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1 /* Basic block reordering routines for the GNU compiler.
2 Copyright (C) 2000-2016 Free Software Foundation, Inc.
4 This file is part of GCC.
6 GCC is free software; you can redistribute it and/or modify it
7 under the terms of the GNU General Public License as published by
8 the Free Software Foundation; either version 3, or (at your option)
9 any later version.
11 GCC is distributed in the hope that it will be useful, but WITHOUT
12 ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
13 or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public
14 License 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 contains the "reorder blocks" pass, which changes the control
21 flow of a function to encounter fewer branches; the "partition blocks"
22 pass, which divides the basic blocks into "hot" and "cold" partitions,
23 which are kept separate; and the "duplicate computed gotos" pass, which
24 duplicates blocks ending in an indirect jump.
26 There are two algorithms for "reorder blocks": the "simple" algorithm,
27 which just rearranges blocks, trying to minimize the number of executed
28 unconditional branches; and the "software trace cache" algorithm, which
29 also copies code, and in general tries a lot harder to have long linear
30 pieces of machine code executed. This algorithm is described next. */
32 /* This (greedy) algorithm constructs traces in several rounds.
33 The construction starts from "seeds". The seed for the first round
34 is the entry point of the function. When there are more than one seed,
35 the one with the lowest key in the heap is selected first (see bb_to_key).
36 Then the algorithm repeatedly adds the most probable successor to the end
37 of a trace. Finally it connects the traces.
39 There are two parameters: Branch Threshold and Exec Threshold.
40 If the probability of an edge to a successor of the current basic block is
41 lower than Branch Threshold or its frequency is lower than Exec Threshold,
42 then the successor will be the seed in one of the next rounds.
43 Each round has these parameters lower than the previous one.
44 The last round has to have these parameters set to zero so that the
45 remaining blocks are picked up.
47 The algorithm selects the most probable successor from all unvisited
48 successors and successors that have been added to this trace.
49 The other successors (that has not been "sent" to the next round) will be
50 other seeds for this round and the secondary traces will start from them.
51 If the successor has not been visited in this trace, it is added to the
52 trace (however, there is some heuristic for simple branches).
53 If the successor has been visited in this trace, a loop has been found.
54 If the loop has many iterations, the loop is rotated so that the source
55 block of the most probable edge going out of the loop is the last block
56 of the trace.
57 If the loop has few iterations and there is no edge from the last block of
58 the loop going out of the loop, the loop header is duplicated.
60 When connecting traces, the algorithm first checks whether there is an edge
61 from the last block of a trace to the first block of another trace.
62 When there are still some unconnected traces it checks whether there exists
63 a basic block BB such that BB is a successor of the last block of a trace
64 and BB is a predecessor of the first block of another trace. In this case,
65 BB is duplicated, added at the end of the first trace and the traces are
66 connected through it.
67 The rest of traces are simply connected so there will be a jump to the
68 beginning of the rest of traces.
70 The above description is for the full algorithm, which is used when the
71 function is optimized for speed. When the function is optimized for size,
72 in order to reduce long jumps and connect more fallthru edges, the
73 algorithm is modified as follows:
74 (1) Break long traces to short ones. A trace is broken at a block that has
75 multiple predecessors/ successors during trace discovery. When connecting
76 traces, only connect Trace n with Trace n + 1. This change reduces most
77 long jumps compared with the above algorithm.
78 (2) Ignore the edge probability and frequency for fallthru edges.
79 (3) Keep the original order of blocks when there is no chance to fall
80 through. We rely on the results of cfg_cleanup.
82 To implement the change for code size optimization, block's index is
83 selected as the key and all traces are found in one round.
85 References:
87 "Software Trace Cache"
88 A. Ramirez, J. Larriba-Pey, C. Navarro, J. Torrellas and M. Valero; 1999
89 http://citeseer.nj.nec.com/15361.html
91 */
120 /* The number of rounds. In most cases there will only be 4 rounds, but
121 when partitioning hot and cold basic blocks into separate sections of
122 the object file there will be an extra round. */
123 #define N_ROUNDS 5
126 #if SWITCHABLE_TARGET
128 #endif
130 #define uncond_jump_length \
131 (this_target_bb_reorder->x_uncond_jump_length)
133 /* Branch thresholds in thousandths (per mille) of the REG_BR_PROB_BASE. */
136 /* Exec thresholds in thousandths (per mille) of the frequency of bb 0. */
139 /* If edge frequency is lower than DUPLICATION_THRESHOLD per mille of entry
140 block the edge destination is not duplicated while connecting traces. */
141 #define DUPLICATION_THRESHOLD 100
146 /* Structure to hold needed information for each basic block. */
147 struct bbro_basic_block_data
148 {
149 /* Which trace is the bb start of (-1 means it is not a start of any). */
152 /* Which trace is the bb end of (-1 means it is not an end of any). */
155 /* Which trace is the bb in? */
158 /* Which trace was this bb visited in? */
161 /* Cached maximum frequency of interesting incoming edges.
162 Minus one means not yet computed. */
165 /* Which heap is BB in (if any)? */
168 /* Which heap node is BB in (if any)? */
170 };
172 /* The current size of the following dynamic array. */
175 /* The array which holds needed information for basic blocks. */
178 /* To avoid frequent reallocation the size of arrays is greater than needed,
179 the number of elements is (not less than) 1.25 * size_wanted. */
180 #define GET_ARRAY_SIZE(X) ((((X) / 4) + 1) * 5)
182 /* Free the memory and set the pointer to NULL. */
183 #define FREE(P) (gcc_assert (P), free (P), P = 0)
185 /* Structure for holding information about a trace. */
186 struct trace
187 {
188 /* First and last basic block of the trace. */
191 /* The round of the STC creation which this trace was found in. */
194 /* The length (i.e. the number of basic blocks) of the trace. */
196 };
198 /* Maximum frequency and count of one of the entry blocks. */
202 /* Local function prototypes. */
211 const_edge);
217 \f
218 /* Return the trace number in which BB was visited. */
220 static int
222 {
225 }
227 /* This function marks BB that it was visited in trace number TRACE. */
229 static void
231 {
234 {
238 }
239 }
241 /* Check to see if bb should be pushed into the next round of trace
242 collections or not. Reasons for pushing the block forward are 1).
243 If the block is cold, we are doing partitioning, and there will be
244 another round (cold partition blocks are not supposed to be
245 collected into traces until the very last round); or 2). There will
246 be another round, and the basic block is not "hot enough" for the
247 current round of trace collection. */
249 static bool
252 {
265 else
267 }
269 /* Find the traces for Software Trace Cache. Chain each trace through
270 RBI()->next. Store the number of traces to N_TRACES and description of
271 traces to TRACES. */
273 static void
275 {
278 edge e;
279 edge_iterator ei;
282 /* Add one extra round of trace collection when partitioning hot/cold
283 basic blocks into separate sections. The last round is for all the
284 cold blocks (and ONLY the cold blocks). */
288 /* Insert entry points of function into heap. */
292 {
299 }
301 /* Find the traces. */
303 {
304 gcov_type count_threshold;
311 else
317 number_of_rounds);
318 }
322 {
324 {
325 basic_block bb;
333 }
335 }
336 }
338 /* Rotate loop whose back edge is BACK_EDGE in the tail of trace TRACE
339 (with sequential number TRACE_N). */
341 static basic_block
343 {
344 basic_block bb;
346 /* Information about the best end (end after rotation) of the loop. */
351 /* The best edge is preferred when its destination is not visited yet
352 or is a start block of some trace. */
355 /* Find the most frequent edge that goes out from current trace. */
357 do
358 {
359 edge e;
360 edge_iterator ei;
367 {
369 {
370 /* The best edge is preferred. */
373 {
374 /* The current edge E is also preferred. */
377 {
382 }
383 }
384 }
385 else
386 {
389 {
390 /* The current edge E is preferred. */
396 }
397 else
398 {
401 {
406 }
407 }
408 }
409 }
411 }
415 {
416 /* Rotate the loop so that the BEST_EDGE goes out from the last block of
417 the trace. */
419 {
421 }
422 else
423 {
424 basic_block prev_bb;
429 ;
432 /* Try to get rid of uncond jump to cond jump. */
434 {
437 /* Duplicate HEADER if it is a small block containing cond jump
438 in the end. */
442 }
443 }
444 }
445 else
446 {
447 /* We have not found suitable loop tail so do no rotation. */
449 }
452 }
454 /* One round of finding traces. Find traces for BRANCH_TH and EXEC_TH i.e. do
455 not include basic blocks whose probability is lower than BRANCH_TH or whose
456 frequency is lower than EXEC_TH into traces (or whose count is lower than
457 COUNT_TH). Store the new traces into TRACES and modify the number of
458 traces *N_TRACES. Set the round (which the trace belongs to) to ROUND.
459 The function expects starting basic blocks to be in *HEAP and will delete
460 *HEAP and store starting points for the next round into new *HEAP. */
462 static void
466 {
467 /* Heap for discarded basic blocks which are possible starting points for
468 the next round. */
473 {
474 basic_block bb;
478 edge_iterator ei;
487 /* If the BB's frequency is too low, send BB to the next round. When
488 partitioning hot/cold blocks into separate sections, make sure all
489 the cold blocks (and ONLY the cold blocks) go into the (extra) final
490 round. When optimizing for size, do not push to next round. */
494 count_th))
495 {
505 }
514 do
515 {
519 /* The probability and frequency of the best edge. */
533 /* Select the successor that will be placed after BB. */
535 {
551 /* The only sensible preference for a call instruction is the
552 fallthru edge. Don't bother selecting anything else. */
554 {
556 {
560 }
562 }
564 /* Edge that cannot be fallthru or improbable or infrequent
565 successor (i.e. it is unsuitable successor). When optimizing
566 for size, ignore the probability and frequency. */
572 /* If partitioning hot/cold basic blocks, don't consider edges
573 that cross section boundaries. */
576 best_edge))
577 {
581 }
582 }
584 /* If the best destination has multiple predecessors, and can be
585 duplicated cheaper than a jump, don't allow it to be added
586 to a trace. We'll duplicate it when connecting traces. */
591 /* If the best destination has multiple successors or predecessors,
592 don't allow it to be added when optimizing for size. This makes
593 sure predecessors with smaller index are handled before the best
594 destinarion. It breaks long trace and reduces long jumps.
596 Take if-then-else as an example.
597 A
598 / \
599 B C
600 \ /
601 D
602 If we do not remove the best edge B->D/C->D, the final order might
603 be A B D ... C. C is at the end of the program. If D's successors
604 and D are complicated, might need long jumps for A->C and C->D.
605 Similar issue for order: A C D ... B.
607 After removing the best edge, the final result will be ABCD/ ACBD.
608 It does not add jump compared with the previous order. But it
609 reduces the possibility of long jumps. */
615 /* Add all non-selected successors to the heaps. */
617 {
626 {
627 /* E->DEST is already in some heap. */
629 {
631 {
636 key);
637 }
640 }
641 }
642 else
643 {
653 {
654 /* When partitioning hot/cold basic blocks, make sure
655 the cold blocks (and only the cold blocks) all get
656 pushed to the last round of trace collection. When
657 optimizing for size, do not push to next round. */
660 number_of_rounds,
663 }
669 {
674 }
676 }
677 }
680 {
682 {
683 /* We do nothing with one basic block loops. */
685 {
688 {
689 /* The loop has at least 4 iterations. If the loop
690 header is not the first block of the function
691 we can rotate the loop. */
695 {
697 {
701 }
706 }
707 }
708 else
709 {
710 /* The loop has less than 4 iterations. */
714 optimize_edge_for_speed_p
716 {
720 }
721 }
722 }
724 /* Terminate the trace. */
726 }
727 else
728 {
729 /* Check for a situation
731 A
732 /|
733 B |
734 \|
735 C
737 where
738 EDGE_FREQUENCY (AB) + EDGE_FREQUENCY (BC)
739 >= EDGE_FREQUENCY (AC).
740 (i.e. 2 * B->frequency >= EDGE_FREQUENCY (AC) )
741 Best ordering is then A B C.
743 When optimizing for size, A B C is always the best order.
745 This situation is created for example by:
747 if (A) B;
748 C;
750 */
766 {
772 }
777 }
778 }
779 }
784 {
786 /* Update the cached maximum frequency for interesting predecessor
787 edges for successors of the new trace end. */
791 }
793 /* The trace is terminated so we have to recount the keys in heap
794 (some block can have a lower key because now one of its predecessors
795 is an end of the trace). */
797 {
803 {
806 {
808 {
813 }
816 }
817 }
818 }
819 }
823 /* "Return" the new heap. */
825 }
827 /* Create a duplicate of the basic block OLD_BB and redirect edge E to it, add
828 it to trace after BB, mark OLD_BB visited and update pass' data structures
829 (TRACE is a number of trace which OLD_BB is duplicated to). */
831 static basic_block
833 {
834 basic_block new_bb;
848 {
856 {
864 }
868 {
871 array_size);
872 }
873 }
883 }
885 /* Compute and return the key (for the heap) of the basic block BB. */
887 static long
889 {
890 edge e;
891 edge_iterator ei;
893 /* Use index as key to align with its original order. */
897 /* Do not start in probably never executed blocks. */
903 /* Prefer blocks whose predecessor is an end of some trace
904 or whose predecessor edge is EDGE_DFS_BACK. */
907 {
910 {
914 {
919 }
920 }
922 }
925 /* The block with priority should have significantly lower key. */
929 }
931 /* Return true when the edge E from basic block BB is better than the temporary
932 best edge (details are in function). The probability of edge E is PROB. The
933 frequency of the successor is FREQ. The current best probability is
934 BEST_PROB, the best frequency is BEST_FREQ.
935 The edge is considered to be equivalent when PROB does not differ much from
936 BEST_PROB; similarly for frequency. */
938 static bool
941 {
944 /* The BEST_* values do not have to be best, but can be a bit smaller than
945 maximum values. */
949 /* The smaller one is better to keep the original order. */
955 /* The edge has higher probability than the temporary best edge. */
958 /* The edge has lower probability than the temporary best edge. */
961 /* The edge and the temporary best edge have almost equivalent
962 probabilities. The higher frequency of a successor now means
963 that there is another edge going into that successor.
964 This successor has lower frequency so it is better. */
967 /* This successor has higher frequency so it is worse. */
970 /* The edges have equivalent probabilities and the successors
971 have equivalent frequencies. Select the previous successor. */
973 else
976 /* If we are doing hot/cold partitioning, make sure that we always favor
977 non-crossing edges over crossing edges. */
980 && flag_reorder_blocks_and_partition
981 && cur_best_edge
987 }
989 /* Return true when the edge E is better than the temporary best edge
990 CUR_BEST_EDGE. If SRC_INDEX_P is true, the function compares the src bb of
991 E and CUR_BEST_EDGE; otherwise it will compare the dest bb.
992 BEST_LEN is the trace length of src (or dest) bb in CUR_BEST_EDGE.
993 TRACES record the information about traces.
994 When optimizing for size, the edge with smaller index is better.
995 When optimizing for speed, the edge with bigger probability or longer trace
996 is better. */
998 static bool
1001 {
1010 {
1014 /* The smaller one is better to keep the original order. */
1016 }
1019 {
1023 /* The edge has higher probability than the temporary best edge. */
1026 /* The edge has lower probability than the temporary best edge. */
1029 /* The edge and the temporary best edge have equivalent probabilities.
1030 The edge with longer trace is better. */
1032 else
1034 }
1035 else
1036 {
1040 /* The edge has higher probability than the temporary best edge. */
1043 /* The edge has lower probability than the temporary best edge. */
1046 /* The edge and the temporary best edge have equivalent probabilities.
1047 The edge with longer trace is better. */
1049 else
1051 }
1054 }
1056 /* Connect traces in array TRACES, N_TRACES is the count of traces. */
1058 static void
1060 {
1068 gcov_type count_threshold;
1074 else
1090 {
1097 {
1104 else
1106 }
1117 /* Find the predecessor traces. */
1119 {
1120 edge_iterator ei;
1124 {
1134 {
1137 }
1138 }
1140 {
1146 {
1149 }
1150 }
1151 else
1153 }
1159 /* Find the successor traces. */
1161 {
1162 /* Find the continuation of the chain. */
1163 edge_iterator ei;
1167 {
1177 {
1180 }
1181 }
1184 {
1186 /* Stop finding the successor traces. */
1189 /* It is OK to connect block n with block n + 1 or a block
1190 before n. For others, only connect to the loop header. */
1192 {
1197 count--;
1199 /* If dest has multiple predecessors, skip it. We expect
1200 that one predecessor with smaller index connects with it
1201 later. */
1204 }
1206 /* Only connect Trace n with Trace n + 1. It is conservative
1207 to keep the order as close as possible to the original order.
1208 It also helps to reduce long jumps. */
1220 }
1222 {
1224 {
1227 }
1232 }
1233 else
1234 {
1235 /* Try to connect the traces by duplication of 1 block. */
1236 edge e2;
1245 {
1246 edge_iterator ei;
1250 /* If the destination is a start of a trace which is only
1251 one block long, then no need to search the successor
1252 blocks of the trace. Accept it. */
1256 {
1260 }
1263 {
1274 && (!best2
1279 {
1284 else
1288 }
1289 }
1290 }
1295 /* Copy tiny blocks always; copy larger blocks only when the
1296 edge is traversed frequently enough. */
1302 {
1303 basic_block new_bb;
1306 {
1313 else
1315 }
1320 {
1325 }
1326 else
1328 }
1329 else
1331 }
1332 }
1333 }
1336 {
1337 basic_block bb;
1344 }
1347 }
1349 /* Return true when BB can and should be copied. CODE_MAY_GROW is true
1350 when code size is allowed to grow by duplication. */
1352 static bool
1354 {
1366 /* Avoid duplicating blocks which have many successors (PR/13430). */
1374 {
1377 }
1383 {
1387 }
1390 }
1392 /* Return the length of unconditional jump instruction. */
1394 int
1396 {
1406 }
1408 /* The landing pad OLD_LP, in block OLD_BB, has edges from both partitions.
1409 Duplicate the landing pad and split the edges so that no EH edge
1410 crosses partitions. */
1412 static void
1414 {
1415 eh_landing_pad new_lp;
1419 edge_iterator ei;
1420 edge e;
1422 /* Generate the new landing-pad structure. */
1428 /* Put appropriate instructions in new bb. */
1439 /* Create new basic block to be dest for lp. */
1449 /* Make sure new bb is in the other partition. */
1454 /* Fix up the edges. */
1457 {
1465 /* Adjust the edge to the new destination. */
1467 }
1468 else
1470 }
1473 /* Ensure that all hot bbs are included in a hot path through the
1474 procedure. This is done by calling this function twice, once
1475 with WALK_UP true (to look for paths from the entry to hot bbs) and
1476 once with WALK_UP false (to look for paths from hot bbs to the exit).
1477 Returns the updated value of COLD_BB_COUNT and adds newly-hot bbs
1478 to BBS_IN_HOT_PARTITION. */
1480 static unsigned int
1483 {
1484 /* Callers check this. */
1487 /* Keep examining hot bbs while we still have some left to check
1488 and there are remaining cold bbs. */
1492 {
1495 edge e;
1496 edge_iterator ei;
1502 /* Walk the preds/succs and check if there is at least one already
1503 marked hot. Keep track of the most frequent pred/succ so that we
1504 can mark it hot if we don't find one. */
1506 {
1513 {
1516 }
1517 /* The following loop will look for the hottest edge via
1518 the edge count, if it is non-zero, then fallback to the edge
1519 frequency and finally the edge probability. */
1527 }
1529 /* If bb is reached by (or reaches, in the case of !WALK_UP) another hot
1530 block (or unpartitioned, e.g. the entry block) then it is ok. If not,
1531 then the most frequent pred (or succ) needs to be adjusted. In the
1532 case where multiple preds/succs have the same frequency (e.g. a
1533 50-50 branch), then both will be adjusted. */
1538 {
1541 /* Select the hottest edge using the edge count, if it is non-zero,
1542 then fallback to the edge frequency and finally the edge
1543 probability. */
1545 {
1548 }
1550 {
1553 }
1559 /* We have a hot bb with an immediate dominator that is cold.
1560 The dominator needs to be re-marked hot. */
1562 cold_bb_count--;
1564 /* Now we need to examine newly-hot reach_bb to see if it is also
1565 dominated by a cold bb. */
1568 }
1569 }
1572 }
1575 /* Find the basic blocks that are rarely executed and need to be moved to
1576 a separate section of the .o file (to cut down on paging and improve
1577 cache locality). Return a vector of all edges that cross. */
1581 {
1583 basic_block bb;
1584 edge e;
1585 edge_iterator ei;
1589 /* Mark which partition (hot/cold) each basic block belongs in. */
1591 {
1595 {
1596 /* Handle profile insanities created by upstream optimizations
1597 by also checking the incoming edge weights. If there is a non-cold
1598 incoming edge, conservatively prevent this block from being split
1599 into the cold section. */
1603 {
1606 }
1607 }
1609 {
1611 cold_bb_count++;
1612 }
1613 else
1614 {
1617 }
1618 }
1620 /* Ensure that hot bbs are included along a hot path from the entry to exit.
1621 Several different possibilities may include cold bbs along all paths
1622 to/from a hot bb. One is that there are edge weight insanities
1623 due to optimization phases that do not properly update basic block profile
1624 counts. The second is that the entry of the function may not be hot, because
1625 it is entered fewer times than the number of profile training runs, but there
1626 is a loop inside the function that causes blocks within the function to be
1627 above the threshold for hotness. This is fixed by walking up from hot bbs
1628 to the entry block, and then down from hot bbs to the exit, performing
1629 partitioning fixups as necessary. */
1631 {
1637 }
1639 /* The format of .gcc_except_table does not allow landing pads to
1640 be in a different partition as the throw. Fix this by either
1641 moving or duplicating the landing pads. */
1643 {
1645 eh_landing_pad lp;
1648 {
1659 {
1663 else
1665 }
1668 ;
1670 {
1674 }
1675 else
1677 }
1678 }
1680 /* Mark every edge that crosses between sections. */
1684 {
1687 /* We should never have EDGE_CROSSING set yet. */
1693 {
1696 }
1698 /* Now that we've split eh edges as appropriate, allow landing pads
1699 to be merged with the post-landing pads. */
1703 }
1706 }
1708 /* Set the flag EDGE_CAN_FALLTHRU for edges that can be fallthru. */
1710 static void
1712 {
1713 basic_block bb;
1716 {
1717 edge e;
1718 edge_iterator ei;
1721 {
1724 /* The FALLTHRU edge is also CAN_FALLTHRU edge. */
1727 }
1729 /* If the BB ends with an invertible condjump all (2) edges are
1730 CAN_FALLTHRU edges. */
1742 }
1743 }
1745 /* If any destination of a crossing edge does not have a label, add label;
1746 Convert any easy fall-through crossing edges to unconditional jumps. */
1748 static void
1750 {
1752 edge e;
1755 {
1763 /* Make sure dest has a label. */
1766 /* Nothing to do for non-fallthru edges. */
1772 /* If the block does not end with a control flow insn, then we
1773 can trivially add a jump to the end to fixup the crossing.
1774 Otherwise the jump will have to go in a new bb, which will
1775 be handled by fix_up_fall_thru_edges function. */
1779 /* Make sure there's only one successor. */
1789 /* Mark edge as non-fallthru. */
1791 }
1792 }
1794 /* Find any bb's where the fall-through edge is a crossing edge (note that
1795 these bb's must also contain a conditional jump or end with a call
1796 instruction; we've already dealt with fall-through edges for blocks
1797 that didn't have a conditional jump or didn't end with call instruction
1798 in the call to add_labels_and_missing_jumps). Convert the fall-through
1799 edge to non-crossing edge by inserting a new bb to fall-through into.
1800 The new bb will contain an unconditional jump (crossing edge) to the
1801 original fall through destination. */
1803 static void
1805 {
1806 basic_block cur_bb;
1807 basic_block new_bb;
1808 edge succ1;
1809 edge succ2;
1810 edge fall_thru;
1818 {
1822 else
1827 else
1830 /* Find the fall-through edge. */
1834 {
1837 }
1840 {
1843 }
1847 {
1848 edge e;
1849 edge_iterator ei;
1853 {
1856 }
1857 }
1860 {
1861 /* Check to see if the fall-thru edge is a crossing edge. */
1864 {
1865 /* The fall_thru edge crosses; now check the cond jump edge, if
1866 it exists. */
1872 /* Find the jump instruction, if there is one. */
1875 {
1879 /* We know the fall-thru edge crosses; if the cond
1880 jump edge does NOT cross, and its destination is the
1881 next block in the bb order, invert the jump
1882 (i.e. fix it so the fall through does not cross and
1883 the cond jump does). */
1886 {
1887 /* Find label in fall_thru block. We've already added
1888 any missing labels, so there must be one. */
1893 {
1899 }
1902 {
1909 }
1910 }
1911 }
1914 {
1915 /* This is the case where both edges out of the basic
1916 block are crossing edges. Here we will fix up the
1917 fall through edge. The jump edge will be taken care
1918 of later. The EDGE_CROSSING flag of fall_thru edge
1919 is unset before the call to force_nonfallthru
1920 function because if a new basic-block is created
1921 this edge remains in the current section boundary
1922 while the edge between new_bb and the fall_thru->dest
1923 becomes EDGE_CROSSING. */
1929 {
1933 /* This is done by force_nonfallthru_and_redirect. */
1938 }
1939 else
1940 {
1941 /* If a new basic-block was not created; restore
1942 the EDGE_CROSSING flag. */
1944 }
1946 /* Add barrier after new jump */
1948 }
1949 }
1950 }
1951 }
1952 }
1954 /* This function checks the destination block of a "crossing jump" to
1955 see if it has any crossing predecessors that begin with a code label
1956 and end with an unconditional jump. If so, it returns that predecessor
1957 block. (This is to avoid creating lots of new basic blocks that all
1958 contain unconditional jumps to the same destination). */
1960 static basic_block
1962 {
1964 edge e;
1966 edge_iterator ei;
1970 {
1973 /* Check each predecessor to see if it has a label, and contains
1974 only one executable instruction, which is an unconditional jump.
1975 If so, we can use it. */
1981 {
1986 {
1989 }
1990 }
1994 }
1997 }
1999 /* Find all BB's with conditional jumps that are crossing edges;
2000 insert a new bb and make the conditional jump branch to the new
2001 bb instead (make the new bb same color so conditional branch won't
2002 be a 'crossing' edge). Insert an unconditional jump from the
2003 new bb to the original destination of the conditional jump. */
2005 static void
2007 {
2008 basic_block cur_bb;
2009 basic_block new_bb;
2010 basic_block dest;
2011 edge succ1;
2012 edge succ2;
2013 edge crossing_edge;
2014 edge new_edge;
2015 rtx set_src;
2020 {
2024 else
2029 else
2032 /* We already took care of fall-through edges, so only one successor
2033 can be a crossing edge. */
2041 {
2044 /* Check to make sure the jump instruction is a
2045 conditional jump. */
2050 {
2054 {
2058 else
2060 }
2061 }
2064 {
2073 /* Check to see if new bb for jumping to that dest has
2074 already been created; if so, use it; if not, create
2075 a new one. */
2081 else
2082 {
2083 basic_block last_bb;
2087 /* Create new basic block to be dest for
2088 conditional jump. */
2090 /* Put appropriate instructions in new bb. */
2108 /* Make sure new bb is in same partition as source
2109 of conditional branch. */
2111 }
2113 /* Make old jump branch to new bb. */
2117 /* Remove crossing_edge as predecessor of 'dest'. */
2123 /* Make a new edge from new_bb to old dest; new edge
2124 will be a successor for new_bb and a predecessor
2125 for 'dest'. */
2129 else
2134 }
2135 }
2136 }
2137 }
2139 /* Find any unconditional branches that cross between hot and cold
2140 sections. Convert them into indirect jumps instead. */
2142 static void
2144 {
2145 basic_block cur_bb;
2147 rtx label;
2148 rtx label_addr;
2151 rtx new_reg;
2153 edge succ;
2156 {
2164 /* Check to see if bb ends in a crossing (unconditional) jump. At
2165 this point, no crossing jumps should be conditional. */
2169 {
2172 /* Make sure the jump is not already an indirect or table jump. */
2176 {
2177 /* We have found a "crossing" unconditional branch. Now
2178 we must convert it to an indirect jump. First create
2179 reference of label, as target for jump. */
2185 /* Get a register to use for the indirect jump. */
2189 /* Generate indirect the jump sequence. */
2197 /* Make sure every instruction in the new jump sequence has
2198 its basic block set to be cur_bb. */
2202 {
2207 }
2209 /* Insert the new (indirect) jump sequence immediately before
2210 the unconditional jump, then delete the unconditional jump. */
2218 /* Make BB_END for cur_bb be the jump instruction (NOT the
2219 barrier instruction at the end of the sequence...). */
2222 }
2223 }
2224 }
2225 }
2227 /* Update CROSSING_JUMP_P flags on all jump insns. */
2229 static void
2231 {
2232 basic_block bb;
2233 edge e;
2234 edge_iterator ei;
2239 {
2241 /* Some flags were added during fix_up_fall_thru_edges, via
2242 force_nonfallthru_and_redirect. */
2246 }
2247 }
2249 /* Reorder basic blocks using the software trace cache (STC) algorithm. */
2251 static void
2253 {
2261 /* We are estimating the length of uncond jump insn only once since the code
2262 for getting the insn length always returns the minimal length now. */
2266 /* We need to know some information for each basic block. */
2270 {
2278 }
2286 }
2288 /* Return true if edge E1 is more desirable as a fallthrough edge than
2289 edge E2 is. */
2291 static bool
2293 {
2295 }
2297 /* Reorder basic blocks using the "simple" algorithm. This tries to
2298 maximize the dynamic number of branches that are fallthrough, without
2299 copying instructions. The algorithm is greedy, looking at the most
2300 frequently executed branch first. */
2302 static void
2304 {
2310 /* First, collect all edges that can be optimized by reordering blocks:
2311 simple jumps and conditional jumps, as well as the function entry edge. */
2316 basic_block bb;
2318 {
2324 /* We cannot optimize asm goto. */
2331 {
2334 /* When optimizing for size it is best to keep the original
2335 fallthrough edges. */
2340 }
2341 }
2343 /* Sort the edges, the most desirable first. When optimizing for size
2344 all edges are equally desirable. */
2349 /* Now decide which of those edges to make fallthrough edges. We set
2350 BB_VISITED if a block already has a fallthrough successor assigned
2351 to it. We make ->AUX of an endpoint point to the opposite endpoint
2352 of a sequence of blocks that fall through, and ->AUX will be NULL
2353 for a block that is in such a sequence but not an endpoint anymore.
2355 To start with, everything points to itself, nothing is assigned yet. */
2358 {
2361 }
2365 /* Now for all edges, the most desirable first, see if that edge can
2366 connect two sequences. If it can, update AUX and BB_VISITED; if it
2367 cannot, zero out the edge in the table. */
2370 {
2378 /* An edge cannot connect two sequences if:
2379 - it crosses partitions;
2380 - its src is not a current endpoint;
2381 - its dest is not a current endpoint;
2382 - or, it would create a loop. */
2386 || !tail_b
2389 {
2392 }
2399 }
2401 /* Put the pieces together, in the same order that the start blocks of
2402 the sequences already had. The hot/cold partitioning gives a little
2403 complication: as a first pass only do this for blocks in the same
2404 partition as the start block, and (if there is anything left to do)
2405 in a second pass handle the other partition. */
2413 {
2418 {
2420 {
2423 }
2427 }
2430 }
2434 /* Finally, link all the chosen fallthrough edges. */
2442 /* If the entry edge no longer falls through we have to make a new
2443 block so it can do so again. */
2447 {
2451 }
2452 }
2454 /* Reorder basic blocks. The main entry point to this file. */
2456 static void
2458 {
2468 {
2479 }
2484 {
2488 }
2490 /* Signal that rtl_verify_flow_info_1 can now verify that there
2491 is at most one switch between hot/cold sections. */
2493 }
2495 /* Determine which partition the first basic block in the function
2496 belongs to, then find the first basic block in the current function
2497 that belongs to a different section, and insert a
2498 NOTE_INSN_SWITCH_TEXT_SECTIONS note immediately before it in the
2499 instruction stream. When writing out the assembly code,
2500 encountering this note will make the compiler switch between the
2501 hot and cold text sections. */
2503 void
2505 {
2506 basic_block bb;
2514 {
2518 {
2523 }
2524 }
2525 }
2530 {
2540 };
2543 {
2547 {}
2549 /* opt_pass methods: */
2551 {
2556 }
2562 unsigned int
2564 {
2565 basic_block bb;
2567 /* Last attempt to optimize CFG, as scheduling, peepholing and insn
2568 splitting possibly introduced more crossjumping opportunities. */
2580 }
2584 rtl_opt_pass *
2586 {
2588 }
2590 /* Duplicate the blocks containing computed gotos. This basically unfactors
2591 computed gotos that were factored early on in the compilation process to
2592 speed up edge based data flow. We used to not unfactoring them again,
2593 which can seriously pessimize code with many computed jumps in the source
2594 code, such as interpreters. See e.g. PR15242. */
2599 {
2609 };
2612 {
2616 {}
2618 /* opt_pass methods: */
2624 bool
2626 {
2630 && flag_expensive_optimizations
2632 }
2634 unsigned int
2636 {
2638 bitmap candidates;
2648 /* We are estimating the length of uncond jump insn only once
2649 since the code for getting the insn length always returns
2650 the minimal length now. */
2654 max_size
2658 /* Look for blocks that end in a computed jump, and see if such blocks
2659 are suitable for unfactoring. If a block is a candidate for unfactoring,
2660 mark it in the candidates. */
2662 {
2664 edge e;
2665 edge_iterator ei;
2668 /* Build the reorder chain for the original order of blocks. */
2672 /* Obviously the block has to end in a computed jump. */
2676 /* Only consider blocks that can be duplicated. */
2681 /* Make sure that the block is small enough. */
2685 {
2689 }
2693 /* Final check: there must not be any incoming abnormal edges. */
2701 }
2703 /* Nothing to do if there is no computed jump here. */
2707 /* Duplicate computed gotos. */
2709 {
2715 /* BB must have one outgoing edge. That edge must not lead to
2716 the exit block or the next block.
2717 The destination must have more than one predecessor. */
2724 /* The successor block has to be a duplication candidate. */
2728 /* Don't duplicate a partition crossing edge, which requires difficult
2729 fixup. */
2738 }
2740 done:
2742 {
2743 /* Duplicating blocks above will redirect edges and may cause hot
2744 blocks previously reached by both hot and cold blocks to become
2745 dominated only by cold blocks. */
2748 /* Merge the duplicated blocks into predecessors, when possible. */
2751 }
2752 else
2757 }
2761 rtl_opt_pass *
2763 {
2765 }
2767 /* This function is the main 'entrance' for the optimization that
2768 partitions hot and cold basic blocks into separate sections of the
2769 .o file (to improve performance and cache locality). Ideally it
2770 would be called after all optimizations that rearrange the CFG have
2771 been called. However part of this optimization may introduce new
2772 register usage, so it must be called before register allocation has
2773 occurred. This means that this optimization is actually called
2774 well before the optimization that reorders basic blocks (see
2775 function above).
2777 This optimization checks the feedback information to determine
2778 which basic blocks are hot/cold, updates flags on the basic blocks
2779 to indicate which section they belong in. This information is
2780 later used for writing out sections in the .o file. Because hot
2781 and cold sections can be arbitrarily large (within the bounds of
2782 memory), far beyond the size of a single function, it is necessary
2783 to fix up all edges that cross section boundaries, to make sure the
2784 instructions used can actually span the required distance. The
2785 fixes are described below.
2787 Fall-through edges must be changed into jumps; it is not safe or
2788 legal to fall through across a section boundary. Whenever a
2789 fall-through edge crossing a section boundary is encountered, a new
2790 basic block is inserted (in the same section as the fall-through
2791 source), and the fall through edge is redirected to the new basic
2792 block. The new basic block contains an unconditional jump to the
2793 original fall-through target. (If the unconditional jump is
2794 insufficient to cross section boundaries, that is dealt with a
2795 little later, see below).
2797 In order to deal with architectures that have short conditional
2798 branches (which cannot span all of memory) we take any conditional
2799 jump that attempts to cross a section boundary and add a level of
2800 indirection: it becomes a conditional jump to a new basic block, in
2801 the same section. The new basic block contains an unconditional
2802 jump to the original target, in the other section.
2804 For those architectures whose unconditional branch is also
2805 incapable of reaching all of memory, those unconditional jumps are
2806 converted into indirect jumps, through a register.
2808 IMPORTANT NOTE: This optimization causes some messy interactions
2809 with the cfg cleanup optimizations; those optimizations want to
2810 merge blocks wherever possible, and to collapse indirect jump
2811 sequences (change "A jumps to B jumps to C" directly into "A jumps
2812 to C"). Those optimizations can undo the jump fixes that
2813 partitioning is required to make (see above), in order to ensure
2814 that jumps attempting to cross section boundaries are really able
2815 to cover whatever distance the jump requires (on many architectures
2816 conditional or unconditional jumps are not able to reach all of
2817 memory). Therefore tests have to be inserted into each such
2818 optimization to make sure that it does not undo stuff necessary to
2819 cross partition boundaries. This would be much less of a problem
2820 if we could perform this optimization later in the compilation, but
2821 unfortunately the fact that we may need to create indirect jumps
2822 (through registers) requires that this optimization be performed
2823 before register allocation.
2825 Hot and cold basic blocks are partitioned and put in separate
2826 sections of the .o file, to reduce paging and improve cache
2827 performance (hopefully). This can result in bits of code from the
2828 same function being widely separated in the .o file. However this
2829 is not obvious to the current bb structure. Therefore we must take
2830 care to ensure that: 1). There are no fall_thru edges that cross
2831 between sections; 2). For those architectures which have "short"
2832 conditional branches, all conditional branches that attempt to
2833 cross between sections are converted to unconditional branches;
2834 and, 3). For those architectures which have "short" unconditional
2835 branches, all unconditional branches that attempt to cross between
2836 sections are converted to indirect jumps.
2838 The code for fixing up fall_thru edges that cross between hot and
2839 cold basic blocks does so by creating new basic blocks containing
2840 unconditional branches to the appropriate label in the "other"
2841 section. The new basic block is then put in the same (hot or cold)
2842 section as the original conditional branch, and the fall_thru edge
2843 is modified to fall into the new basic block instead. By adding
2844 this level of indirection we end up with only unconditional branches
2845 crossing between hot and cold sections.
2847 Conditional branches are dealt with by adding a level of indirection.
2848 A new basic block is added in the same (hot/cold) section as the
2849 conditional branch, and the conditional branch is retargeted to the
2850 new basic block. The new basic block contains an unconditional branch
2851 to the original target of the conditional branch (in the other section).
2853 Unconditional branches are dealt with by converting them into
2854 indirect jumps. */
2859 {
2869 };
2872 {
2876 {}
2878 /* opt_pass methods: */
2884 bool
2886 {
2887 /* The optimization to partition hot/cold basic blocks into separate
2888 sections of the .o file does not work well with linkonce or with
2889 user defined section attributes. Don't call it if either case
2890 arises. */
2892 && optimize
2893 /* See pass_reorder_blocks::gate. We should not partition if
2894 we are going to omit the reordering. */
2898 }
2900 unsigned
2902 {
2916 /* Make sure the source of any crossing edge ends in a jump and the
2917 destination of any crossing edge has a label. */
2920 /* Convert all crossing fall_thru edges to non-crossing fall
2921 thrus to unconditional jumps (that jump to the original fall
2922 through dest). */
2925 /* If the architecture does not have conditional branches that can
2926 span all of memory, convert crossing conditional branches into
2927 crossing unconditional branches. */
2931 /* If the architecture does not have unconditional branches that
2932 can span all of memory, convert crossing unconditional branches
2933 into indirect jumps. Since adding an indirect jump also adds
2934 a new register usage, update the register usage information as
2935 well. */
2941 /* Clear bb->aux fields that the above routines were using. */
2946 /* ??? FIXME: DF generates the bb info for a block immediately.
2947 And by immediately, I mean *during* creation of the block.
2949 #0 df_bb_refs_collect
2950 #1 in df_bb_refs_record
2951 #2 in create_basic_block_structure
2953 Which means that the bb_has_eh_pred test in df_bb_refs_collect
2954 will *always* fail, because no edges can have been added to the
2955 block yet. Which of course means we don't add the right
2956 artificial refs, which means we fail df_verify (much) later.
2958 Cleanest solution would seem to make DF_DEFER_INSN_RESCAN imply
2959 that we also shouldn't grab data from the new blocks those new
2960 insns are in either. In this way one can create the block, link
2961 it up properly, and have everything Just Work later, when deferred
2962 insns are processed.
2964 In the meantime, we have no other option but to throw away all
2965 of the DF data and recompute it all. */
2967 {
2971 /* Not all post-landing pads use all of the EH_RETURN_DATA_REGNO
2972 data. We blindly generated all of them when creating the new
2973 landing pad. Delete those assignments we don't use. */
2976 }
2979 }
2983 rtl_opt_pass *
2985 {
2987 }