| blob | bedee1b56d155e94ff3ae4a2cb594799e9adb8a5 |
1 /*
2 * Copyright 2008-2009 Katholieke Universiteit Leuven
3 * Copyright 2014 INRIA Rocquencourt
4 *
5 * Use of this software is governed by the MIT license
6 *
7 * Written by Sven Verdoolaege, K.U.Leuven, Departement
8 * Computerwetenschappen, Celestijnenlaan 200A, B-3001 Leuven, Belgium
9 * and Inria Paris - Rocquencourt, Domaine de Voluceau - Rocquencourt,
10 * B.P. 105 - 78153 Le Chesnay, France
11 */
13 #include <isl_ctx_private.h>
14 #include <isl_map_private.h>
15 #include <isl_lp_private.h>
16 #include <isl/map.h>
17 #include <isl_mat_private.h>
18 #include <isl_vec_private.h>
19 #include <isl/set.h>
20 #include <isl_seq.h>
21 #include <isl_options_private.h>
24 #include <isl_sort.h>
26 #include <bset_to_bmap.c>
27 #include <bset_from_bmap.c>
28 #include <set_to_map.c>
33 /* Remove redundant
34 * constraints. If the minimal value along the normal of a constraint
35 * is the same if the constraint is removed, then the constraint is redundant.
36 *
37 * Since some constraints may be mutually redundant, sort the constraints
38 * first such that constraints that involve existentially quantified
39 * variables are considered for removal before those that do not.
40 * The sorting is also needed for the use in map_simple_hull.
41 *
42 * Note that isl_tab_detect_implicit_equalities may also end up
43 * marking some constraints as redundant. Make sure the constraints
44 * are preserved and undo those marking such that isl_tab_detect_redundant
45 * can consider the constraints in the sorted order.
46 *
47 * Alternatively, we could have intersected the basic map with the
48 * corresponding equality and then checked if the dimension was that
49 * of a facet.
50 */
53 {
86 error:
90 }
94 {
97 }
99 /* Remove redundant constraints in each of the basic maps.
100 */
102 {
105 }
108 {
110 }
112 /* Check if the set set is bound in the direction of the affine
113 * constraint c and if so, set the constant term such that the
114 * resulting constraint is a bounding constraint for the set.
115 */
117 {
120 isl_int opt;
121 isl_int opt_denom;
143 }
148 }
150 }
154 error:
158 }
162 {
182 error:
185 }
189 {
199 }
201 error:
204 }
206 /* Given a union of basic sets, construct the constraints for wrapping
207 * a facet around one of its ridges.
208 * In particular, if each of n the d-dimensional basic sets i in "set"
209 * contains the origin, satisfies the constraints x_1 >= 0 and x_2 >= 0
210 * and is defined by the constraints
211 * [ 1 ]
212 * A_i [ x ] >= 0
213 *
214 * then the resulting set is of dimension n*(1+d) and has as constraints
215 *
216 * [ a_i ]
217 * A_i [ x_i ] >= 0
218 *
219 * a_i >= 0
220 *
221 * \sum_i x_{i,1} = 1
222 */
224 {
240 }
252 }
263 }
270 }
271 }
273 }
275 /* Given a facet "facet" of the convex hull of "set" and a facet "ridge"
276 * of that facet, compute the other facet of the convex hull that contains
277 * the ridge.
278 *
279 * We first transform the set such that the facet constraint becomes
280 *
281 * x_1 >= 0
282 *
283 * I.e., the facet lies in
284 *
285 * x_1 = 0
286 *
287 * and on that facet, the constraint that defines the ridge is
288 *
289 * x_2 >= 0
290 *
291 * (This transformation is not strictly needed, all that is needed is
292 * that the ridge contains the origin.)
293 *
294 * Since the ridge contains the origin, the cone of the convex hull
295 * will be of the form
296 *
297 * x_1 >= 0
298 * x_2 >= a x_1
299 *
300 * with this second constraint defining the new facet.
301 * The constant a is obtained by settting x_1 in the cone of the
302 * convex hull to 1 and minimizing x_2.
303 * Now, each element in the cone of the convex hull is the sum
304 * of elements in the cones of the basic sets.
305 * If a_i is the dilation factor of basic set i, then the problem
306 * we need to solve is
307 *
308 * min \sum_i x_{i,2}
309 * st
310 * \sum_i x_{i,1} = 1
311 * a_i >= 0
312 * [ a_i ]
313 * A [ x_i ] >= 0
314 *
315 * with
316 * [ 1 ]
317 * A_i [ x_i ] >= 0
318 *
319 * the constraints of each (transformed) basic set.
320 * If a = n/d, then the constraint defining the new facet (in the transformed
321 * space) is
322 *
323 * -n x_1 + d x_2 >= 0
324 *
325 * In the original space, we need to take the same combination of the
326 * corresponding constraints "facet" and "ridge".
327 *
328 * If a = -infty = "-1/0", then we just return the original facet constraint.
329 * This means that the facet is unbounded, but has a bounded intersection
330 * with the union of sets.
331 */
334 {
372 }
381 }
392 error:
397 }
399 /* Compute the constraint of a facet of "set".
400 *
401 * We first compute the intersection with a bounding constraint
402 * that is orthogonal to one of the coordinate axes.
403 * If the affine hull of this intersection has only one equality,
404 * we have found a facet.
405 * Otherwise, we wrap the current bounding constraint around
406 * one of the equalities of the face (one that is not equal to
407 * the current bounding constraint).
408 * This process continues until we have found a facet.
409 * The dimension of the intersection increases by at least
410 * one on each iteration, so termination is guaranteed.
411 */
413 {
444 }
455 }
458 error:
462 }
464 /* Given the bounding constraint "c" of a facet of the convex hull of "set",
465 * compute a hyperplane description of the facet, i.e., compute the facets
466 * of the facet.
467 *
468 * We compute an affine transformation that transforms the constraint
469 *
470 * [ 1 ]
471 * c [ x ] = 0
472 *
473 * to the constraint
474 *
475 * z_1 = 0
476 *
477 * by computing the right inverse U of a matrix that starts with the rows
478 *
479 * [ 1 0 ]
480 * [ c ]
481 *
482 * Then
483 * [ 1 ] [ 1 ]
484 * [ x ] = U [ z ]
485 * and
486 * [ 1 ] [ 1 ]
487 * [ z ] = Q [ x ]
488 *
489 * with Q = U^{-1}
490 * Since z_1 is zero, we can drop this variable as well as the corresponding
491 * column of U to obtain
492 *
493 * [ 1 ] [ 1 ]
494 * [ x ] = U' [ z' ]
495 * and
496 * [ 1 ] [ 1 ]
497 * [ z' ] = Q' [ x ]
498 *
499 * with Q' equal to Q, but without the corresponding row.
500 * After computing the facets of the facet in the z' space,
501 * we convert them back to the x space through Q.
502 */
505 {
531 error:
535 }
537 /* Given an initial facet constraint, compute the remaining facets.
538 * We do this by running through all facets found so far and computing
539 * the adjacent facets through wrapping, adding those facets that we
540 * hadn't already found before.
541 *
542 * For each facet we have found so far, we first compute its facets
543 * in the resulting convex hull. That is, we compute the ridges
544 * of the resulting convex hull contained in the facet.
545 * We also compute the corresponding facet in the current approximation
546 * of the convex hull. There is no need to wrap around the ridges
547 * in this facet since that would result in a facet that is already
548 * present in the current approximation.
549 *
550 * This function can still be significantly optimized by checking which of
551 * the facets of the basic sets are also facets of the convex hull and
552 * using all the facets so far to help in constructing the facets of the
553 * facets
554 * and/or
555 * using the technique in section "3.1 Ridge Generation" of
556 * "Extended Convex Hull" by Fukuda et al.
557 */
560 {
603 }
606 }
610 error:
615 }
617 /* Special case for computing the convex hull of a one dimensional set.
618 * We simply collect the lower and upper bounds of each basic set
619 * and the biggest of those.
620 */
622 {
634 }
653 }
662 }
663 }
664 }
683 }
691 }
692 }
703 }
709 }
710 }
715 }
726 }
730 }
735 error:
739 }
742 {
750 else
754 }
756 /* Compute the convex hull of a pair of basic sets without any parameters or
757 * integer divisions using Fourier-Motzkin elimination.
758 * The convex hull is the set of all points that can be written as
759 * the sum of points from both basic sets (in homogeneous coordinates).
760 * We set up the constraints in a space with dimensions for each of
761 * the three sets and then project out the dimensions corresponding
762 * to the two original basic sets, retaining only those corresponding
763 * to the convex hull.
764 */
767 {
791 }
800 }
806 }
815 }
822 error:
827 }
829 /* Is the set bounded for each value of the parameters?
830 */
832 {
834 isl_bool bounded;
845 }
847 /* Is the image bounded for each value of the parameters and
848 * the domain variables?
849 */
851 {
854 isl_bool bounded;
864 }
866 /* Is the set bounded for each value of the parameters?
867 */
869 {
879 }
881 }
883 /* Compute the lineality space of the convex hull of bset1 and bset2.
884 *
885 * We first compute the intersection of the recession cone of bset1
886 * with the negative of the recession cone of bset2 and then compute
887 * the linear hull of the resulting cone.
888 */
891 {
912 }
919 }
926 }
933 }
938 error:
943 }
947 /* Given a set and a linear space "lin" of dimension n > 0,
948 * project the linear space from the set, compute the convex hull
949 * and then map the set back to the original space.
950 *
951 * Let
952 *
953 * M x = 0
954 *
955 * describe the linear space. We first compute the Hermite normal
956 * form H = M U of M = H Q, to obtain
957 *
958 * H Q x = 0
959 *
960 * The last n rows of H will be zero, so the last n variables of x' = Q x
961 * are the one we want to project out. We do this by transforming each
962 * basic set A x >= b to A U x' >= b and then removing the last n dimensions.
963 * After computing the convex hull in x'_1, i.e., A' x'_1 >= b',
964 * we transform the hull back to the original space as A' Q_1 x >= b',
965 * with Q_1 all but the last n rows of Q.
966 */
969 {
996 error:
1000 }
1002 /* Given two polyhedra with as constraints h_{ij} x >= 0 in homegeneous space,
1003 * set up an LP for solving
1004 *
1005 * \sum_j \alpha_{1j} h_{1j} = \sum_j \alpha_{2j} h_{2j}
1006 *
1007 * \alpha{i0} corresponds to the (implicit) positivity constraint 1 >= 0
1008 * The next \alpha{ij} correspond to the equalities and come in pairs.
1009 * The final \alpha{ij} correspond to the inequalities.
1010 */
1013 {
1036 }
1043 /* positivity constraint 1 >= 0 */
1048 }
1051 }
1052 /* positivity constraint 1 >= 0 */
1057 }
1060 }
1061 }
1066 error:
1070 }
1072 /* Compute a vector s in the homogeneous space such that <s, r> > 0
1073 * for all rays in the homogeneous space of the two cones that correspond
1074 * to the input polyhedra bset1 and bset2.
1075 *
1076 * We compute s as a vector that satisfies
1077 *
1078 * s = \sum_j \alpha_{ij} h_{ij} for i = 1,2 (*)
1079 *
1080 * with h_{ij} the normals of the facets of polyhedron i
1081 * (including the "positivity constraint" 1 >= 0) and \alpha_{ij}
1082 * strictly positive numbers. For simplicity we impose \alpha_{ij} >= 1.
1083 * We first set up an LP with as variables the \alpha{ij}.
1084 * In this formulation, for each polyhedron i,
1085 * the first constraint is the positivity constraint, followed by pairs
1086 * of variables for the equalities, followed by variables for the inequalities.
1087 * We then simply pick a feasible solution and compute s using (*).
1088 *
1089 * Note that we simply pick any valid direction and make no attempt
1090 * to pick a "good" or even the "best" valid direction.
1091 */
1094 {
1119 /* positivity constraint 1 >= 0 */
1129 }
1139 error:
1144 }
1146 /* Given a polyhedron b_i + A_i x >= 0 and a map T = S^{-1},
1147 * compute b_i' + A_i' x' >= 0, with
1148 *
1149 * [ b_i A_i ] [ y' ] [ y' ]
1150 * [ 1 0 ] S^{-1} [ x' ] >= 0 or [ b_i' A_i' ] [ x' ] >= 0
1151 *
1152 * In particular, add the "positivity constraint" and then perform
1153 * the mapping.
1154 */
1157 {
1170 error:
1174 }
1176 /* Compute the convex hull of a pair of basic sets without any parameters or
1177 * integer divisions, where the convex hull is known to be pointed,
1178 * but the basic sets may be unbounded.
1179 *
1180 * We turn this problem into the computation of a convex hull of a pair
1181 * _bounded_ polyhedra by "changing the direction of the homogeneous
1182 * dimension". This idea is due to Matthias Koeppe.
1183 *
1184 * Consider the cones in homogeneous space that correspond to the
1185 * input polyhedra. The rays of these cones are also rays of the
1186 * polyhedra if the coordinate that corresponds to the homogeneous
1187 * dimension is zero. That is, if the inner product of the rays
1188 * with the homogeneous direction is zero.
1189 * The cones in the homogeneous space can also be considered to
1190 * correspond to other pairs of polyhedra by chosing a different
1191 * homogeneous direction. To ensure that both of these polyhedra
1192 * are bounded, we need to make sure that all rays of the cones
1193 * correspond to vertices and not to rays.
1194 * Let s be a direction such that <s, r> > 0 for all rays r of both cones.
1195 * Then using s as a homogeneous direction, we obtain a pair of polytopes.
1196 * The vector s is computed in valid_direction.
1197 *
1198 * Note that we need to consider _all_ rays of the cones and not just
1199 * the rays that correspond to rays in the polyhedra. If we were to
1200 * only consider those rays and turn them into vertices, then we
1201 * may inadvertently turn some vertices into rays.
1202 *
1203 * The standard homogeneous direction is the unit vector in the 0th coordinate.
1204 * We therefore transform the two polyhedra such that the selected
1205 * direction is mapped onto this standard direction and then proceed
1206 * with the normal computation.
1207 * Let S be a non-singular square matrix with s as its first row,
1208 * then we want to map the polyhedra to the space
1209 *
1210 * [ y' ] [ y ] [ y ] [ y' ]
1211 * [ x' ] = S [ x ] i.e., [ x ] = S^{-1} [ x' ]
1212 *
1213 * We take S to be the unimodular completion of s to limit the growth
1214 * of the coefficients in the following computations.
1215 *
1216 * Let b_i + A_i x >= 0 be the constraints of polyhedron i.
1217 * We first move to the homogeneous dimension
1218 *
1219 * b_i y + A_i x >= 0 [ b_i A_i ] [ y ] [ 0 ]
1220 * y >= 0 or [ 1 0 ] [ x ] >= [ 0 ]
1221 *
1222 * Then we change directoin
1223 *
1224 * [ b_i A_i ] [ y' ] [ y' ]
1225 * [ 1 0 ] S^{-1} [ x' ] >= 0 or [ b_i' A_i' ] [ x' ] >= 0
1226 *
1227 * Then we compute the convex hull of the polytopes b_i' + A_i' x' >= 0
1228 * resulting in b' + A' x' >= 0, which we then convert back
1229 *
1230 * [ y ] [ y ]
1231 * [ b' A' ] S [ x ] >= 0 or [ b A ] [ x ] >= 0
1232 *
1233 * The polyhedron b + A x >= 0 is then the convex hull of the input polyhedra.
1234 */
1237 {
1270 error:
1275 }
1281 /* Compute the convex hull of a pair of basic sets without any parameters or
1282 * integer divisions.
1283 *
1284 * This function is called from uset_convex_hull_unbounded, which
1285 * means that the complete convex hull is unbounded. Some pairs
1286 * of basic sets may still be bounded, though.
1287 * They may even lie inside a lower dimensional space, in which
1288 * case they need to be handled inside their affine hull since
1289 * the main algorithm assumes that the result is full-dimensional.
1290 *
1291 * If the convex hull of the two basic sets would have a non-trivial
1292 * lineality space, we first project out this lineality space.
1293 */
1296 {
1331 }
1338 }
1342 error:
1346 }
1348 /* Compute the lineality space of a basic set.
1349 * We basically just drop the constants and turn every inequality
1350 * into an equality.
1351 * Any explicit representations of local variables are removed
1352 * because they may no longer be valid representations
1353 * in the lineality space.
1354 */
1357 {
1380 }
1393 }
1396 error:
1400 }
1402 /* Compute the (linear) hull of the lineality spaces of the basic sets in the
1403 * set "set".
1404 */
1407 {
1417 }
1425 }
1427 /* Compute the convex hull of a set without any parameters or
1428 * integer divisions.
1429 * In each step, we combined two basic sets until only one
1430 * basic set is left.
1431 * The input basic sets are assumed not to have a non-trivial
1432 * lineality space. If any of the intermediate results has
1433 * a non-trivial lineality space, it is projected out.
1434 */
1437 {
1451 isl_error_internal,
1459 }
1471 }
1475 }
1477 }
1480 error:
1483 }
1485 /* Compute an initial hull for wrapping containing a single initial
1486 * facet.
1487 * This function assumes that the given set is bounded.
1488 */
1491 {
1510 error:
1514 }
1520 };
1523 {
1528 }
1532 {
1546 }
1554 }
1558 }
1560 /* Check whether the constraint hash table "table" constains the constraint
1561 * "con".
1562 */
1565 {
1579 }
1581 /* Check for inequality constraints of a basic set without equalities
1582 * such that the same or more stringent copies of the constraint appear
1583 * in all of the basic sets. Such constraints are necessarily facet
1584 * constraints of the convex hull.
1585 *
1586 * If the resulting basic set is by chance identical to one of
1587 * the basic sets in "set", then we know that this basic set contains
1588 * all other basic sets and is therefore the convex hull of set.
1589 * In this case we set *is_hull to 1.
1590 */
1593 {
1617 }
1619 min_constraints);
1633 }
1644 }
1657 }
1658 }
1663 }
1665 }
1676 }
1687 }
1690 }
1698 error:
1706 }
1708 /* Create a template for the convex hull of "set" and fill it up
1709 * obvious facet constraints, if any. If the result happens to
1710 * be the convex hull of "set" then *is_hull is set to 1.
1711 */
1714 {
1723 }
1729 }
1732 {
1741 }
1745 }
1747 /* Compute the convex hull of a set without any parameters or
1748 * integer divisions. Depending on whether the set is bounded,
1749 * we pass control to the wrapping based convex hull or
1750 * the Fourier-Motzkin elimination based convex hull.
1751 * We also handle a few special cases before checking the boundedness.
1752 */
1754 {
1755 isl_bool bounded;
1771 }
1787 }
1793 error:
1797 }
1799 /* This is the core procedure, where "set" is a "pure" set, i.e.,
1800 * without parameters or divs and where the convex hull of set is
1801 * known to be full-dimensional.
1802 */
1805 {
1816 }
1827 }
1832 error:
1835 }
1837 /* Compute the convex hull of set "set" with affine hull "affine_hull",
1838 * We first remove the equalities (transforming the set), compute the
1839 * convex hull of the transformed set and then add the equalities back
1840 * (after performing the inverse transformation.
1841 */
1844 {
1860 error:
1866 }
1868 /* Return an empty basic map living in the same space as "map".
1869 */
1872 {
1878 }
1880 /* Compute the convex hull of a map.
1881 *
1882 * The implementation was inspired by "Extended Convex Hull" by Fukuda et al.,
1883 * specifically, the wrapping of facets to obtain new facets.
1884 */
1886 {
1914 }
1924 error:
1928 }
1931 {
1933 }
1936 {
1941 }
1944 {
1946 }
1951 };
1953 /* Holds the data needed during the simple hull computation.
1954 * In particular,
1955 * n the number of basic sets in the original set
1956 * hull_table a hash table of already computed constraints
1957 * in the simple hull
1958 * p for each basic set,
1959 * table a hash table of the constraints
1960 * tab the tableau corresponding to the basic set
1961 */
1967 };
1970 {
1979 }
1981 }
1986 };
1989 {
1995 }
1999 {
2012 }
2014 /* Fill hash table "table" with the constraints of "bset".
2015 * Equalities are added as two inequalities.
2016 * The value in the hash table is a pointer to the (in)equality of "bset".
2017 */
2020 {
2029 }
2030 }
2034 }
2036 }
2039 {
2060 }
2062 error:
2065 }
2067 /* Check if inequality "ineq" is a bound for basic set "j" or if
2068 * it can be relaxed (by increasing the constant term) to become
2069 * a bound for that basic set. In the latter case, the constant
2070 * term is updated.
2071 * Relaxation of the constant term is only allowed if "shift" is set.
2072 *
2073 * Return 1 if "ineq" is a bound
2074 * 0 if "ineq" may attain arbitrarily small values on basic set "j"
2075 * -1 if some error occurred
2076 */
2079 {
2081 isl_int opt;
2087 }
2096 else
2098 }
2104 }
2106 /* Set the constant term of "ineq" to the maximum of those of the constraints
2107 * in the basic sets of "set" following "i" that are parallel to "ineq".
2108 * That is, if any of the basic sets of "set" following "i" have a more
2109 * relaxed copy of "ineq", then replace "ineq" by the most relaxed copy.
2110 * "c_hash" is the hash value of the linear part of "ineq".
2111 * "v" has been set up for use by has_ineq.
2112 *
2113 * Note that the two inequality constraints corresponding to an equality are
2114 * represented by the same inequality constraint in data->p[j].table
2115 * (but with different hash values). This means the constraint (or at
2116 * least its constant term) may need to be temporarily negated to get
2117 * the actually hashed constraint.
2118 */
2121 {
2144 }
2145 }
2147 /* Check if inequality "ineq" from basic set "i" is or can be relaxed to
2148 * become a bound on the whole set. If so, add the (relaxed) inequality
2149 * to "hull". Relaxation is only allowed if "shift" is set.
2150 *
2151 * We first check if "hull" already contains a translate of the inequality.
2152 * If so, we are done.
2153 * Then, we check if any of the previous basic sets contains a translate
2154 * of the inequality. If so, then we have already considered this
2155 * inequality and we are done.
2156 * Otherwise, for each basic set other than "i", we check if the inequality
2157 * is a bound on the basic set, but first replace the constant term
2158 * by the maximal value of any translate of the inequality in any
2159 * of the following basic sets.
2160 * For previous basic sets, we know that they do not contain a translate
2161 * of the inequality, so we directly call is_bound.
2162 * For following basic sets, we first check if a translate of the
2163 * inequality appears in its description. If so, the constant term
2164 * of the inequality has already been updated with respect to this
2165 * translate and the inequality is therefore known to be a bound
2166 * of this basic set.
2167 */
2171 {
2194 }
2211 }
2215 }
2228 }
2232 }
2241 error:
2244 }
2246 /* Check if any inequality from basic set "i" is or can be relaxed to
2247 * become a bound on the whole set. If so, add the (relaxed) inequality
2248 * to "hull". Relaxation is only allowed if "shift" is set.
2249 */
2252 {
2260 shift);
2261 }
2262 }
2266 }
2268 /* Compute a superset of the convex hull of set that is described
2269 * by only (translates of) the constraints in the constituents of set.
2270 * Translation is only allowed if "shift" is set.
2271 */
2274 {
2288 }
2305 error:
2310 }
2312 /* Compute a superset of the convex hull of map that is described
2313 * by only (translates of) the constraints in the constituents of map.
2314 * Handle trivial cases where map is NULL or contains at most one disjunct.
2315 */
2318 {
2329 }
2331 /* Return a copy of the simple hull cached inside "map".
2332 * "shift" determines whether to return the cached unshifted or shifted
2333 * simple hull.
2334 */
2337 {
2344 }
2346 /* Compute a superset of the convex hull of map that is described
2347 * by only (translates of) the constraints in the constituents of map.
2348 * Translation is only allowed if "shift" is set.
2349 *
2350 * The constraints are sorted while removing redundant constraints
2351 * in order to indicate a preference of which constraints should
2352 * be preserved. In particular, pairs of constraints that are
2353 * sorted together are preferred to either both be preserved
2354 * or both be removed. The sorting is performed inside
2355 * isl_basic_map_remove_redundancies.
2356 *
2357 * The result of the computation is stored in map->cached_simple_hull[shift]
2358 * such that it can be reused in subsequent calls. The cache is cleared
2359 * whenever the map is modified (in isl_map_cow).
2360 * Note that the results need to be stored in the input map for there
2361 * to be any chance that they may get reused. In particular, they
2362 * are stored in a copy of the input map that is saved before
2363 * the integer division alignment.
2364 */
2367 {
2401 }
2409 }
2411 /* Compute a superset of the convex hull of map that is described
2412 * by only translates of the constraints in the constituents of map.
2413 */
2415 {
2417 }
2420 {
2422 }
2424 /* Compute a superset of the convex hull of map that is described
2425 * by only the constraints in the constituents of map.
2426 */
2429 {
2431 }
2435 {
2437 }
2439 /* Drop all inequalities from "bmap1" that do not also appear in "bmap2".
2440 * A constraint that appears with different constant terms
2441 * in "bmap1" and "bmap2" is also kept, with the least restrictive
2442 * (i.e., greatest) constant term.
2443 * "bmap1" and "bmap2" are assumed to have the same (known)
2444 * integer divisions.
2445 * The constraints of both "bmap1" and "bmap2" are assumed
2446 * to have been sorted using isl_basic_map_sort_constraints.
2447 *
2448 * Run through the inequality constraints of "bmap1" and "bmap2"
2449 * in sorted order.
2450 * Each constraint of "bmap1" without a matching constraint in "bmap2"
2451 * is removed.
2452 * If a match is found, the constraint is kept. If needed, the constant
2453 * term of the constraint is adjusted.
2454 */
2457 {
2474 }
2480 }
2485 }
2491 }
2493 /* Drop all equalities from "bmap1" that do not also appear in "bmap2".
2494 * "bmap1" and "bmap2" are assumed to have the same (known)
2495 * integer divisions.
2496 *
2497 * Run through the equality constraints of "bmap1" and "bmap2".
2498 * Each constraint of "bmap1" without a matching constraint in "bmap2"
2499 * is removed.
2500 */
2503 {
2523 }
2529 }
2533 }
2536 }
2542 }
2544 /* Compute a superset of "bmap1" and "bmap2" that is described
2545 * by only the constraints that appear in both "bmap1" and "bmap2".
2546 *
2547 * First drop constraints that involve unknown integer divisions
2548 * since it is not trivial to check whether two such integer divisions
2549 * in different basic maps are the same.
2550 * Then align the remaining (known) divs and sort the constraints.
2551 * Finally drop all inequalities and equalities from "bmap1" that
2552 * do not also appear in "bmap2".
2553 */
2556 {
2572 }
2574 /* Compute a superset of the convex hull of "map" that is described
2575 * by only the constraints in the constituents of "map".
2576 * In particular, the result is composed of constraints that appear
2577 * in each of the basic maps of "map"
2578 *
2579 * Constraints that involve unknown integer divisions are dropped
2580 * since it is not trivial to check whether two such integer divisions
2581 * in different basic maps are the same.
2582 *
2583 * The hull is initialized from the first basic map and then
2584 * updated with respect to the other basic maps in turn.
2585 */
2588 {
2603 }
2607 }
2609 /* Compute a superset of the convex hull of "set" that is described
2610 * by only the constraints in the constituents of "set".
2611 * In particular, the result is composed of constraints that appear
2612 * in each of the basic sets of "set"
2613 */
2616 {
2618 }
2620 /* Check if "ineq" is a bound on "set" and, if so, add it to "hull".
2621 *
2622 * For each basic set in "set", we first check if the basic set
2623 * contains a translate of "ineq". If this translate is more relaxed,
2624 * then we assume that "ineq" is not a bound on this basic set.
2625 * Otherwise, we know that it is a bound.
2626 * If the basic set does not contain a translate of "ineq", then
2627 * we call is_bound to perform the test.
2628 */
2632 {
2664 else
2666 }
2672 }
2682 }
2684 /* Compute a superset of the convex hull of "set" that is described
2685 * by only some of the "n_ineq" constraints in the list "ineq", where "set"
2686 * has no parameters or integer divisions.
2687 *
2688 * The inequalities in "ineq" are assumed to have been sorted such
2689 * that constraints with the same linear part appear together and
2690 * that among constraints with the same linear part, those with
2691 * smaller constant term appear first.
2692 *
2693 * We reuse the same data structure that is used by uset_simple_hull,
2694 * but we do not need the hull table since we will not consider the
2695 * same constraint more than once. We therefore allocate it with zero size.
2696 *
2697 * We run through the constraints and try to add them one by one,
2698 * skipping identical constraints. If we have added a constraint and
2699 * the next constraint is a more relaxed translate, then we skip this
2700 * next constraint as well.
2701 */
2704 {
2725 dim);
2733 }
2738 error:
2743 }
2745 /* Collect pointers to all the inequalities in the elements of "list"
2746 * in "ineq". For equalities, store both a pointer to the equality and
2747 * a pointer to its opposite, which is first copied to "mat".
2748 * "ineq" and "mat" are assumed to have been preallocated to the right size
2749 * (the number of inequalities + 2 times the number of equalites and
2750 * the number of equalities, respectively).
2751 */
2754 {
2772 }
2776 }
2779 }
2781 /* Comparison routine for use as an isl_sort callback.
2782 *
2783 * Constraints with the same linear part are sorted together and
2784 * among constraints with the same linear part, those with smaller
2785 * constant term are sorted first.
2786 */
2788 {
2798 }
2800 /* Compute a superset of the convex hull of "set" that is described
2801 * by only constraints in the elements of "list", where "set" has
2802 * no parameters or integer divisions.
2803 *
2804 * We collect all the constraints in those elements and then
2805 * sort the constraints such that constraints with the same linear part
2806 * are sorted together and that those with smaller constant term are
2807 * sorted first.
2808 */
2811 {
2834 }
2855 error:
2861 }
2863 /* Compute a superset of the convex hull of "map" that is described
2864 * by only constraints in the elements of "list".
2865 *
2866 * If the list is empty, then we can only describe the universe set.
2867 * If the input map is empty, then all constraints are valid, so
2868 * we return the intersection of the elements in "list".
2869 *
2870 * Otherwise, we align all divs and temporarily treat them
2871 * as regular variables, computing the unshifted simple hull in
2872 * uset_unshifted_simple_hull_from_basic_set_list.
2873 */
2876 {
2892 }
2896 }
2912 error:
2916 }
2918 /* Return a sequence of the basic maps that make up the maps in "list".
2919 */
2922 {
2942 }
2946 }
2948 /* Compute a superset of the convex hull of "map" that is described
2949 * by only constraints in the elements of "list".
2950 *
2951 * If "map" is the universe, then the convex hull (and therefore
2952 * any superset of the convexhull) is the universe as well.
2953 *
2954 * Otherwise, we collect all the basic maps in the map list and
2955 * continue with map_unshifted_simple_hull_from_basic_map_list.
2956 */
2959 {
2969 }
2973 }
2975 /* Compute a superset of the convex hull of "set" that is described
2976 * by only constraints in the elements of "list".
2977 */
2980 {
2982 }
2984 /* Given a set "set", return parametric bounds on the dimension "dim".
2985 */
2987 {
2993 }
2995 /* Computes a "simple hull" and then check if each dimension in the
2996 * resulting hull is bounded by a symbolic constant. If not, the
2997 * hull is intersected with the corresponding bounds on the whole set.
2998 */
3000 {
3022 }
3036 else
3040 }
3050 }
3055 }
3059 error:
3063 }