| blob | d62f9d7acf613639171211458c3081106c2f9e27 |
1 /* Language-dependent node constructors for parse phase of GNU compiler.
2 Copyright (C) 1987, 1988, 1992, 1993, 1994, 1995, 1996, 1997, 1998,
3 1999, 2000, 2001, 2002, 2003, 2004, 2005, 2007, 2008, 2009
4 Free Software Foundation, Inc.
5 Hacked 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/>. */
53 /* If REF is an lvalue, returns the kind of lvalue that REF is.
54 Otherwise, returns clk_none. */
56 static cp_lvalue_kind
58 {
62 /* Expressions of reference type are sometimes wrapped in
63 INDIRECT_REFs. INDIRECT_REFs are just internal compiler
64 representation, not part of the language, so we have to look
65 through them. */
72 {
73 /* unnamed rvalue references are rvalues */
80 /* lvalue references and named rvalue references are lvalues. */
82 }
88 {
91 /* preincrements and predecrements are valid lvals, provided
92 what they refer to are valid lvals. */
103 /* Look at the member designator. */
105 ;
107 /* The "field" can be a FUNCTION_DECL or an OVERLOAD in some
108 situations. If we're seeing a COMPONENT_REF, it's a non-static
109 member, so it isn't an lvalue. */
114 {
115 /* Clear the ordinary bit. If this object was a class
116 rvalue we want to preserve that information. */
118 /* The lvalue is for a bitfield. */
120 }
131 /* CONST_DECL without TREE_STATIC are enumeration values and
132 thus not lvalues. With TREE_STATIC they are used by ObjC++
133 in objc_build_string_object and need to be considered as
134 lvalues. */
150 /* A currently unresolved scope ref. */
155 /* Disallow <? and >? as lvalues if either argument side-effects. */
183 /* Any class-valued call would be wrapped in a TARGET_EXPR. */
187 /* All functions (except non-static-member functions) are
188 lvalues. */
193 /* We now represent a reference to a single static member function
194 with a BASELINK. */
195 /* This CONST_CAST is okay because BASELINK_FUNCTIONS returns
196 its argument unmodified and we assign it to a const_tree. */
200 /* We must consider NON_DEPENDENT_EXPRs to be lvalues so that
201 things like "&E" where "E" is an expression with a
202 non-dependent type work. It is safe to be lenient because an
203 error will be issued when the template is instantiated if "E"
204 is not an lvalue. */
209 }
211 /* If one operand is not an lvalue at all, then this expression is
212 not an lvalue. */
216 /* Otherwise, it's an lvalue, and it has all the odd properties
217 contributed by either operand. */
219 /* It's not an ordinary lvalue if it involves any other kind. */
222 /* It can't be both a pseudo-lvalue and a non-addressable lvalue.
223 A COND_EXPR of those should be wrapped in a TARGET_EXPR. */
228 }
230 /* Returns the kind of lvalue that REF is, in the sense of
231 [basic.lval]. This function should really be named lvalue_p; it
232 computes the C++ definition of lvalue. */
234 cp_lvalue_kind
236 {
240 else
242 }
244 /* This differs from real_lvalue_p in that class rvalues are considered
245 lvalues. */
247 bool
249 {
251 }
253 /* This differs from real_lvalue_p in that rvalues formed by dereferencing
254 rvalue references are considered rvalues. */
256 bool
258 {
262 else
264 }
266 /* Test whether DECL is a builtin that may appear in a
267 constant-expression. */
269 bool
271 {
272 /* At present BUILT_IN_CONSTANT_P is the only builtin we're allowing
273 in constant-expressions. We may want to add other builtins later. */
275 }
277 /* Build a TARGET_EXPR, initializing the DECL with the VALUE. */
279 static tree
281 {
282 tree t;
284 #ifdef ENABLE_CHECKING
289 #endif
293 /* We always set TREE_SIDE_EFFECTS so that expand_expr does not
294 ignore the TARGET_EXPR. If there really turn out to be no
295 side-effects, then the optimizer should be able to get rid of
296 whatever code is generated anyhow. */
300 }
302 /* Return an undeclared local temporary of type TYPE for use in building a
303 TARGET_EXPR. */
305 static tree
307 {
315 }
317 /* Set various status flags when building an AGGR_INIT_EXPR object T. */
319 static void
321 {
326 {
330 {
333 {
336 }
337 }
338 }
340 }
342 /* Build an AGGR_INIT_EXPR of class tcc_vl_exp with the indicated RETURN_TYPE,
343 FN, and SLOT. NARGS is the number of call arguments which are specified
344 as a tree array ARGS. */
346 static tree
349 {
350 tree t;
361 }
363 /* INIT is a CALL_EXPR or AGGR_INIT_EXPR which needs info about its
364 target. TYPE is the type to be initialized.
366 Build an AGGR_INIT_EXPR to represent the initialization. This function
367 differs from build_cplus_new in that an AGGR_INIT_EXPR can only be used
368 to initialize another object, whereas a TARGET_EXPR can either
369 initialize another object or create its own temporary object, and as a
370 result building up a TARGET_EXPR requires that the type's destructor be
371 callable. */
373 tree
375 {
376 tree fn;
377 tree slot;
378 tree rval;
381 /* Make sure that we're not trying to create an instance of an
382 abstract class. */
389 else
396 /* We split the CALL_EXPR into its function and its arguments here.
397 Then, in expand_expr, we put them back together. The reason for
398 this is that this expression might be a default argument
399 expression. In that case, we need a new temporary every time the
400 expression is used. That's what break_out_target_exprs does; it
401 replaces every AGGR_INIT_EXPR with a copy that uses a fresh
402 temporary slot. Then, expand_expr builds up a call-expression
403 using the new slot. */
405 /* If we don't need to use a constructor to create an object of this
406 type, don't mess with AGGR_INIT_EXPR. */
408 {
415 else
422 }
423 else
427 }
429 /* INIT is a CALL_EXPR or AGGR_INIT_EXPR which needs info about its
430 target. TYPE is the type that this initialization should appear to
431 have.
433 Build an encapsulation of the initialization to perform
434 and return it so that it can be processed by language-independent
435 and language-specific expression expanders. */
437 tree
439 {
441 tree slot;
447 else
454 }
456 /* Return a TARGET_EXPR which expresses the direct-initialization of one
457 array from another. */
459 tree
461 {
470 }
472 /* Build a TARGET_EXPR using INIT to initialize a new temporary of the
473 indicated TYPE. */
475 tree
477 {
487 /* We need to build up a copy constructor call. A void initializer
488 means we're being called from bot_manip. COND_EXPR is a special
489 case because we already have copies on the arms and we don't want
490 another one here. A CONSTRUCTOR is aggregate initialization, which
491 is handled separately. A VA_ARG_EXPR is magic creation of an
492 aggregate; there's no additional work to be done. */
496 }
498 /* Like the above function, but without the checking. This function should
499 only be used by code which is deliberately trying to subvert the type
500 system, such as call_builtin_trap. Or build_over_call, to avoid
501 infinite recursion. */
503 tree
505 {
506 tree slot;
512 }
514 /* Like build_target_expr_with_type, but use the type of INIT. */
516 tree
518 {
521 else
523 }
525 /* If EXPR is a bitfield reference, convert it to the declared type of
526 the bitfield, and return the resulting expression. Otherwise,
527 return EXPR itself. */
529 tree
531 {
532 tree bitfield_type;
537 expr);
539 }
541 /* EXPR is being used in an rvalue context. Return a version of EXPR
542 that is marked as an rvalue. */
544 tree
546 {
547 tree type;
554 /* [basic.lval]
556 Non-class rvalues always have cv-unqualified types. */
561 /* We need to do this for rvalue refs as well to get the right answer
562 from decltype; see c++/36628. */
569 }
571 \f
572 /* Hash an ARRAY_TYPE. K is really of type `tree'. */
574 static hashval_t
576 {
577 hashval_t hash;
584 }
587 tree type;
588 tree domain;
591 /* Compare two ARRAY_TYPEs. K1 is really of type `tree', K2 is really
592 of type `cplus_array_info*'. */
594 static int
596 {
601 }
603 /* Hash table containing dependent array types, which are unsuitable for
604 the language-independent type hash table. */
607 /* Like build_array_type, but handle special C++ semantics. */
609 tree
611 {
612 tree t;
620 {
622 cplus_array_info cai;
623 hashval_t hash;
637 /* We have found the type: we're done. */
639 else
640 {
641 /* Build a new array type. */
646 /* Store it in the hash table. */
649 /* Set the canonical type for this new node. */
654 || (index_type
657 = build_cplus_array_type
660 else
662 }
663 }
664 else
667 /* We want TYPE_MAIN_VARIANT of an array to strip cv-quals from the
668 element type as well, so fix it up if needed. */
670 {
672 index_type);
674 {
678 }
679 }
681 /* Push these needs up so that initialization takes place
682 more easily. */
688 }
690 /* Return an ARRAY_TYPE with element type ELT and length N. */
692 tree
694 {
696 }
698 /* Return a reference type node referring to TO_TYPE. If RVAL is
699 true, return an rvalue reference type, otherwise return an lvalue
700 reference type. If a type node exists, reuse it, otherwise create
701 a new one. */
702 tree
704 {
710 /* This code to create rvalue reference types is based on and tied
711 to the code creating lvalue reference types in the middle-end
712 functions build_reference_type_for_mode and build_reference_type.
714 It works by putting the rvalue reference type nodes after the
715 lvalue reference nodes in the TYPE_NEXT_REF_TO linked list, so
716 they will effectively be ignored by the middle end. */
733 else
740 }
742 /* Returns EXPR cast to rvalue reference type, like std::move. */
744 tree
746 {
751 }
753 /* Used by the C++ front end to build qualified array types. However,
754 the C version of this function does not properly maintain canonical
755 types (which are not used in C). */
756 tree
758 {
760 }
762 \f
763 /* Make a variant of TYPE, qualified with the TYPE_QUALS. Handles
764 arrays correctly. In particular, if TYPE is an array of T's, and
765 TYPE_QUALS is non-empty, returns an array of qualified T's.
767 FLAGS determines how to deal with ill-formed qualifications. If
768 tf_ignore_bad_quals is set, then bad qualifications are dropped
769 (this is permitted if TYPE was introduced via a typedef or template
770 type parameter). If bad qualifications are dropped and tf_warning
771 is set, then a warning is issued for non-const qualifications. If
772 tf_ignore_bad_quals is not set and tf_error is not set, we
773 return error_mark_node. Otherwise, we issue an error, and ignore
774 the qualifications.
776 Qualification of a reference type is valid when the reference came
777 via a typedef or template type argument. [dcl.ref] No such
778 dispensation is provided for qualifying a function type. [dcl.fct]
779 DR 295 queries this and the proposed resolution brings it into line
780 with qualifying a reference. We implement the DR. We also behave
781 in a similar manner for restricting non-pointer types. */
783 tree
786 tsubst_flags_t complain)
787 {
788 tree result;
798 {
799 /* In C++, the qualification really applies to the array element
800 type. Obtain the appropriately qualified element type. */
801 tree t;
802 tree element_type
804 type_quals,
805 complain);
810 /* See if we already have an identically qualified type. Tests
811 should be equivalent to those in check_qualified_type. */
821 {
824 /* Keep the typedef name. */
826 {
829 }
830 }
832 /* Even if we already had this variant, we update
833 TYPE_NEEDS_CONSTRUCTING and TYPE_HAS_NONTRIVIAL_DESTRUCTOR in case
834 they changed since the variant was originally created.
836 This seems hokey; if there is some way to use a previous
837 variant *without* coming through here,
838 TYPE_NEEDS_CONSTRUCTING will never be updated. */
844 }
846 {
847 /* For a pointer-to-member type, we can't just return a
848 cv-qualified version of the RECORD_TYPE. If we do, we
849 haven't changed the field that contains the actual pointer to
850 a method, and so TYPE_PTRMEMFUNC_FN_TYPE will be wrong. */
851 tree t;
856 }
858 {
863 }
865 /* A reference or method type shall not be cv-qualified.
866 [dcl.ref], [dcl.fct]. This used to be an error, but as of DR 295
867 (in CD1) we always ignore extra cv-quals on functions. */
872 {
876 }
878 /* But preserve any function-cv-quals on a FUNCTION_TYPE. */
882 /* A restrict-qualified type must be a pointer (or reference)
883 to object or incomplete type. */
888 {
891 }
898 else
899 {
903 }
905 /* Retrieve (or create) the appropriately qualified variant. */
908 /* If this was a pointer-to-method type, and we just made a copy,
909 then we need to unshare the record that holds the cached
910 pointer-to-member-function type, because these will be distinct
911 between the unqualified and qualified types. */
918 /* We may also have ended up building a new copy of the canonical
919 type of a pointer-to-method type, which could have the same
920 sharing problem described above. */
929 }
931 /* Return TYPE with const and volatile removed. */
933 tree
935 {
944 }
946 /* Builds a qualified variant of T that is not a typedef variant.
947 E.g. consider the following declarations:
948 typedef const int ConstInt;
949 typedef ConstInt* PtrConstInt;
950 If T is PtrConstInt, this function returns a type representing
951 const int*.
952 In other words, if T is a typedef, the function returns the underlying type.
953 The cv-qualification and attributes of the type returned match the
954 input type.
955 They will always be compatible types.
956 The returned type is built so that all of its subtypes
957 recursively have their typedefs stripped as well.
959 This is different from just returning TYPE_CANONICAL (T)
960 Because of several reasons:
961 * If T is a type that needs structural equality
962 its TYPE_CANONICAL (T) will be NULL.
963 * TYPE_CANONICAL (T) desn't carry type attributes
964 and looses template parameter names. */
966 tree
968 {
977 {
993 {
996 }
1005 {
1008 arg_node;
1010 {
1016 arg_types =
1018 }
1023 /* A list of parameters not ending with an ellipsis
1024 must end with void_list_node. */
1030 {
1033 result =
1036 }
1037 else
1038 {
1040 arg_types);
1042 }
1047 }
1051 }
1058 }
1060 /* Setup a TYPE_DECL node as a typedef representation.
1061 See comments of set_underlying_type in c-common.c. */
1063 void
1065 {
1067 /* If T is a template type parm, make it require structural equality.
1068 This is useful when comparing two template type parms,
1069 because it forces the comparison of the template parameters of their
1070 decls. */
1073 }
1075 \f
1076 /* Makes a copy of BINFO and TYPE, which is to be inherited into a
1077 graph dominated by T. If BINFO is NULL, TYPE is a dependent base,
1078 and we do a shallow copy. If BINFO is non-NULL, we do a deep copy.
1079 VIRT indicates whether TYPE is inherited virtually or not.
1080 IGO_PREV points at the previous binfo of the inheritance graph
1081 order chain. The newly copied binfo's TREE_CHAIN forms this
1082 ordering.
1084 The CLASSTYPE_VBASECLASSES vector of T is constructed in the
1085 correct order. That is in the order the bases themselves should be
1086 constructed in.
1088 The BINFO_INHERITANCE of a virtual base class points to the binfo
1089 of the most derived type. ??? We could probably change this so that
1090 BINFO_INHERITANCE becomes synonymous with BINFO_PRIMARY, and hence
1091 remove a field. They currently can only differ for primary virtual
1092 virtual bases. */
1094 tree
1096 {
1097 tree new_binfo;
1100 {
1101 /* See if we've already made this virtual base. */
1105 }
1110 /* Chain it into the inheritance graph. */
1115 {
1117 tree base_binfo;
1125 /* We do not need to copy the accesses, as they are read only. */
1128 /* Recursively copy base binfos of BINFO. */
1130 {
1131 tree new_base_binfo;
1141 }
1142 }
1143 else
1147 {
1148 /* Push it onto the list after any virtual bases it contains
1149 will have been pushed. */
1153 }
1156 }
1157 \f
1158 /* Hashing of lists so that we don't make duplicates.
1159 The entry point is `list_hash_canon'. */
1161 /* Now here is the hash table. When recording a list, it is added
1162 to the slot whose index is the hash code mod the table size.
1163 Note that the hash table is used for several kinds of lists.
1164 While all these live in the same table, they are completely independent,
1165 and the hash code is computed differently for each of these. */
1169 struct list_proxy
1170 {
1171 tree purpose;
1172 tree value;
1173 tree chain;
1174 };
1176 /* Compare ENTRY (an entry in the hash table) with DATA (a list_proxy
1177 for a node we are thinking about adding). */
1179 static int
1181 {
1188 }
1190 /* Compute a hash code for a list (chain of TREE_LIST nodes
1191 with goodies in the TREE_PURPOSE, TREE_VALUE, and bits of the
1192 TREE_COMMON slots), by adding the hash codes of the individual entries. */
1194 static hashval_t
1196 {
1204 else
1208 else
1211 }
1213 /* Hash an already existing TREE_LIST. */
1215 static hashval_t
1217 {
1222 }
1224 /* Given list components PURPOSE, VALUE, AND CHAIN, return the canonical
1225 object for an identical list if one already exists. Otherwise, build a
1226 new one, and record it as the canonical object. */
1228 tree
1230 {
1235 /* Hash the list node. */
1237 /* Create a proxy for the TREE_LIST we would like to create. We
1238 don't actually create it so as to avoid creating garbage. */
1242 /* See if it is already in the table. */
1244 INSERT);
1245 /* If not, create a new node. */
1249 }
1251 /* Constructor for hashed lists. */
1253 tree
1255 {
1257 }
1258 \f
1259 void
1261 {
1262 HOST_WIDE_INT n;
1263 tree virtuals;
1273 else
1280 {
1287 }
1288 }
1290 /* Build a representation for the qualified name SCOPE::NAME. TYPE is
1291 the type of the result expression, if known, or NULL_TREE if the
1292 resulting expression is type-dependent. If TEMPLATE_P is true,
1293 NAME is known to be a template because the user explicitly used the
1294 "template" keyword after the "::".
1296 All SCOPE_REFs should be built by use of this function. */
1298 tree
1300 {
1301 tree t;
1311 }
1313 /* Returns nonzero if X is an expression for a (possibly overloaded)
1314 function. If "f" is a function or function template, "f", "c->f",
1315 "c.f", "C::f", and "f<int>" will all be considered possibly
1316 overloaded functions. Returns 2 if the function is actually
1317 overloaded, i.e., if it is impossible to know the type of the
1318 function without performing overload resolution. */
1320 int
1322 {
1323 /* A baselink is also considered an overloaded function. */
1336 }
1338 /* Returns true iff X is an expression for an overloaded function
1339 whose type cannot be known without performing overload
1340 resolution. */
1342 bool
1344 {
1346 }
1348 tree
1350 {
1352 /* A baselink is also considered an overloaded function. */
1361 }
1363 tree
1365 {
1367 }
1369 /* Return a new OVL node, concatenating it with the old one. */
1371 tree
1373 {
1380 }
1382 /* Build a new overloaded function. If this is the first one,
1383 just return it; otherwise, ovl_cons the _DECLs */
1385 tree
1387 {
1393 }
1395 \f
1396 #define PRINT_RING_SIZE 4
1400 {
1407 /* Only cache functions. */
1413 /* See if this print name is lying around. */
1416 /* yes, so return it. */
1423 {
1424 /* There may be both translated and untranslated versions of the
1425 name cached. */
1427 {
1432 }
1434 }
1443 }
1447 {
1449 }
1453 {
1455 }
1456 \f
1457 /* Build the FUNCTION_TYPE or METHOD_TYPE which may throw exceptions
1458 listed in RAISES. */
1460 tree
1462 {
1463 tree v;
1475 /* Need to build a new variant. */
1479 }
1481 /* Given a TEMPLATE_TEMPLATE_PARM node T, create a new
1482 BOUND_TEMPLATE_TEMPLATE_PARM bound with NEWARGS as its template
1483 arguments. */
1485 tree
1487 {
1489 tree t2;
1495 /* These nodes have to be created to reflect new TYPE_DECL and template
1496 arguments. */
1509 }
1511 /* Called from count_trees via walk_tree. */
1513 static tree
1515 {
1522 }
1524 /* Debugging function for measuring the rough complexity of a tree
1525 representation. */
1527 int
1529 {
1533 }
1535 /* Called from verify_stmt_tree via walk_tree. */
1537 static tree
1541 {
1549 /* If this statement is already present in the hash table, then
1550 there is a circularity in the statement tree. */
1557 }
1559 /* Debugging function to check that the statement T has not been
1560 corrupted. For now, this function simply checks that T contains no
1561 circularities. */
1563 void
1565 {
1566 htab_t statements;
1570 }
1572 /* Check if the type T depends on a type with no linkage and if so, return
1573 it. If RELAXED_P then do not consider a class type declared within
1574 a vague-linkage function to have no linkage. */
1576 tree
1578 {
1579 tree r;
1581 /* There's no point in checking linkage on template functions; we
1582 can't know their complete types. */
1587 {
1591 /* Lambda types that don't have mangling scope have no linkage. We
1592 check CLASSTYPE_LAMBDA_EXPR here rather than LAMBDA_TYPE_P because
1593 when we get here from pushtag none of the lambda information is
1594 set up yet, so we want to assume that the lambda has linkage and
1595 fix it up later if not. */
1599 /* Fall through. */
1603 /* Fall through. */
1605 /* Only treat anonymous types as having no linkage if they're at
1606 namespace scope. This is core issue 966. */
1611 {
1612 /* If we're a nested type of a !TREE_PUBLIC class, we might not
1613 have linkage, or we might just be in an anonymous namespace.
1614 If we're in a TREE_PUBLIC class, we have linkage. */
1618 {
1621 else
1623 }
1624 else
1626 }
1636 ptrmem:
1638 relaxed_p);
1647 /* Fall through. */
1649 {
1650 tree parm;
1654 {
1658 }
1660 }
1664 }
1665 }
1667 #ifdef GATHER_STATISTICS
1669 #endif
1671 void
1673 {
1677 #ifdef GATHER_STATISTICS
1679 depth_reached);
1680 #endif
1681 }
1683 /* Return, as an INTEGER_CST node, the number of elements for TYPE
1684 (which is an ARRAY_TYPE). This counts only elements of the top
1685 array. */
1687 tree
1689 {
1693 size_one_node);
1694 }
1696 /* Return, as an INTEGER_CST node, the number of elements for TYPE
1697 (which is an ARRAY_TYPE). This one is a recursive count of all
1698 ARRAY_TYPEs that are clumped together. */
1700 tree
1702 {
1706 {
1711 }
1713 }
1715 /* Called from break_out_target_exprs via mapcar. */
1717 static tree
1719 {
1724 {
1725 /* There can't be any TARGET_EXPRs or their slot variables below
1726 this point. We used to check !TREE_SIDE_EFFECTS, but then we
1727 failed to copy an ADDR_EXPR of the slot VAR_DECL. */
1730 }
1732 {
1733 tree u;
1737 else
1740 /* Map the old variable to the new one. */
1747 /* Replace the old expression with the new version. */
1749 /* We don't have to go below this point; the recursive call to
1750 break_out_target_exprs will have handled anything below this
1751 point. */
1754 }
1756 /* Make a copy of this node. */
1758 }
1760 /* Replace all remapped VAR_DECLs in T with their new equivalents.
1761 DATA is really a splay-tree mapping old variables to new
1762 variables. */
1764 static tree
1768 {
1772 {
1777 }
1780 }
1782 /* When we parse a default argument expression, we may create
1783 temporary variables via TARGET_EXPRs. When we actually use the
1784 default-argument expression, we make a copy of the expression, but
1785 we must replace the temporaries with appropriate local versions. */
1787 tree
1789 {
1801 {
1804 }
1807 }
1809 /* Similar to `build_nt', but for template definitions of dependent
1810 expressions */
1812 tree
1814 {
1815 tree t;
1828 {
1831 }
1835 }
1838 /* Similar to `build', but for template definitions. */
1840 tree
1842 {
1843 tree t;
1857 {
1862 }
1866 }
1868 /* Similar to `build', but for template definitions of non-dependent
1869 expressions. NON_DEP is the non-dependent expression that has been
1870 built. */
1872 tree
1874 {
1875 tree t;
1890 {
1893 }
1896 /* This should not be considered a COMPOUND_EXPR, because it
1897 resolves to an overload. */
1902 }
1904 /* Similar to `build_nt_call_vec', but for template definitions of
1905 non-dependent expressions. NON_DEP is the non-dependent expression
1906 that has been built. */
1908 tree
1910 {
1915 }
1917 tree
1919 {
1926 }
1928 /* Returns the namespace that contains DECL, whether directly or
1929 indirectly. */
1931 tree
1933 {
1935 {
1940 else
1942 }
1943 }
1945 /* Returns true if decl is within an anonymous namespace, however deeply
1946 nested, or false otherwise. */
1948 bool
1950 {
1952 {
1958 /* Classes and namespaces inside anonymous namespaces have
1959 TREE_PUBLIC == 0, so we can shortcut the search. */
1964 else
1966 }
1967 }
1969 /* Return truthvalue of whether T1 is the same tree structure as T2.
1970 Return 1 if they are the same. Return 0 if they are different. */
1972 bool
1974 {
1993 /* They might have become equal now. */
2001 {
2023 /* We need to do this when determining whether or not two
2024 non-type pointer to member function template arguments
2025 are the same. */
2027 /* The first operand is RTL. */
2043 {
2058 }
2061 {
2065 /* Special case: if either target is an unallocated VAR_DECL,
2066 it means that it's going to be unified with whatever the
2067 TARGET_EXPR is really supposed to initialize, so treat it
2068 as being equivalent to anything. */
2079 }
2092 /* For comparing uses of parameters in late-specified return types
2093 with an out-of-class definition of the function. */
2097 else
2123 {
2144 }
2148 {
2156 else
2158 }
2161 {
2173 }
2176 /* Two pointer-to-members are the same if they point to the same
2177 field or function in the same class. */
2196 }
2199 {
2207 {
2220 }
2226 }
2227 /* We can get here with --disable-checking. */
2229 }
2231 /* The type of ARG when used as an lvalue. */
2233 tree
2235 {
2238 }
2240 /* The type of ARG for printing error messages; denote lvalues with
2241 reference types. */
2243 tree
2245 {
2249 ;
2251 ;
2258 }
2260 /* Does FUNCTION use a variable-length argument list? */
2262 int
2264 {
2270 }
2272 /* Returns 1 if decl is a member of a class. */
2274 int
2276 {
2279 }
2281 /* Create a placeholder for member access where we don't actually have an
2282 object that the access is against. */
2284 tree
2286 {
2289 }
2291 /* We've gotten a reference to a member of TYPE. Return *this if appropriate,
2292 or a dummy object otherwise. If BINFOP is non-0, it is filled with the
2293 binfo path from current_class_type to TYPE, or 0. */
2295 tree
2297 {
2299 tree binfo;
2305 else
2306 {
2307 /* Reference from a nested class member function. */
2310 }
2316 /* Kludge: Make sure that current_class_type is actually
2317 correct. It might not be if we're in the middle of
2318 tsubst_default_argument. */
2320 current_class_type))
2324 /* In a lambda, need to go through 'this' capture. */
2325 decl = (cp_build_indirect_ref
2326 ((lambda_expr_this_capture
2329 else
2333 }
2335 /* Returns 1 if OB is a placeholder object, or a pointer to one. */
2337 int
2339 {
2344 }
2346 /* Returns 1 iff type T is something we want to treat as a scalar type for
2347 the purpose of deciding whether it is trivial/POD/standard-layout. */
2349 static bool
2351 {
2357 }
2359 /* Returns true iff T requires non-trivial default initialization. */
2361 bool
2363 {
2368 else
2370 }
2372 /* Returns true iff copying an object of type T (including via move
2373 constructor) is non-trivial. That is, T has no non-trivial copy
2374 constructors and no non-trivial move constructors. */
2376 bool
2378 {
2382 {
2387 }
2388 else
2390 }
2392 /* Returns 1 iff type T is a trivially copyable type, as defined in
2393 [basic.types] and [class]. */
2395 bool
2397 {
2408 else
2410 }
2412 /* Returns 1 iff type T is a trivial type, as defined in [basic.types] and
2413 [class]. */
2415 bool
2417 {
2423 else
2425 }
2427 /* Returns 1 iff type T is a POD type, as defined in [basic.types]. */
2429 bool
2431 {
2432 /* This CONST_CAST is okay because strip_array_types returns its
2433 argument unmodified and we assign it to a const_tree. */
2439 /* [class]/10: A POD struct is a class that is both a trivial class and a
2440 standard-layout class, and has no non-static data members of type
2441 non-POD struct, non-POD union (or array of such types).
2443 We don't need to check individual members because if a member is
2444 non-std-layout or non-trivial, the class will be too. */
2446 else
2447 /* The C++98 definition of POD is different. */
2449 }
2451 /* Returns true iff T is POD for the purpose of layout, as defined in the
2452 C++ ABI. */
2454 bool
2456 {
2461 else
2463 }
2465 /* Returns true iff T is a standard-layout type, as defined in
2466 [basic.types]. */
2468 bool
2470 {
2475 else
2477 }
2479 /* Nonzero iff type T is a class template implicit specialization. */
2481 bool
2483 {
2485 }
2487 /* Returns 1 iff zero initialization of type T means actually storing
2488 zeros in it. */
2490 int
2492 {
2493 /* This CONST_CAST is okay because strip_array_types returns its
2494 argument unmodified and we assign it to a const_tree. */
2500 /* NULL pointers to data members are initialized with -1. */
2504 /* Classes that contain types that can't be zero-initialized, cannot
2505 be zero-initialized themselves. */
2510 }
2512 /* Table of valid C++ attributes. */
2514 {
2515 /* { name, min_len, max_len, decl_req, type_req, fn_type_req, handler } */
2520 };
2522 /* Handle a "java_interface" attribute; arguments as in
2523 struct attribute_spec.handler. */
2524 static tree
2526 tree name,
2527 tree args ATTRIBUTE_UNUSED ,
2530 {
2534 {
2536 name);
2539 }
2545 }
2547 /* Handle a "com_interface" attribute; arguments as in
2548 struct attribute_spec.handler. */
2549 static tree
2551 tree name,
2552 tree args ATTRIBUTE_UNUSED ,
2555 {
2563 {
2567 }
2571 name);
2574 }
2576 /* Handle an "init_priority" attribute; arguments as in
2577 struct attribute_spec.handler. */
2578 static tree
2580 tree name,
2581 tree args,
2584 {
2593 {
2597 }
2609 /* Static objects in functions are initialized the
2610 first time control passes through that
2611 function. This is not precise enough to pin down an
2612 init_priority value, so don't allow it. */
2614 {
2619 }
2622 {
2626 }
2628 /* Check for init_priorities that are reserved for
2629 language and runtime support implementations.*/
2631 {
2632 warning
2634 }
2637 {
2641 }
2642 else
2643 {
2647 }
2648 }
2650 /* Return a new PTRMEM_CST of the indicated TYPE. The MEMBER is the
2651 thing pointed to by the constant. */
2653 tree
2655 {
2660 }
2662 /* Build a variant of TYPE that has the indicated ATTRIBUTES. May
2663 return an existing type if an appropriate type already exists. */
2665 tree
2667 {
2668 tree new_type;
2676 /* Making a new main variant of a class type is broken. */
2680 }
2682 /* Return TRUE if TYPE1 and TYPE2 are identical for type hashing purposes.
2683 Called only after doing all language independent checks. Only
2684 to check TYPE_RAISES_EXCEPTIONS for FUNCTION_TYPE, the rest is already
2685 compared in type_hash_eq. */
2687 bool
2689 {
2694 }
2696 /* Apply FUNC to all language-specific sub-trees of TP in a pre-order
2697 traversal. Called from walk_tree. */
2699 tree
2702 {
2704 tree result;
2706 #define WALK_SUBTREE(NODE) \
2707 do \
2708 { \
2709 result = cp_walk_tree (&(NODE), func, data, pset); \
2710 if (result) goto out; \
2711 } \
2712 while (0)
2714 /* Not one of the easy cases. We must explicitly go through the
2715 children. */
2718 {
2727 /* None of these have subtrees other than those already walked
2728 above. */
2766 {
2771 }
2792 {
2796 }
2814 }
2816 /* We didn't find what we were looking for. */
2817 out:
2820 #undef WALK_SUBTREE
2821 }
2823 /* Like save_expr, but for C++. */
2825 tree
2827 {
2828 /* There is no reason to create a SAVE_EXPR within a template; if
2829 needed, we can create the SAVE_EXPR when instantiating the
2830 template. Furthermore, the middle-end cannot handle C++-specific
2831 tree codes. */
2835 }
2837 /* Initialize tree.c. */
2839 void
2841 {
2843 }
2845 /* Returns the kind of special function that DECL (a FUNCTION_DECL)
2846 is. Note that sfk_none is zero, so this function can be used as a
2847 predicate to test whether or not DECL is a special function. */
2849 special_function_kind
2851 {
2852 /* Rather than doing all this stuff with magic names, we should
2853 probably have a field of type `special_function_kind' in
2854 DECL_LANG_SPECIFIC. */
2862 {
2867 }
2880 }
2882 /* Returns nonzero if TYPE is a character type, including wchar_t. */
2884 int
2886 {
2893 }
2895 /* Returns the kind of linkage associated with the indicated DECL. Th
2896 value returned is as specified by the language standard; it is
2897 independent of implementation details regarding template
2898 instantiation, etc. For example, it is possible that a declaration
2899 to which this function assigns external linkage would not show up
2900 as a global symbol when you run `nm' on the resulting object file. */
2902 linkage_kind
2904 {
2905 /* This function doesn't attempt to calculate the linkage from first
2906 principles as given in [basic.link]. Instead, it makes use of
2907 the fact that we have already set TREE_PUBLIC appropriately, and
2908 then handles a few special cases. Ideally, we would calculate
2909 linkage first, and then transform that into a concrete
2910 implementation. */
2912 /* Things that don't have names have no linkage. */
2916 /* Fields have no linkage. */
2920 /* Things that are TREE_PUBLIC have external linkage. */
2927 /* Linkage of a CONST_DECL depends on the linkage of the enumeration
2928 type. */
2932 /* Some things that are not TREE_PUBLIC have external linkage, too.
2933 For example, on targets that don't have weak symbols, we make all
2934 template instantiations have internal linkage (in the object
2935 file), but the symbols should still be treated as having external
2936 linkage from the point of view of the language. */
2942 /* Things in local scope do not have linkage, if they don't have
2943 TREE_PUBLIC set. */
2947 /* Members of the anonymous namespace also have TREE_PUBLIC unset, but
2948 are considered to have external linkage for language purposes. DECLs
2949 really meant to have internal linkage have DECL_THIS_STATIC set. */
2953 {
2957 /* Static data members and static member functions from classes
2958 in anonymous namespace also don't have TREE_PUBLIC set. */
2961 }
2963 /* Everything else has internal linkage. */
2965 }
2966 \f
2967 /* EXP is an expression that we want to pre-evaluate. Returns (in
2968 *INITP) an expression that will perform the pre-evaluation. The
2969 value returned by this function is a side-effect free expression
2970 equivalent to the pre-evaluated expression. Callers must ensure
2971 that *INITP is evaluated before EXP. */
2973 tree
2975 {
2976 tree init_expr;
2982 {
2985 }
2986 else
2987 {
2992 }
2997 }
2999 /* Add NEW_EXPR, an expression whose value we don't care about, after the
3000 similar expression ORIG. */
3002 tree
3004 {
3010 }
3012 /* Like stabilize_expr, but for a call whose arguments we want to
3013 pre-evaluate. CALL is modified in place to use the pre-evaluated
3014 arguments, while, upon return, *INITP contains an expression to
3015 compute the arguments. */
3017 void
3019 {
3025 {
3028 }
3033 {
3034 tree init;
3038 }
3041 }
3043 /* Like stabilize_expr, but for an AGGR_INIT_EXPR whose arguments we want
3044 to pre-evaluate. CALL is modified in place to use the pre-evaluated
3045 arguments, while, upon return, *INITP contains an expression to
3046 compute the arguments. */
3048 void
3050 {
3061 {
3062 tree init;
3066 }
3069 }
3071 /* Like stabilize_expr, but for an initialization.
3073 If the initialization is for an object of class type, this function
3074 takes care not to introduce additional temporaries.
3076 Returns TRUE iff the expression was successfully pre-evaluated,
3077 i.e., if INIT is now side-effect free, except for, possible, a
3078 single call to a constructor. */
3080 bool
3082 {
3093 {
3096 }
3106 /* Default-initialization. */
3109 /* If the initializer is a COND_EXPR, we can't preevaluate
3110 anything. */
3115 {
3118 }
3121 {
3124 }
3126 /* The initialization is being performed via a bitwise copy -- and
3127 the item copied may have side effects. */
3129 }
3131 /* Like "fold", but should be used whenever we might be processing the
3132 body of a template. */
3134 tree
3136 {
3137 /* In the body of a template, there is never any need to call
3138 "fold". We will call fold later when actually instantiating the
3139 template. Integral constant expressions in templates will be
3140 evaluated via fold_non_dependent_expr, as necessary. */
3144 /* Fold C++ front-end specific tree codes. */
3149 }
3151 /* Returns true if a cast to TYPE may appear in an integral constant
3152 expression. */
3154 bool
3156 {
3160 }
3162 /* Return true if we need to fix linkage information of DECL. */
3164 static bool
3166 {
3167 /* Skip if DECL is not externally visible. */
3171 /* We need to fix DECL if it a appears to be exported but with no
3172 function body. Thunks do not have CFGs and we may need to
3173 handle them specially later. */
3177 {
3180 /* Don't fix same_body aliases. Although they don't have their own
3181 CFG, they share it with what they alias to. */
3186 }
3189 }
3191 /* Clean the C++ specific parts of the tree T. */
3193 void
3195 {
3198 {
3199 /* Default args are not interesting anymore. */
3202 {
3205 }
3206 }
3209 {
3210 /* If T is used in this translation unit at all, the definition
3211 must exist somewhere else since we have decided to not emit it
3212 in this TU. So make it an external reference. */
3215 }
3218 {
3222 /* Drop anonymous names. */
3226 }
3227 }
3229 /* Stub for c-common. Please keep in sync with c-decl.c.
3230 FIXME: If address space support is target specific, then this
3231 should be a C target hook. But currently this is not possible,
3232 because this function is called via REGISTER_TARGET_PRAGMAS. */
3233 void
3235 addr_space_t as ATTRIBUTE_UNUSED)
3236 {
3237 }
3239 \f
3240 #if defined ENABLE_TREE_CHECKING && (GCC_VERSION >= 2007)
3241 /* Complain that some language-specific thing hanging off a tree
3242 node has been accessed improperly. */
3244 void
3246 {
3249 }