| blob | d06b693ec768b0de86370b034819dd00671b363a |
1 /* Reassociation for trees.
2 Copyright (C) 2005-2020 Free Software Foundation, Inc.
3 Contributed by Daniel Berlin <dan@dberlin.org>
5 This file is part of GCC.
7 GCC is free software; you can redistribute it and/or modify
8 it 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,
13 but WITHOUT ANY WARRANTY; without even the implied warranty of
14 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 GNU General Public 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/>. */
55 /* This is a simple global reassociation pass. It is, in part, based
56 on the LLVM pass of the same name (They do some things more/less
57 than we do, in different orders, etc).
59 It consists of five steps:
61 1. Breaking up subtract operations into addition + negate, where
62 it would promote the reassociation of adds.
64 2. Left linearization of the expression trees, so that (A+B)+(C+D)
65 becomes (((A+B)+C)+D), which is easier for us to rewrite later.
66 During linearization, we place the operands of the binary
67 expressions into a vector of operand_entry_*
69 3. Optimization of the operand lists, eliminating things like a +
70 -a, a & a, etc.
72 3a. Combine repeated factors with the same occurrence counts
73 into a __builtin_powi call that will later be optimized into
74 an optimal number of multiplies.
76 4. Rewrite the expression trees we linearized and optimized so
77 they are in proper rank order.
79 5. Repropagate negates, as nothing else will clean it up ATM.
81 A bit of theory on #4, since nobody seems to write anything down
82 about why it makes sense to do it the way they do it:
84 We could do this much nicer theoretically, but don't (for reasons
85 explained after how to do it theoretically nice :P).
87 In order to promote the most redundancy elimination, you want
88 binary expressions whose operands are the same rank (or
89 preferably, the same value) exposed to the redundancy eliminator,
90 for possible elimination.
92 So the way to do this if we really cared, is to build the new op
93 tree from the leaves to the roots, merging as you go, and putting the
94 new op on the end of the worklist, until you are left with one
95 thing on the worklist.
97 IE if you have to rewrite the following set of operands (listed with
98 rank in parentheses), with opcode PLUS_EXPR:
100 a (1), b (1), c (1), d (2), e (2)
103 We start with our merge worklist empty, and the ops list with all of
104 those on it.
106 You want to first merge all leaves of the same rank, as much as
107 possible.
109 So first build a binary op of
111 mergetmp = a + b, and put "mergetmp" on the merge worklist.
113 Because there is no three operand form of PLUS_EXPR, c is not going to
114 be exposed to redundancy elimination as a rank 1 operand.
116 So you might as well throw it on the merge worklist (you could also
117 consider it to now be a rank two operand, and merge it with d and e,
118 but in this case, you then have evicted e from a binary op. So at
119 least in this situation, you can't win.)
121 Then build a binary op of d + e
122 mergetmp2 = d + e
124 and put mergetmp2 on the merge worklist.
126 so merge worklist = {mergetmp, c, mergetmp2}
128 Continue building binary ops of these operations until you have only
129 one operation left on the worklist.
131 So we have
133 build binary op
134 mergetmp3 = mergetmp + c
136 worklist = {mergetmp2, mergetmp3}
138 mergetmp4 = mergetmp2 + mergetmp3
140 worklist = {mergetmp4}
142 because we have one operation left, we can now just set the original
143 statement equal to the result of that operation.
145 This will at least expose a + b and d + e to redundancy elimination
146 as binary operations.
148 For extra points, you can reuse the old statements to build the
149 mergetmps, since you shouldn't run out.
151 So why don't we do this?
153 Because it's expensive, and rarely will help. Most trees we are
154 reassociating have 3 or less ops. If they have 2 ops, they already
155 will be written into a nice single binary op. If you have 3 ops, a
156 single simple check suffices to tell you whether the first two are of the
157 same rank. If so, you know to order it
159 mergetmp = op1 + op2
160 newstmt = mergetmp + op3
162 instead of
163 mergetmp = op2 + op3
164 newstmt = mergetmp + op1
166 If all three are of the same rank, you can't expose them all in a
167 single binary operator anyway, so the above is *still* the best you
168 can do.
170 Thus, this is what we do. When we have three ops left, we check to see
171 what order to put them in, and call it a day. As a nod to vector sum
172 reduction, we check if any of the ops are really a phi node that is a
173 destructive update for the associating op, and keep the destructive
174 update together for vector sum reduction recognition. */
176 /* Enable insertion of __builtin_powi calls during execute_reassoc. See
177 point 3a in the pass header comment. */
180 /* Statistics */
181 static struct
182 {
191 /* Operator, rank pair. */
192 struct operand_entry
193 {
196 tree op;
199 };
204 /* This is used to assign a unique ID to each struct operand_entry
205 so that qsort results are identical on different hosts. */
208 /* Starting rank number for a given basic block, so that we can rank
209 operations using unmovable instructions in that BB based on the bb
210 depth. */
213 /* Operand->rank hashtable. */
216 /* Vector of SSA_NAMEs on which after reassociate_bb is done with
217 all basic blocks the CFG should be adjusted - basic blocks
218 split right after that SSA_NAME's definition statement and before
219 the only use, which must be a bit ior. */
222 /* Forward decls. */
226 /* Wrapper around gsi_remove, which adjusts gimple_uid of debug stmts
227 possibly added by gsi_remove. */
229 bool
231 {
244 else
248 {
252 }
254 }
256 /* Bias amount for loop-carried phis. We want this to be larger than
257 the depth of any reassociation tree we can see, but not larger than
258 the rank difference between two blocks. */
259 #define PHI_LOOP_BIAS (1 << 15)
261 /* Rank assigned to a phi statement. If STMT is a loop-carried phi of
262 an innermost loop, and the phi has only a single use which is inside
263 the loop, then the rank is the block rank of the loop latch plus an
264 extra bias for the loop-carried dependence. This causes expressions
265 calculated into an accumulator variable to be independent for each
266 iteration of the loop. If STMT is some other phi, the rank is the
267 block rank of its containing block. */
268 static long
270 {
273 tree res;
275 use_operand_p use;
278 /* We only care about real loops (those with a latch). */
282 /* Interesting phis must be in headers of innermost loops. */
287 /* Ignore virtual SSA_NAMEs. */
292 /* The phi definition must have a single use, and that use must be
293 within the loop. Otherwise this isn't an accumulator pattern. */
298 /* Look for phi arguments from within the loop. If found, bias this phi. */
300 {
304 {
308 }
309 }
311 /* Must be an uninteresting phi. */
313 }
315 /* If EXP is an SSA_NAME defined by a PHI statement that represents a
316 loop-carried dependence of an innermost loop, return TRUE; else
317 return FALSE. */
318 static bool
320 {
333 /* Non-loop-carried phis have block rank. Loop-carried phis have
334 an additional bias added in. If this phi doesn't have block rank,
335 it's biased and should not be propagated. */
342 }
344 /* Return the maximum of RANK and the rank that should be propagated
345 from expression OP. For most operands, this is just the rank of OP.
346 For loop-carried phis, the value is zero to avoid undoing the bias
347 in favor of the phi. */
348 static long
350 {
359 }
361 /* Look up the operand rank structure for expression E. */
365 {
368 }
370 /* Insert {E,RANK} into the operand rank hashtable. */
374 {
377 }
379 /* Given an expression E, return the rank of the expression. */
381 static long
383 {
384 /* SSA_NAME's have the rank of the expression they are the result
385 of.
386 For globals and uninitialized values, the rank is 0.
387 For function arguments, use the pre-setup rank.
388 For PHI nodes, stores, asm statements, etc, we use the rank of
389 the BB.
390 For simple operations, the rank is the maximum rank of any of
391 its operands, or the bb_rank, whichever is less.
392 I make no claims that this is optimal, however, it gives good
393 results. */
395 /* We make an exception to the normal ranking system to break
396 dependences of accumulator variables in loops. Suppose we
397 have a simple one-block loop containing:
399 x_1 = phi(x_0, x_2)
400 b = a + x_1
401 c = b + d
402 x_2 = c + e
404 As shown, each iteration of the calculation into x is fully
405 dependent upon the iteration before it. We would prefer to
406 see this in the form:
408 x_1 = phi(x_0, x_2)
409 b = a + d
410 c = b + e
411 x_2 = c + x_1
413 If the loop is unrolled, the calculations of b and c from
414 different iterations can be interleaved.
416 To obtain this result during reassociation, we bias the rank
417 of the phi definition x_1 upward, when it is recognized as an
418 accumulator pattern. The artificial rank causes it to be
419 added last, providing the desired independence. */
422 {
423 ssa_op_iter iter;
426 tree op;
438 /* If we already have a rank for this expression, use that. */
443 /* Otherwise, find the maximum rank for the operands. As an
444 exception, remove the bias from loop-carried phis when propagating
445 the rank so that dependent operations are not also biased. */
446 /* Simply walk over all SSA uses - this takes advatage of the
447 fact that non-SSA operands are is_gimple_min_invariant and
448 thus have rank 0. */
454 {
458 }
460 /* Note the rank in the hashtable so we don't recompute it. */
463 }
465 /* Constants, globals, etc., are rank 0 */
467 }
470 /* We want integer ones to end up last no matter what, since they are
471 the ones we can do the most with. */
472 #define INTEGER_CONST_TYPE 1 << 4
473 #define FLOAT_ONE_CONST_TYPE 1 << 3
474 #define FLOAT_CONST_TYPE 1 << 2
475 #define OTHER_CONST_TYPE 1 << 1
477 /* Classify an invariant tree into integer, float, or other, so that
478 we can sort them to be near other constants of the same type. */
481 {
485 {
486 /* Sort -1.0 and 1.0 constants last, while in some cases
487 const_binop can't optimize some inexact operations, multiplication
488 by -1.0 or 1.0 can be always merged with others. */
492 }
493 else
495 }
497 /* qsort comparison function to sort operand entries PA and PB by rank
498 so that the sorted array is ordered by rank in decreasing order. */
499 static int
501 {
508 /* It's nicer for optimize_expression if constants that are likely
509 to fold when added/multiplied/whatever are put next to each
510 other. Since all constants have rank 0, order them by type. */
512 {
515 else
516 /* To make sorting result stable, we use unique IDs to determine
517 order. */
519 }
522 {
525 else
527 }
531 /* Lastly, make sure the versions that are the same go next to each
532 other. */
534 {
535 /* As SSA_NAME_VERSION is assigned pretty randomly, because we reuse
536 versions of removed SSA_NAMEs, so if possible, prefer to sort
537 based on basic block and gimple_uid of the SSA_NAME_DEF_STMT.
538 See PR60418. */
544 {
545 /* One of the SSA_NAMEs can be defined in oeN->stmt_to_insert
546 but the other might not. */
551 /* If neither is, compare bb_rank. */
554 }
562 }
565 }
567 /* Add an operand entry to *OPS for the tree operand OP. */
569 static void
571 {
580 }
582 /* Add an operand entry to *OPS for the tree operand OP with repeat
583 count REPEAT. */
585 static void
587 HOST_WIDE_INT repeat)
588 {
599 }
601 /* Return true if STMT is reassociable operation containing a binary
602 operation with tree code CODE, and is inside LOOP. */
604 static bool
606 {
618 {
629 }
632 }
635 /* Return true if STMT is a nop-conversion. */
637 static bool
639 {
641 {
646 }
648 }
650 /* Given NAME, if NAME is defined by a unary operation OPCODE, return the
651 operand of the negate operation. Otherwise, return NULL. */
653 static tree
655 {
658 /* Look through nop conversions (sign changes). */
669 }
671 /* Return true if OP1 and OP2 have the same value if casted to either type. */
673 static bool
675 {
681 {
684 {
688 }
689 }
692 {
695 {
700 }
701 }
704 }
707 /* If CURR and LAST are a pair of ops that OPCODE allows us to
708 eliminate through equivalences, do so, remove them from OPS, and
709 return true. Otherwise, return false. */
711 static bool
718 {
720 /* If we have two of the same op, and the opcode is & |, min, or max,
721 we can eliminate one of them.
722 If we have two of the same op, and the opcode is ^, we can
723 eliminate both of them. */
726 {
728 {
734 {
741 }
750 {
756 }
761 {
765 }
766 else
767 {
770 }
776 }
777 }
779 }
783 /* If OPCODE is PLUS_EXPR, CURR->OP is a negate expression or a bitwise not
784 expression, look in OPS for a corresponding positive operation to cancel
785 it out. If we find one, remove the other from OPS, replace
786 OPS[CURRINDEX] with 0 or -1, respectively, and return true. Otherwise,
787 return false. */
789 static bool
794 {
795 tree negateop;
796 tree notop;
808 /* Any non-negated version will have a rank that is one less than
809 the current rank. So once we hit those ranks, if we don't find
810 one, we can stop. */
815 i++)
816 {
819 {
821 {
827 }
835 }
838 {
842 {
848 }
856 }
857 }
859 /* If CURR->OP is a negate expr without nop conversion in a plus expr:
860 save it for later inspection in repropagate_negates(). */
866 }
868 /* If OPCODE is BIT_IOR_EXPR, BIT_AND_EXPR, and, CURR->OP is really a
869 bitwise not expression, look in OPS for a corresponding operand to
870 cancel it out. If we find one, remove the other from OPS, replace
871 OPS[CURRINDEX] with 0, and return true. Otherwise, return
872 false. */
874 static bool
879 {
880 tree notop;
892 /* Any non-not version will have a rank that is one less than
893 the current rank. So once we hit those ranks, if we don't find
894 one, we can stop. */
899 i++)
900 {
902 {
904 {
916 }
927 }
928 }
931 }
933 /* Use constant value that may be present in OPS to try to eliminate
934 operands. Note that this function is only really used when we've
935 eliminated ops for other reasons, or merged constants. Across
936 single statements, fold already does all of this, plus more. There
937 is little point in duplicating logic, so I've only included the
938 identities that I could ever construct testcases to trigger. */
940 static void
943 {
949 {
951 {
954 {
956 {
965 }
966 }
968 {
970 {
975 }
976 }
980 {
982 {
991 }
992 }
994 {
996 {
1001 }
1002 }
1010 {
1012 {
1020 }
1021 }
1026 {
1028 {
1034 }
1035 }
1045 {
1047 {
1053 }
1054 }
1058 }
1059 }
1060 }
1066 /* Structure for tracking and counting operands. */
1071 tree op;
1072 };
1075 /* The heap for the oecount hashtable and the sorted list of operands. */
1079 /* Oecount hashtable helpers. */
1082 {
1085 };
1087 /* Hash function for oecount. */
1089 inline hashval_t
1091 {
1094 }
1096 /* Comparison function for oecount. */
1100 {
1104 }
1106 /* Comparison function for qsort sorting oecount elements by count. */
1108 static int
1110 {
1115 else
1116 /* If counts are identical, use unique IDs to stabilize qsort. */
1118 }
1120 /* Return TRUE iff STMT represents a builtin call that raises OP
1121 to some exponent. */
1123 static bool
1125 {
1130 {
1131 CASE_CFN_POW:
1132 CASE_CFN_POWI:
1137 }
1138 }
1140 /* Given STMT which is a __builtin_pow* call, decrement its exponent
1141 in place and return the result. Assumes that stmt_is_power_of_op
1142 was previously called for STMT and returned TRUE. */
1144 static HOST_WIDE_INT
1146 {
1148 HOST_WIDE_INT power;
1149 tree arg1;
1152 {
1153 CASE_CFN_POW:
1161 CASE_CFN_POWI:
1169 }
1170 }
1172 /* Replace SSA defined by STMT and replace all its uses with new
1173 SSA. Also return the new SSA. */
1175 static tree
1177 {
1179 use_operand_p use;
1180 imm_use_iterator iter;
1187 /* Also need to update GIMPLE_DEBUGs. */
1189 {
1192 {
1194 {
1196 gdebug *def_temp
1200 stmt);
1207 }
1209 }
1213 }
1215 }
1217 /* Replace all SSAs defined in STMTS_TO_FIX and replace its
1218 uses with new SSAs. Also do this for the stmt that defines DEF
1219 if *DEF is not OP. */
1221 static void
1224 {
1236 }
1238 /* Find the single immediate use of STMT's LHS, and replace it
1239 with OP. Remove STMT. If STMT's LHS is the same as *DEF,
1240 replace *DEF with OP as well. */
1242 static void
1244 {
1245 tree lhs;
1247 use_operand_p use;
1248 gimple_stmt_iterator gsi;
1252 else
1266 }
1268 /* Walks the linear chain with result *DEF searching for an operation
1269 with operand OP and code OPCODE removing that from the chain. *DEF
1270 is updated if there is only one operand but no operation left. */
1272 static void
1274 {
1277 /* PR72835 - Record the stmt chain that has to be updated such that
1278 we dont use the same LHS when the values computed are different. */
1281 do
1282 {
1283 tree name;
1286 {
1288 {
1290 {
1294 }
1296 }
1298 {
1300 {
1306 }
1309 {
1310 gimple_assign_set_rhs_code
1313 }
1314 }
1315 }
1319 /* If this is the operation we look for and one of the operands
1320 is ours simply propagate the other operand into the stmts
1321 single use. */
1325 {
1332 }
1334 /* We might have a multiply of two __builtin_pow* calls, and
1335 the operand might be hiding in the rightmost one. Likewise
1336 this can happen for a negate. */
1341 {
1344 {
1347 else
1350 }
1353 {
1355 {
1359 }
1362 {
1364 gimple_assign_set_rhs_code
1367 }
1368 }
1369 }
1371 /* Continue walking the chain. */
1376 }
1381 }
1383 /* Returns true if statement S1 dominates statement S2. Like
1384 stmt_dominates_stmt_p, but uses stmt UIDs to optimize. */
1386 static bool
1388 {
1391 /* If bb1 is NULL, it should be a GIMPLE_NOP def stmt of an (D)
1392 SSA_NAME. Assume it lives at the beginning of function and
1393 thus dominates everything. */
1397 /* If bb2 is NULL, it doesn't dominate any stmt with a bb. */
1402 {
1403 /* PHIs in the same basic block are assumed to be
1404 executed all in parallel, if only one stmt is a PHI,
1405 it dominates the other stmt in the same basic block. */
1423 {
1429 }
1432 }
1435 }
1437 /* Insert STMT after INSERT_POINT. */
1439 static void
1441 {
1442 gimple_stmt_iterator gsi;
1443 basic_block bb;
1448 {
1453 }
1454 else
1455 /* We assume INSERT_POINT is a SSA_NAME_DEF_STMT of some SSA_NAME,
1456 thus if it must end a basic block, it should be a call that can
1457 throw, or some assignment that can throw. If it throws, the LHS
1458 of it will not be initialized though, so only valid places using
1459 the SSA_NAME should be dominated by the fallthru edge. */
1463 {
1467 }
1468 else
1471 }
1473 /* Builds one statement performing OP1 OPCODE OP2 using TMPVAR for
1474 the result. Places the statement after the definition of either
1475 OP1 or OP2. Returns the new statement. */
1479 {
1481 gimple_stmt_iterator gsi;
1482 tree op;
1485 /* Create the addition statement. */
1489 /* Find an insertion place and insert. */
1496 {
1499 {
1500 gimple_stmt_iterator gsi2
1504 }
1505 else
1508 }
1509 else
1510 {
1516 else
1519 }
1523 }
1525 /* Perform un-distribution of divisions and multiplications.
1526 A * X + B * X is transformed into (A + B) * X and A / X + B / X
1527 to (A + B) / X for real X.
1529 The algorithm is organized as follows.
1531 - First we walk the addition chain *OPS looking for summands that
1532 are defined by a multiplication or a real division. This results
1533 in the candidates bitmap with relevant indices into *OPS.
1535 - Second we build the chains of multiplications or divisions for
1536 these candidates, counting the number of occurrences of (operand, code)
1537 pairs in all of the candidates chains.
1539 - Third we sort the (operand, code) pairs by number of occurrence and
1540 process them starting with the pair with the most uses.
1542 * For each such pair we walk the candidates again to build a
1543 second candidate bitmap noting all multiplication/division chains
1544 that have at least one occurrence of (operand, code).
1546 * We build an alternate addition chain only covering these
1547 candidates with one (operand, code) operation removed from their
1548 multiplication/division chain.
1550 * The first candidate gets replaced by the alternate addition chain
1551 multiplied/divided by the operand.
1553 * All candidate chains get disabled for further processing and
1554 processing of (operand, code) pairs continues.
1556 The alternate addition chains built are re-processed by the main
1557 reassociation algorithm which allows optimizing a * x * y + b * y * x
1558 to (a + b ) * x * y in one invocation of the reassociation pass. */
1560 static bool
1563 {
1568 sbitmap_iterator sbi0;
1577 /* Build a list of candidates to process. */
1582 {
1598 nr_candidates++;
1599 }
1605 {
1610 }
1612 /* Build linearized sub-operand lists and the counting table. */
1617 /* ??? Macro arguments cannot have multi-argument template types in
1618 them. This typedef is needed to workaround that limitation. */
1622 {
1633 {
1634 oecount c;
1645 {
1647 }
1648 else
1649 {
1652 }
1653 }
1654 }
1656 /* Sort the counting table. */
1660 {
1664 {
1670 }
1671 }
1673 /* Process the (operand, code) pairs in order of most occurrence. */
1676 {
1681 /* Now collect the operands in the outer chain that contain
1682 the common operand in their inner chain. */
1686 {
1692 /* If we undistributed in this chain already this may be
1693 a constant. */
1703 {
1705 {
1709 }
1710 }
1711 }
1714 {
1719 /* Build the new addition chain. */
1722 {
1725 }
1728 {
1732 {
1735 }
1742 }
1744 /* Apply the multiplication/division. */
1748 {
1752 }
1754 /* Record it in the addition chain and disable further
1755 undistribution with this op. */
1761 }
1764 }
1772 }
1774 /* Pair to hold the information of one specific VECTOR_TYPE SSA_NAME:
1775 first: element index for each relevant BIT_FIELD_REF.
1776 second: the index of vec ops* for each relevant BIT_FIELD_REF. */
1779 tree vec_type;
1781 };
1784 /* Comparison function for qsort on VECTOR SSA_NAME trees by machine mode. */
1785 static int
1787 {
1801 }
1803 /* Cleanup hash map for VECTOR information. */
1804 static void
1806 {
1809 {
1813 }
1814 }
1816 /* Perform un-distribution of BIT_FIELD_REF on VECTOR_TYPE.
1817 V1[0] + V1[1] + ... + V1[k] + V2[0] + V2[1] + ... + V2[k] + ... Vn[k]
1818 is transformed to
1819 Vs = (V1 + V2 + ... + Vn)
1820 Vs[0] + Vs[1] + ... + Vs[k]
1822 The basic steps are listed below:
1824 1) Check the addition chain *OPS by looking those summands coming from
1825 VECTOR bit_field_ref on VECTOR type. Put the information into
1826 v_info_map for each satisfied summand, using VECTOR SSA_NAME as key.
1828 2) For each key (VECTOR SSA_NAME), validate all its BIT_FIELD_REFs are
1829 continuous, they can cover the whole VECTOR perfectly without any holes.
1830 Obtain one VECTOR list which contain candidates to be transformed.
1832 3) Sort the VECTOR list by machine mode of VECTOR type, for each group of
1833 candidates with same mode, build the addition statements for them and
1834 generate BIT_FIELD_REFs accordingly.
1836 TODO:
1837 The current implementation requires the whole VECTORs should be fully
1838 covered, but it can be extended to support partial, checking adjacent
1839 but not fill the whole, it may need some cost model to define the
1840 boundary to do or not.
1841 */
1842 static bool
1845 {
1860 /* Find those summands from VECTOR BIT_FIELD_REF in addition chain, put the
1861 information into map. */
1863 {
1883 /* Ignore it if target machine can't support this VECTOR type. */
1887 /* Check const vector type, constrain BIT_FIELD_REF offset and size. */
1895 /* The type of BIT_FIELD_REF might not be equal to the element type of
1896 the vector. We want to use a vector type with element type the
1897 same as the BIT_FIELD_REF and size the same as TREE_TYPE (vec). */
1899 {
1900 machine_mode simd_mode;
1902 unsigned HOST_WIDE_INT elem_size
1914 /* Ignore it if target machine can't support this VECTOR type. */
1918 /* Check const vector type, constrain BIT_FIELD_REF offset and
1919 size. */
1926 }
1937 /* Ignore it if target machine can't support this type of VECTOR
1938 operation. */
1946 {
1949 }
1953 }
1955 /* At least two VECTOR to combine. */
1957 {
1960 }
1962 /* Verify all VECTOR candidates by checking two conditions:
1963 1) sorted offsets are adjacent, no holes.
1964 2) can fill the whole VECTOR perfectly.
1965 And add the valid candidates to a vector for further handling. */
1969 {
1972 unsigned int num_elems
1981 {
1983 {
1986 }
1987 else
1989 }
1993 }
1995 /* At least two VECTOR to combine. */
1997 {
2000 }
2003 /* Go through all candidates by machine mode order, query the mode_to_total
2004 to get the total number for each mode and skip the single one. */
2006 {
2010 /* Skip modes with only a single candidate. */
2021 /* Build the sum for all candidates with same mode. */
2022 do
2023 {
2028 {
2029 /* Update the operands only after build_and_add_sum,
2030 so that we don't have to repeat the placement algorithm
2031 of build_and_add_sum. */
2041 {
2048 }
2050 }
2054 /* Update those related ops of current candidate VECTOR. */
2056 {
2059 /* Set this then op definition will get DCEd later. */
2067 else
2068 {
2072 }
2074 }
2076 {
2079 }
2080 i++;
2081 }
2085 /* Referring to first valid VECTOR with this mode, generate the
2086 BIT_FIELD_REF statements accordingly. */
2091 {
2101 /* Set this then op definition will get DCEd later. */
2106 {
2109 }
2110 }
2111 }
2119 }
2121 /* If OPCODE is BIT_IOR_EXPR or BIT_AND_EXPR and CURR is a comparison
2122 expression, examine the other OPS to see if any of them are comparisons
2123 of the same values, which we may be able to combine or eliminate.
2124 For example, we can rewrite (a < b) | (a == b) as (a <= b). */
2126 static bool
2131 {
2141 /* Check that CURR is a comparison. */
2153 /* Now look for a similar comparison in the remaining OPS. */
2155 {
2156 tree t;
2167 /* If we got here, we have a match. See if we can combine the
2168 two comparisons. */
2175 else
2183 /* maybe_fold_and_comparisons and maybe_fold_or_comparisons
2184 always give us a boolean_type_node value back. If the original
2185 BIT_AND_EXPR or BIT_IOR_EXPR was of a wider integer type,
2186 we need to convert. */
2192 {
2202 }
2205 {
2213 }
2215 /* Now we can delete oe, as it has been subsumed by the new combined
2216 expression t. */
2220 /* If t is the same as curr->op, we're done. Otherwise we must
2221 replace curr->op with t. Special case is if we got a constant
2222 back, in which case we add it to the end instead of in place of
2223 the current entry. */
2225 {
2228 }
2230 {
2233 tree newop1;
2234 tree newop2;
2243 }
2245 }
2248 }
2251 /* Transform repeated addition of same values into multiply with
2252 constant. */
2253 static bool
2255 {
2268 /* Look for repeated operands. */
2270 {
2272 {
2276 }
2278 {
2279 count++;
2281 }
2282 else
2283 {
2289 }
2290 }
2296 {
2297 /* Convert repeated operand addition to multiplication. */
2306 gassign *mul_stmt
2312 }
2315 }
2318 /* Perform various identities and other optimizations on the list of
2319 operand entries, stored in OPS. The tree code for the binary
2320 operation between all the operands is OPCODE. */
2322 static void
2325 {
2337 /* If the last two are constants, pop the constants off, merge them
2338 and try the next two. */
2340 {
2347 {
2352 {
2364 }
2365 }
2366 }
2372 {
2380 {
2386 }
2388 i++;
2389 }
2393 }
2395 /* The following functions are subroutines to optimize_range_tests and allow
2396 it to try to change a logical combination of comparisons into a range
2397 test.
2399 For example, both
2400 X == 2 || X == 5 || X == 3 || X == 4
2401 and
2402 X >= 2 && X <= 5
2403 are converted to
2404 (unsigned) (X - 2) <= 3
2406 For more information see comments above fold_test_range in fold-const.c,
2407 this implementation is for GIMPLE. */
2409 struct range_entry
2410 {
2411 tree exp;
2412 tree low;
2413 tree high;
2417 };
2422 /* Dump the range entry R to FILE, skipping its expression if SKIP_EXP. */
2424 void
2426 {
2434 }
2436 /* Dump the range entry R to STDERR. */
2438 DEBUG_FUNCTION void
2440 {
2443 }
2445 /* This is similar to make_range in fold-const.c, but on top of
2446 GIMPLE instead of trees. If EXP is non-NULL, it should be
2447 an SSA_NAME and STMT argument is ignored, otherwise STMT
2448 argument should be a GIMPLE_COND. */
2450 static void
2452 {
2466 /* Start with simply saying "EXP != 0" and then look at the code of EXP
2467 and see if we can refine the range. Some of the cases below may not
2468 happen, but it doesn't seem worth worrying about this. We "continue"
2469 the outer loop when we've changed something; otherwise we "break"
2470 the switch, which will "break" the while. */
2479 {
2482 else
2484 }
2489 {
2492 tree nexp;
2493 location_t loc;
2496 {
2509 }
2510 else
2511 {
2516 }
2523 {
2526 /* Ensure the range is either +[-,0], +[0,0],
2527 -[-,0], -[0,0] or +[1,-], +[1,1], -[1,-] or
2528 -[1,1]. If it is e.g. +[-,-] or -[-,-]
2529 or similar expression of unconditional true or
2530 false, it should not be negated. */
2533 {
2537 }
2542 CASE_CONVERT:
2544 {
2549 }
2551 {
2554 else
2556 }
2567 /* FALLTHRU */
2571 do_default:
2576 {
2580 }
2582 }
2584 }
2586 {
2592 }
2593 }
2595 /* Comparison function for qsort. Sort entries
2596 without SSA_NAME exp first, then with SSA_NAMEs sorted
2597 by increasing SSA_NAME_VERSION, and for the same SSA_NAMEs
2598 by increasing ->low and if ->low is the same, by increasing
2599 ->high. ->low == NULL_TREE means minimum, ->high == NULL_TREE
2600 maximum. */
2602 static int
2604 {
2609 {
2611 {
2612 /* Group range_entries for the same SSA_NAME together. */
2617 /* If ->low is different, NULL low goes first, then by
2618 ascending low. */
2620 {
2622 {
2631 }
2632 else
2634 }
2637 /* If ->high is different, NULL high goes last, before that by
2638 ascending high. */
2640 {
2642 {
2651 }
2652 else
2654 }
2657 /* If both ranges are the same, sort below by ascending idx. */
2658 }
2659 else
2661 }
2667 else
2668 {
2671 }
2672 }
2674 /* Helper function for update_range_test. Force EXPR into an SSA_NAME,
2675 insert needed statements BEFORE or after GSI. */
2677 static tree
2679 {
2683 {
2687 else
2690 }
2692 }
2694 /* Helper routine of optimize_range_test.
2695 [EXP, IN_P, LOW, HIGH, STRICT_OVERFLOW_P] is a merged range for
2696 RANGE and OTHERRANGE through OTHERRANGE + COUNT - 1 ranges,
2697 OPCODE and OPS are arguments of optimize_range_tests. If OTHERRANGE
2698 is NULL, OTHERRANGEP should not be and then OTHERRANGEP points to
2699 an array of COUNT pointers to other ranges. Return
2700 true if the range merge has been successful.
2701 If OPCODE is ERROR_MARK, this is called from within
2702 maybe_optimize_range_tests and is performing inter-bb range optimization.
2703 In that case, whether an op is BIT_AND_EXPR or BIT_IOR_EXPR is found in
2704 oe->rank. */
2706 static bool
2712 {
2722 gimple_stmt_iterator gsi;
2728 /* If op is default def SSA_NAME, there is no place to insert the
2729 new comparison. Give up, unless we can use OP itself as the
2730 range test. */
2732 {
2742 {
2745 }
2746 else
2748 }
2752 "assuming signed overflow does not occur "
2756 {
2761 {
2764 else
2769 {
2772 }
2773 else
2774 {
2777 }
2778 }
2782 }
2790 {
2793 }
2794 else
2795 {
2798 }
2801 /* In rare cases range->exp can be equal to lhs of stmt.
2802 In that case we have to insert after the stmt rather then before
2803 it. If stmt is a PHI, insert it at the start of the basic block. */
2805 {
2809 }
2811 {
2814 }
2815 else
2816 {
2820 else
2821 {
2825 {
2828 }
2829 }
2834 else
2836 }
2840 else
2851 {
2854 else
2857 /* Now change all the other range test immediate uses, so that
2858 those tests will be optimized away. */
2860 {
2864 else
2867 }
2868 else
2873 }
2875 }
2877 /* Optimize X == CST1 || X == CST2
2878 if popcount (CST1 ^ CST2) == 1 into
2879 (X & ~(CST1 ^ CST2)) == (CST1 & ~(CST1 ^ CST2)).
2880 Similarly for ranges. E.g.
2881 X != 2 && X != 3 && X != 10 && X != 11
2882 will be transformed by the previous optimization into
2883 !((X - 2U) <= 1U || (X - 10U) <= 1U)
2884 and this loop can transform that into
2885 !(((X & ~8) - 2U) <= 1U). */
2887 static bool
2893 {
2895 /* Check lowi ^ lowj == highi ^ highj and
2896 popcount (lowi ^ lowj) == 1. */
2914 {
2920 }
2927 rangei->strict_overflow_p
2931 }
2933 /* Optimize X == CST1 || X == CST2
2934 if popcount (CST2 - CST1) == 1 into
2935 ((X - CST1) & ~(CST2 - CST1)) == 0.
2936 Similarly for ranges. E.g.
2937 X == 43 || X == 76 || X == 44 || X == 78 || X == 77 || X == 46
2938 || X == 75 || X == 45
2939 will be transformed by the previous optimization into
2940 (X - 43U) <= 3U || (X - 75U) <= 3U
2941 and this loop can transform that into
2942 ((X - 43U) & ~(75U - 43U)) <= 3U. */
2943 static bool
2949 {
2951 /* Check highi - lowi == highj - lowj. */
2958 /* Check popcount (lowj - lowi) == 1. */
2973 else
2985 rangei->strict_overflow_p
2989 }
2991 /* It does some common checks for function optimize_range_tests_xor and
2992 optimize_range_tests_diff.
2993 If OPTIMIZE_XOR is TRUE, it calls optimize_range_tests_xor.
2994 Else it calls optimize_range_tests_diff. */
2996 static bool
3000 {
3004 {
3019 {
3029 /* Check lowj > highi. */
3038 else
3043 {
3046 }
3047 }
3048 }
3050 }
3052 /* Helper function of optimize_range_tests_to_bit_test. Handle a single
3053 range, EXP, LOW, HIGH, compute bit mask of bits to test and return
3054 EXP on success, NULL otherwise. */
3056 static tree
3059 {
3072 {
3077 {
3084 {
3087 widest_int bias
3092 {
3095 }
3101 {
3104 }
3105 }
3106 }
3107 }
3121 }
3123 /* Attempt to optimize small range tests using bit test.
3124 E.g.
3125 X != 43 && X != 76 && X != 44 && X != 78 && X != 49
3126 && X != 77 && X != 46 && X != 75 && X != 45 && X != 82
3127 has been by earlier optimizations optimized into:
3128 ((X - 43U) & ~32U) > 3U && X != 49 && X != 82
3129 As all the 43 through 82 range is less than 64 numbers,
3130 for 64-bit word targets optimize that into:
3131 (X - 43U) > 40U && ((1 << (X - 43U)) & 0x8F0000004FULL) == 0 */
3133 static bool
3137 {
3144 {
3158 wide_int mask;
3167 {
3168 tree exp2;
3172 ;
3174 {
3177 ;
3179 {
3184 }
3185 else
3187 }
3188 else
3196 wide_int mask2;
3204 }
3206 /* If every possible relative value of the expression is a valid shift
3207 amount, then we can merge the entry test in the bit test. In this
3208 case, if we would need otherwise 2 or more comparisons, then use
3209 the bit test; in the other cases, the threshold is 3 comparisons. */
3215 {
3218 {
3221 }
3223 {
3226 }
3228 }
3229 else
3232 {
3243 /* See if it isn't cheaper to pretend the minimum value of the
3244 range is 0, if maximum value is small enough.
3245 We can avoid then subtraction of the minimum value, but the
3246 mask constant could be perhaps more expensive. */
3249 {
3264 {
3267 }
3268 }
3270 tree tem;
3272 {
3277 }
3278 else
3295 /* The shift might have undefined behavior if TEM is true,
3296 but reassociate_bb isn't prepared to have basic blocks
3297 split when it is running. So, temporarily emit a code
3298 with BIT_IOR_EXPR instead of &&, and fix it up in
3299 branch_fixup. */
3302 {
3306 }
3307 gimple_seq seq2;
3313 {
3319 }
3324 {
3328 }
3329 else
3331 }
3332 }
3334 }
3336 /* Optimize x != 0 && y != 0 && z != 0 into (x | y | z) != 0
3337 and similarly x != -1 && y != -1 && y != -1 into (x & y & z) != -1. */
3339 static bool
3343 {
3352 {
3373 }
3377 {
3380 {
3385 }
3391 {
3396 ;
3399 {
3403 }
3404 }
3407 {
3412 ;
3417 }
3424 {
3427 {
3430 }
3432 {
3436 }
3440 {
3444 }
3450 }
3457 else
3459 }
3462 }
3464 /* Attempt to optimize for signed a and b where b is known to be >= 0:
3465 a >= 0 && a < b into (unsigned) a < (unsigned) b
3466 a >= 0 && a <= b into (unsigned) a <= (unsigned) b */
3468 static bool
3472 basic_block first_bb)
3473 {
3479 {
3492 /* EXP >= 0 here. */
3496 }
3502 {
3509 {
3516 else
3518 }
3521 tree_code ccode;
3524 {
3533 }
3534 else
3535 {
3543 }
3551 {
3559 }
3563 {
3574 }
3580 /* maybe_optimize_range_tests allows statements without side-effects
3581 in the basic blocks as long as they are consumed in the same bb.
3582 Make sure rhs2's def stmt is not among them, otherwise we can't
3583 use safely get_nonzero_bits on it. E.g. in:
3584 # RANGE [-83, 1] NONZERO 173
3585 # k_32 = PHI <k_47(13), k_12(9)>
3586 ...
3587 if (k_32 >= 0)
3588 goto <bb 5>; [26.46%]
3589 else
3590 goto <bb 9>; [73.54%]
3592 <bb 5> [local count: 140323371]:
3593 # RANGE [0, 1] NONZERO 1
3594 _5 = (int) k_32;
3595 # RANGE [0, 4] NONZERO 4
3596 _21 = _5 << 2;
3597 # RANGE [0, 4] NONZERO 4
3598 iftmp.0_44 = (char) _21;
3599 if (k_32 < iftmp.0_44)
3600 goto <bb 6>; [84.48%]
3601 else
3602 goto <bb 9>; [15.52%]
3603 the ranges on _5/_21/iftmp.0_44 are flow sensitive, assume that
3604 k_32 >= 0. If we'd optimize k_32 >= 0 to true and k_32 < iftmp.0_44
3605 to (unsigned) k_32 < (unsigned) iftmp.0_44, then we would execute
3606 those stmts even for negative k_32 and the value ranges would be no
3607 longer guaranteed and so the optimization would be invalid. */
3609 {
3615 {
3616 /* As an exception, handle a few common cases. */
3619 {
3624 /* Zero-extension is always ok. */
3629 {
3630 /* Cast from signed to unsigned or vice versa. Retry
3631 with the op0 as new rhs2. */
3634 }
3635 }
3640 /* Masking with INTEGER_CST with MSB clear is always ok
3641 too. */
3644 }
3646 }
3654 /* We have EXP < RHS2 or EXP <= RHS2 where EXP >= 0
3655 and RHS2 is known to be RHS2 >= 0. */
3663 "assuming signed overflow does not occur "
3667 {
3688 }
3694 {
3697 }
3706 {
3711 }
3713 {
3716 }
3718 {
3724 }
3725 else
3726 {
3736 {
3741 }
3746 }
3749 /* Now change all the other range test immediate uses, so that
3750 those tests will be optimized away. */
3752 {
3756 else
3759 }
3760 else
3766 }
3770 }
3772 /* Optimize range tests, similarly how fold_range_test optimizes
3773 it on trees. The tree code for the binary
3774 operation between all the operands is OPCODE.
3775 If OPCODE is ERROR_MARK, optimize_range_tests is called from within
3776 maybe_optimize_range_tests for inter-bb range optimization.
3777 In that case if oe->op is NULL, oe->id is bb->index whose
3778 GIMPLE_COND is && or ||ed into the test, and oe->rank says
3779 the actual opcode.
3780 FIRST_BB is the first basic block if OPCODE is ERROR_MARK. */
3782 static bool
3785 {
3796 {
3800 oe->op
3801 ? NULL
3803 /* For | invert it now, we will invert it again before emitting
3804 the optimized expression. */
3808 }
3815 /* Try to merge ranges. */
3817 {
3825 {
3832 }
3840 {
3843 }
3844 /* Avoid quadratic complexity if all merge_ranges calls would succeed,
3845 while update_range_test would fail. */
3848 else
3850 }
3867 {
3870 {
3875 j++;
3876 }
3878 }
3882 }
3884 /* A subroutine of optimize_vec_cond_expr to extract and canonicalize
3885 the operands of the VEC_COND_EXPR. Returns ERROR_MARK on failure,
3886 otherwise the comparison code. TYPE is a return value that is set
3887 to type of comparison. */
3889 static tree_code
3892 {
3902 /* ??? If we start creating more COND_EXPR, we could perform
3903 this same optimization with them. For now, simplify. */
3923 /* ??? For now, allow only canonical true and false result vectors.
3924 We could expand this to other constants should the need arise,
3925 but at the moment we don't create them. */
3932 {
3935 }
3936 else
3941 /* Success! */
3949 }
3951 /* Optimize the condition of VEC_COND_EXPRs which have been combined
3952 with OPCODE (either BIT_AND_EXPR or BIT_IOR_EXPR). */
3954 static bool
3956 {
3964 {
3976 {
3986 tree comb;
3993 else
3998 /* Success! */
4000 {
4008 }
4021 }
4022 }
4025 {
4029 {
4034 j++;
4035 }
4037 }
4040 }
4042 /* Return true if STMT is a cast like:
4043 <bb N>:
4044 ...
4045 _123 = (int) _234;
4047 <bb M>:
4048 # _345 = PHI <_123(N), 1(...), 1(...)>
4049 where _234 has bool type, _123 has single use and
4050 bb N has a single successor M. This is commonly used in
4051 the last block of a range test.
4053 Also Return true if STMT is tcc_compare like:
4054 <bb N>:
4055 ...
4056 _234 = a_2(D) == 2;
4058 <bb M>:
4059 # _345 = PHI <_234(N), 1(...), 1(...)>
4060 _346 = (int) _345;
4061 where _234 has booltype, single use and
4062 bb N has a single successor M. This is commonly used in
4063 the last block of a range test. */
4065 static bool
4067 {
4069 edge e;
4071 use_operand_p use_p;
4098 /* Test whether lhs is consumed only by a PHI in the only successor bb. */
4106 /* And that the rhs is defined in the same loop. */
4108 {
4113 }
4114 else
4115 {
4120 }
4123 }
4125 /* Return true if BB is suitable basic block for inter-bb range test
4126 optimization. If BACKWARD is true, BB should be the only predecessor
4127 of TEST_BB, and *OTHER_BB is either NULL and filled by the routine,
4128 or compared with to find a common basic block to which all conditions
4129 branch to if true resp. false. If BACKWARD is false, TEST_BB should
4130 be the only predecessor of BB. */
4132 static bool
4135 {
4139 gphi_iterator gsi;
4145 /* Check last stmt first. */
4156 {
4157 /* If last stmt is GIMPLE_COND, verify that one of the succ edges
4158 goes to the next bb (if BACKWARD, it is TEST_BB), and the other
4159 to *OTHER_BB (if not set yet, try to find it out). */
4163 {
4167 {
4170 else
4172 }
4176 {
4184 }
4189 }
4192 }
4196 /* Now check all PHIs of *OTHER_BB. */
4200 {
4202 /* If both BB and TEST_BB end with GIMPLE_COND, all PHI arguments
4203 corresponding to BB and TEST_BB predecessor must be the same. */
4206 {
4207 /* Otherwise, if one of the blocks doesn't end with GIMPLE_COND,
4208 one of the PHIs should have the lhs of the last stmt in
4209 that block as PHI arg and that PHI should have 0 or 1
4210 corresponding to it in all other range test basic blocks
4211 considered. */
4213 {
4220 }
4221 else
4222 {
4230 }
4233 }
4234 }
4236 }
4238 /* Return true if BB doesn't have side-effects that would disallow
4239 range test optimization, all SSA_NAMEs set in the bb are consumed
4240 in the bb and there are no PHIs. */
4242 static bool
4244 {
4245 gimple_stmt_iterator gsi;
4252 {
4254 tree lhs;
4255 imm_use_iterator imm_iter;
4256 use_operand_p use_p;
4272 {
4278 }
4279 }
4281 }
4283 /* If VAR is set by CODE (BIT_{AND,IOR}_EXPR) which is reassociable,
4284 return true and fill in *OPS recursively. */
4286 static bool
4289 {
4304 {
4313 }
4315 }
4317 /* Find the ops that were added by get_ops starting from VAR, see if
4318 they were changed during update_range_test and if yes, create new
4319 stmts. */
4321 static tree
4324 {
4338 {
4341 {
4344 else
4346 }
4347 }
4350 {
4358 }
4360 }
4362 /* Structure to track the initial value passed to get_ops and
4363 the range in the ops vector for each basic block. */
4365 struct inter_bb_range_test_entry
4366 {
4367 tree op;
4369 };
4371 /* Inter-bb range test optimization.
4373 Returns TRUE if a gimple conditional is optimized to a true/false,
4374 otherwise return FALSE.
4376 This indicates to the caller that it should run a CFG cleanup pass
4377 once reassociation is completed. */
4379 static bool
4381 {
4385 basic_block bb;
4386 edge_iterator ei;
4387 edge e;
4393 /* Consider only basic blocks that end with GIMPLE_COND or
4394 a cast statement satisfying final_range_test_p. All
4395 but the last bb in the first_bb .. last_bb range
4396 should end with GIMPLE_COND. */
4398 {
4401 }
4404 else
4410 /* As relative ordering of post-dominator sons isn't fixed,
4411 maybe_optimize_range_tests can be called first on any
4412 bb in the range we want to optimize. So, start searching
4413 backwards, if first_bb can be set to a predecessor. */
4415 {
4422 }
4423 /* If first_bb is last_bb, other_bb hasn't been computed yet.
4424 Before starting forward search in last_bb successors, find
4425 out the other_bb. */
4427 {
4429 /* As non-GIMPLE_COND last stmt always terminates the range,
4430 if forward search didn't discover anything, just give up. */
4433 /* Look at both successors. Either it ends with a GIMPLE_COND
4434 and satisfies suitable_cond_bb, or ends with a cast and
4435 other_bb is that cast's successor. */
4441 {
4446 {
4449 else
4451 }
4455 {
4459 }
4460 }
4463 }
4464 /* Now do the forward search, moving last_bb to successor bbs
4465 that aren't other_bb. */
4467 {
4480 }
4483 /* Here basic blocks first_bb through last_bb's predecessor
4484 end with GIMPLE_COND, all of them have one of the edges to
4485 other_bb and another to another block in the range,
4486 all blocks except first_bb don't have side-effects and
4487 last_bb ends with either GIMPLE_COND, or cast satisfying
4488 final_range_test_p. */
4490 {
4493 inter_bb_range_test_entry bb_ent;
4502 {
4503 use_operand_p use_p;
4505 edge e2;
4512 /* stmt is
4513 _123 = (int) _234;
4514 OR
4515 _234 = a_2(D) == 2;
4517 followed by:
4518 <bb M>:
4519 # _345 = PHI <_123(N), 1(...), 1(...)>
4521 or 0 instead of 1. If it is 0, the _234
4522 range test is anded together with all the
4523 other range tests, if it is 1, it is ored with
4524 them. */
4532 else
4533 {
4536 }
4538 /* If _234 SSA_NAME_DEF_STMT is
4539 _234 = _567 | _789;
4540 (or &, corresponding to 1/0 in the phi arguments,
4541 push into ops the individual range test arguments
4542 of the bitwise or resp. and, recursively. */
4549 {
4550 /* Otherwise, push the _234 range test itself. */
4561 }
4568 {
4577 }
4578 else
4579 {
4582 }
4585 }
4586 /* Otherwise stmt is GIMPLE_COND. */
4594 /* Either push into ops the individual bitwise
4595 or resp. and operands, depending on which
4596 edge is other_bb. */
4601 {
4602 /* Or push the GIMPLE_COND stmt itself. */
4608 /* oe->op = NULL signs that there is no SSA_NAME
4609 for the range test, and oe->id instead is the
4610 basic block number, at which's end the GIMPLE_COND
4611 is. */
4618 }
4620 {
4623 }
4627 }
4631 {
4633 /* update_ops relies on has_single_use predicates returning the
4634 same values as it did during get_ops earlier. Additionally it
4635 never removes statements, only adds new ones and it should walk
4636 from the single imm use and check the predicate already before
4637 making those changes.
4638 On the other side, the handling of GIMPLE_COND directly can turn
4639 previously multiply used SSA_NAMEs into single use SSA_NAMEs, so
4640 it needs to be done in a separate loop afterwards. */
4642 {
4645 {
4646 tree new_op;
4656 {
4659 }
4661 {
4662 imm_use_iterator iter;
4663 use_operand_p use_p;
4674 && (TREE_CODE_CLASS
4680 else
4684 {
4688 enum tree_code rhs_code
4694 {
4697 }
4698 else
4700 gimple_stmt_iterator gsi
4712 else
4714 }
4715 }
4716 }
4719 }
4721 {
4725 {
4731 /* If we collapse the conditional to a true/false
4732 condition, then bubble that knowledge up to our caller. */
4734 {
4737 }
4739 {
4742 }
4743 else
4744 {
4749 }
4751 }
4754 }
4756 /* The above changes could result in basic blocks after the first
4757 modified one, up to and including last_bb, to be executed even if
4758 they would not be in the original program. If the value ranges of
4759 assignment lhs' in those bbs were dependent on the conditions
4760 guarding those basic blocks which now can change, the VRs might
4761 be incorrect. As no_side_effect_bb should ensure those SSA_NAMEs
4762 are only used within the same bb, it should be not a big deal if
4763 we just reset all the VRs in those bbs. See PR68671. */
4766 }
4768 }
4770 /* Return true if OPERAND is defined by a PHI node which uses the LHS
4771 of STMT in it's operands. This is also known as a "destructive
4772 update" operation. */
4774 static bool
4776 {
4779 tree lhs;
4780 use_operand_p arg_p;
4781 ssa_op_iter i;
4797 }
4799 /* Remove def stmt of VAR if VAR has zero uses and recurse
4800 on rhs1 operand if so. */
4802 static void
4804 {
4806 gimple_stmt_iterator gsi;
4809 {
4814 {
4819 }
4820 else
4822 }
4823 }
4825 /* This function checks three consequtive operands in
4826 passed operands vector OPS starting from OPINDEX and
4827 swaps two operands if it is profitable for binary operation
4828 consuming OPINDEX + 1 abnd OPINDEX + 2 operands.
4830 We pair ops with the same rank if possible.
4832 The alternative we try is to see if STMT is a destructive
4833 update style statement, which is like:
4834 b = phi (a, ...)
4835 a = c + b;
4836 In that case, we want to use the destructive update form to
4837 expose the possible vectorizer sum reduction opportunity.
4838 In that case, the third operand will be the phi node. This
4839 check is not performed if STMT is null.
4841 We could, of course, try to be better as noted above, and do a
4842 lot of work to try to find these opportunities in >3 operand
4843 cases, but it is unlikely to be worth it. */
4845 static void
4848 {
4867 }
4869 /* If definition of RHS1 or RHS2 dominates STMT, return the later of those
4870 two definitions, otherwise return STMT. */
4874 {
4882 }
4884 /* If the stmt that defines operand has to be inserted, insert it
4885 before the use. */
4886 static void
4888 {
4896 /* If the insert point is not stmt, then insert_point would be
4897 the point where operand rhs1 or rhs2 is defined. In this case,
4898 stmt_to_insert has to be inserted afterwards. This would
4899 only happen when the stmt insertion point is flexible. */
4902 else
4904 }
4907 /* Recursively rewrite our linearized statements so that the operators
4908 match those in OPS[OPINDEX], putting the computation in rank
4909 order. Return new lhs.
4910 CHANGED is true if we shouldn't reuse the lhs SSA_NAME both in
4911 the current stmt and during recursive invocations.
4912 NEXT_CHANGED is true if we shouldn't reuse the lhs SSA_NAME in
4913 recursive invocations. */
4915 static tree
4918 {
4924 /* The final recursion case for this function is that you have
4925 exactly two operations left.
4926 If we had exactly one op in the entire list to start with, we
4927 would have never called this function, and the tail recursion
4928 rewrites them one at a time. */
4930 {
4937 {
4942 {
4945 }
4947 /* If the stmt that defines operand has to be inserted, insert it
4948 before the use. */
4953 /* Even when changed is false, reassociation could have e.g. removed
4954 some redundant operations, so unless we are just swapping the
4955 arguments or unless there is no change at all (then we just
4956 return lhs), force creation of a new SSA_NAME. */
4958 {
4959 gimple *insert_point
4962 stmt
4969 else
4971 }
4972 else
4973 {
4979 }
4985 {
4988 }
4989 }
4991 }
4993 /* If we hit here, we should have 3 or more ops left. */
4996 /* Rewrite the next operator. */
4999 /* If the stmt that defines operand has to be inserted, insert it
5000 before the use. */
5004 /* Recurse on the LHS of the binary operator, which is guaranteed to
5005 be the non-leaf side. */
5006 tree new_rhs1
5012 {
5014 {
5017 }
5019 /* If changed is false, this is either opindex == 0
5020 or all outer rhs2's were equal to corresponding oe->op,
5021 and powi_result is NULL.
5022 That means lhs is equivalent before and after reassociation.
5023 Otherwise ensure the old lhs SSA_NAME is not reused and
5024 create a new stmt as well, so that any debug stmts will be
5025 properly adjusted. */
5027 {
5039 else
5041 }
5042 else
5043 {
5049 }
5052 {
5055 }
5056 }
5058 }
5060 /* Find out how many cycles we need to compute statements chain.
5061 OPS_NUM holds number os statements in a chain. CPU_WIDTH is a
5062 maximum number of independent statements we may execute per cycle. */
5064 static int
5066 {
5071 /* While we have more than 2 * cpu_width operands
5072 we may reduce number of operands by cpu_width
5073 per cycle. */
5076 /* Remained operands count may be reduced twice per cycle
5077 until we have only one operand. */
5082 else
5086 }
5088 /* Returns an optimal number of registers to use for computation of
5089 given statements. */
5091 static int
5093 machine_mode mode)
5094 {
5102 else
5108 /* Get the minimal time required for sequence computation. */
5111 /* Check if we may use less width and still compute sequence for
5112 the same time. It will allow us to reduce registers usage.
5113 get_required_cycles is monotonically increasing with lower width
5114 so we can perform a binary search for the minimal width that still
5115 results in the optimal cycle count. */
5118 {
5125 else
5127 }
5130 }
5132 /* Recursively rewrite our linearized statements so that the operators
5133 match those in OPS[OPINDEX], putting the computation in rank
5134 order and trying to allow operations to be executed in
5135 parallel. */
5137 static void
5140 {
5153 /* We start expression rewriting from the top statements.
5154 So, in this loop we create a full list of statements
5155 we will work with. */
5161 {
5164 /* Determine whether we should use results of
5165 already handled statements or not. */
5170 /* Now we choose operands for the next statement. Non zero
5171 value in ready_stmts_end means here that we should use
5172 the result of already generated statements as new operand. */
5174 {
5179 {
5183 }
5184 else
5185 {
5188 }
5192 }
5193 else
5194 {
5203 }
5205 /* If we emit the last statement then we should put
5206 operands into the last statement. It will also
5207 break the loop. */
5212 {
5215 }
5217 /* If the stmt that defines operand has to be inserted, insert it
5218 before the use. */
5225 /* We keep original statement only for the last one. All
5226 others are recreated. */
5228 {
5232 }
5233 else
5234 {
5237 }
5239 {
5242 }
5243 }
5246 }
5248 /* Transform STMT, which is really (A +B) + (C + D) into the left
5249 linear form, ((A+B)+C)+D.
5250 Recurse on D if necessary. */
5252 static void
5254 {
5255 gimple_stmt_iterator gsi;
5282 {
5285 }
5298 /* Tail recurse on the new rhs if it still needs reassociation. */
5300 /* ??? This should probably be linearize_expr (newbinrhs) but I don't
5301 want to change the algorithm while converting to tuples. */
5303 }
5305 /* If LHS has a single immediate use that is a GIMPLE_ASSIGN statement, return
5306 it. Otherwise, return NULL. */
5310 {
5311 use_operand_p immuse;
5320 }
5322 /* Recursively negate the value of TONEGATE, and return the SSA_NAME
5323 representing the negated value. Insertions of any necessary
5324 instructions go before GSI.
5325 This function is recursive in that, if you hand it "a_5" as the
5326 value to negate, and a_5 is defined by "a_5 = b_3 + b_4", it will
5327 transform b_3 + b_4 into a_5 = -b_3 + -b_4. */
5329 static tree
5331 {
5333 tree resultofnegate;
5334 gimple_stmt_iterator gsi;
5337 /* If we are trying to negate a name, defined by an add, negate the
5338 add operands instead. */
5346 {
5365 }
5373 {
5378 }
5380 }
5382 /* Return true if we should break up the subtract in STMT into an add
5383 with negate. This is true when we the subtract operands are really
5384 adds, or the subtract itself is used in an add expression. In
5385 either case, breaking up the subtract into an add with negate
5386 exposes the adds to reassociation. */
5388 static bool
5390 {
5414 }
5416 /* Transform STMT from A - B into A + -B. */
5418 static void
5420 {
5425 {
5428 }
5433 }
5435 /* Determine whether STMT is a builtin call that raises an SSA name
5436 to an integer power and has only one use. If so, and this is early
5437 reassociation and unsafe math optimizations are permitted, place
5438 the SSA name in *BASE and the exponent in *EXPONENT, and return TRUE.
5439 If any of these conditions does not hold, return FALSE. */
5441 static bool
5443 {
5444 tree arg1;
5448 {
5449 CASE_CFN_POW:
5471 CASE_CFN_POWI:
5483 }
5485 /* Expanding negative exponents is generally unproductive, so we don't
5486 complicate matters with those. Exponents of zero and one should
5487 have been handled by expression folding. */
5492 }
5494 /* Try to derive and add operand entry for OP to *OPS. Return false if
5495 unsuccessful. */
5497 static bool
5501 {
5510 && reassoc_insert_powi_p
5511 && flag_unsafe_math_optimizations
5514 {
5518 }
5525 {
5532 }
5535 }
5537 /* Recursively linearize a binary expression that is the RHS of STMT.
5538 Place the operands of the expression tree in the vector named OPS. */
5540 static void
5543 {
5556 {
5560 }
5563 {
5567 }
5569 /* If the LHS is not reassociable, but the RHS is, we need to swap
5570 them. If neither is reassociable, there is nothing we can do, so
5571 just put them in the ops vector. If the LHS is reassociable,
5572 linearize it. If both are reassociable, then linearize the RHS
5573 and the LHS. */
5576 {
5577 /* If this is not a associative operation like division, give up. */
5579 {
5582 }
5585 {
5593 }
5596 {
5599 }
5607 {
5610 }
5612 /* We want to make it so the lhs is always the reassociative op,
5613 so swap. */
5615 }
5617 {
5621 }
5631 }
5633 /* Repropagate the negates back into subtracts, since no other pass
5634 currently does it. */
5636 static void
5638 {
5640 tree negate;
5643 {
5649 /* The negate operand can be either operand of a PLUS_EXPR
5650 (it can be the LHS if the RHS is a constant for example).
5652 Force the negate operand to the RHS of the PLUS_EXPR, then
5653 transform the PLUS_EXPR into a MINUS_EXPR. */
5655 {
5656 /* If the negated operand appears on the LHS of the
5657 PLUS_EXPR, exchange the operands of the PLUS_EXPR
5658 to force the negated operand to the RHS of the PLUS_EXPR. */
5660 {
5664 }
5666 /* Now transform the PLUS_EXPR into a MINUS_EXPR and replace
5667 the RHS of the PLUS_EXPR with the operand of the NEGATE_EXPR. */
5669 {
5675 }
5676 }
5678 {
5680 {
5681 /* We have
5682 x = -a
5683 y = x - b
5684 which we transform into
5685 x = a + b
5686 y = -x .
5687 This pushes down the negate which we possibly can merge
5688 into some other operation, hence insert it into the
5689 plus_negates vector. */
5704 }
5705 else
5706 {
5707 /* Transform "x = -a; y = b - x" into "y = b + a", getting
5708 rid of one operation. */
5715 }
5716 }
5717 }
5718 }
5720 /* Returns true if OP is of a type for which we can do reassociation.
5721 That is for integral or non-saturating fixed-point types, and for
5722 floating point type when associative-math is enabled. */
5724 static bool
5726 {
5735 }
5737 /* Break up subtract operations in block BB.
5739 We do this top down because we don't know whether the subtract is
5740 part of a possible chain of reassociation except at the top.
5742 IE given
5743 d = f + g
5744 c = a + e
5745 b = c - d
5746 q = b - r
5747 k = t - q
5749 we want to break up k = t - q, but we won't until we've transformed q
5750 = b - r, which won't be broken up until we transform b = c - d.
5752 En passant, clear the GIMPLE visited flag on every statement
5753 and set UIDs within each basic block. */
5755 static void
5757 {
5758 gimple_stmt_iterator gsi;
5759 basic_block son;
5763 {
5772 /* Look for simple gimple subtract operations. */
5774 {
5779 /* Check for a subtract used only in an addition. If this
5780 is the case, transform it into add of a negate for better
5781 reassociation. IE transform C = A-B into C = A + -B if C
5782 is only used in an addition. */
5785 }
5789 }
5791 son;
5794 }
5796 /* Used for repeated factor analysis. */
5797 struct repeat_factor
5798 {
5799 /* An SSA name that occurs in a multiply chain. */
5800 tree factor;
5802 /* Cached rank of the factor. */
5805 /* Number of occurrences of the factor in the chain. */
5806 HOST_WIDE_INT count;
5808 /* An SSA name representing the product of this factor and
5809 all factors appearing later in the repeated factor vector. */
5810 tree repr;
5811 };
5816 /* Used for sorting the repeat factor vector. Sort primarily by
5817 ascending occurrence count, secondarily by descending rank. */
5819 static int
5821 {
5829 }
5831 /* Look for repeated operands in OPS in the multiply tree rooted at
5832 STMT. Replace them with an optimal sequence of multiplies and powi
5833 builtin calls, and remove the used operands from OPS. Return an
5834 SSA name representing the value of the replacement sequence. */
5836 static tree
5838 {
5843 repeat_factor rfnew;
5851 /* Nothing to do if BUILT_IN_POWI doesn't exist for this type and
5852 target. */
5856 /* Allocate the repeated factor vector. */
5859 /* Scan the OPS vector for all SSA names in the product and build
5860 up a vector of occurrence counts for each factor. */
5862 {
5864 {
5866 {
5868 {
5871 }
5872 }
5875 {
5881 }
5882 }
5883 }
5885 /* Sort the repeated factor vector by (a) increasing occurrence count,
5886 and (b) decreasing rank. */
5889 /* It is generally best to combine as many base factors as possible
5890 into a product before applying __builtin_powi to the result.
5891 However, the sort order chosen for the repeated factor vector
5892 allows us to cache partial results for the product of the base
5893 factors for subsequent use. When we already have a cached partial
5894 result from a previous iteration, it is best to make use of it
5895 before looking for another __builtin_pow opportunity.
5897 As an example, consider x * x * y * y * y * z * z * z * z.
5898 We want to first compose the product x * y * z, raise it to the
5899 second power, then multiply this by y * z, and finally multiply
5900 by z. This can be done in 5 multiplies provided we cache y * z
5901 for use in both expressions:
5903 t1 = y * z
5904 t2 = t1 * x
5905 t3 = t2 * t2
5906 t4 = t1 * t3
5907 result = t4 * z
5909 If we instead ignored the cached y * z and first multiplied by
5910 the __builtin_pow opportunity z * z, we would get the inferior:
5912 t1 = y * z
5913 t2 = t1 * x
5914 t3 = t2 * t2
5915 t4 = z * z
5916 t5 = t3 * t4
5917 result = t5 * y */
5921 /* Repeatedly look for opportunities to create a builtin_powi call. */
5923 {
5924 HOST_WIDE_INT power;
5926 /* First look for the largest cached product of factors from
5927 preceding iterations. If found, create a builtin_powi for
5928 it if the minimum occurrence count for its factors is at
5929 least 2, or just use this cached product as our next
5930 multiplicand if the minimum occurrence count is 1. */
5932 {
5935 }
5938 {
5942 {
5946 {
5951 {
5956 }
5958 }
5959 }
5960 else
5961 {
5965 power));
5972 {
5976 dump_file);
5978 {
5983 }
5985 power);
5986 }
5987 }
5988 }
5989 else
5990 {
5991 /* Otherwise, find the first factor in the repeated factor
5992 vector whose occurrence count is at least 2. If no such
5993 factor exists, there are no builtin_powi opportunities
5994 remaining. */
5996 {
5999 }
6007 {
6012 {
6017 }
6019 }
6023 /* Visit each element of the vector in reverse order (so that
6024 high-occurrence elements are visited first, and within the
6025 same occurrence count, lower-ranked elements are visited
6026 first). Form a linear product of all elements in this order
6027 whose occurrencce count is at least that of element J.
6028 Record the SSA name representing the product of each element
6029 with all subsequent elements in the vector. */
6032 else
6033 {
6035 {
6041 /* Init the last factor's representative to be itself. */
6056 /* Don't reprocess the multiply we just introduced. */
6058 }
6059 }
6061 /* Form a call to __builtin_powi for the maximum product
6062 just formed, raised to the power obtained earlier. */
6067 power));
6072 }
6074 /* If we previously formed at least one other builtin_powi call,
6075 form the product of this one and those others. */
6077 {
6086 }
6087 else
6090 /* Decrement the occurrence count of each element in the product
6091 by the count found above, and remove this many copies of each
6092 factor from OPS. */
6094 {
6102 {
6104 {
6106 {
6112 }
6113 else
6114 {
6117 }
6118 }
6119 }
6120 }
6121 }
6123 /* At this point all elements in the repeated factor vector have a
6124 remaining occurrence count of 0 or 1, and those with a count of 1
6125 don't have cached representatives. Re-sort the ops vector and
6126 clean up. */
6130 /* Return the final product computed herein. Note that there may
6131 still be some elements with single occurrence count left in OPS;
6132 those will be handled by the normal reassociation logic. */
6134 }
6136 /* Attempt to optimize
6137 CST1 * copysign (CST2, y) -> copysign (CST1 * CST2, y) if CST1 > 0, or
6138 CST1 * copysign (CST2, y) -> -copysign (CST1 * CST2, y) if CST1 < 0. */
6140 static void
6142 {
6152 {
6155 {
6158 {
6161 {
6162 CASE_CFN_COPYSIGN:
6163 CASE_CFN_COPYSIGN_FN:
6166 /* The first argument of copysign must be a constant,
6167 otherwise there's nothing to do. */
6169 {
6172 /* If we couldn't fold to a single constant, skip it.
6173 That happens e.g. for inexact multiplication when
6174 -frounding-math. */
6177 /* Instead of adjusting OLD_CALL, let's build a new
6178 call to not leak the LHS and prevent keeping bogus
6179 debug statements. DCE will clean up the old call. */
6182 new_call = gimple_build_call_internal
6184 else
6185 new_call = gimple_build_call
6192 /* We've used the constant, get rid of it. */
6195 /* Handle the CST1 < 0 case by negating the result. */
6197 {
6199 gimple *negate_stmt
6203 }
6204 else
6207 {
6220 }
6222 }
6226 }
6227 }
6228 }
6229 }
6230 }
6232 /* Transform STMT at *GSI into a copy by replacing its rhs with NEW_RHS. */
6234 static void
6236 {
6237 tree rhs1;
6240 {
6243 }
6251 {
6254 }
6255 }
6257 /* Transform STMT at *GSI into a multiply of RHS1 and RHS2. */
6259 static void
6262 {
6264 {
6267 }
6274 {
6277 }
6278 }
6280 /* Reassociate expressions in basic block BB and its post-dominator as
6281 children.
6283 Bubble up return status from maybe_optimize_range_tests. */
6285 static bool
6287 {
6288 gimple_stmt_iterator gsi;
6289 basic_block son;
6299 {
6305 {
6309 /* If this was part of an already processed statement,
6310 we don't need to touch it again. */
6312 {
6313 /* This statement might have become dead because of previous
6314 reassociations. */
6316 {
6319 /* We might end up removing the last stmt above which
6320 places the iterator to the end of the sequence.
6321 Reset it to the last stmt in this case and make sure
6322 we don't do gsi_prev in that case. */
6324 {
6327 }
6328 }
6330 }
6332 /* If this is not a gimple binary expression, there is
6333 nothing for us to do with it. */
6341 /* For non-bit or min/max operations we can't associate
6342 all types. Verify that here. */
6354 {
6359 /* There may be no immediate uses left by the time we
6360 get here because we may have eliminated them all. */
6371 {
6374 }
6377 {
6380 }
6386 {
6389 else
6391 }
6394 {
6400 }
6406 {
6413 {
6416 }
6417 }
6420 /* If the operand vector is now empty, all operands were
6421 consumed by the __builtin_powi optimization. */
6425 {
6428 /* If the stmt that defines operand has to be inserted, insert it
6429 before the use. */
6434 powi_result);
6435 else
6437 }
6438 else
6439 {
6444 /* For binary bit operations, if there are at least 3
6445 operands and the last operand in OPS is a constant,
6446 move it to the front. This helps ensure that we generate
6447 (X & Y) & C rather than (X & C) & Y. The former will
6448 often match a canonical bit test when we get to RTL. */
6456 /* Only rewrite the expression tree to parallel in the
6457 last reassoc pass to avoid useless work back-and-forth
6458 with initial linearization. */
6463 {
6467 width);
6470 }
6471 else
6472 {
6473 /* When there are three operands left, we want
6474 to make sure the ones that get the double
6475 binary op are chosen wisely. */
6481 powi_result != NULL
6484 }
6486 /* If we combined some repeated factors into a
6487 __builtin_powi call, multiply that result by the
6488 reassociated operands. */
6490 {
6498 {
6501 }
6507 }
6508 }
6511 {
6518 tmp);
6522 }
6523 }
6524 }
6525 }
6527 son;
6532 }
6534 /* Add jumps around shifts for range tests turned into bit tests.
6535 For each SSA_NAME VAR we have code like:
6536 VAR = ...; // final stmt of range comparison
6537 // bit test here...;
6538 OTHERVAR = ...; // final stmt of the bit test sequence
6539 RES = VAR | OTHERVAR;
6540 Turn the above into:
6541 VAR = ...;
6542 if (VAR != 0)
6543 goto <l3>;
6544 else
6545 goto <l2>;
6546 <l2>:
6547 // bit test here...;
6548 OTHERVAR = ...;
6549 <l3>:
6550 # RES = PHI<1(l1), OTHERVAR(l2)>; */
6552 static void
6554 {
6555 tree var;
6559 {
6562 use_operand_p use;
6593 else
6604 }
6606 }
6611 /* Dump the operand entry vector OPS to FILE. */
6613 void
6615 {
6620 {
6624 }
6625 }
6627 /* Dump the operand entry vector OPS to STDERR. */
6629 DEBUG_FUNCTION void
6631 {
6633 }
6635 /* Bubble up return status from reassociate_bb. */
6637 static bool
6639 {
6642 }
6644 /* Initialize the reassociation pass. */
6646 static void
6648 {
6653 /* Find the loops, so that we can prevent moving calculations in
6654 them. */
6661 /* Reverse RPO (Reverse Post Order) will give us something where
6662 deeper loops come later. */
6667 /* Give each default definition a distinct rank. This includes
6668 parameters and the static chain. Walk backwards over all
6669 SSA names so that we get proper rank ordering according
6670 to tree_swap_operands_p. */
6672 {
6676 }
6678 /* Set up rank for each BB */
6685 }
6687 /* Cleanup after the reassociation pass, and print stats if
6688 requested. */
6690 static void
6692 {
6712 }
6714 /* Gate and execute functions for Reassociation. If INSERT_POWI_P, enable
6715 insertion of __builtin_powi calls.
6717 Returns TODO_cfg_cleanup if a CFG cleanup pass is desired due to
6718 optimization of a gimple conditional. Otherwise returns zero. */
6720 static unsigned int
6722 {
6734 }
6739 {
6749 };
6752 {
6756 {}
6758 /* opt_pass methods: */
6761 {
6764 }
6770 /* Enable insertion of __builtin_powi calls during execute_reassoc. See
6771 point 3a in the pass header comment. */
6777 gimple_opt_pass *
6779 {
6781 }