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1 /* Global, SSA-based optimizations using mathematical identities.
2 Copyright (C) 2005-2014 Free Software Foundation, Inc.
4 This file is part of GCC.
6 GCC is free software; you can redistribute it and/or modify it
7 under the terms of the GNU General Public License as published by the
8 Free Software Foundation; either version 3, or (at your option) any
9 later version.
11 GCC is distributed in the hope that it will be useful, but WITHOUT
12 ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
13 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
14 for more details.
16 You should have received a copy of the GNU General Public License
17 along with GCC; see the file COPYING3. If not see
18 <http://www.gnu.org/licenses/>. */
20 /* Currently, the only mini-pass in this file tries to CSE reciprocal
21 operations. These are common in sequences such as this one:
23 modulus = sqrt(x*x + y*y + z*z);
24 x = x / modulus;
25 y = y / modulus;
26 z = z / modulus;
28 that can be optimized to
30 modulus = sqrt(x*x + y*y + z*z);
31 rmodulus = 1.0 / modulus;
32 x = x * rmodulus;
33 y = y * rmodulus;
34 z = z * rmodulus;
36 We do this for loop invariant divisors, and with this pass whenever
37 we notice that a division has the same divisor multiple times.
39 Of course, like in PRE, we don't insert a division if a dominator
40 already has one. However, this cannot be done as an extension of
41 PRE for several reasons.
43 First of all, with some experiments it was found out that the
44 transformation is not always useful if there are only two divisions
45 hy the same divisor. This is probably because modern processors
46 can pipeline the divisions; on older, in-order processors it should
47 still be effective to optimize two divisions by the same number.
48 We make this a param, and it shall be called N in the remainder of
49 this comment.
51 Second, if trapping math is active, we have less freedom on where
52 to insert divisions: we can only do so in basic blocks that already
53 contain one. (If divisions don't trap, instead, we can insert
54 divisions elsewhere, which will be in blocks that are common dominators
55 of those that have the division).
57 We really don't want to compute the reciprocal unless a division will
58 be found. To do this, we won't insert the division in a basic block
59 that has less than N divisions *post-dominating* it.
61 The algorithm constructs a subset of the dominator tree, holding the
62 blocks containing the divisions and the common dominators to them,
63 and walk it twice. The first walk is in post-order, and it annotates
64 each block with the number of divisions that post-dominate it: this
65 gives information on where divisions can be inserted profitably.
66 The second walk is in pre-order, and it inserts divisions as explained
67 above, and replaces divisions by multiplications.
69 In the best case, the cost of the pass is O(n_statements). In the
70 worst-case, the cost is due to creating the dominator tree subset,
71 with a cost of O(n_basic_blocks ^ 2); however this can only happen
72 for n_statements / n_basic_blocks statements. So, the amortized cost
73 of creating the dominator tree subset is O(n_basic_blocks) and the
74 worst-case cost of the pass is O(n_statements * n_basic_blocks).
76 More practically, the cost will be small because there are few
77 divisions, and they tend to be in the same basic block, so insert_bb
78 is called very few times.
80 If we did this using domwalk.c, an efficient implementation would have
81 to work on all the variables in a single pass, because we could not
82 work on just a subset of the dominator tree, as we do now, and the
83 cost would also be something like O(n_statements * n_basic_blocks).
84 The data structures would be more complex in order to work on all the
85 variables in a single pass. */
119 /* FIXME: RTL headers have to be included here for optabs. */
124 /* This structure represents one basic block that either computes a
125 division, or is a common dominator for basic block that compute a
126 division. */
128 /* The basic block represented by this structure. */
129 basic_block bb;
131 /* If non-NULL, the SSA_NAME holding the definition for a reciprocal
132 inserted in BB. */
133 tree recip_def;
135 /* If non-NULL, the GIMPLE_ASSIGN for a reciprocal computation that
136 was inserted in BB. */
137 gimple recip_def_stmt;
139 /* Pointer to a list of "struct occurrence"s for blocks dominated
140 by BB. */
143 /* Pointer to the next "struct occurrence"s in the list of blocks
144 sharing a common dominator. */
147 /* The number of divisions that are in BB before compute_merit. The
148 number of divisions that are in BB or post-dominate it after
149 compute_merit. */
152 /* True if the basic block has a division, false if it is a common
153 dominator for basic blocks that do. If it is false and trapping
154 math is active, BB is not a candidate for inserting a reciprocal. */
156 };
158 static struct
159 {
160 /* Number of 1.0/X ops inserted. */
163 /* Number of 1.0/FUNC ops inserted. */
167 static struct
168 {
169 /* Number of cexpi calls inserted. */
173 static struct
174 {
175 /* Number of hand-written 16-bit nop / bswaps found. */
178 /* Number of hand-written 32-bit nop / bswaps found. */
181 /* Number of hand-written 64-bit nop / bswaps found. */
185 static struct
186 {
187 /* Number of widening multiplication ops inserted. */
190 /* Number of integer multiply-and-accumulate ops inserted. */
193 /* Number of fp fused multiply-add ops inserted. */
197 /* The instance of "struct occurrence" representing the highest
198 interesting block in the dominator tree. */
201 /* Allocation pool for getting instances of "struct occurrence". */
206 /* Allocate and return a new struct occurrence for basic block BB, and
207 whose children list is headed by CHILDREN. */
210 {
219 }
222 /* Insert NEW_OCC into our subset of the dominator tree. P_HEAD points to a
223 list of "struct occurrence"s, one per basic block, having IDOM as
224 their common dominator.
226 We try to insert NEW_OCC as deep as possible in the tree, and we also
227 insert any other block that is a common dominator for BB and one
228 block already in the tree. */
230 static void
233 {
237 {
241 {
242 /* BB dominates OCC_BB. OCC becomes NEW_OCC's child: remove OCC
243 from its list. */
248 /* Try the next block (it may as well be dominated by BB). */
249 }
252 {
253 /* OCC_BB dominates BB. Tail recurse to look deeper. */
256 }
259 {
262 /* There is a dominator between IDOM and BB, add it and make
263 two children out of NEW_OCC and OCC. First, remove OCC from
264 its list. */
269 /* None of the previous blocks has DOM as a dominator: if we tail
270 recursed, we would reexamine them uselessly. Just switch BB with
271 DOM, and go on looking for blocks dominated by DOM. */
273 }
275 else
276 {
277 /* Nothing special, go on with the next element. */
279 }
280 }
282 /* No place was found as a child of IDOM. Make BB a sibling of IDOM. */
285 }
287 /* Register that we found a division in BB. */
291 {
296 {
299 }
303 }
306 /* Compute the number of divisions that postdominate each block in OCC and
307 its children. */
309 static void
311 {
316 {
317 basic_block bb;
323 else
328 }
329 }
332 /* Return whether USE_STMT is a floating-point division by DEF. */
335 {
339 /* Do not recognize x / x as valid division, as we are getting
340 confused later by replacing all immediate uses x in such
341 a stmt. */
343 }
345 /* Walk the subset of the dominator tree rooted at OCC, setting the
346 RECIP_DEF field to a definition of 1.0 / DEF that can be used in
347 the given basic block. The field may be left NULL, of course,
348 if it is not possible or profitable to do the optimization.
350 DEF_BSI is an iterator pointing at the statement defining DEF.
351 If RECIP_DEF is set, a dominator already has a computation that can
352 be used. */
354 static void
357 {
358 tree type;
359 gimple new_stmt;
360 gimple_stmt_iterator gsi;
366 {
367 /* Make a variable with the replacement and substitute it. */
374 {
375 /* Case 1: insert before an existing division. */
381 }
383 {
384 /* Case 2: insert right after the definition. Note that this will
385 never happen if the definition statement can throw, because in
386 that case the sole successor of the statement's basic block will
387 dominate all the uses as well. */
389 }
390 else
391 {
392 /* Case 3: insert in a basic block not containing defs/uses. */
395 }
400 }
405 }
408 /* Replace the division at USE_P with a multiplication by the reciprocal, if
409 possible. */
413 {
420 {
426 }
427 }
430 /* Free OCC and return one more "struct occurrence" to be freed. */
434 {
437 /* First get the two pointers hanging off OCC. */
443 /* Now ensure that we don't recurse unless it is necessary. */
446 else
447 {
452 }
453 }
456 /* Look for floating-point divisions among DEF's uses, and try to
457 replace them by multiplications with the reciprocal. Add
458 as many statements computing the reciprocal as needed.
460 DEF must be a GIMPLE register of a floating-point type. */
462 static void
464 {
465 use_operand_p use_p;
466 imm_use_iterator use_iter;
473 {
476 {
478 count++;
479 }
480 }
482 /* Do the expensive part only if we can hope to optimize something. */
485 {
486 gimple use_stmt;
488 {
491 }
494 {
496 {
499 }
500 }
501 }
507 }
509 /* Go through all the floating-point SSA_NAMEs, and call
510 execute_cse_reciprocals_1 on each of them. */
514 {
524 };
527 {
531 {}
533 /* opt_pass methods: */
539 unsigned int
541 {
542 basic_block bb;
543 tree arg;
553 #ifdef ENABLE_CHECKING
556 #endif
561 {
565 }
568 {
569 gimple_stmt_iterator gsi;
570 gimple phi;
571 tree def;
574 {
580 }
583 {
591 }
596 /* Scan for a/func(b) and convert it to reciprocal a*rfunc(b). */
598 {
600 tree fndecl;
604 {
606 gimple stmt1;
618 {
621 imm_use_iterator ui;
622 use_operand_p use_p;
631 /* Check that all uses of the SSA name are divisions,
632 otherwise replacing the defining statement will do
633 the wrong thing. */
636 {
644 {
647 }
648 }
658 {
663 }
664 }
665 }
666 }
667 }
678 }
682 gimple_opt_pass *
684 {
686 }
688 /* Records an occurrence at statement USE_STMT in the vector of trees
689 STMTS if it is dominated by *TOP_BB or dominates it or this basic block
690 is not yet initialized. Returns true if the occurrence was pushed on
691 the vector. Adjusts *TOP_BB to be the basic block dominating all
692 statements in the vector. */
694 static bool
697 {
705 {
708 }
709 else
713 }
715 /* Look for sin, cos and cexpi calls with the same argument NAME and
716 create a single call to cexpi CSEing the result in this case.
717 We first walk over all immediate uses of the argument collecting
718 statements that we can CSE in a vector and in a second pass replace
719 the statement rhs with a REALPART or IMAGPART expression on the
720 result of the cexpi call we insert before the use statement that
721 dominates all other candidates. */
723 static bool
725 {
726 gimple_stmt_iterator gsi;
727 imm_use_iterator use_iter;
738 {
746 {
760 }
761 }
764 {
767 }
769 /* Simply insert cexpi at the beginning of top_bb but not earlier than
770 the name def statement. */
782 {
785 }
786 else
787 {
790 }
793 /* And adjust the recorded old call sites. */
795 {
800 {
815 }
817 /* Replace call with a copy. */
824 }
829 }
831 /* To evaluate powi(x,n), the floating point value x raised to the
832 constant integer exponent n, we use a hybrid algorithm that
833 combines the "window method" with look-up tables. For an
834 introduction to exponentiation algorithms and "addition chains",
835 see section 4.6.3, "Evaluation of Powers" of Donald E. Knuth,
836 "Seminumerical Algorithms", Vol. 2, "The Art of Computer Programming",
837 3rd Edition, 1998, and Daniel M. Gordon, "A Survey of Fast Exponentiation
838 Methods", Journal of Algorithms, Vol. 27, pp. 129-146, 1998. */
840 /* Provide a default value for POWI_MAX_MULTS, the maximum number of
841 multiplications to inline before calling the system library's pow
842 function. powi(x,n) requires at worst 2*bits(n)-2 multiplications,
843 so this default never requires calling pow, powf or powl. */
845 #ifndef POWI_MAX_MULTS
846 #define POWI_MAX_MULTS (2*HOST_BITS_PER_WIDE_INT-2)
847 #endif
849 /* The size of the "optimal power tree" lookup table. All
850 exponents less than this value are simply looked up in the
851 powi_table below. This threshold is also used to size the
852 cache of pseudo registers that hold intermediate results. */
853 #define POWI_TABLE_SIZE 256
855 /* The size, in bits of the window, used in the "window method"
856 exponentiation algorithm. This is equivalent to a radix of
857 (1<<POWI_WINDOW_SIZE) in the corresponding "m-ary method". */
858 #define POWI_WINDOW_SIZE 3
860 /* The following table is an efficient representation of an
861 "optimal power tree". For each value, i, the corresponding
862 value, j, in the table states than an optimal evaluation
863 sequence for calculating pow(x,i) can be found by evaluating
864 pow(x,j)*pow(x,i-j). An optimal power tree for the first
865 100 integers is given in Knuth's "Seminumerical algorithms". */
868 {
901 };
904 /* Return the number of multiplications required to calculate
905 powi(x,n) where n is less than POWI_TABLE_SIZE. This is a
906 subroutine of powi_cost. CACHE is an array indicating
907 which exponents have already been calculated. */
909 static int
911 {
912 /* If we've already calculated this exponent, then this evaluation
913 doesn't require any additional multiplications. */
920 }
922 /* Return the number of multiplications required to calculate
923 powi(x,n) for an arbitrary x, given the exponent N. This
924 function needs to be kept in sync with powi_as_mults below. */
926 static int
928 {
937 /* Ignore the reciprocal when calculating the cost. */
940 /* Initialize the exponent cache. */
947 {
949 {
954 }
955 else
956 {
958 result++;
959 }
960 }
963 }
965 /* Recursive subroutine of powi_as_mults. This function takes the
966 array, CACHE, of already calculated exponents and an exponent N and
967 returns a tree that corresponds to CACHE[1]**N, with type TYPE. */
969 static tree
972 {
975 gimple mult_stmt;
983 {
987 }
989 {
993 }
994 else
995 {
998 }
1005 }
1007 /* Convert ARG0**N to a tree of multiplications of ARG0 with itself.
1008 This function needs to be kept in sync with powi_cost above. */
1010 static tree
1013 {
1015 gimple div_stmt;
1016 tree target;
1028 /* If the original exponent was negative, reciprocate the result. */
1032 result);
1037 }
1039 /* ARG0 and N are the two arguments to a powi builtin in GSI with
1040 location info LOC. If the arguments are appropriate, create an
1041 equivalent sequence of statements prior to GSI using an optimal
1042 number of multiplications, and return an expession holding the
1043 result. */
1045 static tree
1048 {
1049 /* Avoid largest negative number. */
1057 }
1059 /* Build a gimple call statement that calls FN with argument ARG.
1060 Set the lhs of the call statement to a fresh SSA name. Insert the
1061 statement prior to GSI's current position, and return the fresh
1062 SSA name. */
1064 static tree
1067 {
1068 gimple call_stmt;
1069 tree ssa_target;
1078 }
1080 /* Build a gimple binary operation with the given CODE and arguments
1081 ARG0, ARG1, assigning the result to a new SSA name for variable
1082 TARGET. Insert the statement prior to GSI's current position, and
1083 return the fresh SSA name.*/
1085 static tree
1089 {
1095 }
1097 /* Build a gimple reference operation with the given CODE and argument
1098 ARG, assigning the result to a new SSA name of TYPE with NAME.
1099 Insert the statement prior to GSI's current position, and return
1100 the fresh SSA name. */
1105 {
1111 }
1113 /* Build a gimple assignment to cast VAL to TYPE. Insert the statement
1114 prior to GSI's current position, and return the fresh SSA name. */
1116 static tree
1119 {
1125 }
1127 /* ARG0 and ARG1 are the two arguments to a pow builtin call in GSI
1128 with location info LOC. If possible, create an equivalent and
1129 less expensive sequence of statements prior to GSI, and return an
1130 expession holding the result. */
1132 static tree
1135 {
1138 HOST_WIDE_INT n;
1143 /* If the exponent isn't a constant, there's nothing of interest
1144 to be done. */
1148 /* If the exponent is equivalent to an integer, expand to an optimal
1149 multiplication sequence when profitable. */
1157 || (flag_unsafe_math_optimizations
1162 /* Attempt various optimizations using sqrt and cbrt. */
1167 /* Optimize pow(x,0.5) = sqrt(x). This replacement is always safe
1168 unless signed zeros must be maintained. pow(-0,0.5) = +0, while
1169 sqrt(-0) = -0. */
1175 /* Optimize pow(x,0.25) = sqrt(sqrt(x)). Assume on most machines that
1176 a builtin sqrt instruction is smaller than a call to pow with 0.25,
1177 so do this optimization even if -Os. Don't do this optimization
1178 if we don't have a hardware sqrt insn. */
1184 && sqrtfn
1187 {
1188 /* sqrt(x) */
1191 /* sqrt(sqrt(x)) */
1193 }
1195 /* Optimize pow(x,0.75) = sqrt(x) * sqrt(sqrt(x)) unless we are
1196 optimizing for space. Don't do this optimization if we don't have
1197 a hardware sqrt insn. */
1202 && sqrtfn
1206 {
1207 /* sqrt(x) */
1210 /* sqrt(sqrt(x)) */
1213 /* sqrt(x) * sqrt(sqrt(x)) */
1216 }
1218 /* Optimize pow(x,1./3.) = cbrt(x). This requires unsafe math
1219 optimizations since 1./3. is not exactly representable. If x
1220 is negative and finite, the correct value of pow(x,1./3.) is
1221 a NaN with the "invalid" exception raised, because the value
1222 of 1./3. actually has an even denominator. The correct value
1223 of cbrt(x) is a negative real value. */
1228 && cbrtfn
1233 /* Optimize pow(x,1./6.) = cbrt(sqrt(x)). Don't do this optimization
1234 if we don't have a hardware sqrt insn. */
1239 && sqrtfn
1240 && cbrtfn
1243 && hw_sqrt_exists
1245 {
1246 /* sqrt(x) */
1249 /* cbrt(sqrt(x)) */
1251 }
1253 /* Optimize pow(x,c), where n = 2c for some nonzero integer n
1254 and c not an integer, into
1256 sqrt(x) * powi(x, n/2), n > 0;
1257 1.0 / (sqrt(x) * powi(x, abs(n/2))), n < 0.
1259 Do not calculate the powi factor when n/2 = 0. */
1266 && sqrtfn
1267 && c2_is_int
1268 && !c_is_int
1270 {
1273 /* Attempt to fold powi(arg0, abs(n/2)) into multiplies. If not
1274 possible or profitable, give up. Skip the degenerate case when
1275 n is 1 or -1, where the result is always 1. */
1277 {
1282 }
1284 /* Calculate sqrt(x). When n is not 1 or -1, multiply it by the
1285 result of the optimal multiply sequence just calculated. */
1290 else
1294 /* If n is negative, reciprocate the result. */
1299 }
1301 /* Optimize pow(x,c), where 3c = n for some nonzero integer n, into
1303 powi(x, n/3) * powi(cbrt(x), n%3), n > 0;
1304 1.0 / (powi(x, abs(n)/3) * powi(cbrt(x), abs(n)%3)), n < 0.
1306 Do not calculate the first factor when n/3 = 0. As cbrt(x) is
1307 different from pow(x, 1./3.) due to rounding and behavior with
1308 negative x, we need to constrain this transformation to unsafe
1309 math and positive x or finite math. */
1319 && cbrtfn
1322 && !c2_is_int
1325 {
1328 /* Attempt to fold powi(arg0, abs(n/3)) into multiplies. If not
1329 possible or profitable, give up. Skip the degenerate case when
1330 abs(n) < 3, where the result is always 1. */
1332 {
1337 }
1339 /* Calculate powi(cbrt(x), n%3). Don't use gimple_expand_builtin_powi
1340 as that creates an unnecessary variable. Instead, just produce
1341 either cbrt(x) or cbrt(x) * cbrt(x). */
1346 else
1350 /* Multiply the two subexpressions, unless powi(x,abs(n)/3) = 1. */
1353 else
1357 /* If n is negative, reciprocate the result. */
1363 }
1365 /* No optimizations succeeded. */
1367 }
1369 /* ARG is the argument to a cabs builtin call in GSI with location info
1370 LOC. Create a sequence of statements prior to GSI that calculates
1371 sqrt(R*R + I*I), where R and I are the real and imaginary components
1372 of ARG, respectively. Return an expression holding the result. */
1374 static tree
1376 {
1384 || !sqrtfn
1400 }
1402 /* Go through all calls to sin, cos and cexpi and call execute_cse_sincos_1
1403 on the SSA_NAME argument of each of them. Also expand powi(x,n) into
1404 an optimal number of multiplies, when n is a constant. */
1409 {
1419 };
1422 {
1426 {}
1428 /* opt_pass methods: */
1430 {
1431 /* We no longer require either sincos or cexp, since powi expansion
1432 piggybacks on this pass. */
1434 }
1440 unsigned int
1442 {
1443 basic_block bb;
1450 {
1451 gimple_stmt_iterator gsi;
1455 {
1457 tree fndecl;
1459 /* Only the last stmt in a bb could throw, no need to call
1460 gimple_purge_dead_eh_edges if we change something in the middle
1461 of a basic block. */
1468 {
1470 HOST_WIDE_INT n;
1471 location_t loc;
1474 {
1478 /* Make sure we have either sincos or cexp. */
1496 {
1505 }
1514 {
1516 gimple stmt;
1525 arg1,
1533 cond,
1537 }
1538 else
1539 {
1545 }
1548 {
1557 }
1566 {
1575 }
1579 }
1580 }
1581 }
1584 }
1591 }
1595 gimple_opt_pass *
1597 {
1599 }
1601 /* A symbolic number is used to detect byte permutation and selection
1602 patterns. Therefore the field N contains an artificial number
1603 consisting of octet sized markers:
1605 0 - target byte has the value 0
1606 FF - target byte has an unknown value (eg. due to sign extension)
1607 1..size - marker value is the target byte index minus one.
1609 To detect permutations on memory sources (arrays and structures), a symbolic
1610 number is also associated a base address (the array or structure the load is
1611 made from), an offset from the base address and a range which gives the
1612 difference between the highest and lowest accessed memory location to make
1613 such a symbolic number. The range is thus different from size which reflects
1614 the size of the type of current expression. Note that for non memory source,
1615 range holds the same value as size.
1617 For instance, for an array char a[], (short) a[0] | (short) a[3] would have
1618 a size of 2 but a range of 4 while (short) a[0] | ((short) a[0] << 1) would
1619 still have a size of 2 but this time a range of 1. */
1623 tree type;
1624 tree base_addr;
1625 tree offset;
1626 HOST_WIDE_INT bytepos;
1627 tree alias_set;
1628 tree vuse;
1630 };
1632 #define BITS_PER_MARKER 8
1633 #define MARKER_MASK ((1 << BITS_PER_MARKER) - 1)
1634 #define MARKER_BYTE_UNKNOWN MARKER_MASK
1635 #define HEAD_MARKER(n, size) \
1636 ((n) & ((uint64_t) MARKER_MASK << (((size) - 1) * BITS_PER_MARKER)))
1638 /* The number which the find_bswap_or_nop_1 result should match in
1639 order to have a nop. The number is masked according to the size of
1640 the symbolic number before using it. */
1641 #define CMPNOP (sizeof (int64_t) < 8 ? 0 : \
1642 (uint64_t)0x08070605 << 32 | 0x04030201)
1644 /* The number which the find_bswap_or_nop_1 result should match in
1645 order to have a byte swap. The number is masked according to the
1646 size of the symbolic number before using it. */
1647 #define CMPXCHG (sizeof (int64_t) < 8 ? 0 : \
1648 (uint64_t)0x01020304 << 32 | 0x05060708)
1650 /* Perform a SHIFT or ROTATE operation by COUNT bits on symbolic
1651 number N. Return false if the requested operation is not permitted
1652 on a symbolic number. */
1658 {
1666 /* Zero out the extra bits of N in order to avoid them being shifted
1667 into the significant bits. */
1672 {
1679 /* Arithmetic shift of signed type: result is dependent on the value. */
1693 }
1694 /* Zero unused bits for size. */
1698 }
1700 /* Perform sanity checking for the symbolic number N and the gimple
1701 statement STMT. */
1705 {
1706 tree lhs_type;
1717 }
1719 /* Initialize the symbolic number N for the bswap pass from the base element
1720 SRC manipulated by the bitwise OR expression. */
1722 static bool
1724 {
1729 /* Set up the symbolic number N by setting each byte to a value between 1 and
1730 the byte size of rhs1. The highest order byte is set to n->size and the
1731 lowest order byte to 1. */
1746 }
1748 /* Check if STMT might be a byte swap or a nop from a memory source and returns
1749 the answer. If so, REF is that memory source and the base of the memory area
1750 accessed and the offset of the access from that base are recorded in N. */
1752 bool
1754 {
1755 /* Leaf node is an array or component ref. Memorize its base and
1756 offset from base to compare to other such leaf node. */
1769 {
1774 {
1778 }
1782 /* Avoid returning a negative bitpos as this may wreak havoc later. */
1784 {
1787 /* TEM is the bitpos rounded to BITS_PER_UNIT towards -Inf.
1788 Subtract it to BIT_OFFSET and add it (scaled) to OFFSET. */
1794 else
1796 }
1799 }
1816 }
1818 /* find_bswap_or_nop_1 invokes itself recursively with N and tries to perform
1819 the operation given by the rhs of STMT on the result. If the operation
1820 could successfully be executed the function returns a gimple stmt whose
1821 rhs's first tree is the expression of the source operand and NULL
1822 otherwise. */
1824 static gimple
1826 {
1850 /* Handle unary rhs and binary rhs with integer constants as second
1851 operand. */
1856 {
1868 /* If find_bswap_or_nop_1 returned NULL, STMT is a leaf node and
1869 we have to initialize the symbolic number. */
1871 {
1876 }
1879 {
1881 {
1886 /* Only constants masking full bytes are allowed. */
1894 }
1903 CASE_CONVERT:
1904 {
1906 tree type;
1916 /* Sign extension: result is dependent on the value. */
1924 {
1925 /* If STMT casts to a smaller type mask out the bits not
1926 belonging to the target type. */
1928 }
1932 }
1936 };
1938 }
1940 /* Handle binary rhs. */
1943 {
1947 gimple source_stmt2;
1958 {
1979 {
1981 HOST_WIDE_INT off_sub;
1991 /* We swap n1 with n2 to have n1 < n2. */
1993 {
2000 }
2004 /* Check that the range of memory covered can be represented by
2005 a symbolic number. */
2010 /* Reinterpret byte marks in symbolic number holding the value of
2011 bigger weight according to target endianness. */
2016 else
2019 {
2024 }
2025 }
2026 else
2032 else
2042 {
2049 }
2058 }
2060 }
2062 }
2064 /* Check if STMT completes a bswap implementation or a read in a given
2065 endianness consisting of ORs, SHIFTs and ANDs and sets *BSWAP
2066 accordingly. It also sets N to represent the kind of operations
2067 performed: size of the resulting expression and whether it works on
2068 a memory source, and if so alias-set and vuse. At last, the
2069 function returns a stmt whose rhs's first tree is the source
2070 expression. */
2072 static gimple
2074 {
2075 /* The number which the find_bswap_or_nop_1 result should match in order
2076 to have a full byte swap. The number is shifted to the right
2077 according to the size of the symbolic number before using it. */
2081 gimple source_stmt;
2084 /* The last parameter determines the depth search limit. It usually
2085 correlates directly to the number n of bytes to be touched. We
2086 increase that number by log2(n) + 1 here in order to also
2087 cover signed -> unsigned conversions of the src operand as can be seen
2088 in libgcc, and for initial shift/and operation of the src operand. */
2096 /* Find real size of result (highest non zero byte). */
2098 {
2104 }
2106 /* Zero out the extra bits of N and CMP*. */
2108 {
2114 }
2116 /* A complete byte swap should make the symbolic number to start with
2117 the largest digit in the highest order byte. Unchanged symbolic
2118 number indicates a read with same endianness as target architecture. */
2123 else
2126 /* Useless bit manipulation performed by code. */
2132 }
2137 {
2147 };
2150 {
2154 {}
2156 /* opt_pass methods: */
2158 {
2160 }
2166 /* Perform the bswap optimization: replace the statement CUR_STMT at
2167 GSI with a load of type, VUSE and set-alias as described by N if a
2168 memory source is involved (N->base_addr is non null), followed by
2169 the builtin bswap invocation in FNDECL if BSWAP is true. SRC_STMT
2170 gives where should the replacement be made. It also gives the
2171 source on which CUR_STMT is operating via its rhs's first tree nad
2172 N->range gives the size of the expression involved for maintaining
2173 some statistics. */
2175 static bool
2179 {
2181 gimple call;
2186 /* Need to load the value from memory first. */
2188 {
2204 /* Compute address to load from and cast according to the size
2205 of the load. */
2209 else
2210 {
2215 }
2217 /* Perform the load. */
2223 load_offset_ptr);
2226 {
2231 else
2232 {
2235 }
2237 /* Convert the result of load if necessary. */
2239 {
2247 }
2248 else
2249 {
2253 }
2257 {
2262 }
2264 }
2265 else
2266 {
2271 }
2273 }
2279 else
2280 {
2283 }
2287 /* Convert the src expression if necessary. */
2289 {
2290 gimple convert_stmt;
2294 }
2300 /* Convert the result if necessary. */
2302 {
2303 gimple convert_stmt;
2307 }
2312 {
2316 }
2321 }
2323 /* Find manual byte swap implementations as well as load in a given
2324 endianness. Byte swaps are turned into a bswap builtin invokation
2325 while endian loads are converted to bswap builtin invokation or
2326 simple load according to the target endianness. */
2328 unsigned int
2330 {
2331 basic_block bb;
2347 /* Determine the argument type of the builtins. The code later on
2348 assumes that the return and argument type are the same. */
2350 {
2353 }
2356 {
2359 }
2362 {
2365 }
2371 {
2372 gimple_stmt_iterator gsi;
2374 /* We do a reverse scan for bswap patterns to make sure we get the
2375 widest match. As bswap pattern matching doesn't handle
2376 previously inserted smaller bswap replacements as sub-
2377 patterns, the wider variant wouldn't be detected. */
2379 {
2395 {
2399 {
2402 }
2407 {
2410 }
2415 {
2418 }
2422 }
2430 }
2431 }
2447 }
2451 gimple_opt_pass *
2453 {
2455 }
2457 /* Return true if stmt is a type conversion operation that can be stripped
2458 when used in a widening multiply operation. */
2459 static bool
2461 {
2465 {
2466 tree op_type;
2467 tree inner_op_type;
2474 /* If the type of OP has the same precision as the result, then
2475 we can strip this conversion. The multiply operation will be
2476 selected to create the correct extension as a by-product. */
2480 /* We can also strip a conversion if it preserves the signed-ness of
2481 the operation and doesn't narrow the range. */
2484 /* If the inner-most type is unsigned, then we can strip any
2485 intermediate widening operation. If it's signed, then the
2486 intermediate widening operation must also be signed. */
2493 }
2496 }
2498 /* Return true if RHS is a suitable operand for a widening multiplication,
2499 assuming a target type of TYPE.
2500 There are two cases:
2502 - RHS makes some value at least twice as wide. Store that value
2503 in *NEW_RHS_OUT if so, and store its type in *TYPE_OUT.
2505 - RHS is an integer constant. Store that value in *NEW_RHS_OUT if so,
2506 but leave *TYPE_OUT untouched. */
2508 static bool
2511 {
2512 gimple stmt;
2516 {
2519 {
2522 else
2523 {
2527 {
2531 }
2532 }
2533 }
2534 else
2546 }
2549 {
2553 }
2556 }
2558 /* Return true if STMT performs a widening multiplication, assuming the
2559 output type is TYPE. If so, store the unwidened types of the operands
2560 in *TYPE1_OUT and *TYPE2_OUT respectively. Also fill *RHS1_OUT and
2561 *RHS2_OUT such that converting those operands to types *TYPE1_OUT
2562 and *TYPE2_OUT would give the operands of the multiplication. */
2564 static bool
2568 {
2576 rhs1_out))
2580 rhs2_out))
2584 {
2588 }
2591 {
2595 }
2597 /* Ensure that the larger of the two operands comes first. */
2599 {
2600 tree tmp;
2607 }
2610 }
2612 /* Process a single gimple statement STMT, which has a MULT_EXPR as
2613 its rhs, and try to convert it into a WIDEN_MULT_EXPR. The return
2614 value is true iff we converted the statement. */
2616 static bool
2618 {
2622 optab op;
2644 else
2651 {
2653 {
2654 /* We can use a signed multiply with unsigned types as long as
2655 there is a wider mode to use, or it is the smaller of the two
2656 types that is unsigned. Note that type1 >= type2, always. */
2661 {
2665 }
2676 }
2677 else
2679 }
2681 /* Ensure that the inputs to the handler are in the correct precison
2682 for the opcode. This will be the full mode size. */
2689 build_nonstandard_integer_type
2694 build_nonstandard_integer_type
2697 /* Handle constants. */
2709 }
2711 /* Process a single gimple statement STMT, which is found at the
2712 iterator GSI and has a either a PLUS_EXPR or a MINUS_EXPR as its
2713 rhs (given by CODE), and try to convert it into a
2714 WIDEN_MULT_PLUS_EXPR or a WIDEN_MULT_MINUS_EXPR. The return value
2715 is true iff we converted the statement. */
2717 static bool
2720 {
2726 optab this_optab;
2742 else
2749 {
2753 }
2756 {
2760 }
2762 /* Allow for one conversion statement between the multiply
2763 and addition/subtraction statement. If there are more than
2764 one conversions then we assume they would invalidate this
2765 transformation. If that's not the case then they should have
2766 been folded before now. */
2768 {
2772 {
2776 }
2777 else
2779 }
2781 {
2785 {
2789 }
2790 else
2792 }
2794 /* If code is WIDEN_MULT_EXPR then it would seem unnecessary to call
2795 is_widening_mult_p, but we still need the rhs returns.
2797 It might also appear that it would be sufficient to use the existing
2798 operands of the widening multiply, but that would limit the choice of
2799 multiply-and-accumulate instructions.
2801 If the widened-multiplication result has more than one uses, it is
2802 probably wiser not to do the conversion. */
2805 {
2812 }
2814 {
2821 }
2822 else
2831 /* There's no such thing as a mixed sign madd yet, so use a wider mode. */
2833 {
2836 /* We can use a signed multiply with unsigned types as long as
2837 there is a wider mode to use, or it is the smaller of the two
2838 types that is unsigned. Note that type1 >= type2, always. */
2841 || (from_unsigned2
2843 {
2847 }
2852 }
2854 /* If there was a conversion between the multiply and addition
2855 then we need to make sure it fits a multiply-and-accumulate.
2856 The should be a single mode change which does not change the
2857 value. */
2859 {
2860 /* We use the original, unmodified data types for this. */
2867 {
2868 /* Conversion is a truncate. */
2871 }
2873 {
2874 /* Conversion is an extend. Check it's the right sort. */
2878 }
2879 /* else convert is a no-op for our purposes. */
2880 }
2882 /* Verify that the machine can perform a widening multiply
2883 accumulate in this mode/signedness combination, otherwise
2884 this transformation is likely to pessimize code. */
2892 /* Ensure that the inputs to the handler are in the correct precison
2893 for the opcode. This will be the full mode size. */
2898 build_nonstandard_integer_type
2900 mult_rhs1);
2904 build_nonstandard_integer_type
2906 mult_rhs2);
2911 /* Handle constants. */
2918 add_rhs);
2922 }
2924 /* Combine the multiplication at MUL_STMT with operands MULOP1 and MULOP2
2925 with uses in additions and subtractions to form fused multiply-add
2926 operations. Returns true if successful and MUL_STMT should be removed. */
2928 static bool
2930 {
2934 use_operand_p use_p;
2935 imm_use_iterator imm_iter;
2941 /* We don't want to do bitfield reduction ops. */
2947 /* If the target doesn't support it, don't generate it. We assume that
2948 if fma isn't available then fms, fnma or fnms are not either. */
2952 /* If the multiplication has zero uses, it is kept around probably because
2953 of -fnon-call-exceptions. Don't optimize it away in that case,
2954 it is DCE job. */
2958 /* Make sure that the multiplication statement becomes dead after
2959 the transformation, thus that all uses are transformed to FMAs.
2960 This means we assume that an FMA operation has the same cost
2961 as an addition. */
2963 {
2973 /* For now restrict this operations to single basic blocks. In theory
2974 we would want to support sinking the multiplication in
2975 m = a*b;
2976 if ()
2977 ma = m + c;
2978 else
2979 d = m;
2980 to form a fma in the then block and sink the multiplication to the
2981 else block. */
2990 /* A negate on the multiplication leads to FNMA. */
2992 {
2993 ssa_op_iter iter;
2994 use_operand_p usep;
2998 /* Make sure the negate statement becomes dead with this
2999 single transformation. */
3004 /* Make sure the multiplication isn't also used on that stmt. */
3009 /* Re-validate. */
3018 }
3021 {
3029 /* FMA can only be formed from PLUS and MINUS. */
3031 }
3033 /* If the subtrahend (gimple_assign_rhs2 (use_stmt)) is computed
3034 by a MULT_EXPR that we'll visit later, we might be able to
3035 get a more profitable match with fnma.
3036 OTOH, if we don't, a negate / fma pair has likely lower latency
3037 that a mult / subtract pair. */
3042 {
3046 {
3052 }
3053 }
3055 /* We can't handle a * b + a * b. */
3059 /* While it is possible to validate whether or not the exact form
3060 that we've recognized is available in the backend, the assumption
3061 is that the transformation is never a loss. For instance, suppose
3062 the target only has the plain FMA pattern available. Consider
3063 a*b-c -> fma(a,b,-c): we've exchanged MUL+SUB for FMA+NEG, which
3064 is still two operations. Consider -(a*b)-c -> fma(-a,b,-c): we
3065 still have 3 operations, but in the FMA form the two NEGs are
3066 independent and could be run in parallel. */
3067 }
3070 {
3081 {
3091 }
3094 {
3096 /* a * b - c -> a * b + (-c) */
3102 GSI_SAME_STMT);
3103 }
3104 else
3105 {
3107 /* a - b * c -> (-b) * c + a */
3110 }
3117 GSI_SAME_STMT);
3122 addop);
3125 }
3128 }
3130 /* Find integer multiplications where the operands are extended from
3131 smaller types, and replace the MULT_EXPR with a WIDEN_MULT_EXPR
3132 where appropriate. */
3137 {
3147 };
3150 {
3154 {}
3156 /* opt_pass methods: */
3158 {
3160 }
3166 unsigned int
3168 {
3169 basic_block bb;
3175 {
3176 gimple_stmt_iterator gsi;
3179 {
3184 {
3187 {
3193 {
3197 }
3206 }
3207 }
3210 {
3214 {
3216 {
3221 && REAL_VALUES_EQUAL
3223 dconst2)
3227 {
3234 }
3238 }
3239 }
3240 }
3242 }
3243 }
3253 }
3257 gimple_opt_pass *
3259 {
3261 }