| blob | 1e8d7ee44017a4b068be7674e3dc608e39b334cc |
1 /* Statement Analysis and Transformation for Vectorization
2 Copyright (C) 2003, 2004, 2005, 2006, 2007, 2008, 2009, 2010, 2011, 2012
3 Free Software Foundation, Inc.
4 Contributed by Dorit Naishlos <dorit@il.ibm.com>
5 and Ira Rosen <irar@il.ibm.com>
7 This file is part of GCC.
9 GCC is free software; you can redistribute it and/or modify it under
10 the terms of the GNU General Public License as published by the Free
11 Software Foundation; either version 3, or (at your option) any later
12 version.
14 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
15 WARRANTY; without even the implied warranty of MERCHANTABILITY or
16 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
17 for more details.
19 You should have received a copy of the GNU General Public License
20 along with GCC; see the file COPYING3. If not see
21 <http://www.gnu.org/licenses/>. */
42 /* For lang_hooks.types.type_for_mode. */
45 /* Return the vectorized type for the given statement. */
47 tree
49 {
51 }
53 /* Return TRUE iff the given statement is in an inner loop relative to
54 the loop being vectorized. */
55 bool
57 {
69 }
71 /* Record the cost of a statement, either by directly informing the
72 target model or by saving it in a vector for later processing.
73 Return a preliminary estimate of the statement's cost. */
75 unsigned
79 {
81 {
85 misalign);
89 }
90 else
91 {
98 else
103 }
104 }
106 /* Return a variable of type ELEM_TYPE[NELEMS]. */
108 static tree
110 {
113 }
115 /* ARRAY is an array of vectors created by create_vector_array.
116 Return an SSA_NAME for the vector in index N. The reference
117 is part of the vectorization of STMT and the vector is associated
118 with scalar destination SCALAR_DEST. */
120 static tree
123 {
125 gimple new_stmt;
140 }
142 /* ARRAY is an array of vectors created by create_vector_array.
143 Emit code to store SSA_NAME VECT in index N of the array.
144 The store is part of the vectorization of STMT. */
146 static void
149 {
150 tree array_ref;
151 gimple new_stmt;
159 }
161 /* PTR is a pointer to an array of type TYPE. Return a representation
162 of *PTR. The memory reference replaces those in FIRST_DR
163 (and its group). */
165 static tree
167 {
172 /* Arrays have the same alignment as their type. */
175 }
177 /* Utility functions used by vect_mark_stmts_to_be_vectorized. */
179 /* Function vect_mark_relevant.
181 Mark STMT as "relevant for vectorization" and add it to WORKLIST. */
183 static void
187 {
191 gimple pattern_stmt;
197 /* If this stmt is an original stmt in a pattern, we might need to mark its
198 related pattern stmt instead of the original stmt. However, such stmts
199 may have their own uses that are not in any pattern, in such cases the
200 stmt itself should be marked. */
202 {
205 {
206 imm_use_iterator imm_iter;
207 use_operand_p use_p;
208 gimple use_stmt;
209 tree lhs;
215 else
218 /* This use is out of pattern use, if LHS has other uses that are
219 pattern uses, we should mark the stmt itself, and not the pattern
220 stmt. */
223 {
233 {
236 }
237 }
238 }
241 {
242 /* This is the last stmt in a sequence that was detected as a
243 pattern that can potentially be vectorized. Don't mark the stmt
244 as relevant/live because it's not going to be vectorized.
245 Instead mark the pattern-stmt that replaces it. */
251 "last stmt in pattern. don't mark"
258 }
259 }
267 {
272 }
275 }
278 /* Function vect_stmt_relevant_p.
280 Return true if STMT in loop that is represented by LOOP_VINFO is
281 "relevant for vectorization".
283 A stmt is considered "relevant for vectorization" if:
284 - it has uses outside the loop.
285 - it has vdefs (it alters memory).
286 - control stmts in the loop (except for the exit condition).
288 CHECKME: what other side effects would the vectorizer allow? */
290 static bool
293 {
295 ssa_op_iter op_iter;
296 imm_use_iterator imm_iter;
297 use_operand_p use_p;
298 def_operand_p def_p;
303 /* cond stmt other than loop exit cond. */
309 /* changing memory. */
312 {
317 }
319 /* uses outside the loop. */
321 {
323 {
326 {
334 /* We expect all such uses to be in the loop exit phis
335 (because of loop closed form) */
340 }
341 }
342 }
345 }
348 /* Function exist_non_indexing_operands_for_use_p
350 USE is one of the uses attached to STMT. Check if USE is
351 used in STMT for anything other than indexing an array. */
353 static bool
355 {
356 tree operand;
359 /* USE corresponds to some operand in STMT. If there is no data
360 reference in STMT, then any operand that corresponds to USE
361 is not indexing an array. */
365 /* STMT has a data_ref. FORNOW this means that its of one of
366 the following forms:
367 -1- ARRAY_REF = var
368 -2- var = ARRAY_REF
369 (This should have been verified in analyze_data_refs).
371 'var' in the second case corresponds to a def, not a use,
372 so USE cannot correspond to any operands that are not used
373 for array indexing.
375 Therefore, all we need to check is if STMT falls into the
376 first case, and whether var corresponds to USE. */
390 }
393 /*
394 Function process_use.
396 Inputs:
397 - a USE in STMT in a loop represented by LOOP_VINFO
398 - LIVE_P, RELEVANT - enum values to be set in the STMT_VINFO of the stmt
399 that defined USE. This is done by calling mark_relevant and passing it
400 the WORKLIST (to add DEF_STMT to the WORKLIST in case it is relevant).
401 - FORCE is true if exist_non_indexing_operands_for_use_p check shouldn't
402 be performed.
404 Outputs:
405 Generally, LIVE_P and RELEVANT are used to define the liveness and
406 relevance info of the DEF_STMT of this USE:
407 STMT_VINFO_LIVE_P (DEF_STMT_info) <-- live_p
408 STMT_VINFO_RELEVANT (DEF_STMT_info) <-- relevant
409 Exceptions:
410 - case 1: If USE is used only for address computations (e.g. array indexing),
411 which does not need to be directly vectorized, then the liveness/relevance
412 of the respective DEF_STMT is left unchanged.
413 - case 2: If STMT is a reduction phi and DEF_STMT is a reduction stmt, we
414 skip DEF_STMT cause it had already been processed.
415 - case 3: If DEF_STMT and STMT are in different nests, then "relevant" will
416 be modified accordingly.
418 Return true if everything is as expected. Return false otherwise. */
420 static bool
424 {
427 stmt_vec_info dstmt_vinfo;
429 tree def;
430 gimple def_stmt;
433 /* case 1: we are only interested in uses that need to be vectorized. Uses
434 that are used for address computation are not considered relevant. */
439 {
444 }
451 {
455 }
457 /* case 2: A reduction phi (STMT) defined by a reduction stmt (DEF_STMT).
458 DEF_STMT must have already been processed, because this should be the
459 only way that STMT, which is a reduction-phi, was put in the worklist,
460 as there should be no other uses for DEF_STMT in the loop. So we just
461 check that everything is as expected, and we are done. */
469 {
479 }
481 /* case 3a: outer-loop stmt defining an inner-loop stmt:
482 outer-loop-header-bb:
483 d = def_stmt
484 inner-loop:
485 stmt # use (d)
486 outer-loop-tail-bb:
487 ... */
489 {
495 {
516 }
517 }
519 /* case 3b: inner-loop stmt defining an outer-loop stmt:
520 outer-loop-header-bb:
521 ...
522 inner-loop:
523 d = def_stmt
524 outer-loop-tail-bb (or outer-loop-exit-bb in double reduction):
525 stmt # use (d) */
527 {
533 {
550 }
551 }
556 }
559 /* Function vect_mark_stmts_to_be_vectorized.
561 Not all stmts in the loop need to be vectorized. For example:
563 for i...
564 for j...
565 1. T0 = i + j
566 2. T1 = a[T0]
568 3. j = j + 1
570 Stmt 1 and 3 do not need to be vectorized, because loop control and
571 addressing of vectorized data-refs are handled differently.
573 This pass detects such stmts. */
575 bool
577 {
582 gimple_stmt_iterator si;
583 gimple stmt;
585 stmt_vec_info stmt_vinfo;
586 basic_block bb;
587 gimple phi;
598 /* 1. Init worklist. */
600 {
603 {
606 {
609 }
613 }
615 {
618 {
621 }
625 }
626 }
628 /* 2. Process_worklist */
630 {
631 use_operand_p use_p;
632 ssa_op_iter iter;
636 {
639 }
641 /* Examine the USEs of STMT. For each USE, mark the stmt that defines it
642 (DEF_STMT) as relevant/irrelevant and live/dead according to the
643 liveness and relevance properties of STMT. */
648 /* Generally, the liveness and relevance properties of STMT are
649 propagated as is to the DEF_STMTs of its USEs:
650 live_p <-- STMT_VINFO_LIVE_P (STMT_VINFO)
651 relevant <-- STMT_VINFO_RELEVANT (STMT_VINFO)
653 One exception is when STMT has been identified as defining a reduction
654 variable; in this case we set the liveness/relevance as follows:
655 live_p = false
656 relevant = vect_used_by_reduction
657 This is because we distinguish between two kinds of relevant stmts -
658 those that are used by a reduction computation, and those that are
659 (also) used by a regular computation. This allows us later on to
660 identify stmts that are used solely by a reduction, and therefore the
661 order of the results that they produce does not have to be kept. */
666 {
669 {
677 /* fall through */
685 }
694 {
701 }
709 {
716 }
723 }
726 {
727 /* Pattern statements are not inserted into the code, so
728 FOR_EACH_PHI_OR_STMT_USE optimizes their operands out, and we
729 have to scan the RHS or function arguments instead. */
731 {
737 {
742 {
745 }
747 }
749 {
753 {
756 }
757 }
758 }
760 {
762 {
766 {
769 }
770 }
771 }
772 }
773 else
775 {
779 {
782 }
783 }
786 {
787 tree off;
792 {
795 }
796 }
801 }
804 /* Function vect_model_simple_cost.
806 Models cost for simple operations, i.e. those that only emit ncopies of a
807 single op. Right now, this does not account for multiple insns that could
808 be generated for the single vector op. We will handle that shortly. */
810 void
815 {
819 /* The SLP costs were already calculated during SLP tree build. */
823 /* FORNOW: Assuming maximum 2 args per stmts. */
829 /* Pass the inside-of-loop statements to the target-specific cost model. */
835 "vect_model_simple_cost: inside_cost = %d, "
837 }
840 /* Model cost for type demotion and promotion operations. PWR is normally
841 zero for single-step promotions and demotions. It will be one if
842 two-step promotion/demotion is required, and so on. Each additional
843 step doubles the number of instructions required. */
845 static void
848 {
855 /* The SLP costs were already calculated during SLP tree build. */
861 else
865 {
870 vect_body);
871 }
873 /* FORNOW: Assuming maximum 2 args per stmts. */
881 "vect_model_promotion_demotion_cost: inside_cost = %d, "
883 }
885 /* Function vect_cost_group_size
887 For grouped load or store, return the group_size only if it is the first
888 load or store of a group, else return 1. This ensures that group size is
889 only returned once per group. */
891 static int
893 {
900 }
903 /* Function vect_model_store_cost
905 Models cost for stores. In the case of grouped accesses, one access
906 has the overhead of the grouped access attributed to it. */
908 void
911 slp_tree slp_node,
914 {
918 gimple first_stmt;
920 /* The SLP costs were already calculated during SLP tree build. */
928 /* Grouped access? */
930 {
932 {
935 }
936 else
937 {
940 }
943 }
944 /* Not a grouped access. */
945 else
946 {
949 }
951 /* We assume that the cost of a single store-lanes instruction is
952 equivalent to the cost of GROUP_SIZE separate stores. If a grouped
953 access is instead being provided by a permute-and-store operation,
954 include the cost of the permutes. */
956 {
957 /* Uses a high and low interleave operation for each needed permute. */
966 group_size);
967 }
969 /* Costs of the stores. */
974 "vect_model_store_cost: inside_cost = %d, "
976 }
979 /* Calculate cost of DR's memory access. */
980 void
984 {
990 {
992 {
995 vect_body);
1001 }
1004 {
1005 /* Here, we assign an additional cost for the unaligned store. */
1011 "vect_model_store_cost: unaligned supported by "
1014 }
1017 {
1024 }
1028 }
1029 }
1032 /* Function vect_model_load_cost
1034 Models cost for loads. In the case of grouped accesses, the last access
1035 has the overhead of the grouped access attributed to it. Since unaligned
1036 accesses are supported for loads, we also account for the costs of the
1037 access scheme chosen. */
1039 void
1044 {
1046 gimple first_stmt;
1050 /* The SLP costs were already calculated during SLP tree build. */
1054 /* Grouped accesses? */
1057 {
1060 }
1061 /* Not a grouped access. */
1062 else
1063 {
1066 }
1068 /* We assume that the cost of a single load-lanes instruction is
1069 equivalent to the cost of GROUP_SIZE separate loads. If a grouped
1070 access is instead being provided by a load-and-permute operation,
1071 include the cost of the permutes. */
1073 {
1074 /* Uses an even and odd extract operations for each needed permute. */
1082 group_size);
1083 }
1085 /* The loads themselves. */
1087 {
1088 /* N scalar loads plus gathering them into a vector. */
1095 }
1096 else
1105 "vect_model_load_cost: inside_cost = %d, "
1107 }
1110 /* Calculate cost of DR's memory access. */
1111 void
1118 {
1124 {
1126 {
1135 }
1137 {
1138 /* Here, we assign an additional cost for the unaligned load. */
1145 "vect_model_load_cost: unaligned supported by "
1149 }
1151 {
1157 /* FIXME: If the misalignment remains fixed across the iterations of
1158 the containing loop, the following cost should be added to the
1159 prologue costs. */
1169 }
1171 {
1174 "vect_model_load_cost: unaligned software "
1177 /* Unaligned software pipeline has a load of an address, an initial
1178 load, and possibly a mask operation to "prime" the loop. However,
1179 if this is an access in a group of loads, which provide grouped
1180 access, then the above cost should only be considered for one
1181 access in the group. Inside the loop, there is a load op
1182 and a realignment op. */
1185 {
1193 }
1205 }
1208 {
1215 }
1219 }
1220 }
1222 /* Insert the new stmt NEW_STMT at *GSI or at the appropriate place in
1223 the loop preheader for the vectorized stmt STMT. */
1225 static void
1227 {
1230 else
1231 {
1236 {
1238 basic_block new_bb;
1239 edge pe;
1247 }
1248 else
1249 {
1251 basic_block bb;
1252 gimple_stmt_iterator gsi_bb_start;
1258 }
1259 }
1262 {
1266 }
1267 }
1269 /* Function vect_init_vector.
1271 Insert a new stmt (INIT_STMT) that initializes a new variable of type
1272 TYPE with the value VAL. If TYPE is a vector type and VAL does not have
1273 vector type a vector with all elements equal to VAL is created first.
1274 Place the initialization at BSI if it is not NULL. Otherwise, place the
1275 initialization at the loop preheader.
1276 Return the DEF of INIT_STMT.
1277 It will be used in the vectorization of STMT. */
1279 tree
1281 {
1282 tree new_var;
1283 gimple init_stmt;
1284 tree vec_oprnd;
1285 tree new_temp;
1289 {
1291 {
1294 else
1295 {
1299 NULL_TREE);
1302 }
1303 }
1305 }
1314 }
1317 /* Function vect_get_vec_def_for_operand.
1319 OP is an operand in STMT. This function returns a (vector) def that will be
1320 used in the vectorized stmt for STMT.
1322 In the case that OP is an SSA_NAME which is defined in the loop, then
1323 STMT_VINFO_VEC_STMT of the defining stmt holds the relevant def.
1325 In case OP is an invariant or constant, a new stmt that creates a vector def
1326 needs to be introduced. */
1328 tree
1330 {
1331 tree vec_oprnd;
1332 gimple vec_stmt;
1333 gimple def_stmt;
1338 tree def;
1341 tree vector_type;
1344 {
1348 }
1354 {
1357 {
1361 }
1363 {
1366 else
1369 }
1370 }
1373 {
1374 /* Case 1: operand is a constant. */
1376 {
1384 /* Create 'vect_cst_ = {cst,cst,...,cst}' */
1390 }
1392 /* Case 2: operand is defined outside the loop - loop invariant. */
1394 {
1401 /* Create 'vec_inv = {inv,inv,..,inv}' */
1406 }
1408 /* Case 3: operand is defined inside the loop. */
1410 {
1414 /* Get the def from the vectorized stmt. */
1418 /* Get vectorized pattern statement. */
1429 else
1432 }
1434 /* Case 4: operand is defined by a loop header phi - reduction */
1438 {
1444 /* Get the def before the loop */
1447 }
1449 /* Case 5: operand is defined by loop-header phi - induction. */
1451 {
1454 /* Get the def from the vectorized stmt. */
1459 else
1462 }
1466 }
1467 }
1470 /* Function vect_get_vec_def_for_stmt_copy
1472 Return a vector-def for an operand. This function is used when the
1473 vectorized stmt to be created (by the caller to this function) is a "copy"
1474 created in case the vectorized result cannot fit in one vector, and several
1475 copies of the vector-stmt are required. In this case the vector-def is
1476 retrieved from the vector stmt recorded in the STMT_VINFO_RELATED_STMT field
1477 of the stmt that defines VEC_OPRND.
1478 DT is the type of the vector def VEC_OPRND.
1480 Context:
1481 In case the vectorization factor (VF) is bigger than the number
1482 of elements that can fit in a vectype (nunits), we have to generate
1483 more than one vector stmt to vectorize the scalar stmt. This situation
1484 arises when there are multiple data-types operated upon in the loop; the
1485 smallest data-type determines the VF, and as a result, when vectorizing
1486 stmts operating on wider types we need to create 'VF/nunits' "copies" of the
1487 vector stmt (each computing a vector of 'nunits' results, and together
1488 computing 'VF' results in each iteration). This function is called when
1489 vectorizing such a stmt (e.g. vectorizing S2 in the illustration below, in
1490 which VF=16 and nunits=4, so the number of copies required is 4):
1492 scalar stmt: vectorized into: STMT_VINFO_RELATED_STMT
1494 S1: x = load VS1.0: vx.0 = memref0 VS1.1
1495 VS1.1: vx.1 = memref1 VS1.2
1496 VS1.2: vx.2 = memref2 VS1.3
1497 VS1.3: vx.3 = memref3
1499 S2: z = x + ... VSnew.0: vz0 = vx.0 + ... VSnew.1
1500 VSnew.1: vz1 = vx.1 + ... VSnew.2
1501 VSnew.2: vz2 = vx.2 + ... VSnew.3
1502 VSnew.3: vz3 = vx.3 + ...
1504 The vectorization of S1 is explained in vectorizable_load.
1505 The vectorization of S2:
1506 To create the first vector-stmt out of the 4 copies - VSnew.0 -
1507 the function 'vect_get_vec_def_for_operand' is called to
1508 get the relevant vector-def for each operand of S2. For operand x it
1509 returns the vector-def 'vx.0'.
1511 To create the remaining copies of the vector-stmt (VSnew.j), this
1512 function is called to get the relevant vector-def for each operand. It is
1513 obtained from the respective VS1.j stmt, which is recorded in the
1514 STMT_VINFO_RELATED_STMT field of the stmt that defines VEC_OPRND.
1516 For example, to obtain the vector-def 'vx.1' in order to create the
1517 vector stmt 'VSnew.1', this function is called with VEC_OPRND='vx.0'.
1518 Given 'vx0' we obtain the stmt that defines it ('VS1.0'); from the
1519 STMT_VINFO_RELATED_STMT field of 'VS1.0' we obtain the next copy - 'VS1.1',
1520 and return its def ('vx.1').
1521 Overall, to create the above sequence this function will be called 3 times:
1522 vx.1 = vect_get_vec_def_for_stmt_copy (dt, vx.0);
1523 vx.2 = vect_get_vec_def_for_stmt_copy (dt, vx.1);
1524 vx.3 = vect_get_vec_def_for_stmt_copy (dt, vx.2); */
1526 tree
1528 {
1529 gimple vec_stmt_for_operand;
1530 stmt_vec_info def_stmt_info;
1532 /* Do nothing; can reuse same def. */
1544 else
1547 }
1550 /* Get vectorized definitions for the operands to create a copy of an original
1551 stmt. See vect_get_vec_def_for_stmt_copy () for details. */
1553 static void
1557 {
1564 {
1568 }
1569 }
1572 /* Get vectorized definitions for OP0 and OP1.
1573 REDUC_INDEX is the index of reduction operand in case of reduction,
1574 and -1 otherwise. */
1576 void
1581 {
1583 {
1602 }
1603 else
1604 {
1605 tree vec_oprnd;
1612 {
1616 }
1617 }
1618 }
1621 /* Function vect_finish_stmt_generation.
1623 Insert a new stmt. */
1625 void
1628 {
1637 {
1641 {
1644 /* If we have an SSA vuse and insert a store, update virtual
1645 SSA form to avoid triggering the renamer. Do so only
1646 if we can easily see all uses - which is what almost always
1647 happens with the way vectorized stmts are inserted. */
1654 {
1658 }
1659 }
1660 }
1664 bb_vinfo));
1667 {
1670 }
1673 }
1675 /* Checks if CALL can be vectorized in type VECTYPE. Returns
1676 a function declaration if the target has a vectorized version
1677 of the function, or NULL_TREE if the function cannot be vectorized. */
1679 tree
1681 {
1684 /* We only handle functions that do not read or clobber memory -- i.e.
1685 const or novops ones. */
1695 vectype_in);
1696 }
1698 /* Function vectorizable_call.
1700 Check if STMT performs a function call that can be vectorized.
1701 If VEC_STMT is also passed, vectorize the STMT: create a vectorized
1702 stmt to replace it, put it in VEC_STMT, and insert it at BSI.
1703 Return FALSE if not a vectorizable STMT, TRUE otherwise. */
1705 static bool
1707 slp_tree slp_node)
1708 {
1709 tree vec_dest;
1710 tree scalar_dest;
1720 gimple def_stmt;
1728 tree lhs;
1736 /* Is STMT a vectorizable call? */
1748 /* Process function arguments. */
1753 /* Bail out if the function has more than three arguments, we do not have
1754 interesting builtin functions to vectorize with more than two arguments
1755 except for fma. No arguments is also not good. */
1760 {
1761 tree opvectype;
1765 /* We can only handle calls with arguments of the same type. */
1768 {
1773 }
1779 {
1784 }
1790 {
1795 }
1796 }
1797 /* If all arguments are external or constant defs use a vector type with
1798 the same size as the output vector type. */
1804 {
1806 {
1810 }
1813 }
1815 /* FORNOW */
1824 else
1827 /* For now, we only vectorize functions if a target specific builtin
1828 is available. TODO -- in some cases, it might be profitable to
1829 insert the calls for pieces of the vector, in order to be able
1830 to vectorize other operations in the loop. */
1833 {
1839 }
1847 else
1850 /* Sanity check: make sure that at least one copy of the vectorized stmt
1851 needs to be generated. */
1855 {
1861 }
1863 /** Transform. **/
1868 /* Handle def. */
1874 {
1877 {
1878 /* Build argument list for the vectorized call. */
1881 else
1885 {
1895 /* Arguments are ready. Create the new vector stmt. */
1897 {
1900 {
1903 }
1909 }
1912 {
1915 }
1918 }
1921 {
1924 vec_oprnd0
1926 else
1927 {
1929 vec_oprnd0
1931 }
1934 }
1943 else
1947 }
1953 {
1954 /* Build argument list for the vectorized call. */
1957 else
1961 {
1971 /* Arguments are ready. Create the new vector stmt. */
1973 {
1977 {
1981 }
1987 }
1990 {
1993 }
1996 }
1999 {
2002 {
2003 vec_oprnd0
2005 vec_oprnd1
2007 }
2008 else
2009 {
2011 vec_oprnd0
2013 vec_oprnd1
2015 }
2019 }
2028 else
2032 }
2039 /* No current target implements this case. */
2041 }
2045 /* Update the exception handling table with the vector stmt if necessary. */
2049 /* The call in STMT might prevent it from being removed in dce.
2050 We however cannot remove it here, due to the way the ssa name
2051 it defines is mapped to the new definition. So just replace
2052 rhs of the statement with something harmless. */
2060 else
2070 }
2073 /* Function vect_gen_widened_results_half
2075 Create a vector stmt whose code, type, number of arguments, and result
2076 variable are CODE, OP_TYPE, and VEC_DEST, and its arguments are
2077 VEC_OPRND0 and VEC_OPRND1. The new vector stmt is to be inserted at BSI.
2078 In the case that CODE is a CALL_EXPR, this means that a call to DECL
2079 needs to be created (DECL is a function-decl of a target-builtin).
2080 STMT is the original scalar stmt that we are vectorizing. */
2082 static gimple
2084 tree decl,
2087 gimple stmt)
2088 {
2089 gimple new_stmt;
2090 tree new_temp;
2092 /* Generate half of the widened result: */
2094 {
2095 /* Target specific support */
2098 else
2102 }
2103 else
2104 {
2105 /* Generic support */
2110 vec_oprnd1);
2113 }
2117 }
2120 /* Get vectorized definitions for loop-based vectorization. For the first
2121 operand we call vect_get_vec_def_for_operand() (with OPRND containing
2122 scalar operand), and for the rest we get a copy with
2123 vect_get_vec_def_for_stmt_copy() using the previous vector definition
2124 (stored in OPRND). See vect_get_vec_def_for_stmt_copy() for details.
2125 The vectors are collected into VEC_OPRNDS. */
2127 static void
2130 {
2131 tree vec_oprnd;
2133 /* Get first vector operand. */
2134 /* All the vector operands except the very first one (that is scalar oprnd)
2135 are stmt copies. */
2138 else
2143 /* Get second vector operand. */
2149 /* For conversion in multiple steps, continue to get operands
2150 recursively. */
2153 }
2156 /* Create vectorized demotion statements for vector operands from VEC_OPRNDS.
2157 For multi-step conversions store the resulting vectors and call the function
2158 recursively. */
2160 static void
2167 {
2170 gimple new_stmt;
2176 {
2177 /* Create demotion operation. */
2186 /* Store the resulting vector for next recursive call. */
2188 else
2189 {
2190 /* This is the last step of the conversion sequence. Store the
2191 vectors in SLP_NODE or in vector info of the scalar statement
2192 (or in STMT_VINFO_RELATED_STMT chain). */
2195 else
2196 {
2199 else
2203 }
2204 }
2205 }
2207 /* For multi-step demotion operations we first generate demotion operations
2208 from the source type to the intermediate types, and then combine the
2209 results (stored in VEC_OPRNDS) in demotion operation to the destination
2210 type. */
2212 {
2213 /* At each level of recursion we have half of the operands we had at the
2214 previous level. */
2218 VEC_PACK_TRUNC_EXPR,
2219 prev_stmt_info);
2220 }
2223 }
2226 /* Create vectorized promotion statements for vector operands from VEC_OPRNDS0
2227 and VEC_OPRNDS1 (for binary operations). For multi-step conversions store
2228 the resulting vectors and call the function recursively. */
2230 static void
2238 {
2246 {
2249 else
2252 /* Generate the two halves of promotion operation. */
2258 {
2261 }
2262 else
2263 {
2266 }
2268 /* Store the results for the next step. */
2271 }
2275 }
2278 /* Check if STMT performs a conversion operation, that can be vectorized.
2279 If VEC_STMT is also passed, vectorize the STMT: create a vectorized
2280 stmt to replace it, put it in VEC_STMT, and insert it at GSI.
2281 Return FALSE if not a vectorizable STMT, TRUE otherwise. */
2283 static bool
2286 {
2287 tree vec_dest;
2288 tree scalar_dest;
2296 tree new_temp;
2297 tree def;
2298 gimple def_stmt;
2301 stmt_vec_info prev_stmt_info;
2310 tree vop0;
2320 /* Is STMT a vectorizable conversion? */
2344 /* Check types of lhs and rhs. */
2365 {
2370 }
2372 /* Check the operands of the operation. */
2375 {
2380 }
2382 {
2387 /* For WIDEN_MULT_EXPR, if OP0 is a constant, use the type of
2388 OP1. */
2392 else
2397 {
2402 }
2403 }
2405 /* If op0 is an external or constant defs use a vector type of
2406 the same size as the output vector type. */
2412 {
2414 {
2418 }
2421 }
2429 else
2432 /* Multiple types in SLP are handled by creating the appropriate number of
2433 vectorized stmts for each SLP node. Hence, NCOPIES is always 1 in
2434 case of SLP. */
2439 else
2442 /* Sanity check: make sure that at least one copy of the vectorized stmt
2443 needs to be generated. */
2446 /* Supportable by target? */
2448 {
2455 /* FALLTHRU */
2456 unsupported:
2466 {
2467 /* Binary widening operation can only be supported directly by the
2468 architecture. */
2471 }
2483 {
2484 cvt_type
2491 {
2495 }
2501 else
2508 }
2515 else
2516 {
2517 multi_step_cvt++;
2520 }
2536 cvt_type
2552 }
2555 {
2560 {
2563 }
2565 {
2568 }
2569 else
2570 {
2573 }
2576 }
2578 /** Transform. **/
2584 {
2589 }
2591 /* In case of multi-step conversion, we first generate conversion operations
2592 to the intermediate types, and then from that types to the final one.
2593 We create vector destinations for the intermediate type (TYPES) received
2594 from supportable_*_operation, and store them in the correct order
2595 for future use in vect_create_vectorized_*_stmts (). */
2603 {
2606 {
2608 intermediate_type);
2610 }
2611 }
2615 modifier == WIDEN
2619 {
2623 {
2627 }
2628 else
2631 }
2638 {
2641 {
2645 else
2649 {
2650 /* Arguments are ready, create the new vector stmt. */
2652 {
2656 }
2657 else
2658 {
2664 }
2669 }
2673 else
2676 }
2680 /* In case the vectorization factor (VF) is bigger than the number
2681 of elements that we can fit in a vectype (nunits), we have to
2682 generate more than one vector stmt - i.e - we need to "unroll"
2683 the vector stmt by a factor VF/nunits. */
2685 {
2686 /* Handle uses. */
2688 {
2690 {
2692 {
2696 /* Store vec_oprnd1 for every vector stmt to be created
2697 for SLP_NODE. We check during the analysis that all
2698 the shift arguments are the same. */
2704 }
2705 else
2708 }
2709 else
2710 {
2714 {
2717 else
2719 NULL);
2721 }
2722 }
2723 }
2724 else
2725 {
2730 {
2733 else
2735 vec_oprnd1);
2738 }
2739 }
2741 /* Arguments are ready. Create the new vector stmts. */
2743 {
2747 {
2750 }
2755 op_type);
2756 }
2759 {
2761 {
2763 {
2767 }
2768 else
2769 {
2773 new_temp,
2775 }
2778 }
2779 else
2784 else
2785 {
2788 else
2791 }
2792 }
2793 }
2799 /* In case the vectorization factor (VF) is bigger than the number
2800 of elements that we can fit in a vectype (nunits), we have to
2801 generate more than one vector stmt - i.e - we need to "unroll"
2802 the vector stmt by a factor VF/nunits. */
2804 {
2805 /* Handle uses. */
2809 else
2810 {
2814 }
2816 /* Arguments are ready. Create the new vector stmts. */
2819 {
2821 {
2825 }
2826 else
2827 {
2832 }
2836 }
2842 }
2846 }
2854 }
2857 /* Function vectorizable_assignment.
2859 Check if STMT performs an assignment (copy) that can be vectorized.
2860 If VEC_STMT is also passed, vectorize the STMT: create a vectorized
2861 stmt to replace it, put it in VEC_STMT, and insert it at BSI.
2862 Return FALSE if not a vectorizable STMT, TRUE otherwise. */
2864 static bool
2867 {
2868 tree vec_dest;
2869 tree scalar_dest;
2870 tree op;
2874 tree new_temp;
2875 tree def;
2876 gimple def_stmt;
2882 tree vop;
2887 tree vectype_in;
2889 /* Multiple types in SLP are handled by creating the appropriate number of
2890 vectorized stmts for each SLP node. Hence, NCOPIES is always 1 in
2891 case of SLP. */
2894 else
2905 /* Is vectorizable assignment? */
2918 else
2926 {
2931 }
2933 /* We can handle NOP_EXPR conversions that do not change the number
2934 of elements or the vector size. */
2937 && (!vectype_in
2943 /* We do not handle bit-precision changes. */
2951 /* But a conversion that does not change the bit-pattern is ok. */
2955 {
2958 "type conversion to/from bit-precision "
2961 }
2964 {
2971 }
2973 /** Transform. **/
2977 /* Handle def. */
2980 /* Handle use. */
2982 {
2983 /* Handle uses. */
2986 else
2989 /* Arguments are ready. create the new vector stmt. */
2991 {
3001 }
3008 else
3012 }
3016 }
3019 /* Return TRUE if CODE (a shift operation) is supported for SCALAR_TYPE
3020 either as shift by a scalar or by a vector. */
3022 bool
3024 {
3027 optab optab;
3029 tree vectype;
3038 {
3044 }
3052 }
3055 /* Function vectorizable_shift.
3057 Check if STMT performs a shift operation that can be vectorized.
3058 If VEC_STMT is also passed, vectorize the STMT: create a vectorized
3059 stmt to replace it, put it in VEC_STMT, and insert it at BSI.
3060 Return FALSE if not a vectorizable STMT, TRUE otherwise. */
3062 static bool
3065 {
3066 tree vec_dest;
3067 tree scalar_dest;
3071 tree vectype;
3075 tree new_temp;
3076 optab optab;
3079 tree def;
3080 gimple def_stmt;
3083 stmt_vec_info prev_stmt_info;
3086 tree vectype_out;
3087 tree op1_vectype;
3104 /* Is STMT a vectorizable binary/unary operation? */
3121 {
3126 }
3131 {
3136 }
3137 /* If op0 is an external or constant def use a vector type with
3138 the same size as the output vector type. */
3144 {
3149 }
3159 {
3164 }
3168 else
3171 /* Multiple types in SLP are handled by creating the appropriate number of
3172 vectorized stmts for each SLP node. Hence, NCOPIES is always 1 in
3173 case of SLP. */
3176 else
3181 /* Determine whether the shift amount is a vector, or scalar. If the
3182 shift/rotate amount is a vector, use the vector/vector shift optabs. */
3189 {
3190 /* In SLP, need to check whether the shift count is the same,
3191 in loops if it is a constant or invariant, it is always
3192 a scalar shift. */
3194 {
3196 gimple slpstmt;
3201 }
3202 }
3203 else
3204 {
3209 }
3211 /* Vector shifted by vector. */
3213 {
3223 {
3226 "unusable type for last operand in"
3229 }
3230 }
3231 /* See if the machine has a vector shifted by scalar insn and if not
3232 then see if it has a vector shifted by vector insn. */
3233 else
3234 {
3238 {
3242 }
3243 else
3244 {
3249 {
3256 /* Unlike the other binary operators, shifts/rotates have
3257 the rhs being int, instead of the same type as the lhs,
3258 so make sure the scalar is the right type if we are
3259 dealing with vectors of long long/long/short/char. */
3264 {
3268 {
3271 "unusable type for last operand in"
3274 }
3276 {
3280 }
3281 }
3282 }
3283 }
3284 }
3286 /* Supportable by target? */
3288 {
3293 }
3297 {
3301 /* Check only during analysis. */
3308 }
3310 /* Worthwhile without SIMD support? Check only during analysis. */
3314 {
3319 }
3322 {
3328 }
3330 /** Transform. **/
3336 /* Handle def. */
3339 /* Allocate VECs for vector operands. In case of SLP, vector operands are
3340 created in the previous stages of the recursion, so no allocation is
3341 needed, except for the case of shift with scalar shift argument. In that
3342 case we store the scalar operand in VEC_OPRNDS1 for every vector stmt to
3343 be created to vectorize the SLP group, i.e., SLP_NODE->VEC_STMTS_SIZE.
3344 In case of loop-based vectorization we allocate VECs of size 1. We
3345 allocate VEC_OPRNDS1 only in case of binary operation. */
3347 {
3350 }
3356 {
3357 /* Handle uses. */
3359 {
3361 {
3362 /* Vector shl and shr insn patterns can be defined with scalar
3363 operand 2 (shift operand). In this case, use constant or loop
3364 invariant op1 directly, without extending it to vector mode
3365 first. */
3368 {
3375 {
3376 /* Store vec_oprnd1 for every vector stmt to be created
3377 for SLP_NODE. We check during the analysis that all
3378 the shift arguments are the same.
3379 TODO: Allow different constants for different vector
3380 stmts generated for an SLP instance. */
3383 }
3384 }
3385 }
3387 /* vec_oprnd1 is available if operand 1 should be of a scalar-type
3388 (a special case for certain kind of vector shifts); otherwise,
3389 operand 1 should be of a vector type (the usual case). */
3393 else
3396 }
3397 else
3400 /* Arguments are ready. Create the new vector stmt. */
3402 {
3410 }
3417 else
3420 }
3426 }
3430 gimple_stmt_iterator *);
3433 /* Function vectorizable_operation.
3435 Check if STMT performs a binary, unary or ternary operation that can
3436 be vectorized.
3437 If VEC_STMT is also passed, vectorize the STMT: create a vectorized
3438 stmt to replace it, put it in VEC_STMT, and insert it at BSI.
3439 Return FALSE if not a vectorizable STMT, TRUE otherwise. */
3441 static bool
3444 {
3445 tree vec_dest;
3446 tree scalar_dest;
3449 tree vectype;
3453 tree new_temp;
3455 optab optab;
3457 tree def;
3458 gimple def_stmt;
3462 stmt_vec_info prev_stmt_info;
3465 tree vectype_out;
3481 /* Is STMT a vectorizable binary/unary operation? */
3490 /* For pointer addition, we should use the normal plus for
3491 the vector addition. */
3495 /* Support only unary or binary operations. */
3498 {
3502 op_type);
3504 }
3509 /* Most operations cannot handle bit-precision types without extra
3510 truncations. */
3513 /* Exception are bitwise binary operations. */
3517 {
3522 }
3527 {
3532 }
3533 /* If op0 is an external or constant def use a vector type with
3534 the same size as the output vector type. */
3540 {
3542 {
3547 }
3550 }
3558 {
3562 {
3567 }
3568 }
3570 {
3574 {
3579 }
3580 }
3584 else
3587 /* Multiple types in SLP are handled by creating the appropriate number of
3588 vectorized stmts for each SLP node. Hence, NCOPIES is always 1 in
3589 case of SLP. */
3592 else
3597 /* Shifts are handled in vectorizable_shift (). */
3602 /* Supportable by target? */
3606 {
3609 else
3611 }
3612 else
3613 {
3616 {
3621 }
3623 }
3626 {
3630 /* Check only during analysis. */
3636 }
3638 /* Worthwhile without SIMD support? Check only during analysis. */
3640 && !vec_stmt
3642 {
3647 }
3650 {
3657 }
3659 /** Transform. **/
3665 /* Handle def. */
3668 /* In case the vectorization factor (VF) is bigger than the number
3669 of elements that we can fit in a vectype (nunits), we have to generate
3670 more than one vector stmt - i.e - we need to "unroll" the
3671 vector stmt by a factor VF/nunits. In doing so, we record a pointer
3672 from one copy of the vector stmt to the next, in the field
3673 STMT_VINFO_RELATED_STMT. This is necessary in order to allow following
3674 stages to find the correct vector defs to be used when vectorizing
3675 stmts that use the defs of the current stmt. The example below
3676 illustrates the vectorization process when VF=16 and nunits=4 (i.e.,
3677 we need to create 4 vectorized stmts):
3679 before vectorization:
3680 RELATED_STMT VEC_STMT
3681 S1: x = memref - -
3682 S2: z = x + 1 - -
3684 step 1: vectorize stmt S1 (done in vectorizable_load. See more details
3685 there):
3686 RELATED_STMT VEC_STMT
3687 VS1_0: vx0 = memref0 VS1_1 -
3688 VS1_1: vx1 = memref1 VS1_2 -
3689 VS1_2: vx2 = memref2 VS1_3 -
3690 VS1_3: vx3 = memref3 - -
3691 S1: x = load - VS1_0
3692 S2: z = x + 1 - -
3694 step2: vectorize stmt S2 (done here):
3695 To vectorize stmt S2 we first need to find the relevant vector
3696 def for the first operand 'x'. This is, as usual, obtained from
3697 the vector stmt recorded in the STMT_VINFO_VEC_STMT of the stmt
3698 that defines 'x' (S1). This way we find the stmt VS1_0, and the
3699 relevant vector def 'vx0'. Having found 'vx0' we can generate
3700 the vector stmt VS2_0, and as usual, record it in the
3701 STMT_VINFO_VEC_STMT of stmt S2.
3702 When creating the second copy (VS2_1), we obtain the relevant vector
3703 def from the vector stmt recorded in the STMT_VINFO_RELATED_STMT of
3704 stmt VS1_0. This way we find the stmt VS1_1 and the relevant
3705 vector def 'vx1'. Using 'vx1' we create stmt VS2_1 and record a
3706 pointer to it in the STMT_VINFO_RELATED_STMT of the vector stmt VS2_0.
3707 Similarly when creating stmts VS2_2 and VS2_3. This is the resulting
3708 chain of stmts and pointers:
3709 RELATED_STMT VEC_STMT
3710 VS1_0: vx0 = memref0 VS1_1 -
3711 VS1_1: vx1 = memref1 VS1_2 -
3712 VS1_2: vx2 = memref2 VS1_3 -
3713 VS1_3: vx3 = memref3 - -
3714 S1: x = load - VS1_0
3715 VS2_0: vz0 = vx0 + v1 VS2_1 -
3716 VS2_1: vz1 = vx1 + v1 VS2_2 -
3717 VS2_2: vz2 = vx2 + v1 VS2_3 -
3718 VS2_3: vz3 = vx3 + v1 - -
3719 S2: z = x + 1 - VS2_0 */
3723 {
3724 /* Handle uses. */
3726 {
3730 else
3734 {
3737 stmt,
3738 NULL));
3739 }
3740 }
3741 else
3742 {
3745 {
3748 vec_oprnd));
3749 }
3750 }
3752 /* Arguments are ready. Create the new vector stmt. */
3754 {
3766 }
3773 else
3776 }
3783 }
3786 /* Function vectorizable_store.
3788 Check if STMT defines a non scalar data-ref (array/pointer/structure) that
3789 can be vectorized.
3790 If VEC_STMT is also passed, vectorize the STMT: create a vectorized
3791 stmt to replace it, put it in VEC_STMT, and insert it at BSI.
3792 Return FALSE if not a vectorizable STMT, TRUE otherwise. */
3794 static bool
3796 slp_tree slp_node)
3797 {
3798 tree scalar_dest;
3799 tree data_ref;
3800 tree op;
3805 tree elem_type;
3809 tree dummy;
3811 tree def;
3812 gimple def_stmt;
3831 tree aggr_type;
3836 /* Multiple types in SLP are handled by creating the appropriate number of
3837 vectorized stmts for each SLP node. Hence, NCOPIES is always 1 in
3838 case of SLP. */
3841 else
3846 /* FORNOW. This restriction should be relaxed. */
3848 {
3853 }
3861 /* Is vectorizable store? */
3882 {
3887 }
3892 /* FORNOW. In some cases can vectorize even if data-type not supported
3893 (e.g. - array initialization with 0). */
3903 {
3908 }
3911 {
3915 {
3921 }
3924 {
3925 /* STMT is the leader of the group. Check the operands of all the
3926 stmts of the group. */
3929 {
3934 {
3939 }
3941 }
3942 }
3943 }
3946 {
3951 }
3953 /** Transform. **/
3956 {
3962 /* FORNOW */
3965 /* We vectorize all the stmts of the interleaving group when we
3966 reach the last stmt in the group. */
3970 {
3973 }
3976 {
3978 /* VEC_NUM is the number of vect stmts to be created for this
3979 group. */
3984 }
3985 else
3986 /* VEC_NUM is the number of vect stmts to be created for this
3987 group. */
3989 }
3990 else
3991 {
3995 }
4006 /* Targets with store-lane instructions must not require explicit
4007 realignment. */
4014 else
4017 /* In case the vectorization factor (VF) is bigger than the number
4018 of elements that we can fit in a vectype (nunits), we have to generate
4019 more than one vector stmt - i.e - we need to "unroll" the
4020 vector stmt by a factor VF/nunits. For more details see documentation in
4021 vect_get_vec_def_for_copy_stmt. */
4023 /* In case of interleaving (non-unit grouped access):
4025 S1: &base + 2 = x2
4026 S2: &base = x0
4027 S3: &base + 1 = x1
4028 S4: &base + 3 = x3
4030 We create vectorized stores starting from base address (the access of the
4031 first stmt in the chain (S2 in the above example), when the last store stmt
4032 of the chain (S4) is reached:
4034 VS1: &base = vx2
4035 VS2: &base + vec_size*1 = vx0
4036 VS3: &base + vec_size*2 = vx1
4037 VS4: &base + vec_size*3 = vx3
4039 Then permutation statements are generated:
4041 VS5: vx5 = VEC_PERM_EXPR < vx0, vx3, {0, 8, 1, 9, 2, 10, 3, 11} >
4042 VS6: vx6 = VEC_PERM_EXPR < vx0, vx3, {4, 12, 5, 13, 6, 14, 7, 15} >
4043 ...
4045 And they are put in STMT_VINFO_VEC_STMT of the corresponding scalar stmts
4046 (the order of the data-refs in the output of vect_permute_store_chain
4047 corresponds to the order of scalar stmts in the interleaving chain - see
4048 the documentation of vect_permute_store_chain()).
4050 In case of both multiple types and interleaving, above vector stores and
4051 permutation stmts are created for every copy. The result vector stmts are
4052 put in STMT_VINFO_VEC_STMT for the first copy and in the corresponding
4053 STMT_VINFO_RELATED_STMT for the next copies.
4054 */
4058 {
4059 gimple new_stmt;
4060 gimple ptr_incr;
4063 {
4065 {
4066 /* Get vectorized arguments for SLP_NODE. */
4071 }
4072 else
4073 {
4074 /* For interleaved stores we collect vectorized defs for all the
4075 stores in the group in DR_CHAIN and OPRNDS. DR_CHAIN is then
4076 used as an input to vect_permute_store_chain(), and OPRNDS as
4077 an input to vect_get_vec_def_for_stmt_copy() for the next copy.
4079 If the store is not grouped, GROUP_SIZE is 1, and DR_CHAIN and
4080 OPRNDS are of size 1. */
4083 {
4084 /* Since gaps are not supported for interleaved stores,
4085 GROUP_SIZE is the exact number of stmts in the chain.
4086 Therefore, NEXT_STMT can't be NULL_TREE. In case that
4087 there is no interleaving, GROUP_SIZE is 1, and only one
4088 iteration of the loop will be executed. */
4094 NULL);
4098 }
4099 }
4101 /* We should have catched mismatched types earlier. */
4108 }
4109 else
4110 {
4111 /* For interleaved stores we created vectorized defs for all the
4112 defs stored in OPRNDS in the previous iteration (previous copy).
4113 DR_CHAIN is then used as an input to vect_permute_store_chain(),
4114 and OPRNDS as an input to vect_get_vec_def_for_stmt_copy() for the
4115 next copy.
4116 If the store is not grouped, GROUP_SIZE is 1, and DR_CHAIN and
4117 OPRNDS are of size 1. */
4119 {
4126 }
4129 }
4132 {
4133 tree vec_array;
4135 /* Combine all the vectors into an array. */
4138 {
4141 }
4143 /* Emit:
4144 MEM_REF[...all elements...] = STORE_LANES (VEC_ARRAY). */
4149 }
4150 else
4151 {
4154 {
4156 /* Permute. */
4159 }
4163 {
4167 /* Bump the vector pointer. */
4174 /* For grouped stores vectorized defs are interleaved in
4175 vect_permute_store_chain(). */
4185 {
4191 }
4192 else
4193 {
4198 }
4200 misalign);
4202 /* Arguments are ready. Create the new vector stmt. */
4212 }
4213 }
4215 {
4218 else
4221 }
4222 }
4230 }
4232 /* Given a vector type VECTYPE and permutation SEL returns
4233 the VECTOR_CST mask that implements the permutation of the
4234 vector elements. If that is impossible to do, returns NULL. */
4236 tree
4238 {
4257 }
4259 /* Given a vector type VECTYPE returns the VECTOR_CST mask that implements
4260 reversal of the vector elements. If that is impossible to do,
4261 returns NULL. */
4263 static tree
4265 {
4276 }
4278 /* Given a vector variable X and Y, that was generated for the scalar
4279 STMT, generate instructions to permute the vector elements of X and Y
4280 using permutation mask MASK_VEC, insert them at *GSI and return the
4281 permuted vector variable. */
4283 static tree
4286 {
4289 gimple perm_stmt;
4294 /* Generate the permute statement. */
4300 }
4302 /* vectorizable_load.
4304 Check if STMT reads a non scalar data-ref (array/pointer/structure) that
4305 can be vectorized.
4306 If VEC_STMT is also passed, vectorize the STMT: create a vectorized
4307 stmt to replace it, put it in VEC_STMT, and insert it at BSI.
4308 Return FALSE if not a vectorizable STMT, TRUE otherwise. */
4310 static bool
4313 {
4314 tree scalar_dest;
4318 stmt_vec_info prev_stmt_info;
4325 tree elem_type;
4326 tree new_temp;
4329 tree dummy;
4332 gimple ptr_incr;
4343 gimple first_stmt;
4354 tree aggr_type;
4362 {
4366 }
4367 else
4370 /* Multiple types in SLP are handled by creating the appropriate number of
4371 vectorized stmts for each SLP node. Hence, NCOPIES is always 1 in
4372 case of SLP. */
4375 else
4380 /* FORNOW. This restriction should be relaxed. */
4382 {
4387 }
4395 /* Is vectorizable load? */
4419 /* FORNOW. In some cases can vectorize even if data-type not supported
4420 (e.g. - data copies). */
4422 {
4427 }
4429 /* Check if the load is a part of an interleaving chain. */
4431 {
4433 /* FORNOW */
4438 {
4444 }
4445 }
4449 {
4450 gimple def_stmt;
4451 tree def;
4458 {
4463 }
4464 }
4466 {
4470 }
4471 else
4472 {
4478 {
4483 }
4486 {
4491 {
4496 }
4498 {
4503 }
4504 }
4505 }
4508 {
4512 }
4518 /** Transform. **/
4521 {
4527 gimple_seq seq;
4528 basic_block new_bb;
4535 {
4544 }
4546 {
4557 }
4558 else
4574 {
4578 }
4580 /* Currently we support only unconditional gather loads,
4581 so mask should be all ones. */
4585 {
4586 REAL_VALUE_TYPE r;
4592 }
4593 else
4602 {
4607 op = vec_oprnd0
4609 else
4610 op = vec_oprnd0
4614 {
4620 new_stmt
4625 }
4627 new_stmt
4631 {
4640 new_stmt
4642 NULL_TREE);
4643 }
4644 else
4645 {
4648 }
4653 {
4655 {
4658 }
4662 }
4666 else
4669 }
4671 }
4673 {
4674 gimple_stmt_iterator incr_gsi;
4676 gimple incr;
4677 tree offvar;
4679 tree ivstep;
4680 tree running_off;
4686 /* For a load with loop-invariant (but other than power-of-2)
4687 stride (i.e. not a grouped access) like so:
4689 for (i = 0; i < n; i += stride)
4690 ... = array[i];
4692 we generate a new induction variable and new accesses to
4693 form a new vector (or vectors, depending on ncopies):
4695 for (j = 0; ; j += VF*stride)
4696 tmp1 = array[j];
4697 tmp2 = array[j + stride];
4698 ...
4699 vectemp = {tmp1, tmp2, ...}
4700 */
4721 {
4722 tree vec_inv;
4726 {
4728 gimple incr;
4730 {
4733 running_off,
4738 newref);
4739 }
4740 else
4742 running_off,
4747 GSI_SAME_STMT);
4753 else
4759 }
4767 else
4770 }
4772 }
4775 {
4782 /* Check if the chain of loads is already vectorized. */
4784 {
4787 }
4791 /* VEC_NUM is the number of vect stmts to be created for this group. */
4793 {
4798 }
4799 else
4801 }
4802 else
4803 {
4807 }
4811 /* Targets with load-lane instructions must not require explicit
4812 realignment. */
4817 /* In case the vectorization factor (VF) is bigger than the number
4818 of elements that we can fit in a vectype (nunits), we have to generate
4819 more than one vector stmt - i.e - we need to "unroll" the
4820 vector stmt by a factor VF/nunits. In doing so, we record a pointer
4821 from one copy of the vector stmt to the next, in the field
4822 STMT_VINFO_RELATED_STMT. This is necessary in order to allow following
4823 stages to find the correct vector defs to be used when vectorizing
4824 stmts that use the defs of the current stmt. The example below
4825 illustrates the vectorization process when VF=16 and nunits=4 (i.e., we
4826 need to create 4 vectorized stmts):
4828 before vectorization:
4829 RELATED_STMT VEC_STMT
4830 S1: x = memref - -
4831 S2: z = x + 1 - -
4833 step 1: vectorize stmt S1:
4834 We first create the vector stmt VS1_0, and, as usual, record a
4835 pointer to it in the STMT_VINFO_VEC_STMT of the scalar stmt S1.
4836 Next, we create the vector stmt VS1_1, and record a pointer to
4837 it in the STMT_VINFO_RELATED_STMT of the vector stmt VS1_0.
4838 Similarly, for VS1_2 and VS1_3. This is the resulting chain of
4839 stmts and pointers:
4840 RELATED_STMT VEC_STMT
4841 VS1_0: vx0 = memref0 VS1_1 -
4842 VS1_1: vx1 = memref1 VS1_2 -
4843 VS1_2: vx2 = memref2 VS1_3 -
4844 VS1_3: vx3 = memref3 - -
4845 S1: x = load - VS1_0
4846 S2: z = x + 1 - -
4848 See in documentation in vect_get_vec_def_for_stmt_copy for how the
4849 information we recorded in RELATED_STMT field is used to vectorize
4850 stmt S2. */
4852 /* In case of interleaving (non-unit grouped access):
4854 S1: x2 = &base + 2
4855 S2: x0 = &base
4856 S3: x1 = &base + 1
4857 S4: x3 = &base + 3
4859 Vectorized loads are created in the order of memory accesses
4860 starting from the access of the first stmt of the chain:
4862 VS1: vx0 = &base
4863 VS2: vx1 = &base + vec_size*1
4864 VS3: vx3 = &base + vec_size*2
4865 VS4: vx4 = &base + vec_size*3
4867 Then permutation statements are generated:
4869 VS5: vx5 = VEC_PERM_EXPR < vx0, vx1, { 0, 2, ..., i*2 } >
4870 VS6: vx6 = VEC_PERM_EXPR < vx0, vx1, { 1, 3, ..., i*2+1 } >
4871 ...
4873 And they are put in STMT_VINFO_VEC_STMT of the corresponding scalar stmts
4874 (the order of the data-refs in the output of vect_permute_load_chain
4875 corresponds to the order of scalar stmts in the interleaving chain - see
4876 the documentation of vect_permute_load_chain()).
4877 The generation of permutation stmts and recording them in
4878 STMT_VINFO_VEC_STMT is done in vect_transform_grouped_load().
4880 In case of both multiple types and interleaving, the vector loads and
4881 permutation stmts above are created for every copy. The result vector
4882 stmts are put in STMT_VINFO_VEC_STMT for the first copy and in the
4883 corresponding STMT_VINFO_RELATED_STMT for the next copies. */
4885 /* If the data reference is aligned (dr_aligned) or potentially unaligned
4886 on a target that supports unaligned accesses (dr_unaligned_supported)
4887 we generate the following code:
4888 p = initial_addr;
4889 indx = 0;
4890 loop {
4891 p = p + indx * vectype_size;
4892 vec_dest = *(p);
4893 indx = indx + 1;
4894 }
4896 Otherwise, the data reference is potentially unaligned on a target that
4897 does not support unaligned accesses (dr_explicit_realign_optimized) -
4898 then generate the following code, in which the data in each iteration is
4899 obtained by two vector loads, one from the previous iteration, and one
4900 from the current iteration:
4901 p1 = initial_addr;
4902 msq_init = *(floor(p1))
4903 p2 = initial_addr + VS - 1;
4904 realignment_token = call target_builtin;
4905 indx = 0;
4906 loop {
4907 p2 = p2 + indx * vectype_size
4908 lsq = *(floor(p2))
4909 vec_dest = realign_load (msq, lsq, realignment_token)
4910 indx = indx + 1;
4911 msq = lsq;
4912 } */
4914 /* If the misalignment remains the same throughout the execution of the
4915 loop, we can create the init_addr and permutation mask at the loop
4916 preheader. Otherwise, it needs to be created inside the loop.
4917 This can only occur when vectorizing memory accesses in the inner-loop
4918 nested within an outer-loop that is being vectorized. */
4923 {
4926 }
4931 {
4936 {
4939 }
4940 }
4941 else
4949 else
4954 {
4955 /* 1. Create the vector or array pointer update chain. */
4960 else
4968 {
4969 tree vec_array;
4973 /* Emit:
4974 VEC_ARRAY = LOAD_LANES (MEM_REF[...all elements...]). */
4980 /* Extract each vector into an SSA_NAME. */
4982 {
4986 }
4988 /* Record the mapping between SSA_NAMEs and statements. */
4990 }
4991 else
4992 {
4994 {
4999 /* 2. Create the vector-load in the loop. */
5001 {
5004 {
5007 data_ref
5013 {
5016 }
5018 {
5024 }
5025 else
5026 {
5031 }
5035 }
5037 {
5039 tree vs_minus_1;
5046 dr_explicit_realign,
5050 new_stmt = gimple_build_assign_with_ops
5052 build_int_cst
5056 data_ref
5061 vectype);
5073 new_stmt = gimple_build_assign_with_ops
5075 build_int_cst
5081 data_ref
5086 }
5089 new_stmt = gimple_build_assign_with_ops
5091 build_int_cst
5095 data_ref
5102 }
5109 /* 3. Handle explicit realignment if necessary/supported.
5110 Create in loop:
5111 vec_dest = realign_load (msq, lsq, realignment_token) */
5114 {
5119 new_stmt
5122 realignment_token);
5128 {
5133 UNKNOWN_LOCATION);
5135 }
5136 }
5138 /* 4. Handle invariant-load. */
5140 {
5147 }
5150 {
5155 }
5157 /* Collect vector loads and later create their permutation in
5158 vect_transform_grouped_load (). */
5162 /* Store vector loads in the corresponding SLP_NODE. */
5165 }
5166 }
5172 {
5175 {
5178 }
5179 }
5180 else
5181 {
5183 {
5187 }
5188 else
5189 {
5192 else
5195 }
5196 }
5198 }
5201 }
5203 /* Function vect_is_simple_cond.
5205 Input:
5206 LOOP - the loop that is being vectorized.
5207 COND - Condition that is checked for simple use.
5209 Output:
5210 *COMP_VECTYPE - the vector type for the comparison.
5212 Returns whether a COND can be vectorized. Checks whether
5213 condition operands are supportable using vec_is_simple_use. */
5215 static bool
5218 {
5220 tree def;
5231 {
5236 }
5242 {
5247 }
5254 }
5256 /* vectorizable_condition.
5258 Check if STMT is conditional modify expression that can be vectorized.
5259 If VEC_STMT is also passed, vectorize the STMT: create a vectorized
5260 stmt using VEC_COND_EXPR to replace it, put it in VEC_STMT, and insert it
5261 at GSI.
5263 When STMT is vectorized as nested cycle, REDUC_DEF is the vector variable
5264 to be used at REDUC_INDEX (in then clause if REDUC_INDEX is 1, and in
5265 else caluse if it is 2).
5267 Return FALSE if not a vectorizable STMT, TRUE otherwise. */
5269 bool
5272 slp_tree slp_node)
5273 {
5283 tree new_temp;
5285 tree def;
5301 else
5319 /* FORNOW: not yet supported. */
5321 {
5326 }
5328 /* Is vectorizable conditional operation? */
5347 {
5352 }
5359 {
5364 }
5371 {
5377 }
5380 {
5383 }
5385 /* Transform. */
5388 {
5393 }
5395 /* Handle def. */
5399 /* Handle cond expr. */
5401 {
5404 {
5406 {
5424 }
5425 else
5426 {
5427 gimple gtemp;
5428 vec_cond_lhs =
5434 vec_cond_rhs =
5441 else
5442 {
5447 }
5450 else
5451 {
5456 }
5457 }
5458 }
5459 else
5460 {
5469 }
5472 {
5477 }
5479 /* Arguments are ready. Create the new vector stmt. */
5481 {
5497 }
5504 else
5508 }
5516 }
5519 /* Make sure the statement is vectorizable. */
5521 bool
5523 {
5529 gimple pattern_stmt;
5530 gimple_seq pattern_def_seq;
5533 {
5536 }
5539 {
5545 }
5547 /* Skip stmts that do not need to be vectorized. In loops this is expected
5548 to include:
5549 - the COND_EXPR which is the loop exit condition
5550 - any LABEL_EXPRs in the loop
5551 - computations that are used only for array indexing or loop control.
5552 In basic blocks we only analyze statements that are a part of some SLP
5553 instance, therefore, all the statements are relevant.
5555 Pattern statement needs to be analyzed instead of the original statement
5556 if the original statement is not relevant. Otherwise, we analyze both
5557 statements. In basic blocks we are called from some SLP instance
5558 traversal, don't analyze pattern stmts instead, the pattern stmts
5559 already will be part of SLP instance. */
5564 {
5566 && pattern_stmt
5569 {
5570 /* Analyze PATTERN_STMT instead of the original stmt. */
5574 {
5578 }
5579 }
5580 else
5581 {
5586 }
5587 }
5590 && pattern_stmt
5593 {
5594 /* Analyze PATTERN_STMT too. */
5596 {
5600 }
5604 }
5609 {
5610 gimple_stmt_iterator si;
5613 {
5617 {
5618 /* Analyze def stmt of STMT if it's a pattern stmt. */
5620 {
5624 }
5629 }
5630 }
5631 }
5634 {
5651 }
5654 {
5659 {
5663 }
5667 {
5669 {
5673 scalar_type);
5674 }
5676 }
5679 {
5682 }
5685 }
5688 {
5692 }
5707 else
5708 {
5718 }
5721 {
5723 {
5728 }
5731 }
5736 /* Stmts that are (also) "live" (i.e. - that are used out of the loop)
5737 need extra handling, except for vectorizable reductions. */
5743 {
5745 {
5750 }
5753 }
5756 }
5759 /* Function vect_transform_stmt.
5761 Create a vectorized stmt to replace STMT, and insert it at BSI. */
5763 bool
5766 slp_instance slp_node_instance)
5767 {
5774 {
5805 slp_node_instance);
5813 {
5814 /* In case of interleaving, the whole chain is vectorized when the
5815 last store in the chain is reached. Store stmts before the last
5816 one are skipped, and there vec_stmt_info shouldn't be freed
5817 meanwhile. */
5821 }
5822 else
5843 {
5848 }
5849 }
5851 /* Handle inner-loop stmts whose DEF is used in the loop-nest that
5852 is being vectorized, but outside the immediately enclosing loop. */
5860 vect_used_in_outer_by_reduction))
5861 {
5864 imm_use_iterator imm_iter;
5865 use_operand_p use_p;
5866 tree scalar_dest;
5867 gimple exit_phi;
5873 /* Find the relevant loop-exit phi-node, and reord the vec_stmt there
5874 (to be used when vectorizing outer-loop stmts that use the DEF of
5875 STMT). */
5878 else
5882 {
5884 {
5887 }
5888 }
5889 }
5891 /* Handle stmts whose DEF is used outside the loop-nest that is
5892 being vectorized. */
5895 {
5898 }
5904 }
5907 /* Remove a group of stores (for SLP or interleaving), free their
5908 stmt_vec_info. */
5910 void
5912 {
5914 gimple tmp;
5915 gimple_stmt_iterator next_si;
5918 {
5924 /* Free the attached stmt_vec_info and remove the stmt. */
5931 }
5932 }
5935 /* Function new_stmt_vec_info.
5937 Create and initialize a new stmt_vec_info struct for STMT. */
5939 stmt_vec_info
5941 bb_vec_info bb_vinfo)
5942 {
5943 stmt_vec_info res;
5969 else
5983 }
5986 /* Create a hash table for stmt_vec_info. */
5988 void
5990 {
5993 }
5996 /* Free hash table for stmt_vec_info. */
5998 void
6000 {
6003 }
6006 /* Free stmt vectorization related info. */
6008 void
6010 {
6016 /* Check if this statement has a related "pattern stmt"
6017 (introduced by the vectorizer during the pattern recognition
6018 pass). Free pattern's stmt_vec_info and def stmt's stmt_vec_info
6019 too. */
6021 {
6022 stmt_vec_info patt_info
6025 {
6028 {
6029 gimple_stmt_iterator si;
6032 }
6034 }
6035 }
6040 }
6043 /* Function get_vectype_for_scalar_type_and_size.
6045 Returns the vector type corresponding to SCALAR_TYPE and SIZE as supported
6046 by the target. */
6048 static tree
6050 {
6055 tree vectype;
6064 /* For vector types of elements whose mode precision doesn't
6065 match their types precision we use a element type of mode
6066 precision. The vectorization routines will have to make sure
6067 they support the proper result truncation/extension.
6068 We also make sure to build vector types with INTEGER_TYPE
6069 component type only. */
6076 /* We shouldn't end up building VECTOR_TYPEs of non-scalar components.
6077 When the component mode passes the above test simply use a type
6078 corresponding to that mode. The theory is that any use that
6079 would cause problems with this will disable vectorization anyway. */
6085 /* We can't build a vector type of elements with alignment bigger than
6086 their size. */
6090 /* If we felt back to using the mode fail if there was
6091 no scalar type for it. */
6095 /* If no size was supplied use the mode the target prefers. Otherwise
6096 lookup a vector mode of the specified size. */
6099 else
6107 {
6111 }
6117 {
6120 }
6124 {
6129 }
6132 }
6136 /* Function get_vectype_for_scalar_type.
6138 Returns the vector type corresponding to SCALAR_TYPE as supported
6139 by the target. */
6141 tree
6143 {
6144 tree vectype;
6146 current_vector_size);
6151 }
6153 /* Function get_same_sized_vectype
6155 Returns a vector type corresponding to SCALAR_TYPE of size
6156 VECTOR_TYPE if supported by the target. */
6158 tree
6160 {
6161 return get_vectype_for_scalar_type_and_size
6163 }
6165 /* Function vect_is_simple_use.
6167 Input:
6168 LOOP_VINFO - the vect info of the loop that is being vectorized.
6169 BB_VINFO - the vect info of the basic block that is being vectorized.
6170 OPERAND - operand of STMT in the loop or bb.
6171 DEF - the defining stmt in case OPERAND is an SSA_NAME.
6173 Returns whether a stmt with OPERAND can be vectorized.
6174 For loops, supportable operands are constants, loop invariants, and operands
6175 that are defined by the current iteration of the loop. Unsupportable
6176 operands are those that are defined by a previous iteration of the loop (as
6177 is the case in reduction/induction computations).
6178 For basic blocks, supportable operands are constants and bb invariants.
6179 For now, operands defined outside the basic block are not supported. */
6181 bool
6185 {
6186 basic_block bb;
6187 stmt_vec_info stmt_vinfo;
6197 {
6201 }
6204 {
6207 }
6210 {
6214 }
6217 {
6221 }
6224 {
6229 }
6233 {
6238 }
6241 {
6244 }
6246 /* Empty stmt is expected only in case of a function argument.
6247 (Otherwise - we expect a phi_node or a GIMPLE_ASSIGN). */
6249 {
6253 }
6261 else
6262 {
6265 }
6268 || (stmt
6271 {
6276 }
6282 {
6295 /* FALLTHRU */
6301 }
6304 }
6306 /* Function vect_is_simple_use_1.
6308 Same as vect_is_simple_use_1 but also determines the vector operand
6309 type of OPERAND and stores it to *VECTYPE. If the definition of
6310 OPERAND is vect_uninitialized_def, vect_constant_def or
6311 vect_external_def *VECTYPE will be set to NULL_TREE and the caller
6312 is responsible to compute the best suited vector type for the
6313 scalar operand. */
6315 bool
6319 {
6324 /* Now get a vector type if the def is internal, otherwise supply
6325 NULL_TREE and leave it up to the caller to figure out a proper
6326 type for the use stmt. */
6332 {
6342 }
6347 else
6351 }
6354 /* Function supportable_widening_operation
6356 Check whether an operation represented by the code CODE is a
6357 widening operation that is supported by the target platform in
6358 vector form (i.e., when operating on arguments of type VECTYPE_IN
6359 producing a result of type VECTYPE_OUT).
6361 Widening operations we currently support are NOP (CONVERT), FLOAT
6362 and WIDEN_MULT. This function checks if these operations are supported
6363 by the target platform either directly (via vector tree-codes), or via
6364 target builtins.
6366 Output:
6367 - CODE1 and CODE2 are codes of vector operations to be used when
6368 vectorizing the operation, if available.
6369 - MULTI_STEP_CVT determines the number of required intermediate steps in
6370 case of multi-step conversion (like char->short->int - in that case
6371 MULTI_STEP_CVT will be 1).
6372 - INTERM_TYPES contains the intermediate type required to perform the
6373 widening operation (short in the above example). */
6375 bool
6381 {
6401 {
6403 /* The result of a vectorized widening operation usually requires
6404 two vectors (because the widened results do not fit into one vector).
6405 The generated vector results would normally be expected to be
6406 generated in the same order as in the original scalar computation,
6407 i.e. if 8 results are generated in each vector iteration, they are
6408 to be organized as follows:
6409 vect1: [res1,res2,res3,res4],
6410 vect2: [res5,res6,res7,res8].
6412 However, in the special case that the result of the widening
6413 operation is used in a reduction computation only, the order doesn't
6414 matter (because when vectorizing a reduction we change the order of
6415 the computation). Some targets can take advantage of this and
6416 generate more efficient code. For example, targets like Altivec,
6417 that support widen_mult using a sequence of {mult_even,mult_odd}
6418 generate the following vectors:
6419 vect1: [res1,res3,res5,res7],
6420 vect2: [res2,res4,res6,res8].
6422 When vectorizing outer-loops, we execute the inner-loop sequentially
6423 (each vectorized inner-loop iteration contributes to VF outer-loop
6424 iterations in parallel). We therefore don't allow to change the
6425 order of the computation in the inner-loop during outer-loop
6426 vectorization. */
6427 /* TODO: Another case in which order doesn't *really* matter is when we
6428 widen and then contract again, e.g. (short)((int)x * y >> 8).
6429 Normally, pack_trunc performs an even/odd permute, whereas the
6430 repack from an even/odd expansion would be an interleave, which
6431 would be significantly simpler for e.g. AVX2. */
6432 /* In any case, in order to avoid duplicating the code below, recurse
6433 on VEC_WIDEN_MULT_EVEN_EXPR. If it succeeds, all the return values
6434 are properly set up for the caller. If we fail, we'll continue with
6435 a VEC_WIDEN_MULT_LO/HI_EXPR check. */
6442 interm_types))
6449 /* Support the recursion induced just above. */
6459 CASE_CONVERT:
6470 /* ??? Not yet implemented due to missing VEC_UNPACK_FIX_TRUNC_HI_EXPR/
6471 VEC_UNPACK_FIX_TRUNC_LO_EXPR tree codes and optabs used for
6472 computing the operation. */
6477 }
6480 {
6484 }
6487 {
6488 /* The signedness is determined from output operand. */
6491 }
6492 else
6493 {
6496 }
6513 /* Check if it's a multi-step conversion that can be done using intermediate
6514 types. */
6522 /* We assume here that there will not be more than MAX_INTERM_CVT_STEPS
6523 intermediate steps in promotion sequence. We try
6524 MAX_INTERM_CVT_STEPS to get to NARROW_VECTYPE, and fail if we do
6525 not. */
6528 {
6530 intermediate_type
6556 }
6560 }
6563 /* Function supportable_narrowing_operation
6565 Check whether an operation represented by the code CODE is a
6566 narrowing operation that is supported by the target platform in
6567 vector form (i.e., when operating on arguments of type VECTYPE_IN
6568 and producing a result of type VECTYPE_OUT).
6570 Narrowing operations we currently support are NOP (CONVERT) and
6571 FIX_TRUNC. This function checks if these operations are supported by
6572 the target platform directly via vector tree-codes.
6574 Output:
6575 - CODE1 is the code of a vector operation to be used when
6576 vectorizing the operation, if available.
6577 - MULTI_STEP_CVT determines the number of required intermediate steps in
6578 case of multi-step conversion (like int->short->char - in that case
6579 MULTI_STEP_CVT will be 1).
6580 - INTERM_TYPES contains the intermediate type required to perform the
6581 narrowing operation (short in the above example). */
6583 bool
6588 {
6595 tree intermediate_type;
6602 {
6603 CASE_CONVERT:
6612 /* ??? Not yet implemented due to missing VEC_PACK_FLOAT_EXPR
6613 tree code and optabs used for computing the operation. */
6618 }
6621 /* The signedness is determined from output operand. */
6623 else
6638 /* Check if it's a multi-step conversion that can be done using intermediate
6639 types. */
6643 else
6646 /* For multi-step FIX_TRUNC_EXPR prefer signed floating to integer
6647 conversion over unsigned, as unsigned FIX_TRUNC_EXPR is often more
6648 costly than signed. */
6650 {
6653 intermediate_type
6655 interm_optab
6661 {
6665 }
6666 }
6668 /* We assume here that there will not be more than MAX_INTERM_CVT_STEPS
6669 intermediate steps in promotion sequence. We try
6670 MAX_INTERM_CVT_STEPS to get to NARROW_VECTYPE, and fail if we do not. */
6673 {
6675 intermediate_type
6677 interm_optab
6679 optab_default);
6695 }
6699 }