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1 /* Discovery of auto-inc and auto-dec instructions.
2 Copyright (C) 2006-2018 Free Software Foundation, Inc.
3 Contributed by Kenneth Zadeck <zadeck@naturalbridge.com>
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 3, 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 COPYING3. If not see
19 <http://www.gnu.org/licenses/>. */
40 /* This pass was originally removed from flow.c. However there is
41 almost nothing that remains of that code.
43 There are (4) basic forms that are matched:
45 (1) FORM_PRE_ADD
46 a <- b + c
47 ...
48 *a
50 becomes
52 a <- b
53 ...
54 *(a += c) pre
57 (2) FORM_PRE_INC
58 a += c
59 ...
60 *a
62 becomes
64 *(a += c) pre
67 (3) FORM_POST_ADD
68 *a
69 ...
70 b <- a + c
72 (For this case to be true, b must not be assigned or used between
73 the *a and the assignment to b. B must also be a Pmode reg.)
75 becomes
77 b <- a
78 ...
79 *(b += c) post
82 (4) FORM_POST_INC
83 *a
84 ...
85 a <- a + c
87 becomes
89 *(a += c) post
91 There are three types of values of c.
93 1) c is a constant equal to the width of the value being accessed by
94 the pointer. This is useful for machines that have
95 HAVE_PRE_INCREMENT, HAVE_POST_INCREMENT, HAVE_PRE_DECREMENT or
96 HAVE_POST_DECREMENT defined.
98 2) c is a constant not equal to the width of the value being accessed
99 by the pointer. This is useful for machines that have
100 HAVE_PRE_MODIFY_DISP, HAVE_POST_MODIFY_DISP defined.
102 3) c is a register. This is useful for machines that have
103 HAVE_PRE_MODIFY_REG, HAVE_POST_MODIFY_REG
105 The is one special case: if a already had an offset equal to it +-
106 its width and that offset is equal to -c when the increment was
107 before the ref or +c if the increment was after the ref, then if we
108 can do the combination but switch the pre/post bit. */
111 enum form
112 {
113 FORM_PRE_ADD,
114 FORM_PRE_INC,
115 FORM_POST_ADD,
116 FORM_POST_INC,
117 FORM_last
118 };
120 /* The states of the second operands of mem refs and inc insns. If no
121 second operand of the mem_ref was found, it is assumed to just be
122 ZERO. SIZE is the size of the mode accessed in the memref. The
123 ANY is used for constants that are not +-size or 0. REG is used if
124 the forms are reg1 + reg2. */
126 enum inc_state
127 {
134 INC_last
135 };
137 /* The eight forms that pre/post inc/dec can take. */
138 enum gen_form
139 {
140 NOTHING,
148 REG_POST /* reg++ */
149 };
151 /* Tmp mem rtx for use in cost modeling. */
154 static enum inc_state
156 {
161 else
163 }
165 /* The DECISION_TABLE that describes what form, if any, the increment
166 or decrement will take. It is a three dimensional table. The first
167 index is the type of constant or register found as the second
168 operand of the inc insn. The second index is the type of constant
169 or register found as the second operand of the memory reference (if
170 no second operand exists, 0 is used). The third index is the form
171 and location (relative to the mem reference) of inc insn. */
176 static void
178 {
182 {
183 /* Prefer the simple form if both are available. */
191 }
194 {
195 /* Prefer the simple form if both are available. */
203 }
206 {
207 /* Prefer the simple form if both are available. */
215 }
218 {
219 /* Prefer the simple form if both are available. */
227 }
230 {
242 }
245 {
257 }
259 /* This is much simpler than the other cases because we do not look
260 for the reg1-reg2 case. Note that we do not have a INC_POS_REG
261 and INC_NEG_REG states. Most of the use of such states would be
262 on a target that had an R1 - R2 update address form.
264 There is the remote possibility that you could also catch a = a +
265 b; *(a - b) as a postdecrement of (a + b). However, it is
266 unclear if *(a - b) would ever be generated on a machine that did
267 not have that kind of addressing mode. The IA-64 and RS6000 will
268 not do this, and I cannot speak for any other. If any
269 architecture does have an a-b update for, these cases should be
270 added. */
272 {
278 }
281 {
284 }
287 }
289 /* Parsed fields of an inc insn of the form "reg_res = reg0+reg1" or
290 "reg_res = reg0+c". */
292 static struct inc_insn
293 {
298 rtx reg_res;
299 rtx reg0;
300 rtx reg1;
306 /* Dump the parsed inc insn to FILE. */
308 static void
310 {
317 {
325 else
338 else
346 }
347 }
350 /* Parsed fields of a mem ref of the form "*(reg0+reg1)" or "*(reg0+c)". */
352 static struct mem_insn
353 {
357 /* that is to be replaced. */
359 rtx reg0;
361 reg1_is_const. */
367 /* Dump the parsed mem insn to FILE. */
369 static void
371 {
378 else
382 }
385 /* The following three arrays contain pointers to instructions. They
386 are indexed by REGNO. At any point in the basic block where we are
387 looking these three arrays contain, respectively, the next insn
388 that uses REGNO, the next inc or add insn that uses REGNO and the
389 next insn that sets REGNO.
391 The arrays are not cleared when we move from block to block so
392 whenever an insn is retrieved from these arrays, it's block number
393 must be compared with the current block.
394 */
401 /* Move dead note that match PATTERN to TO_INSN from FROM_INSN. We do
402 not really care about moving any other notes from the inc or add
403 insn. Moving the REG_EQUAL and REG_EQUIV is clearly wrong and it
404 does not appear that there are any other kinds of relevant notes. */
406 static void
408 {
409 rtx note;
410 rtx next_note;
414 {
419 {
424 else
426 }
428 }
429 }
431 /* Change mem_insn.mem_loc so that uses NEW_ADDR which has an
432 increment of INC_REG. To have reached this point, the change is a
433 legitimate one from a dataflow point of view. The only questions
434 are is this a valid change to the instruction and is this a
435 profitable change to the instruction. */
437 static bool
439 {
440 /* There are four cases: For the two cases that involve an add
441 instruction, we are going to have to delete the add and insert a
442 mov. We are going to assume that the mov is free. This is
443 fairly early in the backend and there are a lot of opportunities
444 for removing that move later. In particular, there is the case
445 where the move may be dead, this is what dead code elimination
446 passes are for. The two cases where we have an inc insn will be
447 handled mov free. */
454 rtx new_mem;
467 /* In the FORM_PRE_ADD and FORM_POST_ADD cases we emit an extra move
468 whose cost we should account for. */
471 {
477 }
479 /* The first item of business is to see if this is profitable. */
481 {
485 }
487 /* Jump through a lot of hoops to keep the attributes up to date. We
488 do not want to call one of the change address variants that take
489 an offset even though we know the offset in many cases. These
490 assume you are changing where the address is pointing by the
491 offset. */
494 {
498 }
500 /* From here to the end of the function we are committed to the
501 change, i.e. nothing fails. Generate any necessary movs, move
502 any regnotes, and fix up the reg_next_{use,inc_use,def}. */
504 {
506 /* Replace the addition with a move. Do it at the location of
507 the addition since the operand of the addition may change
508 before the memory reference. */
514 else
530 /* Fallthru. */
543 /* Do not move anything to the mov insn because the instruction
544 pointer for the main iteration has not yet hit that. It is
545 still pointing to the mem insn. */
561 }
564 {
570 }
575 {
578 }
580 /* Record that this insn has an implicit side effect. */
584 {
587 }
590 }
593 /* Try to combine the instruction in INC_INSN with the instruction in
594 MEM_INSN. First the form is determined using the DECISION_TABLE
595 and the results of parsing the INC_INSN and the MEM_INSN.
596 Assuming the form is ok, a prototype new address is built which is
597 passed to ATTEMPT_CHANGE for final processing. */
599 static bool
601 {
607 /* The width of the mem being accessed. */
613 {
625 }
627 /* Cannot handle auto inc of the stack. */
629 {
633 }
635 /* Look to see if the inc register is dead after the memory
636 reference. If it is, do not do the combination. */
638 {
642 }
649 /* Now get the form that we are generating. */
650 gen_form = decision_table
657 {
686 inc_reg,
688 inc_reg,
690 inc_reg);
696 inc_reg,
698 inc_reg,
700 inc_reg);
706 inc_reg,
708 inc_reg,
710 inc_reg);
716 inc_reg,
718 inc_reg,
720 inc_reg);
721 }
722 }
724 /* Return the next insn that uses (if reg_next_use is passed in
725 NEXT_ARRAY) or defines (if reg_next_def is passed in NEXT_ARRAY)
726 REGNO in BB. */
730 {
733 /* Lazy about cleaning out the next_arrays. */
735 {
738 }
741 }
744 /* Return true if INSN is of a form "a = b op c" where a and b are
745 regs. op is + if c is a reg and +|- if c is a const. Fill in
746 INC_INSN with what is found.
748 This function is called in two contexts, if BEFORE_MEM is true,
749 this is called for each insn in the basic block. If BEFORE_MEM is
750 false, it is called for the instruction in the block that uses the
751 index register for some memory reference that is currently being
752 processed. */
754 static bool
756 {
761 /* Result must be single reg. */
777 /* Block any auto increment of the frame pointer since it expands into
778 an addition and cannot be removed by copy propagation. */
784 else
788 {
789 /* Process a = b + c where c is a const. */
792 {
795 }
796 else
797 {
800 }
802 }
806 {
807 /* Process a = b + c where c is a reg. */
815 {
816 /* Reverse the two operands and turn *_ADD into *_INC since
817 a = c + a. */
821 }
822 else
824 }
827 }
830 /* A recursive function that checks all of the mem uses in
831 ADDRESS_OF_X to see if any single one of them is compatible with
832 what has been found in inc_insn. To avoid accidental matches, we
833 will only find MEMs with FINDREG, be it inc_insn.reg_res, be it
834 inc_insn.reg0.
836 -1 is returned for success. 0 is returned if nothing was found and
837 1 is returned for failure. */
839 static int
841 {
851 {
852 /* Match with *reg_res. */
859 }
863 {
864 /* Match with *reg0, assumed to be equivalent to
865 *(reg_res - reg1_val); callers must check whether this is the case. */
872 }
876 {
883 {
884 /* Match with *(reg0 + reg1) where reg1 is a const. */
888 {
891 }
892 }
895 /* Match with *(reg0 + reg1). */
897 }
900 {
901 /* If REG occurs inside a MEM used in a bit-field reference,
902 that is unacceptable. */
905 }
910 /* Time for some deep diving. */
912 {
914 {
916 /* If this is the first use, let it go so the rest of the
917 insn can be checked. */
921 /* More than one match was found. */
923 }
925 {
928 {
930 /* If this is the first use, let it go so the rest of
931 the insn can be checked. */
935 /* More than one match was found. */
937 }
938 }
939 }
941 }
943 /* Once a suitable mem reference has been found and the MEM_INSN
944 structure has been filled in, FIND_INC is called to see if there is
945 a suitable add or inc insn that follows the mem reference and
946 determine if it is suitable to merge.
948 In the case where the MEM_INSN has two registers in the reference,
949 this function may be called recursively. The first time looking
950 for an add of the first register, and if that fails, looking for an
951 add of the second register. The FIRST_TRY parameter is used to
952 only allow the parameters to be reversed once. */
954 static bool
956 {
960 df_ref def;
962 /* Make sure this reg appears only once in this insn. */
964 {
968 }
973 /* Find the next use that is an inc. */
976 reg_next_inc_use);
980 /* Even though we know the next use is an add or inc because it came
981 from the reg_next_inc_use, we must still reparse. */
983 {
984 /* Next use was not an add. Look for one extra case. It could be
985 that we have:
987 *(a + b)
988 ...= a;
989 ...= b + a
991 if we reverse the operands in the mem ref we would
992 find this. Only try it once though. */
994 {
997 }
998 else
1000 }
1002 /* Need to assure that none of the operands of the inc instruction are
1003 assigned to by the mem insn. */
1005 {
1009 {
1013 }
1015 {
1019 }
1020 }
1026 {
1027 /* Make sure that there is no insn that assigns to inc_insn.res
1028 between the mem_insn and the inc_insn. */
1031 reg_next_def);
1033 {
1038 }
1042 reg_next_use);
1046 {
1051 }
1053 /* For the post_add to work, the result_reg of the inc must not be
1054 used in the mem insn since this will become the new index
1055 register. */
1057 {
1061 }
1062 }
1065 {
1067 {
1069 {
1070 /* The mem looks like *r0 and the rhs of the add has two
1071 registers. */
1074 {
1075 /* The trick is that we are not going to increment r0,
1076 we are going to increment the result of the add insn.
1077 For this trick to be correct, the result reg of
1078 the inc must be a valid addressing reg. */
1082 {
1086 }
1088 /* We also need to make sure that the next use of
1089 inc result is after the inc. */
1090 other_insn
1097 }
1099 other_insn
1103 }
1104 }
1105 /* Both the inc/add and the mem have a constant. Need to check
1106 that the constants are ok. */
1110 }
1111 else
1112 {
1113 /* The mem insn is of the form *(a + b) where a and b are both
1114 regs. It may be that in order to match the add or inc we
1115 need to treat it as if it was *(b + a). It may also be that
1116 the add is of the form a + c where c does not match b and
1117 then we just abandon this. */
1122 /* Make sure this reg appears only once in this insn. */
1127 {
1128 /* For this trick to be correct, the result reg of the inc
1129 must be a valid addressing reg. */
1133 {
1137 }
1140 {
1142 {
1143 /* See comment above on find_inc (false) call. */
1145 {
1148 }
1149 else
1151 }
1153 /* Need to check that there are no assignments to b
1154 before the add insn. */
1155 other_insn
1159 /* All ok for the next step. */
1160 }
1161 else
1162 {
1163 /* We know that mem_insn.reg0 must equal inc_insn.reg1
1164 or else we would not have found the inc insn. */
1167 {
1168 /* See comment above on find_inc (false) call. */
1171 else
1173 }
1174 /* To have gotten here know that.
1175 *(b + a)
1177 ... = (b + a)
1179 We also know that the lhs of the inc is not b or a. We
1180 need to make sure that there are no assignments to b
1181 between the mem ref and the inc. */
1183 other_insn
1187 }
1189 /* Need to check that the next use of the add result is later than
1190 add insn since this will be the reg incremented. */
1191 other_insn
1195 }
1197 know that operands must line up. */
1198 {
1200 /* See comment above on find_inc (false) call. */
1201 {
1203 {
1206 }
1207 else
1209 }
1211 /* To have gotten here know that.
1212 *(a + b)
1214 ... = (a + b)
1216 We also know that the lhs of the inc is not b. We need to make
1217 sure that there are no assignments to b between the mem ref and
1218 the inc. */
1219 other_insn
1223 }
1224 }
1227 {
1228 other_insn
1230 /* When we found inc_insn, we were looking for the
1231 next add or inc, not the next insn that used the
1232 reg. Because we are going to increment the reg
1233 in this form, we need to make sure that there
1234 were no intervening uses of reg. */
1237 }
1240 }
1243 /* A recursive function that walks ADDRESS_OF_X to find all of the mem
1244 uses in pat that could be used as an auto inc or dec. It then
1245 calls FIND_INC for each one. */
1247 static bool
1249 {
1256 {
1257 /* Match with *reg0. */
1265 }
1268 {
1274 {
1276 /* Match with *(reg0 + c) where c is a const. */
1280 }
1282 {
1283 /* Match with *(reg0 + reg1). */
1287 }
1288 }
1291 {
1292 /* If REG occurs inside a MEM used in a bit-field reference,
1293 that is unacceptable. */
1295 }
1297 /* Time for some deep diving. */
1299 {
1301 {
1304 }
1306 {
1311 }
1312 }
1314 }
1317 /* Try to combine all incs and decs by constant values with memory
1318 references in BB. */
1320 static void
1322 {
1331 {
1337 /* This continue is deliberate. We do not want the uses of the
1338 jump put into reg_next_use because it is not considered safe to
1339 combine a preincrement with a jump. */
1346 /* Does this instruction increment or decrement a register? */
1348 {
1350 /* Cannot handle case where there are three separate regs
1351 before a mem ref. Too many moves would be needed to be
1352 profitable. */
1354 {
1357 {
1360 {
1361 /* We are only here if we are going to try a
1362 HAVE_*_MODIFY_REG type transformation. c is a
1363 reg and we must sure that the path from the
1364 inc_insn to the mem_insn.insn is both def and use
1365 clear of c because the inc insn is going to move
1366 into the mem_insn.insn. */
1368 rtx_insn *other_insn
1374 other_insn
1379 }
1386 {
1390 {
1391 success_in_block++;
1393 }
1394 }
1395 }
1398 /* find_address will only recognize an address
1399 with a reg0 that's not reg_res when
1400 reg1_is_const, so cut it off early if we
1401 already know it won't match. */
1405 {
1406 /* If we identified an inc_insn that uses two
1407 different pseudos, it's of the form
1409 (set reg_res (plus reg0 reg1))
1411 where reg1 is a constant (*).
1413 The next use of reg_res was not idenfied by
1414 find_address as a mem_insn that we could turn
1415 into auto-inc, so see if we find a suitable
1416 MEM in the next use of reg0, as long as it's
1417 before any subsequent use of reg_res:
1419 ... (mem (... reg0 ...)) ...
1421 ... reg_res ...
1423 In this case, we can turn the plus into a
1424 copy, and the reg0 in the MEM address into a
1425 post_inc of reg_res:
1427 (set reg_res reg0)
1429 ... (mem (... (post_add reg_res reg1) ...)) ...
1431 reg_res will then have the correct value at
1432 subsequent uses, and reg0 will remain
1433 unchanged.
1435 (*) We could support non-const reg1, but then
1436 we'd have to check that reg1 remains
1437 unchanged all the way to the modified MEM,
1438 and we'd have to extend find_address to
1439 represent a non-const negated reg1. */
1442 reg_next_use);
1444 /* Give up if the next use of reg0 is after the next
1445 use of reg_res (same insn is ok; we might have
1446 found a MEM with reg_res before, and that failed,
1447 but now we try reg0, which might work), or defs
1448 of reg_res (same insn is not ok, we'd introduce
1449 another def in the same insn) or reg0. */
1451 {
1454 /* It might seem pointless to introduce an
1455 auto-inc if there's no subsequent use of
1456 reg_res (i.e., mem_insn.insn == NULL), but
1457 the next use might be in the next iteration
1458 of a loop, and it won't hurt if we make the
1459 change even if it's not needed. */
1464 rtx_insn *other_insn
1466 reg_next_def);
1471 other_insn
1473 reg_next_def);
1477 }
1484 {
1488 {
1489 success_in_block++;
1491 }
1492 }
1493 }
1494 }
1495 }
1496 else
1497 {
1501 success_in_block++;
1502 }
1504 /* If the inc insn was merged with a mem, the inc insn is gone
1505 and there is noting to update. */
1507 {
1510 /* Need to update next use. */
1512 {
1516 }
1519 {
1523 else
1525 }
1526 }
1530 }
1532 /* If we were successful, try again. There may have been several
1533 opportunities that were interleaved. This is rare but
1534 gcc.c-torture/compile/pr17273.c actually exhibits this. */
1536 {
1537 /* In this case, we must clear these vectors since the trick of
1538 testing if the stale insn in the block will not work. */
1544 }
1545 }
1547 /* Discover auto-inc auto-dec instructions. */
1552 {
1562 };
1565 {
1569 {}
1571 /* opt_pass methods: */
1573 {
1578 }
1585 unsigned int
1587 {
1591 basic_block bb;
1615 }
1619 rtl_opt_pass *
1621 {
1623 }