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parse.y
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1995-11-03
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113KB
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3,907 lines
/* YACC parser for C++ syntax.
Copyright (C) 1988, 1989, 1993, 1994, 1995 Free Software Foundation, Inc.
Hacked by Michael Tiemann (tiemann@cygnus.com)
This file is part of GNU CC.
GNU CC 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.
GNU CC 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 GNU CC; see the file COPYING. If not, write to
the Free Software Foundation, 59 Temple Place - Suite 330,
Boston, MA 02111-1307, USA. */
/* This grammar is based on the GNU CC grammar. */
/* Note: Bison automatically applies a default action of "$$ = $1" for
all derivations; this is applied before the explicit action, if one
is given. Keep this in mind when reading the actions. */
%{
/* Cause the `yydebug' variable to be defined. */
#define YYDEBUG 1
#include "config.h"
#include <stdio.h>
#include <errno.h>
#include "tree.h"
#include "input.h"
#include "flags.h"
#include "lex.h"
#include "cp-tree.h"
#include "output.h"
/* Since parsers are distinct for each language, put the language string
definition here. (fnf) */
char *language_string = "GNU C++";
extern tree void_list_node;
extern struct obstack permanent_obstack;
#ifndef errno
extern int errno;
#endif
extern int end_of_file;
extern int current_class_depth;
/* FSF LOCAL dje prefix attributes */
extern tree strip_attrs PROTO((tree));
/* END FSF LOCAL */
void yyerror ();
/* Like YYERROR but do call yyerror. */
#define YYERROR1 { yyerror ("syntax error"); YYERROR; }
#define OP0(NODE) (TREE_OPERAND (NODE, 0))
#define OP1(NODE) (TREE_OPERAND (NODE, 1))
/* Contains the statement keyword (if/while/do) to include in an
error message if the user supplies an empty conditional expression. */
static char *cond_stmt_keyword;
/* Nonzero if we have an `extern "C"' acting as an extern specifier. */
int have_extern_spec;
int used_extern_spec;
void yyhook ();
/* Cons up an empty parameter list. */
#ifdef __GNUC__
__inline
#endif
static tree
empty_parms ()
{
tree parms;
if (strict_prototype)
parms = void_list_node;
else
parms = NULL_TREE;
return parms;
}
%}
%start program
%union {long itype; tree ttype; char *strtype; enum tree_code code; }
/* All identifiers that are not reserved words
and are not declared typedefs in the current block */
%token IDENTIFIER
/* All identifiers that are declared typedefs in the current block.
In some contexts, they are treated just like IDENTIFIER,
but they can also serve as typespecs in declarations. */
%token TYPENAME
/* Reserved words that specify storage class.
yylval contains an IDENTIFIER_NODE which indicates which one. */
%token SCSPEC
/* Reserved words that specify type.
yylval contains an IDENTIFIER_NODE which indicates which one. */
%token TYPESPEC
/* Reserved words that qualify type: "const" or "volatile".
yylval contains an IDENTIFIER_NODE which indicates which one. */
%token TYPE_QUAL
/* Character or numeric constants.
yylval is the node for the constant. */
%token CONSTANT
/* String constants in raw form.
yylval is a STRING_CST node. */
%token STRING
/* "...", used for functions with variable arglists. */
%token ELLIPSIS
/* the reserved words */
/* SCO include files test "ASM", so use something else. */
%token SIZEOF ENUM /* STRUCT UNION */ IF ELSE WHILE DO FOR SWITCH CASE DEFAULT
%token BREAK CONTINUE RETURN GOTO ASM_KEYWORD GCC_ASM_KEYWORD TYPEOF ALIGNOF
%token SIGOF
%token ATTRIBUTE EXTENSION LABEL
/* the reserved words... C++ extensions */
%token <ttype> AGGR
%token <itype> VISSPEC
%token DELETE NEW OVERLOAD THIS OPERATOR CXX_TRUE CXX_FALSE
%token NAMESPACE TYPENAME_KEYWORD USING
%token LEFT_RIGHT TEMPLATE
%token TYPEID DYNAMIC_CAST STATIC_CAST REINTERPRET_CAST CONST_CAST
%token <itype> SCOPE
/* Define the operator tokens and their precedences.
The value is an integer because, if used, it is the tree code
to use in the expression made from the operator. */
%left EMPTY /* used to resolve s/r with epsilon */
%left error
/* Add precedence rules to solve dangling else s/r conflict */
%nonassoc IF
%nonassoc ELSE
%left IDENTIFIER TYPENAME PTYPENAME SCSPEC TYPESPEC TYPE_QUAL ENUM AGGR ELLIPSIS TYPEOF SIGOF OPERATOR NSNAME TYPENAME_KEYWORD
%left '{' ',' ';'
%nonassoc THROW
%right <code> ':'
%right <code> ASSIGN '='
%right <code> '?'
%left <code> OROR
%left <code> ANDAND
%left <code> '|'
%left <code> '^'
%left <code> '&'
%left <code> MIN_MAX
%left <code> EQCOMPARE
%left <code> ARITHCOMPARE '<' '>'
%left <code> LSHIFT RSHIFT
%left <code> '+' '-'
%left <code> '*' '/' '%'
%left <code> POINTSAT_STAR DOT_STAR
%right <code> UNARY PLUSPLUS MINUSMINUS '~'
%left HYPERUNARY
%left <ttype> PAREN_STAR_PAREN LEFT_RIGHT
%left <code> POINTSAT '.' '(' '['
%right SCOPE /* C++ extension */
%nonassoc NEW DELETE TRY CATCH
%type <code> unop
%type <ttype> identifier IDENTIFIER TYPENAME CONSTANT expr nonnull_exprlist
%type <ttype> paren_expr_or_null nontrivial_exprlist
%type <ttype> expr_no_commas cast_expr unary_expr primary string STRING
%type <ttype> typed_declspecs reserved_declspecs boolean.literal
%type <ttype> typed_typespecs reserved_typespecquals
%type <ttype> declmods typespec typespecqual_reserved
%type <ttype> SCSPEC TYPESPEC TYPE_QUAL nonempty_type_quals maybe_type_qual
%type <itype> initdecls notype_initdecls initdcl /* C++ modification */
%type <ttype> init initlist maybeasm maybe_init
%type <ttype> asm_operands nonnull_asm_operands asm_operand asm_clobbers
%type <ttype> maybe_attribute attributes attribute attribute_list attrib
%type <ttype> any_word
%type <ttype> compstmt implicitly_scoped_stmt
%type <ttype> declarator notype_declarator after_type_declarator
%type <ttype> direct_notype_declarator direct_after_type_declarator
%type <ttype> structsp opt.component_decl_list component_decl_list
%type <ttype> component_decl component_decl_1 components notype_components
%type <ttype> component_declarator component_declarator0
%type <ttype> notype_component_declarator notype_component_declarator0
%type <ttype> after_type_component_declarator after_type_component_declarator0
%type <ttype> enumlist enumerator
%type <ttype> type_id absdcl type_quals
%type <ttype> direct_abstract_declarator conversion_declarator
%type <ttype> new_type_id new_declarator direct_new_declarator
%type <ttype> xexpr parmlist parms parm bad_parm full_parm
%type <ttype> identifiers_or_typenames
%type <ttype> fcast_or_absdcl regcast_or_absdcl
%type <ttype> expr_or_declarator complex_notype_declarator
%type <ttype> notype_unqualified_id unqualified_id qualified_id
%type <ttype> overqualified_id notype_qualified_id any_id
%type <ttype> complex_direct_notype_declarator functional_cast
%type <ttype> named_parm complex_parmlist typed_declspecs1 parms_comma
/* C++ extensions */
%token <ttype> TYPENAME_ELLIPSIS PTYPENAME
%token <ttype> PRE_PARSED_FUNCTION_DECL EXTERN_LANG_STRING ALL
%token <ttype> PRE_PARSED_CLASS_DECL
%type <ttype> fn.def1 /* Not really! */
%type <ttype> fn.def2 return_id
%type <itype> ctor_initializer_opt
%type <ttype> named_class_head named_class_head_sans_basetype
%type <ttype> named_complex_class_head_sans_basetype
%type <ttype> unnamed_class_head
%type <ttype> class_head base_class_list
%type <itype> base_class_access_list
%type <ttype> base_class maybe_base_class_list base_class.1
%type <ttype> exception_specification_opt ansi_raise_identifier ansi_raise_identifiers
%type <ttype> operator_name
%type <ttype> object aggr
%type <itype> new delete
/* %type <ttype> primary_no_id */
%type <ttype> nonmomentary_expr maybe_parmlist
%type <itype> initdcl0 notype_initdcl0 member_init_list
%type <ttype> template_header template_parm_list template_parm
%type <ttype> template_type_parm
%type <ttype> template_type template_arg_list template_arg
%type <ttype> template_instantiation template_type_name tmpl.2
%type <ttype> template_instantiate_once template_instantiate_some
%type <itype> fn_tmpl_end
/* %type <itype> try_for_typename */
%type <ttype> condition xcond paren_cond_or_null
%type <ttype> type_name nested_name_specifier nested_type ptr_to_mem
%type <ttype> qualified_type_name complete_type_name notype_identifier
%type <ttype> complex_type_name nested_name_specifier_1
%type <itype> nomods_initdecls nomods_initdcl0
%type <ttype> new_initializer new_placement specialization type_specifier_seq
%type <ttype> using_decl .poplevel
/* in order to recognize aggr tags as defining and thus shadowing. */
%token TYPENAME_DEFN IDENTIFIER_DEFN PTYPENAME_DEFN
%type <ttype> named_class_head_sans_basetype_defn
%type <ttype> identifier_defn IDENTIFIER_DEFN TYPENAME_DEFN PTYPENAME_DEFN
%token NSNAME
%type <ttype> NSNAME
/* Used in lex.c for parsing pragmas. */
%token END_OF_LINE
/* lex.c and pt.c depends on this being the last token. Define
any new tokens before this one! */
%token END_OF_SAVED_INPUT
%{
/* List of types and structure classes of the current declaration. */
static tree current_declspecs;
/* List of prefix attributes in effect.
Prefix attributes are parsed by the reserved_declspecs and declmods
rules. They create a list that contains *both* declspecs and attrs. */
/* ??? It is not clear yet that all cases where an attribute can now appear in
a declspec list have been updated. */
static tree prefix_attributes;
/* When defining an aggregate, this is the most recent one being defined. */
static tree current_aggr;
/* Tell yyparse how to print a token's value, if yydebug is set. */
#define YYPRINT(FILE,YYCHAR,YYLVAL) yyprint(FILE,YYCHAR,YYLVAL)
extern void yyprint ();
extern tree combine_strings PROTO((tree));
%}
%%
program: /* empty */
| extdefs
{
/* In case there were missing closebraces,
get us back to the global binding level. */
while (! global_bindings_p ())
poplevel (0, 0, 0);
finish_file ();
}
;
/* the reason for the strange actions in this rule
is so that notype_initdecls when reached via datadef
can find a valid list of type and sc specs in $0. */
extdefs:
{ $<ttype>$ = NULL_TREE; } lang_extdef
{ $<ttype>$ = NULL_TREE; }
| extdefs lang_extdef
{ $<ttype>$ = NULL_TREE; }
;
extdefs_opt:
extdefs
| /* empty */
;
.hush_warning:
{ have_extern_spec = 1;
used_extern_spec = 0;
$<ttype>$ = NULL_TREE; }
;
.warning_ok:
{ have_extern_spec = 0; }
;
asm_keyword:
ASM_KEYWORD
| GCC_ASM_KEYWORD
;
lang_extdef:
{ if (pending_lang_change) do_pending_lang_change(); }
extdef
{ if (! toplevel_bindings_p () && ! pseudo_global_level_p())
pop_everything (); }
;
extdef:
fndef
{ if (pending_inlines) do_pending_inlines (); }
| datadef
{ if (pending_inlines) do_pending_inlines (); }
| template_def
{ if (pending_inlines) do_pending_inlines (); }
| overloaddef
| asm_keyword '(' string ')' ';'
{ if (TREE_CHAIN ($3)) $3 = combine_strings ($3);
assemble_asm ($3); }
| extern_lang_string '{' extdefs_opt '}'
{ pop_lang_context (); }
| extern_lang_string .hush_warning fndef .warning_ok
{ if (pending_inlines) do_pending_inlines ();
pop_lang_context (); }
| extern_lang_string .hush_warning datadef .warning_ok
{ if (pending_inlines) do_pending_inlines ();
pop_lang_context (); }
| NAMESPACE identifier '{'
{ push_namespace ($2); }
extdefs_opt '}'
{ pop_namespace (); }
| NAMESPACE '{'
{ push_namespace (NULL_TREE); }
extdefs_opt '}'
{ pop_namespace (); }
| NAMESPACE identifier '=' any_id ';'
{ do_namespace_alias ($2, $4); }
| using_decl ';'
{ do_toplevel_using_decl ($1); }
| USING NAMESPACE any_id ';'
{ do_using_directive ($3); }
;
using_decl:
USING qualified_id
{ $$ = $2; }
| USING global_scope qualified_id
{ $$ = $3; }
| USING global_scope unqualified_id
{ $$ = $3; }
;
any_id:
unqualified_id
| qualified_id
| global_scope qualified_id
{ $$ = $2; }
| global_scope unqualified_id
{ $$ = $2; }
;
extern_lang_string:
EXTERN_LANG_STRING
{ push_lang_context ($1); }
| extern_lang_string EXTERN_LANG_STRING
{ if (current_lang_name != $2)
cp_error ("use of linkage spec `%D' is different from previous spec `%D'", $2, current_lang_name);
pop_lang_context (); push_lang_context ($2); }
;
template_header:
TEMPLATE '<'
{ begin_template_parm_list (); }
template_parm_list '>'
{ $$ = end_template_parm_list ($4); }
;
template_parm_list:
template_parm
{ $$ = process_template_parm (NULL_TREE, $1); }
| template_parm_list ',' template_parm
{ $$ = process_template_parm ($1, $3); }
;
template_type_parm:
aggr
{
$$ = build_tree_list ($1, NULL_TREE);
ttpa:
if (TREE_PURPOSE ($$) == signature_type_node)
sorry ("signature as template type parameter");
else if (TREE_PURPOSE ($$) != class_type_node)
pedwarn ("template type parameters must use the keyword `class'");
}
| aggr identifier
{ $$ = build_tree_list ($1, $2); goto ttpa; }
| TYPENAME_KEYWORD
{ $$ = build_tree_list (class_type_node, NULL_TREE); }
| TYPENAME_KEYWORD identifier
{ $$ = build_tree_list (class_type_node, $2); }
;
template_parm:
/* The following rules introduce a new reduce/reduce
conflict on the ',' and '>' input tokens: they are valid
prefixes for a `structsp', which means they could match a
nameless parameter. See 14.6, paragraph 3.
By putting them before the `parm' rule, we get
their match before considering them nameless parameter
declarations. */
template_type_parm
{ $$ = build_tree_list (NULL_TREE, $$); }
| template_type_parm '=' typespec
{ $$ = build_tree_list ($3, $$); }
| full_parm
;
overloaddef:
OVERLOAD ov_identifiers ';'
{ warning ("use of `overload' is an anachronism"); }
;
ov_identifiers: IDENTIFIER
{ declare_overloaded ($1); }
| ov_identifiers ',' IDENTIFIER
{ declare_overloaded ($3); }
;
template_def:
/* Class template declarations go here; they aren't normal class
declarations, because we can't process the bodies yet. */
template_header named_class_head_sans_basetype '{'
{ yychar = '{'; goto template1; }
';'
| template_header named_class_head_sans_basetype_defn '{'
{ yychar = '{'; goto template1; }
';'
| template_header named_class_head_sans_basetype ':'
{ yychar = ':'; goto template1; }
';'
| template_header named_class_head_sans_basetype_defn ':'
{
yychar = ':';
template1:
if (current_aggr == signature_type_node)
sorry ("template type defining a signature");
/* Maybe pedantic warning for union?
How about an enum? :-) */
end_template_decl ($1, $2, current_aggr, 1);
reinit_parse_for_template (yychar, $1, $2);
yychar = YYEMPTY;
}
';'
| template_header named_class_head_sans_basetype ';'
{
end_template_decl ($1, $2, current_aggr, 0);
/* declare $2 as template name with $1 parm list */
}
| template_header named_class_head_sans_basetype_defn ';'
{
end_template_decl ($1, $2, current_aggr, 0);
/* declare $2 as template name with $1 parm list */
}
| template_header /* notype_initdcl0 ';' */
notype_declarator exception_specification_opt maybeasm maybe_attribute
fn_tmpl_end
{
tree d;
int momentary;
int def = ($6 != ';');
momentary = suspend_momentary ();
d = start_decl ($<ttype>2, /*current_declspecs*/NULL_TREE, 0,
$3);
cplus_decl_attributes (d, $5, /*prefix_attributes*/NULL_TREE);
cp_finish_decl (d, NULL_TREE, $4, 0, 0);
end_template_decl ($1, d, 0, def);
if (def)
reinit_parse_for_template ((int) $6, $1, d);
resume_momentary (momentary);
}
| template_header typed_declspecs /*initdcl0*/
declarator exception_specification_opt maybeasm maybe_attribute
fn_tmpl_end
{
tree d, specs, attrs;
int momentary;
int def = ($7 != ';');
split_specs_attrs ($2, &specs, &attrs);
momentary = suspend_momentary ();
d = start_decl ($<ttype>3, specs, 0, $<ttype>4);
cplus_decl_attributes (d, $6, attrs);
cp_finish_decl (d, NULL_TREE, $5, 0, 0);
end_template_decl ($1, d, 0, def);
if (def)
{
reinit_parse_for_template ((int) $7, $1, d);
yychar = YYEMPTY;
}
note_list_got_semicolon ($<ttype>2);
resume_momentary (momentary);
}
| template_header declmods notype_declarator fn_tmpl_end
{
tree d, specs, attrs;
int def = ($4 != ';');
split_specs_attrs ($2, &specs, &attrs);
d = start_decl ($<ttype>3, specs, 0, NULL_TREE);
cplus_decl_attributes (d, NULL_TREE, attrs);
cp_finish_decl (d, NULL_TREE, NULL_TREE, 0, 0);
end_template_decl ($1, d, 0, def);
if (def)
reinit_parse_for_template ((int) $4, $1, d);
}
/* Try to recover from syntax errors in templates. */
| template_header error '}' { end_template_decl ($1, 0, 0, 0); }
| template_header error ';' { end_template_decl ($1, 0, 0, 0); }
;
fn_tmpl_end: '{' { $$ = '{'; }
| ':' { $$ = ':'; }
| ';' { $$ = ';'; }
| '=' { $$ = '='; }
| RETURN { $$ = RETURN; }
;
datadef:
nomods_initdecls ';'
{}
| declmods notype_initdecls ';'
{}
/* Normal case to make fast: "const i;". */
| declmods notype_declarator ';'
{ tree d, specs, attrs;
split_specs_attrs ($1, &specs, &attrs);
d = start_decl ($<ttype>2, specs, 0, NULL_TREE);
cplus_decl_attributes (d, NULL_TREE, attrs);
cp_finish_decl (d, NULL_TREE, NULL_TREE, 0, 0);
}
| typed_declspecs initdecls ';'
{
note_list_got_semicolon ($<ttype>$);
}
/* Normal case: make this fast. */
| typed_declspecs declarator ';'
{ tree d, specs, attrs;
split_specs_attrs ($1, &specs, &attrs);
d = start_decl ($<ttype>2, specs, 0, NULL_TREE);
cplus_decl_attributes (d, NULL_TREE, attrs);
cp_finish_decl (d, NULL_TREE, NULL_TREE, 0, 0);
note_list_got_semicolon ($<ttype>$);
}
| declmods ';'
{ pedwarn ("empty declaration"); }
| explicit_instantiation ';'
| typed_declspecs ';'
{
tree t, attrs;
split_specs_attrs ($1, &t, &attrs);
shadow_tag (t);
if (TREE_CODE (t) == TREE_LIST
&& TREE_PURPOSE (t) == NULL_TREE)
{
t = TREE_VALUE (t);
if (IS_AGGR_TYPE (t)
&& IDENTIFIER_TEMPLATE (TYPE_IDENTIFIER (t)))
{
if (CLASSTYPE_USE_TEMPLATE (t) == 0)
SET_CLASSTYPE_TEMPLATE_SPECIALIZATION (t);
else if (CLASSTYPE_TEMPLATE_INSTANTIATION (t))
error ("override declaration for already-expanded template");
}
}
note_list_got_semicolon ($<ttype>$);
}
| error ';'
| error '}'
| ';'
;
ctor_initializer_opt:
nodecls
{ $$ = 0; }
| base_init
{ $$ = 1; }
;
maybe_return_init:
/* empty */
| return_init
| return_init ';'
;
eat_saved_input:
/* empty */
| END_OF_SAVED_INPUT
;
fndef:
fn.def1 maybe_return_init ctor_initializer_opt compstmt_or_error
{
finish_function (lineno, (int)$3, 0);
if ($<ttype>$) process_next_inline ($<ttype>$);
}
| fn.def1 maybe_return_init function_try_block
{
if ($<ttype>$) process_next_inline ($<ttype>$);
}
eat_saved_input
| typed_declspecs declarator error
{}
| declmods notype_declarator error
{}
| notype_declarator error
{}
;
fn.def1:
typed_declspecs declarator exception_specification_opt
{ tree specs, attrs;
split_specs_attrs ($1, &specs, &attrs);
if (! start_function (specs, $2, $3, attrs, 0))
YYERROR1;
reinit_parse_for_function ();
$$ = NULL_TREE; }
| declmods notype_declarator exception_specification_opt
{ tree specs = strip_attrs ($1);
if (! start_function (specs, $2, $3, NULL_TREE, 0))
YYERROR1;
reinit_parse_for_function ();
$$ = NULL_TREE; }
| notype_declarator exception_specification_opt
{ if (! start_function (NULL_TREE, $$, $2, NULL_TREE, 0))
YYERROR1;
reinit_parse_for_function ();
$$ = NULL_TREE; }
| PRE_PARSED_FUNCTION_DECL
{ start_function (NULL_TREE, TREE_VALUE ($$),
NULL_TREE, NULL_TREE, 1);
reinit_parse_for_function (); }
;
/* more C++ complexity. See component_decl for a comment on the
reduce/reduce conflict introduced by these rules. */
fn.def2:
typed_declspecs '(' parmlist ')' type_quals exception_specification_opt
{ tree specs = strip_attrs ($1);
$$ = build_parse_node (CALL_EXPR, TREE_VALUE (specs), $3, $5);
$$ = start_method (TREE_CHAIN (specs), $$, $6);
rest_of_mdef:
if (! $$)
YYERROR1;
if (yychar == YYEMPTY)
yychar = YYLEX;
reinit_parse_for_method (yychar, $$); }
| typed_declspecs LEFT_RIGHT type_quals exception_specification_opt
{ tree specs = strip_attrs ($1);
$$ = build_parse_node (CALL_EXPR, TREE_VALUE (specs),
empty_parms (), $3);
$$ = start_method (TREE_CHAIN (specs), $$, $4);
goto rest_of_mdef;
}
| typed_declspecs declarator exception_specification_opt
{ tree specs = strip_attrs ($1);
$$ = start_method (specs, $2, $3); goto rest_of_mdef; }
| declmods notype_declarator exception_specification_opt
{ tree specs = strip_attrs ($1);
$$ = start_method (specs, $2, $3); goto rest_of_mdef; }
| notype_declarator exception_specification_opt
{ $$ = start_method (NULL_TREE, $$, $2); goto rest_of_mdef; }
;
return_id: RETURN IDENTIFIER
{
if (! current_function_parms_stored)
store_parm_decls ();
$$ = $2;
}
;
return_init: return_id maybe_init
{ store_return_init ($<ttype>$, $2); }
| return_id '(' nonnull_exprlist ')'
{ store_return_init ($<ttype>$, $3); }
| return_id LEFT_RIGHT
{ store_return_init ($<ttype>$, NULL_TREE); }
;
base_init:
':' .set_base_init member_init_list
{
if ($3 == 0)
error ("no base initializers given following ':'");
setup_vtbl_ptr ();
/* Always keep the BLOCK node associated with the outermost
pair of curley braces of a function. These are needed
for correct operation of dwarfout.c. */
keep_next_level ();
}
;
.set_base_init:
/* empty */
{
if (! current_function_parms_stored)
store_parm_decls ();
if (DECL_CONSTRUCTOR_P (current_function_decl))
{
/* Make a contour for the initializer list. */
pushlevel (0);
clear_last_expr ();
expand_start_bindings (0);
}
else if (current_class_type == NULL_TREE)
error ("base initializers not allowed for non-member functions");
else if (! DECL_CONSTRUCTOR_P (current_function_decl))
error ("only constructors take base initializers");
}
;
member_init_list:
/* empty */
{ $$ = 0; }
| member_init
{ $$ = 1; }
| member_init_list ',' member_init
| member_init_list error
;
member_init: '(' nonnull_exprlist ')'
{
if (current_class_name && !flag_traditional)
pedwarn ("anachronistic old style base class initializer");
expand_member_init (C_C_D, NULL_TREE, $2);
}
| LEFT_RIGHT
{
if (current_class_name && !flag_traditional)
pedwarn ("anachronistic old style base class initializer");
expand_member_init (C_C_D, NULL_TREE, void_type_node);
}
| notype_identifier '(' nonnull_exprlist ')'
{ expand_member_init (C_C_D, $<ttype>$, $3); }
| notype_identifier LEFT_RIGHT
{ expand_member_init (C_C_D, $<ttype>$, void_type_node); }
| complete_type_name '(' nonnull_exprlist ')'
{ expand_member_init (C_C_D, $<ttype>$, $3); }
| complete_type_name LEFT_RIGHT
{ expand_member_init (C_C_D, $<ttype>$, void_type_node); }
/* GNU extension */
| notype_qualified_id '(' nonnull_exprlist ')'
{
do_member_init (OP0 ($1), OP1 ($1), $3);
}
| notype_qualified_id LEFT_RIGHT
{
do_member_init (OP0 ($1), OP1 ($1), void_type_node);
}
;
identifier:
IDENTIFIER
| TYPENAME
| PTYPENAME
| NSNAME
;
notype_identifier:
IDENTIFIER
| PTYPENAME
| NSNAME %prec EMPTY
;
identifier_defn:
IDENTIFIER_DEFN
| TYPENAME_DEFN
| PTYPENAME_DEFN
;
explicit_instantiation:
TEMPLATE specialization template_instantiation
{ do_type_instantiation ($3 ? $3 : $2, NULL_TREE); }
| TEMPLATE typed_declspecs declarator
{ tree specs = strip_attrs ($2);
do_function_instantiation (specs, $3, NULL_TREE); }
| TEMPLATE notype_declarator
{ do_function_instantiation (NULL_TREE, $2, NULL_TREE); }
| SCSPEC TEMPLATE specialization template_instantiation
{ do_type_instantiation ($4 ? $4 : $3, $1); }
| SCSPEC TEMPLATE typed_declspecs declarator
{ tree specs = strip_attrs ($3);
do_function_instantiation (specs, $4, $1); }
| SCSPEC TEMPLATE notype_declarator
{ do_function_instantiation (NULL_TREE, $3, $1); }
;
template_type:
template_type_name tmpl.2 template_instantiation
{ if ($3) $$ = $3; }
;
template_type_name:
PTYPENAME '<' template_arg_list '>'
{ $$ = lookup_template_class ($$, $3, NULL_TREE); }
| PTYPENAME '<' '>'
{ $$ = lookup_template_class ($$, NULL_TREE, NULL_TREE); }
| TYPENAME '<' template_arg_list '>'
{ $$ = lookup_template_class ($$, $3, NULL_TREE); }
;
tmpl.2:
/* empty */ %prec EMPTY
{ $$ = instantiate_class_template ($<ttype>0, 1); }
;
template_arg_list:
template_arg
{ $$ = build_tree_list (NULL_TREE, $$); }
| template_arg_list ',' template_arg
{ $$ = chainon ($$, build_tree_list (NULL_TREE, $3)); }
;
template_arg:
type_id
{ $$ = groktypename ($$); }
| expr_no_commas %prec UNARY
;
template_instantiate_once:
PRE_PARSED_CLASS_DECL maybe_base_class_list
{
tree t, decl, tmpl;
tmpl = TREE_PURPOSE (IDENTIFIER_TEMPLATE ($1));
t = xref_tag (DECL_TEMPLATE_INFO (tmpl)->aggr, $1, $2, 0);
set_current_level_tags_transparency (1);
my_friendly_assert (TREE_CODE (t) == RECORD_TYPE
|| TREE_CODE (t) == UNION_TYPE, 257);
$<ttype>$ = t;
/* Now, put a copy of the decl in global scope, to avoid
recursive expansion. */
decl = IDENTIFIER_LOCAL_VALUE ($1);
if (!decl)
decl = IDENTIFIER_CLASS_VALUE ($1);
/* Now, put a copy of the decl in global scope, to avoid
recursive expansion. */
if (decl)
{
/* Need to copy it to clear the chain pointer,
and need to get it into permanent storage. */
my_friendly_assert (TREE_CODE (decl) == TYPE_DECL, 258);
push_obstacks (&permanent_obstack, &permanent_obstack);
decl = copy_node (decl);
if (DECL_LANG_SPECIFIC (decl))
copy_lang_decl (decl);
pop_obstacks ();
pushdecl_top_level (decl);
}
/* Kludge; see instantiate_class_template. */
TYPE_BEING_DEFINED (t) = 0;
}
left_curly opt.component_decl_list '}'
{
tree t = finish_struct ($<ttype>3, $5, 0);
pop_obstacks ();
end_template_instantiation ($1);
repo_template_used (t);
/* Now go after the methods & class data. */
instantiate_member_templates ($1);
pop_tinst_level();
CLASSTYPE_GOT_SEMICOLON (t) = 1;
}
;
template_instantiation:
/* empty */
{ $$ = NULL_TREE; }
| template_instantiate_once
{ $$ = $1; }
;
template_instantiate_some:
/* empty */
{ $$ = NULL_TREE; /* never used from here... */}
| template_instantiate_once template_instantiate_some
{ $$ = $1; /*???*/ }
;
unop: '-'
{ $$ = NEGATE_EXPR; }
| '+'
{ $$ = CONVERT_EXPR; }
| PLUSPLUS
{ $$ = PREINCREMENT_EXPR; }
| MINUSMINUS
{ $$ = PREDECREMENT_EXPR; }
| '!'
{ $$ = TRUTH_NOT_EXPR; }
;
expr: nontrivial_exprlist
{ $$ = build_x_compound_expr ($$); }
| expr_no_commas
;
paren_expr_or_null:
LEFT_RIGHT
{ error ("ANSI C++ forbids an empty condition for `%s'",
cond_stmt_keyword);
$$ = integer_zero_node; }
| '(' expr ')'
{ $$ = condition_conversion ($2); }
;
paren_cond_or_null:
LEFT_RIGHT
{ error ("ANSI C++ forbids an empty condition for `%s'",
cond_stmt_keyword);
$$ = integer_zero_node; }
| '(' condition ')'
{ $$ = condition_conversion ($2); }
;
xcond:
/* empty */
{ $$ = NULL_TREE; }
| condition
{ $$ = condition_conversion ($$); }
| error
{ $$ = NULL_TREE; }
;
condition:
type_specifier_seq declarator exception_specification_opt maybeasm maybe_attribute '='
{ {
tree d;
for (d = getdecls (); d; d = TREE_CHAIN (d))
if (TREE_CODE (d) == TYPE_DECL) {
tree s = TREE_TYPE (d);
if (TREE_CODE (s) == RECORD_TYPE)
cp_error ("definition of class `%T' in condition", s);
else if (TREE_CODE (s) == ENUMERAL_TYPE)
cp_error ("definition of enum `%T' in condition", s);
}
}
current_declspecs = $1;
$<itype>6 = suspend_momentary ();
$<ttype>$ = start_decl ($<ttype>2, current_declspecs, 1, $3);
cplus_decl_attributes ($<ttype>$, $5,
/*prefix_attributes*/ NULL_TREE);
}
init
{
cp_finish_decl ($<ttype>7, $8, $5, 0, LOOKUP_ONLYCONVERTING);
resume_momentary ($<itype>6);
$$ = $<ttype>7;
if (TREE_CODE (TREE_TYPE ($$)) == ARRAY_TYPE)
cp_error ("definition of array `%#D' in condition", $$);
}
| expr
;
compstmtend:
'}'
| maybe_label_decls stmts '}'
| maybe_label_decls stmts error '}'
| maybe_label_decls error '}'
;
already_scoped_stmt:
'{' compstmtend
{ finish_stmt (); }
| simple_stmt
;
nontrivial_exprlist:
expr_no_commas ',' expr_no_commas
{ $$ = tree_cons (NULL_TREE, $$,
build_tree_list (NULL_TREE, $3)); }
| expr_no_commas ',' error
{ $$ = tree_cons (NULL_TREE, $$,
build_tree_list (NULL_TREE, error_mark_node)); }
| nontrivial_exprlist ',' expr_no_commas
{ chainon ($$, build_tree_list (NULL_TREE, $3)); }
| nontrivial_exprlist ',' error
{ chainon ($$, build_tree_list (NULL_TREE, error_mark_node)); }
;
nonnull_exprlist:
expr_no_commas
{ $$ = build_tree_list (NULL_TREE, $$); }
| nontrivial_exprlist
;
unary_expr:
primary %prec UNARY
{
#if 0
if (TREE_CODE ($$) == TYPE_EXPR)
$$ = build_component_type_expr (C_C_D, $$, NULL_TREE, 1);
#endif
}
/* __extension__ turns off -pedantic for following primary. */
| EXTENSION
{ $<itype>1 = pedantic;
pedantic = 0; }
cast_expr %prec UNARY
{ $$ = $3;
pedantic = $<itype>1; }
| '*' cast_expr %prec UNARY
{ $$ = build_x_indirect_ref ($2, "unary *"); }
| '&' cast_expr %prec UNARY
{ $$ = build_x_unary_op (ADDR_EXPR, $2); }
| '~' cast_expr
{ $$ = build_x_unary_op (BIT_NOT_EXPR, $2); }
| unop cast_expr %prec UNARY
{ $$ = build_x_unary_op ($1, $2);
if ($1 == NEGATE_EXPR && TREE_CODE ($2) == INTEGER_CST)
TREE_NEGATED_INT ($$) = 1;
overflow_warning ($$);
}
/* Refer to the address of a label as a pointer. */
| ANDAND identifier
{ tree label = lookup_label ($2);
if (label == NULL_TREE)
$$ = null_pointer_node;
else
{
TREE_USED (label) = 1;
$$ = build1 (ADDR_EXPR, ptr_type_node, label);
TREE_CONSTANT ($$) = 1;
}
}
| SIZEOF unary_expr %prec UNARY
{ if (TREE_CODE ($2) == COMPONENT_REF
&& DECL_BIT_FIELD (TREE_OPERAND ($2, 1)))
error ("sizeof applied to a bit-field");
/* ANSI says arrays and functions are converted inside comma.
But we can't really convert them in build_compound_expr
because that would break commas in lvalues.
So do the conversion here if operand was a comma. */
if (TREE_CODE ($2) == COMPOUND_EXPR
&& (TREE_CODE (TREE_TYPE ($2)) == ARRAY_TYPE
|| TREE_CODE (TREE_TYPE ($2)) == FUNCTION_TYPE))
$2 = default_conversion ($2);
else if (TREE_CODE ($2) == TREE_LIST)
{
tree t = TREE_VALUE ($2);
if (t != NULL_TREE
&& ((TREE_TYPE (t)
&& TREE_CODE (TREE_TYPE (t)) == FUNCTION_TYPE)
|| is_overloaded_fn (t)))
pedwarn ("ANSI C++ forbids taking the sizeof a function type");
}
$$ = c_sizeof (TREE_TYPE ($2)); }
| SIZEOF '(' type_id ')' %prec HYPERUNARY
{ $$ = c_sizeof (groktypename ($3)); }
| ALIGNOF unary_expr %prec UNARY
{ $$ = grok_alignof ($2); }
| ALIGNOF '(' type_id ')' %prec HYPERUNARY
{ $$ = c_alignof (groktypename ($3)); }
/* The %prec EMPTY's here are required by the = init initializer
syntax extension; see below. */
| new new_type_id %prec EMPTY
{ $$ = build_new (NULL_TREE, $2, NULL_TREE, $1); }
| new new_type_id new_initializer
{ $$ = build_new (NULL_TREE, $2, $3, $1); }
| new new_placement new_type_id %prec EMPTY
{ $$ = build_new ($2, $3, NULL_TREE, $1); }
| new new_placement new_type_id new_initializer
{ $$ = build_new ($2, $3, $4, $1); }
| new '(' type_id ')' %prec EMPTY
{ $$ = build_new (NULL_TREE, groktypename($3),
NULL_TREE, $1); }
| new '(' type_id ')' new_initializer
{ $$ = build_new (NULL_TREE, groktypename($3), $5, $1); }
| new new_placement '(' type_id ')' %prec EMPTY
{ $$ = build_new ($2, groktypename($4), NULL_TREE, $1); }
| new new_placement '(' type_id ')' new_initializer
{ $$ = build_new ($2, groktypename($4), $6, $1); }
| delete cast_expr %prec UNARY
{ $$ = delete_sanity ($2, NULL_TREE, 0, $1); }
| delete '[' ']' cast_expr %prec UNARY
{ $$ = delete_sanity ($4, NULL_TREE, 1, $1);
if (yychar == YYEMPTY)
yychar = YYLEX; }
| delete '[' expr ']' cast_expr %prec UNARY
{ $$ = delete_sanity ($5, $3, 2, $1);
if (yychar == YYEMPTY)
yychar = YYLEX; }
;
new_placement:
'(' nonnull_exprlist ')'
{ $$ = $2; }
| '{' nonnull_exprlist '}'
{
$$ = $2;
pedwarn ("old style placement syntax, use () instead");
}
;
new_initializer:
'(' nonnull_exprlist ')'
{ $$ = $2; }
| LEFT_RIGHT
{ $$ = NULL_TREE; }
| '(' typespec ')'
{
cp_error ("`%T' is not a valid expression", $2);
$$ = error_mark_node;
}
/* GNU extension so people can use initializer lists. Note that
this alters the meaning of `new int = 1', which was previously
syntactically valid but semantically invalid. */
| '=' init
{
if (pedantic)
pedwarn ("ANSI C++ forbids initialization of new expression with `='");
$$ = $2;
}
;
/* This is necessary to postpone reduction of `int ((int)(int)(int))'. */
regcast_or_absdcl:
'(' type_id ')' %prec EMPTY
{ $2 = tree_cons (NULL_TREE, $2, void_list_node);
TREE_PARMLIST ($2) = 1;
$$ = build_parse_node (CALL_EXPR, NULL_TREE, $2,
NULL_TREE); }
| regcast_or_absdcl '(' type_id ')' %prec EMPTY
{ $3 = tree_cons (NULL_TREE, $3, void_list_node);
TREE_PARMLIST ($3) = 1;
$$ = build_parse_node (CALL_EXPR, $$, $3, NULL_TREE); }
;
cast_expr:
unary_expr
| regcast_or_absdcl unary_expr %prec UNARY
{ $$ = reparse_absdcl_as_casts ($$, $2); }
| regcast_or_absdcl '{' initlist maybecomma '}' %prec UNARY
{
tree init = build_nt (CONSTRUCTOR, NULL_TREE,
nreverse ($3));
if (pedantic)
pedwarn ("ANSI C++ forbids constructor-expressions");
/* Indicate that this was a GNU C constructor expression. */
TREE_HAS_CONSTRUCTOR (init) = 1;
$$ = reparse_absdcl_as_casts ($$, init);
}
;
expr_no_commas:
cast_expr
/* Handle general members. */
| expr_no_commas POINTSAT_STAR expr_no_commas
{ $$ = build_x_binary_op (MEMBER_REF, $$, $3); }
| expr_no_commas DOT_STAR expr_no_commas
{ $$ = build_m_component_ref ($$, $3); }
| expr_no_commas '+' expr_no_commas
{ $$ = build_x_binary_op ($2, $$, $3); }
| expr_no_commas '-' expr_no_commas
{ $$ = build_x_binary_op ($2, $$, $3); }
| expr_no_commas '*' expr_no_commas
{ $$ = build_x_binary_op ($2, $$, $3); }
| expr_no_commas '/' expr_no_commas
{ $$ = build_x_binary_op ($2, $$, $3); }
| expr_no_commas '%' expr_no_commas
{ $$ = build_x_binary_op ($2, $$, $3); }
| expr_no_commas LSHIFT expr_no_commas
{ $$ = build_x_binary_op ($2, $$, $3); }
| expr_no_commas RSHIFT expr_no_commas
{ $$ = build_x_binary_op ($2, $$, $3); }
| expr_no_commas ARITHCOMPARE expr_no_commas
{ $$ = build_x_binary_op ($2, $$, $3); }
| expr_no_commas '<' expr_no_commas
{ $$ = build_x_binary_op (LT_EXPR, $$, $3); }
| expr_no_commas '>' expr_no_commas
{ $$ = build_x_binary_op (GT_EXPR, $$, $3); }
| expr_no_commas EQCOMPARE expr_no_commas
{ $$ = build_x_binary_op ($2, $$, $3); }
| expr_no_commas MIN_MAX expr_no_commas
{ $$ = build_x_binary_op ($2, $$, $3); }
| expr_no_commas '&' expr_no_commas
{ $$ = build_x_binary_op ($2, $$, $3); }
| expr_no_commas '|' expr_no_commas
{ $$ = build_x_binary_op ($2, $$, $3); }
| expr_no_commas '^' expr_no_commas
{ $$ = build_x_binary_op ($2, $$, $3); }
| expr_no_commas ANDAND expr_no_commas
{ $$ = build_x_binary_op (TRUTH_ANDIF_EXPR, $$, $3); }
| expr_no_commas OROR expr_no_commas
{ $$ = build_x_binary_op (TRUTH_ORIF_EXPR, $$, $3); }
| expr_no_commas '?' xexpr ':' expr_no_commas
{ $$ = build_x_conditional_expr ($$, $3, $5); }
| expr_no_commas '=' expr_no_commas
{ $$ = build_modify_expr ($$, NOP_EXPR, $3);
C_SET_EXP_ORIGINAL_CODE ($$, MODIFY_EXPR); }
| expr_no_commas ASSIGN expr_no_commas
{ register tree rval;
if ((rval = build_opfncall (MODIFY_EXPR, LOOKUP_NORMAL, $$, $3,
make_node ($2))))
$$ = rval;
else
$$ = build_modify_expr ($$, $2, $3); }
| THROW
{ $$ = build_throw (NULL_TREE); }
| THROW expr_no_commas
{ $$ = build_throw ($2); }
/* These extensions are not defined. The second arg to build_m_component_ref
is old, build_m_component_ref now does an implicit
build_indirect_ref (x, NULL_PTR) on the second argument.
| object '&' expr_no_commas %prec UNARY
{ $$ = build_m_component_ref ($$, build_x_unary_op (ADDR_EXPR, $3)); }
| object unop expr_no_commas %prec UNARY
{ $$ = build_m_component_ref ($$, build_x_unary_op ($2, $3)); }
| object '(' type_id ')' expr_no_commas %prec UNARY
{ tree type = groktypename ($3);
$$ = build_m_component_ref ($$, build_c_cast (type, $5, 0)); }
| object primary_no_id %prec UNARY
{ $$ = build_m_component_ref ($$, $2); }
*/
;
notype_unqualified_id:
'~' see_typename identifier
{ $$ = build_parse_node (BIT_NOT_EXPR, $3); }
| operator_name
| IDENTIFIER
| PTYPENAME
| NSNAME %prec EMPTY
;
unqualified_id:
notype_unqualified_id
| TYPENAME
;
expr_or_declarator:
notype_unqualified_id
| '*' expr_or_declarator %prec UNARY
{ $$ = build_parse_node (INDIRECT_REF, $2); }
| '&' expr_or_declarator %prec UNARY
{ $$ = build_parse_node (ADDR_EXPR, $2); }
| '(' expr_or_declarator ')'
{ $$ = $2; }
;
direct_notype_declarator:
complex_direct_notype_declarator
| notype_unqualified_id
| '(' expr_or_declarator ')'
{ $$ = finish_decl_parsing ($2); }
;
primary:
notype_unqualified_id
{
if (TREE_CODE ($$) == BIT_NOT_EXPR)
$$ = build_x_unary_op (BIT_NOT_EXPR, TREE_OPERAND ($$, 0));
else if (IDENTIFIER_OPNAME_P ($$))
{
tree op = $$;
$$ = lookup_name (op, 0);
if ($$ == NULL_TREE)
{
if (op != ansi_opname[ERROR_MARK])
error ("operator %s not defined",
operator_name_string (op));
$$ = error_mark_node;
}
}
else
$$ = do_identifier ($$);
}
| CONSTANT
| boolean.literal
| string
{ $$ = combine_strings ($$); }
| '(' expr ')'
{ char class;
$$ = $2;
class = TREE_CODE_CLASS (TREE_CODE ($$));
if (class == 'e' || class == '1'
|| class == '2' || class == '<')
/* This inhibits warnings in truthvalue_conversion. */
C_SET_EXP_ORIGINAL_CODE ($$, ERROR_MARK); }
| '(' expr_or_declarator ')'
{ char class;
$$ = reparse_decl_as_expr (NULL_TREE, $2);
class = TREE_CODE_CLASS (TREE_CODE ($$));
if (class == 'e' || class == '1'
|| class == '2' || class == '<')
/* This inhibits warnings in truthvalue_conversion. */
C_SET_EXP_ORIGINAL_CODE ($$, ERROR_MARK); }
| '(' error ')'
{ $$ = error_mark_node; }
| '('
{ if (current_function_decl == 0)
{
error ("braced-group within expression allowed only inside a function");
YYERROR;
}
keep_next_level ();
$<ttype>$ = expand_start_stmt_expr (); }
compstmt ')'
{ tree rtl_exp;
if (pedantic)
pedwarn ("ANSI C++ forbids braced-groups within expressions");
rtl_exp = expand_end_stmt_expr ($<ttype>2);
/* The statements have side effects, so the group does. */
TREE_SIDE_EFFECTS (rtl_exp) = 1;
if (TREE_CODE ($3) == BLOCK)
{
/* Make a BIND_EXPR for the BLOCK already made. */
$$ = build (BIND_EXPR, TREE_TYPE (rtl_exp),
NULL_TREE, rtl_exp, $3);
/* Remove the block from the tree at this point.
It gets put back at the proper place
when the BIND_EXPR is expanded. */
delete_block ($3);
}
else
$$ = $3;
}
| primary '(' nonnull_exprlist ')'
{ /* [eichin:19911016.1902EST] */
$<ttype>$ = build_x_function_call ($1, $3, current_class_decl);
/* here we instantiate_class_template as needed... */
do_pending_templates ();
} template_instantiate_some {
if (TREE_CODE ($<ttype>5) == CALL_EXPR
&& TREE_TYPE ($<ttype>5) != void_type_node)
$$ = require_complete_type ($<ttype>5);
else
$$ = $<ttype>5;
}
| primary LEFT_RIGHT
{
$$ = build_x_function_call ($$, NULL_TREE, current_class_decl);
if (TREE_CODE ($$) == CALL_EXPR
&& TREE_TYPE ($$) != void_type_node)
$$ = require_complete_type ($$);
}
| primary '[' expr ']'
{ $$ = grok_array_decl ($$, $3); }
| primary PLUSPLUS
{ /* If we get an OFFSET_REF, turn it into what it really
means (e.g., a COMPONENT_REF). This way if we've got,
say, a reference to a static member that's being operated
on, we don't end up trying to find a member operator for
the class it's in. */
if (TREE_CODE ($$) == OFFSET_REF)
$$ = resolve_offset_ref ($$);
$$ = build_x_unary_op (POSTINCREMENT_EXPR, $$); }
| primary MINUSMINUS
{ if (TREE_CODE ($$) == OFFSET_REF)
$$ = resolve_offset_ref ($$);
$$ = build_x_unary_op (POSTDECREMENT_EXPR, $$); }
/* C++ extensions */
| THIS
{ if (current_class_decl)
{
#ifdef WARNING_ABOUT_CCD
TREE_USED (current_class_decl) = 1;
#endif
$$ = current_class_decl;
}
else if (current_function_decl
&& DECL_STATIC_FUNCTION_P (current_function_decl))
{
error ("`this' is unavailable for static member functions");
$$ = error_mark_node;
}
else
{
if (current_function_decl)
error ("invalid use of `this' in non-member function");
else
error ("invalid use of `this' at top level");
$$ = error_mark_node;
}
}
| TYPE_QUAL '(' nonnull_exprlist ')'
{
tree type;
tree id = $$;
/* This is a C cast in C++'s `functional' notation. */
if ($3 == error_mark_node)
{
$$ = error_mark_node;
break;
}
#if 0
if ($3 == NULL_TREE)
{
error ("cannot cast null list to type `%s'",
IDENTIFIER_POINTER (TYPE_NAME (id)));
$$ = error_mark_node;
break;
}
#endif
#if 0
/* type is not set! (mrs) */
if (type == error_mark_node)
$$ = error_mark_node;
else
#endif
{
if (id == ridpointers[(int) RID_CONST])
type = build_type_variant (integer_type_node, 1, 0);
else if (id == ridpointers[(int) RID_VOLATILE])
type = build_type_variant (integer_type_node, 0, 1);
#if 0
/* should not be able to get here (mrs) */
else if (id == ridpointers[(int) RID_FRIEND])
{
error ("cannot cast expression to `friend' type");
$$ = error_mark_node;
break;
}
#endif
else my_friendly_abort (79);
$$ = build_c_cast (type, build_compound_expr ($3), 1);
}
}
| functional_cast
| DYNAMIC_CAST '<'
{ dont_allow_type_definitions = "inside dynamic_cast"; }
type_id '>'
{ dont_allow_type_definitions = 0; }
'(' expr ')'
{ tree type = groktypename ($4);
$$ = build_dynamic_cast (type, $8); }
| STATIC_CAST '<'
{ dont_allow_type_definitions = "inside static_cast"; }
type_id '>'
{ dont_allow_type_definitions = 0; }
'(' expr ')'
{ tree type = groktypename ($4);
$$ = build_static_cast (type, $8); }
| REINTERPRET_CAST '<'
{ dont_allow_type_definitions = "inside reinterpret_cast"; }
type_id '>'
{ dont_allow_type_definitions = 0; }
'(' expr ')'
{ tree type = groktypename ($4);
$$ = build_reinterpret_cast (type, $8); }
| CONST_CAST '<'
{ dont_allow_type_definitions = "inside const_cast"; }
type_id '>'
{ dont_allow_type_definitions = 0; }
'(' expr ')'
{ tree type = groktypename ($4);
$$ = build_const_cast (type, $8); }
| TYPEID '(' expr ')'
{ $$ = build_typeid ($3); }
| TYPEID '(' type_id ')'
{ tree type = groktypename ($3);
$$ = get_typeid (TYPE_MAIN_VARIANT (type)); }
| global_scope IDENTIFIER
{
do_scoped_id:
$$ = IDENTIFIER_GLOBAL_VALUE ($2);
if (yychar == YYEMPTY)
yychar = YYLEX;
if (! $$)
{
if (yychar == '(' || yychar == LEFT_RIGHT)
$$ = implicitly_declare ($2);
else
{
if (IDENTIFIER_GLOBAL_VALUE ($2) != error_mark_node)
error ("undeclared variable `%s' (first use here)",
IDENTIFIER_POINTER ($2));
$$ = error_mark_node;
/* Prevent repeated error messages. */
IDENTIFIER_GLOBAL_VALUE ($2) = error_mark_node;
}
}
else
{
if (TREE_CODE ($$) == ADDR_EXPR)
assemble_external (TREE_OPERAND ($$, 0));
else
assemble_external ($$);
TREE_USED ($$) = 1;
}
if (TREE_CODE ($$) == CONST_DECL)
{
/* XXX CHS - should we set TREE_USED of the constant? */
$$ = DECL_INITIAL ($$);
/* This is to prevent an enum whose value is 0
from being considered a null pointer constant. */
$$ = build1 (NOP_EXPR, TREE_TYPE ($$), $$);
TREE_CONSTANT ($$) = 1;
}
}
| global_scope operator_name
{
got_scope = NULL_TREE;
if (TREE_CODE ($2) == IDENTIFIER_NODE)
goto do_scoped_id;
$$ = $2;
}
| overqualified_id %prec HYPERUNARY
{ $$ = build_offset_ref (OP0 ($$), OP1 ($$)); }
| overqualified_id '(' nonnull_exprlist ')'
{ $$ = build_member_call (OP0 ($$), OP1 ($$), $3); }
| overqualified_id LEFT_RIGHT
{ $$ = build_member_call (OP0 ($$), OP1 ($$), NULL_TREE); }
| object unqualified_id %prec UNARY
{ got_object = NULL_TREE;
$$ = build_component_ref ($$, $2, NULL_TREE, 1); }
| object overqualified_id %prec UNARY
{ got_object = NULL_TREE;
$$ = build_object_ref ($$, OP0 ($2), OP1 ($2)); }
| object unqualified_id '(' nonnull_exprlist ')'
{
got_object = NULL_TREE;
#if 0
/* This is a future direction of this code, but because
build_x_function_call cannot always undo what is done
in build_component_ref entirely yet, we cannot do this. */
$$ = build_x_function_call (build_component_ref ($$, $2, NULL_TREE, 1), $4, $$);
if (TREE_CODE ($$) == CALL_EXPR
&& TREE_TYPE ($$) != void_type_node)
$$ = require_complete_type ($$);
#else
$$ = build_method_call ($$, $2, $4, NULL_TREE,
(LOOKUP_NORMAL|LOOKUP_AGGR));
#endif
}
| object unqualified_id LEFT_RIGHT
{
got_object = NULL_TREE;
#if 0
/* This is a future direction of this code, but because
build_x_function_call cannot always undo what is done
in build_component_ref entirely yet, we cannot do this. */
$$ = build_x_function_call (build_component_ref ($$, $2, NULL_TREE, 1), NULL_TREE, $$);
if (TREE_CODE ($$) == CALL_EXPR
&& TREE_TYPE ($$) != void_type_node)
$$ = require_complete_type ($$);
#else
$$ = build_method_call ($$, $2, NULL_TREE, NULL_TREE,
(LOOKUP_NORMAL|LOOKUP_AGGR));
#endif
}
| object overqualified_id '(' nonnull_exprlist ')'
{
got_object = NULL_TREE;
if (IS_SIGNATURE (IDENTIFIER_TYPE_VALUE (OP0 ($2))))
{
warning ("signature name in scope resolution ignored");
$$ = build_method_call ($$, OP1 ($2), $4, NULL_TREE,
(LOOKUP_NORMAL|LOOKUP_AGGR));
}
else
$$ = build_scoped_method_call ($$, OP0 ($2), OP1 ($2), $4);
}
| object overqualified_id LEFT_RIGHT
{
got_object = NULL_TREE;
if (IS_SIGNATURE (IDENTIFIER_TYPE_VALUE (OP0 ($2))))
{
warning ("signature name in scope resolution ignored");
$$ = build_method_call ($$, OP1 ($2), NULL_TREE, NULL_TREE,
(LOOKUP_NORMAL|LOOKUP_AGGR));
}
else
$$ = build_scoped_method_call ($$, OP0 ($2), OP1 ($2), NULL_TREE);
}
/* p->int::~int() is valid -- 12.4 */
| object '~' TYPESPEC LEFT_RIGHT
{
got_object = NULL_TREE;
if (IDENTIFIER_GLOBAL_VALUE ($3)
&& (TREE_CODE (TREE_TYPE ($1))
!= TREE_CODE (TREE_TYPE (IDENTIFIER_GLOBAL_VALUE ($3)))))
cp_error ("`%E' is not of type `%T'", $1, $3);
$$ = convert (void_type_node, $1);
}
| object TYPESPEC SCOPE '~' TYPESPEC LEFT_RIGHT
{
got_object = NULL_TREE;
if ($2 != $5)
cp_error ("destructor specifier `%T::~%T()' must have matching names", $2, $5);
if (TREE_CODE (TREE_TYPE ($1))
!= TREE_CODE (TREE_TYPE (IDENTIFIER_GLOBAL_VALUE ($2))))
cp_error ("`%E' is not of type `%T'", $1, $2);
$$ = convert (void_type_node, $1);
}
| object error
{
got_object = NULL_TREE;
$$ = error_mark_node;
}
;
/* Not needed for now.
primary_no_id:
'(' expr ')'
{ $$ = $2; }
| '(' error ')'
{ $$ = error_mark_node; }
| '('
{ if (current_function_decl == 0)
{
error ("braced-group within expression allowed only inside a function");
YYERROR;
}
$<ttype>$ = expand_start_stmt_expr (); }
compstmt ')'
{ if (pedantic)
pedwarn ("ANSI C++ forbids braced-groups within expressions");
$$ = expand_end_stmt_expr ($<ttype>2); }
| primary_no_id '(' nonnull_exprlist ')'
{ $$ = build_x_function_call ($$, $3, current_class_decl); }
| primary_no_id LEFT_RIGHT
{ $$ = build_x_function_call ($$, NULL_TREE, current_class_decl); }
| primary_no_id '[' expr ']'
{ goto do_array; }
| primary_no_id PLUSPLUS
{ $$ = build_x_unary_op (POSTINCREMENT_EXPR, $$); }
| primary_no_id MINUSMINUS
{ $$ = build_x_unary_op (POSTDECREMENT_EXPR, $$); }
| SCOPE IDENTIFIER
{ goto do_scoped_id; }
| SCOPE operator_name
{ if (TREE_CODE ($2) == IDENTIFIER_NODE)
goto do_scoped_id;
goto do_scoped_operator;
}
;
*/
new: NEW
{ $$ = 0; }
| global_scope NEW
{ got_scope = NULL_TREE; $$ = 1; }
;
delete: DELETE
{ $$ = 0; }
| global_scope delete
{ got_scope = NULL_TREE; $$ = 1; }
;
boolean.literal:
CXX_TRUE
{ $$ = boolean_true_node; }
| CXX_FALSE
{ $$ = boolean_false_node; }
;
/* Produces a STRING_CST with perhaps more STRING_CSTs chained onto it. */
string:
STRING
| string STRING
{ $$ = chainon ($$, $2); }
;
nodecls:
/* empty */
{
if (! current_function_parms_stored)
store_parm_decls ();
setup_vtbl_ptr ();
/* Always keep the BLOCK node associated with the outermost
pair of curley braces of a function. These are needed
for correct operation of dwarfout.c. */
keep_next_level ();
}
;
object: primary '.'
{ got_object = TREE_TYPE ($$); }
| primary POINTSAT
{
$$ = build_x_arrow ($$);
got_object = TREE_TYPE ($$);
}
;
decl:
/* Normal case: make this fast. */
typespec declarator ';'
{ tree d = get_decl_list ($1);
int yes = suspend_momentary ();
d = start_decl ($2, d, 0, NULL_TREE);
cp_finish_decl (d, NULL_TREE, NULL_TREE, 0, 0);
resume_momentary (yes);
if (IS_AGGR_TYPE_CODE (TREE_CODE ($1)))
note_got_semicolon ($1);
}
| typed_declspecs declarator ';'
{ tree d, specs, attrs;
int yes;
split_specs_attrs ($1, &specs, &attrs);
yes = suspend_momentary ();
d = start_decl ($2, specs, 0, NULL_TREE);
cplus_decl_attributes (d, NULL_TREE, attrs);
cp_finish_decl (d, NULL_TREE, NULL_TREE, 0, 0);
resume_momentary (yes);
note_list_got_semicolon ($1);
}
| typespec initdecls ';'
{
resume_momentary ($2);
if (IS_AGGR_TYPE_CODE (TREE_CODE ($1)))
note_got_semicolon ($1);
}
| typed_declspecs initdecls ';'
{
resume_momentary ($2);
note_list_got_semicolon ($1);
}
| declmods notype_initdecls ';'
{ resume_momentary ($2); }
| typed_declspecs ';'
{
shadow_tag ($1);
note_list_got_semicolon ($1);
}
| declmods ';'
{ warning ("empty declaration"); }
;
/* Any kind of declarator (thus, all declarators allowed
after an explicit typespec). */
declarator:
after_type_declarator %prec EMPTY
| notype_declarator %prec EMPTY
;
/* This is necessary to postpone reduction of `int()()()()'. */
fcast_or_absdcl:
LEFT_RIGHT %prec EMPTY
{ $$ = build_parse_node (CALL_EXPR, NULL_TREE, empty_parms (),
NULL_TREE); }
| fcast_or_absdcl LEFT_RIGHT %prec EMPTY
{ $$ = build_parse_node (CALL_EXPR, $$, empty_parms (),
NULL_TREE); }
;
/* ANSI type-id (8.1) */
type_id:
typed_typespecs absdcl
{ $$ = build_decl_list ($$, $2); }
| nonempty_type_quals absdcl
{ $$ = build_decl_list ($$, $2); }
| typespec absdcl
{ $$ = build_decl_list (get_decl_list ($$), $2); }
| typed_typespecs %prec EMPTY
{ $$ = build_decl_list ($$, NULL_TREE); }
| nonempty_type_quals %prec EMPTY
{ $$ = build_decl_list ($$, NULL_TREE); }
;
/* Declspecs which contain at least one type specifier or typedef name.
(Just `const' or `volatile' is not enough.)
A typedef'd name following these is taken as a name to be declared.
In the result, declspecs have a non-NULL TREE_VALUE, attributes do not. */
typed_declspecs:
typed_typespecs %prec EMPTY
| typed_declspecs1
;
typed_declspecs1:
declmods typespec
{ $$ = decl_tree_cons (NULL_TREE, $2, $$); }
| typespec reserved_declspecs %prec HYPERUNARY
{ $$ = decl_tree_cons (NULL_TREE, $$, $2); }
| typespec reserved_typespecquals reserved_declspecs
{ $$ = decl_tree_cons (NULL_TREE, $$, chainon ($2, $3)); }
| declmods typespec reserved_declspecs
{ $$ = decl_tree_cons (NULL_TREE, $2, chainon ($3, $$)); }
| declmods typespec reserved_typespecquals
{ $$ = decl_tree_cons (NULL_TREE, $2, chainon ($3, $$)); }
| declmods typespec reserved_typespecquals reserved_declspecs
{ $$ = decl_tree_cons (NULL_TREE, $2,
chainon ($3, chainon ($4, $$))); }
;
reserved_declspecs:
SCSPEC
{ if (extra_warnings)
warning ("`%s' is not at beginning of declaration",
IDENTIFIER_POINTER ($$));
$$ = build_decl_list (NULL_TREE, $$); }
| reserved_declspecs typespecqual_reserved
{ $$ = decl_tree_cons (NULL_TREE, $2, $$); }
| reserved_declspecs SCSPEC
{ if (extra_warnings)
warning ("`%s' is not at beginning of declaration",
IDENTIFIER_POINTER ($2));
$$ = decl_tree_cons (NULL_TREE, $2, $$); }
| reserved_declspecs attributes
{ $$ = decl_tree_cons ($2, NULL_TREE, $1); }
| attributes
{ $$ = decl_tree_cons ($1, NULL_TREE, NULL_TREE); }
;
/* List of just storage classes and type modifiers.
A declaration can start with just this, but then it cannot be used
to redeclare a typedef-name.
In the result, declspecs have a non-NULL TREE_VALUE, attributes do not. */
declmods:
nonempty_type_quals %prec EMPTY
{ TREE_STATIC ($$) = 1; }
| SCSPEC
{ $$ = IDENTIFIER_AS_LIST ($$); }
| declmods TYPE_QUAL
{ $$ = decl_tree_cons (NULL_TREE, $2, $$);
TREE_STATIC ($$) = 1; }
| declmods SCSPEC
{ if (extra_warnings && TREE_STATIC ($$))
warning ("`%s' is not at beginning of declaration",
IDENTIFIER_POINTER ($2));
$$ = decl_tree_cons (NULL_TREE, $2, $$);
TREE_STATIC ($$) = TREE_STATIC ($1); }
| declmods attributes
{ $$ = decl_tree_cons ($2, NULL_TREE, $1); }
| attributes
{ $$ = decl_tree_cons ($1, NULL_TREE, NULL_TREE); }
;
/* Used instead of declspecs where storage classes are not allowed
(that is, for typenames and structure components).
C++ can takes storage classes for structure components.
Don't accept a typedef-name if anything but a modifier precedes it. */
typed_typespecs:
typespec %prec EMPTY
{ $$ = get_decl_list ($$); }
| nonempty_type_quals typespec
{ $$ = decl_tree_cons (NULL_TREE, $2, $$); }
| typespec reserved_typespecquals
{ $$ = decl_tree_cons (NULL_TREE, $$, $2); }
| nonempty_type_quals typespec reserved_typespecquals
{ $$ = decl_tree_cons (NULL_TREE, $2, chainon ($3, $$)); }
;
reserved_typespecquals:
typespecqual_reserved
{ $$ = build_decl_list (NULL_TREE, $$); }
| reserved_typespecquals typespecqual_reserved
{ $$ = decl_tree_cons (NULL_TREE, $2, $$); }
;
/* A typespec (but not a type qualifier).
Once we have seen one of these in a declaration,
if a typedef name appears then it is being redeclared. */
typespec: structsp
| TYPESPEC %prec EMPTY
| complete_type_name
| TYPEOF '(' expr ')'
{ $$ = TREE_TYPE ($3);
if (pedantic && !in_system_header)
pedwarn ("ANSI C++ forbids `typeof'"); }
| TYPEOF '(' type_id ')'
{ $$ = groktypename ($3);
if (pedantic && !in_system_header)
pedwarn ("ANSI C++ forbids `typeof'"); }
| SIGOF '(' expr ')'
{ tree type = TREE_TYPE ($3);
if (IS_AGGR_TYPE (type))
{
sorry ("sigof type specifier");
$$ = type;
}
else
{
error ("`sigof' applied to non-aggregate expression");
$$ = error_mark_node;
}
}
| SIGOF '(' type_id ')'
{ tree type = groktypename ($3);
if (IS_AGGR_TYPE (type))
{
sorry ("sigof type specifier");
$$ = type;
}
else
{
error("`sigof' applied to non-aggregate type");
$$ = error_mark_node;
}
}
;
/* A typespec that is a reserved word, or a type qualifier. */
typespecqual_reserved: TYPESPEC
| TYPE_QUAL
| structsp
;
initdecls:
initdcl0
| initdecls ',' initdcl
;
notype_initdecls:
notype_initdcl0
| notype_initdecls ',' initdcl
;
nomods_initdecls:
nomods_initdcl0
| nomods_initdecls ',' initdcl
;
maybeasm:
/* empty */
{ $$ = NULL_TREE; }
| asm_keyword '(' string ')'
{ if (TREE_CHAIN ($3)) $3 = combine_strings ($3); $$ = $3; }
;
initdcl0:
declarator exception_specification_opt maybeasm maybe_attribute '='
{ split_specs_attrs ($<ttype>0, ¤t_declspecs,
&prefix_attributes);
if (TREE_CODE (current_declspecs) != TREE_LIST)
current_declspecs = get_decl_list (current_declspecs);
if (have_extern_spec && !used_extern_spec)
{
current_declspecs = decl_tree_cons
(NULL_TREE, get_identifier ("extern"),
current_declspecs);
used_extern_spec = 1;
}
$<itype>5 = suspend_momentary ();
$<ttype>$ = start_decl ($<ttype>1, current_declspecs, 1, $2);
cplus_decl_attributes ($<ttype>$, $4, prefix_attributes); }
init
/* Note how the declaration of the variable is in effect while its init is parsed! */
{ cp_finish_decl ($<ttype>6, $7, $3, 0, LOOKUP_ONLYCONVERTING);
$$ = $<itype>5; }
| declarator exception_specification_opt maybeasm maybe_attribute
{ tree d;
split_specs_attrs ($<ttype>0, ¤t_declspecs,
&prefix_attributes);
if (TREE_CODE (current_declspecs) != TREE_LIST)
current_declspecs = get_decl_list (current_declspecs);
if (have_extern_spec && !used_extern_spec)
{
current_declspecs = decl_tree_cons
(NULL_TREE, get_identifier ("extern"),
current_declspecs);
used_extern_spec = 1;
}
$$ = suspend_momentary ();
d = start_decl ($<ttype>1, current_declspecs, 0, $2);
cplus_decl_attributes (d, $4, prefix_attributes);
cp_finish_decl (d, NULL_TREE, $3, 0, 0); }
;
initdcl:
declarator exception_specification_opt maybeasm maybe_attribute '='
{ $<ttype>$ = start_decl ($<ttype>1, current_declspecs, 1, $2);
cplus_decl_attributes ($<ttype>$, $4, prefix_attributes); }
init
/* Note how the declaration of the variable is in effect while its init is parsed! */
{ cp_finish_decl ($<ttype>6, $7, $3, 0, LOOKUP_ONLYCONVERTING); }
| declarator exception_specification_opt maybeasm maybe_attribute
{ $<ttype>$ = start_decl ($<ttype>1, current_declspecs, 0, $2);
cplus_decl_attributes ($<ttype>$, $4, prefix_attributes);
cp_finish_decl ($<ttype>$, NULL_TREE, $3, 0, 0); }
;
notype_initdcl0:
notype_declarator exception_specification_opt maybeasm maybe_attribute '='
{ split_specs_attrs ($<ttype>0, ¤t_declspecs,
&prefix_attributes);
$<itype>5 = suspend_momentary ();
$<ttype>$ = start_decl ($<ttype>1, current_declspecs, 1, $2);
cplus_decl_attributes ($<ttype>$, $4, prefix_attributes); }
init
/* Note how the declaration of the variable is in effect while its init is parsed! */
{ cp_finish_decl ($<ttype>6, $7, $3, 0, LOOKUP_ONLYCONVERTING);
$$ = $<itype>5; }
| notype_declarator exception_specification_opt maybeasm maybe_attribute
{ tree d;
split_specs_attrs ($<ttype>0, ¤t_declspecs,
&prefix_attributes);
$$ = suspend_momentary ();
d = start_decl ($<ttype>1, current_declspecs, 0, $2);
cplus_decl_attributes (d, $4, prefix_attributes);
cp_finish_decl (d, NULL_TREE, $3, 0, 0); }
;
nomods_initdcl0:
notype_declarator exception_specification_opt maybeasm maybe_attribute '='
{ current_declspecs = NULL_TREE;
prefix_attributes = NULL_TREE;
$<itype>5 = suspend_momentary ();
$<ttype>$ = start_decl ($1, current_declspecs, 1, $2);
cplus_decl_attributes ($<ttype>$, $4, prefix_attributes); }
init
/* Note how the declaration of the variable is in effect while its init is parsed! */
{ cp_finish_decl ($<ttype>6, $7, $3, 0, LOOKUP_ONLYCONVERTING);
$$ = $<itype>5; }
| notype_declarator exception_specification_opt maybeasm maybe_attribute
{ tree d;
current_declspecs = NULL_TREE;
prefix_attributes = NULL_TREE;
$$ = suspend_momentary ();
d = start_decl ($1, current_declspecs, 0, $2);
cplus_decl_attributes (d, $4, prefix_attributes);
cp_finish_decl (d, NULL_TREE, $3, 0, 0); }
;
/* the * rules are dummies to accept the Apollo extended syntax
so that the header files compile. */
maybe_attribute:
/* empty */
{ $$ = NULL_TREE; }
| attributes
{ $$ = $1; }
;
attributes:
attribute
{ $$ = $1; }
| attributes attribute
{ $$ = chainon ($1, $2); }
;
attribute:
ATTRIBUTE '(' '(' attribute_list ')' ')'
{ $$ = $4; }
;
attribute_list:
attrib
{ $$ = $1; }
| attribute_list ',' attrib
{ $$ = chainon ($1, $3); }
;
attrib:
/* empty */
{ $$ = NULL_TREE; }
| any_word
{ $$ = build_tree_list ($1, NULL_TREE); }
| any_word '(' IDENTIFIER ')'
{ $$ = build_tree_list ($1, build_tree_list (NULL_TREE, $3)); }
| any_word '(' IDENTIFIER ',' nonnull_exprlist ')'
{ $$ = build_tree_list ($1, tree_cons (NULL_TREE, $3, $5)); }
| any_word '(' nonnull_exprlist ')'
{ $$ = build_tree_list ($1, $3); }
;
/* This still leaves out most reserved keywords,
shouldn't we include them? */
any_word:
identifier
| SCSPEC
| TYPESPEC
| TYPE_QUAL
;
/* A nonempty list of identifiers, including typenames. */
identifiers_or_typenames:
identifier
{ $$ = build_tree_list (NULL_TREE, $1); }
| identifiers_or_typenames ',' identifier
{ $$ = chainon ($1, build_tree_list (NULL_TREE, $3)); }
;
maybe_init:
%prec EMPTY /* empty */
{ $$ = NULL_TREE; }
| '=' init
{ $$ = $2; }
init:
expr_no_commas %prec '='
| '{' '}'
{ $$ = build_nt (CONSTRUCTOR, NULL_TREE, NULL_TREE);
TREE_HAS_CONSTRUCTOR ($$) = 1; }
| '{' initlist '}'
{ $$ = build_nt (CONSTRUCTOR, NULL_TREE, nreverse ($2));
TREE_HAS_CONSTRUCTOR ($$) = 1; }
| '{' initlist ',' '}'
{ $$ = build_nt (CONSTRUCTOR, NULL_TREE, nreverse ($2));
TREE_HAS_CONSTRUCTOR ($$) = 1; }
| error
{ $$ = NULL_TREE; }
;
/* This chain is built in reverse order,
and put in forward order where initlist is used. */
initlist:
init
{ $$ = build_tree_list (NULL_TREE, $$); }
| initlist ',' init
{ $$ = tree_cons (NULL_TREE, $3, $$); }
/* These are for labeled elements. */
| '[' expr_no_commas ']' init
{ $$ = build_tree_list ($2, $4); }
| initlist ',' CASE expr_no_commas ':' init
{ $$ = tree_cons ($4, $6, $$); }
| identifier ':' init
{ $$ = build_tree_list ($$, $3); }
| initlist ',' identifier ':' init
{ $$ = tree_cons ($3, $5, $$); }
;
structsp:
ENUM identifier '{'
{ $<itype>3 = suspend_momentary ();
$$ = start_enum ($2); }
enumlist maybecomma_warn '}'
{ $$ = finish_enum ($<ttype>4, $5);
resume_momentary ((int) $<itype>3);
check_for_missing_semicolon ($<ttype>4); }
| ENUM identifier '{' '}'
{ $$ = finish_enum (start_enum ($2), NULL_TREE);
check_for_missing_semicolon ($$); }
| ENUM '{'
{ $<itype>2 = suspend_momentary ();
$$ = start_enum (make_anon_name ()); }
enumlist maybecomma_warn '}'
{ $$ = finish_enum ($<ttype>3, $4);
resume_momentary ((int) $<itype>1);
check_for_missing_semicolon ($<ttype>3); }
| ENUM '{' '}'
{ $$ = finish_enum (start_enum (make_anon_name()), NULL_TREE);
check_for_missing_semicolon ($$); }
| ENUM identifier
{ $$ = xref_tag (enum_type_node, $2, NULL_TREE, 1); }
| ENUM complex_type_name
{ $$ = xref_tag (enum_type_node, $2, NULL_TREE, 1); }
| TYPENAME_KEYWORD complex_type_name
{ $$ = $2; }
/* C++ extensions, merged with C to avoid shift/reduce conflicts */
| class_head left_curly opt.component_decl_list '}'
{
int semi;
tree id;
#if 0
/* Need to rework class nesting in the
presence of nested classes, etc. */
shadow_tag (CLASSTYPE_AS_LIST ($$)); */
#endif
if (yychar == YYEMPTY)
yychar = YYLEX;
semi = yychar == ';';
/* finish_struct nukes this anyway; if
finish_exception does too, then it can go. */
if (semi)
note_got_semicolon ($$);
if (TREE_CODE ($$) == ENUMERAL_TYPE)
/* $$ = $1 from default rule. */;
else
{
$$ = finish_struct ($$, $3, semi);
if (semi) note_got_semicolon ($$);
}
pop_obstacks ();
id = TYPE_IDENTIFIER ($$);
if (id && IDENTIFIER_TEMPLATE (id))
{
tree decl;
/* I don't know if the copying of this TYPE_DECL is
* really needed. However, it's such a small per-
* formance penalty that the extra safety is a bargain.
* - niklas@appli.se
*/
push_obstacks (&permanent_obstack, &permanent_obstack);
decl = copy_node (lookup_name (id, 0));
if (DECL_LANG_SPECIFIC (decl))
copy_lang_decl (decl);
pop_obstacks ();
undo_template_name_overload (id, 0);
pushdecl_top_level (decl);
}
if (! semi)
check_for_missing_semicolon ($$); }
| class_head %prec EMPTY
{
/* struct B: public A; is not accepted by the WP grammar. */
if (TYPE_BINFO_BASETYPES ($$) && !TYPE_SIZE ($$)
&& ! TYPE_BEING_DEFINED ($$))
cp_error ("base clause without member specification for `%#T'",
$$);
}
;
maybecomma:
/* empty */
| ','
;
maybecomma_warn:
/* empty */
| ','
{ if (pedantic) pedwarn ("comma at end of enumerator list"); }
;
aggr: AGGR
| aggr SCSPEC
{ error ("storage class specifier `%s' not allowed after struct or class", IDENTIFIER_POINTER ($2)); }
| aggr TYPESPEC
{ error ("type specifier `%s' not allowed after struct or class", IDENTIFIER_POINTER ($2)); }
| aggr TYPE_QUAL
{ error ("type qualifier `%s' not allowed after struct or class", IDENTIFIER_POINTER ($2)); }
| aggr AGGR
{ error ("no body nor ';' separates two class, struct or union declarations"); }
;
specialization:
aggr template_type_name ';'
{
yyungetc (';', 1); current_aggr = $$; $$ = $2;
if ($<ttype>0 == ridpointers[(int) RID_TEMPLATE])
instantiate_class_template ($$, 2);
}
;
named_class_head_sans_basetype:
aggr identifier
{ current_aggr = $$; $$ = $2; }
| specialization
;
named_class_head_sans_basetype_defn:
aggr identifier_defn %prec EMPTY
{ current_aggr = $$; $$ = $2; }
| aggr template_type_name '{'
{ yyungetc ('{', 1);
aggr2:
current_aggr = $$;
$$ = $2;
overload_template_name ($$, 0); }
| aggr template_type_name ':'
{ yyungetc (':', 1); goto aggr2; }
;
named_complex_class_head_sans_basetype:
aggr nested_name_specifier identifier
{ current_aggr = $$; $$ = $3; }
| aggr template_type %prec EMPTY
{ current_aggr = $$; $$ = $2; }
;
do_xref_defn: /* empty */ %prec EMPTY
{ $<ttype>$ = xref_tag (current_aggr, $<ttype>0, NULL_TREE, 0); }
;
named_class_head:
named_class_head_sans_basetype %prec EMPTY
{ $$ = xref_tag (current_aggr, $1, NULL_TREE, 1); }
| named_class_head_sans_basetype_defn do_xref_defn
maybe_base_class_list %prec EMPTY
{
$$ = $<ttype>2;
if ($3)
xref_basetypes (current_aggr, $1, $<ttype>2, $3);
}
| named_complex_class_head_sans_basetype maybe_base_class_list
{
$$ = TREE_TYPE ($1);
if ($2)
xref_basetypes (current_aggr, $1, TREE_TYPE ($1), $2);
}
;
unnamed_class_head: aggr '{'
{ $$ = xref_tag ($$, make_anon_name (), NULL_TREE, 0);
yyungetc ('{', 1); }
;
class_head: unnamed_class_head | named_class_head ;
maybe_base_class_list:
%prec EMPTY /* empty */
{ $$ = NULL_TREE; }
| ':' see_typename %prec EMPTY
{ yyungetc(':', 1); $$ = NULL_TREE; }
| ':' see_typename base_class_list %prec EMPTY
{ $$ = $3; }
;
base_class_list:
base_class
| base_class_list ',' see_typename base_class
{ $$ = chainon ($$, $4); }
;
base_class:
base_class.1
{
tree type;
type = IDENTIFIER_TYPE_VALUE ($$);
if (! is_aggr_typedef ($$, 1))
$$ = NULL_TREE;
else if (current_aggr == signature_type_node
&& (! type) && (! IS_SIGNATURE (type)))
{
error ("class name not allowed as base signature");
$$ = NULL_TREE;
}
else if (current_aggr == signature_type_node)
{
sorry ("signature inheritance, base type `%s' ignored",
IDENTIFIER_POINTER ($$));
$$ = build_tree_list ((tree)access_public, $$);
}
else if (type && IS_SIGNATURE (type))
{
error ("signature name not allowed as base class");
$$ = NULL_TREE;
}
else
$$ = build_tree_list ((tree)access_default, $$);
}
| base_class_access_list see_typename base_class.1
{
tree type;
type = IDENTIFIER_TYPE_VALUE ($3);
if (current_aggr == signature_type_node)
error ("access and source specifiers not allowed in signature");
if (! is_aggr_typedef ($3, 1))
$$ = NULL_TREE;
else if (current_aggr == signature_type_node
&& (! type) && (! IS_SIGNATURE (type)))
{
error ("class name not allowed as base signature");
$$ = NULL_TREE;
}
else if (current_aggr == signature_type_node)
{
sorry ("signature inheritance, base type `%s' ignored",
IDENTIFIER_POINTER ($$));
$$ = build_tree_list ((tree)access_public, $3);
}
else if (type && IS_SIGNATURE (type))
{
error ("signature name not allowed as base class");
$$ = NULL_TREE;
}
else
$$ = build_tree_list ((tree) $$, $3);
}
;
base_class.1:
complete_type_name
| SIGOF '(' expr ')'
{
if (current_aggr == signature_type_node)
{
if (IS_AGGR_TYPE (TREE_TYPE ($3)))
{
sorry ("`sigof' as base signature specifier");
/* need to return some dummy signature identifier */
$$ = $3;
}
else
{
error ("`sigof' applied to non-aggregate expression");
$$ = error_mark_node;
}
}
else
{
error ("`sigof' in struct or class declaration");
$$ = error_mark_node;
}
}
| SIGOF '(' type_id ')'
{
if (current_aggr == signature_type_node)
{
if (IS_AGGR_TYPE (groktypename ($3)))
{
sorry ("`sigof' as base signature specifier");
/* need to return some dummy signature identifier */
$$ = $3;
}
else
{
error ("`sigof' applied to non-aggregate expression");
$$ = error_mark_node;
}
}
else
{
error ("`sigof' in struct or class declaration");
$$ = error_mark_node;
}
}
;
base_class_access_list:
VISSPEC see_typename
| SCSPEC see_typename
{ if ($<ttype>$ != ridpointers[(int)RID_VIRTUAL])
sorry ("non-virtual access");
$$ = access_default_virtual; }
| base_class_access_list VISSPEC see_typename
{ int err = 0;
if ($2 == access_protected)
{
warning ("`protected' access not implemented");
$2 = access_public;
err++;
}
else if ($2 == access_public)
{
if ($1 == access_private)
{
mixed:
error ("base class cannot be public and private");
}
else if ($1 == access_default_virtual)
$$ = access_public_virtual;
}
else /* $2 == access_private */
{
if ($1 == access_public)
goto mixed;
else if ($1 == access_default_virtual)
$$ = access_private_virtual;
}
}
| base_class_access_list SCSPEC see_typename
{ if ($2 != ridpointers[(int)RID_VIRTUAL])
sorry ("non-virtual access");
if ($$ == access_public)
$$ = access_public_virtual;
else if ($$ == access_private)
$$ = access_private_virtual; }
;
left_curly: '{'
{ tree t = $<ttype>0;
push_obstacks_nochange ();
end_temporary_allocation ();
if (! IS_AGGR_TYPE (t))
{
t = $<ttype>0 = make_lang_type (RECORD_TYPE);
TYPE_NAME (t) = get_identifier ("erroneous type");
}
if (TYPE_SIZE (t))
duplicate_tag_error (t);
if (TYPE_SIZE (t) || TYPE_BEING_DEFINED (t))
{
t = make_lang_type (TREE_CODE (t));
pushtag (TYPE_IDENTIFIER ($<ttype>0), t, 0);
$<ttype>0 = t;
}
pushclass (t, 0);
TYPE_BEING_DEFINED (t) = 1;
/* Reset the interface data, at the earliest possible
moment, as it might have been set via a class foo;
before. */
/* Don't change signatures. */
if (! IS_SIGNATURE (t))
{
extern tree pending_vtables;
int needs_writing;
tree name = TYPE_IDENTIFIER (t);
if (! ANON_AGGRNAME_P (name))
{
CLASSTYPE_INTERFACE_ONLY (t) = interface_only;
SET_CLASSTYPE_INTERFACE_UNKNOWN_X
(t, interface_unknown);
}
/* Record how to set the access of this class's
virtual functions. If write_virtuals == 2 or 3, then
inline virtuals are ``extern inline''. */
switch (write_virtuals)
{
case 0:
case 1:
needs_writing = 1;
break;
case 2:
needs_writing = !! value_member (name, pending_vtables);
break;
case 3:
needs_writing = ! CLASSTYPE_INTERFACE_ONLY (t)
&& CLASSTYPE_INTERFACE_KNOWN (t);
break;
default:
needs_writing = 0;
}
CLASSTYPE_VTABLE_NEEDS_WRITING (t) = needs_writing;
}
#if 0
t = TYPE_IDENTIFIER ($<ttype>0);
if (t && IDENTIFIER_TEMPLATE (t))
overload_template_name (t, 1);
#endif
}
;
opt.component_decl_list:
/* empty */
{ $$ = NULL_TREE; }
| component_decl_list
{
if (current_aggr == signature_type_node)
$$ = build_tree_list ((tree) access_public, $$);
else
$$ = build_tree_list ((tree) access_default, $$);
}
| opt.component_decl_list VISSPEC ':' component_decl_list
{
tree visspec = (tree) $2;
if (current_aggr == signature_type_node)
{
error ("access specifier not allowed in signature");
visspec = (tree) access_public;
}
$$ = chainon ($$, build_tree_list (visspec, $4));
}
| opt.component_decl_list VISSPEC ':'
{
if (current_aggr == signature_type_node)
error ("access specifier not allowed in signature");
}
;
/* Note: we no longer warn about the semicolon after a component_decl_list.
ARM $9.2 says that the semicolon is optional, and therefore allowed. */
component_decl_list:
component_decl
{ if ($$ == void_type_node) $$ = NULL_TREE;
}
| component_decl_list component_decl
{ /* In pushdecl, we created a reverse list of names
in this binding level. Make sure that the chain
of what we're trying to add isn't the item itself
(which can happen with what pushdecl's doing). */
if ($2 != NULL_TREE && $2 != void_type_node)
{
if (TREE_CHAIN ($2) != $$)
$$ = chainon ($$, $2);
else
$$ = $2;
}
}
;
component_decl:
component_decl_1 ';'
{ }
| component_decl_1 '}'
{ error ("missing ';' before right brace");
yyungetc ('}', 0); }
/* C++: handle constructors, destructors and inline functions */
/* note that INLINE is like a TYPESPEC */
| fn.def2 ':' /* base_init compstmt */
{ $$ = finish_method ($$); }
| fn.def2 TRY /* base_init compstmt */
{ $$ = finish_method ($$); }
| fn.def2 RETURN /* base_init compstmt */
{ $$ = finish_method ($$); }
| fn.def2 '{' /* nodecls compstmt */
{ $$ = finish_method ($$); }
| ';'
{ $$ = NULL_TREE; }
;
component_decl_1:
/* Do not add a "typed_declspecs declarator" rule here for
speed; we need to call grok_x_components for enums, so the
speedup would be insignificant. */
typed_declspecs components
{ $$ = grok_x_components ($1, $2); }
| declmods notype_components
{ $$ = grok_x_components ($1, $2); }
| notype_declarator exception_specification_opt maybeasm maybe_attribute maybe_init
{ $$ = grokfield ($$, NULL_TREE, $2, $5, $3,
build_tree_list ($4, NULL_TREE)); }
| ':' expr_no_commas
{ $$ = grokbitfield (NULL_TREE, NULL_TREE, $2); }
| error
{ $$ = NULL_TREE; }
/* These rules introduce a reduce/reduce conflict; in
typedef int foo, bar;
class A {
foo (bar);
};
should "A::foo" be declared as a function or "A::bar" as a data
member? In other words, is "bar" an after_type_declarator or a
parmlist? */
| typed_declspecs '(' parmlist ')' type_quals exception_specification_opt maybeasm maybe_attribute maybe_init
{ tree specs, attrs;
split_specs_attrs ($1, &specs, &attrs);
$$ = build_parse_node (CALL_EXPR, TREE_VALUE (specs),
$3, $5);
$$ = grokfield ($$, TREE_CHAIN (specs), $6, $9, $7,
build_tree_list ($8, attrs)); }
| typed_declspecs LEFT_RIGHT type_quals exception_specification_opt maybeasm maybe_attribute maybe_init
{ tree specs, attrs;
split_specs_attrs ($1, &specs, &attrs);
$$ = build_parse_node (CALL_EXPR, TREE_VALUE (specs),
empty_parms (), $3);
$$ = grokfield ($$, TREE_CHAIN (specs), $4, $7, $5,
build_tree_list ($6, attrs)); }
| using_decl
{ $$ = do_class_using_decl ($1); }
;
/* The case of exactly one component is handled directly by component_decl. */
/* ??? Huh? ^^^ */
components:
/* empty: possibly anonymous */
{ $$ = NULL_TREE; }
| component_declarator0
| components ',' component_declarator
{
/* In this context, void_type_node encodes
friends. They have been recorded elsewhere. */
if ($$ == void_type_node)
$$ = $3;
else
$$ = chainon ($$, $3);
}
;
notype_components:
/* empty: possibly anonymous */
{ $$ = NULL_TREE; }
| notype_component_declarator0
| notype_components ',' notype_component_declarator
{
/* In this context, void_type_node encodes
friends. They have been recorded elsewhere. */
if ($$ == void_type_node)
$$ = $3;
else
$$ = chainon ($$, $3);
}
;
component_declarator0:
after_type_component_declarator0
| notype_component_declarator0
;
component_declarator:
after_type_component_declarator
| notype_component_declarator
;
after_type_component_declarator0:
after_type_declarator exception_specification_opt maybeasm maybe_attribute maybe_init
{ split_specs_attrs ($<ttype>0, ¤t_declspecs,
&prefix_attributes);
$<ttype>0 = current_declspecs;
$$ = grokfield ($$, current_declspecs, $2, $5, $3,
build_tree_list ($4, prefix_attributes)); }
| TYPENAME ':' expr_no_commas maybe_attribute
{ split_specs_attrs ($<ttype>0, ¤t_declspecs,
&prefix_attributes);
$<ttype>0 = current_declspecs;
$$ = grokbitfield ($$, current_declspecs, $3);
cplus_decl_attributes ($$, $4, prefix_attributes); }
;
notype_component_declarator0:
notype_declarator exception_specification_opt maybeasm maybe_attribute maybe_init
{ split_specs_attrs ($<ttype>0, ¤t_declspecs,
&prefix_attributes);
$<ttype>0 = current_declspecs;
$$ = grokfield ($$, current_declspecs, $2, $5, $3,
build_tree_list ($4, prefix_attributes)); }
| IDENTIFIER ':' expr_no_commas maybe_attribute
{ split_specs_attrs ($<ttype>0, ¤t_declspecs,
&prefix_attributes);
$<ttype>0 = current_declspecs;
$$ = grokbitfield ($$, current_declspecs, $3);
cplus_decl_attributes ($$, $4, prefix_attributes); }
| ':' expr_no_commas maybe_attribute
{ split_specs_attrs ($<ttype>0, ¤t_declspecs,
&prefix_attributes);
$<ttype>0 = current_declspecs;
$$ = grokbitfield (NULL_TREE, current_declspecs, $2);
cplus_decl_attributes ($$, $3, prefix_attributes); }
;
after_type_component_declarator:
after_type_declarator exception_specification_opt maybeasm maybe_attribute maybe_init
{ $$ = grokfield ($$, current_declspecs, $2, $5, $3,
build_tree_list ($4, prefix_attributes)); }
| TYPENAME ':' expr_no_commas maybe_attribute
{ $$ = grokbitfield ($$, current_declspecs, $3);
cplus_decl_attributes ($$, $4, prefix_attributes); }
;
notype_component_declarator:
notype_declarator exception_specification_opt maybeasm maybe_attribute maybe_init
{ $$ = grokfield ($$, current_declspecs, $2, $5, $3,
build_tree_list ($4, prefix_attributes)); }
| IDENTIFIER ':' expr_no_commas maybe_attribute
{ $$ = grokbitfield ($$, current_declspecs, $3);
cplus_decl_attributes ($$, $4, prefix_attributes); }
| ':' expr_no_commas maybe_attribute
{ $$ = grokbitfield (NULL_TREE, current_declspecs, $2);
cplus_decl_attributes ($$, $3, prefix_attributes); }
;
/* We chain the enumerators in reverse order.
Because of the way enums are built, the order is
insignificant. Take advantage of this fact. */
enumlist:
enumerator
| enumlist ',' enumerator
{ TREE_CHAIN ($3) = $$; $$ = $3; }
;
enumerator:
identifier
{ $$ = build_enumerator ($$, NULL_TREE); }
| identifier '=' expr_no_commas
{ $$ = build_enumerator ($$, $3); }
;
/* ANSI new-type-id (5.3.4) */
new_type_id:
type_specifier_seq new_declarator
{ $$ = build_decl_list ($$, $2); }
| type_specifier_seq %prec EMPTY
{ $$ = build_decl_list ($$, NULL_TREE); }
/* GNU extension to allow arrays of arbitrary types with
non-constant dimension. */
| '(' type_id ')' '[' expr ']'
{
if (pedantic)
pedwarn ("ANSI C++ forbids array dimensions with parenthesized type in new");
$$ = build_parse_node (ARRAY_REF, TREE_VALUE ($2), $5);
$$ = build_decl_list (TREE_PURPOSE ($2), $$);
}
;
type_quals:
/* empty */ %prec EMPTY
{ $$ = NULL_TREE; }
| type_quals TYPE_QUAL
{ $$ = decl_tree_cons (NULL_TREE, $2, $$); }
;
nonempty_type_quals:
TYPE_QUAL
{ $$ = IDENTIFIER_AS_LIST ($$); }
| nonempty_type_quals TYPE_QUAL
{ $$ = decl_tree_cons (NULL_TREE, $2, $$); }
;
/* These rules must follow the rules for function declarations
and component declarations. That way, longer rules are preferred. */
suspend_mom:
{ $<itype>$ = suspend_momentary (); }
/* An expression which will not live on the momentary obstack. */
nonmomentary_expr:
suspend_mom expr
{ resume_momentary ((int) $<itype>1); $$ = $2; }
;
/* An expression which will not live on the momentary obstack. */
maybe_parmlist:
suspend_mom '(' nonnull_exprlist ')'
{ resume_momentary ((int) $<itype>1); $$ = $3; }
| suspend_mom '(' parmlist ')'
{ resume_momentary ((int) $<itype>1); $$ = $3; }
| suspend_mom LEFT_RIGHT
{ resume_momentary ((int) $<itype>1); $$ = empty_parms (); }
| suspend_mom '(' error ')'
{ resume_momentary ((int) $<itype>1); $$ = NULL_TREE; }
;
/* A declarator that is allowed only after an explicit typespec. */
/* may all be followed by prec '.' */
after_type_declarator:
'*' nonempty_type_quals after_type_declarator %prec UNARY
{ $$ = make_pointer_declarator ($2, $3); }
| '&' nonempty_type_quals after_type_declarator %prec UNARY
{ $$ = make_reference_declarator ($2, $3); }
| '*' after_type_declarator %prec UNARY
{ $$ = make_pointer_declarator (NULL_TREE, $2); }
| '&' after_type_declarator %prec UNARY
{ $$ = make_reference_declarator (NULL_TREE, $2); }
| ptr_to_mem type_quals after_type_declarator
{ tree arg = make_pointer_declarator ($2, $3);
$$ = build_parse_node (SCOPE_REF, $1, arg);
}
| direct_after_type_declarator
;
qualified_type_name:
type_name %prec EMPTY
{
/* Remember that this name has been used in the class
definition, as per [class.scope0] */
if (current_class_type
&& TYPE_BEING_DEFINED (current_class_type)
&& ! IDENTIFIER_CLASS_VALUE ($$))
{
tree t = lookup_name ($$, -2);
if (t)
pushdecl_class_level (t);
}
}
| nested_type
;
nested_type:
nested_name_specifier type_name %prec EMPTY
{ $$ = $2; }
;
direct_after_type_declarator:
direct_after_type_declarator maybe_parmlist type_quals %prec '.'
{ $$ = build_parse_node (CALL_EXPR, $$, $2, $3); }
| direct_after_type_declarator '[' nonmomentary_expr ']'
{ $$ = build_parse_node (ARRAY_REF, $$, $3); }
| direct_after_type_declarator '[' ']'
{ $$ = build_parse_node (ARRAY_REF, $$, NULL_TREE); }
| '(' after_type_declarator ')'
{ $$ = $2; }
| nested_name_specifier type_name %prec EMPTY
{ push_nested_class (TREE_TYPE ($$), 3);
$$ = build_parse_node (SCOPE_REF, $$, $2);
TREE_COMPLEXITY ($$) = current_class_depth; }
| type_name %prec EMPTY
;
/* A declarator allowed whether or not there has been
an explicit typespec. These cannot redeclare a typedef-name. */
notype_declarator:
'*' nonempty_type_quals notype_declarator %prec UNARY
{ $$ = make_pointer_declarator ($2, $3); }
| '&' nonempty_type_quals notype_declarator %prec UNARY
{ $$ = make_reference_declarator ($2, $3); }
| '*' notype_declarator %prec UNARY
{ $$ = make_pointer_declarator (NULL_TREE, $2); }
| '&' notype_declarator %prec UNARY
{ $$ = make_reference_declarator (NULL_TREE, $2); }
| ptr_to_mem type_quals notype_declarator
{ tree arg = make_pointer_declarator ($2, $3);
$$ = build_parse_node (SCOPE_REF, $1, arg);
}
| direct_notype_declarator
;
complex_notype_declarator:
'*' nonempty_type_quals notype_declarator %prec UNARY
{ $$ = make_pointer_declarator ($2, $3); }
| '&' nonempty_type_quals notype_declarator %prec UNARY
{ $$ = make_reference_declarator ($2, $3); }
| '*' complex_notype_declarator %prec UNARY
{ $$ = make_pointer_declarator (NULL_TREE, $2); }
| '&' complex_notype_declarator %prec UNARY
{ $$ = make_reference_declarator (NULL_TREE, $2); }
| ptr_to_mem type_quals notype_declarator
{ tree arg = make_pointer_declarator ($2, $3);
$$ = build_parse_node (SCOPE_REF, $1, arg);
}
| complex_direct_notype_declarator
;
complex_direct_notype_declarator:
direct_notype_declarator maybe_parmlist type_quals %prec '.'
{ $$ = build_parse_node (CALL_EXPR, $$, $2, $3); }
| '(' complex_notype_declarator ')'
{ $$ = $2; }
| direct_notype_declarator '[' nonmomentary_expr ']'
{ $$ = build_parse_node (ARRAY_REF, $$, $3); }
| direct_notype_declarator '[' ']'
{ $$ = build_parse_node (ARRAY_REF, $$, NULL_TREE); }
| notype_qualified_id
{ if (TREE_TYPE (OP0 ($$)) != current_class_type)
{
push_nested_class (TREE_TYPE (OP0 ($$)), 3);
TREE_COMPLEXITY ($$) = current_class_depth;
}
}
;
qualified_id:
nested_name_specifier unqualified_id
{ got_scope = NULL_TREE;
$$ = build_parse_node (SCOPE_REF, $$, $2); }
;
notype_qualified_id:
nested_name_specifier notype_unqualified_id
{ got_scope = NULL_TREE;
$$ = build_parse_node (SCOPE_REF, $$, $2); }
;
overqualified_id:
notype_qualified_id
| global_scope notype_qualified_id
{ $$ = $2; }
;
functional_cast:
typespec '(' nonnull_exprlist ')'
{ $$ = build_functional_cast ($$, $3); }
| typespec '(' expr_or_declarator ')'
{ $$ = reparse_decl_as_expr ($$, $3); }
| typespec fcast_or_absdcl %prec EMPTY
{ $$ = reparse_absdcl_as_expr ($$, $2); }
;
type_name:
TYPENAME
| template_type %prec EMPTY
;
nested_name_specifier:
nested_name_specifier_1
| nested_name_specifier nested_name_specifier_1
{ $$ = $2; }
;
/* Why the @#$%^& do type_name and notype_identifier need to be expanded
inline here?!? (jason) */
nested_name_specifier_1:
TYPENAME SCOPE
{ got_scope = TREE_TYPE ($$); }
| NSNAME SCOPE
{ got_scope = $$; }
| template_type SCOPE
{ got_scope = TREE_TYPE ($$); }
/* These break 'const i;'
| IDENTIFIER SCOPE
{
failed_scope:
cp_error ("`%D' is not an aggregate typedef",
lastiddecl ? lastiddecl : $$);
$$ = error_mark_node;
}
| PTYPENAME SCOPE
{ goto failed_scope; } */
;
complete_type_name:
qualified_type_name
| global_scope qualified_type_name
{ $$ = $2; }
;
complex_type_name:
nested_type
| global_scope qualified_type_name
{ $$ = $2; }
;
ptr_to_mem:
nested_name_specifier '*'
{ got_scope = NULL_TREE; }
| global_scope nested_name_specifier '*'
{ $$ = $2; got_scope = NULL_TREE; }
;
/* All uses of explicit global scope must go through this nonterminal so
that got_scope will be set before yylex is called to get the next token. */
global_scope:
SCOPE
{ got_scope = void_type_node; }
;
/* ANSI new-declarator (5.3.4) */
new_declarator:
'*' type_quals new_declarator
{ $$ = make_pointer_declarator ($2, $3); }
| '*' type_quals %prec EMPTY
{ $$ = make_pointer_declarator ($2, NULL_TREE); }
| '&' type_quals new_declarator %prec EMPTY
{ $$ = make_reference_declarator ($2, $3); }
| '&' type_quals %prec EMPTY
{ $$ = make_reference_declarator ($2, NULL_TREE); }
| ptr_to_mem type_quals %prec EMPTY
{ tree arg = make_pointer_declarator ($2, NULL_TREE);
$$ = build_parse_node (SCOPE_REF, $1, arg);
}
| ptr_to_mem type_quals new_declarator
{ tree arg = make_pointer_declarator ($2, $3);
$$ = build_parse_node (SCOPE_REF, $1, arg);
}
| direct_new_declarator %prec EMPTY
;
/* ANSI direct-new-declarator (5.3.4) */
direct_new_declarator:
'[' expr ']'
{ $$ = build_parse_node (ARRAY_REF, NULL_TREE, $2); }
| direct_new_declarator '[' nonmomentary_expr ']'
{ $$ = build_parse_node (ARRAY_REF, $$, $3); }
;
/* ANSI abstract-declarator (8.1) */
absdcl:
'*' nonempty_type_quals absdcl
{ $$ = make_pointer_declarator ($2, $3); }
| '*' absdcl
{ $$ = make_pointer_declarator (NULL_TREE, $2); }
| '*' nonempty_type_quals %prec EMPTY
{ $$ = make_pointer_declarator ($2, NULL_TREE); }
| '*' %prec EMPTY
{ $$ = make_pointer_declarator (NULL_TREE, NULL_TREE); }
| '&' nonempty_type_quals absdcl
{ $$ = make_reference_declarator ($2, $3); }
| '&' absdcl
{ $$ = make_reference_declarator (NULL_TREE, $2); }
| '&' nonempty_type_quals %prec EMPTY
{ $$ = make_reference_declarator ($2, NULL_TREE); }
| '&' %prec EMPTY
{ $$ = make_reference_declarator (NULL_TREE, NULL_TREE); }
| ptr_to_mem type_quals %prec EMPTY
{ tree arg = make_pointer_declarator ($2, NULL_TREE);
$$ = build_parse_node (SCOPE_REF, $1, arg);
}
| ptr_to_mem type_quals absdcl
{ tree arg = make_pointer_declarator ($2, $3);
$$ = build_parse_node (SCOPE_REF, $1, arg);
}
| direct_abstract_declarator %prec EMPTY
;
/* ANSI direct-abstract-declarator (8.1) */
direct_abstract_declarator:
'(' absdcl ')'
{ $$ = $2; }
/* `(typedef)1' is `int'. */
| PAREN_STAR_PAREN
| direct_abstract_declarator '(' parmlist ')' type_quals %prec '.'
{ $$ = build_parse_node (CALL_EXPR, $$, $3, $5); }
| direct_abstract_declarator LEFT_RIGHT type_quals %prec '.'
{ $$ = build_parse_node (CALL_EXPR, $$, empty_parms (), $3); }
| direct_abstract_declarator '[' nonmomentary_expr ']' %prec '.'
{ $$ = build_parse_node (ARRAY_REF, $$, $3); }
| direct_abstract_declarator '[' ']' %prec '.'
{ $$ = build_parse_node (ARRAY_REF, $$, NULL_TREE); }
| '(' complex_parmlist ')' type_quals %prec '.'
{ $$ = build_parse_node (CALL_EXPR, NULL_TREE, $2, $4); }
| regcast_or_absdcl type_quals %prec '.'
{ TREE_OPERAND ($$, 2) = $2; }
| fcast_or_absdcl type_quals %prec '.'
{ TREE_OPERAND ($$, 2) = $2; }
| '[' nonmomentary_expr ']' %prec '.'
{ $$ = build_parse_node (ARRAY_REF, NULL_TREE, $2); }
| '[' ']' %prec '.'
{ $$ = build_parse_node (ARRAY_REF, NULL_TREE, NULL_TREE); }
;
/* For C++, decls and stmts can be intermixed, so we don't need to
have a special rule that won't start parsing the stmt section
until we have a stmt that parses without errors. */
stmts:
stmt
| errstmt
| stmts stmt
| stmts errstmt
;
errstmt: error ';'
;
/* build the LET_STMT node before parsing its contents,
so that any LET_STMTs within the context can have their display pointers
set up to point at this one. */
.pushlevel: /* empty */
{ emit_line_note (input_filename, lineno);
pushlevel (0);
clear_last_expr ();
push_momentary ();
expand_start_bindings (0); }
;
.poplevel: /* empty */
{ expand_end_bindings (getdecls (), kept_level_p (), 1);
$$ = poplevel (kept_level_p (), 1, 0);
pop_momentary (); }
;
/* Read zero or more forward-declarations for labels
that nested functions can jump to. */
maybe_label_decls:
/* empty */
| label_decls
{ if (pedantic)
pedwarn ("ANSI C++ forbids label declarations"); }
;
label_decls:
label_decl
| label_decls label_decl
;
label_decl:
LABEL identifiers_or_typenames ';'
{ tree link;
for (link = $2; link; link = TREE_CHAIN (link))
{
tree label = shadow_label (TREE_VALUE (link));
C_DECLARED_LABEL_FLAG (label) = 1;
declare_nonlocal_label (label);
}
}
;
/* This is the body of a function definition.
It causes syntax errors to ignore to the next openbrace. */
compstmt_or_error:
compstmt
{}
| error compstmt
;
compstmt: '{' .pushlevel compstmtend .poplevel
{ $$ = $4; }
;
simple_if:
IF
{ cond_stmt_keyword = "if"; }
.pushlevel paren_cond_or_null
{ emit_line_note (input_filename, lineno);
expand_start_cond ($4, 0); }
implicitly_scoped_stmt
;
implicitly_scoped_stmt:
compstmt
{ finish_stmt (); }
| .pushlevel simple_stmt .poplevel
{ $$ = $3; }
;
stmt:
compstmt
{ finish_stmt (); }
| simple_stmt
;
simple_stmt:
decl
{ finish_stmt (); }
| expr ';'
{
tree expr = $1;
emit_line_note (input_filename, lineno);
/* Do default conversion if safe and possibly important,
in case within ({...}). */
if ((TREE_CODE (TREE_TYPE (expr)) == ARRAY_TYPE
&& lvalue_p (expr))
|| TREE_CODE (TREE_TYPE (expr)) == FUNCTION_TYPE)
expr = default_conversion (expr);
cplus_expand_expr_stmt (expr);
clear_momentary ();
finish_stmt (); }
| simple_if ELSE
{ expand_start_else (); }
implicitly_scoped_stmt
{ expand_end_cond (); }
.poplevel
{ finish_stmt (); }
| simple_if %prec IF
{ expand_end_cond ();
expand_end_bindings (getdecls (), kept_level_p (), 1);
poplevel (kept_level_p (), 1, 0);
pop_momentary ();
finish_stmt (); }
| WHILE
{ emit_nop ();
emit_line_note (input_filename, lineno);
expand_start_loop (1);
cond_stmt_keyword = "while"; }
.pushlevel paren_cond_or_null
{ expand_exit_loop_if_false (0, $4); }
already_scoped_stmt .poplevel
{ expand_end_loop ();
finish_stmt (); }
| DO
{ emit_nop ();
emit_line_note (input_filename, lineno);
expand_start_loop_continue_elsewhere (1); }
implicitly_scoped_stmt WHILE
{ expand_loop_continue_here ();
cond_stmt_keyword = "do"; }
paren_expr_or_null ';'
{ emit_line_note (input_filename, lineno);
expand_exit_loop_if_false (0, $6);
expand_end_loop ();
clear_momentary ();
finish_stmt (); }
| FOR
{ emit_line_note (input_filename, lineno);
if (flag_new_for_scope > 0)
{
/* Conditionalize .pushlevel */
pushlevel (0);
note_level_for_for ();
clear_last_expr ();
push_momentary ();
expand_start_bindings (0);
}
}
'(' for.init.statement
{ emit_nop ();
emit_line_note (input_filename, lineno);
expand_start_loop_continue_elsewhere (1); }
.pushlevel xcond ';'
{ emit_line_note (input_filename, lineno);
if ($7) expand_exit_loop_if_false (0, $7); }
xexpr ')'
/* Don't let the tree nodes for $10 be discarded
by clear_momentary during the parsing of the next stmt. */
{ push_momentary (); }
already_scoped_stmt .poplevel
{ emit_line_note (input_filename, lineno);
expand_loop_continue_here ();
if ($10) cplus_expand_expr_stmt ($10);
pop_momentary ();
expand_end_loop ();
if (flag_new_for_scope > 0)
{
expand_end_bindings (getdecls (), kept_level_p (), 1);
poplevel (kept_level_p (), 1, 0);
pop_momentary ();
}
finish_stmt (); }
| SWITCH .pushlevel '(' condition ')'
{ emit_line_note (input_filename, lineno);
c_expand_start_case ($4);
push_switch ();
/* Don't let the tree nodes for $4 be discarded by
clear_momentary during the parsing of the next stmt. */
push_momentary (); }
implicitly_scoped_stmt
{ expand_end_case ($4);
pop_momentary ();
pop_switch (); }
.poplevel
{ finish_stmt (); }
| CASE expr_no_commas ':'
{ register tree value = check_cp_case_value ($2);
register tree label
= build_decl (LABEL_DECL, NULL_TREE, NULL_TREE);
if (value != error_mark_node)
{
tree duplicate;
int success = pushcase (value, convert_and_check,
label, &duplicate);
if (success == 1)
cp_error ("case label `%E' not within a switch statement", $2);
else if (success == 2)
{
cp_error ("duplicate case value `%E'", $2);
cp_error_at ("previously used here", duplicate);
}
else if (success == 3)
warning ("case value out of range");
else if (success == 5)
cp_error ("case label `%E' within scope of cleanup or variable array", $2);
}
define_case_label (label);
}
stmt
| CASE expr_no_commas ELLIPSIS expr_no_commas ':'
{ register tree value1 = check_cp_case_value ($2);
register tree value2 = check_cp_case_value ($4);
register tree label
= build_decl (LABEL_DECL, NULL_TREE, NULL_TREE);
if (pedantic)
pedwarn ("ANSI C++ forbids range expressions in switch statement");
if (value1 != error_mark_node
&& value2 != error_mark_node)
{
tree duplicate;
int success = pushcase_range (value1, value2,
convert_and_check, label,
&duplicate);
if (success == 1)
error ("case label not within a switch statement");
else if (success == 2)
{
error ("duplicate (or overlapping) case value");
error_with_decl (duplicate, "this is the first entry overlapping that value");
}
else if (success == 3)
warning ("case value out of range");
else if (success == 4)
warning ("empty range specified");
else if (success == 5)
error ("case label within scope of cleanup or variable array");
}
define_case_label (label);
}
stmt
| DEFAULT ':'
{
tree duplicate;
register tree label
= build_decl (LABEL_DECL, NULL_TREE, NULL_TREE);
int success = pushcase (NULL_TREE, 0, label, &duplicate);
if (success == 1)
error ("default label not within a switch statement");
else if (success == 2)
{
error ("multiple default labels in one switch");
error_with_decl (duplicate, "this is the first default label");
}
define_case_label (NULL_TREE);
}
stmt
| BREAK ';'
{ emit_line_note (input_filename, lineno);
if ( ! expand_exit_something ())
error ("break statement not within loop or switch"); }
| CONTINUE ';'
{ emit_line_note (input_filename, lineno);
if (! expand_continue_loop (0))
error ("continue statement not within a loop"); }
| RETURN ';'
{ emit_line_note (input_filename, lineno);
c_expand_return (NULL_TREE); }
| RETURN expr ';'
{ emit_line_note (input_filename, lineno);
c_expand_return ($2);
finish_stmt ();
}
| asm_keyword maybe_type_qual '(' string ')' ';'
{ if (TREE_CHAIN ($4)) $4 = combine_strings ($4);
emit_line_note (input_filename, lineno);
expand_asm ($4);
finish_stmt ();
}
/* This is the case with just output operands. */
| asm_keyword maybe_type_qual '(' string ':' asm_operands ')' ';'
{ if (TREE_CHAIN ($4)) $4 = combine_strings ($4);
emit_line_note (input_filename, lineno);
c_expand_asm_operands ($4, $6, NULL_TREE, NULL_TREE,
$2 == ridpointers[(int)RID_VOLATILE],
input_filename, lineno);
finish_stmt ();
}
/* This is the case with input operands as well. */
| asm_keyword maybe_type_qual '(' string ':' asm_operands ':' asm_operands ')' ';'
{ if (TREE_CHAIN ($4)) $4 = combine_strings ($4);
emit_line_note (input_filename, lineno);
c_expand_asm_operands ($4, $6, $8, NULL_TREE,
$2 == ridpointers[(int)RID_VOLATILE],
input_filename, lineno);
finish_stmt ();
}
/* This is the case with clobbered registers as well. */
| asm_keyword maybe_type_qual '(' string ':' asm_operands ':'
asm_operands ':' asm_clobbers ')' ';'
{ if (TREE_CHAIN ($4)) $4 = combine_strings ($4);
emit_line_note (input_filename, lineno);
c_expand_asm_operands ($4, $6, $8, $10,
$2 == ridpointers[(int)RID_VOLATILE],
input_filename, lineno);
finish_stmt ();
}
| GOTO '*' expr ';'
{ emit_line_note (input_filename, lineno);
expand_computed_goto ($3); }
| GOTO identifier ';'
{ tree decl;
emit_line_note (input_filename, lineno);
decl = lookup_label ($2);
TREE_USED (decl) = 1;
expand_goto (decl); }
| label_colon stmt
{ finish_stmt (); }
| label_colon '}'
{ error ("label must be followed by statement");
yyungetc ('}', 0);
finish_stmt (); }
| ';'
{ finish_stmt (); }
| try_block
;
function_try_block:
TRY
{
if (! current_function_parms_stored)
store_parm_decls ();
expand_start_early_try_stmts ();
}
ctor_initializer_opt compstmt_or_error
{ expand_end_try_stmts ();
expand_start_all_catch (); }
handler_seq
{
expand_end_all_catch ();
finish_function (lineno, (int)$3, 0);
}
;
try_block:
TRY
{ expand_start_try_stmts (); }
compstmt
{ expand_end_try_stmts ();
expand_start_all_catch (); }
handler_seq
{ expand_end_all_catch (); }
;
handler_seq:
/* empty */
| handler_seq CATCH .pushlevel
{ dont_allow_type_definitions = "inside exception declarations"; }
handler_args
{ dont_allow_type_definitions = 0; }
compstmt
{ expand_end_catch_block (); }
.poplevel
;
type_specifier_seq:
typed_typespecs %prec EMPTY
| nonempty_type_quals %prec EMPTY
;
handler_args:
'(' ELLIPSIS ')'
{ expand_start_catch_block (NULL_TREE, NULL_TREE); }
/* This doesn't allow reference parameters, the below does.
| '(' type_specifier_seq absdcl ')'
{ expand_start_catch_block ($2, $3); }
| '(' type_specifier_seq ')'
{ expand_start_catch_block ($2, NULL_TREE); }
| '(' type_specifier_seq notype_declarator ')'
{ expand_start_catch_block ($2, $3); }
| '(' typed_typespecs after_type_declarator ')'
{ expand_start_catch_block ($2, $3); }
This allows reference parameters... */
| '(' parm ')'
{ expand_start_catch_block (TREE_PURPOSE ($2),
TREE_VALUE ($2)); }
;
label_colon:
IDENTIFIER ':'
{ tree label;
do_label:
label = define_label (input_filename, lineno, $1);
if (label)
expand_label (label);
}
| PTYPENAME ':'
{ goto do_label; }
| TYPENAME ':'
{ goto do_label; }
;
for.init.statement:
xexpr ';'
{ if ($1) cplus_expand_expr_stmt ($1); }
| decl
| '{' compstmtend
;
/* Either a type-qualifier or nothing. First thing in an `asm' statement. */
maybe_type_qual:
/* empty */
{ emit_line_note (input_filename, lineno);
$$ = NULL_TREE; }
| TYPE_QUAL
{ emit_line_note (input_filename, lineno); }
;
xexpr:
/* empty */
{ $$ = NULL_TREE; }
| expr
| error
{ $$ = NULL_TREE; }
;
/* These are the operands other than the first string and colon
in asm ("addextend %2,%1": "=dm" (x), "0" (y), "g" (*x)) */
asm_operands: /* empty */
{ $$ = NULL_TREE; }
| nonnull_asm_operands
;
nonnull_asm_operands:
asm_operand
| nonnull_asm_operands ',' asm_operand
{ $$ = chainon ($$, $3); }
;
asm_operand:
STRING '(' expr ')'
{ $$ = build_tree_list ($$, $3); }
;
asm_clobbers:
STRING
{ $$ = tree_cons (NULL_TREE, $$, NULL_TREE); }
| asm_clobbers ',' STRING
{ $$ = tree_cons (NULL_TREE, $3, $$); }
;
/* This is what appears inside the parens in a function declarator.
Its value is represented in the format that grokdeclarator expects.
In C++, declaring a function with no parameters
means that that function takes *no* parameters. */
parmlist: /* empty */
{
if (strict_prototype)
$$ = void_list_node;
else
$$ = NULL_TREE;
}
| complex_parmlist
| type_id
{ $$ = tree_cons (NULL_TREE, $$, void_list_node);
TREE_PARMLIST ($$) = 1; }
;
/* This nonterminal does not include the common sequence '(' type_id ')',
as it is ambiguous and must be disambiguated elsewhere. */
complex_parmlist:
parms
{
$$ = chainon ($$, void_list_node);
TREE_PARMLIST ($$) = 1;
}
| parms_comma ELLIPSIS
{
TREE_PARMLIST ($$) = 1;
}
/* C++ allows an ellipsis without a separating ',' */
| parms ELLIPSIS
{
TREE_PARMLIST ($$) = 1;
}
| type_id ELLIPSIS
{
$$ = build_tree_list (NULL_TREE, $$);
TREE_PARMLIST ($$) = 1;
}
| ELLIPSIS
{
/* ARM $8.2.5 has this as a boxed-off comment. */
if (pedantic)
warning ("use of `...' without a first argument is non-portable");
$$ = NULL_TREE;
}
| TYPENAME_ELLIPSIS
{
TREE_PARMLIST ($$) = 1;
}
| parms TYPENAME_ELLIPSIS
{
TREE_PARMLIST ($$) = 1;
}
| type_id TYPENAME_ELLIPSIS
{
$$ = build_tree_list (NULL_TREE, $$);
TREE_PARMLIST ($$) = 1;
}
| parms ':'
{
/* This helps us recover from really nasty
parse errors, for example, a missing right
parenthesis. */
yyerror ("possibly missing ')'");
$$ = chainon ($$, void_list_node);
TREE_PARMLIST ($$) = 1;
yyungetc (':', 0);
yychar = ')';
}
| type_id ':'
{
/* This helps us recover from really nasty
parse errors, for example, a missing right
parenthesis. */
yyerror ("possibly missing ')'");
$$ = tree_cons (NULL_TREE, $$, void_list_node);
TREE_PARMLIST ($$) = 1;
yyungetc (':', 0);
yychar = ')';
}
;
/* A nonempty list of parameter declarations or type names. */
parms:
named_parm
{ $$ = build_tree_list (NULL_TREE, $$); }
| parm '=' init
{ $$ = build_tree_list ($3, $$); }
| parms_comma full_parm
{ $$ = chainon ($$, $2); }
| parms_comma bad_parm
{ $$ = chainon ($$, build_tree_list (NULL_TREE, $2)); }
| parms_comma bad_parm '=' init
{ $$ = chainon ($$, build_tree_list ($4, $2)); }
;
parms_comma:
parms ','
| type_id ','
{ $$ = build_tree_list (NULL_TREE, $$); }
;
/* A single parameter declaration or parameter type name,
as found in a parmlist. The first four cases make up for 10%
of the time spent parsing C++. We cannot use them because
of `int id[]' which won't get parsed properly. */
named_parm:
/*
typed_declspecs dont_see_typename '*' IDENTIFIER
{ tree specs = strip_attrs ($1);
$$ = build_tree_list (specs, build_parse_node (INDIRECT_REF, $4));
see_typename (); }
| typed_declspecs dont_see_typename '&' IDENTIFIER
{ tree specs = strip_attrs ($1);
$$ = build_tree_list (specs, build_parse_node (ADDR_EXPR, $4));
see_typename (); }
| TYPENAME IDENTIFIER
{ $$ = build_tree_list (get_decl_list ($$), $2); }
| TYPESPEC IDENTIFIER
{ $$ = build_tree_list (get_decl_list ($$), $2); }
| */
/* Here we expand typed_declspecs inline to avoid mis-parsing of
TYPESPEC IDENTIFIER. */
typed_declspecs1 declarator
{ tree specs = strip_attrs ($1);
$$ = build_tree_list (specs, $2); }
| typed_typespecs declarator
{ $$ = build_tree_list ($$, $2); }
| typespec declarator
{ $$ = build_tree_list (get_decl_list ($$), $2); }
| typed_declspecs1 absdcl
{ tree specs = strip_attrs ($1);
$$ = build_tree_list (specs, $2); }
| typed_declspecs1 %prec EMPTY
{ tree specs = strip_attrs ($1);
$$ = build_tree_list (specs, NULL_TREE); }
| declmods notype_declarator
{ tree specs = strip_attrs ($1);
$$ = build_tree_list (specs, $2); }
;
full_parm:
parm maybe_init
{ $$ = build_tree_list ($2, $$); }
;
parm:
named_parm
| type_id
;
see_typename: %prec EMPTY
{ see_typename (); }
;
/*
dont_see_typename: %prec EMPTY
{ dont_see_typename (); }
;
try_for_typename:
{
if ($<ttype>-1 == error_mark_node)
$$ = 0;
else
{
$$ = 1;
pushclass ($<ttype>-1, 1);
}
}
;
*/
bad_parm:
/* empty */ %prec EMPTY
{
error ("type specifier omitted for parameter");
$$ = build_tree_list (integer_type_node, NULL_TREE);
}
| notype_declarator
{
error ("type specifier omitted for parameter");
$$ = build_tree_list (integer_type_node, $$);
}
;
exception_specification_opt:
%prec EMPTY /* empty */
{ $$ = NULL_TREE; }
| THROW '(' ansi_raise_identifiers ')' %prec EMPTY
{ $$ = $3; }
| THROW LEFT_RIGHT %prec EMPTY
{ $$ = build_decl_list (NULL_TREE, NULL_TREE); }
;
ansi_raise_identifier:
type_id
{ $$ = build_decl_list (NULL_TREE, groktypename($$)); }
;
ansi_raise_identifiers:
ansi_raise_identifier
| ansi_raise_identifiers ',' ansi_raise_identifier
{
TREE_CHAIN ($3) = $$;
$$ = $3;
}
;
conversion_declarator:
/* empty */ %prec EMPTY
{ $$ = NULL_TREE; }
| '*' type_quals conversion_declarator
{ $$ = make_pointer_declarator ($2, $3); }
| '&' type_quals conversion_declarator
{ $$ = make_reference_declarator ($2, $3); }
| ptr_to_mem type_quals conversion_declarator
{ tree arg = make_pointer_declarator ($2, $3);
$$ = build_parse_node (SCOPE_REF, $1, arg);
}
;
operator: OPERATOR
{ got_scope = NULL_TREE; }
;
operator_name:
operator '*'
{ $$ = ansi_opname[MULT_EXPR]; }
| operator '/'
{ $$ = ansi_opname[TRUNC_DIV_EXPR]; }
| operator '%'
{ $$ = ansi_opname[TRUNC_MOD_EXPR]; }
| operator '+'
{ $$ = ansi_opname[PLUS_EXPR]; }
| operator '-'
{ $$ = ansi_opname[MINUS_EXPR]; }
| operator '&'
{ $$ = ansi_opname[BIT_AND_EXPR]; }
| operator '|'
{ $$ = ansi_opname[BIT_IOR_EXPR]; }
| operator '^'
{ $$ = ansi_opname[BIT_XOR_EXPR]; }
| operator '~'
{ $$ = ansi_opname[BIT_NOT_EXPR]; }
| operator ','
{ $$ = ansi_opname[COMPOUND_EXPR]; }
| operator ARITHCOMPARE
{ $$ = ansi_opname[$2]; }
| operator '<'
{ $$ = ansi_opname[LT_EXPR]; }
| operator '>'
{ $$ = ansi_opname[GT_EXPR]; }
| operator EQCOMPARE
{ $$ = ansi_opname[$2]; }
| operator ASSIGN
{ $$ = ansi_assopname[$2]; }
| operator '='
{ $$ = ansi_opname [MODIFY_EXPR]; }
| operator LSHIFT
{ $$ = ansi_opname[$2]; }
| operator RSHIFT
{ $$ = ansi_opname[$2]; }
| operator PLUSPLUS
{ $$ = ansi_opname[POSTINCREMENT_EXPR]; }
| operator MINUSMINUS
{ $$ = ansi_opname[PREDECREMENT_EXPR]; }
| operator ANDAND
{ $$ = ansi_opname[TRUTH_ANDIF_EXPR]; }
| operator OROR
{ $$ = ansi_opname[TRUTH_ORIF_EXPR]; }
| operator '!'
{ $$ = ansi_opname[TRUTH_NOT_EXPR]; }
| operator '?' ':'
{ $$ = ansi_opname[COND_EXPR]; }
| operator MIN_MAX
{ $$ = ansi_opname[$2]; }
| operator POINTSAT %prec EMPTY
{ $$ = ansi_opname[COMPONENT_REF]; }
| operator POINTSAT_STAR %prec EMPTY
{ $$ = ansi_opname[MEMBER_REF]; }
| operator LEFT_RIGHT
{ $$ = ansi_opname[CALL_EXPR]; }
| operator '[' ']'
{ $$ = ansi_opname[ARRAY_REF]; }
| operator NEW %prec EMPTY
{ $$ = ansi_opname[NEW_EXPR]; }
| operator DELETE %prec EMPTY
{ $$ = ansi_opname[DELETE_EXPR]; }
| operator NEW '[' ']'
{ $$ = ansi_opname[VEC_NEW_EXPR]; }
| operator DELETE '[' ']'
{ $$ = ansi_opname[VEC_DELETE_EXPR]; }
/* Names here should be looked up in class scope ALSO. */
| operator type_specifier_seq conversion_declarator
{ $$ = grokoptypename ($2, $3); }
| operator error
{ $$ = ansi_opname[ERROR_MARK]; }
;
%%
#ifdef SPEW_DEBUG
const char *
debug_yytranslate (value)
int value;
{
return yytname[YYTRANSLATE (value)];
}
#endif
