| blob | de39e9052e702e5a2beaef43ce4d520f85ae31e9 |
1 /* Register renaming for the GNU compiler.
2 Copyright (C) 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008, 2009,
3 2010 Free Software Foundation, Inc.
5 This file is part of GCC.
7 GCC is free software; you can redistribute it and/or modify it
8 under the terms of the GNU General Public License as published by
9 the Free Software Foundation; either version 3, or (at your option)
10 any later version.
12 GCC is distributed in the hope that it will be useful, but WITHOUT
13 ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
14 or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public
15 License for more details.
17 You should have received a copy of the GNU General Public License
18 along with GCC; see the file COPYING3. If not see
19 <http://www.gnu.org/licenses/>. */
45 /* This file implements the RTL register renaming pass of the compiler. It is
46 a semi-local pass whose goal is to maximize the usage of the register file
47 of the processor by substituting registers for others in the solution given
48 by the register allocator. The algorithm is as follows:
50 1. Local def/use chains are built: within each basic block, chains are
51 opened and closed; if a chain isn't closed at the end of the block,
52 it is dropped. We pre-open chains if we have already examined a
53 predecessor block and found chains live at the end which match
54 live registers at the start of the new block.
56 2. We try to combine the local chains across basic block boundaries by
57 comparing chains that were open at the start or end of a block to
58 those in successor/predecessor blocks.
60 3. For each chain, the set of possible renaming registers is computed.
61 This takes into account the renaming of previously processed chains.
62 Optionally, a preferred class is computed for the renaming register.
64 4. The best renaming register is computed for the chain in the above set,
65 using a round-robin allocation. If a preferred class exists, then the
66 round-robin allocation is done within the class first, if possible.
67 The round-robin allocation of renaming registers itself is global.
69 5. If a renaming register has been found, it is substituted in the chain.
71 Targets can parameterize the pass by specifying a preferred class for the
72 renaming register for a given (super)class of registers to be renamed. */
74 #if HOST_BITS_PER_WIDE_INT <= MAX_RECOG_OPERANDS
76 #endif
78 enum scan_actions
79 {
80 terminate_write,
81 terminate_dead,
82 mark_all_read,
83 mark_read,
84 mark_write,
85 /* mark_access is for marking the destination regs in
86 REG_FRAME_RELATED_EXPR notes (as if they were read) so that the
87 note is updated properly. */
88 mark_access
89 };
92 {
98 "mark_access"
99 };
101 /* TICK and THIS_TICK are used to record the last time we saw each
102 register. */
108 /* If nonnull, the code calling into the register renamer requested
109 information about insn operands, and we store it here. */
116 /* The id to be given to the next opened chain. */
119 /* A mapping of unique id numbers to chains. */
122 /* List of currently open chains. */
125 /* Bitmap of open chains. The bits set always match the list found in
126 open_chains. */
129 /* Record the registers being tracked in open_chains. */
132 /* Record the registers that are live but not tracked. The intersection
133 between this and live_in_chains is empty. */
136 /* Set while scanning RTL if INSN_RR is nonnull, i.e. if the current analysis
137 is for a caller that requires operand data. Used in
138 record_operand_use. */
141 /* Return the chain corresponding to id number ID. Take into account that
142 chains may have been merged. */
143 du_head_p
145 {
149 {
152 }
155 }
157 /* Dump all def/use chains, starting at id FROM. */
159 static void
161 {
162 du_head_p head;
165 {
171 {
175 }
178 }
179 }
181 static void
183 {
185 du_head_p ptr;
190 }
192 /* Walk all chains starting with CHAINS and record that they conflict with
193 another chain whose id is ID. */
195 static void
197 {
199 {
202 }
203 }
205 /* Examine cur_operand, and if it is nonnull, record information about the
206 use THIS_DU which is part of the chain HEAD. */
208 static void
210 {
216 }
218 /* Create a new chain for THIS_NREGS registers starting at THIS_REGNO,
219 and record its occurrence in *LOC, which is being written to in INSN.
220 This access requires a register of class CL. */
222 static du_head_p
225 {
243 /* Since we're tracking this as a chain now, remove it from the
244 list of conflicting live hard registers and track it in
245 live_in_chains instead. */
248 {
251 }
259 {
265 }
268 {
271 }
282 }
284 /* For a def-use chain HEAD, find which registers overlap its lifetime and
285 set the corresponding bits in *PSET. */
287 static void
289 {
290 bitmap_iterator bi;
294 {
300 }
301 }
303 /* Check if NEW_REG can be the candidate register to rename for
304 REG in THIS_HEAD chain. THIS_UNAVAILABLE is a set of unavailable hard
305 registers. */
307 static bool
310 {
320 /* Can't use regs which aren't saved by the prologue. */
323 #ifdef LEAF_REGISTERS
324 /* We can't use a non-leaf register if we're in a
325 leaf function. */
326 || (current_function_is_leaf
328 #endif
329 #ifdef HARD_REGNO_RENAME_OK
331 #endif
332 )
335 /* See whether it accepts all modes that occur in
336 definition and uses. */
341 && ! (HARD_REGNO_CALL_PART_CLOBBERED
343 && (HARD_REGNO_CALL_PART_CLOBBERED
348 }
350 /* For the chain THIS_HEAD, compute and return the best register to
351 rename to. SUPER_CLASS is the superunion of register classes in
352 the chain. UNAVAILABLE is a set of registers that cannot be used.
353 OLD_REG is the register currently used for the chain. */
355 int
358 {
364 /* Further narrow the set of registers we can use for renaming.
365 If the chain needs a call-saved register, mark the call-used
366 registers as unavailable. */
370 /* Mark registers that overlap this chain's lifetime as unavailable. */
373 /* Compute preferred rename class of super union of all the classes
374 in the chain. */
375 preferred_class
378 /* If PREFERRED_CLASS is not NO_REGS, we iterate in the first pass
379 over registers that belong to PREFERRED_CLASS and try to find the
380 best register within the class. If that failed, we iterate in
381 the second pass over registers that don't belong to the class.
382 If PREFERRED_CLASS is NO_REGS, we iterate over all registers in
383 ascending order without any preference. */
386 {
389 {
393 new_reg))
396 /* In the first pass, we force the renaming of registers that
397 don't belong to PREFERRED_CLASS to registers that do, even
398 though the latters were used not very long ago. */
403 best_new_reg))
406 }
409 }
411 }
413 /* Perform register renaming on the current function. */
414 static void
416 {
417 HARD_REG_SET unavailable;
418 du_head_p this_head;
424 /* Don't clobber traceback for noreturn functions. */
426 {
428 #if !HARD_FRAME_POINTER_IS_FRAME_POINTER
430 #endif
431 }
434 {
438 HARD_REG_SET this_unavailable;
446 #if !HARD_FRAME_POINTER_IS_FRAME_POINTER
448 #else
450 #endif
451 )
456 /* Iterate over elements in the chain in order to:
457 1. Count number of uses, and narrow the set of registers we can
458 use for renaming.
459 2. Compute the superunion of register classes in this chain. */
463 {
466 n_uses++;
469 super_class
471 }
480 {
485 }
488 {
493 }
501 }
502 }
504 /* A structure to record information for each hard register at the start of
505 a basic block. */
507 /* Holds the number of registers used in the chain that gave us information
508 about this register. Zero means no information known yet, while a
509 negative value is used for something that is part of, but not the first
510 register in a multi-register value. */
512 /* Set to true if we have accesses that conflict in the number of registers
513 used. */
515 };
517 /* A structure recording information about each basic block. It is saved
518 and restored around basic block boundaries.
519 A pointer to such a structure is stored in each basic block's aux field
520 during regrename_analyze, except for blocks we know can't be optimized
521 (such as entry and exit blocks). */
522 struct bb_rename_info
523 {
524 /* The basic block corresponding to this structure. */
525 basic_block bb;
526 /* Copies of the global information. */
527 bitmap_head open_chains_set;
528 bitmap_head incoming_open_chains_set;
530 };
532 /* Initialize a rename_info structure P for basic block BB, which starts a new
533 scan. */
534 static void
536 {
539 HARD_REG_SET start_chains_set;
551 {
555 }
557 /* Open chains based on information from (at least one) predecessor
558 block. This gives us a chance later on to combine chains across
559 basic block boundaries. Inconsistencies (in access sizes) will
560 be caught normally and dealt with conservatively by disabling the
561 chain for renaming, and there is no risk of losing optimization
562 opportunities by opening chains either: if we did not open the
563 chains, we'd have to track the live register as a hard reg, and
564 we'd be unable to rename it in any case. */
567 {
571 {
574 }
575 }
577 {
580 {
581 du_head_p chain;
586 }
587 }
588 }
590 /* Record in RI that the block corresponding to it has an incoming
591 live value, described by CHAIN. */
592 static void
594 {
599 /* If we've recorded the same information before, everything is fine. */
601 {
606 }
608 /* If we have no information for any of the involved registers, update
609 the incoming array. */
616 {
625 }
627 /* There must be some kind of conflict. Prevent both the old and
628 new ranges from being used. */
633 }
635 /* Merge the two chains C1 and C2 so that all conflict information is
636 recorded and C1, and the id of C2 is changed to that of C1. */
637 static void
639 {
644 {
647 else
650 }
660 }
662 /* Analyze the current function and build chains for renaming. */
664 void
666 {
669 basic_block bb;
676 /* Gather some information about the blocks in this function. */
680 {
685 else
687 i++;
688 }
694 /* The order in which we visit blocks ensures that whenever
695 possible, we only process a block after at least one of its
696 predecessors, which provides a "seeding" effect to make the logic
697 in set_incoming_from_chain and init_rename_info useful. */
700 {
704 edge e;
705 edge_iterator ei;
719 {
728 {
729 rtx insn;
731 {
735 }
736 }
738 }
744 /* Add successor blocks to the worklist if necessary, and record
745 data about our own open chains at the end of this block, which
746 will be used to pre-open chains when processing the successors. */
748 {
762 }
763 }
767 /* Now, combine the chains data we have gathered across basic block
768 boundaries.
770 For every basic block, there may be chains open at the start, or at the
771 end. Rather than exclude them from renaming, we look for open chains
772 with matching registers at the other side of the CFG edge.
774 For a given chain using register R, open at the start of block B, we
775 must find an open chain using R on the other side of every edge leading
776 to B, if the register is live across this edge. In the code below,
777 N_PREDS_USED counts the number of edges where the register is live, and
778 N_PREDS_JOINED counts those where we found an appropriate chain for
779 joining.
781 We perform the analysis for both incoming and outgoing edges, but we
782 only need to merge once (in the second part, after verifying outgoing
783 edges). */
785 {
788 bitmap_iterator bi;
797 {
798 edge e;
799 edge_iterator ei;
804 {
807 bitmap_iterator bi2;
808 HARD_REG_SET live;
815 n_preds_used++;
826 {
831 {
832 n_preds_joined++;
835 }
836 }
840 }
842 {
846 }
847 }
848 }
850 {
853 bitmap_iterator bi;
862 {
863 edge e;
864 edge_iterator ei;
869 {
873 bitmap_iterator bi2;
874 HARD_REG_SET live;
881 n_succs_used++;
889 {
894 {
896 {
906 }
909 n_succs_joined++;
911 }
912 }
913 }
915 {
918 j);
920 }
921 }
922 }
928 }
930 void
932 {
938 {
945 else
946 {
952 }
955 }
960 }
963 /* True if we found a register with a size mismatch, which means that we
964 can't track its lifetime accurately. If so, we abort the current block
965 without renaming. */
968 /* Return true if OP is a reg for which all bits are set in PSET, false
969 if all bits are clear.
970 In other cases, set fail_current_block and return false. */
972 static bool
974 {
986 else
989 {
992 }
994 }
996 /* Return true if OP is a reg that is being tracked already in some form.
997 May set fail_current_block if it sees an unhandled case of overlap. */
999 static bool
1001 {
1004 }
1006 /* Called through note_stores. DATA points to a rtx_code, either SET or
1007 CLOBBER, which tells us which kind of rtx to look at. If we have a
1008 match, record the set register in live_hard_regs and in the hard_conflicts
1009 bitmap of open chains. */
1011 static void
1013 {
1021 /* There must not be pseudos at this point. */
1026 }
1028 static void
1031 {
1039 {
1043 }
1049 {
1062 {
1065 }
1068 {
1069 /* ??? Class NO_REGS can happen if the md file makes use of
1070 EXTRA_CONSTRAINTS to match registers. Which is arguably
1071 wrong, but there we are. */
1074 {
1082 {
1092 }
1094 {
1099 }
1100 }
1101 else
1102 {
1111 else
1115 }
1116 /* Avoid adding the same location in a DEBUG_INSN multiple times,
1117 which could happen with non-exact overlap. */
1120 /* Otherwise, find any other chains that do not match exactly;
1121 ensure they all get marked unrenamable. */
1124 }
1126 /* Whether the terminated chain can be used for renaming
1127 depends on the action and this being an exact match.
1128 In either case, we remove this element from open_chains. */
1132 {
1141 {
1147 }
1156 }
1158 {
1159 /* In this case, tracking liveness gets too hard. Fail the
1160 entire basic block. */
1166 }
1167 else
1168 {
1176 }
1177 }
1178 }
1180 /* Adapted from find_reloads_address_1. CL is INDEX_REG_CLASS or
1181 BASE_REG_CLASS depending on how the register is being considered. */
1183 static void
1186 addr_space_t as)
1187 {
1197 {
1199 {
1211 {
1214 }
1217 {
1220 }
1224 {
1228 }
1231 {
1235 }
1238 {
1241 }
1244 {
1247 }
1249 {
1264 else
1270 }
1272 {
1276 }
1278 {
1282 }
1292 }
1300 #ifndef AUTO_INC_DEC
1301 /* If the target doesn't claim to handle autoinc, this must be
1302 something special, like a stack push. Kill this chain. */
1304 #endif
1320 }
1324 {
1330 }
1331 }
1333 static void
1336 {
1344 {
1394 /* Should only happen inside MEM. */
1411 }
1415 {
1421 }
1422 }
1424 /* Hide operands of the current insn (of which there are N_OPS) by
1425 substituting cc0 for them.
1426 Previous values are stored in the OLD_OPERANDS and OLD_DUPS.
1427 For every bit set in DO_NOT_HIDE, we leave the operand alone.
1428 If INOUT_AND_EC_ONLY is set, we only do this for OP_INOUT type operands
1429 and earlyclobbers. */
1431 static void
1434 {
1438 {
1440 /* Don't squash match_operator or match_parallel here, since
1441 we don't know that all of the contained registers are
1442 reachable by proper operands. */
1450 }
1452 {
1460 }
1461 }
1463 /* Undo the substitution performed by hide_operands. INSN is the insn we
1464 are processing; the arguments are the same as in hide_operands. */
1466 static void
1468 {
1476 }
1478 /* For each output operand of INSN, call scan_rtx to create a new
1479 open chain. Do this only for normal or earlyclobber outputs,
1480 depending on EARLYCLOBBER. If INSN_INFO is nonnull, use it to
1481 record information about the operands in the insn. */
1483 static void
1485 {
1492 {
1512 /* ??? Many targets have output constraints on the SET_DEST
1513 of a call insn, which is stupid, since these are certainly
1514 ABI defined hard registers. For these, and for asm operands
1515 that originally referenced hard registers, we must record that
1516 the chain cannot be renamed. */
1521 {
1524 }
1525 }
1527 }
1529 /* Build def/use chain. */
1531 static bool
1533 {
1534 rtx insn;
1540 {
1542 {
1544 rtx note;
1554 /* Process the insn, determining its effect on the def-use
1555 chains and live hard registers. We perform the following
1556 steps with the register references in the insn, simulating
1557 its effect:
1558 (1) Deal with earlyclobber operands and CLOBBERs of non-operands
1559 by creating chains and marking hard regs live.
1560 (2) Any read outside an operand causes any chain it overlaps
1561 with to be marked unrenamable.
1562 (3) Any read inside an operand is added if there's already
1563 an open chain for it.
1564 (4) For any REG_DEAD note we find, close open chains that
1565 overlap it.
1566 (5) For any non-earlyclobber write we find, close open chains
1567 that overlap it.
1568 (6) For any non-earlyclobber write we find in an operand, make
1569 a new chain or mark the hard register as live.
1570 (7) For any REG_UNUSED, close any chains we just opened.
1572 We cannot deal with situations where we track a reg in one mode
1573 and see a reference in another mode; these will cause the chain
1574 to be marked unrenamable or even cause us to abort the entire
1575 basic block. */
1586 {
1592 }
1594 /* Simplify the code below by rewriting things to reflect
1595 matching constraints. Also promote OP_OUT to OP_INOUT in
1596 predicated instructions, but only for register operands
1597 that are already tracked, so that we can create a chain
1598 when the first SET makes a register live. */
1602 {
1609 {
1611 /* A special case to deal with instruction patterns that
1612 have matching operands with different modes. If we're
1613 not already tracking such a reg, we won't start here,
1614 and we must instead make sure to make the operand visible
1615 to the machinery that tracks hard registers. */
1620 {
1623 }
1624 }
1625 /* If there's an in-out operand with a register that is not
1626 being tracked at all yet, open a chain. */
1631 {
1636 NO_REGS);
1637 }
1638 }
1643 /* Step 1a: Mark hard registers that are clobbered in this insn,
1644 outside an operand, as live. */
1650 /* Step 1b: Begin new chains for earlyclobbered writes inside
1651 operands. */
1654 /* Step 2: Mark chains for which we have reads outside operands
1655 as unrenamable.
1656 We do this by munging all operands into CC0, and closing
1657 everything remaining. */
1664 /* Step 2B: Can't rename function call argument registers. */
1669 /* Step 2C: Can't rename asm operands that were originally
1670 hard registers. */
1673 {
1682 }
1684 /* Step 3: Append to chains for reads inside operands. */
1686 {
1694 /* Don't scan match_operand here, since we've no reg class
1695 information to pass down. Any operands that we could
1696 substitute in will be represented elsewhere. */
1706 else
1708 }
1711 /* Step 3B: Record updates for regs in REG_INC notes, and
1712 source regs in REG_FRAME_RELATED_EXPR notes. */
1717 OP_INOUT);
1719 /* Step 4: Close chains for registers that die here. */
1722 {
1727 OP_IN);
1728 }
1730 /* Step 4B: If this is a call, any chain live at this point
1731 requires a caller-saved reg. */
1733 {
1737 }
1739 /* Step 5: Close open chains that overlap writes. Similar to
1740 step 2, we hide in-out operands, since we do not want to
1741 close these chains. We also hide earlyclobber operands,
1742 since we've opened chains for them in step 1, and earlier
1743 chains they would overlap with must have been closed at
1744 the previous insn at the latest, as such operands cannot
1745 possibly overlap with any input operands. */
1752 /* Step 6a: Mark hard registers that are set in this insn,
1753 outside an operand, as live. */
1759 /* Step 6b: Begin new chains for writes inside operands. */
1762 /* Step 6c: Record destination regs in REG_FRAME_RELATED_EXPR
1763 notes for update. */
1767 OP_INOUT);
1769 /* Step 7: Close chains for registers that were never
1770 really used here. */
1773 {
1778 OP_IN);
1779 }
1780 }
1783 {
1786 }
1789 }
1795 }
1796 \f
1797 /* Initialize the register renamer. If INSN_INFO is true, ensure that
1798 insn_rr is nonnull. */
1799 void
1801 {
1806 }
1808 /* Free all global data used by the register renamer. */
1809 void
1811 {
1815 }
1817 /* Perform register renaming on the current function. */
1819 static unsigned int
1821 {
1836 }
1837 \f
1838 static bool
1840 {
1842 }
1845 {
1846 {
1847 RTL_PASS,
1861 }
1862 };