Look for the `::' operator. */
cp_parser_global_scope_opt (parser,
/*current_scope_valid_p=*/false);
/* Look for the nested-name-specifier. */
if (tag_type == typename_type)
{
if (cp_parser_nested_name_specifier (parser,
/*typename_keyword_p=*/true,
/*check_dependency_p=*/true,
/*type_p=*/true)
== error_mark_node)
return error_mark_node;
}
else
/* Even though `typename' is not present, the proposed resolution
to Core Issue 180 says that in `class A<T>::B', `B' should be
considered a type-name, even if `A<T>' is dependent. */
cp_parser_nested_name_specifier_opt (parser,
/*typename_keyword_p=*/true,
/*check_dependency_p=*/true,
/*type_p=*/true);
/* For everything but enumeration types, consider a template-id. */
if (tag_type != enum_type)
{
bool template_p = false;
tree decl;
/* Allow the `template' keyword. */
template_p = cp_parser_optional_template_keyword (parser);
/* If we didn't see `template', we don't know if there's a
template-id or not. */
if (!template_p)
cp_parser_parse_tentatively (parser);
/* Parse the template-id. */
decl = cp_parser_template_id (parser, template_p,
/*check_dependency_p=*/true);
/* If we didn't find a template-id, look for an ordinary
identifier. */
if (!template_p && !cp_parser_parse_definitely (parser))
;
/* If DECL is a TEMPLATE_ID_EXPR, and the `typename' keyword is
in effect, then we must assume that, upon instantiation, the
template will correspond to a class. */
else if (TREE_CODE (decl) == TEMPLATE_ID_EXPR
&& tag_type == typename_type)
type = make_typename_type (parser->scope, decl,
/*complain=*/1);
else
type = TREE_TYPE (decl);
}
/* For an enumeration type, consider only a plain identifier. */
if (!type)
{
identifier = cp_parser_identifier (parser);
if (identifier == error_mark_node)
return error_mark_node;
/* For a `typename', we needn't call xref_tag. */
if (tag_type == typename_type)
return make_typename_type (parser->scope, identifier,
/*complain=*/1);
/* Look up a qualified name in the usual way. */
if (parser->scope)
{
tree decl;
/* In an elaborated-type-specifier, names are assumed to name
types, so we set IS_TYPE to TRUE when calling
cp_parser_lookup_name. */
decl = cp_parser_lookup_name (parser, identifier,
/*is_type=*/true,
/*is_namespace=*/false,
/*check_dependency=*/true);
/* If we are parsing friend declaration, DECL may be a
TEMPLATE_DECL tree node here. However, we need to check
whether this TEMPLATE_DECL results in valid code. Consider
the following example:
namespace N {
template <class T> class C {};
}
class X {
template <class T> friend class N::C; // #1, valid code
};
template <class T> class Y {
friend class N::C; // #2, invalid code
};
For both case #1 and #2, we arrive at a TEMPLATE_DECL after
name lookup of `N::C'. We see that friend declaration must
be template for the code to be valid. Note that
processing_template_decl does not work here since it is
always 1 for the above two cases. */
decl = (cp_parser_maybe_treat_template_as_class
(decl, /*tag_name_p=*/is_friend
&& parser->num_template_parameter_lists));
if (TREE_CODE (decl) != TYPE_DECL)
{
error ("expected type-name");
return error_mark_node;
}
else if (TREE_CODE (TREE_TYPE (decl)) == ENUMERAL_TYPE
&& tag_type != enum_type)
error ("`%T' referred to as `%s'", TREE_TYPE (decl),
tag_type == record_type ? "struct" : "class");
else if (TREE_CODE (TREE_TYPE (decl)) != ENUMERAL_TYPE
&& tag_type == enum_type)
error ("`%T' referred to as enum", TREE_TYPE (decl));
type = TREE_TYPE (decl);
}
else
{
/* An elaborated-type-specifier sometimes introduces a new type and
sometimes names an existing type. Normally, the rule is that it
introduces a new type only if there is not an existing type of
the same name already in scope. For example, given:
struct S {};
void f() { struct S s; }
the `struct S' in the body of `f' is the same `struct S' as in
the global scope; the existing definition is used. However, if
there were no global declaration, this would introduce a new
local class named `S'.
An exception to this rule applies to the following code:
namespace N { struct S; }
Here, the elaborated-type-specifier names a new type
unconditionally; even if there is already an `S' in the
containing scope this declaration names a new type.
This exception only applies if the elaborated-type-specifier
forms the complete declaration:
[class.name]
A declaration consisting solely of `class-key identifier ;' is
either a redeclaration of the name in the current scope or a
forward declaration of the identifier as a class name. It
introduces the name into the current scope.
We are in this situation precisely when the next token is a `;'.
An exception to the exception is that a `friend' declaration does
*not* name a new type; i.e., given:
struct S { friend struct T; };
`T' is not a new type in the scope of `S'.
Also, `new struct S' or `sizeof (struct S)' never results in the
definition of a new type; a new type can only be declared in a
declaration context. */
type = xref_tag (tag_type, identifier,
/*attributes=*/NULL_TREE,
(is_friend
|| !is_declaration
|| cp_lexer_next_token_is_not (parser->lexer,
CPP_SEMICOLON)));
}
}
if (tag_type != enum_type)
cp_parser_check_class_key (tag_type, type);
return type;
}
/* Parse an enum-specifier.
enum-specifier:
enum identifier [opt] { enumerator-list [opt] }
Returns an ENUM_TYPE representing the enumeration. */
static tree
cp_parser_enum_specifier (cp_parser* parser)
{
cp_token *token;
tree identifier = NULL_TREE;
tree type;
/* Look for the `enum' keyword. */
if (!cp_parser_require_keyword (parser, RID_ENUM, "`enum'"))
return error_mark_node;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* See if it is an identifier. */
if (token->type == CPP_NAME)
identifier = cp_parser_identifier (parser);
/* Look for the `{'. */
if (!cp_parser_require (parser, CPP_OPEN_BRACE, "`{'"))
return error_mark_node;
/* At this point, we're going ahead with the enum-specifier, even
if some other problem occurs. */
cp_parser_commit_to_tentative_parse (parser);
/* Issue an error message if type-definitions are forbidden here. */
cp_parser_check_type_definition (parser);
/* Create the new type. */
type = start_enum (identifier ? identifier : make_anon_name ());
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If it's not a `}', then there are some enumerators. */
if (token->type != CPP_CLOSE_BRACE)
cp_parser_enumerator_list (parser, type);
/* Look for the `}'. */
cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'");
/* Finish up the enumeration. */
finish_enum (type);
return type;
}
/* Parse an enumerator-list. The enumerators all have the indicated
TYPE.
enumerator-list:
enumerator-definition
enumerator-list , enumerator-definition */
static void
cp_parser_enumerator_list (cp_parser* parser, tree type)
{
while (true)
{
cp_token *token;
/* Parse an enumerator-definition. */
cp_parser_enumerator_definition (parser, type);
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If it's not a `,', then we've reached the end of the
list. */
if (token->type != CPP_COMMA)
break;
/* Otherwise, consume the `,' and keep going. */
cp_lexer_consume_token (parser->lexer);
/* If the next token is a `}', there is a trailing comma. */
if (cp_lexer_next_token_is (parser->lexer, CPP_CLOSE_BRACE))
{
if (pedantic && !in_system_header)
pedwarn ("comma at end of enumerator list");
break;
}
}
}
/* Parse an enumerator-definition. The enumerator has the indicated
TYPE.
enumerator-definition:
enumerator
enumerator = constant-expression
enumerator:
identifier */
static void
cp_parser_enumerator_definition (cp_parser* parser, tree type)
{
cp_token *token;
tree identifier;
tree value;
/* Look for the identifier. */
identifier = cp_parser_identifier (parser);
if (identifier == error_mark_node)
return;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If it's an `=', then there's an explicit value. */
if (token->type == CPP_EQ)
{
/* Consume the `=' token. */
cp_lexer_consume_token (parser->lexer);
/* Parse the value. */
value = cp_parser_constant_expression (parser,
/*allow_non_constant=*/false,
NULL);
}
else
value = NULL_TREE;
/* Create the enumerator. */
build_enumerator (identifier, value, type);
}
/* Parse a namespace-name.
namespace-name:
original-namespace-name
namespace-alias
Returns the NAMESPACE_DECL for the namespace. */
static tree
cp_parser_namespace_name (cp_parser* parser)
{
tree identifier;
tree namespace_decl;
/* Get the name of the namespace. */
identifier = cp_parser_identifier (parser);
if (identifier == error_mark_node)
return error_mark_node;
/* Look up the identifier in the currently active scope. Look only
for namespaces, due to:
[basic.lookup.udir]
When looking up a namespace-name in a using-directive or alias
definition, only namespace names are considered.
And:
[basic.lookup.qual]
During the lookup of a name preceding the :: scope resolution
operator, object, function, and enumerator names are ignored.
(Note that cp_parser_class_or_namespace_name only calls this
function if the token after the name is the scope resolution
operator.) */
namespace_decl = cp_parser_lookup_name (parser, identifier,
/*is_type=*/false,
/*is_namespace=*/true,
/*check_dependency=*/true);
/* If it's not a namespace, issue an error. */
if (namespace_decl == error_mark_node
|| TREE_CODE (namespace_decl) != NAMESPACE_DECL)
{
cp_parser_error (parser, "expected namespace-name");
namespace_decl = error_mark_node;
}
return namespace_decl;
}
/* Parse a namespace-definition.
namespace-definition:
named-namespace-definition
unnamed-namespace-definition
named-namespace-definition:
original-namespace-definition
extension-namespace-definition
original-namespace-definition:
namespace identifier { namespace-body }
extension-namespace-definition:
namespace original-namespace-name { namespace-body }
unnamed-namespace-definition:
namespace { namespace-body } */
static void
cp_parser_namespace_definition (cp_parser* parser)
{
tree identifier;
/* Look for the `namespace' keyword. */
cp_parser_require_keyword (parser, RID_NAMESPACE, "`namespace'");
/* Get the name of the namespace. We do not attempt to distinguish
between an original-namespace-definition and an
extension-namespace-definition at this point. The semantic
analysis routines are responsible for that. */
if (cp_lexer_next_token_is (parser->lexer, CPP_NAME))
identifier = cp_parser_identifier (parser);
else
identifier = NULL_TREE;
/* Look for the `{' to start the namespace. */
cp_parser_require (parser, CPP_OPEN_BRACE, "`{'");
/* Start the namespace. */
push_namespace (identifier);
/* Parse the body of the namespace. */
cp_parser_namespace_body (parser);
/* Finish the namespace. */
pop_namespace ();
/* Look for the final `}'. */
cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'");
}
/* Parse a namespace-body.
namespace-body:
declaration-seq [opt] */
static void
cp_parser_namespace_body (cp_parser* parser)
{
cp_parser_declaration_seq_opt (parser);
}
/* Parse a namespace-alias-definition.
namespace-alias-definition:
namespace identifier = qualified-namespace-specifier ; */
static void
cp_parser_namespace_alias_definition (cp_parser* parser)
{
tree identifier;
tree namespace_specifier;
/* Look for the `namespace' keyword. */
cp_parser_require_keyword (parser, RID_NAMESPACE, "`namespace'");
/* Look for the identifier. */
identifier = cp_parser_identifier (parser);
if (identifier == error_mark_node)
return;
/* Look for the `=' token. */
cp_parser_require (parser, CPP_EQ, "`='");
/* Look for the qualified-namespace-specifier. */
namespace_specifier
= cp_parser_qualified_namespace_specifier (parser);
/* Look for the `;' token. */
cp_parser_require (parser, CPP_SEMICOLON, "`;'");
/* Register the alias in the symbol table. */
do_namespace_alias (identifier, namespace_specifier);
}
/* Parse a qualified-namespace-specifier.
qualified-namespace-specifier:
:: [opt] nested-name-specifier [opt] namespace-name
Returns a NAMESPACE_DECL corresponding to the specified
namespace. */
static tree
cp_parser_qualified_namespace_specifier (cp_parser* parser)
{
/* Look for the optional `::'. */
cp_parser_global_scope_opt (parser,
/*current_scope_valid_p=*/false);
/* Look for the optional nested-name-specifier. */
cp_parser_nested_name_specifier_opt (parser,
/*typename_keyword_p=*/false,
/*check_dependency_p=*/true,
/*type_p=*/false);
return cp_parser_namespace_name (parser);
}
/* Parse a using-declaration.
using-declaration:
using typename [opt] :: [opt] nested-name-specifier unqualified-id ;
using :: unqualified-id ; */
static void
cp_parser_using_declaration (cp_parser* parser)
{
cp_token *token;
bool typename_p = false;
bool global_scope_p;
tree decl;
tree identifier;
tree scope;
/* Look for the `using' keyword. */
cp_parser_require_keyword (parser, RID_USING, "`using'");
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* See if it's `typename'. */
if (token->keyword == RID_TYPENAME)
{
/* Remember that we've seen it. */
typename_p = true;
/* Consume the `typename' token. */
cp_lexer_consume_token (parser->lexer);
}
/* Look for the optional global scope qualification. */
global_scope_p
= (cp_parser_global_scope_opt (parser,
/*current_scope_valid_p=*/false)
!= NULL_TREE);
/* If we saw `typename', or didn't see `::', then there must be a
nested-name-specifier present. */
if (typename_p || !global_scope_p)
cp_parser_nested_name_specifier (parser, typename_p,
/*check_dependency_p=*/true,
/*type_p=*/false);
/* Otherwise, we could be in either of the two productions. In that
case, treat the nested-name-specifier as optional. */
else
cp_parser_nested_name_specifier_opt (parser,
/*typename_keyword_p=*/false,
/*check_dependency_p=*/true,
/*type_p=*/false);
/* Parse the unqualified-id. */
identifier = cp_parser_unqualified_id (parser,
/*template_keyword_p=*/false,
/*check_dependency_p=*/true);
/* The function we call to handle a using-declaration is different
depending on what scope we are in. */
scope = current_scope ();
if (scope && TYPE_P (scope))
{
/* Create the USING_DECL. */
decl = do_class_using_decl (build_nt (SCOPE_REF,
parser->scope,
identifier));
/* Add it to the list of members in this class. */
finish_member_declaration (decl);
}
else
{
decl = cp_parser_lookup_name_simple (parser, identifier);
if (decl == error_mark_node)
{
if (parser->scope && parser->scope != global_namespace)
error ("`%D::%D' has not been declared",
parser->scope, identifier);
else
error ("`::%D' has not been declared", identifier);
}
else if (scope)
do_local_using_decl (decl);
else
do_toplevel_using_decl (decl);
}
/* Look for the final `;'. */
cp_parser_require (parser, CPP_SEMICOLON, "`;'");
}
/* Parse a using-directive.
using-directive:
using namespace :: [opt] nested-name-specifier [opt]
namespace-name ; */
static void
cp_parser_using_directive (cp_parser* parser)
{
tree namespace_decl;
/* Look for the `using' keyword. */
cp_parser_require_keyword (parser, RID_USING, "`using'");
/* And the `namespace' keyword. */
cp_parser_require_keyword (parser, RID_NAMESPACE, "`namespace'");
/* Look for the optional `::' operator. */
cp_parser_global_scope_opt (parser, /*current_scope_valid_p=*/false);
/* And the optional nested-name-sepcifier. */
cp_parser_nested_name_specifier_opt (parser,
/*typename_keyword_p=*/false,
/*check_dependency_p=*/true,
/*type_p=*/false);
/* Get the namespace being used. */
namespace_decl = cp_parser_namespace_name (parser);
/* Update the symbol table. */
do_using_directive (namespace_decl);
/* Look for the final `;'. */
cp_parser_require (parser, CPP_SEMICOLON, "`;'");
}
/* Parse an asm-definition.
asm-definition:
asm ( string-literal ) ;
GNU Extension:
asm-definition:
asm volatile [opt] ( string-literal ) ;
asm volatile [opt] ( string-literal : asm-operand-list [opt] ) ;
asm volatile [opt] ( string-literal : asm-operand-list [opt]
: asm-operand-list [opt] ) ;
asm volatile [opt] ( string-literal : asm-operand-list [opt]
: asm-operand-list [opt]
: asm-operand-list [opt] ) ; */
static void
cp_parser_asm_definition (cp_parser* parser)
{
cp_token *token;
tree string;
tree outputs = NULL_TREE;
tree inputs = NULL_TREE;
tree clobbers = NULL_TREE;
tree asm_stmt;
bool volatile_p = false;
bool extended_p = false;
/* Look for the `asm' keyword. */
cp_parser_require_keyword (parser, RID_ASM, "`asm'");
/* See if the next token is `volatile'. */
if (cp_parser_allow_gnu_extensions_p (parser)
&& cp_lexer_next_token_is_keyword (parser->lexer, RID_VOLATILE))
{
/* Remember that we saw the `volatile' keyword. */
volatile_p = true;
/* Consume the token. */
cp_lexer_consume_token (parser->lexer);
}
/* Look for the opening `('. */
cp_parser_require (parser, CPP_OPEN_PAREN, "`('");
/* Look for the string. */
token = cp_parser_require (parser, CPP_STRING, "asm body");
if (!token)
return;
string = token->value;
/* If we're allowing GNU extensions, check for the extended assembly
syntax. Unfortunately, the `:' tokens need not be separated by
a space in C, and so, for compatibility, we tolerate that here
too. Doing that means that we have to treat the `::' operator as
two `:' tokens. */
if (cp_parser_allow_gnu_extensions_p (parser)
&& at_function_scope_p ()
&& (cp_lexer_next_token_is (parser->lexer, CPP_COLON)
|| cp_lexer_next_token_is (parser->lexer, CPP_SCOPE)))
{
bool inputs_p = false;
bool clobbers_p = false;
/* The extended syntax was used. */
extended_p = true;
/* Look for outputs. */
if (cp_lexer_next_token_is (parser->lexer, CPP_COLON))
{
/* Consume the `:'. */
cp_lexer_consume_token (parser->lexer);
/* Parse the output-operands. */
if (cp_lexer_next_token_is_not (parser->lexer,
CPP_COLON)
&& cp_lexer_next_token_is_not (parser->lexer,
CPP_SCOPE)
&& cp_lexer_next_token_is_not (parser->lexer,
CPP_CLOSE_PAREN))
outputs = cp_parser_asm_operand_list (parser);
}
/* If the next token is `::', there are no outputs, and the
next token is the beginning of the inputs. */
else if (cp_lexer_next_token_is (parser->lexer, CPP_SCOPE))
{
/* Consume the `::' token. */
cp_lexer_consume_token (parser->lexer);
/* The inputs are coming next. */
inputs_p = true;
}
/* Look for inputs. */
if (inputs_p
|| cp_lexer_next_token_is (parser->lexer, CPP_COLON))
{
if (!inputs_p)
/* Consume the `:'. */
cp_lexer_consume_token (parser->lexer);
/* Parse the output-operands. */
if (cp_lexer_next_token_is_not (parser->lexer,
CPP_COLON)
&& cp_lexer_next_token_is_not (parser->lexer,
CPP_SCOPE)
&& cp_lexer_next_token_is_not (parser->lexer,
CPP_CLOSE_PAREN))
inputs = cp_parser_asm_operand_list (parser);
}
else if (cp_lexer_next_token_is (parser->lexer, CPP_SCOPE))
/* The clobbers are coming next. */
clobbers_p = true;
/* Look for clobbers. */
if (clobbers_p
|| cp_lexer_next_token_is (parser->lexer, CPP_COLON))
{
if (!clobbers_p)
/* Consume the `:'. */
cp_lexer_consume_token (parser->lexer);
/* Parse the clobbers. */
if (cp_lexer_next_token_is_not (parser->lexer,
CPP_CLOSE_PAREN))
clobbers = cp_parser_asm_clobber_list (parser);
}
}
/* Look for the closing `)'. */
if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"))
cp_parser_skip_to_closing_parenthesis (parser);
cp_parser_require (parser, CPP_SEMICOLON, "`;'");
/* Create the ASM_STMT. */
if (at_function_scope_p ())
{
asm_stmt =
finish_asm_stmt (volatile_p
? ridpointers[(int) RID_VOLATILE] : NULL_TREE,
string, outputs, inputs, clobbers);
/* If the extended syntax was not used, mark the ASM_STMT. */
if (!extended_p)
ASM_INPUT_P (asm_stmt) = 1;
}
else
assemble_asm (string);
}
/* Declarators [gram.dcl.decl] */
/* Parse an init-declarator.
init-declarator:
declarator initializer [opt]
GNU Extension:
init-declarator:
declarator asm-specification [opt] attributes [opt] initializer [opt]
The DECL_SPECIFIERS and PREFIX_ATTRIBUTES apply to this declarator.
Returns a representation of the entity declared. If MEMBER_P is TRUE,
then this declarator appears in a class scope. The new DECL created
by this declarator is returned.
If FUNCTION_DEFINITION_ALLOWED_P then we handle the declarator and
for a function-definition here as well. If the declarator is a
declarator for a function-definition, *FUNCTION_DEFINITION_P will
be TRUE upon return. By that point, the function-definition will
have been completely parsed.
FUNCTION_DEFINITION_P may be NULL if FUNCTION_DEFINITION_ALLOWED_P
is FALSE. */
static tree
cp_parser_init_declarator (cp_parser* parser,
tree decl_specifiers,
tree prefix_attributes,
bool function_definition_allowed_p,
bool member_p,
bool* function_definition_p)
{
cp_token *token;
tree declarator;
tree attributes;
tree asm_specification;
tree initializer;
tree decl = NULL_TREE;
tree scope;
bool is_initialized;
bool is_parenthesized_init;
bool ctor_dtor_or_conv_p;
bool friend_p;
/* Assume that this is not the declarator for a function
definition. */
if (function_definition_p)
*function_definition_p = false;
/* Defer access checks while parsing the declarator; we cannot know
what names are accessible until we know what is being
declared. */
resume_deferring_access_checks ();
/* Parse the declarator. */
declarator
= cp_parser_declarator (parser, CP_PARSER_DECLARATOR_NAMED,
&ctor_dtor_or_conv_p);
/* Gather up the deferred checks. */
stop_deferring_access_checks ();
/* If the DECLARATOR was erroneous, there's no need to go
further. */
if (declarator == error_mark_node)
return error_mark_node;
/* Figure out what scope the entity declared by the DECLARATOR is
located in. `grokdeclarator' sometimes changes the scope, so
we compute it now. */
scope = get_scope_of_declarator (declarator);
/* If we're allowing GNU extensions, look for an asm-specification
and attributes. */
if (cp_parser_allow_gnu_extensions_p (parser))
{
/* Look for an asm-specification. */
asm_specification = cp_parser_asm_specification_opt (parser);
/* And attributes. */
attributes = cp_parser_attributes_opt (parser);
}
else
{
asm_specification = NULL_TREE;
attributes = NULL_TREE;
}
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* Check to see if the token indicates the start of a
function-definition. */
if (cp_parser_token_starts_function_definition_p (token))
{
if (!function_definition_allowed_p)
{
/* If a function-definition should not appear here, issue an
error message. */
cp_parser_error (parser,
"a function-definition is not allowed here");
return error_mark_node;
}
else
{
/* Neither attributes nor an asm-specification are allowed
on a function-definition. */
if (asm_specification)
error ("an asm-specification is not allowed on a function-definition");
if (attributes)
error ("attributes are not allowed on a function-definition");
/* This is a function-definition. */
*function_definition_p = true;
/* Parse the function definition. */
decl = (cp_parser_function_definition_from_specifiers_and_declarator
(parser, decl_specifiers, prefix_attributes, declarator));
return decl;
}
}
/* [dcl.dcl]
Only in function declarations for constructors, destructors, and
type conversions can the decl-specifier-seq be omitted.
We explicitly postpone this check past the point where we handle
function-definitions because we tolerate function-definitions
that are missing their return types in some modes. */
if (!decl_specifiers && !ctor_dtor_or_conv_p)
{
cp_parser_error (parser,
"expected constructor, destructor, or type conversion");
return error_mark_node;
}
/* An `=' or an `(' indicates an initializer. */
is_initialized = (token->type == CPP_EQ
|| token->type == CPP_OPEN_PAREN);
/* If the init-declarator isn't initialized and isn't followed by a
`,' or `;', it's not a valid init-declarator. */
if (!is_initialized
&& token->type != CPP_COMMA
&& token->type != CPP_SEMICOLON)
{
cp_parser_error (parser, "expected init-declarator");
return error_mark_node;
}
/* Because start_decl has side-effects, we should only call it if we
know we're going ahead. By this point, we know that we cannot
possibly be looking at any other construct. */
cp_parser_commit_to_tentative_parse (parser);
/* Check to see whether or not this declaration is a friend. */
friend_p = cp_parser_friend_p (decl_specifiers);
/* Check that the number of template-parameter-lists is OK. */
if (!cp_parser_check_declarator_template_parameters (parser,
declarator))
return error_mark_node;
/* Enter the newly declared entry in the symbol table. If we're
processing a declaration in a class-specifier, we wait until
after processing the initializer. */
if (!member_p)
{
if (parser->in_unbraced_linkage_specification_p)
{
decl_specifiers = tree_cons (error_mark_node,
get_identifier ("extern"),
decl_specifiers);
have_extern_spec = false;
}
decl = start_decl (declarator,
decl_specifiers,
is_initialized,
attributes,
prefix_attributes);
}
/* Enter the SCOPE. That way unqualified names appearing in the
initializer will be looked up in SCOPE. */
if (scope)
push_scope (scope);
/* Perform deferred access control checks, now that we know in which
SCOPE the declared entity resides. */
if (!member_p && decl)
{
tree saved_current_function_decl = NULL_TREE;
/* If the entity being declared is a function, pretend that we
are in its scope. If it is a `friend', it may have access to
things that would not otherwise be accessible. */
if (TREE_CODE (decl) == FUNCTION_DECL)
{
saved_current_function_decl = current_function_decl;
current_function_decl = decl;
}
/* Perform the access control checks for the declarator and the
the decl-specifiers. */
perform_deferred_access_checks ();
/* Restore the saved value. */
if (TREE_CODE (decl) == FUNCTION_DECL)
current_function_decl = saved_current_function_decl;
}
/* Parse the initializer. */
if (is_initialized)
initializer = cp_parser_initializer (parser, &is_parenthesized_init);
else
{
initializer = NULL_TREE;
is_parenthesized_init = false;
}
/* The old parser allows attributes to appear after a parenthesized
initializer. Mark Mitchell proposed removing this functionality
on the GCC mailing lists on 2002-08-13. This parser accepts the
attributes -- but ignores them. */
if (cp_parser_allow_gnu_extensions_p (parser) && is_parenthesized_init)
if (cp_parser_attributes_opt (parser))
warning ("attributes after parenthesized initializer ignored");
/* Leave the SCOPE, now that we have processed the initializer. It
is important to do this before calling cp_finish_decl because it
makes decisions about whether to create DECL_STMTs or not based
on the current scope. */
if (scope)
pop_scope (scope);
/* For an in-class declaration, use `grokfield' to create the
declaration. */
if (member_p)
decl = grokfield (declarator, decl_specifiers,
initializer, /*asmspec=*/NULL_TREE,
/*attributes=*/NULL_TREE);
/* Finish processing the declaration. But, skip friend
declarations. */
if (!friend_p && decl)
cp_finish_decl (decl,
initializer,
asm_specification,
/* If the initializer is in parentheses, then this is
a direct-initialization, which means that an
`explicit' constructor is OK. Otherwise, an
`explicit' constructor cannot be used. */
((is_parenthesized_init || !is_initialized)
? 0 : LOOKUP_ONLYCONVERTING));
return decl;
}
/* Parse a declarator.
declarator:
direct-declarator
ptr-operator declarator
abstract-declarator:
ptr-operator abstract-declarator [opt]
direct-abstract-declarator
GNU Extensions:
declarator:
attributes [opt] direct-declarator
attributes [opt] ptr-operator declarator
abstract-declarator:
attributes [opt] ptr-operator abstract-declarator [opt]
attributes [opt] direct-abstract-declarator
Returns a representation of the declarator. If the declarator has
the form `* declarator', then an INDIRECT_REF is returned, whose
only operand is the sub-declarator. Analagously, `& declarator' is
represented as an ADDR_EXPR. For `X::* declarator', a SCOPE_REF is
used. The first operand is the TYPE for `X'. The second operand
is an INDIRECT_REF whose operand is the sub-declarator.
Otherwise, the reprsentation is as for a direct-declarator.
(It would be better to define a structure type to represent
declarators, rather than abusing `tree' nodes to represent
declarators. That would be much clearer and save some memory.
There is no reason for declarators to be garbage-collected, for
example; they are created during parser and no longer needed after
`grokdeclarator' has been called.)
For a ptr-operator that has the optional cv-qualifier-seq,
cv-qualifiers will be stored in the TREE_TYPE of the INDIRECT_REF
node.
If CTOR_DTOR_OR_CONV_P is not NULL, *CTOR_DTOR_OR_CONV_P is set to
true if this declarator represents a constructor, destructor, or
type conversion operator. Otherwise, it is set to false.
(The reason for CTOR_DTOR_OR_CONV_P is that a declaration must have
a decl-specifier-seq unless it declares a constructor, destructor,
or conversion. It might seem that we could check this condition in
semantic analysis, rather than parsing, but that makes it difficult
to handle something like `f()'. We want to notice that there are
no decl-specifiers, and therefore realize that this is an
expression, not a declaration.) */
static tree
cp_parser_declarator (cp_parser* parser,
cp_parser_declarator_kind dcl_kind,
bool* ctor_dtor_or_conv_p)
{
cp_token *token;
tree declarator;
enum tree_code code;
tree cv_qualifier_seq;
tree class_type;
tree attributes = NULL_TREE;
/* Assume this is not a constructor, destructor, or type-conversion
operator. */
if (ctor_dtor_or_conv_p)
*ctor_dtor_or_conv_p = false;
if (cp_parser_allow_gnu_extensions_p (parser))
attributes = cp_parser_attributes_opt (parser);
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* Check for the ptr-operator production. */
cp_parser_parse_tentatively (parser);
/* Parse the ptr-operator. */
code = cp_parser_ptr_operator (parser,
&class_type,
&cv_qualifier_seq);
/* If that worked, then we have a ptr-operator. */
if (cp_parser_parse_definitely (parser))
{
/* The dependent declarator is optional if we are parsing an
abstract-declarator. */
if (dcl_kind != CP_PARSER_DECLARATOR_NAMED)
cp_parser_parse_tentatively (parser);
/* Parse the dependent declarator. */
declarator = cp_parser_declarator (parser, dcl_kind,
/*ctor_dtor_or_conv_p=*/NULL);
/* If we are parsing an abstract-declarator, we must handle the
case where the dependent declarator is absent. */
if (dcl_kind != CP_PARSER_DECLARATOR_NAMED
&& !cp_parser_parse_definitely (parser))
declarator = NULL_TREE;
/* Build the representation of the ptr-operator. */
if (code == INDIRECT_REF)
declarator = make_pointer_declarator (cv_qualifier_seq,
declarator);
else
declarator = make_reference_declarator (cv_qualifier_seq,
declarator);
/* Handle the pointer-to-member case. */
if (class_type)
declarator = build_nt (SCOPE_REF, class_type, declarator);
}
/* Everything else is a direct-declarator. */
else
declarator = cp_parser_direct_declarator (parser,
dcl_kind,
ctor_dtor_or_conv_p);
if (attributes && declarator != error_mark_node)
declarator = tree_cons (attributes, declarator, NULL_TREE);
return declarator;
}
/* Parse a direct-declarator or direct-abstract-declarator.
direct-declarator:
declarator-id
direct-declarator ( parameter-declaration-clause )
cv-qualifier-seq [opt]
exception-specification [opt]
direct-declarator [ constant-expression [opt] ]
( declarator )
direct-abstract-declarator:
direct-abstract-declarator [opt]
( parameter-declaration-clause )
cv-qualifier-seq [opt]
exception-specification [opt]
direct-abstract-declarator [opt] [ constant-expression [opt] ]
( abstract-declarator )
Returns a representation of the declarator. DCL_KIND is
CP_PARSER_DECLARATOR_ABSTRACT, if we are parsing a
direct-abstract-declarator. It is CP_PARSER_DECLARATOR_NAMED, if
we are parsing a direct-declarator. It is
CP_PARSER_DECLARATOR_EITHER, if we can accept either - in the case
of ambiguity we prefer an abstract declarator, as per
[dcl.ambig.res]. CTOR_DTOR_OR_CONV_P is as for
cp_parser_declarator.
For the declarator-id production, the representation is as for an
id-expression, except that a qualified name is represented as a
SCOPE_REF. A function-declarator is represented as a CALL_EXPR;
see the documentation of the FUNCTION_DECLARATOR_* macros for
information about how to find the various declarator components.
An array-declarator is represented as an ARRAY_REF. The
direct-declarator is the first operand; the constant-expression
indicating the size of the array is the second operand. */
static tree
cp_parser_direct_declarator (cp_parser* parser,
cp_parser_declarator_kind dcl_kind,
bool* ctor_dtor_or_conv_p)
{
cp_token *token;
tree declarator = NULL_TREE;
tree scope = NULL_TREE;
bool saved_default_arg_ok_p = parser->default_arg_ok_p;
bool saved_in_declarator_p = parser->in_declarator_p;
bool first = true;
while (true)
{
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
if (token->type == CPP_OPEN_PAREN)
{
/* This is either a parameter-declaration-clause, or a
parenthesized declarator. When we know we are parsing a
named declarator, it must be a paranthesized declarator
if FIRST is true. For instance, `(int)' is a
parameter-declaration-clause, with an omitted
direct-abstract-declarator. But `((*))', is a
parenthesized abstract declarator. Finally, when T is a
template parameter `(T)' is a
paremeter-declaration-clause, and not a parenthesized
named declarator.
We first try and parse a parameter-declaration-clause,
and then try a nested declarator (if FIRST is true).
It is not an error for it not to be a
parameter-declaration-clause, even when FIRST is
false. Consider,
int i (int);
int i (3);
The first is the declaration of a function while the
second is a the definition of a variable, including its
initializer.
Having seen only the parenthesis, we cannot know which of
these two alternatives should be selected. Even more
complex are examples like:
int i (int (a));
int i (int (3));
The former is a function-declaration; the latter is a
variable initialization.
Thus again, we try a parameter-declation-clause, and if
that fails, we back out and return. */
if (!first || dcl_kind != CP_PARSER_DECLARATOR_NAMED)
{
tree params;
cp_parser_parse_tentatively (parser);
/* Consume the `('. */
cp_lexer_consume_token (parser->lexer);
if (first)
{
/* If this is going to be an abstract declarator, we're
in a declarator and we can't have default args. */
parser->default_arg_ok_p = false;
parser->in_declarator_p = true;
}
/* Parse the parameter-declaration-clause. */
params = cp_parser_parameter_declaration_clause (parser);
/* If all went well, parse the cv-qualifier-seq and the
exception-specfication. */
if (cp_parser_parse_definitely (parser))
{
tree cv_qualifiers;
tree exception_specification;
first = false;
/* Consume the `)'. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
/* Parse the cv-qualifier-seq. */
cv_qualifiers = cp_parser_cv_qualifier_seq_opt (parser);
/* And the exception-specification. */
exception_specification
= cp_parser_exception_specification_opt (parser);
/* Create the function-declarator. */
declarator = make_call_declarator (declarator,
params,
cv_qualifiers,
exception_specification);
/* Any subsequent parameter lists are to do with
return type, so are not those of the declared
function. */
parser->default_arg_ok_p = false;
/* Repeat the main loop. */
continue;
}
}
/* If this is the first, we can try a parenthesized
declarator. */
if (first)
{
parser->default_arg_ok_p = saved_default_arg_ok_p;
parser->in_declarator_p = saved_in_declarator_p;
/* Consume the `('. */
cp_lexer_consume_token (parser->lexer);
/* Parse the nested declarator. */
declarator
= cp_parser_declarator (parser, dcl_kind, ctor_dtor_or_conv_p);
first = false;
/* Expect a `)'. */
if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"))
declarator = error_mark_node;
if (declarator == error_mark_node)
break;
goto handle_declarator;
}
/* Otherwise, we must be done. */
else
break;
}
else if ((!first || dcl_kind != CP_PARSER_DECLARATOR_NAMED)
&& token->type == CPP_OPEN_SQUARE)
{
/* Parse an array-declarator. */
tree bounds;
first = false;
parser->default_arg_ok_p = false;
parser->in_declarator_p = true;
/* Consume the `['. */
cp_lexer_consume_token (parser->lexer);
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If the next token is `]', then there is no
constant-expression. */
if (token->type != CPP_CLOSE_SQUARE)
{
bool non_constant_p;
bounds
= cp_parser_constant_expression (parser,
/*allow_non_constant=*/true,
&non_constant_p);
/* If we're in a template, but the constant-expression
isn't value dependent, simplify it. We're supposed
to treat:
template <typename T> void f(T[1 + 1]);
template <typename T> void f(T[2]);
as two declarations of the same function, for
example. */
if (processing_template_decl
&& !non_constant_p
&& !value_dependent_expression_p (bounds))
{
HOST_WIDE_INT saved_processing_template_decl;
saved_processing_template_decl = processing_template_decl;
processing_template_decl = 0;
bounds = build_expr_from_tree (bounds);
processing_template_decl = saved_processing_template_decl;
}
}
else
bounds = NULL_TREE;
/* Look for the closing `]'. */
if (!cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'"))
{
declarator = error_mark_node;
break;
}
declarator = build_nt (ARRAY_REF, declarator, bounds);
}
else if (first && dcl_kind != CP_PARSER_DECLARATOR_ABSTRACT)
{
/* Parse a declarator_id */
if (dcl_kind == CP_PARSER_DECLARATOR_EITHER)
cp_parser_parse_tentatively (parser);
declarator = cp_parser_declarator_id (parser);
if (dcl_kind == CP_PARSER_DECLARATOR_EITHER)
{
if (!cp_parser_parse_definitely (parser))
declarator = error_mark_node;
else if (TREE_CODE (declarator) != IDENTIFIER_NODE)
{
cp_parser_error (parser, "expected unqualified-id");
declarator = error_mark_node;
}
}
if (declarator == error_mark_node)
break;
if (TREE_CODE (declarator) == SCOPE_REF)
{
tree scope = TREE_OPERAND (declarator, 0);
/* In the declaration of a member of a template class
outside of the class itself, the SCOPE will sometimes
be a TYPENAME_TYPE. For example, given:
template <typename T>
int S<T>::R::i = 3;
the SCOPE will be a TYPENAME_TYPE for `S<T>::R'. In
this context, we must resolve S<T>::R to an ordinary
type, rather than a typename type.
The reason we normally avoid resolving TYPENAME_TYPEs
is that a specialization of `S' might render
`S<T>::R' not a type. However, if `S' is
specialized, then this `i' will not be used, so there
is no harm in resolving the types here. */
if (TREE_CODE (scope) == TYPENAME_TYPE)
{
tree type;
/* Resolve the TYPENAME_TYPE. */
type = resolve_typename_type (scope,
/*only_current_p=*/false);
/* If that failed, the declarator is invalid. */
if (type != error_mark_node)
scope = type;
/* Build a new DECLARATOR. */
declarator = build_nt (SCOPE_REF,
scope,
TREE_OPERAND (declarator, 1));
}
}
/* Check to see whether the declarator-id names a constructor,
destructor, or conversion. */
if (declarator && ctor_dtor_or_conv_p
&& ((TREE_CODE (declarator) == SCOPE_REF
&& CLASS_TYPE_P (TREE_OPERAND (declarator, 0)))
|| (TREE_CODE (declarator) != SCOPE_REF
&& at_class_scope_p ())))
{
tree unqualified_name;
tree class_type;
/* Get the unqualified part of the name. */
if (TREE_CODE (declarator) == SCOPE_REF)
{
class_type = TREE_OPERAND (declarator, 0);
unqualified_name = TREE_OPERAND (declarator, 1);
}
else
{
class_type = current_class_type;
unqualified_name = declarator;
}
/* See if it names ctor, dtor or conv. */
if (TREE_CODE (unqualified_name) == BIT_NOT_EXPR
|| IDENTIFIER_TYPENAME_P (unqualified_name)
|| constructor_name_p (unqualified_name, class_type))
*ctor_dtor_or_conv_p = true;
}
handle_declarator:;
scope = get_scope_of_declarator (declarator);
if (scope)
/* Any names that appear after the declarator-id for a member
are looked up in the containing scope. */
push_scope (scope);
parser->in_declarator_p = true;
if ((ctor_dtor_or_conv_p && *ctor_dtor_or_conv_p)
|| (declarator
&& (TREE_CODE (declarator) == SCOPE_REF
|| TREE_CODE (declarator) == IDENTIFIER_NODE)))
/* Default args are only allowed on function
declarations. */
parser->default_arg_ok_p = saved_default_arg_ok_p;
else
parser->default_arg_ok_p = false;
first = false;
}
/* We're done. */
else
break;
}
/* For an abstract declarator, we might wind up with nothing at this
point. That's an error; the declarator is not optional. */
if (!declarator)
cp_parser_error (parser, "expected declarator");
/* If we entered a scope, we must exit it now. */
if (scope)
pop_scope (scope);
parser->default_arg_ok_p = saved_default_arg_ok_p;
parser->in_declarator_p = saved_in_declarator_p;
return declarator;
}
/* Parse a ptr-operator.
ptr-operator:
* cv-qualifier-seq [opt]
&
:: [opt] nested-name-specifier * cv-qualifier-seq [opt]
GNU Extension:
ptr-operator:
& cv-qualifier-seq [opt]
Returns INDIRECT_REF if a pointer, or pointer-to-member, was
used. Returns ADDR_EXPR if a reference was used. In the
case of a pointer-to-member, *TYPE is filled in with the
TYPE containing the member. *CV_QUALIFIER_SEQ is filled in
with the cv-qualifier-seq, or NULL_TREE, if there are no
cv-qualifiers. Returns ERROR_MARK if an error occurred. */
static enum tree_code
cp_parser_ptr_operator (cp_parser* parser,
tree* type,
tree* cv_qualifier_seq)
{
enum tree_code code = ERROR_MARK;
cp_token *token;
/* Assume that it's not a pointer-to-member. */
*type = NULL_TREE;
/* And that there are no cv-qualifiers. */
*cv_qualifier_seq = NULL_TREE;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If it's a `*' or `&' we have a pointer or reference. */
if (token->type == CPP_MULT || token->type == CPP_AND)
{
/* Remember which ptr-operator we were processing. */
code = (token->type == CPP_AND ? ADDR_EXPR : INDIRECT_REF);
/* Consume the `*' or `&'. */
cp_lexer_consume_token (parser->lexer);
/* A `*' can be followed by a cv-qualifier-seq, and so can a
`&', if we are allowing GNU extensions. (The only qualifier
that can legally appear after `&' is `restrict', but that is
enforced during semantic analysis. */
if (code == INDIRECT_REF
|| cp_parser_allow_gnu_extensions_p (parser))
*cv_qualifier_seq = cp_parser_cv_qualifier_seq_opt (parser);
}
else
{
/* Try the pointer-to-member case. */
cp_parser_parse_tentatively (parser);
/* Look for the optional `::' operator. */
cp_parser_global_scope_opt (parser,
/*current_scope_valid_p=*/false);
/* Look for the nested-name specifier. */
cp_parser_nested_name_specifier (parser,
/*typename_keyword_p=*/false,
/*check_dependency_p=*/true,
/*type_p=*/false);
/* If we found it, and the next token is a `*', then we are
indeed looking at a pointer-to-member operator. */
if (!cp_parser_error_occurred (parser)
&& cp_parser_require (parser, CPP_MULT, "`*'"))
{
/* The type of which the member is a member is given by the
current SCOPE. */
*type = parser->scope;
/* The next name will not be qualified. */
parser->scope = NULL_TREE;
parser->qualifying_scope = NULL_TREE;
parser->object_scope = NULL_TREE;
/* Indicate that the `*' operator was used. */
code = INDIRECT_REF;
/* Look for the optional cv-qualifier-seq. */
*cv_qualifier_seq = cp_parser_cv_qualifier_seq_opt (parser);
}
/* If that didn't work we don't have a ptr-operator. */
if (!cp_parser_parse_definitely (parser))
cp_parser_error (parser, "expected ptr-operator");
}
return code;
}
/* Parse an (optional) cv-qualifier-seq.
cv-qualifier-seq:
cv-qualifier cv-qualifier-seq [opt]
Returns a TREE_LIST. The TREE_VALUE of each node is the
representation of a cv-qualifier. */
static tree
cp_parser_cv_qualifier_seq_opt (cp_parser* parser)
{
tree cv_qualifiers = NULL_TREE;
while (true)
{
tree cv_qualifier;
/* Look for the next cv-qualifier. */
cv_qualifier = cp_parser_cv_qualifier_opt (parser);
/* If we didn't find one, we're done. */
if (!cv_qualifier)
break;
/* Add this cv-qualifier to the list. */
cv_qualifiers
= tree_cons (NULL_TREE, cv_qualifier, cv_qualifiers);
}
/* We built up the list in reverse order. */
return nreverse (cv_qualifiers);
}
/* Parse an (optional) cv-qualifier.
cv-qualifier:
const
volatile
GNU Extension:
cv-qualifier:
__restrict__ */
static tree
cp_parser_cv_qualifier_opt (cp_parser* parser)
{
cp_token *token;
tree cv_qualifier = NULL_TREE;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* See if it's a cv-qualifier. */
switch (token->keyword)
{
case RID_CONST:
case RID_VOLATILE:
case RID_RESTRICT:
/* Save the value of the token. */
cv_qualifier = token->value;
/* Consume the token. */
cp_lexer_consume_token (parser->lexer);
break;
default:
break;
}
return cv_qualifier;
}
/* Parse a declarator-id.
declarator-id:
id-expression
:: [opt] nested-name-specifier [opt] type-name
In the `id-expression' case, the value returned is as for
cp_parser_id_expression if the id-expression was an unqualified-id.
If the id-expression was a qualified-id, then a SCOPE_REF is
returned. The first operand is the scope (either a NAMESPACE_DECL
or TREE_TYPE), but the second is still just a representation of an
unqualified-id. */
static tree
cp_parser_declarator_id (cp_parser* parser)
{
tree id_expression;
/* The expression must be an id-expression. Assume that qualified
names are the names of types so that:
template <class T>
int S<T>::R::i = 3;
will work; we must treat `S<T>::R' as the name of a type.
Similarly, assume that qualified names are templates, where
required, so that:
template <class T>
int S<T>::R<T>::i = 3;
will work, too. */
id_expression = cp_parser_id_expression (parser,
/*template_keyword_p=*/false,
/*check_dependency_p=*/false,
/*template_p=*/NULL);
/* If the name was qualified, create a SCOPE_REF to represent
that. */
if (parser->scope)
{
id_expression = build_nt (SCOPE_REF, parser->scope, id_expression);
parser->scope = NULL_TREE;
}
return id_expression;
}
/* Parse a type-id.
type-id:
type-specifier-seq abstract-declarator [opt]
Returns the TYPE specified. */
static tree
cp_parser_type_id (cp_parser* parser)
{
tree type_specifier_seq;
tree abstract_declarator;
/* Parse the type-specifier-seq. */
type_specifier_seq
= cp_parser_type_specifier_seq (parser);
if (type_specifier_seq == error_mark_node)
return error_mark_node;
/* There might or might not be an abstract declarator. */
cp_parser_parse_tentatively (parser);
/* Look for the declarator. */
abstract_declarator
= cp_parser_declarator (parser, CP_PARSER_DECLARATOR_ABSTRACT, NULL);
/* Check to see if there really was a declarator. */
if (!cp_parser_parse_definitely (parser))
abstract_declarator = NULL_TREE;
return groktypename (build_tree_list (type_specifier_seq,
abstract_declarator));
}
/* Parse a type-specifier-seq.
type-specifier-seq:
type-specifier type-specifier-seq [opt]
GNU extension:
type-specifier-seq:
attributes type-specifier-seq [opt]
Returns a TREE_LIST. Either the TREE_VALUE of each node is a
type-specifier, or the TREE_PURPOSE is a list of attributes. */
static tree
cp_parser_type_specifier_seq (cp_parser* parser)
{
bool seen_type_specifier = false;
tree type_specifier_seq = NULL_TREE;
/* Parse the type-specifiers and attributes. */
while (true)
{
tree type_specifier;
/* Check for attributes first. */
if (cp_lexer_next_token_is_keyword (parser->lexer, RID_ATTRIBUTE))
{
type_specifier_seq = tree_cons (cp_parser_attributes_opt (parser),
NULL_TREE,
type_specifier_seq);
continue;
}
/* After the first type-specifier, others are optional. */
if (seen_type_specifier)
cp_parser_parse_tentatively (parser);
/* Look for the type-specifier. */
type_specifier = cp_parser_type_specifier (parser,
CP_PARSER_FLAGS_NONE,
/*is_friend=*/false,
/*is_declaration=*/false,
NULL,
NULL);
/* If the first type-specifier could not be found, this is not a
type-specifier-seq at all. */
if (!seen_type_specifier && type_specifier == error_mark_node)
return error_mark_node;
/* If subsequent type-specifiers could not be found, the
type-specifier-seq is complete. */
else if (seen_type_specifier && !cp_parser_parse_definitely (parser))
break;
/* Add the new type-specifier to the list. */
type_specifier_seq
= tree_cons (NULL_TREE, type_specifier, type_specifier_seq);
seen_type_specifier = true;
}
/* We built up the list in reverse order. */
return nreverse (type_specifier_seq);
}
/* Parse a parameter-declaration-clause.
parameter-declaration-clause:
parameter-declaration-list [opt] ... [opt]
parameter-declaration-list , ...
Returns a representation for the parameter declarations. Each node
is a TREE_LIST. (See cp_parser_parameter_declaration for the exact
representation.) If the parameter-declaration-clause ends with an
ellipsis, PARMLIST_ELLIPSIS_P will hold of the first node in the
list. A return value of NULL_TREE indicates a
parameter-declaration-clause consisting only of an ellipsis. */
static tree
cp_parser_parameter_declaration_clause (cp_parser* parser)
{
tree parameters;
cp_token *token;
bool ellipsis_p;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* Check for trivial parameter-declaration-clauses. */
if (token->type == CPP_ELLIPSIS)
{
/* Consume the `...' token. */
cp_lexer_consume_token (parser->lexer);
return NULL_TREE;
}
else if (token->type == CPP_CLOSE_PAREN)
/* There are no parameters. */
{
#ifndef NO_IMPLICIT_EXTERN_C
if (in_system_header && current_class_type == NULL
&& current_lang_name == lang_name_c)
return NULL_TREE;
else
#endif
return void_list_node;
}
/* Check for `(void)', too, which is a special case. */
else if (token->keyword == RID_VOID
&& (cp_lexer_peek_nth_token (parser->lexer, 2)->type
== CPP_CLOSE_PAREN))
{
/* Consume the `void' token. */
cp_lexer_consume_token (parser->lexer);
/* There are no parameters. */
return void_list_node;
}
/* Parse the parameter-declaration-list. */
parameters = cp_parser_parameter_declaration_list (parser);
/* If a parse error occurred while parsing the
parameter-declaration-list, then the entire
parameter-declaration-clause is erroneous. */
if (parameters == error_mark_node)
return error_mark_node;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If it's a `,', the clause should terminate with an ellipsis. */
if (token->type == CPP_COMMA)
{
/* Consume the `,'. */
cp_lexer_consume_token (parser->lexer);
/* Expect an ellipsis. */
ellipsis_p
= (cp_parser_require (parser, CPP_ELLIPSIS, "`...'") != NULL);
}
/* It might also be `...' if the optional trailing `,' was
omitted. */
else if (token->type == CPP_ELLIPSIS)
{
/* Consume the `...' token. */
cp_lexer_consume_token (parser->lexer);
/* And remember that we saw it. */
ellipsis_p = true;
}
else
ellipsis_p = false;
/* Finish the parameter list. */
return finish_parmlist (parameters, ellipsis_p);
}
/* Parse a parameter-declaration-list.
parameter-declaration-list:
parameter-declaration
parameter-declaration-list , parameter-declaration
Returns a representation of the parameter-declaration-list, as for
cp_parser_parameter_declaration_clause. However, the
`void_list_node' is never appended to the list. */
static tree
cp_parser_parameter_declaration_list (cp_parser* parser)
{
tree parameters = NULL_TREE;
/* Look for more parameters. */
while (true)
{
tree parameter;
/* Parse the parameter. */
parameter
= cp_parser_parameter_declaration (parser, /*template_parm_p=*/false);
/* If a parse error ocurred parsing the parameter declaration,
then the entire parameter-declaration-list is erroneous. */
if (parameter == error_mark_node)
{
parameters = error_mark_node;
break;
}
/* Add the new parameter to the list. */
TREE_CHAIN (parameter) = parameters;
parameters = parameter;
/* Peek at the next token. */
if (cp_lexer_next_token_is (parser->lexer, CPP_CLOSE_PAREN)
|| cp_lexer_next_token_is (parser->lexer, CPP_ELLIPSIS))
/* The parameter-declaration-list is complete. */
break;
else if (cp_lexer_next_token_is (parser->lexer, CPP_COMMA))
{
cp_token *token;
/* Peek at the next token. */
token = cp_lexer_peek_nth_token (parser->lexer, 2);
/* If it's an ellipsis, then the list is complete. */
if (token->type == CPP_ELLIPSIS)
break;
/* Otherwise, there must be more parameters. Consume the
`,'. */
cp_lexer_consume_token (parser->lexer);
}
else
{
cp_parser_error (parser, "expected `,' or `...'");
break;
}
}
/* We built up the list in reverse order; straighten it out now. */
return nreverse (parameters);
}
/* Parse a parameter declaration.
parameter-declaration:
decl-specifier-seq declarator
decl-specifier-seq declarator = assignment-expression
decl-specifier-seq abstract-declarator [opt]
decl-specifier-seq abstract-declarator [opt] = assignment-expression
If TEMPLATE_PARM_P is TRUE, then this parameter-declaration
declares a template parameter. (In that case, a non-nested `>'
token encountered during the parsing of the assignment-expression
is not interpreted as a greater-than operator.)
Returns a TREE_LIST representing the parameter-declaration. The
TREE_VALUE is a representation of the decl-specifier-seq and
declarator. In particular, the TREE_VALUE will be a TREE_LIST
whose TREE_PURPOSE represents the decl-specifier-seq and whose
TREE_VALUE represents the declarator. */
static tree
cp_parser_parameter_declaration (cp_parser *parser,
bool template_parm_p)
{
bool declares_class_or_enum;
bool greater_than_is_operator_p;
tree decl_specifiers;
tree attributes;
tree declarator;
tree default_argument;
tree parameter;
cp_token *token;
const char *saved_message;
/* In a template parameter, `>' is not an operator.
[temp.param]
When parsing a default template-argument for a non-type
template-parameter, the first non-nested `>' is taken as the end
of the template parameter-list rather than a greater-than
operator. */
greater_than_is_operator_p = !template_parm_p;
/* Type definitions may not appear in parameter types. */
saved_message = parser->type_definition_forbidden_message;
parser->type_definition_forbidden_message
= "types may not be defined in parameter types";
/* Parse the declaration-specifiers. */
decl_specifiers
= cp_parser_decl_specifier_seq (parser,
CP_PARSER_FLAGS_NONE,
&attributes,
&declares_class_or_enum);
/* If an error occurred, there's no reason to attempt to parse the
rest of the declaration. */
if (cp_parser_error_occurred (parser))
{
parser->type_definition_forbidden_message = saved_message;
return error_mark_node;
}
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If the next token is a `)', `,', `=', `>', or `...', then there
is no declarator. */
if (token->type == CPP_CLOSE_PAREN
|| token->type == CPP_COMMA
|| token->type == CPP_EQ
|| token->type == CPP_ELLIPSIS
|| token->type == CPP_GREATER)
declarator = NULL_TREE;
/* Otherwise, there should be a declarator. */
else
{
bool saved_default_arg_ok_p = parser->default_arg_ok_p;
parser->default_arg_ok_p = false;
declarator = cp_parser_declarator (parser,
CP_PARSER_DECLARATOR_EITHER,
/*ctor_dtor_or_conv_p=*/NULL);
parser->default_arg_ok_p = saved_default_arg_ok_p;
/* After the declarator, allow more attributes. */
attributes = chainon (attributes, cp_parser_attributes_opt (parser));
}
/* The restriction on defining new types applies only to the type
of the parameter, not to the default argument. */
parser->type_definition_forbidden_message = saved_message;
/* If the next token is `=', then process a default argument. */
if (cp_lexer_next_token_is (parser->lexer, CPP_EQ))
{
bool saved_greater_than_is_operator_p;
/* Consume the `='. */
cp_lexer_consume_token (parser->lexer);
/* If we are defining a class, then the tokens that make up the
default argument must be saved and processed later. */
if (!template_parm_p && at_class_scope_p ()
&& TYPE_BEING_DEFINED (current_class_type))
{
unsigned depth = 0;
/* Create a DEFAULT_ARG to represented the unparsed default
argument. */
default_argument = make_node (DEFAULT_ARG);
DEFARG_TOKENS (default_argument) = cp_token_cache_new ();
/* Add tokens until we have processed the entire default
argument. */
while (true)
{
bool done = false;
cp_token *token;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* What we do depends on what token we have. */
switch (token->type)
{
/* In valid code, a default argument must be
immediately followed by a `,' `)', or `...'. */
case CPP_COMMA:
case CPP_CLOSE_PAREN:
case CPP_ELLIPSIS:
/* If we run into a non-nested `;', `}', or `]',
then the code is invalid -- but the default
argument is certainly over. */
case CPP_SEMICOLON:
case CPP_CLOSE_BRACE:
case CPP_CLOSE_SQUARE:
if (depth == 0)
done = true;
/* Update DEPTH, if necessary. */
else if (token->type == CPP_CLOSE_PAREN
|| token->type == CPP_CLOSE_BRACE
|| token->type == CPP_CLOSE_SQUARE)
--depth;
break;
case CPP_OPEN_PAREN:
case CPP_OPEN_SQUARE:
case CPP_OPEN_BRACE:
++depth;
break;
case CPP_GREATER:
/* If we see a non-nested `>', and `>' is not an
operator, then it marks the end of the default
argument. */
if (!depth && !greater_than_is_operator_p)
done = true;
break;
/* If we run out of tokens, issue an error message. */
case CPP_EOF:
error ("file ends in default argument");
done = true;
break;
case CPP_NAME:
case CPP_SCOPE:
/* In these cases, we should look for template-ids.
For example, if the default argument is
`X<int, double>()', we need to do name lookup to
figure out whether or not `X' is a template; if
so, the `,' does not end the deault argument.
That is not yet done. */
break;
default:
break;
}
/* If we've reached the end, stop. */
if (done)
break;
/* Add the token to the token block. */
token = cp_lexer_consume_token (parser->lexer);
cp_token_cache_push_token (DEFARG_TOKENS (default_argument),
token);
}
}
/* Outside of a class definition, we can just parse the
assignment-expression. */
else
{
bool saved_local_variables_forbidden_p;
/* Make sure that PARSER->GREATER_THAN_IS_OPERATOR_P is
set correctly. */
saved_greater_than_is_operator_p
= parser->greater_than_is_operator_p;
parser->greater_than_is_operator_p = greater_than_is_operator_p;
/* Local variable names (and the `this' keyword) may not
appear in a default argument. */
saved_local_variables_forbidden_p
= parser->local_variables_forbidden_p;
parser->local_variables_forbidden_p = true;
/* Parse the assignment-expression. */
default_argument = cp_parser_assignment_expression (parser);
/* Restore saved state. */
parser->greater_than_is_operator_p
= saved_greater_than_is_operator_p;
parser->local_variables_forbidden_p
= saved_local_variables_forbidden_p;
}
if (!parser->default_arg_ok_p)
{
pedwarn ("default arguments are only permitted on functions");
if (flag_pedantic_errors)
default_argument = NULL_TREE;
}
}
else
default_argument = NULL_TREE;
/* Create the representation of the parameter. */
if (attributes)
decl_specifiers = tree_cons (attributes, NULL_TREE, decl_specifiers);
parameter = build_tree_list (default_argument,
build_tree_list (decl_specifiers,
declarator));
return parameter;
}
/* Parse a function-definition.
function-definition:
decl-specifier-seq [opt] declarator ctor-initializer [opt]
function-body
decl-specifier-seq [opt] declarator function-try-block
GNU Extension:
function-definition:
__extension__ function-definition
Returns the FUNCTION_DECL for the function. If FRIEND_P is
non-NULL, *FRIEND_P is set to TRUE iff the function was declared to
be a `friend'. */
static tree
cp_parser_function_definition (cp_parser* parser, bool* friend_p)
{
tree decl_specifiers;
tree attributes;
tree declarator;
tree fn;
cp_token *token;
bool declares_class_or_enum;
bool member_p;
/* The saved value of the PEDANTIC flag. */
int saved_pedantic;
/* Any pending qualification must be cleared by our caller. It is
more robust to force the callers to clear PARSER->SCOPE than to
do it here since if the qualification is in effect here, it might
also end up in effect elsewhere that it is not intended. */
my_friendly_assert (!parser->scope, 20010821);
/* Handle `__extension__'. */
if (cp_parser_extension_opt (parser, &saved_pedantic))
{
/* Parse the function-definition. */
fn = cp_parser_function_definition (parser, friend_p);
/* Restore the PEDANTIC flag. */
pedantic = saved_pedantic;
return fn;
}
/* Check to see if this definition appears in a class-specifier. */
member_p = (at_class_scope_p ()
&& TYPE_BEING_DEFINED (current_class_type));
/* Defer access checks in the decl-specifier-seq until we know what
function is being defined. There is no need to do this for the
definition of member functions; we cannot be defining a member
from another class. */
push_deferring_access_checks (member_p ? dk_no_check: dk_deferred);
/* Parse the decl-specifier-seq. */
decl_specifiers
= cp_parser_decl_specifier_seq (parser,
CP_PARSER_FLAGS_OPTIONAL,
&attributes,
&declares_class_or_enum);
/* Figure out whether this declaration is a `friend'. */
if (friend_p)
*friend_p = cp_parser_friend_p (decl_specifiers);
/* Parse the declarator. */
declarator = cp_parser_declarator (parser, CP_PARSER_DECLARATOR_NAMED,
/*ctor_dtor_or_conv_p=*/NULL);
/* Gather up any access checks that occurred. */
stop_deferring_access_checks ();
/* If something has already gone wrong, we may as well stop now. */
if (declarator == error_mark_node)
{
/* Skip to the end of the function, or if this wasn't anything
like a function-definition, to a `;' in the hopes of finding
a sensible place from which to continue parsing. */
cp_parser_skip_to_end_of_block_or_statement (parser);
pop_deferring_access_checks ();
return error_mark_node;
}
/* The next character should be a `{' (for a simple function
definition), a `:' (for a ctor-initializer), or `try' (for a
function-try block). */
token = cp_lexer_peek_token (parser->lexer);
if (!cp_parser_token_starts_function_definition_p (token))
{
/* Issue the error-message. */
cp_parser_error (parser, "expected function-definition");
/* Skip to the next `;'. */
cp_parser_skip_to_end_of_block_or_statement (parser);
pop_deferring_access_checks ();
return error_mark_node;
}
/* If we are in a class scope, then we must handle
function-definitions specially. In particular, we save away the
tokens that make up the function body, and parse them again
later, in order to handle code like:
struct S {
int f () { return i; }
int i;
};
Here, we cannot parse the body of `f' until after we have seen
the declaration of `i'. */
if (member_p)
{
cp_token_cache *cache;
/* Create the function-declaration. */
fn = start_method (decl_specifiers, declarator, attributes);
/* If something went badly wrong, bail out now. */
if (fn == error_mark_node)
{
/* If there's a function-body, skip it. */
if (cp_parser_token_starts_function_definition_p
(cp_lexer_peek_token (parser->lexer)))
cp_parser_skip_to_end_of_block_or_statement (parser);
pop_deferring_access_checks ();
return error_mark_node;
}
/* Create a token cache. */
cache = cp_token_cache_new ();
/* Save away the tokens that make up the body of the
function. */
cp_parser_cache_group (parser, cache, CPP_CLOSE_BRACE, /*depth=*/0);
/* Handle function try blocks. */
while (cp_lexer_next_token_is_keyword (parser->lexer, RID_CATCH))
cp_parser_cache_group (parser, cache, CPP_CLOSE_BRACE, /*depth=*/0);
/* Save away the inline definition; we will process it when the
class is complete. */
DECL_PENDING_INLINE_INFO (fn) = cache;
DECL_PENDING_INLINE_P (fn) = 1;
/* We need to know that this was defined in the class, so that
friend templates are handled correctly. */
DECL_INITIALIZED_IN_CLASS_P (fn) = 1;
/* We're done with the inline definition. */
finish_method (fn);
/* Add FN to the queue of functions to be parsed later. */
TREE_VALUE (parser->unparsed_functions_queues)
= tree_cons (NULL_TREE, fn,
TREE_VALUE (parser->unparsed_functions_queues));
pop_deferring_access_checks ();
return fn;
}
/* Check that the number of template-parameter-lists is OK. */
if (!cp_parser_check_declarator_template_parameters (parser,
declarator))
{
cp_parser_skip_to_end_of_block_or_statement (parser);
pop_deferring_access_checks ();
return error_mark_node;
}
fn = cp_parser_function_definition_from_specifiers_and_declarator
(parser, decl_specifiers, attributes, declarator);
pop_deferring_access_checks ();
return fn;
}
/* Parse a function-body.
function-body:
compound_statement */
static void
cp_parser_function_body (cp_parser *parser)
{
cp_parser_compound_statement (parser);
}
/* Parse a ctor-initializer-opt followed by a function-body. Return
true if a ctor-initializer was present. */
static bool
cp_parser_ctor_initializer_opt_and_function_body (cp_parser *parser)
{
tree body;
bool ctor_initializer_p;
/* Begin the function body. */
body = begin_function_body ();
/* Parse the optional ctor-initializer. */
ctor_initializer_p = cp_parser_ctor_initializer_opt (parser);
/* Parse the function-body. */
cp_parser_function_body (parser);
/* Finish the function body. */
finish_function_body (body);
return ctor_initializer_p;
}
/* Parse an initializer.
initializer:
= initializer-clause
( expression-list )
Returns a expression representing the initializer. If no
initializer is present, NULL_TREE is returned.
*IS_PARENTHESIZED_INIT is set to TRUE if the `( expression-list )'
production is used, and zero otherwise. *IS_PARENTHESIZED_INIT is
set to FALSE if there is no initializer present. */
static tree
cp_parser_initializer (cp_parser* parser, bool* is_parenthesized_init)
{
cp_token *token;
tree init;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* Let our caller know whether or not this initializer was
parenthesized. */
*is_parenthesized_init = (token->type == CPP_OPEN_PAREN);
if (token->type == CPP_EQ)
{
/* Consume the `='. */
cp_lexer_consume_token (parser->lexer);
/* Parse the initializer-clause. */
init = cp_parser_initializer_clause (parser);
}
else if (token->type == CPP_OPEN_PAREN)
{
/* Consume the `('. */
cp_lexer_consume_token (parser->lexer);
/* Parse the expression-list. */
init = cp_parser_expression_list (parser);
/* Consume the `)' token. */
if (!cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'"))
cp_parser_skip_to_closing_parenthesis (parser);
}
else
{
/* Anything else is an error. */
cp_parser_error (parser, "expected initializer");
init = error_mark_node;
}
return init;
}
/* Parse an initializer-clause.
initializer-clause:
assignment-expression
{ initializer-list , [opt] }
{ }
Returns an expression representing the initializer.
If the `assignment-expression' production is used the value
returned is simply a reprsentation for the expression.
Otherwise, a CONSTRUCTOR is returned. The CONSTRUCTOR_ELTS will be
the elements of the initializer-list (or NULL_TREE, if the last
production is used). The TREE_TYPE for the CONSTRUCTOR will be
NULL_TREE. There is no way to detect whether or not the optional
trailing `,' was provided. */
static tree
cp_parser_initializer_clause (cp_parser* parser)
{
tree initializer;
/* If it is not a `{', then we are looking at an
assignment-expression. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_OPEN_BRACE))
initializer = cp_parser_assignment_expression (parser);
else
{
/* Consume the `{' token. */
cp_lexer_consume_token (parser->lexer);
/* Create a CONSTRUCTOR to represent the braced-initializer. */
initializer = make_node (CONSTRUCTOR);
/* Mark it with TREE_HAS_CONSTRUCTOR. This should not be
necessary, but check_initializer depends upon it, for
now. */
TREE_HAS_CONSTRUCTOR (initializer) = 1;
/* If it's not a `}', then there is a non-trivial initializer. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_BRACE))
{
/* Parse the initializer list. */
CONSTRUCTOR_ELTS (initializer)
= cp_parser_initializer_list (parser);
/* A trailing `,' token is allowed. */
if (cp_lexer_next_token_is (parser->lexer, CPP_COMMA))
cp_lexer_consume_token (parser->lexer);
}
/* Now, there should be a trailing `}'. */
cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'");
}
return initializer;
}
/* Parse an initializer-list.
initializer-list:
initializer-clause
initializer-list , initializer-clause
GNU Extension:
initializer-list:
identifier : initializer-clause
initializer-list, identifier : initializer-clause
Returns a TREE_LIST. The TREE_VALUE of each node is an expression
for the initializer. If the TREE_PURPOSE is non-NULL, it is the
IDENTIFIER_NODE naming the field to initialize. */
static tree
cp_parser_initializer_list (cp_parser* parser)
{
tree initializers = NULL_TREE;
/* Parse the rest of the list. */
while (true)
{
cp_token *token;
tree identifier;
tree initializer;
/* If the next token is an identifier and the following one is a
colon, we are looking at the GNU designated-initializer
syntax. */
if (cp_parser_allow_gnu_extensions_p (parser)
&& cp_lexer_next_token_is (parser->lexer, CPP_NAME)
&& cp_lexer_peek_nth_token (parser->lexer, 2)->type == CPP_COLON)
{
/* Consume the identifier. */
identifier = cp_lexer_consume_token (parser->lexer)->value;
/* Consume the `:'. */
cp_lexer_consume_token (parser->lexer);
}
else
identifier = NULL_TREE;
/* Parse the initializer. */
initializer = cp_parser_initializer_clause (parser);
/* Add it to the list. */
initializers = tree_cons (identifier, initializer, initializers);
/* If the next token is not a comma, we have reached the end of
the list. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA))
break;
/* Peek at the next token. */
token = cp_lexer_peek_nth_token (parser->lexer, 2);
/* If the next token is a `}', then we're still done. An
initializer-clause can have a trailing `,' after the
initializer-list and before the closing `}'. */
if (token->type == CPP_CLOSE_BRACE)
break;
/* Consume the `,' token. */
cp_lexer_consume_token (parser->lexer);
}
/* The initializers were built up in reverse order, so we need to
reverse them now. */
return nreverse (initializers);
}
/* Classes [gram.class] */
/* Parse a class-name.
class-name:
identifier
template-id
TYPENAME_KEYWORD_P is true iff the `typename' keyword has been used
to indicate that names looked up in dependent types should be
assumed to be types. TEMPLATE_KEYWORD_P is true iff the `template'
keyword has been used to indicate that the name that appears next
is a template. TYPE_P is true iff the next name should be treated
as class-name, even if it is declared to be some other kind of name
as well. If CHECK_DEPENDENCY_P is FALSE, names are looked up in
dependent scopes. If CLASS_HEAD_P is TRUE, this class is the class
being defined in a class-head.
Returns the TYPE_DECL representing the class. */
static tree
cp_parser_class_name (cp_parser *parser,
bool typename_keyword_p,
bool template_keyword_p,
bool type_p,
bool check_dependency_p,
bool class_head_p)
{
tree decl;
tree scope;
bool typename_p;
cp_token *token;
/* All class-names start with an identifier. */
token = cp_lexer_peek_token (parser->lexer);
if (token->type != CPP_NAME && token->type != CPP_TEMPLATE_ID)
{
cp_parser_error (parser, "expected class-name");
return error_mark_node;
}
/* PARSER->SCOPE can be cleared when parsing the template-arguments
to a template-id, so we save it here. */
scope = parser->scope;
/* Any name names a type if we're following the `typename' keyword
in a qualified name where the enclosing scope is type-dependent. */
typename_p = (typename_keyword_p && scope && TYPE_P (scope)
&& dependent_type_p (scope));
/* Handle the common case (an identifier, but not a template-id)
efficiently. */
if (token->type == CPP_NAME
&& cp_lexer_peek_nth_token (parser->lexer, 2)->type != CPP_LESS)
{
tree identifier;
/* Look for the identifier. */
identifier = cp_parser_identifier (parser);
/* If the next token isn't an identifier, we are certainly not
looking at a class-name. */
if (identifier == error_mark_node)
decl = error_mark_node;
/* If we know this is a type-name, there's no need to look it
up. */
else if (typename_p)
decl = identifier;
else
{
/* If the next token is a `::', then the name must be a type
name.
[basic.lookup.qual]
During the lookup for a name preceding the :: scope
resolution operator, object, function, and enumerator
names are ignored. */
if (cp_lexer_next_token_is (parser->lexer, CPP_SCOPE))
type_p = true;
/* Look up the name. */
decl = cp_parser_lookup_name (parser, identifier,
type_p,
/*is_namespace=*/false,
check_dependency_p);
}
}
else
{
/* Try a template-id. */
decl = cp_parser_template_id (parser, template_keyword_p,
check_dependency_p);
if (decl == error_mark_node)
return error_mark_node;
}
decl = cp_parser_maybe_treat_template_as_class (decl, class_head_p);
/* If this is a typename, create a TYPENAME_TYPE. */
if (typename_p && decl != error_mark_node)
decl = TYPE_NAME (make_typename_type (scope, decl,
/*complain=*/1));
/* Check to see that it is really the name of a class. */
if (TREE_CODE (decl) == TEMPLATE_ID_EXPR
&& TREE_CODE (TREE_OPERAND (decl, 0)) == IDENTIFIER_NODE
&& cp_lexer_next_token_is (parser->lexer, CPP_SCOPE))
/* Situations like this:
template <typename T> struct A {
typename T::template X<int>::I i;
};
are problematic. Is `T::template X<int>' a class-name? The
standard does not seem to be definitive, but there is no other
valid interpretation of the following `::'. Therefore, those
names are considered class-names. */
decl = TYPE_NAME (make_typename_type (scope, decl, tf_error));
else if (decl == error_mark_node
|| TREE_CODE (decl) != TYPE_DECL
|| !IS_AGGR_TYPE (TREE_TYPE (decl)))
{
cp_parser_error (parser, "expected class-name");
return error_mark_node;
}
return decl;
}
/* Parse a class-specifier.
class-specifier:
class-head { member-specification [opt] }
Returns the TREE_TYPE representing the class. */
static tree
cp_parser_class_specifier (cp_parser* parser)
{
cp_token *token;
tree type;
tree attributes = NULL_TREE;
int has_trailing_semicolon;
bool nested_name_specifier_p;
unsigned saved_num_template_parameter_lists;
push_deferring_access_checks (dk_no_deferred);
/* Parse the class-head. */
type = cp_parser_class_head (parser,
&nested_name_specifier_p);
/* If the class-head was a semantic disaster, skip the entire body
of the class. */
if (!type)
{
cp_parser_skip_to_end_of_block_or_statement (parser);
pop_deferring_access_checks ();
return error_mark_node;
}
/* Look for the `{'. */
if (!cp_parser_require (parser, CPP_OPEN_BRACE, "`{'"))
{
pop_deferring_access_checks ();
return error_mark_node;
}
/* Issue an error message if type-definitions are forbidden here. */
cp_parser_check_type_definition (parser);
/* Remember that we are defining one more class. */
++parser->num_classes_being_defined;
/* Inside the class, surrounding template-parameter-lists do not
apply. */
saved_num_template_parameter_lists
= parser->num_template_parameter_lists;
parser->num_template_parameter_lists = 0;
/* Start the class. */
type = begin_class_definition (type);
if (type == error_mark_node)
/* If the type is erroneous, skip the entire body of the class. */
cp_parser_skip_to_closing_brace (parser);
else
/* Parse the member-specification. */
cp_parser_member_specification_opt (parser);
/* Look for the trailing `}'. */
cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'");
/* We get better error messages by noticing a common problem: a
missing trailing `;'. */
token = cp_lexer_peek_token (parser->lexer);
has_trailing_semicolon = (token->type == CPP_SEMICOLON);
/* Look for attributes to apply to this class. */
if (cp_parser_allow_gnu_extensions_p (parser))
attributes = cp_parser_attributes_opt (parser);
/* Finish the class definition. */
type = finish_class_definition (type,
attributes,
has_trailing_semicolon,
nested_name_specifier_p);
/* If this class is not itself within the scope of another class,
then we need to parse the bodies of all of the queued function
definitions. Note that the queued functions defined in a class
are not always processed immediately following the
class-specifier for that class. Consider:
struct A {
struct B { void f() { sizeof (A); } };
};
If `f' were processed before the processing of `A' were
completed, there would be no way to compute the size of `A'.
Note that the nesting we are interested in here is lexical --
not the semantic nesting given by TYPE_CONTEXT. In particular,
for:
struct A { struct B; };
struct A::B { void f() { } };
there is no need to delay the parsing of `A::B::f'. */
if (--parser->num_classes_being_defined == 0)
{
tree last_scope = NULL_TREE;
tree queue_entry;
tree fn;
/* Reverse the queue, so that we process it in the order the
functions were declared. */
TREE_VALUE (parser->unparsed_functions_queues)
= nreverse (TREE_VALUE (parser->unparsed_functions_queues));
/* In a first pass, parse default arguments to the functions.
Then, in a second pass, parse the bodies of the functions.
This two-phased approach handles cases like:
struct S {
void f() { g(); }
void g(int i = 3);
};
*/
for (queue_entry = TREE_VALUE (parser->unparsed_functions_queues);
queue_entry;
queue_entry = TREE_CHAIN (queue_entry))
{
fn = TREE_VALUE (queue_entry);
if (DECL_FUNCTION_TEMPLATE_P (fn))
fn = DECL_TEMPLATE_RESULT (fn);
/* Make sure that any template parameters are in scope. */
maybe_begin_member_template_processing (fn);
/* If there are default arguments that have not yet been processed,
take care of them now. */
cp_parser_late_parsing_default_args (parser, fn);
/* Remove any template parameters from the symbol table. */
maybe_end_member_template_processing ();
}
/* Now parse the body of the functions. */
while (TREE_VALUE (parser->unparsed_functions_queues))
{
/* Figure out which function we need to process. */
queue_entry = TREE_VALUE (parser->unparsed_functions_queues);
fn = TREE_VALUE (queue_entry);
/* Parse the function. */
cp_parser_late_parsing_for_member (parser, fn);
TREE_VALUE (parser->unparsed_functions_queues)
= TREE_CHAIN (TREE_VALUE (parser->unparsed_functions_queues));
}
/* If LAST_SCOPE is non-NULL, then we have pushed scopes one
more time than we have popped, so me must pop here. */
if (last_scope)
pop_scope (last_scope);
}
/* Put back any saved access checks. */
pop_deferring_access_checks ();
/* Restore the count of active template-parameter-lists. */
parser->num_template_parameter_lists
= saved_num_template_parameter_lists;
return type;
}
/* Parse a class-head.
class-head:
class-key identifier [opt] base-clause [opt]
class-key nested-name-specifier identifier base-clause [opt]
class-key nested-name-specifier [opt] template-id
base-clause [opt]
GNU Extensions:
class-key attributes identifier [opt] base-clause [opt]
class-key attributes nested-name-specifier identifier base-clause [opt]
class-key attributes nested-name-specifier [opt] template-id
base-clause [opt]
Returns the TYPE of the indicated class. Sets
*NESTED_NAME_SPECIFIER_P to TRUE iff one of the productions
involving a nested-name-specifier was used, and FALSE otherwise.
Returns NULL_TREE if the class-head is syntactically valid, but
semantically invalid in a way that means we should skip the entire
body of the class. */
static tree
cp_parser_class_head (cp_parser* parser,
bool* nested_name_specifier_p)
{
cp_token *token;
tree nested_name_specifier;
enum tag_types class_key;
tree id = NULL_TREE;
tree type = NULL_TREE;
tree attributes;
bool template_id_p = false;
bool qualified_p = false;
bool invalid_nested_name_p = false;
unsigned num_templates;
/* Assume no nested-name-specifier will be present. */
*nested_name_specifier_p = false;
/* Assume no template parameter lists will be used in defining the
type. */
num_templates = 0;
/* Look for the class-key. */
class_key = cp_parser_class_key (parser);
if (class_key == none_type)
return error_mark_node;
/* Parse the attributes. */
attributes = cp_parser_attributes_opt (parser);
/* If the next token is `::', that is invalid -- but sometimes
people do try to write:
struct ::S {};
Handle this gracefully by accepting the extra qualifier, and then
issuing an error about it later if this really is a
class-head. If it turns out just to be an elaborated type
specifier, remain silent. */
if (cp_parser_global_scope_opt (parser, /*current_scope_valid_p=*/false))
qualified_p = true;
push_deferring_access_checks (dk_no_check);
/* Determine the name of the class. Begin by looking for an
optional nested-name-specifier. */
nested_name_specifier
= cp_parser_nested_name_specifier_opt (parser,
/*typename_keyword_p=*/false,
/*check_dependency_p=*/true,
/*type_p=*/false);
/* If there was a nested-name-specifier, then there *must* be an
identifier. */
if (nested_name_specifier)
{
/* Although the grammar says `identifier', it really means
`class-name' or `template-name'. You are only allowed to
define a class that has already been declared with this
syntax.
The proposed resolution for Core Issue 180 says that whever
you see `class T::X' you should treat `X' as a type-name.
It is OK to define an inaccessible class; for example:
class A { class B; };
class A::B {};
We do not know if we will see a class-name, or a
template-name. We look for a class-name first, in case the
class-name is a template-id; if we looked for the
template-name first we would stop after the template-name. */
cp_parser_parse_tentatively (parser);
type = cp_parser_class_name (parser,
/*typename_keyword_p=*/false,
/*template_keyword_p=*/false,
/*type_p=*/true,
/*check_dependency_p=*/false,
/*class_head_p=*/true);
/* If that didn't work, ignore the nested-name-specifier. */
if (!cp_parser_parse_definitely (parser))
{
invalid_nested_name_p = true;
id = cp_parser_identifier (parser);
if (id == error_mark_node)
id = NULL_TREE;
}
/* If we could not find a corresponding TYPE, treat this
declaration like an unqualified declaration. */
if (type == error_mark_node)
nested_name_specifier = NULL_TREE;
/* Otherwise, count the number of templates used in TYPE and its
containing scopes. */
else
{
tree scope;
for (scope = TREE_TYPE (type);
scope && TREE_CODE (scope) != NAMESPACE_DECL;
scope = (TYPE_P (scope)
? TYPE_CONTEXT (scope)
: DECL_CONTEXT (scope)))
if (TYPE_P (scope)
&& CLASS_TYPE_P (scope)
&& CLASSTYPE_TEMPLATE_INFO (scope)
&& PRIMARY_TEMPLATE_P (CLASSTYPE_TI_TEMPLATE (scope))
&& !CLASSTYPE_TEMPLATE_SPECIALIZATION (scope))
++num_templates;
}
}
/* Otherwise, the identifier is optional. */
else
{
/* We don't know whether what comes next is a template-id,
an identifier, or nothing at all. */
cp_parser_parse_tentatively (parser);
/* Check for a template-id. */
id = cp_parser_template_id (parser,
/*template_keyword_p=*/false,
/*check_dependency_p=*/true);
/* If that didn't work, it could still be an identifier. */
if (!cp_parser_parse_definitely (parser))
{
if (cp_lexer_next_token_is (parser->lexer, CPP_NAME))
id = cp_parser_identifier (parser);
else
id = NULL_TREE;
}
else
{
template_id_p = true;
++num_templates;
}
}
pop_deferring_access_checks ();
/* If it's not a `:' or a `{' then we can't really be looking at a
class-head, since a class-head only appears as part of a
class-specifier. We have to detect this situation before calling
xref_tag, since that has irreversible side-effects. */
if (!cp_parser_next_token_starts_class_definition_p (parser))
{
cp_parser_error (parser, "expected `{' or `:'");
return error_mark_node;
}
/* At this point, we're going ahead with the class-specifier, even
if some other problem occurs. */
cp_parser_commit_to_tentative_parse (parser);
/* Issue the error about the overly-qualified name now. */
if (qualified_p)
cp_parser_error (parser,
"global qualification of class name is invalid");
else if (invalid_nested_name_p)
cp_parser_error (parser,
"qualified name does not name a class");
/* Make sure that the right number of template parameters were
present. */
if (!cp_parser_check_template_parameters (parser, num_templates))
/* If something went wrong, there is no point in even trying to
process the class-definition. */
return NULL_TREE;
/* Look up the type. */
if (template_id_p)
{
type = TREE_TYPE (id);
maybe_process_partial_specialization (type);
}
else if (!nested_name_specifier)
{
/* If the class was unnamed, create a dummy name. */
if (!id)
id = make_anon_name ();
type = xref_tag (class_key, id, attributes, /*globalize=*/0);
}
else
{
tree class_type;
tree scope;
/* Given:
template <typename T> struct S { struct T };
template <typename T> struct S<T>::T { };
we will get a TYPENAME_TYPE when processing the definition of
`S::T'. We need to resolve it to the actual type before we
try to define it. */
if (TREE_CODE (TREE_TYPE (type)) == TYPENAME_TYPE)
{
class_type = resolve_typename_type (TREE_TYPE (type),
/*only_current_p=*/false);
if (class_type != error_mark_node)
type = TYPE_NAME (class_type);
else
{
cp_parser_error (parser, "could not resolve typename type");
type = error_mark_node;
}
}
/* Figure out in what scope the declaration is being placed. */
scope = current_scope ();
if (!scope)
scope = current_namespace;
/* If that scope does not contain the scope in which the
class was originally declared, the program is invalid. */
if (scope && !is_ancestor (scope, CP_DECL_CONTEXT (type)))
{
error ("declaration of `%D' in `%D' which does not "
"enclose `%D'", type, scope, nested_name_specifier);
return NULL_TREE;
}
maybe_process_partial_specialization (TREE_TYPE (type));
class_type = current_class_type;
type = TREE_TYPE (handle_class_head (class_key,
nested_name_specifier,
type,
attributes));
if (type != error_mark_node)
{
if (!class_type && TYPE_CONTEXT (type))
*nested_name_specifier_p = true;
else if (class_type && !same_type_p (TYPE_CONTEXT (type),
class_type))
*nested_name_specifier_p = true;
}
}
/* Indicate whether this class was declared as a `class' or as a
`struct'. */
if (TREE_CODE (type) == RECORD_TYPE)
CLASSTYPE_DECLARED_CLASS (type) = (class_key == class_type);
cp_parser_check_class_key (class_key, type);
/* Enter the scope containing the class; the names of base classes
should be looked up in that context. For example, given:
struct A { struct B {}; struct C; };
struct A::C : B {};
is valid. */
if (nested_name_specifier)
push_scope (nested_name_specifier);
/* Now, look for the base-clause. */
token = cp_lexer_peek_token (parser->lexer);
if (token->type == CPP_COLON)
{
tree bases;
/* Get the list of base-classes. */
bases = cp_parser_base_clause (parser);
/* Process them. */
xref_basetypes (type, bases);
}
/* Leave the scope given by the nested-name-specifier. We will
enter the class scope itself while processing the members. */
if (nested_name_specifier)
pop_scope (nested_name_specifier);
return type;
}
/* Parse a class-key.
class-key:
class
struct
union
Returns the kind of class-key specified, or none_type to indicate
error. */
static enum tag_types
cp_parser_class_key (cp_parser* parser)
{
cp_token *token;
enum tag_types tag_type;
/* Look for the class-key. */
token = cp_parser_require (parser, CPP_KEYWORD, "class-key");
if (!token)
return none_type;
/* Check to see if the TOKEN is a class-key. */
tag_type = cp_parser_token_is_class_key (token);
if (!tag_type)
cp_parser_error (parser, "expected class-key");
return tag_type;
}
/* Parse an (optional) member-specification.
member-specification:
member-declaration member-specification [opt]
access-specifier : member-specification [opt] */
static void
cp_parser_member_specification_opt (cp_parser* parser)
{
while (true)
{
cp_token *token;
enum rid keyword;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If it's a `}', or EOF then we've seen all the members. */
if (token->type == CPP_CLOSE_BRACE || token->type == CPP_EOF)
break;
/* See if this token is a keyword. */
keyword = token->keyword;
switch (keyword)
{
case RID_PUBLIC:
case RID_PROTECTED:
case RID_PRIVATE:
/* Consume the access-specifier. */
cp_lexer_consume_token (parser->lexer);
/* Remember which access-specifier is active. */
current_access_specifier = token->value;
/* Look for the `:'. */
cp_parser_require (parser, CPP_COLON, "`:'");
break;
default:
/* Otherwise, the next construction must be a
member-declaration. */
cp_parser_member_declaration (parser);
}
}
}
/* Parse a member-declaration.
member-declaration:
decl-specifier-seq [opt] member-declarator-list [opt] ;
function-definition ; [opt]
:: [opt] nested-name-specifier template [opt] unqualified-id ;
using-declaration
template-declaration
member-declarator-list:
member-declarator
member-declarator-list , member-declarator
member-declarator:
declarator pure-specifier [opt]
declarator constant-initializer [opt]
identifier [opt] : constant-expression
GNU Extensions:
member-declaration:
__extension__ member-declaration
member-declarator:
declarator attributes [opt] pure-specifier [opt]
declarator attributes [opt] constant-initializer [opt]
identifier [opt] attributes [opt] : constant-expression */
static void
cp_parser_member_declaration (cp_parser* parser)
{
tree decl_specifiers;
tree prefix_attributes;
tree decl;
bool declares_class_or_enum;
bool friend_p;
cp_token *token;
int saved_pedantic;
/* Check for the `__extension__' keyword. */
if (cp_parser_extension_opt (parser, &saved_pedantic))
{
/* Recurse. */
cp_parser_member_declaration (parser);
/* Restore the old value of the PEDANTIC flag. */
pedantic = saved_pedantic;
return;
}
/* Check for a template-declaration. */
if (cp_lexer_next_token_is_keyword (parser->lexer, RID_TEMPLATE))
{
/* Parse the template-declaration. */
cp_parser_template_declaration (parser, /*member_p=*/true);
return;
}
/* Check for a using-declaration. */
if (cp_lexer_next_token_is_keyword (parser->lexer, RID_USING))
{
/* Parse the using-declaration. */
cp_parser_using_declaration (parser);
return;
}
/* We can't tell whether we're looking at a declaration or a
function-definition. */
cp_parser_parse_tentatively (parser);
/* Parse the decl-specifier-seq. */
decl_specifiers
= cp_parser_decl_specifier_seq (parser,
CP_PARSER_FLAGS_OPTIONAL,
&prefix_attributes,
&declares_class_or_enum);
/* Check for an invalid type-name. */
if (cp_parser_diagnose_invalid_type_name (parser))
return;
/* If there is no declarator, then the decl-specifier-seq should
specify a type. */
if (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON))
{
/* If there was no decl-specifier-seq, and the next token is a
`;', then we have something like:
struct S { ; };
[class.mem]
Each member-declaration shall declare at least one member
name of the class. */
if (!decl_specifiers)
{
if (pedantic)
pedwarn ("extra semicolon");
}
else
{
tree type;
/* See if this declaration is a friend. */
friend_p = cp_parser_friend_p (decl_specifiers);
/* If there were decl-specifiers, check to see if there was
a class-declaration. */
type = check_tag_decl (decl_specifiers);
/* Nested classes have already been added to the class, but
a `friend' needs to be explicitly registered. */
if (friend_p)
{
/* If the `friend' keyword was present, the friend must
be introduced with a class-key. */
if (!declares_class_or_enum)
error ("a class-key must be used when declaring a friend");
/* In this case:
template <typename T> struct A {
friend struct A<T>::B;
};
A<T>::B will be represented by a TYPENAME_TYPE, and
therefore not recognized by check_tag_decl. */
if (!type)
{
tree specifier;
for (specifier = decl_specifiers;
specifier;
specifier = TREE_CHAIN (specifier))
{
tree s = TREE_VALUE (specifier);
if (TREE_CODE (s) == IDENTIFIER_NODE
&& IDENTIFIER_GLOBAL_VALUE (s))
type = IDENTIFIER_GLOBAL_VALUE (s);
if (TREE_CODE (s) == TYPE_DECL)
s = TREE_TYPE (s);
if (TYPE_P (s))
{
type = s;
break;
}
}
}
if (!type)
error ("friend declaration does not name a class or "
"function");
else
make_friend_class (current_class_type, type);
}
/* If there is no TYPE, an error message will already have
been issued. */
else if (!type)
;
/* An anonymous aggregate has to be handled specially; such
a declaration really declares a data member (with a
particular type), as opposed to a nested class. */
else if (ANON_AGGR_TYPE_P (type))
{
/* Remove constructors and such from TYPE, now that we
know it is an anoymous aggregate. */
fixup_anonymous_aggr (type);
/* And make the corresponding data member. */
decl = build_decl (FIELD_DECL, NULL_TREE, type);
/* Add it to the class. */
finish_member_declaration (decl);
}
}
}
else
{
/* See if these declarations will be friends. */
friend_p = cp_parser_friend_p (decl_specifiers);
/* Keep going until we hit the `;' at the end of the
declaration. */
while (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON))
{
tree attributes = NULL_TREE;
tree first_attribute;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* Check for a bitfield declaration. */
if (token->type == CPP_COLON
|| (token->type == CPP_NAME
&& cp_lexer_peek_nth_token (parser->lexer, 2)->type
== CPP_COLON))
{
tree identifier;
tree width;
/* Get the name of the bitfield. Note that we cannot just
check TOKEN here because it may have been invalidated by
the call to cp_lexer_peek_nth_token above. */
if (cp_lexer_peek_token (parser->lexer)->type != CPP_COLON)
identifier = cp_parser_identifier (parser);
else
identifier = NULL_TREE;
/* Consume the `:' token. */
cp_lexer_consume_token (parser->lexer);
/* Get the width of the bitfield. */
width
= cp_parser_constant_expression (parser,
/*allow_non_constant=*/false,
NULL);
/* Look for attributes that apply to the bitfield. */
attributes = cp_parser_attributes_opt (parser);
/* Remember which attributes are prefix attributes and
which are not. */
first_attribute = attributes;
/* Combine the attributes. */
attributes = chainon (prefix_attributes, attributes);
/* Create the bitfield declaration. */
decl = grokbitfield (identifier,
decl_specifiers,
width);
/* Apply the attributes. */
cplus_decl_attributes (&decl, attributes, /*flags=*/0);
}
else
{
tree declarator;
tree initializer;
tree asm_specification;
bool ctor_dtor_or_conv_p;
/* Parse the declarator. */
declarator
= cp_parser_declarator (parser, CP_PARSER_DECLARATOR_NAMED,
&ctor_dtor_or_conv_p);
/* If something went wrong parsing the declarator, make sure
that we at least consume some tokens. */
if (declarator == error_mark_node)
{
/* Skip to the end of the statement. */
cp_parser_skip_to_end_of_statement (parser);
break;
}
/* Look for an asm-specification. */
asm_specification = cp_parser_asm_specification_opt (parser);
/* Look for attributes that apply to the declaration. */
attributes = cp_parser_attributes_opt (parser);
/* Remember which attributes are prefix attributes and
which are not. */
first_attribute = attributes;
/* Combine the attributes. */
attributes = chainon (prefix_attributes, attributes);
/* If it's an `=', then we have a constant-initializer or a
pure-specifier. It is not correct to parse the
initializer before registering the member declaration
since the member declaration should be in scope while
its initializer is processed. However, the rest of the
front end does not yet provide an interface that allows
us to handle this correctly. */
if (cp_lexer_next_token_is (parser->lexer, CPP_EQ))
{
/* In [class.mem]:
A pure-specifier shall be used only in the declaration of
a virtual function.
A member-declarator can contain a constant-initializer
only if it declares a static member of integral or
enumeration type.
Therefore, if the DECLARATOR is for a function, we look
for a pure-specifier; otherwise, we look for a
constant-initializer. When we call `grokfield', it will
perform more stringent semantics checks. */
if (TREE_CODE (declarator) == CALL_EXPR)
initializer = cp_parser_pure_specifier (parser);
else
{
/* This declaration cannot be a function
definition. */
cp_parser_commit_to_tentative_parse (parser);
/* Parse the initializer. */
initializer = cp_parser_constant_initializer (parser);
}
}
/* Otherwise, there is no initializer. */
else
initializer = NULL_TREE;
/* See if we are probably looking at a function
definition. We are certainly not looking at at a
member-declarator. Calling `grokfield' has
side-effects, so we must not do it unless we are sure
that we are looking at a member-declarator. */
if (cp_parser_token_starts_function_definition_p
(cp_lexer_peek_token (parser->lexer)))
decl = error_mark_node;
else
/* Create the declaration. */
decl = grokfield (declarator,
decl_specifiers,
initializer,
asm_specification,
attributes);
}
/* Reset PREFIX_ATTRIBUTES. */
while (attributes && TREE_CHAIN (attributes) != first_attribute)
attributes = TREE_CHAIN (attributes);
if (attributes)
TREE_CHAIN (attributes) = NULL_TREE;
/* If there is any qualification still in effect, clear it
now; we will be starting fresh with the next declarator. */
parser->scope = NULL_TREE;
parser->qualifying_scope = NULL_TREE;
parser->object_scope = NULL_TREE;
/* If it's a `,', then there are more declarators. */
if (cp_lexer_next_token_is (parser->lexer, CPP_COMMA))
cp_lexer_consume_token (parser->lexer);
/* If the next token isn't a `;', then we have a parse error. */
else if (cp_lexer_next_token_is_not (parser->lexer,
CPP_SEMICOLON))
{
cp_parser_error (parser, "expected `;'");
/* Skip tokens until we find a `;' */
cp_parser_skip_to_end_of_statement (parser);
break;
}
if (decl)
{
/* Add DECL to the list of members. */
if (!friend_p)
finish_member_declaration (decl);
/* If DECL is a function, we must return
to parse it later. (Even though there is no definition,
there might be default arguments that need handling.) */
if (TREE_CODE (decl) == FUNCTION_DECL)
TREE_VALUE (parser->unparsed_functions_queues)
= tree_cons (NULL_TREE, decl,
TREE_VALUE (parser->unparsed_functions_queues));
}
}
}
/* If everything went well, look for the `;'. */
if (cp_parser_parse_definitely (parser))
{
cp_parser_require (parser, CPP_SEMICOLON, "`;'");
return;
}
/* Parse the function-definition. */
decl = cp_parser_function_definition (parser, &friend_p);
/* If the member was not a friend, declare it here. */
if (!friend_p)
finish_member_declaration (decl);
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If the next token is a semicolon, consume it. */
if (token->type == CPP_SEMICOLON)
cp_lexer_consume_token (parser->lexer);
}
/* Parse a pure-specifier.
pure-specifier:
= 0
Returns INTEGER_ZERO_NODE if a pure specifier is found.
Otherwiser, ERROR_MARK_NODE is returned. */
static tree
cp_parser_pure_specifier (cp_parser* parser)
{
cp_token *token;
/* Look for the `=' token. */
if (!cp_parser_require (parser, CPP_EQ, "`='"))
return error_mark_node;
/* Look for the `0' token. */
token = cp_parser_require (parser, CPP_NUMBER, "`0'");
/* Unfortunately, this will accept `0L' and `0x00' as well. We need
to get information from the lexer about how the number was
spelled in order to fix this problem. */
if (!token || !integer_zerop (token->value))
return error_mark_node;
return integer_zero_node;
}
/* Parse a constant-initializer.
constant-initializer:
= constant-expression
Returns a representation of the constant-expression. */
static tree
cp_parser_constant_initializer (cp_parser* parser)
{
/* Look for the `=' token. */
if (!cp_parser_require (parser, CPP_EQ, "`='"))
return error_mark_node;
/* It is invalid to write:
struct S { static const int i = { 7 }; };
*/
if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_BRACE))
{
cp_parser_error (parser,
"a brace-enclosed initializer is not allowed here");
/* Consume the opening brace. */
cp_lexer_consume_token (parser->lexer);
/* Skip the initializer. */
cp_parser_skip_to_closing_brace (parser);
/* Look for the trailing `}'. */
cp_parser_require (parser, CPP_CLOSE_BRACE, "`}'");
return error_mark_node;
}
return cp_parser_constant_expression (parser,
/*allow_non_constant=*/false,
NULL);
}
/* Derived classes [gram.class.derived] */
/* Parse a base-clause.
base-clause:
: base-specifier-list
base-specifier-list:
base-specifier
base-specifier-list , base-specifier
Returns a TREE_LIST representing the base-classes, in the order in
which they were declared. The representation of each node is as
described by cp_parser_base_specifier.
In the case that no bases are specified, this function will return
NULL_TREE, not ERROR_MARK_NODE. */
static tree
cp_parser_base_clause (cp_parser* parser)
{
tree bases = NULL_TREE;
/* Look for the `:' that begins the list. */
cp_parser_require (parser, CPP_COLON, "`:'");
/* Scan the base-specifier-list. */
while (true)
{
cp_token *token;
tree base;
/* Look for the base-specifier. */
base = cp_parser_base_specifier (parser);
/* Add BASE to the front of the list. */
if (base != error_mark_node)
{
TREE_CHAIN (base) = bases;
bases = base;
}
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If it's not a comma, then the list is complete. */
if (token->type != CPP_COMMA)
break;
/* Consume the `,'. */
cp_lexer_consume_token (parser->lexer);
}
/* PARSER->SCOPE may still be non-NULL at this point, if the last
base class had a qualified name. However, the next name that
appears is certainly not qualified. */
parser->scope = NULL_TREE;
parser->qualifying_scope = NULL_TREE;
parser->object_scope = NULL_TREE;
return nreverse (bases);
}
/* Parse a base-specifier.
base-specifier:
:: [opt] nested-name-specifier [opt] class-name
virtual access-specifier [opt] :: [opt] nested-name-specifier
[opt] class-name
access-specifier virtual [opt] :: [opt] nested-name-specifier
[opt] class-name
Returns a TREE_LIST. The TREE_PURPOSE will be one of
ACCESS_{DEFAULT,PUBLIC,PROTECTED,PRIVATE}_[VIRTUAL]_NODE to
indicate the specifiers provided. The TREE_VALUE will be a TYPE
(or the ERROR_MARK_NODE) indicating the type that was specified. */
static tree
cp_parser_base_specifier (cp_parser* parser)
{
cp_token *token;
bool done = false;
bool virtual_p = false;
bool duplicate_virtual_error_issued_p = false;
bool duplicate_access_error_issued_p = false;
bool class_scope_p, template_p;
tree access = access_default_node;
tree type;
/* Process the optional `virtual' and `access-specifier'. */
while (!done)
{
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* Process `virtual'. */
switch (token->keyword)
{
case RID_VIRTUAL:
/* If `virtual' appears more than once, issue an error. */
if (virtual_p && !duplicate_virtual_error_issued_p)
{
cp_parser_error (parser,
"`virtual' specified more than once in base-specified");
duplicate_virtual_error_issued_p = true;
}
virtual_p = true;
/* Consume the `virtual' token. */
cp_lexer_consume_token (parser->lexer);
break;
case RID_PUBLIC:
case RID_PROTECTED:
case RID_PRIVATE:
/* If more than one access specifier appears, issue an
error. */
if (access != access_default_node
&& !duplicate_access_error_issued_p)
{
cp_parser_error (parser,
"more than one access specifier in base-specified");
duplicate_access_error_issued_p = true;
}
access = ridpointers[(int) token->keyword];
/* Consume the access-specifier. */
cp_lexer_consume_token (parser->lexer);
break;
default:
done = true;
break;
}
}
/* Look for the optional `::' operator. */
cp_parser_global_scope_opt (parser, /*current_scope_valid_p=*/false);
/* Look for the nested-name-specifier. The simplest way to
implement:
[temp.res]
The keyword `typename' is not permitted in a base-specifier or
mem-initializer; in these contexts a qualified name that
depends on a template-parameter is implicitly assumed to be a
type name.
is to pretend that we have seen the `typename' keyword at this
point. */
cp_parser_nested_name_specifier_opt (parser,
/*typename_keyword_p=*/true,
/*check_dependency_p=*/true,
/*type_p=*/true);
/* If the base class is given by a qualified name, assume that names
we see are type names or templates, as appropriate. */
class_scope_p = (parser->scope && TYPE_P (parser->scope));
template_p = class_scope_p && cp_parser_optional_template_keyword (parser);
/* Finally, look for the class-name. */
type = cp_parser_class_name (parser,
class_scope_p,
template_p,
/*type_p=*/true,
/*check_dependency_p=*/true,
/*class_head_p=*/false);
if (type == error_mark_node)
return error_mark_node;
return finish_base_specifier (TREE_TYPE (type), access, virtual_p);
}
/* Exception handling [gram.exception] */
/* Parse an (optional) exception-specification.
exception-specification:
throw ( type-id-list [opt] )
Returns a TREE_LIST representing the exception-specification. The
TREE_VALUE of each node is a type. */
static tree
cp_parser_exception_specification_opt (cp_parser* parser)
{
cp_token *token;
tree type_id_list;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If it's not `throw', then there's no exception-specification. */
if (!cp_parser_is_keyword (token, RID_THROW))
return NULL_TREE;
/* Consume the `throw'. */
cp_lexer_consume_token (parser->lexer);
/* Look for the `('. */
cp_parser_require (parser, CPP_OPEN_PAREN, "`('");
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If it's not a `)', then there is a type-id-list. */
if (token->type != CPP_CLOSE_PAREN)
{
const char *saved_message;
/* Types may not be defined in an exception-specification. */
saved_message = parser->type_definition_forbidden_message;
parser->type_definition_forbidden_message
= "types may not be defined in an exception-specification";
/* Parse the type-id-list. */
type_id_list = cp_parser_type_id_list (parser);
/* Restore the saved message. */
parser->type_definition_forbidden_message = saved_message;
}
else
type_id_list = empty_except_spec;
/* Look for the `)'. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
return type_id_list;
}
/* Parse an (optional) type-id-list.
type-id-list:
type-id
type-id-list , type-id
Returns a TREE_LIST. The TREE_VALUE of each node is a TYPE,
in the order that the types were presented. */
static tree
cp_parser_type_id_list (cp_parser* parser)
{
tree types = NULL_TREE;
while (true)
{
cp_token *token;
tree type;
/* Get the next type-id. */
type = cp_parser_type_id (parser);
/* Add it to the list. */
types = add_exception_specifier (types, type, /*complain=*/1);
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If it is not a `,', we are done. */
if (token->type != CPP_COMMA)
break;
/* Consume the `,'. */
cp_lexer_consume_token (parser->lexer);
}
return nreverse (types);
}
/* Parse a try-block.
try-block:
try compound-statement handler-seq */
static tree
cp_parser_try_block (cp_parser* parser)
{
tree try_block;
cp_parser_require_keyword (parser, RID_TRY, "`try'");
try_block = begin_try_block ();
cp_parser_compound_statement (parser);
finish_try_block (try_block);
cp_parser_handler_seq (parser);
finish_handler_sequence (try_block);
return try_block;
}
/* Parse a function-try-block.
function-try-block:
try ctor-initializer [opt] function-body handler-seq */
static bool
cp_parser_function_try_block (cp_parser* parser)
{
tree try_block;
bool ctor_initializer_p;
/* Look for the `try' keyword. */
if (!cp_parser_require_keyword (parser, RID_TRY, "`try'"))
return false;
/* Let the rest of the front-end know where we are. */
try_block = begin_function_try_block ();
/* Parse the function-body. */
ctor_initializer_p
= cp_parser_ctor_initializer_opt_and_function_body (parser);
/* We're done with the `try' part. */
finish_function_try_block (try_block);
/* Parse the handlers. */
cp_parser_handler_seq (parser);
/* We're done with the handlers. */
finish_function_handler_sequence (try_block);
return ctor_initializer_p;
}
/* Parse a handler-seq.
handler-seq:
handler handler-seq [opt] */
static void
cp_parser_handler_seq (cp_parser* parser)
{
while (true)
{
cp_token *token;
/* Parse the handler. */
cp_parser_handler (parser);
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If it's not `catch' then there are no more handlers. */
if (!cp_parser_is_keyword (token, RID_CATCH))
break;
}
}
/* Parse a handler.
handler:
catch ( exception-declaration ) compound-statement */
static void
cp_parser_handler (cp_parser* parser)
{
tree handler;
tree declaration;
cp_parser_require_keyword (parser, RID_CATCH, "`catch'");
handler = begin_handler ();
cp_parser_require (parser, CPP_OPEN_PAREN, "`('");
declaration = cp_parser_exception_declaration (parser);
finish_handler_parms (declaration, handler);
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
cp_parser_compound_statement (parser);
finish_handler (handler);
}
/* Parse an exception-declaration.
exception-declaration:
type-specifier-seq declarator
type-specifier-seq abstract-declarator
type-specifier-seq
...
Returns a VAR_DECL for the declaration, or NULL_TREE if the
ellipsis variant is used. */
static tree
cp_parser_exception_declaration (cp_parser* parser)
{
tree type_specifiers;
tree declarator;
const char *saved_message;
/* If it's an ellipsis, it's easy to handle. */
if (cp_lexer_next_token_is (parser->lexer, CPP_ELLIPSIS))
{
/* Consume the `...' token. */
cp_lexer_consume_token (parser->lexer);
return NULL_TREE;
}
/* Types may not be defined in exception-declarations. */
saved_message = parser->type_definition_forbidden_message;
parser->type_definition_forbidden_message
= "types may not be defined in exception-declarations";
/* Parse the type-specifier-seq. */
type_specifiers = cp_parser_type_specifier_seq (parser);
/* If it's a `)', then there is no declarator. */
if (cp_lexer_next_token_is (parser->lexer, CPP_CLOSE_PAREN))
declarator = NULL_TREE;
else
declarator = cp_parser_declarator (parser, CP_PARSER_DECLARATOR_EITHER,
/*ctor_dtor_or_conv_p=*/NULL);
/* Restore the saved message. */
parser->type_definition_forbidden_message = saved_message;
return start_handler_parms (type_specifiers, declarator);
}
/* Parse a throw-expression.
throw-expression:
throw assignment-expresion [opt]
Returns a THROW_EXPR representing the throw-expression. */
static tree
cp_parser_throw_expression (cp_parser* parser)
{
tree expression;
cp_parser_require_keyword (parser, RID_THROW, "`throw'");
/* We can't be sure if there is an assignment-expression or not. */
cp_parser_parse_tentatively (parser);
/* Try it. */
expression = cp_parser_assignment_expression (parser);
/* If it didn't work, this is just a rethrow. */
if (!cp_parser_parse_definitely (parser))
expression = NULL_TREE;
return build_throw (expression);
}
/* GNU Extensions */
/* Parse an (optional) asm-specification.
asm-specification:
asm ( string-literal )
If the asm-specification is present, returns a STRING_CST
corresponding to the string-literal. Otherwise, returns
NULL_TREE. */
static tree
cp_parser_asm_specification_opt (cp_parser* parser)
{
cp_token *token;
tree asm_specification;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If the next token isn't the `asm' keyword, then there's no
asm-specification. */
if (!cp_parser_is_keyword (token, RID_ASM))
return NULL_TREE;
/* Consume the `asm' token. */
cp_lexer_consume_token (parser->lexer);
/* Look for the `('. */
cp_parser_require (parser, CPP_OPEN_PAREN, "`('");
/* Look for the string-literal. */
token = cp_parser_require (parser, CPP_STRING, "string-literal");
if (token)
asm_specification = token->value;
else
asm_specification = NULL_TREE;
/* Look for the `)'. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`('");
return asm_specification;
}
/* Parse an asm-operand-list.
asm-operand-list:
asm-operand
asm-operand-list , asm-operand
asm-operand:
string-literal ( expression )
[ string-literal ] string-literal ( expression )
Returns a TREE_LIST representing the operands. The TREE_VALUE of
each node is the expression. The TREE_PURPOSE is itself a
TREE_LIST whose TREE_PURPOSE is a STRING_CST for the bracketed
string-literal (or NULL_TREE if not present) and whose TREE_VALUE
is a STRING_CST for the string literal before the parenthesis. */
static tree
cp_parser_asm_operand_list (cp_parser* parser)
{
tree asm_operands = NULL_TREE;
while (true)
{
tree string_literal;
tree expression;
tree name;
cp_token *token;
if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_SQUARE))
{
/* Consume the `[' token. */
cp_lexer_consume_token (parser->lexer);
/* Read the operand name. */
name = cp_parser_identifier (parser);
if (name != error_mark_node)
name = build_string (IDENTIFIER_LENGTH (name),
IDENTIFIER_POINTER (name));
/* Look for the closing `]'. */
cp_parser_require (parser, CPP_CLOSE_SQUARE, "`]'");
}
else
name = NULL_TREE;
/* Look for the string-literal. */
token = cp_parser_require (parser, CPP_STRING, "string-literal");
string_literal = token ? token->value : error_mark_node;
/* Look for the `('. */
cp_parser_require (parser, CPP_OPEN_PAREN, "`('");
/* Parse the expression. */
expression = cp_parser_expression (parser);
/* Look for the `)'. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
/* Add this operand to the list. */
asm_operands = tree_cons (build_tree_list (name, string_literal),
expression,
asm_operands);
/* If the next token is not a `,', there are no more
operands. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA))
break;
/* Consume the `,'. */
cp_lexer_consume_token (parser->lexer);
}
return nreverse (asm_operands);
}
/* Parse an asm-clobber-list.
asm-clobber-list:
string-literal
asm-clobber-list , string-literal
Returns a TREE_LIST, indicating the clobbers in the order that they
appeared. The TREE_VALUE of each node is a STRING_CST. */
static tree
cp_parser_asm_clobber_list (cp_parser* parser)
{
tree clobbers = NULL_TREE;
while (true)
{
cp_token *token;
tree string_literal;
/* Look for the string literal. */
token = cp_parser_require (parser, CPP_STRING, "string-literal");
string_literal = token ? token->value : error_mark_node;
/* Add it to the list. */
clobbers = tree_cons (NULL_TREE, string_literal, clobbers);
/* If the next token is not a `,', then the list is
complete. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_COMMA))
break;
/* Consume the `,' token. */
cp_lexer_consume_token (parser->lexer);
}
return clobbers;
}
/* Parse an (optional) series of attributes.
attributes:
attributes attribute
attribute:
__attribute__ (( attribute-list [opt] ))
The return value is as for cp_parser_attribute_list. */
static tree
cp_parser_attributes_opt (cp_parser* parser)
{
tree attributes = NULL_TREE;
while (true)
{
cp_token *token;
tree attribute_list;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If it's not `__attribute__', then we're done. */
if (token->keyword != RID_ATTRIBUTE)
break;
/* Consume the `__attribute__' keyword. */
cp_lexer_consume_token (parser->lexer);
/* Look for the two `(' tokens. */
cp_parser_require (parser, CPP_OPEN_PAREN, "`('");
cp_parser_require (parser, CPP_OPEN_PAREN, "`('");
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
if (token->type != CPP_CLOSE_PAREN)
/* Parse the attribute-list. */
attribute_list = cp_parser_attribute_list (parser);
else
/* If the next token is a `)', then there is no attribute
list. */
attribute_list = NULL;
/* Look for the two `)' tokens. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
/* Add these new attributes to the list. */
attributes = chainon (attributes, attribute_list);
}
return attributes;
}
/* Parse an attribute-list.
attribute-list:
attribute
attribute-list , attribute
attribute:
identifier
identifier ( identifier )
identifier ( identifier , expression-list )
identifier ( expression-list )
Returns a TREE_LIST. Each node corresponds to an attribute. THe
TREE_PURPOSE of each node is the identifier indicating which
attribute is in use. The TREE_VALUE represents the arguments, if
any. */
static tree
cp_parser_attribute_list (cp_parser* parser)
{
tree attribute_list = NULL_TREE;
while (true)
{
cp_token *token;
tree identifier;
tree attribute;
/* Look for the identifier. We also allow keywords here; for
example `__attribute__ ((const))' is legal. */
token = cp_lexer_peek_token (parser->lexer);
if (token->type != CPP_NAME
&& token->type != CPP_KEYWORD)
return error_mark_node;
/* Consume the token. */
token = cp_lexer_consume_token (parser->lexer);
/* Save away the identifier that indicates which attribute this is. */
identifier = token->value;
attribute = build_tree_list (identifier, NULL_TREE);
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If it's an `(', then parse the attribute arguments. */
if (token->type == CPP_OPEN_PAREN)
{
tree arguments;
int arguments_allowed_p = 1;
/* Consume the `('. */
cp_lexer_consume_token (parser->lexer);
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* Check to see if the next token is an identifier. */
if (token->type == CPP_NAME)
{
/* Save the identifier. */
identifier = token->value;
/* Consume the identifier. */
cp_lexer_consume_token (parser->lexer);
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If the next token is a `,', then there are some other
expressions as well. */
if (token->type == CPP_COMMA)
/* Consume the comma. */
cp_lexer_consume_token (parser->lexer);
else
arguments_allowed_p = 0;
}
else
identifier = NULL_TREE;
/* If there are arguments, parse them too. */
if (arguments_allowed_p)
arguments = cp_parser_expression_list (parser);
else
arguments = NULL_TREE;
/* Combine the identifier and the arguments. */
if (identifier)
arguments = tree_cons (NULL_TREE, identifier, arguments);
/* Save the identifier and arguments away. */
TREE_VALUE (attribute) = arguments;
/* Look for the closing `)'. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
}
/* Add this attribute to the list. */
TREE_CHAIN (attribute) = attribute_list;
attribute_list = attribute;
/* Now, look for more attributes. */
token = cp_lexer_peek_token (parser->lexer);
/* If the next token isn't a `,', we're done. */
if (token->type != CPP_COMMA)
break;
/* Consume the commma and keep going. */
cp_lexer_consume_token (parser->lexer);
}
/* We built up the list in reverse order. */
return nreverse (attribute_list);
}
/* Parse an optional `__extension__' keyword. Returns TRUE if it is
present, and FALSE otherwise. *SAVED_PEDANTIC is set to the
current value of the PEDANTIC flag, regardless of whether or not
the `__extension__' keyword is present. The caller is responsible
for restoring the value of the PEDANTIC flag. */
static bool
cp_parser_extension_opt (cp_parser* parser, int* saved_pedantic)
{
/* Save the old value of the PEDANTIC flag. */
*saved_pedantic = pedantic;
if (cp_lexer_next_token_is_keyword (parser->lexer, RID_EXTENSION))
{
/* Consume the `__extension__' token. */
cp_lexer_consume_token (parser->lexer);
/* We're not being pedantic while the `__extension__' keyword is
in effect. */
pedantic = 0;
return true;
}
return false;
}
/* Parse a label declaration.
label-declaration:
__label__ label-declarator-seq ;
label-declarator-seq:
identifier , label-declarator-seq
identifier */
static void
cp_parser_label_declaration (cp_parser* parser)
{
/* Look for the `__label__' keyword. */
cp_parser_require_keyword (parser, RID_LABEL, "`__label__'");
while (true)
{
tree identifier;
/* Look for an identifier. */
identifier = cp_parser_identifier (parser);
/* Declare it as a lobel. */
finish_label_decl (identifier);
/* If the next token is a `;', stop. */
if (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON))
break;
/* Look for the `,' separating the label declarations. */
cp_parser_require (parser, CPP_COMMA, "`,'");
}
/* Look for the final `;'. */
cp_parser_require (parser, CPP_SEMICOLON, "`;'");
}
/* Support Functions */
/* Looks up NAME in the current scope, as given by PARSER->SCOPE.
NAME should have one of the representations used for an
id-expression. If NAME is the ERROR_MARK_NODE, the ERROR_MARK_NODE
is returned. If PARSER->SCOPE is a dependent type, then a
SCOPE_REF is returned.
If NAME is a TEMPLATE_ID_EXPR, then it will be immediately
returned; the name was already resolved when the TEMPLATE_ID_EXPR
was formed. Abstractly, such entities should not be passed to this
function, because they do not need to be looked up, but it is
simpler to check for this special case here, rather than at the
call-sites.
In cases not explicitly covered above, this function returns a
DECL, OVERLOAD, or baselink representing the result of the lookup.
If there was no entity with the indicated NAME, the ERROR_MARK_NODE
is returned.
If IS_TYPE is TRUE, bindings that do not refer to types are
ignored.
If IS_NAMESPACE is TRUE, bindings that do not refer to namespaces
are ignored.
If CHECK_DEPENDENCY is TRUE, names are not looked up in dependent
types. */
static tree
cp_parser_lookup_name (cp_parser *parser, tree name,
bool is_type, bool is_namespace, bool check_dependency)
{
tree decl;
tree object_type = parser->context->object_type;
/* Now that we have looked up the name, the OBJECT_TYPE (if any) is
no longer valid. Note that if we are parsing tentatively, and
the parse fails, OBJECT_TYPE will be automatically restored. */
parser->context->object_type = NULL_TREE;
if (name == error_mark_node)
return error_mark_node;
/* A template-id has already been resolved; there is no lookup to
do. */
if (TREE_CODE (name) == TEMPLATE_ID_EXPR)
return name;
if (BASELINK_P (name))
{
my_friendly_assert ((TREE_CODE (BASELINK_FUNCTIONS (name))
== TEMPLATE_ID_EXPR),
20020909);
return name;
}
/* A BIT_NOT_EXPR is used to represent a destructor. By this point,
it should already have been checked to make sure that the name
used matches the type being destroyed. */
if (TREE_CODE (name) == BIT_NOT_EXPR)
{
tree type;
/* Figure out to which type this destructor applies. */
if (parser->scope)
type = parser->scope;
else if (object_type)
type = object_type;
else
type = current_class_type;
/* If that's not a class type, there is no destructor. */
if (!type || !CLASS_TYPE_P (type))
return error_mark_node;
/* If it was a class type, return the destructor. */
return CLASSTYPE_DESTRUCTORS (type);
}
/* By this point, the NAME should be an ordinary identifier. If
the id-expression was a qualified name, the qualifying scope is
stored in PARSER->SCOPE at this point. */
my_friendly_assert (TREE_CODE (name) == IDENTIFIER_NODE,
20000619);
/* Perform the lookup. */
if (parser->scope)
{
bool dependent_p;
if (parser->scope == error_mark_node)
return error_mark_node;
/* If the SCOPE is dependent, the lookup must be deferred until
the template is instantiated -- unless we are explicitly
looking up names in uninstantiated templates. Even then, we
cannot look up the name if the scope is not a class type; it
might, for example, be a template type parameter. */
dependent_p = (TYPE_P (parser->scope)
&& !(parser->in_declarator_p
&& currently_open_class (parser->scope))
&& dependent_type_p (parser->scope));
if ((check_dependency || !CLASS_TYPE_P (parser->scope))
&& dependent_p)
{
if (!is_type)
decl = build_nt (SCOPE_REF, parser->scope, name);
else
/* The resolution to Core Issue 180 says that `struct A::B'
should be considered a type-name, even if `A' is
dependent. */
decl = TYPE_NAME (make_typename_type (parser->scope,
name,
/*complain=*/1));
}
else
{
/* If PARSER->SCOPE is a dependent type, then it must be a
class type, and we must not be checking dependencies;
otherwise, we would have processed this lookup above. So
that PARSER->SCOPE is not considered a dependent base by
lookup_member, we must enter the scope here. */
if (dependent_p)
push_scope (parser->scope);
/* If the PARSER->SCOPE is a a template specialization, it
may be instantiated during name lookup. In that case,
errors may be issued. Even if we rollback the current
tentative parse, those errors are valid. */
decl = lookup_qualified_name (parser->scope, name, is_type,
/*flags=*/0);
if (dependent_p)
pop_scope (parser->scope);
}
parser->qualifying_scope = parser->scope;
parser->object_scope = NULL_TREE;
}
else if (object_type)
{
tree object_decl = NULL_TREE;
/* Look up the name in the scope of the OBJECT_TYPE, unless the
OBJECT_TYPE is not a class. */
if (CLASS_TYPE_P (object_type))
/* If the OBJECT_TYPE is a template specialization, it may
be instantiated during name lookup. In that case, errors
may be issued. Even if we rollback the current tentative
parse, those errors are valid. */
object_decl = lookup_member (object_type,
name,
/*protect=*/0, is_type);
/* Look it up in the enclosing context, too. */
decl = lookup_name_real (name, is_type, /*nonclass=*/0,
is_namespace,
/*flags=*/0);
parser->object_scope = object_type;
parser->qualifying_scope = NULL_TREE;
if (object_decl)
decl = object_decl;
}
else
{
decl = lookup_name_real (name, is_type, /*nonclass=*/0,
is_namespace,
/*flags=*/0);
parser->qualifying_scope = NULL_TREE;
parser->object_scope = NULL_TREE;
}
/* If the lookup failed, let our caller know. */
if (!decl
|| decl == error_mark_node
|| (TREE_CODE (decl) == FUNCTION_DECL
&& DECL_ANTICIPATED (decl)))
return error_mark_node;
/* If it's a TREE_LIST, the result of the lookup was ambiguous. */
if (TREE_CODE (decl) == TREE_LIST)
{
/* The error message we have to print is too complicated for
cp_parser_error, so we incorporate its actions directly. */
if (!cp_parser_simulate_error (parser))
{
error ("reference to `%D' is ambiguous", name);
print_candidates (decl);
}
return error_mark_node;
}
my_friendly_assert (DECL_P (decl)
|| TREE_CODE (decl) == OVERLOAD
|| TREE_CODE (decl) == SCOPE_REF
|| BASELINK_P (decl),
20000619);
/* If we have resolved the name of a member declaration, check to
see if the declaration is accessible. When the name resolves to
set of overloaded functions, accesibility is checked when
overload resolution is done.
During an explicit instantiation, access is not checked at all,
as per [temp.explicit]. */
if (DECL_P (decl))
{
tree qualifying_type;
/* Figure out the type through which DECL is being
accessed. */
qualifying_type
= cp_parser_scope_through_which_access_occurs (decl,
object_type,
parser->scope);
if (qualifying_type)
perform_or_defer_access_check (qualifying_type, decl);
}
return decl;
}
/* Like cp_parser_lookup_name, but for use in the typical case where
CHECK_ACCESS is TRUE, IS_TYPE is FALSE, and CHECK_DEPENDENCY is
TRUE. */
static tree
cp_parser_lookup_name_simple (cp_parser* parser, tree name)
{
return cp_parser_lookup_name (parser, name,
/*is_type=*/false,
/*is_namespace=*/false,
/*check_dependency=*/true);
}
/* If DECL is a TEMPLATE_DECL that can be treated like a TYPE_DECL in
the current context, return the TYPE_DECL. If TAG_NAME_P is
true, the DECL indicates the class being defined in a class-head,
or declared in an elaborated-type-specifier.
Otherwise, return DECL. */
static tree
cp_parser_maybe_treat_template_as_class (tree decl, bool tag_name_p)
{
/* If the TEMPLATE_DECL is being declared as part of a class-head,
the translation from TEMPLATE_DECL to TYPE_DECL occurs:
struct A {
template <typename T> struct B;
};
template <typename T> struct A::B {};
Similarly, in a elaborated-type-specifier:
namespace N { struct X{}; }
struct A {
template <typename T> friend struct N::X;
};
However, if the DECL refers to a class type, and we are in
the scope of the class, then the name lookup automatically
finds the TYPE_DECL created by build_self_reference rather
than a TEMPLATE_DECL. For example, in:
template <class T> struct S {
S s;
};
there is no need to handle such case. */
if (DECL_CLASS_TEMPLATE_P (decl) && tag_name_p)
return DECL_TEMPLATE_RESULT (decl);
return decl;
}
/* If too many, or too few, template-parameter lists apply to the
declarator, issue an error message. Returns TRUE if all went well,
and FALSE otherwise. */
static bool
cp_parser_check_declarator_template_parameters (cp_parser* parser,
tree declarator)
{
unsigned num_templates;
/* We haven't seen any classes that involve template parameters yet. */
num_templates = 0;
switch (TREE_CODE (declarator))
{
case CALL_EXPR:
case ARRAY_REF:
case INDIRECT_REF:
case ADDR_EXPR:
{
tree main_declarator = TREE_OPERAND (declarator, 0);
return
cp_parser_check_declarator_template_parameters (parser,
main_declarator);
}
case SCOPE_REF:
{
tree scope;
tree member;
scope = TREE_OPERAND (declarator, 0);
member = TREE_OPERAND (declarator, 1);
/* If this is a pointer-to-member, then we are not interested
in the SCOPE, because it does not qualify the thing that is
being declared. */
if (TREE_CODE (member) == INDIRECT_REF)
return (cp_parser_check_declarator_template_parameters
(parser, member));
while (scope && CLASS_TYPE_P (scope))
{
/* You're supposed to have one `template <...>'
for every template class, but you don't need one
for a full specialization. For example:
template <class T> struct S{};
template <> struct S<int> { void f(); };
void S<int>::f () {}
is correct; there shouldn't be a `template <>' for
the definition of `S<int>::f'. */
if (CLASSTYPE_TEMPLATE_INFO (scope)
&& (CLASSTYPE_TEMPLATE_INSTANTIATION (scope)
|| uses_template_parms (CLASSTYPE_TI_ARGS (scope)))
&& PRIMARY_TEMPLATE_P (CLASSTYPE_TI_TEMPLATE (scope)))
++num_templates;
scope = TYPE_CONTEXT (scope);
}
}
/* Fall through. */
default:
/* If the DECLARATOR has the form `X<y>' then it uses one
additional level of template parameters. */
if (TREE_CODE (declarator) == TEMPLATE_ID_EXPR)
++num_templates;
return cp_parser_check_template_parameters (parser,
num_templates);
}
}
/* NUM_TEMPLATES were used in the current declaration. If that is
invalid, return FALSE and issue an error messages. Otherwise,
return TRUE. */
static bool
cp_parser_check_template_parameters (cp_parser* parser,
unsigned num_templates)
{
/* If there are more template classes than parameter lists, we have
something like:
template <class T> void S<T>::R<T>::f (); */
if (parser->num_template_parameter_lists < num_templates)
{
error ("too few template-parameter-lists");
return false;
}
/* If there are the same number of template classes and parameter
lists, that's OK. */
if (parser->num_template_parameter_lists == num_templates)
return true;
/* If there are more, but only one more, then we are referring to a
member template. That's OK too. */
if (parser->num_template_parameter_lists == num_templates + 1)
return true;
/* Otherwise, there are too many template parameter lists. We have
something like:
template <class T> template <class U> void S::f(); */
error ("too many template-parameter-lists");
return false;
}
/* Parse a binary-expression of the general form:
binary-expression:
<expr>
binary-expression <token> <expr>
The TOKEN_TREE_MAP maps <token> types to <expr> codes. FN is used
to parser the <expr>s. If the first production is used, then the
value returned by FN is returned directly. Otherwise, a node with
the indicated EXPR_TYPE is returned, with operands corresponding to
the two sub-expressions. */
static tree
cp_parser_binary_expression (cp_parser* parser,
const cp_parser_token_tree_map token_tree_map,
cp_parser_expression_fn fn)
{
tree lhs;
/* Parse the first expression. */
lhs = (*fn) (parser);
/* Now, look for more expressions. */
while (true)
{
cp_token *token;
const cp_parser_token_tree_map_node *map_node;
tree rhs;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If the token is `>', and that's not an operator at the
moment, then we're done. */
if (token->type == CPP_GREATER
&& !parser->greater_than_is_operator_p)
break;
/* If we find one of the tokens we want, build the correspoding
tree representation. */
for (map_node = token_tree_map;
map_node->token_type != CPP_EOF;
++map_node)
if (map_node->token_type == token->type)
{
/* Consume the operator token. */
cp_lexer_consume_token (parser->lexer);
/* Parse the right-hand side of the expression. */
rhs = (*fn) (parser);
/* Build the binary tree node. */
lhs = build_x_binary_op (map_node->tree_type, lhs, rhs);
break;
}
/* If the token wasn't one of the ones we want, we're done. */
if (map_node->token_type == CPP_EOF)
break;
}
return lhs;
}
/* Parse an optional `::' token indicating that the following name is
from the global namespace. If so, PARSER->SCOPE is set to the
GLOBAL_NAMESPACE. Otherwise, PARSER->SCOPE is set to NULL_TREE,
unless CURRENT_SCOPE_VALID_P is TRUE, in which case it is left alone.
Returns the new value of PARSER->SCOPE, if the `::' token is
present, and NULL_TREE otherwise. */
static tree
cp_parser_global_scope_opt (cp_parser* parser, bool current_scope_valid_p)
{
cp_token *token;
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If we're looking at a `::' token then we're starting from the
global namespace, not our current location. */
if (token->type == CPP_SCOPE)
{
/* Consume the `::' token. */
cp_lexer_consume_token (parser->lexer);
/* Set the SCOPE so that we know where to start the lookup. */
parser->scope = global_namespace;
parser->qualifying_scope = global_namespace;
parser->object_scope = NULL_TREE;
return parser->scope;
}
else if (!current_scope_valid_p)
{
parser->scope = NULL_TREE;
parser->qualifying_scope = NULL_TREE;
parser->object_scope = NULL_TREE;
}
return NULL_TREE;
}
/* Returns TRUE if the upcoming token sequence is the start of a
constructor declarator. If FRIEND_P is true, the declarator is
preceded by the `friend' specifier. */
static bool
cp_parser_constructor_declarator_p (cp_parser *parser, bool friend_p)
{
bool constructor_p;
tree type_decl = NULL_TREE;
bool nested_name_p;
cp_token *next_token;
/* The common case is that this is not a constructor declarator, so
try to avoid doing lots of work if at all possible. It's not
valid declare a constructor at function scope. */
if (at_function_scope_p ())
return false;
/* And only certain tokens can begin a constructor declarator. */
next_token = cp_lexer_peek_token (parser->lexer);
if (next_token->type != CPP_NAME
&& next_token->type != CPP_SCOPE
&& next_token->type != CPP_NESTED_NAME_SPECIFIER
&& next_token->type != CPP_TEMPLATE_ID)
return false;
/* Parse tentatively; we are going to roll back all of the tokens
consumed here. */
cp_parser_parse_tentatively (parser);
/* Assume that we are looking at a constructor declarator. */
constructor_p = true;
/* Look for the optional `::' operator. */
cp_parser_global_scope_opt (parser,
/*current_scope_valid_p=*/false);
/* Look for the nested-name-specifier. */
nested_name_p
= (cp_parser_nested_name_specifier_opt (parser,
/*typename_keyword_p=*/false,
/*check_dependency_p=*/false,
/*type_p=*/false)
!= NULL_TREE);
/* Outside of a class-specifier, there must be a
nested-name-specifier. */
if (!nested_name_p &&
(!at_class_scope_p () || !TYPE_BEING_DEFINED (current_class_type)
|| friend_p))
constructor_p = false;
/* If we still think that this might be a constructor-declarator,
look for a class-name. */
if (constructor_p)
{
/* If we have:
template <typename T> struct S { S(); };
template <typename T> S<T>::S ();
we must recognize that the nested `S' names a class.
Similarly, for:
template <typename T> S<T>::S<T> ();
we must recognize that the nested `S' names a template. */
type_decl = cp_parser_class_name (parser,
/*typename_keyword_p=*/false,
/*template_keyword_p=*/false,
/*type_p=*/false,
/*check_dependency_p=*/false,
/*class_head_p=*/false);
/* If there was no class-name, then this is not a constructor. */
constructor_p = !cp_parser_error_occurred (parser);
}
/* If we're still considering a constructor, we have to see a `(',
to begin the parameter-declaration-clause, followed by either a
`)', an `...', or a decl-specifier. We need to check for a
type-specifier to avoid being fooled into thinking that:
S::S (f) (int);
is a constructor. (It is actually a function named `f' that
takes one parameter (of type `int') and returns a value of type
`S::S'. */
if (constructor_p
&& cp_parser_require (parser, CPP_OPEN_PAREN, "`('"))
{
if (cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_PAREN)
&& cp_lexer_next_token_is_not (parser->lexer, CPP_ELLIPSIS)
&& !cp_parser_storage_class_specifier_opt (parser))
{
tree type;
/* Names appearing in the type-specifier should be looked up
in the scope of the class. */
if (current_class_type)
type = NULL_TREE;
else
{
type = TREE_TYPE (type_decl);
if (TREE_CODE (type) == TYPENAME_TYPE)
{
type = resolve_typename_type (type,
/*only_current_p=*/false);
if (type == error_mark_node)
{
cp_parser_abort_tentative_parse (parser);
return false;
}
}
push_scope (type);
}
/* Look for the type-specifier. */
cp_parser_type_specifier (parser,
CP_PARSER_FLAGS_NONE,
/*is_friend=*/false,
/*is_declarator=*/true,
/*declares_class_or_enum=*/NULL,
/*is_cv_qualifier=*/NULL);
/* Leave the scope of the class. */
if (type)
pop_scope (type);
constructor_p = !cp_parser_error_occurred (parser);
}
}
else
constructor_p = false;
/* We did not really want to consume any tokens. */
cp_parser_abort_tentative_parse (parser);
return constructor_p;
}
/* Parse the definition of the function given by the DECL_SPECIFIERS,
ATTRIBUTES, and DECLARATOR. The access checks have been deferred;
they must be performed once we are in the scope of the function.
Returns the function defined. */
static tree
cp_parser_function_definition_from_specifiers_and_declarator
(cp_parser* parser,
tree decl_specifiers,
tree attributes,
tree declarator)
{
tree fn;
bool success_p;
/* Begin the function-definition. */
success_p = begin_function_definition (decl_specifiers,
attributes,
declarator);
/* If there were names looked up in the decl-specifier-seq that we
did not check, check them now. We must wait until we are in the
scope of the function to perform the checks, since the function
might be a friend. */
perform_deferred_access_checks ();
if (!success_p)
{
/* If begin_function_definition didn't like the definition, skip
the entire function. */
error ("invalid function declaration");
cp_parser_skip_to_end_of_block_or_statement (parser);
fn = error_mark_node;
}
else
fn = cp_parser_function_definition_after_declarator (parser,
/*inline_p=*/false);
return fn;
}
/* Parse the part of a function-definition that follows the
declarator. INLINE_P is TRUE iff this function is an inline
function defined with a class-specifier.
Returns the function defined. */
static tree
cp_parser_function_definition_after_declarator (cp_parser* parser,
bool inline_p)
{
tree fn;
bool ctor_initializer_p = false;
bool saved_in_unbraced_linkage_specification_p;
unsigned saved_num_template_parameter_lists;
/* If the next token is `return', then the code may be trying to
make use of the "named return value" extension that G++ used to
support. */
if (cp_lexer_next_token_is_keyword (parser->lexer, RID_RETURN))
{
/* Consume the `return' keyword. */
cp_lexer_consume_token (parser->lexer);
/* Look for the identifier that indicates what value is to be
returned. */
cp_parser_identifier (parser);
/* Issue an error message. */
error ("named return values are no longer supported");
/* Skip tokens until we reach the start of the function body. */
while (cp_lexer_next_token_is_not (parser->lexer, CPP_OPEN_BRACE))
cp_lexer_consume_token (parser->lexer);
}
/* The `extern' in `extern "C" void f () { ... }' does not apply to
anything declared inside `f'. */
saved_in_unbraced_linkage_specification_p
= parser->in_unbraced_linkage_specification_p;
parser->in_unbraced_linkage_specification_p = false;
/* Inside the function, surrounding template-parameter-lists do not
apply. */
saved_num_template_parameter_lists
= parser->num_template_parameter_lists;
parser->num_template_parameter_lists = 0;
/* If the next token is `try', then we are looking at a
function-try-block. */
if (cp_lexer_next_token_is_keyword (parser->lexer, RID_TRY))
ctor_initializer_p = cp_parser_function_try_block (parser);
/* A function-try-block includes the function-body, so we only do
this next part if we're not processing a function-try-block. */
else
ctor_initializer_p
= cp_parser_ctor_initializer_opt_and_function_body (parser);
/* Finish the function. */
fn = finish_function ((ctor_initializer_p ? 1 : 0) |
(inline_p ? 2 : 0));
/* Generate code for it, if necessary. */
expand_body (fn);
/* Restore the saved values. */
parser->in_unbraced_linkage_specification_p
= saved_in_unbraced_linkage_specification_p;
parser->num_template_parameter_lists
= saved_num_template_parameter_lists;
return fn;
}
/* Parse a template-declaration, assuming that the `export' (and
`extern') keywords, if present, has already been scanned. MEMBER_P
is as for cp_parser_template_declaration. */
static void
cp_parser_template_declaration_after_export (cp_parser* parser, bool member_p)
{
tree decl = NULL_TREE;
tree parameter_list;
bool friend_p = false;
/* Look for the `template' keyword. */
if (!cp_parser_require_keyword (parser, RID_TEMPLATE, "`template'"))
return;
/* And the `<'. */
if (!cp_parser_require (parser, CPP_LESS, "`<'"))
return;
/* Parse the template parameters. */
begin_template_parm_list ();
/* If the next token is `>', then we have an invalid
specialization. Rather than complain about an invalid template
parameter, issue an error message here. */
if (cp_lexer_next_token_is (parser->lexer, CPP_GREATER))
{
cp_parser_error (parser, "invalid explicit specialization");
parameter_list = NULL_TREE;
}
else
parameter_list = cp_parser_template_parameter_list (parser);
parameter_list = end_template_parm_list (parameter_list);
/* Look for the `>'. */
cp_parser_skip_until_found (parser, CPP_GREATER, "`>'");
/* We just processed one more parameter list. */
++parser->num_template_parameter_lists;
/* If the next token is `template', there are more template
parameters. */
if (cp_lexer_next_token_is_keyword (parser->lexer,
RID_TEMPLATE))
cp_parser_template_declaration_after_export (parser, member_p);
else
{
decl = cp_parser_single_declaration (parser,
member_p,
&friend_p);
/* If this is a member template declaration, let the front
end know. */
if (member_p && !friend_p && decl)
decl = finish_member_template_decl (decl);
else if (friend_p && decl && TREE_CODE (decl) == TYPE_DECL)
make_friend_class (current_class_type, TREE_TYPE (decl));
}
/* We are done with the current parameter list. */
--parser->num_template_parameter_lists;
/* Finish up. */
finish_template_decl (parameter_list);
/* Register member declarations. */
if (member_p && !friend_p && decl && !DECL_CLASS_TEMPLATE_P (decl))
finish_member_declaration (decl);
/* If DECL is a function template, we must return to parse it later.
(Even though there is no definition, there might be default
arguments that need handling.) */
if (member_p && decl
&& (TREE_CODE (decl) == FUNCTION_DECL
|| DECL_FUNCTION_TEMPLATE_P (decl)))
TREE_VALUE (parser->unparsed_functions_queues)
= tree_cons (NULL_TREE, decl,
TREE_VALUE (parser->unparsed_functions_queues));
}
/* Parse a `decl-specifier-seq [opt] init-declarator [opt] ;' or
`function-definition' sequence. MEMBER_P is true, this declaration
appears in a class scope.
Returns the DECL for the declared entity. If FRIEND_P is non-NULL,
*FRIEND_P is set to TRUE iff the declaration is a friend. */
static tree
cp_parser_single_declaration (cp_parser* parser,
bool member_p,
bool* friend_p)
{
bool declares_class_or_enum;
tree decl = NULL_TREE;
tree decl_specifiers;
tree attributes;
/* Parse the dependent declaration. We don't know yet
whether it will be a function-definition. */
cp_parser_parse_tentatively (parser);
/* Defer access checks until we know what is being declared. */
push_deferring_access_checks (dk_deferred);
/* Try the `decl-specifier-seq [opt] init-declarator [opt]'
alternative. */
decl_specifiers
= cp_parser_decl_specifier_seq (parser,
CP_PARSER_FLAGS_OPTIONAL,
&attributes,
&declares_class_or_enum);
/* Gather up the access checks that occurred the
decl-specifier-seq. */
stop_deferring_access_checks ();
/* Check for the declaration of a template class. */
if (declares_class_or_enum)
{
if (cp_parser_declares_only_class_p (parser))
{
decl = shadow_tag (decl_specifiers);
if (decl)
decl = TYPE_NAME (decl);
else
decl = error_mark_node;
}
}
else
decl = NULL_TREE;
/* If it's not a template class, try for a template function. If
the next token is a `;', then this declaration does not declare
anything. But, if there were errors in the decl-specifiers, then
the error might well have come from an attempted class-specifier.
In that case, there's no need to warn about a missing declarator. */
if (!decl
&& (cp_lexer_next_token_is_not (parser->lexer, CPP_SEMICOLON)
|| !value_member (error_mark_node, decl_specifiers)))
decl = cp_parser_init_declarator (parser,
decl_specifiers,
attributes,
/*function_definition_allowed_p=*/false,
member_p,
/*function_definition_p=*/NULL);
pop_deferring_access_checks ();
/* Clear any current qualification; whatever comes next is the start
of something new. */
parser->scope = NULL_TREE;
parser->qualifying_scope = NULL_TREE;
parser->object_scope = NULL_TREE;
/* Look for a trailing `;' after the declaration. */
if (!cp_parser_require (parser, CPP_SEMICOLON, "`;'")
&& cp_parser_committed_to_tentative_parse (parser))
cp_parser_skip_to_end_of_block_or_statement (parser);
/* If it worked, set *FRIEND_P based on the DECL_SPECIFIERS. */
if (cp_parser_parse_definitely (parser))
{
if (friend_p)
*friend_p = cp_parser_friend_p (decl_specifiers);
}
/* Otherwise, try a function-definition. */
else
decl = cp_parser_function_definition (parser, friend_p);
return decl;
}
/* Parse a functional cast to TYPE. Returns an expression
representing the cast. */
static tree
cp_parser_functional_cast (cp_parser* parser, tree type)
{
tree expression_list;
/* Look for the opening `('. */
if (!cp_parser_require (parser, CPP_OPEN_PAREN, "`('"))
return error_mark_node;
/* If the next token is not an `)', there are arguments to the
cast. */
if (cp_lexer_next_token_is_not (parser->lexer, CPP_CLOSE_PAREN))
expression_list = cp_parser_expression_list (parser);
else
expression_list = NULL_TREE;
/* Look for the closing `)'. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
return build_functional_cast (type, expression_list);
}
/* MEMBER_FUNCTION is a member function, or a friend. If default
arguments, or the body of the function have not yet been parsed,
parse them now. */
static void
cp_parser_late_parsing_for_member (cp_parser* parser, tree member_function)
{
cp_lexer *saved_lexer;
/* If this member is a template, get the underlying
FUNCTION_DECL. */
if (DECL_FUNCTION_TEMPLATE_P (member_function))
member_function = DECL_TEMPLATE_RESULT (member_function);
/* There should not be any class definitions in progress at this
point; the bodies of members are only parsed outside of all class
definitions. */
my_friendly_assert (parser->num_classes_being_defined == 0, 20010816);
/* While we're parsing the member functions we might encounter more
classes. We want to handle them right away, but we don't want
them getting mixed up with functions that are currently in the
queue. */
parser->unparsed_functions_queues
= tree_cons (NULL_TREE, NULL_TREE, parser->unparsed_functions_queues);
/* Make sure that any template parameters are in scope. */
maybe_begin_member_template_processing (member_function);
/* If the body of the function has not yet been parsed, parse it
now. */
if (DECL_PENDING_INLINE_P (member_function))
{
tree function_scope;
cp_token_cache *tokens;
/* The function is no longer pending; we are processing it. */
tokens = DECL_PENDING_INLINE_INFO (member_function);
DECL_PENDING_INLINE_INFO (member_function) = NULL;
DECL_PENDING_INLINE_P (member_function) = 0;
/* If this was an inline function in a local class, enter the scope
of the containing function. */
function_scope = decl_function_context (member_function);
if (function_scope)
push_function_context_to (function_scope);
/* Save away the current lexer. */
saved_lexer = parser->lexer;
/* Make a new lexer to feed us the tokens saved for this function. */
parser->lexer = cp_lexer_new_from_tokens (tokens);
parser->lexer->next = saved_lexer;
/* Set the current source position to be the location of the first
token in the saved inline body. */
cp_lexer_peek_token (parser->lexer);
/* Let the front end know that we going to be defining this
function. */
start_function (NULL_TREE, member_function, NULL_TREE,
SF_PRE_PARSED | SF_INCLASS_INLINE);
/* Now, parse the body of the function. */
cp_parser_function_definition_after_declarator (parser,
/*inline_p=*/true);
/* Leave the scope of the containing function. */
if (function_scope)
pop_function_context_from (function_scope);
/* Restore the lexer. */
parser->lexer = saved_lexer;
}
/* Remove any template parameters from the symbol table. */
maybe_end_member_template_processing ();
/* Restore the queue. */
parser->unparsed_functions_queues
= TREE_CHAIN (parser->unparsed_functions_queues);
}
/* FN is a FUNCTION_DECL which may contains a parameter with an
unparsed DEFAULT_ARG. Parse the default args now. */
static void
cp_parser_late_parsing_default_args (cp_parser *parser, tree fn)
{
cp_lexer *saved_lexer;
cp_token_cache *tokens;
bool saved_local_variables_forbidden_p;
tree parameters;
for (parameters = TYPE_ARG_TYPES (TREE_TYPE (fn));
parameters;
parameters = TREE_CHAIN (parameters))
{
if (!TREE_PURPOSE (parameters)
|| TREE_CODE (TREE_PURPOSE (parameters)) != DEFAULT_ARG)
continue;
/* Save away the current lexer. */
saved_lexer = parser->lexer;
/* Create a new one, using the tokens we have saved. */
tokens = DEFARG_TOKENS (TREE_PURPOSE (parameters));
parser->lexer = cp_lexer_new_from_tokens (tokens);
/* Set the current source position to be the location of the
first token in the default argument. */
cp_lexer_peek_token (parser->lexer);
/* Local variable names (and the `this' keyword) may not appear
in a default argument. */
saved_local_variables_forbidden_p = parser->local_variables_forbidden_p;
parser->local_variables_forbidden_p = true;
/* Parse the assignment-expression. */
if (DECL_CONTEXT (fn))
push_nested_class (DECL_CONTEXT (fn));
TREE_PURPOSE (parameters) = cp_parser_assignment_expression (parser);
if (DECL_CONTEXT (fn))
pop_nested_class ();
/* Restore saved state. */
parser->lexer = saved_lexer;
parser->local_variables_forbidden_p = saved_local_variables_forbidden_p;
}
}
/* Parse the operand of `sizeof' (or a similar operator). Returns
either a TYPE or an expression, depending on the form of the
input. The KEYWORD indicates which kind of expression we have
encountered. */
static tree
cp_parser_sizeof_operand (cp_parser* parser, enum rid keyword)
{
static const char *format;
tree expr = NULL_TREE;
const char *saved_message;
bool saved_constant_expression_p;
/* Initialize FORMAT the first time we get here. */
if (!format)
format = "types may not be defined in `%s' expressions";
/* Types cannot be defined in a `sizeof' expression. Save away the
old message. */
saved_message = parser->type_definition_forbidden_message;
/* And create the new one. */
parser->type_definition_forbidden_message
= ((const char *)
xmalloc (strlen (format)
+ strlen (IDENTIFIER_POINTER (ridpointers[keyword]))
+ 1 /* `\0' */));
sprintf ((char *) parser->type_definition_forbidden_message,
format, IDENTIFIER_POINTER (ridpointers[keyword]));
/* The restrictions on constant-expressions do not apply inside
sizeof expressions. */
saved_constant_expression_p = parser->constant_expression_p;
parser->constant_expression_p = false;
/* Do not actually evaluate the expression. */
++skip_evaluation;
/* If it's a `(', then we might be looking at the type-id
construction. */
if (cp_lexer_next_token_is (parser->lexer, CPP_OPEN_PAREN))
{
tree type;
/* We can't be sure yet whether we're looking at a type-id or an
expression. */
cp_parser_parse_tentatively (parser);
/* Consume the `('. */
cp_lexer_consume_token (parser->lexer);
/* Parse the type-id. */
type = cp_parser_type_id (parser);
/* Now, look for the trailing `)'. */
cp_parser_require (parser, CPP_CLOSE_PAREN, "`)'");
/* If all went well, then we're done. */
if (cp_parser_parse_definitely (parser))
{
/* Build a list of decl-specifiers; right now, we have only
a single type-specifier. */
type = build_tree_list (NULL_TREE,
type);
/* Call grokdeclarator to figure out what type this is. */
expr = grokdeclarator (NULL_TREE,
type,
TYPENAME,
/*initialized=*/0,
/*attrlist=*/NULL);
}
}
/* If the type-id production did not work out, then we must be
looking at the unary-expression production. */
if (!expr)
expr = cp_parser_unary_expression (parser, /*address_p=*/false);
/* Go back to evaluating expressions. */
--skip_evaluation;
/* Free the message we created. */
free ((char *) parser->type_definition_forbidden_message);
/* And restore the old one. */
parser->type_definition_forbidden_message = saved_message;
parser->constant_expression_p = saved_constant_expression_p;
return expr;
}
/* If the current declaration has no declarator, return true. */
static bool
cp_parser_declares_only_class_p (cp_parser *parser)
{
/* If the next token is a `;' or a `,' then there is no
declarator. */
return (cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON)
|| cp_lexer_next_token_is (parser->lexer, CPP_COMMA));
}
/* DECL_SPECIFIERS is the representation of a decl-specifier-seq.
Returns TRUE iff `friend' appears among the DECL_SPECIFIERS. */
static bool
cp_parser_friend_p (tree decl_specifiers)
{
while (decl_specifiers)
{
/* See if this decl-specifier is `friend'. */
if (TREE_CODE (TREE_VALUE (decl_specifiers)) == IDENTIFIER_NODE
&& C_RID_CODE (TREE_VALUE (decl_specifiers)) == RID_FRIEND)
return true;
/* Go on to the next decl-specifier. */
decl_specifiers = TREE_CHAIN (decl_specifiers);
}
return false;
}
/* If the next token is of the indicated TYPE, consume it. Otherwise,
issue an error message indicating that TOKEN_DESC was expected.
Returns the token consumed, if the token had the appropriate type.
Otherwise, returns NULL. */
static cp_token *
cp_parser_require (cp_parser* parser,
enum cpp_ttype type,
const char* token_desc)
{
if (cp_lexer_next_token_is (parser->lexer, type))
return cp_lexer_consume_token (parser->lexer);
else
{
/* Output the MESSAGE -- unless we're parsing tentatively. */
if (!cp_parser_simulate_error (parser))
error ("expected %s", token_desc);
return NULL;
}
}
/* Like cp_parser_require, except that tokens will be skipped until
the desired token is found. An error message is still produced if
the next token is not as expected. */
static void
cp_parser_skip_until_found (cp_parser* parser,
enum cpp_ttype type,
const char* token_desc)
{
cp_token *token;
unsigned nesting_depth = 0;
if (cp_parser_require (parser, type, token_desc))
return;
/* Skip tokens until the desired token is found. */
while (true)
{
/* Peek at the next token. */
token = cp_lexer_peek_token (parser->lexer);
/* If we've reached the token we want, consume it and
stop. */
if (token->type == type && !nesting_depth)
{
cp_lexer_consume_token (parser->lexer);
return;
}
/* If we've run out of tokens, stop. */
if (token->type == CPP_EOF)
return;
if (token->type == CPP_OPEN_BRACE
|| token->type == CPP_OPEN_PAREN
|| token->type == CPP_OPEN_SQUARE)
++nesting_depth;
else if (token->type == CPP_CLOSE_BRACE
|| token->type == CPP_CLOSE_PAREN
|| token->type == CPP_CLOSE_SQUARE)
{
if (nesting_depth-- == 0)
return;
}
/* Consume this token. */
cp_lexer_consume_token (parser->lexer);
}
}
/* If the next token is the indicated keyword, consume it. Otherwise,
issue an error message indicating that TOKEN_DESC was expected.
Returns the token consumed, if the token had the appropriate type.
Otherwise, returns NULL. */
static cp_token *
cp_parser_require_keyword (cp_parser* parser,
enum rid keyword,
const char* token_desc)
{
cp_token *token = cp_parser_require (parser, CPP_KEYWORD, token_desc);
if (token && token->keyword != keyword)
{
dyn_string_t error_msg;
/* Format the error message. */
error_msg = dyn_string_new (0);
dyn_string_append_cstr (error_msg, "expected ");
dyn_string_append_cstr (error_msg, token_desc);
cp_parser_error (parser, error_msg->s);
dyn_string_delete (error_msg);
return NULL;
}
return token;
}
/* Returns TRUE iff TOKEN is a token that can begin the body of a
function-definition. */
static bool
cp_parser_token_starts_function_definition_p (cp_token* token)
{
return (/* An ordinary function-body begins with an `{'. */
token->type == CPP_OPEN_BRACE
/* A ctor-initializer begins with a `:'. */
|| token->type == CPP_COLON
/* A function-try-block begins with `try'. */
|| token->keyword == RID_TRY
/* The named return value extension begins with `return'. */
|| token->keyword == RID_RETURN);
}
/* Returns TRUE iff the next token is the ":" or "{" beginning a class
definition. */
static bool
cp_parser_next_token_starts_class_definition_p (cp_parser *parser)
{
cp_token *token;
token = cp_lexer_peek_token (parser->lexer);
return (token->type == CPP_OPEN_BRACE || token->type == CPP_COLON);
}
/* Returns the kind of tag indicated by TOKEN, if it is a class-key,
or none_type otherwise. */
static enum tag_types
cp_parser_token_is_class_key (cp_token* token)
{
switch (token->keyword)
{
case RID_CLASS:
return class_type;
case RID_STRUCT:
return record_type;
case RID_UNION:
return union_type;
default:
return none_type;
}
}
/* Issue an error message if the CLASS_KEY does not match the TYPE. */
static void
cp_parser_check_class_key (enum tag_types class_key, tree type)
{
if ((TREE_CODE (type) == UNION_TYPE) != (class_key == union_type))
pedwarn ("`%s' tag used in naming `%#T'",
class_key == union_type ? "union"
: class_key == record_type ? "struct" : "class",
type);
}
/* Look for the `template' keyword, as a syntactic disambiguator.
Return TRUE iff it is present, in which case it will be
consumed. */
static bool
cp_parser_optional_template_keyword (cp_parser *parser)
{
if (cp_lexer_next_token_is_keyword (parser->lexer, RID_TEMPLATE))
{
/* The `template' keyword can only be used within templates;
outside templates the parser can always figure out what is a
template and what is not. */
if (!processing_template_decl)
{
error ("`template' (as a disambiguator) is only allowed "
"within templates");
/* If this part of the token stream is rescanned, the same
error message would be generated. So, we purge the token
from the stream. */
cp_lexer_purge_token (parser->lexer);
return false;
}
else
{
/* Consume the `template' keyword. */
cp_lexer_consume_token (parser->lexer);
return true;
}
}
return false;
}
/* The next token is a CPP_NESTED_NAME_SPECIFIER. Consume the token,
set PARSER->SCOPE, and perform other related actions. */
static void
cp_parser_pre_parsed_nested_name_specifier (cp_parser *parser)
{
tree value;
tree check;
/* Get the stored value. */
value = cp_lexer_consume_token (parser->lexer)->value;
/* Perform any access checks that were deferred. */
for (check = TREE_PURPOSE (value); check; check = TREE_CHAIN (check))
perform_or_defer_access_check (TREE_PURPOSE (check), TREE_VALUE (check));
/* Set the scope from the stored value. */
parser->scope = TREE_VALUE (value);
parser->qualifying_scope = TREE_TYPE (value);
parser->object_scope = NULL_TREE;
}
/* Add tokens to CACHE until an non-nested END token appears. */
static void
cp_parser_cache_group (cp_parser *parser,
cp_token_cache *cache,
enum cpp_ttype end,
unsigned depth)
{
while (true)
{
cp_token *token;
/* Abort a parenthesized expression if we encounter a brace. */
if ((end == CPP_CLOSE_PAREN || depth == 0)
&& cp_lexer_next_token_is (parser->lexer, CPP_SEMICOLON))
return;
/* Consume the next token. */
token = cp_lexer_consume_token (parser->lexer);
/* If we've reached the end of the file, stop. */
if (token->type == CPP_EOF)
return;
/* Add this token to the tokens we are saving. */
cp_token_cache_push_token (cache, token);
/* See if it starts a new group. */
if (token->type == CPP_OPEN_BRACE)
{
cp_parser_cache_group (parser, cache, CPP_CLOSE_BRACE, depth + 1);
if (depth == 0)
return;
}
else if (token->type == CPP_OPEN_PAREN)
cp_parser_cache_group (parser, cache, CPP_CLOSE_PAREN, depth + 1);
else if (token->type == end)
return;
}
}
/* Begin parsing tentatively. We always save tokens while parsing
tentatively so that if the tentative parsing fails we can restore the
tokens. */
static void
cp_parser_parse_tentatively (cp_parser* parser)
{
/* Enter a new parsing context. */
parser->context = cp_parser_context_new (parser->context);
/* Begin saving tokens. */
cp_lexer_save_tokens (parser->lexer);
/* In order to avoid repetitive access control error messages,
access checks are queued up until we are no longer parsing
tentatively. */
push_deferring_access_checks (dk_deferred);
}
/* Commit to the currently active tentative parse. */
static void
cp_parser_commit_to_tentative_parse (cp_parser* parser)
{
cp_parser_context *context;
cp_lexer *lexer;
/* Mark all of the levels as committed. */
lexer = parser->lexer;
for (context = parser->context; context->next; context = context->next)
{
if (context->status == CP_PARSER_STATUS_KIND_COMMITTED)
break;
context->status = CP_PARSER_STATUS_KIND_COMMITTED;
while (!cp_lexer_saving_tokens (lexer))
lexer = lexer->next;
cp_lexer_commit_tokens (lexer);
}
}
/* Abort the currently active tentative parse. All consumed tokens
will be rolled back, and no diagnostics will be issued. */
static void
cp_parser_abort_tentative_parse (cp_parser* parser)
{
cp_parser_simulate_error (parser);
/* Now, pretend that we want to see if the construct was
successfully parsed. */
cp_parser_parse_definitely (parser);
}
/* Stop parsing tentatively. If a parse error has ocurred, restore the
token stream. Otherwise, commit to the tokens we have consumed.
Returns true if no error occurred; false otherwise. */
static bool
cp_parser_parse_definitely (cp_parser* parser)
{
bool error_occurred;
cp_parser_context *context;
/* Remember whether or not an error ocurred, since we are about to
destroy that information. */
error_occurred = cp_parser_error_occurred (parser);
/* Remove the topmost context from the stack. */
context = parser->context;
parser->context = context->next;
/* If no parse errors occurred, commit to the tentative parse. */
if (!error_occurred)
{
/* Commit to the tokens read tentatively, unless that was
already done. */
if (context->status != CP_PARSER_STATUS_KIND_COMMITTED)
cp_lexer_commit_tokens (parser->lexer);
pop_to_parent_deferring_access_checks ();
}
/* Otherwise, if errors occurred, roll back our state so that things
are just as they were before we began the tentative parse. */
else
{
cp_lexer_rollback_tokens (parser->lexer);
pop_deferring_access_checks ();
}
/* Add the context to the front of the free list. */
context->next = cp_parser_context_free_list;
cp_parser_context_free_list = context;
return !error_occurred;
}
/* Returns true if we are parsing tentatively -- but have decided that
we will stick with this tentative parse, even if errors occur. */
static bool
cp_parser_committed_to_tentative_parse (cp_parser* parser)
{
return (cp_parser_parsing_tentatively (parser)
&& parser->context->status == CP_PARSER_STATUS_KIND_COMMITTED);
}
/* Returns non-zero iff an error has occurred during the most recent
tentative parse. */
static bool
cp_parser_error_occurred (cp_parser* parser)
{
return (cp_parser_parsing_tentatively (parser)
&& parser->context->status == CP_PARSER_STATUS_KIND_ERROR);
}
/* Returns non-zero if GNU extensions are allowed. */
static bool
cp_parser_allow_gnu_extensions_p (cp_parser* parser)
{
return parser->allow_gnu_extensions_p;
}
/* The parser. */
static GTY (()) cp_parser *the_parser;
/* External interface. */
/* Parse the entire translation unit. */
int
yyparse (void)
{
bool error_occurred;
the_parser = cp_parser_new ();
push_deferring_access_checks (flag_access_control
? dk_no_deferred : dk_no_check);
error_occurred = cp_parser_translation_unit (the_parser);
the_parser = NULL;
finish_file ();
return error_occurred;
}
/* Clean up after parsing the entire translation unit. */
void
free_parser_stacks (void)
{
/* Nothing to do. */
}
/* This variable must be provided by every front end. */
int yydebug;
#include "gt-cp-parser.h"
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