| blob | 873e310adfba8a1b9ffe629c76f0a755ec29c0fa |
1 /*
2 * Copyright 2005-2007 Universiteit Leiden
3 * Copyright 2008-2009 Katholieke Universiteit Leuven
4 * Copyright 2010 INRIA Saclay
5 *
6 * Use of this software is governed by the GNU LGPLv2.1 license
7 *
8 * Written by Sven Verdoolaege, Leiden Institute of Advanced Computer Science,
9 * Universiteit Leiden, Niels Bohrweg 1, 2333 CA Leiden, The Netherlands
10 * and K.U.Leuven, Departement Computerwetenschappen, Celestijnenlaan 200A,
11 * B-3001 Leuven, Belgium
12 * and INRIA Saclay - Ile-de-France, Parc Club Orsay Universite,
13 * ZAC des vignes, 4 rue Jacques Monod, 91893 Orsay, France
14 */
16 #include <isl_flow.h>
18 /* A private structure to keep track of a mapping together with
19 * a user-specified identifier and a boolean indicating whether
20 * the map represents a must or may access/dependence.
21 */
26 };
28 /* A structure containing the input for dependence analysis:
29 * - a sink
30 * - n_must + n_may (<= max_source) sources
31 * - a function for determining the relative order of sources and sink
32 * The must sources are placed before the may sources.
33 */
36 isl_access_level_before level_before;
41 };
43 /* A structure containing the output of dependence analysis:
44 * - n_source dependences
45 * - a subset of the sink for which definitely no source could be found
46 * - a subset of the sink for which possibly no source could be found
47 */
53 };
55 /* Construct an isl_access_info structure and fill it up with
56 * the given data. The number of sources is set to 0.
57 */
60 {
82 error:
85 }
87 /* Free the given isl_access_info structure.
88 * This function is static because the user is expected to call
89 * isl_access_info_compute_flow on any isl_access_info structure
90 * he creates.
91 */
93 {
102 }
104 /* Add another source to an isl_access_info structure, making
105 * sure the "must" sources are placed before the "may" sources.
106 * This function may be called at most max_source times on a
107 * given isl_access_info structure, with max_source as specified
108 * in the call to isl_access_info_alloc that constructed the structure.
109 */
113 {
132 }
135 error:
139 }
141 /* A temporary structure used while sorting the accesses in an isl_access_info.
142 */
147 };
149 /* Return -n, 0 or n (with n a positive value), depending on whether
150 * the source access identified by p1 should be sorted before, together
151 * or after that identified by p2.
152 *
153 * If p1 and p2 share a different number of levels with the sink,
154 * then the one with the lowest number of shared levels should be
155 * sorted first.
156 * If they both share no levels, then the order is irrelevant.
157 * Otherwise, if p1 appears before p2, then it should be sorted first.
158 */
160 {
175 }
177 /* Sort the must source accesses in order of increasing number of shared
178 * levels with the sink access.
179 * Source accesses with the same number of shared levels are sorted
180 * in their textual order.
181 */
184 {
202 }
205 access_sort_cmp);
210 }
215 error:
218 }
220 /* Initialize an empty isl_flow structure corresponding to a given
221 * isl_access_info structure.
222 * For each must access, two dependences are created (initialized
223 * to the empty relation), one for the resulting must dependences
224 * and one for the resulting may dependences. May accesses can
225 * only lead to may dependences, so only one dependence is created
226 * for each of them.
227 * This function is private as isl_flow structures are only supposed
228 * to be created by isl_access_info_compute_flow.
229 */
231 {
262 }
272 }
275 error:
278 }
280 /* Iterate over all sources and for each resulting flow dependence
281 * that is not empty, call the user specfied function.
282 * The second argument in this function call identifies the source,
283 * while the third argument correspond to the final argument of
284 * the isl_flow_foreach call.
285 */
289 {
301 }
304 }
306 /* Return a copy of the subset of the sink for which no source could be found.
307 */
309 {
315 else
317 }
320 {
331 }
333 }
335 /* Return a map that enforces that the domain iteration occurs after
336 * the range iteration at the given level.
337 * If level is odd, then the domain iteration should occur after
338 * the target iteration in their shared level/2 outermost loops.
339 * In this case we simply need to enforce that these outermost
340 * loop iterations are the same.
341 * If level is even, then the loop iterator of the domain should
342 * be greater than the loop iterator of the range at the last
343 * of the level/2 shared loops, i.e., loop level/2 - 1.
344 */
346 {
351 else
355 }
357 /* Compute the last iteration of must source j that precedes the sink
358 * at the given level for sink iterations in set_C.
359 * The subset of set_C for which no such iteration can be found is returned
360 * in *empty.
361 */
365 {
382 }
384 /* For a given mapping between iterations of must source j and iterations
385 * of the sink, compute the last iteration of must source k preceding
386 * the sink at level before_level for any of the sink iterations,
387 * but following the corresponding iteration of must source j at level
388 * after_level.
389 */
395 {
423 }
425 /* Given a shared_level between two accesses, return 1 if the
426 * the first can precede the second at the requested target_level.
427 * If the target level is odd, i.e., refers to a statement level
428 * dimension, then first needs to precede second at the requested
429 * level, i.e., shared_level must be equal to target_level.
430 * If the target level is odd, then the two loops should share
431 * at least the requested number of outer loops.
432 */
434 {
440 }
442 /* Given a possible flow dependence temp_rel[j] between source j and the sink
443 * at level sink_level, remove those elements for which
444 * there is an iteration of another source k < j that is closer to the sink.
445 * The flow dependences temp_rel[k] are updated with the improved sources.
446 * Any improved source needs to precede the sink at the same level
447 * and needs to follow source j at the same or a deeper level.
448 * The lower this level, the later the execution date of source k.
449 * We therefore consider lower levels first.
450 *
451 * If temp_rel[j] is empty, then there can be no improvement and
452 * we return immediately.
453 */
456 {
487 }
490 }
491 }
494 }
496 /* Compute all iterations of may source j that precedes the sink at the given
497 * level for sink iterations in set_C.
498 */
501 {
516 }
518 /* For a given mapping between iterations of must source k and iterations
519 * of the sink, compute the all iteration of may source j preceding
520 * the sink at level before_level for any of the sink iterations,
521 * but following the corresponding iteration of must source k at level
522 * after_level.
523 */
527 {
552 }
554 /* Given the must and may dependence relations for the must accesses
555 * for level sink_level, check if there are any accesses of may access j
556 * that occur in between and return their union.
557 * If some of these accesses are intermediate with respect to
558 * (previously thought to be) must dependences, then these
559 * must dependences are turned into may dependences.
560 */
565 {
602 ran);
604 }
605 }
608 }
610 /* Compute dependences for the case where all accesses are "may"
611 * accesses, which boils down to computing memory based dependences.
612 * The generic algorithm would also work in this case, but it would
613 * be overkill to use it.
614 */
617 {
644 else
652 }
660 error:
663 }
665 /* Compute dependences for the case where there is at least one
666 * "must" access.
667 *
668 * The core algorithm considers all levels in which a source may precede
669 * the sink, where a level may either be a statement level or a loop level.
670 * The outermost statement level is 1, the first loop level is 2, etc...
671 * The algorithm basically does the following:
672 * for all levels l of the read access from innermost to outermost
673 * for all sources w that may precede the sink access at that level
674 * compute the last iteration of the source that precedes the sink access
675 * at that level
676 * add result to possible last accesses at level l of source w
677 * for all sources w2 that we haven't considered yet at this level that may
678 * also precede the sink access
679 * for all levels l2 of w from l to innermost
680 * for all possible last accesses dep of w at l
681 * compute last iteration of w2 between the source and sink
682 * of dep
683 * add result to possible last accesses at level l of write w2
684 * and replace possible last accesses dep by the remainder
685 *
686 *
687 * The above algorithm is applied to the must access. During the course
688 * of the algorithm, we keep track of sink iterations that still
689 * need to be considered. These iterations are split into those that
690 * haven't been matched to any source access (mustdo) and those that have only
691 * been matched to may accesses (maydo).
692 * At the end of each level, we also consider the may accesses.
693 * In particular, we consider may accesses that precede the remaining
694 * sink iterations, moving elements from mustdo to maydo when appropriate,
695 * and may accesses that occur between a must source and a sink of any
696 * dependences found at the current level, turning must dependences into
697 * may dependences when appropriate.
698 *
699 */
702 {
738 }
765 }
776 }
802 }
811 }
816 }
820 done:
825 error:
833 }
835 /* Given a "sink" access, a list of n "source" accesses,
836 * compute for each iteration of the sink access
837 * and for each element accessed by that iteration,
838 * the source access in the list that last accessed the
839 * element accessed by the sink access before this sink access.
840 * Each access is given as a map from the loop iterators
841 * to the array indices.
842 * The result is a list of n relations between source and sink
843 * iterations and a subset of the domain of the sink access,
844 * corresponding to those iterations that access an element
845 * not previously accessed.
846 *
847 * To deal with multi-valued sink access relations, the sink iteration
848 * domain is first extended with dimensions that correspond to the data
849 * space. After the computation is finished, these extra dimensions are
850 * projected out again.
851 */
853 {
877 else
887 }
894 error:
897 error2:
900 }