| blob | 5e60f34f74927d8c99e5abbe6723e2c618e2bb04 |
1 /* Shrink-wrapping related optimizations.
2 Copyright (C) 1987-2021 Free Software Foundation, Inc.
4 This file is part of GCC.
6 GCC is free software; you can redistribute it and/or modify it under
7 the terms of the GNU General Public License as published by the Free
8 Software Foundation; either version 3, or (at your option) any later
9 version.
11 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
12 WARRANTY; without even the implied warranty of MERCHANTABILITY or
13 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
14 for more details.
16 You should have received a copy of the GNU General Public License
17 along with GCC; see the file COPYING3. If not see
18 <http://www.gnu.org/licenses/>. */
20 /* This file handles shrink-wrapping related optimizations. */
48 /* Return true if INSN requires the stack frame to be set up.
49 PROLOGUE_USED contains the hard registers used in the function
50 prologue. SET_UP_BY_PROLOGUE is the set of registers we expect the
51 prologue to set up for the function. */
52 bool
54 HARD_REG_SET set_up_by_prologue)
55 {
57 HARD_REG_SET hardregs;
63 /* We need a frame to get the unique CFA expected by the unwinder. */
69 {
76 }
86 {
94 }
99 }
101 /* See whether there has a single live edge from BB, which dest uses
102 [REGNO, END_REGNO). Return the live edge if its dest bb has
103 one or two predecessors. Otherwise return NULL. */
105 static edge
107 {
109 edge_iterator ei;
110 bitmap live;
115 {
119 {
123 }
124 }
126 /* We can sometimes encounter dead code. Don't try to move it
127 into the exit block. */
131 /* Reject targets of abnormal edges. This is needed for correctness
132 on ports like Alpha and MIPS, whose pic_offset_table_rtx can die on
133 exception edges even though it is generally treated as call-saved
134 for the majority of the compilation. Moving across abnormal edges
135 isn't going to be interesting for shrink-wrap usage anyway. */
139 /* When live_edge->dest->preds == 2, we can create a new block on
140 the edge to make it meet the requirement. */
145 }
147 /* Try to move INSN from BB to a successor. Return true on success.
148 USES and DEFS are the set of registers that are used and defined
149 after INSN in BB. SPLIT_P indicates whether a live edge from BB
150 is splitted or not. */
152 static bool
154 const_hard_reg_set uses,
155 const_hard_reg_set defs,
158 {
164 basic_block next_block;
165 edge live_edge;
167 df_ref def;
169 /* Look for a simple register assignment. We don't use single_set here
170 because we can't deal with any CLOBBERs, USEs, or REG_UNUSED secondary
171 destinations. */
180 /* For the destination, we want only a register. Also disallow STACK
181 or FRAME related adjustments. They are likely part of the prologue,
182 so keep them in the entry block. */
189 /* For the source, we want one of:
190 (1) A (non-overlapping) register
191 (2) A constant,
192 (3) An expression involving no more than one register.
194 That last point comes from the code following, which was originally
195 written to handle only register move operations, and still only handles
196 a single source register when checking for overlaps. Happily, the
197 same checks can be applied to expressions like (plus reg const). */
200 ;
202 {
210 {
213 {
221 /* Constant or expression. Continue. */
227 {
233 /* Ok. Continue. */
237 /* Fail if we see a second inner register. */
245 }
250 }
251 }
255 }
257 /* Make sure that the source register isn't defined later in BB. */
259 {
264 }
266 /* Make sure that the destination register isn't referenced later in BB. */
273 /* See whether there is a successor block to which we could move INSN. */
279 /* Create a new basic block on the edge. */
281 {
282 /* split_edge for a block with only one successor is meaningless. */
286 /* If DF_LIVE doesn't exist, i.e. at -O1, just give up. */
293 /* We create a new basic block. Call df_grow_bb_info to make sure
294 all data structures are allocated. */
301 /* We should not split more than once for a function. */
306 }
308 /* At this point we are committed to moving INSN, but let's try to
309 move it as far as we can. */
310 do
311 {
313 {
316 {
317 df_ref use;
322 }
325 }
330 /* Check whether BB uses DEST or clobbers DEST. We need to add
331 INSN to BB if so. Either way, DEST is no longer live on entry,
332 except for any part that overlaps SRC (next loop). */
334 {
337 }
339 {
341 {
349 }
351 /* Check whether BB clobbers SRC. We need to add INSN to BB if so.
352 Either way, SRC is now live on entry. */
354 {
361 }
362 }
363 else
364 {
365 /* DF_LR_BB_INFO (bb)->def does not comprise the DF_REF_PARTIAL and
366 DF_REF_CONDITIONAL defs. So if DF_LIVE doesn't exist, i.e.
367 at -O1, just give up searching NEXT_BLOCK. */
370 {
373 }
376 {
379 }
380 }
382 /* If we don't need to add the move to BB, look for a single
383 successor block. */
385 {
390 }
391 }
394 /* For the new created basic block, there is no dataflow info at all.
395 So skip the following dataflow update and check. */
397 {
398 /* BB now defines DEST. It only uses the parts of DEST that overlap SRC
399 (next loop). */
401 {
404 }
406 /* BB now uses SRC. */
409 }
411 /* Insert debug temps for dead REGs used in subsequent debug insns. */
415 DEBUG_TEMP_BEFORE_WITH_VALUE);
418 /* Update the LABEL_NUSES count on any referenced labels. The ideal
419 solution here would be to actually move the instruction instead
420 of copying/deleting it as this loses some notations on the
421 insn. */
425 }
427 /* Look for register copies in the first block of the function, and move
428 them down into successor blocks if the register is used only on one
429 path. This exposes more opportunities for shrink-wrapping. These
430 kinds of sets often occur when incoming argument registers are moved
431 to call-saved registers because their values are live across one or
432 more calls during the function. */
434 static void
436 {
438 rtx x;
446 {
447 /* To have more shrink-wrapping opportunities, prepare_shrink_wrap tries
448 to sink the copies from parameter to callee saved register out of
449 entry block. copyprop_hardreg_forward_bb_without_debug_insn is called
450 to release some dependences. */
452 }
462 {
463 /* Add all defined registers to DEFs. */
465 {
470 }
472 /* Add all used registers to USESs. */
474 {
479 }
480 }
483 }
485 /* Return whether basic block PRO can get the prologue. It cannot if it
486 has incoming complex edges that need a prologue inserted (we make a new
487 block for the prologue, so those edges would need to be redirected, which
488 does not work). It also cannot if there exist registers live on entry
489 to PRO that are clobbered by the prologue. */
491 static bool
493 {
494 edge e;
495 edge_iterator ei;
501 HARD_REG_SET live;
507 }
509 /* Return whether we can duplicate basic block BB for shrink wrapping. We
510 cannot if the block cannot be duplicated at all, or if any of its incoming
511 edges are complex and come from a block that does not require a prologue
512 (we cannot redirect such edges), or if the block is too big to copy.
513 PRO is the basic block before which we would put the prologue, MAX_SIZE is
514 the maximum size block we allow to be copied. */
516 static bool
518 {
522 edge e;
523 edge_iterator ei;
534 {
538 }
541 }
543 /* Do whatever needs to be done for exits that run without prologue.
544 Sibcalls need nothing done. Normal exits get a simple_return inserted. */
546 static void
548 {
551 {
552 /* Tell function.c to take no further action on this edge. */
558 }
560 /* If the basic block the edge comes from has multiple successors,
561 split the edge. */
563 {
576 }
587 }
589 /* Try to perform a kind of shrink-wrapping, making sure the
590 prologue/epilogue is emitted only around those parts of the
591 function that require it.
593 There will be exactly one prologue, and it will be executed either
594 zero or one time, on any path. Depending on where the prologue is
595 placed, some of the basic blocks can be reached via both paths with
596 and without a prologue. Such blocks will be duplicated here, and the
597 edges changed to match.
599 Paths that go to the exit without going through the prologue will use
600 a simple_return instead of the epilogue. We maximize the number of
601 those, making sure to only duplicate blocks that can be duplicated.
602 If the prologue can then still be placed in multiple locations, we
603 place it as early as possible.
605 An example, where we duplicate blocks with control flow (legend:
606 _B_egin, _R_eturn and _S_imple_return; edges without arrowhead should
607 be taken to point down or to the right, to simplify the diagram; here,
608 block 3 needs a prologue, the rest does not):
611 B B
612 | |
613 2 2
614 |\ |\
615 | 3 becomes | 3
616 |/ | \
617 4 7 4
618 |\ |\ |\
619 | 5 | 8 | 5
620 |/ |/ |/
621 6 9 6
622 | | |
623 R S R
626 (bb 4 is duplicated to 7, and so on; the prologue is inserted on the
627 edge 2->3).
629 Another example, where part of a loop is duplicated (again, bb 3 is
630 the only block that needs a prologue):
633 B 3<-- B ->3<--
634 | | | | | | |
635 | v | becomes | | v |
636 2---4--- 2---5-- 4---
637 | | |
638 R S R
641 (bb 4 is duplicated to 5; the prologue is inserted on the edge 5->3).
643 ENTRY_EDGE is the edge where the prologue will be placed, possibly
644 changed by this function. PROLOGUE_SEQ is the prologue we will insert. */
646 void
648 {
649 /* If we cannot shrink-wrap, are told not to shrink-wrap, or it makes
650 no sense to shrink-wrap: then do not shrink-wrap! */
664 {
667 }
671 /* Move some code down to expose more shrink-wrapping opportunities. */
679 /* Compute the registers set and used in the prologue. */
686 {
687 HARD_REG_SET this_used;
693 }
698 /* Find out what registers are set up by the prologue; any use of these
699 cannot happen before the prologue. */
707 HARD_FRAME_POINTER_REGNUM);
711 PIC_OFFSET_TABLE_REGNUM);
719 /* We will insert the prologue before the basic block PRO. PRO should
720 dominate all basic blocks that need the prologue to be executed
721 before them. First, make PRO the "tightest wrap" possible. */
727 basic_block bb;
728 edge e;
729 edge_iterator ei;
731 {
737 {
739 {
743 }
746 }
747 }
749 /* If nothing needs a prologue, just put it at the start. This really
750 shouldn't happen, but we cannot fix it here. */
753 {
758 }
764 /* Now see if we can put the prologue at the start of PRO. Putting it
765 there might require duplicating a block that cannot be duplicated,
766 or in some cases we cannot insert the prologue there at all. If PRO
767 wont't do, try again with the immediate dominator of PRO, and so on.
769 The blocks that need duplicating are those reachable from PRO but
770 not dominated by it. We keep in BB_WITH a bitmap of the blocks
771 reachable from PRO that we already found, and in VEC a stack of
772 those we still need to consider (to find successors). */
774 auto_bitmap bb_with;
785 {
787 {
792 }
797 {
804 }
810 }
816 /* If we can move PRO back without having to duplicate more blocks, do so.
817 We do this because putting the prologue earlier is better for scheduling.
819 We can move back to a block PRE if every path from PRE will eventually
820 need a prologue, that is, PRO is a post-dominator of PRE. PRE needs
821 to dominate every block reachable from itself. We keep in BB_TMP a
822 bitmap of the blocks reachable from PRE that we already found, and in
823 VEC a stack of those we still need to consider.
825 Any block reachable from PRE is also reachable from all predecessors
826 of PRE, so if we find we need to move PRE back further we can leave
827 everything not considered so far on the stack. Any block dominated
828 by PRE is also dominated by all other dominators of PRE, so anything
829 found good for some PRE does not need to be reconsidered later.
831 We don't need to update BB_WITH because none of the new blocks found
832 can jump to a block that does not need the prologue. */
835 {
838 auto_bitmap bb_tmp;
844 {
854 {
856 {
859 }
865 }
871 }
876 }
885 {
888 }
890 /* Compute what fraction of the frequency and count of the blocks that run
891 both with and without prologue are for running with prologue. This gives
892 the correct answer for reducible flow graphs; for irreducible flow graphs
893 our profile is messed up beyond repair anyway. */
900 {
905 }
907 /* All is okay, so do it. */
913 /* Copy the blocks that can run both with and without prologue. The
914 originals run with prologue, the copies without. Store a pointer to
915 the copy in the ->aux field of the original. */
920 {
937 }
939 /* Now change the edges to point to the copies, where appropriate. */
943 {
949 {
955 {
961 }
965 }
966 }
968 /* Also redirect the function entry edge if necessary. */
973 {
977 }
979 /* Make a simple_return for those exits that run without prologue. */
987 /* Finally, we want a single edge to put the prologue on. Make a new
988 block before the PRO block; the edge beteen them is the edge we want.
989 Then redirect those edges into PRO that come from blocks without the
990 prologue, to point to the new block instead. The new prologue block
991 is put at the end of the insn chain. */
1000 {
1003 {
1006 }
1013 }
1019 }
1020 \f
1021 /* Separate shrink-wrapping
1023 Instead of putting all of the prologue and epilogue in one spot, we
1024 can put parts of it in places where those components are executed less
1025 frequently. The following code does this, for prologue and epilogue
1026 components that can be put in more than one location, and where those
1027 components can be executed more than once (the epilogue component will
1028 always be executed before the prologue component is executed a second
1029 time).
1031 What exactly is a component is target-dependent. The more usual
1032 components are simple saves/restores to/from the frame of callee-saved
1033 registers. This code treats components abstractly (as an sbitmap),
1034 letting the target handle all details.
1036 Prologue components are placed in such a way that for every component
1037 the prologue is executed as infrequently as possible. We do this by
1038 walking the dominator tree, comparing the cost of placing a prologue
1039 component before a block to the sum of costs determined for all subtrees
1040 of that block.
1042 From this placement, we then determine for each component all blocks
1043 where at least one of this block's dominators (including itself) will
1044 get a prologue inserted. That then is how the components are placed.
1045 We could place the epilogue components a bit smarter (we can save a
1046 bit of code size sometimes); this is a possible future improvement.
1048 Prologues and epilogues are preferably placed into a block, either at
1049 the beginning or end of it, if it is needed for all predecessor resp.
1050 successor edges; or placed on the edge otherwise.
1052 If the placement of any prologue/epilogue leads to a situation we cannot
1053 handle (for example, an abnormal edge would need to be split, or some
1054 targets want to use some specific registers that may not be available
1055 where we want to put them), separate shrink-wrapping for the components
1056 in that prologue/epilogue is aborted. */
1059 /* Print the sbitmap COMPONENTS to the DUMP_FILE if not empty, with the
1060 label LABEL. */
1061 static void
1063 {
1074 }
1076 /* The data we collect for each bb. */
1078 /* What components does this BB need? */
1079 sbitmap needs_components;
1081 /* What components does this BB have? This is the main decision this
1082 pass makes. */
1083 sbitmap has_components;
1085 /* The components for which we placed code at the start of the BB (instead
1086 of on all incoming edges). */
1087 sbitmap head_components;
1089 /* The components for which we placed code at the end of the BB (instead
1090 of on all outgoing edges). */
1091 sbitmap tail_components;
1093 /* The frequency of executing the prologue for this BB, if a prologue is
1094 placed on this BB. This is a pessimistic estimate (no prologue is
1095 needed for edges from blocks that have the component under consideration
1096 active already). */
1097 gcov_type own_cost;
1099 /* The frequency of executing the prologue for this BB and all BBs
1100 dominated by it. */
1101 gcov_type total_cost;
1102 };
1104 /* A helper function for accessing the pass-specific info. */
1107 {
1110 }
1112 /* Create the pass-specific data structures for separately shrink-wrapping
1113 with components COMPONENTS. */
1114 static void
1116 {
1117 basic_block bb;
1119 {
1124 /* Mark all basic blocks without successor as needing all components.
1125 This avoids problems in at least cfgcleanup, sel-sched, and
1126 regrename (largely to do with all paths to such a block still
1127 needing the same dwarf CFI info). */
1132 {
1136 }
1142 }
1143 }
1145 /* Destroy the pass-specific data. */
1146 static void
1148 {
1149 basic_block bb;
1152 {
1159 }
1160 }
1162 /* Place the prologue for component WHICH, in the basic blocks dominated
1163 by HEAD. Do a DFS over the dominator tree, and set bit WHICH in the
1164 HAS_COMPONENTS of a block if either the block has that bit set in
1165 NEEDS_COMPONENTS, or it is cheaper to place the prologue here than in all
1166 dominator subtrees separately. */
1167 static void
1169 {
1170 /* The block we are currently dealing with. */
1172 /* Is this the first time we visit this block, i.e. have we just gone
1173 down the tree. */
1176 /* Walk the dominator tree, visit one block per iteration of this loop.
1177 Each basic block is visited twice: once before visiting any children
1178 of the block, and once after visiting all of them (leaf nodes are
1179 visited only once). As an optimization, we do not visit subtrees
1180 that can no longer influence the prologue placement. */
1182 {
1183 /* First visit of a block: set the (children) cost accumulator to zero;
1184 if the block does not have the component itself, walk down. */
1186 {
1187 /* Initialize the cost. The cost is the block execution frequency
1188 that does not come from backedges. Calculating this by simply
1189 adding the cost of all edges that aren't backedges does not
1190 work: this does not always add up to the block frequency at
1191 all, and even if it does, rounding error makes for bad
1192 decisions. */
1195 edge e;
1196 edge_iterator ei;
1199 {
1202 else
1204 }
1210 {
1213 }
1214 }
1216 /* If this block does need the component itself, or it is cheaper to
1217 put the prologue here than in all the descendants that need it,
1218 mark it so. If this block's immediate post-dominator is dominated
1219 by this block, and that needs the prologue, we can put it on this
1220 block as well (earlier is better). */
1223 {
1226 }
1227 else
1228 {
1232 {
1235 }
1236 }
1238 /* We are back where we started, so we are done now. */
1242 /* We now know the cost of the subtree rooted at the current block.
1243 Accumulate this cost in the parent. */
1247 /* Don't walk the tree down unless necessary. */
1250 {
1253 }
1254 else
1255 {
1258 }
1259 }
1260 }
1262 /* Set HAS_COMPONENTS in every block to the maximum it can be set to without
1263 setting it on any path from entry to exit where it was not already set
1264 somewhere (or, for blocks that have no path to the exit, consider only
1265 paths from the entry to the block itself). Return whether any changes
1266 were made to some HAS_COMPONENTS. */
1267 static bool
1269 {
1273 /* A stack of all blocks left to consider, and a bitmap of all blocks
1274 on that stack. */
1277 auto_bitmap seen;
1281 /* Find for every block the components that are *not* needed on some path
1282 from the entry to that block. Do this with a flood fill from the entry
1283 block. Every block can be visited at most as often as the number of
1284 components (plus one), and usually much less often. */
1289 basic_block bb;
1295 edge e;
1296 edge_iterator ei;
1301 {
1319 }
1321 /* Find for every block the components that are *not* needed on some reverse
1322 path from the exit to that block. */
1327 /* First, mark all blocks not reachable from the exit block as not needing
1328 any component on any path to the exit. Mark everything, and then clear
1329 again by a flood fill. */
1335 {
1338 }
1341 {
1352 }
1354 /* And then, flood fill backwards to find for every block the components
1355 not needed on some path to the exit. */
1360 {
1363 }
1366 {
1384 }
1388 /* Finally, mark everything not needed both forwards and backwards. */
1393 {
1403 }
1406 {
1408 {
1412 }
1413 }
1416 }
1418 /* If we cannot handle placing some component's prologues or epilogues where
1419 we decided we should place them, unmark that component in COMPONENTS so
1420 that it is not wrapped separately. */
1421 static void
1423 {
1427 basic_block bb;
1429 {
1430 edge e;
1431 edge_iterator ei;
1433 {
1434 /* Find which components we want pro/epilogues for here. */
1440 /* Ask the target what it thinks about things. */
1448 /* If this edge doesn't need splitting, we're fine. */
1453 /* If the edge can be split, that is fine too. */
1457 /* We also can handle sibcalls. */
1459 {
1462 }
1464 /* Remove from consideration those components we would need
1465 pro/epilogues for on edges where we cannot insert them. */
1470 {
1477 }
1480 {
1487 }
1488 }
1489 }
1490 }
1492 /* Place code for prologues and epilogues for COMPONENTS where we can put
1493 that code at the start of basic blocks. */
1494 static void
1496 {
1501 basic_block bb;
1506 {
1507 /* Find which prologue resp. epilogue components are needed for all
1508 predecessor edges to this block. */
1510 /* First, select all possible components. */
1514 edge e;
1515 edge_iterator ei;
1517 {
1519 {
1523 }
1525 /* Deselect those epilogue components that should not be inserted
1526 for this edge. */
1531 /* Similar, for the prologue. */
1535 }
1548 /* Place code after the BB note. */
1550 {
1560 }
1563 {
1573 }
1574 }
1575 }
1577 /* Place code for prologues and epilogues for COMPONENTS where we can put
1578 that code at the end of basic blocks. */
1579 static void
1581 {
1586 basic_block bb;
1591 {
1592 /* Find which prologue resp. epilogue components are needed for all
1593 successor edges from this block. */
1597 /* First, select all possible components. */
1601 edge e;
1602 edge_iterator ei;
1604 {
1606 {
1610 }
1612 /* Deselect those epilogue components that should not be inserted
1613 for this edge, and also those that are already put at the head
1614 of the successor block. */
1620 /* Similarly, for the prologue. */
1625 }
1627 /* If the last insn of this block is a control flow insn we cannot
1628 put anything after it. We can put our code before it instead,
1629 but only if that jump insn is a simple jump. */
1632 {
1635 }
1648 /* Put the code at the end of the BB, but before any final jump. */
1650 {
1659 else
1663 }
1666 {
1675 else
1679 }
1680 }
1681 }
1683 /* Place prologues and epilogues for COMPONENTS on edges, if we haven't already
1684 placed them inside blocks directly. */
1685 static void
1687 {
1691 basic_block bb;
1693 {
1697 edge e;
1698 edge_iterator ei;
1700 {
1701 /* Find which pro/epilogue components are needed on this edge. */
1709 /* Deselect those we already have put at the head or tail of the
1710 edge's dest resp. src. */
1717 {
1719 {
1729 }
1731 /* Put the epilogue components in place. */
1739 {
1745 }
1747 {
1751 }
1752 else
1755 /* Put the prologue components in place. */
1763 }
1764 }
1765 }
1768 }
1770 /* The main entry point to this subpass. FIRST_BB is where the prologue
1771 would be normally put. */
1772 void
1774 {
1776 && flag_shrink_wrap_separate
1781 /* We don't handle "strange" functions. */
1790 /* Ask the target what components there are. If it returns NULL, don't
1791 do anything. */
1796 /* We need LIVE info, not defining anything in the entry block and not
1797 using anything in the exit block. A block then needs a component if
1798 the register for that component is in the IN or GEN or KILL set for
1799 that block. */
1811 sbitmap_iterator sbi;
1816 /* Try to minimize the number of saves and restores. Do this as long as
1817 it changes anything. This does not iterate more than a few times. */
1820 {
1821 spread_times++;
1825 }
1829 /* Don't separately shrink-wrap anything where the "main" prologue will
1830 go; the target code can often optimize things if it is presented with
1831 all components together (say, if it generates store-multiple insns). */
1835 {
1838 }
1839 else
1840 {
1842 {
1848 }
1868 }
1876 /* All done. */
1881 }