| blob | f225030de681ac7d1622995e97189db15ce710b4 |
1 /* Dead code elimination pass for the GNU compiler.
2 Copyright (C) 2002, 2003, 2004, 2005, 2006, 2007, 2008, 2009, 2010, 2011
3 Free Software Foundation, Inc.
4 Contributed by Ben Elliston <bje@redhat.com>
5 and Andrew MacLeod <amacleod@redhat.com>
6 Adapted to use control dependence by Steven Bosscher, SUSE Labs.
8 This file is part of GCC.
10 GCC is free software; you can redistribute it and/or modify it
11 under the terms of the GNU General Public License as published by the
12 Free Software Foundation; either version 3, or (at your option) any
13 later version.
15 GCC is distributed in the hope that it will be useful, but WITHOUT
16 ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
17 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
18 for more details.
20 You should have received a copy of the GNU General Public License
21 along with GCC; see the file COPYING3. If not see
22 <http://www.gnu.org/licenses/>. */
24 /* Dead code elimination.
26 References:
28 Building an Optimizing Compiler,
29 Robert Morgan, Butterworth-Heinemann, 1998, Section 8.9.
31 Advanced Compiler Design and Implementation,
32 Steven Muchnick, Morgan Kaufmann, 1997, Section 18.10.
34 Dead-code elimination is the removal of statements which have no
35 impact on the program's output. "Dead statements" have no impact
36 on the program's output, while "necessary statements" may have
37 impact on the output.
39 The algorithm consists of three phases:
40 1. Marking as necessary all statements known to be necessary,
41 e.g. most function calls, writing a value to memory, etc;
42 2. Propagating necessary statements, e.g., the statements
43 giving values to operands in necessary statements; and
44 3. Removing dead statements. */
64 static struct stmt_stats
65 {
72 #define STMT_NECESSARY GF_PLF_1
76 /* Vector indicating an SSA name has already been processed and marked
77 as necessary. */
80 /* Vector indicating that the last statement of a basic block has already
81 been marked as necessary. */
84 /* Vector indicating that BB contains statements that are live. */
87 /* Before we can determine whether a control branch is dead, we need to
88 compute which blocks are control dependent on which edges.
90 We expect each block to be control dependent on very few edges so we
91 use a bitmap for each block recording its edges. An array holds the
92 bitmap. The Ith bit in the bitmap is set if that block is dependent
93 on the Ith edge. */
96 /* Vector indicating that a basic block has already had all the edges
97 processed that it is control dependent on. */
100 /* TRUE if this pass alters the CFG (by removing control statements).
101 FALSE otherwise.
103 If this pass alters the CFG, then it will arrange for the dominators
104 to be recomputed. */
107 /* Execute code that follows the macro for each edge (given number
108 EDGE_NUMBER within the CODE) for which the block with index N is
109 control dependent. */
110 #define EXECUTE_IF_CONTROL_DEPENDENT(BI, N, EDGE_NUMBER) \
111 EXECUTE_IF_SET_IN_BITMAP (control_dependence_map[(N)], 0, \
112 (EDGE_NUMBER), (BI))
115 /* Indicate block BB is control dependent on an edge with index EDGE_INDEX. */
118 {
123 }
125 /* Clear all control dependences for block BB. */
128 {
130 }
133 /* Find the immediate postdominator PDOM of the specified basic block BLOCK.
134 This function is necessary because some blocks have negative numbers. */
138 {
143 else
144 {
149 }
150 }
153 /* Determine all blocks' control dependences on the given edge with edge_list
154 EL index EDGE_INDEX, ala Morgan, Section 3.6. */
156 static void
158 {
159 basic_block current_block;
160 basic_block ending_block;
166 else
172 {
175 /* For abnormal edges, we don't make current_block control
176 dependent because instructions that throw are always necessary
177 anyway. */
182 }
183 }
186 /* Record all blocks' control dependences on all edges in the edge
187 list EL, ala Morgan, Section 3.6. */
189 static void
191 {
196 }
198 /* If STMT is not already marked necessary, mark it, and add it to the
199 worklist if ADD_TO_WORKLIST is true. */
203 {
210 {
214 }
221 }
224 /* Mark the statement defining operand OP as necessary. */
228 {
229 gimple stmt;
236 {
241 }
251 {
256 }
262 }
265 /* Mark STMT as necessary if it obviously is. Add it to the worklist if
266 it can make other statements necessary.
268 If AGGRESSIVE is false, control statements are conservatively marked as
269 necessary. */
271 static void
273 {
274 /* With non-call exceptions, we have to assume that all statements could
275 throw. If a statement may throw, it is inherently necessary. */
277 {
280 }
282 /* Statements that are implicitly live. Most function calls, asm
283 and return statements are required. Labels and GIMPLE_BIND nodes
284 are kept because they are control flow, and we have no way of
285 knowing whether they can be removed. DCE can eliminate all the
286 other statements in a block, and CFG can then remove the block
287 and labels. */
289 {
302 {
307 {
314 }
315 /* Most, but not all function calls are required. Function calls that
316 produce no result and have no side effects (i.e. const pure
317 functions) are unnecessary. */
319 {
322 }
326 }
329 /* Debug temps without a value are not useful. ??? If we could
330 easily locate the debug temp bind stmt for a use thereof,
331 would could refrain from marking all debug temps here, and
332 mark them only if they're used. */
346 /* Fall through. */
355 }
357 /* If the statement has volatile operands, it needs to be preserved.
358 Same for statements that can alter control flow in unpredictable
359 ways. */
361 {
364 }
367 {
370 }
373 }
376 /* Mark the last statement of BB as necessary. */
378 static void
380 {
386 /* We actually mark the statement only if it is a control statement. */
389 }
392 /* Mark control dependent edges of BB as necessary. We have to do this only
393 once for each basic block so we set the appropriate bit after we're done.
395 When IGNORE_SELF is true, ignore BB in the list of control dependences. */
397 static void
400 {
401 bitmap_iterator bi;
411 {
415 {
418 }
422 }
426 }
429 /* Find obviously necessary statements. These are things like most function
430 calls, and stores to file level variables.
432 If EL is NULL, control statements are conservatively marked as
433 necessary. Otherwise it contains the list of edges used by control
434 dependence analysis. */
436 static void
438 {
439 basic_block bb;
440 gimple_stmt_iterator gsi;
441 edge e;
446 {
447 /* PHI nodes are never inherently necessary. */
449 {
452 }
454 /* Check all statements in the block. */
456 {
460 }
461 }
463 /* Pure and const functions are finite and thus have no infinite loops in
464 them. */
469 /* Prevent the empty possibly infinite loops from being removed. */
471 {
472 loop_iterator li;
477 {
478 edge_iterator ei;
482 {
487 }
488 }
492 {
496 }
498 }
499 }
502 /* Return true if REF is based on an aliased base, otherwise false. */
504 static bool
506 {
515 }
523 /* Worker for the walker that marks reaching definitions of REF,
524 which is based on a non-aliased decl, necessary. It returns
525 true whenever the defining statement of the current VDEF is
526 a kill for REF, as no dominating may-defs are necessary for REF
527 anymore. DATA points to the basic-block that contains the
528 stmt that refers to REF. */
530 static bool
532 {
535 /* All stmts we visit are necessary. */
538 /* If the stmt lhs kills ref, then we can stop walking. */
541 /* The assignment is not necessarily carried out if it can throw
542 and we can catch it in the current function where we could inspect
543 the previous value.
544 ??? We only need to care about the RHS throwing. For aggregate
545 assignments or similar calls and non-call exceptions the LHS
546 might throw as well. */
548 {
553 /* We can get MEM[symbol: sZ, index: D.8862_1] here,
554 so base == refd->base does not always hold. */
556 {
557 /* For a must-alias check we need to be able to constrain
558 the accesses properly. */
561 {
565 }
566 /* Or they need to be exactly the same. */
568 /* Make sure there is no induction variable involved
569 in the references (gcc.c-torture/execute/pr42142.c).
570 The simplest way is to check if the kill dominates
571 the use. */
576 }
577 }
579 /* Otherwise keep walking. */
581 }
583 static void
585 {
587 ao_ref refd;
591 mark_aliased_reaching_defs_necessary_1,
596 nr_walks++;
597 }
599 /* Worker for the walker that marks reaching definitions of REF, which
600 is not based on a non-aliased decl. For simplicity we need to end
601 up marking all may-defs necessary that are not based on a non-aliased
602 decl. The only job of this walker is to skip may-defs based on
603 a non-aliased decl. */
605 static bool
608 {
611 /* We have to skip already visited (and thus necessary) statements
612 to make the chaining work after we dropped back to simple mode. */
615 {
619 }
621 /* We want to skip stores to non-aliased variables. */
624 {
628 }
630 /* We want to skip statments that do not constitute stores but have
631 a virtual definition. */
633 {
638 {
646 }
647 }
652 }
654 static void
656 {
659 }
661 /* Return true for PHI nodes with one or identical arguments
662 can be removed. */
663 static bool
665 {
672 }
674 /* Propagate necessity using the operands of necessary statements.
675 Process the uses on each statement in the worklist, and add all
676 feeding statements which contribute to the calculation of this
677 value to the worklist.
679 In conservative mode, EL is NULL. */
681 static void
683 {
684 gimple stmt;
691 {
692 /* Take STMT from worklist. */
696 {
700 }
703 {
704 /* Mark the last statement of the basic blocks on which the block
705 containing STMT is control dependent, but only if we haven't
706 already done so. */
711 }
714 /* We do not process virtual PHI nodes nor do we track their
715 necessity. */
717 {
718 /* PHI nodes are somewhat special in that each PHI alternative has
719 data and control dependencies. All the statements feeding the
720 PHI node's arguments are always necessary. In aggressive mode,
721 we also consider the control dependent edges leading to the
722 predecessor block associated with each PHI alternative as
723 necessary. */
727 {
731 }
733 /* For PHI operands it matters from where the control flow arrives
734 to the BB. Consider the following example:
736 a=exp1;
737 b=exp2;
738 if (test)
739 ;
740 else
741 ;
742 c=PHI(a,b)
744 We need to mark control dependence of the empty basic blocks, since they
745 contains computation of PHI operands.
747 Doing so is too restrictive in the case the predecestor block is in
748 the loop. Consider:
750 if (b)
751 {
752 int i;
753 for (i = 0; i<1000; ++i)
754 ;
755 j = 0;
756 }
757 return j;
759 There is PHI for J in the BB containing return statement.
760 In this case the control dependence of predecestor block (that is
761 within the empty loop) also contains the block determining number
762 of iterations of the block that would prevent removing of empty
763 loop in this case.
765 This scenario can be avoided by splitting critical edges.
766 To save the critical edge splitting pass we identify how the control
767 dependence would look like if the edge was split.
769 Consider the modified CFG created from current CFG by splitting
770 edge B->C. In the postdominance tree of modified CFG, C' is
771 always child of C. There are two cases how chlids of C' can look
772 like:
774 1) C' is leaf
776 In this case the only basic block C' is control dependent on is B.
778 2) C' has single child that is B
780 In this case control dependence of C' is same as control
781 dependence of B in original CFG except for block B itself.
782 (since C' postdominate B in modified CFG)
784 Now how to decide what case happens? There are two basic options:
786 a) C postdominate B. Then C immediately postdominate B and
787 case 2 happens iff there is no other way from B to C except
788 the edge B->C.
790 There is other way from B to C iff there is succesor of B that
791 is not postdominated by B. Testing this condition is somewhat
792 expensive, because we need to iterate all succesors of B.
793 We are safe to assume that this does not happen: we will mark B
794 as needed when processing the other path from B to C that is
795 conrol dependent on B and marking control dependencies of B
796 itself is harmless because they will be processed anyway after
797 processing control statement in B.
799 b) C does not postdominate B. Always case 1 happens since there is
800 path from C to exit that does not go through B and thus also C'. */
803 {
805 {
810 {
813 }
818 }
819 }
820 }
821 else
822 {
823 /* Propagate through the operands. Examine all the USE, VUSE and
824 VDEF operands in this statement. Mark all the statements
825 which feed this statement's uses as necessary. */
826 ssa_op_iter iter;
827 tree use;
829 /* If this is a call to free which is directly fed by an
830 allocation function do not mark that necessary through
831 processing the argument. */
833 {
835 gimple def_stmt;
836 tree def_callee;
837 /* If the pointer we free is defined by an allocation
838 function do not add the call to the worklist. */
846 }
855 /* If we dropped to simple mode make all immediately
856 reachable definitions necessary. */
858 {
861 }
863 /* For statements that may load from memory (have a VUSE) we
864 have to mark all reaching (may-)definitions as necessary.
865 We partition this task into two cases:
866 1) explicit loads based on decls that are not aliased
867 2) implicit loads (like calls) and explicit loads not
868 based on decls that are not aliased (like indirect
869 references or loads from globals)
870 For 1) we mark all reaching may-defs as necessary, stopping
871 at dominating kills. For 2) we want to mark all dominating
872 references necessary, but non-aliased ones which we handle
873 in 1). By keeping a global visited bitmap for references
874 we walk for 2) we avoid quadratic behavior for those. */
877 {
881 /* Calls to functions that are merely acting as barriers
882 or that only store to memory do not make any previous
883 stores necessary. */
898 /* Calls implicitly load from memory, their arguments
899 in addition may explicitly perform memory loads. */
902 {
911 }
912 }
914 {
915 tree rhs;
917 /* If this is a load mark things necessary. */
921 {
924 else
926 }
929 }
931 {
933 /* A return statement may perform a load. */
937 {
940 else
942 }
943 }
945 {
948 /* Inputs may perform loads. */
950 {
956 }
957 }
958 else
961 /* If we over-used our alias oracle budget drop to simple
962 mode. The cost metric allows quadratic behavior
963 (number of uses times number of may-defs queries) up to
964 a constant maximal number of queries and after that falls back to
965 super-linear complexity. */
968 /* Linear in the number of may-defs. */
970 /* Linear in the number of uses. */
972 {
976 }
977 }
978 }
979 }
981 /* Replace all uses of result of PHI by underlying variable and mark it
982 for renaming. */
984 void
986 {
988 imm_use_iterator iter;
989 use_operand_p use_p;
990 gimple stmt;
994 {
998 }
1003 {
1008 }
1011 }
1013 /* Remove dead PHI nodes from block BB. */
1015 static bool
1017 {
1019 gimple_seq phis;
1020 gimple phi;
1021 gimple_stmt_iterator gsi;
1025 {
1029 /* We do not track necessity of virtual PHI nodes. Instead do
1030 very simple dead PHI removal here. */
1032 {
1033 /* Virtual PHI nodes with one or identical arguments
1034 can be removed. */
1036 {
1040 use_operand_p use_p;
1041 imm_use_iterator iter;
1042 gimple use_stmt;
1049 }
1050 else
1052 }
1055 {
1058 {
1062 }
1067 }
1070 }
1072 }
1074 /* Forward edge E to respective POST_DOM_BB and update PHIs. */
1076 static edge
1078 {
1079 gimple_stmt_iterator gsi;
1081 edge_iterator ei;
1090 /* If edge was already around, no updating is neccesary. */
1095 {
1096 /* We are sure that for every live PHI we are seeing control dependent BB.
1097 This means that we can pick any edge to duplicate PHI args from. */
1102 {
1104 tree op;
1105 source_location locus;
1107 /* PHIs for virtuals have no control dependency relation on them.
1108 We are lost here and must force renaming of the symbol. */
1110 {
1114 }
1116 /* Dead PHI do not imply control dependency. */
1118 {
1121 }
1126 /* The resulting PHI if not dead can only be degenerate. */
1129 }
1130 }
1132 }
1134 /* Remove dead statement pointed to by iterator I. Receives the basic block BB
1135 containing I so that we don't have to look it up. */
1137 static void
1139 {
1143 {
1147 }
1151 /* If we have determined that a conditional branch statement contributes
1152 nothing to the program, then we not only remove it, but we also change
1153 the flow graph so that the current block will simply fall-thru to its
1154 immediate post-dominator. The blocks we are circumventing will be
1155 removed by cleanup_tree_cfg if this change in the flow graph makes them
1156 unreachable. */
1158 {
1159 basic_block post_dom_bb;
1161 edge_iterator ei;
1167 /* If edge is already there, try to use it. This avoids need to update
1168 PHI nodes. Also watch for cases where post dominator does not exists
1169 or is exit block. These can happen for infinite loops as we create
1170 fake edges in the dominator tree. */
1172 ;
1175 else
1181 /* The edge is no longer associated with a conditional, so it does
1182 not have TRUE/FALSE flags. */
1185 /* The lone outgoing edge from BB will be a fallthru edge. */
1188 /* Remove the remaining outgoing edges. */
1191 {
1194 }
1195 else
1197 }
1202 }
1204 /* Eliminate unnecessary statements. Any instruction not marked as necessary
1205 contributes nothing to the program, and can be deleted. */
1207 static bool
1209 {
1211 basic_block bb;
1213 gimple stmt;
1214 tree call;
1222 /* Walking basic blocks and statements in reverse order avoids
1223 releasing SSA names before any other DEFs that refer to them are
1224 released. This helps avoid loss of debug information, as we get
1225 a chance to propagate all RHSs of removed SSAs into debug uses,
1226 rather than only the latest ones. E.g., consider:
1228 x_3 = y_1 + z_2;
1229 a_5 = x_3 - b_4;
1230 # DEBUG a => a_5
1232 If we were to release x_3 before a_5, when we reached a_5 and
1233 tried to substitute it into the debug stmt, we'd see x_3 there,
1234 but x_3's DEF, type, etc would have already been disconnected.
1235 By going backwards, the debug stmt first changes to:
1237 # DEBUG a => x_3 - b_4
1239 and then to:
1241 # DEBUG a => y_1 + z_2 - b_4
1243 as desired. */
1248 {
1251 /* Remove dead statements. */
1253 {
1261 /* We can mark a call to free as not necessary if the
1262 defining statement of its argument is an allocation
1263 function and that is not necessary itself. */
1265 {
1267 tree callee2;
1268 gimple def_stmt;
1282 }
1284 /* If GSI is not necessary then remove it. */
1286 {
1290 }
1292 {
1295 {
1296 tree name;
1298 /* When LHS of var = call (); is dead, simplify it into
1299 call (); saving one operand. */
1303 {
1306 {
1310 }
1316 }
1318 }
1319 }
1320 }
1321 }
1325 /* Since we don't track liveness of virtual PHI nodes, it is possible that we
1326 rendered some PHI nodes unreachable while they are still in use.
1327 Mark them for renaming. */
1329 {
1330 basic_block prev_bb;
1334 /* Delete all unreachable basic blocks in reverse dominator order. */
1336 {
1341 {
1344 {
1346 imm_use_iterator iter;
1349 {
1354 {
1357 }
1358 }
1361 }
1364 {
1365 /* Speed up the removal of blocks that don't
1366 dominate others. Walking backwards, this should
1367 be the common case. ??? Do we need to recompute
1368 dominators because of cfg_altered? */
1372 else
1373 {
1377 {
1380 /* Rearrangements to the CFG may have failed
1381 to update the dominators tree, so that
1382 formerly-dominated blocks are now
1383 otherwise reachable. */
1387 }
1390 }
1391 }
1392 }
1393 }
1394 }
1396 {
1397 /* Remove dead PHI nodes. */
1399 }
1402 }
1405 /* Print out removed statement statistics. */
1407 static void
1409 {
1418 else
1423 }
1425 /* Initialization for this pass. Set up the used data structures. */
1427 static void
1429 {
1433 {
1444 }
1451 }
1453 /* Cleanup after this pass. */
1455 static void
1457 {
1459 {
1470 }
1475 }
1477 /* Main routine to eliminate dead code.
1479 AGGRESSIVE controls the aggressiveness of the algorithm.
1480 In conservative mode, we ignore control dependence and simply declare
1481 all but the most trivially dead branches necessary. This mode is fast.
1482 In aggressive mode, control dependences are taken into account, which
1483 results in more dead code elimination, but at the cost of some time.
1485 FIXME: Aggressive mode before PRE doesn't work currently because
1486 the dominance info is not invalidated after DCE1. This is
1487 not an issue right now because we only run aggressive DCE
1488 as the last tree SSA pass, but keep this in mind when you
1489 start experimenting with pass ordering. */
1491 static unsigned int
1493 {
1499 /* Preheaders are needed for SCEV to work.
1500 Simple lateches and recorded exits improve chances that loop will
1501 proved to be finite in testcases such as in loop-15.c and loop-24.c */
1509 {
1510 /* Compute control dependence. */
1521 }
1539 /* We do not update postdominators, so free them unconditionally. */
1542 /* If we removed paths in the CFG, then we need to update
1543 dominators as well. I haven't investigated the possibility
1544 of incrementally updating dominators. */
1551 /* Debugging dumps. */
1562 else
1564 }
1566 /* Pass entry points. */
1567 static unsigned int
1569 {
1571 }
1573 static unsigned int
1575 {
1579 {
1582 }
1584 }
1586 static unsigned int
1588 {
1590 }
1592 static bool
1594 {
1596 }
1599 {
1600 {
1601 GIMPLE_PASS,
1613 TODO_verify_ssa /* todo_flags_finish */
1614 }
1615 };
1618 {
1619 {
1620 GIMPLE_PASS,
1632 TODO_verify_ssa /* todo_flags_finish */
1633 }
1634 };
1637 {
1638 {
1639 GIMPLE_PASS,
1651 TODO_verify_ssa
1653 }
1654 };