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1 /* Data References Analysis and Manipulation Utilities for Vectorization.
2 Copyright (C) 2003, 2004, 2005, 2006, 2007, 2008, 2009, 2010, 2011
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 /* Need to include rtl.h, expr.h, etc. for optabs. */
46 /* Return true if load- or store-lanes optab OPTAB is implemented for
47 COUNT vectors of type VECTYPE. NAME is the name of OPTAB. */
49 static bool
52 {
62 {
67 }
70 {
75 }
82 }
85 /* Return the smallest scalar part of STMT.
86 This is used to determine the vectype of the stmt. We generally set the
87 vectype according to the type of the result (lhs). For stmts whose
88 result-type is different than the type of the arguments (e.g., demotion,
89 promotion), vectype will be reset appropriately (later). Note that we have
90 to visit the smallest datatype in this function, because that determines the
91 VF. If the smallest datatype in the loop is present only as the rhs of a
92 promotion operation - we'd miss it.
93 Such a case, where a variable of this datatype does not appear in the lhs
94 anywhere in the loop, can only occur if it's an invariant: e.g.:
95 'int_x = (int) short_inv', which we'd expect to have been optimized away by
96 invariant motion. However, we cannot rely on invariant motion to always
97 take invariants out of the loop, and so in the case of promotion we also
98 have to check the rhs.
99 LHS_SIZE_UNIT and RHS_SIZE_UNIT contain the sizes of the corresponding
100 types. */
102 tree
105 {
115 {
121 }
126 }
129 /* Find the place of the data-ref in STMT in the interleaving chain that starts
130 from FIRST_STMT. Return -1 if the data-ref is not a part of the chain. */
132 int
134 {
142 {
143 result++;
145 }
149 else
151 }
154 /* Function vect_insert_into_interleaving_chain.
156 Insert DRA into the interleaving chain of DRB according to DRA's INIT. */
158 static void
161 {
163 tree next_init;
170 {
173 {
174 /* Insert here. */
178 }
181 }
183 /* We got to the end of the list. Insert here. */
186 }
189 /* Function vect_update_interleaving_chain.
191 For two data-refs DRA and DRB that are a part of a chain interleaved data
192 accesses, update the interleaving chain. DRB's INIT is smaller than DRA's.
194 There are four possible cases:
195 1. New stmts - both DRA and DRB are not a part of any chain:
196 FIRST_DR = DRB
197 NEXT_DR (DRB) = DRA
198 2. DRB is a part of a chain and DRA is not:
199 no need to update FIRST_DR
200 no need to insert DRB
201 insert DRA according to init
202 3. DRA is a part of a chain and DRB is not:
203 if (init of FIRST_DR > init of DRB)
204 FIRST_DR = DRB
205 NEXT(FIRST_DR) = previous FIRST_DR
206 else
207 insert DRB according to its init
208 4. both DRA and DRB are in some interleaving chains:
209 choose the chain with the smallest init of FIRST_DR
210 insert the nodes of the second chain into the first one. */
212 static void
215 {
220 tree node_init;
223 /* 1. New stmts - both DRA and DRB are not a part of any chain. */
225 {
230 }
232 /* 2. DRB is a part of a chain and DRA is not. */
234 {
236 /* Insert DRA into the chain of DRB. */
239 }
241 /* 3. DRA is a part of a chain and DRB is not. */
243 {
246 old_first_stmt)));
247 gimple tmp;
250 {
251 /* DRB's init is smaller than the init of the stmt previously marked
252 as the first stmt of the interleaving chain of DRA. Therefore, we
253 update FIRST_STMT and put DRB in the head of the list. */
257 /* Update all the stmts in the list to point to the new FIRST_STMT. */
260 {
263 }
264 }
265 else
266 {
267 /* Insert DRB in the list of DRA. */
270 }
272 }
274 /* 4. both DRA and DRB are in some interleaving chains. */
283 {
284 /* Insert the nodes of DRA chain into the DRB chain.
285 After inserting a node, continue from this node of the DRB chain (don't
286 start from the beginning. */
290 }
291 else
292 {
293 /* Insert the nodes of DRB chain into the DRA chain.
294 After inserting a node, continue from this node of the DRA chain (don't
295 start from the beginning. */
299 }
302 {
306 {
309 {
310 /* Insert here. */
315 }
318 }
320 {
321 /* We got to the end of the list. Insert here. */
325 }
328 }
329 }
331 /* Check dependence between DRA and DRB for basic block vectorization.
332 If the accesses share same bases and offsets, we can compare their initial
333 constant offsets to decide whether they differ or not. In case of a read-
334 write dependence we check that the load is before the store to ensure that
335 vectorization will not change the order of the accesses. */
337 static bool
340 {
342 gimple earlier_stmt;
344 /* We only call this function for pairs of loads and stores, but we verify
345 it here. */
347 {
350 else
352 }
354 /* Check that the data-refs have same bases and offsets. If not, we can't
355 determine if they are dependent. */
360 /* Check the types. */
372 /* Two different locations - no dependence. */
376 /* We have a read-write dependence. Check that the load is before the store.
377 When we vectorize basic blocks, vector load can be only before
378 corresponding scalar load, and vector store can be only after its
379 corresponding scalar store. So the order of the acceses is preserved in
380 case the load is before the store. */
386 }
389 /* Function vect_check_interleaving.
391 Check if DRA and DRB are a part of interleaving. In case they are, insert
392 DRA and DRB in an interleaving chain. */
394 static bool
397 {
400 /* Check that the data-refs have same first location (except init) and they
401 are both either store or load (not load and store). */
408 /* Check:
409 1. data-refs are of the same type
410 2. their steps are equal
411 3. the step (if greater than zero) is greater than the difference between
412 data-refs' inits. */
427 {
428 /* If init_a == init_b + the size of the type * k, we have an interleaving,
429 and DRB is accessed before DRA. */
436 {
439 {
444 }
446 }
447 }
448 else
449 {
450 /* If init_b == init_a + the size of the type * k, we have an
451 interleaving, and DRA is accessed before DRB. */
458 {
461 {
466 }
468 }
469 }
472 }
474 /* Check if data references pointed by DR_I and DR_J are same or
475 belong to same interleaving group. Return FALSE if drs are
476 different, otherwise return TRUE. */
478 static bool
480 {
490 else
492 }
494 /* If address ranges represented by DDR_I and DDR_J are equal,
495 return TRUE, otherwise return FALSE. */
497 static bool
499 {
505 else
507 }
509 /* Insert DDR into LOOP_VINFO list of ddrs that may alias and need to be
510 tested at run-time. Return TRUE if DDR was successfully inserted.
511 Return false if versioning is not supported. */
513 static bool
515 {
522 {
527 }
530 {
534 }
536 /* FORNOW: We don't support versioning with outer-loop vectorization. */
538 {
542 }
546 }
549 /* Function vect_analyze_data_ref_dependence.
551 Return TRUE if there (might) exist a dependence between a memory-reference
552 DRA and a memory-reference DRB. When versioning for alias may check a
553 dependence at run-time, return FALSE. Adjust *MAX_VF according to
554 the data dependence. */
556 static bool
560 {
567 lambda_vector dist_v;
570 /* Don't bother to analyze statements marked as unvectorizable. */
576 {
577 /* Independent data accesses. */
580 }
589 {
591 {
593 {
599 }
601 /* Add to list of ddrs that need to be tested at run-time. */
603 }
605 /* When vectorizing a basic block unknown depnedence can still mean
606 strided access. */
611 {
616 }
618 /* We do not vectorize basic blocks with write-write dependencies. */
622 /* We deal with read-write dependencies in basic blocks later (by
623 verifying that all the loads in the basic block are before all the
624 stores). */
627 }
629 /* Versioning for alias is not yet supported for basic block SLP, and
630 dependence distance is unapplicable, hence, in case of known data
631 dependence, basic block vectorization is impossible for now. */
633 {
638 {
643 }
645 /* Do not vectorize basic blcoks with write-write dependences. */
649 /* Check if this dependence is allowed in basic block vectorization. */
651 }
653 /* Loop-based vectorization and known data dependence. */
655 {
657 {
662 }
663 /* Add to list of ddrs that need to be tested at run-time. */
665 }
669 {
676 {
678 {
683 }
685 /* For interleaving, mark that there is a read-write dependency if
686 necessary. We check before that one of the data-refs is store. */
689 else
690 {
693 }
696 }
699 {
700 /* If DDR_REVERSED_P the order of the data-refs in DDR was
701 reversed (to make distance vector positive), and the actual
702 distance is negative. */
706 }
710 {
711 /* The dependence distance requires reduction of the maximal
712 vectorization factor. */
717 }
720 {
721 /* Dependence distance does not create dependence, as far as
722 vectorization is concerned, in this case. */
726 }
729 {
735 }
738 }
741 }
743 /* Function vect_analyze_data_ref_dependences.
745 Examine all the data references in the loop, and make sure there do not
746 exist any data dependences between them. Set *MAX_VF according to
747 the maximum vectorization factor the data dependences allow. */
749 bool
753 {
763 else
768 data_dependence_in_bb))
772 }
775 /* Function vect_compute_data_ref_alignment
777 Compute the misalignment of the data reference DR.
779 Output:
780 1. If during the misalignment computation it is found that the data reference
781 cannot be vectorized then false is returned.
782 2. DR_MISALIGNMENT (DR) is defined.
784 FOR NOW: No analysis is actually performed. Misalignment is calculated
785 only for trivial cases. TODO. */
787 static bool
789 {
795 tree vectype;
798 tree misalign;
807 /* Initialize misalignment to unknown. */
815 /* In case the dataref is in an inner-loop of the loop that is being
816 vectorized (LOOP), we use the base and misalignment information
817 relative to the outer-loop (LOOP). This is ok only if the misalignment
818 stays the same throughout the execution of the inner-loop, which is why
819 we have to check that the stride of the dataref in the inner-loop evenly
820 divides by the vector size. */
822 {
827 {
833 }
834 else
835 {
839 }
840 }
847 {
849 {
852 }
854 }
864 else
868 {
869 /* Do not change the alignment of global variables if
870 flag_section_anchors is enabled. */
873 {
875 {
878 }
880 }
882 /* Force the alignment of the decl.
883 NOTE: This is the only change to the code we make during
884 the analysis phase, before deciding to vectorize the loop. */
886 {
889 }
893 }
895 /* At this point we assume that the base is aligned. */
900 /* If this is a backward running DR then first access in the larger
901 vectype actually is N-1 elements before the address in the DR.
902 Adjust misalign accordingly. */
904 {
906 /* DR_STEP(dr) is the same as -TYPE_SIZE of the scalar type,
907 otherwise we wouldn't be here. */
909 /* PLUS because DR_STEP was negative. */
911 }
913 /* Modulo alignment. */
917 {
918 /* Negative or overflowed misalignment value. */
922 }
927 {
930 }
933 }
936 /* Function vect_compute_data_refs_alignment
938 Compute the misalignment of data references in the loop.
939 Return FALSE if a data reference is found that cannot be vectorized. */
941 static bool
943 bb_vec_info bb_vinfo)
944 {
951 else
957 {
959 {
960 /* Mark unsupported statement as unvectorizable. */
963 }
964 else
966 }
969 }
972 /* Function vect_update_misalignment_for_peel
974 DR - the data reference whose misalignment is to be adjusted.
975 DR_PEEL - the data reference whose misalignment is being made
976 zero in the vector loop by the peel.
977 NPEEL - the number of iterations in the peel loop if the misalignment
978 of DR_PEEL is known at compile time. */
980 static void
983 {
992 /* For interleaved data accesses the step in the loop must be multiplied by
993 the size of the interleaving group. */
999 /* It can be assumed that the data refs with the same alignment as dr_peel
1000 are aligned in the vector loop. */
1001 same_align_drs
1004 {
1011 }
1015 {
1023 }
1028 }
1031 /* Function vect_verify_datarefs_alignment
1033 Return TRUE if all data references in the loop can be
1034 handled with respect to alignment. */
1036 bool
1038 {
1046 else
1050 {
1054 /* For interleaving, only the alignment of the first access matters.
1055 Skip statements marked as not vectorizable. */
1063 {
1065 {
1069 else
1074 }
1076 }
1080 }
1082 }
1085 /* Function vector_alignment_reachable_p
1087 Return true if vector alignment for DR is reachable by peeling
1088 a few loop iterations. Return false otherwise. */
1090 static bool
1092 {
1098 {
1099 /* For interleaved access we peel only if number of iterations in
1100 the prolog loop ({VF - misalignment}), is a multiple of the
1101 number of the interleaved accesses. */
1105 /* FORNOW: handle only known alignment. */
1114 }
1116 /* If misalignment is known at the compile time then allow peeling
1117 only if natural alignment is reachable through peeling. */
1119 {
1120 HOST_WIDE_INT elmsize =
1123 {
1126 }
1128 {
1132 }
1133 }
1136 {
1151 else
1153 }
1156 }
1159 /* Calculate the cost of the memory access represented by DR. */
1161 static void
1165 {
1176 else
1177 {
1180 else
1182 }
1187 }
1190 static hashval_t
1192 {
1197 }
1200 static int
1202 {
1208 }
1211 /* Insert DR into peeling hash table with NPEEL as key. */
1213 static void
1216 {
1226 else
1227 {
1233 INSERT);
1235 }
1239 }
1242 /* Traverse peeling hash table to find peeling option that aligns maximum
1243 number of data accesses. */
1245 static int
1247 {
1252 {
1256 }
1259 }
1262 /* Traverse peeling hash table and calculate cost for each peeling option.
1263 Find the one with the lowest cost. */
1265 static int
1267 {
1279 {
1282 /* For interleaving, only the alignment of the first access
1283 matters. */
1292 }
1299 {
1304 }
1307 }
1310 /* Choose best peeling option by traversing peeling hash table and either
1311 choosing an option with the lowest cost (if cost model is enabled) or the
1312 option that aligns as many accesses as possible. */
1317 {
1323 {
1328 }
1329 else
1330 {
1334 }
1338 }
1341 /* Function vect_enhance_data_refs_alignment
1343 This pass will use loop versioning and loop peeling in order to enhance
1344 the alignment of data references in the loop.
1346 FOR NOW: we assume that whatever versioning/peeling takes place, only the
1347 original loop is to be vectorized. Any other loops that are created by
1348 the transformations performed in this pass - are not supposed to be
1349 vectorized. This restriction will be relaxed.
1351 This pass will require a cost model to guide it whether to apply peeling
1352 or versioning or a combination of the two. For example, the scheme that
1353 intel uses when given a loop with several memory accesses, is as follows:
1354 choose one memory access ('p') which alignment you want to force by doing
1355 peeling. Then, either (1) generate a loop in which 'p' is aligned and all
1356 other accesses are not necessarily aligned, or (2) use loop versioning to
1357 generate one loop in which all accesses are aligned, and another loop in
1358 which only 'p' is necessarily aligned.
1360 ("Automatic Intra-Register Vectorization for the Intel Architecture",
1361 Aart J.C. Bik, Milind Girkar, Paul M. Grey and Ximmin Tian, International
1362 Journal of Parallel Programming, Vol. 30, No. 2, April 2002.)
1364 Devising a cost model is the most critical aspect of this work. It will
1365 guide us on which access to peel for, whether to use loop versioning, how
1366 many versions to create, etc. The cost model will probably consist of
1367 generic considerations as well as target specific considerations (on
1368 powerpc for example, misaligned stores are more painful than misaligned
1369 loads).
1371 Here are the general steps involved in alignment enhancements:
1373 -- original loop, before alignment analysis:
1374 for (i=0; i<N; i++){
1375 x = q[i]; # DR_MISALIGNMENT(q) = unknown
1376 p[i] = y; # DR_MISALIGNMENT(p) = unknown
1377 }
1379 -- After vect_compute_data_refs_alignment:
1380 for (i=0; i<N; i++){
1381 x = q[i]; # DR_MISALIGNMENT(q) = 3
1382 p[i] = y; # DR_MISALIGNMENT(p) = unknown
1383 }
1385 -- Possibility 1: we do loop versioning:
1386 if (p is aligned) {
1387 for (i=0; i<N; i++){ # loop 1A
1388 x = q[i]; # DR_MISALIGNMENT(q) = 3
1389 p[i] = y; # DR_MISALIGNMENT(p) = 0
1390 }
1391 }
1392 else {
1393 for (i=0; i<N; i++){ # loop 1B
1394 x = q[i]; # DR_MISALIGNMENT(q) = 3
1395 p[i] = y; # DR_MISALIGNMENT(p) = unaligned
1396 }
1397 }
1399 -- Possibility 2: we do loop peeling:
1400 for (i = 0; i < 3; i++){ # (scalar loop, not to be vectorized).
1401 x = q[i];
1402 p[i] = y;
1403 }
1404 for (i = 3; i < N; i++){ # loop 2A
1405 x = q[i]; # DR_MISALIGNMENT(q) = 0
1406 p[i] = y; # DR_MISALIGNMENT(p) = unknown
1407 }
1409 -- Possibility 3: combination of loop peeling and versioning:
1410 for (i = 0; i < 3; i++){ # (scalar loop, not to be vectorized).
1411 x = q[i];
1412 p[i] = y;
1413 }
1414 if (p is aligned) {
1415 for (i = 3; i<N; i++){ # loop 3A
1416 x = q[i]; # DR_MISALIGNMENT(q) = 0
1417 p[i] = y; # DR_MISALIGNMENT(p) = 0
1418 }
1419 }
1420 else {
1421 for (i = 3; i<N; i++){ # loop 3B
1422 x = q[i]; # DR_MISALIGNMENT(q) = 0
1423 p[i] = y; # DR_MISALIGNMENT(p) = unaligned
1424 }
1425 }
1427 These loops are later passed to loop_transform to be vectorized. The
1428 vectorizer will use the alignment information to guide the transformation
1429 (whether to generate regular loads/stores, or with special handling for
1430 misalignment). */
1432 bool
1434 {
1444 gimple stmt;
1445 stmt_vec_info stmt_info;
1451 tree vectype;
1457 /* While cost model enhancements are expected in the future, the high level
1458 view of the code at this time is as follows:
1460 A) If there is a misaligned access then see if peeling to align
1461 this access can make all data references satisfy
1462 vect_supportable_dr_alignment. If so, update data structures
1463 as needed and return true.
1465 B) If peeling wasn't possible and there is a data reference with an
1466 unknown misalignment that does not satisfy vect_supportable_dr_alignment
1467 then see if loop versioning checks can be used to make all data
1468 references satisfy vect_supportable_dr_alignment. If so, update
1469 data structures as needed and return true.
1471 C) If neither peeling nor versioning were successful then return false if
1472 any data reference does not satisfy vect_supportable_dr_alignment.
1474 D) Return true (all data references satisfy vect_supportable_dr_alignment).
1476 Note, Possibility 3 above (which is peeling and versioning together) is not
1477 being done at this time. */
1479 /* (1) Peeling to force alignment. */
1481 /* (1.1) Decide whether to perform peeling, and how many iterations to peel:
1482 Considerations:
1483 + How many accesses will become aligned due to the peeling
1484 - How many accesses will become unaligned due to the peeling,
1485 and the cost of misaligned accesses.
1486 - The cost of peeling (the extra runtime checks, the increase
1487 in code size). */
1490 {
1494 /* For interleaving, only the alignment of the first access
1495 matters. */
1503 {
1505 {
1510 /* Save info about DR in the hash table. */
1520 npeel_tmp = (negative
1524 /* For multiple types, it is possible that the bigger type access
1525 will have more than one peeling option. E.g., a loop with two
1526 types: one of size (vector size / 4), and the other one of
1527 size (vector size / 8). Vectorization factor will 8. If both
1528 access are misaligned by 3, the first one needs one scalar
1529 iteration to be aligned, and the second one needs 5. But the
1530 the first one will be aligned also by peeling 5 scalar
1531 iterations, and in that case both accesses will be aligned.
1532 Hence, except for the immediate peeling amount, we also want
1533 to try to add full vector size, while we don't exceed
1534 vectorization factor.
1535 We do this automtically for cost model, since we calculate cost
1536 for every peeling option. */
1540 /* Handle the aligned case. We may decide to align some other
1541 access, making DR unaligned. */
1543 {
1546 possible_npeel_number++;
1547 }
1550 {
1554 }
1557 /* Data-ref that was chosen for the case that all the
1558 misalignments are unknown is not relevant anymore, since we
1559 have a data-ref with known alignment. */
1561 }
1562 else
1563 {
1564 /* If we don't know all the misalignment values, we prefer
1565 peeling for data-ref that has maximum number of data-refs
1566 with the same alignment, unless the target prefers to align
1567 stores over load. */
1569 {
1573 {
1577 }
1581 }
1583 /* If there are both known and unknown misaligned accesses in the
1584 loop, we choose peeling amount according to the known
1585 accesses. */
1589 {
1593 }
1594 }
1595 }
1596 else
1597 {
1599 {
1604 }
1605 }
1606 }
1608 vect_versioning_for_alias_required
1611 /* Temporarily, if versioning for alias is required, we disable peeling
1612 until we support peeling and versioning. Often peeling for alignment
1613 will require peeling for loop-bound, which in turn requires that we
1614 know how to adjust the loop ivs after the loop. */
1622 {
1624 /* Check if the target requires to prefer stores over loads, i.e., if
1625 misaligned stores are more expensive than misaligned loads (taking
1626 drs with same alignment into account). */
1628 {
1639 /* Calculate the penalty for leaving FIRST_STORE unaligned (by
1640 aligning the load DR0). */
1646 i++)
1648 {
1651 }
1652 else
1653 {
1656 }
1658 /* Calculate the penalty for leaving DR0 unaligned (by
1659 aligning the FIRST_STORE). */
1665 i++)
1667 {
1670 }
1671 else
1672 {
1675 }
1681 }
1683 /* In case there are only loads with different unknown misalignments, use
1684 peeling only if it may help to align other accesses in the loop. */
1690 }
1693 {
1694 /* Peeling is possible, but there is no data access that is not supported
1695 unless aligned. So we try to choose the best possible peeling. */
1697 /* We should get here only if there are drs with known misalignment. */
1700 /* Choose the best peeling from the hash table. */
1704 }
1707 {
1714 {
1718 {
1719 /* Since it's known at compile time, compute the number of
1720 iterations in the peeled loop (the peeling factor) for use in
1721 updating DR_MISALIGNMENT values. The peeling factor is the
1722 vectorization factor minus the misalignment as an element
1723 count. */
1728 }
1730 /* For interleaved data access every iteration accesses all the
1731 members of the group, therefore we divide the number of iterations
1732 by the group size. */
1739 }
1741 /* Ensure that all data refs can be vectorized after the peel. */
1743 {
1751 /* For interleaving, only the alignment of the first access
1752 matters. */
1763 {
1766 }
1767 }
1770 {
1774 else
1776 }
1779 {
1780 /* (1.2) Update the DR_MISALIGNMENT of each data reference DR_i.
1781 If the misalignment of DR_i is identical to that of dr0 then set
1782 DR_MISALIGNMENT (DR_i) to zero. If the misalignment of DR_i and
1783 dr0 are known at compile time then increment DR_MISALIGNMENT (DR_i)
1784 by the peeling factor times the element size of DR_i (MOD the
1785 vectorization factor times the size). Otherwise, the
1786 misalignment of DR_i must be set to unknown. */
1794 else
1806 }
1807 }
1810 /* (2) Versioning to force alignment. */
1812 /* Try versioning if:
1813 1) flag_tree_vect_loop_version is TRUE
1814 2) optimize loop for speed
1815 3) there is at least one unsupported misaligned data ref with an unknown
1816 misalignment, and
1817 4) all misaligned data refs with a known misalignment are supported, and
1818 5) the number of runtime alignment checks is within reason. */
1820 do_versioning =
1821 flag_tree_vect_loop_version
1826 {
1828 {
1832 /* For interleaving, only the alignment of the first access
1833 matters. */
1842 {
1843 gimple stmt;
1845 tree vectype;
1851 {
1854 }
1860 /* The rightmost bits of an aligned address must be zeros.
1861 Construct the mask needed for this test. For example,
1862 GET_MODE_SIZE for the vector mode V4SI is 16 bytes so the
1863 mask must be 15 = 0xf. */
1866 /* FORNOW: use the same mask to test all potentially unaligned
1867 references in the loop. The vectorizer currently supports
1868 a single vector size, see the reference to
1869 GET_MODE_NUNITS (TYPE_MODE (vectype)) where the
1870 vectorization factor is computed. */
1877 }
1878 }
1880 /* Versioning requires at least one misaligned data reference. */
1885 }
1888 {
1891 gimple stmt;
1893 /* It can now be assumed that the data references in the statements
1894 in LOOP_VINFO_MAY_MISALIGN_STMTS will be aligned in the version
1895 of the loop being vectorized. */
1897 {
1903 }
1908 /* Peeling and versioning can't be done together at this time. */
1914 }
1916 /* This point is reached if neither peeling nor versioning is being done. */
1921 }
1924 /* Function vect_find_same_alignment_drs.
1926 Update group and alignment relations according to the chosen
1927 vectorization factor. */
1929 static void
1931 loop_vec_info loop_vinfo)
1932 {
1942 lambda_vector dist_v;
1954 /* Loop-based vectorization and known data dependence. */
1958 /* Data-dependence analysis reports a distance vector of zero
1959 for data-references that overlap only in the first iteration
1960 but have different sign step (see PR45764).
1961 So as a sanity check require equal DR_STEP. */
1967 {
1973 /* Same loop iteration. */
1976 {
1977 /* Two references with distance zero have the same alignment. */
1983 {
1988 }
1989 }
1990 }
1991 }
1994 /* Function vect_analyze_data_refs_alignment
1996 Analyze the alignment of the data-references in the loop.
1997 Return FALSE if a data reference is found that cannot be vectorized. */
1999 bool
2001 bb_vec_info bb_vinfo)
2002 {
2006 /* Mark groups of data references with same alignment using
2007 data dependence information. */
2009 {
2016 }
2019 {
2024 }
2027 }
2030 /* Analyze groups of strided accesses: check that DR belongs to a group of
2031 strided accesses of legal size, step, etc. Detect gaps, single element
2032 interleaving, and other special cases. Set strided access info.
2033 Collect groups of strided stores for further use in SLP analysis. */
2035 static bool
2037 {
2046 HOST_WIDE_INT stride;
2049 /* For interleaving, STRIDE is STEP counted in elements, i.e., the size of the
2050 interleaving group (including gaps). */
2053 /* Not consecutive access is possible only if it is a part of interleaving. */
2055 {
2056 /* Check if it this DR is a part of interleaving, and is a single
2057 element of the group that is accessed in the loop. */
2059 /* Gaps are supported only for loads. STEP must be a multiple of the type
2060 size. The size of the group must be a power of 2. */
2065 {
2069 {
2074 }
2076 }
2079 {
2082 }
2085 {
2086 /* Mark the statement as unvectorizable. */
2089 }
2092 }
2095 {
2096 /* First stmt in the interleaving chain. Check the chain. */
2100 tree next_step;
2106 {
2107 /* Skip same data-refs. In case that two or more stmts share
2108 data-ref (supported only for loads), we vectorize only the first
2109 stmt, and the rest get their vectorized loads from the first
2110 one. */
2114 {
2116 {
2120 }
2122 /* Check that there is no load-store dependencies for this loads
2123 to prevent a case of load-store-load to the same location. */
2126 {
2131 }
2133 /* For load use the same data-ref load. */
2139 }
2142 /* Check that all the accesses have the same STEP. */
2145 {
2149 }
2152 /* Check that the distance between two accesses is equal to the type
2153 size. Otherwise, we have gaps. */
2157 {
2158 /* FORNOW: SLP of accesses with gaps is not supported. */
2161 {
2165 }
2168 }
2170 /* Store the gap from the previous member of the group. If there is no
2171 gap in the access, GROUP_GAP is always 1. */
2176 /* Count the number of data-refs in the chain. */
2177 count++;
2178 }
2180 /* COUNT is the number of accesses found, we multiply it by the size of
2181 the type to get COUNT_IN_BYTES. */
2184 /* Check that the size of the interleaving (including gaps) is not
2185 greater than STEP. */
2187 {
2189 {
2192 }
2194 }
2196 /* Check that the size of the interleaving is equal to STEP for stores,
2197 i.e., that there are no gaps. */
2199 {
2201 {
2203 /* There is a gap after the last load in the group. This gap is a
2204 difference between the stride and the number of elements. When
2205 there is no gap, this difference should be 0. */
2207 }
2208 else
2209 {
2213 }
2214 }
2216 /* Check that STEP is a multiple of type size. */
2218 {
2220 {
2225 TDF_SLIM);
2226 }
2228 }
2237 /* SLP: create an SLP data structure for every interleaving group of
2238 stores for further analysis in vect_analyse_slp. */
2240 {
2243 stmt);
2246 stmt);
2247 }
2248 }
2251 }
2254 /* Analyze the access pattern of the data-reference DR.
2255 In case of non-consecutive accesses call vect_analyze_group_access() to
2256 analyze groups of strided accesses. */
2258 static bool
2260 {
2273 {
2277 }
2279 /* Don't allow invariant accesses in loops. */
2284 {
2285 /* Interleaved accesses are not yet supported within outer-loop
2286 vectorization for references in the inner-loop. */
2289 /* For the rest of the analysis we use the outer-loop step. */
2294 {
2299 else
2301 }
2302 }
2304 /* Consecutive? */
2308 {
2309 /* Mark that it is not interleaving. */
2312 }
2315 {
2319 }
2321 /* Not consecutive access - check if it's a part of interleaving group. */
2323 }
2326 /* Function vect_analyze_data_ref_accesses.
2328 Analyze the access pattern of all the data references in the loop.
2330 FORNOW: the only access pattern that is considered vectorizable is a
2331 simple step 1 (consecutive) access.
2333 FORNOW: handle only arrays and pointer accesses. */
2335 bool
2337 {
2347 else
2353 {
2358 {
2359 /* Mark the statement as not vectorizable. */
2362 }
2363 else
2365 }
2368 }
2370 /* Function vect_prune_runtime_alias_test_list.
2372 Prune a list of ddrs to be tested at run-time by versioning for alias.
2373 Return FALSE if resulting list of ddrs is longer then allowed by
2374 PARAM_VECT_MAX_VERSION_FOR_ALIAS_CHECKS, otherwise return TRUE. */
2376 bool
2378 {
2387 {
2389 ddr_p ddr_i;
2395 {
2399 {
2401 {
2410 }
2413 }
2414 }
2417 {
2420 }
2421 i++;
2422 }
2426 {
2428 {
2430 "disable versioning for alias - max number of generated "
2432 }
2437 }
2440 }
2443 /* Function vect_analyze_data_refs.
2445 Find all the data references in the loop or basic block.
2447 The general structure of the analysis of data refs in the vectorizer is as
2448 follows:
2449 1- vect_analyze_data_refs(loop/bb): call
2450 compute_data_dependences_for_loop/bb to find and analyze all data-refs
2451 in the loop/bb and their dependences.
2452 2- vect_analyze_dependences(): apply dependence testing using ddrs.
2453 3- vect_analyze_drs_alignment(): check that ref_stmt.alignment is ok.
2454 4- vect_analyze_drs_access(): check that ref_stmt.step is ok.
2456 */
2458 bool
2460 bb_vec_info bb_vinfo,
2462 {
2468 tree scalar_type;
2475 {
2477 res = compute_data_dependences_for_loop
2484 {
2489 }
2492 }
2493 else
2494 {
2500 {
2505 }
2508 }
2510 /* Go through the data-refs, check that the analysis succeeded. Update
2511 pointer from stmt_vec_info struct to DR and vectype. */
2514 {
2515 gimple stmt;
2516 stmt_vec_info stmt_info;
2521 {
2525 }
2530 /* Check that analysis of the data-ref succeeded. */
2533 {
2535 {
2538 }
2541 {
2542 /* Mark the statement as not vectorizable. */
2545 }
2546 else
2548 }
2551 {
2556 {
2557 /* Mark the statement as not vectorizable. */
2560 }
2561 else
2563 }
2570 {
2572 {
2576 }
2578 }
2580 /* Update DR field in stmt_vec_info struct. */
2582 /* If the dataref is in an inner-loop of the loop that is considered for
2583 for vectorization, we also want to analyze the access relative to
2584 the outer-loop (DR contains information only relative to the
2585 inner-most enclosing loop). We do that by building a reference to the
2586 first location accessed by the inner-loop, and analyze it relative to
2587 the outer-loop. */
2589 {
2592 tree poffset;
2596 tree dinit;
2598 /* Build a reference to the first location accessed by the
2599 inner-loop: *(BASE+INIT). (The first location is actually
2600 BASE+INIT+OFFSET, but we add OFFSET separately later). */
2601 tree inner_base = build_fold_indirect_ref
2607 {
2610 }
2617 {
2621 }
2626 {
2630 }
2633 {
2636 poffset);
2637 else
2639 }
2642 {
2645 }
2648 {
2652 }
2665 /* FIXME: Use canonicalize_base_object_address (base_iv.base); */
2674 {
2685 }
2686 }
2689 {
2691 {
2695 }
2697 }
2701 /* Set vectype for STMT. */
2706 {
2708 {
2714 }
2717 {
2718 /* Mark the statement as not vectorizable. */
2721 }
2722 else
2724 }
2726 /* Adjust the minimal vectorization factor according to the
2727 vector type. */
2731 }
2734 }
2737 /* Function vect_get_new_vect_var.
2739 Returns a name for a new variable. The current naming scheme appends the
2740 prefix "vect_" or "vect_p" (depending on the value of VAR_KIND) to
2741 the name of vectorizer generated variables, and appends that to NAME if
2742 provided. */
2744 tree
2746 {
2748 tree new_vect_var;
2751 {
2763 }
2766 {
2770 }
2771 else
2774 /* Mark vector typed variable as a gimple register variable. */
2779 }
2782 /* Function vect_create_addr_base_for_vector_ref.
2784 Create an expression that computes the address of the first memory location
2785 that will be accessed for a data reference.
2787 Input:
2788 STMT: The statement containing the data reference.
2789 NEW_STMT_LIST: Must be initialized to NULL_TREE or a statement list.
2790 OFFSET: Optional. If supplied, it is be added to the initial address.
2791 LOOP: Specify relative to which loop-nest should the address be computed.
2792 For example, when the dataref is in an inner-loop nested in an
2793 outer-loop that is now being vectorized, LOOP can be either the
2794 outer-loop, or the inner-loop. The first memory location accessed
2795 by the following dataref ('in' points to short):
2797 for (i=0; i<N; i++)
2798 for (j=0; j<M; j++)
2799 s += in[i+j]
2801 is as follows:
2802 if LOOP=i_loop: &in (relative to i_loop)
2803 if LOOP=j_loop: &in+i*2B (relative to j_loop)
2805 Output:
2806 1. Return an SSA_NAME whose value is the address of the memory location of
2807 the first vector of the data reference.
2808 2. If new_stmt_list is not NULL_TREE after return then the caller must insert
2809 these statement(s) which define the returned SSA_NAME.
2811 FORNOW: We are only handling array accesses with step 1. */
2813 tree
2816 tree offset,
2818 {
2822 tree base_name;
2823 tree data_ref_base_var;
2824 tree vec_stmt;
2826 tree dest;
2830 tree vect_ptr_type;
2833 tree base;
2836 {
2844 }
2848 else
2849 {
2853 }
2858 data_ref_base_var);
2861 /* Create base_offset */
2871 {
2881 }
2883 /* base + base_offset */
2887 else
2888 {
2892 }
2898 vect_ptr_type
2911 {
2914 {
2917 }
2918 }
2921 {
2924 }
2927 }
2930 /* Function vect_create_data_ref_ptr.
2932 Create a new pointer-to-AGGR_TYPE variable (ap), that points to the first
2933 location accessed in the loop by STMT, along with the def-use update
2934 chain to appropriately advance the pointer through the loop iterations.
2935 Also set aliasing information for the pointer. This pointer is used by
2936 the callers to this function to create a memory reference expression for
2937 vector load/store access.
2939 Input:
2940 1. STMT: a stmt that references memory. Expected to be of the form
2941 GIMPLE_ASSIGN <name, data-ref> or
2942 GIMPLE_ASSIGN <data-ref, name>.
2943 2. AGGR_TYPE: the type of the reference, which should be either a vector
2944 or an array.
2945 3. AT_LOOP: the loop where the vector memref is to be created.
2946 4. OFFSET (optional): an offset to be added to the initial address accessed
2947 by the data-ref in STMT.
2948 5. BSI: location where the new stmts are to be placed if there is no loop
2949 6. ONLY_INIT: indicate if ap is to be updated in the loop, or remain
2950 pointing to the initial address.
2952 Output:
2953 1. Declare a new ptr to vector_type, and have it point to the base of the
2954 data reference (initial addressed accessed by the data reference).
2955 For example, for vector of type V8HI, the following code is generated:
2957 v8hi *ap;
2958 ap = (v8hi *)initial_address;
2960 if OFFSET is not supplied:
2961 initial_address = &a[init];
2962 if OFFSET is supplied:
2963 initial_address = &a[init + OFFSET];
2965 Return the initial_address in INITIAL_ADDRESS.
2967 2. If ONLY_INIT is true, just return the initial pointer. Otherwise, also
2968 update the pointer in each iteration of the loop.
2970 Return the increment stmt that updates the pointer in PTR_INCR.
2972 3. Set INV_P to true if the access pattern of the data reference in the
2973 vectorized loop is invariant. Set it to false otherwise.
2975 4. Return the pointer. */
2977 tree
2982 {
2983 tree base_name;
2989 tree aggr_ptr_type;
2990 tree aggr_ptr;
2991 tree new_temp;
2992 gimple vec_stmt;
2995 basic_block new_bb;
2996 tree aggr_ptr_init;
2998 tree aptr;
2999 gimple_stmt_iterator incr_gsi;
3003 gimple incr;
3004 tree step;
3006 tree base;
3012 {
3017 }
3018 else
3019 {
3023 }
3025 /* Check the step (evolution) of the load in LOOP, and record
3026 whether it's invariant. */
3029 else
3034 else
3038 /* Create an expression for the first address accessed by this load
3039 in LOOP. */
3043 {
3056 }
3058 /* (1) Create the new aggregate-pointer variable. */
3063 aggr_ptr_type
3069 /* Vector and array types inherit the alias set of their component
3070 type by default so we need to use a ref-all pointer if the data
3071 reference does not conflict with the created aggregated data
3072 reference because it is not addressable. */
3075 {
3076 aggr_ptr_type
3081 }
3083 /* Likewise for any of the data references in the stmt group. */
3085 {
3087 do
3088 {
3092 {
3093 aggr_ptr_type
3096 aggr_ptr
3100 }
3103 }
3105 }
3109 /* Note: If the dataref is in an inner-loop nested in LOOP, and we are
3110 vectorizing LOOP (i.e., outer-loop vectorization), we need to create two
3111 def-use update cycles for the pointer: one relative to the outer-loop
3112 (LOOP), which is what steps (3) and (4) below do. The other is relative
3113 to the inner-loop (which is the inner-most loop containing the dataref),
3114 and this is done be step (5) below.
3116 When vectorizing inner-most loops, the vectorized loop (LOOP) is also the
3117 inner-most loop, and so steps (3),(4) work the same, and step (5) is
3118 redundant. Steps (3),(4) create the following:
3120 vp0 = &base_addr;
3121 LOOP: vp1 = phi(vp0,vp2)
3122 ...
3123 ...
3124 vp2 = vp1 + step
3125 goto LOOP
3127 If there is an inner-loop nested in loop, then step (5) will also be
3128 applied, and an additional update in the inner-loop will be created:
3130 vp0 = &base_addr;
3131 LOOP: vp1 = phi(vp0,vp2)
3132 ...
3133 inner: vp3 = phi(vp1,vp4)
3134 vp4 = vp3 + inner_step
3135 if () goto inner
3136 ...
3137 vp2 = vp1 + step
3138 if () goto LOOP */
3140 /* (2) Calculate the initial address of the aggregate-pointer, and set
3141 the aggregate-pointer to point to it before the loop. */
3143 /* Create: (&(base[init_val+offset]) in the loop preheader. */
3148 {
3150 {
3153 }
3154 else
3156 }
3160 /* Create: p = (aggr_type *) initial_base */
3163 {
3167 /* Copy the points-to information if it exists. */
3172 {
3175 }
3176 else
3178 }
3179 else
3182 /* (3) Handle the updating of the aggregate-pointer inside the loop.
3183 This is needed when ONLY_INIT is false, and also when AT_LOOP is the
3184 inner-loop nested in LOOP (during outer-loop vectorization). */
3186 /* No update in loop is required. */
3189 else
3190 {
3191 /* The step of the aggregate pointer is the type size. */
3193 /* One exception to the above is when the scalar step of the load in
3194 LOOP is zero. In this case the step here is also zero. */
3209 /* Copy the points-to information if it exists. */
3211 {
3214 }
3219 }
3225 /* (4) Handle the updating of the aggregate-pointer inside the inner-loop
3226 nested in LOOP, if exists. */
3230 {
3239 /* Copy the points-to information if it exists. */
3241 {
3244 }
3249 }
3250 else
3252 }
3255 /* Function bump_vector_ptr
3257 Increment a pointer (to a vector type) by vector-size. If requested,
3258 i.e. if PTR-INCR is given, then also connect the new increment stmt
3259 to the existing def-use update-chain of the pointer, by modifying
3260 the PTR_INCR as illustrated below:
3262 The pointer def-use update-chain before this function:
3263 DATAREF_PTR = phi (p_0, p_2)
3264 ....
3265 PTR_INCR: p_2 = DATAREF_PTR + step
3267 The pointer def-use update-chain after this function:
3268 DATAREF_PTR = phi (p_0, p_2)
3269 ....
3270 NEW_DATAREF_PTR = DATAREF_PTR + BUMP
3271 ....
3272 PTR_INCR: p_2 = NEW_DATAREF_PTR + step
3274 Input:
3275 DATAREF_PTR - ssa_name of a pointer (to vector type) that is being updated
3276 in the loop.
3277 PTR_INCR - optional. The stmt that updates the pointer in each iteration of
3278 the loop. The increment amount across iterations is expected
3279 to be vector_size.
3280 BSI - location where the new update stmt is to be placed.
3281 STMT - the original scalar memory-access stmt that is being vectorized.
3282 BUMP - optional. The offset by which to bump the pointer. If not given,
3283 the offset is assumed to be vector_size.
3285 Output: Return NEW_DATAREF_PTR as illustrated above.
3287 */
3289 tree
3292 {
3298 gimple incr_stmt;
3299 ssa_op_iter iter;
3300 use_operand_p use_p;
3301 tree new_dataref_ptr;
3312 /* Copy the points-to information if it exists. */
3314 {
3318 }
3323 /* Update the vector-pointer's cross-iteration increment. */
3325 {
3330 else
3332 }
3335 }
3338 /* Function vect_create_destination_var.
3340 Create a new temporary of type VECTYPE. */
3342 tree
3344 {
3345 tree vec_dest;
3347 tree type;
3362 }
3364 /* Function vect_strided_store_supported.
3366 Returns TRUE is INTERLEAVE_HIGH and INTERLEAVE_LOW operations are supported,
3367 and FALSE otherwise. */
3369 bool
3371 {
3377 /* vect_permute_store_chain requires the group size to be a power of two. */
3379 {
3384 }
3386 /* Check that the operation is supported. */
3392 {
3396 }
3400 {
3404 }
3407 }
3410 /* Return TRUE if vec_store_lanes is available for COUNT vectors of
3411 type VECTYPE. */
3413 bool
3415 {
3417 vec_store_lanes_optab,
3419 }
3422 /* Function vect_permute_store_chain.
3424 Given a chain of interleaved stores in DR_CHAIN of LENGTH that must be
3425 a power of 2, generate interleave_high/low stmts to reorder the data
3426 correctly for the stores. Return the final references for stores in
3427 RESULT_CHAIN.
3429 E.g., LENGTH is 4 and the scalar type is short, i.e., VF is 8.
3430 The input is 4 vectors each containing 8 elements. We assign a number to
3431 each element, the input sequence is:
3433 1st vec: 0 1 2 3 4 5 6 7
3434 2nd vec: 8 9 10 11 12 13 14 15
3435 3rd vec: 16 17 18 19 20 21 22 23
3436 4th vec: 24 25 26 27 28 29 30 31
3438 The output sequence should be:
3440 1st vec: 0 8 16 24 1 9 17 25
3441 2nd vec: 2 10 18 26 3 11 19 27
3442 3rd vec: 4 12 20 28 5 13 21 30
3443 4th vec: 6 14 22 30 7 15 23 31
3445 i.e., we interleave the contents of the four vectors in their order.
3447 We use interleave_high/low instructions to create such output. The input of
3448 each interleave_high/low operation is two vectors:
3449 1st vec 2nd vec
3450 0 1 2 3 4 5 6 7
3451 the even elements of the result vector are obtained left-to-right from the
3452 high/low elements of the first vector. The odd elements of the result are
3453 obtained left-to-right from the high/low elements of the second vector.
3454 The output of interleave_high will be: 0 4 1 5
3455 and of interleave_low: 2 6 3 7
3458 The permutation is done in log LENGTH stages. In each stage interleave_high
3459 and interleave_low stmts are created for each pair of vectors in DR_CHAIN,
3460 where the first argument is taken from the first half of DR_CHAIN and the
3461 second argument from it's second half.
3462 In our example,
3464 I1: interleave_high (1st vec, 3rd vec)
3465 I2: interleave_low (1st vec, 3rd vec)
3466 I3: interleave_high (2nd vec, 4th vec)
3467 I4: interleave_low (2nd vec, 4th vec)
3469 The output for the first stage is:
3471 I1: 0 16 1 17 2 18 3 19
3472 I2: 4 20 5 21 6 22 7 23
3473 I3: 8 24 9 25 10 26 11 27
3474 I4: 12 28 13 29 14 30 15 31
3476 The output of the second stage, i.e. the final result is:
3478 I1: 0 8 16 24 1 9 17 25
3479 I2: 2 10 18 26 3 11 19 27
3480 I3: 4 12 20 28 5 13 21 30
3481 I4: 6 14 22 30 7 15 23 31. */
3483 void
3486 gimple stmt,
3489 {
3491 gimple perm_stmt;
3502 {
3504 {
3508 /* Create interleaving stmt:
3509 in the case of big endian:
3510 high = interleave_high (vect1, vect2)
3511 and in the case of little endian:
3512 high = interleave_low (vect1, vect2). */
3517 {
3520 }
3521 else
3522 {
3525 }
3533 /* Create interleaving stmt:
3534 in the case of big endian:
3535 low = interleave_low (vect1, vect2)
3536 and in the case of little endian:
3537 low = interleave_high (vect1, vect2). */
3547 }
3549 }
3550 }
3552 /* Function vect_setup_realignment
3554 This function is called when vectorizing an unaligned load using
3555 the dr_explicit_realign[_optimized] scheme.
3556 This function generates the following code at the loop prolog:
3558 p = initial_addr;
3559 x msq_init = *(floor(p)); # prolog load
3560 realignment_token = call target_builtin;
3561 loop:
3562 x msq = phi (msq_init, ---)
3564 The stmts marked with x are generated only for the case of
3565 dr_explicit_realign_optimized.
3567 The code above sets up a new (vector) pointer, pointing to the first
3568 location accessed by STMT, and a "floor-aligned" load using that pointer.
3569 It also generates code to compute the "realignment-token" (if the relevant
3570 target hook was defined), and creates a phi-node at the loop-header bb
3571 whose arguments are the result of the prolog-load (created by this
3572 function) and the result of a load that takes place in the loop (to be
3573 created by the caller to this function).
3575 For the case of dr_explicit_realign_optimized:
3576 The caller to this function uses the phi-result (msq) to create the
3577 realignment code inside the loop, and sets up the missing phi argument,
3578 as follows:
3579 loop:
3580 msq = phi (msq_init, lsq)
3581 lsq = *(floor(p')); # load in loop
3582 result = realign_load (msq, lsq, realignment_token);
3584 For the case of dr_explicit_realign:
3585 loop:
3586 msq = *(floor(p)); # load in loop
3587 p' = p + (VS-1);
3588 lsq = *(floor(p')); # load in loop
3589 result = realign_load (msq, lsq, realignment_token);
3591 Input:
3592 STMT - (scalar) load stmt to be vectorized. This load accesses
3593 a memory location that may be unaligned.
3594 BSI - place where new code is to be inserted.
3595 ALIGNMENT_SUPPORT_SCHEME - which of the two misalignment handling schemes
3596 is used.
3598 Output:
3599 REALIGNMENT_TOKEN - the result of a call to the builtin_mask_for_load
3600 target hook, if defined.
3601 Return value - the result of the loop-header phi node. */
3603 tree
3607 tree init_addr,
3609 {
3617 tree vec_dest;
3618 gimple inc;
3619 tree ptr;
3620 tree data_ref;
3621 gimple new_stmt;
3622 basic_block new_bb;
3624 tree new_temp;
3625 gimple phi_stmt;
3635 {
3638 }
3643 /* We need to generate three things:
3644 1. the misalignment computation
3645 2. the extra vector load (for the optimized realignment scheme).
3646 3. the phi node for the two vectors from which the realignment is
3647 done (for the optimized realignment scheme). */
3649 /* 1. Determine where to generate the misalignment computation.
3651 If INIT_ADDR is NULL_TREE, this indicates that the misalignment
3652 calculation will be generated by this function, outside the loop (in the
3653 preheader). Otherwise, INIT_ADDR had already been computed for us by the
3654 caller, inside the loop.
3656 Background: If the misalignment remains fixed throughout the iterations of
3657 the loop, then both realignment schemes are applicable, and also the
3658 misalignment computation can be done outside LOOP. This is because we are
3659 vectorizing LOOP, and so the memory accesses in LOOP advance in steps that
3660 are a multiple of VS (the Vector Size), and therefore the misalignment in
3661 different vectorized LOOP iterations is always the same.
3662 The problem arises only if the memory access is in an inner-loop nested
3663 inside LOOP, which is now being vectorized using outer-loop vectorization.
3664 This is the only case when the misalignment of the memory access may not
3665 remain fixed throughout the iterations of the inner-loop (as explained in
3666 detail in vect_supportable_dr_alignment). In this case, not only is the
3667 optimized realignment scheme not applicable, but also the misalignment
3668 computation (and generation of the realignment token that is passed to
3669 REALIGN_LOAD) have to be done inside the loop.
3671 In short, INIT_ADDR indicates whether we are in a COMPUTE_IN_LOOP mode
3672 or not, which in turn determines if the misalignment is computed inside
3673 the inner-loop, or outside LOOP. */
3676 {
3679 }
3682 /* 2. Determine where to generate the extra vector load.
3684 For the optimized realignment scheme, instead of generating two vector
3685 loads in each iteration, we generate a single extra vector load in the
3686 preheader of the loop, and in each iteration reuse the result of the
3687 vector load from the previous iteration. In case the memory access is in
3688 an inner-loop nested inside LOOP, which is now being vectorized using
3689 outer-loop vectorization, we need to determine whether this initial vector
3690 load should be generated at the preheader of the inner-loop, or can be
3691 generated at the preheader of LOOP. If the memory access has no evolution
3692 in LOOP, it can be generated in the preheader of LOOP. Otherwise, it has
3693 to be generated inside LOOP (in the preheader of the inner-loop). */
3696 {
3701 }
3702 else
3710 /* 3. For the case of the optimized realignment, create the first vector
3711 load at the loop preheader. */
3714 {
3715 /* Create msq_init = *(floor(p1)) in the loop preheader */
3722 new_stmt = gimple_build_assign_with_ops
3730 data_ref
3738 {
3741 }
3742 else
3746 }
3748 /* 4. Create realignment token using a target builtin, if available.
3749 It is done either inside the containing loop, or before LOOP (as
3750 determined above). */
3753 {
3754 tree builtin_decl;
3756 /* Compute INIT_ADDR - the initial addressed accessed by this memref. */
3758 {
3759 /* Generate the INIT_ADDR computation outside LOOP. */
3763 {
3767 }
3768 else
3770 }
3774 vec_dest =
3782 else
3783 {
3784 /* Generate the misalignment computation outside LOOP. */
3788 }
3792 /* The result of the CALL_EXPR to this builtin is determined from
3793 the value of the parameter and no global variables are touched
3794 which makes the builtin a "const" function. Requiring the
3795 builtin to have the "const" attribute makes it unnecessary
3796 to call mark_call_clobbered. */
3798 }
3807 /* 5. Create msq = phi <msq_init, lsq> in loop */
3817 }
3820 /* Function vect_strided_load_supported.
3822 Returns TRUE is EXTRACT_EVEN and EXTRACT_ODD operations are supported,
3823 and FALSE otherwise. */
3825 bool
3827 {
3833 /* vect_permute_load_chain requires the group size to be a power of two. */
3835 {
3840 }
3843 optab_default);
3845 {
3849 }
3852 {
3856 }
3859 optab_default);
3861 {
3865 }
3868 {
3872 }
3874 }
3876 /* Return TRUE if vec_load_lanes is available for COUNT vectors of
3877 type VECTYPE. */
3879 bool
3881 {
3883 vec_load_lanes_optab,
3885 }
3887 /* Function vect_permute_load_chain.
3889 Given a chain of interleaved loads in DR_CHAIN of LENGTH that must be
3890 a power of 2, generate extract_even/odd stmts to reorder the input data
3891 correctly. Return the final references for loads in RESULT_CHAIN.
3893 E.g., LENGTH is 4 and the scalar type is short, i.e., VF is 8.
3894 The input is 4 vectors each containing 8 elements. We assign a number to each
3895 element, the input sequence is:
3897 1st vec: 0 1 2 3 4 5 6 7
3898 2nd vec: 8 9 10 11 12 13 14 15
3899 3rd vec: 16 17 18 19 20 21 22 23
3900 4th vec: 24 25 26 27 28 29 30 31
3902 The output sequence should be:
3904 1st vec: 0 4 8 12 16 20 24 28
3905 2nd vec: 1 5 9 13 17 21 25 29
3906 3rd vec: 2 6 10 14 18 22 26 30
3907 4th vec: 3 7 11 15 19 23 27 31
3909 i.e., the first output vector should contain the first elements of each
3910 interleaving group, etc.
3912 We use extract_even/odd instructions to create such output. The input of
3913 each extract_even/odd operation is two vectors
3914 1st vec 2nd vec
3915 0 1 2 3 4 5 6 7
3917 and the output is the vector of extracted even/odd elements. The output of
3918 extract_even will be: 0 2 4 6
3919 and of extract_odd: 1 3 5 7
3922 The permutation is done in log LENGTH stages. In each stage extract_even
3923 and extract_odd stmts are created for each pair of vectors in DR_CHAIN in
3924 their order. In our example,
3926 E1: extract_even (1st vec, 2nd vec)
3927 E2: extract_odd (1st vec, 2nd vec)
3928 E3: extract_even (3rd vec, 4th vec)
3929 E4: extract_odd (3rd vec, 4th vec)
3931 The output for the first stage will be:
3933 E1: 0 2 4 6 8 10 12 14
3934 E2: 1 3 5 7 9 11 13 15
3935 E3: 16 18 20 22 24 26 28 30
3936 E4: 17 19 21 23 25 27 29 31
3938 In order to proceed and create the correct sequence for the next stage (or
3939 for the correct output, if the second stage is the last one, as in our
3940 example), we first put the output of extract_even operation and then the
3941 output of extract_odd in RESULT_CHAIN (which is then copied to DR_CHAIN).
3942 The input for the second stage is:
3944 1st vec (E1): 0 2 4 6 8 10 12 14
3945 2nd vec (E3): 16 18 20 22 24 26 28 30
3946 3rd vec (E2): 1 3 5 7 9 11 13 15
3947 4th vec (E4): 17 19 21 23 25 27 29 31
3949 The output of the second stage:
3951 E1: 0 4 8 12 16 20 24 28
3952 E2: 2 6 10 14 18 22 26 30
3953 E3: 1 5 9 13 17 21 25 29
3954 E4: 3 7 11 15 19 23 27 31
3956 And RESULT_CHAIN after reordering:
3958 1st vec (E1): 0 4 8 12 16 20 24 28
3959 2nd vec (E3): 1 5 9 13 17 21 25 29
3960 3rd vec (E2): 2 6 10 14 18 22 26 30
3961 4th vec (E4): 3 7 11 15 19 23 27 31. */
3963 static void
3966 gimple stmt,
3969 {
3971 gimple perm_stmt;
3980 {
3982 {
3986 /* data_ref = permute_even (first_data_ref, second_data_ref); */
3993 second_vect);
4002 /* data_ref = permute_odd (first_data_ref, second_data_ref); */
4009 second_vect);
4016 }
4018 }
4019 }
4022 /* Function vect_transform_strided_load.
4024 Given a chain of input interleaved data-refs (in DR_CHAIN), build statements
4025 to perform their permutation and ascribe the result vectorized statements to
4026 the scalar statements.
4027 */
4029 void
4032 {
4035 /* DR_CHAIN contains input data-refs that are a part of the interleaving.
4036 RESULT_CHAIN is the output of vect_permute_load_chain, it contains permuted
4037 vectors, that are ready for vector computation. */
4042 }
4044 /* RESULT_CHAIN contains the output of a group of strided loads that were
4045 generated as part of the vectorization of STMT. Assign the statement
4046 for each vector to the associated scalar statement. */
4048 void
4050 {
4054 tree tmp_data_ref;
4056 /* Put a permuted data-ref in the VECTORIZED_STMT field.
4057 Since we scan the chain starting from it's first node, their order
4058 corresponds the order of data-refs in RESULT_CHAIN. */
4062 {
4066 /* Skip the gaps. Loads created for the gaps will be removed by dead
4067 code elimination pass later. No need to check for the first stmt in
4068 the group, since it always exists.
4069 GROUP_GAP is the number of steps in elements from the previous
4070 access (if there is no gap GROUP_GAP is 1). We skip loads that
4071 correspond to the gaps. */
4074 {
4075 gap_count++;
4077 }
4080 {
4082 /* We assume that if VEC_STMT is not NULL, this is a case of multiple
4083 copies, and we put the new vector statement in the first available
4084 RELATED_STMT. */
4087 else
4088 {
4090 {
4091 gimple prev_stmt =
4093 gimple rel_stmt =
4096 {
4098 rel_stmt =
4100 }
4103 new_stmt;
4104 }
4105 }
4109 /* If NEXT_STMT accesses the same DR as the previous statement,
4110 put the same TMP_DATA_REF as its vectorized statement; otherwise
4111 get the next data-ref from RESULT_CHAIN. */
4114 }
4115 }
4116 }
4118 /* Function vect_force_dr_alignment_p.
4120 Returns whether the alignment of a DECL can be forced to be aligned
4121 on ALIGNMENT bit boundary. */
4123 bool
4125 {
4137 else
4139 }
4142 /* Return whether the data reference DR is supported with respect to its
4143 alignment.
4144 If CHECK_ALIGNED_ACCESSES is TRUE, check if the access is supported even
4145 it is aligned, i.e., check if it is possible to vectorize it with different
4146 alignment. */
4148 enum dr_alignment_support
4151 {
4164 {
4167 }
4169 /* Possibly unaligned access. */
4171 /* We can choose between using the implicit realignment scheme (generating
4172 a misaligned_move stmt) and the explicit realignment scheme (generating
4173 aligned loads with a REALIGN_LOAD). There are two variants to the
4174 explicit realignment scheme: optimized, and unoptimized.
4175 We can optimize the realignment only if the step between consecutive
4176 vector loads is equal to the vector size. Since the vector memory
4177 accesses advance in steps of VS (Vector Size) in the vectorized loop, it
4178 is guaranteed that the misalignment amount remains the same throughout the
4179 execution of the vectorized loop. Therefore, we can create the
4180 "realignment token" (the permutation mask that is passed to REALIGN_LOAD)
4181 at the loop preheader.
4183 However, in the case of outer-loop vectorization, when vectorizing a
4184 memory access in the inner-loop nested within the LOOP that is now being
4185 vectorized, while it is guaranteed that the misalignment of the
4186 vectorized memory access will remain the same in different outer-loop
4187 iterations, it is *not* guaranteed that is will remain the same throughout
4188 the execution of the inner-loop. This is because the inner-loop advances
4189 with the original scalar step (and not in steps of VS). If the inner-loop
4190 step happens to be a multiple of VS, then the misalignment remains fixed
4191 and we can use the optimized realignment scheme. For example:
4193 for (i=0; i<N; i++)
4194 for (j=0; j<M; j++)
4195 s += a[i+j];
4197 When vectorizing the i-loop in the above example, the step between
4198 consecutive vector loads is 1, and so the misalignment does not remain
4199 fixed across the execution of the inner-loop, and the realignment cannot
4200 be optimized (as illustrated in the following pseudo vectorized loop):
4202 for (i=0; i<N; i+=4)
4203 for (j=0; j<M; j++){
4204 vs += vp[i+j]; // misalignment of &vp[i+j] is {0,1,2,3,0,1,2,3,...}
4205 // when j is {0,1,2,3,4,5,6,7,...} respectively.
4206 // (assuming that we start from an aligned address).
4207 }
4209 We therefore have to use the unoptimized realignment scheme:
4211 for (i=0; i<N; i+=4)
4212 for (j=k; j<M; j+=4)
4213 vs += vp[i+j]; // misalignment of &vp[i+j] is always k (assuming
4214 // that the misalignment of the initial address is
4215 // 0).
4217 The loop can then be vectorized as follows:
4219 for (k=0; k<4; k++){
4220 rt = get_realignment_token (&vp[k]);
4221 for (i=0; i<N; i+=4){
4222 v1 = vp[i+k];
4223 for (j=k; j<M; j+=4){
4224 v2 = vp[i+j+VS-1];
4225 va = REALIGN_LOAD <v1,v2,rt>;
4226 vs += va;
4227 v1 = v2;
4228 }
4229 }
4230 } */
4233 {
4240 {
4247 else
4249 }
4251 {
4256 }
4261 /* Can't software pipeline the loads, but can at least do them. */
4263 }
4264 else
4265 {
4270 {
4275 }
4281 }
4283 /* Unsupported. */
4285 }