| blob | f028b25b19a0df9562c2faa43d704a0ed60041ec |
1 /* Rewrite a program in Normal form into SSA.
2 Copyright (C) 2001-2013 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/>. */
44 /* This file builds the SSA form for a function as described in:
45 R. Cytron, J. Ferrante, B. Rosen, M. Wegman, and K. Zadeck. Efficiently
46 Computing Static Single Assignment Form and the Control Dependence
47 Graph. ACM Transactions on Programming Languages and Systems,
48 13(4):451-490, October 1991. */
50 /* Structure to map a variable VAR to the set of blocks that contain
51 definitions for VAR. */
52 struct def_blocks_d
53 {
54 /* Blocks that contain definitions of VAR. Bit I will be set if the
55 Ith block contains a definition of VAR. */
56 bitmap def_blocks;
58 /* Blocks that contain a PHI node for VAR. */
59 bitmap phi_blocks;
61 /* Blocks where VAR is live-on-entry. Similar semantics as
62 DEF_BLOCKS. */
63 bitmap livein_blocks;
64 };
69 /* Stack of trees used to restore the global currdefs to its original
70 state after completing rewriting of a block and its dominator
71 children. Its elements have the following properties:
73 - An SSA_NAME (N) indicates that the current definition of the
74 underlying variable should be set to the given SSA_NAME. If the
75 symbol associated with the SSA_NAME is not a GIMPLE register, the
76 next slot in the stack must be a _DECL node (SYM). In this case,
77 the name N in the previous slot is the current reaching
78 definition for SYM.
80 - A _DECL node indicates that the underlying variable has no
81 current definition.
83 - A NULL node at the top entry is used to mark the last slot
84 associated with the current block. */
88 /* Set of existing SSA names being replaced by update_ssa. */
91 /* Set of new SSA names being added by update_ssa. Note that both
92 NEW_SSA_NAMES and OLD_SSA_NAMES are dense bitmaps because most of
93 the operations done on them are presence tests. */
96 sbitmap interesting_blocks;
98 /* Set of SSA names that have been marked to be released after they
99 were registered in the replacement table. They will be finally
100 released after we finish updating the SSA web. */
103 /* vec of vec of PHIs to rewrite in a basic block. Element I corresponds
104 the to basic block with index I. Allocated once per compilation, *not*
105 released between different functions. */
108 /* The bitmap of non-NULL elements of PHIS_TO_REWRITE. */
111 /* Growth factor for NEW_SSA_NAMES and OLD_SSA_NAMES. These sets need
112 to grow as the callers to create_new_def_for will create new names on
113 the fly.
114 FIXME. Currently set to 1/3 to avoid frequent reallocations but still
115 need to find a reasonable growth strategy. */
116 #define NAME_SETS_GROWTH_FACTOR (MAX (3, num_ssa_names / 3))
119 /* The function the SSA updating data structures have been initialized for.
120 NULL if they need to be initialized by create_new_def_for. */
123 /* Global data to attach to the main dominator walk structure. */
124 struct mark_def_sites_global_data
125 {
126 /* This bitmap contains the variables which are set before they
127 are used in a basic block. */
128 bitmap kills;
129 };
131 /* Information stored for both SSA names and decls. */
132 struct common_info_d
133 {
134 /* This field indicates whether or not the variable may need PHI nodes.
135 See the enum's definition for more detailed information about the
136 states. */
139 /* The current reaching definition replacing this var. */
140 tree current_def;
142 /* Definitions for this var. */
144 };
146 /* The information associated with decls and SSA names. */
149 /* Information stored for decls. */
150 struct var_info_d
151 {
152 /* The variable. */
153 tree var;
155 /* Information stored for both SSA names and decls. */
157 };
159 /* The information associated with decls. */
163 /* VAR_INFOS hashtable helpers. */
166 {
171 };
173 inline hashval_t
175 {
177 }
181 {
183 }
186 /* Each entry in VAR_INFOS contains an element of type STRUCT
187 VAR_INFO_D. */
191 /* Information stored for SSA names. */
192 struct ssa_name_info
193 {
194 /* Age of this record (so that info_for_ssa_name table can be cleared
195 quickly); if AGE < CURRENT_INFO_FOR_SSA_NAME_AGE, then the fields
196 are assumed to be null. */
199 /* Replacement mappings, allocated from update_ssa_obstack. */
200 bitmap repl_set;
202 /* Information stored for both SSA names and decls. */
204 };
206 /* The information associated with names. */
214 /* The set of blocks affected by update_ssa. */
217 /* The main entry point to the SSA renamer (rewrite_blocks) may be
218 called several times to do different, but related, tasks.
219 Initially, we need it to rename the whole program into SSA form.
220 At other times, we may need it to only rename into SSA newly
221 exposed symbols. Finally, we can also call it to incrementally fix
222 an already built SSA web. */
224 /* Convert the whole function into SSA form. */
225 REWRITE_ALL,
227 /* Incrementally update the SSA web by replacing existing SSA
228 names with new ones. See update_ssa for details. */
229 REWRITE_UPDATE
230 };
235 /* Prototypes for debugging functions. */
253 /* The set of symbols we ought to re-write into SSA form in update_ssa. */
257 /* Mark SYM for renaming. */
259 static void
261 {
266 }
268 /* Return true if SYM is marked for renaming. */
270 static bool
272 {
276 }
279 /* Return true if STMT needs to be rewritten. When renaming a subset
280 of the variables, not all statements will be processed. This is
281 decided in mark_def_sites. */
285 {
287 }
290 /* Set the rewrite marker on STMT to the value given by REWRITE_P. */
294 {
296 }
299 /* Return true if the DEFs created by statement STMT should be
300 registered when marking new definition sites. This is slightly
301 different than rewrite_uses_p: it's used by update_ssa to
302 distinguish statements that need to have both uses and defs
303 processed from those that only need to have their defs processed.
304 Statements that define new SSA names only need to have their defs
305 registered, but they don't need to have their uses renamed. */
309 {
311 }
314 /* If REGISTER_DEFS_P is true, mark STMT to have its DEFs registered. */
318 {
320 }
323 /* Get the information associated with NAME. */
327 {
332 /* Re-allocate the vector at most once per update/into-SSA. */
336 /* But allocate infos lazily. */
339 {
344 }
347 {
355 }
358 }
360 /* Return and allocate the auxiliar information for DECL. */
364 {
370 {
375 }
377 }
380 /* Clears info for SSA names. */
382 static void
384 {
385 current_info_for_ssa_name_age++;
387 /* If current_info_for_ssa_name_age wraps we use stale information.
388 Asser that this does not happen. */
390 }
393 /* Get access to the auxiliar information stored per SSA name or decl. */
397 {
400 else
402 }
405 /* Return the current definition for VAR. */
407 tree
409 {
411 }
414 /* Sets current definition of VAR to DEF. */
416 void
418 {
420 }
422 /* Cleans up the REWRITE_THIS_STMT and REGISTER_DEFS_IN_THIS_STMT flags for
423 all statements in basic block BB. */
425 static void
427 {
428 gimple stmt;
429 gimple_stmt_iterator gsi;
432 {
436 }
439 {
442 /* We are going to use the operand cache API, such as
443 SET_USE, SET_DEF, and FOR_EACH_IMM_USE_FAST. The operand
444 cache for each statement should be up-to-date. */
448 }
449 }
451 /* Mark block BB as interesting for update_ssa. */
453 static void
455 {
460 }
462 /* Return the set of blocks where variable VAR is defined and the blocks
463 where VAR is live on entry (livein). If no entry is found in
464 DEF_BLOCKS, a new one is created and returned. */
468 {
471 {
475 }
478 }
481 /* Mark block BB as the definition site for variable VAR. PHI_P is true if
482 VAR is defined by a PHI node. */
484 static void
486 {
488 common_info_p info;
493 /* Set the bit corresponding to the block where VAR is defined. */
498 /* Keep track of whether or not we may need to insert PHI nodes.
500 If we are in the UNKNOWN state, then this is the first definition
501 of VAR. Additionally, we have not seen any uses of VAR yet, so
502 we do not need a PHI node for this variable at this time (i.e.,
503 transition to NEED_PHI_STATE_NO).
505 If we are in any other state, then we either have multiple definitions
506 of this variable occurring in different blocks or we saw a use of the
507 variable which was not dominated by the block containing the
508 definition(s). In this case we may need a PHI node, so enter
509 state NEED_PHI_STATE_MAYBE. */
512 else
514 }
517 /* Mark block BB as having VAR live at the entry to BB. */
519 static void
521 {
522 common_info_p info;
528 /* Set the bit corresponding to the block where VAR is live in. */
531 /* Keep track of whether or not we may need to insert PHI nodes.
533 If we reach here in NEED_PHI_STATE_NO, see if this use is dominated
534 by the single block containing the definition(s) of this variable. If
535 it is, then we remain in NEED_PHI_STATE_NO, otherwise we transition to
536 NEED_PHI_STATE_MAYBE. */
538 {
545 }
546 else
548 }
551 /* Return true if NAME is in OLD_SSA_NAMES. */
555 {
561 }
564 /* Return true if NAME is in NEW_SSA_NAMES. */
568 {
574 }
577 /* Return the names replaced by NEW_TREE (i.e., REPL_TBL[NEW_TREE].SET). */
581 {
583 }
586 /* Add OLD to REPL_TBL[NEW_TREE].SET. */
590 {
595 }
598 /* Add a new mapping NEW_TREE -> OLD REPL_TBL. Every entry N_i in REPL_TBL
599 represents the set of names O_1 ... O_j replaced by N_i. This is
600 used by update_ssa and its helpers to introduce new SSA names in an
601 already formed SSA web. */
603 static void
605 {
606 /* OLD and NEW_TREE must be different SSA names for the same symbol. */
610 /* We may need to grow NEW_SSA_NAMES and OLD_SSA_NAMES because our
611 caller may have created new names since the set was created. */
613 {
617 }
619 /* Update the REPL_TBL table. */
622 /* If OLD had already been registered as a new name, then all the
623 names that OLD replaces should also be replaced by NEW_TREE. */
627 /* Register NEW_TREE and OLD in NEW_SSA_NAMES and OLD_SSA_NAMES,
628 respectively. */
631 }
634 /* Call back for walk_dominator_tree used to collect definition sites
635 for every variable in the function. For every statement S in block
636 BB:
638 1- Variables defined by S in the DEFS of S are marked in the bitmap
639 KILLS.
641 2- If S uses a variable VAR and there is no preceding kill of VAR,
642 then it is marked in the LIVEIN_BLOCKS bitmap associated with VAR.
644 This information is used to determine which variables are live
645 across block boundaries to reduce the number of PHI nodes
646 we create. */
648 static void
650 {
651 tree def;
652 use_operand_p use_p;
653 ssa_op_iter iter;
655 /* Since this is the first time that we rewrite the program into SSA
656 form, force an operand scan on every statement. */
664 {
666 {
670 }
674 }
676 /* If a variable is used before being set, then the variable is live
677 across a block boundary, so mark it live-on-entry to BB. */
679 {
685 }
687 /* Now process the defs. Mark BB as the definition block and add
688 each def to the set of killed symbols. */
690 {
695 }
697 /* If we found the statement interesting then also mark the block BB
698 as interesting. */
701 }
703 /* Structure used by prune_unused_phi_nodes to record bounds of the intervals
704 in the dfs numbering of the dominance tree. */
706 struct dom_dfsnum
707 {
708 /* Basic block whose index this entry corresponds to. */
711 /* The dfs number of this node. */
713 };
715 /* Compares two entries of type struct dom_dfsnum by dfs_num field. Callback
716 for qsort. */
718 static int
720 {
725 }
727 /* Among the intervals starting at the N points specified in DEFS, find
728 the one that contains S, and return its bb_index. */
730 static unsigned
732 {
736 {
740 else
742 }
745 }
747 /* Clean bits from PHIS for phi nodes whose value cannot be used in USES.
748 KILLS is a bitmap of blocks where the value is defined before any use. */
750 static void
752 {
754 bitmap_iterator bi;
756 bitmap live_phis;
758 edge e;
759 edge_iterator ei;
760 bitmap to_remove;
765 {
768 }
770 /* The phi must dominate a use, or an argument of a live phi. Also, we
771 do not create any phi nodes in def blocks, unless they are also livein. */
776 {
779 }
781 /* We want to remove the unnecessary phi nodes, but we do not want to compute
782 liveness information, as that may be linear in the size of CFG, and if
783 there are lot of different variables to rewrite, this may lead to quadratic
784 behavior.
786 Instead, we basically emulate standard dce. We put all uses to worklist,
787 then for each of them find the nearest def that dominates them. If this
788 def is a phi node, we mark it live, and if it was not live before, we
789 add the predecessors of its basic block to the worklist.
791 To quickly locate the nearest def that dominates use, we use dfs numbering
792 of the dominance tree (that is already available in order to speed up
793 queries). For each def, we have the interval given by the dfs number on
794 entry to and on exit from the corresponding subtree in the dominance tree.
795 The nearest dominator for a given use is the smallest of these intervals
796 that contains entry and exit dfs numbers for the basic block with the use.
797 If we store the bounds for all the uses to an array and sort it, we can
798 locate the nearest dominating def in logarithmic time by binary search.*/
806 {
813 }
819 /* Now each DEFS entry contains the number of the basic block to that the
820 dfs number corresponds. Change them to the number of basic block that
821 corresponds to the interval following the dfs number. Also, for the
822 dfs_out numbers, increase the dfs number by one (so that it corresponds
823 to the start of the following interval, not to the end of the current
824 one). We use WORKLIST as a stack. */
830 {
833 {
834 /* This is a closing element. Interval corresponding to the top
835 of the stack after removing it follows. */
840 }
841 else
842 {
843 /* Opening element. Nothing to do, just push it to the stack and move
844 it to the correct position. */
849 }
851 /* If this interval starts at the same point as the previous one, cancel
852 the previous one. */
855 else
856 n_defs++;
857 }
861 /* Now process the uses. */
864 {
866 }
869 {
874 /* If there is a phi node in USE_BB, it is made live. Otherwise,
875 find the def that dominates the immediate dominator of USE_BB
876 (the kill in USE_BB does not dominate the use). */
879 else
880 {
886 }
888 /* If the phi node is already live, there is nothing to do. */
892 /* Add the new uses to the worklist. */
895 {
900 /* In case there is a kill directly in the use block, do not record
901 the use (this is also necessary for correctness, as we assume that
902 uses dominated by a def directly in their block have been filtered
903 out before). */
909 }
910 }
916 }
918 /* Return the set of blocks where variable VAR is defined and the blocks
919 where VAR is live on entry (livein). Return NULL, if no entry is
920 found in DEF_BLOCKS. */
924 {
929 }
932 /* Marks phi node PHI in basic block BB for rewrite. */
934 static void
936 {
937 gimple_vec phis;
959 }
961 /* Insert PHI nodes for variable VAR using the iterated dominance
962 frontier given in PHI_INSERTION_POINTS. If UPDATE_P is true, this
963 function assumes that the caller is incrementally updating the
964 existing SSA form, in which case VAR may be an SSA name instead of
965 a symbol.
967 PHI_INSERTION_POINTS is updated to reflect nodes that already had a
968 PHI node for VAR. On exit, only the nodes that received a PHI node
969 for VAR will be present in PHI_INSERTION_POINTS. */
971 static void
973 {
975 edge e;
976 gimple phi;
977 basic_block bb;
978 bitmap_iterator bi;
981 /* Remove the blocks where we already have PHI nodes for VAR. */
984 /* Remove obviously useless phi nodes. */
988 /* And insert the PHI nodes. */
990 {
996 {
1000 }
1004 {
1005 /* If we are rewriting SSA names, create the LHS of the PHI
1006 node by duplicating VAR. This is useful in the case of
1007 pointers, to also duplicate pointer attributes (alias
1008 information, in particular). */
1009 edge_iterator ei;
1010 tree new_lhs;
1017 /* Add VAR to every argument slot of PHI. We need VAR in
1018 every argument so that rewrite_update_phi_arguments knows
1019 which name is this PHI node replacing. If VAR is a
1020 symbol marked for renaming, this is not necessary, the
1021 renamer will use the symbol on the LHS to get its
1022 reaching definition. */
1025 }
1026 else
1027 {
1028 tree tracked_var;
1035 {
1038 phi);
1041 }
1042 }
1044 /* Mark this PHI node as interesting for update_ssa. */
1047 }
1048 }
1050 /* Sort var_infos after DECL_UID of their var. */
1052 static int
1054 {
1059 else
1061 }
1063 /* Insert PHI nodes at the dominance frontier of blocks with variable
1064 definitions. DFS contains the dominance frontier information for
1065 the flowgraph. */
1067 static void
1069 {
1072 var_info_p info;
1082 /* Do two stages to avoid code generation differences for UID
1083 differences but no UID ordering differences. */
1087 {
1091 }
1096 }
1099 /* Push SYM's current reaching definition into BLOCK_DEFS_STACK and
1100 register DEF (an SSA_NAME) to be a new definition for SYM. */
1102 static void
1104 {
1106 tree currdef;
1108 /* If this variable is set in a single basic block and all uses are
1109 dominated by the set(s) in that single basic block, then there is
1110 no reason to record anything for this variable in the block local
1111 definition stacks. Doing so just wastes time and memory.
1113 This is the same test to prune the set of variables which may
1114 need PHI nodes. So we just use that information since it's already
1115 computed and available for us to use. */
1117 {
1120 }
1124 /* If SYM is not a GIMPLE register, then CURRDEF may be a name whose
1125 SSA_NAME_VAR is not necessarily SYM. In this case, also push SYM
1126 in the stack so that we know which symbol is being defined by
1127 this SSA name when we unwind the stack. */
1131 /* Push the current reaching definition into BLOCK_DEFS_STACK. This
1132 stack is later used by the dominator tree callbacks to restore
1133 the reaching definitions for all the variables defined in the
1134 block after a recursive visit to all its immediately dominated
1135 blocks. If there is no current reaching definition, then just
1136 record the underlying _DECL node. */
1139 /* Set the current reaching definition for SYM to be DEF. */
1141 }
1144 /* Perform a depth-first traversal of the dominator tree looking for
1145 variables to rename. BB is the block where to start searching.
1146 Renaming is a five step process:
1148 1- Every definition made by PHI nodes at the start of the blocks is
1149 registered as the current definition for the corresponding variable.
1151 2- Every statement in BB is rewritten. USE and VUSE operands are
1152 rewritten with their corresponding reaching definition. DEF and
1153 VDEF targets are registered as new definitions.
1155 3- All the PHI nodes in successor blocks of BB are visited. The
1156 argument corresponding to BB is replaced with its current reaching
1157 definition.
1159 4- Recursively rewrite every dominator child block of BB.
1161 5- Restore (in reverse order) the current reaching definition for every
1162 new definition introduced in this block. This is done so that when
1163 we return from the recursive call, all the current reaching
1164 definitions are restored to the names that were valid in the
1165 dominator parent of BB. */
1167 /* Return the current definition for variable VAR. If none is found,
1168 create a new SSA name to act as the zeroth definition for VAR. */
1170 static tree
1172 {
1174 tree currdef;
1176 /* Lookup the current reaching definition for VAR. */
1179 /* If there is no reaching definition for VAR, create and register a
1180 default definition for it (if needed). */
1182 {
1185 }
1187 /* Return the current reaching definition for VAR, or the default
1188 definition, if we had to create one. */
1190 }
1193 /* Helper function for rewrite_stmt. Rewrite uses in a debug stmt. */
1195 static void
1197 {
1198 use_operand_p use_p;
1199 ssa_op_iter iter;
1203 {
1209 {
1211 {
1212 gimple_stmt_iterator gsi
1215 /* Search a few source bind stmts at the start of first bb to
1216 see if a DEBUG_EXPR_DECL can't be reused. */
1220 {
1225 {
1229 else
1231 }
1232 }
1233 /* If not, add a new source bind stmt. */
1235 {
1236 gimple def_temp;
1244 }
1246 }
1247 }
1248 else
1249 {
1250 /* Check if info->current_def can be trusted. */
1252 basic_block def_bb
1256 /* If definition is in current bb, it is fine. */
1258 ;
1259 /* If definition bb doesn't dominate the current bb,
1260 it can't be used. */
1263 /* If there is just one definition and dominates the current
1264 bb, it is fine. */
1266 ;
1267 else
1268 {
1271 /* If there are some non-debug uses in the current bb,
1272 it is fine. */
1274 ;
1275 /* Otherwise give up for now. */
1276 else
1278 }
1279 }
1281 {
1285 }
1287 }
1290 }
1292 /* SSA Rewriting Step 2. Rewrite every variable used in each statement in
1293 the block with its immediate reaching definitions. Update the current
1294 definition of a variable when a new real or virtual definition is found. */
1296 static void
1298 {
1299 use_operand_p use_p;
1300 def_operand_p def_p;
1301 ssa_op_iter iter;
1304 /* If mark_def_sites decided that we don't need to rewrite this
1305 statement, ignore it. */
1311 {
1315 }
1317 /* Step 1. Rewrite USES in the statement. */
1319 {
1322 else
1324 {
1328 }
1329 }
1331 /* Step 2. Register the statement's DEF operands. */
1334 {
1336 tree name;
1337 tree tracked_var;
1343 {
1344 /* If we rewrite a DECL into SSA form then drop its
1345 clobber stmts and replace uses with a new default def. */
1351 }
1359 {
1362 }
1363 }
1364 }
1367 /* SSA Rewriting Step 3. Visit all the successor blocks of BB looking for
1368 PHI nodes. For every PHI node found, add a new argument containing the
1369 current reaching definition for the variable and the edge through which
1370 that definition is reaching the PHI node. */
1372 static void
1374 {
1375 edge e;
1376 edge_iterator ei;
1379 {
1380 gimple phi;
1381 gimple_stmt_iterator gsi;
1385 {
1387 location_t loc;
1392 /* Virtual operand PHI args do not need a location. */
1395 else
1398 }
1399 }
1400 }
1402 /* SSA Rewriting Step 1. Initialization, create a block local stack
1403 of reaching definitions for new SSA names produced in this block
1404 (BLOCK_DEFS). Register new definitions for every PHI node in the
1405 block. */
1407 static void
1409 basic_block bb)
1410 {
1411 gimple_stmt_iterator gsi;
1416 /* Mark the unwind point for this block. */
1419 /* Step 1. Register new definitions for every PHI node in the block.
1420 Conceptually, all the PHI nodes are executed in parallel and each PHI
1421 node introduces a new version for the associated variable. */
1423 {
1426 }
1428 /* Step 2. Rewrite every variable used in each statement in the block
1429 with its immediate reaching definitions. Update the current definition
1430 of a variable when a new real or virtual definition is found. */
1435 /* Step 3. Visit all the successor blocks of BB looking for PHI nodes.
1436 For every PHI node found, add a new argument containing the current
1437 reaching definition for the variable and the edge through which that
1438 definition is reaching the PHI node. */
1440 }
1444 /* Called after visiting all the statements in basic block BB and all
1445 of its dominator children. Restore CURRDEFS to its original value. */
1447 static void
1449 basic_block bb ATTRIBUTE_UNUSED)
1450 {
1451 /* Restore CURRDEFS to its original state. */
1453 {
1461 {
1462 /* If we recorded an SSA_NAME, then make the SSA_NAME the
1463 current definition of its underlying variable. Note that
1464 if the SSA_NAME is not for a GIMPLE register, the symbol
1465 being defined is stored in the next slot in the stack.
1466 This mechanism is needed because an SSA name for a
1467 non-register symbol may be the definition for more than
1468 one symbol (e.g., SFTs, aliased variables, etc). */
1473 }
1474 else
1475 {
1476 /* If we recorded anything else, it must have been a _DECL
1477 node and its current reaching definition must have been
1478 NULL. */
1481 }
1484 }
1485 }
1488 /* Dump bitmap SET (assumed to contain VAR_DECLs) to FILE. */
1490 void
1492 {
1494 {
1495 bitmap_iterator bi;
1501 {
1504 }
1507 }
1508 else
1510 }
1513 /* Dump bitmap SET (assumed to contain VAR_DECLs) to FILE. */
1515 DEBUG_FUNCTION void
1517 {
1520 }
1523 /* Dump the renaming stack (block_defs_stack) to FILE. Traverse the
1524 stack up to a maximum of N levels. If N is -1, the whole stack is
1525 dumped. New levels are created when the dominator tree traversal
1526 used for renaming enters a new sub-tree. */
1528 void
1530 {
1541 {
1546 {
1547 i++;
1552 }
1555 {
1558 }
1559 else
1560 {
1563 {
1564 j--;
1566 }
1567 }
1574 else
1577 }
1578 }
1581 /* Dump the renaming stack (block_defs_stack) to stderr. Traverse the
1582 stack up to a maximum of N levels. If N is -1, the whole stack is
1583 dumped. New levels are created when the dominator tree traversal
1584 used for renaming enters a new sub-tree. */
1586 DEBUG_FUNCTION void
1588 {
1590 }
1593 /* Dump the current reaching definition of every symbol to FILE. */
1595 void
1597 {
1599 tree var;
1606 {
1613 else
1616 }
1617 }
1620 /* Dump the current reaching definition of every symbol to stderr. */
1622 DEBUG_FUNCTION void
1624 {
1626 }
1629 /* Dump SSA information to FILE. */
1631 void
1633 {
1643 }
1646 /* Dump SSA information to stderr. */
1648 DEBUG_FUNCTION void
1650 {
1652 }
1655 /* Dump statistics for the hash table HTAB. */
1657 static void
1659 {
1664 }
1667 /* Dump SSA statistics on FILE. */
1669 void
1671 {
1673 {
1678 }
1679 }
1682 /* Dump SSA statistics on stderr. */
1684 DEBUG_FUNCTION void
1686 {
1688 }
1691 /* Callback for htab_traverse to dump the VAR_INFOS hash table. */
1693 int
1695 {
1708 }
1711 /* Dump the VAR_INFOS hash table on FILE. */
1713 void
1715 {
1719 }
1722 /* Dump the VAR_INFOS hash table on stderr. */
1724 DEBUG_FUNCTION void
1726 {
1728 }
1731 /* Register NEW_NAME to be the new reaching definition for OLD_NAME. */
1735 {
1739 /* Push the current reaching definition into BLOCK_DEFS_STACK.
1740 This stack is later used by the dominator tree callbacks to
1741 restore the reaching definitions for all the variables
1742 defined in the block after a recursive visit to all its
1743 immediately dominated blocks. */
1748 /* Set the current reaching definition for OLD_NAME to be
1749 NEW_NAME. */
1751 }
1754 /* Register NEW_NAME to be the new reaching definition for all the
1755 names in OLD_NAMES. Used by the incremental SSA update routines to
1756 replace old SSA names with new ones. */
1760 {
1761 bitmap_iterator bi;
1766 }
1770 /* If the operand pointed to by USE_P is a name in OLD_SSA_NAMES or
1771 it is a symbol marked for renaming, replace it with USE_P's current
1772 reaching definition. */
1776 {
1788 }
1791 /* Same as maybe_replace_use, but without introducing default stmts,
1792 returning false to indicate a need to do so. */
1796 {
1804 {
1806 /* We can't assume that, if there's no current definition, the
1807 default one should be used. It could be the case that we've
1808 rearranged blocks so that the earlier definition no longer
1809 dominates the use. */
1812 }
1813 else
1820 }
1823 /* If the operand pointed to by DEF_P is an SSA name in NEW_SSA_NAMES
1824 or OLD_SSA_NAMES, or if it is a symbol marked for renaming,
1825 register it as the current definition for the names replaced by
1826 DEF_P. */
1830 gimple_stmt_iterator gsi)
1831 {
1835 /* If DEF is a naked symbol that needs renaming, create a new
1836 name for it. */
1838 {
1840 {
1841 tree tracked_var;
1848 {
1850 /* If stmt ends the bb, insert the debug stmt on the single
1851 non-EH edge from the stmt. */
1853 {
1855 edge_iterator ei;
1859 {
1862 }
1863 /* If there are other predecessors to ef->dest, then
1864 there must be PHI nodes for the modified
1865 variable, and therefore there will be debug bind
1866 stmts after the PHI nodes. The debug bind notes
1867 we'd insert would force the creation of a new
1868 block (diverging codegen) and be redundant with
1869 the post-PHI bind stmts, so don't add them.
1871 As for the exit edge, there wouldn't be redundant
1872 bind stmts, but there wouldn't be a PC to bind
1873 them to either, so avoid diverging the CFG. */
1876 {
1877 /* If there were PHI nodes in the node, we'd
1878 have to make sure the value we're binding
1879 doesn't need rewriting. But there shouldn't
1880 be PHI nodes in a single-predecessor block,
1881 so we just add the note. */
1883 }
1884 }
1885 else
1887 }
1888 }
1891 }
1892 else
1893 {
1894 /* If DEF is a new name, register it as a new definition
1895 for all the names replaced by DEF. */
1899 /* If DEF is an old name, register DEF as a new
1900 definition for itself. */
1903 }
1904 }
1907 /* Update every variable used in the statement pointed-to by SI. The
1908 statement is assumed to be in SSA form already. Names in
1909 OLD_SSA_NAMES used by SI will be updated to their current reaching
1910 definition. Names in OLD_SSA_NAMES or NEW_SSA_NAMES defined by SI
1911 will be registered as a new definition for their corresponding name
1912 in OLD_SSA_NAMES. */
1914 static void
1916 {
1917 use_operand_p use_p;
1918 def_operand_p def_p;
1919 ssa_op_iter iter;
1921 /* Only update marked statements. */
1926 {
1929 }
1931 /* Rewrite USES included in OLD_SSA_NAMES and USES whose underlying
1932 symbol is marked for renaming. */
1934 {
1936 {
1941 {
1944 }
1947 {
1948 /* DOM sometimes threads jumps in such a way that a
1949 debug stmt ends up referencing a SSA variable that no
1950 longer dominates the debug stmt, but such that all
1951 incoming definitions refer to the same definition in
1952 an earlier dominator. We could try to recover that
1953 definition somehow, but this will have to do for now.
1955 Introducing a default definition, which is what
1956 maybe_replace_use() would do in such cases, may
1957 modify code generation, for the otherwise-unused
1958 default definition would never go away, modifying SSA
1959 version numbers all over. */
1962 }
1963 }
1964 else
1965 {
1968 }
1969 }
1971 /* Register definitions of names in NEW_SSA_NAMES and OLD_SSA_NAMES.
1972 Also register definitions for names whose underlying symbol is
1973 marked for renaming. */
1977 }
1980 /* Visit all the successor blocks of BB looking for PHI nodes. For
1981 every PHI node found, check if any of its arguments is in
1982 OLD_SSA_NAMES. If so, and if the argument has a current reaching
1983 definition, replace it. */
1985 static void
1987 {
1988 edge e;
1989 edge_iterator ei;
1993 {
1994 gimple phi;
1995 gimple_vec phis;
2002 {
2004 use_operand_p arg_p;
2017 {
2018 /* When updating a PHI node for a recently introduced
2019 symbol we may find NULL arguments. That's why we
2020 take the symbol from the LHS of the PHI node. */
2023 }
2024 else
2025 {
2032 }
2034 /* Update the argument if there is a reaching def. */
2036 {
2037 source_location locus;
2042 /* Virtual operands do not need a location. */
2045 else
2046 {
2049 /* Single element PHI nodes behave like copies, so get the
2050 location from the phi argument. */
2054 else
2056 }
2059 }
2064 }
2065 }
2066 }
2069 /* Initialization of block data structures for the incremental SSA
2070 update pass. Create a block local stack of reaching definitions
2071 for new SSA names produced in this block (BLOCK_DEFS). Register
2072 new definitions for every PHI node in the block. */
2074 static void
2076 basic_block bb)
2077 {
2079 gimple_stmt_iterator gsi;
2085 /* Mark the unwind point for this block. */
2091 /* Mark the LHS if any of the arguments flows through an abnormal
2092 edge. */
2095 /* If any of the PHI nodes is a replacement for a name in
2096 OLD_SSA_NAMES or it's one of the names in NEW_SSA_NAMES, then
2097 register it as a new definition for its corresponding name. Also
2098 register definitions for names whose underlying symbols are
2099 marked for renaming. */
2101 {
2113 else
2114 {
2116 /* If LHS is a new name, register a new definition for all
2117 the names replaced by LHS. */
2121 /* If LHS is an OLD name, register it as a new definition
2122 for itself. */
2125 }
2129 }
2131 /* Step 2. Rewrite every variable used in each statement in the block. */
2133 {
2137 }
2139 /* Step 3. Update PHI nodes. */
2141 }
2143 /* Called after visiting block BB. Unwind BLOCK_DEFS_STACK to restore
2144 the current reaching definition of every name re-written in BB to
2145 the original reaching definition before visiting BB. This
2146 unwinding must be done in the opposite order to what is done in
2147 register_new_update_set. */
2149 static void
2151 basic_block bb ATTRIBUTE_UNUSED)
2152 {
2154 {
2156 tree saved_def;
2158 /* NULL indicates the unwind stop point for this block (see
2159 rewrite_update_enter_block). */
2165 }
2166 }
2169 /* Rewrite the actual blocks, statements, and PHI arguments, to be in SSA
2170 form.
2172 ENTRY indicates the block where to start. Every block dominated by
2173 ENTRY will be rewritten.
2175 WHAT indicates what actions will be taken by the renamer (see enum
2176 rewrite_mode).
2178 BLOCKS are the set of interesting blocks for the dominator walker
2179 to process. If this set is NULL, then all the nodes dominated
2180 by ENTRY are walked. Otherwise, blocks dominated by ENTRY that
2181 are not present in BLOCKS are ignored. */
2183 static void
2185 {
2188 /* Rewrite all the basic blocks in the program. */
2191 /* Setup callbacks for the generic dominator tree walker. */
2197 {
2200 }
2202 {
2205 }
2206 else
2211 /* Initialize the dominator walker. */
2214 /* Recursively walk the dominator tree rewriting each statement in
2215 each basic block. */
2218 /* Finalize the dominator walker. */
2221 /* Debugging dumps. */
2223 {
2227 }
2232 }
2235 /* Block processing routine for mark_def_sites. Clear the KILLS bitmap
2236 at the start of each block, and call mark_def_sites for each statement. */
2238 static void
2240 {
2242 bitmap kills;
2243 gimple_stmt_iterator gsi;
2251 }
2254 /* Mark the definition site blocks for each variable, so that we know
2255 where the variable is actually live.
2257 The INTERESTING_BLOCKS global will be filled in with all the blocks
2258 that should be processed by the renamer. It is assumed that the
2259 caller has already initialized and zeroed it. */
2261 static void
2263 {
2267 /* Setup callbacks for the generic dominator tree walker to find and
2268 mark definition sites. */
2274 /* Notice that this bitmap is indexed using variable UIDs, so it must be
2275 large enough to accommodate all the variables referenced in the
2276 function, not just the ones we are renaming. */
2280 /* We do not have any local data. */
2283 /* Initialize the dominator walker. */
2286 /* Recursively walk the dominator tree. */
2289 /* Finalize the dominator walker. */
2292 /* We no longer need this bitmap, clear and free it. */
2294 }
2297 /* Initialize internal data needed during renaming. */
2299 static void
2301 {
2304 /* Allocate memory for the DEF_BLOCKS hash table. */
2309 }
2312 /* Deallocate internal data structures used by the renamer. */
2314 static void
2316 {
2325 }
2327 /* Main entry point into the SSA builder. The renaming process
2328 proceeds in four main phases:
2330 1- Compute dominance frontier and immediate dominators, needed to
2331 insert PHI nodes and rename the function in dominator tree
2332 order.
2334 2- Find and mark all the blocks that define variables
2335 (mark_def_site_blocks).
2337 3- Insert PHI nodes at dominance frontiers (insert_phi_nodes).
2339 4- Rename all the blocks (rewrite_blocks) and statements in the program.
2341 Steps 3 and 4 are done using the dominator tree walker
2342 (walk_dominator_tree). */
2344 static unsigned int
2346 {
2348 basic_block bb;
2351 /* Initialize operand data structures. */
2354 /* Initialize internal data needed by the renamer. */
2357 /* Initialize the set of interesting blocks. The callback
2358 mark_def_sites will add to this set those blocks that the renamer
2359 should process. */
2363 /* Initialize dominance frontier. */
2368 /* 1- Compute dominance frontiers. */
2372 /* 2- Find and mark definition sites. */
2375 /* 3- Insert PHI nodes at dominance frontiers of definition blocks. */
2378 /* 4- Rename all the blocks. */
2381 /* Free allocated memory. */
2390 /* Try to get rid of all gimplifier generated temporaries by making
2391 its SSA names anonymous. This way we can garbage collect them
2392 all after removing unused locals which we do in our TODO. */
2394 {
2407 }
2410 }
2414 {
2415 {
2416 GIMPLE_PASS,
2429 TODO_verify_ssa
2431 }
2432 };
2435 /* Mark the definition of VAR at STMT and BB as interesting for the
2436 renamer. BLOCKS is the set of blocks that need updating. */
2438 static void
2440 {
2445 {
2450 /* If VAR is an SSA name in NEW_SSA_NAMES, this is a definition
2451 site for both itself and all the old names replaced by it. */
2453 {
2454 bitmap_iterator bi;
2460 }
2461 }
2462 }
2465 /* Mark the use of VAR at STMT and BB as interesting for the
2466 renamer. INSERT_PHI_P is true if we are going to insert new PHI
2467 nodes. */
2471 {
2479 else
2480 {
2485 }
2487 /* If VAR has not been defined in BB, then it is live-on-entry
2488 to BB. Note that we cannot just use the block holding VAR's
2489 definition because if VAR is one of the names in OLD_SSA_NAMES,
2490 it will have several definitions (itself and all the names that
2491 replace it). */
2493 {
2497 }
2498 }
2501 /* Do a dominator walk starting at BB processing statements that
2502 reference symbols in SSA operands. This is very similar to
2503 mark_def_sites, but the scan handles statements whose operands may
2504 already be SSA names.
2506 If INSERT_PHI_P is true, mark those uses as live in the
2507 corresponding block. This is later used by the PHI placement
2508 algorithm to make PHI pruning decisions.
2510 FIXME. Most of this would be unnecessary if we could associate a
2511 symbol to all the SSA names that reference it. But that
2512 sounds like it would be expensive to maintain. Still, it
2513 would be interesting to see if it makes better sense to do
2514 that. */
2516 static void
2518 {
2519 basic_block son;
2520 gimple_stmt_iterator si;
2521 edge e;
2522 edge_iterator ei;
2526 /* Process PHI nodes marking interesting those that define or use
2527 the symbols that we are interested in. */
2529 {
2542 /* Mark the uses in phi nodes as interesting. It would be more correct
2543 to process the arguments of the phi nodes of the successor edges of
2544 BB at the end of prepare_block_for_update, however, that turns out
2545 to be significantly more expensive. Doing it here is conservatively
2546 correct -- it may only cause us to believe a value to be live in a
2547 block that also contains its definition, and thus insert a few more
2548 phi nodes for it. */
2551 }
2553 /* Process the statements. */
2555 {
2556 gimple stmt;
2557 ssa_op_iter i;
2558 use_operand_p use_p;
2559 def_operand_p def_p;
2565 {
2570 }
2573 {
2579 }
2583 {
2588 }
2591 {
2597 }
2598 }
2600 /* Now visit all the blocks dominated by BB. */
2602 son;
2605 }
2608 /* Helper for prepare_names_to_update. Mark all the use sites for
2609 NAME as interesting. BLOCKS and INSERT_PHI_P are as in
2610 prepare_names_to_update. */
2612 static void
2614 {
2615 use_operand_p use_p;
2616 imm_use_iterator iter;
2619 {
2624 {
2628 }
2629 else
2630 {
2631 /* For regular statements, mark this as an interesting use
2632 for NAME. */
2634 }
2635 }
2636 }
2639 /* Helper for prepare_names_to_update. Mark the definition site for
2640 NAME as interesting. BLOCKS and INSERT_PHI_P are as in
2641 prepare_names_to_update. */
2643 static void
2645 {
2646 gimple stmt;
2647 basic_block bb;
2656 {
2660 }
2661 }
2664 /* Mark definition and use sites of names in NEW_SSA_NAMES and
2665 OLD_SSA_NAMES. INSERT_PHI_P is true if the caller wants to insert
2666 PHI nodes for newly created names. */
2668 static void
2670 {
2672 bitmap_iterator bi;
2673 sbitmap_iterator sbi;
2675 /* If a name N from NEW_SSA_NAMES is also marked to be released,
2676 remove it from NEW_SSA_NAMES so that we don't try to visit its
2677 defining basic block (which most likely doesn't exist). Notice
2678 that we cannot do the same with names in OLD_SSA_NAMES because we
2679 want to replace existing instances. */
2684 /* First process names in NEW_SSA_NAMES. Otherwise, uses of old
2685 names may be considered to be live-in on blocks that contain
2686 definitions for their replacements. */
2690 /* If an old name is in NAMES_TO_RELEASE, we cannot remove it from
2691 OLD_SSA_NAMES, but we have to ignore its definition site. */
2693 {
2697 }
2698 }
2701 /* Dump all the names replaced by NAME to FILE. */
2703 void
2705 {
2707 bitmap old_set;
2708 bitmap_iterator bi;
2715 {
2718 }
2721 }
2724 /* Dump all the names replaced by NAME to stderr. */
2726 DEBUG_FUNCTION void
2728 {
2730 }
2733 /* Dump SSA update information to FILE. */
2735 void
2737 {
2739 bitmap_iterator bi;
2745 {
2746 sbitmap_iterator sbi;
2754 }
2757 {
2761 }
2764 {
2767 {
2770 }
2772 }
2773 }
2776 /* Dump SSA update information to stderr. */
2778 DEBUG_FUNCTION void
2780 {
2782 }
2785 /* Initialize data structures used for incremental SSA updates. */
2787 static void
2789 {
2790 /* Reserve more space than the current number of names. The calls to
2791 add_new_name_mapping are typically done after creating new SSA
2792 names, so we'll need to reallocate these arrays. */
2803 }
2806 /* Deallocate data structures used for incremental SSA updates. */
2808 void
2810 {
2812 bitmap_iterator bi;
2825 {
2829 }
2837 {
2841 }
2847 }
2850 /* Create a new name for OLD_NAME in statement STMT and replace the
2851 operand pointed to by DEF_P with the newly created name. If DEF_P
2852 is NULL then STMT should be a GIMPLE assignment.
2853 Return the new name and register the replacement mapping <NEW, OLD> in
2854 update_ssa's tables. */
2856 tree
2858 {
2859 tree new_name;
2871 else
2875 {
2878 /* If needed, mark NEW_NAME as occurring in an abnormal PHI node. */
2880 }
2884 /* For the benefit of passes that will be updating the SSA form on
2885 their own, set the current reaching definition of OLD_NAME to be
2886 NEW_NAME. */
2892 }
2895 /* Mark virtual operands of FN for renaming by update_ssa. */
2897 void
2899 {
2902 }
2905 /* Return true if there is any work to be done by update_ssa
2906 for function FN. */
2908 bool
2910 {
2914 }
2916 /* Return true if name N has been registered in the replacement table. */
2918 bool
2920 {
2927 }
2930 /* Mark NAME to be released after update_ssa has finished. */
2932 void
2934 {
2941 }
2944 /* Insert new PHI nodes to replace VAR. DFS contains dominance
2945 frontier information. BLOCKS is the set of blocks to be updated.
2947 This is slightly different than the regular PHI insertion
2948 algorithm. The value of UPDATE_FLAGS controls how PHI nodes for
2949 real names (i.e., GIMPLE registers) are inserted:
2951 - If UPDATE_FLAGS == TODO_update_ssa, we are only interested in PHI
2952 nodes inside the region affected by the block that defines VAR
2953 and the blocks that define all its replacements. All these
2954 definition blocks are stored in DEF_BLOCKS[VAR]->DEF_BLOCKS.
2956 First, we compute the entry point to the region (ENTRY). This is
2957 given by the nearest common dominator to all the definition
2958 blocks. When computing the iterated dominance frontier (IDF), any
2959 block not strictly dominated by ENTRY is ignored.
2961 We then call the standard PHI insertion algorithm with the pruned
2962 IDF.
2964 - If UPDATE_FLAGS == TODO_update_ssa_full_phi, the IDF for real
2965 names is not pruned. PHI nodes are inserted at every IDF block. */
2967 static void
2970 {
2971 basic_block entry;
2974 bitmap_iterator bi;
2979 else
2982 /* Get all the definition sites for VAR. */
2985 /* No need to do anything if there were no definitions to VAR. */
2989 /* Compute the initial iterated dominance frontier. */
2994 {
2996 {
2997 /* If doing regular SSA updates for GIMPLE registers, we are
2998 only interested in IDF blocks dominated by the nearest
2999 common dominator of all the definition blocks. */
3007 }
3008 else
3009 {
3010 /* Otherwise, do not prune the IDF for VAR. */
3013 }
3014 }
3015 else
3016 {
3017 /* Otherwise, VAR is a symbol that needs to be put into SSA form
3018 for the first time, so we need to compute the full IDF for
3019 it. */
3021 }
3024 {
3025 /* Make sure that PRUNED_IDF blocks and all their feeding blocks
3026 are included in the region to be updated. The feeding blocks
3027 are important to guarantee that the PHI arguments are renamed
3028 properly. */
3030 /* FIXME, this is not needed if we are updating symbols. We are
3031 already starting at the ENTRY block anyway. */
3034 {
3035 edge e;
3036 edge_iterator ei;
3042 }
3045 }
3049 }
3051 /* Sort symbols_to_rename after their DECL_UID. */
3053 static int
3055 {
3061 }
3063 /* Given a set of newly created SSA names (NEW_SSA_NAMES) and a set of
3064 existing SSA names (OLD_SSA_NAMES), update the SSA form so that:
3066 1- The names in OLD_SSA_NAMES dominated by the definitions of
3067 NEW_SSA_NAMES are all re-written to be reached by the
3068 appropriate definition from NEW_SSA_NAMES.
3070 2- If needed, new PHI nodes are added to the iterated dominance
3071 frontier of the blocks where each of NEW_SSA_NAMES are defined.
3073 The mapping between OLD_SSA_NAMES and NEW_SSA_NAMES is setup by
3074 calling create_new_def_for to create new defs for names that the
3075 caller wants to replace.
3077 The caller cretaes the new names to be inserted and the names that need
3078 to be replaced by calling create_new_def_for for each old definition
3079 to be replaced. Note that the function assumes that the
3080 new defining statement has already been inserted in the IL.
3082 For instance, given the following code:
3084 1 L0:
3085 2 x_1 = PHI (0, x_5)
3086 3 if (x_1 < 10)
3087 4 if (x_1 > 7)
3088 5 y_2 = 0
3089 6 else
3090 7 y_3 = x_1 + x_7
3091 8 endif
3092 9 x_5 = x_1 + 1
3093 10 goto L0;
3094 11 endif
3096 Suppose that we insert new names x_10 and x_11 (lines 4 and 8).
3098 1 L0:
3099 2 x_1 = PHI (0, x_5)
3100 3 if (x_1 < 10)
3101 4 x_10 = ...
3102 5 if (x_1 > 7)
3103 6 y_2 = 0
3104 7 else
3105 8 x_11 = ...
3106 9 y_3 = x_1 + x_7
3107 10 endif
3108 11 x_5 = x_1 + 1
3109 12 goto L0;
3110 13 endif
3112 We want to replace all the uses of x_1 with the new definitions of
3113 x_10 and x_11. Note that the only uses that should be replaced are
3114 those at lines 5, 9 and 11. Also, the use of x_7 at line 9 should
3115 *not* be replaced (this is why we cannot just mark symbol 'x' for
3116 renaming).
3118 Additionally, we may need to insert a PHI node at line 11 because
3119 that is a merge point for x_10 and x_11. So the use of x_1 at line
3120 11 will be replaced with the new PHI node. The insertion of PHI
3121 nodes is optional. They are not strictly necessary to preserve the
3122 SSA form, and depending on what the caller inserted, they may not
3123 even be useful for the optimizers. UPDATE_FLAGS controls various
3124 aspects of how update_ssa operates, see the documentation for
3125 TODO_update_ssa*. */
3127 void
3129 {
3131 bitmap_iterator bi;
3134 sbitmap_iterator sbi;
3135 tree sym;
3137 /* Only one update flag should be set. */
3154 {
3155 /* If we only need to update virtuals, remove all the mappings for
3156 real names before proceeding. The caller is responsible for
3157 having dealt with the name mappings before calling update_ssa. */
3160 }
3169 /* Ensure that the dominance information is up-to-date. */
3174 /* If there are names defined in the replacement table, prepare
3175 definition and use sites for all the names in NEW_SSA_NAMES and
3176 OLD_SSA_NAMES. */
3178 {
3181 /* If all the names in NEW_SSA_NAMES had been marked for
3182 removal, and there are no symbols to rename, then there's
3183 nothing else to do. */
3187 }
3189 /* Next, determine the block at which to start the renaming process. */
3191 {
3192 /* If we rename bare symbols initialize the mapping to
3193 auxiliar info we need to keep track of. */
3196 /* If we have to rename some symbols from scratch, we need to
3197 start the process at the root of the CFG. FIXME, it should
3198 be possible to determine the nearest block that had a
3199 definition for each of the symbols that are marked for
3200 updating. For now this seems more work than it's worth. */
3203 /* Traverse the CFG looking for existing definitions and uses of
3204 symbols in SSA operands. Mark interesting blocks and
3205 statements and set local live-in information for the PHI
3206 placement heuristics. */
3209 #ifdef ENABLE_CHECKING
3211 {
3217 /* For all but virtual operands, which do not have SSA names
3218 with overlapping life ranges, ensure that symbols marked
3219 for renaming do not have existing SSA names associated with
3220 them as we do not re-write them out-of-SSA before going
3221 into SSA for the remaining symbol uses. */
3223 {
3229 }
3230 }
3231 #endif
3232 }
3233 else
3234 {
3235 /* Otherwise, the entry block to the region is the nearest
3236 common dominator for the blocks in BLOCKS. */
3238 blocks_to_update);
3239 }
3241 /* If requested, insert PHI nodes at the iterated dominance frontier
3242 of every block, creating new definitions for names in OLD_SSA_NAMES
3243 and for symbols found. */
3245 {
3248 /* If the caller requested PHI nodes to be added, compute
3249 dominance frontiers. */
3256 {
3257 sbitmap_iterator sbi;
3259 /* insert_update_phi_nodes_for will call add_new_name_mapping
3260 when inserting new PHI nodes, so the set OLD_SSA_NAMES
3261 will grow while we are traversing it (but it will not
3262 gain any new members). Copy OLD_SSA_NAMES to a temporary
3263 for traversal. */
3268 update_flags);
3270 }
3275 update_flags);
3281 /* Insertion of PHI nodes may have added blocks to the region.
3282 We need to re-compute START_BB to include the newly added
3283 blocks. */
3286 blocks_to_update);
3287 }
3289 /* Reset the current definition for name and symbol before renaming
3290 the sub-graph. */
3297 /* Now start the renaming process at START_BB. */
3307 /* Debugging dumps. */
3309 {
3320 c++;
3326 {
3331 }
3334 }
3336 /* Free allocated memory. */
3337 done:
3341 }