| blob | a61b3598cb8145179a4a4689c2414b95858bf71f |
1 /* Process declarations and variables for C++ compiler.
2 Copyright (C) 1988, 1992, 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000,
3 2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008, 2009, 2010, 2011
4 Free Software Foundation, Inc.
5 Contributed by Michael Tiemann (tiemann@cygnus.com)
7 This file is part of GCC.
9 GCC is free software; you can redistribute it and/or modify
10 it under the terms of the GNU General Public License as published by
11 the Free Software Foundation; either version 3, or (at your option)
12 any later version.
14 GCC is distributed in the hope that it will be useful,
15 but WITHOUT ANY WARRANTY; without even the implied warranty of
16 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
17 GNU General Public License for more details.
19 You should have received a copy of the GNU General Public License
20 along with GCC; see the file COPYING3. If not see
21 <http://www.gnu.org/licenses/>. */
24 /* Process declarations and symbol lookup for C++ front end.
25 Also constructs types; the standard scalar types at initialization,
26 and structure, union, array and enum types when they are declared. */
28 /* ??? not all decl nodes are given the most useful possible
29 line numbers. For example, the CONST_DECLs for enum values. */
58 /* Possible cases of bad specifiers type used by bad_specifiers. */
63 BSP_FIELD /* field */
64 };
110 static tree check_special_function_return_type
118 /* The following symbols are subsumed in the cp_global_trees array, and
119 listed here individually for documentation purposes.
121 C++ extensions
122 tree wchar_decl_node;
124 tree vtable_entry_type;
125 tree delta_type_node;
126 tree __t_desc_type_node;
128 tree class_type_node;
129 tree unknown_type_node;
131 Array type `vtable_entry_type[]'
133 tree vtbl_type_node;
134 tree vtbl_ptr_type_node;
136 Namespaces,
138 tree std_node;
139 tree abi_node;
141 A FUNCTION_DECL which can call `abort'. Not necessarily the
142 one that the user will declare, but sufficient to be called
143 by routines that want to abort the program.
145 tree abort_fndecl;
147 The FUNCTION_DECL for the default `::operator delete'.
149 tree global_delete_fndecl;
151 Used by RTTI
152 tree type_info_type_node, tinfo_decl_id, tinfo_decl_type;
153 tree tinfo_var_id; */
157 /* Indicates that there is a type value in some namespace, although
158 that is not necessarily in scope at the moment. */
160 tree global_type_node;
162 /* The node that holds the "name" of the global scope. */
163 tree global_scope_name;
165 #define local_names cp_function_chain->x_local_names
167 /* A list of objects which have constructors or destructors
168 which reside in the global scope. The decl is stored in
169 the TREE_VALUE slot and the initializer is stored
170 in the TREE_PURPOSE slot. */
171 tree static_aggregates;
173 /* -- end of C++ */
175 /* A node for the integer constant 2. */
177 tree integer_two_node;
179 /* Used only for jumps to as-yet undefined labels, since jumps to
180 defined labels can have their validity checked immediately. */
184 /* The binding level to which this entry is *currently* attached.
185 This is initially the binding level in which the goto appeared,
186 but is modified as scopes are closed. */
188 /* The head of the names list that was current when the goto appeared,
189 or the inner scope popped. These are the decls that will *not* be
190 skipped when jumping to the label. */
191 tree names_in_scope;
192 /* The location of the goto, for error reporting. */
193 location_t o_goto_locus;
194 /* True if an OpenMP structured block scope has been closed since
195 the goto appeared. This means that the branch from the label will
196 illegally exit an OpenMP scope. */
198 };
200 /* A list of all LABEL_DECLs in the function that have names. Here so
201 we can clear out their names' definitions at the end of the
202 function, and so we can check the validity of jumps to these labels. */
205 /* The decl itself. */
206 tree label_decl;
208 /* The binding level to which the label is *currently* attached.
209 This is initially set to the binding level in which the label
210 is defined, but is modified as scopes are closed. */
212 /* The head of the names list that was current when the label was
213 defined, or the inner scope popped. These are the decls that will
214 be skipped when jumping to the label. */
215 tree names_in_scope;
216 /* A vector of all decls from all binding levels that would be
217 crossed by a backward branch to the label. */
220 /* A list of uses of the label, before the label is defined. */
223 /* The following bits are set after the label is defined, and are
224 updated as scopes are popped. They indicate that a backward jump
225 to the label will illegally enter a scope of the given flavor. */
229 };
231 #define named_labels cp_function_chain->x_named_labels
232 \f
233 /* The number of function bodies which we are currently processing.
234 (Zero if we are at namespace scope, one inside the body of a
235 function, two inside the body of a function in a local class, etc.) */
238 /* To avoid unwanted recursion, finish_function defers all mark_used calls
239 encountered during its execution until it finishes. */
243 /* States indicating how grokdeclarator() should handle declspecs marked
244 with __attribute__((deprecated)). An object declared as
245 __attribute__((deprecated)) suppresses warnings of uses of other
246 deprecated items. */
249 \f
250 /* A list of VAR_DECLs whose type was incomplete at the time the
251 variable was declared. */
254 tree decl;
255 tree incomplete_type;
262 \f
263 /* Returns the kind of template specialization we are currently
264 processing, given that it's declaration contained N_CLASS_SCOPES
265 explicit scope qualifications. */
267 tmpl_spec_kind
269 {
275 /* Scan through the template parameter scopes. */
279 {
280 /* If we see a specialization scope inside a parameter scope,
281 then something is wrong. That corresponds to a declaration
282 like:
284 template <class T> template <> ...
286 which is always invalid since [temp.expl.spec] forbids the
287 specialization of a class member template if the enclosing
288 class templates are not explicitly specialized as well. */
290 {
293 else
295 }
300 }
302 /* Handle explicit instantiations. */
304 {
306 /* We've seen a template parameter list during an explicit
307 instantiation. For example:
309 template <class T> template void f(int);
311 This is erroneous. */
313 else
315 }
318 /* We've not seen enough template headers to match all the
319 specialized classes present. For example:
321 template <class T> void R<T>::S<T>::f(int);
323 This is invalid; there needs to be one set of template
324 parameters for each class. */
327 /* We're processing a non-template declaration (even though it may
328 be a member of a template class.) For example:
330 template <class T> void S<T>::f(int);
332 The `class T' matches the `S<T>', leaving no template headers
333 corresponding to the `f'. */
336 /* We've got too many template headers. For example:
338 template <> template <class T> void f (T);
340 There need to be more enclosing classes. */
342 else
343 /* This must be a template. It's of the form:
345 template <class T> template <class U> void S<T>::f(U);
347 This is a specialization if the innermost level was a
348 specialization; otherwise it's just a definition of the
349 template. */
351 }
353 /* Exit the current scope. */
355 void
357 {
359 }
361 /* When a label goes out of scope, check to see if that label was used
362 in a valid manner, and issue any appropriate warnings or errors. */
364 static void
366 {
368 {
370 {
371 location_t location;
375 /* Avoid crashing later. */
377 }
378 else
380 }
383 }
385 /* At the end of a function, all labels declared within the function
386 go out of scope. BLOCK is the top-level block for the
387 function. */
389 static int
391 {
397 /* Put the labels into the "variables" of the top-level block,
398 so debugger can see them. */
405 }
407 static void
409 {
411 {
414 }
415 }
417 /* At the end of a block with local labels, restore the outer definition. */
419 static void
421 {
430 }
432 /* The following two routines are used to interface to Objective-C++.
433 The binding level is purposely treated as an opaque type. */
437 {
439 }
441 /* The following routine is used by the NeXT-style SJLJ exceptions;
442 variables get marked 'volatile' so as to not be clobbered by
443 _setjmp()/_longjmp() calls. All variables in the current scope,
444 as well as parent scopes up to (but not including) ENCLOSING_BLK
445 shall be thusly marked. */
447 void
449 {
455 {
456 tree decl;
461 /* Do not climb up past the current function. */
464 }
465 }
467 /* Update data for defined and undefined labels when leaving a scope. */
469 static int
471 {
477 {
478 tree decl;
480 /* ENT->NAMES_IN_SCOPE may contain a mixture of DECLs and
481 TREE_LISTs representing OVERLOADs, so be careful. */
491 {
503 }
504 }
506 {
511 {
516 }
517 }
520 }
522 /* Saved errorcount to avoid -Wunused-but-set-{parameter,variable} warnings
523 when errors were reported, except for -Werror-unused-but-set-*. */
526 /* Exit a binding level.
527 Pop the level off, and restore the state of the identifier-decl mappings
528 that were in effect when this level was entered.
530 If KEEP == 1, this level had explicit declarations, so
531 and create a "block" (a BLOCK node) for the level
532 to record its declarations and subblocks for symbol table output.
534 If FUNCTIONBODY is nonzero, this level is the body of a function,
535 so create a block as if KEEP were set and also clear out all
536 label names.
538 If REVERSE is nonzero, reverse the order of decls before putting
539 them into the BLOCK. */
541 tree
543 {
544 tree link;
545 /* The chain of decls was accumulated in reverse order.
546 Put it into forward order, just for cleanliness. */
547 tree decls;
548 tree subblocks;
549 tree block;
550 tree decl;
552 scope_kind kind;
557 restart:
570 /* We used to use KEEP == 2 to indicate that the new block should go
571 at the beginning of the list of blocks at this binding level,
572 rather than the end. This hack is no longer used. */
578 /* Any uses of undefined labels, and any defined labels, now operate
579 under constraints of next binding contour. */
582 current_binding_level);
584 /* Get the decls in the order they were written.
585 Usually current_binding_level->names is in reverse order.
586 But parameter decls were previously put in forward order. */
589 current_binding_level->names
591 else
594 /* If there were any declarations or structure tags in that level,
595 or if this level is a function body,
596 create a BLOCK to record them for the life of this function. */
601 {
604 }
606 /* In each subblock, record that this is its superior. */
611 /* We still support the old for-scope rules, whereby the variables
612 in a for-init statement were in scope after the for-statement
613 ended. We only use the new rules if flag_new_for_scope is
614 nonzero. */
615 leaving_for_scope
618 /* Before we remove the declarations first check for unused variables. */
626 {
635 {
639 }
640 }
642 /* Remove declarations for all the DECLs in this level. */
644 {
646 /* It's hard to make this ARM compatibility hack play nicely with
647 lambdas, and it really isn't necessary in C++11 mode. */
650 {
653 tree ns_binding;
660 else
664 /* We have something like:
666 int i;
667 for (int i; ;);
669 and we are leaving the `for' scope. There's no reason to
670 keep the binding of the inner `i' in this case. */
674 /* Here, we have something like:
676 typedef int I;
678 void f () {
679 for (int I; ;);
680 }
682 We must pop the for-scope binding so we know what's a
683 type and what isn't. */
685 else
686 {
687 /* Mark this VAR_DECL as dead so that we can tell we left it
688 there only for backward compatibility. */
691 /* Keep track of what should have happened when we
692 popped the binding. */
694 {
697 }
699 /* Add it to the list of dead variables in the next
700 outermost binding to that we can remove these when we
701 leave that binding. */
704 link);
706 /* Although we don't pop the cxx_binding, we do clear
707 its SCOPE since the scope is going away now. */
710 }
711 }
712 else
713 {
714 tree name;
716 /* Remove the binding. */
728 }
729 }
731 /* Remove declarations for any `for' variables from inner scopes
732 that we kept around. */
737 /* Restore the IDENTIFIER_TYPE_VALUEs. */
742 /* Restore the IDENTIFIER_LABEL_VALUEs for local labels. */
748 /* There may be OVERLOADs (wrapped in TREE_LISTs) on the BLOCK_VARs
749 list if a `using' declaration put them there. The debugging
750 back ends won't understand OVERLOAD, so we remove them here.
751 Because the BLOCK_VARS are (temporarily) shared with
752 CURRENT_BINDING_LEVEL->NAMES we must do this fixup after we have
753 popped all the bindings. */
755 {
759 {
762 else
764 }
765 }
767 /* If the level being exited is the top level of a function,
768 check over all the labels. */
770 {
771 /* Since this is the top level block of a function, the vars are
772 the function's parameters. Don't leave them in the BLOCK
773 because they are found in the FUNCTION_DECL instead. */
776 }
780 {
781 tree stmt;
783 /* If this is a temporary binding created for a cleanup, then we'll
784 have pushed a statement list level. Pop that, create a new
785 BIND_EXPR for the block, and insert it into the stream. */
789 }
793 {
794 /* The current function is being defined, so its DECL_INITIAL
795 should be error_mark_node. */
798 }
800 current_binding_level->blocks
803 /* If we did not make a block for the level just exited,
804 any blocks made for inner levels
805 (since they cannot be recorded as subblocks in that level)
806 must be carried forward so they will later become subblocks
807 of something else. */
809 current_binding_level->blocks
812 /* Each and every BLOCK node created here in `poplevel' is important
813 (e.g. for proper debugging information) so if we created one
814 earlier, mark it as "used". */
818 /* All temporary bindings created for cleanups are popped silently. */
824 }
826 /* Walk all the namespaces contained NAMESPACE, including NAMESPACE
827 itself, calling F for each. The DATA is passed to F as well. */
829 static int
831 {
841 }
843 /* Walk all the namespaces, calling F for each. The DATA is passed to
844 F as well. */
846 int
848 {
850 }
852 /* Call wrapup_globals_declarations for the globals in NAMESPACE. If
853 DATA is non-NULL, this is the last time we will call
854 wrapup_global_declarations for this NAMESPACE. */
856 int
858 {
866 {
870 }
872 /* Write out any globals that need to be output. */
874 }
876 \f
877 /* In C++, you don't have to write `struct S' to refer to `S'; you
878 can just use `S'. We accomplish this by creating a TYPE_DECL as
879 if the user had written `typedef struct S S'. Create and return
880 the TYPE_DECL for TYPE. */
882 tree
884 {
885 tree decl;
889 /* There are other implicit type declarations, like the one *within*
890 a class that allows you to write `S::S'. We must distinguish
891 amongst these. */
897 }
899 /* Remember a local name for name-mangling purposes. */
901 static void
903 {
913 {
916 {
922 else
928 }
929 }
933 }
934 \f
935 /* Subroutine of duplicate_decls: return truthvalue of whether
936 or not types of these decls match.
938 For C++, we must compare the parameter list so that `int' can match
939 `int&' in a parameter position, but `int&' is not confused with
940 `const int&'. */
942 int
944 {
951 /* If the two DECLs are not even the same kind of thing, we're not
952 interested in their types. */
956 {
962 /* Specializations of different templates are different functions
963 even if they have the same type. */
978 #ifdef NO_IMPLICIT_EXTERN_C
979 /* A new declaration doesn't match a built-in one unless it
980 is also extern "C". */
984 #endif
990 {
993 #ifndef NO_IMPLICIT_EXTERN_C
996 #endif
997 ))
998 {
1002 }
1003 #ifndef NO_IMPLICIT_EXTERN_C
1011 {
1014 }
1015 #endif
1016 else
1017 types_match =
1022 }
1023 else
1025 }
1027 {
1039 else
1042 }
1043 else
1044 {
1045 /* Need to check scope for variable declaration (VAR_DECL).
1046 For typedef (TYPE_DECL), scope is ignored. */
1049 /* [dcl.link]
1050 Two declarations for an object with C language linkage
1051 with the same name (ignoring the namespace that qualify
1052 it) that appear in different namespace scopes refer to
1053 the same object. */
1063 else
1066 COMPARE_REDECLARATION);
1067 }
1070 }
1072 /* If NEWDECL is `static' and an `extern' was seen previously,
1073 warn about it. OLDDECL is the previous declaration.
1075 Note that this does not apply to the C++ case of declaring
1076 a variable `extern const' and then later `const'.
1078 Don't complain about built-in functions, since they are beyond
1079 the user's control. */
1081 void
1083 {
1090 /* Don't get confused by static member functions; that's a different
1091 use of `static'. */
1096 /* If the old declaration was `static', or the new one isn't, then
1097 everything is OK. */
1101 /* It's OK to declare a builtin function as `static'. */
1108 }
1110 /* NEW_DECL is a redeclaration of OLD_DECL; both are functions or
1111 function templates. If their exception specifications do not
1112 match, issue a diagnostic. */
1114 static void
1116 tree old_decl)
1117 {
1118 tree new_type;
1119 tree old_type;
1120 tree new_exceptions;
1121 tree old_exceptions;
1128 /* [except.spec]
1130 If any declaration of a function has an exception-specification,
1131 all declarations, including the definition and an explicit
1132 specialization, of that function shall have an
1133 exception-specification with the same set of type-ids. */
1136 && flag_exceptions
1138 {
1140 new_decl);
1142 }
1143 }
1145 /* Return true if OLD_DECL and NEW_DECL agree on constexprness.
1146 Otherwise issue diagnostics. */
1148 static bool
1150 {
1160 {
1161 /* Hide a built-in declaration. */
1165 }
1169 }
1171 #define GNU_INLINE_P(fn) (DECL_DECLARED_INLINE_P (fn) \
1173 DECL_ATTRIBUTES (fn)))
1175 /* If NEWDECL is a redeclaration of OLDDECL, merge the declarations.
1176 If the redeclaration is invalid, a diagnostic is issued, and the
1177 error_mark_node is returned. Otherwise, OLDDECL is returned.
1179 If NEWDECL is not a redeclaration of OLDDECL, NULL_TREE is
1180 returned.
1182 NEWDECL_IS_FRIEND is true if NEWDECL was declared as a friend. */
1184 tree
1186 {
1190 tree new_template_info;
1197 /* If either the type of the new decl or the type of the old decl is an
1198 error_mark_node, then that implies that we have already issued an
1199 error (earlier) for some bogus type specification, and in that case,
1200 it is rather pointless to harass the user with yet more error message
1201 about the same declaration, so just pretend the types match here. */
1210 {
1222 {
1224 newdecl);
1227 }
1231 {
1235 olddecl);
1236 }
1237 }
1239 /* Check for redeclaration and other discrepancies. */
1242 {
1245 {
1246 /* Avoid warnings redeclaring built-ins which have not been
1247 explicitly declared. */
1251 /* If you declare a built-in or predefined function name as static,
1252 the old definition is overridden, but optionally warn this was a
1253 bad choice of name. */
1255 {
1260 /* Discard the old built-in function. */
1262 }
1263 /* If the built-in is not ansi, then programs can override
1264 it even globally without an error. */
1268 else
1269 {
1272 olddecl);
1273 }
1275 }
1277 {
1278 /* Avoid warnings redeclaring built-ins which have not been
1279 explicitly declared. */
1281 {
1282 /* Deal with fileptr_type_node. FILE type is not known
1283 at the time we create the builtins. */
1293 {
1301 {
1309 newdecl_is_friend);
1311 }
1312 }
1315 }
1320 {
1321 /* A near match; override the builtin. */
1324 {
1327 olddecl);
1328 }
1329 else
1334 }
1335 else
1336 /* Discard the old built-in function. */
1339 /* Replace the old RTL to avoid problems with inlining. */
1341 }
1342 /* Even if the types match, prefer the new declarations type for
1343 built-ins which have not been explicitly declared, for
1344 exception lists, etc... */
1346 {
1353 }
1355 /* If a function is explicitly declared "throw ()", propagate that to
1356 the corresponding builtin. */
1366 /* Whether or not the builtin can throw exceptions has no
1367 bearing on this declarator. */
1371 {
1372 /* If a builtin function is redeclared as `static', merge
1373 the declarations, but make the original one static. */
1377 /* Make the old declaration consistent with the new one so
1378 that all remnants of the builtin-ness of this function
1379 will be banished. */
1382 }
1383 }
1385 {
1386 /* C++ Standard, 3.3, clause 4:
1387 "[Note: a namespace name or a class template name must be unique
1388 in its declarative region (7.3.2, clause 14). ]" */
1395 {
1400 {
1401 /* We do nothing special here, because C++ does such nasty
1402 things with TYPE_DECLs. Instead, just let the TYPE_DECL
1403 get shadowed, and know that if we need to find a TYPE_DECL
1404 for a given name, we can look in the IDENTIFIER_TYPE_VALUE
1405 slot of the identifier. */
1407 }
1414 }
1422 }
1424 {
1426 /* These are certainly not duplicate declarations; they're
1427 from different scopes. */
1431 {
1432 /* The name of a class template may not be declared to refer to
1433 any other template, class, function, object, namespace, value,
1434 or type in the same scope. */
1437 {
1440 }
1447 /* Template functions can be disambiguated by
1448 return type. */
1451 {
1454 }
1456 }
1458 {
1460 {
1462 newdecl);
1465 }
1468 {
1472 }
1473 else
1475 }
1476 else
1477 {
1481 }
1482 }
1492 /* It's OK to have a template specialization and a non-template
1493 with the same type, or to have specializations of two
1494 different templates with the same type. Note that if one is a
1495 specialization, and the other is an instantiation of the same
1496 template, that we do not exit at this point. That situation
1497 can occur if we instantiate a template class, and then
1498 specialize one of its methods. This situation is valid, but
1499 the declarations must be merged in the usual way. */
1506 /* One of the declarations is a template instantiation, and the
1507 other is not a template at all. That's OK. */
1510 {
1511 /* In [namespace.alias] we have:
1513 In a declarative region, a namespace-alias-definition can be
1514 used to redefine a namespace-alias declared in that declarative
1515 region to refer only to the namespace to which it already
1516 refers.
1518 Therefore, if we encounter a second alias directive for the same
1519 alias, we can just ignore the second directive. */
1524 /* [namespace.alias]
1526 A namespace-name or namespace-alias shall not be declared as
1527 the name of any other entity in the same declarative region.
1528 A namespace-name defined at global scope shall not be
1529 declared as the name of any other entity in any global scope
1530 of the program. */
1534 }
1535 else
1536 {
1539 {
1546 }
1551 {
1552 /* Prototype decl follows defn w/o prototype. */
1556 }
1560 {
1561 /* [dcl.link]
1562 If two declarations of the same function or object
1563 specify different linkage-specifications ..., the program
1564 is ill-formed.... Except for functions with C++ linkage,
1565 a function declaration without a linkage specification
1566 shall not precede the first linkage specification for
1567 that function. A function can be declared without a
1568 linkage specification after an explicit linkage
1569 specification has been seen; the linkage explicitly
1570 specified in the earlier declaration is not affected by
1571 such a function declaration.
1573 DR 563 raises the question why the restrictions on
1574 functions should not also apply to objects. Older
1575 versions of G++ silently ignore the linkage-specification
1576 for this example:
1578 namespace N {
1579 extern int i;
1580 extern "C" int i;
1581 }
1583 which is clearly wrong. Therefore, we now treat objects
1584 like functions. */
1586 {
1587 /* There is no explicit linkage-specification, so we use
1588 the linkage from the previous declaration. */
1592 }
1593 else
1594 {
1599 }
1600 }
1603 ;
1605 {
1616 {
1619 {
1623 }
1624 else
1625 {
1629 olddecl);
1630 }
1631 }
1632 }
1633 }
1635 /* Do not merge an implicit typedef with an explicit one. In:
1637 class A;
1638 ...
1639 typedef class A A __attribute__ ((foo));
1641 the attribute should apply only to the typedef. */
1647 /* If new decl is `static' and an `extern' was seen previously,
1648 warn about it. */
1654 /* We have committed to returning 1 at this point. */
1656 {
1657 /* Now that functions must hold information normally held
1658 by field decls, there is extra work to do so that
1659 declaration information does not get destroyed during
1660 definition. */
1672 SET_OVERLOADED_OPERATOR_CODE
1676 /* Optionally warn about more than one declaration for the same
1677 name, but don't warn about a function declaration followed by a
1678 definition. */
1681 /* Don't warn about extern decl followed by definition. */
1683 /* Don't warn about friends, let add_friend take care of it. */
1685 {
1688 }
1691 {
1694 }
1696 }
1698 /* Deal with C++: must preserve virtual function table size. */
1700 {
1710 }
1712 /* Copy all the DECL_... slots specified in the new decl
1713 except for any that we copy here from the old type. */
1718 {
1719 tree old_result;
1720 tree new_result;
1732 {
1735 {
1738 else
1750 }
1751 else
1752 {
1758 }
1759 }
1761 /* If the new declaration is a definition, update the file and
1762 line information on the declaration, and also make
1763 the old declaration the same definition. */
1765 {
1771 {
1772 tree parm;
1778 }
1779 }
1782 }
1785 {
1786 /* Automatically handles default parameters. */
1788 tree newtype;
1793 /* Merge the data types specified in the two decls. */
1796 /* If merge_types produces a non-typedef type, just use the old type. */
1802 {
1810 /* Merge the threadprivate attribute from OLDDECL into NEWDECL. */
1813 {
1814 /* Allocate a LANG_SPECIFIC structure for NEWDECL, if needed. */
1820 }
1821 }
1823 /* Do this after calling `merge_types' so that default
1824 parameters don't confuse us. */
1832 /* Lay the type out, unless already done. */
1846 /* Merge the type qualifiers. */
1854 /* Merge deprecatedness. */
1858 /* Preserve function specific target and optimization options */
1860 {
1870 }
1872 /* Merge the initialization information. */
1875 {
1879 {
1882 }
1883 }
1885 /* Merge the section attribute.
1886 We want to issue an error if the sections conflict but that must be
1887 done later in decl_attributes since we are called before attributes
1888 are assigned. */
1893 {
1905 /* Keep the old RTL. */
1907 }
1910 {
1911 /* Keep the old RTL. We cannot keep the old RTL if the old
1912 declaration was for an incomplete object and the new
1913 declaration is not since many attributes of the RTL will
1914 change. */
1916 }
1917 }
1918 /* If cannot merge, then use the new type and qualifiers,
1919 and don't preserve the old rtl. */
1920 else
1921 {
1922 /* Clean out any memory we had of the old declaration. */
1931 }
1933 /* Merge the storage class information. */
1947 {
1956 {
1963 }
1966 {
1970 }
1975 /* If the OLDDECL is an instantiation and/or specialization,
1976 then the NEWDECL must be too. But, it may not yet be marked
1977 as such if the caller has created NEWDECL, but has not yet
1978 figured out that it is a redeclaration. */
1982 /* Don't really know how much of the language-specific
1983 values we should copy from old to new. */
1990 {
1996 }
1997 /* Only functions have these fields. */
2000 {
2009 /* DECL_THUNKS is only valid for virtual functions,
2010 otherwise it is a DECL_FRIEND_CONTEXT. */
2013 }
2014 /* Only variables have this field. */
2018 }
2021 {
2022 tree parm;
2024 /* Merge parameter attributes. */
2033 }
2037 {
2038 /* If newdecl is not a specialization, then it is not a
2039 template-related function at all. And that means that we
2040 should have exited above, returning 0. */
2044 /* From [temp.expl.spec]:
2046 If a template, a member template or the member of a class
2047 template is explicitly specialized then that
2048 specialization shall be declared before the first use of
2049 that specialization that would cause an implicit
2050 instantiation to take place, in every translation unit in
2051 which such a use occurs. */
2053 olddecl);
2057 /* Don't propagate visibility from the template to the
2058 specialization here. We'll do that in determine_visibility if
2059 appropriate. */
2062 /* [temp.expl.spec/14] We don't inline explicit specialization
2063 just because the primary template says so. */
2065 /* But still keep DECL_DISREGARD_INLINE_LIMITS in sync with
2066 the always_inline attribute. */
2069 {
2072 else
2076 }
2077 }
2079 {
2080 /* Never inline re-defined extern inline functions.
2081 FIXME: this could be better handled by keeping both
2082 function as separate declarations. */
2084 }
2085 else
2086 {
2099 }
2101 /* Preserve abstractness on cloned [cd]tors. */
2104 /* Update newdecl's parms to point at olddecl. */
2110 {
2114 }
2116 {
2117 /* These need to be copied so that the names are available.
2118 Note that if the types do match, we'll preserve inline
2119 info and other bits, but if not, we won't. */
2122 }
2124 /* If defining a function declared with other language
2125 linkage, use the previously declared language linkage. */
2128 {
2129 /* If redeclaring a builtin function, and not a definition,
2130 it stays built in. */
2132 {
2135 /* If we're keeping the built-in definition, keep the rtl,
2136 regardless of declaration matches. */
2138 }
2141 /* Don't clear out the arguments if we're just redeclaring a
2142 function. */
2145 }
2146 }
2150 /* Now preserve various other info from the definition. */
2156 /* Warn about conflicting visibility specifications. */
2160 {
2165 }
2166 /* Choose the declaration which specified visibility. */
2168 {
2171 }
2172 /* Init priority used to be merged from newdecl to olddecl by the memcpy,
2173 so keep this behavior. */
2175 {
2178 }
2179 /* Likewise for DECL_USER_ALIGN and DECL_PACKED. */
2184 /* The DECL_LANG_SPECIFIC information in OLDDECL will be replaced
2185 with that from NEWDECL below. */
2187 {
2191 }
2193 /* Merge the USED information. */
2199 {
2204 }
2211 {
2224 /* If newdecl is a template instantiation, it is possible that
2225 the following sequence of events has occurred:
2227 o A friend function was declared in a class template. The
2228 class template was instantiated.
2230 o The instantiation of the friend declaration was
2231 recorded on the instantiation list, and is newdecl.
2233 o Later, however, instantiate_class_template called pushdecl
2234 on the newdecl to perform name injection. But, pushdecl in
2235 turn called duplicate_decls when it discovered that another
2236 declaration of a global function with the same name already
2237 existed.
2239 o Here, in duplicate_decls, we decided to clobber newdecl.
2241 If we're going to do that, we'd better make sure that
2242 olddecl, and not newdecl, is on the list of
2243 instantiations so that if we try to do the instantiation
2244 again we won't get the clobbered declaration. */
2246 new_template_info,
2247 olddecl);
2248 }
2249 else
2250 {
2256 {
2264 {
2269 }
2277 }
2278 }
2283 {
2286 }
2288 /* NEWDECL contains the merged attribute lists.
2289 Update OLDDECL to be the same. */
2292 /* If OLDDECL had its DECL_RTL instantiated, re-invoke make_decl_rtl
2293 so that encode_section_info has a chance to look at the new decl
2294 flags and attributes. */
2301 /* The NEWDECL will no longer be needed. Because every out-of-class
2302 declaration of a member results in a call to duplicate_decls,
2303 freeing these nodes represents in a significant savings. */
2307 }
2308 \f
2309 /* Return zero if the declaration NEWDECL is valid
2310 when the declaration OLDDECL (assumed to be for the same name)
2311 has already been seen.
2312 Otherwise return an error message format string with a %s
2313 where the identifier should go. */
2317 {
2319 {
2320 /* Because C++ can put things into name space for free,
2321 constructs like "typedef struct foo { ... } foo"
2322 would look like an erroneous redeclaration. */
2325 else
2327 }
2329 {
2330 /* If this is a pure function, its olddecl will actually be
2331 the original initialization to `0' (which we force to call
2332 abort()). Don't complain about redefinition in this case. */
2337 /* If both functions come from different namespaces, this is not
2338 a redeclaration - this is a conflict with a used function. */
2344 /* We'll complain about linkage mismatches in
2345 warn_extern_redeclared_static. */
2347 /* Defining the same name twice is no good. */
2350 {
2356 }
2359 {
2364 {
2368 else
2371 }
2372 }
2375 }
2377 {
2381 {
2386 }
2404 {
2409 {
2413 else
2416 }
2417 }
2419 /* Core issue #226 (C++0x):
2421 If a friend function template declaration specifies a
2422 default template-argument, that declaration shall be a
2423 definition and shall be the only declaration of the
2424 function template in the translation unit. */
2434 }
2440 {
2441 /* Only variables can be thread-local, and all declarations must
2442 agree on this property. */
2446 else
2449 }
2451 {
2452 /* The objects have been declared at namespace scope. If either
2453 is a member of an anonymous union, then this is an invalid
2454 redeclaration. For example:
2456 int i;
2457 union { int i; };
2459 is invalid. */
2463 /* If at least one declaration is a reference, there is no
2464 conflict. For example:
2466 int i = 3;
2467 extern int i;
2469 is valid. */
2472 /* Reject two definitions. */
2474 }
2475 else
2476 {
2477 /* Objects declared with block scope: */
2478 /* Reject two definitions, and reject a definition
2479 together with an external reference. */
2483 }
2484 }
2485 \f
2486 /* Hash and equality functions for the named_label table. */
2488 static hashval_t
2490 {
2493 }
2495 static int
2497 {
2501 }
2503 /* Create a new label, named ID. */
2505 static tree
2507 {
2510 tree decl;
2518 /* Say where one reference is to the label, for the sake of the
2519 error if it is not defined. */
2522 /* Record the fact that this identifier is bound to this label. */
2525 /* Create the label htab for the function on demand. */
2530 /* Record this label on the list of labels used in this function.
2531 We do this before calling make_label_decl so that we get the
2532 IDENTIFIER_LABEL_VALUE before the new label is declared. */
2541 }
2543 /* Look for a label named ID in the current function. If one cannot
2544 be found, create one. (We keep track of used, but undefined,
2545 labels, and complain about them at the end of a function.) */
2547 static tree
2549 {
2550 tree decl;
2552 /* You can't use labels at global scope. */
2554 {
2557 }
2559 /* See if we've already got this label. */
2566 }
2568 /* Wrapper for lookup_label_1. */
2570 tree
2572 {
2573 tree ret;
2578 }
2580 /* Declare a local label named ID. */
2582 tree
2584 {
2585 tree decl;
2588 /* Add a new entry to the SHADOWED_LABELS list so that when we leave
2589 this scope we can restore the old value of IDENTIFIER_TYPE_VALUE. */
2598 }
2600 /* Returns nonzero if it is ill-formed to jump past the declaration of
2601 DECL. Returns 2 if it's also a real problem. */
2603 static int
2605 {
2606 /* [stmt.dcl]/3: A program that jumps from a point where a local variable
2607 with automatic storage duration is not in scope to a point where it is
2608 in scope is ill-formed unless the variable has scalar type, class type
2609 with a trivial default constructor and a trivial destructor, a
2610 cv-qualified version of one of these types, or an array of one of the
2611 preceding types and is declared without an initializer (8.5). */
2628 }
2630 /* A subroutine of check_previous_goto_1 to identify a branch to the user. */
2632 static void
2634 {
2637 else
2641 }
2643 /* Check that a single previously seen jump to a newly defined label
2644 is OK. DECL is the LABEL_DECL or 0; LEVEL is the binding_level for
2645 the jump context; NAMES are the names in scope in LEVEL at the jump
2646 context; LOCUS is the source position of the jump or 0. Returns
2647 true if all is well. */
2649 static bool
2652 {
2657 {
2661 }
2664 {
2669 {
2675 {
2678 }
2681 else
2684 }
2689 {
2691 {
2694 }
2697 else
2700 }
2702 {
2704 {
2707 }
2710 }
2711 }
2714 }
2716 static void
2718 {
2722 }
2724 static bool
2726 {
2728 }
2730 /* Check that a new jump to a label DECL is OK. Called by
2731 finish_goto_stmt. */
2733 void
2735 {
2738 tree bad;
2741 /* We can't know where a computed goto is jumping.
2742 So we assume that it's OK. */
2746 /* We didn't record any information about this label when we created it,
2747 and there's not much point since it's trivial to analyze as a return. */
2755 /* If the label hasn't been defined yet, defer checking. */
2757 {
2760 /* Don't bother creating another use if the last goto had the
2761 same data, and will therefore create the same set of errors. */
2775 }
2779 {
2783 }
2786 {
2790 {
2791 /* Can't skip init of __exception_info. */
2794 }
2797 else
2800 }
2810 {
2813 {
2817 {
2819 {
2823 }
2826 }
2827 }
2828 }
2829 }
2831 /* Check that a return is ok wrt OpenMP structured blocks.
2832 Called by finish_return_stmt. Returns true if all is well. */
2834 bool
2836 {
2840 {
2843 }
2847 }
2849 /* Define a label, specifying the location in the source file.
2850 Return the LABEL_DECL node for the label. */
2852 static tree
2854 {
2857 tree decl;
2865 /* After labels, make any new cleanups in the function go into their
2866 own new (temporary) binding contour. */
2876 {
2879 }
2880 else
2881 {
2884 /* Mark label as having been defined. */
2886 /* Say where in the source. */
2895 }
2898 }
2900 /* Wrapper for define_label_1. */
2902 tree
2904 {
2905 tree ret;
2910 }
2913 struct cp_switch
2914 {
2917 /* The SWITCH_STMT being built. */
2918 tree switch_stmt;
2919 /* A splay-tree mapping the low element of a case range to the high
2920 element, or NULL_TREE if there is no high element. Used to
2921 determine whether or not a new case label duplicates an old case
2922 label. We need a tree, rather than simply a hash table, because
2923 of the GNU case range extension. */
2924 splay_tree cases;
2925 };
2927 /* A stack of the currently active switch statements. The innermost
2928 switch statement is on the top of the stack. There is no need to
2929 mark the stack for garbage collection because it is only active
2930 during the processing of the body of a function, and we never
2931 collect at that point. */
2935 /* Called right after a switch-statement condition is parsed.
2936 SWITCH_STMT is the switch statement being parsed. */
2938 void
2940 {
2947 }
2949 void
2951 {
2953 location_t switch_location;
2955 /* Emit warnings as needed. */
2965 }
2967 /* Convert a case constant VALUE in a switch to the type TYPE of the switch
2968 condition. Note that if TYPE and VALUE are already integral we don't
2969 really do the conversion because the language-independent
2970 warning/optimization code will work better that way. */
2972 static tree
2974 {
2981 {
2985 }
2987 }
2989 /* Note that we've seen a definition of a case label, and complain if this
2990 is a bad place for one. */
2992 tree
2994 {
2997 tree type;
3000 {
3001 tree label;
3003 /* For templates, just add the case label; we'll do semantic
3004 analysis at instantiation-time. */
3007 }
3009 /* Find the condition on which this switch statement depends. */
3025 /* After labels, make any new cleanups in the function go into their
3026 own new (temporary) binding contour. */
3033 }
3034 \f
3035 /* Hash a TYPENAME_TYPE. K is really of type `tree'. */
3037 static hashval_t
3039 {
3040 hashval_t hash;
3047 }
3050 tree scope;
3051 tree name;
3052 tree template_id;
3057 /* Compare two TYPENAME_TYPEs. K1 is really of type `tree', K2 is
3058 really of type `typename_info*' */
3060 static int
3062 {
3071 }
3073 /* Build a TYPENAME_TYPE. If the type is `typename T::t', CONTEXT is
3074 the type of `T', NAME is the IDENTIFIER_NODE for `t'.
3076 Returns the new TYPENAME_TYPE. */
3080 static tree
3083 {
3084 tree t;
3085 tree d;
3086 typename_info ti;
3088 hashval_t hash;
3104 /* See if we already have this type. */
3108 else
3109 {
3110 /* Build the TYPENAME_TYPE. */
3117 /* Build the corresponding TYPE_DECL. */
3124 /* Store it in the hash table. */
3127 /* TYPENAME_TYPEs must always be compared structurally, because
3128 they may or may not resolve down to another type depending on
3129 the currently open classes. */
3131 }
3134 }
3136 /* Resolve `typename CONTEXT::NAME'. TAG_TYPE indicates the tag
3137 provided to name the type. Returns an appropriate type, unless an
3138 error occurs, in which case error_mark_node is returned. If we
3139 locate a non-artificial TYPE_DECL and TF_KEEP_TYPE_DECL is set, we
3140 return that, rather than the _TYPE it corresponds to, in other
3141 cases we look through the type decl. If TF_ERROR is set, complain
3142 about errors, otherwise be quiet. */
3144 tree
3146 tsubst_flags_t complain)
3147 {
3148 tree fullname;
3149 tree t;
3158 {
3163 else
3164 /* Create a TEMPLATE_ID_EXPR for the type. */
3168 }
3175 {
3180 {
3183 }
3184 }
3186 {
3189 }
3194 {
3198 }
3200 /* When the CONTEXT is a dependent type, NAME could refer to a
3201 dependent base class of CONTEXT. But look inside it anyway
3202 if CONTEXT is a currently open scope, in case it refers to a
3203 member of the current instantiation or a non-dependent base;
3204 lookup will stop when we hit a dependent base. */
3206 /* We should only set WANT_TYPE when we're a nested typename type.
3207 Then we can give better diagnostics if we find a non-type. */
3209 else
3218 {
3223 }
3225 /* Pull out the template from an injected-class-name (or multiple). */
3230 {
3232 {
3235 }
3237 }
3240 {
3245 }
3247 {
3252 }
3257 /* If we are currently parsing a template and if T is a typedef accessed
3258 through CONTEXT then we need to remember and check access of T at
3259 template instantiation time. */
3272 }
3274 /* Resolve `CONTEXT::template NAME'. Returns a TEMPLATE_DECL if the name
3275 can be resolved or an UNBOUND_CLASS_TEMPLATE, unless an error occurs,
3276 in which case error_mark_node is returned.
3278 If PARM_LIST is non-NULL, also make sure that the template parameter
3279 list of TEMPLATE_DECL matches.
3281 If COMPLAIN zero, don't complain about any errors that occur. */
3283 tree
3285 tsubst_flags_t complain)
3286 {
3287 tree t;
3288 tree d;
3298 {
3308 {
3312 }
3316 {
3318 {
3321 }
3323 }
3329 }
3331 /* Build the UNBOUND_CLASS_TEMPLATE. */
3337 /* Build the corresponding TEMPLATE_DECL. */
3346 }
3348 \f
3350 /* Push the declarations of builtin types into the namespace.
3351 RID_INDEX is the index of the builtin type in the array
3352 RID_POINTERS. NAME is the name used when looking up the builtin
3353 type. TYPE is the _TYPE node for the builtin type. */
3355 void
3358 tree type)
3359 {
3368 /* The calls to SET_IDENTIFIER_GLOBAL_VALUE below should be
3369 eliminated. Built-in types should not be looked up name; their
3370 names are keywords that the parser can recognize. However, there
3371 is code in c-common.c that uses identifier_global_value to look
3372 up built-in types by name. */
3374 {
3378 }
3380 {
3382 {
3385 }
3387 }
3394 }
3396 /* Record one of the standard Java types.
3397 * Declare it as having the given NAME.
3398 * If SIZE > 0, it is the size of one of the integral types;
3399 * otherwise it is the negative of the size of one of the other types. */
3401 static tree
3403 {
3406 {
3409 }
3411 {
3412 tree stype;
3413 /* "__java_char" or ""__java_boolean". */
3416 /* Get the signed type cached and attached to the unsigned type,
3417 so it doesn't get garbage-collected at "random" times,
3418 causing potential codegen differences out of different UIDs
3419 and different alias set numbers. */
3423 /*if (size == -1) TREE_SET_CODE (type, BOOLEAN_TYPE);*/
3424 }
3425 else
3430 }
3434 /* Suppress generate debug symbol entries for these types,
3435 since for normal C++ they are just clutter.
3436 However, push_lang_context undoes this if extern "Java" is seen. */
3441 }
3443 /* Push a type into the namespace so that the back ends ignore it. */
3445 static void
3447 {
3450 /* Make sure the "unknown type" typedecl gets ignored for debug info. */
3457 }
3459 /* A string for which we should create an IDENTIFIER_NODE at
3460 startup. */
3463 {
3464 /* The name of the identifier. */
3466 /* The place where the IDENTIFIER_NODE should be stored. */
3468 /* Nonzero if this is the name of a constructor or destructor. */
3472 /* Create all the predefined identifiers. */
3474 static void
3476 {
3479 /* A table of identifiers to create at startup. */
3484 /* Some of these names have a trailing space so that it is
3485 impossible for them to conflict with names written by users. */
3503 };
3506 {
3510 }
3511 }
3513 /* Create the predefined scalar types of C,
3514 and some nodes representing standard constants (0, 1, (void *)0).
3515 Initialize the global binding level.
3516 Make definitions for built-in primitive functions. */
3518 void
3520 {
3521 tree void_ftype;
3522 tree void_ftype_ptr;
3524 /* Create all the identifiers we need. */
3527 /* Create the global variables. */
3532 /* Enter the global namespace. */
3535 void_type_node);
3543 /* Initially, C. */
3546 /* Create the `std' namespace. */
3573 #if 0
3575 #endif
3584 void_ftype_ptr
3587 /* C++ extensions */
3592 /* Indirecting an UNKNOWN_TYPE node yields an UNKNOWN_TYPE node. */
3595 /* Looking up TYPE_POINTER_TO and TYPE_REFERENCE_TO yield the same
3596 result. */
3607 {
3608 /* Make sure we get a unique function type, so we can give
3609 its pointer type a name. (This wins for gdb.) */
3616 }
3619 vtbl_type_node
3635 /* Now, C++. */
3638 {
3639 tree newattrs;
3641 tree ptr_ftype_sizetype;
3642 tree new_eh_spec;
3644 ptr_ftype_sizetype
3647 {
3648 tree bad_alloc_id;
3649 tree bad_alloc_type_node;
3650 tree bad_alloc_decl;
3656 bad_alloc_decl
3661 new_eh_spec
3663 }
3664 else
3667 /* Ensure attribs.c is initialized. */
3669 newattrs
3688 }
3690 abort_fndecl
3693 /* Perform other language dependent initializations. */
3707 /* Show we use EH for cleanups. */
3710 }
3712 /* Generate an initializer for a function naming variable from
3713 NAME. NAME may be NULL, to indicate a dependent name. TYPE_P is
3714 filled in with the type of the init. */
3716 tree
3718 {
3720 tree type;
3725 {
3729 }
3738 else
3742 }
3744 /* Create the VAR_DECL for __FUNCTION__ etc. ID is the name to give
3745 the decl, LOC is the location to give the decl, NAME is the
3746 initialization string and TYPE_DEP indicates whether NAME depended
3747 on the type of the function. We make use of that to detect
3748 __PRETTY_FUNCTION__ inside a template fn. This is being done lazily
3749 at the point of first use, so we mustn't push the decl now. */
3751 static tree
3753 {
3756 tree type;
3763 /* As we're using pushdecl_with_scope, we must set the context. */
3774 {
3782 LOOKUP_ONLYCONVERTING);
3783 }
3784 else
3785 {
3788 }
3791 }
3793 static tree
3795 {
3804 /* Runtime library routines are, by definition, available in an
3805 external shared object. */
3813 else
3816 /* A function in the user's namespace should have an explicit
3817 declaration before it is used. Mark the built-in function as
3818 anticipated but not actually declared. */
3822 {
3825 /* Treat __*_chk fortification functions as anticipated as well,
3826 unless they are __builtin_*. */
3831 }
3834 }
3836 tree
3838 {
3841 /* All builtins that don't begin with an '_' should additionally
3842 go in the 'std' namespace. */
3844 {
3849 }
3852 }
3854 /* Like cxx_builtin_function, but guarantee the function is added to the global
3855 scope. This is to allow function specific options to add new machine
3856 dependent builtins when the target ISA changes via attribute((target(...)))
3857 which saves space on program startup if the program does not use non-generic
3858 ISAs. */
3860 tree
3862 {
3866 /* All builtins that don't begin with an '_' should additionally
3867 go in the 'std' namespace. */
3869 {
3874 }
3877 }
3879 /* Generate a FUNCTION_DECL with the typical flags for a runtime library
3880 function. Not called directly. */
3882 static tree
3884 {
3891 /* Runtime library routines are, by definition, available in an
3892 external shared object. */
3896 }
3898 /* Returns the _DECL for a library function with C linkage.
3899 We assume that such functions never throw; if this is incorrect,
3900 callers should unset TREE_NOTHROW. */
3902 static tree
3904 {
3908 }
3910 /* Returns the _DECL for a library function with C++ linkage. */
3912 static tree
3914 {
3920 }
3922 /* Like build_library_fn, but takes a C string instead of an
3923 IDENTIFIER_NODE. */
3925 tree
3927 {
3929 }
3931 /* Like build_cp_library_fn, but takes a C string instead of an
3932 IDENTIFIER_NODE. */
3934 tree
3936 {
3938 }
3940 /* Like build_library_fn, but also pushes the function so that we will
3941 be able to find it via IDENTIFIER_GLOBAL_VALUE. Also, the function
3942 may throw exceptions listed in RAISES. */
3944 tree
3946 {
3947 tree fn;
3955 }
3957 /* Like build_cp_library_fn, but also pushes the function so that it
3958 will be found by normal lookup. */
3960 static tree
3962 {
3964 operator_code,
3965 type);
3968 }
3970 /* Like push_library_fn, but takes a TREE_LIST of parm types rather than
3971 a FUNCTION_TYPE. */
3973 tree
3975 {
3978 }
3980 /* Like push_library_fn, but also note that this function throws
3981 and does not return. Used for __throw_foo and the like. */
3983 tree
3985 {
3990 }
3991 \f
3992 /* When we call finish_struct for an anonymous union, we create
3993 default copy constructors and such. But, an anonymous union
3994 shouldn't have such things; this function undoes the damage to the
3995 anonymous union type T.
3997 (The reason that we create the synthesized methods is that we don't
3998 distinguish `union { int i; }' from `typedef union { int i; } U'.
3999 The first is an anonymous union; the second is just an ordinary
4000 union type.) */
4002 void
4004 {
4007 /* Wipe out memory of synthesized methods. */
4015 /* Splice the implicitly generated functions out of the TYPE_METHODS
4016 list. */
4019 {
4022 else
4024 }
4026 /* ISO C++ 9.5.3. Anonymous unions may not have function members. */
4028 {
4034 else
4037 }
4039 /* Anonymous aggregates cannot have fields with ctors, dtors or complex
4040 assignment operators (because they cannot have these methods themselves).
4041 For anonymous unions this is already checked because they are not allowed
4042 in any union, otherwise we have to check it. */
4044 {
4049 {
4052 {
4062 }
4063 }
4064 }
4065 }
4067 /* Make sure that a declaration with no declarator is well-formed, i.e.
4068 just declares a tagged type or anonymous union.
4070 Returns the type declared; or NULL_TREE if none. */
4072 tree
4074 {
4077 /* If a class, struct, or enum type is declared by the DECLSPECS
4078 (i.e, if a class-specifier, enum-specifier, or non-typename
4079 elaborated-type-specifier appears in the DECLSPECS),
4080 DECLARED_TYPE is set to the corresponding type. */
4087 {
4092 }
4104 /* Check for an anonymous union. */
4107 {
4108 /* 7/3 In a simple-declaration, the optional init-declarator-list
4109 can be omitted only when declaring a class (clause 9) or
4110 enumeration (7.2), that is, when the decl-specifier-seq contains
4111 either a class-specifier, an elaborated-type-specifier with
4112 a class-key (9.1), or an enum-specifier. In these cases and
4113 whenever a class-specifier or enum-specifier is present in the
4114 decl-specifier-seq, the identifiers in these specifiers are among
4115 the names being declared by the declaration (as class-name,
4116 enum-names, or enumerators, depending on the syntax). In such
4117 cases, and except for the declaration of an unnamed bit-field (9.6),
4118 the decl-specifier-seq shall introduce one or more names into the
4119 program, or shall redeclare a name introduced by a previous
4120 declaration. [Example:
4121 enum { }; // ill-formed
4122 typedef class { }; // ill-formed
4123 --end example] */
4125 {
4128 }
4134 }
4136 else
4137 {
4144 && (!current_class_type
4162 }
4165 }
4167 /* Called when a declaration is seen that contains no names to declare.
4168 If its type is a reference to a structure, union or enum inherited
4169 from a containing scope, shadow that tag name for the current scope
4170 with a forward reference.
4171 If its type defines a new named structure or union
4172 or defines an enum, it is valid but we need not do anything here.
4173 Otherwise, it is an error.
4175 C++: may have to grok the declspecs to learn about static,
4176 complain for anonymous unions.
4178 Returns the TYPE declared -- or NULL_TREE if none. */
4180 tree
4182 {
4189 {
4194 }
4199 /* This is where the variables in an anonymous union are
4200 declared. An anonymous union declaration looks like:
4201 union { ... } ;
4202 because there is no declarator after the union, the parser
4203 sends that declaration here. */
4205 {
4209 {
4213 }
4214 }
4217 }
4218 \f
4219 /* Decode a "typename", such as "int **", returning a ..._TYPE node. */
4221 tree
4225 {
4226 tree attrs;
4227 tree type;
4228 enum decl_context context
4234 {
4239 /* A template type parameter or other dependent type. */
4242 else
4244 }
4246 }
4248 /* Process a DECLARATOR for a function-scope variable declaration,
4249 namespace-scope variable declaration, or function declaration.
4250 (Function definitions go through start_function; class member
4251 declarations appearing in the body of the class go through
4252 grokfield.) The DECL corresponding to the DECLARATOR is returned.
4253 If an error occurs, the error_mark_node is returned instead.
4255 DECLSPECS are the decl-specifiers for the declaration. INITIALIZED is
4256 SD_INITIALIZED if an explicit initializer is present, or SD_DEFAULTED
4257 for an explicitly defaulted function, or SD_DELETED for an explicitly
4258 deleted function, but 0 (SD_UNINITIALIZED) if this is a variable
4259 implicitly initialized via a default constructor. ATTRIBUTES and
4260 PREFIX_ATTRIBUTES are GNU attributes associated with this declaration.
4261 *PUSHED_SCOPE_P is set to the scope entered in this function, if any; if
4262 set, the caller is responsible for calling pop_scope. */
4264 tree
4268 tree attributes,
4269 tree prefix_attributes,
4271 {
4272 tree decl;
4273 tree context;
4280 /* An object declared as __attribute__((deprecated)) suppresses
4281 warnings of uses of other deprecated items. */
4301 /* Is it valid for this decl to have an initializer at all?
4302 If not, set INITIALIZED to zero, which will indirectly
4303 tell `cp_finish_decl' to ignore the initializer once it is parsed. */
4305 {
4312 /* We'll handle the rest of the semantics later, but we need to
4313 set this now so it's visible to duplicate_decls. */
4319 }
4322 {
4326 decl);
4330 }
4336 /* If this is a typedef that names the class for linkage purposes
4337 (7.1.3p8), apply any attributes directly to the type. */
4342 else
4345 /* Set attributes here so if duplicate decl, will have proper attributes. */
4348 /* Dllimported symbols cannot be defined. Static data members (which
4349 can be initialized in-class and dllimported) go through grokfield,
4350 not here, so we don't need to exclude those decls when checking for
4351 a definition. */
4353 {
4356 }
4358 /* If #pragma weak was used, mark the decl weak now. */
4368 {
4370 {
4374 else
4375 {
4377 {
4384 }
4390 /* Static data member are tricky; an in-class initialization
4391 still doesn't provide a definition, so the in-class
4392 declaration will have DECL_EXTERNAL set, but will have an
4393 initialization. Thus, duplicate_decls won't warn
4394 about this situation, and so we check here. */
4402 }
4403 }
4404 else
4405 {
4407 (processing_template_decl
4409 ? current_template_parms
4415 }
4417 /* cp_finish_decl sets DECL_EXTERNAL if DECL_IN_AGGR_P is set. */
4419 /* Do not mark DECL as an explicit specialization if it was not
4420 already marked as an instantiation; a declaration should
4421 never be marked as a specialization unless we know what
4422 template is being specialized. */
4424 {
4427 /* [temp.expl.spec] An explicit specialization of a static data
4428 member of a template is a definition if the declaration
4429 includes an initializer; otherwise, it is a declaration.
4431 We check for processing_specialization so this only applies
4432 to the new specialization syntax. */
4435 }
4438 /* Aliases are definitions. */
4441 decl);
4442 }
4446 /* Enter this declaration into the symbol table. */
4454 /* Tell the back end to use or not use .common as appropriate. If we say
4455 -fconserve-space, we want this to save .data space, at the expense of
4456 wrong semantics. If we say -fno-conserve-space, we want this to
4457 produce errors about redefs; to do this we force variables into the
4458 data segment. */
4469 {
4470 /* This is a const variable with implicit 'static'. Set
4471 DECL_THIS_STATIC so we can tell it from variables that are
4472 !TREE_PUBLIC because of the anonymous namespace. */
4475 }
4481 }
4483 /* Process the declaration of a variable DECL. INITIALIZED is true
4484 iff DECL is explicitly initialized. (INITIALIZED is false if the
4485 variable is initialized via an implicitly-called constructor.)
4486 This function must be called for ordinary variables (including, for
4487 example, implicit instantiations of templates), but must not be
4488 called for template declarations. */
4490 void
4492 {
4493 tree type;
4508 /* If an explicit initializer is present, or if this is a definition
4509 of an aggregate, then we need a complete type at this point.
4510 (Scalars are always complete types, so there is nothing to
4511 check.) This code just sets COMPLETE_P; errors (if necessary)
4512 are issued below. */
4514 && !complete_p
4516 {
4518 /* We will not yet have set TREE_READONLY on DECL if the type
4519 was "const", but incomplete, before this point. But, now, we
4520 have a complete type, so we can try again. */
4522 }
4525 /* Is it valid for this decl to have an initializer at all? */
4526 {
4527 /* Don't allow initializations for incomplete types except for
4528 arrays which might be completed by the initialization. */
4534 {
4537 }
4539 {
4542 /* else we already gave an error in start_decl. */
4543 }
4544 }
4546 {
4549 else
4551 decl);
4552 /* Change the type so that assemble_variable will give
4553 DECL an rtl we can live with: (mem (const_int 0)). */
4555 }
4557 /* Create a new scope to hold this declaration if necessary.
4558 Whether or not a new scope is necessary cannot be determined
4559 until after the type has been completed; if the type is a
4560 specialization of a class template it is not until after
4561 instantiation has occurred that TYPE_HAS_NONTRIVIAL_DESTRUCTOR
4562 will be set correctly. */
4564 }
4566 /* Handle initialization of references. DECL, TYPE, and INIT have the
4567 same meaning as in cp_finish_decl. *CLEANUP must be NULL on entry,
4568 but will be set to a new CLEANUP_STMT if a temporary is created
4569 that must be destroyed subsequently.
4571 Returns an initializer expression to use to initialize DECL, or
4572 NULL if the initialization can be performed statically.
4574 Quotes on semantics can be found in ARM 8.4.3. */
4576 static tree
4579 {
4580 tree tmp;
4583 {
4589 }
4593 tf_warning_or_error);
4597 /* Note: default conversion is only called in very special cases. */
4600 /* Convert INIT to the reference type TYPE. This may involve the
4601 creation of a temporary, whose lifetime must be the same as that
4602 of the reference. If so, a DECL_EXPR for the temporary will be
4603 added just after the DECL_EXPR for DECL. That's why we don't set
4604 DECL_INITIAL for local references (instead assigning to them
4605 explicitly); we need to allow the temporary to be initialized
4606 first. */
4608 tf_warning_or_error);
4610 {
4614 }
4619 {
4622 }
4630 }
4632 /* Subroutine of check_initializer. We're initializing a DECL of
4633 std::initializer_list<T> TYPE from a braced-init-list INIT, and need to
4634 extend the lifetime of the underlying array to match that of the decl,
4635 just like for reference initialization. CLEANUP is as for
4636 grok_reference_init. */
4638 static tree
4641 {
4653 /* If the array is constant, finish_compound_literal already made it a
4654 static variable and we don't need to do anything here. */
4656 {
4661 }
4663 }
4665 /* Designated initializers in arrays are not supported in GNU C++.
4666 The parser cannot detect this error since it does not know whether
4667 a given brace-enclosed initializer is for a class type or for an
4668 array. This function checks that CE does not use a designated
4669 initializer. If it does, an error is issued. Returns true if CE
4670 is valid, i.e., does not have a designated initializer. */
4672 static bool
4675 {
4676 /* Designated initializers for array elements are not supported. */
4678 {
4679 /* The parser only allows identifiers as designated
4680 initializers. */
4685 {
4686 /* A C99 designator is OK if it matches the current index. */
4689 else
4691 }
4692 else
4693 {
4697 }
4699 }
4702 }
4704 /* When parsing `int a[] = {1, 2};' we don't know the size of the
4705 array until we finish parsing the initializer. If that's the
4706 situation we're in, update DECL accordingly. */
4708 static void
4710 {
4716 {
4717 /* do_default is really a C-ism to deal with tentative definitions.
4718 But let's leave it here to ease the eventual merge. */
4723 /* Check that there are no designated initializers in INIT, as
4724 those are not supported in GNU C++, and as the middle-end
4725 will crash if presented with a non-numeric designated
4726 initializer. */
4728 {
4731 HOST_WIDE_INT i;
4735 }
4738 {
4740 do_default);
4742 {
4745 }
4747 {
4749 {
4752 }
4753 /* If a `static' var's size isn't known, make it extern as
4754 well as static, so it does not get allocated. If it's not
4755 `static', then don't mark it extern; finish_incomplete_decl
4756 will give it a default size and it will get allocated. */
4759 }
4761 {
4764 }
4765 }
4770 }
4771 }
4773 /* Set DECL_SIZE, DECL_ALIGN, etc. for DECL (a VAR_DECL), and issue
4774 any appropriate error messages regarding the layout. */
4776 static void
4778 {
4779 tree type;
4785 /* If we haven't already layed out this declaration, do so now.
4786 Note that we must not call complete type for an external object
4787 because it's type might involve templates that we are not
4788 supposed to instantiate yet. (And it's perfectly valid to say
4789 `extern X x' for some incomplete type `X'.) */
4801 {
4802 /* An automatic variable with an incomplete type: that is an error.
4803 Don't talk about array types here, since we took care of that
4804 message in grokdeclarator. */
4807 }
4808 #if 0
4809 /* Keep this code around in case we later want to control debug info
4810 based on whether a type is "used". (jason 1999-11-11) */
4813 /* Let debugger know it should output info for this type. */
4818 #endif
4823 {
4826 else
4827 {
4830 }
4831 }
4832 }
4834 /* If a local static variable is declared in an inline function, or if
4835 we have a weak definition, we must endeavor to create only one
4836 instance of the variable at link-time. */
4838 void
4840 {
4841 /* Static data in a function with comdat linkage also has comdat
4842 linkage. */
4844 /* Don't mess with __FUNCTION__. */
4848 {
4850 {
4851 /* With weak symbols, we simply make the variable COMDAT;
4852 that will cause copies in multiple translations units to
4853 be merged. */
4855 }
4856 else
4857 {
4860 {
4861 /* Without weak symbols, we can use COMMON to merge
4862 uninitialized variables. */
4865 }
4866 else
4867 {
4868 /* While for initialized variables, we must use internal
4869 linkage -- which means that multiple copies will not
4870 be merged. */
4874 "sorry: semantics of inline function static "
4875 "data %q+#D are wrong (you%'ll wind up "
4878 " you can work around this by removing "
4880 }
4881 }
4882 }
4884 /* Set it up again; we might have set DECL_INITIAL since the last
4885 time. */
4887 }
4889 /* Issue an error message if DECL is an uninitialized const variable. */
4891 static void
4893 {
4896 /* ``Unless explicitly declared extern, a const object does not have
4897 external linkage and must be initialized. ($8.4; $12.1)'' ARM
4898 7.1.6 */
4905 {
4911 {
4912 tree defaulted_ctor;
4919 "constructor is not user-provided because it is "
4921 }
4922 }
4923 }
4924 \f
4925 /* Structure holding the current initializer being processed by reshape_init.
4926 CUR is a pointer to the current element being processed, END is a pointer
4927 after the last element present in the initializer. */
4929 {
4936 /* FIELD is a FIELD_DECL or NULL. In the former case, the value
4937 returned is the next FIELD_DECL (possibly FIELD itself) that can be
4938 initialized. If there are no more such fields, the return value
4939 will be NULL. */
4941 tree
4943 {
4951 }
4953 /* Subroutine of reshape_init_array and reshape_init_vector, which does
4954 the actual work. ELT_TYPE is the element type of the array. MAX_INDEX is an
4955 INTEGER_CST representing the size of the array minus one (the maximum index),
4956 or NULL_TREE if the array was declared without specifying the size. D is
4957 the iterator within the constructor. */
4959 static tree
4961 tsubst_flags_t complain)
4962 {
4963 tree new_init;
4968 /* The initializer for an array is always a CONSTRUCTOR. */
4972 {
4973 /* Minus 1 is used for zero sized arrays. */
4979 /* sizetype is sign extended, not zero extended. */
4980 else
4983 }
4985 /* Loop until there are no more initializers. */
4989 {
4990 tree elt_init;
4994 complain);
5001 }
5004 }
5006 /* Subroutine of reshape_init_r, processes the initializers for arrays.
5007 Parameters are the same of reshape_init_r. */
5009 static tree
5011 {
5020 }
5022 /* Subroutine of reshape_init_r, processes the initializers for vectors.
5023 Parameters are the same of reshape_init_r. */
5025 static tree
5027 {
5033 {
5036 {
5041 }
5044 }
5046 /* For a vector, we initialize it as an array of the appropriate size. */
5051 }
5053 /* Subroutine of reshape_init_r, processes the initializers for classes
5054 or union. Parameters are the same of reshape_init_r. */
5056 static tree
5058 tsubst_flags_t complain)
5059 {
5060 tree field;
5061 tree new_init;
5065 /* The initializer for a class is always a CONSTRUCTOR. */
5070 {
5071 /* [dcl.init.aggr]
5073 An initializer for an aggregate member that is an
5074 empty class shall have the form of an empty
5075 initializer-list {}. */
5077 {
5081 }
5083 }
5085 /* Loop through the initializable fields, gathering initializers. */
5087 {
5088 tree field_init;
5090 /* Handle designated initializers, as an extension. */
5092 {
5096 {
5101 }
5102 }
5104 /* If we processed all the member of the class, we are done. */
5115 /* [dcl.init.aggr]
5117 When a union is initialized with a brace-enclosed
5118 initializer, the braces shall only contain an
5119 initializer for the first member of the union. */
5124 }
5127 }
5129 /* Subroutine of reshape_init, which processes a single initializer (part of
5130 a CONSTRUCTOR). TYPE is the type of the variable being initialized, D is the
5131 iterator within the CONSTRUCTOR which points to the initializer to process.
5132 FIRST_INITIALIZER_P is true if this is the first initializer of the
5133 outermost CONSTRUCTOR node. */
5135 static tree
5137 tsubst_flags_t complain)
5138 {
5145 {
5146 /* A complex type can be initialized from one or two initializers,
5147 but braces are not elided. */
5150 {
5152 {
5155 else
5157 }
5158 }
5160 {
5166 }
5168 }
5170 /* A non-aggregate type is always initialized with a single
5171 initializer. */
5173 {
5174 /* It is invalid to initialize a non-aggregate type with a
5175 brace-enclosed initializer before C++0x.
5176 We need to check for BRACE_ENCLOSED_INITIALIZER_P here because
5177 of g++.old-deja/g++.mike/p7626.C: a pointer-to-member constant is
5178 a CONSTRUCTOR (with a record type). */
5181 {
5183 {
5187 }
5188 else
5190 }
5194 }
5196 /* [dcl.init.aggr]
5198 All implicit type conversions (clause _conv_) are considered when
5199 initializing the aggregate member with an initializer from an
5200 initializer-list. If the initializer can initialize a member,
5201 the member is initialized. Otherwise, if the member is itself a
5202 non-empty subaggregate, brace elision is assumed and the
5203 initializer is considered for the initialization of the first
5204 member of the subaggregate. */
5206 /* But don't try this for the first initializer, since that would be
5207 looking through the outermost braces; A a2 = { a1 }; is not a
5208 valid aggregate initialization. */
5209 && !first_initializer_p
5212 {
5215 }
5217 /* [dcl.init.string]
5219 A char array (whether plain char, signed char, or unsigned char)
5220 can be initialized by a string-literal (optionally enclosed in
5221 braces); a wchar_t array can be initialized by a wide
5222 string-literal (optionally enclosed in braces). */
5225 {
5228 /* Strip one level of braces if and only if they enclose a single
5229 element (as allowed by [dcl.init.string]). */
5233 {
5236 }
5238 /* If it's a string literal, then it's the initializer for the array
5239 as a whole. Otherwise, continue with normal initialization for
5240 array types (one value per array element). */
5242 {
5245 }
5246 }
5248 /* The following cases are about aggregates. If we are not within a full
5249 initializer already, and there is not a CONSTRUCTOR, it means that there
5250 is a missing set of braces (that is, we are processing the case for
5251 which reshape_init exists). */
5253 {
5255 {
5257 /* There is no need to reshape pointer-to-member function
5258 initializers, as they are always constructed correctly
5259 by the front end. */
5260 ;
5262 /* For a nested compound literal, there is no need to reshape since
5263 brace elision is not allowed. Even if we decided to allow it,
5264 we should add a call to reshape_init in finish_compound_literal,
5265 before calling digest_init, so changing this code would still
5266 not be necessary. */
5268 else
5269 {
5273 }
5274 }
5277 type);
5278 }
5280 /* Dispatch to specialized routines. */
5287 else
5289 }
5291 /* Undo the brace-elision allowed by [dcl.init.aggr] in a
5292 brace-enclosed aggregate initializer.
5294 INIT is the CONSTRUCTOR containing the list of initializers describing
5295 a brace-enclosed initializer for an entity of the indicated aggregate TYPE.
5296 It may not presently match the shape of the TYPE; for example:
5298 struct S { int a; int b; };
5299 struct S a[] = { 1, 2, 3, 4 };
5301 Here INIT will hold a VEC of four elements, rather than a
5302 VEC of two elements, each itself a VEC of two elements. This
5303 routine transforms INIT from the former form into the latter. The
5304 revised CONSTRUCTOR node is returned. */
5306 tree
5308 {
5310 reshape_iter d;
5311 tree new_init;
5317 /* An empty constructor does not need reshaping, and it is always a valid
5318 initializer. */
5322 /* Recurse on this CONSTRUCTOR. */
5330 /* Make sure all the element of the constructor were used. Otherwise,
5331 issue an error about exceeding initializers. */
5333 {
5336 else
5338 }
5341 }
5343 /* Verify array initializer. Returns true if errors have been reported. */
5345 bool
5347 {
5350 /* The array type itself need not be complete, because the
5351 initializer may tell us how many elements are in the array.
5352 But, the elements of the array must be complete. */
5354 {
5357 else
5360 }
5361 /* It is not valid to initialize a VLA. */
5365 {
5368 else
5371 }
5373 }
5375 /* Subroutine of check_initializer; args are passed down from that function.
5376 Set stmts_are_full_exprs_p to 1 across a call to build_aggr_init. */
5378 static tree
5381 {
5384 {
5387 }
5391 saved_stmts_are_full_exprs_p;
5393 }
5395 /* Verify INIT (the initializer for DECL), and record the
5396 initialization in DECL_INITIAL, if appropriate. CLEANUP is as for
5397 grok_reference_init.
5399 If the return value is non-NULL, it is an expression that must be
5400 evaluated dynamically to initialize DECL. */
5402 static tree
5404 {
5408 tree core_type;
5410 /* Things that are going to be initialized need to have complete
5411 type. */
5415 {
5416 /* A variable with DECL_HAS_VALUE_EXPR_P set is just a placeholder,
5417 it doesn't have storage to be initialized. */
5420 }
5423 /* We will have already complained. */
5427 {
5430 }
5432 {
5436 }
5437 else
5438 /* There is no way to make a variable-sized class type in GNU C++. */
5442 {
5445 {
5447 {
5450 }
5452 {
5454 decl);
5457 }
5458 }
5459 }
5462 {
5469 }
5471 ;
5475 {
5478 /* Do not reshape constructors of vectors (they don't need to be
5479 reshaped. */
5481 {
5486 {
5487 /* Don't reshape if the class has constructors. */
5491 decl);
5492 }
5494 {
5497 }
5498 else
5499 {
5503 }
5504 }
5506 /* If DECL has an array type without a specific bound, deduce the
5507 array size from the initializer. */
5516 {
5519 /* If this is a constexpr initializer, expand_default_init will
5520 have returned an INIT_EXPR rather than a CALL_EXPR. In that
5521 case, pull the initializer back out and pass it down into
5522 store_init_value. */
5527 {
5530 /* Don't call digest_init; it's unnecessary and will complain
5531 about aggregate initialization of non-aggregate classes. */
5533 }
5535 {
5536 /* Declared constexpr, but no suitable initializer; massage
5537 init appropriately so we can pass it into store_init_value
5538 for the error. */
5541 tf_warning_or_error);
5544 {
5548 }
5550 }
5551 else
5553 }
5556 {
5565 }
5566 }
5567 else
5568 {
5576 }
5585 {
5590 else
5594 {
5597 }
5598 }
5601 }
5603 /* If DECL is not a local variable, give it RTL. */
5605 static void
5607 {
5612 /* Set the DECL_ASSEMBLER_NAME for the object. */
5614 {
5615 /* The `register' keyword, when used together with an
5616 asm-specification, indicates that the variable should be
5617 placed in a particular register. */
5619 {
5622 }
5623 else
5624 {
5629 }
5630 }
5632 /* Handle non-variables up front. */
5634 {
5637 }
5639 /* If we see a class member here, it should be a static data
5640 member. */
5642 {
5644 /* An in-class declaration of a static data member should be
5645 external; it is only a declaration, and not a definition. */
5648 }
5650 /* We don't create any RTL for local variables. */
5654 /* We defer emission of local statics until the corresponding
5655 DECL_EXPR is expanded. */
5658 /* We try to defer namespace-scope static constants so that they are
5659 not emitted into the object file unnecessarily. */
5667 && toplev
5669 {
5670 /* Fool with the linkage of static consts according to #pragma
5671 interface. */
5674 {
5677 }
5680 }
5681 /* Likewise for template instantiations. */
5686 /* If we're not deferring, go ahead and assemble the variable. */
5689 }
5691 /* walk_tree helper for wrap_temporary_cleanups, below. */
5693 static tree
5695 {
5697 {
5700 }
5703 {
5708 /* Tell honor_protect_cleanup_actions to handle this as a separate
5709 cleanup. */
5713 }
5716 }
5718 /* We're initializing a local variable which has a cleanup GUARD. If there
5719 are any temporaries used in the initializer INIT of this variable, we
5720 need to wrap their cleanups with TRY_CATCH_EXPR (, GUARD) so that the
5721 variable will be cleaned up properly if one of them throws.
5723 Unfortunately, there's no way to express this properly in terms of
5724 nesting, as the regions for the temporaries overlap the region for the
5725 variable itself; if there are two temporaries, the variable needs to be
5726 the first thing destroyed if either of them throws. However, we only
5727 want to run the variable's cleanup if it actually got constructed. So
5728 we need to guard the temporary cleanups with the variable's cleanup if
5729 they are run on the normal path, but not if they are run on the
5730 exceptional path. We implement this by telling
5731 honor_protect_cleanup_actions to strip the variable cleanup from the
5732 exceptional path. */
5734 static void
5736 {
5738 }
5740 /* Generate code to initialize DECL (a local variable). */
5742 static void
5744 {
5746 tree cleanup;
5754 {
5755 /* If we used it already as memory, it must stay in memory. */
5759 }
5764 /* Compute and store the initial value. */
5769 /* Generate a cleanup, if necessary. */
5772 /* Perform the initialization. */
5774 {
5777 {
5778 /* Stick simple initializers in DECL_INITIAL so that
5779 -Wno-init-self works (c++/34772). */
5782 }
5783 else
5784 {
5787 /* If we're only initializing a single object, guard the
5788 destructors of any temporaries used in its initializer with
5789 its destructor. This isn't right for arrays because each
5790 element initialization is a full-expression. */
5799 saved_stmts_are_full_exprs_p;
5800 }
5801 }
5803 /* Set this to 0 so we can tell whether an aggregate which was
5804 initialized was ever used. Don't do this if it has a
5805 destructor, so we don't complain about the 'resource
5806 allocation is initialization' idiom. Now set
5807 attribute((unused)) on types so decls of that type will be
5808 marked used. (see TREE_USED, above.) */
5810 && ! already_used
5819 }
5821 /* DECL is a VAR_DECL for a compiler-generated variable with static
5822 storage duration (like a virtual table) whose initializer is a
5823 compile-time constant. Initialize the variable and provide it to the
5824 back end. */
5826 void
5828 {
5829 tree init;
5839 }
5841 /* INIT is the initializer for a variable, as represented by the
5842 parser. Returns true iff INIT is type-dependent. */
5844 static bool
5846 {
5848 /* A parenthesized initializer, e.g.: int i (3, 2); ? */
5851 /* A brace-enclosed initializer, e.g.: int i = { 3 }; ? */
5852 {
5863 }
5864 else
5865 /* It must be a simple expression, e.g., int i = 3; */
5869 }
5871 /* INIT is the initializer for a variable, as represented by the
5872 parser. Returns true iff INIT is value-dependent. */
5874 static bool
5876 {
5878 /* A parenthesized initializer, e.g.: int i (3, 2); ? */
5881 /* A brace-enclosed initializer, e.g.: int i = { 3 }; ? */
5882 {
5893 }
5894 else
5895 /* It must be a simple expression, e.g., int i = 3; */
5899 }
5901 /* Finish processing of a declaration;
5902 install its line number and initial value.
5903 If the length of an array type is not known before,
5904 it must be determined now, from the initial value, or it is an error.
5906 INIT is the initializer (if any) for DECL. If INIT_CONST_EXPR_P is
5907 true, then INIT is an integral constant expression.
5909 FLAGS is LOOKUP_ONLYCONVERTING if the = init syntax was used, else 0
5910 if the (init) syntax was used. */
5912 void
5915 {
5916 tree type;
5917 tree cleanup;
5921 tree auto_node;
5926 {
5930 }
5933 /* Parameters are handled by store_parm_decls, not cp_finish_decl. */
5940 /* Assume no cleanup is required. */
5943 /* If a name was specified, get the string. */
5958 {
5959 tree d_init;
5961 {
5965 }
5969 tf_warning_or_error);
5972 auto_node);
5975 }
5986 {
5987 tree clone;
5989 {
5990 /* FIXME check this is 1st decl. */
5995 {
5999 }
6001 }
6003 {
6006 else
6008 }
6009 }
6012 {
6014 /* If DECL is a reference, then we want to know whether init is a
6015 reference constant; init_const_expr_p as passed tells us whether
6016 it's an rvalue constant. */
6020 {
6021 /* Set these flags now for templates. We'll update the flags in
6022 store_init_value for instantiations. */
6026 }
6027 }
6030 {
6033 /* Add this declaration to the statement-tree. */
6040 {
6043 }
6045 /* Generally, initializers in templates are expanded when the
6046 template is instantiated. But, if DECL is a variable constant
6047 then it can be used in future constant expressions, so its value
6048 must be available. */
6053 && init_const_expr_p
6054 && !type_dependent_p
6058 {
6059 /* This variable seems to be a non-dependent constant, so process
6060 its initializer. If check_initializer returns non-null the
6061 initialization wasn't constant after all. */
6065 }
6067 /* Deduce array size even if the initializer is dependent. */
6073 }
6075 /* Take care of TYPE_DECLs up front. */
6077 {
6080 {
6084 }
6086 /* If we have installed this as the canonical typedef for this
6087 type, and that type has not been defined yet, delay emitting
6088 the debug information for it, as we will emit it later. */
6094 at_eof);
6096 }
6098 /* A reference will be modified here, as it is initialized. */
6102 {
6105 }
6108 {
6109 /* Only variables with trivial initialization and destruction can
6110 have thread-local storage. */
6116 /* If this is a local variable that will need a mangled name,
6117 register it now. We must do this before processing the
6118 initializer for the variable, since the initialization might
6119 require a guard variable, and since the mangled name of the
6120 guard variable will depend on the mangled name of this
6121 variable. */
6125 {
6129 /* Normally local_decls is populated during GIMPLE lowering,
6130 but [cd]tors are never actually compiled directly. We need
6131 to put statics on the list so we can deal with the label
6132 address extension. */
6134 }
6136 /* Convert the initializer to the type of DECL, if we have not
6137 already initialized DECL. */
6139 /* If !DECL_EXTERNAL then DECL is being defined. In the
6140 case of a static data member initialized inside the
6141 class-specifier, there can be an initializer even if DECL
6142 is *not* defined. */
6144 {
6146 {
6147 tree jclass
6149 /* Allow libjava/prims.cc define primitive classes. */
6154 || !same_type_ignoring_top_level_qualifiers_p
6158 }
6160 /* Thread-local storage cannot be dynamically initialized. */
6162 {
6166 }
6168 /* Check that the initializer for a static data member was a
6169 constant. Although we check in the parser that the
6170 initializer is an integral constant expression, we do not
6171 simplify division-by-zero at the point at which it
6172 occurs. Therefore, in:
6174 struct S { static const int i = 7 / 0; };
6176 we issue an error at this point. It would
6177 probably be better to forbid division by zero in
6178 integral constant expressions. */
6180 {
6185 }
6187 /* Handle:
6189 [dcl.init]
6191 The memory occupied by any object of static storage
6192 duration is zero-initialized at program startup before
6193 any other initialization takes place.
6195 We cannot create an appropriate initializer until after
6196 the type of DECL is finalized. If DECL_INITIAL is set,
6197 then the DECL is statically initialized, and any
6198 necessary zero-initialization has already been performed. */
6203 /* Remember that the initialization for this variable has
6204 taken place. */
6206 /* This declaration is the definition of this variable,
6207 unless we are initializing a static data member within
6208 the class specifier. */
6211 }
6212 /* If the variable has an array type, lay out the type, even if
6213 there is no initializer. It is valid to index through the
6214 array, and we must get TYPE_ALIGN set correctly on the array
6215 type. */
6222 /* So decl is a global variable or a static member of a
6223 non local class. Record the types it uses
6224 so that we can decide later to emit debug info for them. */
6226 }
6231 /* Add this declaration to the statement-tree. This needs to happen
6232 after the call to check_initializer so that the DECL_EXPR for a
6233 reference temp is added before the DECL_EXPR for the reference itself. */
6237 /* Let the middle end know about variables and functions -- but not
6238 static data members in uninstantiated class templates. */
6241 {
6243 {
6246 }
6248 /* This needs to happen after the linkage is set. */
6252 {
6253 /* If a TREE_READONLY variable needs initialization
6254 at runtime, it is no longer readonly and we need to
6255 avoid MEM_READONLY_P being set on RTL created for it. */
6257 {
6261 }
6264 }
6268 /* Check for abstractness of the type. Notice that there is no
6269 need to strip array types here since the check for those types
6270 is already done within create_array_type_for_decl. */
6274 else
6278 /* No initialization required. */
6279 ;
6281 {
6283 {
6285 {
6286 /* An out-of-class default definition is defined at
6287 the point where it is explicitly defaulted. */
6292 }
6293 else
6295 }
6296 /* else no initialization required. */
6297 }
6301 {
6304 }
6305 /* A variable definition. */
6307 /* Initialize the local variable. */
6310 /* If a variable is defined, and then a subsequent
6311 definition with external linkage is encountered, we will
6312 get here twice for the same variable. We want to avoid
6313 calling expand_static_init more than once. For variables
6314 that are not static data members, we can call
6315 expand_static_init only when we actually process the
6316 initializer. It is not legal to redeclare a static data
6317 member, so this issue does not arise in that case. */
6320 }
6322 /* If a CLEANUP_STMT was created to destroy a temporary bound to a
6323 reference, insert it in the statement-tree now. */
6331 }
6333 /* Returns a declaration for a VAR_DECL as if:
6335 extern "C" TYPE NAME;
6337 had been seen. Used to create compiler-generated global
6338 variables. */
6340 static tree
6342 {
6343 tree decl;
6350 /* If the user has explicitly declared this variable (perhaps
6351 because the code we are compiling is part of a low-level runtime
6352 library), then it is possible that our declaration will be merged
6353 with theirs by pushdecl. */
6359 }
6361 /* Returns the type for the argument to "__cxa_atexit" (or "atexit",
6362 if "__cxa_atexit" is not being used) corresponding to the function
6363 to be called when the program exits. */
6365 static tree
6367 {
6368 tree fn_type;
6371 {
6372 tree arg_type;
6375 /* The parameter to "__cxa_atexit" is "void (*)(void *)". */
6377 else
6378 /* The parameter to "atexit" is "void (*)(void)". */
6384 }
6387 }
6389 /* Returns a pointer to the `atexit' function. Note that if
6390 FLAG_USE_CXA_ATEXIT is nonzero, then this will actually be the new
6391 `__cxa_atexit' function specified in the IA64 C++ ABI. */
6393 static tree
6395 {
6396 tree atexit_fndecl;
6397 tree fn_type;
6398 tree fn_ptr_type;
6406 {
6407 /* The declaration for `__cxa_atexit' is:
6409 int __cxa_atexit (void (*)(void *), void *, void *)
6411 We build up the argument types and then the function type
6412 itself. */
6416 /* First, build the pointer-to-function type for the first
6417 argument. */
6419 /* Then, build the rest of the argument types. */
6422 {
6425 }
6426 else
6427 {
6430 }
6431 /* And the final __cxa_atexit type. */
6434 NULL_TREE);
6438 else
6440 }
6441 else
6442 {
6443 /* The declaration for `atexit' is:
6445 int atexit (void (*)());
6447 We build up the argument types and then the function type
6448 itself. */
6450 /* Build the final atexit type. */
6454 }
6456 /* Now, build the function declaration. */
6464 }
6466 /* Returns the __dso_handle VAR_DECL. */
6468 static tree
6470 {
6474 /* Declare the variable. */
6476 ptr_type_node);
6478 #ifdef HAVE_GAS_HIDDEN
6481 #endif
6484 }
6486 /* Begin a new function with internal linkage whose job will be simply
6487 to destroy some particular variable. */
6491 static tree
6493 {
6495 tree fntype;
6496 tree fndecl;
6502 /* No need to mangle this. */
6505 /* Build the name of the function. */
6507 /* Build the function declaration. */
6510 /* It's a function with internal linkage, generated by the
6511 compiler. */
6514 /* Make the function `inline' so that it is only emitted if it is
6515 actually needed. It is unlikely that it will be inlined, since
6516 it is only called via a function pointer, but we avoid unnecessary
6517 emissions this way. */
6520 /* Build the parameter. */
6522 {
6523 tree parmdecl;
6530 }
6538 }
6540 /* Finish the cleanup function begun by start_cleanup_fn. */
6542 static void
6544 {
6548 }
6550 /* Generate code to handle the destruction of DECL, an object with
6551 static storage duration. */
6553 tree
6555 {
6556 tree cleanup;
6557 tree compound_stmt;
6558 tree fcall;
6559 tree type;
6567 /* If we're using "__cxa_atexit" (or "__aeabi_atexit"), and DECL is
6568 a class object, we can just pass the destructor to
6569 "__cxa_atexit"; we don't have to build a temporary function to do
6570 the cleanup. */
6571 use_dtor = (flag_use_cxa_atexit
6575 {
6578 /* Find the destructor. */
6582 /* Make sure it is accessible. */
6584 }
6585 else
6586 {
6587 /* Call build_cleanup before we enter the anonymous function so
6588 that any access checks will be done relative to the current
6589 scope, rather than the scope of the anonymous function. */
6592 /* Now start the function. */
6595 /* Now, recompute the cleanup. It may contain SAVE_EXPRs that refer
6596 to the original function, rather than the anonymous one. That
6597 will make the back end think that nested functions are in use,
6598 which causes confusion. */
6603 /* Create the body of the anonymous function. */
6608 }
6610 /* Call atexit with the cleanup function. */
6614 {
6615 tree addr;
6618 {
6619 /* We must convert CLEANUP to the type that "__cxa_atexit"
6620 expects. */
6622 /* "__cxa_atexit" will pass the address of DECL to the
6623 cleanup function. */
6626 /* The declared type of the parameter to "__cxa_atexit" is
6627 "void *". For plain "T*", we could just let the
6628 machinery in cp_build_function_call convert it -- but if the
6629 type is "cv-qualified T *", then we need to convert it
6630 before passing it in, to avoid spurious errors. */
6632 }
6633 else
6634 /* Since the cleanup functions we build ignore the address
6635 they're given, there's no reason to pass the actual address
6636 in, and, in general, it's cheaper to pass NULL than any
6637 other value. */
6640 tf_warning_or_error);
6642 {
6645 }
6646 else
6647 {
6650 }
6651 }
6652 else
6656 }
6658 /* DECL is a VAR_DECL with static storage duration. INIT, if present,
6659 is its initializer. Generate code to handle the construction
6660 and destruction of DECL. */
6662 static void
6664 {
6668 /* Some variables require no dynamic initialization. */
6674 {
6675 /* Emit code to perform this initialization but once. */
6681 /* Emit code to perform this initialization but once. This code
6682 looks like:
6684 static <type> guard;
6685 if (!guard.first_byte) {
6686 if (__cxa_guard_acquire (&guard)) {
6687 bool flag = false;
6688 try {
6689 // Do initialization.
6690 flag = true; __cxa_guard_release (&guard);
6691 // Register variable for destruction at end of program.
6692 } catch {
6693 if (!flag) __cxa_guard_abort (&guard);
6694 }
6695 }
6697 Note that the `flag' variable is only set to 1 *after* the
6698 initialization is complete. This ensures that an exception,
6699 thrown during the construction, will cause the variable to
6700 reinitialized when we pass through this code again, as per:
6702 [stmt.dcl]
6704 If the initialization exits by throwing an exception, the
6705 initialization is not complete, so it will be tried again
6706 the next time control enters the declaration.
6708 This process should be thread-safe, too; multiple threads
6709 should not be able to initialize the variable more than
6710 once. */
6712 /* Create the guard variable. */
6715 /* This optimization isn't safe on targets with relaxed memory
6716 consistency. On such targets we force synchronization in
6717 __cxa_guard_acquire. */
6719 {
6720 /* Begin the conditional initialization. */
6724 }
6727 {
6740 acquire_fn = push_library_fn
6743 NULL_TREE),
6744 NULL_TREE);
6748 NULL_TREE);
6756 inner_if_stmt);
6764 void_zero_node,
6768 /* Do the initialization itself. */
6770 init = add_stmt_to_compound
6772 init = add_stmt_to_compound
6774 }
6775 else
6778 /* Use atexit to register a function for destroying this static
6779 variable. */
6785 {
6789 }
6792 {
6796 }
6797 }
6798 else
6800 }
6802 \f
6803 /* Make TYPE a complete type based on INITIAL_VALUE.
6804 Return 0 if successful, 1 if INITIAL_VALUE can't be deciphered,
6805 2 if there was no information (in which case assume 0 if DO_DEFAULT),
6806 3 if the initializer list is empty (in pedantic mode). */
6808 int
6810 {
6815 {
6817 tree value;
6819 /* An array of character type can be initialized from a
6820 brace-enclosed string constant.
6822 FIXME: this code is duplicated from reshape_init. Probably
6823 we should just call reshape_init here? */
6827 {
6834 }
6836 /* If any of the elements are parameter packs, we can't actually
6837 complete this type now because the array size is dependent. */
6839 {
6842 {
6845 }
6846 }
6847 }
6851 /* We can create the array before the element type is complete, which
6852 means that we didn't have these two bits set in the original type
6853 either. In completing the type, we are expected to propagate these
6854 bits. See also complete_type which does the same thing for arrays
6855 of fixed size. */
6858 {
6863 }
6866 }
6868 /* As above, but either give an error or reject zero-size arrays, depending
6869 on COMPLAIN. */
6871 int
6874 {
6877 /* In SFINAE context we can't be lenient about zero-size arrays. */
6884 {
6890 {
6893 }
6897 }
6899 }
6900 \f
6901 /* Return zero if something is declared to be a member of type
6902 CTYPE when in the context of CUR_TYPE. STRING is the error
6903 message to print in that case. Otherwise, quietly return 1. */
6905 static int
6907 {
6909 {
6912 else
6915 }
6917 }
6918 \f
6919 /* Subroutine of `grokdeclarator'. */
6921 /* Generate errors possibly applicable for a given set of specifiers.
6922 This is for ARM $7.1.2. */
6924 static void
6932 {
6934 {
6973 }
6982 }
6984 /* DECL is a member function or static data member and is presently
6985 being defined. Check that the definition is taking place in a
6986 valid namespace. */
6988 static void
6990 {
6991 /* These checks only apply to member functions and static data
6992 members. */
6995 /* We check for problems with specializations in pt.c in
6996 check_specialization_namespace, where we can issue better
6997 diagnostics. */
7000 /* There are no restrictions on the placement of
7001 explicit instantiations. */
7004 /* [class.mfct]
7006 A member function definition that appears outside of the
7007 class definition shall appear in a namespace scope enclosing
7008 the class definition.
7010 [class.static.data]
7012 The definition for a static data member shall appear in a
7013 namespace scope enclosing the member's class definition. */
7017 }
7019 /* Build a PARM_DECL for the "this" parameter. TYPE is the
7020 METHOD_TYPE for a non-static member function; QUALS are the
7021 cv-qualifiers that apply to the function. */
7023 tree
7025 {
7026 tree this_type;
7027 tree qual_type;
7028 tree parm;
7029 cp_cv_quals this_quals;
7032 {
7033 this_type
7036 }
7037 else
7039 /* The `this' parameter is implicitly `const'; it cannot be
7040 assigned to. */
7046 }
7048 /* DECL is a static member function. Complain if it was declared
7049 with function-cv-quals. */
7051 static void
7053 {
7056 decl);
7057 }
7059 /* CTYPE is class type, or null if non-class.
7060 TYPE is type this FUNCTION_DECL should have, either FUNCTION_TYPE
7061 or METHOD_TYPE.
7062 DECLARATOR is the function's name.
7063 PARMS is a chain of PARM_DECLs for the function.
7064 VIRTUALP is truthvalue of whether the function is virtual or not.
7065 FLAGS are to be passed through to `grokclassfn'.
7066 QUALS are qualifiers indicating whether the function is `const'
7067 or `volatile'.
7068 RAISES is a list of exceptions that this function can raise.
7069 CHECK is 1 if we must find this method in CTYPE, 0 if we should
7070 not look, and -1 if we should not call `grokclassfn' at all.
7072 SFK is the kind of special function (if any) for the new function.
7074 Returns `NULL_TREE' if something goes wrong, after issuing
7075 applicable error messages. */
7077 static tree
7079 tree type,
7080 tree declarator,
7081 tree parms,
7082 tree orig_declarator,
7085 cp_cv_quals quals,
7086 tree raises,
7091 special_function_kind sfk,
7094 tree in_namespace,
7096 location_t location)
7097 {
7098 tree decl;
7100 tree t;
7107 /* If we have an explicit location, use it, otherwise use whatever
7108 build_lang_decl used (probably input_location). */
7113 {
7114 tree parm;
7118 }
7122 /* Propagate volatile out from type to decl. */
7126 /* Setup decl according to sfk. */
7128 {
7139 }
7141 /* If pointers to member functions use the least significant bit to
7142 indicate whether a function is virtual, ensure a pointer
7143 to this function will have that bit clear. */
7151 {
7153 error
7155 orig_declarator);
7156 else
7157 {
7162 {
7163 /* Something like `template <class T> friend void f<T>()'. */
7166 orig_declarator);
7168 }
7171 /* A friend declaration of the form friend void f<>(). Record
7172 the information in the TEMPLATE_ID_EXPR. */
7176 {
7177 /* Due to bison parser ickiness, we will have already looked
7178 up an operator_name or PFUNCNAME within the current class
7179 (see template_id in parse.y). If the current class contains
7180 such a name, we'll get a COMPONENT_REF here. Undo that. */
7185 }
7193 {
7196 decl);
7198 }
7201 {
7204 decl);
7206 }
7207 }
7208 }
7210 /* If this decl has namespace scope, set that up. */
7216 /* `main' and builtins have implicit 'C' linkage. */
7227 /* Should probably propagate const out from type to decl I bet (mrs). */
7229 {
7232 }
7235 {
7239 }
7242 {
7251 }
7253 /* Members of anonymous types and local classes have no linkage; make
7254 them internal. If a typedef is made later, this will be changed. */
7260 {
7261 /* [basic.link]: A name with no linkage (notably, the name of a class
7262 or enumeration declared in a local scope) shall not be used to
7263 declare an entity with linkage.
7265 DR 757 relaxes this restriction for C++0x. */
7269 {
7271 {
7274 else
7275 {
7278 decl);
7283 }
7284 }
7285 else
7288 }
7289 }
7293 {
7296 }
7298 /* If the declaration was declared inline, mark it as such. */
7306 {
7310 decl);
7312 }
7319 /* Make the init_value nonzero so pushdecl knows this is not
7320 tentative. error_mark_node is replaced later with the BLOCK. */
7326 /* Caller will do the rest of this. */
7334 template_count,
7344 {
7347 }
7349 /* Check main's type after attributes have been applied. */
7351 {
7353 integer_type_node))
7354 {
7356 tree newtype;
7360 }
7363 }
7368 {
7370 (processing_template_decl
7372 ? current_template_parms
7379 {
7380 tree ok;
7381 tree pushed_scope;
7384 /* Because grokfndecl is always supposed to return a
7385 FUNCTION_DECL, we pull out the DECL_TEMPLATE_RESULT
7386 here. We depend on our callers to figure out that its
7387 really a template that's being returned. */
7392 {
7393 /* Remove the `this' parm added by grokclassfn. */
7396 }
7398 {
7401 }
7403 /* Since we've smashed OLD_DECL to its
7404 DECL_TEMPLATE_RESULT, we must do the same to DECL. */
7408 /* Attempt to merge the declarations. This can fail, in
7409 the case of some invalid specialization declarations. */
7415 {
7419 }
7421 }
7422 }
7434 }
7436 /* decl is a FUNCTION_DECL.
7437 specifiers are the parsed virt-specifiers.
7439 Set flags to reflect the virt-specifiers.
7441 Returns decl. */
7443 static tree
7445 {
7453 }
7455 /* DECL is a VAR_DECL for a static data member. Set flags to reflect
7456 the linkage that DECL will receive in the object file. */
7458 static void
7460 {
7461 /* A static data member always has static storage duration and
7462 external linkage. Note that static data members are forbidden in
7463 local classes -- the only situation in which a class has
7464 non-external linkage. */
7467 /* For non-template classes, static data members are always put
7468 out in exactly those files where they are defined, just as
7469 with ordinary namespace-scope variables. */
7472 }
7474 /* Create a VAR_DECL named NAME with the indicated TYPE.
7476 If SCOPE is non-NULL, it is the class type or namespace containing
7477 the variable. If SCOPE is NULL, the variable should is created in
7478 the innermost enclosings scope. */
7480 static tree
7482 tree name,
7486 tree scope)
7487 {
7488 tree decl;
7489 tree explicit_scope;
7493 /* Compute the scope in which to place the variable, but remember
7494 whether or not that scope was explicitly specified by the user. */
7497 {
7498 /* An explicit "extern" specifier indicates a namespace-scope
7499 variable. */
7504 }
7508 template, we need DECL_LANG_SPECIFIC. */
7510 /* Similarly for namespace-scope variables with language linkage
7511 other than C++. */
7514 /* Similarly for static data members. */
7517 else
7522 else
7526 {
7529 }
7532 {
7534 /* This function is only called with out-of-class definitions. */
7537 }
7538 /* At top level, either `static' or no s.c. makes a definition
7539 (perhaps tentative), and absence of `static' makes it public. */
7541 {
7545 }
7546 /* Not at top level, only `static' makes a static definition. */
7547 else
7548 {
7551 }
7556 /* If the type of the decl has no linkage, make sure that we'll
7557 notice that in mark_used. */
7566 {
7567 /* [basic.link]: A name with no linkage (notably, the name of a class
7568 or enumeration declared in a local scope) shall not be used to
7569 declare an entity with linkage.
7571 DR 757 relaxes this restriction for C++0x. */
7575 {
7577 {
7579 /* Allow this; it's pretty common in C. */
7580 ;
7581 else
7582 {
7583 /* DRs 132, 319 and 389 seem to indicate types with
7584 no linkage can only be used to declare extern "C"
7585 entities. Since it's not always an error in the
7586 ISO C++ 90 Standard, we only issue a warning. */
7593 }
7594 }
7595 else
7598 }
7599 }
7600 else
7604 }
7606 /* Create and return a canonical pointer to member function type, for
7607 TYPE, which is a POINTER_TYPE to a METHOD_TYPE. */
7609 tree
7611 {
7613 tree t;
7619 /* If a canonical type already exists for this type, use it. We use
7620 this method instead of type_hash_canon, because it only does a
7621 simple equality check on the list of field members. */
7626 /* Make sure that we always have the unqualified pointer-to-member
7627 type first. */
7629 unqualified_variant
7635 /* Let the front end know this is a pointer to member function... */
7637 /* ... and not really a class type. */
7644 delta_type_node);
7650 /* Zap out the name so that the back end will give us the debugging
7651 information for this anonymous RECORD_TYPE. */
7654 /* If this is not the unqualified form of this pointer-to-member
7655 type, set the TYPE_MAIN_VARIANT for this type to be the
7656 unqualified type. Since they are actually RECORD_TYPEs that are
7657 not variants of each other, we must do this manually.
7658 As we just built a new type there is no need to do yet another copy. */
7660 {
7669 }
7671 /* Cache this pointer-to-member type so that we can find it again
7672 later. */
7681 }
7683 /* Create and return a pointer to data member type. */
7685 tree
7687 {
7689 {
7693 }
7694 else
7695 {
7698 }
7699 }
7701 /* DECL is a VAR_DECL defined in-class, whose TYPE is also given.
7702 Check to see that the definition is valid. Issue appropriate error
7703 messages. Return 1 if the definition is particularly bad, or 0
7704 otherwise. */
7706 static int
7708 {
7709 /* Can't check yet if we don't know the type. */
7712 /* If DECL is declared constexpr, we'll do the appropriate checks
7713 in check_initializer. */
7717 {
7721 else
7725 }
7727 /* Motion 10 at San Diego: If a static const integral data member is
7728 initialized with an integral constant expression, the initializer
7729 may appear either in the declaration (within the class), or in
7730 the definition, but not both. If it appears in the class, the
7731 member is a member constant. The file-scope definition is always
7732 required. */
7734 {
7737 type);
7739 }
7743 decl);
7749 }
7751 /* *expr_p is part of the TYPE_SIZE of a variably-sized array. If any
7752 SAVE_EXPRs in *expr_p wrap expressions with side-effects, break those
7753 expressions out into temporary variables so that walk_tree doesn't
7754 step into them (c++/15764). */
7756 static tree
7758 {
7762 {
7768 }
7772 }
7774 /* Entry point for the above. */
7776 static void
7778 {
7780 /* Break out any function calls into temporary variables. */
7782 }
7784 /* Given the SIZE (i.e., number of elements) in an array, compute an
7785 appropriate index type for the array. If non-NULL, NAME is the
7786 name of the thing being declared. */
7788 tree
7790 {
7791 tree type;
7792 tree itype;
7800 /* type_dependent_expression_p? */
7802 {
7807 /* In C++98, we mark a non-constant array bound with a magic
7809 else
7810 {
7815 {
7818 {
7824 else
7827 }
7831 /* We didn't support this case in GCC 3.2, so don't bother
7832 trying to model it now in ABI v1. */
7834 }
7839 }
7844 /* The array bound must be an integer type. */
7846 {
7851 else
7855 }
7856 }
7858 /* A type is dependent if it is...an array type constructed from any
7859 dependent type or whose size is specified by a constant expression
7860 that is value-dependent. */
7861 /* We can only call value_dependent_expression_p on integral constant
7862 expressions; treat non-constant expressions as dependent, too. */
7866 {
7867 /* We cannot do any checking for a SIZE that isn't known to be
7868 constant. Just build the index type and mark that it requires
7869 structural equality checks. */
7876 }
7880 /* For abi-1, we handled all instances in templates the same way,
7881 even when they were non-dependent. This affects the manglings
7882 produced. So, we do the normal checking for non-dependent
7883 sizes, but at the end we'll return the same type that abi-1
7884 would have, but with TYPE_CANONICAL set to the "right"
7885 value that the current ABI would provide. */
7889 /* Normally, the array-bound will be a constant. */
7891 {
7892 /* Check to see if the array bound overflowed. Make that an
7893 error, no matter how generous we're being. */
7896 /* An array must have a positive number of elements. */
7898 {
7903 else
7906 }
7907 /* As an extension we allow zero-sized arrays. */
7909 {
7911 /* We must fail if performing argument deduction (as
7912 indicated by the state of complain), so that
7913 another substitution can be found. */
7919 else
7921 }
7922 }
7924 /* We don't allow VLAs at non-function scopes, or during
7925 tentative template substitution. */
7927 {
7930 /* `(int) &fn' is not a valid array bound. */
7933 name);
7934 else
7937 }
7939 {
7942 else
7944 }
7946 {
7950 else
7953 }
7956 /* A variable sized array. */
7958 else
7959 {
7960 HOST_WIDE_INT saved_processing_template_decl;
7962 /* Compute the index of the largest element in the array. It is
7963 one less than the number of elements in the array. We save
7964 and restore PROCESSING_TEMPLATE_DECL so that computations in
7965 cp_build_binary_op will be appropriately folded. */
7969 MINUS_EXPR,
7972 tf_warning_or_error);
7977 /* A variable sized array. */
7979 /* Make sure that there was no overflow when creating to a signed
7980 index type. (For example, on a 32-bit machine, an array with
7981 size 2^32 - 1 is too big.) */
7984 {
7989 }
7990 }
7992 /* Create and return the appropriate index type. */
7994 {
7998 }
7999 else
8002 /* If the index type were dependent, we would have returned early, so
8003 remember that it isn't. */
8007 }
8009 /* Returns the scope (if any) in which the entity declared by
8010 DECLARATOR will be located. If the entity was declared with an
8011 unqualified name, NULL_TREE is returned. */
8013 tree
8015 {
8019 /* If the declarator-id is a SCOPE_REF, the scope in which the
8020 declaration occurs is the first operand. */
8025 /* Otherwise, the declarator is not a qualified name; the entity will
8026 be declared in the current scope. */
8028 }
8030 /* Returns an ARRAY_TYPE for an array with SIZE elements of the
8031 indicated TYPE. If non-NULL, NAME is the NAME of the declaration
8032 with this type. */
8034 static tree
8036 {
8039 /* If things have already gone awry, bail now. */
8043 /* 8.3.4/1: If the type of the identifier of D contains the auto
8044 type-specifier, the program is ill-formed. */
8049 /* If there are some types which cannot be array elements,
8050 issue an error-message and return. */
8052 {
8056 else
8063 else
8070 else
8077 else
8083 }
8085 /* [dcl.array]
8087 The constant expressions that specify the bounds of the arrays
8088 can be omitted only for the first member of the sequence. */
8090 {
8094 name);
8095 else
8100 }
8102 /* Figure out the index type for the array. */
8106 /* [dcl.array]
8107 T is called the array element type; this type shall not be [...] an
8108 abstract class type. */
8112 }
8114 /* Check that it's OK to declare a function with the indicated TYPE.
8115 SFK indicates the kind of special function (if any) that this
8116 function is. OPTYPE is the type given in a conversion operator
8117 declaration, or the class type for a constructor/destructor.
8118 Returns the actual return type of the function; that
8119 may be different than TYPE if an error occurs, or for certain
8120 special functions. */
8122 static tree
8124 tree type,
8125 tree optype)
8126 {
8128 {
8135 else
8142 /* We can't use the proper return type here because we run into
8143 problems with ambiguous bases and covariant returns.
8144 Java classes are left unchanged because (void *) isn't a valid
8145 Java type, and we don't want to change the Java ABI. */
8148 else
8160 }
8163 }
8165 /* A variable or data member (whose unqualified name is IDENTIFIER)
8166 has been declared with the indicated TYPE. If the TYPE is not
8167 acceptable, issue an error message and return a type to use for
8168 error-recovery purposes. */
8170 tree
8172 {
8174 {
8178 {
8181 }
8182 else
8185 }
8188 }
8190 /* Given declspecs and a declarator (abstract or otherwise), determine
8191 the name and type of the object declared and construct a DECL node
8192 for it.
8194 DECLSPECS points to the representation of declaration-specifier
8195 sequence that precedes declarator.
8197 DECL_CONTEXT says which syntactic context this declaration is in:
8198 NORMAL for most contexts. Make a VAR_DECL or FUNCTION_DECL or TYPE_DECL.
8199 FUNCDEF for a function definition. Like NORMAL but a few different
8200 error messages in each case. Return value may be zero meaning
8201 this definition is too screwy to try to parse.
8202 MEMFUNCDEF for a function definition. Like FUNCDEF but prepares to
8203 handle member functions (which have FIELD context).
8204 Return value may be zero meaning this definition is too screwy to
8205 try to parse.
8206 PARM for a parameter declaration (either within a function prototype
8207 or before a function body). Make a PARM_DECL, or return void_type_node.
8208 TPARM for a template parameter declaration.
8209 CATCHPARM for a parameter declaration before a catch clause.
8210 TYPENAME if for a typename (in a cast or sizeof).
8211 Don't make a DECL node; just return the ..._TYPE node.
8212 FIELD for a struct or union field; make a FIELD_DECL.
8213 BITFIELD for a field with specified width.
8215 INITIALIZED is as for start_decl.
8217 ATTRLIST is a pointer to the list of attributes, which may be NULL
8218 if there are none; *ATTRLIST may be modified if attributes from inside
8219 the declarator should be applied to the declaration.
8221 When this function is called, scoping variables (such as
8222 CURRENT_CLASS_TYPE) should reflect the scope in which the
8223 declaration occurs, not the scope in which the new declaration will
8224 be placed. For example, on:
8226 void S::f() { ... }
8228 when grokdeclarator is called for `S::f', the CURRENT_CLASS_TYPE
8229 should not be `S'.
8231 Returns a DECL (if a declarator is present), a TYPE (if there is no
8232 declarator, in cases like "struct S;"), or the ERROR_MARK_NODE if an
8233 error occurs. */
8235 tree
8241 {
8254 /* True if this declarator is a function definition. */
8258 #if 0
8259 /* See the code below that used this. */
8261 #endif
8263 /* Keep track of what sort of function is being processed
8264 so that we can warn about default return values, or explicit
8265 return values which do not match prescribed defaults. */
8271 /* cv-qualifiers that apply to the declarator, for a declaration of
8272 a member function. */
8274 /* virt-specifiers that apply to the declarator, for a declaration of
8275 a member function. */
8277 /* cv-qualifiers that apply to the type specified by the DECLSPECS. */
8284 /* The unqualified name of the declarator; either an
8285 IDENTIFIER_NODE, BIT_NOT_EXPR, or TEMPLATE_ID_EXPR. */
8286 tree unqualified_id;
8287 /* The class type, if any, in which this entity is located,
8288 or NULL_TREE if none. Note that this value may be different from
8289 the current class type; for example if an attempt is made to declare
8290 "A::f" inside "B", this value will be "A". */
8292 /* The NAMESPACE_DECL for the namespace in which this entity is
8293 located. If an unqualified name is used to declare the entity,
8294 this value will be NULL_TREE, even if the entity is located at
8295 namespace scope. */
8297 cp_storage_class storage_class;
8328 /* Look inside a declarator for the name being declared
8329 and get it as a string, for an error message. */
8331 id_declarator;
8333 {
8338 {
8342 {
8346 }
8350 {
8356 {
8358 {
8359 /* [dcl.meaning]
8361 A declarator-id shall not be qualified except
8362 for ...
8364 None of the cases are permitted in block
8365 scope. */
8368 decl);
8372 else
8376 }
8378 {
8381 {
8384 }
8386 && current_class_type
8388 current_class_type))
8389 {
8393 }
8394 }
8397 }
8399 {
8401 {
8402 tree type;
8405 {
8408 }
8411 {
8414 }
8421 }
8425 {
8430 {
8433 }
8434 }
8435 /* Fall through. */
8442 {
8444 dname);
8446 }
8449 else
8450 {
8457 else
8459 }
8464 }
8466 }
8479 }
8482 }
8484 /* [dcl.fct.edf]
8486 The declarator in a function-definition shall have the form
8487 D1 ( parameter-declaration-clause) ... */
8489 {
8492 }
8497 {
8500 }
8503 {
8505 {
8508 }
8510 {
8513 }
8514 }
8516 /* Anything declared one level down from the top level
8517 must be one of the parameters of a function
8518 (because the body is at least two levels down). */
8520 /* This heuristic cannot be applied to C++ nodes! Fixed, however,
8521 by not allowing C++ class definitions to specify their parameters
8522 with xdecls (must be spec.d in the parmlist).
8524 Since we now wait to push a class scope until we are sure that
8525 we are in a legitimate method context, we must set oldcname
8526 explicitly (since current_class_name is not yet alive).
8528 We also want to avoid calling this a PARM if it is in a namespace. */
8531 {
8537 }
8543 {
8546 }
8548 /* If there were multiple types specified in the decl-specifier-seq,
8549 issue an error message. */
8551 {
8554 }
8557 {
8560 }
8562 /* Extract the basic type from the decl-specifier-seq. */
8565 {
8568 }
8569 /* If the entire declaration is itself tagged as deprecated then
8570 suppress reports of deprecated items. */
8575 {
8582 }
8583 /* No type at all: default to `int', and set DEFAULTED_INT
8584 because it was not a user-defined typedef. */
8586 {
8587 /* These imply 'int'. */
8590 }
8591 /* Gather flags. */
8595 #if 0
8596 /* See the code below that used this. */
8599 #endif
8608 ctor_return_type);
8610 {
8615 /* We handle `main' specially here, because 'main () { }' is so
8616 common. With no options, it is allowed. With -Wreturn-type,
8617 it is a warning. It is only an error with -pedantic-errors. */
8618 is_main = (funcdef_flag
8634 else
8639 }
8643 /* Now process the modifiers that were specified
8644 and check for invalid combinations. */
8646 /* Long double is a special combination. */
8648 {
8652 }
8654 /* Check all other uses of type modifiers. */
8657 {
8681 {
8686 }
8687 else
8688 {
8691 {
8694 name);
8697 }
8699 {
8701 {
8704 }
8706 {
8709 name);
8712 }
8713 }
8714 }
8716 /* Discard the type modifiers if they are invalid. */
8718 {
8725 }
8726 }
8728 /* Decide whether an integer type is signed or not.
8729 Optionally treat bitfields as signed by default. */
8731 /* [class.bit]
8733 It is implementation-defined whether a plain (neither
8734 explicitly signed or unsigned) char, short, int, or long
8735 bit-field is signed or unsigned.
8737 Naturally, we extend this to long long as well. Note that
8738 this does not include wchar_t. */
8740 && !signed_p
8741 /* A typedef for plain `int' without `signed' can be
8742 controlled just like plain `int', but a typedef for
8743 `signed int' cannot be so controlled. */
8744 && !(typedef_decl
8748 {
8761 else
8763 }
8776 {
8779 /* If we just have "complex", it is equivalent to
8780 "complex double", but if any modifiers at all are specified it is
8781 the complex form of TYPE. E.g, "complex short" is
8782 "complex short int". */
8794 else
8796 }
8807 ctor_return_type);
8810 type = cp_build_qualified_type_real
8813 /* We might have ignored or rejected some of the qualifiers. */
8826 {
8830 }
8834 {
8837 }
8839 /* Issue errors about use of storage classes for parameters. */
8841 {
8843 {
8846 }
8848 {
8851 }
8857 /* Function parameters cannot be constexpr. If we saw one, moan
8858 and pretend it wasn't there. */
8860 {
8863 }
8864 }
8866 /* Give error if `virtual' is used outside of class declaration. */
8869 {
8872 }
8874 /* Static anonymous unions are dealt with here. */
8880 /* Warn about storage classes that are invalid for certain
8881 kinds of declarations (parameters, typenames, etc.). */
8883 && ((storage_class
8887 {
8890 }
8895 {
8899 ;
8901 ;
8903 /* C++ allows static class elements. */
8905 /* C++ also allows inlines and signed and unsigned elements,
8906 but in those cases we don't come in here. */
8907 ;
8908 else
8909 {
8912 else
8913 {
8916 else
8918 }
8924 }
8925 }
8930 {
8933 }
8937 {
8939 name);
8941 }
8944 {
8948 }
8952 else
8953 {
8956 {
8969 }
8970 }
8972 /* Determine the type of the entity declared by recurring on the
8973 declarator. */
8975 {
8977 tree attrs;
8984 {
8996 attr_flags);
8997 }
9005 {
9012 {
9013 tree arg_types;
9016 /* Declaring a function type.
9017 Make sure we have a valid type for the function to return. */
9020 {
9024 /* We now know that the TYPE_QUALS don't apply to the
9025 decl, but to its return type. */
9027 }
9030 {
9033 }
9035 /* Error about some types functions can't return. */
9038 {
9041 }
9043 {
9046 }
9048 /* Pick up type qualifiers which should be applied to `this'. */
9050 /* Pick up virt-specifiers. */
9052 /* Pick up the exception specifications. */
9054 /* If the exception-specification is ill-formed, let's pretend
9055 there wasn't one. */
9059 /* Say it's a definition only for the CALL_EXPR
9060 closest to the identifier. */
9063 /* Handle a late-specified return type. */
9065 {
9067 {
9069 {
9073 }
9075 {
9080 }
9081 }
9083 {
9087 }
9088 }
9089 type = splice_late_return_type
9096 && funcdecl_p
9102 {
9103 /* We are within a class's scope. If our declarator name
9104 is the same as the class name, and we are defining
9105 a function, then it is a constructor/destructor, and
9106 therefore returns a void type. */
9108 /* ISO C++ 12.4/2. A destructor may not be declared
9109 const or volatile. A destructor may not be
9110 static.
9112 ISO C++ 12.1. A constructor may not be declared
9113 const or volatile. A constructor may not be
9114 virtual. A constructor may not be static. */
9120 {
9125 }
9129 current_class_type,
9130 flags))
9134 {
9135 /* It's a constructor. */
9139 {
9142 }
9146 }
9149 }
9151 {
9155 {
9156 /* Cannot be both friend and virtual. */
9159 }
9165 name);
9166 }
9168 {
9170 {
9173 }
9174 }
9183 {
9187 }
9190 }
9196 /* Filter out pointers-to-references and references-to-references.
9197 We can get these if a TYPE_DECL is used. */
9200 {
9202 {
9205 }
9207 /* In C++0x, we allow reference to reference declarations
9208 that occur indirectly through typedefs [7.1.3/8 dcl.typedef]
9209 and template type arguments [14.3.1/4 temp.arg.type]. The
9210 check for direct reference to reference declarations, which
9211 are still forbidden, occurs below. Reasoning behind the change
9212 can be found in DR106, DR540, and the rvalue reference
9213 proposals. */
9215 {
9218 }
9219 }
9221 {
9226 }
9228 /* We now know that the TYPE_QUALS don't apply to the decl,
9229 but to the target of the pointer. */
9235 {
9239 memfn_quals);
9243 }
9250 type);
9252 /* When the pointed-to type involves components of variable size,
9253 care must be taken to ensure that the size evaluation code is
9254 emitted early enough to dominate all the possible later uses
9255 and late enough for the variables on which it depends to have
9256 been assigned.
9258 This is expected to happen automatically when the pointed-to
9259 type has a name/declaration of it's own, but special attention
9260 is required if the type is anonymous.
9262 We handle the NORMAL and FIELD contexts here by inserting a
9263 dummy statement that just evaluates the size at a safe point
9264 and ensures it is not deferred until e.g. within a deeper
9265 conditional context (c++/43555).
9267 We expect nothing to be needed here for PARM or TYPENAME.
9268 Evaluating the size at this point for TYPENAME would
9269 actually be incorrect, as we might be in the middle of an
9270 expression with side effects on the pointed-to type size
9271 "arguments" prior to the pointer declaration point and the
9272 size evaluation could end up prior to the side effects. */
9278 {
9279 /* First break out any side-effects. */
9281 /* And then force evaluation of the SAVE_EXPR. */
9283 }
9286 {
9287 /* In C++0x, the type we are creating a reference to might be
9288 a typedef which is itself a reference type. In that case,
9289 we follow the reference collapsing rules in
9290 [7.1.3/8 dcl.typedef] to create the final reference type:
9292 "If a typedef TD names a type that is a reference to a type
9293 T, an attempt to create the type 'lvalue reference to cv TD'
9294 creates the type 'lvalue reference to T,' while an attempt
9295 to create the type "rvalue reference to cv TD' creates the
9296 type TD."
9297 */
9301 {
9304 else
9306 }
9307 else
9308 type = cp_build_reference_type
9311 /* In C++0x, we need this check for direct reference to
9312 reference declarations, which are forbidden by
9313 [8.3.2/5 dcl.ref]. Reference to reference declarations
9314 are only allowed indirectly through typedefs and template
9315 type arguments. Example:
9317 void foo(int & &); // invalid ref-to-ref decl
9319 typedef int & int_ref;
9320 void foo(int_ref &); // valid ref-to-ref decl
9321 */
9325 }
9329 {
9333 /* We will already have complained. */
9335 else
9337 type);
9338 }
9339 else
9342 /* Process a list of type modifier keywords (such as
9343 const or volatile) that were given inside the `*' or `&'. */
9346 {
9347 type
9351 }
9360 }
9361 }
9363 /* We need to stabilize side-effects in VLA sizes for regular array
9364 declarations too, not just pointers to arrays. */
9371 /* A `constexpr' specifier used in an object declaration declares
9372 the object as `const'. */
9374 {
9380 {
9383 }
9384 }
9389 {
9391 unqualified_id);
9393 }
9395 /* If TYPE is a FUNCTION_TYPE, but the function name was explicitly
9396 qualified with a class-name, turn it into a METHOD_TYPE, unless
9397 we know that the function is static. We take advantage of this
9398 opportunity to do other processing that pertains to entities
9399 explicitly declared to be class members. Note that if DECLARATOR
9400 is non-NULL, we know it is a cdk_id declarator; otherwise, we
9401 would not have exited the loop above. */
9405 {
9406 tree t;
9412 {
9413 /* You're supposed to have one `template <...>' for every
9414 template class, but you don't need one for a full
9415 specialization. For example:
9417 template <class T> struct S{};
9418 template <> struct S<int> { void f(); };
9419 void S<int>::f () {}
9421 is correct; there shouldn't be a `template <>' for the
9422 definition of `S<int>::f'. */
9425 /* T is an explicit (not partial) specialization. All
9426 containing classes must therefore also be explicitly
9427 specialized. */
9435 }
9438 {
9440 {
9443 }
9444 else
9448 }
9450 can skip the following checks. */
9453 qualifying type must certainly be complete. */
9454 funcdef_flag
9455 /* A friend declaration of "T::f" is OK, even if
9456 "T" is a template parameter. But, if this
9457 function is not a friend, the qualifying type
9458 must be a class. */
9460 /* For a declaration, the type need not be
9461 complete, if either it is dependent (since there
9462 is no meaningful definition of complete in that
9463 case) or the qualifying class is currently being
9464 defined. */
9467 /* Check that the qualifying type is complete. */
9471 {
9474 {
9480 }
9481 }
9484 {
9488 }
9489 }
9494 /* Now TYPE has the actual type. */
9497 {
9500 else
9502 }
9504 /* Handle parameter packs. */
9506 {
9508 /* Turn the type into a pack expansion.*/
9510 else
9512 }
9514 /* Did array size calculations overflow? */
9520 {
9522 /* If we proceed with the array type as it is, we'll eventually
9523 crash in tree_low_cst(). */
9525 }
9528 && !processing_template_decl
9530 {
9533 else
9536 }
9539 {
9540 /* [dcl.fct.spec] The explicit specifier shall only be used in
9541 declarations of constructors within a class definition. */
9544 }
9547 {
9549 {
9552 }
9554 {
9557 }
9560 {
9563 }
9565 {
9568 }
9570 {
9573 }
9575 {
9579 }
9580 }
9582 /* If this is declaring a typedef name, return a TYPE_DECL. */
9584 {
9585 tree decl;
9587 /* Note that the grammar rejects storage classes
9588 in typenames, fields or parameters. */
9592 /* This declaration:
9594 typedef void f(int) const;
9596 declares a function type which is not a member of any
9597 particular class, but which is cv-qualified; for
9598 example "f S::*" declares a pointer to a const-qualified
9599 member function of S. We record the cv-qualification in the
9600 function type. */
9602 {
9605 /* We have now dealt with these qualifiers. */
9607 }
9610 {
9613 }
9617 else
9623 }
9626 {
9630 || (DECL_MAYBE_IN_CHARGE_DESTRUCTOR_P
9632 /* The TYPE_DECL is "abstract" because there will be
9633 clones of this constructor/destructor, and there will
9634 be copies of this TYPE_DECL generated in those
9635 clones. */
9637 }
9641 unqualified_id);
9643 /* If the user declares "typedef struct {...} foo" then the
9644 struct will have an anonymous name. Fill that name in now.
9645 Nothing can refer to it, so nothing needs know about the name
9646 change. */
9648 && unqualified_id
9654 {
9655 tree t;
9657 /* Replace the anonymous name with the real name everywhere. */
9659 {
9661 /* We do not rename the debug info representing the
9662 anonymous tagged type because the standard says in
9663 [dcl.typedef] that the naming applies only for
9664 linkage purposes. */
9665 /*debug_hooks->set_name (t, decl);*/
9667 }
9672 /* If this is a typedef within a template class, the nested
9673 type is a (non-primary) template. The name for the
9674 template needs updating as well. */
9679 /* Adjust linkage now that we aren't anonymous anymore. */
9683 /* FIXME remangle member functions; member functions of a
9684 type with external linkage have external linkage. */
9685 }
9696 }
9698 /* Detect the case of an array type of unspecified size
9699 which came, as such, direct from a typedef name.
9700 We must copy the type, so that the array's domain can be
9701 individually set by the object's initializer. */
9708 /* Detect where we're using a typedef of function type to declare a
9709 function. PARMS will not be set, so we must create it now. */
9712 {
9714 tree args;
9719 {
9724 }
9729 {
9730 /* A cv-qualifier-seq shall only be part of the function type
9731 for a non-static member function. [8.3.5/4 dcl.fct] */
9734 {
9741 }
9743 /* The qualifiers on the function type become the qualifiers on
9744 the non-static member function. */
9747 }
9748 }
9750 /* If this is a type name (such as, in a cast or sizeof),
9751 compute the type and return it now. */
9754 {
9755 /* Note that the grammar rejects storage classes
9756 in typenames, fields or parameters. */
9760 /* Special case: "friend class foo" looks like a TYPENAME context. */
9762 {
9764 {
9767 }
9769 {
9772 }
9775 {
9776 /* Don't allow friend declaration without a class-key. */
9783 else
9786 type);
9787 }
9789 /* Only try to do this stuff if we didn't already give up. */
9791 {
9792 /* A friendly class? */
9796 else
9798 type);
9801 }
9802 }
9804 {
9811 /* Core issue #547: need to allow this in template type args. */
9814 else
9816 }
9819 }
9824 {
9827 }
9829 /* Only functions may be declared using an operator-function-id. */
9834 {
9837 }
9839 /* We don't check parameter types here because we can emit a better
9840 error message later. */
9842 {
9846 }
9848 /* Now create the decl, which may be a VAR_DECL, a PARM_DECL
9849 or a FUNCTION_DECL, depending on DECL_CONTEXT and TYPE. */
9852 {
9857 {
9860 }
9862 /* A parameter declared as an array of T is really a pointer to T.
9863 One declared as a function is really a pointer to a function.
9864 One declared as a member is really a pointer to member. */
9867 {
9868 /* Transfer const-ness of array into that of type pointed to. */
9871 }
9874 }
9878 {
9883 }
9885 {
9886 tree decl;
9889 {
9895 }
9897 {
9898 /* The C99 flexible array extension. */
9901 {
9903 tf_warning_or_error);
9905 }
9908 {
9909 /* Happens when declaring arrays of sizes which
9910 are error_mark_node, for example. */
9912 }
9914 {
9915 /* Something like struct S { int N::j; }; */
9918 }
9921 {
9923 tree function_context;
9926 {
9927 /* This should never happen in pure C++ (the check
9928 could be an assert). It could happen in
9929 Objective-C++ if someone writes invalid code that
9930 uses a function declaration for an instance
9931 variable or property (instance variables and
9932 properties are parsed as FIELD_DECLs, but they are
9933 part of an Objective-C class, not a C++ class).
9934 That code is invalid and is caught by this
9935 check. */
9937 {
9939 unqualified_id);
9941 }
9943 /* ``A union may [ ... ] not [ have ] virtual functions.''
9944 ARM 9.5 */
9946 {
9948 unqualified_id);
9950 }
9953 {
9955 {
9958 unqualified_id);
9960 }
9961 }
9962 }
9964 /* Check that the name used for a destructor makes sense. */
9966 {
9970 {
9975 }
9978 {
9982 }
9984 {
9987 }
9988 }
9990 {
9995 }
9997 /* Tell grokfndecl if it needs to set TREE_PUBLIC on the node. */
10005 parms,
10006 unqualified_id,
10010 sfk,
10016 #if 0
10017 /* This clobbers the attrs stored in `decl' from `attrlist'. */
10018 /* The decl and setting of decl_attr is also turned off. */
10020 #endif
10022 /* [class.conv.ctor]
10024 A constructor declared without the function-specifier
10025 explicit that can be called with a single parameter
10026 specifies a conversion from the type of its first
10027 parameter to the type of its class. Such a constructor
10028 is called a converting constructor. */
10031 }
10035 {
10038 else
10041 /* If we're instantiating a template, tell them which
10042 instantiation made the field's type be incomplete. */
10049 current_class_type);
10052 }
10053 else
10054 {
10056 {
10060 }
10062 }
10065 {
10066 /* Friends are treated specially. */
10070 {
10072 {
10073 decl = check_explicit_specialization
10078 }
10082 funcdef_flag);
10084 }
10085 else
10087 }
10089 /* Structure field. It may not be a function, except for C++. */
10092 {
10094 {
10096 {
10097 /* An attempt is being made to initialize a non-static
10098 member. But, from [class.mem]:
10100 4 A member-declarator can contain a
10101 constant-initializer only if it declares a static
10102 member (_class.static_) of integral or enumeration
10103 type, see _class.static.data_.
10105 This used to be relatively common practice, but
10106 the rest of the compiler does not correctly
10107 handle the initialization unless the member is
10108 static so we make it static below. */
10110 {
10112 }
10113 else
10114 {
10116 unqualified_id);
10119 }
10120 }
10121 }
10124 {
10125 /* C++ allows static class members. All other work
10126 for this is done by grokfield. */
10129 /* Even if there is an in-class initialization, DECL
10130 is considered undefined until an out-of-class
10131 definition is provided. */
10138 {
10142 }
10143 }
10144 else
10145 {
10147 {
10149 unqualified_id);
10151 }
10159 {
10162 }
10163 }
10168 }
10169 }
10172 {
10173 tree original_name;
10181 else
10193 /* Function declaration not at top level.
10194 Storage classes other than `extern' are not allowed
10195 and `extern' makes no difference. */
10200 {
10203 "%<static%> specified invalid for function %qs "
10205 else
10207 "%<inline%> specifier invalid for function %qs "
10209 }
10212 {
10214 {
10217 }
10220 {
10225 }
10226 }
10228 /* Record presence of `static'. */
10237 funcdef_flag,
10244 {
10247 /* Don't allow a static member function in a class, and forbid
10248 declaring main to be static. */
10250 {
10254 }
10256 {
10257 /* FIXME need arm citation */
10260 }
10263 {
10266 }
10267 }
10268 }
10269 else
10270 {
10271 /* It's a variable. */
10273 /* An uninitialized decl with `extern' is a reference. */
10275 declspecs,
10276 initialized,
10284 {
10287 {
10292 }
10294 {
10297 }
10299 {
10301 "cannot explicitly declare member %q#D to have "
10304 }
10305 }
10307 {
10309 decl);
10311 }
10312 }
10315 {
10317 {
10318 /* It's common practice (and completely valid) to have a const
10319 be initialized and declared extern. */
10322 }
10323 else
10324 {
10327 }
10328 }
10330 /* Record `register' declaration for warnings on &
10331 and in case doing stupid register allocation. */
10340 /* Set constexpr flag on vars (functions got it in grokfndecl). */
10344 /* Record constancy and volatility on the DECL itself . There's
10345 no need to do this when processing a template; we'll do this
10346 for the instantiated declaration based on the type of DECL. */
10351 }
10352 }
10353 \f
10354 /* Subroutine of start_function. Ensure that each of the parameter
10355 types (as listed in PARMS) is complete, as is required for a
10356 function definition. */
10358 static void
10360 {
10362 {
10367 {
10370 }
10371 else
10372 /* grokparms or complete_type_or_else will have already issued
10373 an error. */
10375 }
10376 }
10378 /* Returns nonzero if T is a local variable. */
10380 int
10382 {
10384 /* A VAR_DECL with a context that is a _TYPE is a static data
10385 member. */
10387 /* Any other non-local variable must be at namespace scope. */
10393 }
10395 /* Like local_variable_p, but suitable for use as a tree-walking
10396 function. */
10398 static tree
10401 {
10408 }
10411 /* Check that ARG, which is a default-argument expression for a
10412 parameter DECL, is valid. Returns ARG, or ERROR_MARK_NODE, if
10413 something goes wrong. DECL may also be a _TYPE node, rather than a
10414 DECL, if there is no DECL available. */
10416 tree
10418 {
10419 tree var;
10420 tree decl_type;
10423 /* We get a DEFAULT_ARG when looking at an in-class declaration
10424 with a default argument. Ignore the argument for now; we'll
10425 deal with it after the class is complete. */
10429 {
10432 }
10433 else
10440 /* Something already went wrong. There's no need to check
10441 further. */
10444 /* [dcl.fct.default]
10446 A default argument expression is implicitly converted to the
10447 parameter type. */
10450 {
10454 else
10459 }
10461 /* [dcl.fct.default]
10463 Local variables shall not be used in default argument
10464 expressions.
10466 The keyword `this' shall not be used in a default argument of a
10467 member function. */
10470 {
10473 }
10475 /* All is well. */
10477 }
10479 /* Returns a deprecated type used within TYPE, or NULL_TREE if none. */
10481 static tree
10483 {
10491 /* Do warn about using typedefs to a deprecated class. */
10503 return type_is_deprecated
10507 }
10509 /* Decode the list of parameter types for a function type.
10510 Given the list of things declared inside the parens,
10511 return a list of types.
10513 If this parameter does not end with an ellipsis, we append
10514 void_list_node.
10516 *PARMS is set to the chain of PARM_DECLs created. */
10518 static tree
10520 {
10523 tree parm;
10527 {
10541 {
10545 /* this is a parmlist of `(void)', which is ok. */
10548 /* It's not a good idea to actually create parameters of
10549 type `void'; other parts of the compiler assume that a
10550 void type terminates the parameter list. */
10553 }
10558 {
10563 }
10567 {
10571 }
10574 {
10576 {
10580 }
10582 /* Top-level qualifiers on the parameters are
10583 ignored for function types. */
10586 {
10590 }
10594 {
10595 /* [dcl.fct]/6, parameter types cannot contain pointers
10596 (references) to arrays of unknown bound. */
10601 {
10609 }
10617 }
10623 }
10628 }
10636 }
10638 \f
10639 /* D is a constructor or overloaded `operator='.
10641 Let T be the class in which D is declared. Then, this function
10642 returns:
10644 -1 if D's is an ill-formed constructor or copy assignment operator
10645 whose first parameter is of type `T'.
10646 0 if D is not a copy constructor or copy assignment
10647 operator.
10648 1 if D is a copy constructor or copy assignment operator whose
10649 first parameter is a reference to non-const qualified T.
10650 2 if D is a copy constructor or copy assignment operator whose
10651 first parameter is a reference to const qualified T.
10653 This function can be used as a predicate. Positive values indicate
10654 a copy constructor and nonzero values indicate a copy assignment
10655 operator. */
10657 int
10659 {
10660 tree args;
10661 tree arg_type;
10669 /* Instantiations of template member functions are never copy
10670 functions. Note that member functions of templated classes are
10671 represented as template functions internally, and we must
10672 accept those as copy functions. */
10684 {
10685 /* Pass by value copy assignment operator. */
10687 }
10691 {
10694 }
10695 else
10701 /* There are more non-optional args. */
10705 }
10707 /* D is a constructor or overloaded `operator='.
10709 Let T be the class in which D is declared. Then, this function
10710 returns true when D is a move constructor or move assignment
10711 operator, false otherwise. */
10713 bool
10715 {
10716 tree args;
10717 tree arg_type;
10723 /* There are no move constructors if we are in C++98 mode. */
10729 /* Instantiations of template member functions are never copy
10730 functions. Note that member functions of templated classes are
10731 represented as template functions internally, and we must
10732 accept those as copy functions. */
10752 /* There are more non-optional args. */
10756 }
10758 /* Remember any special properties of member function DECL. */
10760 void
10762 {
10763 tree class_type;
10770 {
10777 {
10778 /* [class.copy]
10780 A non-template constructor for class X is a copy
10781 constructor if its first parameter is of type X&, const
10782 X&, volatile X& or const volatile X&, and either there
10783 are no other parameters or else all other parameters have
10784 default arguments. */
10790 }
10792 {
10796 }
10805 }
10807 {
10808 /* [class.copy]
10810 A non-template assignment operator for class X is a copy
10811 assignment operator if its parameter is of type X, X&, const
10812 X&, volatile X& or const volatile X&. */
10817 {
10823 }
10826 }
10827 /* Destructors are handled in check_methods. */
10828 }
10830 /* Check a constructor DECL has the correct form. Complains
10831 if the class has a constructor of the form X(X). */
10833 int
10835 {
10839 {
10840 /* [class.copy]
10842 A declaration of a constructor for a class X is ill-formed if
10843 its first parameter is of type (optionally cv-qualified) X
10844 and either there are no other parameters or else all other
10845 parameters have default arguments.
10847 We *don't* complain about member template instantiations that
10848 have this form, though; they can occur as we try to decide
10849 what constructor to use during overload resolution. Since
10850 overload resolution will never prefer such a constructor to
10851 the non-template copy constructor (which is either explicitly
10852 or implicitly defined), there's no need to worry about their
10853 existence. Theoretically, they should never even be
10854 instantiated, but that's hard to forestall. */
10858 }
10861 }
10863 /* An operator with this code is unary, but can also be binary. */
10865 static int
10867 {
10874 }
10876 /* An operator with this name can only be unary. */
10878 static int
10880 {
10885 }
10887 /* DECL is a declaration for an overloaded operator. If COMPLAIN is true,
10888 errors are issued for invalid declarations. */
10890 bool
10892 {
10894 tree argtype;
10900 tree class_type;
10902 /* Count the number of arguments and check for ellipsis. */
10915 else
10916 do
10917 {
10918 #define DEF_OPERATOR(NAME, CODE, MANGLING, ARITY, ASSN_P) \
10919 if (ansi_opname (CODE) == name) \
10920 { \
10921 operator_code = (CODE); \
10922 break; \
10923 } \
10924 else if (ansi_assopname (CODE) == name) \
10925 { \
10926 operator_code = (CODE); \
10927 DECL_ASSIGNMENT_OPERATOR_P (decl) = 1; \
10928 break; \
10929 }
10932 #undef DEF_OPERATOR
10935 }
10942 {
10961 }
10963 /* [basic.std.dynamic.allocation]/1:
10965 A program is ill-formed if an allocation function is declared
10966 in a namespace scope other than global scope or declared static
10967 in global scope.
10969 The same also holds true for deallocation functions. */
10972 {
10974 {
10976 {
10979 }
10981 {
10984 }
10985 }
10986 }
10989 {
10992 }
10995 else
10996 {
10997 /* An operator function must either be a non-static member function
10998 or have at least one parameter of a class, a reference to a class,
10999 an enumeration, or a reference to an enumeration. 13.4.0.6 */
11001 {
11007 {
11010 }
11011 else
11012 {
11013 tree p;
11016 {
11020 }
11023 {
11028 /* MAYBE_CLASS_TYPE_P, rather than CLASS_TYPE_P, is used
11029 because these checks are performed even on
11030 template functions. */
11034 }
11037 {
11042 }
11043 }
11044 }
11046 /* There are no restrictions on the arguments to an overloaded
11047 "operator ()". */
11051 /* Warn about conversion operators that will never be used. */
11054 && warn_conversion
11055 /* Warn only declaring the function; there is no need to
11056 warn again about out-of-class definitions. */
11058 {
11067 ref
11073 {
11076 ref
11081 /* Don't force t to be complete here. */
11086 ref
11091 }
11093 }
11096 {
11097 /* 13.4.0.3 */
11100 }
11102 {
11105 }
11107 {
11109 /* We pick the one-argument operator codes by default, so
11110 we don't have to change anything. */
11111 ;
11113 {
11114 /* If we thought this was a unary operator, we now know
11115 it to be a binary operator. */
11117 {
11144 }
11150 && ! processing_template_decl
11152 {
11155 decl);
11156 else
11160 }
11161 }
11162 else
11163 {
11166 else
11169 }
11171 /* More Effective C++ rule 6. */
11177 {
11185 {
11188 arg))
11191 }
11192 else
11193 {
11196 }
11197 }
11198 }
11200 {
11202 {
11205 else
11208 }
11209 }
11211 {
11213 {
11216 else
11219 }
11221 /* More Effective C++ rule 7. */
11227 decl);
11228 }
11230 /* Effective C++ rule 23. */
11242 /* [over.oper]/8 */
11246 {
11250 {
11252 decl);
11253 }
11254 else
11255 {
11258 }
11259 }
11260 }
11262 }
11263 \f
11264 /* Return a string giving the keyword associate with CODE. */
11268 {
11270 {
11283 }
11284 }
11286 /* Name lookup in an elaborated-type-specifier (after the keyword
11287 indicated by TAG_CODE) has found the TYPE_DECL DECL. If the
11288 elaborated-type-specifier is invalid, issue a diagnostic and return
11289 error_mark_node; otherwise, return the *_TYPE to which it referred.
11290 If ALLOW_TEMPLATE_P is true, TYPE may be a class template. */
11292 tree
11294 tree decl,
11296 {
11297 tree type;
11299 /* In the case of:
11301 struct S { struct S *p; };
11303 name lookup will find the TYPE_DECL for the implicit "S::S"
11304 typedef. Adjust for that here. */
11310 /* Check TEMPLATE_TYPE_PARM first because DECL_IMPLICIT_TYPEDEF_P
11311 is false for this case as well. */
11313 {
11317 }
11318 /* [dcl.type.elab]
11320 If the identifier resolves to a typedef-name or a template
11321 type-parameter, the elaborated-type-specifier is ill-formed.
11323 In other words, the only legitimate declaration to use in the
11324 elaborated type specifier is the implicit typedef created when
11325 the type is declared. */
11329 {
11333 }
11338 {
11342 }
11345 {
11349 }
11353 {
11354 /* If a class template appears as elaborated type specifier
11355 without a template header such as:
11357 template <class T> class C {};
11358 void f(class C); // No template header here
11360 then the required template argument is missing. */
11365 }
11368 }
11370 /* Lookup NAME in elaborate type specifier in scope according to
11371 SCOPE and issue diagnostics if necessary.
11372 Return *_TYPE node upon success, NULL_TREE when the NAME is not
11373 found, and ERROR_MARK_NODE for type error. */
11375 static tree
11378 {
11379 tree t;
11380 tree decl;
11382 {
11383 /* First try ordinary name lookup, ignoring hidden class name
11384 injected via friend declaration. */
11386 /* If that fails, the name will be placed in the smallest
11387 non-class, non-function-prototype scope according to 3.3.1/5.
11388 We may already have a hidden name declared as friend in this
11389 scope. So lookup again but not ignoring hidden names.
11390 If we find one, that name will be made visible rather than
11391 creating a new tag. */
11394 }
11395 else
11402 {
11403 /* Look for invalid nested type:
11404 class C {
11405 class C {};
11406 }; */
11408 {
11411 decl);
11413 }
11415 /* Two cases we need to consider when deciding if a class
11416 template is allowed as an elaborated type specifier:
11417 1. It is a self reference to its own class.
11418 2. It comes with a template header.
11420 For example:
11422 template <class T> class C {
11423 class C *c1; // DECL_SELF_REFERENCE_P is true
11424 class D;
11425 };
11426 template <class U> class C; // template_header_p is true
11427 template <class T> class C<T>::D {
11428 class C *c2; // DECL_SELF_REFERENCE_P is true
11429 }; */
11432 decl,
11433 template_header_p
11436 }
11438 {
11442 }
11443 else
11445 }
11447 /* Get the struct, enum or union (TAG_CODE says which) with tag NAME.
11448 Define the tag as a forward-reference if it is not defined.
11450 If a declaration is given, process it here, and report an error if
11451 multiple declarations are not identical.
11453 SCOPE is TS_CURRENT when this is also a definition. Only look in
11454 the current frame for the name (since C++ allows new names in any
11455 scope.) It is TS_WITHIN_ENCLOSING_NON_CLASS if this is a friend
11456 declaration. Only look beginning from the current scope outward up
11457 till the nearest non-class scope. Otherwise it is TS_GLOBAL.
11459 TEMPLATE_HEADER_P is true when this declaration is preceded by
11460 a set of template parameters. */
11462 static tree
11465 {
11467 tree t;
11473 {
11486 }
11488 /* In case of anonymous name, xref_tag is only called to
11489 make type node and push name. Name lookup is not required. */
11492 else
11502 {
11503 /* Since SCOPE is not TS_CURRENT, we are not looking at a
11504 definition of this tag. Since, in addition, we are currently
11505 processing a (member) template declaration of a template
11506 class, we must be very careful; consider:
11508 template <class X>
11509 struct S1
11511 template <class U>
11512 struct S2
11513 { template <class V>
11514 friend struct S1; };
11516 Here, the S2::S1 declaration should not be confused with the
11517 outer declaration. In particular, the inner version should
11518 have a template parameter of level 2, not level 1. This
11519 would be particularly important if the member declaration
11520 were instead:
11522 template <class V = U> friend struct S1;
11524 say, when we should tsubst into `U' when instantiating
11525 S2. On the other hand, when presented with:
11527 template <class T>
11528 struct S1 {
11529 template <class U>
11530 struct S2 {};
11531 template <class U>
11532 friend struct S2;
11533 };
11535 we must find the inner binding eventually. We
11536 accomplish this by making sure that the new type we
11537 create to represent this declaration has the right
11538 TYPE_CONTEXT. */
11541 }
11544 {
11545 /* If no such tag is yet defined, create a forward-reference node
11546 and record it as the "definition".
11547 When a real declaration of this type is found,
11548 the forward-reference will be altered into a real type. */
11550 {
11553 }
11554 else
11555 {
11559 }
11560 }
11561 else
11562 {
11564 {
11567 }
11571 {
11575 }
11577 /* Make injected friend class visible. */
11580 {
11585 {
11588 }
11589 }
11590 }
11593 }
11595 /* Wrapper for xref_tag_1. */
11597 tree
11600 {
11601 tree ret;
11607 }
11610 tree
11612 {
11617 else
11624 }
11626 /* Create the binfo hierarchy for REF with (possibly NULL) base list
11627 BASE_LIST. For each element on BASE_LIST the TREE_PURPOSE is an
11628 access_* node, and the TREE_VALUE is the type of the base-class.
11629 Non-NULL TREE_TYPE indicates virtual inheritance.
11631 Returns true if the binfo hierarchy was successfully created,
11632 false if an error was detected. */
11634 bool
11636 {
11642 tree default_access;
11648 /* The base of a derived class is private by default, all others are
11649 public. */
11654 /* First, make sure that any templates in base-classes are
11655 instantiated. This ensures that if we call ourselves recursively
11656 we do not get confused about which classes are marked and which
11657 are not. */
11660 {
11665 /* An incomplete type. Remove it from the list. */
11667 else
11668 {
11669 max_bases++;
11671 max_vbases++;
11675 }
11676 }
11680 /* The binfo slot should be empty, unless this is an (ill-formed)
11681 redefinition. */
11683 {
11686 }
11696 /* Apply base-class info set up to the variants of this type. */
11700 {
11702 /* An aggregate cannot have baseclasses. */
11706 {
11709 }
11710 }
11713 {
11715 {
11718 }
11719 }
11722 {
11726 {
11729 }
11730 }
11733 {
11746 {
11748 basetype);
11750 }
11757 {
11759 /* The original basetype could have been a typedef'd type. */
11762 /* Inherit flags from the base. */
11773 }
11775 /* We must do this test after we've seen through a typedef
11776 type. */
11778 {
11781 else
11784 }
11787 /* Regenerate the pack expansion for the bases. */
11799 }
11802 /* If we have space in the vbase vector, we must have shared at
11803 least one of them, and are therefore diamond shaped. */
11806 /* Unmark all the types. */
11811 /* Now see if we have a repeated base type. */
11813 {
11816 {
11818 {
11821 }
11823 }
11828 else
11830 }
11833 }
11835 \f
11836 /* Copies the enum-related properties from type SRC to type DST.
11837 Used with the underlying type of an enum and the enum itself. */
11838 static void
11840 {
11850 }
11852 /* Begin compiling the definition of an enumeration type.
11853 NAME is its name,
11855 if ENUMTYPE is not NULL_TREE then the type has alredy been found.
11857 UNDERLYING_TYPE is the type that will be used as the storage for
11858 the enumeration type. This should be NULL_TREE if no storage type
11859 was specified.
11861 SCOPED_ENUM_P is true if this is a scoped enumeration type.
11863 if IS_NEW is not NULL, gets TRUE iff a new type is created.
11865 Returns the type object, as yet incomplete.
11866 Also records info about it so that build_enumerator
11867 may be used to declare the individual values as they are read. */
11869 tree
11872 {
11878 /* [C++0x dcl.enum]p5:
11880 If not explicitly specified, the underlying type of a scoped
11881 enumeration type is int. */
11888 /* If this is the real definition for a previous forward reference,
11889 fill in the contents in the same object that used to be the
11890 forward reference. */
11896 /* In case of a template_decl, the only check that should be deferred
11897 to instantiation time is the comparison of underlying types. */
11899 {
11901 {
11907 }
11909 {
11915 }
11921 {
11927 }
11928 }
11932 {
11933 /* In case of error, make a dummy enum to allow parsing to
11934 continue. */
11936 {
11939 }
11941 /* enumtype may be an ENUMERAL_TYPE if this is a redefinition
11942 of an opaque enum, or an opaque enum of an already defined
11943 enumeration (C++0x only).
11944 In any other case, it'll be NULL_TREE. */
11946 {
11949 }
11956 /* The enum is considered opaque until the opening '{' of the
11957 enumerator list. */
11960 }
11965 {
11967 {
11970 }
11973 else
11976 }
11978 /* If into a template class, the returned enum is always the first
11979 declaration (opaque or not) seen. This way all the references to
11980 this type will be to the same declaration. The following ones are used
11981 only to check for definition errors. */
11984 else
11986 }
11988 /* After processing and defining all the values of an enumeration type,
11989 install their decls in the enumeration type.
11990 ENUMTYPE is the type object. */
11992 void
11994 {
11995 tree values;
11996 tree underlying_type;
11997 tree decl;
11998 tree value;
12000 tree t;
12002 bool fixed_underlying_type_p
12005 /* We built up the VALUES in reverse order. */
12008 /* For an enum defined in a template, just set the type of the values;
12009 all further processing is postponed until the template is
12010 instantiated. We need to set the type so that tsubst of a CONST_DECL
12011 works. */
12013 {
12015 values;
12019 }
12021 /* Determine the minimum and maximum values of the enumerators. */
12023 {
12027 values;
12029 {
12032 /* [dcl.enum]: Following the closing brace of an enum-specifier,
12033 each enumerator has the type of its enumeration. Prior to the
12034 closing brace, the type of each enumerator is the type of its
12035 initializing value. */
12038 /* Update the minimum and maximum values, if appropriate. */
12042 /* Figure out what the minimum and maximum values of the
12043 enumerators are. */
12050 }
12051 }
12052 else
12053 /* [dcl.enum]
12055 If the enumerator-list is empty, the underlying type is as if
12056 the enumeration had a single enumerator with value 0. */
12060 {
12061 /* Compute the number of bits require to represent all values of the
12062 enumeration. We must do this before the type of MINNODE and
12063 MAXNODE are transformed, since tree_int_cst_min_precision relies
12064 on the TREE_TYPE of the value it is passed. */
12072 /* Determine the underlying type of the enumeration.
12074 [dcl.enum]
12076 The underlying type of an enumeration is an integral type that
12077 can represent all the enumerator values defined in the
12078 enumeration. It is implementation-defined which integral type is
12079 used as the underlying type for an enumeration except that the
12080 underlying type shall not be larger than int unless the value of
12081 an enumerator cannot fit in an int or unsigned int.
12083 We use "int" or an "unsigned int" as the underlying type, even if
12084 a smaller integral type would work, unless the user has
12085 explicitly requested that we use the smallest possible type. The
12086 user can request that for all enumerations with a command line
12087 flag, or for just one enumeration with an attribute. */
12089 use_short_enum = flag_short_enums
12094 itk++)
12095 {
12101 }
12103 {
12104 /* DR 377
12106 IF no integral type can represent all the enumerator values, the
12107 enumeration is ill-formed. */
12112 }
12114 /* [dcl.enum]
12116 The value of sizeof() applied to an enumeration type, an object
12117 of an enumeration type, or an enumerator, is the value of sizeof()
12118 applied to the underlying type. */
12121 /* Compute the minimum and maximum values for the type.
12123 [dcl.enum]
12125 For an enumeration where emin is the smallest enumerator and emax
12126 is the largest, the values of the enumeration are the values of the
12127 underlying type in the range bmin to bmax, where bmin and bmax are,
12128 respectively, the smallest and largest values of the smallest bit-
12129 field that can store emin and emax. */
12131 /* The middle-end currently assumes that types with TYPE_PRECISION
12132 narrower than their underlying type are suitably zero or sign
12133 extended to fill their mode. Similarly, it assumes that the front
12134 end assures that a value of a particular type must be within
12135 TYPE_MIN_VALUE and TYPE_MAX_VALUE.
12137 We used to set these fields based on bmin and bmax, but that led
12138 to invalid assumptions like optimizing away bounds checking. So
12139 now we just set the TYPE_PRECISION, TYPE_MIN_VALUE, and
12140 TYPE_MAX_VALUE to the values for the mode above and only restrict
12141 the ENUM_UNDERLYING_TYPE for the benefit of diagnostics. */
12145 set_min_and_max_values_for_integral_type
12148 /* If -fstrict-enums, still constrain TYPE_MIN/MAX_VALUE. */
12151 unsignedp);
12152 }
12153 else
12156 /* Convert each of the enumerators to the type of the underlying
12157 type of the enumeration. */
12159 {
12160 location_t saved_location;
12166 /* If the enumeration type has a fixed underlying type, we
12167 already checked all of the enumerator values. */
12169 else
12172 tf_warning_or_error);
12175 /* Do not clobber shared ints. */
12180 }
12182 /* Fix up all variant types of this enum type. */
12186 /* Finish debugging output for this type. */
12188 }
12190 /* Finishes the enum type. This is called only the first time an
12191 enumeration is seen, be it opaque or odinary.
12192 ENUMTYPE is the type object. */
12194 void
12196 {
12198 {
12202 }
12204 /* Here there should not be any variants of this type. */
12207 }
12209 /* Build and install a CONST_DECL for an enumeration constant of the
12210 enumeration type ENUMTYPE whose NAME and VALUE (if any) are provided.
12211 LOC is the location of NAME.
12212 Assignment of sequential values by default is handled here. */
12214 void
12216 {
12217 tree decl;
12218 tree context;
12219 tree type;
12221 /* If the VALUE was erroneous, pretend it wasn't there; that will
12222 result in the enum being assigned the next value in sequence. */
12226 /* Remove no-op casts from the value. */
12231 {
12232 /* Validate and default VALUE. */
12234 {
12239 {
12241 }
12242 else
12243 {
12246 }
12247 }
12249 /* Default based on previous value. */
12251 {
12253 {
12254 HOST_WIDE_INT hi;
12256 tree prev_value;
12259 /* C++03 7.2/4: If no initializer is specified for the first
12260 enumerator, the type is an unspecified integral
12261 type. Otherwise the type is the same as the type of the
12262 initializing value of the preceding enumerator unless the
12263 incremented value is not representable in that type, in
12264 which case the type is an unspecified integral type
12265 sufficient to contain the incremented value. */
12269 else
12270 {
12275 {
12276 double_int di;
12281 {
12284 {
12290 }
12296 }
12299 else
12301 }
12304 {
12307 }
12308 }
12309 }
12310 else
12312 }
12314 /* Remove no-op casts from the value. */
12317 /* If the underlying type of the enum is fixed, check whether
12318 the enumerator values fits in the underlying type. If it
12319 does not fit, the program is ill-formed [C++0x dcl.enum]. */
12321 && value
12324 {
12328 /* Silently convert the value so that we can continue. */
12331 }
12332 }
12334 /* C++ associates enums with global, function, or class declarations. */
12337 /* Build the actual enumeration constant. Note that the enumeration
12338 constants have the underlying type of the enum (if it is fixed)
12339 or the type of their initializer (if the underlying type of the
12340 enum is not fixed):
12342 [ C++0x dcl.enum ]
12344 If the underlying type is fixed, the type of each enumerator
12345 prior to the closing brace is the underlying type; if the
12346 initializing value of an enumerator cannot be represented by
12347 the underlying type, the program is ill-formed. If the
12348 underlying type is not fixed, the type of each enumerator is
12349 the type of its initializing value.
12351 If the underlying type is not fixed, it will be computed by
12352 finish_enum and we will reset the type of this enumerator. Of
12353 course, if we're processing a template, there may be no value. */
12357 /* This enum declaration is local to the class. We need the full
12358 lang_decl so that we can record DECL_CLASS_CONTEXT, for example. */
12360 else
12361 /* It's a global enum, or it's local to a function. (Note local to
12362 a function could mean local to a class method. */
12371 /* In something like `struct S { enum E { i = 7 }; };' we put `i'
12372 on the TYPE_FIELDS list for `S'. (That's so that you can say
12373 things like `S::i' later.) */
12375 else
12378 /* Add this enumeration constant to the list for this type. */
12380 }
12382 /* Look for an enumerator with the given NAME within the enumeration
12383 type ENUMTYPE. This routine is used primarily for qualified name
12384 lookup into an enumerator in C++0x, e.g.,
12386 enum class Color { Red, Green, Blue };
12388 Color color = Color::Red;
12390 Returns the value corresponding to the enumerator, or
12391 NULL_TREE if no such enumerator was found. */
12392 tree
12394 {
12395 tree e;
12400 }
12402 \f
12403 /* We're defining DECL. Make sure that its type is OK. */
12405 static void
12407 {
12411 /* In a function definition, arg types must be complete. */
12418 {
12423 else
12426 /* Make it return void instead. */
12429 void_type_node,
12431 else
12433 fntype
12436 fntype = (cp_build_type_attribute_variant
12439 }
12440 else
12442 }
12444 /* Create the FUNCTION_DECL for a function definition.
12445 DECLSPECS and DECLARATOR are the parts of the declaration;
12446 they describe the function's name and the type it returns,
12447 but twisted together in a fashion that parallels the syntax of C.
12449 FLAGS is a bitwise or of SF_PRE_PARSED (indicating that the
12450 DECLARATOR is really the DECL for the function we are about to
12451 process and that DECLSPECS should be ignored), SF_INCLASS_INLINE
12452 indicating that the function is an inline defined in-class.
12454 This function creates a binding context for the function body
12455 as well as setting up the FUNCTION_DECL in current_function_decl.
12457 For C++, we must first check whether that datum makes any sense.
12458 For example, "class A local_a(1,2);" means that variable local_a
12459 is an aggregate of type A, which should have a constructor
12460 applied to it with the argument list [1, 2].
12462 On entry, DECL_INITIAL (decl1) should be NULL_TREE or error_mark_node,
12463 or may be a BLOCK if the function has been defined previously
12464 in this translation unit. On exit, DECL_INITIAL (decl1) will be
12465 error_mark_node if the function has never been defined, or
12466 a BLOCK if the function has been defined somewhere. */
12468 void
12470 {
12472 tree fntype;
12473 tree restype;
12476 tree current_function_parms;
12481 /* Sanity check. */
12489 /* ISO C++ 11.4/5. A friend function defined in a class is in
12490 the (lexical) scope of the class in which it is defined. */
12492 {
12495 /* CTYPE could be null here if we're dealing with a template;
12496 for example, `inline friend float foo()' inside a template
12497 will have no CTYPE set. */
12500 else
12502 }
12508 /* Handle gnu_inline attribute. */
12510 {
12515 }
12518 /* This is a constructor, we must ensure that any default args
12519 introduced by this definition are propagated to the clones
12520 now. The clones are used directly in overload resolution. */
12523 /* Sometimes we don't notice that a function is a static member, and
12524 build a METHOD_TYPE for it. Fix that up now. */
12528 /* Set up current_class_type, and enter the scope of the class, if
12529 appropriate. */
12535 /* Now that we have entered the scope of the class, we must restore
12536 the bindings for any template parameters surrounding DECL1, if it
12537 is an inline member template. (Order is important; consider the
12538 case where a template parameter has the same name as a field of
12539 the class.) It is not until after this point that
12540 PROCESSING_TEMPLATE_DECL is guaranteed to be set up correctly. */
12544 /* Effective C++ rule 15. */
12550 /* Make the init_value nonzero so pushdecl knows this is not tentative.
12551 error_mark_node is replaced below (in poplevel) with the BLOCK. */
12555 /* This function exists in static storage.
12556 (This does not mean `static' in the C sense!) */
12559 /* We must call push_template_decl after current_class_type is set
12560 up. (If we are processing inline definitions after exiting a
12561 class scope, current_class_type will be NULL_TREE until set above
12562 by push_nested_class.) */
12564 {
12565 /* FIXME: Handle error_mark_node more gracefully. */
12569 }
12571 /* We are now in the scope of the function being defined. */
12574 /* Save the parm names or decls from this function's declarator
12575 where store_parm_decls will find them. */
12578 /* Make sure the parameter and return types are reasonable. When
12579 you declare a function, these types can be incomplete, but they
12580 must be complete when you define the function. */
12583 /* Build the return declaration for the function. */
12586 {
12587 tree resdecl;
12595 }
12597 /* Let the user know we're compiling this function. */
12600 /* Record the decl so that the function name is defined.
12601 If we already have a decl for this name, and it is a FUNCTION_DECL,
12602 use the old decl. */
12604 {
12605 /* A specialization is not used to guide overload resolution. */
12609 {
12613 /* If something went wrong when registering the declaration,
12614 use DECL1; we have to have a FUNCTION_DECL to use when
12615 parsing the body of the function. */
12616 ;
12617 else
12618 {
12619 /* Otherwise, OLDDECL is either a previous declaration
12620 of the same function or DECL1 itself. */
12627 {
12628 tree context;
12630 /* Check whether DECL1 is in an anonymous
12631 namespace. */
12633 context;
12635 {
12639 }
12644 }
12647 }
12648 }
12649 else
12650 {
12651 /* We need to set the DECL_CONTEXT. */
12654 }
12657 /* If #pragma weak applies, mark the decl appropriately now.
12658 The pragma only applies to global functions. Because
12659 determining whether or not the #pragma applies involves
12660 computing the mangled name for the declaration, we cannot
12661 apply the pragma until after we have merged this declaration
12662 with any previous declarations; if the original declaration
12663 has a linkage specification, that specification applies to
12664 the definition as well, and may affect the mangled name. */
12667 }
12669 /* Reset this in case the call to pushdecl changed it. */
12674 /* This function may already have been parsed, in which case just
12675 return; our caller will skip over the body without parsing. */
12679 /* Initialize RTL machinery. We cannot do this until
12680 CURRENT_FUNCTION_DECL and DECL_RESULT are set up. We do this
12681 even when processing a template; this is how we get
12682 CFUN set up, and our per-function variables initialized.
12683 FIXME factor out the non-RTL stuff. */
12687 /* Initialize the language data structures. Whenever we start
12688 a new function, we destroy temporaries in the usual way. */
12693 /* Start the statement-tree, start the tree now. */
12696 /* If we are (erroneously) defining a function that we have already
12697 defined before, wipe out what we knew before. */
12702 {
12703 /* We know that this was set up by `grokclassfn'. We do not
12704 wait until `store_parm_decls', since evil parse errors may
12705 never get us to that point. Here we keep the consistency
12706 between `current_class_type' and `current_class_ptr'. */
12712 cp_function_chain->x_current_class_ref
12714 /* Set this second to avoid shortcut in cp_build_indirect_ref. */
12717 /* Constructors and destructors need to know whether they're "in
12718 charge" of initializing virtual base classes. */
12721 {
12724 }
12726 {
12729 }
12730 }
12733 /* Implicitly-defined methods (like the
12734 destructor for a class in which no destructor
12735 is explicitly declared) must not be defined
12736 until their definition is needed. So, we
12737 ignore interface specifications for
12738 compiler-generated functions. */
12744 {
12752 /* This is a function in a local class in an extern inline
12753 function. */
12755 }
12756 /* If this function belongs to an interface, it is public.
12757 If it belongs to someone else's interface, it is also external.
12758 This only affects inlines and template instantiations. */
12760 {
12763 {
12767 && ! flag_implement_inlines
12770 /* For WIN32 we also want to put these in linkonce sections. */
12772 }
12773 else
12776 /* If this function is in an interface implemented in this file,
12777 make sure that the back end knows to emit this function
12778 here. */
12781 }
12784 {
12785 /* If MULTIPLE_SYMBOL_SPACES is defined and we saw a #pragma
12786 interface, we will have both finfo->interface_unknown and
12787 finfo->interface_only set. In that case, we don't want to
12788 use the normal heuristics because someone will supply a
12789 #pragma implementation elsewhere, and deducing it here would
12790 produce a conflict. */
12795 }
12796 else
12797 {
12798 /* This is a definition, not a reference.
12799 So clear DECL_EXTERNAL, unless this is a GNU extern inline. */
12807 else
12809 }
12811 /* Determine the ELF visibility attribute for the function. We must not
12812 do this before calling "pushdecl", as we must allow "duplicate_decls"
12813 to merge any attributes appropriately. We also need to wait until
12814 linkage is set. */
12825 {
12829 }
12834 }
12837 /* Like start_preparsed_function, except that instead of a
12838 FUNCTION_DECL, this function takes DECLSPECS and DECLARATOR.
12840 Returns 1 on success. If the DECLARATOR is not suitable for a function
12841 (it defines a datum instead), we return 0, which tells
12842 yyparse to report a parse error. */
12844 int
12847 tree attrs)
12848 {
12849 tree decl1;
12854 /* If the declarator is not suitable for a function definition,
12855 cause a syntax error. */
12857 {
12860 }
12863 /* main must return int. grokfndecl should have corrected it
12864 (and issued a diagnostic) if the user got it wrong. */
12866 integer_type_node));
12871 }
12872 \f
12873 /* Returns true iff an EH_SPEC_BLOCK should be created in the body of
12874 FN. */
12876 static bool
12878 {
12880 && !processing_template_decl
12882 /* We insert the EH_SPEC_BLOCK only in the original
12883 function; then, it is copied automatically to the
12884 clones. */
12886 /* Implicitly-generated constructors and destructors have
12887 exception specifications. However, those specifications
12888 are the union of the possible exceptions specified by the
12889 constructors/destructors for bases and members, so no
12890 unallowed exception will ever reach this function. By
12891 not creating the EH_SPEC_BLOCK we save a little memory,
12892 and we avoid spurious warnings about unreachable
12893 code. */
12895 }
12897 /* Store the parameter declarations into the current function declaration.
12898 This is called after parsing the parameter declarations, before
12899 digesting the body of the function.
12901 Also install to binding contour return value identifier, if any. */
12903 static void
12905 {
12907 tree parm;
12909 /* This is a chain of any other decls that came in among the parm
12910 declarations. If a parm is declared with enum {foo, bar} x;
12911 then CONST_DECLs for foo and bar are put here. */
12915 {
12916 /* This case is when the function was defined with an ANSI prototype.
12917 The parms already have decls, so we need not do anything here
12918 except record them as in effect
12919 and complain if any redundant old-style parm decls were written. */
12922 tree next;
12924 /* Must clear this because it might contain TYPE_DECLs declared
12925 at class level. */
12928 /* If we're doing semantic analysis, then we'll call pushdecl
12929 for each of these. We must do them in reverse order so that
12930 they end in the correct forward order. */
12934 {
12937 {
12941 else
12943 }
12944 else
12945 {
12946 /* If we find an enum constant or a type tag,
12947 put it aside for the moment. */
12950 }
12951 }
12953 /* Get the decls in their original chain order and record in the
12954 function. This is all and only the PARM_DECLs that were
12955 pushed into scope by the loop above. */
12957 }
12958 else
12961 /* Now store the final chain of decls for the arguments
12962 as the decl-chain of the current lexical scope.
12963 Put the enumerators in as well, at the front so that
12964 DECL_ARGUMENTS is not modified. */
12969 }
12971 \f
12972 /* We have finished doing semantic analysis on DECL, but have not yet
12973 generated RTL for its body. Save away our current state, so that
12974 when we want to generate RTL later we know what to do. */
12976 static void
12978 {
12981 /* Save the language-specific per-function data so that we can
12982 get it back when we really expand this function. */
12985 /* Make a copy. */
12990 /* Clear out the bits we don't need. */
12994 }
12997 /* Set the return value of the constructor (if present). */
12999 static void
13001 {
13002 tree val;
13003 tree exprstmt;
13007 {
13008 /* Any return from a constructor will end up here. */
13014 /* Return the address of the object. */
13017 }
13018 }
13020 /* Do all the processing for the beginning of a destructor; set up the
13021 vtable pointers and cleanups for bases and members. */
13023 static void
13025 {
13026 tree compound_stmt;
13028 /* If the CURRENT_CLASS_TYPE is incomplete, we will have already
13029 issued an error message. We still want to try to process the
13030 body of the function, but initialize_vtbl_ptrs will crash if
13031 TYPE_BINFO is NULL. */
13033 {
13035 /* Make all virtual function table pointers in non-virtual base
13036 classes point to CURRENT_CLASS_TYPE's virtual function
13037 tables. */
13041 /* And insert cleanups for our bases and members so that they
13042 will be properly destroyed if we throw. */
13044 }
13045 }
13047 /* At the end of every destructor we generate code to delete the object if
13048 necessary. Do that now. */
13050 static void
13052 {
13053 tree exprstmt;
13055 /* Any return from a destructor will end up here; that way all base
13056 and member cleanups will be run when the function returns. */
13059 /* In a virtual destructor, we must call delete. */
13061 {
13062 tree if_stmt;
13065 /* [class.dtor]
13067 At the point of definition of a virtual destructor (including
13068 an implicit definition), non-placement operator delete shall
13069 be looked up in the scope of the destructor's class and if
13070 found shall be accessible and unambiguous. */
13072 virtual_size,
13079 current_in_charge_parm,
13080 integer_one_node),
13081 if_stmt);
13085 }
13088 {
13089 tree val;
13094 /* Return the address of the object. */
13097 }
13098 }
13100 /* Do the necessary processing for the beginning of a function body, which
13101 in this case includes member-initializers, but not the catch clauses of
13102 a function-try-block. Currently, this means opening a binding level
13103 for the member-initializers (in a ctor), member cleanups (in a dtor),
13104 and capture proxies (in a lambda operator()). */
13106 tree
13108 {
13109 tree stmt;
13116 else
13117 /* Always keep the BLOCK node associated with the outermost pair of
13118 curly braces of a function. These are needed for correct
13119 operation of dwarfout.c. */
13130 }
13132 /* Do the processing for the end of a function body. Currently, this means
13133 closing out the cleanups for fully-constructed bases and members, and in
13134 the case of the destructor, deleting the object if desired. Again, this
13135 is only meaningful for [cd]tors, since they are the only functions where
13136 there is a significant distinction between the main body and any
13137 function catch clauses. Handling, say, main() return semantics here
13138 would be wrong, as flowing off the end of a function catch clause for
13139 main() would also need to return 0. */
13141 void
13143 {
13147 /* Close the block. */
13156 }
13158 /* Given a function, returns the BLOCK corresponding to the outermost level
13159 of curly braces, skipping the artificial block created for constructor
13160 initializers. */
13162 tree
13164 {
13167 /* Skip the artificial function body block. */
13170 }
13172 /* If FNDECL is a class's key method, add the class to the list of
13173 keyed classes that should be emitted. */
13175 static void
13177 {
13181 {
13185 }
13186 }
13188 /* Subroutine of finish_function.
13189 Save the body of constexpr functions for possible
13190 future compile time evaluation. */
13192 static void
13194 {
13199 }
13201 /* Finish up a function declaration and compile that function
13202 all the way to assembler language output. The free the storage
13203 for the function definition.
13205 FLAGS is a bitwise or of the following values:
13206 2 - INCLASS_INLINE
13207 We just finished processing the body of an in-class inline
13208 function definition. (This processing will have taken place
13209 after the class definition is complete.) */
13211 tree
13213 {
13218 /* When we get some parse errors, we can end up without a
13219 current_function_decl, so cope. */
13233 /* TREE_READONLY (fndecl) = 1;
13234 This caused &foo to be of type ptr-to-const-function
13235 which then got a warning when stored in a ptr-to-function variable. */
13238 /* The current function is being defined, so its DECL_INITIAL should
13239 be set, and unless there's a multiple definition, it should be
13240 error_mark_node. */
13243 /* For a cloned function, we've already got all the code we need;
13244 there's no need to add any extra bits. */
13246 {
13248 {
13249 /* Make it so that `main' always returns 0 by default (or
13250 1 for VMS). */
13251 #if VMS_TARGET
13253 #else
13255 #endif
13256 }
13261 current_eh_spec_block);
13262 }
13264 /* If we're saving up tree structure, tie off the function now. */
13269 /* If this function can't throw any exceptions, remember that. */
13272 && !flag_non_call_exceptions
13276 /* This must come after expand_function_end because cleanups might
13277 have declarations (from inline functions) that need to go into
13278 this function's blocks. */
13280 /* If the current binding level isn't the outermost binding level
13281 for this function, either there is a bug, or we have experienced
13282 syntax errors and the statement tree is malformed. */
13284 {
13285 /* Make sure we have already experienced errors. */
13288 /* Throw away the broken statement tree and extra binding
13289 levels. */
13293 {
13296 else
13298 }
13299 }
13302 /* Statements should always be full-expressions at the outermost set
13303 of curly braces for a function. */
13306 /* Save constexpr function body before it gets munged by
13307 the NRV transformation. */
13310 /* Set up the named return value optimization, if we can. Candidate
13311 variables are selected in check_return_expr. */
13313 {
13315 tree outer;
13318 /* This is only worth doing for fns that return in memory--and
13319 simpler, since we don't have to worry about promoted modes. */
13321 /* Only allow this for variables declared in the outer scope of
13322 the function so we know that their lifetime always ends with a
13323 return; see g++.dg/opt/nrv6.C. We could be more flexible if
13324 we were to do this optimization in tree-ssa. */
13330 }
13332 /* Remember that we were in class scope. */
13336 /* Must mark the RESULT_DECL as being in this function. */
13339 /* Set the BLOCK_SUPERCONTEXT of the outermost function scope to point
13340 to the FUNCTION_DECL node itself. */
13343 /* Save away current state, if appropriate. */
13347 /* Complain if there's just no return statement. */
13352 /* Don't complain if we abort or throw. */
13353 && !current_function_returns_abnormally
13354 /* Don't complain if we are declared noreturn. */
13358 /* Structor return values (if any) are set by the compiler. */
13361 {
13365 }
13367 /* Store the end of the function, so that we get good line number
13368 info for the epilogue. */
13371 /* Complain about parameters that are only set, but never otherwise used. */
13373 && !processing_template_decl
13376 {
13377 tree decl;
13380 decl;
13396 }
13398 /* Complain about locally defined typedefs that are not used in this
13399 function. */
13402 /* Genericize before inlining. */
13404 {
13408 /* Clear out the bits we don't need. */
13417 }
13418 /* Clear out the bits we don't need. */
13421 /* We're leaving the context of this function, so zap cfun. It's still in
13422 DECL_STRUCT_FUNCTION, and we'll restore it in tree_rest_of_compilation. */
13426 /* If this is an in-class inline definition, we may have to pop the
13427 bindings for the template parameters that we added in
13428 maybe_begin_member_template_processing when start_function was
13429 called. */
13433 /* Leave the scope of the class. */
13439 /* Clean up. */
13444 {
13446 tree decl;
13451 }
13454 }
13455 \f
13456 /* Create the FUNCTION_DECL for a function definition.
13457 DECLSPECS and DECLARATOR are the parts of the declaration;
13458 they describe the return type and the name of the function,
13459 but twisted together in a fashion that parallels the syntax of C.
13461 This function creates a binding context for the function body
13462 as well as setting up the FUNCTION_DECL in current_function_decl.
13464 Returns a FUNCTION_DECL on success.
13466 If the DECLARATOR is not suitable for a function (it defines a datum
13467 instead), we return 0, which tells yyparse to report a parse error.
13469 May return void_type_node indicating that this method is actually
13470 a friend. See grokfield for more details.
13472 Came here with a `.pushlevel' .
13474 DO NOT MAKE ANY CHANGES TO THIS CODE WITHOUT MAKING CORRESPONDING
13475 CHANGES TO CODE IN `grokfield'. */
13477 tree
13480 {
13488 {
13491 }
13496 /* Pass friends other than inline friend functions back. */
13501 {
13506 }
13513 /* We process method specializations in finish_struct_1. */
13515 {
13519 }
13522 {
13524 {
13527 }
13528 }
13534 }
13535 \f
13537 /* VAR is a VAR_DECL. If its type is incomplete, remember VAR so that
13538 we can lay it out later, when and if its type becomes complete. */
13540 void
13542 {
13545 /* Keep track of variables with incomplete types. */
13548 {
13556 /* RTTI TD entries are created while defining the type_info. */
13559 {
13560 incomplete_var *iv
13564 }
13565 }
13566 }
13568 /* Called when a class type (given by TYPE) is defined. If there are
13569 any existing VAR_DECLs whose type has been completed by this
13570 declaration, update them now. */
13572 void
13574 {
13579 {
13581 {
13584 /* Complete the type of the variable. The VAR_DECL itself
13585 will be laid out in expand_expr. */
13588 /* Remove this entry from the list. */
13590 }
13591 else
13592 ix++;
13593 }
13595 /* Check for pending declarations which may have abstract type. */
13597 }
13599 /* If DECL is of a type which needs a cleanup, build and return an
13600 expression to perform that cleanup here. Return NULL_TREE if no
13601 cleanup need be done. */
13603 tree
13605 {
13606 tree type;
13607 tree attr;
13608 tree cleanup;
13610 /* Assume no cleanup is required. */
13616 /* Handle "__attribute__((cleanup))". We run the cleanup function
13617 before the destructor since the destructor is what actually
13618 terminates the lifetime of the object. */
13621 {
13622 tree id;
13623 tree fn;
13624 tree arg;
13626 /* Get the name specified by the user for the cleanup function. */
13628 /* Look up the name to find the cleanup function to call. It is
13629 important to use lookup_name here because that is what is
13630 used in c-common.c:handle_cleanup_attribute when performing
13631 initial checks on the attribute. Note that those checks
13632 include ensuring that the function found is not an overloaded
13633 function, or an object with an overloaded call operator,
13634 etc.; we can rely on the fact that the function found is an
13635 ordinary FUNCTION_DECL. */
13642 }
13643 /* Handle ordinary C++ destructors. */
13646 {
13650 tree addr;
13651 tree call;
13655 else
13658 /* Optimize for space over speed here. */
13668 else
13670 }
13673 }
13674 \f
13675 /* When a stmt has been parsed, this function is called. */
13677 void
13679 {
13680 }
13682 /* Return the FUNCTION_TYPE that corresponds to MEMFNTYPE, which can be a
13683 FUNCTION_DECL, METHOD_TYPE, FUNCTION_TYPE, pointer or reference to
13684 METHOD_TYPE or FUNCTION_TYPE, or pointer to member function. */
13686 tree
13688 {
13689 tree fntype;
13690 tree args;
13703 fntype = (cp_build_type_attribute_variant
13705 fntype = (build_exception_variant
13708 }
13710 /* DECL was originally constructed as a non-static member function,
13711 but turned out to be static. Update it accordingly. */
13713 void
13715 {
13727 }
13729 /* Return which tree structure is used by T, or TS_CP_GENERIC if T is
13730 one of the language-independent trees. */
13732 enum cp_tree_node_structure_enum
13734 {
13736 {
13750 }
13751 }
13753 /* Build the void_list_node (void_type_node having been created). */
13754 tree
13756 {
13759 }
13761 bool
13763 {
13764 /* A missing noreturn is ok for the `main' function. */
13766 }
13768 /* Return the COMDAT group into which DECL should be placed. */
13770 tree
13772 {
13773 tree name;
13775 /* Virtual tables, construction virtual tables, and virtual table
13776 tables all go in a single COMDAT group, named after the primary
13777 virtual table. */
13780 /* For all other DECLs, the COMDAT group is the mangled name of the
13781 declaration itself. */
13782 else
13783 {
13785 {
13786 /* If TARGET_USE_LOCAL_THUNK_ALIAS_P, use_thunk puts the thunk
13787 into the same section as the target function. In that case
13788 we must return target's name. */
13794 else
13796 }
13798 }
13801 }