| blob | 01d1850276bb9d75de58452754ff03b2167e9390 |
1 /* Vectorizer Specific Loop Manipulations
2 Copyright (C) 2003-2018 Free Software Foundation, Inc.
3 Contributed by Dorit Naishlos <dorit@il.ibm.com>
4 and Ira Rosen <irar@il.ibm.com>
6 This file is part of GCC.
8 GCC is free software; you can redistribute it and/or modify it under
9 the terms of the GNU General Public License as published by the Free
10 Software Foundation; either version 3, or (at your option) any later
11 version.
13 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
14 WARRANTY; without even the implied warranty of MERCHANTABILITY or
15 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
16 for more details.
18 You should have received a copy of the GNU General Public License
19 along with GCC; see the file COPYING3. If not see
20 <http://www.gnu.org/licenses/>. */
51 /*************************************************************************
52 Simple Loop Peeling Utilities
54 Utilities to support loop peeling for vectorization purposes.
55 *************************************************************************/
58 /* Renames the use *OP_P. */
60 static void
62 {
63 tree new_name;
70 /* Something defined outside of the loop. */
74 /* An ordinary ssa name defined in the loop. */
77 }
80 /* Renames the variables in basic block BB. Allow renaming of PHI arguments
81 on edges incoming from outer-block header if RENAME_FROM_OUTER_LOOP is
82 true. */
84 static void
86 {
88 use_operand_p use_p;
89 ssa_op_iter iter;
90 edge e;
91 edge_iterator ei;
96 {
99 }
103 {
107 }
110 {
112 {
116 {
118 {
119 /* If outer_loop has 2 inner loops, allow there to
120 be an extra basic block which decides which of the
121 two loops to use using LOOP_VECTORIZED. */
125 }
126 }
127 }
131 }
132 }
135 struct adjust_info
136 {
138 basic_block bb;
139 };
141 /* A stack of values to be adjusted in debug stmts. We have to
142 process them LIFO, so that the closest substitution applies. If we
143 processed them FIFO, without the stack, we might substitute uses
144 with a PHI DEF that would soon become non-dominant, and when we got
145 to the suitable one, it wouldn't have anything to substitute any
146 more. */
149 /* Adjust any debug stmts that referenced AI->from values to use the
150 loop-closed AI->to, if the references are dominated by AI->bb and
151 not by the definition of AI->from. */
153 static void
155 {
159 imm_use_iterator imm_iter;
165 /* Adjust any debug stmts that held onto non-loop-closed
166 references. */
168 {
169 use_operand_p use_p;
170 basic_block bbuse;
183 {
187 else
188 {
191 }
192 }
193 }
194 }
196 /* Adjust debug stmts as scheduled before. */
198 static void
200 {
207 {
210 }
211 }
213 /* Adjust any debug stmts that referenced FROM values to use the
214 loop-closed TO, if the references are dominated by BB and not by
215 the definition of FROM. If adjust_vec is non-NULL, adjustments
216 will be postponed until adjust_vec_debug_stmts is called. */
218 static void
220 {
221 adjust_info ai;
227 {
234 else
236 }
237 }
239 /* Change E's phi arg in UPDATE_PHI to NEW_DEF, and record information
240 to adjust any debug stmts that referenced the old phi arg,
241 presumably non-loop-closed references left over from other
242 transformations. */
244 static void
246 {
254 }
256 /* Define one loop mask MASK from loop LOOP. INIT_MASK is the value that
257 the mask should have during the first iteration and NEXT_MASK is the
258 value that it should have on subsequent iterations. */
260 static void
262 tree next_mask)
263 {
267 }
269 /* Add SEQ to the end of LOOP's preheader block. */
271 static void
273 {
275 {
279 }
280 }
282 /* Add SEQ to the beginning of LOOP's header block. */
284 static void
286 {
288 {
291 }
292 }
294 /* Return true if the target can interleave elements of two vectors.
295 OFFSET is 0 if the first half of the vectors should be interleaved
296 or 1 if the second half should. When returning true, store the
297 associated permutation in INDICES. */
299 static bool
302 {
307 {
310 }
313 }
315 /* Try to use permutes to define the masks in DEST_RGM using the masks
316 in SRC_RGM, given that the former has twice as many masks as the
317 latter. Return true on success, adding any new statements to SEQ. */
319 static bool
322 {
329 {
330 /* Unpacking the source masks gives at least as many mask bits as
331 we need. We can then VIEW_CONVERT any excess bits away. */
334 {
338 ? VEC_UNPACK_HI_EXPR
343 else
344 {
351 }
353 }
355 }
360 {
361 /* The destination requires twice as many mask bits as the source, so
362 we can use interleaving permutes to double up the number of bits. */
367 {
373 }
375 }
377 }
379 /* Helper for vect_set_loop_condition_masked. Generate definitions for
380 all the masks in RGM and return a mask that is nonzero when the loop
381 needs to iterate. Add any new preheader statements to PREHEADER_SEQ.
382 Use LOOP_COND_GSI to insert code before the exit gcond.
384 RGM belongs to loop LOOP. The loop originally iterated NITERS
385 times and has been vectorized according to LOOP_VINFO. Each iteration
386 of the vectorized loop handles VF iterations of the scalar loop.
388 If NITERS_SKIP is nonnull, the first iteration of the vectorized loop
389 starts with NITERS_SKIP dummy iterations of the scalar loop before
390 the real work starts. The mask elements for these dummy iterations
391 must be 0, to ensure that the extra iterations do not have an effect.
393 It is known that:
395 NITERS * RGM->max_nscalars_per_iter
397 does not overflow. However, MIGHT_WRAP_P says whether an induction
398 variable that starts at 0 and has step:
400 VF * RGM->max_nscalars_per_iter
402 might overflow before hitting a value above:
404 (NITERS + NITERS_SKIP) * RGM->max_nscalars_per_iter
406 This means that we cannot guarantee that such an induction variable
407 would ever hit a value that produces a set of all-false masks for RGM. */
409 static tree
412 gimple_stmt_iterator loop_cond_gsi,
416 {
422 /* Calculate the maximum number of scalar values that the rgroup
423 handles in total, the number that it handles for each iteration
424 of the vector loop, and the number that it should skip during the
425 first iteration of the vector loop. */
430 {
431 /* We checked before choosing to use a fully-masked loop that these
432 multiplications don't overflow. */
441 }
443 /* Create an induction variable that counts the number of scalars
444 processed. */
446 gimple_stmt_iterator incr_gsi;
456 {
457 /* In principle the loop should stop iterating once the incremented
458 IV reaches a value greater than or equal to:
460 NSCALARS_TOTAL +[infinite-prec] NSCALARS_SKIP
462 However, there's no guarantee that this addition doesn't overflow
463 the comparison type, or that the IV hits a value above it before
464 wrapping around. We therefore adjust the limit down by one
465 IV step:
467 (NSCALARS_TOTAL +[infinite-prec] NSCALARS_SKIP)
468 -[infinite-prec] NSCALARS_STEP
470 and compare the IV against this limit _before_ incrementing it.
471 Since the comparison type is unsigned, we actually want the
472 subtraction to saturate at zero:
474 (NSCALARS_TOTAL +[infinite-prec] NSCALARS_SKIP)
475 -[sat] NSCALARS_STEP
477 And since NSCALARS_SKIP < NSCALARS_STEP, we can reassociate this as:
479 NSCALARS_TOTAL -[sat] (NSCALARS_STEP - NSCALARS_SKIP)
481 where the rightmost subtraction can be done directly in
482 COMPARE_TYPE. */
494 /* Get a safe limit for the first iteration. */
496 {
497 /* The first vector iteration can handle at most NSCALARS_STEP
498 scalars. NSCALARS_STEP <= CONST_LIMIT, and adding
499 NSCALARS_SKIP to that cannot overflow. */
507 }
508 else
509 /* For the first iteration it doesn't matter whether the IV hits
510 a value above NSCALARS_TOTAL. That only matters for the latch
511 condition. */
513 }
514 else
515 {
516 /* Test the incremented IV, which will always hit a value above
517 the bound before wrapping. */
526 }
528 /* Provide a definition of each mask in the group. */
530 tree mask;
533 {
534 /* Previous masks will cover BIAS scalars. This mask covers the
535 next batch. */
540 /* See whether the first iteration of the vector loop is known
541 to have a full mask. */
542 poly_uint64 const_limit;
543 bool first_iteration_full
547 /* Rather than have a new IV that starts at BIAS and goes up to
548 TEST_LIMIT, prefer to use the same 0-based IV for each mask
549 and adjust the bound down by BIAS. */
552 {
555 bias_tree);
558 bias_tree);
559 }
561 /* Create the initial mask. First include all scalars that
562 are within the loop limit. */
565 {
568 {
569 /* Use a natural test between zero (the initial IV value)
570 and the loop limit. The "else" block would be valid too,
571 but this choice can avoid the need to load BIAS_TREE into
572 a register. */
575 }
576 else
577 {
578 /* FIRST_LIMIT is the maximum number of scalars handled by the
579 first iteration of the vector loop. Test the portion
580 associated with this mask. */
583 }
588 }
590 /* Now AND out the bits that are within the number of skipped
591 scalars. */
592 poly_uint64 const_skip;
596 {
602 else
604 }
607 /* First iteration is full. */
610 /* Get the mask value for the next iteration of the loop. */
616 }
618 }
620 /* Make LOOP iterate NITERS times using masking and WHILE_ULT calls.
621 LOOP_VINFO describes the vectorization of LOOP. NITERS is the
622 number of iterations of the original scalar loop that should be
623 handled by the vector loop. NITERS_MAYBE_ZERO and FINAL_IV are
624 as for vect_set_loop_condition.
626 Insert the branch-back condition before LOOP_COND_GSI and return the
627 final gcond. */
633 gimple_stmt_iterator loop_cond_gsi)
634 {
643 /* Type of the initial value of NITERS. */
647 /* Convert NITERS to the same size as the compare. */
650 {
651 /* We know that there is always at least one iteration, so if the
652 count is zero then it must have wrapped. Cope with this by
653 subtracting 1 before the conversion and adding 1 to the result. */
660 }
661 else
664 /* Convert skip_niters to the right type. */
667 /* Now calculate the value that the induction variable must be able
668 to hit in order to ensure that we end the loop with an all-false mask.
669 This involves adding the maximum number of inactive trailing scalar
670 iterations. */
671 widest_int iv_limit;
674 {
676 {
677 /* Add the maximum number of skipped iterations to the
678 maximum iteration count. */
681 else
683 }
684 /* IV_LIMIT is the maximum number of latch iterations, which is also
685 the maximum in-range IV value. Round this value down to the previous
686 vector alignment boundary and then add an extra full iteration. */
689 }
691 /* Get the vectorization factor in tree form. */
695 /* Iterate over all the rgroups and fill in their masks. We could use
696 the first mask from any rgroup for the loop condition; here we
697 arbitrarily pick the last. */
704 {
705 /* First try using permutes. This adds a single vector
706 instruction to the loop for each mask, but needs no extra
707 loop invariants or IVs. */
710 {
715 }
717 /* See whether zero-based IV would ever generate all-false masks
718 before wrapping around. */
719 bool might_wrap_p
720 = (!known_max_iters
722 UNSIGNED)
725 /* Set up all masks for this group. */
730 might_wrap_p);
731 }
733 /* Emit all accumulated statements. */
737 /* Get a boolean result that tells us whether to iterate. */
745 /* The loop iterates (NITERS - 1) / VF + 1 times.
746 Subtract one from this to get the latch count. */
755 {
758 }
761 }
763 /* Like vect_set_loop_condition, but handle the case in which there
764 are no loop masks. */
770 gimple_stmt_iterator loop_cond_gsi)
771 {
777 gimple_stmt_iterator incr_gsi;
788 {
789 /* In this case we can use a simple 0-based IV:
791 A:
792 x = 0;
793 do
794 {
795 ...
796 x += 1;
797 }
798 while (x < NITERS); */
802 }
803 else
804 {
805 /* The following works for all values of NITERS except 0:
807 B:
808 x = 0;
809 do
810 {
811 ...
812 x += STEP;
813 }
814 while (x <= NITERS - STEP);
816 so that the loop continues to iterate if x + STEP - 1 < NITERS
817 but stops if x + STEP - 1 >= NITERS.
819 However, if NITERS is zero, x never hits a value above NITERS - STEP
820 before wrapping around. There are two obvious ways of dealing with
821 this:
823 - start at STEP - 1 and compare x before incrementing it
824 - start at -1 and compare x after incrementing it
826 The latter is simpler and is what we use. The loop in this case
827 looks like:
829 C:
830 x = -1;
831 do
832 {
833 ...
834 x += STEP;
835 }
836 while (x < NITERS - STEP);
838 In both cases the loop limit is NITERS - STEP. */
843 {
846 }
848 {
849 /* Case C. */
852 }
853 else
854 {
855 /* Case B. */
858 }
859 }
866 GSI_SAME_STMT);
871 NULL_TREE);
875 /* Record the number of latch iterations. */
877 /* Case A: the loop iterates NITERS times. Subtract one to get the
878 latch count. */
881 else
882 /* Case B or C: the loop iterates (NITERS - STEP) / STEP + 1 times.
883 Subtract one from this to get the latch count. */
888 {
892 }
895 }
897 /* If we're using fully-masked loops, make LOOP iterate:
899 N == (NITERS - 1) / STEP + 1
901 times. When NITERS is zero, this is equivalent to making the loop
902 execute (1 << M) / STEP times, where M is the precision of NITERS.
903 NITERS_MAYBE_ZERO is true if this last case might occur.
905 If we're not using fully-masked loops, make LOOP iterate:
907 N == (NITERS - STEP) / STEP + 1
909 times, where NITERS is known to be outside the range [1, STEP - 1].
910 This is equivalent to making the loop execute NITERS / STEP times
911 when NITERS is nonzero and (1 << M) / STEP times otherwise.
912 NITERS_MAYBE_ZERO again indicates whether this last case might occur.
914 If FINAL_IV is nonnull, it is an SSA name that should be set to
915 N * STEP on exit from the loop.
917 Assumption: the exit-condition of LOOP is the last stmt in the loop. */
919 void
923 {
931 loop_cond_gsi);
932 else
935 loop_cond_gsi);
937 /* Remove old loop exit test. */
942 {
945 }
946 }
948 /* Helper routine of slpeel_tree_duplicate_loop_to_edge_cfg.
949 For all PHI arguments in FROM->dest and TO->dest from those
950 edges ensure that TO->dest PHI arguments have current_def
951 to that in from. */
953 static void
955 {
961 {
967 {
970 }
972 {
975 }
978 else
979 {
982 }
985 }
992 }
995 /* Given LOOP this function generates a new copy of it and puts it
996 on E which is either the entry or exit of LOOP. If SCALAR_LOOP is
997 non-NULL, assume LOOP and SCALAR_LOOP are equivalent and copy the
998 basic blocks from SCALAR_LOOP instead of LOOP, but to either the
999 entry or exit of LOOP. */
1004 {
1009 basic_block exit_dest;
1024 /* Allow duplication of outer loops. */
1027 /* Check whether duplication is possible. */
1029 {
1032 }
1034 /* Generate new loop structure. */
1043 /* Also copy the pre-header, this avoids jumping through hoops to
1044 duplicate the loop entry PHI arguments. Create an empty
1045 pre-header unconditionally for this. */
1061 {
1062 /* If we copied from SCALAR_LOOP rather than LOOP, SSA_NAMEs from
1063 SCALAR_LOOP will have current_def set to SSA_NAMEs in the new_loop,
1064 but LOOP will not. slpeel_update_phi_nodes_for_guard{1,2} expects
1065 the LOOP SSA_NAMEs (on the exit edge and edge from latch to
1066 header) to have current_def set, so copy them over. */
1068 exit);
1072 }
1075 {
1077 {
1078 gphi_iterator gsi;
1083 {
1086 location_t orig_locus
1090 }
1091 }
1098 /* And remove the non-necessary forwarder again. Keep the other
1099 one so we have a proper pre-header for the loop at the exit edge. */
1105 }
1107 {
1109 {
1110 /* Remove the non-necessary forwarder of scalar_loop again. */
1118 }
1128 /* And remove the non-necessary forwarder again. Keep the other
1129 one so we have a proper pre-header for the loop at the exit edge. */
1135 }
1137 /* Skip new preheader since it's deleted if copy loop is added at entry. */
1142 {
1143 /* Update new_loop->header PHIs, so that on the preheader
1144 edge they are the ones from loop rather than scalar_loop. */
1153 {
1157 location_t orig_locus
1161 }
1162 }
1170 }
1173 /* Given the condition expression COND, put it as the last statement of
1174 GUARD_BB; set both edges' probability; set dominator of GUARD_TO to
1175 DOM_BB; return the skip edge. GUARD_TO is the target basic block to
1176 skip the loop. PROBABILITY is the skip edge's probability. Mark the
1177 new edge as irreducible if IRREDUCIBLE_P is true. */
1179 static edge
1183 {
1184 gimple_stmt_iterator gsi;
1195 NULL_TREE);
1203 /* Add new edge to connect guard block to the merge/loop-exit block. */
1213 /* Split enter_e to preserve LOOPS_HAVE_PREHEADERS. */
1218 }
1221 /* This function verifies that the following restrictions apply to LOOP:
1222 (1) it consists of exactly 2 basic blocks - header, and an empty latch
1223 for innermost loop and 5 basic blocks for outer-loop.
1224 (2) it is single entry, single exit
1225 (3) its exit condition is the last stmt in the header
1226 (4) E is the entry/exit edge of LOOP.
1227 */
1229 bool
1231 {
1238 /* All loops have an outer scope; the only case loop->outer is NULL is for
1239 the function itself. */
1244 /* Verify that new loop exit condition can be trivially modified. */
1250 }
1252 /* If the loop has a virtual PHI, but exit bb doesn't, create a virtual PHI
1253 in the exit bb and rename all the uses after the loop. This simplifies
1254 the *guard[12] routines, which assume loop closed SSA form for all PHIs
1255 (but normally loop closed SSA form doesn't require virtual PHIs to be
1256 in the same form). Doing this early simplifies the checking what
1257 uses should be renamed. */
1259 static void
1261 {
1262 gphi_iterator gsi;
1267 {
1274 {
1278 imm_use_iterator imm_iter;
1280 use_operand_p use_p;
1291 }
1293 }
1295 }
1297 /* Function vect_get_loop_location.
1299 Extract the location of the loop in the source code.
1300 If the loop is not well formed for vectorization, an estimated
1301 location is calculated.
1302 Return the loop location if succeed and NULL if not. */
1304 dump_user_location_t
1306 {
1308 basic_block bb;
1309 gimple_stmt_iterator si;
1320 /* If we got here the loop is probably not "well formed",
1321 try to estimate the loop location */
1329 {
1333 }
1336 }
1338 /* Return true if PHI defines an IV of the loop to be vectorized. */
1340 static bool
1342 {
1353 }
1355 /* Function vect_can_advance_ivs_p
1357 In case the number of iterations that LOOP iterates is unknown at compile
1358 time, an epilog loop will be generated, and the loop induction variables
1359 (IVs) will be "advanced" to the value they are supposed to take just before
1360 the epilog loop. Here we check that the access function of the loop IVs
1361 and the expression that represents the loop bound are simple enough.
1362 These restrictions will be relaxed in the future. */
1364 bool
1366 {
1369 gphi_iterator gsi;
1371 /* Analyze phi functions of the loop header. */
1376 {
1377 tree evolution_part;
1381 {
1384 }
1386 /* Skip virtual phi's. The data dependences that are associated with
1387 virtual defs/uses (i.e., memory accesses) are analyzed elsewhere.
1389 Skip reduction phis. */
1391 {
1396 }
1398 /* Analyze the evolution function. */
1400 evolution_part
1403 {
1408 }
1410 /* FORNOW: We do not transform initial conditions of IVs
1411 which evolution functions are not invariants in the loop. */
1414 {
1419 }
1421 /* FORNOW: We do not transform initial conditions of IVs
1422 which evolution functions are a polynomial of degree >= 2. */
1425 {
1430 }
1431 }
1434 }
1437 /* Function vect_update_ivs_after_vectorizer.
1439 "Advance" the induction variables of LOOP to the value they should take
1440 after the execution of LOOP. This is currently necessary because the
1441 vectorizer does not handle induction variables that are used after the
1442 loop. Such a situation occurs when the last iterations of LOOP are
1443 peeled, because:
1444 1. We introduced new uses after LOOP for IVs that were not originally used
1445 after LOOP: the IVs of LOOP are now used by an epilog loop.
1446 2. LOOP is going to be vectorized; this means that it will iterate N/VF
1447 times, whereas the loop IVs should be bumped N times.
1449 Input:
1450 - LOOP - a loop that is going to be vectorized. The last few iterations
1451 of LOOP were peeled.
1452 - NITERS - the number of iterations that LOOP executes (before it is
1453 vectorized). i.e, the number of times the ivs should be bumped.
1454 - UPDATE_E - a successor edge of LOOP->exit that is on the (only) path
1455 coming out from LOOP on which there are uses of the LOOP ivs
1456 (this is the path from LOOP->exit to epilog_loop->preheader).
1458 The new definitions of the ivs are placed in LOOP->exit.
1459 The phi args associated with the edge UPDATE_E in the bb
1460 UPDATE_E->dest are updated accordingly.
1462 Assumption 1: Like the rest of the vectorizer, this function assumes
1463 a single loop exit that has a single predecessor.
1465 Assumption 2: The phi nodes in the LOOP header and in update_bb are
1466 organized in the same order.
1468 Assumption 3: The access function of the ivs is simple enough (see
1469 vect_can_advance_ivs_p). This assumption will be relaxed in the future.
1471 Assumption 4: Exactly one of the successors of LOOP exit-bb is on a path
1472 coming out of LOOP on which the ivs of LOOP are used (this is the path
1473 that leads to the epilog loop; other paths skip the epilog loop). This
1474 path starts with the edge UPDATE_E, and its destination (denoted update_bb)
1475 needs to have its phis updated.
1476 */
1478 static void
1481 {
1487 /* Make sure there exists a single-predecessor exit bb: */
1494 {
1495 tree init_expr;
1497 tree type;
1499 gimple_stmt_iterator last_gsi;
1504 {
1508 }
1510 /* Skip reduction and virtual phis. */
1512 {
1517 }
1523 /* FORNOW: We do not support IVs whose evolution function is a polynomial
1524 of degree >= 2 or exponential. */
1531 step_expr);
1534 else
1543 /* Exit_bb shouldn't be empty. */
1546 else
1549 /* Fix phi expressions in the successor bb. */
1551 }
1552 }
1554 /* Return a gimple value containing the misalignment (measured in vector
1555 elements) for the loop described by LOOP_VINFO, i.e. how many elements
1556 it is away from a perfectly aligned address. Add any new statements
1557 to SEQ. */
1559 static tree
1561 {
1571 tree offset = (negative
1575 offset);
1578 HOST_WIDE_INT elem_size
1582 /* Create: misalign_in_bytes = addr & (target_align - 1). */
1585 target_align_minus_1);
1587 /* Create: misalign_in_elems = misalign_in_bytes / element_size. */
1589 elem_size_log);
1592 }
1594 /* Function vect_gen_prolog_loop_niters
1596 Generate the number of iterations which should be peeled as prolog for the
1597 loop represented by LOOP_VINFO. It is calculated as the misalignment of
1598 DR - the data reference recorded in LOOP_VINFO_UNALIGNED_DR (LOOP_VINFO).
1599 As a result, after the execution of this loop, the data reference DR will
1600 refer to an aligned location. The following computation is generated:
1602 If the misalignment of DR is known at compile time:
1603 addr_mis = int mis = DR_MISALIGNMENT (dr);
1604 Else, compute address misalignment in bytes:
1605 addr_mis = addr & (target_align - 1)
1607 prolog_niters = ((VF - addr_mis/elem_size)&(VF-1))/step
1609 (elem_size = element type size; an element is the scalar element whose type
1610 is the inner type of the vectype)
1612 The computations will be emitted at the end of BB. We also compute and
1613 store upper bound (included) of the result in BOUND.
1615 When the step of the data-ref in the loop is not 1 (as in interleaved data
1616 and SLP), the number of iterations of the prolog must be divided by the step
1617 (which is equal to the size of interleaved group).
1619 The above formulas assume that VF == number of elements in the vector. This
1620 may not hold when there are multiple-types in the loop.
1621 In this case, for some data-references in the loop the VF does not represent
1622 the number of elements that fit in the vector. Therefore, instead of VF we
1623 use TYPE_VECTOR_SUBPARTS. */
1625 static tree
1628 {
1630 tree var;
1640 {
1649 }
1650 else
1651 {
1654 HOST_WIDE_INT elem_size
1660 /* Create: (niters_type) ((align_in_elems - misalign_in_elems)
1661 & (align_in_elems - 1)). */
1665 align_in_elems_tree);
1666 else
1668 misalign_in_elems);
1672 }
1675 {
1680 }
1688 {
1693 else
1695 }
1697 }
1700 /* Function vect_update_init_of_dr
1702 If CODE is PLUS, the vector loop starts NITERS iterations after the
1703 scalar one, otherwise CODE is MINUS and the vector loop starts NITERS
1704 iterations before the scalar one (using masking to skip inactive
1705 elements). This function updates the information recorded in DR to
1706 account for the difference. Specifically, it updates the OFFSET
1707 field of DR. */
1709 static void
1711 {
1720 }
1723 /* Function vect_update_inits_of_drs
1725 Apply vect_update_inits_of_dr to all accesses in LOOP_VINFO.
1726 CODE and NITERS are as for vect_update_inits_of_dr. */
1728 static void
1730 tree_code code)
1731 {
1738 /* Adjust niters to sizetype and insert stmts on loop preheader edge. */
1740 {
1741 gimple_seq seq;
1748 {
1751 }
1752 }
1755 {
1759 }
1760 }
1762 /* For the information recorded in LOOP_VINFO prepare the loop for peeling
1763 by masking. This involves calculating the number of iterations to
1764 be peeled and then aligning all memory references appropriately. */
1766 void
1768 {
1769 tree misalign_in_elems;
1774 /* From the information recorded in LOOP_VINFO get the number of iterations
1775 that need to be skipped via masking. */
1777 {
1781 }
1782 else
1783 {
1791 {
1795 }
1796 }
1799 {
1804 }
1809 }
1811 /* This function builds ni_name = number of iterations. Statements
1812 are emitted on the loop preheader edge. If NEW_VAR_P is not NULL, set
1813 it to TRUE if new ssa_var is generated. */
1815 tree
1817 {
1821 else
1822 {
1830 {
1834 }
1837 }
1838 }
1840 /* Calculate the number of iterations above which vectorized loop will be
1841 preferred than scalar loop. NITERS_PROLOG is the number of iterations
1842 of prolog loop. If it's integer const, the integer number is also passed
1843 in INT_NITERS_PROLOG. BOUND_PROLOG is the upper bound (inclusive) of the
1844 number of iterations of the prolog loop. BOUND_EPILOG is the corresponding
1845 value for the epilog loop. If CHECK_PROFITABILITY is true, TH is the
1846 threshold below which the scalar (rather than vectorized) loop will be
1847 executed. This function stores the upper bound (inclusive) of the result
1848 in BOUND_SCALAR. */
1850 static tree
1855 {
1862 {
1863 /* TH indicates the minimum niters of vectorized loop, while we
1864 compute the maximum niters of scalar loop. */
1865 th--;
1866 /* Peeling for constant times. */
1868 {
1871 }
1872 /* Peeling an unknown number of times. Note that both BOUND_PROLOG
1873 and BOUND_EPILOG are inclusive upper bounds. */
1875 {
1878 }
1879 /* Need to do runtime comparison. */
1881 {
1885 }
1886 }
1888 }
1890 /* NITERS is the number of times that the original scalar loop executes
1891 after peeling. Work out the maximum number of iterations N that can
1892 be handled by the vectorized form of the loop and then either:
1894 a) set *STEP_VECTOR_PTR to the vectorization factor and generate:
1896 niters_vector = N
1898 b) set *STEP_VECTOR_PTR to one and generate:
1900 niters_vector = N / vf
1902 In both cases, store niters_vector in *NITERS_VECTOR_PTR and add
1903 any new statements on the loop preheader edge. NITERS_NO_OVERFLOW
1904 is true if NITERS doesn't overflow (i.e. if NITERS is always nonzero). */
1906 void
1910 {
1917 /* If epilogue loop is required because of data accesses with gaps, we
1918 subtract one iteration from the total number of iterations here for
1919 correct calculation of RATIO. */
1921 {
1925 {
1931 }
1932 }
1933 else
1939 {
1940 /* Create: niters >> log2(vf) */
1941 /* If it's known that niters == number of latch executions + 1 doesn't
1942 overflow, we can generate niters >> log2(vf); otherwise we generate
1943 (niters - vf) >> log2(vf) + 1 by using the fact that we know ratio
1944 will be at least one. */
1948 else
1949 niters_vector
1953 ni_minus_gap,
1955 log_vf),
1958 }
1959 else
1960 {
1963 }
1966 {
1971 /* Peeling algorithm guarantees that vector loop bound is at least ONE,
1972 we set range information to make niters analyzer's life easier. */
1978 log_vf)));
1979 }
1984 }
1986 /* Given NITERS_VECTOR which is the number of iterations for vectorized
1987 loop specified by LOOP_VINFO after vectorization, compute the number
1988 of iterations before vectorization (niters_vector * vf) and store it
1989 to NITERS_VECTOR_MULT_VF_PTR. */
1991 static void
1993 tree niters_vector,
1995 {
1996 /* We should be using a step_vector of VF if VF is variable. */
2007 {
2014 }
2016 }
2018 /* Function slpeel_tree_duplicate_loop_to_edge_cfg duplciates FIRST/SECOND
2019 from SECOND/FIRST and puts it at the original loop's preheader/exit
2020 edge, the two loops are arranged as below:
2022 preheader_a:
2023 first_loop:
2024 header_a:
2025 i_1 = PHI<i_0, i_2>;
2026 ...
2027 i_2 = i_1 + 1;
2028 if (cond_a)
2029 goto latch_a;
2030 else
2031 goto between_bb;
2032 latch_a:
2033 goto header_a;
2035 between_bb:
2036 ;; i_x = PHI<i_2>; ;; LCSSA phi node to be created for FIRST,
2038 second_loop:
2039 header_b:
2040 i_3 = PHI<i_0, i_4>; ;; Use of i_0 to be replaced with i_x,
2041 or with i_2 if no LCSSA phi is created
2042 under condition of CREATE_LCSSA_FOR_IV_PHIS.
2043 ...
2044 i_4 = i_3 + 1;
2045 if (cond_b)
2046 goto latch_b;
2047 else
2048 goto exit_bb;
2049 latch_b:
2050 goto header_b;
2052 exit_bb:
2054 This function creates loop closed SSA for the first loop; update the
2055 second loop's PHI nodes by replacing argument on incoming edge with the
2056 result of newly created lcssa PHI nodes. IF CREATE_LCSSA_FOR_IV_PHIS
2057 is false, Loop closed ssa phis will only be created for non-iv phis for
2058 the first loop.
2060 This function assumes exit bb of the first loop is preheader bb of the
2061 second loop, i.e, between_bb in the example code. With PHIs updated,
2062 the second loop will execute rest iterations of the first. */
2064 static void
2068 {
2078 /* Either the first loop or the second is the loop to be vectorized. */
2085 {
2090 /* Generate lcssa PHI node for the first loop. */
2093 {
2098 }
2100 /* Update PHI node in the second loop by replacing arg on the loop's
2101 incoming edge. */
2103 }
2104 }
2106 /* Function slpeel_add_loop_guard adds guard skipping from the beginning
2107 of SKIP_LOOP to the beginning of UPDATE_LOOP. GUARD_EDGE and MERGE_EDGE
2108 are two pred edges of the merge point before UPDATE_LOOP. The two loops
2109 appear like below:
2111 guard_bb:
2112 if (cond)
2113 goto merge_bb;
2114 else
2115 goto skip_loop;
2117 skip_loop:
2118 header_a:
2119 i_1 = PHI<i_0, i_2>;
2120 ...
2121 i_2 = i_1 + 1;
2122 if (cond_a)
2123 goto latch_a;
2124 else
2125 goto exit_a;
2126 latch_a:
2127 goto header_a;
2129 exit_a:
2130 i_5 = PHI<i_2>;
2132 merge_bb:
2133 ;; PHI (i_x = PHI<i_0, i_5>) to be created at merge point.
2135 update_loop:
2136 header_b:
2137 i_3 = PHI<i_5, i_4>; ;; Use of i_5 to be replaced with i_x.
2138 ...
2139 i_4 = i_3 + 1;
2140 if (cond_b)
2141 goto latch_b;
2142 else
2143 goto exit_bb;
2144 latch_b:
2145 goto header_b;
2147 exit_bb:
2149 This function creates PHI nodes at merge_bb and replaces the use of i_5
2150 in the update_loop's PHI node with the result of new PHI result. */
2152 static void
2156 {
2166 {
2170 /* Generate new phi node at merge bb of the guard. */
2174 /* Merge bb has two incoming edges: GUARD_EDGE and MERGE_EDGE. Set the
2175 args in NEW_PHI for these edges. */
2183 /* Update phi in UPDATE_PHI. */
2185 }
2186 }
2188 /* LCSSA_PHI is a lcssa phi of EPILOG loop which is copied from LOOP,
2189 this function searches for the corresponding lcssa phi node in exit
2190 bb of LOOP. If it is found, return the phi result; otherwise return
2191 NULL. */
2193 static tree
2196 {
2197 gphi_iterator gsi;
2202 {
2207 }
2209 }
2211 /* LOOP and EPILOG are two consecutive loops in CFG and EPILOG is copied
2212 from LOOP. Function slpeel_add_loop_guard adds guard skipping from a
2213 point between the two loops to the end of EPILOG. Edges GUARD_EDGE
2214 and MERGE_EDGE are the two pred edges of merge_bb at the end of EPILOG.
2215 The CFG looks like:
2217 loop:
2218 header_a:
2219 i_1 = PHI<i_0, i_2>;
2220 ...
2221 i_2 = i_1 + 1;
2222 if (cond_a)
2223 goto latch_a;
2224 else
2225 goto exit_a;
2226 latch_a:
2227 goto header_a;
2229 exit_a:
2231 guard_bb:
2232 if (cond)
2233 goto merge_bb;
2234 else
2235 goto epilog_loop;
2237 ;; fall_through_bb
2239 epilog_loop:
2240 header_b:
2241 i_3 = PHI<i_2, i_4>;
2242 ...
2243 i_4 = i_3 + 1;
2244 if (cond_b)
2245 goto latch_b;
2246 else
2247 goto merge_bb;
2248 latch_b:
2249 goto header_b;
2251 merge_bb:
2252 ; PHI node (i_y = PHI<i_2, i_4>) to be created at merge point.
2254 exit_bb:
2255 i_x = PHI<i_4>; ;Use of i_4 to be replaced with i_y in merge_bb.
2257 For each name used out side EPILOG (i.e - for each name that has a lcssa
2258 phi in exit_bb) we create a new PHI in merge_bb. The new PHI has two
2259 args corresponding to GUARD_EDGE and MERGE_EDGE. Arg for MERGE_EDGE is
2260 the arg of the original PHI in exit_bb, arg for GUARD_EDGE is defined
2261 by LOOP and is found in the exit bb of LOOP. Arg of the original PHI
2262 in exit_bb will also be updated. */
2264 static void
2267 {
2268 gphi_iterator gsi;
2278 {
2281 /* This loop-closed-phi actually doesn't represent a use out of the
2282 loop - the phi arg is a constant. */
2291 /* If the var is live after loop but not a reduction, we simply
2292 use the old arg. */
2296 /* Create new phi node in MERGE_BB: */
2300 /* MERGE_BB has two incoming edges: GUARD_EDGE and MERGE_EDGE, Set
2301 the two PHI args in merge_phi for these edges. */
2305 /* Update the original phi in exit_bb. */
2307 }
2308 }
2310 /* EPILOG loop is duplicated from the original loop for vectorizing,
2311 the arg of its loop closed ssa PHI needs to be updated. */
2313 static void
2315 {
2316 gphi_iterator gsi;
2323 }
2325 /* Function vect_do_peeling.
2327 Input:
2328 - LOOP_VINFO: Represent a loop to be vectorized, which looks like:
2330 preheader:
2331 LOOP:
2332 header_bb:
2333 loop_body
2334 if (exit_loop_cond) goto exit_bb
2335 else goto header_bb
2336 exit_bb:
2338 - NITERS: The number of iterations of the loop.
2339 - NITERSM1: The number of iterations of the loop's latch.
2340 - NITERS_NO_OVERFLOW: No overflow in computing NITERS.
2341 - TH, CHECK_PROFITABILITY: Threshold of niters to vectorize loop if
2342 CHECK_PROFITABILITY is true.
2343 Output:
2344 - *NITERS_VECTOR and *STEP_VECTOR describe how the main loop should
2345 iterate after vectorization; see vect_set_loop_condition for details.
2346 - *NITERS_VECTOR_MULT_VF_VAR is either null or an SSA name that
2347 should be set to the number of scalar iterations handled by the
2348 vector loop. The SSA name is only used on exit from the loop.
2350 This function peels prolog and epilog from the loop, adds guards skipping
2351 PROLOG and EPILOG for various conditions. As a result, the changed CFG
2352 would look like:
2354 guard_bb_1:
2355 if (prefer_scalar_loop) goto merge_bb_1
2356 else goto guard_bb_2
2358 guard_bb_2:
2359 if (skip_prolog) goto merge_bb_2
2360 else goto prolog_preheader
2362 prolog_preheader:
2363 PROLOG:
2364 prolog_header_bb:
2365 prolog_body
2366 if (exit_prolog_cond) goto prolog_exit_bb
2367 else goto prolog_header_bb
2368 prolog_exit_bb:
2370 merge_bb_2:
2372 vector_preheader:
2373 VECTOR LOOP:
2374 vector_header_bb:
2375 vector_body
2376 if (exit_vector_cond) goto vector_exit_bb
2377 else goto vector_header_bb
2378 vector_exit_bb:
2380 guard_bb_3:
2381 if (skip_epilog) goto merge_bb_3
2382 else goto epilog_preheader
2384 merge_bb_1:
2386 epilog_preheader:
2387 EPILOG:
2388 epilog_header_bb:
2389 epilog_body
2390 if (exit_epilog_cond) goto merge_bb_3
2391 else goto epilog_header_bb
2393 merge_bb_3:
2395 Note this function peels prolog and epilog only if it's necessary,
2396 as well as guards.
2397 Returns created epilogue or NULL.
2399 TODO: Guard for prefer_scalar_loop should be emitted along with
2400 versioning conditions if loop versioning is needed. */
2408 {
2445 {
2448 }
2451 /* Record the anchor bb at which the guard should be placed if the scalar
2452 loop might be preferred. */
2455 /* Generate the number of iterations for the prolog loop. We do this here
2456 so that we can also get the upper bound on the number of iterations. */
2457 tree niters_prolog;
2462 else
2465 /* Prolog loop may be skipped. */
2467 /* Skip to epilog if scalar loop may be preferred. It's only needed
2468 when we peel for epilog loop and when it hasn't been checked with
2469 loop versioning. */
2474 /* Epilog loop must be executed if the number of iterations for epilog
2475 loop is known at compile time, otherwise we need to add a check at
2476 the end of vector loop and skip to the end of epilog loop. */
2480 /* PEELING_FOR_GAPS is special because epilog loop must be executed. */
2485 {
2488 /* Due to the order in which we peel prolog and epilog, we first
2489 propagate probability to the whole loop. The purpose is to
2490 avoid adjusting probabilities of both prolog and vector loops
2491 separately. Note in this case, the probability of epilog loop
2492 needs to be scaled back later. */
2495 {
2498 }
2499 }
2504 {
2507 {
2511 }
2512 /* Peel prolog and put it on preheader edge of loop. */
2515 {
2519 }
2524 /* Update the number of iterations for prolog loop. */
2529 /* Skip the prolog loop. */
2531 {
2540 irred_flag);
2547 }
2548 /* Update init address of DRs. */
2550 /* Update niters for vector loop. */
2558 /* It's guaranteed that vector loop bound before vectorization is at
2559 least VF, so set range information for newly generated var. */
2565 /* Prolog iterates at most bound_prolog times, latch iterates at
2566 most bound_prolog - 1 times. */
2571 }
2574 {
2577 {
2581 }
2582 /* Peel epilog and put it on exit edge of loop. */
2585 {
2589 }
2592 /* Scalar version loop may be preferred. In this case, add guard
2593 and skip to epilog. Note this only happens when the number of
2594 iterations of loop is unknown at compile time, otherwise this
2595 won't be vectorized. */
2597 {
2598 /* Additional epilogue iteration is peeled if gap exists. */
2602 check_profitability);
2603 /* Build guard against NITERSM1 since NITERS may overflow. */
2610 irred_flag);
2615 /* Simply propagate profile info from guard_bb to guard_to which is
2616 a merge point of control flow. */
2619 /* Scale probability of epilog loop back.
2620 FIXME: We should avoid scaling down and back up. Profile may
2621 get lost if we scale down to 0. */
2629 }
2632 tree niters_vector_mult_vf;
2633 /* If loop is peeled for non-zero constant times, now niters refers to
2634 orig_niters - prolog_peeling, it won't overflow even the orig_niters
2635 overflows. */
2639 niters_no_overflow);
2641 {
2642 /* On exit from the loop we will have an easy way of calcalating
2643 NITERS_VECTOR / STEP * STEP. Install a dummy definition
2644 until then. */
2648 }
2649 else
2652 /* Update IVs of original loop as if they were advanced by
2653 niters_vector_mult_vf steps. */
2657 update_e);
2660 {
2668 irred_flag);
2671 /* Only need to handle basic block before epilog loop if it's not
2672 the guard_bb, which is the case when skip_vector is true. */
2674 {
2678 }
2680 }
2681 else
2686 {
2688 /* -1 to convert loop iterations to latch iterations. */
2690 }
2695 }
2700 }
2702 /* Function vect_create_cond_for_niters_checks.
2704 Create a conditional expression that represents the run-time checks for
2705 loop's niter. The loop is guaranteed to terminate if the run-time
2706 checks hold.
2708 Input:
2709 COND_EXPR - input conditional expression. New conditions will be chained
2710 with logical AND operation. If it is NULL, then the function
2711 is used to return the number of alias checks.
2712 LOOP_VINFO - field LOOP_VINFO_MAY_ALIAS_STMTS contains the list of ddrs
2713 to be checked.
2715 Output:
2716 COND_EXPR - conditional expression.
2718 The returned COND_EXPR is the conditional expression to be used in the
2719 if statement that controls which version of the loop gets executed at
2720 runtime. */
2722 static void
2724 {
2730 else
2732 }
2734 /* Set *COND_EXPR to a tree that is true when both the original *COND_EXPR
2735 and PART_COND_EXPR are true. Treat a null *COND_EXPR as "true". */
2737 static void
2739 {
2743 else
2745 }
2747 /* Function vect_create_cond_for_align_checks.
2749 Create a conditional expression that represents the alignment checks for
2750 all of data references (array element references) whose alignment must be
2751 checked at runtime.
2753 Input:
2754 COND_EXPR - input conditional expression. New conditions will be chained
2755 with logical AND operation.
2756 LOOP_VINFO - two fields of the loop information are used.
2757 LOOP_VINFO_PTR_MASK is the mask used to check the alignment.
2758 LOOP_VINFO_MAY_MISALIGN_STMTS contains the refs to be checked.
2760 Output:
2761 COND_EXPR_STMT_LIST - statements needed to construct the conditional
2762 expression.
2763 The returned value is the conditional expression to be used in the if
2764 statement that controls which version of the loop gets executed at runtime.
2766 The algorithm makes two assumptions:
2767 1) The number of bytes "n" in a vector is a power of 2.
2768 2) An address "a" is aligned if a%n is zero and that this
2769 test can be done as a&(n-1) == 0. For example, for 16
2770 byte vectors the test is a&0xf == 0. */
2772 static void
2776 {
2781 tree mask_cst;
2783 tree int_ptrsize_type;
2786 tree and_tmp_name;
2788 tree ptrsize_zero;
2789 tree part_cond_expr;
2791 /* Check that mask is one less than a power of 2, i.e., mask is
2792 all zeros followed by all ones. */
2797 /* Create expression (mask & (dr_1 || ... || dr_n)) where dr_i is the address
2798 of the first vector of the i'th data reference. */
2801 {
2803 tree addr_base;
2804 tree addr_tmp_name;
2805 tree new_or_tmp_name;
2811 tree offset = negative
2814 /* create: addr_tmp = (int)(address_of_first_vector) */
2815 addr_base =
2817 offset);
2826 /* The addresses are OR together. */
2829 {
2830 /* create: or_tmp = or_tmp | addr_tmp */
2837 }
2838 else
2845 /* create: and_tmp = or_tmp & mask */
2852 /* Make and_tmp the left operand of the conditional test against zero.
2853 if and_tmp has a nonzero bit then some address is unaligned. */
2858 }
2860 /* If LOOP_VINFO_CHECK_UNEQUAL_ADDRS contains <A1, B1>, ..., <An, Bn>,
2861 create a tree representation of: (&A1 != &B1) && ... && (&An != &Bn).
2862 Set *COND_EXPR to a tree that is true when both the original *COND_EXPR
2863 and this new condition are true. Treat a null *COND_EXPR as "true". */
2865 static void
2867 {
2872 {
2878 }
2879 }
2881 /* Create an expression that is true when all lower-bound conditions for
2882 the vectorized loop are met. Chain this condition with *COND_EXPR. */
2884 static void
2886 {
2889 {
2895 {
2899 }
2903 }
2904 }
2906 /* Function vect_create_cond_for_alias_checks.
2908 Create a conditional expression that represents the run-time checks for
2909 overlapping of address ranges represented by a list of data references
2910 relations passed as input.
2912 Input:
2913 COND_EXPR - input conditional expression. New conditions will be chained
2914 with logical AND operation. If it is NULL, then the function
2915 is used to return the number of alias checks.
2916 LOOP_VINFO - field LOOP_VINFO_MAY_ALIAS_STMTS contains the list of ddrs
2917 to be checked.
2919 Output:
2920 COND_EXPR - conditional expression.
2922 The returned COND_EXPR is the conditional expression to be used in the if
2923 statement that controls which version of the loop gets executed at runtime.
2924 */
2926 void
2928 {
2941 }
2944 /* Function vect_loop_versioning.
2946 If the loop has data references that may or may not be aligned or/and
2947 has data reference relations whose independence was not proven then
2948 two versions of the loop need to be generated, one which is vectorized
2949 and one which isn't. A test is then generated to control which of the
2950 loops is executed. The test checks for the alignment of all of the
2951 data references that may or may not be aligned. An additional
2952 sequence of runtime tests is generated for each pairs of DDRs whose
2953 independence was not proven. The vectorized version of loop is
2954 executed only if both alias and alignment tests are passed.
2956 The test generated to check which version of loop is executed
2957 is modified to also check for profitability as indicated by the
2958 cost model threshold TH.
2960 The versioning precondition(s) are placed in *COND_EXPR and
2961 *COND_EXPR_STMT_LIST. */
2963 void
2966 poly_uint64 versioning_threshold)
2967 {
2970 basic_block condition_bb;
2971 gphi_iterator gsi;
2972 gimple_stmt_iterator cond_exp_gsi;
2973 basic_block merge_bb;
2974 basic_block new_exit_bb;
2979 tree arg;
2992 {
2999 else
3001 }
3015 {
3019 }
3028 {
3029 edge scalar_e;
3032 /* We don't want to scale SCALAR_LOOP's frequencies, we need to
3033 scale LOOP's frequencies instead. */
3037 /* CONDITION_BB was created above SCALAR_LOOP's preheader,
3038 while we need to move it above LOOP's preheader. */
3041 /* The vector loop preheader might not be empty, since new
3042 invariants could have been created while analyzing the loop. */
3052 scalar_preheader);
3060 condition_bb);
3061 }
3062 else
3067 {
3068 /* The versioned loop could be infinite, we need to clear existing
3069 niter information which is copied from the original loop. */
3072 /* And set constraint LOOP_C_INFINITE for niter analyzer. */
3074 }
3078 {
3081 "loop versioned for vectorization because of "
3085 "loop versioned for vectorization to enhance "
3088 }
3091 /* Loop versioning violates an assumption we try to maintain during
3092 vectorization - that the loop exit block has a single predecessor.
3093 After versioning, the exit block of both loop versions is the same
3094 basic block (i.e. it has two predecessors). Just in order to simplify
3095 following transformations in the vectorizer, we fix this situation
3096 here by adding a new (empty) block on the exit-edge of the loop,
3097 with the proper loop-exit phis to maintain loop-closed-form.
3098 If loop versioning wasn't done from loop, but scalar_loop instead,
3099 merge_bb will have already just a single successor. */
3103 {
3110 {
3111 tree new_res;
3119 }
3120 }
3122 /* End loop-exit-fixes after versioning. */
3125 {
3128 GSI_SAME_STMT);
3129 }
3131 }