| blob | 33c15f52bebaff770ff857e20a7e61d7c6c553e7 |
1 /* Alias analysis for trees.
2 Copyright (C) 2004-2019 Free Software Foundation, Inc.
3 Contributed by Diego Novillo <dnovillo@redhat.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/>. */
42 /* Broad overview of how alias analysis on gimple works:
44 Statements clobbering or using memory are linked through the
45 virtual operand factored use-def chain. The virtual operand
46 is unique per function, its symbol is accessible via gimple_vop (cfun).
47 Virtual operands are used for efficiently walking memory statements
48 in the gimple IL and are useful for things like value-numbering as
49 a generation count for memory references.
51 SSA_NAME pointers may have associated points-to information
52 accessible via the SSA_NAME_PTR_INFO macro. Flow-insensitive
53 points-to information is (re-)computed by the TODO_rebuild_alias
54 pass manager todo. Points-to information is also used for more
55 precise tracking of call-clobbered and call-used variables and
56 related disambiguations.
58 This file contains functions for disambiguating memory references,
59 the so called alias-oracle and tools for walking of the gimple IL.
61 The main alias-oracle entry-points are
63 bool stmt_may_clobber_ref_p (gimple *, tree)
65 This function queries if a statement may invalidate (parts of)
66 the memory designated by the reference tree argument.
68 bool ref_maybe_used_by_stmt_p (gimple *, tree)
70 This function queries if a statement may need (parts of) the
71 memory designated by the reference tree argument.
73 There are variants of these functions that only handle the call
74 part of a statement, call_may_clobber_ref_p and ref_maybe_used_by_call_p.
75 Note that these do not disambiguate against a possible call lhs.
77 bool refs_may_alias_p (tree, tree)
79 This function tries to disambiguate two reference trees.
81 bool ptr_deref_may_alias_global_p (tree)
83 This function queries if dereferencing a pointer variable may
84 alias global memory.
86 More low-level disambiguators are available and documented in
87 this file. Low-level disambiguators dealing with points-to
88 information are in tree-ssa-structalias.c. */
91 /* Query statistics for the different low-level disambiguators.
92 A high-level query may trigger multiple of them. */
105 void
107 {
110 HOST_WIDE_INT_PRINT_DEC" disambiguations, "
113 alias_stats.refs_may_alias_p_no_alias
116 HOST_WIDE_INT_PRINT_DEC" disambiguations, "
119 alias_stats.refs_may_alias_p_no_alias
122 HOST_WIDE_INT_PRINT_DEC" disambiguations, "
125 alias_stats.call_may_clobber_ref_p_no_alias
128 HOST_WIDE_INT_PRINT_DEC" disambiguations, "
131 alias_stats.aliasing_component_refs_p_no_alias
134 }
137 /* Return true, if dereferencing PTR may alias with a global variable. */
139 bool
141 {
144 /* If we end up with a pointer constant here that may point
145 to global memory. */
151 /* If we do not have points-to information for this variable,
152 we have to punt. */
156 /* ??? This does not use TBAA to prune globals ptr may not access. */
158 }
160 /* Return true if dereferencing PTR may alias DECL.
161 The caller is responsible for applying TBAA to see if PTR
162 may access DECL at all. */
164 static bool
166 {
169 /* Conversions are irrelevant for points-to information and
170 data-dependence analysis can feed us those. */
173 /* Anything we do not explicilty handle aliases. */
183 /* Disregard pointer offsetting. */
185 {
186 do
187 {
189 }
192 }
194 /* ADDR_EXPR pointers either just offset another pointer or directly
195 specify the pointed-to set. */
197 {
209 else
211 }
213 /* Non-aliased variables cannot be pointed to. */
217 /* If we do not have useful points-to information for this pointer
218 we cannot disambiguate anything else. */
224 }
226 /* Return true if dereferenced PTR1 and PTR2 may alias.
227 The caller is responsible for applying TBAA to see if accesses
228 through PTR1 and PTR2 may conflict at all. */
230 bool
232 {
235 /* Conversions are irrelevant for points-to information and
236 data-dependence analysis can feed us those. */
240 /* Disregard pointer offsetting. */
242 {
243 do
244 {
246 }
249 }
251 {
252 do
253 {
255 }
258 }
260 /* ADDR_EXPR pointers either just offset another pointer or directly
261 specify the pointed-to set. */
263 {
272 else
274 }
276 {
285 else
287 }
289 /* From here we require SSA name pointers. Anything else aliases. */
296 /* We may end up with two empty points-to solutions for two same pointers.
297 In this case we still want to say both pointers alias, so shortcut
298 that here. */
302 /* If we do not have useful points-to information for either pointer
303 we cannot disambiguate anything else. */
309 /* ??? This does not use TBAA to prune decls from the intersection
310 that not both pointers may access. */
312 }
314 /* Return true if dereferencing PTR may alias *REF.
315 The caller is responsible for applying TBAA to see if PTR
316 may access *REF at all. */
318 static bool
320 {
330 }
332 /* Returns true if PTR1 and PTR2 compare unequal because of points-to. */
334 bool
336 {
337 /* First resolve the pointers down to a SSA name pointer base or
338 a VAR_DECL, PARM_DECL or RESULT_DECL. This explicitely does
339 not yet try to handle LABEL_DECLs, FUNCTION_DECLs, CONST_DECLs
340 or STRING_CSTs which needs points-to adjustments to track them
341 in the points-to sets. */
345 {
355 }
357 {
367 }
369 /* Canonicalize ptr vs. object. */
371 {
374 }
379 {
381 /* We may not use restrict to optimize pointer comparisons.
382 See PR71062. So we have to assume that restrict-pointed-to
383 may be in fact obj1. */
390 {
392 /* If obj1 may bind to NULL give up (see below). */
397 }
399 }
401 /* ??? We'd like to handle ptr1 != NULL and ptr1 != ptr2
402 but those require pt.null to be conservatively correct. */
405 }
407 /* Returns whether reference REF to BASE may refer to global memory. */
409 static bool
411 {
418 }
420 bool
422 {
425 }
427 bool
429 {
432 }
434 /* Return true whether STMT may clobber global memory. */
436 bool
438 {
439 tree lhs;
444 /* ??? We can ask the oracle whether an artificial pointer
445 dereference with a pointer with points-to information covering
446 all global memory (what about non-address taken memory?) maybe
447 clobbered by this call. As there is at the moment no convenient
448 way of doing that without generating garbage do some manual
449 checking instead.
450 ??? We could make a NULL ao_ref argument to the various
451 predicates special, meaning any global memory. */
454 {
463 }
464 }
467 /* Dump alias information on FILE. */
469 void
471 {
473 tree ptr;
476 tree var;
483 {
486 }
496 {
506 }
509 }
512 /* Dump alias information on stderr. */
514 DEBUG_FUNCTION void
516 {
518 }
521 /* Dump the points-to set *PT into FILE. */
523 void
525 {
542 {
549 {
553 {
556 }
558 {
561 }
563 {
566 }
568 {
571 }
575 }
576 }
577 }
580 /* Unified dump function for pt_solution. */
582 DEBUG_FUNCTION void
584 {
586 }
588 DEBUG_FUNCTION void
590 {
593 else
595 }
598 /* Dump points-to information for SSA_NAME PTR into FILE. */
600 void
602 {
609 else
613 }
616 /* Dump points-to information for VAR into stderr. */
618 DEBUG_FUNCTION void
620 {
622 }
625 /* Initializes the alias-oracle reference representation *R from REF. */
627 void
629 {
638 }
640 /* Returns the base object of the memory reference *REF. */
642 tree
644 {
652 }
654 /* Returns the base object alias set of the memory reference *REF. */
656 alias_set_type
658 {
659 tree base_ref;
669 }
671 /* Returns the reference alias set of the memory reference *REF. */
673 alias_set_type
675 {
680 }
682 /* Init an alias-oracle reference representation from a gimple pointer
683 PTR and a gimple size SIZE in bytes. If SIZE is NULL_TREE then the
684 size is assumed to be unknown. The access is assumed to be only
685 to or after of the pointer target, not before it. */
687 void
689 {
693 {
701 {
704 }
705 }
708 {
712 else
713 {
717 }
718 }
719 else
720 {
725 }
731 else
736 }
738 /* S1 and S2 are TYPE_SIZE or DECL_SIZE. Compare them:
739 Return -1 if S1 < S2
740 Return 1 if S1 > S2
741 Return 0 if equal or incomparable. */
743 static int
745 {
749 poly_uint64 size1;
750 poly_uint64 size2;
759 }
761 /* Compare TYPE1 and TYPE2 by its size.
762 Return -1 if size of TYPE1 < size of TYPE2
763 Return 1 if size of TYPE1 > size of TYPE2
764 Return 0 if types are of equal sizes or we can not compare them. */
766 static int
768 {
769 /* Be conservative for arrays and vectors. We want to support partial
770 overlap on int[3] and int[3] as tested in gcc.dg/torture/alias-2.c. */
778 }
780 /* Return 1 if TYPE1 and TYPE2 are to be considered equivalent for the
781 purpose of TBAA. Return 0 if they are distinct and -1 if we cannot
782 decide. */
786 {
790 /* If we would have to do structural comparison bail out. */
795 /* Compare the canonical types. */
799 /* ??? Array types are not properly unified in all cases as we have
800 spurious changes in the index types for example. Removing this
801 causes all sorts of problems with the Fortran frontend. */
806 /* ??? In Ada, an lvalue of an unconstrained type can be used to access an
807 object of one of its constrained subtypes, e.g. when a function with an
808 unconstrained parameter passed by reference is called on an object and
809 inlined. But, even in the case of a fixed size, type and subtypes are
810 not equivalent enough as to share the same TYPE_CANONICAL, since this
811 would mean that conversions between them are useless, whereas they are
812 not (e.g. type and subtypes can have different modes). So, in the end,
813 they are only guaranteed to have the same alias set. */
817 /* The types are known to be not equal. */
819 }
821 /* Determine if the two component references REF1 and REF2 which are
822 based on access types TYPE1 and TYPE2 and of which at least one is based
823 on an indirect reference may alias. REF2 is the only one that can
824 be a decl in which case REF2_IS_DECL is true.
825 REF1_ALIAS_SET, BASE1_ALIAS_SET, REF2_ALIAS_SET and BASE2_ALIAS_SET
826 are the respective alias sets. */
828 static bool
830 alias_set_type ref1_alias_set,
831 alias_set_type base1_alias_set,
833 tree ref2,
834 alias_set_type ref2_alias_set,
835 alias_set_type base2_alias_set,
838 {
839 /* If one reference is a component references through pointers try to find a
840 common base and apply offset based disambiguation. This handles
841 for example
842 struct A { int i; int j; } *q;
843 struct B { struct A a; int k; } *p;
844 disambiguating q->i and p->a.j. */
850 /* Choose bases and base types to search for. */
860 /* Now search for the type1 in the access path of ref2. This
861 would be a common base for doing offset based disambiguation on.
862 This however only makes sense if type2 is big enough to hold type1. */
865 {
868 {
869 /* We walk from inner type to the outer types. If type we see is
870 already too large to be part of type1, terminate the search. */
874 /* If types may be of same size, see if we can decide about their
875 equality. */
877 {
881 }
885 }
887 {
895 {
898 }
899 else
900 {
903 }
904 }
905 }
907 /* If we didn't find a common base, try the other way around. */
909 {
912 {
916 /* If types may be of same size, see if we can decide about their
917 equality. */
919 {
923 }
927 }
929 {
938 {
941 }
942 else
943 {
946 }
947 }
948 }
950 /* In the following code we make an assumption that the types in access
951 paths do not overlap and thus accesses alias only if one path can be
952 continuation of another. If we was not able to decide about equivalence,
953 we need to give up. */
957 /* If we have two type access paths B1.path1 and B2.path2 they may
958 only alias if either B1 is in B2.path2 or B2 is in B1.path1.
959 But we can still have a path that goes B1.path1...B2.path2 with
960 a part that we do not see. So we can only disambiguate now
961 if there is no B2 in the tail of path1 and no B1 on the
962 tail of path2. */
966 {
969 }
970 /* If this is ptr vs. decl then we know there is no ptr ... decl path. */
975 {
978 }
981 }
983 /* Return true if we can determine that component references REF1 and REF2,
984 that are within a common DECL, cannot overlap. */
986 static bool
988 {
992 /* Create the stack of handled components for REF1. */
994 {
997 }
999 {
1003 }
1005 /* Create the stack of handled components for REF2. */
1007 {
1010 }
1012 {
1016 }
1018 /* Bases must be either same or uncomparable. */
1023 /* Pop the stacks in parallel and examine the COMPONENT_REFs of the same
1024 rank. This is sufficient because we start from the same DECL and you
1025 cannot reference several fields at a time with COMPONENT_REFs (unlike
1026 with ARRAY_RANGE_REFs for arrays) so you always need the same number
1027 of them to access a sub-component, unless you're in a union, in which
1028 case the return value will precisely be false. */
1030 {
1031 do
1032 {
1036 }
1039 do
1040 {
1044 }
1047 /* Beware of BIT_FIELD_REF. */
1055 /* ??? We cannot simply use the type of operand #0 of the refs here
1056 as the Fortran compiler smuggles type punning into COMPONENT_REFs
1057 for common blocks instead of using unions like everyone else. */
1061 /* We cannot disambiguate fields in a union or qualified union. */
1066 {
1067 /* A field and its representative need to be considered the
1068 same. */
1072 /* Different fields of the same record type cannot overlap.
1073 ??? Bitfields can overlap at RTL level so punt on them. */
1077 }
1078 }
1081 }
1083 /* qsort compare function to sort FIELD_DECLs after their
1084 DECL_FIELD_CONTEXT TYPE_UID. */
1088 {
1098 }
1100 /* Return true if we can determine that the fields referenced cannot
1101 overlap for any pair of objects. */
1103 static bool
1105 {
1114 {
1120 }
1125 {
1131 }
1135 /* Most common case first. */
1144 {
1147 }
1148 else
1152 {
1155 }
1156 else
1160 do
1161 {
1167 {
1168 /* We're left with accessing different fields of a structure,
1169 no possible overlap. */
1171 {
1172 /* A field and its representative need to be considered the
1173 same. */
1177 /* Different fields of the same record type cannot overlap.
1178 ??? Bitfields can overlap at RTL level so punt on them. */
1182 }
1183 }
1185 {
1186 i++;
1189 }
1190 else
1191 {
1192 j++;
1195 }
1196 }
1200 }
1203 /* Return true if two memory references based on the variables BASE1
1204 and BASE2 constrained to [OFFSET1, OFFSET1 + MAX_SIZE1) and
1205 [OFFSET2, OFFSET2 + MAX_SIZE2) may alias. REF1 and REF2
1206 if non-NULL are the complete memory reference trees. */
1208 static bool
1213 {
1216 /* If both references are based on different variables, they cannot alias. */
1220 /* If both references are based on the same variable, they cannot alias if
1221 the accesses do not overlap. */
1225 /* For components with variable position, the above test isn't sufficient,
1226 so we disambiguate component references manually. */
1233 }
1235 /* Return true if an indirect reference based on *PTR1 constrained
1236 to [OFFSET1, OFFSET1 + MAX_SIZE1) may alias a variable based on BASE2
1237 constrained to [OFFSET2, OFFSET2 + MAX_SIZE2). *PTR1 and BASE2 have
1238 the alias sets BASE1_ALIAS_SET and BASE2_ALIAS_SET which can be -1
1239 in which case they are computed on-demand. REF1 and REF2
1240 if non-NULL are the complete memory reference trees. */
1242 static bool
1245 alias_set_type ref1_alias_set,
1246 alias_set_type base1_alias_set,
1249 alias_set_type ref2_alias_set,
1251 {
1252 tree ptr1;
1262 /* If only one reference is based on a variable, they cannot alias if
1263 the pointer access is beyond the extent of the variable access.
1264 (the pointer base cannot validly point to an offset less than zero
1265 of the variable).
1266 ??? IVOPTs creates bases that do not honor this restriction,
1267 so do not apply this optimization for TARGET_MEM_REFs. */
1271 /* They also cannot alias if the pointer may not point to the decl. */
1275 /* Disambiguations that rely on strict aliasing rules follow. */
1281 /* If the alias set for a pointer access is zero all bets are off. */
1285 /* When we are trying to disambiguate an access with a pointer dereference
1286 as base versus one with a decl as base we can use both the size
1287 of the decl and its dynamic type for extra disambiguation.
1288 ??? We do not know anything about the dynamic type of the decl
1289 other than that its alias-set contains base2_alias_set as a subset
1290 which does not help us here. */
1291 /* As we know nothing useful about the dynamic type of the decl just
1292 use the usual conflict check rather than a subset test.
1293 ??? We could introduce -fvery-strict-aliasing when the language
1294 does not allow decls to have a dynamic type that differs from their
1295 static type. Then we can check
1296 !alias_set_subset_of (base1_alias_set, base2_alias_set) instead. */
1300 /* If the size of the access relevant for TBAA through the pointer
1301 is bigger than the size of the decl we can't possibly access the
1302 decl via that pointer. */
1304 a member of union type U is accessed through a pointer to
1305 type U and sizeof T is smaller than sizeof U. */
1315 /* If the decl is accessed via a MEM_REF, reconstruct the base
1316 we can use for TBAA and an appropriately adjusted offset. */
1326 /* If either reference is view-converted, give up now. */
1331 /* If both references are through the same type, they do not alias
1332 if the accesses do not overlap. This does extra disambiguation
1333 for mixed/pointer accesses but requires strict aliasing.
1334 For MEM_REFs we require that the component-ref offset we computed
1335 is relative to the start of the type which we ensure by
1336 comparing rvalue and access type and disregarding the constant
1337 pointer offset. */
1347 /* Do access-path based disambiguation. */
1353 ref2,
1358 }
1360 /* Return true if two indirect references based on *PTR1
1361 and *PTR2 constrained to [OFFSET1, OFFSET1 + MAX_SIZE1) and
1362 [OFFSET2, OFFSET2 + MAX_SIZE2) may alias. *PTR1 and *PTR2 have
1363 the alias sets BASE1_ALIAS_SET and BASE2_ALIAS_SET which can be -1
1364 in which case they are computed on-demand. REF1 and REF2
1365 if non-NULL are the complete memory reference trees. */
1367 static bool
1370 alias_set_type ref1_alias_set,
1371 alias_set_type base1_alias_set,
1374 alias_set_type ref2_alias_set,
1376 {
1377 tree ptr1;
1378 tree ptr2;
1389 /* If both bases are based on pointers they cannot alias if they may not
1390 point to the same memory object or if they point to the same object
1391 and the accesses do not overlap. */
1412 {
1417 }
1421 /* Disambiguations that rely on strict aliasing rules follow. */
1428 /* If the alias set for a pointer access is zero all bets are off. */
1433 /* If both references are through the same type, they do not alias
1434 if the accesses do not overlap. This does extra disambiguation
1435 for mixed/pointer accesses but requires strict aliasing. */
1444 /* But avoid treating arrays as "objects", instead assume they
1445 can overlap by an exact multiple of their element size. */
1449 /* Do type-based disambiguation. */
1454 /* If either reference is view-converted, give up now. */
1463 /* Do access-path based disambiguation. */
1469 ref2,
1474 }
1476 /* Return true, if the two memory references REF1 and REF2 may alias. */
1478 static bool
1480 {
1501 /* Decompose the references into their base objects and the access. */
1509 /* We can end up with registers or constants as bases for example from
1510 *D.1663_44 = VIEW_CONVERT_EXPR<struct DB_LSN>(__tmp$B0F64_59);
1511 which is seen as a struct copy. */
1524 /* We can end up referring to code via function and label decls.
1525 As we likely do not properly track code aliases conservatively
1526 bail out. */
1533 /* Two volatile accesses always conflict. */
1538 /* Defer to simple offset based disambiguation if we have
1539 references based on two decls. Do this before defering to
1540 TBAA to handle must-alias cases in conformance with the
1541 GCC extension of allowing type-punning through unions. */
1548 /* Handle restrict based accesses.
1549 ??? ao_ref_base strips inner MEM_REF [&decl], recover from that
1550 here. */
1554 {
1559 }
1561 {
1566 }
1570 /* If the accesses are in the same restrict clique... */
1572 /* But based on different pointers they do not alias. */
1581 /* Canonicalize the pointer-vs-decl case. */
1583 {
1592 }
1594 /* First defer to TBAA if possible. */
1596 && flag_strict_aliasing
1601 /* If the reference is based on a pointer that points to memory
1602 that may not be written to then the other reference cannot possibly
1603 clobber it. */
1606 || (ind1_p
1611 /* Dispatch to the pointer-vs-decl or pointer-vs-pointer disambiguators. */
1621 tbaa_p);
1631 tbaa_p);
1634 }
1636 /* Return true, if the two memory references REF1 and REF2 may alias
1637 and update statistics. */
1639 bool
1641 {
1645 else
1648 }
1650 static bool
1652 {
1653 ao_ref r1;
1656 }
1658 bool
1660 {
1665 }
1667 /* Returns true if there is a anti-dependence for the STORE that
1668 executes after the LOAD. */
1670 bool
1672 {
1677 }
1679 /* Returns true if there is a output dependence for the stores
1680 STORE1 and STORE2. */
1682 bool
1684 {
1689 }
1691 /* If the call CALL may use the memory reference REF return true,
1692 otherwise return false. */
1694 static bool
1696 {
1701 /* Const functions without a static chain do not implicitly use memory. */
1710 /* A call that is not without side-effects might involve volatile
1711 accesses and thus conflicts with all other volatile accesses. */
1715 /* If the reference is based on a decl that is not aliased the call
1716 cannot possibly use it. */
1719 /* But local statics can be used through recursion. */
1725 /* Handle those builtin functions explicitly that do not act as
1726 escape points. See tree-ssa-structalias.c:find_func_aliases
1727 for the list of builtins we might need to handle here. */
1731 {
1732 /* All the following functions read memory pointed to by
1733 their second argument. strcat/strncat additionally
1734 reads memory pointed to by the first argument. */
1737 {
1738 ao_ref dref;
1741 NULL_TREE);
1744 }
1745 /* FALLTHRU */
1755 {
1756 ao_ref dref;
1762 size);
1764 }
1767 {
1768 ao_ref dref;
1771 NULL_TREE);
1774 }
1775 /* FALLTHRU */
1783 {
1784 ao_ref dref;
1790 size);
1792 }
1794 {
1795 ao_ref dref;
1799 size);
1801 }
1803 /* The following functions read memory pointed to by their
1804 first argument. */
1828 /* These read memory pointed to by the first argument. */
1832 {
1833 ao_ref dref;
1839 size);
1841 }
1842 /* These read memory pointed to by the first argument. */
1846 {
1847 ao_ref dref;
1850 NULL_TREE);
1852 }
1853 /* These read memory pointed to by the first argument with size
1854 in the third argument. */
1856 {
1857 ao_ref dref;
1862 }
1863 /* These read memory pointed to by the first and second arguments. */
1866 {
1867 ao_ref dref;
1870 NULL_TREE);
1875 NULL_TREE);
1877 }
1879 /* The following builtins do not read from memory. */
1885 CASE_BUILT_IN_ALLOCA:
1912 /* __sync_* builtins and some OpenMP builtins act as threading
1913 barriers. */
1914 #undef DEF_SYNC_BUILTIN
1915 #define DEF_SYNC_BUILTIN(ENUM, NAME, TYPE, ATTRS) case ENUM:
1917 #undef DEF_SYNC_BUILTIN
1940 }
1942 /* Check if base is a global static variable that is not read
1943 by the function. */
1945 {
1947 bitmap not_read;
1949 /* FIXME: Callee can be an OMP builtin that does not have a call graph
1950 node yet. We should enforce that there are nodes for all decls in the
1951 IL and remove this check instead. */
1956 }
1958 /* Check if the base variable is call-used. */
1960 {
1963 }
1967 {
1974 }
1975 else
1978 /* Inspect call arguments for passed-by-value aliases. */
1979 process_args:
1981 {
1993 {
1994 ao_ref r;
1998 }
1999 }
2002 }
2004 static bool
2006 {
2011 else
2014 }
2017 /* If the statement STMT may use the memory reference REF return
2018 true, otherwise return false. */
2020 bool
2022 {
2024 {
2025 tree rhs;
2027 /* All memory assign statements are single. */
2038 }
2042 {
2049 /* If ref escapes the function then the return acts as a use. */
2052 ;
2059 }
2062 }
2064 bool
2066 {
2067 ao_ref r;
2070 }
2072 /* If the call in statement CALL may clobber the memory reference REF
2073 return true, otherwise return false. */
2075 bool
2077 {
2078 tree base;
2079 tree callee;
2081 /* If the call is pure or const it cannot clobber anything. */
2087 {
2088 /* Treat these internal calls like ECF_PURE for aliasing,
2089 they don't write to any memory the program should care about.
2090 They have important other side-effects, and read memory,
2091 so can't be ECF_NOVOPS. */
2101 }
2111 /* A call that is not without side-effects might involve volatile
2112 accesses and thus conflicts with all other volatile accesses. */
2116 /* If the reference is based on a decl that is not aliased the call
2117 cannot possibly clobber it. */
2120 /* But local non-readonly statics can be modified through recursion
2121 or the call may implement a threading barrier which we must
2122 treat as may-def. */
2127 /* If the reference is based on a pointer that points to memory
2128 that may not be written to then the call cannot possibly clobber it. */
2137 /* Handle those builtin functions explicitly that do not act as
2138 escape points. See tree-ssa-structalias.c:find_func_aliases
2139 for the list of builtins we might need to handle here. */
2143 {
2144 /* All the following functions clobber memory pointed to by
2145 their first argument. */
2169 {
2170 ao_ref dref;
2172 /* Don't pass in size for strncat, as the maximum size
2173 is strlen (dest) + n + 1 instead of n, resp.
2174 n + 1 at dest + strlen (dest), but strlen (dest) isn't
2175 known. */
2181 size);
2183 }
2194 {
2195 ao_ref dref;
2197 /* Don't pass in size for __strncat_chk, as the maximum size
2198 is strlen (dest) + n + 1 instead of n, resp.
2199 n + 1 at dest + strlen (dest), but strlen (dest) isn't
2200 known. */
2206 size);
2208 }
2210 {
2211 ao_ref dref;
2215 size);
2217 }
2218 /* Allocating memory does not have any side-effects apart from
2219 being the definition point for the pointer. */
2225 /* Unix98 specifies that errno is set on allocation failure. */
2231 CASE_BUILT_IN_ALLOCA:
2234 /* But posix_memalign stores a pointer into the memory pointed to
2235 by its first argument. */
2237 {
2239 ao_ref dref;
2243 || (flag_errno_math
2245 }
2246 /* Freeing memory kills the pointed-to memory. More importantly
2247 the call has to serve as a barrier for moving loads and stores
2248 across it. */
2251 {
2254 }
2255 /* Realloc serves both as allocation point and deallocation point. */
2257 {
2259 /* Unix98 specifies that errno is set on allocation failure. */
2263 }
2270 {
2277 }
2284 {
2287 }
2291 {
2298 }
2302 {
2307 }
2308 /* __sync_* builtins and some OpenMP builtins act as threading
2309 barriers. */
2310 #undef DEF_SYNC_BUILTIN
2311 #define DEF_SYNC_BUILTIN(ENUM, NAME, TYPE, ATTRS) case ENUM:
2313 #undef DEF_SYNC_BUILTIN
2335 }
2337 /* Check if base is a global static variable that is not written
2338 by the function. */
2340 {
2342 bitmap not_written;
2348 }
2350 /* Check if the base variable is call-clobbered. */
2356 {
2362 }
2365 }
2367 /* If the call in statement CALL may clobber the memory reference REF
2368 return true, otherwise return false. */
2370 bool
2372 {
2374 ao_ref r;
2379 else
2382 }
2385 /* If the statement STMT may clobber the memory reference REF return true,
2386 otherwise return false. */
2388 bool
2390 {
2392 {
2396 {
2397 ao_ref r;
2401 }
2404 }
2406 {
2409 {
2410 ao_ref r;
2413 }
2414 }
2419 }
2421 bool
2423 {
2424 ao_ref r;
2427 }
2429 /* Return true if store1 and store2 described by corresponding tuples
2430 <BASE, OFFSET, SIZE, MAX_SIZE> have the same size and store to the same
2431 address. */
2433 static bool
2435 poly_int64 max_size1,
2437 poly_int64 max_size2)
2438 {
2439 /* Offsets need to be 0. */
2447 /* We need one object. */
2452 /* And we need one MEM_REF. */
2459 /* Sizes need to be valid. */
2466 /* Max_size needs to match size. */
2471 /* Sizes need to match. */
2476 /* Check that memref is a store to pointer with singleton points-to info. */
2488 /* Be conservative with non-call exceptions when the address might
2489 be NULL. */
2493 /* Check that ptr points relative to obj. */
2498 /* Check that the object size is the same as the store size. That ensures us
2499 that ptr points to the start of obj. */
2503 }
2505 /* If STMT kills the memory reference REF return true, otherwise
2506 return false. */
2508 bool
2510 {
2516 /* The assignment is not necessarily carried out if it can throw
2517 and we can catch it in the current function where we could inspect
2518 the previous value.
2519 ??? We only need to care about the RHS throwing. For aggregate
2520 assignments or similar calls and non-call exceptions the LHS
2521 might throw as well. */
2523 {
2525 /* If LHS is literally a base of the access we are done. */
2527 {
2531 {
2534 {
2537 }
2538 do
2539 {
2540 /* Just compare the outermost handled component, if
2541 they are equal we have found a possible common
2542 base. */
2549 /* Remember if we drop an array-ref that we need to
2550 double-check not being at struct end. */
2554 /* Otherwise drop handled components of the access. */
2556 }
2560 }
2561 /* Finally check if the lhs has the same address and size as the
2562 base candidate of the access. Watch out if we have dropped
2563 an array-ref that was at struct end, this means ref->ref may
2564 be outside of the TYPE_SIZE of its base. */
2576 OEP_ADDRESS_OF
2579 }
2581 /* Now look for non-literal equal bases with the restriction of
2582 handling constant offset and size. */
2583 /* For a must-alias check we need to be able to constrain
2584 the access properly. */
2591 /* We can get MEM[symbol: sZ, index: D.8862_1] here,
2592 so base == ref->base does not always hold. */
2594 {
2595 /* Try using points-to info. */
2600 /* If both base and ref->base are MEM_REFs, only compare the
2601 first operand, and if the second operand isn't equal constant,
2602 try to add the offsets into offset and ref_offset. */
2605 {
2608 {
2617 }
2618 }
2619 else
2621 }
2622 /* For a must-alias check we need to be able to constrain
2623 the access properly. */
2627 }
2630 {
2635 {
2637 {
2644 }
2656 {
2657 /* For a must-alias check we need to be able to constrain
2658 the access properly. */
2667 ao_ref dref;
2674 {
2677 // Compare pointers.
2682 }
2689 }
2692 {
2695 {
2699 }
2701 }
2704 }
2705 }
2707 }
2709 bool
2711 {
2712 ao_ref r;
2715 }
2718 /* Walk the virtual use-def chain of VUSE until hitting the virtual operand
2719 TARGET or a statement clobbering the memory reference REF in which
2720 case false is returned. The walk starts with VUSE, one argument of PHI. */
2722 static bool
2728 {
2736 /* Walk until we hit the target. */
2738 {
2740 /* If we are searching for the target VUSE by walking up to
2741 TARGET_BB dominating the original PHI we are finished once
2742 we reach a default def or a definition in a block dominating
2743 that block. Update TARGET and return. */
2748 {
2751 }
2753 /* Recurse for PHI nodes. */
2755 {
2756 /* An already visited PHI node ends the walk successfully. */
2765 }
2768 else
2769 {
2770 /* A clobbering statement or the end of the IL ends it failing. */
2775 {
2779 ;
2780 else
2782 }
2783 }
2784 /* If we reach a new basic-block see if we already skipped it
2785 in a previous walk that ended successfully. */
2787 {
2791 }
2793 }
2795 }
2798 /* Starting from a PHI node for the virtual operand of the memory reference
2799 REF find a continuation virtual operand that allows to continue walking
2800 statements dominating PHI skipping only statements that cannot possibly
2801 clobber REF. Decrements LIMIT for each alias disambiguation done
2802 and aborts the walk, returning NULL_TREE if it reaches zero.
2803 Returns NULL_TREE if no suitable virtual operand can be found. */
2805 tree
2811 {
2814 /* Through a single-argument PHI we can simply look through. */
2818 /* For two or more arguments try to pairwise skip non-aliasing code
2819 until we hit the phi argument definition that dominates the other one. */
2824 /* Find a candidate for the virtual operand which definition
2825 dominates those of all others. */
2826 /* First look if any of the args themselves satisfy this. */
2828 {
2837 }
2838 /* If not, look if we can reach such candidate by walking defs
2839 until we hit the immediate dominator. maybe_skip_until will
2840 do that for us. */
2843 /* Then check against the (to be) found candidate. */
2845 {
2848 ;
2850 abort_on_visited,
2851 /* Do not translate when walking over
2852 backedges. */
2853 dominated_by_p
2856 phi_bb)
2859 }
2862 }
2864 /* Based on the memory reference REF and its virtual use VUSE call
2865 WALKER for each virtual use that is equivalent to VUSE, including VUSE
2866 itself. That is, for each virtual use for which its defining statement
2867 does not clobber REF.
2869 WALKER is called with REF, the current virtual use and DATA. If
2870 WALKER returns non-NULL the walk stops and its result is returned.
2871 At the end of a non-successful walk NULL is returned.
2873 TRANSLATE if non-NULL is called with a pointer to REF, the virtual
2874 use which definition is a statement that may clobber REF and DATA.
2875 If TRANSLATE returns (void *)-1 the walk stops and NULL is returned.
2876 If TRANSLATE returns non-NULL the walk stops and its result is returned.
2877 If TRANSLATE returns NULL the walk continues and TRANSLATE is supposed
2878 to adjust REF and *DATA to make that valid.
2880 VALUEIZE if non-NULL is called with the next VUSE that is considered
2881 and return value is substituted for that. This can be used to
2882 implement optimistic value-numbering for example. Note that the
2883 VUSE argument is assumed to be valueized already.
2885 LIMIT specifies the number of alias queries we are allowed to do,
2886 the walk stops when it reaches zero and NULL is returned. LIMIT
2887 is decremented by the number of alias queries (plus adjustments
2888 done by the callbacks) upon return.
2890 TODO: Cache the vector of equivalent vuses per ref, vuse pair. */
2898 {
2905 do
2906 {
2909 /* ??? Do we want to account this to TV_ALIAS_STMT_WALK? */
2911 /* Abort walk. */
2913 {
2916 }
2917 /* Lookup succeeded. */
2922 {
2925 {
2928 }
2929 }
2936 else
2937 {
2939 {
2942 }
2944 {
2949 /* Failed lookup and translation. */
2951 {
2954 }
2955 /* Lookup succeeded. */
2958 /* Translation succeeded, continue walking. */
2960 }
2962 }
2963 }
2972 }
2975 /* Based on the memory reference REF call WALKER for each vdef which
2976 defining statement may clobber REF, starting with VDEF. If REF
2977 is NULL_TREE, each defining statement is visited.
2979 WALKER is called with REF, the current vdef and DATA. If WALKER
2980 returns true the walk is stopped, otherwise it continues.
2982 If function entry is reached, FUNCTION_ENTRY_REACHED is set to true.
2983 The pointer may be NULL and then we do not track this information.
2985 At PHI nodes walk_aliased_vdefs forks into one walk for reach
2986 PHI argument (but only one walk continues on merge points), the
2987 return value is true if any of the walks was successful.
2989 The function returns the number of statements walked or -1 if
2990 LIMIT stmts were walked and the walk was aborted at this point.
2991 If LIMIT is zero the walk is not aborted. */
2993 static int
2998 {
2999 do
3000 {
3008 {
3012 }
3014 {
3019 {
3027 }
3029 }
3031 /* ??? Do we want to account this to TV_ALIAS_STMT_WALK? */
3032 cnt++;
3041 }
3043 }
3045 int
3050 {
3068 }