| blob | 4b32fcb027b1b3b47b9811b72563a36b842ab941 |
1 /* Alias analysis for GNU C
2 Copyright (C) 1997-2014 Free Software Foundation, Inc.
3 Contributed by John Carr (jfc@mit.edu).
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/>. */
52 /* The aliasing API provided here solves related but different problems:
54 Say there exists (in c)
56 struct X {
57 struct Y y1;
58 struct Z z2;
59 } x1, *px1, *px2;
61 struct Y y2, *py;
62 struct Z z2, *pz;
65 py = &x1.y1;
66 px2 = &x1;
68 Consider the four questions:
70 Can a store to x1 interfere with px2->y1?
71 Can a store to x1 interfere with px2->z2?
72 Can a store to x1 change the value pointed to by with py?
73 Can a store to x1 change the value pointed to by with pz?
75 The answer to these questions can be yes, yes, yes, and maybe.
77 The first two questions can be answered with a simple examination
78 of the type system. If structure X contains a field of type Y then
79 a store through a pointer to an X can overwrite any field that is
80 contained (recursively) in an X (unless we know that px1 != px2).
82 The last two questions can be solved in the same way as the first
83 two questions but this is too conservative. The observation is
84 that in some cases we can know which (if any) fields are addressed
85 and if those addresses are used in bad ways. This analysis may be
86 language specific. In C, arbitrary operations may be applied to
87 pointers. However, there is some indication that this may be too
88 conservative for some C++ types.
90 The pass ipa-type-escape does this analysis for the types whose
91 instances do not escape across the compilation boundary.
93 Historically in GCC, these two problems were combined and a single
94 data structure that was used to represent the solution to these
95 problems. We now have two similar but different data structures,
96 The data structure to solve the last two questions is similar to
97 the first, but does not contain the fields whose address are never
98 taken. For types that do escape the compilation unit, the data
99 structures will have identical information.
100 */
102 /* The alias sets assigned to MEMs assist the back-end in determining
103 which MEMs can alias which other MEMs. In general, two MEMs in
104 different alias sets cannot alias each other, with one important
105 exception. Consider something like:
107 struct S { int i; double d; };
109 a store to an `S' can alias something of either type `int' or type
110 `double'. (However, a store to an `int' cannot alias a `double'
111 and vice versa.) We indicate this via a tree structure that looks
112 like:
113 struct S
114 / \
115 / \
116 |/_ _\|
117 int double
119 (The arrows are directed and point downwards.)
120 In this situation we say the alias set for `struct S' is the
121 `superset' and that those for `int' and `double' are `subsets'.
123 To see whether two alias sets can point to the same memory, we must
124 see if either alias set is a subset of the other. We need not trace
125 past immediate descendants, however, since we propagate all
126 grandchildren up one level.
128 Alias set zero is implicitly a superset of all other alias sets.
129 However, this is no actual entry for alias set zero. It is an
130 error to attempt to explicitly construct a subset of zero. */
133 /* The alias set number, as stored in MEM_ALIAS_SET. */
134 alias_set_type alias_set;
136 /* Nonzero if would have a child of zero: this effectively makes this
137 alias set the same as alias set zero. */
140 /* The children of the alias set. These are not just the immediate
141 children, but, in fact, all descendants. So, if we have:
143 struct T { struct S s; float f; }
145 continuing our example above, the children here will be all of
146 `int', `double', `float', and `struct S'. */
148 };
168 /* Set up all info needed to perform alias analysis on memory references. */
170 /* Returns the size in bytes of the mode of X. */
171 #define SIZE_FOR_MODE(X) (GET_MODE_SIZE (GET_MODE (X)))
173 /* Cap the number of passes we make over the insns propagating alias
174 information through set chains.
175 ??? 10 is a completely arbitrary choice. This should be based on the
176 maximum loop depth in the CFG, but we do not have this information
177 available (even if current_loops _is_ available). */
178 #define MAX_ALIAS_LOOP_PASSES 10
180 /* reg_base_value[N] gives an address to which register N is related.
181 If all sets after the first add or subtract to the current value
182 or otherwise modify it so it does not point to a different top level
183 object, reg_base_value[N] is equal to the address part of the source
184 of the first set.
186 A base address can be an ADDRESS, SYMBOL_REF, or LABEL_REF. ADDRESS
187 expressions represent three types of base:
189 1. incoming arguments. There is just one ADDRESS to represent all
190 arguments, since we do not know at this level whether accesses
191 based on different arguments can alias. The ADDRESS has id 0.
193 2. stack_pointer_rtx, frame_pointer_rtx, hard_frame_pointer_rtx
194 (if distinct from frame_pointer_rtx) and arg_pointer_rtx.
195 Each of these rtxes has a separate ADDRESS associated with it,
196 each with a negative id.
198 GCC is (and is required to be) precise in which register it
199 chooses to access a particular region of stack. We can therefore
200 assume that accesses based on one of these rtxes do not alias
201 accesses based on another of these rtxes.
203 3. bases that are derived from malloc()ed memory (REG_NOALIAS).
204 Each such piece of memory has a separate ADDRESS associated
205 with it, each with an id greater than 0.
207 Accesses based on one ADDRESS do not alias accesses based on other
208 ADDRESSes. Accesses based on ADDRESSes in groups (2) and (3) do not
209 alias globals either; the ADDRESSes have Pmode to indicate this.
210 The ADDRESS in group (1) _may_ alias globals; it has VOIDmode to
211 indicate this. */
216 /* The single VOIDmode ADDRESS that represents all argument bases.
217 It has id 0. */
220 /* Used to allocate unique ids to each REG_NOALIAS ADDRESS. */
223 /* We preserve the copy of old array around to avoid amount of garbage
224 produced. About 8% of garbage produced were attributed to this
225 array. */
228 /* Values of XINT (address, 0) of Pmode ADDRESS rtxes for special
229 registers. */
230 #define UNIQUE_BASE_VALUE_SP -1
231 #define UNIQUE_BASE_VALUE_ARGP -2
232 #define UNIQUE_BASE_VALUE_FP -3
233 #define UNIQUE_BASE_VALUE_HFP -4
235 #define static_reg_base_value \
236 (this_target_rtl->x_static_reg_base_value)
238 #define REG_BASE_VALUE(X) \
239 (REGNO (X) < vec_safe_length (reg_base_value) \
240 ? (*reg_base_value)[REGNO (X)] : 0)
242 /* Vector indexed by N giving the initial (unchanging) value known for
243 pseudo-register N. This vector is initialized in init_alias_analysis,
244 and does not change until end_alias_analysis is called. */
247 /* Vector recording for each reg_known_value whether it is due to a
248 REG_EQUIV note. Future passes (viz., reload) may replace the
249 pseudo with the equivalent expression and so we account for the
250 dependences that would be introduced if that happens.
252 The REG_EQUIV notes created in assign_parms may mention the arg
253 pointer, and there are explicit insns in the RTL that modify the
254 arg pointer. Thus we must ensure that such insns don't get
255 scheduled across each other because that would invalidate the
256 REG_EQUIV notes. One could argue that the REG_EQUIV notes are
257 wrong, but solving the problem in the scheduler will likely give
258 better code, so we do it here. */
261 /* True when scanning insns from the start of the rtl to the
262 NOTE_INSN_FUNCTION_BEG note. */
266 /* The splay-tree used to store the various alias set entries. */
268 \f
269 /* Build a decomposed reference object for querying the alias-oracle
270 from the MEM rtx and store it in *REF.
271 Returns false if MEM is not suitable for the alias-oracle. */
273 static bool
275 {
277 tree base;
284 /* Get the base of the reference and see if we have to reject or
285 adjust it. */
290 /* The tree oracle doesn't like bases that are neither decls
291 nor indirect references of SSA names. */
299 /* If this is a reference based on a partitioned decl replace the
300 base with a MEM_REF of the pointer representative we
301 created during stack slot partitioning. */
305 {
310 }
314 /* If MEM_OFFSET or MEM_SIZE are unknown what we got from MEM_EXPR
315 is conservative, so trust it. */
320 /* If the base decl is a parameter we can have negative MEM_OFFSET in
321 case of promoted subregs on bigendian targets. Trust the MEM_EXPR
322 here. */
327 /* Otherwise continue and refine size and offset we got from analyzing
328 MEM_EXPR by using MEM_SIZE and MEM_OFFSET. */
333 /* The MEM may extend into adjacent fields, so adjust max_size if
334 necessary. */
339 /* If MEM_OFFSET and MEM_SIZE get us outside of the base object of
340 the MEM_EXPR punt. This happens for STRICT_ALIGNMENT targets a lot. */
350 }
352 /* Query the alias-oracle on whether the two memory rtx X and MEM may
353 alias. If TBAA_P is set also apply TBAA. Returns true if the
354 two rtxen may alias, false otherwise. */
356 static bool
358 {
366 tbaa_p
369 }
371 /* Returns a pointer to the alias set entry for ALIAS_SET, if there is
372 such an entry, or NULL otherwise. */
376 {
378 }
380 /* Returns nonzero if the alias sets for MEM1 and MEM2 are such that
381 the two MEMs cannot alias each other. */
385 {
386 /* Perform a basic sanity check. Namely, that there are no alias sets
387 if we're not using strict aliasing. This helps to catch bugs
388 whereby someone uses PUT_CODE, but doesn't clear MEM_ALIAS_SET, or
389 where a MEM is allocated in some way other than by the use of
390 gen_rtx_MEM, and the MEM_ALIAS_SET is not cleared. If we begin to
391 use alias sets to indicate that spilled registers cannot alias each
392 other, we might need to remove this check. */
397 }
399 /* Insert the NODE into the splay tree given by DATA. Used by
400 record_alias_subset via splay_tree_foreach. */
402 static int
404 {
408 }
410 /* Return true if the first alias set is a subset of the second. */
412 bool
414 {
415 alias_set_entry ase;
417 /* Everything is a subset of the "aliases everything" set. */
421 /* Otherwise, check if set1 is a subset of set2. */
429 }
431 /* Return 1 if the two specified alias sets may conflict. */
433 int
435 {
436 alias_set_entry ase;
438 /* The easy case. */
442 /* See if the first alias set is a subset of the second. */
450 /* Now do the same, but with the alias sets reversed. */
458 /* The two alias sets are distinct and neither one is the
459 child of the other. Therefore, they cannot conflict. */
461 }
463 /* Return 1 if the two specified alias sets will always conflict. */
465 int
467 {
472 }
474 /* Return 1 if any MEM object of type T1 will always conflict (using the
475 dependency routines in this file) with any MEM object of type T2.
476 This is used when allocating temporary storage. If T1 and/or T2 are
477 NULL_TREE, it means we know nothing about the storage. */
479 int
481 {
484 /* If neither has a type specified, we don't know if they'll conflict
485 because we may be using them to store objects of various types, for
486 example the argument and local variables areas of inlined functions. */
490 /* If they are the same type, they must conflict. */
492 /* Likewise if both are volatile. */
499 /* We can't use alias_sets_conflict_p because we must make sure
500 that every subtype of t1 will conflict with every subtype of
501 t2 for which a pair of subobjects of these respective subtypes
502 overlaps on the stack. */
504 }
505 \f
506 /* Return the outermost parent of component present in the chain of
507 component references handled by get_inner_reference in T with the
508 following property:
509 - the component is non-addressable, or
510 - the parent has alias set zero,
511 or NULL_TREE if no such parent exists. In the former cases, the alias
512 set of this parent is the alias set that must be used for T itself. */
514 tree
516 {
520 {
522 {
540 /* Bitfields and casts are never addressable. */
546 }
552 }
558 }
561 /* Return whether the pointer-type T effective for aliasing may
562 access everything and thus the reference has to be assigned
563 alias-set zero. */
565 static bool
567 {
570 }
572 /* Return the alias set for the memory pointed to by T, which may be
573 either a type or an expression. Return -1 if there is nothing
574 special about dereferencing T. */
576 static alias_set_type
578 {
579 /* All we care about is the type. */
583 /* If we have an INDIRECT_REF via a void pointer, we don't
584 know anything about what that might alias. Likewise if the
585 pointer is marked that way. */
590 }
592 /* Return the alias set for the memory pointed to by T, which may be
593 either a type or an expression. */
595 alias_set_type
597 {
598 /* If we're not doing any alias analysis, just assume everything
599 aliases everything else. */
605 /* Fall back to the alias-set of the pointed-to type. */
607 {
611 }
614 }
616 /* Return the pointer-type relevant for TBAA purposes from the
617 memory reference tree *T or NULL_TREE in which case *T is
618 adjusted to point to the outermost component reference that
619 can be used for assigning an alias set. */
621 static tree
623 {
624 tree inner;
626 /* Get the base object of the reference. */
629 {
630 /* If there is a VIEW_CONVERT_EXPR in the chain we cannot use
631 the type of any component references that wrap it to
632 determine the alias-set. */
636 }
638 /* Handle pointer dereferences here, they can override the
639 alias-set. */
649 /* If the innermost reference is a MEM_REF that has a
650 conversion embedded treat it like a VIEW_CONVERT_EXPR above,
651 using the memory access type for determining the alias-set. */
654 != TYPE_MAIN_VARIANT
658 /* Otherwise, pick up the outermost object that we could have
659 a pointer to. */
665 }
667 /* Return the pointer-type relevant for TBAA purposes from the
668 gimple memory reference tree T. This is the type to be used for
669 the offset operand of MEM_REF or TARGET_MEM_REF replacements of T
670 and guarantees that get_alias_set will return the same alias
671 set for T and the replacement. */
673 tree
675 {
677 /* If there is a given pointer type for aliasing purposes, return it. */
681 /* Otherwise build one from the outermost component reference we
682 may use. */
686 else
688 }
690 /* Return whether the pointer-types T1 and T2 used to determine
691 two alias sets of two references will yield the same answer
692 from get_deref_alias_set. */
694 bool
696 {
706 }
708 /* Return the alias set for T, which may be either a type or an
709 expression. Call language-specific routine for help, if needed. */
711 alias_set_type
713 {
714 alias_set_type set;
716 /* If we're not doing any alias analysis, just assume everything
717 aliases everything else. Also return 0 if this or its type is
718 an error. */
724 /* We can be passed either an expression or a type. This and the
725 language-specific routine may make mutually-recursive calls to each other
726 to figure out what to do. At each juncture, we see if this is a tree
727 that the language may need to handle specially. First handle things that
728 aren't types. */
730 {
731 /* Give the language a chance to do something with this tree
732 before we look at it. */
738 /* Get the alias pointer-type to use or the outermost object
739 that we could have a pointer to. */
744 /* If we've already determined the alias set for a decl, just return
745 it. This is necessary for C++ anonymous unions, whose component
746 variables don't look like union members (boo!). */
751 /* Now all we care about is the type. */
753 }
755 /* Variant qualifiers don't affect the alias set, so get the main
756 variant. */
759 /* Always use the canonical type as well. If this is a type that
760 requires structural comparisons to identify compatible types
761 use alias set zero. */
763 {
764 /* Allow the language to specify another alias set for this
765 type. */
770 }
774 /* The canonical type should not require structural equality checks. */
777 /* If this is a type with a known alias set, return it. */
781 /* We don't want to set TYPE_ALIAS_SET for incomplete types. */
783 {
784 /* For arrays with unknown size the conservative answer is the
785 alias set of the element type. */
789 /* But return zero as a conservative answer for incomplete types. */
791 }
793 /* See if the language has special handling for this type. */
798 /* There are no objects of FUNCTION_TYPE, so there's no point in
799 using up an alias set for them. (There are, of course, pointers
800 and references to functions, but that's different.) */
804 /* Unless the language specifies otherwise, let vector types alias
805 their components. This avoids some nasty type punning issues in
806 normal usage. And indeed lets vectors be treated more like an
807 array slice. */
811 /* Unless the language specifies otherwise, treat array types the
812 same as their components. This avoids the asymmetry we get
813 through recording the components. Consider accessing a
814 character(kind=1) through a reference to a character(kind=1)[1:1].
815 Or consider if we want to assign integer(kind=4)[0:D.1387] and
816 integer(kind=4)[4] the same alias set or not.
817 Just be pragmatic here and make sure the array and its element
818 type get the same alias set assigned. */
822 /* From the former common C and C++ langhook implementation:
824 Unfortunately, there is no canonical form of a pointer type.
825 In particular, if we have `typedef int I', then `int *', and
826 `I *' are different types. So, we have to pick a canonical
827 representative. We do this below.
829 Technically, this approach is actually more conservative that
830 it needs to be. In particular, `const int *' and `int *'
831 should be in different alias sets, according to the C and C++
832 standard, since their types are not the same, and so,
833 technically, an `int **' and `const int **' cannot point at
834 the same thing.
836 But, the standard is wrong. In particular, this code is
837 legal C++:
839 int *ip;
840 int **ipp = &ip;
841 const int* const* cipp = ipp;
842 And, it doesn't make sense for that to be legal unless you
843 can dereference IPP and CIPP. So, we ignore cv-qualifiers on
844 the pointed-to types. This issue has been reported to the
845 C++ committee.
847 In addition to the above canonicalization issue, with LTO
848 we should also canonicalize `T (*)[]' to `T *' avoiding
849 alias issues with pointer-to element types and pointer-to
850 array types.
852 Likewise we need to deal with the situation of incomplete
853 pointed-to types and make `*(struct X **)&a' and
854 `*(struct X {} **)&a' alias. Otherwise we will have to
855 guarantee that all pointer-to incomplete type variants
856 will be replaced by pointer-to complete type variants if
857 they are available.
859 With LTO the convenient situation of using `void *' to
860 access and store any pointer type will also become
861 more apparent (and `void *' is just another pointer-to
862 incomplete type). Assigning alias-set zero to `void *'
863 and all pointer-to incomplete types is a not appealing
864 solution. Assigning an effective alias-set zero only
865 affecting pointers might be - by recording proper subset
866 relationships of all pointer alias-sets.
868 Pointer-to function types are another grey area which
869 needs caution. Globbing them all into one alias-set
870 or the above effective zero set would work.
872 For now just assign the same alias-set to all pointers.
873 That's simple and avoids all the above problems. */
878 /* Otherwise make a new alias set for this type. */
879 else
880 {
881 /* Each canonical type gets its own alias set, so canonical types
882 shouldn't form a tree. It doesn't really matter for types
883 we handle specially above, so only check it where it possibly
884 would result in a bogus alias set. */
888 }
892 /* If this is an aggregate type or a complex type, we must record any
893 component aliasing information. */
898 }
900 /* Return a brand-new alias set. */
902 alias_set_type
904 {
906 {
911 }
912 else
914 }
916 /* Indicate that things in SUBSET can alias things in SUPERSET, but that
917 not everything that aliases SUPERSET also aliases SUBSET. For example,
918 in C, a store to an `int' can alias a load of a structure containing an
919 `int', and vice versa. But it can't alias a load of a 'double' member
920 of the same structure. Here, the structure would be the SUPERSET and
921 `int' the SUBSET. This relationship is also described in the comment at
922 the beginning of this file.
924 This function should be called only once per SUPERSET/SUBSET pair.
926 It is illegal for SUPERSET to be zero; everything is implicitly a
927 subset of alias set zero. */
929 void
931 {
932 alias_set_entry superset_entry;
933 alias_set_entry subset_entry;
935 /* It is possible in complex type situations for both sets to be the same,
936 in which case we can ignore this operation. */
944 {
945 /* Create an entry for the SUPERSET, so that we have a place to
946 attach the SUBSET. */
949 superset_entry->children
951 ggc_alloc_splay_tree_scalar_scalar_splay_tree_s,
952 ggc_alloc_splay_tree_scalar_scalar_splay_tree_node_s);
955 }
959 else
960 {
962 /* If there is an entry for the subset, enter all of its children
963 (if they are not already present) as children of the SUPERSET. */
965 {
971 }
973 /* Enter the SUBSET itself as a child of the SUPERSET. */
976 }
977 }
979 /* Record that component types of TYPE, if any, are part of that type for
980 aliasing purposes. For record types, we only record component types
981 for fields that are not marked non-addressable. For array types, we
982 only record the component type if it is not marked non-aliased. */
984 void
986 {
988 tree field;
994 {
1007 /* VECTOR_TYPE and ARRAY_TYPE share the alias set with their
1008 element type. */
1012 }
1013 }
1015 /* Allocate an alias set for use in storing and reading from the varargs
1016 spill area. */
1020 alias_set_type
1022 {
1023 #if 1
1024 /* We now lower VA_ARG_EXPR, and there's currently no way to attach the
1025 varargs alias set to an INDIRECT_REF (FIXME!), so we can't
1026 consistently use the varargs alias set for loads from the varargs
1027 area. So don't use it anywhere. */
1029 #else
1034 #endif
1035 }
1037 /* Likewise, but used for the fixed portions of the frame, e.g., register
1038 save areas. */
1042 alias_set_type
1044 {
1049 }
1051 /* Create a new, unique base with id ID. */
1053 static rtx
1055 {
1057 }
1059 /* Return true if accesses based on any other base value cannot alias
1060 those based on X. */
1062 static bool
1064 {
1066 }
1068 /* Return true if X is known to be a base value. */
1070 static bool
1072 {
1074 {
1080 /* Arguments may or may not be bases; we don't know for sure. */
1085 }
1086 }
1088 /* Inside SRC, the source of a SET, find a base address. */
1090 static rtx
1092 {
1095 #if defined (FIND_BASE_TERM)
1096 /* Try machine-dependent ways to find the base term. */
1098 #endif
1101 {
1108 /* At the start of a function, argument registers have known base
1109 values which may be lost later. Returning an ADDRESS
1110 expression here allows optimization based on argument values
1111 even when the argument registers are used for other purposes. */
1115 /* If a pseudo has a known base value, return it. Do not do this
1116 for non-fixed hard regs since it can result in a circular
1117 dependency chain for registers which have values at function entry.
1119 The test above is not sufficient because the scheduler may move
1120 a copy out of an arg reg past the NOTE_INSN_FUNCTION_BEGIN. */
1123 {
1124 /* If we're inside init_alias_analysis, use new_reg_base_value
1125 to reduce the number of relaxation iterations. */
1132 }
1137 /* Check for an argument passed in memory. Only record in the
1138 copying-arguments block; it is too hard to track changes
1139 otherwise. */
1152 /* ... fall through ... */
1156 {
1159 /* If either operand is a REG that is a known pointer, then it
1160 is the base. */
1166 /* If either operand is a REG, then see if we already have
1167 a known value for it. */
1169 {
1173 }
1176 {
1180 }
1182 /* If either base is named object or a special address
1183 (like an argument or stack reference), then use it for the
1184 base term. */
1191 /* Guess which operand is the base address:
1192 If either operand is a symbol, then it is the base. If
1193 either operand is a CONST_INT, then the other is the base. */
1200 }
1203 /* The standard form is (lo_sum reg sym) so look only at the
1204 second operand. */
1208 /* If the second operand is constant set the base
1209 address to the first operand. */
1215 /* As we do not know which address space the pointer is referring to, we can
1216 handle this only if the target does not support different pointer or
1217 address modes depending on the address space. */
1222 /* Fall through. */
1234 /* As we do not know which address space the pointer is referring to, we can
1235 handle this only if the target does not support different pointer or
1236 address modes depending on the address space. */
1240 {
1247 }
1251 }
1254 }
1256 /* Called from init_alias_analysis indirectly through note_stores,
1257 or directly if DEST is a register with a REG_NOALIAS note attached.
1258 SET is null in the latter case. */
1260 /* While scanning insns to find base values, reg_seen[N] is nonzero if
1261 register N has been set in this function. */
1264 static void
1266 {
1268 rtx src;
1278 /* If this spans multiple hard registers, then we must indicate that every
1279 register has an unusable value. */
1282 else
1285 {
1287 {
1290 }
1292 }
1295 {
1296 /* A CLOBBER wipes out any old value but does not prevent a previously
1297 unset register from acquiring a base address (i.e. reg_seen is not
1298 set). */
1300 {
1303 }
1305 }
1306 else
1307 {
1308 /* There's a REG_NOALIAS note against DEST. */
1310 {
1313 }
1317 }
1319 /* If this is not the first set of REGNO, see whether the new value
1320 is related to the old one. There are two cases of interest:
1322 (1) The register might be assigned an entirely new value
1323 that has the same base term as the original set.
1325 (2) The set might be a simple self-modification that
1326 cannot change REGNO's base value.
1328 If neither case holds, reject the original base value as invalid.
1329 Note that the following situation is not detected:
1331 extern int x, y; int *p = &x; p += (&y-&x);
1333 ANSI C does not allow computing the difference of addresses
1334 of distinct top level objects. */
1338 {
1345 /* If the value we add in the PLUS is also a valid base value,
1346 this might be the actual base value, and the original value
1347 an index. */
1348 {
1359 }
1367 }
1368 /* If this is the first set of a register, record the value. */
1374 }
1376 /* Return REG_BASE_VALUE for REGNO. Selective scheduler uses this to avoid
1377 using hard registers with non-null REG_BASE_VALUE for renaming. */
1378 rtx
1380 {
1382 }
1384 /* If a value is known for REGNO, return it. */
1386 rtx
1388 {
1390 {
1394 }
1396 }
1398 /* Set it. */
1400 static void
1402 {
1404 {
1408 }
1409 }
1411 /* Similarly for reg_known_equiv_p. */
1413 bool
1415 {
1417 {
1421 }
1423 }
1425 static void
1427 {
1429 {
1432 {
1435 else
1437 }
1438 }
1439 }
1442 /* Returns a canonical version of X, from the point of view alias
1443 analysis. (For example, if X is a MEM whose address is a register,
1444 and the register has a known value (say a SYMBOL_REF), then a MEM
1445 whose address is the SYMBOL_REF is returned.) */
1447 rtx
1449 {
1450 /* Recursively look for equivalences. */
1452 {
1458 }
1461 {
1466 {
1472 }
1473 }
1475 /* This gives us much better alias analysis when called from
1476 the loop optimizer. Note we want to leave the original
1477 MEM alone, but need to return the canonicalized MEM with
1478 all the flags with their original values. */
1483 }
1485 /* Return 1 if X and Y are identical-looking rtx's.
1486 Expect that X and Y has been already canonicalized.
1488 We use the data in reg_known_value above to see if two registers with
1489 different numbers are, in fact, equivalent. */
1491 static int
1493 {
1508 /* Rtx's of different codes cannot be equal. */
1512 /* (MULT:SI x y) and (MULT:HI x y) are NOT equivalent.
1513 (REG:SI x) and (REG:HI x) are NOT equivalent. */
1518 /* Some RTL can be compared without a recursive examination. */
1520 {
1531 /* This is magic, don't go through canonicalization et al. */
1535 CASE_CONST_UNIQUE:
1536 /* There's no need to compare the contents of CONST_DOUBLEs or
1537 CONST_INTs because pointer equality is a good enough
1538 comparison for these nodes. */
1543 }
1545 /* canon_rtx knows how to handle plus. No need to canonicalize. */
1551 /* For commutative operations, the RTX match if the operand match in any
1552 order. Also handle the simple binary and unary cases without a loop. */
1554 {
1563 }
1565 {
1570 }
1575 /* Compare the elements. If any pair of corresponding elements
1576 fail to match, return 0 for the whole things.
1578 Limit cases to types which actually appear in addresses. */
1582 {
1584 {
1591 /* Two vectors must have the same length. */
1595 /* And the corresponding elements must match. */
1608 /* This can happen for asm operands. */
1614 /* This can happen for an asm which clobbers memory. */
1618 /* It is believed that rtx's at this level will never
1619 contain anything but integers and other rtx's,
1620 except for within LABEL_REFs and SYMBOL_REFs. */
1623 }
1624 }
1626 }
1628 static rtx
1630 {
1633 rtx ret;
1635 #if defined (FIND_BASE_TERM)
1636 /* Try machine-dependent ways to find the base term. */
1638 #endif
1641 {
1646 /* As we do not know which address space the pointer is referring to, we can
1647 handle this only if the target does not support different pointer or
1648 address modes depending on the address space. */
1653 /* Fall through. */
1665 /* As we do not know which address space the pointer is referring to, we can
1666 handle this only if the target does not support different pointer or
1667 address modes depending on the address space. */
1671 {
1678 }
1691 /* Temporarily reset val->locs to avoid infinite recursion. */
1707 /* The standard form is (lo_sum reg sym) so look only at the
1708 second operand. */
1715 /* Fall through. */
1718 {
1722 /* This is a little bit tricky since we have to determine which of
1723 the two operands represents the real base address. Otherwise this
1724 routine may return the index register instead of the base register.
1726 That may cause us to believe no aliasing was possible, when in
1727 fact aliasing is possible.
1729 We use a few simple tests to guess the base register. Additional
1730 tests can certainly be added. For example, if one of the operands
1731 is a shift or multiply, then it must be the index register and the
1732 other operand is the base register. */
1737 /* If either operand is known to be a pointer, then prefer it
1738 to determine the base term. */
1740 ;
1742 {
1746 }
1748 /* Go ahead and find the base term for both operands. If either base
1749 term is from a pointer or is a named object or a special address
1750 (like an argument or stack reference), then use it for the
1751 base term. */
1763 /* We could not determine which of the two operands was the
1764 base register and which was the index. So we can determine
1765 nothing from the base alias check. */
1767 }
1780 }
1781 }
1783 /* Return true if accesses to address X may alias accesses based
1784 on the stack pointer. */
1786 bool
1788 {
1791 }
1793 /* Return 0 if the addresses X and Y are known to point to different
1794 objects, 1 if they might be pointers to the same object. */
1796 static int
1799 {
1800 /* If the address itself has no known base see if a known equivalent
1801 value has one. If either address still has no known base, nothing
1802 is known about aliasing. */
1804 {
1805 rtx x_c;
1813 }
1816 {
1817 rtx y_c;
1824 }
1826 /* If the base addresses are equal nothing is known about aliasing. */
1830 /* The base addresses are different expressions. If they are not accessed
1831 via AND, there is no conflict. We can bring knowledge of object
1832 alignment into play here. For example, on alpha, "char a, b;" can
1833 alias one another, though "char a; long b;" cannot. AND addesses may
1834 implicitly alias surrounding objects; i.e. unaligned access in DImode
1835 via AND address can alias all surrounding object types except those
1836 with aligment 8 or higher. */
1848 /* Differing symbols not accessed via AND never alias. */
1856 }
1858 /* Callback for for_each_rtx, that returns 1 upon encountering a VALUE
1859 whose UID is greater than the int uid that D points to. */
1861 static int
1863 {
1868 }
1870 /* Return TRUE if EXPR refers to a VALUE whose uid is greater than
1871 that of V. */
1873 static bool
1875 {
1879 }
1881 /* Convert the address X into something we can use. This is done by returning
1882 it unchanged unless it is a value; in the latter case we call cselib to get
1883 a more useful rtx. */
1885 rtx
1887 {
1895 {
1904 /* Avoid infinite recursion when potentially dealing with
1905 var-tracking artificial equivalences, by skipping the
1906 equivalences themselves, and not choosing expressions
1907 that refer to newer VALUEs. */
1908 && (!have_equivs
1913 {
1919 /* Return the canonical value. */
1921 }
1924 }
1926 }
1928 /* Return the address of the (N_REFS + 1)th memory reference to ADDR
1929 where SIZE is the size in bytes of the memory reference. If ADDR
1930 is not modified by the memory reference then ADDR is returned. */
1932 static rtx
1934 {
1938 {
1954 }
1959 else
1964 }
1966 /* Return TRUE if an object X sized at XSIZE bytes and another object
1967 Y sized at YSIZE bytes, starting C bytes after X, may overlap. If
1968 any of the sizes is zero, assume an overlap, otherwise use the
1969 absolute value of the sizes as the actual sizes. */
1973 {
1978 }
1980 /* Return one if X and Y (memory addresses) reference the
1981 same location in memory or if the references overlap.
1982 Return zero if they do not overlap, else return
1983 minus one in which case they still might reference the same location.
1985 C is an offset accumulator. When
1986 C is nonzero, we are testing aliases between X and Y + C.
1987 XSIZE is the size in bytes of the X reference,
1988 similarly YSIZE is the size in bytes for Y.
1989 Expect that canon_rtx has been already called for X and Y.
1991 If XSIZE or YSIZE is zero, we do not know the amount of memory being
1992 referenced (the reference was BLKmode), so make the most pessimistic
1993 assumptions.
1995 If XSIZE or YSIZE is negative, we may access memory outside the object
1996 being referenced as a side effect. This can happen when using AND to
1997 align memory references, as is done on the Alpha.
1999 Nice to notice that varying addresses cannot conflict with fp if no
2000 local variables had their addresses taken, but that's too hard now.
2002 ??? Contrary to the tree alias oracle this does not return
2003 one for X + non-constant and Y + non-constant when X and Y are equal.
2004 If that is fixed the TBAA hack for union type-punning can be removed. */
2006 static int
2008 {
2010 {
2012 {
2021 else
2023 }
2024 /* Don't call get_addr if y is the same VALUE. */
2027 }
2029 {
2031 {
2040 else
2042 }
2043 /* Don't call get_addr if x is the same VALUE. */
2046 }
2051 else
2057 else
2061 {
2063 }
2065 /* This code used to check for conflicts involving stack references and
2066 globals but the base address alias code now handles these cases. */
2069 {
2070 /* The fact that X is canonicalized means that this
2071 PLUS rtx is canonicalized. */
2076 {
2077 /* The fact that Y is canonicalized means that this
2078 PLUS rtx is canonicalized. */
2087 {
2091 else
2094 }
2099 }
2102 }
2104 {
2105 /* The fact that Y is canonicalized means that this
2106 PLUS rtx is canonicalized. */
2112 else
2114 }
2118 {
2120 {
2121 /* Handle cases where we expect the second operands to be the
2122 same, and check only whether the first operand would conflict
2123 or not. */
2134 /* Can't properly adjust our sizes. */
2141 }
2145 }
2147 /* Deal with alignment ANDs by adjusting offset and size so as to
2148 cover the maximum range, without taking any previously known
2149 alignment into account. Make a size negative after such an
2150 adjustments, so that, if we end up with e.g. two SYMBOL_REFs, we
2151 assume a potential overlap, because they may end up in contiguous
2152 memory locations and the stricter-alignment access may span over
2153 part of both. */
2155 {
2159 {
2167 }
2168 }
2170 {
2174 {
2182 }
2183 }
2186 {
2188 {
2191 }
2194 {
2198 else
2201 }
2206 /* Assume a potential overlap for symbolic addresses that went
2207 through alignment adjustments (i.e., that have negative
2208 sizes), because we can't know how far they are from each
2209 other. */
2214 }
2217 }
2219 /* Functions to compute memory dependencies.
2221 Since we process the insns in execution order, we can build tables
2222 to keep track of what registers are fixed (and not aliased), what registers
2223 are varying in known ways, and what registers are varying in unknown
2224 ways.
2226 If both memory references are volatile, then there must always be a
2227 dependence between the two references, since their order can not be
2228 changed. A volatile and non-volatile reference can be interchanged
2229 though.
2231 We also must allow AND addresses, because they may generate accesses
2232 outside the object being referenced. This is used to generate aligned
2233 addresses from unaligned addresses, for instance, the alpha
2234 storeqi_unaligned pattern. */
2236 /* Read dependence: X is read after read in MEM takes place. There can
2237 only be a dependence here if both reads are volatile, or if either is
2238 an explicit barrier. */
2240 int
2242 {
2249 }
2251 /* qsort compare function to sort FIELD_DECLs after their
2252 DECL_FIELD_CONTEXT TYPE_UID. */
2256 {
2259 unsigned int uid1
2261 unsigned int uid2
2268 }
2270 /* Return true if we can determine that the fields referenced cannot
2271 overlap for any pair of objects. */
2273 static bool
2275 {
2286 {
2292 }
2297 {
2303 }
2307 /* Most common case first. */
2316 {
2318 {
2322 }
2323 }
2324 else
2328 {
2330 {
2334 }
2335 }
2336 else
2340 do
2341 {
2347 {
2348 /* We're left with accessing different fields of a structure,
2349 no possible overlap, unless they are both bitfields. */
2352 }
2354 {
2355 i++;
2358 }
2359 else
2360 {
2361 j++;
2364 }
2365 }
2369 }
2371 /* Look at the bottom of the COMPONENT_REF list for a DECL, and return it. */
2373 static tree
2375 {
2376 do
2377 {
2379 }
2383 }
2385 /* Walk up the COMPONENT_REF list in X and adjust *OFFSET to compensate
2386 for the offset of the field reference. *KNOWN_P says whether the
2387 offset is known. */
2389 static void
2392 {
2395 do
2396 {
2401 {
2404 }
2410 }
2412 }
2414 /* Return nonzero if we can determine the exprs corresponding to memrefs
2415 X and Y and they do not overlap.
2416 If LOOP_VARIANT is set, skip offset-based disambiguation */
2418 int
2420 {
2428 /* Unless both have exprs, we can't tell anything. */
2432 /* For spill-slot accesses make sure we have valid offsets. */
2439 /* If the field reference test failed, look at the DECLs involved. */
2444 {
2450 }
2456 {
2462 }
2467 /* With invalid code we can end up storing into the constant pool.
2468 Bail out to avoid ICEing when creating RTL for this.
2469 See gfortran.dg/lto/20091028-2_0.f90. */
2477 /* If either RTL is not a MEM, it must be a REG or CONCAT, meaning they
2478 can't overlap unless they are the same because we never reuse that part
2479 of the stack frame used for locals for spilled pseudos. */
2484 /* If we have MEMs referring to different address spaces (which can
2485 potentially overlap), we cannot easily tell from the addresses
2486 whether the references overlap. */
2491 /* Get the base and offsets of both decls. If either is a register, we
2492 know both are and are the same, so use that as the base. The only
2493 we can avoid overlap is if we can deduce that they are nonoverlapping
2494 pieces of that decl, which is very rare. */
2503 /* If the bases are different, we know they do not overlap if both
2504 are constants or if one is a constant and the other a pointer into the
2505 stack frame. Otherwise a different base means we can't tell if they
2506 overlap or not. */
2514 /* Offset based disambiguation not appropriate for loop invariant */
2525 /* If we have an offset for either memref, it can update the values computed
2526 above. */
2532 /* If a memref has both a size and an offset, we can use the smaller size.
2533 We can't do this if the offset isn't known because we must view this
2534 memref as being anywhere inside the DECL's MEM. */
2540 /* Put the values of the memref with the lower offset in X's values. */
2542 {
2545 }
2547 /* If we don't know the size of the lower-offset value, we can't tell
2548 if they conflict. Otherwise, we do the test. */
2550 }
2552 /* Helper for true_dependence and canon_true_dependence.
2553 Checks for true dependence: X is read after store in MEM takes place.
2555 If MEM_CANONICALIZED is FALSE, then X_ADDR and MEM_ADDR should be
2556 NULL_RTX, and the canonical addresses of MEM and X are both computed
2557 here. If MEM_CANONICALIZED, then MEM must be already canonicalized.
2559 If X_ADDR is non-NULL, it is used in preference of XEXP (x, 0).
2561 Returns 1 if there is a true dependence, 0 otherwise. */
2563 static int
2566 {
2567 rtx base;
2576 /* (mem:BLK (scratch)) is a special mechanism to conflict with everything.
2577 This is used in epilogue deallocation functions, and in cselib. */
2586 /* Read-only memory is by definition never modified, and therefore can't
2587 conflict with anything. We don't expect to find read-only set on MEM,
2588 but stupid user tricks can produce them, so don't die. */
2592 /* If we have MEMs referring to different address spaces (which can
2593 potentially overlap), we cannot easily tell from the addresses
2594 whether the references overlap. */
2599 {
2603 }
2606 {
2614 {
2618 }
2619 }
2650 }
2652 /* True dependence: X is read after store in MEM takes place. */
2654 int
2656 {
2659 }
2661 /* Canonical true dependence: X is read after store in MEM takes place.
2662 Variant of true_dependence which assumes MEM has already been
2663 canonicalized (hence we no longer do that here).
2664 The mem_addr argument has been added, since true_dependence_1 computed
2665 this value prior to canonicalizing. */
2667 int
2670 {
2673 }
2675 /* Returns nonzero if a write to X might alias a previous read from
2676 (or, if WRITEP is true, a write to) MEM.
2677 If X_CANONCALIZED is true, then X_ADDR is the canonicalized address of X,
2678 and X_MODE the mode for that access.
2679 If MEM_CANONICALIZED is true, MEM is canonicalized. */
2681 static int
2685 {
2686 rtx mem_addr;
2687 rtx base;
2697 /* (mem:BLK (scratch)) is a special mechanism to conflict with everything.
2698 This is used in epilogue deallocation functions. */
2707 /* A read from read-only memory can't conflict with read-write memory. */
2711 /* If we have MEMs referring to different address spaces (which can
2712 potentially overlap), we cannot easily tell from the addresses
2713 whether the references overlap. */
2719 {
2727 {
2731 }
2732 }
2736 && base
2748 {
2751 }
2763 }
2765 /* Anti dependence: X is written after read in MEM takes place. */
2767 int
2769 {
2773 }
2775 /* Likewise, but we already have a canonicalized MEM, and X_ADDR for X.
2776 Also, consider X in X_MODE (which might be from an enclosing
2777 STRICT_LOW_PART / ZERO_EXTRACT).
2778 If MEM_CANONICALIZED is true, MEM is canonicalized. */
2780 int
2783 {
2787 }
2789 /* Output dependence: X is written after store in MEM takes place. */
2791 int
2793 {
2797 }
2798 \f
2801 /* Check whether X may be aliased with MEM. Don't do offset-based
2802 memory disambiguation & TBAA. */
2803 int
2805 {
2811 /* (mem:BLK (scratch)) is a special mechanism to conflict with everything.
2812 This is used in epilogue deallocation functions. */
2821 /* Read-only memory is by definition never modified, and therefore can't
2822 conflict with anything. We don't expect to find read-only set on MEM,
2823 but stupid user tricks can produce them, so don't die. */
2827 /* If we have MEMs referring to different address spaces (which can
2828 potentially overlap), we cannot easily tell from the addresses
2829 whether the references overlap. */
2841 {
2844 }
2858 /* TBAA not valid for loop_invarint */
2860 }
2862 void
2864 {
2873 /* Check whether this register can hold an incoming pointer
2874 argument. FUNCTION_ARG_REGNO_P tests outgoing register
2875 numbers, so translate if necessary due to register windows. */
2886 #if !HARD_FRAME_POINTER_IS_FRAME_POINTER
2889 #endif
2890 }
2892 /* Set MEMORY_MODIFIED when X modifies DATA (that is assumed
2893 to be memory reference. */
2895 static void
2897 {
2899 {
2902 }
2903 }
2906 /* Return true when INSN possibly modify memory contents of MEM
2907 (i.e. address can be modified). */
2908 bool
2910 {
2916 }
2918 /* Return TRUE if the destination of a set is rtx identical to
2919 ITEM. */
2922 {
2925 }
2927 /* Like memory_modified_in_insn_p, but return TRUE if INSN will
2928 *DEFINITELY* modify the memory contents of MEM. */
2929 bool
2931 {
2938 {
2941 {
2946 }
2947 }
2949 }
2951 /* Initialize the aliasing machinery. Initialize the REG_KNOWN_VALUE
2952 array. */
2954 void
2956 {
2971 /* If we have memory allocated from the previous run, use it. */
2983 /* The basic idea is that each pass through this loop will use the
2984 "constant" information from the previous pass to propagate alias
2985 information through another level of assignments.
2987 The propagation is done on the CFG in reverse post-order, to propagate
2988 things forward as far as possible in each iteration.
2990 This could get expensive if the assignment chains are long. Maybe
2991 we should throttle the number of iterations, possibly based on
2992 the optimization level or flag_expensive_optimizations.
2994 We could propagate more information in the first pass by making use
2995 of DF_REG_DEF_COUNT to determine immediately that the alias information
2996 for a pseudo is "constant".
2998 A program with an uninitialized variable can cause an infinite loop
2999 here. Instead of doing a full dataflow analysis to detect such problems
3000 we just cap the number of iterations for the loop.
3002 The state of the arrays for the set chain in question does not matter
3003 since the program has undefined behavior. */
3009 do
3010 {
3011 /* Assume nothing will change this iteration of the loop. */
3014 /* We want to assign the same IDs each iteration of this loop, so
3015 start counting from one each iteration of the loop. */
3018 /* We're at the start of the function each iteration through the
3019 loop, so we're copying arguments. */
3022 /* Wipe the potential alias information clean for this pass. */
3025 /* Wipe the reg_seen array clean. */
3028 /* Initialize the alias information for this pass. */
3031 {
3034 }
3036 /* Walk the insns adding values to the new_reg_base_value array. */
3038 {
3041 {
3043 {
3046 #if defined (HAVE_prologue) || defined (HAVE_epilogue)
3047 /* The prologue/epilogue insns are not threaded onto the
3048 insn chain until after reload has completed. Thus,
3049 there is no sense wasting time checking if INSN is in
3050 the prologue/epilogue until after reload has completed. */
3054 #endif
3056 /* If this insn has a noalias note, process it, Otherwise,
3057 scan for sets. A simple set will have no side effects
3058 which could change the base value of any other register. */
3064 else
3072 {
3075 rtx t;
3087 {
3091 }
3097 {
3102 }
3105 {
3108 }
3109 }
3110 }
3114 }
3115 }
3117 /* Now propagate values from new_reg_base_value to reg_base_value. */
3121 {
3125 {
3128 }
3129 }
3130 }
3134 /* Fill in the remaining entries. */
3136 {
3140 }
3142 /* Clean up. */
3148 }
3150 /* Equate REG_BASE_VALUE (reg1) to REG_BASE_VALUE (reg2).
3151 Special API for var-tracking pass purposes. */
3153 void
3155 {
3157 }
3159 void
3161 {
3165 }