| blob | 3f219016990b778f0d72d30f0e2c41a4774adee4 |
1 /*
2 * Copyright 2008-2009 Katholieke Universiteit Leuven
3 * Copyright 2010 INRIA Saclay
4 * Copyright 2012 Ecole Normale Superieure
5 *
6 * Use of this software is governed by the MIT license
7 *
8 * Written by Sven Verdoolaege, K.U.Leuven, Departement
9 * Computerwetenschappen, Celestijnenlaan 200A, B-3001 Leuven, Belgium
10 * and INRIA Saclay - Ile-de-France, Parc Club Orsay Universite,
11 * ZAC des vignes, 4 rue Jacques Monod, 91893 Orsay, France
12 * and Ecole Normale Superieure, 45 rue d'Ulm, 75230 Paris, France
13 */
15 #include <isl_ctx_private.h>
16 #include <isl_map_private.h>
17 #include <isl_seq.h>
18 #include <isl/set.h>
19 #include <isl/lp.h>
20 #include <isl/map.h>
24 #include <isl_mat_private.h>
25 #include <isl_vec_private.h>
29 {
51 error:
55 }
59 {
62 }
65 {
75 }
78 error:
81 }
83 /* Make eq[row][col] of both bmaps equal so we can add the row
84 * add the column to the common matrix.
85 * Note that because of the echelon form, the columns of row row
86 * after column col are zero.
87 */
91 {
106 }
108 /* Delete a given equality, moving all the following equalities one up.
109 */
111 {
120 }
122 /* Make first row entries in column col of bset1 identical to
123 * those of bset2, using the fact that entry bset1->eq[row][col]=a
124 * is non-zero. Initially, these elements of bset1 are all zero.
125 * For each row i < row, we set
126 * A[i] = a * A[i] + B[i][col] * A[row]
127 * B[i] = a * B[i]
128 * so that
129 * A[i][col] = B[i][col] = a * old(B[i][col])
130 */
134 {
136 isl_int a;
137 isl_int b;
152 }
156 }
158 /* Make first row entries in column col of bset1 identical to
159 * those of bset2, using only these entries of the two matrices.
160 * Let t be the last row with different entries.
161 * For each row i < t, we set
162 * A[i] = (A[t][col]-B[t][col]) * A[i] + (B[i][col]-A[i][col) * A[t]
163 * B[i] = (A[t][col]-B[t][col]) * B[i] + (B[i][col]-A[i][col) * B[t]
164 * so that
165 * A[i][col] = B[i][col] = old(A[t][col]*B[i][col]-A[i][col]*B[t][col])
166 */
170 {
192 total);
194 total);
195 }
202 }
204 /* The implementation is based on Section 5.2 of Michael Karr,
205 * "Affine Relationships Among Variables of a Program",
206 * except that the echelon form we use starts from the last column
207 * and that we are dealing with integer coefficients.
208 */
211 {
237 }
238 }
243 error:
247 }
249 /* Find an integer point in the set represented by "tab"
250 * that lies outside of the equality "eq" e(x) = 0.
251 * If "up" is true, look for a point satisfying e(x) - 1 >= 0.
252 * Otherwise, look for a point satisfying -e(x) - 1 >= 0 (i.e., e(x) <= -1).
253 * The point, if found, is returned.
254 * If no point can be found, a zero-length vector is returned.
255 *
256 * Before solving an ILP problem, we first check if simply
257 * adding the normal of the constraint to one of the known
258 * integer points in the basic set represented by "tab"
259 * yields another point inside the basic set.
260 *
261 * The caller of this function ensures that the tableau is bounded or
262 * that tab->basis and tab->n_unbounded have been set appropriately.
263 */
265 {
309 error:
312 }
315 {
331 error:
334 }
337 {
354 }
357 error:
360 }
362 /* Move "sample" to a point that is one up (or down) from the original
363 * point in dimension "pos".
364 */
366 {
369 else
371 }
373 /* Check if any points that are adjacent to "sample" also belong to "bset".
374 * If so, add them to "hull" and return the updated hull.
375 *
376 * Before checking whether and adjacent point belongs to "bset", we first
377 * check whether it already belongs to "hull" as this test is typically
378 * much cheaper.
379 */
383 {
404 }
412 }
416 }
417 }
422 error:
426 }
428 /* Extend an initial (under-)approximation of the affine hull of basic
429 * set represented by the tableau "tab"
430 * by looking for points that do not satisfy one of the equalities
431 * in the current approximation and adding them to that approximation
432 * until no such points can be found any more.
433 *
434 * The caller of this function ensures that "tab" is bounded or
435 * that tab->basis and tab->n_unbounded have been set appropriately.
436 *
437 * "bset" may be either NULL or the basic set represented by "tab".
438 * If "bset" is not NULL, we check for any point we find if any
439 * of its adjacent points also belong to "bset".
440 */
443 {
474 }
482 bset);
487 }
490 error:
493 }
495 /* Drop all constraints in bmap that involve any of the dimensions
496 * first to first+n-1.
497 */
500 {
515 }
521 }
525 }
527 /* Drop all constraints in bset that involve any of the dimensions
528 * first to first+n-1.
529 */
532 {
534 }
536 /* Drop all constraints in bmap that do not involve any of the dimensions
537 * first to first + n - 1 of the given type.
538 */
542 {
550 }
566 }
572 }
576 }
578 /* Drop all constraints in bset that do not involve any of the dimensions
579 * first to first + n - 1 of the given type.
580 */
584 {
587 }
589 /* Drop all constraints in bmap that involve any of the dimensions
590 * first to first + n - 1 of the given type.
591 */
595 {
611 }
613 /* Drop all constraints in bset that involve any of the dimensions
614 * first to first + n - 1 of the given type.
615 */
619 {
622 }
624 /* Drop all constraints in map that involve any of the dimensions
625 * first to first + n - 1 of the given type.
626 */
630 {
653 }
659 }
661 /* Drop all constraints in set that involve any of the dimensions
662 * first to first + n - 1 of the given type.
663 */
667 {
669 }
671 /* Construct an initial underapproximatino of the hull of "bset"
672 * from "sample" and any of its adjacent points that also belong to "bset".
673 */
676 {
683 }
685 /* Look for all equalities satisfied by the integer points in bset,
686 * which is assumed to be bounded.
687 *
688 * The equalities are obtained by successively looking for
689 * a point that is affinely independent of the points found so far.
690 * In particular, for each equality satisfied by the points so far,
691 * we check if there is any point on a hyperplane parallel to the
692 * corresponding hyperplane shifted by at least one (in either direction).
693 */
695 {
717 }
718 }
727 }
737 }
745 }
754 error:
759 }
761 /* Given an unbounded tableau and an integer point satisfying the tableau,
762 * construct an initial affine hull containing the recession cone
763 * shifted to the given point.
764 *
765 * The unbounded directions are taken from the last rows of the basis,
766 * which is assumed to have been initialized appropriately.
767 */
770 {
795 }
800 error:
804 }
806 /* Given a tableau of a set and a tableau of the corresponding
807 * recession cone, detect and add all equalities to the tableau.
808 * If the tableau is bounded, then we can simply keep the
809 * tableau in its state after the return from extend_affine_hull.
810 * However, if the tableau is unbounded, then
811 * isl_tab_set_initial_basis_with_cone will add some additional
812 * constraints to the tableau that have to be removed again.
813 * In this case, we therefore rollback to the state before
814 * any constraints were added and then add the equalities back in.
815 */
818 {
851 else
858 }
869 }
879 }
880 }
885 error:
889 }
891 /* Compute the affine hull of "bset", where "cone" is the recession cone
892 * of "bset".
893 *
894 * We first compute a unimodular transformation that puts the unbounded
895 * directions in the last dimensions. In particular, we take a transformation
896 * that maps all equalities to equalities (in HNF) on the first dimensions.
897 * Let x be the original dimensions and y the transformed, with y_1 bounded
898 * and y_2 unbounded.
899 *
900 * [ y_1 ] [ y_1 ] [ Q_1 ]
901 * x = U [ y_2 ] [ y_2 ] = [ Q_2 ] x
902 *
903 * Let's call the input basic set S. We compute S' = preimage(S, U)
904 * and drop the final dimensions including any constraints involving them.
905 * This results in set S''.
906 * Then we compute the affine hull A'' of S''.
907 * Let F y_1 >= g be the constraint system of A''. In the transformed
908 * space the y_2 are unbounded, so we can add them back without any constraints,
909 * resulting in
910 *
911 * [ y_1 ]
912 * [ F 0 ] [ y_2 ] >= g
913 * or
914 * [ Q_1 ]
915 * [ F 0 ] [ Q_2 ] x >= g
916 * or
917 * F Q_1 x >= g
918 *
919 * The affine hull in the original space is then obtained as
920 * A = preimage(A'', Q_1).
921 */
924 {
946 cone_dim);
965 else
973 }
978 error:
982 }
984 /* Look for all equalities satisfied by the integer points in bset,
985 * which is assumed not to have any explicit equalities.
986 *
987 * The equalities are obtained by successively looking for
988 * a point that is affinely independent of the points found so far.
989 * In particular, for each equality satisfied by the points so far,
990 * we check if there is any point on a hyperplane parallel to the
991 * corresponding hyperplane shifted by at least one (in either direction).
992 *
993 * Before looking for any outside points, we first compute the recession
994 * cone. The directions of this recession cone will always be part
995 * of the affine hull, so there is no need for looking for any points
996 * in these directions.
997 * In particular, if the recession cone is full-dimensional, then
998 * the affine hull is simply the whole universe.
999 */
1001 {
1016 }
1023 error:
1026 }
1028 /* Look for all equalities satisfied by the integer points in bmap
1029 * that are independent of the equalities already explicitly available
1030 * in bmap.
1031 *
1032 * We first remove all equalities already explicitly available,
1033 * then look for additional equalities in the reduced space
1034 * and then transform the result to the original space.
1035 * The original equalities are _not_ added to this set. This is
1036 * the responsibility of the calling function.
1037 * The resulting basic set has all meaning about the dimensions removed.
1038 * In particular, dimensions that correspond to existential variables
1039 * in bmap and that are found to be fixed are not removed.
1040 */
1043 {
1068 else
1076 }
1079 error:
1085 }
1087 /* Detect and make explicit all equalities satisfied by the (integer)
1088 * points in bmap.
1089 */
1092 {
1113 }
1122 }
1129 error:
1133 }
1137 {
1140 }
1143 {
1146 }
1149 {
1151 }
1153 /* Return the superset of "bmap" described by the equalities
1154 * satisfied by "bmap" that are already known.
1155 */
1158 {
1164 }
1166 /* Return the superset of "bset" described by the equalities
1167 * satisfied by "bset" that are already known.
1168 */
1171 {
1173 }
1175 /* After computing the rational affine hull (by detecting the implicit
1176 * equalities), we compute the additional equalities satisfied by
1177 * the integer points (if any) and add the original equalities back in.
1178 */
1180 {
1184 }
1187 {
1190 }
1192 /* Given a rational affine matrix "M", add stride constraints to "bmap"
1193 * that ensure that
1194 *
1195 * M(x)
1196 *
1197 * is an integer vector. The variables x include all the variables
1198 * of "bmap" except the unknown divs.
1199 *
1200 * If d is the common denominator of M, then we need to impose that
1201 *
1202 * d M(x) = 0 mod d
1203 *
1204 * or
1205 *
1206 * exists alpha : d M(x) = d alpha
1207 *
1208 * This function is similar to add_strides in isl_morph.c
1209 */
1212 {
1214 isl_int gcd;
1238 }
1242 error:
1246 }
1248 /* If there are any equalities that involve (multiple) unknown divs,
1249 * then extract the stride information encoded by those equalities
1250 * and make it explicitly available in "bmap".
1251 *
1252 * We first sort the divs so that the unknown divs appear last and
1253 * then we count how many equalities involve these divs.
1254 *
1255 * Let these equalities be of the form
1256 *
1257 * A(x) + B y = 0
1258 *
1259 * where y represents the unknown divs and x the remaining variables.
1260 * Let [H 0] be the Hermite Normal Form of B, i.e.,
1261 *
1262 * B = [H 0] Q
1263 *
1264 * Then x is a solution of the equalities iff
1265 *
1266 * H^-1 A(x) (= - [I 0] Q y)
1267 *
1268 * is an integer vector. Let d be the common denominator of H^-1.
1269 * We impose
1270 *
1271 * d H^-1 A(x) = d alpha
1272 *
1273 * in add_strides, with alpha fresh existentially quantified variables.
1274 */
1277 {
1323 }
1325 /* Compute the affine hull of each basic map in "map" separately
1326 * and make all stride information explicit so that we can remove
1327 * all unknown divs without losing this information.
1328 * The result is also guaranteed to be gaussed.
1329 *
1330 * In simple cases where a div is determined by an equality,
1331 * calling isl_basic_map_gauss is enough to make the stride information
1332 * explicit, as it will derive an explicit representation for the div
1333 * from the equality. If, however, the stride information
1334 * is encoded through multiple unknown divs then we need to make
1335 * some extra effort in isl_basic_map_make_strides_explicit.
1336 */
1338 {
1351 }
1354 }
1357 {
1359 }
1361 /* Return an empty basic map living in the same space as "map".
1362 */
1365 {
1371 }
1373 /* Compute the affine hull of "map".
1374 *
1375 * We first compute the affine hull of each basic map separately.
1376 * Then we align the divs and recompute the affine hulls of the basic
1377 * maps since some of them may now have extra divs.
1378 * In order to avoid performing parametric integer programming to
1379 * compute explicit expressions for the divs, possible leading to
1380 * an explosion in the number of basic maps, we first drop all unknown
1381 * divs before aligning the divs. Note that isl_map_local_affine_hull tries
1382 * to make sure that all stride information is explicitly available
1383 * in terms of known divs. This involves calling isl_basic_set_gauss,
1384 * which is also needed because affine_hull assumes its input has been gaussed,
1385 * while isl_map_affine_hull may be called on input that has not been gaussed,
1386 * in particular from initial_facet_constraint.
1387 * Similarly, align_divs may reorder some divs so that we need to
1388 * gauss the result again.
1389 * Finally, we combine the individual affine hulls into a single
1390 * affine hull.
1391 */
1393 {
1426 error:
1430 }
1433 {
1436 }