| blob | 6c02c1cf0dac2c993627dd4ab3ecad315cfe0739 |
1 /* RunTime Type Identification
2 Copyright (C) 1995-2013 Free Software Foundation, Inc.
3 Mostly written by Jason Merrill (jason@cygnus.com).
5 This file is part of GCC.
7 GCC is free software; you can redistribute it and/or modify
8 it under the terms of the GNU General Public License as published by
9 the Free Software Foundation; either version 3, or (at your option)
10 any later version.
12 GCC is distributed in the hope that it will be useful,
13 but WITHOUT ANY WARRANTY; without even the implied warranty of
14 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 GNU General Public License for more details.
17 You should have received a copy of the GNU General Public License
18 along with GCC; see the file COPYING3. If not see
19 <http://www.gnu.org/licenses/>. */
33 /* C++ returns type information to the user in struct type_info
34 objects. We also use type information to implement dynamic_cast and
35 exception handlers. Type information for a particular type is
36 indicated with an ABI defined structure derived from type_info.
37 This would all be very straight forward, but for the fact that the
38 runtime library provides the definitions of the type_info structure
39 and the ABI defined derived classes. We cannot build declarations
40 of them directly in the compiler, but we need to layout objects of
41 their type. Somewhere we have to lie.
43 We define layout compatible POD-structs with compiler-defined names
44 and generate the appropriate initializations for them (complete
45 with explicit mention of their vtable). When we have to provide a
46 type_info to the user we reinterpret_cast the internal compiler
47 type to type_info. A well formed program can only explicitly refer
48 to the type_infos of complete types (& cv void). However, we chain
49 pointer type_infos to the pointed-to-type, and that can be
50 incomplete. We only need the addresses of such incomplete
51 type_info objects for static initialization.
53 The type information VAR_DECL of a type is held on the
54 IDENTIFIER_GLOBAL_VALUE of the type's mangled name. That VAR_DECL
55 will be the internal type. It will usually have the correct
56 internal type reflecting the kind of type it represents (pointer,
57 array, function, class, inherited class, etc). When the type it
58 represents is incomplete, it will have the internal type
59 corresponding to type_info. That will only happen at the end of
60 translation, when we are emitting the type info objects. */
62 /* Auxiliary data we hold for each type_info derived object we need. */
67 translation. */
70 the type_info derived type. */
75 {
86 TK_FIXED /* end of fixed descriptors. */
87 /* ... abi::__vmi_type_info<I> */
90 /* Helper macro to get maximum scalar-width of pointer or of the 'long'-type.
91 This of interest for llp64 targets. */
92 #define LONGPTR_T \
93 integer_types[(POINTER_SIZE <= TYPE_PRECISION (integer_types[itk_long]) \
94 ? itk_long : itk_long_long)]
96 /* A vector of all tinfo decls that haven't yet been emitted. */
99 /* A vector of all type_info derived types we need. The first few are
100 fixed and created early. The remainder are for multiple inheritance
101 and are generated as needed. */
125 \f
126 static void
128 {
131 }
133 static void
135 {
138 }
140 /* Declare language defined type_info type and a pointer to const
141 type_info. This is incomplete here, and will be completed when
142 the user #includes <typeinfo>. There are language defined
143 restrictions on what can be done until that is included. Create
144 the internal versions of the ABI types. */
146 void
148 {
149 tree type_info_type;
155 const_type_info_type_node
162 }
164 /* Given the expression EXP of type `class *', return the head of the
165 object pointed to by EXP with type cv void*, if the class has any
166 virtual functions (TYPE_POLYMORPHIC_P), else just return the
167 expression. */
169 tree
171 {
173 tree offset;
174 tree index;
182 /* We use this a couple of times below, protect it. */
185 /* The offset-to-top field is at index -2 from the vptr. */
190 tf_warning_or_error),
191 index);
196 }
198 /* Get a bad_cast node for the program to throw...
200 See libstdc++/exception.cc for __throw_bad_cast */
202 static tree
204 {
208 NULL_TREE));
211 }
213 /* Return an expression for "__cxa_bad_typeid()". The expression
214 returned is an lvalue of type "const std::type_info". */
216 static tree
218 {
221 {
222 tree t;
227 }
230 }
231 \f
232 /* Return an lvalue expression whose type is "const std::type_info"
233 and whose value indicates the type of the expression EXP. If EXP
234 is a reference to a polymorphic class, return the dynamic type;
235 otherwise return the static type of the expression. */
237 static tree
239 {
240 tree type;
241 tree t;
248 /* peel back references, so they match. */
251 /* Peel off cv qualifiers. */
254 /* For UNKNOWN_TYPEs call complete_type_or_else to get diagnostics. */
262 /* If exp is a reference to polymorphic type, get the real type_info. */
264 {
265 /* build reference to type_info from vtable. */
266 tree index;
268 /* The RTTI information is at index -1. */
273 }
274 else
275 /* Otherwise return the type_info for the static type of the expr. */
279 }
281 static bool
283 {
287 {
290 }
293 {
296 }
301 /* Make sure abi::__type_info_pseudo has the same alias set
302 as std::type_info. */
305 else
310 }
312 /* Return an expression for "typeid(EXP)". The expression returned is
313 an lvalue of type "const std::type_info". */
315 tree
317 {
327 /* FIXME when integrating with c_fully_fold, mark
328 resolves_to_fixed_type_p case as a non-constant expression. */
334 {
335 /* So we need to look into the vtable of the type of exp.
336 This is an lvalue use of expr then. */
340 complain);
341 }
349 {
353 }
354 else
358 }
360 /* Generate the NTBS name of a type. If MARK_PRIVATE, put a '*' in front so that
361 comparisons will be done by pointer rather than string comparison. */
362 static tree
364 {
367 tree name_string;
373 {
374 /* Inject '*' at beginning of name to force pointer comparison. */
379 }
380 else
384 }
386 /* Return a VAR_DECL for the internal ABI defined type_info object for
387 TYPE. You must arrange that the decl is mark_used, if actually use
388 it --- decls in vtables are only used if the vtable is output. */
390 tree
392 {
393 tree name;
394 tree d;
397 {
400 type);
402 }
410 /* For a class type, the variable is cached in the type node
411 itself. */
413 {
417 }
423 {
429 /* Remember the type it is for. */
436 /* Mark the variable as undefined -- but remember that we can
437 define it later if we need to do so. */
446 /* Add decl to the global array of tinfo decls. */
448 }
451 }
453 /* Return a pointer to a type_info object describing TYPE, suitably
454 cast to the language defined type. */
456 static tree
458 {
464 }
466 /* Return the type_info object for TYPE. */
468 tree
470 {
477 /* If the type of the type-id is a reference type, the result of the
478 typeid expression refers to a type_info object representing the
479 referenced type. */
482 /* The top-level cv-qualifiers of the lvalue expression or the type-id
483 that is the operand of typeid are always ignored. */
486 /* For UNKNOWN_TYPEs call complete_type_or_else to get diagnostics. */
495 }
497 /* Check whether TEST is null before returning RESULT. If TEST is used in
498 RESULT, it must have previously had a save_expr applied to it. */
500 static tree
502 {
506 complain)),
508 result);
509 }
511 /* Execute a dynamic cast, as described in section 5.2.6 of the 9/93 working
512 paper. */
514 static tree
516 {
518 tree exprtype;
519 tree dcast_fn;
523 /* Save casted types in the function's used types hash table. */
526 /* T shall be a pointer or reference to a complete class type, or
527 `pointer to cv void''. */
529 {
533 /* Fall through. */
536 {
539 }
541 {
544 }
550 }
553 {
557 /* If T is a pointer type, v shall be an rvalue of a pointer to
558 complete class type, and the result is an rvalue of type T. */
563 {
566 }
568 {
571 }
573 {
576 }
577 }
578 else
579 {
584 /* T is a reference type, v shall be an lvalue of a complete class
585 type, and the result is an lvalue of the type referred to by T. */
588 {
591 }
593 {
596 }
598 /* Apply trivial conversion T -> T& for dereferenced ptrs. */
601 }
603 /* The dynamic_cast operator shall not cast away constness. */
606 {
609 }
611 /* If *type is an unambiguous accessible base class of *exprtype,
612 convert statically. */
613 {
614 tree binfo;
620 {
626 }
627 }
629 /* Otherwise *exprtype must be a polymorphic class (have a vtbl). */
631 {
632 tree expr1;
633 /* if TYPE is `void *', return pointer to complete object. */
635 {
636 /* if b is an object, dynamic_cast<void *>(&b) == (void *)&b. */
642 /* Since expr is used twice below, save it. */
649 }
650 else
651 {
652 tree retval;
657 /* If we got here, we can't convert statically. Therefore,
658 dynamic_cast<D&>(b) (b an object) cannot succeed. */
660 {
663 {
668 /* Bash it to the expected type. */
671 }
672 }
673 /* Ditto for dynamic_cast<D*>(&b). */
675 {
679 {
685 }
686 }
688 /* Use of dynamic_cast when -fno-rtti is prohibited. */
690 {
694 }
705 /* Determine how T and V are related. */
708 /* Since expr is used twice below, save it. */
722 {
723 tree tmp;
724 tree tinfo_ptr;
732 tinfo_ptr = build_pointer_type
733 (cp_build_qualified_type
737 const_ptr_type_node,
744 }
748 {
750 tree neq;
757 }
759 /* Now back to the type we want from a void*. */
762 }
763 }
764 else
767 fail:
772 }
774 tree
776 {
777 tree r;
783 {
787 }
793 }
795 /* Return the runtime bit mask encoding the qualifiers of TYPE. */
797 static int
799 {
810 }
812 /* Return true, if the pointer chain TYPE ends at an incomplete type, or
813 contains a pointer to member of an incomplete class. */
815 static bool
817 {
820 {
824 }
827 else
829 }
831 /* Returns true if TYPE involves an incomplete class type; in that
832 case, typeinfo variables for TYPE should be emitted with internal
833 linkage. */
835 static bool
837 {
839 {
844 ptrmem:
845 return
852 /* Fall through. */
858 /* All other types do not involve incomplete class types. */
860 }
861 }
863 /* Return a CONSTRUCTOR for the common part of the type_info objects. This
864 is the vtable pointer and NTBS name. The NTBS name is emitted as a
865 comdat const char array, so it becomes a unique key for the type. Generate
866 and emit that VAR_DECL here. (We can't always emit the type_info itself
867 as comdat, because of pointers to incomplete.) */
869 static tree
871 {
872 tree init;
873 tree name_decl;
874 tree vtable_ptr;
877 {
880 /* Generate the NTBS array variable. */
881 tree name_type = build_cplus_array_type
883 NULL_TREE);
885 /* Determine the name of the variable -- and remember with which
886 type it is associated. */
904 }
908 {
909 tree real_type;
916 {
917 /* We never saw a definition of this type, so we need to
918 tell the compiler that this is an exported class, as
919 indeed all of the __*_type_info classes are. */
922 }
927 /* We need to point into the middle of the vtable. */
928 vtable_ptr = fold_build_pointer_plus
935 }
947 }
949 /* Return the CONSTRUCTOR expr for a type_info of TYPE. TI provides the
950 information about the particular type_info derivation, which adds no
951 additional fields to the type_info base. */
953 static tree
955 {
962 }
964 /* Return the CONSTRUCTOR expr for a type_info of pointer TYPE.
965 TI provides information about the particular type_info derivation,
966 which adds target type and qualifier flags members to the type_info base. */
968 static tree
970 {
989 }
991 /* Return the CONSTRUCTOR expr for a type_info of pointer to member data TYPE.
992 TI provides information about the particular type_info derivation,
993 which adds class, target type and qualifier flags members to the type_info
994 base. */
996 static tree
998 {
1021 }
1023 /* Return the CONSTRUCTOR expr for a type_info of class TYPE.
1024 TI provides information about the particular __class_type_info derivation,
1025 which adds hint flags and N extra initializers to the type_info base. */
1027 static tree
1029 {
1046 }
1048 /* Returns true if the typeinfo for type should be placed in
1049 the runtime library. */
1051 static bool
1053 {
1054 /* The typeinfo objects for `T*' and `const T*' are in the runtime
1055 library for simple types T. */
1062 {
1071 /* fall through. */
1075 }
1076 }
1078 /* Generate the initializer for the type info describing TYPE. TK_INDEX is
1079 the index of the descriptor in the tinfo_desc vector. */
1081 static tree
1083 {
1088 {
1105 {
1109 /* get_tinfo_ptr might have reallocated the tinfo_descs vector. */
1112 }
1115 {
1130 /* Generate the base information initializer. */
1132 {
1134 tree base_init;
1136 tree tinfo;
1137 tree offset;
1144 {
1145 /* We store the vtable offset at which the virtual
1146 base offset can be found. */
1149 }
1150 else
1153 /* Combine offset and flags into one field. */
1168 }
1171 /* get_tinfo_ptr might have reallocated the tinfo_descs vector. */
1176 base_inits);
1177 }
1178 }
1179 }
1181 /* Generate the RECORD_TYPE containing the data layout of a type_info
1182 derivative as used by the runtime. This layout must be consistent with
1183 that defined in the runtime support. Also generate the VAR_DECL for the
1184 type's vtable. We explicitly manage the vtable member, and name it for
1185 real type as used in the runtime. The RECORD type has a different name,
1186 to avoid collisions. Return a TREE_LIST who's TINFO_PSEUDO_TYPE
1187 is the generated type and TINFO_VTABLE_NAME is the name of the
1188 vtable. We have to delay generating the VAR_DECL of the vtable
1189 until the end of the translation, when we'll have seen the library
1190 definition, if there was one.
1192 REAL_NAME is the runtime's name of the type. Trailing arguments are
1193 additional FIELD_DECL's for the structure. The final argument must be
1194 NULL. */
1196 static void
1198 {
1200 tree pseudo_type;
1202 tree fields;
1203 tree field_decl;
1208 /* Generate the pseudo type name. */
1215 /* First field is the pseudo type_info base class. */
1220 /* Now add the derived fields. */
1222 {
1225 }
1227 /* Create the pseudo type. */
1237 /* Pretend this is public so determine_visibility doesn't give vtables
1238 internal linkage. */
1242 }
1244 /* Return the index of a pseudo type info type node used to describe
1245 TYPE. TYPE must be a complete type (or cv void), except at the end
1246 of the translation unit. */
1248 static unsigned
1250 {
1254 {
1278 {
1281 }
1283 {
1288 }
1290 {
1293 }
1294 else
1295 {
1305 {
1306 /* single non-virtual public. */
1309 }
1310 else
1311 {
1317 {
1318 /* too short, extend. */
1324 }
1326 /* already created. */
1329 /* Create the array of __base_class_type_info entries.
1330 G++ 3.2 allocated an array that had one too many
1331 entries, and then filled that extra entries with
1332 zeros. */
1335 else
1338 array_domain);
1341 create_pseudo_type_info
1349 NULL);
1352 }
1353 }
1357 }
1359 }
1361 /* Make sure the required builtin types exist for generating the type_info
1362 variable definitions. */
1364 static void
1366 {
1375 /* Create the internal type_info structure. This is used as a base for
1376 the other structures. */
1377 {
1395 }
1397 /* Fundamental type_info */
1400 /* Array, function and enum type_info. No additional fields. */
1405 /* Class type_info. No additional fields. */
1408 /* Single public non-virtual base class. Add pointer to base class.
1409 This is really a descendant of __class_type_info. */
1413 NULL);
1415 /* Base class internal helper. Pointer to base type, offset to base,
1416 flags. */
1417 {
1436 }
1438 /* Pointer type_info. Adds two fields, qualification mask
1439 and pointer to the pointed to type. This is really a descendant of
1440 __pbase_type_info. */
1446 NULL);
1448 /* Pointer to member data type_info. Add qualifications flags,
1449 pointer to the member's type info and pointer to the class.
1450 This is really a descendant of __pbase_type_info. */
1459 NULL);
1462 }
1464 /* Emit the type_info descriptors which are guaranteed to be in the runtime
1465 support. Generating them here guarantees consistency with the other
1466 structures. We use the following heuristic to determine when the runtime
1467 is being generated. If std::__fundamental_type_info is defined, and its
1468 destructor is defined, then the runtime is being built. */
1470 void
1472 {
1473 /* Dummy static variable so we can put nullptr in the array; it will be
1474 set before we actually start to walk the array. */
1476 {
1489 0
1490 };
1506 {
1516 TYPE_QUAL_CONST));
1519 {
1520 tree tinfo;
1525 /* The C++ ABI requires that these objects be COMDAT. But,
1526 On systems without weak symbols, initialized COMDAT
1527 objects are emitted with internal linkage. (See
1528 comdat_linkage for details.) Since we want these objects
1529 to have external linkage so that copies do not have to be
1530 emitted in code outside the runtime library, we make them
1531 non-COMDAT here.
1533 It might also not be necessary to follow this detail of the
1534 ABI. */
1536 {
1539 }
1540 }
1541 }
1542 }
1544 /* Finish a type info decl. DECL_PTR is a pointer to an unemitted
1545 tinfo decl. Determine whether it needs emitting, and if so
1546 generate the initializer. */
1548 bool
1550 {
1557 {
1560 else
1561 {
1562 /* If we're not in the runtime, then DECL (which is already
1563 DECL_EXTERNAL) will not be defined here. */
1566 }
1567 }
1569 {
1572 /* If TYPE involves an incomplete class type, then the typeinfo
1573 object will be emitted with internal linkage. There is no
1574 way to know whether or not types are incomplete until the end
1575 of the compilation, so this determination must be deferred
1576 until this point. */
1580 }
1584 {
1585 tree init;
1593 }
1594 else
1596 }