| blob | 069495105bfb368f4d87c7369fb09cccf7d55784 |
1 /* Basic IPA utilities for type inheritance graph construction and
2 devirtualization.
3 Copyright (C) 2013-2016 Free Software Foundation, Inc.
4 Contributed by Jan Hubicka
6 This file is part of GCC.
8 GCC is free software; you can redistribute it and/or modify it under
9 the terms of the GNU General Public License as published by the Free
10 Software Foundation; either version 3, or (at your option) any later
11 version.
13 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
14 WARRANTY; without even the implied warranty of MERCHANTABILITY or
15 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
16 for more details.
18 You should have received a copy of the GNU General Public License
19 along with GCC; see the file COPYING3. If not see
20 <http://www.gnu.org/licenses/>. */
22 /* Brief vocabulary:
23 ODR = One Definition Rule
24 In short, the ODR states that:
25 1 In any translation unit, a template, type, function, or object can
26 have no more than one definition. Some of these can have any number
27 of declarations. A definition provides an instance.
28 2 In the entire program, an object or non-inline function cannot have
29 more than one definition; if an object or function is used, it must
30 have exactly one definition. You can declare an object or function
31 that is never used, in which case you don't have to provide
32 a definition. In no event can there be more than one definition.
33 3 Some things, like types, templates, and extern inline functions, can
34 be defined in more than one translation unit. For a given entity,
35 each definition must be the same. Non-extern objects and functions
36 in different translation units are different entities, even if their
37 names and types are the same.
39 OTR = OBJ_TYPE_REF
40 This is the Gimple representation of type information of a polymorphic call.
41 It contains two parameters:
42 otr_type is a type of class whose method is called.
43 otr_token is the index into virtual table where address is taken.
45 BINFO
46 This is the type inheritance information attached to each tree
47 RECORD_TYPE by the C++ frontend. It provides information about base
48 types and virtual tables.
50 BINFO is linked to the RECORD_TYPE by TYPE_BINFO.
51 BINFO also links to its type by BINFO_TYPE and to the virtual table by
52 BINFO_VTABLE.
54 Base types of a given type are enumerated by BINFO_BASE_BINFO
55 vector. Members of this vectors are not BINFOs associated
56 with a base type. Rather they are new copies of BINFOs
57 (base BINFOs). Their virtual tables may differ from
58 virtual table of the base type. Also BINFO_OFFSET specifies
59 offset of the base within the type.
61 In the case of single inheritance, the virtual table is shared
62 and BINFO_VTABLE of base BINFO is NULL. In the case of multiple
63 inheritance the individual virtual tables are pointer to by
64 BINFO_VTABLE of base binfos (that differs of BINFO_VTABLE of
65 binfo associated to the base type).
67 BINFO lookup for a given base type and offset can be done by
68 get_binfo_at_offset. It returns proper BINFO whose virtual table
69 can be used for lookup of virtual methods associated with the
70 base type.
72 token
73 This is an index of virtual method in virtual table associated
74 to the type defining it. Token can be looked up from OBJ_TYPE_REF
75 or from DECL_VINDEX of a given virtual table.
77 polymorphic (indirect) call
78 This is callgraph representation of virtual method call. Every
79 polymorphic call contains otr_type and otr_token taken from
80 original OBJ_TYPE_REF at callgraph construction time.
82 What we do here:
84 build_type_inheritance_graph triggers a construction of the type inheritance
85 graph.
87 We reconstruct it based on types of methods we see in the unit.
88 This means that the graph is not complete. Types with no methods are not
89 inserted into the graph. Also types without virtual methods are not
90 represented at all, though it may be easy to add this.
92 The inheritance graph is represented as follows:
94 Vertices are structures odr_type. Every odr_type may correspond
95 to one or more tree type nodes that are equivalent by ODR rule.
96 (the multiple type nodes appear only with linktime optimization)
98 Edges are represented by odr_type->base and odr_type->derived_types.
99 At the moment we do not track offsets of types for multiple inheritance.
100 Adding this is easy.
102 possible_polymorphic_call_targets returns, given an parameters found in
103 indirect polymorphic edge all possible polymorphic call targets of the call.
105 pass_ipa_devirt performs simple speculative devirtualization.
106 */
132 /* Hash based set of pairs of types. */
133 struct type_pair
134 {
135 tree first;
136 tree second;
137 };
141 {
144 static hashval_t
146 {
148 }
149 static bool
151 {
153 }
154 static bool
156 {
158 }
159 static bool
161 {
163 }
164 static void
166 {
168 }
169 };
178 /* Pointer set of all call targets appearing in the cache. */
181 /* The node of type inheritance graph. For each type unique in
182 One Definition Rule (ODR) sense, we produce one node linking all
183 main variants of types equivalent to it, bases and derived types. */
186 {
187 /* leader type. */
188 tree type;
189 /* All bases; built only for main variants of types. */
191 /* All derived types with virtual methods seen in unit;
192 built only for main variants of types. */
195 /* All equivalent types, if more than one. */
197 /* Set of all equivalent types, if NON-NULL. */
200 /* Unique ID indexing the type in odr_types array. */
202 /* Is it in anonymous namespace? */
204 /* Do we know about all derivations of given type? */
206 /* Did we report ODR violation here? */
208 /* Set when virtual table without RTTI previaled table with. */
210 };
212 /* Return TRUE if all derived types of T are known and thus
213 we may consider the walk of derived type complete.
215 This is typically true only for final anonymous namespace types and types
216 defined within functions (that may be COMDAT and thus shared across units,
217 but with the same set of derived types). */
219 bool
221 {
226 /* Non-C++ types may have IDENTIFIER_NODE here, do not crash. */
232 }
234 /* Return TRUE if type's constructors are all visible. */
236 static bool
238 {
241 /* We can not always use type_all_derivations_known_p.
242 For function local types we must assume case where
243 the function is COMDAT and shared in between units.
245 TODO: These cases are quite easy to get, but we need
246 to keep track of C++ privatizing via -Wno-weak
247 as well as the IPA privatizing. */
249 }
251 /* Return TRUE if type may have instance. */
253 static bool
255 {
256 tree vtable;
259 /* TODO: Add abstract types here. */
268 }
270 /* Hash used to unify ODR types based on their mangled name and for anonymous
271 namespace types. */
274 {
279 };
281 /* Has used to unify ODR types based on their associated virtual table.
282 This hash is needed to keep -fno-lto-odr-type-merging to work and contains
283 only polymorphic types. Types with mangled names are inserted to both. */
286 {
289 };
291 /* Return type that was declared with T's name so that T is an
292 qualified variant of it. */
296 {
299 /* Unnamed types and non-C++ produced types can be compared by variants. */
300 else
302 }
304 static bool
306 {
308 }
310 /* Hash type by its ODR name. */
312 static hashval_t
314 {
317 /* If not in LTO, all main variants are unique, so we can do
318 pointer hash. */
322 /* Anonymous types are unique. */
329 }
331 /* Return the computed hashcode for ODR_TYPE. */
333 inline hashval_t
335 {
337 }
339 static bool
341 {
342 /* vtable hashing can distinguish only main variants. */
345 /* Anonymous namespace types are always handled by name hash. */
350 }
352 /* Hash type by assembler name of its vtable. */
354 static hashval_t
356 {
367 {
370 }
374 }
376 /* Return the computed hashcode for ODR_TYPE. */
378 inline hashval_t
380 {
382 }
384 /* For languages with One Definition Rule, work out if
385 types are the same based on their name.
387 This is non-trivial for LTO where minor differences in
388 the type representation may have prevented type merging
389 to merge two copies of otherwise equivalent type.
391 Until we start streaming mangled type names, this function works
392 only for polymorphic types.
394 When STRICT is true, we compare types by their names for purposes of
395 ODR violation warnings. When strict is false, we consider variants
396 equivalent, because it is all that matters for devirtualization machinery.
397 */
399 bool
401 {
407 {
410 }
418 /* Check for anonymous namespaces. Those have !TREE_PUBLIC
419 on the corresponding TYPE_STUB_DECL. */
425 /* ODR name of the type is set in DECL_ASSEMBLER_NAME of its TYPE_NAME.
427 Ideally we should never need types without ODR names here. It can however
428 happen in two cases:
430 1) for builtin types that are not streamed but rebuilt in lto/lto-lang.c
431 Here testing for equivalence is safe, since their MAIN_VARIANTs are
432 unique.
433 2) for units streamed with -fno-lto-odr-type-merging. Here we can't
434 establish precise ODR equivalency, but for correctness we care only
435 about equivalency on complete polymorphic types. For these we can
436 compare assembler names of their virtual tables. */
439 {
440 /* See if types are obviously different (i.e. different codes
441 or polymorphic wrt non-polymorphic). This is not strictly correct
442 for ODR violating programs, but we can't do better without streaming
443 ODR names. */
455 /* At the moment we have no way to establish ODR equivalence at LTO
456 other than comparing virtual table pointers of polymorphic types.
457 Eventually we should start saving mangled names in TYPE_NAME.
458 Then this condition will become non-trivial. */
464 {
471 && DECL_ASSEMBLER_NAME
473 == DECL_ASSEMBLER_NAME
475 }
477 }
480 }
482 /* Return true if we can decide on ODR equivalency.
484 In non-LTO it is always decide, in LTO however it depends in the type has
485 ODR info attached.
487 When STRICT is false, compare main variants. */
489 bool
491 {
501 }
503 /* Return true if T1 and T2 are ODR equivalent. If ODR equivalency is not
504 known, be conservative and return false. */
506 bool
508 {
511 else
513 }
515 /* If T is compound type, return type it is based on. */
517 static tree
519 {
530 }
532 /* Return true if T is either ODR type or compound type based from it.
533 If the function return true, we know that T is a type originating from C++
534 source even at link-time. */
536 bool
538 {
539 do
540 {
543 /* Function type is a tricky one. Basically we can consider it
544 ODR derived if return type or any of the parameters is.
545 We need to check all parameters because LTO streaming merges
546 common types (such as void) and they are not considered ODR then. */
548 {
551 else
552 {
559 }
560 }
561 else
563 }
566 }
568 /* Compare types T1 and T2 and return true if they are
569 equivalent. */
573 {
582 /* Check for anonymous namespaces. Those have !TREE_PUBLIC
583 on the corresponding TYPE_STUB_DECL. */
591 }
593 /* Compare types T1 and T2 and return true if they are
594 equivalent. */
598 {
612 && DECL_ASSEMBLER_NAME
614 == DECL_ASSEMBLER_NAME
616 }
618 /* Free ODR type V. */
622 {
628 }
630 /* ODR type hash used to look up ODR type based on tree type node. */
637 /* ODR types are also stored into ODR_TYPE vector to allow consistent
638 walking. Bases appear before derived types. Vector is garbage collected
639 so we won't end up visiting empty types. */
642 #define odr_types (*odr_types_ptr)
644 /* Set TYPE_BINFO of TYPE and its variants to BINFO. */
645 void
647 {
651 else
653 }
655 /* Compare T2 and T2 based on name or structure. */
657 static bool
661 {
663 /* This can happen in incomplete types that should be handled earlier. */
671 /* Anonymous namespace types must match exactly. */
676 /* For ODR types be sure to compare their names.
677 To support -wno-odr-type-merging we allow one type to be non-ODR
678 and other ODR even though it is a violation. */
680 {
683 /* Limit recursion: If subtypes are ODR types and we know
684 that they are same, be happy. */
687 }
689 /* Component types, builtins and possibly violating ODR types
690 have to be compared structurally. */
699 {
702 }
706 }
708 /* Return true if DECL1 and DECL2 are identical methods. Consider
709 name equivalent to name.localalias.xyz. */
711 static bool
713 {
729 }
731 /* Compare two virtual tables, PREVAILING and VTABLE and output ODR
732 violation warnings. */
734 void
736 {
740 {
743 {
747 }
750 OPT_Wodr,
754 "variable of same assembler name as the virtual table is "
757 }
761 /* If we do not stream ODR type info, do not bother to do useful compare. */
772 {
779 /* !DECL_VIRTUAL_P means RTTI entry;
780 We warn when RTTI is lost because non-RTTI previals; we silently
781 accept the other case. */
783 && (end1
788 {
792 OPT_Wodr,
793 "virtual table of type %qD contains RTTI "
796 {
799 "but is prevailed by one without from other translation "
805 }
806 n2++;
808 }
810 && (end2
814 {
815 n1++;
817 }
819 /* Finished? */
821 {
822 /* Extra paranoia; compare the sizes. We do not have information
823 about virtual inheritance offsets, so just be sure that these
824 match.
825 Do this as very last check so the not very informative error
826 is not output too often. */
828 {
832 OPT_Wodr,
833 "virtual table of type %qD violates "
836 {
839 "the conflicting type defined in another translation "
841 }
842 }
844 }
847 {
853 /* If the loops above stopped on non-virtual pointer, we have
854 mismatch in RTTI information mangling. */
857 {
860 OPT_Wodr,
861 "virtual table of type %qD violates "
864 {
867 "the conflicting type defined in another translation "
869 }
871 }
872 /* At this point both REF1 and REF2 points either to virtual table
873 or virtual method. If one points to virtual table and other to
874 method we can complain the same way as if one table was shorter
875 than other pointing out the extra method. */
878 {
883 }
884 }
888 /* Complain about size mismatch. Either we have too many virutal
889 functions or too many virtual table pointers. */
891 {
893 {
898 }
901 OPT_Wodr,
902 "virtual table of type %qD violates "
905 {
907 {
910 "the conflicting type defined in another translation "
916 }
917 else
918 {
921 "the conflicting type defined in another translation "
923 }
924 }
926 }
928 /* And in the last case we have either mistmatch in between two virtual
929 methods or two virtual table pointers. */
932 "virtual table of type %qD violates "
935 {
937 {
940 "the conflicting type defined in another translation "
952 }
953 else
956 "the conflicting type defined in another translation "
959 }
960 }
961 }
963 /* Output ODR violation warning about T1 and T2 with REASON.
964 Display location of ST1 and ST2 if REASON speaks about field or
965 method of the type.
966 If WARN is false, do nothing. Set WARNED if warning was indeed
967 output. */
969 void
972 {
980 /* ODR warnings are output druing LTO streaming; we must apply location
981 cache for potential warnings to be output correctly. */
987 t1))
990 ;
991 /* For FIELD_DECL support also case where one of fields is
992 NULL - this is used when the structures have mismatching number of
993 elements. */
995 {
999 {
1002 }
1005 st1);
1008 }
1010 {
1015 st1);
1017 }
1018 else
1024 }
1026 /* Return ture if T1 and T2 are incompatible and we want to recusively
1027 dive into them from warn_type_mismatch to give sensible answer. */
1029 static bool
1031 {
1036 }
1039 /* Types T1 and T2 was found to be incompatible in a context they can't
1040 (either used to declare a symbol of same assembler name or unified by
1041 ODR rule). We already output warning about this, but if possible, output
1042 extra information on how the types mismatch.
1044 This is hard to do in general. We basically handle the common cases.
1046 If LOC1 and LOC2 are meaningful locations, use it in the case the types
1047 themselves do no thave one.*/
1049 void
1051 {
1052 /* Location of type is known only if it has TYPE_NAME and the name is
1053 TYPE_DECL. */
1062 /* With LTO it is a common case that the location of both types match.
1063 See if T2 has a location that is different from T1. If so, we will
1064 inform user about the location.
1065 Do not consider the location passed to us in LOC1/LOC2 as those are
1066 already output. */
1068 {
1071 else
1072 {
1080 }
1081 }
1090 /* It is a quite common bug to reference anonymous namespace type in
1091 non-anonymous namespace class. */
1094 {
1096 {
1099 }
1103 /* Most of the time, the type names will match, do not be unnecesarily
1104 verbose. */
1108 "type %qT defined in anonymous namespace can not match "
1111 else
1113 "type %qT defined in anonymous namespace can not match "
1115 t1);
1120 }
1121 /* If types have mangled ODR names and they are different, it is most
1122 informative to output those.
1123 This also covers types defined in different namespaces. */
1131 {
1139 {
1148 }
1150 }
1151 /* A tricky case are compound types. Often they appear the same in source
1152 code and the mismatch is dragged in by type they are build from.
1153 Look for those differences in subtypes and try to be informative. In other
1154 cases just output nothing because the source code is probably different
1155 and in this case we already output a all necessary info. */
1157 {
1159 {
1162 {
1171 {
1175 }
1176 }
1182 {
1187 {
1190 loc_t2);
1192 }
1197 count++)
1198 {
1200 {
1204 else
1212 }
1213 }
1215 {
1219 }
1220 }
1221 }
1223 }
1229 /* Prevent pointless warnings like "struct aa" should match "struct aa". */
1233 else
1238 }
1240 /* Compare T1 and T2, report ODR violations if WARN is true and set
1241 WARNED to true if anything is reported. Return true if types match.
1242 If true is returned, the types are also compatible in the sense of
1243 gimple_canonical_types_compatible_p.
1244 If LOC1 and LOC2 is not UNKNOWN_LOCATION it may be used to output a warning
1245 about the type if the type itself do not have location. */
1247 static bool
1251 {
1252 /* Check first for the obvious case of pointer identity. */
1258 /* Can't be the same type if the types don't have the same code. */
1260 {
1264 }
1267 {
1272 }
1276 {
1277 /* We can not trip this when comparing ODR types, only when trying to
1278 match different ODR derivations from different declarations.
1279 So WARN should be always false. */
1282 }
1285 {
1290 }
1294 {
1298 {
1300 {
1305 }
1309 {
1314 }
1315 }
1317 {
1322 }
1323 }
1325 /* Non-aggregate types can be handled cheaply. */
1333 {
1335 {
1340 }
1342 {
1347 }
1351 {
1352 /* char WRT uint_8? */
1357 }
1359 /* For canonical type comparisons we do not want to build SCCs
1360 so we cannot compare pointed-to types. But we can, for now,
1361 require the same pointed-to type kind and match what
1362 useless_type_conversion_p would do. */
1364 {
1367 {
1372 }
1376 {
1384 }
1385 }
1390 {
1391 /* Probably specific enough. */
1398 }
1399 }
1400 /* Do type-specific comparisons. */
1402 {
1404 {
1405 /* Array types are the same if the element types are the same and
1406 the number of elements are the same. */
1409 {
1415 }
1423 /* For an incomplete external array, the type domain can be
1424 NULL_TREE. Check this condition also. */
1433 /* In C++, minimums should be always 0. */
1436 {
1441 }
1442 }
1447 /* Function types are the same if the return type and arguments types
1448 are the same. */
1451 {
1458 }
1463 else
1464 {
1470 {
1474 {
1482 }
1483 }
1486 {
1491 }
1494 }
1499 {
1502 /* For aggregate types, all the fields must be the same. */
1504 {
1508 {
1513 else
1518 }
1522 {
1523 /* Skip non-fields. */
1531 {
1536 }
1538 {
1543 }
1546 {
1551 }
1555 {
1556 /* Do not warn about artificial fields and just go into
1557 generic field mismatch warning. */
1567 }
1569 {
1570 /* Do not warn about artificial fields and just go into
1571 generic field mismatch warning. */
1578 }
1581 }
1583 /* If one aggregate has more fields than the other, they
1584 are not the same. */
1586 {
1596 else
1602 }
1610 {
1611 /* Currently free_lang_data sets TYPE_METHODS to error_mark_node
1612 if it is non-NULL so this loop will never realy execute. */
1618 {
1620 {
1623 "is defined in another "
1626 }
1628 {
1633 }
1635 {
1640 }
1644 {
1649 }
1650 }
1652 {
1657 }
1658 }
1659 }
1661 }
1669 }
1671 /* Those are better to come last as they are utterly uninformative. */
1674 {
1679 }
1682 {
1687 }
1692 }
1694 /* Return true if TYPE1 and TYPE2 are equivalent for One Definition Rule. */
1696 bool
1698 {
1705 }
1707 /* TYPE is equivalent to VAL by ODR, but its tree representation differs
1708 from VAL->type. This may happen in LTO where tree merging did not merge
1709 all variants of the same type or due to ODR violation.
1711 Analyze and report ODR violations and add type to duplicate list.
1712 If TYPE is more specified than VAL->type, prevail VAL->type. Also if
1713 this is first time we see definition of a class return true so the
1714 base types are analyzed. */
1716 static bool
1718 {
1726 /* Chose polymorphic type as leader (this happens only in case of ODR
1727 violations. */
1732 {
1735 }
1736 /* Always prefer complete type to be the leader. */
1738 {
1741 }
1743 ;
1751 {
1755 }
1762 /* If we now have a mangled name, be sure to record it to val->type
1763 so ODR hash can work. */
1778 /* If both are class types, compare the bases. */
1783 {
1786 {
1788 {
1789 tree extra_base;
1791 "a type with the same name but different "
1792 "number of polymorphic bases is "
1795 {
1798 extra_base = BINFO_BASE_BINFO
1801 else
1802 extra_base = BINFO_BASE_BINFO
1808 }
1809 }
1811 }
1812 else
1814 {
1821 {
1824 }
1825 else
1829 {
1831 {
1834 "a type with the same name but different base "
1839 }
1841 }
1843 {
1848 "a type with the same name but different base "
1851 }
1852 /* One of bases is not of complete type. */
1854 {
1855 /* If we have a polymorphic type info specified for TYPE1
1856 but not for TYPE2 we possibly missed a base when recording
1857 VAL->type earlier.
1858 Be sure this does not happen. */
1864 }
1865 /* One base is polymorphic and the other not.
1866 This ought to be diagnosed earlier, but do not ICE in the
1867 checking bellow. */
1871 {
1875 "a base of the type is polymorphic only in one "
1879 }
1880 }
1882 {
1888 {
1895 }
1896 }
1897 }
1899 /* Next compare memory layout. */
1905 {
1909 }
1911 /* Sanity check that all bases will be build same way again. */
1919 {
1926 num_poly_bases++;
1929 i++)
1932 {
1933 odr_type base = get_odr_type
1934 (BINFO_TYPE
1936 i)),
1939 j++;
1940 }
1941 }
1944 /* Regularize things a little. During LTO same types may come with
1945 different BINFOs. Either because their virtual table was
1946 not merged by tree merging and only later at decl merging or
1947 because one type comes with external vtable, while other
1948 with internal. We want to merge equivalent binfos to conserve
1949 memory and streaming overhead.
1951 The external vtables are more harmful: they contain references
1952 to external declarations of methods that may be defined in the
1953 merged LTO unit. For this reason we absolutely need to remove
1954 them and replace by internal variants. Not doing so will lead
1955 to incomplete answers from possible_polymorphic_call_targets.
1957 FIXME: disable for now; because ODR types are now build during
1958 streaming in, the variants do not need to be linked to the type,
1959 yet. We need to do the merging in cleanup pass to be implemented
1960 soon. */
1970 {
1976 {
1982 }
1987 {
1992 {
1996 }
1998 }
1999 else
2001 }
2003 }
2005 /* Get ODR type hash entry for TYPE. If INSERT is true, create
2006 possibly new entry. */
2008 odr_type
2010 {
2014 hashval_t hash;
2024 /* Lookup entry, first try name hash, fallback to vtable hash. */
2026 {
2030 }
2032 {
2036 }
2041 /* See if we already have entry for type. */
2043 {
2045 {
2049 {
2052 NO_INSERT);
2055 }
2056 }
2062 {
2064 /* We have type duplicate, but it may introduce vtable name or
2065 mangled name; be sure to keep hashes in sync. */
2068 {
2070 {
2075 }
2077 }
2081 }
2082 }
2083 else
2084 {
2091 else
2099 }
2104 {
2112 /* For now record only polymorphic types. other are
2113 pointless for devirtualization and we can not precisely
2114 determine ODR equivalency of these during LTO. */
2116 {
2124 }
2125 }
2126 /* Ensure that type always appears after bases. */
2128 {
2132 }
2134 {
2136 /* Be sure we did not recorded any derived types; these may need
2137 renumbering too. */
2142 }
2144 }
2146 /* Add TYPE od ODR type hash. */
2148 void
2150 {
2152 {
2156 }
2157 /* Arrange things to be nicer and insert main variants first.
2158 ??? fundamental prerecorded types do not have mangled names; this
2159 makes it possible that non-ODR type is main_odr_variant of ODR type.
2160 Things may get smoother if LTO FE set mangled name of those types same
2161 way as C++ FE does. */
2167 }
2169 /* Return true if type is known to have no derivations. */
2171 bool
2173 {
2176 || (odr_hash
2178 }
2180 /* Dump ODR type T and all its derived types. INDENT specifies indentation for
2181 recursive printing. */
2183 static void
2185 {
2192 {
2193 /*fprintf (f, "%*s defined at: %s:%i\n", indent * 2, "",
2194 DECL_SOURCE_FILE (TYPE_NAME (t->type)),
2195 DECL_SOURCE_LINE (TYPE_NAME (t->type)));*/
2198 IDENTIFIER_POINTER
2200 }
2202 {
2207 }
2209 {
2213 }
2215 }
2217 /* Dump the type inheritance graph. */
2219 static void
2221 {
2227 {
2230 }
2232 {
2234 {
2239 {
2240 tree t;
2245 {
2248 }
2250 }
2251 }
2252 }
2253 }
2255 /* Initialize IPA devirt and build inheritance tree graph. */
2257 void
2259 {
2272 /* We reconstruct the graph starting of types of all methods seen in the
2273 unit. */
2280 /* Look also for virtual tables of types that do not define any methods.
2282 We need it in a case where class B has virtual base of class A
2283 re-defining its virtual method and there is class C with no virtual
2284 methods with B as virtual base.
2286 Here we output B's virtual method in two variant - for non-virtual
2287 and virtual inheritance. B's virtual table has non-virtual version,
2288 while C's has virtual.
2290 For this reason we need to know about C in order to include both
2291 variants of B. More correctly, record_target_from_binfo should
2292 add both variants of the method when walking B, but we have no
2293 link in between them.
2295 We rely on fact that either the method is exported and thus we
2296 assume it is called externally or C is in anonymous namespace and
2297 thus we will see the vtable. */
2306 {
2309 }
2311 }
2313 /* Return true if N has reference from live virtual table
2314 (and thus can be a destination of polymorphic call).
2315 Be conservatively correct when callgraph is not built or
2316 if the method may be referred externally. */
2318 static bool
2320 {
2330 /* Keep this test constant time.
2331 It is unlikely this can happen except for the case where speculative
2332 devirtualization introduced many speculative edges to this node.
2333 In this case the target is very likely alive anyway. */
2337 /* We need references built. */
2347 {
2350 }
2352 }
2354 /* Return if TARGET is cxa_pure_virtual. */
2356 static bool
2358 {
2363 }
2365 /* If TARGET has associated node, record it in the NODES array.
2366 CAN_REFER specify if program can refer to the target directly.
2367 if TARGET is unknown (NULL) or it can not be inserted (for example because
2368 its body was already removed and there is no way to refer to it), clear
2369 COMPLETEP. */
2371 static void
2376 {
2381 /* __builtin_unreachable do not need to be added into
2382 list of targets; the runtime effect of calling them is undefined.
2383 Only "real" virtual methods should be accounted. */
2388 {
2389 /* The only case when method of anonymous namespace becomes unreferable
2390 is when we completely optimized it out. */
2392 || !target
2396 }
2403 /* Prefer alias target over aliases, so we do not get confused by
2404 fake duplicates. */
2406 {
2412 }
2414 /* Method can only be called by polymorphic call if any
2415 of vtables referring to it are alive.
2417 While this holds for non-anonymous functions, too, there are
2418 cases where we want to keep them in the list; for example
2419 inline functions with -fno-weak are static, but we still
2420 may devirtualize them when instance comes from other unit.
2421 The same holds for LTO.
2423 Currently we ignore these functions in speculative devirtualization.
2424 ??? Maybe it would make sense to be more aggressive for LTO even
2425 elsewhere. */
2427 && !pure_virtual
2429 && (!target_node
2431 ;
2432 /* See if TARGET is useful function we can deal with. */
2438 {
2441 /* Only add pure virtual if it is the only possible target. This way
2442 we will preserve the diagnostics about pure virtual called in many
2443 cases without disabling optimization in other. */
2445 {
2448 }
2449 /* If we found a real target, take away cxa_pure_virtual. */
2456 {
2459 }
2460 }
2462 && (!type_in_anonymous_namespace_p
2466 }
2468 /* See if BINFO's type matches OUTER_TYPE. If so, look up
2469 BINFO of subtype of OTR_TYPE at OFFSET and in that BINFO find
2470 method in vtable and insert method to NODES array
2471 or BASES_TO_CONSIDER if this array is non-NULL.
2472 Otherwise recurse to base BINFOs.
2473 This matches what get_binfo_at_offset does, but with offset
2474 being unknown.
2476 TYPE_BINFOS is a stack of BINFOS of types with defined
2477 virtual table seen on way from class type to BINFO.
2479 MATCHED_VTABLES tracks virtual tables we already did lookup
2480 for virtual function in. INSERTED tracks nodes we already
2481 inserted.
2483 ANONYMOUS is true if BINFO is part of anonymous namespace.
2485 Clear COMPLETEP when we hit unreferable target.
2486 */
2488 static void
2491 tree binfo,
2492 tree otr_type,
2494 HOST_WIDE_INT otr_token,
2495 tree outer_type,
2496 HOST_WIDE_INT offset,
2501 {
2504 tree base_binfo;
2510 {
2514 /* Look up BINFO with virtual table. For normal types it is always last
2515 binfo on stack. */
2518 {
2521 }
2524 /* If this is duplicated BINFO for base shared by virtual inheritance,
2525 we may not have its associated vtable. This is not a problem, since
2526 we will walk it on the other path. */
2532 {
2535 }
2536 /* For types in anonymous namespace first check if the respective vtable
2537 is alive. If not, we know the type can't be called. */
2539 {
2548 }
2553 {
2556 inner_binfo,
2560 /* Destructors are never called via construction vtables. */
2563 }
2565 }
2567 /* Walk bases. */
2569 /* Walking bases that have no virtual method is pointless exercise. */
2572 type_binfos,
2577 }
2579 /* Look up virtual methods matching OTR_TYPE (with OFFSET and OTR_TOKEN)
2580 of TYPE, insert them to NODES, recurse into derived nodes.
2581 INSERTED is used to avoid duplicate insertions of methods into NODES.
2582 MATCHED_VTABLES are used to avoid duplicate walking vtables.
2583 Clear COMPLETEP if unreferable target is found.
2585 If CONSIDER_CONSTRUCTION is true, record to BASES_TO_CONSIDER
2586 all cases where BASE_SKIPPED is true (because the base is abstract
2587 class). */
2589 static void
2593 tree otr_type,
2594 odr_type type,
2595 HOST_WIDE_INT otr_token,
2596 tree outer_type,
2597 HOST_WIDE_INT offset,
2601 {
2607 /* We may need to consider types w/o instances because of possible derived
2608 types using their methods either directly or via construction vtables.
2609 We are safe to skip them when all derivations are known, since we will
2610 handle them later.
2611 This is done by recording them to BASES_TO_CONSIDER array. */
2613 {
2615 (!possibly_instantiated
2622 }
2625 matched_vtables,
2626 otr_type,
2630 }
2632 /* Cache of queries for polymorphic call targets.
2634 Enumerating all call targets may get expensive when there are many
2635 polymorphic calls in the program, so we memoize all the previous
2636 queries and avoid duplicated work. */
2638 struct polymorphic_call_target_d
2639 {
2640 HOST_WIDE_INT otr_token;
2641 ipa_polymorphic_call_context context;
2642 odr_type type;
2644 tree decl_warning;
2648 };
2650 /* Polymorphic call target cache helpers. */
2652 struct polymorphic_call_target_hasher
2654 {
2659 };
2661 /* Return the computed hashcode for ODR_QUERY. */
2663 inline hashval_t
2665 {
2673 {
2676 }
2683 }
2685 /* Compare cache entries T1 and T2. */
2690 {
2702 }
2704 /* Remove entry in polymorphic call target cache hash. */
2708 {
2711 }
2713 /* Polymorphic call target query cache. */
2716 polymorphic_call_target_hash_type;
2719 /* Destroy polymorphic call target query cache. */
2721 static void
2723 {
2725 {
2730 }
2731 }
2733 /* When virtual function is removed, we may need to flush the cache. */
2735 static void
2737 {
2741 }
2743 /* Look up base of BINFO that has virtual table VTABLE with OFFSET. */
2745 tree
2747 tree vtable)
2748 {
2751 tree base_binfo;
2755 {
2762 }
2766 {
2770 }
2772 }
2774 /* T is known constant value of virtual table pointer.
2775 Store virtual table to V and its offset to OFFSET.
2776 Return false if T does not look like virtual table reference. */
2778 bool
2781 {
2782 /* We expect &MEM[(void *)&virtual_table + 16B].
2783 We obtain object's BINFO from the context of the virtual table.
2784 This one contains pointer to virtual table represented via
2785 POINTER_PLUS_EXPR. Verify that this pointer matches what
2786 we propagated through.
2788 In the case of virtual inheritance, the virtual tables may
2789 be nested, i.e. the offset may be different from 16 and we may
2790 need to dive into the type representation. */
2799 {
2803 }
2805 /* Alternative representation, used by C++ frontend is POINTER_PLUS_EXPR.
2806 We need to handle it when T comes from static variable initializer or
2807 BINFO. */
2809 {
2812 }
2813 else
2820 }
2822 /* T is known constant value of virtual table pointer. Return BINFO of the
2823 instance type. */
2825 tree
2827 {
2828 tree vtable;
2834 /* FIXME: for stores of construction vtables we return NULL,
2835 because we do not have BINFO for those. Eventually we should fix
2836 our representation to allow this case to be handled, too.
2837 In the case we see store of BINFO we however may assume
2838 that standard folding will be able to cope with it. */
2841 }
2843 /* Walk bases of OUTER_TYPE that contain OTR_TYPE at OFFSET.
2844 Look up their respective virtual methods for OTR_TOKEN and OTR_TYPE
2845 and insert them in NODES.
2847 MATCHED_VTABLES and INSERTED is used to avoid duplicated work. */
2849 static void
2851 HOST_WIDE_INT otr_token,
2852 tree outer_type,
2853 HOST_WIDE_INT offset,
2858 {
2860 {
2862 tree base_binfo;
2863 tree fld;
2869 {
2876 /* Do not get confused by zero sized bases. */
2879 }
2880 /* Within a class type we should always find corresponding fields. */
2883 /* Nonbase types should have been stripped by outer_class_type. */
2892 {
2895 }
2898 {
2901 base_binfo,
2906 }
2907 }
2908 }
2910 /* When virtual table is removed, we may need to flush the cache. */
2912 static void
2915 {
2920 }
2922 /* Record about how many calls would benefit from given type to be final. */
2924 struct odr_type_warn_count
2925 {
2926 tree type;
2928 gcov_type dyn_count;
2929 };
2931 /* Record about how many calls would benefit from given method to be final. */
2933 struct decl_warn_count
2934 {
2935 tree decl;
2937 gcov_type dyn_count;
2938 };
2940 /* Information about type and decl warnings. */
2942 struct final_warning_record
2943 {
2944 gcov_type dyn_count;
2947 };
2950 /* Return vector containing possible targets of polymorphic call of type
2951 OTR_TYPE calling method OTR_TOKEN within type of OTR_OUTER_TYPE and OFFSET.
2952 If INCLUDE_BASES is true, walk also base types of OUTER_TYPES containing
2953 OTR_TYPE and include their virtual method. This is useful for types
2954 possibly in construction or destruction where the virtual table may
2955 temporarily change to one of base types. INCLUDE_DERIVER_TYPES make
2956 us to walk the inheritance graph for all derivations.
2958 If COMPLETEP is non-NULL, store true if the list is complete.
2959 CACHE_TOKEN (if non-NULL) will get stored to an unique ID of entry
2960 in the target cache. If user needs to visit every target list
2961 just once, it can memoize them.
2963 If SPECULATIVE is set, the list will not contain targets that
2964 are not speculatively taken.
2966 Returned vector is placed into cache. It is NOT caller's responsibility
2967 to free it. The vector can be freed on cgraph_remove_node call if
2968 the particular node is a virtual function present in the cache. */
2972 HOST_WIDE_INT otr_token,
2973 ipa_polymorphic_call_context context,
2977 {
2982 polymorphic_call_target_d key;
2992 /* If ODR is not initialized or the context is invalid, return empty
2993 incomplete list. */
2995 {
3001 }
3003 /* Do not bother to compute speculative info when user do not asks for it. */
3009 /* Recording type variants would waste results cache. */
3013 /* Look up the outer class type we want to walk.
3014 If we fail to do so, the context is invalid. */
3017 {
3023 }
3026 /* Check that restrict_to_inner_class kept the main variant. */
3030 /* We canonicalize our query, so we do not need extra hashtable entries. */
3032 /* Without outer type, we have no use for offset. Just do the
3033 basic search from inner type. */
3036 /* We need to update our hierarchy if the type does not exist. */
3038 /* If the type is complete, there are no derivations. */
3042 /* Initialize query cache. */
3044 {
3046 polymorphic_call_target_hash
3049 {
3050 node_removal_hook_holder =
3053 NULL);
3054 }
3055 }
3058 {
3060 context.outer_type
3063 context.speculative_outer_type
3065 }
3067 /* Look up cached answer. */
3076 {
3080 {
3084 }
3086 {
3091 }
3093 }
3097 /* Do actual search. */
3110 /* First insert targets we speculatively identified as likely. */
3112 {
3113 odr_type speculative_outer_type;
3116 /* First insert target from type itself and check if it may have
3117 derived types. */
3126 else
3129 /* In the case we get complete method, we don't need
3130 to walk derivations. */
3139 /* Next walk recursively all derived types. */
3144 otr_type,
3149 bases_to_consider,
3151 }
3154 {
3155 /* First see virtual method of type itself. */
3161 else
3162 {
3165 }
3167 /* Destructors are never called through construction virtual tables,
3168 because the type is always known. */
3173 {
3174 /* In the case we get complete method, we don't need
3175 to walk derivations. */
3178 }
3180 /* If OUTER_TYPE is abstract, we know we are not seeing its instance. */
3183 else
3189 /* Next walk recursively all derived types. */
3191 {
3195 otr_type,
3199 bases_to_consider,
3203 {
3207 {
3209 && warn_suggest_final_types
3211 {
3221 }
3223 && warn_suggest_final_methods
3226 {
3233 {
3236 }
3237 else
3238 {
3242 }
3244 }
3245 }
3247 }
3248 }
3251 {
3252 /* Destructors are never called through construction virtual tables,
3253 because the type is always known. One of entries may be
3254 cxa_pure_virtual so look to at least two of them. */
3260 {
3262 && (!skipped
3272 }
3273 }
3274 }
3283 }
3285 bool
3288 {
3291 }
3293 /* Dump target list TARGETS into FILE. */
3295 static void
3297 {
3301 {
3312 }
3314 }
3316 /* Dump all possible targets of a polymorphic call. */
3318 void
3320 tree otr_type,
3321 HOST_WIDE_INT otr_token,
3323 {
3332 ctx,
3350 ctx,
3353 {
3356 }
3359 }
3362 /* Return true if N can be possibly target of a polymorphic call of
3363 OTR_TYPE/OTR_TOKEN. */
3365 bool
3367 HOST_WIDE_INT otr_token,
3370 {
3378 == BUILT_IN_UNREACHABLE
3392 /* At a moment we allow middle end to dig out new external declarations
3393 as a targets of polymorphic calls. */
3397 }
3401 /* Return true if N can be possibly target of a polymorphic call of
3402 OBJ_TYPE_REF expression REF in STMT. */
3404 bool
3408 {
3413 tree_to_uhwi
3415 context,
3416 n);
3417 }
3420 /* After callgraph construction new external nodes may appear.
3421 Add them into the graph. */
3423 void
3425 {
3432 /* We reconstruct the graph starting from types of all methods seen in the
3433 unit. */
3440 }
3443 /* Return true if N looks like likely target of a polymorphic call.
3444 Rule out cxa_pure_virtual, noreturns, function declared cold and
3445 other obvious cases. */
3447 bool
3449 {
3451 /* cxa_pure_virtual and similar things are not likely. */
3462 /* If there are no live virtual tables referring the target,
3463 the only way the target can be called is an instance coming from other
3464 compilation unit; speculative devirtualization is built around an
3465 assumption that won't happen. */
3469 }
3471 /* Compare type warning records P1 and P2 and choose one with larger count;
3472 helper for qsort. */
3474 int
3476 {
3485 }
3487 /* Compare decl warning records P1 and P2 and choose one with larger count;
3488 helper for qsort. */
3490 int
3492 {
3501 }
3504 /* Try to speculatively devirtualize call to OTR_TYPE with OTR_TOKEN with
3505 context CTX. */
3509 ipa_polymorphic_call_context ctx)
3510 {
3512 = possible_polymorphic_call_targets
3519 {
3523 }
3529 /* Don't use an implicitly-declared destructor (c++/58678). */
3538 }
3540 /* The ipa-devirt pass.
3541 When polymorphic call has only one likely target in the unit,
3542 turn it into a speculative call. */
3544 static unsigned int
3546 {
3562 /* We can output -Wsuggest-final-methods and -Wsuggest-final-types warnings.
3563 This is implemented by setting up final_warning_records that are updated
3564 by get_polymorphic_call_targets.
3565 We need to clear cache in this case to trigger recomputation of all
3566 entries. */
3568 {
3572 }
3575 {
3584 {
3593 = possible_polymorphic_call_targets
3597 /* Trigger warnings by calculating non-speculative targets. */
3602 dump_possible_polymorphic_call_targets
3605 npolymorphic++;
3607 /* See if the call can be devirtualized by means of ipa-prop's
3608 polymorphic call context propagation. If not, we can just
3609 forget about this call being polymorphic and avoid some heavy
3610 lifting in remove_unreachable_nodes that will otherwise try to
3611 keep all possible targets alive until inlining and in the inliner
3612 itself.
3614 This may need to be revisited once we add further ways to use
3615 the may edges, but it is a resonable thing to do right now. */
3621 {
3623 ndropped++;
3627 }
3633 {
3636 ncold++;
3638 }
3640 {
3643 nspeculated++;
3645 /* When dumping see if we agree with speculation. */
3648 }
3650 {
3653 nmultiple++;
3655 }
3658 {
3660 {
3664 nmultiple++;
3666 }
3668 }
3670 {
3673 }
3674 /* This is reached only when dumping; check if we agree or disagree
3675 with the speculation. */
3677 {
3683 {
3685 nok++;
3686 }
3687 else
3688 {
3690 nwrong++;
3691 }
3693 }
3695 {
3698 nnotdefined++;
3700 }
3701 /* Do not introduce new references to external symbols. While we
3702 can handle these just well, it is common for programs to
3703 incorrectly with headers defining methods they are linked
3704 with. */
3706 {
3709 nexternal++;
3711 }
3712 /* Don't use an implicitly-declared destructor (c++/58678). */
3716 {
3719 nartificial++;
3721 }
3724 {
3727 noverwritable++;
3729 }
3731 {
3733 {
3740 }
3742 {
3747 }
3748 nconverted++;
3750 e->make_speculative
3752 }
3753 }
3756 }
3758 {
3760 {
3765 {
3768 long long dyn_count
3774 "Declaring type %qD final "
3776 "Declaring type %qD final "
3778 type,
3779 count);
3780 else
3783 "Declaring type %qD final "
3784 "would enable devirtualization of %i call "
3786 "Declaring type %qD final "
3787 "would enable devirtualization of %i calls "
3789 type,
3790 count,
3791 dyn_count);
3792 }
3793 }
3796 {
3803 {
3812 "Declaring virtual destructor of %qD final "
3814 "Declaring virtual destructor of %qD final "
3817 else
3820 "Declaring method %qD final "
3822 "Declaring method %qD final "
3828 "Declaring virtual destructor of %qD final "
3829 "would enable devirtualization of %i call "
3831 "Declaring virtual destructor of %qD final "
3832 "would enable devirtualization of %i calls "
3835 else
3838 "Declaring method %qD final "
3839 "would enable devirtualization of %i call "
3841 "Declaring method %qD final "
3842 "would enable devirtualization of %i calls "
3845 }
3846 }
3850 }
3854 "%i polymorphic calls, %i devirtualized,"
3856 "%i have multiple targets, %i overwritable,"
3857 " %i already speculated (%i agree, %i disagree),"
3863 }
3868 {
3878 };
3881 {
3894 {}
3896 /* opt_pass methods: */
3898 {
3899 /* In LTO, always run the IPA passes and decide on function basis if the
3900 pass is enabled. */
3904 && (flag_devirtualize_speculatively
3905 || (warn_suggest_final_methods
3908 }
3916 ipa_opt_pass_d *
3918 {
3920 }