| blob | 07d2196749b1c4acf4e04fecff775c511783761e |
1 /* Graph coloring register allocator
2 Copyright (C) 2001, 2002 Free Software Foundation, Inc.
3 Contributed by Michael Matz <matz@suse.de>
4 and Daniel Berlin <dan@cgsoftware.com>.
6 This file is part of GCC.
8 GCC is free software; you can redistribute it and/or modify it under the
9 terms of the GNU General Public License as published by the Free Software
10 Foundation; either version 2, or (at your option) any later version.
12 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
13 WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
14 FOR A PARTICULAR PURPOSE. See the GNU General Public License for more
15 details.
17 You should have received a copy of the GNU General Public License along
18 with GCC; see the file COPYING. If not, write to the Free Software
19 Foundation, 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */
35 /* This file is part of the graph coloring register allocator.
36 It contains the graph colorizer. Given an interference graph
37 as set up in ra-build.c the toplevel function in this file
38 (ra_colorize_graph) colorizes the graph, leaving a list
39 of colored, coalesced and spilled nodes.
41 The algorithm used is a merge of George & Appels iterative coalescing
42 and optimistic coalescing, switchable at runtime. The current default
43 is "optimistic coalescing +", which is based on the normal Briggs/Cooper
44 framework. We can also use biased coloring. Most of the structure
45 here follows the different papers.
47 Additionally there is a custom step to locally improve the overall
48 spill cost of the colored graph (recolor_spills). */
102 /* Push a node onto the front of the list. */
104 static void
108 {
115 }
117 static void
121 {
125 {
128 }
133 }
135 /* Remove a node from the list. */
137 void
141 {
145 else
151 }
153 /* Pop the front of the list. */
158 {
163 }
165 /* Free the given double linked list. */
167 static void
170 {
172 }
174 /* The web WEB should get the given new TYPE. Put it onto the
175 appropriate list.
176 Inline, because it's called with constant TYPE every time. */
182 {
184 {
203 else
208 }
210 }
212 /* After we are done with the whole pass of coloring/spilling,
213 we reset the lists of webs, in preparation of the next pass.
214 The spilled webs become free, colored webs go to the initial list,
215 coalesced webs become free or initial, according to what type of web
216 they are coalesced to. */
218 void
220 {
228 {
231 /* Note, how alias() becomes invalid through the two put_web()'s
232 below. It might set the type of a web to FREE (from COALESCED),
233 which itself is a target of aliasing (i.e. in the middle of
234 an alias chain). We can handle this by checking also for
235 type == FREE. Note nevertheless, that alias() is invalid
236 henceforth. */
239 else
241 }
247 /* All free webs have no conflicts anymore. */
249 {
253 }
255 /* Sanity check, that we only have free, initial or precolored webs. */
257 {
261 }
267 }
269 /* Similar to put_web(), but add the web to the end of the appropriate
270 list. Additionally TYPE may not be SIMPLIFY. */
272 static void
276 {
283 }
285 /* Unlink WEB from the list it's currently on (which corresponds to
286 its current type). */
288 void
291 {
294 else
296 }
298 /* Give MOVE the TYPE, and link it into the correct list. */
304 {
306 {
324 }
326 }
328 /* Build the worklists we are going to process. */
330 static void
333 {
337 /* If we are not the first pass, put all stackwebs (which are still
338 backed by a new pseudo, but conceptually can stand for a stackslot,
339 i.e. it doesn't really matter if they get a color or not), on
340 the SELECT stack first, those with lowest cost first. This way
341 they will be colored last, so do not constrain the coloring of the
342 normal webs. But still those with the highest count are colored
343 before, i.e. get a color more probable. The use of stackregs is
344 a pure optimization, and all would work, if we used real stackslots
345 from the begin. */
347 {
356 {
359 {
365 {
368 }
371 }
372 }
374 }
376 /* For all remaining initial webs, classify them. */
378 {
389 else
391 }
393 /* And put all moves on the worklist for iterated coalescing.
394 Note, that if iterated coalescing is off, then wl_moves doesn't
395 contain any moves. */
398 {
404 }
405 }
407 /* Enable the active moves, in which WEB takes part, to be processed. */
409 static void
412 {
416 {
419 }
420 }
422 /* Decrement the degree of node WEB by the amount DEC.
423 Possibly change the type of WEB, if the number of conflicts is
424 now smaller than its freedom. */
426 static void
430 {
434 {
438 {
442 }
444 {
448 else
450 }
451 }
452 }
454 /* Repeatedly simplify the nodes on the simplify worklists. */
456 static void
458 {
463 {
464 /* We try hard to color all the webs resulting from spills first.
465 Without that on register starved machines (x86 e.g) with some live
466 DImode pseudos, -fPIC, and an asm requiring %edx, it might be, that
467 we do rounds over rounds, because the conflict graph says, we can
468 simplify those short webs, but later due to irregularities we can't
469 color those pseudos. So we have to spill them, which in later rounds
470 leads to other spills. */
483 {
486 {
488 }
489 }
490 }
491 }
493 /* Helper function to remove a move from the movelist of the web. */
495 static void
499 {
504 {
507 }
512 }
514 /* Remove a move from the movelist of the web. Actually this is just a
515 wrapper around remove_move_1(), making sure, the removed move really is
516 not in the list anymore. */
518 static void
522 {
528 }
530 /* Merge the moves for the two webs into the first web's movelist. */
532 void
535 {
536 regset seen;
543 {
546 {
549 }
550 }
553 }
555 /* Add a web to the simplify worklist, from the freeze worklist. */
557 static void
560 {
563 {
566 }
567 }
569 /* Precolored node coalescing heuristic. */
571 static int
574 {
580 /* Normally one would think, the next test wouldn't be needed.
581 We try to coalesce S and T, and S has already a color, and we checked
582 when processing the insns, that both have the same mode. So naively
583 we could conclude, that of course that mode was valid for this color.
584 Hah. But there is sparc. Before reload there are copy insns
585 (e.g. the ones copying arguments to locals) which happily refer to
586 colors in invalid modes. We can't coalesce those things. */
590 /* Sanity for funny modes. */
595 /* We can't coalesce target with a precolored register which isn't in
596 usable_regs. */
600 /* Before usually calling ok() at all, we already test, if the
601 candidates conflict in sup_igraph. But when wide webs are
602 coalesced to hardregs, we only test the hardweb coalesced into.
603 This is only the begin color. When actually coalescing both,
604 it will also take the following size colors, i.e. their webs.
605 We nowhere checked if the candidate possibly conflicts with
606 one of _those_, which is possible with partial conflicts,
607 so we simply do it here (this does one bit-test more than
608 necessary, the first color). Note, that if X is precolored
609 bit [X*num_webs + Y] can't be set (see add_conflict_edge()). */
615 {
620 /* Coalescing target (T) and source (S) is o.k, if for
621 all conflicts C of T it is true, that:
622 1) C will be colored, or
623 2) C is a hardreg (precolored), or
624 3) C already conflicts with S too, or
625 4) a web which contains C conflicts already with S.
626 XXX: we handle here only the special case of 4), that C is
627 a subreg, and the containing thing is the reg itself, i.e.
628 we dont handle the situation, were T conflicts with
629 (subreg:SI x 1), and S conflicts with (subreg:DI x 0), which
630 would be allowed also, as the S-conflict overlaps
631 the T-conflict.
632 So, we first test the whole web for any of these conditions, and
633 continue with the next C, if 1, 2 or 3 is true. */
639 /* This is reached, if not one of 1, 2 or 3 was true. In the case C has
640 no subwebs, 4 can't be true either, so we can't coalesce S and T. */
643 else
644 {
645 /* The main webs do _not_ conflict, only some parts of both. This
646 means, that 4 is possibly true, so we need to check this too.
647 For this we go thru all sub conflicts between T and C, and see if
648 the target part of C already conflicts with S. When this is not
649 the case we disallow coalescing. */
652 {
655 }
656 }
657 }
659 }
661 /* Non-precolored node coalescing heuristic. */
663 static int
666 {
669 regset seen;
673 /* k counts the resulting conflict weight, if target and source
674 would be merged, and all low-degree neighbors would be
675 removed. */
681 {
686 {
689 }
690 }
696 }
698 /* If the web is coalesced, return it's alias. Otherwise, return what
699 was passed in. */
704 {
708 }
710 /* Returns nonzero, if the TYPE belongs to one of those representing
711 SIMPLIFY types. */
716 {
718 }
720 /* Actually combine two webs, that can be coalesced. */
722 static void
725 {
740 /*u->spill_cost = MAX (u->spill_cost, v->spill_cost);*/
742 /* combine add_hardregs's of U and V. */
745 {
747 /* We don't strictly need to move conflicts between webs which are
748 already coalesced or selected, if we do iterated coalescing, or
749 better if we need not to be able to break aliases again.
750 I.e. normally we would use the condition
751 (pweb->type != SELECT && pweb->type != COALESCED).
752 But for now we simply merge all conflicts. It doesn't take that
753 much time. */
755 {
761 /* For precolored U's we need to make conflicts between V's
762 neighbors and as many hardregs from U as V needed if it gets
763 color U. For now we approximate this by V->add_hardregs, which
764 could be too much in multi-length classes. We should really
765 count how many hardregs are needed for V with color U. When U
766 isn't precolored this loop breaks out after one iteration. */
768 {
773 else
774 {
776 /* So, between V and PWEB there are sub_conflicts. We
777 need to relocate those conflicts to be between WEB (==
778 U when it wasn't precolored) and PWEB. In the case
779 only a part of V conflicted with (part of) PWEB we
780 nevertheless make the new conflict between the whole U
781 and the (part of) PWEB. Later we might try to find in
782 U the correct subpart corresponding (by size and
783 offset) to the part of V (sl->s) which was the source
784 of the conflict. */
786 {
787 /* Beware: sl->s is no subweb of web (== U) but of V.
788 We try to search a corresponding subpart of U.
789 If we found none we let it conflict with the whole U.
790 Note that find_subweb() only looks for mode and
791 subreg_byte of the REG rtx but not for the pseudo
792 reg number (otherwise it would be guaranteed to
793 _not_ find any subpart). */
800 }
801 }
804 }
807 }
808 }
810 /* Now merge the usable_regs together. */
811 /* XXX That merging might normally make it necessary to
812 adjust add_hardregs, which also means to adjust neighbors. This can
813 result in making some more webs trivially colorable, (or the opposite,
814 if this increases our add_hardregs). Because we intersect the
815 usable_regs it should only be possible to decrease add_hardregs. So a
816 conservative solution for now is to simply don't change it. */
820 /* Count number of possible hardregs. This might make U a spillweb,
821 but that could also happen, if U and V together had too many
822 conflicts. */
825 /* The next would mean an invalid coalesced move (both webs have no
826 possible hardreg in common), so abort. */
832 {
835 }
837 /* We want the most relaxed combination of spill_temp state.
838 I.e. if any was no spilltemp or a spilltemp2, the result is so too,
839 otherwise if any is short, the result is too. It remains, when both
840 are normal spilltemps. */
847 }
849 /* Attempt to coalesce the first thing on the move worklist.
850 This is used only for iterated coalescing. */
852 static void
854 {
861 {
865 }
867 {
871 }
875 {
881 }
885 {
891 }
892 else
894 }
896 /* Freeze the moves associated with the web. Used for iterated coalescing. */
898 static void
901 {
904 {
910 else
918 /* XXX GA use the original v, instead of alias(v) */
920 {
923 }
924 }
925 }
927 /* Freeze the first thing on the freeze worklist (only for iterated
928 coalescing). */
930 static void
932 {
936 }
938 /* The current spill heuristic. Returns a number for a WEB.
939 Webs with higher numbers are selected later. */
945 /* Our default heuristic is similar to spill_cost / num_conflicts.
946 Just scaled for integer arithmetic, and it favors coalesced webs,
947 and webs which span more insns with deaths. */
949 static unsigned HOST_WIDE_INT
952 {
955 /* Make coalesce targets cheaper to spill, because they will be broken
956 up again into smaller parts. */
961 /* It is better to spill webs that span more insns (deaths in our
962 case) than other webs with the otherwise same spill_cost. So make
963 them a little bit cheaper. Remember that spill_cost is unsigned. */
967 }
969 /* Select the cheapest spill to be potentially spilled (we don't
970 *actually* spill until we need to). */
972 static void
974 {
981 {
985 {
988 }
989 /* Specially marked spill temps can be spilled. Also coalesce
990 targets can. Eventually they will be broken up later in the
991 colorizing process, so if we have nothing better take that. */
993 {
996 }
997 }
999 {
1002 }
1006 /* Note the potential spill. */
1013 }
1015 /* Given a set of forbidden colors to begin at, and a set of still
1016 free colors, and MODE, returns nonzero of color C is still usable. */
1018 static int
1023 {
1027 {
1033 }
1035 }
1037 /* I don't want to clutter up the actual code with ifdef's. */
1038 #ifdef REG_ALLOC_ORDER
1039 #define INV_REG_ALLOC_ORDER(c) inv_reg_alloc_order[c]
1040 #else
1041 #define INV_REG_ALLOC_ORDER(c) c
1042 #endif
1044 /* Searches in FREE_COLORS for a block of hardregs of the right length
1045 for MODE, which doesn't begin at a hardreg mentioned in DONT_BEGIN_COLORS.
1046 If it needs more than one hardreg it prefers blocks beginning
1047 at an even hardreg, and only gives an odd begin reg if no other
1048 block could be found. */
1050 int
1054 {
1065 {
1070 {
1073 }
1075 {
1077 {
1079 {
1082 }
1083 }
1085 {
1088 }
1089 }
1090 else
1092 }
1094 }
1096 /* Similar to get_free_reg(), but first search in colors provided
1097 by BIAS _and_ PREFER_COLORS, then in BIAS alone, then in PREFER_COLORS
1098 alone, and only then for any free color. If flag_ra_biased is zero
1099 only do the last two steps. */
1101 static int
1105 {
1107 HARD_REG_SET s;
1109 {
1121 }
1129 }
1131 /* Counts the number of non-overlapping bitblocks of length LEN
1132 in FREE_COLORS. */
1134 static int
1136 HARD_REG_SET free_colors;
1138 {
1142 {
1148 /* Bits [i .. i+j-1] are free. */
1150 count++;
1152 }
1154 }
1156 /* Given a hardreg set S, return a string representing it.
1157 Either as 0/1 string, or as hex value depending on the implementation
1158 of hardreg sets. Note that this string is statically allocated. */
1162 HARD_REG_SET s;
1163 {
1165 #if FIRST_PSEUDO_REGISTER <= HOST_BITS_PER_WIDE_INT
1167 #else
1172 {
1176 }
1178 #endif
1180 }
1182 /* For WEB, look at its already colored neighbors, and calculate
1183 the set of hardregs which is not allowed as color for WEB. Place
1184 that set int *RESULT. Note that the set of forbidden begin colors
1185 is not the same as all colors taken up by neighbors. E.g. suppose
1186 two DImode webs, but only the lo-part from one conflicts with the
1187 hipart from the other, and suppose the other gets colors 2 and 3
1188 (it needs two SImode hardregs). Now the first can take also color
1189 1 or 2, although in those cases there's a partial overlap. Only
1190 3 can't be used as begin color. */
1192 static void
1196 {
1198 HARD_REG_SET dont_begin;
1199 /* The bits set in dont_begin correspond to the hardregs, at which
1200 WEB may not begin. This differs from the set of _all_ hardregs which
1201 are taken by WEB's conflicts in the presence of wide webs, where only
1202 some parts conflict with others. */
1205 {
1211 {
1213 {
1217 /* ssize is only a first guess for the size. */
1222 /* C1 and C2 can become negative, so unsigned
1223 would be wrong. */
1236 {
1239 /* Because ssize was only guessed above, which influenced our
1240 begin color (c1), we need adjustment, if for that color
1241 another size would be needed. This is done by moving
1242 c1 to a place, where the last of sources hardregs does not
1243 overlap the first of targets colors. */
1247 c1++;
1251 c1--;
1254 }
1255 }
1256 /* The next if() only gets true, if there was no wl->sub at all, in
1257 which case we are only making one go thru this loop with W being
1258 a whole web. */
1263 }
1264 }
1266 }
1268 /* Try to assign a color to WEB. If HARD if nonzero, we try many
1269 tricks to get it one color, including respilling already colored
1270 neighbors.
1272 We also trie very hard, to not constrain the uncolored non-spill
1273 neighbors, which need more hardregs than we. Consider a situation, 2
1274 hardregs free for us (0 and 1), and one of our neighbors needs 2
1275 hardregs, and only conflicts with us. There are 3 hardregs at all. Now
1276 a simple minded method might choose 1 as color for us. Then our neighbor
1277 has two free colors (0 and 2) as it should, but they are not consecutive,
1278 so coloring it later would fail. This leads to nasty problems on
1279 register starved machines, so we try to avoid this. */
1281 static void
1285 {
1295 HARD_REG_SET fat_colors;
1296 HARD_REG_SET bias;
1303 /* First we want to know the colors at which we can't begin. */
1307 /* Now setup the set of colors used by our neighbors neighbors,
1308 and search the biggest noncolored neighbor. */
1311 {
1320 {
1323 {
1326 num_fat++;
1327 }
1332 }
1333 }
1338 /* If there are some fat neighbors, remember their usable regs,
1339 and how many blocks are free in it for that neighbor. */
1341 {
1344 }
1346 /* We break out, if we found a color which doesn't constrain
1347 neighbors, or if we can't find any colors. */
1349 {
1350 HARD_REG_SET call_clobbered;
1352 /* Here we choose a hard-reg for the current web. For non spill
1353 temporaries we first search in the hardregs for it's preferred
1354 class, then, if we found nothing appropriate, in those of the
1355 alternate class. For spill temporaries we only search in
1356 usable_regs of this web (which is probably larger than that of
1357 the preferred or alternate class). All searches first try to
1358 find a non-call-clobbered hard-reg.
1359 XXX this should be more finegraned... First look into preferred
1360 non-callclobbered hardregs, then _if_ the web crosses calls, in
1361 alternate non-cc hardregs, and only _then_ also in preferred cc
1362 hardregs (and alternate ones). Currently we don't track the number
1363 of calls crossed for webs. We should. */
1365 {
1369 }
1370 else
1373 #ifdef CANNOT_CHANGE_MODE_CLASS
1376 #endif
1380 /* If this web got a color in the last pass, try to give it the
1381 same color again. This will to much better colorization
1382 down the line, as we spilled for a certain coloring last time. */
1384 {
1389 }
1390 else
1400 {
1403 else
1406 #ifdef CANNOT_CHANGE_MODE_CLASS
1409 #endif
1418 }
1423 /* If one of the yet uncolored neighbors, which is not a potential
1424 spill needs a block of hardregs be sure, not to destroy such a block
1425 by coloring one reg in the middle. */
1427 {
1430 HARD_REG_SET colors1;
1435 /* If we changed the number of long blocks, and it's now smaller
1436 than needed, we try to avoid this color. */
1438 {
1440 {
1443 }
1446 }
1447 else
1448 /* We found a color which doesn't destroy a block. */
1450 }
1451 /* If we havee no fat neighbors, the current color won't become
1452 "better", so we've found it. */
1453 else
1455 }
1458 {
1459 /* This is a non-potential-spill web, which got a color, which did
1460 destroy a hardreg block for one of it's neighbors. We color
1461 this web anyway and hope for the best for the neighbor, if we are
1462 a spill temp. */
1466 }
1470 {
1471 /* Guard against a simplified node being spilled. */
1472 /* Don't abort. This can happen, when e.g. enough registers
1473 are available in colors, but they are not consecutive. This is a
1474 very serious issue if this web is a short live one, because
1475 even if we spill this one here, the situation won't become better
1476 in the next iteration. It probably will have the same conflicts,
1477 those will have the same colors, and we would come here again, for
1478 all parts, in which this one gets splitted by the spill. This
1479 can result in endless iteration spilling the same register again and
1480 again. That's why we try to find a neighbor, which spans more
1481 instructions that ourself, and got a color, and try to spill _that_.
1483 if (DLIST_WEB (d)->was_spilled < 0)
1484 abort (); */
1486 {
1493 /* We make multiple passes over our conflicts, first trying to
1494 spill those webs, which only got a color by chance, but
1495 were potential spill ones, and if that isn't enough, in a second
1496 pass also to spill normal colored webs. If we still didn't find
1497 a candidate, but we are a spill-temp, we make a third pass
1498 and include also webs, which were targets for coalescing, and
1499 spill those. */
1501 #define set_cand(i, w) \
1502 do { \
1503 if (!candidates[(i)] \
1504 || (candidates[(i)]->spill_cost < (w)->spill_cost)) \
1505 candidates[(i)] = (w); \
1506 } while (0)
1508 {
1511 /* If we are a spill-temp, we also look at webs coalesced
1512 to precolored ones. Otherwise we only look at webs which
1513 themselves were colored, or coalesced to one. */
1516 {
1528 }
1533 {
1538 }
1541 {
1546 }
1548 {
1560 /* For boehm-gc/misc.c. If we are a difficult spilltemp,
1561 also coalesced neighbors are a chance, _even_ if they
1562 too are spilltemps. At least their coalescing can be
1563 broken up, which may be reset usable_regs, and makes
1564 it easier colorable. */
1568 }
1569 }
1573 #undef set_cand
1575 {
1578 {
1585 }
1586 else
1587 {
1590 /* Now try to colorize us again. Can recursively make other
1591 webs also spill, until there are no more unspilled
1592 neighbors. */
1596 {
1597 /* We tried recursively to spill all already colored
1598 neighbors, but we are still uncolorable. So it made
1599 no sense to spill those neighbors. Recolor them. */
1605 }
1606 else
1607 {
1614 else
1616 }
1617 }
1618 }
1619 else
1620 /* No more chances to get a color, so give up hope and
1621 spill us. */
1623 }
1624 else
1626 }
1627 else
1628 {
1632 {
1635 {
1640 }
1641 }
1642 }
1644 {
1648 }
1651 {
1660 }
1661 }
1663 /* Assign the colors to all nodes on the select stack. And update the
1664 colors of coalesced webs. */
1666 static void
1668 {
1672 {
1675 }
1678 {
1681 }
1682 }
1684 /* WEB is a spilled web. Look if we can improve the cost of the graph,
1685 by coloring WEB, even if we then need to spill some of it's neighbors.
1686 For this we calculate the cost for each color C, that results when we
1687 _would_ give WEB color C (i.e. the cost of the then spilled neighbors).
1688 If the lowest cost among them is smaller than the spillcost of WEB, we
1689 do that recoloring, and instead spill the neighbors.
1691 This can sometime help, when due to irregularities in register file,
1692 and due to multi word pseudos, the colorization is suboptimal. But
1693 be aware, that currently this pass is quite slow. */
1695 static void
1698 {
1706 /* For each hard-regs count the number of preceding hardregs, which
1707 would overlap this color, if used in WEB's mode. */
1711 {
1725 }
1730 {
1731 HARD_REG_SET dont_begin;
1737 {
1739 {
1745 }
1747 }
1748 /* Mark colors for which some wide webs are involved. For
1749 those the independent sets are not simply one-node graphs, so
1750 they can't be recolored independent from their neighborhood. This
1751 means, that our cost calculation can be incorrect (assuming it
1752 can avoid spilling a web because it thinks some colors are available,
1753 although it's neighbors which itself need recoloring might take
1754 away exactly those colors). */
1762 /* Note that min_color[] contains 1-based values (zero means
1763 undef). */
1769 {
1771 HARD_REG_SET colors;
1780 {
1783 else
1785 }
1786 }
1787 }
1797 {
1803 newcol);
1809 {
1811 /* If web2 is a coalesce-target, and will become spilled
1812 below in colorize_one_web(), and the current conflict wl
1813 between web and web2 was only the result of that coalescing
1814 this conflict will be deleted, making wl invalid. So save
1815 the next conflict right now. Note that if web2 has indeed
1816 such state, then wl->next can not be deleted in this
1817 iteration. */
1820 {
1830 /* Allow webs to be spilled. */
1836 }
1837 }
1838 /* The actual cost may be smaller than the guessed one, because
1839 partial conflicts could result in some conflicting webs getting
1840 a color, where we assumed it must be spilled. See the comment
1841 above what happens, when wide webs are involved, and why in that
1842 case there might actually be some webs spilled although thought to
1843 be colorable. */
1847 /* But if the new spill-cost is higher than our own, then really loose.
1848 Respill us and recolor neighbors as before. */
1850 {
1857 {
1860 {
1862 {
1866 }
1870 /* This means, that WEB2 once was a part of a coalesced
1871 web, which got spilled in the above colorize_one_web()
1872 call, and whose parts then got splitted and put back
1873 onto the SELECT stack. As the cause for that splitting
1874 (the coloring of WEB) was worthless, we should again
1875 coalesce the parts, as they were before. For now we
1876 simply leave them SELECTed, for our caller to take
1877 care. */
1878 ;
1879 else
1881 }
1882 }
1883 }
1885 }
1888 }
1890 /* This ensures that all conflicts of coalesced webs are seen from
1891 the webs coalesced into. combine() only adds the conflicts which
1892 at the time of combining were not already SELECTed or COALESCED
1893 to not destroy num_conflicts. Here we add all remaining conflicts
1894 and thereby destroy num_conflicts. This should be used when num_conflicts
1895 isn't used anymore, e.g. on a completely colored graph. */
1897 static void
1899 {
1902 {
1907 {
1914 {
1917 /* There might be some conflict edges laying around
1918 where the usable_regs don't intersect. This can happen
1919 when first some webs were coalesced and conflicts
1920 propagated, then some combining narrowed usable_regs and
1921 further coalescing ignored those conflicts. Now there are
1922 some edges to COALESCED webs but not to it's alias.
1923 So abort only when they really should conflict. */
1932 /*if (wl->sub == NULL)
1933 record_conflict (tweb, wl->t);
1934 else
1935 {
1936 struct sub_conflict *sl;
1937 for (sl = wl->sub; sl; sl = sl->next)
1938 record_conflict (tweb, sl->t);
1939 }*/
1942 }
1943 }
1944 }
1945 }
1947 /* A function suitable to pass to qsort(). Compare the spill costs
1948 of webs W1 and W2. When used by qsort, this would order webs with
1949 largest cost first. */
1951 static int
1954 {
1961 else
1963 }
1965 /* This tries to recolor all spilled webs. See try_recolor_web()
1966 how this is done. This just calls it for each spilled web. */
1968 static void
1970 {
1976 {
1978 /* If we aren't breaking aliases, combine() wasn't merging the
1979 spill_costs. So do that here to have sane measures. */
1982 }
1987 {
1991 }
1992 /* It might have been decided in try_recolor_web() (in colorize_one_web())
1993 that a coalesced web should be spilled, so it was put on the
1994 select stack. Those webs need recoloring again, and all remaining
1995 coalesced webs might need their color updated, so simply call
1996 assign_colors() again. */
1999 }
2001 /* This checks the current color assignment for obvious errors,
2002 like two conflicting webs overlapping in colors, or the used colors
2003 not being in usable regs. */
2005 static void
2007 {
2010 {
2021 else
2023 /* The color must be valid for the original usable_regs. */
2027 /* Search the original (pre-coalesce) conflict list. In the current
2028 one some imprecise conflicts may be noted (due to combine() or
2029 insert_coalesced_conflicts() relocating partial conflicts) making
2030 it look like some wide webs are in conflict and having the same
2031 color. */
2038 {
2045 else
2051 }
2052 else
2053 {
2060 {
2075 }
2076 }
2077 }
2078 }
2080 /* WEB was a coalesced web. Make it unaliased again, and put it
2081 back onto SELECT stack. */
2083 static void
2086 {
2090 /* Well, initially everything was spilled, so it isn't incorrect,
2091 that also the individual parts can be spilled.
2092 XXX this isn't entirely correct, as we also relaxed the
2093 spill_temp flag in combine(), which might have made components
2094 spill, although they were a short or spilltemp web. */
2097 /* Spilltemps must be colored right now (i.e. as early as possible),
2098 other webs can be deferred to the end (the code building the
2099 stack assumed that in this stage only one web was colored). */
2102 else
2104 }
2106 /* WEB is a _target_ for coalescing which got spilled.
2107 Break all aliases to WEB, and restore some of its member to the state
2108 they were before coalescing. Due to the suboptimal structure of
2109 the interference graph we need to go through all coalesced webs.
2110 Somewhen we'll change this to be more sane. */
2112 static void
2115 {
2120 {
2123 /* Beware: Don't use alias() here. We really want to check only
2124 one level of aliasing, i.e. only break up webs directly
2125 aliased to WEB, not also those aliased through other webs. */
2127 {
2130 }
2131 }
2134 /* Beware: The following possibly widens usable_regs again. While
2135 it was narrower there might have been some conflicts added which got
2136 ignored because of non-intersecting hardregsets. All those conflicts
2137 would now matter again. Fortunately we only add conflicts when
2138 coalescing, which is also the time of narrowing. And we remove all
2139 those added conflicts again now that we unalias this web.
2140 Therefore this is safe to do. */
2145 /* Reset is_coalesced flag for webs which itself are target of coalescing.
2146 It was cleared above if it was coalesced to WEB. */
2149 }
2151 /* WEB is a web coalesced into a precolored one. Break that alias,
2152 making WEB SELECTed again. Also restores the conflicts which resulted
2153 from initially coalescing both. */
2155 static void
2158 {
2166 /* Now we need to look at each conflict X of WEB, if it conflicts
2167 with [PRE, PRE+nregs), and remove such conflicts, of X has not other
2168 conflicts, which are coalesced into those precolored webs. */
2170 {
2176 HARD_REG_SET regs;
2179 /* First look at which colors can not go away, due to other coalesces
2180 still existing. */
2187 /* Now also remove the colors of those conflicts which already
2188 were there before coalescing at all. */
2192 /* The colors now still set are those for which WEB was the last
2193 cause, i.e. those which can be removed. */
2197 {
2205 }
2210 {
2214 else
2216 }
2217 }
2218 }
2220 /* WEB is a spilled web which was target for coalescing.
2221 Delete all interference edges which were added due to that coalescing,
2222 and break up the coalescing. */
2224 static void
2227 {
2231 /* No original conflict list means no conflict was added at all
2232 after building the graph. So neither we nor any neighbors have
2233 conflicts due to this coalescing. */
2237 {
2243 {
2244 /* We found this conflict also in the original list, so this
2245 was no new conflict. */
2247 }
2248 else
2249 {
2250 /* This is a new conflict, so delete it from us and
2251 the neighbor. */
2266 {
2268 {
2272 }
2273 else
2274 {
2276 }
2277 }
2280 /* wl and owl contain the edge data to be deleted. */
2287 {
2290 }
2291 }
2292 }
2294 /* We must restore usable_regs because record_conflict will use it. */
2296 /* We might have deleted some conflicts above, which really are still
2297 there (diamond pattern coalescing). This is because we don't reference
2298 count interference edges but some of them were the result of different
2299 coalesces. */
2302 {
2305 {
2308 else
2309 {
2312 {
2319 }
2320 }
2323 }
2324 }
2325 }
2327 /* Repeatedly break aliases for spilled webs, which were target for
2328 coalescing, and recolorize the resulting parts. Do this as long as
2329 there are any spilled coalesce targets. */
2331 static void
2333 {
2336 {
2349 /* WEB was a spilled web and isn't anymore. Everything coalesced
2350 to WEB is now SELECTed and might potentially get a color.
2351 If those other webs were itself targets of coalescing it might be
2352 that there are still some conflicts from aliased webs missing,
2353 because they were added in combine() right into the now
2354 SELECTed web. So we need to add those missing conflicts here. */
2361 {
2364 }
2365 }
2367 {
2370 {
2373 }
2374 }
2376 }
2378 /* A structure for fast hashing of a pair of webs.
2379 Used to cumulate savings (from removing copy insns) for coalesced webs.
2380 All the pairs are also put into a single linked list. */
2381 struct web_pair
2382 {
2389 };
2391 /* The actual hash table. */
2392 #define WEB_PAIR_HASH_SIZE 8192
2397 /* Clear the hash table of web pairs. */
2399 static void
2401 {
2405 }
2407 /* Given two webs connected by a move with cost COST which together
2408 have CONFLICTS conflicts, add that pair to the hash table, or if
2409 already in, cumulate the costs and conflict number. */
2411 static void
2416 {
2420 {
2424 }
2428 {
2432 }
2442 num_web_pairs++;
2443 }
2445 /* Suitable to be passed to qsort(). Sort web pairs so, that those
2446 with more conflicts and higher cost (which actually is a saving
2447 when the moves are removed) come first. */
2449 static int
2452 {
2463 else
2465 }
2467 /* Given the list of web pairs, begin to combine them from the one
2468 with the most savings. */
2470 static void
2473 {
2486 /* After combining one pair, we actually should adjust the savings
2487 of the other pairs, if they are connected to one of the just coalesced
2488 pair. Later. */
2490 {
2498 {
2502 }
2508 {
2514 }
2515 }
2517 }
2519 /* Greedily coalesce all moves possible. Begin with the web pair
2520 giving the most saving if coalesced. */
2522 static void
2524 {
2530 {
2534 {
2538 }
2543 {
2546 {
2550 }
2552 /* It is !ok(t, s). But later when coloring the graph it might
2553 be possible to take that color. So we remember the preferred
2554 color to try that first. */
2555 {
2558 }
2559 }
2560 else
2561 {
2563 }
2564 }
2566 }
2568 /* This is the difference between optimistic coalescing and
2569 optimistic coalescing+. Extended coalesce tries to coalesce also
2570 non-conflicting nodes, not related by a move. The criteria here is,
2571 the one web must be a source, the other a destination of the same insn.
2572 This actually makes sense, as (because they are in the same insn) they
2573 share many of their neighbors, and if they are coalesced, reduce the
2574 number of conflicts of those neighbors by one. For this we sort the
2575 candidate pairs again according to savings (and this time also conflict
2576 number).
2578 This is also a comparatively slow operation, as we need to go through
2579 all insns, and for each insn, through all defs and uses. */
2581 static void
2583 {
2584 rtx insn;
2591 {
2595 {
2598 {
2604 /* Coalesced webs end up using the same REG rtx in
2605 emit_colors(). So we can only coalesce something
2606 of equal modes. */
2616 dest->num_conflicts
2618 }
2619 }
2620 }
2622 }
2624 /* Check if we forgot to coalesce some moves. */
2626 static void
2628 {
2633 {
2637 {
2641 }
2644 /* Following can happen when a move was coalesced, but later
2645 broken up again. Then s!=t, but m is still MV_COALESCED. */
2653 }
2654 }
2656 /* The toplevel function in this file. Precondition is, that
2657 the interference graph is built completely by ra-build.c. This
2658 produces a list of spilled, colored and coalesced nodes. */
2660 void
2663 {
2668 /* With optimistic coalescing we coalesce everything we can. */
2670 {
2673 }
2675 /* Now build the select stack. */
2676 do
2677 {
2685 }
2691 /* Actually colorize the webs from the select stack. */
2699 /* And try to improve the cost by recoloring spilled webs. */
2703 }
2705 /* Initialize this module. */
2708 {
2709 /* FIXME: Choose spill heuristic for platform if we have one */
2711 }
2713 /* Free all memory. (Note that we don't need to free any per pass
2714 memory). */
2716 void
2718 {
2723 {
2729 {
2732 }
2734 }
2735 }
2737 /*
2738 vim:cinoptions={.5s,g0,p5,t0,(0,^-0.5s,n-0.5s:tw=78:cindent:sw=4:
2739 */