| blob | 9caad5e4fae79de40ea3e266a8a13b21c7e7141a |
1 /* Alias analysis for trees.
2 Copyright (C) 2004, 2005, 2007 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/>. */
51 /* Obstack used to hold grouping bitmaps and other temporary bitmaps used by
52 aliasing */
55 /* 'true' after aliases have been computed (see compute_may_aliases). */
58 /* Structure to map a variable to its alias set and keep track of the
59 virtual operands that will be needed to represent it. */
60 struct alias_map_d
61 {
62 /* Variable and its alias set. */
63 tree var;
64 HOST_WIDE_INT set;
66 /* Total number of virtual operands that will be needed to represent
67 all the aliases of VAR. */
70 /* Nonzero if the aliases for this memory tag have been grouped
71 already. Used in group_aliases. */
74 /* Set of variables aliased with VAR. This is the exact same
75 information contained in VAR_ANN (VAR)->MAY_ALIASES, but in
76 bitmap form to speed up alias grouping. */
77 bitmap may_aliases;
78 };
81 /* Counters used to display statistics on alias analysis. */
82 struct alias_stats_d
83 {
93 };
96 /* Local variables. */
99 /* Local functions. */
118 /* Global declarations. */
120 /* Call clobbered variables in the function. If bit I is set, then
121 REFERENCED_VARS (I) is call-clobbered. */
122 bitmap call_clobbered_vars;
124 /* Addressable variables in the function. If bit I is set, then
125 REFERENCED_VARS (I) has had its address taken. Note that
126 CALL_CLOBBERED_VARS and ADDRESSABLE_VARS are not related. An
127 addressable variable is not necessarily call-clobbered (e.g., a
128 local addressable whose address does not escape) and not all
129 call-clobbered variables are addressable (e.g., a local static
130 variable). */
131 bitmap addressable_vars;
133 /* When the program has too many call-clobbered variables and call-sites,
134 this variable is used to represent the clobbering effects of function
135 calls. In these cases, all the call clobbered variables in the program
136 are forced to alias this variable. This reduces compile times by not
137 having to keep track of too many V_MAY_DEF expressions at call sites. */
138 tree global_var;
140 /* qsort comparison function to sort type/name tags by DECL_UID. */
142 static int
144 {
149 }
151 /* Initialize WORKLIST to contain those memory tags that are marked call
152 clobbered. Initialized WORKLIST2 to contain the reasons these
153 memory tags escaped. */
155 static void
158 {
159 referenced_var_iterator rvi;
160 tree curr;
163 {
165 {
168 }
169 }
170 }
172 /* Add ALIAS to WORKLIST (and the reason for escaping REASON to WORKLIST2) if
173 ALIAS is not already marked call clobbered, and is a memory
174 tag. */
176 static void
180 {
182 {
185 }
186 }
188 /* Mark aliases of TAG as call clobbered, and place any tags on the
189 alias list that were not already call clobbered on WORKLIST. */
191 static void
194 {
197 tree entry;
207 {
209 {
212 }
213 }
214 }
216 /* Tags containing global vars need to be marked as global.
217 Tags containing call clobbered vars need to be marked as call
218 clobbered. */
220 static void
222 {
223 referenced_var_iterator rvi;
224 tree tag;
229 {
233 }
235 /* We sort the taglist by DECL_UID, for two reasons.
236 1. To get a sequential ordering to make the bitmap accesses
237 faster.
238 2. Because of the way we compute aliases, it's more likely that
239 an earlier tag is included in a later tag, and this will reduce
240 the number of iterations.
242 If we had a real tag graph, we would just topo-order it and be
243 done with it. */
247 sort_tags_by_id);
249 /* Go through each tag not marked as global, and if it aliases
250 global vars, mark it global.
252 If the tag contains call clobbered vars, mark it call
253 clobbered.
255 This loop iterates because tags may appear in the may-aliases
256 list of other tags when we group. */
259 {
264 {
267 tree entry;
279 {
280 /* Call clobbered entries cause the tag to be marked
281 call clobbered. */
283 {
287 }
289 /* Global vars cause the tag to be marked global. */
291 {
295 }
297 /* Early exit once both global and cc are set, since the
298 loop can't do any more than that. */
301 }
302 }
303 }
305 }
307 /* Set up the initial variable clobbers and globalness.
308 When this function completes, only tags whose aliases need to be
309 clobbered will be set clobbered. Tags clobbered because they
310 contain call clobbered vars are handled in compute_tag_properties. */
312 static void
314 {
316 referenced_var_iterator rvi;
317 tree var;
318 tree ptr;
321 {
325 {
328 }
332 {
336 }
337 }
340 {
345 {
346 /* If PTR escapes then its associated memory tags and
347 pointed-to variables are call-clobbered. */
355 {
356 bitmap_iterator bi;
361 }
362 }
364 /* If the name tag is call clobbered, so is the symbol tag
365 associated with the base VAR_DECL. */
371 /* Name tags and symbol tags that we don't know where they point
372 to, might point to global memory, and thus, are clobbered.
374 FIXME: This is not quite right. They should only be
375 clobbered if value_escapes_p is true, regardless of whether
376 they point to global memory or not.
377 So removing this code and fixing all the bugs would be nice.
378 It is the cause of a bunch of clobbering. */
381 {
384 }
389 {
392 }
393 }
394 }
397 /* This variable is set to true if we are updating the used alone
398 information for SMTs, or are in a pass that is going to break it
399 temporarily. */
402 /* Compute which variables need to be marked call clobbered because
403 their tag is call clobbered, and which tags need to be marked
404 global because they contain global variables. */
406 static void
408 {
415 {
421 }
425 }
428 /* Helper for recalculate_used_alone. Return a conservatively correct
429 answer as to whether STMT may make a store on the LHS to SYM. */
431 static bool
433 {
443 /* We could do better here by looking at the type tag of LHS, but it
444 is unclear whether this is worth it. */
446 }
448 /* Recalculate the used_alone information for SMTs . */
450 void
452 {
454 block_stmt_iterator bsi;
455 basic_block bb;
456 tree stmt;
458 referenced_var_iterator rvi;
459 tree var;
461 /* First, reset all the SMT used alone bits to zero. */
465 {
468 }
470 /* Walk all the statements.
471 Calls get put into a list of statements to update, since we will
472 need to update operands on them if we make any changes.
473 If we see a bare use of a SMT anywhere in a real virtual use or virtual
474 def, mark the SMT as used alone, and for renaming. */
476 {
478 {
480 ssa_op_iter iter;
487 {
490 }
494 {
501 {
502 /* We only care about the LHS on calls. */
507 {
510 /* Only need to mark for renaming if it wasn't
511 used alone before. */
514 }
515 }
516 }
517 }
518 }
520 /* Update the operands on all the calls we saw. */
522 {
525 }
527 /* We need to mark SMT's that are no longer used for renaming so the
528 symbols go away, or else verification will be angry with us, even
529 though they are dead. */
532 {
535 }
539 }
541 /* Compute may-alias information for every variable referenced in function
542 FNDECL.
544 Alias analysis proceeds in 3 main phases:
546 1- Points-to and escape analysis.
548 This phase walks the use-def chains in the SSA web looking for three
549 things:
551 * Assignments of the form P_i = &VAR
552 * Assignments of the form P_i = malloc()
553 * Pointers and ADDR_EXPR that escape the current function.
555 The concept of 'escaping' is the same one used in the Java world. When
556 a pointer or an ADDR_EXPR escapes, it means that it has been exposed
557 outside of the current function. So, assignment to global variables,
558 function arguments and returning a pointer are all escape sites, as are
559 conversions between pointers and integers.
561 This is where we are currently limited. Since not everything is renamed
562 into SSA, we lose track of escape properties when a pointer is stashed
563 inside a field in a structure, for instance. In those cases, we are
564 assuming that the pointer does escape.
566 We use escape analysis to determine whether a variable is
567 call-clobbered. Simply put, if an ADDR_EXPR escapes, then the variable
568 is call-clobbered. If a pointer P_i escapes, then all the variables
569 pointed-to by P_i (and its memory tag) also escape.
571 2- Compute flow-sensitive aliases
573 We have two classes of memory tags. Memory tags associated with the
574 pointed-to data type of the pointers in the program. These tags are
575 called "symbol memory tag" (SMT). The other class are those associated
576 with SSA_NAMEs, called "name memory tag" (NMT). The basic idea is that
577 when adding operands for an INDIRECT_REF *P_i, we will first check
578 whether P_i has a name tag, if it does we use it, because that will have
579 more precise aliasing information. Otherwise, we use the standard symbol
580 tag.
582 In this phase, we go through all the pointers we found in points-to
583 analysis and create alias sets for the name memory tags associated with
584 each pointer P_i. If P_i escapes, we mark call-clobbered the variables
585 it points to and its tag.
588 3- Compute flow-insensitive aliases
590 This pass will compare the alias set of every symbol memory tag and
591 every addressable variable found in the program. Given a symbol
592 memory tag SMT and an addressable variable V. If the alias sets of
593 SMT and V conflict (as computed by may_alias_p), then V is marked
594 as an alias tag and added to the alias set of SMT.
596 For instance, consider the following function:
598 foo (int i)
599 {
600 int *p, a, b;
602 if (i > 10)
603 p = &a;
604 else
605 p = &b;
607 *p = 3;
608 a = b + 2;
609 return *p;
610 }
612 After aliasing analysis has finished, the symbol memory tag for pointer
613 'p' will have two aliases, namely variables 'a' and 'b'. Every time
614 pointer 'p' is dereferenced, we want to mark the operation as a
615 potential reference to 'a' and 'b'.
617 foo (int i)
618 {
619 int *p, a, b;
621 if (i_2 > 10)
622 p_4 = &a;
623 else
624 p_6 = &b;
625 # p_1 = PHI <p_4(1), p_6(2)>;
627 # a_7 = V_MAY_DEF <a_3>;
628 # b_8 = V_MAY_DEF <b_5>;
629 *p_1 = 3;
631 # a_9 = V_MAY_DEF <a_7>
632 # VUSE <b_8>
633 a_9 = b_8 + 2;
635 # VUSE <a_9>;
636 # VUSE <b_8>;
637 return *p_1;
638 }
640 In certain cases, the list of may aliases for a pointer may grow too
641 large. This may cause an explosion in the number of virtual operands
642 inserted in the code. Resulting in increased memory consumption and
643 compilation time.
645 When the number of virtual operands needed to represent aliased
646 loads and stores grows too large (configurable with @option{--param
647 max-aliased-vops}), alias sets are grouped to avoid severe
648 compile-time slow downs and memory consumption. See group_aliases. */
650 static unsigned int
652 {
657 /* Initialize aliasing information. */
660 /* For each pointer P_i, determine the sets of variables that P_i may
661 point-to. For every addressable variable V, determine whether the
662 address of V escapes the current function, making V call-clobbered
663 (i.e., whether &V is stored in a global variable or if its passed as a
664 function call argument). */
667 /* Collect all pointers and addressable variables, compute alias sets,
668 create memory tags for pointers and promote variables whose address is
669 not needed anymore. */
672 /* Compute flow-sensitive, points-to based aliasing for all the name
673 memory tags. Note that this pass needs to be done before flow
674 insensitive analysis because it uses the points-to information
675 gathered before to mark call-clobbered symbol tags. */
678 /* Compute type-based flow-insensitive aliasing for all the type
679 memory tags. */
682 /* Compute call clobbering information. */
685 /* Determine if we need to enable alias grouping. */
689 /* If the program has too many call-clobbered variables and/or function
690 calls, create .GLOBAL_VAR and use it to model call-clobbering
691 semantics at call sites. This reduces the number of virtual operands
692 considerably, improving compile times at the expense of lost
693 aliasing precision. */
696 /* If the program contains ref-all pointers, finalize may-alias information
697 for them. This pass needs to be run after call-clobbering information
698 has been computed. */
702 /* Debugging dumps. */
704 {
710 }
712 /* Deallocate memory used by aliasing data structures. */
716 {
717 block_stmt_iterator bsi;
718 basic_block bb;
720 {
722 {
724 }
725 }
726 }
730 }
734 {
746 TODO_dump_func | TODO_update_ssa
750 };
753 /* Data structure used to count the number of dereferences to PTR
754 inside an expression. */
755 struct count_ptr_d
756 {
757 tree ptr;
759 };
762 /* Helper for count_uses_and_derefs. Called by walk_tree to look for
763 (ALIGN/MISALIGNED_)INDIRECT_REF nodes for the pointer passed in DATA. */
765 static tree
767 {
770 /* Do not walk inside ADDR_EXPR nodes. In the expression &ptr->fld,
771 pointer 'ptr' is *not* dereferenced, it is simply used to compute
772 the address of 'fld' as 'ptr + offsetof(fld)'. */
774 {
777 }
783 }
786 /* Count the number of direct and indirect uses for pointer PTR in
787 statement STMT. The two counts are stored in *NUM_USES_P and
788 *NUM_DEREFS_P respectively. *IS_STORE_P is set to 'true' if at
789 least one of those dereferences is a store operation. */
791 void
794 {
795 ssa_op_iter i;
796 tree use;
802 /* Find out the total number of uses of PTR in STMT. */
807 /* Now count the number of indirect references to PTR. This is
808 truly awful, but we don't have much choice. There are no parent
809 pointers inside INDIRECT_REFs, so an expression like
810 '*x_1 = foo (x_1, *x_1)' needs to be traversed piece by piece to
811 find all the indirect and direct uses of x_1 inside. The only
812 shortcut we can take is the fact that GIMPLE only allows
813 INDIRECT_REFs inside the expressions below. */
819 {
823 {
826 }
828 {
832 }
834 {
837 }
838 else
839 {
842 }
845 {
852 }
855 {
861 }
862 }
865 }
867 /* Initialize the data structures used for alias analysis. */
871 {
873 referenced_var_iterator rvi;
874 tree var;
885 /* If aliases have been computed before, clear existing information. */
887 {
890 /* Similarly, clear the set of addressable variables. In this
891 case, we can just clear the set because addressability is
892 only computed here. */
895 /* Clear flow-insensitive alias information from each symbol. */
897 {
904 /* Since we are about to re-discover call-clobbered
905 variables, clear the call-clobbered flag. Variables that
906 are intrinsically call-clobbered (globals, local statics,
907 etc) will not be marked by the aliasing code, so we can't
908 remove them from CALL_CLOBBERED_VARS.
910 NB: STRUCT_FIELDS are still call clobbered if they are for
911 a global variable, so we *don't* clear their call clobberedness
912 just because they are tags, though we will clear it if they
913 aren't for global variables. */
918 }
920 /* Clear flow-sensitive points-to information from each SSA name. */
922 {
929 {
932 /* Clear all the flags but keep the name tag to
933 avoid creating new temporaries unnecessarily. If
934 this pointer is found to point to a subset or
935 superset of its former points-to set, then a new
936 tag will need to be created in create_name_tags. */
943 }
944 }
945 }
947 /* Next time, we will need to reset alias information. */
951 }
954 /* Deallocate memory used by alias analysis. */
956 static void
958 {
960 referenced_var_iterator rvi;
961 tree var;
970 {
973 }
988 }
990 /* Used for hashing to identify pointer infos with identical
991 pt_vars bitmaps. */
992 static int
994 {
998 }
1000 static hashval_t
1002 {
1005 }
1007 /* Create name tags for all the pointers that have been dereferenced.
1008 We only create a name tag for a pointer P if P is found to point to
1009 a set of variables (so that we can alias them to *P) or if it is
1010 the result of a call to malloc (which means that P cannot point to
1011 anything else nor alias any other variable).
1013 If two pointers P and Q point to the same set of variables, they
1014 are assigned the same name tag. */
1016 static void
1018 {
1021 tree ptr;
1022 htab_t ptr_hash;
1024 /* Collect the list of pointers with a non-empty points to set. */
1026 {
1038 {
1039 /* No name tags for pointers that have not been
1040 dereferenced or point to an arbitrary location. */
1043 }
1045 /* Set pt_anything on the pointers without pt_vars filled in so
1046 that they are assigned a symbol tag. */
1049 else
1051 }
1053 /* If we didn't find any pointers with pt_vars set, we're done. */
1058 /* Now go through the pointers with pt_vars, and find a name tag
1059 with the same pt_vars as this pointer, or create one if one
1060 doesn't exist. */
1062 {
1067 /* If PTR points to a set of variables, check if we don't
1068 have another pointer Q with the same points-to set before
1069 creating a tag. If so, use Q's tag instead of creating a
1070 new one.
1072 This is important for not creating unnecessary symbols
1073 and also for copy propagation. If we ever need to
1074 propagate PTR into Q or vice-versa, we would run into
1075 problems if they both had different name tags because
1076 they would have different SSA version numbers (which
1077 would force us to take the name tags in and out of SSA). */
1082 else
1083 {
1085 /* If we didn't find a pointer with the same points-to set
1086 as PTR, create a new name tag if needed. */
1089 }
1091 /* If the new name tag computed for PTR is different than
1092 the old name tag that it used to have, then the old tag
1093 needs to be removed from the IL, so we mark it for
1094 renaming. */
1101 /* Mark the new name tag for renaming. */
1103 }
1107 }
1110 /* For every pointer P_i in AI->PROCESSED_PTRS, create may-alias sets for
1111 the name memory tag (NMT) associated with P_i. If P_i escapes, then its
1112 name tag and the variables it points-to are call-clobbered. Finally, if
1113 P_i escapes and we could not determine where it points to, then all the
1114 variables in the same alias set as *P_i are marked call-clobbered. This
1115 is necessary because we must assume that P_i may take the address of any
1116 variable in the same alias set. */
1118 static void
1120 {
1122 tree ptr;
1125 {
1128 }
1133 {
1137 bitmap_iterator bi;
1140 /* Set up aliasing information for PTR's name memory tag (if it has
1141 one). Note that only pointers that have been dereferenced will
1142 have a name memory tag. */
1145 {
1148 }
1149 }
1150 }
1153 /* Compute type-based alias sets. Traverse all the pointers and
1154 addressable variables found in setup_pointers_and_addressables.
1156 For every pointer P in AI->POINTERS and addressable variable V in
1157 AI->ADDRESSABLE_VARS, add V to the may-alias sets of P's symbol
1158 memory tag (SMT) if their alias sets conflict. V is then marked as
1159 an alias tag so that the operand scanner knows that statements
1160 containing V have aliased operands. */
1162 static void
1164 {
1167 /* Initialize counter for the total number of virtual operands that
1168 aliasing will introduce. When AI->TOTAL_ALIAS_VOPS goes beyond the
1169 threshold set by --params max-alias-vops, we enable alias
1170 grouping. */
1173 /* For every pointer P, determine which addressable variables may alias
1174 with P's symbol memory tag. */
1176 {
1181 tree var;
1183 /* Call-clobbering information is not finalized yet at this point. */
1190 /* Add any pre-existing may_aliases to the bitmap used to represent
1191 TAG's alias set in case we need to group aliases. */
1196 {
1198 var_ann_t v_ann;
1205 /* Skip memory tags and variables that have never been
1206 written to. We also need to check if the variables are
1207 call-clobbered because they may be overwritten by
1208 function calls.
1210 Note this is effectively random accessing elements in
1211 the sparse bitset, which can be highly inefficient.
1212 So we first check the call_clobbered status of the
1213 tag and variable before querying the bitmap. */
1222 {
1228 /* Add VAR to TAG's may-aliases set. */
1230 /* We should never have a var with subvars here, because
1231 they shouldn't get into the set of addressable vars */
1236 /* Update the bitmap used to represent TAG's alias set
1237 in case we need to group aliases. */
1240 /* Update the total number of virtual operands due to
1241 aliasing. Since we are adding one more alias to TAG's
1242 may-aliases set, the total number of virtual operands due
1243 to aliasing will be increased by the number of references
1244 made to VAR and TAG (every reference to TAG will also
1245 count as a reference to VAR). */
1250 }
1251 }
1252 }
1254 /* Since this analysis is based exclusively on symbols, it fails to
1255 handle cases where two pointers P and Q have different memory
1256 tags with conflicting alias set numbers but no aliased symbols in
1257 common.
1259 For example, suppose that we have two memory tags SMT.1 and SMT.2
1260 such that
1262 may-aliases (SMT.1) = { a }
1263 may-aliases (SMT.2) = { b }
1265 and the alias set number of SMT.1 conflicts with that of SMT.2.
1266 Since they don't have symbols in common, loads and stores from
1267 SMT.1 and SMT.2 will seem independent of each other, which will
1268 lead to the optimizers making invalid transformations (see
1269 testsuite/gcc.c-torture/execute/pr15262-[12].c).
1271 To avoid this problem, we do a final traversal of AI->POINTERS
1272 looking for pairs of pointers that have no aliased symbols in
1273 common and yet have conflicting alias set numbers. */
1275 {
1285 {
1293 /* If the pointers may not point to each other, do nothing. */
1297 /* The two pointers may alias each other. If they already have
1298 symbols in common, do nothing. */
1303 {
1305 bitmap_iterator bi;
1307 /* Add all the aliases for TAG2 into TAG1's alias set.
1308 FIXME, update grouping heuristic counters. */
1312 }
1313 else
1314 {
1315 /* Since TAG2 does not have any aliases of its own, add
1316 TAG2 itself to the alias set of TAG1. */
1319 }
1320 }
1321 }
1327 }
1330 /* Finalize may-alias information for ref-all pointers. Traverse all
1331 the addressable variables found in setup_pointers_and_addressables.
1333 If flow-sensitive alias analysis has attached a name memory tag to
1334 a ref-all pointer, we will use it for the dereferences because that
1335 will have more precise aliasing information. But if there is no
1336 name tag, we will use a special symbol tag that aliases all the
1337 call-clobbered addressable variables. */
1339 static void
1341 {
1346 else
1347 {
1348 /* First add the real call-clobbered variables. */
1350 {
1354 }
1356 /* Then add the call-clobbered pointer memory tags. See
1357 compute_flow_insensitive_aliasing for the rationale. */
1359 {
1366 }
1367 }
1368 }
1371 /* Comparison function for qsort used in group_aliases. */
1373 static int
1375 {
1381 /* We want to sort in descending order. */
1383 }
1385 /* Group all the aliases for TAG to make TAG represent all the
1386 variables in its alias set. Update the total number
1387 of virtual operands due to aliasing (AI->TOTAL_ALIAS_VOPS). This
1388 function will make TAG be the unique alias tag for all the
1389 variables in its may-aliases. So, given:
1391 may-aliases(TAG) = { V1, V2, V3 }
1393 This function will group the variables into:
1395 may-aliases(V1) = { TAG }
1396 may-aliases(V2) = { TAG }
1397 may-aliases(V2) = { TAG } */
1399 static void
1401 {
1405 bitmap_iterator bi;
1408 {
1412 /* Make TAG the unique alias of VAR. */
1416 /* Note that VAR and TAG may be the same if the function has no
1417 addressable variables (see the discussion at the end of
1418 setup_pointers_and_addressables). */
1422 /* Reduce total number of virtual operands contributed
1423 by TAG on behalf of VAR. Notice that the references to VAR
1424 itself won't be removed. We will merely replace them with
1425 references to TAG. */
1427 }
1429 /* We have reduced the number of virtual operands that TAG makes on
1430 behalf of all the variables formerly aliased with it. However,
1431 we have also "removed" all the virtual operands for TAG itself,
1432 so we add them back. */
1435 /* TAG no longer has any aliases. */
1437 }
1440 /* Group may-aliases sets to reduce the number of virtual operands due
1441 to aliasing.
1443 1- Sort the list of pointers in decreasing number of contributed
1444 virtual operands.
1446 2- Take the first entry in AI->POINTERS and revert the role of
1447 the memory tag and its aliases. Usually, whenever an aliased
1448 variable Vi is found to alias with a memory tag T, we add Vi
1449 to the may-aliases set for T. Meaning that after alias
1450 analysis, we will have:
1452 may-aliases(T) = { V1, V2, V3, ..., Vn }
1454 This means that every statement that references T, will get 'n'
1455 virtual operands for each of the Vi tags. But, when alias
1456 grouping is enabled, we make T an alias tag and add it to the
1457 alias set of all the Vi variables:
1459 may-aliases(V1) = { T }
1460 may-aliases(V2) = { T }
1461 ...
1462 may-aliases(Vn) = { T }
1464 This has two effects: (a) statements referencing T will only get
1465 a single virtual operand, and, (b) all the variables Vi will now
1466 appear to alias each other. So, we lose alias precision to
1467 improve compile time. But, in theory, a program with such a high
1468 level of aliasing should not be very optimizable in the first
1469 place.
1471 3- Since variables may be in the alias set of more than one
1472 memory tag, the grouping done in step (2) needs to be extended
1473 to all the memory tags that have a non-empty intersection with
1474 the may-aliases set of tag T. For instance, if we originally
1475 had these may-aliases sets:
1477 may-aliases(T) = { V1, V2, V3 }
1478 may-aliases(R) = { V2, V4 }
1480 In step (2) we would have reverted the aliases for T as:
1482 may-aliases(V1) = { T }
1483 may-aliases(V2) = { T }
1484 may-aliases(V3) = { T }
1486 But note that now V2 is no longer aliased with R. We could
1487 add R to may-aliases(V2), but we are in the process of
1488 grouping aliases to reduce virtual operands so what we do is
1489 add V4 to the grouping to obtain:
1491 may-aliases(V1) = { T }
1492 may-aliases(V2) = { T }
1493 may-aliases(V3) = { T }
1494 may-aliases(V4) = { T }
1496 4- If the total number of virtual operands due to aliasing is
1497 still above the threshold set by max-alias-vops, go back to (2). */
1499 static void
1501 {
1503 tree ptr;
1505 /* Sort the POINTERS array in descending order of contributed
1506 virtual operands. */
1508 total_alias_vops_cmp);
1510 /* For every pointer in AI->POINTERS, reverse the roles of its tag
1511 and the tag's may-aliases set. */
1513 {
1518 /* Skip tags that have been grouped already. */
1522 /* See if TAG1 had any aliases in common with other symbol tags.
1523 If we find a TAG2 with common aliases with TAG1, add TAG2's
1524 aliases into TAG1. */
1526 {
1530 {
1535 /* TAG2 does not need its aliases anymore. */
1539 /* TAG1 is the unique alias of TAG2. */
1543 }
1544 }
1546 /* Now group all the aliases we collected into TAG1. */
1549 /* If we've reduced total number of virtual operands below the
1550 threshold, stop. */
1553 }
1555 /* Finally, all the variables that have been grouped cannot be in
1556 the may-alias set of name memory tags. Suppose that we have
1557 grouped the aliases in this code so that may-aliases(a) = SMT.20
1559 p_5 = &a;
1560 ...
1561 # a_9 = V_MAY_DEF <a_8>
1562 p_5->field = 0
1563 ... Several modifications to SMT.20 ...
1564 # VUSE <a_9>
1565 x_30 = p_5->field
1567 Since p_5 points to 'a', the optimizers will try to propagate 0
1568 into p_5->field, but that is wrong because there have been
1569 modifications to 'SMT.20' in between. To prevent this we have to
1570 replace 'a' with 'SMT.20' in the name tag of p_5. */
1572 {
1576 tree alias;
1583 {
1589 {
1590 tree new_alias;
1596 }
1597 }
1598 }
1606 }
1609 /* Create a new alias set entry for VAR in AI->ADDRESSABLE_VARS. */
1611 static void
1613 {
1619 }
1622 /* Create memory tags for all the dereferenced pointers and build the
1623 ADDRESSABLE_VARS and POINTERS arrays used for building the may-alias
1624 sets. Based on the address escape and points-to information collected
1625 earlier, this pass will also clear the TREE_ADDRESSABLE flag from those
1626 variables whose address is not needed anymore. */
1628 static void
1630 {
1632 referenced_var_iterator rvi;
1633 tree var;
1635 safe_referenced_var_iterator srvi;
1637 /* Size up the arrays ADDRESSABLE_VARS and POINTERS. */
1641 {
1643 num_addressable_vars++;
1646 {
1647 /* Since we don't keep track of volatile variables, assume that
1648 these pointers are used in indirect store operations. */
1652 num_pointers++;
1653 }
1654 }
1656 /* Create ADDRESSABLE_VARS and POINTERS. Note that these arrays are
1657 always going to be slightly bigger than we actually need them
1658 because some TREE_ADDRESSABLE variables will be marked
1659 non-addressable below and only pointers with unique symbol tags are
1660 going to be added to POINTERS. */
1666 /* Since we will be creating symbol memory tags within this loop,
1667 cache the value of NUM_REFERENCED_VARS to avoid processing the
1668 additional tags unnecessarily. */
1672 {
1674 subvar_t svars;
1676 /* Name memory tags already have flow-sensitive aliasing
1677 information, so they need not be processed by
1678 compute_flow_insensitive_aliasing. Similarly, symbol memory
1679 tags are already accounted for when we process their
1680 associated pointer.
1682 Structure fields, on the other hand, have to have some of this
1683 information processed for them, but it's pointless to mark them
1684 non-addressable (since they are fake variables anyway). */
1688 /* Remove the ADDRESSABLE flag from every addressable variable whose
1689 address is not needed anymore. This is caused by the propagation
1690 of ADDR_EXPR constants into INDIRECT_REF expressions and the
1691 removal of dead pointer assignments done by the early scalar
1692 cleanup passes. */
1694 {
1698 {
1701 /* Since VAR is now a regular GIMPLE register, we will need
1702 to rename VAR into SSA afterwards. */
1705 /* If VAR can have sub-variables, and any of its
1706 sub-variables has its address taken, then we cannot
1707 remove the addressable flag from VAR. */
1710 {
1711 subvar_t sv;
1714 {
1718 }
1719 }
1721 /* The address of VAR is not needed, remove the
1722 addressable bit, so that it can be optimized as a
1723 regular variable. */
1726 }
1727 }
1729 /* Global variables and addressable locals may be aliased. Create an
1730 entry in ADDRESSABLE_VARS for VAR. */
1734 {
1737 }
1739 /* Add pointer variables that have been dereferenced to the POINTERS
1740 array and create a symbol memory tag for them. */
1742 {
1745 {
1746 tree tag;
1747 var_ann_t t_ann;
1749 /* If pointer VAR still doesn't have a memory tag
1750 associated with it, create it now or re-use an
1751 existing one. */
1755 /* The symbol tag will need to be renamed into SSA
1756 afterwards. Note that we cannot do this inside
1757 get_tmt_for because aliasing may run multiple times
1758 and we only create symbol tags the first time. */
1761 /* Similarly, if pointer VAR used to have another type
1762 tag, we will need to process it in the renamer to
1763 remove the stale virtual operands. */
1767 /* Associate the tag with pointer VAR. */
1770 /* If pointer VAR has been used in a store operation,
1771 then its memory tag must be marked as written-to. */
1775 /* All the dereferences of pointer VAR count as
1776 references of TAG. Since TAG can be associated with
1777 several pointers, add the dereferences of VAR to the
1778 TAG. */
1782 }
1783 else
1784 {
1785 /* The pointer has not been dereferenced. If it had a
1786 symbol memory tag, remove it and mark the old tag for
1787 renaming to remove it out of the IL. */
1791 {
1794 }
1795 }
1796 }
1797 }
1799 }
1802 /* Determine whether to use .GLOBAL_VAR to model call clobbering semantics. At
1803 every call site, we need to emit V_MAY_DEF expressions to represent the
1804 clobbering effects of the call for variables whose address escapes the
1805 current function.
1807 One approach is to group all call-clobbered variables into a single
1808 representative that is used as an alias of every call-clobbered variable
1809 (.GLOBAL_VAR). This works well, but it ties the optimizer hands because
1810 references to any call clobbered variable is a reference to .GLOBAL_VAR.
1812 The second approach is to emit a clobbering V_MAY_DEF for every
1813 call-clobbered variable at call sites. This is the preferred way in terms
1814 of optimization opportunities but it may create too many V_MAY_DEF operands
1815 if there are many call clobbered variables and function calls in the
1816 function.
1818 To decide whether or not to use .GLOBAL_VAR we multiply the number of
1819 function calls found by the number of call-clobbered variables. If that
1820 product is beyond a certain threshold, as determined by the parameterized
1821 values shown below, we use .GLOBAL_VAR.
1823 FIXME. This heuristic should be improved. One idea is to use several
1824 .GLOBAL_VARs of different types instead of a single one. The thresholds
1825 have been derived from a typical bootstrap cycle, including all target
1826 libraries. Compile times were found increase by ~1% compared to using
1827 .GLOBAL_VAR. */
1829 static void
1831 {
1833 bitmap_iterator bi;
1835 /* No need to create it, if we have one already. */
1837 {
1838 /* Count all the call-clobbered variables. */
1841 {
1842 n_clobbered++;
1843 }
1845 /* If the number of virtual operands that would be needed to
1846 model all the call-clobbered variables is larger than
1847 GLOBAL_VAR_THRESHOLD, create .GLOBAL_VAR.
1849 Also create .GLOBAL_VAR if there are no call-clobbered
1850 variables and the program contains a mixture of pure/const
1851 and regular function calls. This is to avoid the problem
1852 described in PR 20115:
1854 int X;
1855 int func_pure (void) { return X; }
1856 int func_non_pure (int a) { X += a; }
1857 int foo ()
1858 {
1859 int a = func_pure ();
1860 func_non_pure (a);
1861 a = func_pure ();
1862 return a;
1863 }
1865 Since foo() has no call-clobbered variables, there is
1866 no relationship between the calls to func_pure and
1867 func_non_pure. Since func_pure has no side-effects, value
1868 numbering optimizations elide the second call to func_pure.
1869 So, if we have some pure/const and some regular calls in the
1870 program we create .GLOBAL_VAR to avoid missing these
1871 relations. */
1878 }
1880 /* Mark all call-clobbered symbols for renaming. Since the initial
1881 rewrite into SSA ignored all call sites, we may need to rename
1882 .GLOBAL_VAR and the call-clobbered variables. */
1884 {
1887 /* If the function has calls to clobbering functions and
1888 .GLOBAL_VAR has been created, make it an alias for all
1889 call-clobbered variables. */
1891 {
1894 }
1897 }
1898 }
1901 /* Return TRUE if pointer PTR may point to variable VAR.
1903 MEM_ALIAS_SET is the alias set for the memory location pointed-to by PTR
1904 This is needed because when checking for type conflicts we are
1905 interested in the alias set of the memory location pointed-to by
1906 PTR. The alias set of PTR itself is irrelevant.
1908 VAR_ALIAS_SET is the alias set for VAR. */
1910 static bool
1914 {
1915 tree mem;
1920 /* By convention, a variable cannot alias itself. */
1923 {
1927 }
1929 /* If -fargument-noalias-global is > 2, pointer arguments may
1930 not point to anything else. */
1932 {
1936 }
1938 /* If -fargument-noalias-global is > 1, pointer arguments may
1939 not point to global variables. */
1942 {
1946 }
1948 /* If either MEM or VAR is a read-only global and the other one
1949 isn't, then PTR cannot point to VAR. */
1952 {
1956 }
1962 /* If the alias sets don't conflict then MEM cannot alias VAR. */
1964 {
1968 }
1970 /* If var is a record or union type, ptr cannot point into var
1971 unless there is some operation explicit address operation in the
1972 program that can reference a field of the ptr's dereferenced
1973 type. This also assumes that the types of both var and ptr are
1974 contained within the compilation unit, and that there is no fancy
1975 addressing arithmetic associated with any of the types
1976 involved. */
1979 {
1983 /* The star count is -1 if the type at the end of the pointer_to
1984 chain is not a record or union type. */
1987 {
1990 /* Ipa_type_escape_star_count_of_interesting_type is a little to
1991 restrictive for the pointer type, need to allow pointers to
1992 primitive types as long as those types cannot be pointers
1993 to everything. */
1995 /* Strip the *'s off. */
1996 {
1998 ptr_star_count++;
1999 }
2001 /* There does not appear to be a better test to see if the
2002 pointer type was one of the pointer to everything
2003 types. */
2006 {
2010 {
2014 }
2015 }
2017 {
2018 /* If ptr_type was not really a pointer to type, it cannot
2019 alias. */
2024 }
2025 }
2026 }
2030 }
2033 /* Add ALIAS to the set of variables that may alias VAR. */
2035 static void
2037 {
2041 tree al;
2043 /* Don't allow self-referential aliases. */
2046 /* ALIAS must be addressable if it's being added to an alias set. */
2047 #if 1
2049 #else
2051 #endif
2056 /* Avoid adding duplicates. */
2063 }
2066 /* Replace alias I in the alias sets of VAR with NEW_ALIAS. */
2068 static void
2070 {
2073 }
2076 /* Mark pointer PTR as pointing to an arbitrary memory location. */
2078 static void
2080 {
2086 /* The pointer used to have a name tag, but we now found it pointing
2087 to an arbitrary location. The name tag needs to be renamed and
2088 disassociated from PTR. */
2090 {
2093 }
2094 }
2097 /* Return true if STMT is an "escape" site from the current function. Escape
2098 sites those statements which might expose the address of a variable
2099 outside the current function. STMT is an escape site iff:
2101 1- STMT is a function call, or
2102 2- STMT is an __asm__ expression, or
2103 3- STMT is an assignment to a non-local variable, or
2104 4- STMT is a return statement.
2106 Return the type of escape site found, if we found one, or NO_ESCAPE
2107 if none. */
2109 enum escape_type
2111 {
2114 {
2119 }
2123 {
2126 /* Get to the base of _REF nodes. */
2130 /* If we couldn't recognize the LHS of the assignment, assume that it
2131 is a non-local store. */
2138 {
2142 /* If the RHS is a conversion between a pointer and an integer, the
2143 pointer escapes since we can't track the integer. */
2147 /* Same if the RHS is a conversion between a regular pointer and a
2148 ref-all pointer since we can't track the SMT of the former. */
2152 }
2154 /* If the LHS is an SSA name, it can't possibly represent a non-local
2155 memory store. */
2159 /* FIXME: LHS is not an SSA_NAME. Even if it's an assignment to a
2160 local variables we cannot be sure if it will escape, because we
2161 don't have information about objects not in SSA form. Need to
2162 implement something along the lines of
2164 J.-D. Choi, M. Gupta, M. J. Serrano, V. C. Sreedhar, and S. P.
2165 Midkiff, ``Escape analysis for java,'' in Proceedings of the
2166 Conference on Object-Oriented Programming Systems, Languages, and
2167 Applications (OOPSLA), pp. 1-19, 1999. */
2169 }
2174 }
2176 /* Create a new memory tag of type TYPE.
2177 Does NOT push it into the current binding. */
2179 static tree
2181 {
2182 tree tmp_var;
2183 tree new_type;
2185 /* Make the type of the variable writable. */
2190 type);
2191 /* Make the variable writable. */
2194 /* It doesn't start out global. */
2200 }
2202 /* Create a new memory tag of type TYPE. If IS_TYPE_TAG is true, the tag
2203 is considered to represent all the pointers whose pointed-to types are
2204 in the same alias set class. Otherwise, the tag represents a single
2205 SSA_NAME pointer variable. */
2207 static tree
2209 {
2210 var_ann_t ann;
2214 /* By default, memory tags are local variables. Alias analysis will
2215 determine whether they should be considered globals. */
2218 /* Memory tags are by definition addressable. */
2224 /* Add the tag to the symbol table. */
2228 }
2231 /* Create a name memory tag to represent a specific SSA_NAME pointer P_i.
2232 This is used if P_i has been found to point to a specific set of
2233 variables or to a non-aliased memory location like the address returned
2234 by malloc functions. */
2236 static tree
2238 {
2245 }
2248 /* Return the symbol memory tag associated to pointer PTR. A memory
2249 tag is an artificial variable that represents the memory location
2250 pointed-to by PTR. It is used to model the effects of pointer
2251 de-references on addressable variables.
2253 AI points to the data gathered during alias analysis. This
2254 function populates the array AI->POINTERS. */
2256 static tree
2258 {
2260 tree tag;
2264 /* We use a unique memory tag for all the ref-all pointers. */
2266 {
2270 }
2272 /* To avoid creating unnecessary memory tags, only create one memory tag
2273 per alias set class. Note that it may be tempting to group
2274 memory tags based on conflicting alias sets instead of
2275 equivalence. That would be wrong because alias sets are not
2276 necessarily transitive (as demonstrated by the libstdc++ test
2277 23_containers/vector/cons/4.cc). Given three alias sets A, B, C
2278 such that conflicts (A, B) == true and conflicts (A, C) == true,
2279 it does not necessarily follow that conflicts (B, C) == true. */
2281 {
2285 {
2288 }
2289 }
2291 /* If VAR cannot alias with any of the existing memory tags, create a new
2292 tag for PTR and add it to the POINTERS array. */
2294 {
2297 /* If PTR did not have a symbol tag already, create a new SMT.*
2298 artificial variable representing the memory location
2299 pointed-to by PTR. */
2302 else
2305 /* Add PTR to the POINTERS array. Note that we are not interested in
2306 PTR's alias set. Instead, we cache the alias set for the memory that
2307 PTR points to. */
2312 }
2314 /* If the pointed-to type is volatile, so is the tag. */
2317 /* Make sure that the symbol tag has the same alias set as the
2318 pointed-to type. */
2322 }
2325 /* Create GLOBAL_VAR, an artificial global variable to act as a
2326 representative of all the variables that may be clobbered by function
2327 calls. */
2329 static void
2331 {
2333 void_type_node);
2347 }
2350 /* Dump alias statistics on FILE. */
2352 static void
2354 {
2375 }
2378 /* Dump alias information on FILE. */
2380 void
2382 {
2386 referenced_var_iterator rvi;
2387 tree var;
2394 {
2397 }
2402 {
2406 }
2411 {
2414 }
2420 {
2429 && pi
2432 }
2437 {
2440 }
2443 }
2446 /* Dump alias information on stderr. */
2448 void
2450 {
2452 }
2455 /* Return the alias information associated with pointer T. It creates a
2456 new instance if none existed. */
2460 {
2467 {
2471 }
2474 }
2477 /* Dump points-to information for SSA_NAME PTR into FILE. */
2479 void
2481 {
2487 {
2489 {
2492 }
2507 {
2509 bitmap_iterator bi;
2513 {
2516 }
2518 }
2519 }
2522 }
2525 /* Dump points-to information for VAR into stderr. */
2527 void
2529 {
2531 }
2534 /* Dump points-to information into FILE. NOTE: This function is slow, as
2535 it needs to traverse the whole CFG looking for pointer SSA_NAMEs. */
2537 void
2539 {
2540 basic_block bb;
2541 block_stmt_iterator si;
2542 ssa_op_iter iter;
2545 referenced_var_iterator rvi;
2546 tree var;
2550 /* First dump points-to information for the default definitions of
2551 pointer variables. This is necessary because default definitions are
2552 not part of the code. */
2554 {
2556 {
2560 }
2561 }
2563 /* Dump points-to information for every pointer defined in the program. */
2565 {
2566 tree phi;
2569 {
2573 }
2576 {
2578 tree def;
2582 }
2583 }
2586 }
2589 /* Dump points-to info pointed to by PTO into STDERR. */
2591 void
2593 {
2595 }
2597 /* Dump to FILE the list of variables that may be aliasing VAR. */
2599 void
2601 {
2609 {
2611 tree al;
2614 {
2617 }
2619 }
2620 }
2623 /* Dump to stderr the list of variables that may be aliasing VAR. */
2625 void
2627 {
2629 }
2631 /* Return true if VAR may be aliased. */
2633 bool
2635 {
2636 /* Obviously. */
2640 /* Globally visible variables can have their addresses taken by other
2641 translation units. */
2650 /* Automatic variables can't have their addresses escape any other way.
2651 This must be after the check for global variables, as extern declarations
2652 do not have TREE_STATIC set. */
2656 /* If we're in unit-at-a-time mode, then we must have seen all occurrences
2657 of address-of operators, and so we can trust TREE_ADDRESSABLE. Otherwise
2658 we can only be sure the variable isn't addressable if it's local to the
2659 current function. */
2666 }
2669 /* Given two symbols return TRUE if one is in the alias set of the other. */
2670 bool
2672 {
2675 tree al;
2678 {
2687 }
2688 else
2689 {
2698 }
2701 }
2704 /* Given two tags return TRUE if their may-alias sets intersect. */
2706 bool
2708 {
2713 tree sym;
2715 /* Insert all the symbols from the first may-alias set into the
2716 pointer-set. */
2720 /* Go through the second may-alias set and check if it contains symbols that
2721 are common with the first set. */
2724 {
2727 }
2731 }
2734 /* The following is based on code in add_stmt_operand to ensure that the
2735 same defs/uses/vdefs/vuses will be found after replacing a reference
2736 to var (or ARRAY_REF to var) with an INDIRECT_REF to ptr whose value
2737 is the address of var. Return a memtag for the ptr, after adding the
2738 proper may_aliases to it (which are the aliases of var, if it has any,
2739 or var itself). */
2741 static tree
2743 {
2747 /* Case 1: |aliases| == 1 */
2750 {
2755 }
2757 /* Case 2: |aliases| == 0 */
2760 else
2761 {
2762 /* Case 3: |aliases| > 1 */
2764 tree al;
2768 }
2771 }
2773 /* Create a new symbol tag for PTR. Construct the may-alias list of this type
2774 tag so that it has the aliasing of VAR, or of the relevant subvars of VAR
2775 according to the location accessed by EXPR.
2777 Note, the set of aliases represented by the new symbol tag are not marked
2778 for renaming. */
2780 void
2782 {
2785 tree tag;
2786 subvar_t svars;
2789 tree ref;
2800 /* Add VAR to the may-alias set of PTR's new symbol tag. If VAR has
2801 subvars, add the subvars to the tag instead of the actual var. */
2804 {
2805 subvar_t sv;
2810 {
2815 }
2824 {
2826 tree sv_var;
2829 {
2833 {
2834 /* Can happen only if 'Case 1' of add_may_alias_for_new_tag
2835 took place. Since more than one svar was found, we add
2836 'ali' as one of the may_aliases of the new tag. */
2839 }
2840 }
2841 }
2842 }
2843 else
2849 }
2851 /* This represents the used range of a variable. */
2854 {
2855 HOST_WIDE_INT minused;
2856 HOST_WIDE_INT maxused;
2857 /* True if we have an explicit use/def of some portion of this variable,
2858 even if it is all of it. i.e. a.b = 5 or temp = a.b. */
2860 /* True if we have an implicit use/def of some portion of this
2861 variable. Implicit uses occur when we can't tell what part we
2862 are referencing, and have to make conservative assumptions. */
2864 /* True if the structure is only written to or taken its address. */
2868 /* An array of used_part structures, indexed by variable uid. */
2872 struct used_part_map
2873 {
2875 used_part_t to;
2876 };
2878 /* Return true if the uid in the two used part maps are equal. */
2880 static int
2882 {
2886 }
2888 /* Hash a from uid in a used_part_map. */
2890 static unsigned int
2892 {
2894 }
2896 /* Free a used part map element. */
2898 static void
2900 {
2903 }
2905 /* Lookup a used_part structure for a UID. */
2907 static used_part_t
2909 {
2916 }
2918 /* Insert the pair UID, TO into the used part hashtable. */
2920 static void
2922 {
2934 }
2937 /* Given a variable uid, UID, get or create the entry in the used portions
2938 table for the variable. */
2940 static used_part_t
2942 {
2943 used_part_t up;
2945 {
2952 }
2955 }
2958 /* Create and return a structure sub-variable for field type FIELD at
2959 offset OFFSET, with size SIZE, of variable VAR. */
2961 static tree
2964 {
2965 var_ann_t ann;
2968 /* We need to copy the various flags from VAR to SUBVAR, so that
2969 they are is_global_var iff the original variable was. */
2977 /* Add the new variable to REFERENCED_VARS. */
2985 }
2988 /* Given an aggregate VAR, create the subvariables that represent its
2989 fields. */
2991 static void
2993 {
2995 used_part_t up;
3005 {
3015 /* Not all fields have DECL_SIZE set, and those that don't, we don't
3016 know their size, and thus, can't handle.
3017 The same is true of fields with DECL_SIZE that is not an integer
3018 constant (such as variable sized fields).
3019 Fields with offsets which are not constant will have an offset < 0
3020 We *could* handle fields that are constant sized arrays, but
3021 currently don't. Doing so would require some extra changes to
3022 tree-ssa-operands.c. */
3025 {
3029 {
3032 }
3033 fieldcount++;
3034 }
3036 /* The current heuristic we use is as follows:
3037 If the variable has no used portions in this function, no
3038 structure vars are created for it.
3039 Otherwise,
3040 If the variable has less than SALIAS_MAX_IMPLICIT_FIELDS,
3041 we always create structure vars for them.
3042 If the variable has more than SALIAS_MAX_IMPLICIT_FIELDS, and
3043 some explicit uses, we create structure vars for them.
3044 If the variable has more than SALIAS_MAX_IMPLICIT_FIELDS, and
3045 no explicit uses, we do not create structure vars for them.
3046 */
3050 {
3052 {
3055 fprintf (dump_file, " has no explicit uses in this function, and is > SALIAS_MAX_IMPLICIT_FIELDS, so skipping\n");
3056 }
3058 }
3060 /* Bail out, if we can't create overlap variables. */
3062 {
3065 }
3067 /* Otherwise, create the variables. */
3074 {
3075 subvar_t sv;
3076 HOST_WIDE_INT fosize;
3077 tree currfotype;
3082 /* If this field isn't in the used portion,
3083 or it has the exact same offset and size as the last
3084 field, skip it. */
3098 {
3106 }
3112 }
3114 /* Once we have created subvars, the original is no longer call
3115 clobbered on its own. Its call clobbered status depends
3116 completely on the call clobbered status of the subvars.
3118 add_referenced_var in the above loop will take care of
3119 marking subvars of global variables as call clobbered for us
3120 to start, since they are global as well. */
3122 }
3125 }
3128 /* Find the conservative answer to the question of what portions of what
3129 structures are used by this statement. We assume that if we have a
3130 component ref with a known size + offset, that we only need that part
3131 of the structure. For unknown cases, or cases where we do something
3132 to the whole structure, we assume we need to create fields for the
3133 entire structure. */
3135 static tree
3137 {
3139 {
3141 /* Recurse manually here to track whether the use is in the
3142 LHS of an assignment. */
3149 {
3150 HOST_WIDE_INT bitsize;
3151 HOST_WIDE_INT bitmaxsize;
3152 HOST_WIDE_INT bitpos;
3153 tree ref;
3158 {
3160 used_part_t up;
3171 else
3179 }
3180 }
3182 /* This is here to make sure we mark the entire base variable as used
3183 when you take its address. Because our used portion analysis is
3184 simple, we aren't looking at casts or pointer arithmetic to see what
3185 happens when you take the address. */
3187 {
3195 {
3196 used_part_t up;
3210 }
3211 }
3214 {
3217 {
3220 }
3223 }
3227 {
3232 {
3233 used_part_t up;
3245 }
3246 }
3252 }
3254 }
3256 /* Create structure field variables for structures used in this function. */
3258 static unsigned int
3260 {
3261 basic_block bb;
3262 safe_referenced_var_iterator rvi;
3264 tree var;
3267 free_used_part_map);
3270 {
3271 block_stmt_iterator bsi;
3273 {
3275 find_used_portions,
3276 NULL);
3277 }
3278 }
3280 {
3281 /* The C++ FE creates vars without DECL_SIZE set, for some reason. */
3288 }
3292 }
3294 static bool
3296 {
3298 }
3301 {
3315 };
3317 /* Reset the DECL_CALL_CLOBBERED flags on our referenced vars. In
3318 theory, this only needs to be done for globals. */
3320 static unsigned int
3322 {
3323 tree var;
3324 referenced_var_iterator rvi;
3329 }
3332 {
3346 };