| blob | 3bf460cccfd9d59ab8b563bfd632bc2f61c8e328 |
1 /* Data references and dependences detectors.
2 Copyright (C) 2003-2020 Free Software Foundation, Inc.
3 Contributed by Sebastian Pop <pop@cri.ensmp.fr>
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 3, 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 COPYING3. If not see
19 <http://www.gnu.org/licenses/>. */
21 /* This pass walks a given loop structure searching for array
22 references. The information about the array accesses is recorded
23 in DATA_REFERENCE structures.
25 The basic test for determining the dependences is:
26 given two access functions chrec1 and chrec2 to a same array, and
27 x and y two vectors from the iteration domain, the same element of
28 the array is accessed twice at iterations x and y if and only if:
29 | chrec1 (x) == chrec2 (y).
31 The goals of this analysis are:
33 - to determine the independence: the relation between two
34 independent accesses is qualified with the chrec_known (this
35 information allows a loop parallelization),
37 - when two data references access the same data, to qualify the
38 dependence relation with classic dependence representations:
40 - distance vectors
41 - direction vectors
42 - loop carried level dependence
43 - polyhedron dependence
44 or with the chains of recurrences based representation,
46 - to define a knowledge base for storing the data dependence
47 information,
49 - to define an interface to access this data.
52 Definitions:
54 - subscript: given two array accesses a subscript is the tuple
55 composed of the access functions for a given dimension. Example:
56 Given A[f1][f2][f3] and B[g1][g2][g3], there are three subscripts:
57 (f1, g1), (f2, g2), (f3, g3).
59 - Diophantine equation: an equation whose coefficients and
60 solutions are integer constants, for example the equation
61 | 3*x + 2*y = 1
62 has an integer solution x = 1 and y = -1.
64 References:
66 - "Advanced Compilation for High Performance Computing" by Randy
67 Allen and Ken Kennedy.
68 http://citeseer.ist.psu.edu/goff91practical.html
70 - "Loop Transformations for Restructuring Compilers - The Foundations"
71 by Utpal Banerjee.
74 */
101 static struct datadep_stats
102 {
131 /* Returns true iff A divides B. */
135 {
139 }
141 /* Returns true iff A divides B. */
145 {
147 }
149 /* Return true if reference REF contains a union access. */
151 static bool
153 {
155 {
160 }
162 }
164 \f
166 /* Dump into FILE all the data references from DATAREFS. */
168 static void
170 {
176 }
178 /* Unified dump into FILE all the data references from DATAREFS. */
180 DEBUG_FUNCTION void
182 {
184 }
186 DEBUG_FUNCTION void
188 {
191 else
193 }
196 /* Dump into STDERR all the data references from DATAREFS. */
198 DEBUG_FUNCTION void
200 {
202 }
204 /* Print to STDERR the data_reference DR. */
206 DEBUG_FUNCTION void
208 {
210 }
212 /* Dump function for a DATA_REFERENCE structure. */
214 void
217 {
230 {
233 }
235 }
237 /* Unified dump function for a DATA_REFERENCE structure. */
239 DEBUG_FUNCTION void
241 {
243 }
245 DEBUG_FUNCTION void
247 {
250 else
252 }
255 /* Dumps the affine function described by FN to the file OUTF. */
257 DEBUG_FUNCTION void
259 {
261 tree coef;
265 {
269 }
270 }
272 /* Dumps the conflict function CF to the file OUTF. */
274 DEBUG_FUNCTION void
276 {
283 else
284 {
286 {
292 }
293 }
294 }
296 /* Dump function for a SUBSCRIPT structure. */
298 DEBUG_FUNCTION void
300 {
307 {
311 }
317 {
321 }
326 }
328 /* Print the classic direction vector DIRV to OUTF. */
330 DEBUG_FUNCTION void
332 lambda_vector dirv,
334 {
338 {
343 {
368 }
369 }
371 }
373 /* Print a vector of direction vectors. */
375 DEBUG_FUNCTION void
378 {
380 lambda_vector v;
384 }
386 /* Print out a vector VEC of length N to OUTFILE. */
388 DEBUG_FUNCTION void
390 {
396 }
398 /* Print a vector of distance vectors. */
400 DEBUG_FUNCTION void
403 {
405 lambda_vector v;
409 }
411 /* Dump function for a DATA_DEPENDENCE_RELATION structure. */
413 DEBUG_FUNCTION void
416 {
422 {
424 {
429 else
433 else
435 }
438 }
449 {
455 {
461 }
469 {
473 }
476 {
480 }
481 }
484 }
486 /* Debug version. */
488 DEBUG_FUNCTION void
490 {
492 }
494 /* Dump into FILE all the dependence relations from DDRS. */
496 DEBUG_FUNCTION void
499 {
505 }
507 DEBUG_FUNCTION void
509 {
511 }
513 DEBUG_FUNCTION void
515 {
518 else
520 }
523 /* Dump to STDERR all the dependence relations from DDRS. */
525 DEBUG_FUNCTION void
527 {
529 }
531 /* Dumps the distance and direction vectors in FILE. DDRS contains
532 the dependence relations, and VECT_SIZE is the size of the
533 dependence vectors, or in other words the number of loops in the
534 considered nest. */
536 DEBUG_FUNCTION void
538 {
541 lambda_vector v;
545 {
547 {
551 }
554 {
558 }
559 }
562 }
564 /* Dumps the data dependence relations DDRS in FILE. */
566 DEBUG_FUNCTION void
568 {
576 }
578 DEBUG_FUNCTION void
580 {
582 }
584 static void
589 /* Helper function for split_constant_offset. Expresses OP0 CODE OP1
590 (the type of the result is TYPE) as VAR + OFF, where OFF is a nonzero
591 constant of type ssizetype, and returns true. If we cannot do this
592 with OFF nonzero, OFF and VAR are set to NULL_TREE instead and false
593 is returned. */
595 static bool
600 {
609 {
617 /* FALLTHROUGH */
621 {
626 }
643 {
646 machine_mode pmode;
650 base
660 {
665 else
668 }
672 /* If variable length types are involved, punt, otherwise casts
673 might be converted into ARRAY_REFs in gimplify_conversion.
674 To compute that ARRAY_REF's element size TYPE_SIZE_UNIT, which
675 possibly no longer appears in current GIMPLE, might resurface.
676 This perhaps could run
677 if (CONVERT_EXPR_P (var0))
678 {
679 gimplify_conversion (&var0);
680 // Attempt to fill in any within var0 found ARRAY_REF's
681 // element size from corresponding op embedded ARRAY_REF,
682 // if unsuccessful, just punt.
683 } */
692 }
695 {
707 /* We are using a cache to avoid un-CSEing large amounts of code. */
716 {
721 {
727 }
729 }
743 }
744 CASE_CONVERT:
745 {
746 /* We must not introduce undefined overflow, and we must not change
747 the value. Hence we're okay if the inner type doesn't overflow
748 to start with (pointer or signed), the outer type also is an
749 integer or pointer and the outer precision is at least as large
750 as the inner. */
756 {
760 {
761 /* Split the unconverted operand and try to prove that
762 wrapping isn't a problem. */
766 /* See whether we have an SSA_NAME whose range is known
767 to be [A, B]. */
780 /* See whether the range of OP0 (i.e. TMP_VAR + TMP_OFF)
781 is known to be [A + TMP_OFF, B + TMP_OFF], with all
782 operations done in ITYPE. The addition must overflow
783 at both ends of the range or at neither. */
792 /* Calculate (ssizetype) OP0 - (ssizetype) TMP_VAR. */
797 }
798 else
802 }
804 }
808 }
809 }
811 /* Expresses EXP as VAR + OFF, where off is a constant. The type of OFF
812 will be ssizetype. */
814 static void
818 {
832 {
835 }
836 }
838 void
840 {
847 }
849 /* Returns the address ADDR of an object in a canonical shape (without nop
850 casts, and with type of pointer to the object). */
852 static tree
854 {
859 /* The base address may be obtained by casting from integer, in that case
860 keep the cast. */
868 }
870 /* Analyze the behavior of memory reference REF within STMT.
871 There are two modes:
873 - BB analysis. In this case we simply split the address into base,
874 init and offset components, without reference to any containing loop.
875 The resulting base and offset are general expressions and they can
876 vary arbitrarily from one iteration of the containing loop to the next.
877 The step is always zero.
879 - loop analysis. In this case we analyze the reference both wrt LOOP
880 and on the basis that the reference occurs (is "used") in LOOP;
881 see the comment above analyze_scalar_evolution_in_loop for more
882 information about this distinction. The base, init, offset and
883 step fields are all invariant in LOOP.
885 Perform BB analysis if LOOP is null, or if LOOP is the function's
886 dummy outermost loop. In other cases perform loop analysis.
888 Return true if the analysis succeeded and store the results in DRB if so.
889 BB analysis can only fail for bitfield or reversed-storage accesses. */
891 opt_result
894 {
897 machine_mode pmode;
910 poly_int64 pbytepos;
919 /* Calculate the alignment and misalignment for the inner reference. */
924 /* There are no bitfield references remaining in BASE, so the values
925 we got back must be whole bytes. */
932 {
934 {
935 /* Subtract MOFF from the base and add it to POFFSET instead.
936 Adjust the misalignment to reflect the amount we subtracted. */
942 else
944 }
946 }
947 else
951 {
955 }
956 else
957 {
961 }
964 {
967 }
968 else
969 {
971 {
974 }
978 }
982 /* Subtract any constant component from the base and add it to INIT instead.
983 Adjust the misalignment to reflect the amount we subtracted. */
997 /* See if get_pointer_alignment can guarantee a higher alignment than
998 the one we calculated above. */
1003 /* As above, these values must be whole bytes. */
1010 {
1013 }
1022 else
1023 {
1026 }
1034 }
1036 /* Return true if OP is a valid component reference for a DR access
1037 function. This accepts a subset of what handled_component_p accepts. */
1039 static bool
1041 {
1043 {
1054 }
1055 }
1057 /* Determines the base object and the list of indices of memory reference
1058 DR, analyzed in LOOP and instantiated before NEST. */
1060 static void
1062 {
1067 /* If analyzing a basic-block there are no indices to analyze
1068 and thus no access functions. */
1070 {
1074 }
1078 /* REALPART_EXPR and IMAGPART_EXPR can be handled like accesses
1079 into a two element array with a constant index. The base is
1080 then just the immediate underlying object. */
1082 {
1085 }
1087 {
1090 }
1092 /* Analyze access functions of dimensions we know to be independent.
1093 The list of component references handled here should be kept in
1094 sync with access_fn_component_p. */
1096 {
1098 {
1103 }
1106 {
1107 /* For COMPONENT_REFs of records (but not unions!) use the
1108 FIELD_DECL offset as constant access function so we can
1109 disambiguate a[i].f1 and a[i].f2. */
1117 }
1118 else
1119 /* If we have an unhandled component we could not translate
1120 to an access function stop analyzing. We have determined
1121 our base object in this case. */
1125 }
1127 /* If the address operand of a MEM_REF base has an evolution in the
1128 analyzed nest, add it as an additional independent access-function. */
1130 {
1135 {
1136 tree orig_type;
1143 /* Fold the MEM_REF offset into the evolutions initial
1144 value to make more bases comparable. */
1146 {
1150 }
1151 /* Adjust the offset so it is a multiple of the access type
1152 size and thus we separate bases that can possibly be used
1153 to produce partial overlaps (which the access_fn machinery
1154 cannot handle). */
1155 wide_int rem;
1162 SIGNED);
1163 else
1164 /* If we can't compute the remainder simply force the initial
1165 condition to zero. */
1169 /* And finally replace the initial condition. */
1170 access_fn = chrec_replace_initial_condition
1172 /* ??? This is still not a suitable base object for
1173 dr_may_alias_p - the base object needs to be an
1174 access that covers the object as whole. With
1175 an evolution in the pointer this cannot be
1176 guaranteed.
1177 As a band-aid, mark the access so we can special-case
1178 it in dr_may_alias_p. */
1187 }
1188 }
1190 {
1191 /* Canonicalize DR_BASE_OBJECT to MEM_REF form. */
1195 }
1199 }
1201 /* Extracts the alias analysis information from the memory reference DR. */
1203 static void
1205 {
1211 {
1215 }
1216 }
1218 /* Frees data reference DR. */
1220 void
1222 {
1225 }
1227 /* Analyze memory reference MEMREF, which is accessed in STMT.
1228 The reference is a read if IS_READ is true, otherwise it is a write.
1229 IS_CONDITIONAL_IN_STMT indicates that the reference is conditional
1230 within STMT, i.e. that it might not occur even if STMT is executed
1231 and runs to completion.
1233 Return the data_reference description of MEMREF. NEST is the outermost
1234 loop in which the reference should be instantiated, LOOP is the loop
1235 in which the data reference should be analyzed. */
1240 {
1244 {
1248 }
1262 {
1282 {
1285 }
1286 }
1289 }
1291 /* A helper function computes order between two tree expressions T1 and T2.
1292 This is used in comparator functions sorting objects based on the order
1293 of tree expressions. The function returns -1, 0, or 1. */
1295 int
1297 {
1320 {
1342 /* For decls, compare their UIDs. */
1344 {
1348 }
1349 /* For expressions, compare their operands recursively. */
1351 {
1353 {
1358 }
1359 }
1360 else
1362 }
1365 }
1367 /* Return TRUE it's possible to resolve data dependence DDR by runtime alias
1368 check. */
1370 opt_result
1372 {
1380 "runtime alias check not supported when"
1383 /* FORNOW: We don't support versioning with outer-loop in either
1384 vectorization or loop distribution. */
1387 "runtime alias check not supported for"
1391 }
1393 /* Operator == between two dr_with_seg_len objects.
1395 This equality operator is used to make sure two data refs
1396 are the same one so that we will consider to combine the
1397 aliasing checks of those two pairs of data dependent data
1398 refs. */
1400 static bool
1403 {
1411 }
1413 /* Comparison function for sorting objects of dr_with_seg_len_pair_t
1414 so that we can combine aliasing checks in one scan. */
1416 static int
1418 {
1424 /* For DR pairs (a, b) and (c, d), we only consider to merge the alias checks
1425 if a and c have the same basic address snd step, and b and d have the same
1426 address and step. Therefore, if any a&c or b&d don't have the same address
1427 and step, we don't care the order of those two pairs after sorting. */
1456 }
1458 /* Dump information about ALIAS_PAIR, indenting each line by INDENT. */
1460 static void
1462 {
1476 {
1479 }
1504 }
1506 /* Merge alias checks recorded in ALIAS_PAIRS and remove redundant ones.
1507 FACTOR is number of iterations that each data reference is accessed.
1509 Basically, for each pair of dependent data refs store_ptr_0 & load_ptr_0,
1510 we create an expression:
1512 ((store_ptr_0 + store_segment_length_0) <= load_ptr_0)
1513 || (load_ptr_0 + load_segment_length_0) <= store_ptr_0))
1515 for aliasing checks. However, in some cases we can decrease the number
1516 of checks by combining two checks into one. For example, suppose we have
1517 another pair of data refs store_ptr_0 & load_ptr_1, and if the following
1518 condition is satisfied:
1520 load_ptr_0 < load_ptr_1 &&
1521 load_ptr_1 - load_ptr_0 - load_segment_length_0 < store_segment_length_0
1523 (this condition means, in each iteration of vectorized loop, the accessed
1524 memory of store_ptr_0 cannot be between the memory of load_ptr_0 and
1525 load_ptr_1.)
1527 we then can use only the following expression to finish the alising checks
1528 between store_ptr_0 & load_ptr_0 and store_ptr_0 & load_ptr_1:
1530 ((store_ptr_0 + store_segment_length_0) <= load_ptr_0)
1531 || (load_ptr_1 + load_segment_length_1 <= store_ptr_0))
1533 Note that we only consider that load_ptr_0 and load_ptr_1 have the same
1534 basic address. */
1536 void
1538 poly_uint64)
1539 {
1543 /* Canonicalize each pair so that the base components are ordered wrt
1544 data_ref_compare_tree. This allows the loop below to merge more
1545 cases. */
1549 {
1559 {
1562 }
1563 else
1565 }
1567 /* Sort the collected data ref pairs so that we can scan them once to
1568 combine all possible aliasing checks. */
1571 /* Scan the sorted dr pairs and check if we can combine alias checks
1572 of two neighboring dr pairs. */
1575 {
1576 /* Deal with two ddrs (dr_a1, dr_b1) and (dr_a2, dr_b2). */
1585 /* Remove duplicate data ref pairs. */
1587 {
1594 }
1596 /* Assume that we won't be able to merge the pairs, then correct
1597 if we do. */
1603 {
1604 /* We consider the case that DR_B1 and DR_B2 are same memrefs,
1605 and DR_A1 and DR_A2 are two consecutive memrefs. */
1607 {
1610 }
1613 /* Only consider cases in which the distance between the initial
1614 DR_A1 and the initial DR_A2 is known at compile time. */
1623 /* Don't combine if we can't tell which one comes first. */
1627 /* Work out what the segment length would be if we did combine
1628 DR_A1 and DR_A2:
1630 - If DR_A1 and DR_A2 have equal lengths, that length is
1631 also the combined length.
1633 - If DR_A1 and DR_A2 both have negative "lengths", the combined
1634 length is the lower bound on those lengths.
1636 - If DR_A1 and DR_A2 both have positive lengths, the combined
1637 length is the upper bound on those lengths.
1639 Other cases are unlikely to give a useful combination.
1641 The lengths both have sizetype, so the sign is taken from
1642 the step instead. */
1647 {
1668 else
1670 }
1671 /* At this point we're committed to merging the refs. */
1673 /* Make sure dr_a1 starts left of dr_a2. */
1675 {
1678 }
1680 /* The DR_Bs are equal, so only the DR_As can introduce
1681 mixed steps. */
1686 {
1688 new_seg_len);
1690 }
1692 /* This is always positive due to the swap above. */
1695 /* The new check will start at DR_A1. Make sure that its access
1696 size encompasses the initial DR_A2. */
1698 {
1703 }
1710 }
1711 }
1714 /* Try to restore the original dr_with_seg_len order within each
1715 dr_with_seg_len_pair_t. If we ended up combining swapped and
1716 unswapped pairs into the same check, we have to invalidate any
1717 RAW, WAR and WAW information for it. */
1721 {
1731 }
1732 }
1734 /* A subroutine of create_intersect_range_checks, with a subset of the
1735 same arguments. Try to use IFN_CHECK_RAW_PTRS and IFN_CHECK_WAR_PTRS
1736 to optimize cases in which the references form a simple RAW, WAR or
1737 WAR dependence. */
1739 static bool
1742 {
1746 /* Check for cases in which:
1748 (a) we have a known RAW, WAR or WAR dependence
1749 (b) the accesses are well-ordered in both the original and new code
1750 (see the comment above the DR_ALIAS_* flags for details); and
1751 (c) the DR_STEPs describe all access pairs covered by ALIAS_PAIR. */
1755 /* Make sure that both DRs access the same pattern of bytes,
1756 with a constant length and step. */
1757 poly_uint64 seg_len;
1769 /* See whether the target suports what we want to do. WAW checks are
1770 equivalent to WAR checks here. */
1772 ? IFN_CHECK_RAW_PTRS
1778 {
1783 }
1785 /* Commit to using this form of test. */
1799 {
1802 else
1804 }
1806 }
1808 /* Try to generate a runtime condition that is true if ALIAS_PAIR is
1809 free of aliases, using a condition based on index values instead
1810 of a condition based on addresses. Return true on success,
1811 storing the condition in *COND_EXPR.
1813 This can only be done if the two data references in ALIAS_PAIR access
1814 the same array object and the index is the only difference. For example,
1815 if the two data references are DR_A and DR_B:
1817 DR_A DR_B
1818 data-ref arr[i] arr[j]
1819 base_object arr arr
1820 index {i_0, +, 1}_loop {j_0, +, 1}_loop
1822 The addresses and their index are like:
1824 |<- ADDR_A ->| |<- ADDR_B ->|
1825 ------------------------------------------------------->
1826 | | | | | | | | | |
1827 ------------------------------------------------------->
1828 i_0 ... i_0+4 j_0 ... j_0+4
1830 We can create expression based on index rather than address:
1832 (unsigned) (i_0 - j_0 + 3) <= 6
1834 i.e. the indices are less than 4 apart.
1836 Note evolution step of index needs to be considered in comparison. */
1838 static bool
1841 {
1869 {
1873 }
1875 /* Infer the number of iterations with which the memory segment is accessed
1876 by DR. In other words, alias is checked if memory segment accessed by
1877 DR_A in some iterations intersect with memory segment accessed by DR_B
1878 in the same amount iterations.
1879 Note segnment length is a linear function of number of iterations with
1880 DR_STEP as the coefficient. */
1886 /* Divide each access size by the byte step, rounding up. */
1898 {
1901 /* Two indices must be the same if they are not scev, or not scev wrto
1902 current loop being vecorized. */
1907 {
1912 }
1913 /* The two indices must have the same step. */
1918 /* Index must have const step, otherwise DR_STEP won't be constant. */
1920 /* Index must evaluate in the same direction as DR. */
1928 /* Ideally, alias can be checked against loop's control IV, but we
1929 need to prove linear mapping between control IV and reference
1930 index. Although that should be true, we check against (array)
1931 index of data reference. Like segment length, index length is
1932 linear function of the number of iterations with index_step as
1933 the coefficient, i.e, niter_len * idx_step. */
1935 SIGNED);
1948 /* Each access has the following pattern, with lengths measured
1949 in units of INDEX:
1951 <-- idx_len -->
1952 <--- A: -ve step --->
1953 +-----+-------+-----+-------+-----+
1954 | n-1 | ..... | 0 | ..... | n-1 |
1955 +-----+-------+-----+-------+-----+
1956 <--- B: +ve step --->
1957 <-- idx_len -->
1958 |
1959 min
1961 where "n" is the number of scalar iterations covered by the segment
1962 and where each access spans idx_access units.
1964 A is the range of bytes accessed when the step is negative,
1965 B is the range when the step is positive.
1967 When checking for general overlap, we need to test whether
1968 the range:
1970 [min1 + low_offset1, min2 + high_offset1 + idx_access1 - 1]
1972 overlaps:
1974 [min2 + low_offset2, min2 + high_offset2 + idx_access2 - 1]
1976 where:
1978 low_offsetN = +ve step ? 0 : -idx_lenN;
1979 high_offsetN = +ve step ? idx_lenN : 0;
1981 This is equivalent to testing whether:
1983 min1 + low_offset1 <= min2 + high_offset2 + idx_access2 - 1
1984 && min2 + low_offset2 <= min1 + high_offset1 + idx_access1 - 1
1986 Converting this into a single test, there is an overlap if:
1988 0 <= min2 - min1 + bias <= limit
1990 where bias = high_offset2 + idx_access2 - 1 - low_offset1
1991 limit = (high_offset1 - low_offset1 + idx_access1 - 1)
1992 + (high_offset2 - low_offset2 + idx_access2 - 1)
1993 i.e. limit = idx_len1 + idx_access1 - 1 + idx_len2 + idx_access2 - 1
1995 Combining the tests requires limit to be computable in an unsigned
1996 form of the index type; if it isn't, we fall back to the usual
1997 pointer-based checks.
1999 We can do better if DR_B is a write and if DR_A and DR_B are
2000 well-ordered in both the original and the new code (see the
2001 comment above the DR_ALIAS_* flags for details). In this case
2002 we know that for each i in [0, n-1], the write performed by
2003 access i of DR_B occurs after access numbers j<=i of DR_A in
2004 both the original and the new code. Any write or anti
2005 dependencies wrt those DR_A accesses are therefore maintained.
2007 We just need to make sure that each individual write in DR_B does not
2008 overlap any higher-indexed access in DR_A; such DR_A accesses happen
2009 after the DR_B access in the original code but happen before it in
2010 the new code.
2012 We know the steps for both accesses are equal, so by induction, we
2013 just need to test whether the first write of DR_B overlaps a later
2014 access of DR_A. In other words, we need to move min1 along by
2015 one iteration:
2017 min1' = min1 + idx_step
2019 and use the ranges:
2021 [min1' + low_offset1', min1' + high_offset1' + idx_access1 - 1]
2023 and:
2025 [min2, min2 + idx_access2 - 1]
2027 where:
2029 low_offset1' = +ve step ? 0 : -(idx_len1 - |idx_step|)
2030 high_offset1' = +ve_step ? idx_len1 - |idx_step| : 0. */
2045 /* Equivalent to adding IDX_STEP to MIN1. */
2059 else
2061 }
2063 {
2066 else
2068 }
2070 }
2072 /* A subroutine of create_intersect_range_checks, with a subset of the
2073 same arguments. Try to optimize cases in which the second access
2074 is a write and in which some overlap is valid. */
2076 static bool
2079 {
2083 /* Check for cases in which:
2085 (a) DR_B is always a write;
2086 (b) the accesses are well-ordered in both the original and new code
2087 (see the comment above the DR_ALIAS_* flags for details); and
2088 (c) the DR_STEPs describe all access pairs covered by ALIAS_PAIR. */
2092 /* Check for equal (but possibly variable) steps. */
2097 /* Make sure that we can operate on sizetype without loss of precision. */
2102 /* All addresses involved are known to have a common alignment ALIGN.
2103 We can therefore subtract ALIGN from an exclusive endpoint to get
2104 an inclusive endpoint. In the best (and common) case, ALIGN is the
2105 same as the access sizes of both DRs, and so subtracting ALIGN
2106 cancels out the addition of an access size. */
2111 /* Get a boolean expression that is true when the step is negative. */
2117 /* Get lengths in sizetype. */
2118 tree seg_len_a
2122 /* Each access has the following pattern:
2124 <- |seg_len| ->
2125 <--- A: -ve step --->
2126 +-----+-------+-----+-------+-----+
2127 | n-1 | ..... | 0 | ..... | n-1 |
2128 +-----+-------+-----+-------+-----+
2129 <--- B: +ve step --->
2130 <- |seg_len| ->
2131 |
2132 base address
2134 where "n" is the number of scalar iterations covered by the segment.
2136 A is the range of bytes accessed when the step is negative,
2137 B is the range when the step is positive.
2139 We know that DR_B is a write. We also know (from checking that
2140 DR_A and DR_B are well-ordered) that for each i in [0, n-1],
2141 the write performed by access i of DR_B occurs after access numbers
2142 j<=i of DR_A in both the original and the new code. Any write or
2143 anti dependencies wrt those DR_A accesses are therefore maintained.
2145 We just need to make sure that each individual write in DR_B does not
2146 overlap any higher-indexed access in DR_A; such DR_A accesses happen
2147 after the DR_B access in the original code but happen before it in
2148 the new code.
2150 We know the steps for both accesses are equal, so by induction, we
2151 just need to test whether the first write of DR_B overlaps a later
2152 access of DR_A. In other words, we need to move addr_a along by
2153 one iteration:
2155 addr_a' = addr_a + step
2157 and check whether:
2159 [addr_b, addr_b + last_chunk_b]
2161 overlaps:
2163 [addr_a' + low_offset_a, addr_a' + high_offset_a + last_chunk_a]
2165 where [low_offset_a, high_offset_a] spans accesses [1, n-1]. I.e.:
2167 low_offset_a = +ve step ? 0 : seg_len_a - step
2168 high_offset_a = +ve step ? seg_len_a - step : 0
2170 This is equivalent to testing whether:
2172 addr_a' + low_offset_a <= addr_b + last_chunk_b
2173 && addr_b <= addr_a' + high_offset_a + last_chunk_a
2175 Converting this into a single test, there is an overlap if:
2177 0 <= addr_b + last_chunk_b - addr_a' - low_offset_a <= limit
2179 where limit = high_offset_a - low_offset_a + last_chunk_a + last_chunk_b
2181 If DR_A is performed, limit + |step| - last_chunk_b is known to be
2182 less than the size of the object underlying DR_A. We also know
2183 that last_chunk_b <= |step|; this is checked elsewhere if it isn't
2184 guaranteed at compile time. There can therefore be no overflow if
2185 "limit" is calculated in an unsigned type with pointer precision. */
2194 /* Advance ADDR_A by one iteration and adjust the length to compensate. */
2206 /* We could use COND_EXPR <neg_step, size_zero_node, seg_len_a_minus_step>,
2207 but it's usually more efficient to reuse the LOW_OFFSET_A result. */
2209 low_offset_a);
2211 /* The amount added to addr_b - addr_a'. */
2227 }
2229 /* If ALIGN is nonzero, set up *SEQ_MIN_OUT and *SEQ_MAX_OUT so that for
2230 every address ADDR accessed by D:
2232 *SEQ_MIN_OUT <= ADDR (== ADDR & -ALIGN) <= *SEQ_MAX_OUT
2234 In this case, every element accessed by D is aligned to at least
2235 ALIGN bytes.
2237 If ALIGN is zero then instead set *SEG_MAX_OUT so that:
2239 *SEQ_MIN_OUT <= ADDR < *SEQ_MAX_OUT. */
2241 static void
2244 {
2245 /* Each access has the following pattern:
2247 <- |seg_len| ->
2248 <--- A: -ve step --->
2249 +-----+-------+-----+-------+-----+
2250 | n-1 | ,.... | 0 | ..... | n-1 |
2251 +-----+-------+-----+-------+-----+
2252 <--- B: +ve step --->
2253 <- |seg_len| ->
2254 |
2255 base address
2257 where "n" is the number of scalar iterations covered by the segment.
2258 (This should be VF for a particular pair if we know that both steps
2259 are the same, otherwise it will be the full number of scalar loop
2260 iterations.)
2262 A is the range of bytes accessed when the step is negative,
2263 B is the range when the step is positive.
2265 If the access size is "access_size" bytes, the lowest addressed byte is:
2267 base + (step < 0 ? seg_len : 0) [LB]
2269 and the highest addressed byte is always below:
2271 base + (step < 0 ? 0 : seg_len) + access_size [UB]
2273 Thus:
2275 LB <= ADDR < UB
2277 If ALIGN is nonzero, all three values are aligned to at least ALIGN
2278 bytes, so:
2280 LB <= ADDR <= UB - ALIGN
2282 where "- ALIGN" folds naturally with the "+ access_size" and often
2283 cancels it out.
2285 We don't try to simplify LB and UB beyond this (e.g. by using
2286 MIN and MAX based on whether seg_len rather than the stride is
2287 negative) because it is possible for the absolute size of the
2288 segment to overflow the range of a ssize_t.
2290 Keeping the pointer_plus outside of the cond_expr should allow
2291 the cond_exprs to be shared with other alias checks. */
2299 tree seg_len
2311 }
2313 /* Generate a runtime condition that is true if ALIAS_PAIR is free of aliases,
2314 storing the condition in *COND_EXPR. The fallback is to generate a
2315 a test that the two accesses do not overlap:
2317 end_a <= start_b || end_b <= start_a. */
2319 static void
2322 {
2336 tree_code cmp_code;
2337 /* We don't have to check DR_ALIAS_MIXED_STEPS here, since both versions
2338 are equivalent. This is just an optimization heuristic. */
2341 {
2342 /* In this case adding access_size to seg_len is likely to give
2343 a simple X * step, where X is either the number of scalar
2344 iterations or the vectorization factor. We're better off
2345 keeping that, rather than subtracting an alignment from it.
2347 In this case the maximum values are exclusive and so there is
2348 no alias if the maximum of one segment equals the minimum
2349 of another. */
2352 }
2353 else
2354 {
2355 /* Calculate the minimum alignment shared by all four pointers,
2356 then arrange for this alignment to be subtracted from the
2357 exclusive maximum values to get inclusive maximum values.
2358 This "- min_align" is cumulative with a "+ access_size"
2359 in the calculation of the maximum values. In the best
2360 (and common) case, the two cancel each other out, leaving
2361 us with an inclusive bound based only on seg_len. In the
2362 worst case we're simply adding a smaller number than before.
2364 Because the maximum values are inclusive, there is an alias
2365 if the maximum value of one segment is equal to the minimum
2366 value of the other. */
2369 }
2375 *cond_expr
2381 }
2383 /* Create a conditional expression that represents the run-time checks for
2384 overlapping of address ranges represented by a list of data references
2385 pairs passed in ALIAS_PAIRS. Data references are in LOOP. The returned
2386 COND_EXPR is the conditional expression to be used in the if statement
2387 that controls which version of the loop gets executed at runtime. */
2389 void
2393 {
2394 tree part_cond_expr;
2400 {
2408 /* Create condition expression for each pair data references. */
2413 else
2415 }
2417 }
2419 /* Check if OFFSET1 and OFFSET2 (DR_OFFSETs of some data-refs) are identical
2420 expressions. */
2421 static bool
2423 {
2446 }
2448 /* Check if DRA and DRB have equal offsets. */
2449 bool
2452 {
2459 }
2461 /* Returns true if FNA == FNB. */
2463 static bool
2465 {
2476 }
2478 /* If all the functions in CF are the same, returns one of them,
2479 otherwise returns NULL. */
2481 static affine_fn
2483 {
2485 affine_fn comm;
2497 }
2499 /* Returns the base of the affine function FN. */
2501 static tree
2503 {
2505 }
2507 /* Returns true if FN is a constant. */
2509 static bool
2511 {
2513 tree coef;
2520 }
2522 /* Returns true if FN is the zero constant function. */
2524 static bool
2526 {
2529 }
2531 /* Returns a signed integer type with the largest precision from TA
2532 and TB. */
2534 static tree
2536 {
2539 else
2541 }
2543 /* Applies operation OP on affine functions FNA and FNB, and returns the
2544 result. */
2546 static affine_fn
2548 {
2550 affine_fn ret;
2551 tree coef;
2554 {
2557 }
2558 else
2559 {
2562 }
2566 {
2570 }
2580 }
2582 /* Returns the sum of affine functions FNA and FNB. */
2584 static affine_fn
2586 {
2588 }
2590 /* Returns the difference of affine functions FNA and FNB. */
2592 static affine_fn
2594 {
2596 }
2598 /* Frees affine function FN. */
2600 static void
2602 {
2604 }
2606 /* Determine for each subscript in the data dependence relation DDR
2607 the distance. */
2609 static void
2611 {
2616 {
2620 {
2630 {
2633 }
2638 else
2642 }
2643 }
2644 }
2646 /* Returns the conflict function for "unknown". */
2650 {
2655 }
2657 /* Returns the conflict function for "independent". */
2661 {
2666 }
2668 /* Returns true if the address of OBJ is invariant in LOOP. */
2670 static bool
2672 {
2674 {
2676 {
2681 }
2683 {
2687 }
2689 }
2697 }
2699 /* Returns false if we can prove that data references A and B do not alias,
2700 true otherwise. If LOOP_NEST is false no cross-iteration aliases are
2701 considered. */
2703 bool
2706 {
2710 /* If we are not processing a loop nest but scalar code we
2711 do not need to care about possible cross-iteration dependences
2712 and thus can process the full original reference. Do so,
2713 similar to how loop invariant motion applies extra offset-based
2714 disambiguation. */
2716 {
2725 }
2729 /* For cross-iteration dependences the cliques must be valid for the
2730 whole loop, not just individual iterations. */
2731 && (!loop_nest
2738 /* If we had an evolution in a pointer-based MEM_REF BASE_OBJECT we
2739 do not know the size of the base-object. So we cannot do any
2740 offset/overlap based analysis but have to rely on points-to
2741 information only. */
2745 {
2746 /* For true dependences we can apply TBAA. */
2755 else
2758 }
2762 {
2763 /* For true dependences we can apply TBAA. */
2772 else
2775 }
2777 /* Otherwise DR_BASE_OBJECT is an access that covers the whole object
2778 that is being subsetted in the loop nest. */
2784 }
2786 /* REF_A and REF_B both satisfy access_fn_component_p. Return true
2787 if it is meaningful to compare their associated access functions
2788 when checking for dependencies. */
2790 static bool
2792 {
2793 /* Allow pairs of component refs from the following sets:
2795 { REALPART_EXPR, IMAGPART_EXPR }
2796 { COMPONENT_REF }
2797 { ARRAY_REF }. */
2808 /* ??? We cannot simply use the type of operand #0 of the refs here as
2809 the Fortran compiler smuggles type punning into COMPONENT_REFs.
2810 Use the DECL_CONTEXT of the FIELD_DECLs instead. */
2816 }
2818 /* Initialize a data dependence relation between data accesses A and
2819 B. NB_LOOPS is the number of loops surrounding the references: the
2820 size of the classic distance/direction vectors. */
2826 {
2839 {
2842 }
2844 /* If the data references do not alias, then they are independent. */
2846 {
2849 }
2854 {
2857 }
2859 /* For unconstrained bases, the root (highest-indexed) subscript
2860 describes a variation in the base of the original DR_REF rather
2861 than a component access. We have no type that accurately describes
2862 the new DR_BASE_OBJECT (whose TREE_TYPE describes the type *after*
2863 applying this subscript) so limit the search to the last real
2864 component access.
2866 E.g. for:
2868 void
2869 f (int a[][8], int b[][8])
2870 {
2871 for (int i = 0; i < 8; ++i)
2872 a[i * 2][0] = b[i][0];
2873 }
2875 the a and b accesses have a single ARRAY_REF component reference [0]
2876 but have two subscripts. */
2882 /* These structures describe sequences of component references in
2883 DR_REF (A) and DR_REF (B). Each component reference is tied to a
2884 specific access function. */
2886 /* The sequence starts at DR_ACCESS_FN (A, START_A) of A and
2887 DR_ACCESS_FN (B, START_B) of B (inclusive) and extends to higher
2888 indices. In C notation, these are the indices of the rightmost
2889 component references; e.g. for a sequence .b.c.d, the start
2890 index is for .d. */
2894 /* The sequence contains LENGTH consecutive access functions from
2895 each DR. */
2898 /* The enclosing objects for the A and B sequences respectively,
2899 i.e. the objects to which DR_ACCESS_FN (A, START_A + LENGTH - 1)
2900 and DR_ACCESS_FN (B, START_B + LENGTH - 1) are applied. */
2901 tree object_a;
2902 tree object_b;
2905 /* Before each iteration of the loop:
2907 - REF_A is what you get after applying DR_ACCESS_FN (A, INDEX_A) and
2908 - REF_B is what you get after applying DR_ACCESS_FN (B, INDEX_B). */
2914 /* Now walk the component references from the final DR_REFs back up to
2915 the enclosing base objects. Each component reference corresponds
2916 to one access function in the DR, with access function 0 being for
2917 the final DR_REF and the highest-indexed access function being the
2918 one that is applied to the base of the DR.
2920 Look for a sequence of component references whose access functions
2921 are comparable (see access_fn_components_comparable_p). If more
2922 than one such sequence exists, pick the one nearest the base
2923 (which is the leftmost sequence in C notation). Store this sequence
2924 in FULL_SEQ.
2926 For example, if we have:
2928 struct foo { struct bar s; ... } (*a)[10], (*b)[10];
2930 A: a[0][i].s.c.d
2931 B: __real b[0][i].s.e[i].f
2933 (where d is the same type as the real component of f) then the access
2934 functions would be:
2936 0 1 2 3
2937 A: .d .c .s [i]
2939 0 1 2 3 4 5
2940 B: __real .f [i] .e .s [i]
2942 The A0/B2 column isn't comparable, since .d is a COMPONENT_REF
2943 and [i] is an ARRAY_REF. However, the A1/B3 column contains two
2944 COMPONENT_REF accesses for struct bar, so is comparable. Likewise
2945 the A2/B4 column contains two COMPONENT_REF accesses for struct foo,
2946 so is comparable. The A3/B5 column contains two ARRAY_REFs that
2947 index foo[10] arrays, so is again comparable. The sequence is
2948 therefore:
2950 A: [1, 3] (i.e. [i].s.c)
2951 B: [3, 5] (i.e. [i].s.e)
2953 Also look for sequences of component references whose access
2954 functions are comparable and whose enclosing objects have the same
2955 RECORD_TYPE. Store this sequence in STRUCT_SEQ. In the above
2956 example, STRUCT_SEQ would be:
2958 A: [1, 2] (i.e. s.c)
2959 B: [3, 4] (i.e. s.e) */
2961 {
2962 /* REF_A and REF_B must be one of the component access types
2963 allowed by dr_analyze_indices. */
2967 /* Get the immediately-enclosing objects for REF_A and REF_B,
2968 i.e. the references *before* applying DR_ACCESS_FN (A, INDEX_A)
2969 and DR_ACCESS_FN (B, INDEX_B). */
2976 {
2977 /* This pair of component accesses is comparable for dependence
2978 analysis, so we can include DR_ACCESS_FN (A, INDEX_A) and
2979 DR_ACCESS_FN (B, INDEX_B) in the sequence. */
2982 {
2983 /* The accesses don't extend the current sequence,
2984 so start a new one here. */
2988 }
2990 /* Add this pair of references to the sequence. */
2995 /* If the enclosing objects are structures (and thus have the
2996 same RECORD_TYPE), record the new sequence in STRUCT_SEQ. */
3000 /* Move to the next containing reference for both A and B. */
3006 }
3008 /* Try to approach equal type sizes. */
3018 {
3021 }
3023 {
3026 }
3027 }
3029 /* See whether FULL_SEQ ends at the base and whether the two bases
3030 are equal. We do not care about TBAA or alignment info so we can
3031 use OEP_ADDRESS_OF to avoid false negatives. */
3041 || (object_address_invariant_in_loop_p
3044 /* If the bases are the same, we can include the base variation too.
3045 E.g. the b accesses in:
3047 for (int i = 0; i < n; ++i)
3048 b[i + 4][0] = b[i][0];
3050 have a definite dependence distance of 4, while for:
3052 for (int i = 0; i < n; ++i)
3053 a[i + 4][0] = b[i][0];
3055 the dependence distance depends on the gap between a and b.
3057 If the bases are different then we can only rely on the sequence
3058 rooted at a structure access, since arrays are allowed to overlap
3059 arbitrarily and change shape arbitrarily. E.g. we treat this as
3060 valid code:
3062 int a[256];
3063 ...
3064 ((int (*)[4][3]) &a[1])[i][0] += ((int (*)[4][3]) &a[2])[i][0];
3066 where two lvalues with the same int[4][3] type overlap, and where
3067 both lvalues are distinct from the object's declared type. */
3069 {
3072 }
3073 else
3076 /* Punt if we didn't find a suitable sequence. */
3078 {
3081 }
3084 {
3085 /* Partial overlap is possible for different bases when strict aliasing
3086 is not in effect. It's also possible if either base involves a union
3087 access; e.g. for:
3089 struct s1 { int a[2]; };
3090 struct s2 { struct s1 b; int c; };
3091 struct s3 { int d; struct s1 e; };
3092 union u { struct s2 f; struct s3 g; } *p, *q;
3094 the s1 at "p->f.b" (base "p->f") partially overlaps the s1 at
3095 "p->g.e" (base "p->g") and might partially overlap the s1 at
3096 "q->g.e" (base "q->g"). */
3100 {
3103 }
3111 {
3114 }
3115 }
3124 {
3135 }
3138 }
3140 /* Frees memory used by the conflict function F. */
3142 static void
3144 {
3148 {
3151 }
3153 }
3155 /* Frees memory used by SUBSCRIPTS. */
3157 static void
3159 {
3161 subscript_p s;
3164 {
3168 }
3170 }
3172 /* Set DDR_ARE_DEPENDENT to CHREC and finalize the subscript overlap
3173 description. */
3177 tree chrec)
3178 {
3182 }
3184 /* The dependence relation DDR cannot be represented by a distance
3185 vector. */
3189 {
3194 }
3196 \f
3198 /* This section contains the classic Banerjee tests. */
3200 /* Returns true iff CHREC_A and CHREC_B are not dependent on any index
3201 variables, i.e., if the ZIV (Zero Index Variable) test is true. */
3205 {
3208 }
3210 /* Returns true iff CHREC_A and CHREC_B are dependent on an index
3211 variable, i.e., if the SIV (Single Index Variable) test is true. */
3213 static bool
3215 {
3224 {
3226 {
3229 {
3233 /* FALLTHRU */
3237 }
3241 }
3242 }
3245 }
3247 /* Creates a conflict function with N dimensions. The affine functions
3248 in each dimension follow. */
3252 {
3266 }
3268 /* Returns constant affine function with value CST. */
3270 static affine_fn
3272 {
3273 affine_fn fn;
3277 }
3279 /* Returns affine function with single variable, CST + COEF * x_DIM. */
3281 static affine_fn
3283 {
3284 affine_fn fn;
3294 }
3296 /* Analyze a ZIV (Zero Index Variable) subscript. *OVERLAPS_A and
3297 *OVERLAPS_B are initialized to the functions that describe the
3298 relation between the elements accessed twice by CHREC_A and
3299 CHREC_B. For k >= 0, the following property is verified:
3301 CHREC_A (*OVERLAPS_A (k)) = CHREC_B (*OVERLAPS_B (k)). */
3303 static void
3305 tree chrec_b,
3309 {
3322 {
3325 {
3326 /* The difference is equal to zero: the accessed index
3327 overlaps for each iteration in the loop. */
3332 }
3333 else
3334 {
3335 /* The accesses do not overlap. */
3340 }
3344 /* We're not sure whether the indexes overlap. For the moment,
3345 conservatively answer "don't know". */
3354 }
3358 }
3360 /* Similar to max_stmt_executions_int, but returns the bound as a tree,
3361 and only if it fits to the int type. If this is not the case, or the
3362 bound on the number of iterations of LOOP could not be derived, returns
3363 chrec_dont_know. */
3365 static tree
3367 {
3368 widest_int nit;
3377 }
3379 /* Determine whether the CHREC is always positive/negative. If the expression
3380 cannot be statically analyzed, return false, otherwise set the answer into
3381 VALUE. */
3383 static bool
3385 {
3390 {
3396 /* FIXME -- overflows. */
3398 {
3401 }
3403 /* Otherwise the chrec is under the form: "{-197, +, 2}_1",
3404 and the proof consists in showing that the sign never
3405 changes during the execution of the loop, from 0 to
3406 loop->nb_iterations. */
3414 #if 0
3415 /* TODO -- If the test is after the exit, we may decrease the number of
3416 iterations by one. */
3419 #endif
3431 {
3440 }
3445 }
3446 }
3449 /* Analyze a SIV (Single Index Variable) subscript where CHREC_A is a
3450 constant, and CHREC_B is an affine function. *OVERLAPS_A and
3451 *OVERLAPS_B are initialized to the functions that describe the
3452 relation between the elements accessed twice by CHREC_A and
3453 CHREC_B. For k >= 0, the following property is verified:
3455 CHREC_A (*OVERLAPS_A (k)) = CHREC_B (*OVERLAPS_B (k)). */
3457 static void
3459 tree chrec_b,
3463 {
3472 /* Special case overlap in the first iteration. */
3474 {
3479 }
3482 {
3491 }
3492 else
3493 {
3495 {
3498 {
3507 }
3508 else
3509 {
3511 {
3512 /* Example:
3513 chrec_a = 12
3514 chrec_b = {10, +, 1}
3515 */
3518 {
3519 HOST_WIDE_INT numiter;
3530 /* Perform weak-zero siv test to see if overlap is
3531 outside the loop bounds. */
3536 {
3544 }
3547 }
3549 /* When the step does not divide the difference, there are
3550 no overlaps. */
3551 else
3552 {
3558 }
3559 }
3561 else
3562 {
3563 /* Example:
3564 chrec_a = 12
3565 chrec_b = {10, +, -1}
3567 In this case, chrec_a will not overlap with chrec_b. */
3573 }
3574 }
3575 }
3576 else
3577 {
3580 {
3589 }
3590 else
3591 {
3593 {
3594 /* Example:
3595 chrec_a = 3
3596 chrec_b = {10, +, -1}
3597 */
3599 {
3600 HOST_WIDE_INT numiter;
3609 /* Perform weak-zero siv test to see if overlap is
3610 outside the loop bounds. */
3615 {
3623 }
3626 }
3628 /* When the step does not divide the difference, there
3629 are no overlaps. */
3630 else
3631 {
3637 }
3638 }
3639 else
3640 {
3641 /* Example:
3642 chrec_a = 3
3643 chrec_b = {4, +, 1}
3645 In this case, chrec_a will not overlap with chrec_b. */
3651 }
3652 }
3653 }
3654 }
3655 }
3657 /* Helper recursive function for initializing the matrix A. Returns
3658 the initial value of CHREC. */
3660 static tree
3662 {
3666 {
3676 {
3681 }
3683 CASE_CONVERT:
3684 {
3687 }
3690 {
3691 /* Handle ~X as -1 - X. */
3695 }
3703 }
3704 }
3706 #define FLOOR_DIV(x,y) ((x) / (y))
3708 /* Solves the special case of the Diophantine equation:
3709 | {0, +, STEP_A}_x (OVERLAPS_A) = {0, +, STEP_B}_y (OVERLAPS_B)
3711 Computes the descriptions OVERLAPS_A and OVERLAPS_B. NITER is the
3712 number of iterations that loops X and Y run. The overlaps will be
3713 constructed as evolutions in dimension DIM. */
3715 static void
3717 HOST_WIDE_INT step_a,
3718 HOST_WIDE_INT step_b,
3722 {
3725 {
3734 {
3739 }
3740 else
3745 step_overlaps_a));
3748 step_overlaps_b));
3749 }
3751 else
3752 {
3756 }
3757 }
3759 /* Solves the special case of a Diophantine equation where CHREC_A is
3760 an affine bivariate function, and CHREC_B is an affine univariate
3761 function. For example,
3763 | {{0, +, 1}_x, +, 1335}_y = {0, +, 1336}_z
3765 has the following overlapping functions:
3767 | x (t, u, v) = {{0, +, 1336}_t, +, 1}_v
3768 | y (t, u, v) = {{0, +, 1336}_u, +, 1}_v
3769 | z (t, u, v) = {{{0, +, 1}_t, +, 1335}_u, +, 1}_v
3771 FORNOW: This is a specialized implementation for a case occurring in
3772 a common benchmark. Implement the general algorithm. */
3774 static void
3779 {
3798 {
3806 }
3830 {
3835 {
3844 }
3846 {
3855 }
3857 {
3869 }
3872 }
3873 else
3874 {
3878 }
3886 }
3888 /* Copy the elements of vector VEC1 with length SIZE to VEC2. */
3890 static void
3893 {
3895 }
3897 /* Copy the elements of M x N matrix MAT1 to MAT2. */
3899 static void
3902 {
3907 }
3909 /* Store the N x N identity matrix in MAT. */
3911 static void
3913 {
3919 }
3921 /* Return the index of the first nonzero element of vector VEC1 between
3922 START and N. We must have START <= N.
3923 Returns N if VEC1 is the zero vector. */
3925 static int
3927 {
3930 j++;
3932 }
3934 /* Add a multiple of row R1 of matrix MAT with N columns to row R2:
3935 R2 = R2 + CONST1 * R1. */
3937 static void
3939 lambda_int const1)
3940 {
3948 }
3950 /* Multiply vector VEC1 of length SIZE by a constant CONST1,
3951 and store the result in VEC2. */
3953 static void
3956 {
3961 else
3964 }
3966 /* Negate vector VEC1 with length SIZE and store it in VEC2. */
3968 static void
3971 {
3973 }
3975 /* Negate row R1 of matrix MAT which has N columns. */
3977 static void
3979 {
3981 }
3983 /* Return true if two vectors are equal. */
3985 static bool
3987 {
3993 }
3995 /* Given an M x N integer matrix A, this function determines an M x
3996 M unimodular matrix U, and an M x N echelon matrix S such that
3997 "U.A = S". This decomposition is also known as "right Hermite".
3999 Ref: Algorithm 2.1 page 33 in "Loop Transformations for
4000 Restructuring Compilers" Utpal Banerjee. */
4002 static void
4005 {
4012 {
4014 {
4017 {
4019 {
4034 }
4035 }
4036 }
4037 }
4038 }
4040 /* Determines the overlapping elements due to accesses CHREC_A and
4041 CHREC_B, that are affine functions. This function cannot handle
4042 symbolic evolution functions, ie. when initial conditions are
4043 parameters, because it uses lambda matrices of integers. */
4045 static void
4047 tree chrec_b,
4051 {
4058 {
4059 /* The accessed index overlaps for each iteration in the
4060 loop. */
4065 }
4069 /* For determining the initial intersection, we have to solve a
4070 Diophantine equation. This is the most time consuming part.
4072 For answering to the question: "Is there a dependence?" we have
4073 to prove that there exists a solution to the Diophantine
4074 equation, and that the solution is in the iteration domain,
4075 i.e. the solution is positive or zero, and that the solution
4076 happens before the upper bound loop.nb_iterations. Otherwise
4077 there is no dependence. This function outputs a description of
4078 the iterations that hold the intersections. */
4094 {
4102 }
4105 /* Don't do all the hard work of solving the Diophantine equation
4106 when we already know the solution: for example,
4107 | {3, +, 1}_1
4108 | {3, +, 4}_2
4109 | gamma = 3 - 3 = 0.
4110 Then the first overlap occurs during the first iterations:
4111 | {3, +, 1}_1 ({0, +, 4}_x) = {3, +, 4}_2 ({0, +, 1}_x)
4112 */
4114 {
4116 {
4132 }
4135 compute_overlap_steps_for_affine_1_2
4139 compute_overlap_steps_for_affine_1_2
4142 else
4143 {
4149 }
4151 }
4153 /* U.A = S */
4157 {
4160 }
4163 /* Something went wrong: for example in {1, +, 0}_5 vs. {0, +, 0}_5,
4164 but that is a quite strange case. Instead of ICEing, answer
4165 don't know. */
4167 {
4172 }
4174 /* The classic "gcd-test". */
4176 {
4177 /* The "gcd-test" has determined that there is no integer
4178 solution, i.e. there is no dependence. */
4182 }
4184 /* Both access functions are univariate. This includes SIV and MIV cases. */
4186 {
4187 /* Both functions should have the same evolution sign. */
4190 {
4191 /* The solutions are given by:
4192 |
4193 | [GAMMA/GCD_ALPHA_BETA t].[u11 u12] = [x0]
4194 | [u21 u22] [y0]
4196 For a given integer t. Using the following variables,
4198 | i0 = u11 * gamma / gcd_alpha_beta
4199 | j0 = u12 * gamma / gcd_alpha_beta
4200 | i1 = u21
4201 | j1 = u22
4203 the solutions are:
4205 | x0 = i0 + i1 * t,
4206 | y0 = j0 + j1 * t. */
4216 {
4217 /* There is no solution.
4218 FIXME: The case "i0 > nb_iterations, j0 > nb_iterations"
4219 falls in here, but for the moment we don't look at the
4220 upper bound of the iteration domain. */
4225 }
4228 {
4229 HOST_WIDE_INT niter_a
4231 HOST_WIDE_INT niter_b
4235 /* (X0, Y0) is a solution of the Diophantine equation:
4236 "chrec_a (X0) = chrec_b (Y0)". */
4242 /* (X1, Y1) is the smallest positive solution of the eq
4243 "chrec_a (X1) = chrec_b (Y1)", i.e. this is where the
4244 first conflict occurs. */
4250 {
4251 /* If the overlap occurs outside of the bounds of the
4252 loop, there is no dependence. */
4254 {
4259 }
4261 /* max stmt executions can get quite large, avoid
4262 overflows by using wide ints here. */
4263 widest_int tau2
4269 *last_conflicts
4272 else
4274 }
4275 else
4278 *overlaps_a
4283 *overlaps_b
4288 }
4289 else
4290 {
4291 /* FIXME: For the moment, the upper bound of the
4292 iteration domain for i and j is not checked. */
4298 }
4299 }
4300 else
4301 {
4307 }
4308 }
4309 else
4310 {
4316 }
4318 end_analyze_subs_aa:
4321 {
4327 }
4328 }
4330 /* Returns true when analyze_subscript_affine_affine can be used for
4331 determining the dependence relation between chrec_a and chrec_b,
4332 that contain symbols. This function modifies chrec_a and chrec_b
4333 such that the analysis result is the same, and such that they don't
4334 contain symbols, and then can safely be passed to the analyzer.
4336 Example: The analysis of the following tuples of evolutions produce
4337 the same results: {x+1, +, 1}_1 vs. {x+3, +, 1}_1, and {-2, +, 1}_1
4338 vs. {0, +, 1}_1
4340 {x+1, +, 1}_1 ({2, +, 1}_1) = {x+3, +, 1}_1 ({0, +, 1}_1)
4341 {-2, +, 1}_1 ({2, +, 1}_1) = {0, +, 1}_1 ({0, +, 1}_1)
4342 */
4344 static bool
4346 {
4351 /* FIXME: For the moment not handled. Might be refined later. */
4370 right_b);
4372 }
4374 /* Analyze a SIV (Single Index Variable) subscript. *OVERLAPS_A and
4375 *OVERLAPS_B are initialized to the functions that describe the
4376 relation between the elements accessed twice by CHREC_A and
4377 CHREC_B. For k >= 0, the following property is verified:
4379 CHREC_A (*OVERLAPS_A (k)) = CHREC_B (*OVERLAPS_B (k)). */
4381 static void
4383 tree chrec_b,
4388 {
4406 {
4409 {
4412 last_conflicts);
4420 else
4422 }
4425 {
4428 last_conflicts);
4436 else
4438 }
4439 else
4441 }
4443 else
4444 {
4445 siv_subscript_dontknow:;
4452 }
4456 }
4458 /* Returns false if we can prove that the greatest common divisor of the steps
4459 of CHREC does not divide CST, false otherwise. */
4461 static bool
4463 {
4465 tree step;
4472 {
4478 }
4481 }
4483 /* Analyze a MIV (Multiple Index Variable) subscript with respect to
4484 LOOP_NEST. *OVERLAPS_A and *OVERLAPS_B are initialized to the
4485 functions that describe the relation between the elements accessed
4486 twice by CHREC_A and CHREC_B. For k >= 0, the following property
4487 is verified:
4489 CHREC_A (*OVERLAPS_A (k)) = CHREC_B (*OVERLAPS_B (k)). */
4491 static void
4493 tree chrec_b,
4498 {
4511 {
4512 /* Access functions are the same: all the elements are accessed
4513 in the same order. */
4518 }
4524 {
4525 /* testsuite/.../ssa-chrec-33.c
4526 {{21, +, 2}_1, +, -2}_2 vs. {{20, +, 2}_1, +, -2}_2
4528 The difference is 1, and all the evolution steps are multiples
4529 of 2, consequently there are no overlapping elements. */
4534 }
4540 {
4541 /* testsuite/.../ssa-chrec-35.c
4542 {0, +, 1}_2 vs. {0, +, 1}_3
4543 the overlapping elements are respectively located at iterations:
4544 {0, +, 1}_x and {0, +, 1}_x,
4545 in other words, we have the equality:
4546 {0, +, 1}_2 ({0, +, 1}_x) = {0, +, 1}_3 ({0, +, 1}_x)
4548 Other examples:
4549 {{0, +, 1}_1, +, 2}_2 ({0, +, 1}_x, {0, +, 1}_y) =
4550 {0, +, 1}_1 ({{0, +, 1}_x, +, 2}_y)
4552 {{0, +, 2}_1, +, 3}_2 ({0, +, 1}_y, {0, +, 1}_x) =
4553 {{0, +, 3}_1, +, 2}_2 ({0, +, 1}_x, {0, +, 1}_y)
4554 */
4564 else
4566 }
4568 else
4569 {
4570 /* When the analysis is too difficult, answer "don't know". */
4578 }
4582 }
4584 /* Determines the iterations for which CHREC_A is equal to CHREC_B in
4585 with respect to LOOP_NEST. OVERLAP_ITERATIONS_A and
4586 OVERLAP_ITERATIONS_B are initialized with two functions that
4587 describe the iterations that contain conflicting elements.
4589 Remark: For an integer k >= 0, the following equality is true:
4591 CHREC_A (OVERLAP_ITERATIONS_A (k)) == CHREC_B (OVERLAP_ITERATIONS_B (k)).
4592 */
4594 static void
4596 tree chrec_b,
4600 {
4606 {
4613 }
4619 {
4624 }
4626 /* If they are the same chrec, and are affine, they overlap
4627 on every iteration. */
4631 {
4636 }
4638 /* If they aren't the same, and aren't affine, we can't do anything
4639 yet. */
4644 {
4648 }
4653 last_conflicts);
4660 else
4666 {
4672 }
4673 }
4675 /* Helper function for uniquely inserting distance vectors. */
4677 static void
4679 {
4681 lambda_vector v;
4688 }
4690 /* Helper function for uniquely inserting direction vectors. */
4692 static void
4694 {
4696 lambda_vector v;
4703 }
4705 /* Add a distance of 1 on all the loops outer than INDEX. If we
4706 haven't yet determined a distance for this outer loop, push a new
4707 distance vector composed of the previous distance, and a distance
4708 of 1 for this outer loop. Example:
4710 | loop_1
4711 | loop_2
4712 | A[10]
4713 | endloop_2
4714 | endloop_1
4716 Saved vectors are of the form (dist_in_1, dist_in_2). First, we
4717 save (0, 1), then we have to save (1, 0). */
4719 static void
4722 {
4723 /* For each outer loop where init_v is not set, the accesses are
4724 in dependence of distance 1 in the loop. */
4726 {
4731 }
4732 }
4734 /* Return false when fail to represent the data dependence as a
4735 distance vector. A_INDEX is the index of the first reference
4736 (0 for DDR_A, 1 for DDR_B) and B_INDEX is the index of the
4737 second reference. INIT_B is set to true when a component has been
4738 added to the distance vector DIST_V. INDEX_CARRY is then set to
4739 the index in DIST_V that carries the dependence. */
4741 static bool
4746 {
4752 {
4757 {
4760 }
4767 {
4768 HOST_WIDE_INT dist;
4775 {
4778 }
4780 /* When data references are collected in a loop while data
4781 dependences are analyzed in loop nest nested in the loop, we
4782 would have more number of access functions than number of
4783 loops. Skip access functions of loops not in the loop nest.
4785 See PR89725 for more information. */
4793 /* This is the subscript coupling test. If we have already
4794 recorded a distance for this loop (a distance coming from
4795 another subscript), it should be the same. For example,
4796 in the following code, there is no dependence:
4798 | loop i = 0, N, 1
4799 | T[i+1][i] = ...
4800 | ... = T[i][i]
4801 | endloop
4802 */
4804 {
4807 }
4812 }
4814 {
4815 /* This can be for example an affine vs. constant dependence
4816 (T[i] vs. T[3]) that is not an affine dependence and is
4817 not representable as a distance vector. */
4820 }
4821 }
4824 }
4826 /* Return true when the DDR contains only invariant access functions wrto. loop
4827 number LNUM. */
4829 static bool
4832 {
4842 }
4844 /* Helper function for the case where DDR_A and DDR_B are the same
4845 multivariate access function with a constant step. For an example
4846 see pr34635-1.c. */
4848 static void
4850 {
4854 lambda_vector dist_v;
4857 /* Polynomials with more than 2 variables are not handled yet. When
4858 the evolution steps are parameters, it is not possible to
4859 represent the dependence using classical distance vectors. */
4863 {
4866 }
4871 /* For "{{0, +, 2}_1, +, 3}_2" the distance vector is (3, -2). */
4880 {
4883 }
4890 }
4892 /* Helper function for the case where DDR_A and DDR_B are the same
4893 access functions. */
4895 static void
4897 {
4898 lambda_vector dist_v;
4905 {
4909 {
4911 {
4913 {
4916 }
4922 else
4923 /* The evolution step is not constant: it varies in
4924 the outer loop, so this cannot be represented by a
4925 distance vector. For example in pr34635.c the
4926 evolution is {0, +, {0, +, 4}_1}_2. */
4930 }
4932 /* When data references are collected in a loop while data
4933 dependences are analyzed in loop nest nested in the loop, we
4934 would have more number of access functions than number of
4935 loops. Skip access functions of loops not in the loop nest.
4937 See PR89725 for more information. */
4939 loop))
4945 }
4946 }
4950 }
4952 static void
4954 {
4959 }
4961 /* Adds a unit distance vector to DDR when there is a 0 overlap. This
4962 is the case for example when access functions are the same and
4963 equal to a constant, as in:
4965 | loop_1
4966 | A[3] = ...
4967 | ... = A[3]
4968 | endloop_1
4970 in which case the distance vectors are (0) and (1). */
4972 static void
4974 {
4978 {
4985 {
4988 }
4992 {
4995 }
4996 }
4997 }
4999 /* Return true when the DDR contains two data references that have the
5000 same access functions. */
5004 {
5014 }
5016 /* Compute the classic per loop distance vector. DDR is the data
5017 dependence relation to build a vector from. Return false when fail
5018 to represent the data dependence as a distance vector. */
5020 static bool
5023 {
5026 lambda_vector dist_v;
5032 {
5033 /* Save the 0 vector. */
5044 }
5050 /* Save the distance vector if we initialized one. */
5052 {
5053 /* Verify a basic constraint: classic distance vectors should
5054 always be lexicographically positive.
5056 Data references are collected in the order of execution of
5057 the program, thus for the following loop
5059 | for (i = 1; i < 100; i++)
5060 | for (j = 1; j < 100; j++)
5061 | {
5062 | t = T[j+1][i-1]; // A
5063 | T[j][i] = t + 2; // B
5064 | }
5066 references are collected following the direction of the wind:
5067 A then B. The data dependence tests are performed also
5068 following this order, such that we're looking at the distance
5069 separating the elements accessed by A from the elements later
5070 accessed by B. But in this example, the distance returned by
5071 test_dep (A, B) is lexicographically negative (-1, 1), that
5072 means that the access A occurs later than B with respect to
5073 the outer loop, ie. we're actually looking upwind. In this
5074 case we solve test_dep (B, A) looking downwind to the
5075 lexicographically positive solution, that returns the
5076 distance vector (1, -1). */
5078 {
5089 /* In this case there is a dependence forward for all the
5090 outer loops:
5092 | for (k = 1; k < 100; k++)
5093 | for (i = 1; i < 100; i++)
5094 | for (j = 1; j < 100; j++)
5095 | {
5096 | t = T[j+1][i-1]; // A
5097 | T[j][i] = t + 2; // B
5098 | }
5100 the vectors are:
5101 (0, 1, -1)
5102 (1, 1, -1)
5103 (1, -1, 1)
5104 */
5106 {
5109 }
5110 }
5111 else
5112 {
5117 {
5130 }
5131 else
5133 }
5134 }
5135 else
5136 {
5137 /* There is a distance of 1 on all the outer loops: Example:
5138 there is a dependence of distance 1 on loop_1 for the array A.
5140 | loop_1
5141 | A[5] = ...
5142 | endloop
5143 */
5147 }
5150 {
5155 {
5160 }
5162 }
5165 }
5167 /* Return the direction for a given distance.
5168 FIXME: Computing dir this way is suboptimal, since dir can catch
5169 cases that dist is unable to represent. */
5173 {
5178 else
5180 }
5182 /* Compute the classic per loop direction vector. DDR is the data
5183 dependence relation to build a vector from. */
5185 static void
5187 {
5189 lambda_vector dist_v;
5192 {
5199 }
5200 }
5202 /* Helper function. Returns true when there is a dependence between the
5203 data references. A_INDEX is the index of the first reference (0 for
5204 DDR_A, 1 for DDR_B) and B_INDEX is the index of the second reference. */
5206 static bool
5210 {
5212 tree last_conflicts;
5217 {
5234 /* If there is any undetermined conflict function we have to
5235 give a conservative answer in case we cannot prove that
5236 no dependence exists when analyzing another subscript. */
5239 {
5242 }
5244 /* When there is a subscript with no dependence we can stop. */
5247 {
5250 }
5251 }
5258 else
5262 }
5264 /* Computes the conflicting iterations in LOOP_NEST, and initialize DDR. */
5266 static void
5269 {
5276 }
5278 /* Returns true when all the access functions of A are affine or
5279 constant with respect to LOOP_NEST. */
5281 static bool
5284 {
5287 tree t;
5295 }
5297 /* This computes the affine dependence relation between A and B with
5298 respect to LOOP_NEST. CHREC_KNOWN is used for representing the
5299 independence between two accesses, while CHREC_DONT_KNOW is used
5300 for representing the unknown relation.
5302 Note that it is possible to stop the computation of the dependence
5303 relation the first time we detect a CHREC_KNOWN element for a given
5304 subscript. */
5306 void
5309 {
5314 {
5320 }
5322 /* Analyze only when the dependence relation is not yet known. */
5324 {
5331 /* As a last case, if the dependence cannot be determined, or if
5332 the dependence is considered too difficult to determine, answer
5333 "don't know". */
5334 else
5335 {
5339 {
5344 fprintf (dump_file, "affine dependence test not usable: access function not affine or constant.\n");
5345 }
5347 }
5348 }
5351 {
5356 else
5358 }
5359 }
5361 /* Compute in DEPENDENCE_RELATIONS the data dependence graph for all
5362 the data references in DATAREFS, in the LOOP_NEST. When
5363 COMPUTE_SELF_AND_RR is FALSE, don't compute read-read and self
5364 relations. Return true when successful, i.e. data references number
5365 is small enough to be handled. */
5367 bool
5372 {
5379 {
5382 /* Insert a single relation into dependence_relations:
5383 chrec_dont_know. */
5387 }
5392 {
5397 }
5401 {
5406 }
5409 }
5411 /* Describes a location of a memory reference. */
5413 struct data_ref_loc
5414 {
5415 /* The memory reference. */
5416 tree ref;
5418 /* True if the memory reference is read. */
5421 /* True if the data reference is conditional within the containing
5422 statement, i.e. if it might not occur even when the statement
5423 is executed and runs to completion. */
5425 };
5428 /* Stores the locations of memory references in STMT to REFERENCES. Returns
5429 true if STMT clobbers memory, false otherwise. */
5431 static bool
5433 {
5435 data_ref_loc ref;
5439 /* ASM_EXPR and CALL_EXPR may embed arbitrary side effects.
5440 As we cannot model data-references to not spelled out
5441 accesses give up if they may occur. */
5444 {
5445 /* Allow IFN_GOMP_SIMD_LANE in their own loops. */
5448 {
5450 {
5458 }
5465 }
5466 else
5468 }
5478 {
5479 tree base;
5488 {
5493 }
5494 }
5496 {
5504 {
5509 /* FALLTHRU */
5515 else
5521 ptr);
5526 }
5531 {
5536 {
5541 }
5542 }
5543 }
5544 else
5550 {
5555 }
5557 }
5560 /* Returns true if the loop-nest has any data reference. */
5562 bool
5564 {
5569 {
5571 gimple_stmt_iterator bsi;
5574 {
5578 {
5581 }
5582 }
5583 }
5586 }
5588 /* Stores the data references in STMT to DATAREFS. If there is an unanalyzable
5589 reference, returns false, otherwise returns true. NEST is the outermost
5590 loop of the loop nest in which the references should be analyzed. */
5592 opt_result
5595 {
5599 data_reference_p dr;
5603 stmt);
5606 {
5612 }
5615 }
5617 /* Stores the data references in STMT to DATAREFS. If there is an
5618 unanalyzable reference, returns false, otherwise returns true.
5619 NEST is the outermost loop of the loop nest in which the references
5620 should be instantiated, LOOP is the loop in which the references
5621 should be analyzed. */
5623 bool
5626 {
5631 data_reference_p dr;
5637 {
5642 }
5645 }
5647 /* Search the data references in LOOP, and record the information into
5648 DATAREFS. Returns chrec_dont_know when failing to analyze a
5649 difficult case, returns NULL_TREE otherwise. */
5651 tree
5654 {
5655 gimple_stmt_iterator bsi;
5658 {
5662 {
5668 }
5669 }
5672 }
5674 /* Search the data references in LOOP, and record the information into
5675 DATAREFS. Returns chrec_dont_know when failing to analyze a
5676 difficult case, returns NULL_TREE otherwise.
5678 TODO: This function should be made smarter so that it can handle address
5679 arithmetic as if they were array accesses, etc. */
5681 tree
5684 {
5691 {
5695 {
5698 }
5699 }
5703 }
5705 /* Return the alignment in bytes that DRB is guaranteed to have at all
5706 times. */
5708 unsigned int
5710 {
5711 /* Get the alignment of BASE_ADDRESS + INIT. */
5718 /* Cap it to the alignment of OFFSET. */
5722 /* Cap it to the alignment of STEP. */
5727 }
5729 /* If BASE is a pointer-typed SSA name, try to find the object that it
5730 is based on. Return this object X on success and store the alignment
5731 in bytes of BASE - &X in *ALIGNMENT_OUT. */
5733 static tree
5735 {
5742 /* Peel chrecs and record the minimum alignment preserved by
5743 all steps. */
5746 {
5750 }
5752 /* Punt if the expression is too complicated to handle. */
5756 /* The only useful cases are those for which a dereference folds to something
5757 other than an INDIRECT_REF. */
5763 /* Analyze the base to which the steps we peeled were applied. */
5765 machine_mode mode;
5767 tree offset;
5773 /* Restrict the alignment to that guaranteed by the offsets. */
5778 {
5781 }
5785 }
5787 /* Return the object whose alignment would need to be changed in order
5788 to increase the alignment of ADDR. Store the maximum achievable
5789 alignment in *MAX_ALIGNMENT. */
5791 tree
5793 {
5802 }
5804 /* Recursive helper function. */
5806 static bool
5808 {
5809 /* Inner loops of the nest should not contain siblings. Example:
5810 when there are two consecutive loops,
5812 | loop_0
5813 | loop_1
5814 | A[{0, +, 1}_1]
5815 | endloop_1
5816 | loop_2
5817 | A[{0, +, 1}_2]
5818 | endloop_2
5819 | endloop_0
5821 the dependence relation cannot be captured by the distance
5822 abstraction. */
5830 }
5832 /* Return false when the LOOP is not well nested. Otherwise return
5833 true and insert in LOOP_NEST the loops of the nest. LOOP_NEST will
5834 contain the loops from the outermost to the innermost, as they will
5835 appear in the classic distance vector. */
5837 bool
5839 {
5844 }
5846 /* Returns true when the data dependences have been computed, false otherwise.
5847 Given a loop nest LOOP, the following vectors are returned:
5848 DATAREFS is initialized to all the array elements contained in this loop,
5849 DEPENDENCE_RELATIONS contains the relations between the data references.
5850 Compute read-read and self relations if
5851 COMPUTE_SELF_AND_READ_READ_DEPENDENCES is TRUE. */
5853 bool
5859 {
5864 /* If the loop nest is not well formed, or one of the data references
5865 is not computable, give up without spending time to compute other
5866 dependences. */
5871 compute_self_and_read_read_dependences))
5875 {
5920 }
5923 }
5925 /* Free the memory used by a data dependence relation DDR. */
5927 void
5929 {
5939 }
5941 /* Free the memory used by the data dependence relations from
5942 DEPENDENCE_RELATIONS. */
5944 void
5946 {
5955 }
5957 /* Free the memory used by the data references from DATAREFS. */
5959 void
5961 {
5968 }
5970 /* Common routine implementing both dr_direction_indicator and
5971 dr_zero_step_indicator. Return USEFUL_MIN if the indicator is known
5972 to be >= USEFUL_MIN and -1 if the indicator is known to be negative.
5973 Return the step as the indicator otherwise. */
5975 static tree
5977 {
5982 /* Look for cases where the step is scaled by a positive constant
5983 integer, which will often be the access size. If the multiplication
5984 doesn't change the sign (due to overflow effects) then we can
5985 test the unscaled value instead. */
5989 {
5993 /* Strip widening and truncating conversions as well as nops. */
5999 /* Get the range of step values that would not cause overflow. */
6005 /* Get the range of values that the unconverted step actually has. */
6009 {
6012 }
6014 /* Check whether the unconverted step has an acceptable range. */
6018 {
6023 else
6025 }
6026 }
6028 }
6030 /* Return a value that is negative iff DR has a negative step. */
6032 tree
6034 {
6036 }
6038 /* Return a value that is zero iff DR has a zero step. */
6040 tree
6042 {
6044 }
6046 /* Return true if DR is known to have a nonnegative (but possibly zero)
6047 step. */
6049 bool
6051 {
6057 }