| blob | 0cda11f83b53963201c5d90a466bfe422633a43d |
1 /* Allocate registers for pseudo-registers that span basic blocks.
2 Copyright (C) 1987, 1988, 1991, 1994, 1996, 1997, 1998,
3 1999, 2000, 2002, 2003, 2004 Free Software Foundation, Inc.
5 This file is part of GCC.
7 GCC is free software; you can redistribute it and/or modify it under
8 the terms of the GNU General Public License as published by the Free
9 Software Foundation; either version 2, or (at your option) any later
10 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
14 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
15 for more details.
17 You should have received a copy of the GNU General Public License
18 along with GCC; see the file COPYING. If not, write to the Free
19 Software Foundation, 59 Temple Place - Suite 330, Boston, MA
20 02111-1307, USA. */
42 /* This pass of the compiler performs global register allocation.
43 It assigns hard register numbers to all the pseudo registers
44 that were not handled in local_alloc. Assignments are recorded
45 in the vector reg_renumber, not by changing the rtl code.
46 (Such changes are made by final). The entry point is
47 the function global_alloc.
49 After allocation is complete, the reload pass is run as a subroutine
50 of this pass, so that when a pseudo reg loses its hard reg due to
51 spilling it is possible to make a second attempt to find a hard
52 reg for it. The reload pass is independent in other respects
53 and it is run even when stupid register allocation is in use.
55 1. Assign allocation-numbers (allocnos) to the pseudo-registers
56 still needing allocations and to the pseudo-registers currently
57 allocated by local-alloc which may be spilled by reload.
58 Set up tables reg_allocno and allocno_reg to map
59 reg numbers to allocnos and vice versa.
60 max_allocno gets the number of allocnos in use.
62 2. Allocate a max_allocno by max_allocno conflict bit matrix and clear it.
63 Allocate a max_allocno by FIRST_PSEUDO_REGISTER conflict matrix
64 for conflicts between allocnos and explicit hard register use
65 (which includes use of pseudo-registers allocated by local_alloc).
67 3. For each basic block
68 walk forward through the block, recording which
69 pseudo-registers and which hardware registers are live.
70 Build the conflict matrix between the pseudo-registers
71 and another of pseudo-registers versus hardware registers.
72 Also record the preferred hardware registers
73 for each pseudo-register.
75 4. Sort a table of the allocnos into order of
76 desirability of the variables.
78 5. Allocate the variables in that order; each if possible into
79 a preferred register, else into another register. */
80 \f
81 /* Number of pseudo-registers which are candidates for allocation. */
85 /* Indexed by (pseudo) reg number, gives the allocno, or -1
86 for pseudo registers which are not to be allocated. */
90 struct allocno
91 {
93 /* Gives the number of consecutive hard registers needed by that
94 pseudo reg. */
97 /* Number of calls crossed by each allocno. */
100 /* Number of refs to each allocno. */
103 /* Frequency of uses of each allocno. */
106 /* Guess at live length of each allocno.
107 This is actually the max of the live lengths of the regs. */
110 /* Set of hard regs conflicting with allocno N. */
112 HARD_REG_SET hard_reg_conflicts;
114 /* Set of hard regs preferred by allocno N.
115 This is used to make allocnos go into regs that are copied to or from them,
116 when possible, to reduce register shuffling. */
118 HARD_REG_SET hard_reg_preferences;
120 /* Similar, but just counts register preferences made in simple copy
121 operations, rather than arithmetic. These are given priority because
122 we can always eliminate an insn by using these, but using a register
123 in the above list won't always eliminate an insn. */
125 HARD_REG_SET hard_reg_copy_preferences;
127 /* Similar to hard_reg_preferences, but includes bits for subsequent
128 registers when an allocno is multi-word. The above variable is used for
129 allocation while this is used to build reg_someone_prefers, below. */
131 HARD_REG_SET hard_reg_full_preferences;
133 /* Set of hard registers that some later allocno has a preference for. */
135 HARD_REG_SET regs_someone_prefers;
137 #ifdef STACK_REGS
138 /* Set to true if allocno can't be allocated in the stack register. */
140 #endif
141 };
145 /* A vector of the integers from 0 to max_allocno-1,
146 sorted in the order of first-to-be-allocated first. */
150 /* Indexed by (pseudo) reg number, gives the number of another
151 lower-numbered pseudo reg which can share a hard reg with this pseudo
152 *even if the two pseudos would otherwise appear to conflict*. */
156 /* Define the number of bits in each element of `conflicts' and what
157 type that element has. We use the largest integer format on the
158 host machine. */
160 #define INT_BITS HOST_BITS_PER_WIDE_INT
161 #define INT_TYPE HOST_WIDE_INT
163 /* max_allocno by max_allocno array of bits,
164 recording whether two allocno's conflict (can't go in the same
165 hardware register).
167 `conflicts' is symmetric after the call to mirror_conflicts. */
171 /* Number of ints require to hold max_allocno bits.
172 This is the length of a row in `conflicts'. */
176 /* Two macros to test or store 1 in an element of `conflicts'. */
178 #define CONFLICTP(I, J) \
179 (conflicts[(I) * allocno_row_words + (unsigned) (J) / INT_BITS] \
180 & ((INT_TYPE) 1 << ((unsigned) (J) % INT_BITS)))
182 /* For any allocno set in ALLOCNO_SET, set ALLOCNO to that allocno,
183 and execute CODE. */
184 #define EXECUTE_IF_SET_IN_ALLOCNO_SET(ALLOCNO_SET, ALLOCNO, CODE) \
185 do { \
186 int i_; \
187 int allocno_; \
188 INT_TYPE *p_ = (ALLOCNO_SET); \
189 \
190 for (i_ = allocno_row_words - 1, allocno_ = 0; i_ >= 0; \
191 i_--, allocno_ += INT_BITS) \
192 { \
193 unsigned INT_TYPE word_ = (unsigned INT_TYPE) *p_++; \
194 \
195 for ((ALLOCNO) = allocno_; word_; word_ >>= 1, (ALLOCNO)++) \
196 { \
197 if (word_ & 1) \
198 {CODE;} \
199 } \
200 } \
201 } while (0)
203 /* This doesn't work for non-GNU C due to the way CODE is macro expanded. */
204 #if 0
205 /* For any allocno that conflicts with IN_ALLOCNO, set OUT_ALLOCNO to
206 the conflicting allocno, and execute CODE. This macro assumes that
207 mirror_conflicts has been run. */
208 #define EXECUTE_IF_CONFLICT(IN_ALLOCNO, OUT_ALLOCNO, CODE)\
209 EXECUTE_IF_SET_IN_ALLOCNO_SET (conflicts + (IN_ALLOCNO) * allocno_row_words,\
210 OUT_ALLOCNO, (CODE))
211 #endif
213 /* Set of hard regs currently live (during scan of all insns). */
217 /* Set of registers that global-alloc isn't supposed to use. */
221 /* Set of registers used so far. */
225 /* Number of refs to each hard reg, as used by local alloc.
226 It is zero for a reg that contains global pseudos or is explicitly used. */
230 /* Frequency of uses of given hard reg. */
233 /* Guess at live length of each hard reg, as used by local alloc.
234 This is actually the sum of the live lengths of the specific regs. */
238 /* Set to 1 a bit in a vector TABLE of HARD_REG_SETs, for vector
239 element I, and hard register number J. */
241 #define SET_REGBIT(TABLE, I, J) SET_HARD_REG_BIT (allocno[I].TABLE, J)
243 /* Bit mask for allocnos live at current point in the scan. */
247 /* Test, set or clear bit number I in allocnos_live,
248 a bit vector indexed by allocno. */
250 #define SET_ALLOCNO_LIVE(I) \
251 (allocnos_live[(unsigned) (I) / INT_BITS] \
252 |= ((INT_TYPE) 1 << ((unsigned) (I) % INT_BITS)))
254 #define CLEAR_ALLOCNO_LIVE(I) \
255 (allocnos_live[(unsigned) (I) / INT_BITS] \
256 &= ~((INT_TYPE) 1 << ((unsigned) (I) % INT_BITS)))
258 /* This is turned off because it doesn't work right for DImode.
259 (And it is only used for DImode, so the other cases are worthless.)
260 The problem is that it isn't true that there is NO possibility of conflict;
261 only that there is no conflict if the two pseudos get the exact same regs.
262 If they were allocated with a partial overlap, there would be a conflict.
263 We can't safely turn off the conflict unless we have another way to
264 prevent the partial overlap.
266 Idea: change hard_reg_conflicts so that instead of recording which
267 hard regs the allocno may not overlap, it records where the allocno
268 may not start. Change both where it is used and where it is updated.
269 Then there is a way to record that (reg:DI 108) may start at 10
270 but not at 9 or 11. There is still the question of how to record
271 this semi-conflict between two pseudos. */
272 #if 0
273 /* Reg pairs for which conflict after the current insn
274 is inhibited by a REG_NO_CONFLICT note.
275 If the table gets full, we ignore any other notes--that is conservative. */
276 #define NUM_NO_CONFLICT_PAIRS 4
277 /* Number of pairs in use in this insn. */
283 /* Record all regs that are set in any one insn.
284 Communication from mark_reg_{store,clobber} and global_conflicts. */
289 /* All registers that can be eliminated. */
325 \f
327 /* Perform allocation of pseudo-registers not allocated by local_alloc.
328 FILE is a file to output debugging information on,
329 or zero if such output is not desired.
331 Return value is nonzero if reload failed
332 and we must not do any more for this function. */
334 int
336 {
338 #ifdef ELIMINABLE_REGS
340 #endif
341 int need_fp
342 = (! flag_omit_frame_pointer
347 rtx x;
353 /* A machine may have certain hard registers that
354 are safe to use only within a basic block. */
358 /* Build the regset of all eliminable registers and show we can't use those
359 that we already know won't be eliminated. */
360 #ifdef ELIMINABLE_REGS
362 {
363 bool cannot_elim
368 {
373 }
377 else
379 }
380 #if FRAME_POINTER_REGNUM != HARD_FRAME_POINTER_REGNUM
382 {
386 }
390 else
392 #endif
394 #else
396 {
400 }
403 else
405 #endif
407 /* Track which registers have already been used. Start with registers
408 explicitly in the rtl, then registers allocated by local register
409 allocation. */
412 #ifdef LEAF_REGISTERS
413 /* If we are doing the leaf function optimization, and this is a leaf
414 function, it means that the registers that take work to save are those
415 that need a register window. So prefer the ones that can be used in
416 a leaf function. */
417 {
423 else
428 }
429 #else
430 /* We consider registers that do not have to be saved over calls as if
431 they were already used since there is no cost in using them. */
435 #endif
441 /* Establish mappings from register number to allocation number
442 and vice versa. In the process, count the allocnos. */
449 /* Initialize the shared-hard-reg mapping
450 from the list of pairs that may share. */
453 {
458 else
460 }
463 /* Note that reg_live_length[i] < 0 indicates a "constant" reg
464 that we are supposed to refrain from putting in a hard reg.
465 -2 means do make an allocno but don't allocate it. */
467 /* Don't allocate pseudos that cross calls,
468 if this function receives a nonlocal goto. */
469 && (! current_function_has_nonlocal_label
471 {
475 else
478 }
479 else
486 {
495 }
497 /* Calculate amount of usage of each hard reg by pseudos
498 allocated by local-alloc. This is to see if we want to
499 override it. */
505 {
511 {
515 }
516 }
518 /* We can't override local-alloc for a reg used not just by local-alloc. */
525 /* We used to use alloca here, but the size of what it would try to
526 allocate would occasionally cause it to exceed the stack limit and
527 cause unpredictable core dumps. Some examples were > 2Mb in size. */
532 /* If there is work to be done (at least one reg to allocate),
533 perform global conflict analysis and allocate the regs. */
536 {
537 /* Scan all the insns and compute the conflicts among allocnos
538 and between allocnos and hard regs. */
544 /* Eliminate conflicts between pseudos and eliminable registers. If
545 the register is not eliminated, the pseudo won't really be able to
546 live in the eliminable register, so the conflict doesn't matter.
547 If we do eliminate the register, the conflict will no longer exist.
548 So in either case, we can ignore the conflict. Likewise for
549 preferences. */
552 {
554 eliminable_regset);
556 eliminable_regset);
558 eliminable_regset);
559 }
561 /* Try to expand the preferences by merging them between allocnos. */
565 /* Determine the order to allocate the remaining pseudo registers. */
571 /* Default the size to 1, since allocno_compare uses it to divide by.
572 Also convert allocno_live_length of zero to -1. A length of zero
573 can occur when all the registers for that allocno have reg_live_length
574 equal to -2. In this case, we want to make an allocno, but not
575 allocate it. So avoid the divide-by-zero and set it to a low
576 priority. */
579 {
584 }
593 /* Try allocating them, one by one, in that order,
594 except for parameters marked with reg_live_length[regno] == -2. */
599 {
600 /* If we have more than one register class,
601 first try allocating in the class that is cheapest
602 for this pseudo-reg. If that fails, try any reg. */
604 {
608 }
611 }
614 }
616 /* Do the reloads now while the allocno data still exist, so that we can
617 try to assign new hard regs to any pseudo regs that are spilled. */
620 for the sake of debugging information. */
622 #endif
623 {
626 }
628 /* Clean up. */
636 }
638 /* Sort predicate for ordering the allocnos.
639 Returns -1 (1) if *v1 should be allocated before (after) *v2. */
641 static int
643 {
645 /* Note that the quotient will never be bigger than
646 the value of floor_log2 times the maximum number of
647 times a register can occur in one insn (surely less than 100)
648 weighted by the frequency (maximally REG_FREQ_MAX).
649 Multiplying this by 10000/REG_FREQ_MAX can't overflow. */
650 int pri1
654 int pri2
661 /* If regs are equally good, sort by allocno,
662 so that the results of qsort leave nothing to chance. */
664 }
665 \f
666 /* Scan the rtl code and record all conflicts and register preferences in the
667 conflict matrices and preference tables. */
669 static void
671 {
673 basic_block b;
674 rtx insn;
677 /* Make a vector that mark_reg_{store,clobber} will store in. */
683 {
686 /* Initialize table of registers currently live
687 to the state at the beginning of this basic block.
688 This also marks the conflicts among hard registers
689 and any allocnos that are live.
691 For pseudo-regs, there is only one bit for each one
692 no matter how many hard regs it occupies.
693 This is ok; we know the size from PSEUDO_REGNO_SIZE.
694 For explicit hard regs, we cannot know the size that way
695 since one hard reg can be used with various sizes.
696 Therefore, we must require that all the hard regs
697 implicitly live as part of a multi-word hard reg
698 are explicitly marked in basic_block_live_at_start. */
700 {
703 reg_set_iterator rsi;
707 {
710 {
713 }
716 }
718 /* Record that each allocno now live conflicts with each hard reg
719 now live.
721 It is not necessary to mark any conflicts between pseudos as
722 this point, even for pseudos which are live at the start of
723 the basic block.
725 Given two pseudos X and Y and any point in the CFG P.
727 On any path to point P where X and Y are live one of the
728 following conditions must be true:
730 1. X is live at some instruction on the path that
731 evaluates Y.
733 2. Y is live at some instruction on the path that
734 evaluates X.
736 3. Either X or Y is not evaluated on the path to P
737 (i.e. it is used uninitialized) and thus the
738 conflict can be ignored.
740 In cases #1 and #2 the conflict will be recorded when we
741 scan the instruction that makes either X or Y become live. */
744 /* Pseudos can't go in stack regs at the start of a basic block that
745 is reached by an abnormal edge. Likewise for call clobbered regs,
746 because because caller-save, fixup_abnormal_edges, and possibly
747 the table driven EH machinery are not quite ready to handle such
748 regs live across such edges. */
749 {
750 edge e;
751 edge_iterator ei;
758 {
759 #ifdef STACK_REGS
761 {
763 });
766 #endif
768 /* No need to record conflicts for call clobbered regs if we have
769 nonlocal labels around, as we don't ever try to allocate such
770 regs in this case. */
775 }
776 }
777 }
781 /* Scan the code of this basic block, noting which allocnos
782 and hard regs are born or die. When one is born,
783 record a conflict with all others currently live. */
786 {
788 rtx link;
790 /* Make regs_set an empty set. */
795 {
797 #if 0
803 {
808 i++;
809 }
812 /* Mark any registers clobbered by INSN as live,
813 so they conflict with the inputs. */
817 /* Mark any registers dead after INSN as dead now. */
823 /* Mark any registers set in INSN as live,
824 and mark them as conflicting with all other live regs.
825 Clobbers are processed again, so they conflict with
826 the registers that are set. */
830 #ifdef AUTO_INC_DEC
834 #endif
836 /* If INSN has multiple outputs, then any reg that dies here
837 and is used inside of an output
838 must conflict with the other outputs.
840 It is unsafe to use !single_set here since it will ignore an
841 unused output. Just because an output is unused does not mean
842 the compiler can assume the side effect will not occur.
843 Consider if REG appears in the address of an output and we
844 reload the output. If we allocate REG to the same hard
845 register as an unused output we could set the hard register
846 before the output reload insn. */
850 {
856 {
863 }
866 }
868 /* Mark any registers set in INSN and then never used. */
871 {
876 }
877 }
882 }
883 }
885 /* Clean up. */
888 }
889 /* Expand the preference information by looking for cases where one allocno
890 dies in an insn that sets an allocno. If those two allocnos don't conflict,
891 merge any preferences between those allocnos. */
893 static void
895 {
896 rtx insn;
897 rtx link;
898 rtx set;
900 /* We only try to handle the most common cases here. Most of the cases
901 where this wins are reg-reg copies. */
914 {
919 {
924 }
934 }
935 }
936 \f
937 /* Prune the preferences for global registers to exclude registers that cannot
938 be used.
940 Compute `regs_someone_prefers', which is a bitmask of the hard registers
941 that are preferred by conflicting registers of lower priority. If possible,
942 we will avoid using these registers. */
944 static void
946 {
951 /* Scan least most important to most important.
952 For each allocno, remove from preferences registers that cannot be used,
953 either because of conflicts or register type. Then compute all registers
954 preferred by each lower-priority register that conflicts. */
957 {
958 HARD_REG_SET temp;
966 else
969 IOR_COMPL_HARD_REG_SET
976 }
979 {
980 /* Merge in the preferences of lower-priority registers (they have
981 already been pruned). If we also prefer some of those registers,
982 don't exclude them unless we are of a smaller size (in which case
983 we want to give the lower-priority allocno the first chance for
984 these registers). */
994 allocno2,
995 {
997 {
1001 else
1004 }
1005 });
1010 }
1012 }
1013 \f
1014 /* Assign a hard register to allocno NUM; look for one that is the beginning
1015 of a long enough stretch of hard regs none of which conflicts with ALLOCNO.
1016 The registers marked in PREFREGS are tried first.
1018 LOSERS, if nonzero, is a HARD_REG_SET indicating registers that cannot
1019 be used for this allocation.
1021 If ALT_REGS_P is zero, consider only the preferred class of ALLOCNO's reg.
1022 Otherwise ignore that preferred class and use the alternate class.
1024 If ACCEPT_CALL_CLOBBERED is nonzero, accept a call-clobbered hard reg that
1025 will have to be saved and restored at calls.
1027 RETRYING is nonzero if this is called from retry_global_alloc.
1029 If we find one, record it in reg_renumber.
1030 If not, do nothing. */
1032 static void
1033 find_reg (int num, HARD_REG_SET losers, int alt_regs_p, int accept_call_clobbered, int retrying)
1034 {
1047 else
1050 /* Some registers should not be allocated in global-alloc. */
1060 #ifdef CANNOT_CHANGE_MODE_CLASS
1062 #endif
1064 /* Try each hard reg to see if it fits. Do this in two passes.
1065 In the first pass, skip registers that are preferred by some other pseudo
1066 to give it a better chance of getting one of those registers. Only if
1067 we can't get a register when excluding those do we take one of them.
1068 However, we never allocate a register for the first time in pass 0. */
1077 pass++)
1078 {
1082 {
1083 #ifdef REG_ALLOC_ORDER
1085 #else
1087 #endif
1091 || accept_call_clobbered
1093 {
1099 j++);
1101 {
1104 }
1105 #ifndef REG_ALLOC_ORDER
1107 #endif
1108 }
1109 }
1110 }
1112 /* See if there is a preferred register with the same class as the register
1113 we allocated above. Making this restriction prevents register
1114 preferencing from creating worse register allocation.
1116 Remove from the preferred registers and conflicting registers. Note that
1117 additional conflicts may have been added after `prune_preferences' was
1118 called.
1120 First do this for those register with copy preferences, then all
1121 preferred registers. */
1128 {
1133 || accept_call_clobbered
1140 {
1152 j++);
1154 {
1157 }
1158 }
1159 }
1160 no_copy_prefs:
1167 {
1172 || accept_call_clobbered
1179 {
1191 j++);
1193 {
1196 }
1197 }
1198 }
1199 no_prefs:
1201 /* If we haven't succeeded yet, try with caller-saves.
1202 We need not check to see if the current function has nonlocal
1203 labels because we don't put any pseudos that are live over calls in
1204 registers in that case. */
1207 {
1208 /* Did not find a register. If it would be profitable to
1209 allocate a call-clobbered register and save and restore it
1210 around calls, do that. */
1215 {
1216 HARD_REG_SET new_losers;
1219 else
1225 {
1228 }
1229 }
1230 }
1232 /* If we haven't succeeded yet,
1233 see if some hard reg that conflicts with us
1234 was utilized poorly by local-alloc.
1235 If so, kick out the regs that were put there by local-alloc
1236 so we can use it instead. */
1238 /* Let's not bother with multi-reg allocnos. */
1240 {
1241 /* Count from the end, to find the least-used ones first. */
1243 {
1244 #ifdef REG_ALLOC_ORDER
1246 #else
1248 #endif
1251 /* Don't use a reg no good for this pseudo. */
1254 /* The code below assumes that we need only a single
1255 register, but the check of allocno[num].size above
1256 was not enough. Sometimes we need more than one
1257 register for a single-word value. */
1260 || accept_call_clobbered
1262 #ifdef CANNOT_CHANGE_MODE_CLASS
1264 mode)
1265 #endif
1266 #ifdef STACK_REGS
1269 #endif
1270 )
1271 {
1272 /* We explicitly evaluate the divide results into temporary
1273 variables so as to avoid excess precision problems that occur
1274 on an i386-unknown-sysv4.2 (unixware) host. */
1282 {
1283 /* Hard reg REGNO was used less in total by local regs
1284 than it would be used by this one allocno! */
1288 {
1290 int endregno
1295 }
1299 }
1300 }
1301 }
1302 }
1304 /* Did we find a register? */
1307 {
1309 HARD_REG_SET this_reg;
1311 /* Yes. Record it as the hard register of this pseudo-reg. */
1313 /* Also of any pseudo-regs that share with it. */
1319 /* Make a set of the hard regs being allocated. */
1323 {
1326 /* This is no longer a reg used just by local regs. */
1329 }
1330 /* For each other pseudo-reg conflicting with this one,
1331 mark it as conflicting with the hard regs this one occupies. */
1334 {
1336 });
1337 }
1338 }
1339 \f
1340 /* Called from `reload' to look for a hard reg to put pseudo reg REGNO in.
1341 Perhaps it had previously seemed not worth a hard reg,
1342 or perhaps its old hard reg has been commandeered for reloads.
1343 FORBIDDEN_REGS indicates certain hard regs that may not be used, even if
1344 they do not appear to be allocated.
1345 If FORBIDDEN_REGS is zero, no regs are forbidden. */
1347 void
1349 {
1352 {
1353 /* If we have more than one register class,
1354 first try allocating in the class that is cheapest
1355 for this pseudo-reg. If that fails, try any reg. */
1362 /* If we found a register, modify the RTL for the register to
1363 show the hard register, and mark that register live. */
1365 {
1368 }
1369 }
1370 }
1371 \f
1372 /* Record a conflict between register REGNO
1373 and everything currently live.
1374 REGNO must not be a pseudo reg that was allocated
1375 by local_alloc; such numbers must be translated through
1376 reg_renumber before calling here. */
1378 static void
1380 {
1384 /* When a hard register becomes live,
1385 record conflicts with live pseudo regs. */
1387 {
1389 });
1390 else
1391 /* When a pseudo-register becomes live,
1392 record conflicts first with hard regs,
1393 then with other pseudo regs. */
1394 {
1401 }
1402 }
1404 /* Record all allocnos currently live as conflicting
1405 with all hard regs currently live.
1407 ALLOCNO_VEC is a vector of LEN allocnos, all allocnos that
1408 are currently live. Their bits are also flagged in allocnos_live. */
1410 static void
1412 {
1415 hard_regs_live);
1416 }
1418 /* If CONFLICTP (i, j) is true, make sure CONFLICTP (j, i) is also true. */
1419 static void
1421 {
1430 {
1432 {
1434 q0++;
1435 }
1437 {
1442 {
1445 }
1446 }
1447 }
1448 }
1449 \f
1450 /* Handle the case where REG is set by the insn being scanned,
1451 during the forward scan to accumulate conflicts.
1452 Store a 1 in regs_live or allocnos_live for this register, record how many
1453 consecutive hardware registers it actually needs,
1454 and record a conflict with all other registers already live.
1456 Note that even if REG does not remain alive after this insn,
1457 we must mark it here as live, to ensure a conflict between
1458 REG and any other regs set in this insn that really do live.
1459 This is because those other regs could be considered after this.
1461 REG might actually be something other than a register;
1462 if so, we do nothing.
1464 SETTER is 0 if this register was modified by an auto-increment (i.e.,
1465 a REG_INC note was found for it). */
1467 static void
1469 {
1485 /* Either this is one of the max_allocno pseudo regs not allocated,
1486 or it is or has a hardware reg. First handle the pseudo-regs. */
1488 {
1490 {
1493 }
1494 }
1499 /* Handle hardware regs (and pseudos allocated to hard regs). */
1501 {
1504 {
1507 regno++;
1508 }
1509 }
1510 }
1511 \f
1512 /* Like mark_reg_set except notice just CLOBBERs; ignore SETs. */
1514 static void
1516 {
1519 }
1521 /* Record that REG has conflicts with all the regs currently live.
1522 Do not mark REG itself as live. */
1524 static void
1526 {
1537 /* Either this is one of the max_allocno pseudo regs not allocated,
1538 or it is or has a hardware reg. First handle the pseudo-regs. */
1540 {
1543 }
1548 /* Handle hardware regs (and pseudos allocated to hard regs). */
1550 {
1553 {
1555 regno++;
1556 }
1557 }
1558 }
1559 \f
1560 /* Mark REG as being dead (following the insn being scanned now).
1561 Store a 0 in regs_live or allocnos_live for this register. */
1563 static void
1565 {
1568 /* Either this is one of the max_allocno pseudo regs not allocated,
1569 or it is a hardware reg. First handle the pseudo-regs. */
1571 {
1574 }
1576 /* For pseudo reg, see if it has been assigned a hardware reg. */
1580 /* Handle hardware regs (and pseudos allocated to hard regs). */
1582 {
1583 /* Pseudo regs already assigned hardware regs are treated
1584 almost the same as explicit hardware regs. */
1587 {
1589 regno++;
1590 }
1591 }
1592 }
1594 /* Mark hard reg REGNO as currently live, assuming machine mode MODE
1595 for the value stored in it. MODE determines how many consecutive
1596 registers are actually in use. Do not record conflicts;
1597 it is assumed that the caller will do that. */
1599 static void
1601 {
1604 {
1606 regno++;
1607 }
1608 }
1609 \f
1610 /* Try to set a preference for an allocno to a hard register.
1611 We are passed DEST and SRC which are the operands of a SET. It is known
1612 that SRC is a register. If SRC or the first operand of SRC is a register,
1613 try to set a preference. If one of the two is a hard register and the other
1614 is a pseudo-register, mark the preference.
1616 Note that we are not as aggressive as local-alloc in trying to tie a
1617 pseudo-register to a hard register. */
1619 static void
1621 {
1623 /* Amount to add to the hard regno for SRC, or subtract from that for DEST,
1624 to compensate for subregs in SRC or DEST. */
1632 /* Get the reg number for both SRC and DEST.
1633 If neither is a reg, give up. */
1638 {
1646 else
1649 }
1650 else
1656 {
1664 else
1667 }
1668 else
1671 /* Convert either or both to hard reg numbers. */
1679 /* Now if one is a hard reg and the other is a global pseudo
1680 then give the other a preference. */
1684 {
1687 {
1696 i++)
1698 }
1699 }
1703 {
1706 {
1715 i++)
1717 }
1718 }
1719 }
1720 \f
1721 /* Indicate that hard register number FROM was eliminated and replaced with
1722 an offset from hard register number TO. The status of hard registers live
1723 at the start of a basic block is updated by replacing a use of FROM with
1724 a use of TO. */
1726 void
1728 {
1729 basic_block bb;
1732 {
1735 {
1738 }
1739 }
1740 }
1741 \f
1742 /* Used for communication between the following functions. Holds the
1743 current life information. */
1746 /* Record in live_relevant_regs and REGS_SET that register REG became live.
1747 This is called via note_stores. */
1748 static void
1750 {
1761 {
1764 {
1768 regno++;
1769 }
1770 }
1772 {
1775 }
1776 }
1778 /* Record in live_relevant_regs that register REGNO died. */
1779 static void
1781 {
1783 {
1786 {
1790 regno++;
1791 }
1792 }
1793 else
1794 {
1798 }
1799 }
1801 /* Walk the insns of the current function and build reload_insn_chain,
1802 and record register life information. */
1803 void
1805 {
1809 regset_head live_relevant_regs_head;
1814 {
1818 {
1820 bitmap_iterator bi;
1825 {
1830 }
1831 }
1834 {
1844 {
1845 rtx link;
1847 /* Mark the death of everything that dies in this instruction. */
1853 c);
1857 /* Mark everything born in this instruction as live. */
1861 }
1862 else
1866 {
1867 rtx link;
1869 /* Mark anything that is set in this insn and then unused as dying. */
1875 c);
1876 }
1877 }
1882 /* Stop after we pass the end of the last basic block. Verify that
1883 no real insns are after the end of the last basic block.
1885 We may want to reorganize the loop somewhat since this test should
1886 always be the right exit test. Allow an ADDR_VEC or ADDR_DIF_VEC if
1887 the previous real insn is a JUMP_INSN. */
1889 {
1890 #ifdef ENABLE_CHECKING
1898 #endif
1900 }
1901 }
1904 }
1905 \f
1906 /* Print debugging trace information if -dg switch is given,
1907 showing the information on which the allocation decisions are based. */
1909 static void
1911 {
1917 {
1920 nregs++;
1921 }
1924 {
1935 }
1939 {
1962 }
1964 }
1966 void
1968 {
1974 {
1978 }
1985 }
1987 \f
1989 /* This page contains code to make live information more accurate.
1990 The accurate register liveness at program point P means:
1991 o there is a path from P to usage of the register and the
1992 register is not redefined or killed on the path.
1993 o register at P is partially available, i.e. there is a path from
1994 a register definition to the point P and the register is not
1995 killed (clobbered) on the path
1997 The standard GCC live information means only the first condition.
1998 Without the partial availability, there will be more register
1999 conflicts and as a consequence worse register allocation. The
2000 typical example where the information can be different is a
2001 register initialized in the loop at the basic block preceding the
2002 loop in CFG. */
2004 /* The following structure contains basic block data flow information
2005 used to calculate partial availability of registers. */
2007 struct bb_info
2008 {
2009 /* The basic block reverse post-order number. */
2011 /* Registers used uninitialized in an insn in which there is an
2012 early clobbered register might get the same hard register. */
2013 bitmap earlyclobber;
2014 /* Registers correspondingly killed (clobbered) and defined but not
2015 killed afterward in the basic block. */
2017 /* Registers partially available correspondingly at the start and
2018 end of the basic block. */
2020 };
2022 /* Macros for accessing data flow information of basic blocks. */
2024 #define BB_INFO(BB) ((struct bb_info *) (BB)->aux)
2025 #define BB_INFO_BY_INDEX(N) BB_INFO (BASIC_BLOCK(N))
2027 /* The function allocates the info structures of each basic block. It
2028 also initialized PAVIN and PAVOUT as if all hard registers were
2029 partially available. */
2031 static void
2033 {
2035 basic_block bb;
2037 bitmap init;
2044 {
2053 }
2055 }
2057 /* The function frees the allocated info of all basic blocks. */
2059 static void
2061 {
2062 basic_block bb;
2066 {
2073 }
2075 }
2077 /* The function modifies local info for register REG being changed in
2078 SETTER. DATA is used to pass the current basic block info. */
2080 static void
2082 {
2098 else
2100 }
2102 /* Classes of registers which could be early clobbered in the current
2103 insn. */
2107 /* The function stores classes of registers which could be early
2108 clobbered in INSN. */
2110 static void
2112 {
2119 {
2129 {
2132 {
2144 /* These don't say anything we care about. */
2153 {
2160 }
2173 }
2177 }
2178 }
2179 }
2181 /* The function returns true if register classes C1 and C2 intersect. */
2183 static bool
2185 {
2193 yes:
2195 }
2197 /* The function checks that pseudo-register *X has a class
2198 intersecting with the class of pseudo-register could be early
2199 clobbered in the same insn. */
2201 static int
2203 {
2210 {
2219 pref_class)
2222 alt_class)))
2223 {
2226 }
2227 }
2229 }
2231 /* The function processes all pseudo-registers in *X with the aid of
2232 previous function. */
2234 static void
2236 {
2238 }
2240 /* The function calculates local info for each basic block. */
2242 static void
2244 {
2245 basic_block bb;
2251 {
2255 {
2259 }
2260 }
2261 }
2263 /* The function sets up reverse post-order number of each basic
2264 block. */
2266 static void
2268 {
2277 }
2279 /* Compare function for sorting blocks in reverse postorder. */
2281 static int
2283 {
2287 }
2289 /* The function calculates partial availability of registers. The
2290 function calculates partial availability at the end of basic block
2291 BB by propagating partial availability at end of predecessor basic
2292 block PRED. The function returns true if the partial availability
2293 at the end of BB has been changed or if CHANGED_P. We have the
2294 following equations:
2296 bb.pavin = empty for entry block | union (pavout of predecessors)
2297 bb.pavout = union (bb.pavin - b.killed, bb.avloc) */
2299 static bool
2301 {
2313 }
2315 /* The function calculates partial register availability. */
2317 static void
2319 {
2321 edge e;
2326 sbitmap wset;
2331 {
2333 }
2336 {
2342 {
2343 edge_iterator ei;
2351 {
2354 {
2357 }
2358 }
2359 }
2364 }
2366 }
2368 /* The function modifies partial availability information for two
2369 special cases to prevent incorrect work of the subsequent passes
2370 with the accurate live information based on the partial
2371 availability. */
2373 static void
2375 {
2376 basic_block bb;
2378 #ifdef STACK_REGS
2381 bitmap stack_regs;
2389 {
2395 skip:
2396 ;
2397 }
2398 #endif
2400 {
2403 /* Reload can assign the same hard register to uninitialized
2404 pseudo-register and early clobbered pseudo-register in an
2405 insn if the pseudo-register is used first time in given BB
2406 and not lived at the BB start. To prevent this we don't
2407 change life information for such pseudo-registers. */
2409 #ifdef STACK_REGS
2410 /* We can not use the same stack register for uninitialized
2411 pseudo-register and another living pseudo-register because if the
2412 uninitialized pseudo-register dies, subsequent pass reg-stack
2413 will be confused (it will believe that the other register
2414 dies). */
2416 #endif
2417 }
2418 #ifdef STACK_REGS
2420 #endif
2421 }
2423 /* The following function makes live information more accurate by
2424 modifying global_live_at_start and global_live_at_end of basic
2425 blocks. After the function call a register lives at a program
2426 point only if it is initialized on a path from CFG entry to the
2427 program point. The standard GCC life analysis permits registers to
2428 live uninitialized. */
2430 static void
2432 {
2433 basic_block bb;
2444 {
2449 }
2451 }