| blob | 35fc95e7b1fbaf7b2040c82c831757da1b34ea1c |
12 {
18 }
20 /* Construct a zero sample of the same dimension as bset.
21 * As a special case, if bset is zero-dimensional, this
22 * function creates a zero-dimensional sample point.
23 */
25 {
34 }
37 }
40 {
42 isl_int t;
65 }
68 }
73 else
80 }
85 }
89 error:
93 }
96 {
121 }
144 }
153 }
156 }
160 }
163 {
167 }
169 /* Skew into positive orthant and project out lineality space.
170 *
171 * We perform a unimodular transformation that turns a selected
172 * maximal set of linearly independent bounds into constraints
173 * on the first dimensions that impose that these first dimensions
174 * are non-negative. In particular, the constraint matrix is lower
175 * triangular with positive entries on the diagonal and negative
176 * entries below.
177 * If "bset" has a lineality space then these constraints (and therefore
178 * all constraints in bset) only involve the first dimensions.
179 * The remaining dimensions then do not appear in any constraints and
180 * we can select any value for them, say zero. We therefore project
181 * out this final dimensions and plug in the value zero later. This
182 * is accomplished by simply dropping the final columns of
183 * the unimodular transformation.
184 */
187 {
202 /* Try to move (multiples of) unit rows up. */
213 }
228 error:
233 }
235 /* Find a sample integer point, if any, in bset, which is known
236 * to have equalities. If bset contains no integer points, then
237 * return a zero-length vector.
238 * We simply remove the known equalities, compute a sample
239 * in the resulting bset, using the specified recurse function,
240 * and then transform the sample back to the original space.
241 */
244 {
255 else
258 }
260 /* Return a matrix containing the equalities of the tableau
261 * in constraint form. The tableau is assumed to have
262 * an associated bset that has been kept up-to-date.
263 */
265 {
293 else
297 }
300 error:
303 }
305 /* Compute and return an initial basis for the bounded tableau "tab".
306 *
307 * If the tableau is either full-dimensional or zero-dimensional,
308 * the we simply return an identity matrix.
309 * Otherwise, we construct a basis whose first directions correspond
310 * to equalities.
311 */
313 {
330 }
332 /* Given a tableau representing a set, find and return
333 * an integer point in the set, if there is any.
334 *
335 * We perform a depth first search
336 * for an integer point, by scanning all possible values in the range
337 * attained by a basis vector, where an initial basis may have been set
338 * by the calling function. Otherwise an initial basis that exploits
339 * the equalities in the tableau is created.
340 * tab->n_zero is currently ignored and is clobbered by this function.
341 *
342 * The tableau is allowed to have unbounded direction, but then
343 * the calling function needs to set an initial basis, with the
344 * unbounded directions last and with tab->n_unbounded set
345 * to the number of unbounded directions.
346 * Furthermore, the calling functions needs to add shifted copies
347 * of all constraints involving unbounded directions to ensure
348 * that any feasible rational value in these directions can be rounded
349 * up to yield a feasible integer value.
350 * In particular, let B define the given basis x' = B x
351 * and let T be the inverse of B, i.e., X = T x'.
352 * Let a x + c >= 0 be a constraint of the set represented by the tableau,
353 * or a T x' + c >= 0 in terms of the given basis. Assume that
354 * the bounded directions have an integer value, then we can safely
355 * round up the values for the unbounded directions if we make sure
356 * that x' not only satisfies the original constraint, but also
357 * the constraint "a T x' + c + s >= 0" with s the sum of all
358 * negative values in the last n_unbounded entries of "a T".
359 * The calling function therefore needs to add the constraint
360 * a x + c + s >= 0. The current function then scans the first
361 * directions for an integer value and once those have been found,
362 * it can compute "T ceil(B x)" to yield an integer point in the set.
363 * Note that during the search, the first rows of B may be changed
364 * by a basis reduction, but the last n_unbounded rows of B remain
365 * unaltered and are also not mixed into the first rows.
366 *
367 * The search is implemented iteratively. "level" identifies the current
368 * basis vector. "init" is true if we want the first value at the current
369 * level and false if we want the next value.
370 *
371 * The initial basis is the identity matrix. If the range in some direction
372 * contains more than one integer value, we perform basis reduction based
373 * on the value of ctx->gbr
374 * - ISL_GBR_NEVER: never perform basis reduction
375 * - ISL_GBR_ONCE: only perform basis reduction the first
376 * time such a range is encountered
377 * - ISL_GBR_ALWAYS: always perform basis reduction when
378 * such a range is encountered
379 *
380 * When ctx->gbr is set to ISL_GBR_ALWAYS, then we allow the basis
381 * reduction computation to return early. That is, as soon as it
382 * finds a reasonable first direction.
383 */
385 {
421 sample);
423 }
480 }
487 level--;
492 }
500 }
502 }
510 sample);
514 }
523 error:
529 }
531 /* Given a basic set that is known to be bounded, find and return
532 * an integer point in the basic set, if there is any.
533 *
534 * After handling some trivial cases, we construct a tableau
535 * and then use isl_tab_sample to find a sample, passing it
536 * the identity matrix as initial basis.
537 */
539 {
576 }
581 error:
585 }
587 /* Given a basic set "bset" and a value "sample" for the first coordinates
588 * of bset, plug in these values and drop the corresponding coordinates.
589 *
590 * We do this by computing the preimage of the transformation
591 *
592 * [ 1 0 ]
593 * x = [ s 0 ] x'
594 * [ 0 I ]
595 *
596 * where [1 s] is the sample value and I is the identity matrix of the
597 * appropriate dimension.
598 */
601 {
617 }
621 }
626 error:
630 }
632 /* Given a basic set "bset", return any (possibly non-integer) point
633 * in the basic set.
634 */
636 {
650 }
652 /* Given a linear cone "cone" and a rational point "vec",
653 * construct a polyhedron with shifted copies of the constraints in "cone",
654 * i.e., a polyhedron with "cone" as its recession cone, such that each
655 * point x in this polyhedron is such that the unit box positioned at x
656 * lies entirely inside the affine cone 'vec + cone'.
657 * Any rational point in this polyhedron may therefore be rounded up
658 * to yield an integer point that lies inside said affine cone.
659 *
660 * Denote the constraints of cone by "<a_i, x> >= 0" and the rational
661 * point "vec" by v/d.
662 * Let b_i = <a_i, v>. Then the affine cone 'vec + cone' is given
663 * by <a_i, x> - b/d >= 0.
664 * The polyhedron <a_i, x> - ceil{b/d} >= 0 is a subset of this affine cone.
665 * We prefer this polyhedron over the actual affine cone because it doesn't
666 * require a scaling of the constraints.
667 * If each of the vertices of the unit cube positioned at x lies inside
668 * this polyhedron, then the whole unit cube at x lies inside the affine cone.
669 * We therefore impose that x' = x + \sum e_i, for any selection of unit
670 * vectors lies inside the polyhedron, i.e.,
671 *
672 * <a_i, x'> - ceil{b/d} = <a_i, x> + sum a_i - ceil{b/d} >= 0
673 *
674 * The most stringent of these constraints is the one that selects
675 * all negative a_i, so the polyhedron we are looking for has constraints
676 *
677 * <a_i, x> + sum_{a_i < 0} a_i - ceil{b/d} >= 0
678 *
679 * Note that if cone were known to have only non-negative rays
680 * (which can be accomplished by a unimodular transformation),
681 * then we would only have to check the points x' = x + e_i
682 * and we only have to add the smallest negative a_i (if any)
683 * instead of the sum of all negative a_i.
684 */
687 {
718 }
719 }
725 error:
730 }
732 /* Given a rational point vec in a (transformed) basic set,
733 * such that cone is the recession cone of the original basic set,
734 * "round up" the rational point to an integer point.
735 *
736 * We first check if the rational point just happens to be integer.
737 * If not, we transform the cone in the same way as the basic set,
738 * pick a point x in this cone shifted to the rational point such that
739 * the whole unit cube at x is also inside this affine cone.
740 * Then we simply round up the coordinates of x and return the
741 * resulting integer point.
742 */
745 {
756 }
767 error:
772 }
774 /* Concatenate two integer vectors, i.e., two vectors with denominator
775 * (stored in element 0) equal to 1.
776 */
778 {
799 error:
803 }
805 /* Drop all constraints in bset that involve any of the dimensions
806 * first to first+n-1.
807 */
810 {
822 }
825 }
827 /* Give a basic set "bset" with recession cone "cone", compute and
828 * return an integer point in bset, if any.
829 *
830 * If the recession cone is full-dimensional, then we know that
831 * bset contains an infinite number of integer points and it is
832 * fairly easy to pick one of them.
833 * If the recession cone is not full-dimensional, then we first
834 * transform bset such that the bounded directions appear as
835 * the first dimensions of the transformed basic set.
836 * We do this by using a unimodular transformation that transforms
837 * the equalities in the recession cone to equalities on the first
838 * dimensions.
839 *
840 * The transformed set is then projected onto its bounded dimensions.
841 * Note that to compute this projection, we can simply drop all constraints
842 * involving any of the unbounded dimensions since these constraints
843 * cannot be combined to produce a constraint on the bounded dimensions.
844 * To see this, assume that there is such a combination of constraints
845 * that produces a constraint on the bounded dimensions. This means
846 * that some combination of the unbounded dimensions has both an upper
847 * bound and a lower bound in terms of the bounded dimensions, but then
848 * this combination would be a bounded direction too and would have been
849 * transformed into a bounded dimensions.
850 *
851 * We then compute a sample value in the bounded dimensions.
852 * If no such value can be found, then the original set did not contain
853 * any integer points and we are done.
854 * Otherwise, we plug in the value we found in the bounded dimensions,
855 * project out these bounded dimensions and end up with a set with
856 * a full-dimensional recession cone.
857 * A sample point in this set is computed by "rounding up" any
858 * rational point in the set.
859 *
860 * The sample points in the bounded and unbounded dimensions are
861 * then combined into a single sample point and transformed back
862 * to the original space.
863 */
866 {
900 }
907 error:
911 }
913 /* Compute and return a sample point in bset using generalized basis
914 * reduction. We first check if the input set has a non-trivial
915 * recession cone. If so, we perform some extra preprocessing in
916 * sample_with_cone. Otherwise, we directly perform generalized basis
917 * reduction.
918 */
920 {
933 }
936 {
950 else
954 }
957 {
979 }
980 }
997 }
999 error:
1002 }
1005 {
1007 }
1009 /* Compute an integer sample in "bset", where the caller guarantees
1010 * that "bset" is bounded.
1011 */
1013 {
1015 }
1018 {
1041 }
1045 error:
1049 }
1052 {
1066 }
1069 error:
1072 }
1075 {
1089 }
1094 error:
1097 }
1100 {
1102 }