2 * Copyright 2005-2007 Universiteit Leiden
3 * Copyright 2008-2009 Katholieke Universiteit Leuven
4 * Copyright 2010 INRIA Saclay
5 * Copyright 2012 Universiteit Leiden
7 * Use of this software is governed by the MIT license
9 * Written by Sven Verdoolaege, Leiden Institute of Advanced Computer Science,
10 * Universiteit Leiden, Niels Bohrweg 1, 2333 CA Leiden, The Netherlands
11 * and K.U.Leuven, Departement Computerwetenschappen, Celestijnenlaan 200A,
12 * B-3001 Leuven, Belgium
13 * and INRIA Saclay - Ile-de-France, Parc Club Orsay Universite,
14 * ZAC des vignes, 4 rue Jacques Monod, 91893 Orsay, France
22 enum isl_restriction_type
{
23 isl_restriction_type_empty
,
24 isl_restriction_type_none
,
25 isl_restriction_type_input
,
26 isl_restriction_type_output
29 struct isl_restriction
{
30 enum isl_restriction_type type
;
36 /* Create a restriction of the given type.
38 static __isl_give isl_restriction
*isl_restriction_alloc(
39 __isl_take isl_map
*source_map
, enum isl_restriction_type type
)
42 isl_restriction
*restr
;
47 ctx
= isl_map_get_ctx(source_map
);
48 restr
= isl_calloc_type(ctx
, struct isl_restriction
);
54 isl_map_free(source_map
);
57 isl_map_free(source_map
);
61 /* Create a restriction that doesn't restrict anything.
63 __isl_give isl_restriction
*isl_restriction_none(__isl_take isl_map
*source_map
)
65 return isl_restriction_alloc(source_map
, isl_restriction_type_none
);
68 /* Create a restriction that removes everything.
70 __isl_give isl_restriction
*isl_restriction_empty(
71 __isl_take isl_map
*source_map
)
73 return isl_restriction_alloc(source_map
, isl_restriction_type_empty
);
76 /* Create a restriction on the input of the maximization problem
77 * based on the given source and sink restrictions.
79 __isl_give isl_restriction
*isl_restriction_input(
80 __isl_take isl_set
*source_restr
, __isl_take isl_set
*sink_restr
)
83 isl_restriction
*restr
;
85 if (!source_restr
|| !sink_restr
)
88 ctx
= isl_set_get_ctx(source_restr
);
89 restr
= isl_calloc_type(ctx
, struct isl_restriction
);
93 restr
->type
= isl_restriction_type_input
;
94 restr
->source
= source_restr
;
95 restr
->sink
= sink_restr
;
99 isl_set_free(source_restr
);
100 isl_set_free(sink_restr
);
104 /* Create a restriction on the output of the maximization problem
105 * based on the given source restriction.
107 __isl_give isl_restriction
*isl_restriction_output(
108 __isl_take isl_set
*source_restr
)
111 isl_restriction
*restr
;
116 ctx
= isl_set_get_ctx(source_restr
);
117 restr
= isl_calloc_type(ctx
, struct isl_restriction
);
121 restr
->type
= isl_restriction_type_output
;
122 restr
->source
= source_restr
;
126 isl_set_free(source_restr
);
130 void *isl_restriction_free(__isl_take isl_restriction
*restr
)
135 isl_set_free(restr
->source
);
136 isl_set_free(restr
->sink
);
141 isl_ctx
*isl_restriction_get_ctx(__isl_keep isl_restriction
*restr
)
143 return restr
? isl_set_get_ctx(restr
->source
) : NULL
;
146 /* A private structure to keep track of a mapping together with
147 * a user-specified identifier and a boolean indicating whether
148 * the map represents a must or may access/dependence.
150 struct isl_labeled_map
{
156 /* A structure containing the input for dependence analysis:
158 * - n_must + n_may (<= max_source) sources
159 * - a function for determining the relative order of sources and sink
160 * The must sources are placed before the may sources.
162 * domain_map is an auxiliary map that maps the sink access relation
163 * to the domain of this access relation.
165 * restrict_fn is a callback that (if not NULL) will be called
166 * right before any lexicographical maximization.
168 struct isl_access_info
{
170 struct isl_labeled_map sink
;
171 isl_access_level_before level_before
;
173 isl_access_restrict restrict_fn
;
179 struct isl_labeled_map source
[1];
182 /* A structure containing the output of dependence analysis:
183 * - n_source dependences
184 * - a wrapped subset of the sink for which definitely no source could be found
185 * - a wrapped subset of the sink for which possibly no source could be found
188 isl_set
*must_no_source
;
189 isl_set
*may_no_source
;
191 struct isl_labeled_map
*dep
;
194 /* Construct an isl_access_info structure and fill it up with
195 * the given data. The number of sources is set to 0.
197 __isl_give isl_access_info
*isl_access_info_alloc(__isl_take isl_map
*sink
,
198 void *sink_user
, isl_access_level_before fn
, int max_source
)
201 struct isl_access_info
*acc
;
206 ctx
= isl_map_get_ctx(sink
);
207 isl_assert(ctx
, max_source
>= 0, goto error
);
209 acc
= isl_calloc(ctx
, struct isl_access_info
,
210 sizeof(struct isl_access_info
) +
211 (max_source
- 1) * sizeof(struct isl_labeled_map
));
215 acc
->sink
.map
= sink
;
216 acc
->sink
.data
= sink_user
;
217 acc
->level_before
= fn
;
218 acc
->max_source
= max_source
;
228 /* Free the given isl_access_info structure.
230 void *isl_access_info_free(__isl_take isl_access_info
*acc
)
236 isl_map_free(acc
->domain_map
);
237 isl_map_free(acc
->sink
.map
);
238 for (i
= 0; i
< acc
->n_must
+ acc
->n_may
; ++i
)
239 isl_map_free(acc
->source
[i
].map
);
244 isl_ctx
*isl_access_info_get_ctx(__isl_keep isl_access_info
*acc
)
246 return acc
? isl_map_get_ctx(acc
->sink
.map
) : NULL
;
249 __isl_give isl_access_info
*isl_access_info_set_restrict(
250 __isl_take isl_access_info
*acc
, isl_access_restrict fn
, void *user
)
254 acc
->restrict_fn
= fn
;
255 acc
->restrict_user
= user
;
259 /* Add another source to an isl_access_info structure, making
260 * sure the "must" sources are placed before the "may" sources.
261 * This function may be called at most max_source times on a
262 * given isl_access_info structure, with max_source as specified
263 * in the call to isl_access_info_alloc that constructed the structure.
265 __isl_give isl_access_info
*isl_access_info_add_source(
266 __isl_take isl_access_info
*acc
, __isl_take isl_map
*source
,
267 int must
, void *source_user
)
273 ctx
= isl_map_get_ctx(acc
->sink
.map
);
274 isl_assert(ctx
, acc
->n_must
+ acc
->n_may
< acc
->max_source
, goto error
);
278 acc
->source
[acc
->n_must
+ acc
->n_may
] =
279 acc
->source
[acc
->n_must
];
280 acc
->source
[acc
->n_must
].map
= source
;
281 acc
->source
[acc
->n_must
].data
= source_user
;
282 acc
->source
[acc
->n_must
].must
= 1;
285 acc
->source
[acc
->n_must
+ acc
->n_may
].map
= source
;
286 acc
->source
[acc
->n_must
+ acc
->n_may
].data
= source_user
;
287 acc
->source
[acc
->n_must
+ acc
->n_may
].must
= 0;
293 isl_map_free(source
);
294 isl_access_info_free(acc
);
298 /* Return -n, 0 or n (with n a positive value), depending on whether
299 * the source access identified by p1 should be sorted before, together
300 * or after that identified by p2.
302 * If p1 appears before p2, then it should be sorted first.
303 * For more generic initial schedules, it is possible that neither
304 * p1 nor p2 appears before the other, or at least not in any obvious way.
305 * We therefore also check if p2 appears before p1, in which case p2
306 * should be sorted first.
307 * If not, we try to order the two statements based on the description
308 * of the iteration domains. This results in an arbitrary, but fairly
311 static int access_sort_cmp(const void *p1
, const void *p2
, void *user
)
313 isl_access_info
*acc
= user
;
314 const struct isl_labeled_map
*i1
, *i2
;
317 i1
= (const struct isl_labeled_map
*) p1
;
318 i2
= (const struct isl_labeled_map
*) p2
;
320 level1
= acc
->level_before(i1
->data
, i2
->data
);
324 level2
= acc
->level_before(i2
->data
, i1
->data
);
328 h1
= isl_map_get_hash(i1
->map
);
329 h2
= isl_map_get_hash(i2
->map
);
330 return h1
> h2
? 1 : h1
< h2
? -1 : 0;
333 /* Sort the must source accesses in their textual order.
335 static __isl_give isl_access_info
*isl_access_info_sort_sources(
336 __isl_take isl_access_info
*acc
)
340 if (acc
->n_must
<= 1)
343 if (isl_sort(acc
->source
, acc
->n_must
, sizeof(struct isl_labeled_map
),
344 access_sort_cmp
, acc
) < 0)
345 return isl_access_info_free(acc
);
350 /* Align the parameters of the two spaces if needed and then call
353 static __isl_give isl_space
*space_align_and_join(__isl_take isl_space
*left
,
354 __isl_take isl_space
*right
)
356 if (isl_space_match(left
, isl_dim_param
, right
, isl_dim_param
))
357 return isl_space_join(left
, right
);
359 left
= isl_space_align_params(left
, isl_space_copy(right
));
360 right
= isl_space_align_params(right
, isl_space_copy(left
));
361 return isl_space_join(left
, right
);
364 /* Initialize an empty isl_flow structure corresponding to a given
365 * isl_access_info structure.
366 * For each must access, two dependences are created (initialized
367 * to the empty relation), one for the resulting must dependences
368 * and one for the resulting may dependences. May accesses can
369 * only lead to may dependences, so only one dependence is created
371 * This function is private as isl_flow structures are only supposed
372 * to be created by isl_access_info_compute_flow.
374 static __isl_give isl_flow
*isl_flow_alloc(__isl_keep isl_access_info
*acc
)
378 struct isl_flow
*dep
;
383 ctx
= isl_map_get_ctx(acc
->sink
.map
);
384 dep
= isl_calloc_type(ctx
, struct isl_flow
);
388 n
= 2 * acc
->n_must
+ acc
->n_may
;
389 dep
->dep
= isl_calloc_array(ctx
, struct isl_labeled_map
, n
);
394 for (i
= 0; i
< acc
->n_must
; ++i
) {
396 dim
= space_align_and_join(
397 isl_map_get_space(acc
->source
[i
].map
),
398 isl_space_reverse(isl_map_get_space(acc
->sink
.map
)));
399 dep
->dep
[2 * i
].map
= isl_map_empty(dim
);
400 dep
->dep
[2 * i
+ 1].map
= isl_map_copy(dep
->dep
[2 * i
].map
);
401 dep
->dep
[2 * i
].data
= acc
->source
[i
].data
;
402 dep
->dep
[2 * i
+ 1].data
= acc
->source
[i
].data
;
403 dep
->dep
[2 * i
].must
= 1;
404 dep
->dep
[2 * i
+ 1].must
= 0;
405 if (!dep
->dep
[2 * i
].map
|| !dep
->dep
[2 * i
+ 1].map
)
408 for (i
= acc
->n_must
; i
< acc
->n_must
+ acc
->n_may
; ++i
) {
410 dim
= space_align_and_join(
411 isl_map_get_space(acc
->source
[i
].map
),
412 isl_space_reverse(isl_map_get_space(acc
->sink
.map
)));
413 dep
->dep
[acc
->n_must
+ i
].map
= isl_map_empty(dim
);
414 dep
->dep
[acc
->n_must
+ i
].data
= acc
->source
[i
].data
;
415 dep
->dep
[acc
->n_must
+ i
].must
= 0;
416 if (!dep
->dep
[acc
->n_must
+ i
].map
)
426 /* Iterate over all sources and for each resulting flow dependence
427 * that is not empty, call the user specfied function.
428 * The second argument in this function call identifies the source,
429 * while the third argument correspond to the final argument of
430 * the isl_flow_foreach call.
432 int isl_flow_foreach(__isl_keep isl_flow
*deps
,
433 int (*fn
)(__isl_take isl_map
*dep
, int must
, void *dep_user
, void *user
),
441 for (i
= 0; i
< deps
->n_source
; ++i
) {
442 if (isl_map_plain_is_empty(deps
->dep
[i
].map
))
444 if (fn(isl_map_copy(deps
->dep
[i
].map
), deps
->dep
[i
].must
,
445 deps
->dep
[i
].data
, user
) < 0)
452 /* Return a copy of the subset of the sink for which no source could be found.
454 __isl_give isl_map
*isl_flow_get_no_source(__isl_keep isl_flow
*deps
, int must
)
460 return isl_set_unwrap(isl_set_copy(deps
->must_no_source
));
462 return isl_set_unwrap(isl_set_copy(deps
->may_no_source
));
465 void isl_flow_free(__isl_take isl_flow
*deps
)
471 isl_set_free(deps
->must_no_source
);
472 isl_set_free(deps
->may_no_source
);
474 for (i
= 0; i
< deps
->n_source
; ++i
)
475 isl_map_free(deps
->dep
[i
].map
);
481 isl_ctx
*isl_flow_get_ctx(__isl_keep isl_flow
*deps
)
483 return deps
? isl_set_get_ctx(deps
->must_no_source
) : NULL
;
486 /* Return a map that enforces that the domain iteration occurs after
487 * the range iteration at the given level.
488 * If level is odd, then the domain iteration should occur after
489 * the target iteration in their shared level/2 outermost loops.
490 * In this case we simply need to enforce that these outermost
491 * loop iterations are the same.
492 * If level is even, then the loop iterator of the domain should
493 * be greater than the loop iterator of the range at the last
494 * of the level/2 shared loops, i.e., loop level/2 - 1.
496 static __isl_give isl_map
*after_at_level(__isl_take isl_space
*dim
, int level
)
498 struct isl_basic_map
*bmap
;
501 bmap
= isl_basic_map_equal(dim
, level
/2);
503 bmap
= isl_basic_map_more_at(dim
, level
/2 - 1);
505 return isl_map_from_basic_map(bmap
);
508 /* Compute the partial lexicographic maximum of "dep" on domain "sink",
509 * but first check if the user has set acc->restrict_fn and if so
510 * update either the input or the output of the maximization problem
511 * with respect to the resulting restriction.
513 * Since the user expects a mapping from sink iterations to source iterations,
514 * whereas the domain of "dep" is a wrapped map, mapping sink iterations
515 * to accessed array elements, we first need to project out the accessed
516 * sink array elements by applying acc->domain_map.
517 * Similarly, the sink restriction specified by the user needs to be
518 * converted back to the wrapped map.
520 static __isl_give isl_map
*restricted_partial_lexmax(
521 __isl_keep isl_access_info
*acc
, __isl_take isl_map
*dep
,
522 int source
, __isl_take isl_set
*sink
, __isl_give isl_set
**empty
)
525 isl_restriction
*restr
;
526 isl_set
*sink_domain
;
530 if (!acc
->restrict_fn
)
531 return isl_map_partial_lexmax(dep
, sink
, empty
);
533 source_map
= isl_map_copy(dep
);
534 source_map
= isl_map_apply_domain(source_map
,
535 isl_map_copy(acc
->domain_map
));
536 sink_domain
= isl_set_copy(sink
);
537 sink_domain
= isl_set_apply(sink_domain
, isl_map_copy(acc
->domain_map
));
538 restr
= acc
->restrict_fn(source_map
, sink_domain
,
539 acc
->source
[source
].data
, acc
->restrict_user
);
540 isl_set_free(sink_domain
);
541 isl_map_free(source_map
);
545 if (restr
->type
== isl_restriction_type_input
) {
546 dep
= isl_map_intersect_range(dep
, isl_set_copy(restr
->source
));
547 sink_restr
= isl_set_copy(restr
->sink
);
548 sink_restr
= isl_set_apply(sink_restr
,
549 isl_map_reverse(isl_map_copy(acc
->domain_map
)));
550 sink
= isl_set_intersect(sink
, sink_restr
);
551 } else if (restr
->type
== isl_restriction_type_empty
) {
552 isl_space
*space
= isl_map_get_space(dep
);
554 dep
= isl_map_empty(space
);
557 res
= isl_map_partial_lexmax(dep
, sink
, empty
);
559 if (restr
->type
== isl_restriction_type_output
)
560 res
= isl_map_intersect_range(res
, isl_set_copy(restr
->source
));
562 isl_restriction_free(restr
);
571 /* Compute the last iteration of must source j that precedes the sink
572 * at the given level for sink iterations in set_C.
573 * The subset of set_C for which no such iteration can be found is returned
576 static struct isl_map
*last_source(struct isl_access_info
*acc
,
577 struct isl_set
*set_C
,
578 int j
, int level
, struct isl_set
**empty
)
580 struct isl_map
*read_map
;
581 struct isl_map
*write_map
;
582 struct isl_map
*dep_map
;
583 struct isl_map
*after
;
584 struct isl_map
*result
;
586 read_map
= isl_map_copy(acc
->sink
.map
);
587 write_map
= isl_map_copy(acc
->source
[j
].map
);
588 write_map
= isl_map_reverse(write_map
);
589 dep_map
= isl_map_apply_range(read_map
, write_map
);
590 after
= after_at_level(isl_map_get_space(dep_map
), level
);
591 dep_map
= isl_map_intersect(dep_map
, after
);
592 result
= restricted_partial_lexmax(acc
, dep_map
, j
, set_C
, empty
);
593 result
= isl_map_reverse(result
);
598 /* For a given mapping between iterations of must source j and iterations
599 * of the sink, compute the last iteration of must source k preceding
600 * the sink at level before_level for any of the sink iterations,
601 * but following the corresponding iteration of must source j at level
604 static struct isl_map
*last_later_source(struct isl_access_info
*acc
,
605 struct isl_map
*old_map
,
606 int j
, int before_level
,
607 int k
, int after_level
,
608 struct isl_set
**empty
)
611 struct isl_set
*set_C
;
612 struct isl_map
*read_map
;
613 struct isl_map
*write_map
;
614 struct isl_map
*dep_map
;
615 struct isl_map
*after_write
;
616 struct isl_map
*before_read
;
617 struct isl_map
*result
;
619 set_C
= isl_map_range(isl_map_copy(old_map
));
620 read_map
= isl_map_copy(acc
->sink
.map
);
621 write_map
= isl_map_copy(acc
->source
[k
].map
);
623 write_map
= isl_map_reverse(write_map
);
624 dep_map
= isl_map_apply_range(read_map
, write_map
);
625 dim
= space_align_and_join(isl_map_get_space(acc
->source
[k
].map
),
626 isl_space_reverse(isl_map_get_space(acc
->source
[j
].map
)));
627 after_write
= after_at_level(dim
, after_level
);
628 after_write
= isl_map_apply_range(after_write
, old_map
);
629 after_write
= isl_map_reverse(after_write
);
630 dep_map
= isl_map_intersect(dep_map
, after_write
);
631 before_read
= after_at_level(isl_map_get_space(dep_map
), before_level
);
632 dep_map
= isl_map_intersect(dep_map
, before_read
);
633 result
= restricted_partial_lexmax(acc
, dep_map
, k
, set_C
, empty
);
634 result
= isl_map_reverse(result
);
639 /* Given a shared_level between two accesses, return 1 if the
640 * the first can precede the second at the requested target_level.
641 * If the target level is odd, i.e., refers to a statement level
642 * dimension, then first needs to precede second at the requested
643 * level, i.e., shared_level must be equal to target_level.
644 * If the target level is odd, then the two loops should share
645 * at least the requested number of outer loops.
647 static int can_precede_at_level(int shared_level
, int target_level
)
649 if (shared_level
< target_level
)
651 if ((target_level
% 2) && shared_level
> target_level
)
656 /* Given a possible flow dependence temp_rel[j] between source j and the sink
657 * at level sink_level, remove those elements for which
658 * there is an iteration of another source k < j that is closer to the sink.
659 * The flow dependences temp_rel[k] are updated with the improved sources.
660 * Any improved source needs to precede the sink at the same level
661 * and needs to follow source j at the same or a deeper level.
662 * The lower this level, the later the execution date of source k.
663 * We therefore consider lower levels first.
665 * If temp_rel[j] is empty, then there can be no improvement and
666 * we return immediately.
668 static int intermediate_sources(__isl_keep isl_access_info
*acc
,
669 struct isl_map
**temp_rel
, int j
, int sink_level
)
672 int depth
= 2 * isl_map_dim(acc
->source
[j
].map
, isl_dim_in
) + 1;
674 if (isl_map_plain_is_empty(temp_rel
[j
]))
677 for (k
= j
- 1; k
>= 0; --k
) {
679 plevel
= acc
->level_before(acc
->source
[k
].data
, acc
->sink
.data
);
680 if (!can_precede_at_level(plevel
, sink_level
))
683 plevel2
= acc
->level_before(acc
->source
[j
].data
,
684 acc
->source
[k
].data
);
686 for (level
= sink_level
; level
<= depth
; ++level
) {
688 struct isl_set
*trest
;
689 struct isl_map
*copy
;
691 if (!can_precede_at_level(plevel2
, level
))
694 copy
= isl_map_copy(temp_rel
[j
]);
695 T
= last_later_source(acc
, copy
, j
, sink_level
, k
,
697 if (isl_map_plain_is_empty(T
)) {
702 temp_rel
[j
] = isl_map_intersect_range(temp_rel
[j
], trest
);
703 temp_rel
[k
] = isl_map_union_disjoint(temp_rel
[k
], T
);
710 /* Compute all iterations of may source j that precedes the sink at the given
711 * level for sink iterations in set_C.
713 static __isl_give isl_map
*all_sources(__isl_keep isl_access_info
*acc
,
714 __isl_take isl_set
*set_C
, int j
, int level
)
721 read_map
= isl_map_copy(acc
->sink
.map
);
722 read_map
= isl_map_intersect_domain(read_map
, set_C
);
723 write_map
= isl_map_copy(acc
->source
[acc
->n_must
+ j
].map
);
724 write_map
= isl_map_reverse(write_map
);
725 dep_map
= isl_map_apply_range(read_map
, write_map
);
726 after
= after_at_level(isl_map_get_space(dep_map
), level
);
727 dep_map
= isl_map_intersect(dep_map
, after
);
729 return isl_map_reverse(dep_map
);
732 /* For a given mapping between iterations of must source k and iterations
733 * of the sink, compute the all iteration of may source j preceding
734 * the sink at level before_level for any of the sink iterations,
735 * but following the corresponding iteration of must source k at level
738 static __isl_give isl_map
*all_later_sources(__isl_keep isl_access_info
*acc
,
739 __isl_keep isl_map
*old_map
,
740 int j
, int before_level
, int k
, int after_level
)
747 isl_map
*after_write
;
748 isl_map
*before_read
;
750 set_C
= isl_map_range(isl_map_copy(old_map
));
751 read_map
= isl_map_copy(acc
->sink
.map
);
752 read_map
= isl_map_intersect_domain(read_map
, set_C
);
753 write_map
= isl_map_copy(acc
->source
[acc
->n_must
+ j
].map
);
755 write_map
= isl_map_reverse(write_map
);
756 dep_map
= isl_map_apply_range(read_map
, write_map
);
757 dim
= isl_space_join(isl_map_get_space(acc
->source
[acc
->n_must
+ j
].map
),
758 isl_space_reverse(isl_map_get_space(acc
->source
[k
].map
)));
759 after_write
= after_at_level(dim
, after_level
);
760 after_write
= isl_map_apply_range(after_write
, old_map
);
761 after_write
= isl_map_reverse(after_write
);
762 dep_map
= isl_map_intersect(dep_map
, after_write
);
763 before_read
= after_at_level(isl_map_get_space(dep_map
), before_level
);
764 dep_map
= isl_map_intersect(dep_map
, before_read
);
765 return isl_map_reverse(dep_map
);
768 /* Given the must and may dependence relations for the must accesses
769 * for level sink_level, check if there are any accesses of may access j
770 * that occur in between and return their union.
771 * If some of these accesses are intermediate with respect to
772 * (previously thought to be) must dependences, then these
773 * must dependences are turned into may dependences.
775 static __isl_give isl_map
*all_intermediate_sources(
776 __isl_keep isl_access_info
*acc
, __isl_take isl_map
*map
,
777 struct isl_map
**must_rel
, struct isl_map
**may_rel
,
778 int j
, int sink_level
)
781 int depth
= 2 * isl_map_dim(acc
->source
[acc
->n_must
+ j
].map
,
784 for (k
= 0; k
< acc
->n_must
; ++k
) {
787 if (isl_map_plain_is_empty(may_rel
[k
]) &&
788 isl_map_plain_is_empty(must_rel
[k
]))
791 plevel
= acc
->level_before(acc
->source
[k
].data
,
792 acc
->source
[acc
->n_must
+ j
].data
);
794 for (level
= sink_level
; level
<= depth
; ++level
) {
799 if (!can_precede_at_level(plevel
, level
))
802 copy
= isl_map_copy(may_rel
[k
]);
803 T
= all_later_sources(acc
, copy
, j
, sink_level
, k
, level
);
804 map
= isl_map_union(map
, T
);
806 copy
= isl_map_copy(must_rel
[k
]);
807 T
= all_later_sources(acc
, copy
, j
, sink_level
, k
, level
);
808 ran
= isl_map_range(isl_map_copy(T
));
809 map
= isl_map_union(map
, T
);
810 may_rel
[k
] = isl_map_union_disjoint(may_rel
[k
],
811 isl_map_intersect_range(isl_map_copy(must_rel
[k
]),
813 T
= isl_map_from_domain_and_range(
815 isl_space_domain(isl_map_get_space(must_rel
[k
]))),
817 must_rel
[k
] = isl_map_subtract(must_rel
[k
], T
);
824 /* Compute dependences for the case where all accesses are "may"
825 * accesses, which boils down to computing memory based dependences.
826 * The generic algorithm would also work in this case, but it would
827 * be overkill to use it.
829 static __isl_give isl_flow
*compute_mem_based_dependences(
830 __isl_keep isl_access_info
*acc
)
837 res
= isl_flow_alloc(acc
);
841 mustdo
= isl_map_domain(isl_map_copy(acc
->sink
.map
));
842 maydo
= isl_set_copy(mustdo
);
844 for (i
= 0; i
< acc
->n_may
; ++i
) {
851 plevel
= acc
->level_before(acc
->source
[i
].data
, acc
->sink
.data
);
852 is_before
= plevel
& 1;
855 dim
= isl_map_get_space(res
->dep
[i
].map
);
857 before
= isl_map_lex_le_first(dim
, plevel
);
859 before
= isl_map_lex_lt_first(dim
, plevel
);
860 dep
= isl_map_apply_range(isl_map_copy(acc
->source
[i
].map
),
861 isl_map_reverse(isl_map_copy(acc
->sink
.map
)));
862 dep
= isl_map_intersect(dep
, before
);
863 mustdo
= isl_set_subtract(mustdo
,
864 isl_map_range(isl_map_copy(dep
)));
865 res
->dep
[i
].map
= isl_map_union(res
->dep
[i
].map
, dep
);
868 res
->may_no_source
= isl_set_subtract(maydo
, isl_set_copy(mustdo
));
869 res
->must_no_source
= mustdo
;
874 /* Compute dependences for the case where there is at least one
877 * The core algorithm considers all levels in which a source may precede
878 * the sink, where a level may either be a statement level or a loop level.
879 * The outermost statement level is 1, the first loop level is 2, etc...
880 * The algorithm basically does the following:
881 * for all levels l of the read access from innermost to outermost
882 * for all sources w that may precede the sink access at that level
883 * compute the last iteration of the source that precedes the sink access
885 * add result to possible last accesses at level l of source w
886 * for all sources w2 that we haven't considered yet at this level that may
887 * also precede the sink access
888 * for all levels l2 of w from l to innermost
889 * for all possible last accesses dep of w at l
890 * compute last iteration of w2 between the source and sink
892 * add result to possible last accesses at level l of write w2
893 * and replace possible last accesses dep by the remainder
896 * The above algorithm is applied to the must access. During the course
897 * of the algorithm, we keep track of sink iterations that still
898 * need to be considered. These iterations are split into those that
899 * haven't been matched to any source access (mustdo) and those that have only
900 * been matched to may accesses (maydo).
901 * At the end of each level, we also consider the may accesses.
902 * In particular, we consider may accesses that precede the remaining
903 * sink iterations, moving elements from mustdo to maydo when appropriate,
904 * and may accesses that occur between a must source and a sink of any
905 * dependences found at the current level, turning must dependences into
906 * may dependences when appropriate.
909 static __isl_give isl_flow
*compute_val_based_dependences(
910 __isl_keep isl_access_info
*acc
)
914 isl_set
*mustdo
= NULL
;
915 isl_set
*maydo
= NULL
;
918 isl_map
**must_rel
= NULL
;
919 isl_map
**may_rel
= NULL
;
924 res
= isl_flow_alloc(acc
);
927 ctx
= isl_map_get_ctx(acc
->sink
.map
);
929 depth
= 2 * isl_map_dim(acc
->sink
.map
, isl_dim_in
) + 1;
930 mustdo
= isl_map_domain(isl_map_copy(acc
->sink
.map
));
931 maydo
= isl_set_empty_like(mustdo
);
932 if (!mustdo
|| !maydo
)
934 if (isl_set_plain_is_empty(mustdo
))
937 must_rel
= isl_alloc_array(ctx
, struct isl_map
*, acc
->n_must
);
938 may_rel
= isl_alloc_array(ctx
, struct isl_map
*, acc
->n_must
);
939 if (!must_rel
|| !may_rel
)
942 for (level
= depth
; level
>= 1; --level
) {
943 for (j
= acc
->n_must
-1; j
>=0; --j
) {
944 must_rel
[j
] = isl_map_empty_like(res
->dep
[j
].map
);
945 may_rel
[j
] = isl_map_copy(must_rel
[j
]);
948 for (j
= acc
->n_must
- 1; j
>= 0; --j
) {
950 struct isl_set
*rest
;
953 plevel
= acc
->level_before(acc
->source
[j
].data
,
955 if (!can_precede_at_level(plevel
, level
))
958 T
= last_source(acc
, mustdo
, j
, level
, &rest
);
959 must_rel
[j
] = isl_map_union_disjoint(must_rel
[j
], T
);
962 intermediate_sources(acc
, must_rel
, j
, level
);
964 T
= last_source(acc
, maydo
, j
, level
, &rest
);
965 may_rel
[j
] = isl_map_union_disjoint(may_rel
[j
], T
);
968 intermediate_sources(acc
, may_rel
, j
, level
);
970 if (isl_set_plain_is_empty(mustdo
) &&
971 isl_set_plain_is_empty(maydo
))
974 for (j
= j
- 1; j
>= 0; --j
) {
977 plevel
= acc
->level_before(acc
->source
[j
].data
,
979 if (!can_precede_at_level(plevel
, level
))
982 intermediate_sources(acc
, must_rel
, j
, level
);
983 intermediate_sources(acc
, may_rel
, j
, level
);
986 for (j
= 0; j
< acc
->n_may
; ++j
) {
991 plevel
= acc
->level_before(acc
->source
[acc
->n_must
+ j
].data
,
993 if (!can_precede_at_level(plevel
, level
))
996 T
= all_sources(acc
, isl_set_copy(maydo
), j
, level
);
997 res
->dep
[2 * acc
->n_must
+ j
].map
=
998 isl_map_union(res
->dep
[2 * acc
->n_must
+ j
].map
, T
);
999 T
= all_sources(acc
, isl_set_copy(mustdo
), j
, level
);
1000 ran
= isl_map_range(isl_map_copy(T
));
1001 res
->dep
[2 * acc
->n_must
+ j
].map
=
1002 isl_map_union(res
->dep
[2 * acc
->n_must
+ j
].map
, T
);
1003 mustdo
= isl_set_subtract(mustdo
, isl_set_copy(ran
));
1004 maydo
= isl_set_union_disjoint(maydo
, ran
);
1006 T
= res
->dep
[2 * acc
->n_must
+ j
].map
;
1007 T
= all_intermediate_sources(acc
, T
, must_rel
, may_rel
,
1009 res
->dep
[2 * acc
->n_must
+ j
].map
= T
;
1012 for (j
= acc
->n_must
- 1; j
>= 0; --j
) {
1013 res
->dep
[2 * j
].map
=
1014 isl_map_union_disjoint(res
->dep
[2 * j
].map
,
1016 res
->dep
[2 * j
+ 1].map
=
1017 isl_map_union_disjoint(res
->dep
[2 * j
+ 1].map
,
1021 if (isl_set_plain_is_empty(mustdo
) &&
1022 isl_set_plain_is_empty(maydo
))
1029 res
->must_no_source
= mustdo
;
1030 res
->may_no_source
= maydo
;
1034 isl_set_free(mustdo
);
1035 isl_set_free(maydo
);
1041 /* Given a "sink" access, a list of n "source" accesses,
1042 * compute for each iteration of the sink access
1043 * and for each element accessed by that iteration,
1044 * the source access in the list that last accessed the
1045 * element accessed by the sink access before this sink access.
1046 * Each access is given as a map from the loop iterators
1047 * to the array indices.
1048 * The result is a list of n relations between source and sink
1049 * iterations and a subset of the domain of the sink access,
1050 * corresponding to those iterations that access an element
1051 * not previously accessed.
1053 * To deal with multi-valued sink access relations, the sink iteration
1054 * domain is first extended with dimensions that correspond to the data
1055 * space. After the computation is finished, these extra dimensions are
1056 * projected out again.
1058 __isl_give isl_flow
*isl_access_info_compute_flow(__isl_take isl_access_info
*acc
)
1061 struct isl_flow
*res
= NULL
;
1066 acc
->domain_map
= isl_map_domain_map(isl_map_copy(acc
->sink
.map
));
1067 acc
->sink
.map
= isl_map_range_map(acc
->sink
.map
);
1071 if (acc
->n_must
== 0)
1072 res
= compute_mem_based_dependences(acc
);
1074 acc
= isl_access_info_sort_sources(acc
);
1075 res
= compute_val_based_dependences(acc
);
1080 for (j
= 0; j
< res
->n_source
; ++j
) {
1081 res
->dep
[j
].map
= isl_map_apply_range(res
->dep
[j
].map
,
1082 isl_map_copy(acc
->domain_map
));
1083 if (!res
->dep
[j
].map
)
1086 if (!res
->must_no_source
|| !res
->may_no_source
)
1089 isl_access_info_free(acc
);
1092 isl_access_info_free(acc
);
1098 /* Keep track of some information about a schedule for a given
1099 * access. In particular, keep track of which dimensions
1100 * have a constant value and of the actual constant values.
1102 struct isl_sched_info
{
1107 static void sched_info_free(__isl_take
struct isl_sched_info
*info
)
1111 isl_vec_free(info
->cst
);
1116 /* Extract information on the constant dimensions of the schedule
1117 * for a given access. The "map" is of the form
1121 * with S the schedule domain, D the iteration domain and A the data domain.
1123 static __isl_give
struct isl_sched_info
*sched_info_alloc(
1124 __isl_keep isl_map
*map
)
1128 struct isl_sched_info
*info
;
1134 dim
= isl_space_unwrap(isl_space_domain(isl_map_get_space(map
)));
1137 n
= isl_space_dim(dim
, isl_dim_in
);
1138 isl_space_free(dim
);
1140 ctx
= isl_map_get_ctx(map
);
1141 info
= isl_alloc_type(ctx
, struct isl_sched_info
);
1144 info
->is_cst
= isl_alloc_array(ctx
, int, n
);
1145 info
->cst
= isl_vec_alloc(ctx
, n
);
1146 if (n
&& (!info
->is_cst
|| !info
->cst
))
1149 for (i
= 0; i
< n
; ++i
) {
1152 v
= isl_map_plain_get_val_if_fixed(map
, isl_dim_in
, i
);
1155 info
->is_cst
[i
] = !isl_val_is_nan(v
);
1156 if (info
->is_cst
[i
])
1157 info
->cst
= isl_vec_set_element_val(info
->cst
, i
, v
);
1164 sched_info_free(info
);
1168 struct isl_compute_flow_data
{
1169 isl_union_map
*must_source
;
1170 isl_union_map
*may_source
;
1171 isl_union_map
*must_dep
;
1172 isl_union_map
*may_dep
;
1173 isl_union_map
*must_no_source
;
1174 isl_union_map
*may_no_source
;
1179 struct isl_sched_info
*sink_info
;
1180 struct isl_sched_info
**source_info
;
1181 isl_access_info
*accesses
;
1184 static int count_matching_array(__isl_take isl_map
*map
, void *user
)
1188 struct isl_compute_flow_data
*data
;
1190 data
= (struct isl_compute_flow_data
*)user
;
1192 dim
= isl_space_range(isl_map_get_space(map
));
1194 eq
= isl_space_is_equal(dim
, data
->dim
);
1196 isl_space_free(dim
);
1207 static int collect_matching_array(__isl_take isl_map
*map
, void *user
)
1211 struct isl_sched_info
*info
;
1212 struct isl_compute_flow_data
*data
;
1214 data
= (struct isl_compute_flow_data
*)user
;
1216 dim
= isl_space_range(isl_map_get_space(map
));
1218 eq
= isl_space_is_equal(dim
, data
->dim
);
1220 isl_space_free(dim
);
1229 info
= sched_info_alloc(map
);
1230 data
->source_info
[data
->count
] = info
;
1232 data
->accesses
= isl_access_info_add_source(data
->accesses
,
1233 map
, data
->must
, info
);
1243 /* Determine the shared nesting level and the "textual order" of
1244 * the given accesses.
1246 * We first determine the minimal schedule dimension for both accesses.
1248 * If among those dimensions, we can find one where both have a fixed
1249 * value and if moreover those values are different, then the previous
1250 * dimension is the last shared nesting level and the textual order
1251 * is determined based on the order of the fixed values.
1252 * If no such fixed values can be found, then we set the shared
1253 * nesting level to the minimal schedule dimension, with no textual ordering.
1255 static int before(void *first
, void *second
)
1257 struct isl_sched_info
*info1
= first
;
1258 struct isl_sched_info
*info2
= second
;
1262 n1
= isl_vec_size(info1
->cst
);
1263 n2
= isl_vec_size(info2
->cst
);
1268 for (i
= 0; i
< n1
; ++i
) {
1272 if (!info1
->is_cst
[i
])
1274 if (!info2
->is_cst
[i
])
1276 cmp
= isl_vec_cmp_element(info1
->cst
, info2
->cst
, i
);
1280 r
= 2 * i
+ (cmp
< 0);
1288 /* Given a sink access, look for all the source accesses that access
1289 * the same array and perform dataflow analysis on them using
1290 * isl_access_info_compute_flow.
1292 static int compute_flow(__isl_take isl_map
*map
, void *user
)
1296 struct isl_compute_flow_data
*data
;
1299 data
= (struct isl_compute_flow_data
*)user
;
1301 ctx
= isl_map_get_ctx(map
);
1303 data
->accesses
= NULL
;
1304 data
->sink_info
= NULL
;
1305 data
->source_info
= NULL
;
1307 data
->dim
= isl_space_range(isl_map_get_space(map
));
1309 if (isl_union_map_foreach_map(data
->must_source
,
1310 &count_matching_array
, data
) < 0)
1312 if (isl_union_map_foreach_map(data
->may_source
,
1313 &count_matching_array
, data
) < 0)
1316 data
->sink_info
= sched_info_alloc(map
);
1317 data
->source_info
= isl_calloc_array(ctx
, struct isl_sched_info
*,
1320 data
->accesses
= isl_access_info_alloc(isl_map_copy(map
),
1321 data
->sink_info
, &before
, data
->count
);
1322 if (!data
->sink_info
|| (data
->count
&& !data
->source_info
) ||
1327 if (isl_union_map_foreach_map(data
->must_source
,
1328 &collect_matching_array
, data
) < 0)
1331 if (isl_union_map_foreach_map(data
->may_source
,
1332 &collect_matching_array
, data
) < 0)
1335 flow
= isl_access_info_compute_flow(data
->accesses
);
1336 data
->accesses
= NULL
;
1341 data
->must_no_source
= isl_union_map_union(data
->must_no_source
,
1342 isl_union_map_from_map(isl_flow_get_no_source(flow
, 1)));
1343 data
->may_no_source
= isl_union_map_union(data
->may_no_source
,
1344 isl_union_map_from_map(isl_flow_get_no_source(flow
, 0)));
1346 for (i
= 0; i
< flow
->n_source
; ++i
) {
1348 dep
= isl_union_map_from_map(isl_map_copy(flow
->dep
[i
].map
));
1349 if (flow
->dep
[i
].must
)
1350 data
->must_dep
= isl_union_map_union(data
->must_dep
, dep
);
1352 data
->may_dep
= isl_union_map_union(data
->may_dep
, dep
);
1355 isl_flow_free(flow
);
1357 sched_info_free(data
->sink_info
);
1358 if (data
->source_info
) {
1359 for (i
= 0; i
< data
->count
; ++i
)
1360 sched_info_free(data
->source_info
[i
]);
1361 free(data
->source_info
);
1363 isl_space_free(data
->dim
);
1368 isl_access_info_free(data
->accesses
);
1369 sched_info_free(data
->sink_info
);
1370 if (data
->source_info
) {
1371 for (i
= 0; i
< data
->count
; ++i
)
1372 sched_info_free(data
->source_info
[i
]);
1373 free(data
->source_info
);
1375 isl_space_free(data
->dim
);
1381 /* Given a collection of "sink" and "source" accesses,
1382 * compute for each iteration of a sink access
1383 * and for each element accessed by that iteration,
1384 * the source access in the list that last accessed the
1385 * element accessed by the sink access before this sink access.
1386 * Each access is given as a map from the loop iterators
1387 * to the array indices.
1388 * The result is a relations between source and sink
1389 * iterations and a subset of the domain of the sink accesses,
1390 * corresponding to those iterations that access an element
1391 * not previously accessed.
1393 * We first prepend the schedule dimensions to the domain
1394 * of the accesses so that we can easily compare their relative order.
1395 * Then we consider each sink access individually in compute_flow.
1397 int isl_union_map_compute_flow(__isl_take isl_union_map
*sink
,
1398 __isl_take isl_union_map
*must_source
,
1399 __isl_take isl_union_map
*may_source
,
1400 __isl_take isl_union_map
*schedule
,
1401 __isl_give isl_union_map
**must_dep
, __isl_give isl_union_map
**may_dep
,
1402 __isl_give isl_union_map
**must_no_source
,
1403 __isl_give isl_union_map
**may_no_source
)
1406 isl_union_map
*range_map
= NULL
;
1407 struct isl_compute_flow_data data
;
1409 sink
= isl_union_map_align_params(sink
,
1410 isl_union_map_get_space(must_source
));
1411 sink
= isl_union_map_align_params(sink
,
1412 isl_union_map_get_space(may_source
));
1413 sink
= isl_union_map_align_params(sink
,
1414 isl_union_map_get_space(schedule
));
1415 dim
= isl_union_map_get_space(sink
);
1416 must_source
= isl_union_map_align_params(must_source
, isl_space_copy(dim
));
1417 may_source
= isl_union_map_align_params(may_source
, isl_space_copy(dim
));
1418 schedule
= isl_union_map_align_params(schedule
, isl_space_copy(dim
));
1420 schedule
= isl_union_map_reverse(schedule
);
1421 range_map
= isl_union_map_range_map(schedule
);
1422 schedule
= isl_union_map_reverse(isl_union_map_copy(range_map
));
1423 sink
= isl_union_map_apply_domain(sink
, isl_union_map_copy(schedule
));
1424 must_source
= isl_union_map_apply_domain(must_source
,
1425 isl_union_map_copy(schedule
));
1426 may_source
= isl_union_map_apply_domain(may_source
, schedule
);
1428 data
.must_source
= must_source
;
1429 data
.may_source
= may_source
;
1430 data
.must_dep
= must_dep
?
1431 isl_union_map_empty(isl_space_copy(dim
)) : NULL
;
1432 data
.may_dep
= may_dep
? isl_union_map_empty(isl_space_copy(dim
)) : NULL
;
1433 data
.must_no_source
= must_no_source
?
1434 isl_union_map_empty(isl_space_copy(dim
)) : NULL
;
1435 data
.may_no_source
= may_no_source
?
1436 isl_union_map_empty(isl_space_copy(dim
)) : NULL
;
1438 isl_space_free(dim
);
1440 if (isl_union_map_foreach_map(sink
, &compute_flow
, &data
) < 0)
1443 isl_union_map_free(sink
);
1444 isl_union_map_free(must_source
);
1445 isl_union_map_free(may_source
);
1448 data
.must_dep
= isl_union_map_apply_domain(data
.must_dep
,
1449 isl_union_map_copy(range_map
));
1450 data
.must_dep
= isl_union_map_apply_range(data
.must_dep
,
1451 isl_union_map_copy(range_map
));
1452 *must_dep
= data
.must_dep
;
1455 data
.may_dep
= isl_union_map_apply_domain(data
.may_dep
,
1456 isl_union_map_copy(range_map
));
1457 data
.may_dep
= isl_union_map_apply_range(data
.may_dep
,
1458 isl_union_map_copy(range_map
));
1459 *may_dep
= data
.may_dep
;
1461 if (must_no_source
) {
1462 data
.must_no_source
= isl_union_map_apply_domain(
1463 data
.must_no_source
, isl_union_map_copy(range_map
));
1464 *must_no_source
= data
.must_no_source
;
1466 if (may_no_source
) {
1467 data
.may_no_source
= isl_union_map_apply_domain(
1468 data
.may_no_source
, isl_union_map_copy(range_map
));
1469 *may_no_source
= data
.may_no_source
;
1472 isl_union_map_free(range_map
);
1476 isl_union_map_free(range_map
);
1477 isl_union_map_free(sink
);
1478 isl_union_map_free(must_source
);
1479 isl_union_map_free(may_source
);
1480 isl_union_map_free(data
.must_dep
);
1481 isl_union_map_free(data
.may_dep
);
1482 isl_union_map_free(data
.must_no_source
);
1483 isl_union_map_free(data
.may_no_source
);
1490 *must_no_source
= NULL
;
1492 *may_no_source
= NULL
;