| blob | a79d39c824b4b3b191d5368ae040aa25c9768117 |
1 /* Analysis of polymorphic call context.
2 Copyright (C) 2013-2023 Free Software Foundation, Inc.
3 Contributed by Jan Hubicka
5 This file is part of GCC.
7 GCC is free software; you can redistribute it and/or modify it under
8 the terms of the GNU General Public License as published by the Free
9 Software Foundation; either version 3, or (at your option) any later
10 version.
12 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
13 WARRANTY; without even the implied warranty of MERCHANTABILITY or
14 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
15 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/>. */
45 /* Return true when TYPE contains an polymorphic type and thus is interesting
46 for devirtualization machinery. */
52 bool
54 {
58 {
68 }
72 }
74 /* Return true if it seems valid to use placement new to build EXPECTED_TYPE
75 at position CUR_OFFSET within TYPE.
77 POD can be changed to an instance of a polymorphic type by
78 placement new. Here we play safe and assume that any
79 non-polymorphic type is POD. */
80 bool
82 HOST_WIDE_INT cur_offset)
83 {
92 || (cur_offset
96 }
98 /* THIS->OUTER_TYPE is a type of memory object where object of OTR_TYPE
99 is contained at THIS->OFFSET. Walk the memory representation of
100 THIS->OUTER_TYPE and find the outermost class type that match
101 OTR_TYPE or contain OTR_TYPE as a base. Update THIS
102 to represent it.
104 If OTR_TYPE is NULL, just find outermost polymorphic type with
105 virtual table present at position OFFSET.
107 For example when THIS represents type
108 class A
109 {
110 int a;
111 class B b;
112 }
113 and we look for type at offset sizeof(int), we end up with B and offset 0.
114 If the same is produced by multiple inheritance, we end up with A and offset
115 sizeof(int).
117 If we cannot find corresponding class, give up by setting
118 THIS->OUTER_TYPE to OTR_TYPE and THIS->OFFSET to NULL.
119 Return true when lookup was successful.
121 When CONSIDER_PLACEMENT_NEW is false, reject contexts that may be made
122 valid only via allocation of new polymorphic type inside by means
123 of placement new.
125 When CONSIDER_BASES is false, only look for actual fields, not base types
126 of TYPE. */
128 bool
132 {
139 /* Update OUTER_TYPE to match EXPECTED_TYPE if it is not set. */
141 {
145 }
146 /* See if OFFSET points inside OUTER_TYPE. If it does not, we know
147 that the context is either invalid, or the instance type must be
148 derived from OUTER_TYPE.
150 Because the instance type may contain field whose type is of OUTER_TYPE,
151 we cannot derive any effective information about it.
153 TODO: In the case we know all derived types, we can definitely do better
154 here. */
159 {
166 /* If derived type is not allowed, we know that the context is invalid.
167 For dynamic types, we really do not have information about
168 size of the memory location. It is possible that completely
169 different type is stored after outer_type. */
171 {
175 }
176 }
185 /* Find the sub-object the constant actually refers to and mark whether it is
186 an artificial one (as opposed to a user-defined one).
188 This loop is performed twice; first time for outer_type and second time
189 for speculative_outer_type. The second run has SPECULATIVE set. */
191 {
193 tree fld;
195 /* If we do not know size of TYPE, we need to be more conservative
196 about accepting cases where we cannot find EXPECTED_TYPE.
197 Generally the types that do matter here are of constant size.
198 Size_unknown case should be very rare. */
203 else
206 /* On a match, just return what we found. */
210 || (!otr_type
214 {
216 {
217 /* If we did not match the offset, just give up on speculation. */
219 /* Also check if speculation did not end up being same as
220 non-speculation. */
222 outer_type)
223 && (maybe_derived_type
227 }
228 else
229 {
230 /* If type is known to be final, do not worry about derived
231 types. Testing it here may help us to avoid speculation. */
238 /* Type cannot contain itself on an non-zero offset. In that case
239 just give up. Still accept the case where size is now known.
240 Either the second copy may appear past the end of type or within
241 the non-POD buffer located inside the variably sized type
242 itself. */
245 /* If we determined type precisely or we have no clue on
246 speculation, we are done. */
249 speculative_offset,
250 speculative_maybe_derived_type,
251 otr_type))
252 {
255 }
256 /* Otherwise look into speculation now. */
257 else
258 {
263 }
264 }
265 }
267 /* Walk fields and find corresponding on at OFFSET. */
269 {
271 {
280 /* Do not consider vptr itself. Not even for placement new. */
291 /* We can always skip types smaller than pointer size:
292 those cannot contain a virtual table pointer.
294 Disqualifying fields that are too small to fit OTR_TYPE
295 saves work needed to walk them for no benefit.
296 Because of the way the bases are packed into a class, the
297 field's size may be smaller than type size, so it needs
298 to be done with a care. */
302 + POINTER_SIZE
303 && (!otr_type
309 }
316 /* DECL_ARTIFICIAL represents a basetype. */
318 {
320 {
323 /* As soon as we see an field containing the type,
324 we know we are not looking for derivations. */
326 }
327 else
328 {
332 }
333 }
336 }
338 {
341 /* Give up if we don't know array field size.
342 Also give up on non-polymorphic types as they are used
343 as buffers for placement new. */
352 /* We may see buffer for placement new. In this case the expected type
353 can be bigger than the subtype. */
362 {
366 }
367 else
368 {
372 }
373 }
374 /* Give up on anything else. */
375 else
376 {
377 no_useful_type_info:
382 && !offset
384 {
388 speculative_offset,
389 speculative_maybe_derived_type,
390 otr_type))
393 {
397 }
398 else
400 }
401 /* We found no way to embed EXPECTED_TYPE in TYPE.
402 We still permit two special cases - placement new and
403 the case of variadic types containing themselves. */
405 && consider_placement_new
408 {
409 /* In these weird cases we want to accept the context.
410 In non-speculative run we have no useful outer_type info
411 (TODO: we may eventually want to record upper bound on the
412 type size that can be used to prune the walk),
413 but we still want to consider speculation that may
414 give useful info. */
416 {
420 speculative_offset,
421 speculative_maybe_derived_type,
422 otr_type))
425 {
429 }
430 else
432 }
433 else
434 {
437 }
438 }
439 else
440 {
447 }
448 }
449 }
450 }
452 /* Return true if OUTER_TYPE contains OTR_TYPE at OFFSET.
453 CONSIDER_PLACEMENT_NEW makes function to accept cases where OTR_TYPE can
454 be built within OUTER_TYPE by means of placement new. CONSIDER_BASES makes
455 function to accept cases where OTR_TYPE appears as base of OUTER_TYPE or as
456 base of one of fields of OUTER_TYPE. */
458 static bool
460 tree otr_type,
463 {
464 ipa_polymorphic_call_context context;
466 /* Check that type is within range. */
470 /* PR ipa/71207
471 As OUTER_TYPE can be a type which has a diamond virtual inheritance,
472 it's not necessary that INNER_TYPE will fit within OUTER_TYPE with
473 a given offset. It can happen that INNER_TYPE also contains a base object,
474 however it would point to the same instance in the OUTER_TYPE. */
481 consider_bases);
482 }
485 /* Return a FUNCTION_DECL if FN represent a constructor or destructor.
486 If CHECK_CLONES is true, also check for clones of ctor/dtors. */
488 tree
490 {
493 {
497 /* Watch for clones where we constant propagated the first
498 argument (pointer to the instance). */
504 }
510 }
512 /* Return a FUNCTION_DECL if BLOCK represents a constructor or destructor.
513 If CHECK_CLONES is true, also check for clones of ctor/dtors. */
515 tree
517 {
523 }
526 /* We know that the instance is stored in variable or parameter
527 (not dynamically allocated) and we want to disprove the fact
528 that it may be in construction at invocation of CALL.
530 BASE represents memory location where instance is stored.
531 If BASE is NULL, it is assumed to be global memory.
532 OUTER_TYPE is known type of the instance or NULL if not
533 known.
535 For the variable to be in construction we actually need to
536 be in constructor of corresponding global variable or
537 the inline stack of CALL must contain the constructor.
538 Check this condition. This check works safely only before
539 IPA passes, because inline stacks may become out of date
540 later. */
542 bool
545 {
550 /* After inlining the code unification optimizations may invalidate
551 inline stacks. Also we need to give up on global variables after
552 IPA, because addresses of these may have been propagated to their
553 constructors. */
557 /* Pure functions cannot do any changes on the dynamic type;
558 that require writing to memory. */
567 {
571 {
576 }
579 }
582 {
586 {
589 /* Watch for clones where we constant propagated the first
590 argument (pointer to the instance). */
597 }
600 {
605 }
608 }
610 }
612 /* Dump human readable context to F. If NEWLINE is true, it will be terminated
613 by a newline. */
615 void
617 {
621 else
622 {
626 {
634 offset);
635 }
637 {
645 speculative_offset);
646 }
647 }
650 }
652 /* Print context to stderr. */
654 void
656 {
658 }
660 /* Stream out the context to OB. */
662 void
664 {
682 {
685 }
686 else
688 }
690 /* Stream in the context from IB and DATA_IN. */
692 void
695 {
709 else
713 else
716 {
719 }
720 else
721 {
724 }
725 }
727 /* Produce polymorphic call context for call method of instance
728 that is located within BASE (that is assumed to be a decl) at offset OFF. */
730 void
732 {
737 {
741 }
744 /* Make very conservative assumption that all objects
745 may be in construction.
747 It is up to caller to revisit this via
748 get_dynamic_type or decl_maybe_in_construction_p. */
752 }
754 /* CST is an invariant (address of decl), try to get meaningful
755 polymorphic call context for polymorphic call of method
756 if instance of OTR_TYPE that is located at offset OFF of this invariant.
757 Return FALSE if nothing meaningful can be found. */
759 bool
761 tree otr_type,
762 HOST_WIDE_INT off)
763 {
766 tree base;
780 /* Only type inconsistent programs can have otr_type that is
781 not part of outer type. */
787 }
789 /* See if OP is SSA name initialized as a copy or by single assignment.
790 If so, walk the SSA graph up. Because simple PHI conditional is considered
791 copy, GLOBAL_VISITED may be used to avoid infinite loop walking the SSA
792 graph. */
794 static tree
796 {
801 /* We might be called via fold_stmt during cfgcleanup where
802 SSA form need not be up-to-date. */
806 {
808 {
813 }
814 else
815 {
820 }
821 /* Special case
822 if (ptr == 0)
823 ptr = 0;
824 else
825 ptr = ptr.foo;
826 This pattern is implicitly produced for casts to non-primary
827 bases. When doing context analysis, we do not really care
828 about the case pointer is NULL, because the call will be
829 undefined anyway. */
831 {
842 else
844 }
845 else
846 {
850 }
852 }
853 done:
857 }
859 /* Create polymorphic call context from IP invariant CST.
860 This is typically &global_var.
861 OTR_TYPE specify type of polymorphic call or NULL if unknown, OFF
862 is offset of call. */
865 tree otr_type,
866 HOST_WIDE_INT off)
867 {
870 }
872 /* Build context for pointer REF contained in FNDECL at statement STMT.
873 if INSTANCE is non-NULL, return pointer to the object described by
874 the context or DECL where context is contained in. */
877 tree ref,
880 {
882 tree base_pointer;
886 {
889 }
890 else
893 /* Set up basic info in case we find nothing interesting in the analysis. */
898 /* Walk SSA for outer object. */
900 {
903 {
906 tree base
917 /* If this is a varying address, punt. */
919 {
920 /* We found dereference of a pointer. Type of the pointer
921 and MEM_REF is meaningless, but we can look further. */
922 offset_int mem_offset;
925 {
934 }
935 /* We found base object. In this case the outer_type
936 is known. */
938 {
941 /* Only type inconsistent programs can have otr_type that is
942 not part of outer type. */
946 {
951 }
954 maybe_in_construction
956 outer_type,
957 stmt,
958 fndecl);
962 }
963 else
965 }
966 else
968 }
971 {
972 offset_int o
974 SIGNED);
981 }
982 else
984 }
989 /* Try to determine type of the outer object. */
993 {
994 /* See if parameter is THIS pointer of a method. */
997 {
998 outer_type
1004 /* Handle the case we inlined into a thunk. In this case
1005 thunk has THIS pointer of type bar, but it really receives
1006 address to its base type foo which sits in bar at
1007 0-thunk.fixed_offset. It starts with code that adds
1008 think.fixed_offset to the pointer to compensate for this.
1010 Because we walked all the way to the beginning of thunk, we now
1011 see pointer &bar-thunk.fixed_offset and need to compensate
1012 for it. */
1017 /* Dynamic casting has possibly upcasted the type
1018 in the hierarchy. In this case outer type is less
1019 informative than inner type and we should forget
1020 about it. */
1023 otr_type))
1025 /* If we compile thunk with virtual offset, the THIS pointer
1026 is adjusted by unknown value. We can't thus use outer info
1027 at all. */
1029 {
1034 }
1038 /* If the function is constructor or destructor, then
1039 the type is possibly in construction, but we know
1040 it is not derived type. */
1043 {
1046 }
1047 else
1048 {
1051 }
1053 {
1055 /* If method is expanded thunk, we need to apply thunk offset
1056 to instance pointer. */
1059 else
1061 }
1063 }
1064 /* Non-PODs passed by value are really passed by invisible
1065 reference. In this case we also know the type of the
1066 object. */
1068 {
1069 outer_type
1071 /* Only type inconsistent programs can have otr_type that is
1072 not part of outer type. */
1074 otr_type))
1075 {
1080 }
1081 /* Non-polymorphic types have no interest for us. */
1083 {
1088 }
1094 }
1095 }
1103 {
1108 }
1117 offset,
1119 /* TODO: There are multiple ways to derive a type. For instance
1120 if BASE_POINTER is passed to an constructor call prior our reference.
1121 We do not make this type of flow sensitive analysis yet. */
1125 }
1127 /* Structure to be passed in between detect_type_change and
1128 check_stmt_for_type_change. */
1130 struct type_change_info
1131 {
1132 /* Offset into the object where there is the virtual method pointer we are
1133 looking for. */
1134 HOST_WIDE_INT offset;
1135 /* The declaration or SSA_NAME pointer of the base that we are checking for
1136 type change. */
1137 tree instance;
1138 /* The reference to virtual table pointer used. */
1139 tree vtbl_ptr_ref;
1140 tree otr_type;
1141 /* If we actually can tell the type that the object has changed to, it is
1142 stored in this field. Otherwise it remains NULL_TREE. */
1143 tree known_current_type;
1144 HOST_WIDE_INT known_current_offset;
1146 /* Set to nonzero if we possibly missed some dynamic type changes and we
1147 should consider the set to be speculative. */
1150 /* Set to true if dynamic type change has been detected. */
1152 /* Set to true if multiple types have been encountered. known_current_type
1153 must be disregarded in that case. */
1156 };
1158 /* Return true if STMT is not call and can modify a virtual method table pointer.
1159 We take advantage of fact that vtable stores must appear within constructor
1160 and destructor functions. */
1162 static bool
1164 {
1166 {
1172 {
1180 /* In the future we might want to use get_ref_base_and_extent to find
1181 if there is a field corresponding to the offset and if so, proceed
1182 almost like if it was a component ref. */
1183 }
1184 }
1186 /* Code unification may mess with inline stacks. */
1190 /* Walk the inline stack and watch out for ctors/dtors.
1191 TODO: Maybe we can require the store to appear in toplevel
1192 block of CTOR/DTOR. */
1201 }
1203 /* If STMT can be proved to be an assignment to the virtual method table
1204 pointer of ANALYZED_OBJ and the type associated with the new table
1205 identified, return the type. Otherwise return NULL_TREE if type changes
1206 in unknown way or ERROR_MARK_NODE if type is unchanged. */
1208 static tree
1211 {
1223 {
1227 }
1230 ;
1231 else
1232 {
1235 {
1237 {
1239 {
1245 }
1247 }
1248 }
1250 {
1252 {
1254 {
1260 }
1262 }
1264 {
1266 {
1268 {
1274 }
1276 }
1277 else
1279 }
1280 }
1283 {
1285 {
1291 }
1293 }
1297 {
1299 {
1305 }
1311 }
1312 }
1314 tree vtable;
1318 {
1322 }
1327 {
1330 /* FIXME: We should support construction contexts. */
1332 }
1336 }
1338 /* Record dynamic type change of TCI to TYPE. */
1340 static void
1342 {
1344 {
1346 {
1350 }
1351 else
1353 }
1355 /* If we found a constructor of type that is not polymorphic or
1356 that may contain the type in question as a field (not as base),
1357 restrict to the inner class first to make type matching bellow
1358 happier. */
1360 && (offset
1364 {
1365 ipa_polymorphic_call_context context;
1372 /* If we failed to find the inner type, we know that the call
1373 would be undefined for type produced here. */
1375 {
1379 }
1380 /* Watch for case we reached an POD type and anticipate placement
1381 new. */
1383 {
1386 }
1387 }
1395 }
1398 /* The maximum number of may-defs we visit when looking for a must-def
1399 that changes the dynamic type in check_stmt_for_type_change. Tuned
1400 after the PR12392 testcase which unlimited spends 40% time within
1401 these alias walks and 8% with the following limit. */
1405 {
1408 }
1410 /* Callback of walk_aliased_vdefs and a helper function for
1411 detect_type_change to check whether a particular statement may modify
1412 the virtual table pointer, and if possible also determine the new type of
1413 the (sub-)object. It stores its result into DATA, which points to a
1414 type_change_info structure. */
1416 static bool
1418 {
1421 tree fn;
1423 /* If we already gave up, just terminate the rest of walk. */
1428 {
1432 /* Check for a constructor call. */
1437 {
1444 {
1447 }
1449 /* See if THIS parameter seems like instance pointer. */
1451 {
1452 HOST_WIDE_INT size;
1456 {
1459 }
1461 {
1463 {
1466 }
1470 }
1472 ;
1473 else
1474 {
1477 }
1479 }
1485 /* Some inlined constructors may look as follows:
1486 _3 = operator new (16);
1487 MEM[(struct &)_3] ={v} {CLOBBER};
1488 MEM[(struct CompositeClass *)_3]._vptr.CompositeClass
1489 = &MEM[(void *)&_ZTV14CompositeClass + 16B];
1490 _7 = &MEM[(struct CompositeClass *)_3].object;
1491 EmptyClass::EmptyClass (_7);
1493 When determining dynamic type of _3 and because we stop at first
1494 dynamic type found, we would stop on EmptyClass::EmptyClass (_7).
1495 In this case the emptyclass is not even polymorphic and we miss
1496 it is contained in an outer type that is polymorphic. */
1499 {
1502 }
1503 }
1504 /* Calls may possibly change dynamic type by placement new. Assume
1505 it will not happen, but make result speculative only. */
1507 {
1510 }
1513 }
1514 /* Check for inlined virtual table store. */
1516 {
1517 tree type;
1520 {
1523 }
1530 {
1535 }
1536 else
1539 }
1540 else
1542 }
1544 /* THIS is polymorphic call context obtained from get_polymorphic_context.
1545 OTR_OBJECT is pointer to the instance returned by OBJ_TYPE_REF_OBJECT.
1546 INSTANCE is pointer to the outer instance as returned by
1547 get_polymorphic_context. To avoid creation of temporary expressions,
1548 INSTANCE may also be an declaration of get_polymorphic_context found the
1549 value to be in static storage.
1551 If the type of instance is not fully determined
1552 (either OUTER_TYPE is unknown or MAYBE_IN_CONSTRUCTION/INCLUDE_DERIVED_TYPES
1553 is set), try to walk memory writes and find the actual construction of the
1554 instance.
1556 Return true if memory is unchanged from function entry.
1558 We do not include this analysis in the context analysis itself, because
1559 it needs memory SSA to be fully built and the walk may be expensive.
1560 So it is not suitable for use withing fold_stmt and similar uses.
1562 AA_WALK_BUDGET_P, if not NULL, is how statements we should allow
1563 walk_aliased_vdefs to examine. The value should be decremented by the
1564 number of statements we examined or set to zero if exhausted. */
1566 bool
1568 tree otr_object,
1569 tree otr_type,
1572 {
1574 ao_ref ao;
1578 /* Remember OFFSET before it is modified by restrict_to_inner_class.
1579 This is because we do not update INSTANCE when walking inwards. */
1589 /* Walk into inner type. This may clear maybe_derived_type and save us
1590 from useless work. It also makes later comparisons with static type
1591 easier. */
1593 {
1596 }
1601 /* If we are in fact not looking at any object or the instance is
1602 some placement new into a random load, give up straight away. */
1606 /* We need to obtain reference to virtual table pointer. It is better
1607 to look it up in the code rather than build our own. This require bit
1608 of pattern matching, but we end up verifying that what we found is
1609 correct.
1611 What we pattern match is:
1613 tmp = instance->_vptr.A; // vtbl ptr load
1614 tmp2 = tmp[otr_token]; // vtable lookup
1615 OBJ_TYPE_REF(tmp2;instance->0) (instance);
1617 We want to start alias oracle walk from vtbl pointer load,
1618 but we may not be able to identify it, for example, when PRE moved the
1619 load around. */
1622 {
1627 {
1631 /* If call target is already known, no need to do the expensive
1632 memory walk. */
1636 /* Check if definition looks like vtable lookup. */
1642 {
1643 ref = get_base_address
1647 /* Find base address of the lookup and see if it looks like
1648 vptr load. */
1652 {
1655 tree base_ref
1659 /* Finally verify that what we found looks like read from
1660 OTR_OBJECT or from INSTANCE with offset OFFSET. */
1665 || (!offset2
1670 {
1673 }
1674 }
1675 }
1676 }
1677 }
1679 /* If we failed to look up the reference in code, build our own. */
1681 {
1682 /* If the statement in question does not use memory, we can't tell
1683 anything. */
1687 }
1688 else
1689 /* Otherwise use the real reference. */
1692 /* We look for vtbl pointer read. */
1695 /* We are looking for stores to vptr pointer within the instance of
1696 outer type.
1697 TODO: The vptr pointer type is globally known, we probably should
1698 keep it and do that even when otr_type is unknown. */
1700 {
1701 ao.base_alias_set
1703 ao.ref_alias_set
1705 }
1708 {
1721 }
1738 int walked
1742 /* If we did not find any type changing statements, we may still drop
1743 maybe_in_construction flag if the context already have outer type.
1745 Here we make special assumptions about both constructors and
1746 destructors which are all the functions that are allowed to alter the
1747 VMT pointers. It assumes that destructors begin with assignment into
1748 all VMT pointers and that constructors essentially look in the
1749 following way:
1751 1) The very first thing they do is that they call constructors of
1752 ancestor sub-objects that have them.
1754 2) Then VMT pointers of this and all its ancestors is set to new
1755 values corresponding to the type corresponding to the constructor.
1757 3) Only afterwards, other stuff such as constructor of member
1758 sub-objects and the code written by the user is run. Only this may
1759 include calling virtual functions, directly or indirectly.
1761 4) placement new cannot be used to change type of non-POD statically
1762 allocated variables.
1764 There is no way to call a constructor of an ancestor sub-object in any
1765 other way.
1767 This means that we do not have to care whether constructors get the
1768 correct type information because they will always change it (in fact,
1769 if we define the type to be given by the VMT pointer, it is undefined).
1771 The most important fact to derive from the above is that if, for some
1772 statement in the section 3, we try to detect whether the dynamic type
1773 has changed, we can safely ignore all calls as we examine the function
1774 body backwards until we reach statements in section 2 because these
1775 calls cannot be ancestor constructors or destructors (if the input is
1776 not bogus) and so do not change the dynamic type (this holds true only
1777 for automatically allocated objects but at the moment we devirtualize
1778 only these). We then must detect that statements in section 2 change
1779 the dynamic type and can try to derive the new type. That is enough
1780 and we can stop, we will never see the calls into constructors of
1781 sub-objects in this code.
1783 Therefore if the static outer type was found (outer_type)
1784 we can safely ignore tci.speculative that is set on calls and give up
1785 only if there was dynamic type store that may affect given variable
1786 (seen_unanalyzed_store) */
1789 {
1794 }
1799 || (outer_type
1800 && !dynamic
1805 outer_type))
1808 instance_outer_type)))))
1809 {
1817 }
1820 && !function_entry_reached
1822 {
1824 {
1832 }
1835 {
1841 }
1842 }
1844 {
1848 }
1851 }
1853 /* See if speculation given by SPEC_OUTER_TYPE, SPEC_OFFSET and SPEC_MAYBE_DERIVED_TYPE
1854 seems consistent (and useful) with what we already have in the non-speculative context. */
1856 bool
1858 HOST_WIDE_INT spec_offset,
1861 {
1865 /* Non-polymorphic types are useless for deriving likely polymorphic
1866 call targets. */
1870 /* If we know nothing, speculation is always good. */
1874 /* Speculation is only useful to avoid derived types.
1875 This is not 100% true for placement new, where the outer context may
1876 turn out to be useless, but ignore these for now. */
1880 /* If types agrees, speculation is consistent, but it makes sense only
1881 when it says something new. */
1885 /* If speculation does not contain the type in question, ignore it. */
1890 /* If outer type already contains speculation as a filed,
1891 it is useless. We already know from OUTER_TYPE
1892 SPEC_TYPE and that it is not in the construction. */
1897 /* If speculative outer type is not more specified than outer
1898 type, just give up.
1899 We can only decide this safely if we can compare types with OUTER_TYPE.
1900 */
1907 }
1909 /* Improve THIS with speculation described by NEW_OUTER_TYPE, NEW_OFFSET,
1910 NEW_MAYBE_DERIVED_TYPE
1911 If OTR_TYPE is set, assume the context is used with OTR_TYPE. */
1913 bool
1916 tree otr_type)
1917 {
1921 /* restrict_to_inner_class may eliminate wrong speculation making our job
1922 easier. */
1930 /* New speculation is a win in case we have no speculation or new
1931 speculation does not consider derivations. */
1933 || (speculative_maybe_derived_type
1935 {
1940 }
1942 new_outer_type))
1943 {
1945 {
1946 /* OK we have two contexts that seems valid but they disagree,
1947 just give up.
1949 This is not a lattice operation, so we may want to drop it later. */
1952 "Speculative outer types match, "
1956 }
1957 else
1958 {
1960 {
1963 }
1964 else
1966 }
1967 }
1968 /* Choose type that contains the other. This one either contains the outer
1969 as a field (thus giving exactly one target) or is deeper in the type
1970 hierarchy. */
1972 && speculative_maybe_derived_type
1977 {
1989 /* If the speculation turned out to make no sense, revert to sensible
1990 one. */
1992 {
1997 }
2001 new_outer_type));
2002 }
2004 }
2006 /* Make speculation less specific so
2007 NEW_OUTER_TYPE, NEW_OFFSET, NEW_MAYBE_DERIVED_TYPE is also included.
2008 If OTR_TYPE is set, assume the context is used with OTR_TYPE. */
2010 bool
2013 tree otr_type)
2014 {
2016 {
2019 }
2021 /* restrict_to_inner_class may eliminate wrong speculation making our job
2022 easier. */
2028 speculative_offset,
2029 speculative_maybe_derived_type,
2030 otr_type))
2035 {
2038 }
2041 new_outer_type))
2042 {
2044 {
2047 }
2048 else
2049 {
2051 {
2054 }
2055 else
2057 }
2058 }
2059 /* See if one type contains the other as a field (not base). */
2066 {
2071 }
2072 /* See if OUTER_TYPE is base of CTX.OUTER_TYPE. */
2076 {
2078 {
2081 }
2083 }
2084 /* See if CTX.OUTER_TYPE is base of OUTER_TYPE. */
2087 {
2092 }
2093 else
2094 {
2099 }
2100 }
2102 /* Assume that both THIS and a given context is valid and strengthen THIS
2103 if possible. Return true if any strengthening was made.
2104 If actual type the context is being used in is known, OTR_TYPE should be
2105 set accordingly. This improves quality of combined result. */
2107 bool
2109 tree otr_type)
2110 {
2116 /* Restricting context to inner type makes merging easier, however do not
2117 do that unless we know how the context is used (OTR_TYPE is non-NULL) */
2119 {
2124 }
2127 {
2133 {
2137 }
2138 }
2140 /* If call is known to be invalid, we are done. */
2142 {
2146 }
2149 ;
2151 {
2158 }
2159 /* If types are known to be same, merging is quite easy. */
2161 {
2165 {
2172 }
2176 {
2179 }
2181 {
2184 }
2186 {
2189 }
2190 }
2191 /* If we know the type precisely, there is not much to improve. */
2194 {
2195 /* It may be easy to check if second context permits the first
2196 and set INVALID otherwise. This is not easy to do in general;
2197 contains_type_p may return false negatives for non-comparable
2198 types.
2200 If OTR_TYPE is known, we however can expect that
2201 restrict_to_inner_class should have discovered the same base
2202 type. */
2204 {
2208 }
2209 }
2210 /* See if one type contains the other as a field (not base).
2211 In this case we want to choose the wider type, because it contains
2212 more information. */
2215 {
2220 {
2226 }
2228 /* If we do not know how the context is being used, we cannot
2229 clear MAYBE_IN_CONSTRUCTION because it may be offseted
2230 to other component of OUTER_TYPE later and we know nothing
2231 about it. */
2234 {
2237 }
2238 }
2241 {
2247 {
2250 }
2251 }
2252 /* See if OUTER_TYPE is base of CTX.OUTER_TYPE. */
2255 {
2259 {
2262 {
2266 }
2267 }
2268 /* Pick variant deeper in the hierarchy. */
2269 else
2270 {
2277 }
2278 }
2279 /* See if CTX.OUTER_TYPE is base of OUTER_TYPE. */
2282 {
2286 {
2289 {
2293 }
2294 /* Pick the base type. */
2296 {
2303 }
2304 }
2305 }
2306 /* TODO handle merging using hierarchy. */
2313 otr_type);
2316 {
2320 }
2323 invalidate:
2328 }
2330 /* Take non-speculative info, merge it with speculative and clear speculation.
2331 Used when we no longer manage to keep track of actual outer type, but we
2332 think it is still there.
2334 If OTR_TYPE is set, the transformation can be done more effectively assuming
2335 that context is going to be used only that way. */
2337 void
2339 {
2345 {
2350 }
2355 spec_maybe_derived_type,
2356 otr_type);
2357 }
2359 /* Use when we cannot track dynamic type change. This speculatively assume
2360 type change is not happening. */
2362 void
2364 tree otr_type)
2365 {
2370 }
2372 /* Return TRUE if this context conveys the same information as OTHER. */
2374 bool
2377 {
2386 {
2395 }
2403 {
2414 }
2419 NULL))
2423 }
2425 /* Modify context to be strictly less restrictive than CTX. */
2427 bool
2429 tree otr_type)
2430 {
2436 /* Restricting context to inner type makes merging easier, however do not
2437 do that unless we know how the context is used (OTR_TYPE is non-NULL) */
2439 {
2444 }
2450 {
2453 }
2456 {
2462 {
2466 }
2467 }
2470 {
2473 }
2475 /* If call is known to be invalid, we are done. */
2477 ;
2479 {
2482 }
2483 /* If types are known to be same, merging is quite easy. */
2485 {
2489 {
2494 }
2498 {
2501 }
2503 {
2506 }
2508 {
2511 }
2512 }
2513 /* See if one type contains the other as a field (not base). */
2516 {
2520 /* The second type is more specified, so we keep the first.
2521 We need to set DYNAMIC flag to avoid declaring context INVALID
2522 of OFFSET ends up being out of range. */
2525 || (!otr_type
2530 {
2533 }
2534 }
2537 {
2543 || (!otr_type
2555 }
2556 /* See if OUTER_TYPE is base of CTX.OUTER_TYPE. */
2559 {
2563 {
2566 }
2568 {
2571 }
2573 {
2576 }
2577 }
2578 /* See if CTX.OUTER_TYPE is base of OUTER_TYPE. */
2581 {
2593 }
2594 /* TODO handle merging using hierarchy. */
2595 else
2596 {
2601 }
2606 otr_type);
2609 {
2613 }
2615 }