| blob | 4ca369a25605369c553f7c38b3bba2878498a4f3 |
1 /*
2 * Copyright 2010 INRIA Saclay
3 *
4 * Use of this software is governed by the GNU LGPLv2.1 license
5 *
6 * Written by Sven Verdoolaege, INRIA Saclay - Ile-de-France,
7 * Parc Club Orsay Universite, ZAC des vignes, 4 rue Jacques Monod,
8 * 91893 Orsay, France
9 */
11 #include <isl/map.h>
13 #include <isl/seq.h>
14 #include <isl_dim_private.h>
15 #include <isl/lp.h>
16 #include <isl/union_map.h>
17 #include <isl_mat_private.h>
20 {
29 }
32 {
42 }
44 /* Given a map that represents a path with the length of the path
45 * encoded as the difference between the last output coordindate
46 * and the last input coordinate, set this length to either
47 * exactly "length" (if "exactly" is set) or at least "length"
48 * (if "exactly" is not set).
49 */
52 {
73 }
85 error:
89 }
91 /* Check whether the overapproximation of the power of "map" is exactly
92 * the power of "map". Let R be "map" and A_k the overapproximation.
93 * The approximation is exact if
94 *
95 * A_1 = R
96 * A_k = A_{k-1} \circ R k >= 2
97 *
98 * Since A_k is known to be an overapproximation, we only need to check
99 *
100 * A_1 \subset R
101 * A_k \subset A_{k-1} \circ R k >= 2
102 *
103 * In practice, "app" has an extra input and output coordinate
104 * to encode the length of the path. So, we first need to add
105 * this coordinate to "map" and set the length of the path to
106 * one.
107 */
110 {
128 }
140 }
142 /* Check whether the overapproximation of the power of "map" is exactly
143 * the power of "map", possibly after projecting out the power (if "project"
144 * is set).
145 *
146 * If "project" is set and if "steps" can only result in acyclic paths,
147 * then we check
148 *
149 * A = R \cup (A \circ R)
150 *
151 * where A is the overapproximation with the power projected out, i.e.,
152 * an overapproximation of the transitive closure.
153 * More specifically, since A is known to be an overapproximation, we check
154 *
155 * A \subset R \cup (A \circ R)
156 *
157 * Otherwise, we check if the power is exact.
158 *
159 * Note that "app" has an extra input and output coordinate to encode
160 * the length of the part. If we are only interested in the transitive
161 * closure, then we can simply project out these coordinates first.
162 */
165 {
191 }
193 /*
194 * The transitive closure implementation is based on the paper
195 * "Computing the Transitive Closure of a Union of Affine Integer
196 * Tuple Relations" by Anna Beletska, Denis Barthou, Wlodzimierz Bielecki and
197 * Albert Cohen.
198 */
200 /* Given a set of n offsets v_i (the rows of "steps"), construct a relation
201 * of the given dimension specification (Z^{n+1} -> Z^{n+1})
202 * that maps an element x to any element that can be reached
203 * by taking a non-negative number of steps along any of
204 * the extended offsets v'_i = [v_i 1].
205 * That is, construct
206 *
207 * { [x] -> [y] : exists k_i >= 0, y = x + \sum_i k_i v'_i }
208 *
209 * For any element in this relation, the number of steps taken
210 * is equal to the difference in the final coordinates.
211 */
214 {
236 }
248 else
252 }
260 }
267 error:
271 }
273 #define IMPURE 0
274 #define PURE_PARAM 1
275 #define PURE_VAR 2
276 #define MIXED 3
278 /* Check whether the parametric constant term of constraint c is never
279 * positive in "bset".
280 */
283 {
308 }
314 error:
317 }
319 /* Return PURE_PARAM if only the coefficients of the parameters are non-zero.
320 * Return PURE_VAR if only the coefficients of the set variables are non-zero.
321 * Return MIXED if only the coefficients of the parameters and the set
322 * variables are non-zero and if moreover the parametric constant
323 * can never attain positive values.
324 * Return IMPURE otherwise.
325 */
328 {
347 }
348 }
358 }
361 }
363 /* Return an array of integers indicating the type of each div in bset.
364 * If the div is (recursively) defined in terms of only the parameters,
365 * then the type is PURE_PARAM.
366 * If the div is (recursively) defined in terms of only the set variables,
367 * then the type is PURE_VAR.
368 * Otherwise, the type is IMPURE.
369 */
371 {
394 }
406 }
407 }
409 }
412 }
414 /* Given a path with the as yet unconstrained length at position "pos",
415 * check if setting the length to zero results in only the identity
416 * mapping.
417 */
419 {
437 error:
440 }
446 {
467 }
481 }
484 }
487 error:
490 }
492 /* Given a set of offsets "delta", construct a relation of the
493 * given dimension specification (Z^{n+1} -> Z^{n+1}) that
494 * is an overapproximation of the relations that
495 * maps an element x to any element that can be reached
496 * by taking a non-negative number of steps along any of
497 * the elements in "delta".
498 * That is, construct an approximation of
499 *
500 * { [x] -> [y] : exists f \in \delta, k \in Z :
501 * y = x + k [f, 1] and k >= 0 }
502 *
503 * For any element in this relation, the number of steps taken
504 * is equal to the difference in the final coordinates.
505 *
506 * In particular, let delta be defined as
507 *
508 * \delta = [p] -> { [x] : A x + a >= and B p + b >= 0 and
509 * C x + C'p + c >= 0 and
510 * D x + D'p + d >= 0 }
511 *
512 * where the constraints C x + C'p + c >= 0 are such that the parametric
513 * constant term of each constraint j, "C_j x + C'_j p + c_j",
514 * can never attain positive values, then the relation is constructed as
515 *
516 * { [x] -> [y] : exists [f, k] \in Z^{n+1} : y = x + f and
517 * A f + k a >= 0 and B p + b >= 0 and
518 * C f + C'p + c >= 0 and k >= 1 }
519 * union { [x] -> [x] }
520 *
521 * If the zero-length paths happen to correspond exactly to the identity
522 * mapping, then we return
523 *
524 * { [x] -> [y] : exists [f, k] \in Z^{n+1} : y = x + f and
525 * A f + k a >= 0 and B p + b >= 0 and
526 * C f + C'p + c >= 0 and k >= 0 }
527 *
528 * instead.
529 *
530 * Existentially quantified variables in \delta are handled by
531 * classifying them as independent of the parameters, purely
532 * parameter dependent and others. Constraints containing
533 * any of the other existentially quantified variables are removed.
534 * This is safe, but leads to an additional overapproximation.
535 */
538 {
562 }
572 }
599 }
602 error:
608 }
610 /* Given a dimension specification Z^{n+1} -> Z^{n+1} and a parameter "param",
611 * construct a map that equates the parameter to the difference
612 * in the final coordinates and imposes that this difference is positive.
613 * That is, construct
614 *
615 * { [x,x_s] -> [y,y_s] : k = y_s - x_s > 0 }
616 */
619 {
645 error:
648 }
650 /* Check whether "path" is acyclic, where the last coordinates of domain
651 * and range of path encode the number of steps taken.
652 * That is, check whether
653 *
654 * { d | d = y - x and (x,y) in path }
655 *
656 * does not contain any element with positive last coordinate (positive length)
657 * and zero remaining coordinates (cycle).
658 */
660 {
671 else
673 }
679 }
681 /* Given a union of basic maps R = \cup_i R_i \subseteq D \times D
682 * and a dimension specification (Z^{n+1} -> Z^{n+1}),
683 * construct a map that is an overapproximation of the map
684 * that takes an element from the space D \times Z to another
685 * element from the same space, such that the first n coordinates of the
686 * difference between them is a sum of differences between images
687 * and pre-images in one of the R_i and such that the last coordinate
688 * is equal to the number of steps taken.
689 * That is, let
690 *
691 * \Delta_i = { y - x | (x, y) in R_i }
692 *
693 * then the constructed map is an overapproximation of
694 *
695 * { (x) -> (x + d) | \exists k_i >= 0, \delta_i \in \Delta_i :
696 * d = (\sum_i k_i \delta_i, \sum_i k_i) }
697 *
698 * The elements of the singleton \Delta_i's are collected as the
699 * rows of the steps matrix. For all these \Delta_i's together,
700 * a single path is constructed.
701 * For each of the other \Delta_i's, we compute an overapproximation
702 * of the paths along elements of \Delta_i.
703 * Since each of these paths performs an addition, composition is
704 * symmetric and we can simply compose all resulting paths in any order.
705 */
708 {
736 }
739 }
749 }
750 }
756 }
762 }
767 error:
772 }
775 {
787 }
789 /* Given a union of basic maps R = \cup_i R_i \subseteq D \times D
790 * and a dimension specification (Z^{n+1} -> Z^{n+1}),
791 * construct a map that is an overapproximation of the map
792 * that takes an element from the dom R \times Z to an
793 * element from ran R \times Z, such that the first n coordinates of the
794 * difference between them is a sum of differences between images
795 * and pre-images in one of the R_i and such that the last coordinate
796 * is equal to the number of steps taken.
797 * That is, let
798 *
799 * \Delta_i = { y - x | (x, y) in R_i }
800 *
801 * then the constructed map is an overapproximation of
802 *
803 * { (x) -> (x + d) | \exists k_i >= 0, \delta_i \in \Delta_i :
804 * d = (\sum_i k_i \delta_i, \sum_i k_i) and
805 * x in dom R and x + d in ran R and
806 * \sum_i k_i >= 1 }
807 */
810 {
830 }
847 error:
851 }
853 /* Call construct_component and, if "project" is set, project out
854 * the final coordinates.
855 */
859 {
871 }
873 }
875 /* Compute an extended version, i.e., with path lengths, of
876 * an overapproximation of the transitive closure of "bmap"
877 * with path lengths greater than or equal to zero and with
878 * domain and range equal to "dom".
879 */
882 {
898 error:
901 }
903 /* Check whether qc has any elements of length at least one
904 * with domain and/or range outside of dom and ran.
905 */
908 {
931 }
938 error:
941 }
943 #define LEFT 2
944 #define RIGHT 1
946 /* For each basic map in "map", except i, check whether it combines
947 * with the transitive closure that is reflexive on C combines
948 * to the left and to the right.
949 *
950 * In particular, if
951 *
952 * dom map_j \subseteq C
953 *
954 * then right[j] is set to 1. Otherwise, if
955 *
956 * ran map_i \cap dom map_j = \emptyset
957 *
958 * then right[j] is set to 0. Otherwise, composing to the right
959 * is impossible.
960 *
961 * Similar, for composing to the left, we have if
962 *
963 * ran map_j \subseteq C
964 *
965 * then left[j] is set to 1. Otherwise, if
966 *
967 * dom map_i \cap ran map_j = \emptyset
968 *
969 * then left[j] is set to 0. Otherwise, composing to the left
970 * is impossible.
971 *
972 * The return value is or'd with LEFT if composing to the left
973 * is possible and with RIGHT if composing to the right is possible.
974 */
978 {
1006 else
1008 }
1009 }
1029 else
1031 }
1032 }
1033 }
1036 }
1039 {
1043 }
1045 /* Return a map that is a union of the basic maps in "map", except i,
1046 * composed to left and right with qc based on the entries of "left"
1047 * and "right".
1048 */
1051 {
1069 }
1077 }
1079 /* Compute the transitive closure of "map" incrementally by
1080 * computing
1081 *
1082 * map_i^+ \cup qc^+
1083 *
1084 * or
1085 *
1086 * map_i^+ \cup ((id \cup map_i^) \circ qc^+)
1087 *
1088 * or
1089 *
1090 * map_i^+ \cup (qc^+ \circ (id \cup map_i^))
1091 *
1092 * depending on whether left or right are NULL.
1093 */
1097 {
1119 }
1133 error:
1137 }
1139 /* Given a map "map", try to find a basic map such that
1140 * map^+ can be computed as
1141 *
1142 * map^+ = map_i^+ \cup
1143 * \bigcup_j ((map_i^+ \cup Id_C)^+ \circ map_j \circ (map_i^+ \cup Id_C))^+
1144 *
1145 * with C the simple hull of the domain and range of the input map.
1146 * map_i^ \cup Id_C is computed by allowing the path lengths to be zero
1147 * and by intersecting domain and range with C.
1148 * Of course, we need to check that this is actually equal to map_i^ \cup Id_C.
1149 * Also, we only use the incremental computation if all the transitive
1150 * closures are exact and if the number of basic maps in the union,
1151 * after computing the integer divisions, is smaller than the number
1152 * of basic maps in the input map.
1153 */
1158 {
1173 }
1192 }
1199 }
1211 }
1220 }
1225 error:
1228 }
1230 /* Try and compute the transitive closure of "map" as
1231 *
1232 * map^+ = map_i^+ \cup
1233 * \bigcup_j ((map_i^+ \cup Id_C)^+ \circ map_j \circ (map_i^+ \cup Id_C))^+
1234 *
1235 * with C either the simple hull of the domain and range of the entire
1236 * map or the simple hull of domain and range of map_i.
1237 */
1240 {
1293 }
1300 }
1307 }
1314 }
1325 }
1335 }
1340 }
1349 }
1352 error:
1365 }
1367 /* Given an array of sets "set", add "dom" at position "pos"
1368 * and search for elements at earlier positions that overlap with "dom".
1369 * If any can be found, then merge all of them, together with "dom", into
1370 * a single set and assign the union to the first in the array,
1371 * which becomes the new group leader for all groups involved in the merge.
1372 * During the search, we only consider group leaders, i.e., those with
1373 * group[i] = i, as the other sets have already been combined
1374 * with one of the group leaders.
1375 */
1377 {
1401 }
1405 error:
1408 }
1410 /* Replace each entry in the n by n grid of maps by the cross product
1411 * with the relation { [i] -> [i + 1] }.
1412 */
1414 {
1435 }
1451 }
1453 /* The core of the Floyd-Warshall algorithm.
1454 * Updates the given n x x matrix of relations in place.
1455 *
1456 * The algorithm iterates over all vertices. In each step, the whole
1457 * matrix is updated to include all paths that go to the current vertex,
1458 * possibly stay there a while (including passing through earlier vertices)
1459 * and then come back. At the start of each iteration, the diagonal
1460 * element corresponding to the current vertex is replaced by its
1461 * transitive closure to account for all indirect paths that stay
1462 * in the current vertex.
1463 */
1465 {
1491 }
1492 }
1493 }
1495 /* Given a partition of the domains and ranges of the basic maps in "map",
1496 * apply the Floyd-Warshall algorithm with the elements in the partition
1497 * as vertices.
1498 *
1499 * In particular, there are "n" elements in the partition and "group" is
1500 * an array of length 2 * map->n with entries in [0,n-1].
1501 *
1502 * We first construct a matrix of relations based on the partition information,
1503 * apply Floyd-Warshall on this matrix of relations and then take the
1504 * union of all entries in the matrix as the final result.
1505 *
1506 * If we are actually computing the power instead of the transitive closure,
1507 * i.e., when "project" is not set, then the result should have the
1508 * path lengths encoded as the difference between an extra pair of
1509 * coordinates. We therefore apply the nested transitive closures
1510 * to relations that include these lengths. In particular, we replace
1511 * the input relation by the cross product with the unit length relation
1512 * { [i] -> [i + 1] }.
1513 */
1516 {
1527 }
1538 }
1546 }
1559 }
1566 error:
1574 }
1579 }
1581 /* Partition the domains and ranges of the n basic relations in list
1582 * into disjoint cells.
1583 *
1584 * To find the partition, we simply consider all of the domains
1585 * and ranges in turn and combine those that overlap.
1586 * "set" contains the partition elements and "group" indicates
1587 * to which partition element a given domain or range belongs.
1588 * The domain of basic map i corresponds to element 2 * i in these arrays,
1589 * while the domain corresponds to element 2 * i + 1.
1590 * During the construction group[k] is either equal to k,
1591 * in which case set[k] contains the union of all the domains and
1592 * ranges in the corresponding group, or is equal to some l < k,
1593 * with l another domain or range in the same group.
1594 */
1597 {
1618 }
1626 }
1634 error:
1640 }
1643 }
1645 /* Check if the domains and ranges of the basic maps in "map" can
1646 * be partitioned, and if so, apply Floyd-Warshall on the elements
1647 * of the partition. Note that we also apply this algorithm
1648 * if we want to compute the power, i.e., when "project" is not set.
1649 * However, the results are unlikely to be exact since the recursive
1650 * calls inside the Floyd-Warshall algorithm typically result in
1651 * non-linear path lengths quite quickly.
1652 */
1655 {
1676 error:
1679 }
1681 /* Structure for representing the nodes in the graph being traversed
1682 * using Tarjan's algorithm.
1683 * index represents the order in which nodes are visited.
1684 * min_index is the index of the root of a (sub)component.
1685 * on_stack indicates whether the node is currently on the stack.
1686 */
1691 };
1692 /* Structure for representing the graph being traversed
1693 * using Tarjan's algorithm.
1694 * len is the number of nodes
1695 * node is an array of nodes
1696 * stack contains the nodes on the path from the root to the current node
1697 * sp is the stack pointer
1698 * index is the index of the last node visited
1699 * order contains the elements of the components separated by -1
1700 * op represents the current position in order
1701 *
1702 * check_closed is set if we may have used the fact that
1703 * a pair of basic maps can be interchanged
1704 */
1714 };
1717 {
1724 }
1727 {
1754 error:
1757 }
1759 /* Check whether in the computation of the transitive closure
1760 * "bmap1" (R_1) should follow (or be part of the same component as)
1761 * "bmap2" (R_2).
1762 *
1763 * That is check whether
1764 *
1765 * R_1 \circ R_2
1766 *
1767 * is a subset of
1768 *
1769 * R_2 \circ R_1
1770 *
1771 * If so, then there is no reason for R_1 to immediately follow R_2
1772 * in any path.
1773 *
1774 * *check_closed is set if the subset relation holds while
1775 * R_1 \circ R_2 is not empty.
1776 */
1779 {
1797 }
1803 }
1819 error:
1822 }
1824 /* Perform Tarjan's algorithm for computing the strongly connected components
1825 * in the graph with the disjuncts of "map" as vertices and with an
1826 * edge between any pair of disjuncts such that the first has
1827 * to be applied after the second.
1828 */
1831 {
1862 }
1875 }
1877 /* Decompose the "len" basic relations in "list" into strongly connected
1878 * components.
1879 */
1882 {
1894 }
1897 error:
1900 }
1902 /* Given a union of basic maps R = \cup_i R_i \subseteq D \times D
1903 * and a dimension specification (Z^{n+1} -> Z^{n+1}),
1904 * construct a map that is an overapproximation of the map
1905 * that takes an element from the dom R \times Z to an
1906 * element from ran R \times Z, such that the first n coordinates of the
1907 * difference between them is a sum of differences between images
1908 * and pre-images in one of the R_i and such that the last coordinate
1909 * is equal to the number of steps taken.
1910 * If "project" is set, then these final coordinates are not included,
1911 * i.e., a relation of type Z^n -> Z^n is returned.
1912 * That is, let
1913 *
1914 * \Delta_i = { y - x | (x, y) in R_i }
1915 *
1916 * then the constructed map is an overapproximation of
1917 *
1918 * { (x) -> (x + d) | \exists k_i >= 0, \delta_i \in \Delta_i :
1919 * d = (\sum_i k_i \delta_i, \sum_i k_i) and
1920 * x in dom R and x + d in ran R }
1921 *
1922 * or
1923 *
1924 * { (x) -> (x + d) | \exists k_i >= 0, \delta_i \in \Delta_i :
1925 * d = (\sum_i k_i \delta_i) and
1926 * x in dom R and x + d in ran R }
1927 *
1928 * if "project" is set.
1929 *
1930 * We first split the map into strongly connected components, perform
1931 * the above on each component and then join the results in the correct
1932 * order, at each join also taking in the union of both arguments
1933 * to allow for paths that do not go through one of the two arguments.
1934 */
1937 {
1962 else
1974 }
1984 }
1996 }
1997 }
2003 error:
2008 }
2010 /* Given a union of basic maps R = \cup_i R_i \subseteq D \times D,
2011 * construct a map that is an overapproximation of the map
2012 * that takes an element from the space D to another
2013 * element from the same space, such that the difference between
2014 * them is a strictly positive sum of differences between images
2015 * and pre-images in one of the R_i.
2016 * The number of differences in the sum is equated to parameter "param".
2017 * That is, let
2018 *
2019 * \Delta_i = { y - x | (x, y) in R_i }
2020 *
2021 * then the constructed map is an overapproximation of
2022 *
2023 * { (x) -> (x + d) | \exists k_i >= 0, \delta_i \in \Delta_i :
2024 * d = \sum_i k_i \delta_i and k = \sum_i k_i > 0 }
2025 * or
2026 *
2027 * { (x) -> (x + d) | \exists k_i >= 0, \delta_i \in \Delta_i :
2028 * d = \sum_i k_i \delta_i and \sum_i k_i > 0 }
2029 *
2030 * if "project" is set.
2031 *
2032 * If "project" is not set, then
2033 * we construct an extended mapping with an extra coordinate
2034 * that indicates the number of steps taken. In particular,
2035 * the difference in the last coordinate is equal to the number
2036 * of steps taken to move from a domain element to the corresponding
2037 * image element(s).
2038 */
2041 {
2061 }
2063 /* Compute the positive powers of "map", or an overapproximation.
2064 * If the result is exact, then *exact is set to 1.
2065 *
2066 * If project is set, then we are actually interested in the transitive
2067 * closure, so we can use a more relaxed exactness check.
2068 * The lengths of the paths are also projected out instead of being
2069 * encoded as the difference between an extra pair of final coordinates.
2070 */
2073 {
2090 error:
2094 }
2096 /* Compute the positive powers of "map", or an overapproximation.
2097 * The power is given by parameter "param". If the result is exact,
2098 * then *exact is set to 1.
2099 * map_power constructs an extended relation with the path lengths
2100 * encoded as the difference between the final coordinates.
2101 * In the final step, this difference is equated to the parameter "param"
2102 * and made positive. The extra coordinates are subsequently projected out.
2103 */
2106 {
2138 error:
2141 }
2143 /* Compute a relation that maps each element in the range of the input
2144 * relation to the lengths of all paths composed of edges in the input
2145 * relation that end up in the given range element.
2146 * The result may be an overapproximation, in which case *exact is set to 0.
2147 * The resulting relation is very similar to the power relation.
2148 * The difference are that the domain has been projected out, the
2149 * range has become the domain and the exponent is the range instead
2150 * of a parameter.
2151 */
2154 {
2175 }
2189 }
2191 /* Check whether equality i of bset is a pure stride constraint
2192 * on a single dimensions, i.e., of the form
2193 *
2194 * v = k e
2195 *
2196 * with k a constant and e an existentially quantified variable.
2197 */
2199 {
2237 }
2239 /* Given a map, compute the smallest superset of this map that is of the form
2240 *
2241 * { i -> j : L <= j - i <= U and exists a_p: j_p - i_p = M_p a_p }
2242 *
2243 * (where p ranges over the (non-parametric) dimensions),
2244 * compute the transitive closure of this map, i.e.,
2245 *
2246 * { i -> j : exists k > 0:
2247 * k L <= j - i <= k U and exists a: j_p - i_p = M_p a_p }
2248 *
2249 * and intersect domain and range of this transitive closure with
2250 * the given domain and range.
2251 *
2252 * If with_id is set, then try to include as much of the identity mapping
2253 * as possible, by computing
2254 *
2255 * { i -> j : exists k >= 0:
2256 * k L <= j - i <= k U and exists a: j_p - i_p = M_p a_p }
2257 *
2258 * instead (i.e., allow k = 0).
2259 *
2260 * In practice, we compute the difference set
2261 *
2262 * delta = { j - i | i -> j in map },
2263 *
2264 * look for stride constraint on the individual dimensions and compute
2265 * (constant) lower and upper bounds for each individual dimension,
2266 * adding a constraint for each bound not equal to infinity.
2267 */
2270 {
2282 isl_int opt;
2302 }
2317 }
2340 }
2355 }
2358 }
2381 error:
2391 }
2393 /* Given a map, compute the smallest superset of this map that is of the form
2394 *
2395 * { i -> j : L <= j - i <= U and exists a_p: j_p - i_p = M_p a_p }
2396 *
2397 * (where p ranges over the (non-parametric) dimensions),
2398 * compute the transitive closure of this map, i.e.,
2399 *
2400 * { i -> j : exists k > 0:
2401 * k L <= j - i <= k U and exists a: j_p - i_p = M_p a_p }
2402 *
2403 * and intersect domain and range of this transitive closure with
2404 * domain and range of the original map.
2405 */
2407 {
2417 }
2419 /* Given a map, compute the smallest superset of this map that is of the form
2420 *
2421 * { i -> j : L <= j - i <= U and exists a_p: j_p - i_p = M_p a_p }
2422 *
2423 * (where p ranges over the (non-parametric) dimensions),
2424 * compute the transitive and partially reflexive closure of this map, i.e.,
2425 *
2426 * { i -> j : exists k >= 0:
2427 * k L <= j - i <= k U and exists a: j_p - i_p = M_p a_p }
2428 *
2429 * and intersect domain and range of this transitive closure with
2430 * the given domain.
2431 */
2434 {
2436 }
2438 /* Check whether app is the transitive closure of map.
2439 * In particular, check that app is acyclic and, if so,
2440 * check that
2441 *
2442 * app \subset (map \cup (map \circ app))
2443 */
2446 {
2470 }
2472 /* Check if basic map M_i can be combined with all the other
2473 * basic maps such that
2474 *
2475 * (\cup_j M_j)^+
2476 *
2477 * can be computed as
2478 *
2479 * M_i \cup (\cup_{j \ne i} M_i^* \circ M_j \circ M_i^*)^+
2480 *
2481 * In particular, check if we can compute a compact representation
2482 * of
2483 *
2484 * M_i^* \circ M_j \circ M_i^*
2485 *
2486 * for each j != i.
2487 * Let M_i^? be an extension of M_i^+ that allows paths
2488 * of length zero, i.e., the result of box_closure(., 1).
2489 * The criterion, as proposed by Kelly et al., is that
2490 * id = M_i^? - M_i^+ can be represented as a basic map
2491 * and that
2492 *
2493 * id \circ M_j \circ id = M_j
2494 *
2495 * for each j != i.
2496 *
2497 * If this function returns 1, then tc and qc are set to
2498 * M_i^+ and M_i^?, respectively.
2499 */
2502 {
2544 }
2546 done:
2557 error:
2564 }
2568 {
2577 }
2579 /* Compute an overapproximation of the transitive closure of "map"
2580 * using a variation of the algorithm from
2581 * "Transitive Closure of Infinite Graphs and its Applications"
2582 * by Kelly et al.
2583 *
2584 * We first check whether we can can split of any basic map M_i and
2585 * compute
2586 *
2587 * (\cup_j M_j)^+
2588 *
2589 * as
2590 *
2591 * M_i \cup (\cup_{j \ne i} M_i^* \circ M_j \circ M_i^*)^+
2592 *
2593 * using a recursive call on the remaining map.
2594 *
2595 * If not, we simply call box_closure on the whole map.
2596 */
2599 {
2625 }
2637 }
2641 }
2644 error:
2647 }
2649 /* Compute the transitive closure of "map", or an overapproximation.
2650 * If the result is exact, then *exact is set to 1.
2651 * Simply use map_power to compute the powers of map, but tell
2652 * it to project out the lengths of the paths instead of equating
2653 * the length to a parameter.
2654 */
2657 {
2676 }
2683 error:
2686 }
2689 {
2697 }
2700 {
2709 }
2713 error:
2716 }
2718 /* Perform Floyd-Warshall on the given list of basic relations.
2719 * The basic relations may live in different dimensions,
2720 * but basic relations that get assigned to the diagonal of the
2721 * grid have domains and ranges of the same dimension and so
2722 * the standard algorithm can be used because the nested transitive
2723 * closures are only applied to diagonal elements and because all
2724 * compositions are peformed on relations with compatible domains and ranges.
2725 */
2728 {
2753 }
2754 }
2762 }
2772 }
2781 error:
2789 }
2795 }
2798 }
2800 /* Perform Floyd-Warshall on the given union relation.
2801 * The implementation is very similar to that for non-unions.
2802 * The main difference is that it is applied unconditionally.
2803 * We first extract a list of basic maps from the union map
2804 * and then perform the algorithm on this list.
2805 */
2808 {
2834 }
2838 error:
2843 }
2846 }
2848 /* Decompose the give union relation into strongly connected components.
2849 * The implementation is essentially the same as that of
2850 * construct_power_components with the major difference that all
2851 * operations are performed on union maps.
2852 */
2855 {
2900 }
2908 }
2917 }
2928 }
2933 error:
2939 }
2943 }
2945 /* Compute the transitive closure of "umap", or an overapproximation.
2946 * If the result is exact, then *exact is set to 1.
2947 */
2950 {
2968 error:
2971 }