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1 /* Analysis Utilities for Loop Vectorization.
2 Copyright (C) 2003,2004,2005 Free Software Foundation, Inc.
3 Contributed by Dorit Naishlos <dorit@il.ibm.com>
5 This file is part of GCC.
7 GCC is free software; you can redistribute it and/or modify it under
8 the terms of the GNU General Public License as published by the Free
9 Software Foundation; either version 2, or (at your option) any later
10 version.
12 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
13 WARRANTY; without even the implied warranty of MERCHANTABILITY or
14 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
15 for more details.
17 You should have received a copy of the GNU General Public License
18 along with GCC; see the file COPYING. If not, write to the Free
19 Software Foundation, 59 Temple Place - Suite 330, Boston, MA
20 02111-1307, USA. */
42 /* Main analysis functions. */
55 /* Utility functions for the analyses. */
60 static bool vect_analyze_data_ref_dependence
75 subvar_t *);
81 /* Function vect_get_ptr_offset
83 Compute the OFFSET modulo vector-type alignment of pointer REF in bits. */
85 static tree
87 tree vectype ATTRIBUTE_UNUSED,
89 {
90 /* TODO: Use alignment information. */
92 }
95 /* Function vect_analyze_offset_expr
97 Given an offset expression EXPR received from get_inner_reference, analyze
98 it and create an expression for INITIAL_OFFSET by substituting the variables
99 of EXPR with initial_condition of the corresponding access_fn in the loop.
100 E.g.,
101 for i
102 for (j = 3; j < N; j++)
103 a[j].b[i][j] = 0;
105 For a[j].b[i][j], EXPR will be 'i * C_i + j * C_j + C'. 'i' cannot be
106 substituted, since its access_fn in the inner loop is i. 'j' will be
107 substituted with 3. An INITIAL_OFFSET will be 'i * C_i + C`', where
108 C` = 3 * C_j + C.
110 Compute MISALIGN (the misalignment of the data reference initial access from
111 its base) if possible. Misalignment can be calculated only if all the
112 variables can be substituted with constants, or if a variable is multiplied
113 by a multiple of VECTYPE_ALIGNMENT. In the above example, since 'i' cannot
114 be substituted, MISALIGN will be NULL_TREE in case that C_i is not a multiple
115 of VECTYPE_ALIGNMENT, and C` otherwise. (We perform MISALIGN modulo
116 VECTYPE_ALIGNMENT computation in the caller of this function).
118 STEP is an evolution of the data reference in this loop in bytes.
119 In the above example, STEP is C_j.
121 Return FALSE, if the analysis fails, e.g., there is no access_fn for a
122 variable. In this case, all the outputs (INITIAL_OFFSET, MISALIGN and STEP)
123 are NULL_TREEs. Otherwise, return TRUE.
125 */
127 static bool
130 tree vectype_alignment,
134 {
135 tree oprnd0;
136 tree oprnd1;
150 /* Strip conversions that don't narrow the mode. */
155 /* Stop conditions:
156 1. Constant. */
158 {
163 }
165 /* 2. Variable. Try to substitute with initial_condition of the corresponding
166 access_fn in the current loop. */
168 {
172 /* No access_fn. */
177 /* Not enough information: may be not loop invariant.
178 E.g., for a[b[i]], we get a[D], where D=b[i]. EXPR is D, its
179 initial_condition is D, but it depends on i - loop's induction
180 variable. */
185 /* Evolution is not constant. */
190 else
191 /* Not constant, misalignment cannot be calculated. */
198 }
200 /* Recursive computation. */
202 {
203 /* We expect to get binary expressions (PLUS/MINUS and MULT). */
205 {
208 }
210 }
220 /* The type of the operation: plus, minus or mult. */
223 {
226 /* RIGHT_OFFSET can be not constant. For example, for arrays of variable
227 sized types.
228 FORNOW: We don't support such cases. */
231 /* Strip conversions that don't narrow the mode. */
235 /* Misalignment computation. */
237 {
238 /* If the left side contains variables that can't be substituted with
239 constants, we check if the right side is a multiple of ALIGNMENT.
240 */
244 else
245 /* If the remainder is not zero or the right side isn't constant,
246 we can't compute misalignment. */
248 }
249 else
250 {
251 /* The left operand was successfully substituted with constant. */
253 /* In case of EXPR '(i * C1 + j) * C2', LEFT_MISALIGN is
254 NULL_TREE. */
256 else
258 }
260 /* Step calculation. */
261 /* Multiply the step by the right operand. */
267 /* Combine the recursive calculations for step and misalignment. */
272 else
279 }
281 /* Compute offset. */
284 left_offset,
285 right_offset)));
287 }
290 /* Function vect_determine_vectorization_factor
292 Determine the vectorization factor (VF). VF is the number of data elements
293 that are operated upon in parallel in a single iteration of the vectorized
294 loop. For example, when vectorizing a loop that operates on 4byte elements,
295 on a target with vector size (VS) 16byte, the VF is set to 4, since 4
296 elements can fit in a single vector register.
298 We currently support vectorization of loops in which all types operated upon
299 are of the same size. Therefore this function currently sets VF according to
300 the size of the types operated upon, and fails if there are multiple sizes
301 in the loop.
303 VF is also the factor by which the loop iterations are strip-mined, e.g.:
304 original loop:
305 for (i=0; i<N; i++){
306 a[i] = b[i] + c[i];
307 }
309 vectorized loop:
310 for (i=0; i<N; i+=VF){
311 a[i:VF] = b[i:VF] + c[i:VF];
312 }
313 */
315 static bool
317 {
321 block_stmt_iterator si;
324 tree scalar_type;
330 {
334 {
338 tree vectype;
341 {
344 }
347 /* skip stmts which do not need to be vectorized. */
352 {
355 {
358 }
360 }
366 else
370 {
373 }
377 {
380 {
383 }
385 }
387 {
390 }
398 {
399 /* FORNOW: don't allow mixed units.
400 This restriction will be relaxed in the future. */
402 {
407 }
408 }
409 else
412 #ifdef ENABLE_CHECKING
415 #endif
416 }
417 }
419 /* TODO: Analyze cost. Decide if worth while to vectorize. */
422 {
427 }
431 }
434 /* Function vect_analyze_operations.
436 Scan the loop stmts and make sure they are all vectorizable. */
438 static bool
440 {
444 block_stmt_iterator si;
456 {
460 {
465 {
468 }
472 /* skip stmts which do not need to be vectorized.
473 this is expected to include:
474 - the COND_EXPR which is the loop exit condition
475 - any LABEL_EXPRs in the loop
476 - computations that are used only for array indexing or loop
477 control */
480 {
484 }
486 #ifdef ENABLE_CHECKING
488 {
491 }
492 #endif
501 {
504 {
507 }
509 }
510 }
511 }
513 /* TODO: Analyze cost. Decide if worth while to vectorize. */
523 {
528 }
532 {
536 {
542 }
544 {
550 }
551 }
554 }
557 /* Function exist_non_indexing_operands_for_use_p
559 USE is one of the uses attached to STMT. Check if USE is
560 used in STMT for anything other than indexing an array. */
562 static bool
564 {
565 tree operand;
568 /* USE corresponds to some operand in STMT. If there is no data
569 reference in STMT, then any operand that corresponds to USE
570 is not indexing an array. */
574 /* STMT has a data_ref. FORNOW this means that its of one of
575 the following forms:
576 -1- ARRAY_REF = var
577 -2- var = ARRAY_REF
578 (This should have been verified in analyze_data_refs).
580 'var' in the second case corresponds to a def, not a use,
581 so USE cannot correspond to any operands that are not used
582 for array indexing.
584 Therefore, all we need to check is if STMT falls into the
585 first case, and whether var corresponds to USE. */
599 }
602 /* Function vect_analyze_scalar_cycles.
604 Examine the cross iteration def-use cycles of scalar variables, by
605 analyzing the loop (scalar) PHIs; verify that the cross iteration def-use
606 cycles that they represent do not impede vectorization.
608 FORNOW: Reduction as in the following loop, is not supported yet:
609 loop1:
610 for (i=0; i<N; i++)
611 sum += a[i];
612 The cross-iteration cycle corresponding to variable 'sum' will be
613 considered too complicated and will impede vectorization.
615 FORNOW: Induction as in the following loop, is not supported yet:
616 loop2:
617 for (i=0; i<N; i++)
618 a[i] = i;
620 However, the following loop *is* vectorizable:
621 loop3:
622 for (i=0; i<N; i++)
623 a[i] = b[i];
625 In both loops there exists a def-use cycle for the variable i:
626 loop: i_2 = PHI (i_0, i_1)
627 a[i_2] = ...;
628 i_1 = i_2 + 1;
629 GOTO loop;
631 The evolution of the above cycle is considered simple enough,
632 however, we also check that the cycle does not need to be
633 vectorized, i.e - we check that the variable that this cycle
634 defines is only used for array indexing or in stmts that do not
635 need to be vectorized. This is not the case in loop2, but it
636 *is* the case in loop3. */
638 static bool
640 {
641 tree phi;
644 tree dummy;
650 {
654 {
657 }
659 /* Skip virtual phi's. The data dependences that are associated with
660 virtual defs/uses (i.e., memory accesses) are analyzed elsewhere. */
663 {
667 }
669 /* Analyze the evolution function. */
671 /* FORNOW: The only scalar cross-iteration cycles that we allow are
672 those of loop induction variables; This property is verified here.
674 Furthermore, if that induction variable is used in an operation
675 that needs to be vectorized (i.e, is not solely used to index
676 arrays and check the exit condition) - we do not support its
677 vectorization yet. This property is verified in vect_is_simple_use,
678 during vect_analyze_operations. */
681 (loop,*/
685 {
690 }
694 {
697 }
700 {
705 }
706 }
709 }
712 /* Function vect_base_addr_differ_p.
714 This is the simplest data dependence test: determines whether the
715 data references A and B access the same array/region. Returns
716 false when the property is not computable at compile time.
717 Otherwise return true, and DIFFER_P will record the result. This
718 utility will not be necessary when alias_sets_conflict_p will be
719 less conservative. */
721 static bool
725 {
738 /* Both references are ADDR_EXPR, i.e., we have the objects. */
748 {
751 }
753 /* An instruction writing through a restricted pointer is "independent" of any
754 instruction reading or writing through a different pointer, in the same
755 block/scope. */
758 {
761 }
763 }
766 /* Function vect_analyze_data_ref_dependence.
768 Return TRUE if there (might) exist a dependence between a memory-reference
769 DRA and a memory-reference DRB. */
771 static bool
774 loop_vec_info loop_vinfo)
775 {
786 {
789 {
795 }
797 }
809 {
812 {
818 }
820 }
822 /* Find loop depth. */
824 {
826 {
828 loop_depth++;
829 }
830 else
832 }
834 /* Compute distance vector. */
839 {
842 {
847 }
849 }
853 /* Same loop iteration. */
855 {
859 }
862 /* Dependence distance does not create dependence, as far as vectorization
863 is concerned, in this case. */
868 {
874 }
877 }
880 /* Function vect_analyze_data_ref_dependences.
882 Examine all the data references in the loop, and make sure there do not
883 exist any data dependences between them. */
885 static bool
887 {
892 /* Examine store-store (output) dependences. */
901 {
903 {
910 }
911 }
913 /* Examine load-store (true/anti) dependences. */
919 {
921 {
927 }
928 }
931 }
934 /* Function vect_compute_data_ref_alignment
936 Compute the misalignment of the data reference DR.
938 Output:
939 1. If during the misalignment computation it is found that the data reference
940 cannot be vectorized then false is returned.
941 2. DR_MISALIGNMENT (DR) is defined.
943 FOR NOW: No analysis is actually performed. Misalignment is calculated
944 only for trivial cases. TODO. */
946 static bool
948 {
952 tree vectype;
955 tree misalign;
960 /* Initialize misalignment to unknown. */
969 {
971 {
974 }
976 }
979 {
981 {
983 {
986 }
988 }
990 /* Force the alignment of the decl.
991 NOTE: This is the only change to the code we make during
992 the analysis phase, before deciding to vectorize the loop. */
997 }
999 /* At this point we assume that the base is aligned. */
1004 /* Alignment required, in bytes: */
1007 /* Modulo alignment. */
1010 {
1011 /* Negative misalignment value. */
1015 }
1023 }
1026 /* Function vect_compute_data_refs_alignment
1028 Compute the misalignment of data references in the loop.
1029 This pass may take place at function granularity instead of at loop
1030 granularity.
1032 FOR NOW: No analysis is actually performed. Misalignment is calculated
1033 only for trivial cases. TODO. */
1035 static bool
1037 {
1043 {
1047 }
1050 {
1054 }
1057 }
1060 /* Function vect_enhance_data_refs_alignment
1062 This pass will use loop versioning and loop peeling in order to enhance
1063 the alignment of data references in the loop.
1065 FOR NOW: we assume that whatever versioning/peeling takes place, only the
1066 original loop is to be vectorized; Any other loops that are created by
1067 the transformations performed in this pass - are not supposed to be
1068 vectorized. This restriction will be relaxed. */
1070 static void
1072 {
1075 varray_type datarefs;
1079 /*
1080 This pass will require a cost model to guide it whether to apply peeling
1081 or versioning or a combination of the two. For example, the scheme that
1082 intel uses when given a loop with several memory accesses, is as follows:
1083 choose one memory access ('p') which alignment you want to force by doing
1084 peeling. Then, either (1) generate a loop in which 'p' is aligned and all
1085 other accesses are not necessarily aligned, or (2) use loop versioning to
1086 generate one loop in which all accesses are aligned, and another loop in
1087 which only 'p' is necessarily aligned.
1089 ("Automatic Intra-Register Vectorization for the Intel Architecture",
1090 Aart J.C. Bik, Milind Girkar, Paul M. Grey and Ximmin Tian, International
1091 Journal of Parallel Programming, Vol. 30, No. 2, April 2002.)
1093 Devising a cost model is the most critical aspect of this work. It will
1094 guide us on which access to peel for, whether to use loop versioning, how
1095 many versions to create, etc. The cost model will probably consist of
1096 generic considerations as well as target specific considerations (on
1097 powerpc for example, misaligned stores are more painful than misaligned
1098 loads).
1100 Here is the general steps involved in alignment enhancements:
1102 -- original loop, before alignment analysis:
1103 for (i=0; i<N; i++){
1104 x = q[i]; # DR_MISALIGNMENT(q) = unknown
1105 p[i] = y; # DR_MISALIGNMENT(p) = unknown
1106 }
1108 -- After vect_compute_data_refs_alignment:
1109 for (i=0; i<N; i++){
1110 x = q[i]; # DR_MISALIGNMENT(q) = 3
1111 p[i] = y; # DR_MISALIGNMENT(p) = unknown
1112 }
1114 -- Possibility 1: we do loop versioning:
1115 if (p is aligned) {
1116 for (i=0; i<N; i++){ # loop 1A
1117 x = q[i]; # DR_MISALIGNMENT(q) = 3
1118 p[i] = y; # DR_MISALIGNMENT(p) = 0
1119 }
1120 }
1121 else {
1122 for (i=0; i<N; i++){ # loop 1B
1123 x = q[i]; # DR_MISALIGNMENT(q) = 3
1124 p[i] = y; # DR_MISALIGNMENT(p) = unaligned
1125 }
1126 }
1128 -- Possibility 2: we do loop peeling:
1129 for (i = 0; i < 3; i++){ # (scalar loop, not to be vectorized).
1130 x = q[i];
1131 p[i] = y;
1132 }
1133 for (i = 3; i < N; i++){ # loop 2A
1134 x = q[i]; # DR_MISALIGNMENT(q) = 0
1135 p[i] = y; # DR_MISALIGNMENT(p) = unknown
1136 }
1138 -- Possibility 3: combination of loop peeling and versioning:
1139 for (i = 0; i < 3; i++){ # (scalar loop, not to be vectorized).
1140 x = q[i];
1141 p[i] = y;
1142 }
1143 if (p is aligned) {
1144 for (i = 3; i<N; i++){ # loop 3A
1145 x = q[i]; # DR_MISALIGNMENT(q) = 0
1146 p[i] = y; # DR_MISALIGNMENT(p) = 0
1147 }
1148 }
1149 else {
1150 for (i = 3; i<N; i++){ # loop 3B
1151 x = q[i]; # DR_MISALIGNMENT(q) = 0
1152 p[i] = y; # DR_MISALIGNMENT(p) = unaligned
1153 }
1154 }
1156 These loops are later passed to loop_transform to be vectorized. The
1157 vectorizer will use the alignment information to guide the transformation
1158 (whether to generate regular loads/stores, or with special handling for
1159 misalignment).
1160 */
1162 /* (1) Peeling to force alignment. */
1164 /* (1.1) Decide whether to perform peeling, and how many iterations to peel:
1165 Considerations:
1166 + How many accesses will become aligned due to the peeling
1167 - How many accesses will become unaligned due to the peeling,
1168 and the cost of misaligned accesses.
1169 - The cost of peeling (the extra runtime checks, the increase
1170 in code size).
1172 The scheme we use FORNOW: peel to force the alignment of the first
1173 misaligned store in the loop.
1174 Rationale: misaligned stores are not yet supported.
1176 TODO: Use a better cost model. */
1179 {
1182 {
1186 }
1187 }
1189 /* (1.2) Update the alignment info according to the peeling factor.
1190 If the misalignment of the DR we peel for is M, then the
1191 peeling factor is VF - M, and the misalignment of each access DR_i
1192 in the loop is DR_MISALIGNMENT (DR_i) + VF - M.
1193 If the misalignment of the DR we peel for is unknown, then the
1194 misalignment of each access DR_i in the loop is also unknown.
1196 TODO: - consider accesses that are known to have the same
1197 alignment, even if that alignment is unknown. */
1200 {
1205 {
1206 /* Since it's known at compile time, compute the number of iterations
1207 in the peeled loop (the peeling factor) for use in updating
1208 DR_MISALIGNMENT values. The peeling factor is the vectorization
1209 factor minus the misalignment as an element count. */
1213 }
1217 {
1219 {
1229 {
1234 }
1235 else
1237 }
1239 }
1242 }
1243 }
1246 /* Function vect_analyze_data_refs_alignment
1248 Analyze the alignment of the data-references in the loop.
1249 FOR NOW: Until support for misliagned accesses is in place, only if all
1250 accesses are aligned can the loop be vectorized. This restriction will be
1251 relaxed. */
1253 static bool
1255 {
1265 /* This pass may take place at function granularity instead of at loop
1266 granularity. */
1269 {
1275 }
1278 /* This pass will decide on using loop versioning and/or loop peeling in
1279 order to enhance the alignment of data references in the loop. */
1284 /* Finally, check that all the data references in the loop can be
1285 handled with respect to their alignment. */
1288 {
1292 {
1297 }
1301 }
1303 {
1307 {
1312 }
1316 }
1322 }
1325 /* Function vect_analyze_data_ref_access.
1327 Analyze the access pattern of the data-reference DR. For now, a data access
1328 has to consecutive to be considered vectorizable. */
1330 static bool
1332 {
1339 {
1343 }
1345 }
1348 /* Function vect_analyze_data_ref_accesses.
1350 Analyze the access pattern of all the data references in the loop.
1352 FORNOW: the only access pattern that is considered vectorizable is a
1353 simple step 1 (consecutive) access.
1355 FORNOW: handle only arrays and pointer accesses. */
1357 static bool
1359 {
1368 {
1372 {
1377 }
1378 }
1381 {
1385 {
1390 }
1391 }
1394 }
1397 /* Function vect_analyze_pointer_ref_access.
1399 Input:
1400 STMT - a stmt that contains a data-ref.
1401 MEMREF - a data-ref in STMT, which is an INDIRECT_REF.
1402 ACCESS_FN - the access function of MEMREF.
1404 Output:
1405 If the data-ref access is vectorizable, return a data_reference structure
1406 that represents it (DR). Otherwise - return NULL.
1407 STEP - the stride of MEMREF in the loop.
1408 INIT - the initial condition of MEMREF in the loop.
1409 */
1414 {
1420 tree indx_access_fn;
1425 {
1430 }
1435 {
1441 }
1444 {
1450 }
1454 {
1459 }
1462 {
1467 }
1472 {
1477 }
1479 /* Check that STEP is a multiple of type size. */
1482 {
1487 }
1489 indx_access_fn =
1492 {
1495 }
1499 }
1502 /* Function vect_address_analysis
1504 Return the BASE of the address expression EXPR.
1505 Also compute the INITIAL_OFFSET from BASE, MISALIGN and STEP.
1507 Input:
1508 EXPR - the address expression that is being analyzed
1509 STMT - the statement that contains EXPR or its original memory reference
1510 IS_READ - TRUE if STMT reads from EXPR, FALSE if writes to EXPR
1511 VECTYPE - the type that defines the alignment (i.e, we compute
1512 alignment relative to TYPE_ALIGN(VECTYPE))
1513 DR - data_reference struct for the original memory reference
1515 Output:
1516 BASE (returned value) - the base of the data reference EXPR.
1517 INITIAL_OFFSET - initial offset of EXPR from BASE (an expression)
1518 MISALIGN - offset of EXPR from BASE in bytes (a constant) or NULL_TREE if the
1519 computation is impossible
1520 STEP - evolution of EXPR in the loop
1521 BASE_ALIGNED - indicates if BASE is aligned
1523 If something unexpected is encountered (an unsupported form of data-ref),
1524 then NULL_TREE is returned.
1525 */
1527 static tree
1531 {
1534 tree dummy;
1536 subvar_t dummy2;
1539 {
1542 /* EXPR is of form {base +/- offset} (or {offset +/- base}). */
1549 /* Recursively try to find the base of the address contained in EXPR.
1550 For offset, the returned base will be NULL. */
1553 base_aligned);
1557 base_aligned);
1559 /* We support cases where only one of the operands contains an
1560 address. */
1564 /* To revert STRIP_NOPS. */
1571 /* EXPR is of form {base +/- offset} (or {offset +/- base}). If offset is
1572 a number, we can add it to the misalignment value calculated for base,
1573 otherwise, misalignment is NULL. */
1576 offset_expr);
1577 else
1580 /* Combine offset (from EXPR {base + offset}) with the offset calculated
1581 for base. */
1597 {
1600 else
1602 }
1603 else
1604 {
1607 }
1614 }
1615 }
1618 /* Function vect_object_analysis
1620 Return the BASE of the data reference MEMREF.
1621 Also compute the INITIAL_OFFSET from BASE, MISALIGN and STEP.
1622 E.g., for EXPR a.b[i] + 4B, BASE is a, and OFFSET is the overall offset
1623 'a.b[i] + 4B' from a (can be an expression), MISALIGN is an OFFSET
1624 instantiated with initial_conditions of access_functions of variables,
1625 modulo alignment, and STEP is the evolution of the DR_REF in this loop.
1627 Function get_inner_reference is used for the above in case of ARRAY_REF and
1628 COMPONENT_REF.
1630 The structure of the function is as follows:
1631 Part 1:
1632 Case 1. For handled_component_p refs
1633 1.1 call get_inner_reference
1634 1.1.1 analyze offset expr received from get_inner_reference
1635 1.2. build data-reference structure for MEMREF
1636 (fall through with BASE)
1637 Case 2. For declarations
1638 2.1 check alignment
1639 2.2 update DR_BASE_NAME if necessary for alias
1640 Case 3. For INDIRECT_REFs
1641 3.1 get the access function
1642 3.2 analyze evolution of MEMREF
1643 3.3 set data-reference structure for MEMREF
1644 3.4 call vect_address_analysis to analyze INIT of the access function
1646 Part 2:
1647 Combine the results of object and address analysis to calculate
1648 INITIAL_OFFSET, STEP and misalignment info.
1650 Input:
1651 MEMREF - the memory reference that is being analyzed
1652 STMT - the statement that contains MEMREF
1653 IS_READ - TRUE if STMT reads from MEMREF, FALSE if writes to MEMREF
1654 VECTYPE - the type that defines the alignment (i.e, we compute
1655 alignment relative to TYPE_ALIGN(VECTYPE))
1657 Output:
1658 BASE_ADDRESS (returned value) - the base address of the data reference MEMREF
1659 E.g, if MEMREF is a.b[k].c[i][j] the returned
1660 base is &a.
1661 DR - data_reference struct for MEMREF
1662 INITIAL_OFFSET - initial offset of MEMREF from BASE (an expression)
1663 MISALIGN - offset of MEMREF from BASE in bytes (a constant) or NULL_TREE if
1664 the computation is impossible
1665 STEP - evolution of the DR_REF in the loop
1666 BASE_ALIGNED - indicates if BASE is aligned
1667 MEMTAG - memory tag for aliasing purposes
1668 PTR_INFO - NULL or points-to aliasing info from a pointer SSA_NAME
1669 SUBVAR - Sub-variables of the variable
1671 If something unexpected is encountered (an unsupported form of data-ref),
1672 then NULL_TREE is returned. */
1674 static tree
1680 {
1699 /* Part 1: */
1700 /* Case 1. handled_component_p refs. */
1702 {
1703 /* 1.1 call get_inner_reference. */
1704 /* Find the base and the offset from it. */
1710 /* 1.1.1 analyze offset expr received from get_inner_reference. */
1714 {
1716 {
1719 }
1721 }
1723 /* Add bit position to OFFSET and MISALIGN. */
1726 /* Check that there is no remainder in bits. */
1728 {
1732 }
1736 bit_pos_in_bytes);
1738 /* Create data-reference for MEMREF. TODO: handle COMPONENT_REFs. */
1740 {
1743 else
1744 /* FORNOW. */
1746 }
1748 /* fall through */
1749 }
1751 /* Part 1: Case 2. Declarations. */
1753 {
1754 /* We expect to get a decl only if we already have a DR. */
1756 {
1758 {
1761 }
1763 }
1765 /* 2.1 check the alignment. */
1768 else
1771 /* 2.2 update DR_BASE_NAME if necessary. */
1773 /* For alias analysis. In case the analysis of INDIRECT_REF brought
1774 us to object. */
1781 }
1783 /* Part 1: Case 3. INDIRECT_REFs. */
1785 {
1790 /* 3.1 get the access function. */
1793 {
1798 }
1800 {
1803 }
1805 /* 3.2 analyze evolution of MEMREF. */
1808 {
1816 }
1817 else
1818 {
1820 {
1825 }
1826 /* Since there exists DR for MEMREF, we are analyzing the init of
1827 the access function, which not necessary has evolution in the
1828 loop. */
1831 }
1833 /* 3.3 set data-reference structure for MEMREF. */
1836 /* 3.4 call vect_address_analysis to analyze INIT of the access
1837 function. */
1845 {
1858 {
1861 }
1863 }
1864 }
1867 /* MEMREF cannot be analyzed. */
1873 /* Part 2: Combine the results of object and address analysis to calculate
1874 INITIAL_OFFSET, STEP and misalignment info. */
1878 else
1884 {
1895 }
1897 }
1900 /* Function vect_analyze_data_refs.
1902 Find all the data references in the loop.
1904 The general structure of the analysis of data refs in the vectorizer is as
1905 follows:
1906 1- vect_analyze_data_refs(loop):
1907 Find and analyze all data-refs in the loop:
1908 foreach ref
1909 base_address = vect_object_analysis(ref)
1910 1.1- vect_object_analysis(ref):
1911 Analyze ref, and build a DR (data_referece struct) for it;
1912 compute base, initial_offset, step and alignment.
1913 Call get_inner_reference for refs handled in this function.
1914 Call vect_addr_analysis(addr) to analyze pointer type expressions.
1915 Set ref_stmt.base, ref_stmt.initial_offset, ref_stmt.alignment,
1916 ref_stmt.memtag, ref_stmt.ptr_info and ref_stmt.step accordingly.
1917 2- vect_analyze_dependences(): apply dependence testing using ref_stmt.DR
1918 3- vect_analyze_drs_alignment(): check that ref_stmt.alignment is ok.
1919 4- vect_analyze_drs_access(): check that ref_stmt.step is ok.
1921 FORNOW: Handle aligned INDIRECT_REFs and ARRAY_REFs
1922 which base is really an array (not a pointer) and which alignment
1923 can be forced. This restriction will be relaxed. */
1925 static bool
1927 {
1931 block_stmt_iterator si;
1939 {
1942 {
1955 /* Assumption: there exists a data-ref in stmt, if and only if
1956 it has vuses/vdefs. */
1965 {
1967 {
1970 }
1972 }
1975 {
1977 {
1980 }
1982 }
1985 {
1989 }
1991 {
1995 }
2000 {
2002 {
2007 }
2008 /* It is not possible to vectorize this data reference. */
2010 }
2011 /* Analyze MEMREF. If it is of a supported form, build data_reference
2012 struct for it (DR). */
2019 {
2022 {
2025 }
2027 }
2039 }
2040 }
2043 }
2046 /* Utility functions used by vect_mark_stmts_to_be_vectorized. */
2048 /* Function vect_mark_relevant.
2050 Mark STMT as "relevant for vectorization" and add it to WORKLIST. */
2052 static void
2054 {
2055 stmt_vec_info stmt_info;
2061 {
2064 }
2069 {
2071 {
2074 }
2076 }
2079 {
2083 }
2087 }
2090 /* Function vect_stmt_relevant_p.
2092 Return true if STMT in loop that is represented by LOOP_VINFO is
2093 "relevant for vectorization".
2095 A stmt is considered "relevant for vectorization" if:
2096 - it has uses outside the loop.
2097 - it has vdefs (it alters memory).
2098 - control stmts in the loop (except for the exit condition).
2100 CHECKME: what other side effects would the vectorizer allow? */
2102 static bool
2104 {
2106 ssa_op_iter op_iter;
2107 imm_use_iterator imm_iter;
2108 use_operand_p use_p;
2109 def_operand_p def_p;
2111 /* cond stmt other than loop exit cond. */
2115 /* changing memory. */
2118 {
2122 }
2124 /* uses outside the loop. */
2126 {
2128 {
2131 {
2135 }
2136 }
2137 }
2140 }
2143 /* Function vect_mark_stmts_to_be_vectorized.
2145 Not all stmts in the loop need to be vectorized. For example:
2147 for i...
2148 for j...
2149 1. T0 = i + j
2150 2. T1 = a[T0]
2152 3. j = j + 1
2154 Stmt 1 and 3 do not need to be vectorized, because loop control and
2155 addressing of vectorized data-refs are handled differently.
2157 This pass detects such stmts. */
2159 static bool
2161 {
2166 block_stmt_iterator si;
2168 ssa_op_iter iter;
2171 stmt_vec_info stmt_info;
2172 basic_block bb;
2173 tree phi;
2180 {
2182 {
2185 }
2188 {
2193 }
2194 }
2198 /* 1. Init worklist. */
2201 {
2204 {
2208 {
2211 }
2218 }
2219 }
2222 /* 2. Process_worklist */
2225 {
2229 {
2232 }
2234 /* Examine the USES in this statement. Mark all the statements which
2235 feed this statement's uses as "relevant", unless the USE is used as
2236 an array index. */
2239 {
2240 /* follow the def-use chain inside the loop. */
2242 {
2245 basic_block bb;
2247 {
2253 }
2258 {
2261 }
2266 }
2267 }
2270 {
2272 /* We are only interested in uses that need to be vectorized. Uses
2273 that are used for address computation are not considered relevant.
2274 */
2276 {
2278 basic_block bb;
2280 {
2286 }
2292 {
2295 }
2300 }
2301 }
2306 }
2309 /* Function vect_can_advance_ivs_p
2311 In case the number of iterations that LOOP iterates in unknown at compile
2312 time, an epilog loop will be generated, and the loop induction variables
2313 (IVs) will be "advanced" to the value they are supposed to take just before
2314 the epilog loop. Here we check that the access function of the loop IVs
2315 and the expression that represents the loop bound are simple enough.
2316 These restrictions will be relaxed in the future. */
2318 static bool
2320 {
2323 tree phi;
2325 /* Analyze phi functions of the loop header. */
2328 {
2330 tree evolution_part;
2333 {
2336 }
2338 /* Skip virtual phi's. The data dependences that are associated with
2339 virtual defs/uses (i.e., memory accesses) are analyzed elsewhere. */
2342 {
2346 }
2348 /* Analyze the evolution function. */
2350 access_fn = instantiate_parameters
2354 {
2358 }
2361 {
2364 }
2371 /* FORNOW: We do not transform initial conditions of IVs
2372 which evolution functions are a polynomial of degree >= 2. */
2376 }
2379 }
2382 /* Function vect_get_loop_niters.
2384 Determine how many iterations the loop is executed.
2385 If an expression that represents the number of iterations
2386 can be constructed, place it in NUMBER_OF_ITERATIONS.
2387 Return the loop exit condition. */
2389 static tree
2391 {
2392 tree niters;
2401 {
2405 {
2408 }
2409 }
2412 }
2415 /* Function vect_analyze_loop_form.
2417 Verify the following restrictions (some may be relaxed in the future):
2418 - it's an inner-most loop
2419 - number of BBs = 2 (which are the loop header and the latch)
2420 - the loop has a pre-header
2421 - the loop has a single entry and exit
2422 - the loop exit condition is simple enough, and the number of iterations
2423 can be analyzed (a countable loop). */
2425 static loop_vec_info
2427 {
2428 loop_vec_info loop_vinfo;
2429 tree loop_cond;
2431 LOC loop_loc;
2439 {
2443 }
2448 {
2450 {
2457 }
2460 }
2462 /* We assume that the loop exit condition is at the end of the loop. i.e,
2463 that the loop is represented as a do-while (with a proper if-guard
2464 before the loop if needed), where the loop header contains all the
2465 executable statements, and the latch is empty. */
2467 {
2471 }
2473 /* Make sure there exists a single-predecessor exit bb: */
2475 {
2478 {
2482 }
2483 else
2484 {
2488 }
2489 }
2492 {
2496 }
2500 {
2504 }
2507 {
2512 }
2515 {
2519 }
2525 {
2527 {
2530 }
2531 }
2532 else
2534 {
2538 }
2544 }
2547 /* Function vect_analyze_loop.
2549 Apply a set of analyses on LOOP, and create a loop_vec_info struct
2550 for it. The different analyses will record information in the
2551 loop_vec_info struct. */
2552 loop_vec_info
2554 {
2556 loop_vec_info loop_vinfo;
2561 /* Check the CFG characteristics of the loop (nesting, entry/exit, etc. */
2565 {
2569 }
2571 /* Find all data references in the loop (which correspond to vdefs/vuses)
2572 and analyze their evolution in the loop.
2574 FORNOW: Handle only simple, array references, which
2575 alignment can be forced, and aligned pointer-references. */
2579 {
2584 }
2586 /* Data-flow analysis to detect stmts that do not need to be vectorized. */
2590 {
2595 }
2597 /* Check that all cross-iteration scalar data-flow cycles are OK.
2598 Cross-iteration cycles caused by virtual phis are analyzed separately. */
2602 {
2607 }
2611 {
2616 }
2618 /* Analyze data dependences between the data-refs in the loop.
2619 FORNOW: fail at the first data dependence that we encounter. */
2623 {
2628 }
2630 /* Analyze the access patterns of the data-refs in the loop (consecutive,
2631 complex, etc.). FORNOW: Only handle consecutive access pattern. */
2635 {
2640 }
2642 /* Analyze the alignment of the data-refs in the loop.
2643 FORNOW: Only aligned accesses are handled. */
2647 {
2652 }
2654 /* Scan all the operations in the loop and make sure they are
2655 vectorizable. */
2659 {
2664 }
2669 }