| blob | 2e4e36dcd2896850f6b1c0c81da015b54d1f4864 |
1 /* SLP - Basic Block Vectorization
2 Copyright (C) 2007, 2008, 2009, 2010
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 /* Extract the location of the basic block in the source code.
43 Return the basic block location if succeed and NULL if not. */
45 LOC
47 {
49 gimple_stmt_iterator si;
55 {
59 }
62 }
65 /* Recursively free the memory allocated for the SLP tree rooted at NODE. */
67 static void
69 {
85 }
88 /* Free the memory allocated for the SLP instance. */
90 void
92 {
96 }
99 /* Get the defs for the rhs of STMT (collect them in DEF_STMTS0/1), check that
100 they are of a legal type and that they match the defs of the first stmt of
101 the SLP group (stored in FIRST_STMT_...). */
103 static bool
115 {
116 tree oprnd;
118 tree def;
119 gimple def_stmt;
121 stmt_vec_info stmt_info =
133 {
139 {
141 {
144 }
147 }
149 /* Check if DEF_STMT is a part of a pattern in LOOP and get the def stmt
150 from the pattern. Check that all the stmts of the node are in the
151 pattern. */
156 {
159 else
160 {
164 {
166 {
170 }
173 }
174 }
180 {
184 }
187 {
200 }
201 }
204 {
205 /* op0 of the first stmt of the group - store its info. */
209 else
212 /* Analyze costs (for the first stmt of the group only). */
214 /* Not memory operation (we don't call this functions for loads). */
216 else
217 /* Store. */
219 }
221 else
222 {
224 {
225 /* op1 of the first stmt of the group - store its info. */
229 else
230 {
231 /* We assume that the stmt contains only one constant
232 operand. We fail otherwise, to be on the safe side. */
234 {
239 }
241 }
242 }
243 else
244 {
245 /* Not first stmt of the group, check that the def-stmt/s match
246 the def-stmt/s of the first stmt. */
257 || (!def
260 {
265 }
266 }
267 }
269 /* Check the types of the definitions. */
271 {
280 else
285 /* FORNOW: Not supported. */
287 {
290 }
293 }
294 }
297 }
300 /* Recursively build an SLP tree starting from NODE.
301 Fail (and return FALSE) if def-stmts are not isomorphic, require data
302 permutation or are of unsupported types of operation. Otherwise, return
303 TRUE. */
305 static bool
313 {
323 tree lhs;
327 optab optab;
334 HOST_WIDE_INT dummy;
339 /* For every stmt in NODE find its def stmt/s. */
341 {
343 {
346 }
348 /* Fail to vectorize statements marked as unvectorizable. */
350 {
352 {
356 }
359 }
363 {
365 {
369 }
372 }
377 {
379 {
382 }
384 }
388 {
392 /* FORNOW: multiple types are unsupported in BB SLP. */
395 }
397 /* In case of multiple types we need to detect the smallest type. */
403 else
406 /* Check the operation. */
408 {
411 /* Shift arguments should be equal in all the packed stmts for a
412 vector shift with scalar shift operand. */
416 {
419 /* First see if we have a vector/vector shift. */
421 optab_vector);
425 {
426 /* No vector/vector shift, try for a vector/scalar shift. */
428 optab_scalar);
431 {
435 }
438 {
443 }
446 {
449 }
450 }
451 }
452 }
453 else
454 {
465 {
467 {
471 }
474 }
478 {
480 {
484 }
487 }
488 }
490 /* Strided store or load. */
492 {
494 {
495 /* Store. */
503 ncopies_for_cost,
506 }
507 else
508 {
509 /* Load. */
510 /* FORNOW: Check that there is no gap between the loads. */
515 {
517 {
521 }
524 }
526 /* Check that the size of interleaved loads group is not
527 greater than the SLP group size. */
529 {
531 {
533 "interleaved loads is greater than"
536 }
539 }
543 {
544 /* Check that there are no loads from different interleaving
545 chains in the same node. The only exception is complex
546 numbers. */
550 {
552 {
556 }
559 }
560 }
561 else
565 {
569 {
571 {
575 }
578 }
580 /* Analyze costs (for the first stmt in the group). */
583 }
585 /* Store the place of this load in the interleaving chain. In
586 case that permutation is needed we later decide if a specific
587 permutation is supported. */
589 first_load);
595 /* We stop the tree when we reach a group of loads. */
598 }
600 else
601 {
603 {
604 /* Not strided load. */
606 {
609 }
611 /* FORNOW: Not strided loads are not supported. */
613 }
615 /* Not memory operation. */
618 {
620 {
624 }
627 }
629 /* Find the def-stmts. */
636 ncopies_for_cost,
639 }
640 }
642 /* Add the costs of the node to the overall instance costs. */
646 /* Strided loads were reached - stop the recursion. */
648 {
650 {
652 *inside_cost
655 }
656 else
657 {
658 /* We don't check here complex numbers chains, so we keep them in
659 LOADS for further check in vect_supported_load_permutation_p. */
662 }
665 }
667 /* Create SLP_TREE nodes for the definition node/s. */
669 {
680 vectorization_factor))
684 }
687 {
698 vectorization_factor))
702 }
705 }
708 static void
710 {
712 gimple stmt;
719 {
722 }
727 }
730 /* Mark the tree rooted at NODE with MARK (PURE_SLP or HYBRID).
731 If MARK is HYBRID, it refers to a specific stmt in NODE (the stmt at index
732 J). Otherwise, MARK is PURE_SLP and J is -1, which indicates that all the
733 stmts in NODE are to be marked. */
735 static void
737 {
739 gimple stmt;
750 }
753 /* Mark the statements of the tree rooted at NODE as relevant (vect_used). */
755 static void
757 {
759 gimple stmt;
760 stmt_vec_info stmt_info;
766 {
771 }
775 }
778 /* Check if the permutation required by the SLP INSTANCE is supported.
779 Reorganize the SLP nodes stored in SLP_INSTANCE_LOADS if needed. */
781 static bool
783 {
791 slp_tree load;
793 /* FORNOW: The only supported loads permutation is loads from the same
794 location in all the loads in the node, when the data-refs in
795 nodes of LOADS constitute an interleaving chain.
796 Sort the nodes according to the order of accesses in the chain. */
802 {
804 /* Check that the loads are all in the same interleaving chain. */
806 {
808 {
812 }
816 }
819 }
835 }
838 /* Rearrange the statements of NODE according to PERMUTATION. */
840 static void
843 {
844 gimple stmt;
861 {
864 }
868 }
871 /* Check if the required load permutation is supported.
872 LOAD_PERMUTATION contains a list of indices of the loads.
873 In SLP this permutation is relative to the order of strided stores that are
874 the base of the SLP instance. */
876 static bool
879 {
882 sbitmap load_index;
887 /* FORNOW: permutations are only supported in SLP. */
892 {
896 }
898 /* In case of reduction every load permutation is allowed, since the order
899 of the reduction statements is not important (as opposed to the case of
900 strided stores). The only condition we need to check is that all the
901 load nodes are of the same size and have the same permutation (and then
902 rearrange all the nodes of the SLP instance according to this
903 permutation). */
905 /* Check that all the load nodes are of the same size. */
907 {
916 complex_numbers++;
917 }
919 /* Complex operands can be swapped as following:
920 real_c = real_b + real_a;
921 imag_c = imag_a + imag_b;
922 i.e., we have {real_b, imag_a} and {real_a, imag_b} instead of
923 {real_a, imag_a} and {real_b, imag_b}. We check here that if interleaving
924 chains are mixed, they match the above pattern. */
926 {
928 {
930 {
933 else
934 {
936 {
942 else
953 }
954 }
955 }
956 }
957 }
959 /* We checked that this case ok, so there is no need to proceed with
960 permutation tests. */
962 {
966 }
970 /* LOAD_PERMUTATION is a list of indices of all the loads of the SLP
971 instance, not all the loads belong to the same node or interleaving
972 group. Hence, we need to divide them into groups according to
973 GROUP_SIZE. */
976 /* Reduction (there are no data-refs in the root). */
978 {
981 /* Compare all the permutation sequences to the first one. */
983 {
986 {
991 {
994 }
996 k++;
997 }
1001 }
1004 {
1005 /* This permutaion is valid for reduction. Since the order of the
1006 statements in the nodes is not important unless they are memory
1007 accesses, we can rearrange the statements in all the nodes
1008 according to the order of the loads. */
1010 load_permutation);
1013 }
1014 }
1016 /* FORNOW: the only supported permutation is 0..01..1.. of length equal to
1017 GROUP_SIZE and where each sequence of same drs is of GROUP_SIZE length as
1018 well (unless it's reduction). */
1027 {
1031 {
1033 {
1036 }
1039 }
1042 {
1045 }
1048 }
1061 }
1064 /* Find the first load in the loop that belongs to INSTANCE.
1065 When loads are in several SLP nodes, there can be a case in which the first
1066 load does not appear in the first SLP node to be transformed, causing
1067 incorrect order of statements. Since we generate all the loads together,
1068 they must be inserted before the first load of the SLP instance and not
1069 before the first load of the first node of the instance. */
1071 static gimple
1073 {
1075 slp_tree load_node;
1083 }
1086 /* Find the last store in SLP INSTANCE. */
1088 static gimple
1090 {
1092 slp_tree node;
1098 i++)
1102 }
1105 /* Analyze an SLP instance starting from a group of strided stores. Call
1106 vect_build_slp_tree to build a tree of packed stmts if possible.
1107 Return FALSE if it's impossible to SLP any stmt in the loop. */
1109 static bool
1111 gimple stmt)
1112 {
1113 slp_instance new_instance;
1118 gimple next;
1127 {
1131 }
1132 else
1133 {
1137 }
1140 {
1142 {
1145 }
1148 }
1153 else
1154 /* No multitypes in BB SLP. */
1157 /* Calculate the unrolling factor. */
1160 {
1166 }
1168 /* Create a node (a root of the SLP tree) for the packed strided stores. */
1172 {
1173 /* Collect the stores and store them in SLP_TREE_SCALAR_STMTS. */
1175 {
1178 }
1179 }
1180 else
1181 {
1182 /* Collect reduction statements. */
1184 next);
1185 i++)
1186 {
1189 {
1192 }
1193 }
1194 }
1203 /* Calculate the number of vector stmts to create based on the unrolling
1204 factor (number of vectors is 1 if NUNITS >= GROUP_SIZE, and is
1205 GROUP_SIZE / NUNITS otherwise. */
1211 /* Build the tree for the SLP instance. */
1215 vectorization_factor))
1216 {
1217 /* Create a new SLP instance. */
1221 /* Calculate the unrolling factor based on the smallest type in the
1222 loop. */
1234 {
1236 load_permutation))
1237 {
1239 {
1243 }
1247 }
1251 }
1252 else
1258 new_instance);
1259 else
1261 new_instance);
1267 }
1269 /* Failed to SLP. */
1270 /* Free the allocated memory. */
1276 }
1279 /* Check if there are stmts in the loop can be vectorized using SLP. Build SLP
1280 trees of packed scalar stmts if SLP is possible. */
1282 bool
1284 {
1287 gimple store;
1294 {
1297 }
1298 else
1301 /* Find SLP sequences starting from groups of strided stores. */
1307 {
1312 }
1314 /* Find SLP sequences starting from groups of reductions. */
1321 }
1324 /* For each possible SLP instance decide whether to SLP it and calculate overall
1325 unrolling factor needed to SLP the loop. */
1327 void
1329 {
1332 slp_instance instance;
1339 {
1340 /* FORNOW: SLP if you can. */
1344 /* Mark all the stmts that belong to INSTANCE as PURE_SLP stmts. Later we
1345 call vect_detect_hybrid_slp () to find stmts that need hybrid SLP and
1346 loop-based vectorization. Such stmts will be marked as HYBRID. */
1348 decided_to_slp++;
1349 }
1356 }
1359 /* Find stmts that must be both vectorized and SLPed (since they feed stmts that
1360 can't be SLPed) in the tree rooted at NODE. Mark such stmts as HYBRID. */
1362 static void
1364 {
1366 gimple stmt;
1367 imm_use_iterator imm_iter;
1368 gimple use_stmt;
1369 stmt_vec_info stmt_vinfo;
1389 }
1392 /* Find stmts that must be both vectorized and SLPed. */
1394 void
1396 {
1399 slp_instance instance;
1406 }
1409 /* Create and initialize a new bb_vec_info struct for BB, as well as
1410 stmt_vec_info structs for all the stmts in it. */
1412 static bb_vec_info
1414 {
1416 gimple_stmt_iterator gsi;
1422 {
1426 }
1433 }
1436 /* Free BB_VINFO struct, as well as all the stmt_vec_info structs of all the
1437 stmts in the basic block. */
1439 static void
1441 {
1442 basic_block bb;
1443 gimple_stmt_iterator si;
1451 {
1456 /* Free stmt_vec_info. */
1458 }
1464 }
1467 /* Analyze statements contained in SLP tree node after recursively analyzing
1468 the subtree. Return TRUE if the operations are supported. */
1470 static bool
1472 {
1475 gimple stmt;
1485 {
1492 }
1495 }
1498 /* Analyze statements in SLP instances of the basic block. Return TRUE if the
1499 operations are supported. */
1501 static bool
1503 {
1505 slp_instance instance;
1509 {
1512 {
1515 }
1516 else
1517 i++;
1518 }
1524 }
1526 /* Check if loads and stores are mixed in the basic block (in that
1527 case if we are not sure that the accesses differ, we can't vectorize the
1528 basic block). Also return FALSE in case that there is statement marked as
1529 not vectorizable. */
1531 static bool
1533 {
1535 gimple_stmt_iterator si;
1537 gimple stmt;
1541 {
1544 /* We can't allow not analyzed statements, since they may contain data
1545 accesses. */
1558 }
1561 }
1563 /* Check if vectorization of the basic block is profitable. */
1565 static bool
1567 {
1569 slp_instance instance;
1573 gimple stmt;
1574 gimple_stmt_iterator si;
1580 /* Calculate vector costs. */
1582 {
1585 }
1587 /* Calculate scalar cost. */
1589 {
1598 {
1602 else
1605 }
1606 else
1611 }
1614 {
1617 vec_inside_cost);
1619 vec_outside_cost);
1621 }
1623 /* Vectorization is profitable if its cost is less than the cost of scalar
1624 version. */
1629 }
1631 /* Check if the basic block can be vectorized. */
1633 bb_vec_info
1635 {
1636 bb_vec_info bb_vinfo;
1639 slp_instance instance;
1641 gimple_stmt_iterator gsi;
1651 {
1656 insns++;
1657 }
1660 {
1666 }
1673 {
1680 }
1684 {
1691 }
1696 || (data_dependence_in_bb
1698 {
1705 }
1708 {
1715 }
1718 {
1725 }
1728 {
1735 }
1737 /* Check the SLP opportunities in the basic block, analyze and build SLP
1738 trees. */
1740 {
1747 }
1751 /* Mark all the statements that we want to vectorize as pure SLP and
1752 relevant. */
1754 {
1757 }
1760 {
1766 }
1768 /* Cost model: check if the vectorization is worthwhile. */
1771 {
1778 }
1784 }
1787 /* SLP costs are calculated according to SLP instance unrolling factor (i.e.,
1788 the number of created vector stmts depends on the unrolling factor).
1789 However, the actual number of vector stmts for every SLP node depends on
1790 VF which is set later in vect_analyze_operations (). Hence, SLP costs
1791 should be updated. In this function we assume that the inside costs
1792 calculated in vect_model_xxx_cost are linear in ncopies. */
1794 void
1796 {
1799 slp_instance instance;
1805 /* We assume that costs are linear in ncopies. */
1808 }
1811 /* For constant and loop invariant defs of SLP_NODE this function returns
1812 (vector) defs (VEC_OPRNDS) that will be used in the vectorized stmts.
1813 OP_NUM determines if we gather defs for operand 0 or operand 1 of the scalar
1814 stmts. NUMBER_OF_VECTORS is the number of vector defs to create.
1815 REDUC_INDEX is the index of the reduction operand in the statements, unless
1816 it is -1. */
1818 static void
1822 {
1827 tree vec_cst;
1830 tree vector_type;
1840 {
1843 {
1846 }
1850 /* For additional copies (see the explanation of NUMBER_OF_COPIES below)
1851 we need either neutral operands or the original operands. See
1852 get_initial_def_for_reduction() for details. */
1854 {
1863 else
1871 else
1882 }
1883 }
1886 {
1889 }
1890 else
1891 {
1894 }
1898 else
1906 /* NUMBER_OF_COPIES is the number of times we need to use the same values in
1907 created vectors. It is greater than 1 if unrolling is performed.
1909 For example, we have two scalar operands, s1 and s2 (e.g., group of
1910 strided accesses of size two), while NUNITS is four (i.e., four scalars
1911 of this type can be packed in a vector). The output vector will contain
1912 two copies of each scalar operand: {s1, s2, s1, s2}. (NUMBER_OF_COPIES
1913 will be 2).
1915 If GROUP_SIZE > NUNITS, the scalars will be split into several vectors
1916 containing the operands.
1918 For example, NUNITS is four as before, and the group size is 8
1919 (s1, s2, ..., s8). We will create two vectors {s1, s2, s3, s4} and
1920 {s5, s6, s7, s8}. */
1926 {
1928 {
1931 else
1935 {
1940 /* Get the def before the loop. */
1945 }
1947 /* Create 'vect_ = {op0,op1,...,opn}'. */
1950 number_of_places_left_in_vector--;
1953 {
1958 else
1963 }
1964 }
1965 }
1967 /* Since the vectors are created in the reverse order, we should invert
1968 them. */
1971 {
1974 }
1978 /* In case that VF is greater than the unrolling factor needed for the SLP
1979 group of stmts, NUMBER_OF_VECTORS to be created is greater than
1980 NUMBER_OF_SCALARS/NUNITS or NUNITS/NUMBER_OF_SCALARS, and hence we have
1981 to replicate the vectors. */
1983 {
1987 {
1989 {
1994 }
1997 }
1998 else
1999 {
2002 }
2003 }
2004 }
2007 /* Get vectorized definitions from SLP_NODE that contains corresponding
2008 vectorized def-stmts. */
2010 static void
2012 {
2013 tree vec_oprnd;
2014 gimple vec_def_stmt;
2020 {
2024 }
2025 }
2028 /* Get vectorized definitions for SLP_NODE.
2029 If the scalar definitions are loop invariants or constants, collect them and
2030 call vect_get_constant_vectors() to create vector stmts.
2031 Otherwise, the def-stmts must be already vectorized and the vectorized stmts
2032 must be stored in the LEFT/RIGHT node of SLP_NODE, and we call
2033 vect_get_slp_vect_defs() to retrieve them.
2034 If VEC_OPRNDS1 is NULL, don't get vector defs for the second operand (from
2035 the right node. This is used when the second operand must remain scalar. */
2037 void
2040 {
2041 gimple first_stmt;
2047 /* The number of vector defs is determined by the number of vector statements
2048 in the node from which we get those statements. */
2051 else
2052 {
2054 /* Number of vector stmts was calculated according to LHS in
2055 vect_schedule_slp_instance(), fix it by replacing LHS with RHS, if
2056 necessary. See vect_get_smallest_scalar_type () for details. */
2060 {
2063 }
2064 }
2066 /* Allocate memory for vectorized defs. */
2069 /* SLP_NODE corresponds either to a group of stores or to a group of
2070 unary/binary operations. We don't call this function for loads.
2071 For reduction defs we call vect_get_constant_vectors(), since we are
2072 looking for initial loop invariant values. */
2074 /* The defs are already vectorized. */
2076 else
2077 /* Build vectors from scalar defs. */
2079 reduc_index);
2082 /* Since we don't call this function with loads, this is a group of
2083 stores. */
2086 /* For reductions, we only need initial values. */
2094 /* The number of vector defs is determined by the number of vector statements
2095 in the node from which we get those statements. */
2098 else
2104 /* The defs are already vectorized. */
2106 else
2107 /* Build vectors from scalar defs. */
2109 }
2112 /* Create NCOPIES permutation statements using the mask MASK_BYTES (by
2113 building a vector of type MASK_TYPE from it) and two input vectors placed in
2114 DR_CHAIN at FIRST_VEC_INDX and SECOND_VEC_INDX for the first copy and
2115 shifting by STRIDE elements of DR_CHAIN for every copy.
2116 (STRIDE is the number of vectorized stmts for NODE divided by the number of
2117 copies).
2118 VECT_STMTS_COUNTER specifies the index in the vectorized stmts of NODE, where
2119 the created stmts must be inserted. */
2128 {
2129 tree perm_dest;
2131 stmt_vec_info next_stmt_info;
2137 /* Initialize the vect stmts of NODE to properly insert the generated
2138 stmts later. */
2145 {
2149 /* Generate the permute statement. */
2156 /* Store the vector statement in NODE. */
2162 }
2164 /* Mark the scalar stmt as vectorized. */
2167 }
2170 /* Given FIRST_MASK_ELEMENT - the mask element in element representation,
2171 return in CURRENT_MASK_ELEMENT its equivalent in target specific
2172 representation. Check that the mask is valid and return FALSE if not.
2173 Return TRUE in NEED_NEXT_VECTOR if the permutation requires to move to
2174 the next vector, i.e., the current first vector is not needed. */
2176 static bool
2181 {
2187 /* Convert to target specific representation. */
2189 /* Adjust the value in case it's a mask for second and third vectors. */
2195 /* We have only one input vector to permute but the mask accesses values in
2196 the next vector as well. */
2198 {
2200 {
2203 }
2206 }
2208 /* The mask requires the next vector. */
2210 {
2212 {
2213 /* We either need the first vector too or have already moved to the
2214 next vector. In both cases, this permutation needs three
2215 vectors. */
2217 {
2221 }
2224 }
2226 /* We move to the next vector, dropping the first one and working with
2227 the second and the third - we need to adjust the values of the mask
2228 accordingly. */
2236 }
2240 /* This was the last element of this mask. Start a new one. */
2242 {
2246 }
2249 }
2252 /* Generate vector permute statements from a list of loads in DR_CHAIN.
2253 If ANALYZE_ONLY is TRUE, only check that it is possible to create valid
2254 permute statements for SLP_NODE_INSTANCE. */
2255 bool
2259 {
2263 slp_tree node;
2265 gimple next_scalar_stmt;
2273 {
2275 {
2278 }
2281 }
2286 {
2288 {
2291 }
2294 }
2303 /* The number of vector stmts to generate based only on SLP_NODE_INSTANCE
2304 unrolling factor. */
2310 /* Number of copies is determined by the final vectorization factor
2311 relatively to SLP_NODE_INSTANCE unrolling factor. */
2314 /* Generate permutation masks for every NODE. Number of masks for each NODE
2315 is equal to GROUP_SIZE.
2316 E.g., we have a group of three nodes with three loads from the same
2317 location in each node, and the vector size is 4. I.e., we have a
2318 a0b0c0a1b1c1... sequence and we need to create the following vectors:
2319 for a's: a0a0a0a1 a1a1a2a2 a2a3a3a3
2320 for b's: b0b0b0b1 b1b1b2b2 b2b3b3b3
2321 ...
2323 The masks for a's should be: {0,0,0,3} {3,3,6,6} {6,9,9,9} (in target
2324 scpecific type, e.g., in bytes for Altivec.
2325 The last mask is illegal since we assume two operands for permute
2326 operation, and the mask element values can't be outside that range.
2327 Hence, the last mask must be converted into {2,5,5,5}.
2328 For the first two permutations we need the first and the second input
2329 vectors: {a0,b0,c0,a1} and {b1,c1,a2,b2}, and for the last permutation
2330 we need the second and the third vectors: {b1,c1,a2,b2} and
2331 {c2,a3,b3,c3}. */
2334 {
2342 else
2346 {
2348 {
2351 {
2358 }
2361 {
2365 {
2368 }
2373 mask_vec))
2374 {
2376 {
2379 }
2382 }
2385 {
2387 {
2390 }
2399 }
2400 }
2401 }
2402 }
2403 }
2407 }
2411 /* Vectorize SLP instance tree in postorder. */
2413 static bool
2416 {
2417 gimple stmt;
2419 gimple_stmt_iterator si;
2420 stmt_vec_info stmt_info;
2422 tree vectype;
2424 slp_tree loads_node;
2430 vectorization_factor);
2432 vectorization_factor);
2437 /* VECTYPE is the type of the destination. */
2442 /* For each SLP instance calculate number of vector stmts to be created
2443 for the scalar stmts in each node of the SLP tree. Number of vector
2444 elements in one vector iteration is the number of scalar elements in
2445 one scalar iteration (GROUP_SIZE) multiplied by VF divided by vector
2446 size. */
2449 /* In case of load permutation we have to allocate vectorized statements for
2450 all the nodes that participate in that permutation. */
2452 {
2454 {
2456 {
2458 vec_stmts_size);
2460 }
2461 }
2462 }
2465 {
2468 }
2471 {
2474 }
2476 /* Loads should be inserted before the first load. */
2481 else
2484 /* Stores should be inserted just before the last store. */
2487 {
2490 }
2494 }
2497 /* Generate vector code for all SLP instances in the loop/basic block. */
2499 bool
2501 {
2503 slp_instance instance;
2508 {
2511 }
2512 else
2513 {
2516 }
2519 {
2520 /* Schedule the tree of INSTANCE. */
2526 }
2529 {
2531 gimple store;
2533 gimple_stmt_iterator gsi;
2537 {
2541 /* Free the attached stmt_vec_info and remove the stmt. */
2545 }
2546 }
2549 }
2552 /* Vectorize the basic block. */
2554 void
2556 {
2558 gimple_stmt_iterator si;
2566 {
2568 stmt_vec_info stmt_info;
2571 {
2574 }
2579 /* Schedule all the SLP instances when the first SLP stmt is reached. */
2581 {
2584 }
2585 }
2588 /* The memory tags and pointers in vectorized statements need to
2589 have their SSA forms updated. FIXME, why can't this be delayed
2590 until all the loops have been transformed? */
2597 }