5 #include <isl/union_set.h>
6 #include <isl/polynomial.h>
7 #include <isl_set_polylib.h>
8 #include <barvinok/options.h>
9 #include <barvinok/util.h>
12 #include "lattice_width.h"
13 #include "param_util.h"
14 #include "reduce_domain.h"
16 #define ALLOC(type) (type*)malloc(sizeof(type))
17 #define ALLOCN(type,n) (type*)malloc((n) * sizeof(type))
19 static void clear_width_direction(struct width_direction
*wd
)
21 Vector_Free(wd
->width
);
24 Polyhedron_Free(wd
->domain
);
27 static struct width_direction_array
*new_width_direction_array(void)
29 struct width_direction_array
*dirs
= ALLOC(struct width_direction_array
);
33 dirs
->wd
= ALLOCN(struct width_direction
, dirs
->alloc
);
38 static void grow_width_direction_array(struct width_direction_array
*dirs
,
41 if (dirs
->n
+ extra
<= dirs
->alloc
)
43 dirs
->alloc
= (5*(dirs
->n
+extra
))/4;
44 dirs
->wd
= (struct width_direction
*)realloc(dirs
->wd
,
45 dirs
->alloc
* sizeof(struct width_direction
));
49 void free_width_direction_array(struct width_direction_array
*dirs
)
53 for (i
= 0; i
< dirs
->n
; ++i
)
54 clear_width_direction(&dirs
->wd
[i
]);
59 #define INT_BITS (sizeof(unsigned) * 8)
61 /* For each parametric vertex, compute cone of directions
62 * for which this vertex attains the minimal value.
64 static Matrix
**compute_vertex_dirs(Param_Polyhedron
*PP
)
67 unsigned nvar
= PP
->V
->Vertex
->NbRows
;
69 Matrix
**vertex_dirs
= ALLOCN(Matrix
*, PP
->nbV
);
71 for (i
= 0, V
= PP
->V
; V
; ++i
, V
= V
->next
) {
81 int len
= (PP
->Constraints
->NbRows
+INT_BITS
-1)/INT_BITS
;
83 n
= bit_vector_count(facets
, len
);
85 facets
= supporting_constraints(PP
->Constraints
, V
, &n
);
86 M
= Matrix_Alloc(n
, 1+nvar
+1);
87 for (k
= 0, j
= 0, kx
= 0, bx
= MSB
; j
< n
; ++k
) {
88 if (facets
[kx
] & bx
) {
89 value_set_si(M
->p
[j
][0], 1);
90 Vector_Copy(PP
->Constraints
->p
[k
]+1, M
->p
[j
++]+1, nvar
);
94 P
= Constraints2Polyhedron(M
, 0);
96 vertex_dirs
[i
] = Matrix_Alloc(P
->NbRays
-1, nvar
);
97 for (k
= 0, j
= 0; k
< P
->NbRays
; ++k
) {
98 if (value_notzero_p(P
->Ray
[k
][1+nvar
]))
100 Vector_Copy(P
->Ray
[k
]+1, vertex_dirs
[i
]->p
[j
++], nvar
);
115 static void Vector_Subtract(Value
*a
, Value a_d
,
117 Value
*c
, Value
*c_d
, int len
)
122 value_lcm(*c_d
, a_d
, b_d
);
123 value_divexact(ma
, *c_d
, a_d
);
124 value_divexact(mb
, *c_d
, b_d
);
125 value_oppose(mb
, mb
);
126 Vector_Combine(a
, b
, c
, ma
, mb
, len
);
131 /* Compute width for a given direction dir and initialize width_direction
134 static void compute_width_direction(Matrix
*V_min
, Matrix
*V_max
,
135 Value
*dir
, struct width_direction
*wd
)
137 Vector
*max
= Vector_Alloc(V_min
->NbColumns
);
138 unsigned nvar
= V_min
->NbRows
;
139 unsigned nparam
= V_min
->NbColumns
-2;
141 wd
->width
= Vector_Alloc(V_min
->NbColumns
);
142 wd
->dir
= Vector_Alloc(nvar
);
143 Vector_Copy(dir
, wd
->dir
->p
, nvar
);
149 Vector_Matrix_Product(dir
, V_max
, max
->p
);
150 Vector_Matrix_Product(dir
, V_min
, wd
->width
->p
);
151 Vector_Subtract(max
->p
, V_max
->p
[0][V_max
->NbColumns
],
152 wd
->width
->p
, V_min
->p
[0][V_min
->NbColumns
],
153 wd
->width
->p
, &wd
->width
->p
[nparam
+1],
159 Vector_Normalize(wd
->width
->p
, nparam
+2);
164 static int Vector_Compare(Value
*p1
, Value
*p2
, unsigned len
)
168 for (i
= 0; i
< len
; ++i
) {
169 int sign
= mpz_cmp(p1
[i
], p2
[i
]);
176 static int wd_width_lex_cmp(const void *va
, const void *vb
)
178 const struct width_direction
*a
= (const struct width_direction
*)va
;
179 const struct width_direction
*b
= (const struct width_direction
*)vb
;
181 return Vector_Compare(a
->width
->p
, b
->width
->p
, a
->width
->Size
);
184 static int add_vertex(Matrix
*M
, int n
, Value
*v
)
187 Matrix_Extend(M
, 3*(M
->NbRows
+10)/2);
188 value_set_si(M
->p
[n
][0], 1);
189 Vector_Copy(v
, M
->p
[n
]+1, M
->NbColumns
-2);
190 value_set_si(M
->p
[n
][M
->NbColumns
-1], 1);
194 /* Puts the points in v that lie in P in front of the list
195 * and returns their number.
197 static int valid_vertices(Polyhedron
*P
, Matrix
*v
, int n_v
)
202 assert(v
->NbColumns
== P
->Dimension
+2);
205 for (j
= 0, k
= 0; j
< n_v
; ++j
) {
206 for (i
= 0; i
< P
->NbConstraints
; ++i
) {
207 Inner_Product(v
->p
[j
]+1, P
->Constraint
[i
]+1, P
->Dimension
+1, &tmp
);
208 if (value_neg_p(tmp
))
211 if (i
< P
->NbConstraints
)
214 Vector_Exchange(v
->p
[j
]+1, v
->p
[k
]+1, P
->Dimension
);
222 static struct width_direction_array
*
223 compute_width_directions(Param_Polyhedron
*PP
, struct barvinok_options
*options
)
225 Matrix
**vertex_dirs
;
226 Param_Vertices
*V_max
, *V_min
;
227 int i
, V_max_i
, V_min_i
;
228 unsigned nvar
= PP
->V
->Vertex
->NbRows
;
229 struct width_direction_array
*width_dirs
= new_width_direction_array();
230 Matrix
*all_vertices
= Matrix_Alloc(nvar
, 1+nvar
+1);
233 vertex_dirs
= compute_vertex_dirs(PP
);
235 for (V_max
= PP
->V
; V_max
; V_max
= V_max
->next
)
236 Param_Vertex_Common_Denominator(V_max
);
238 for (V_max
= PP
->V
, V_max_i
= 0; V_max
; V_max
= V_max
->next
, V_max_i
++) {
239 for (V_min
= V_max
->next
, V_min_i
= V_max_i
+1;
241 V_min
= V_min
->next
, V_min_i
++) {
245 unsigned V_max_n
= vertex_dirs
[V_max_i
]->NbRows
;
246 unsigned V_min_n
= vertex_dirs
[V_min_i
]->NbRows
;
249 if (options
->verbose
)
250 fprintf(stderr
, "%d/%d %d/%d %d \r",
255 M
= Matrix_Alloc(V_max_n
+V_min_n
, 1+nvar
+1);
256 for (i
= 0; i
< V_max_n
; ++i
) {
257 value_set_si(M
->p
[i
][0], 1);
258 Vector_Oppose(vertex_dirs
[V_max_i
]->p
[i
], M
->p
[i
]+1, nvar
);
260 for (i
= 0; i
< V_min_n
; ++i
) {
261 value_set_si(M
->p
[V_max_n
+i
][0], 1);
262 Vector_Copy(vertex_dirs
[V_min_i
]->p
[i
], M
->p
[V_max_n
+i
]+1, nvar
);
264 C
= Constraints2Polyhedron(M
, options
->MaxRays
);
266 n_valid
= valid_vertices(C
, all_vertices
, n_vertices
);
267 basis
= Cone_Integer_Hull(C
, all_vertices
, n_valid
, options
);
268 grow_width_direction_array(width_dirs
, basis
->NbRows
);
269 for (i
= 0; i
< basis
->NbRows
; ++i
) {
270 Matrix
*VM_min
, *VM_max
;
273 VM_min
= V_min
->Vertex
;
274 VM_max
= V_max
->Vertex
;
275 pos
= First_Non_Zero(basis
->p
[i
], nvar
);
276 if (value_neg_p(basis
->p
[i
][pos
])) {
277 Vector_Oppose(basis
->p
[i
], basis
->p
[i
], nvar
);
278 VM_min
= V_max
->Vertex
;
279 VM_max
= V_min
->Vertex
;
282 n_vertices
= add_vertex(all_vertices
, n_vertices
, basis
->p
[i
]);
283 compute_width_direction(VM_min
, VM_max
, basis
->p
[i
],
284 &width_dirs
->wd
[width_dirs
->n
++]);
290 Matrix_Free(all_vertices
);
292 for (i
= 0; i
< PP
->nbV
; ++i
)
293 Matrix_Free(vertex_dirs
[i
]);
299 /* Computes the lattice width direction of a parametric polytope.
300 * The parameter space is allowed to be unbounded.
301 * Currently, the parametric polytope and the parameter space
302 * are assumed to be full-dimensional.
304 * First, we compute the parametric vertices.
305 * Then, for each pair of vertices, we construct a (rational) cone
306 * of directions for which one vertex attains the minimal value
307 * and the other vertex attains the maximal value.
308 * The candidate directions are the elements of the integer hulls
310 * The minimal direction is then obtained by computing the
311 * region in the parameter space where each direction yields
312 * a smaller (or equal) width than all the other directions.
314 * In principle, we can avoid computing candidate directions
315 * for vertices with no overlapping activity domains (possibly
316 * after opening some facets of the activity domains in the
319 * The output is a list of triples, consisting of a direction,
320 * the corresponding width and the chamber in the parameter
321 * space where this direction leads to the minimal width.
323 * The algorithm is described in "Integer points in a parameterised
324 * polyhedron" by Friedrich Eisenbrand and Gennady Shmonin.
326 struct width_direction_array
*
327 Polyhedron_Lattice_Width_Directions(Polyhedron
*P
, Polyhedron
*C
,
328 struct barvinok_options
*options
)
330 Param_Polyhedron
*PP
;
331 unsigned nparam
= C
->Dimension
;
333 struct width_direction_array
*width_dirs
;
337 assert(P
->NbEq
== 0);
338 assert(C
->NbEq
== 0);
340 /* Use true context since the algorithm assumes P is non-empty
341 * for every point in the context.
343 TC
= true_context(P
, C
, options
->MaxRays
);
344 inner
= inner_point(TC
);
346 /* This is overkill, as we discard the computed chambers. */
347 PP
= Polyhedron2Param_Polyhedron(P
, TC
, options
);
349 width_dirs
= compute_width_directions(PP
, options
);
350 Param_Polyhedron_Free(PP
);
352 qsort(width_dirs
->wd
, width_dirs
->n
, sizeof(struct width_direction
),
355 for (i
= 1, j
= 1; i
< width_dirs
->n
; ++i
) {
356 /* We could also weed out width_directions that differ by a
357 * (positive) constant from another width_direction, but then
358 * we'd have to put the two width_directions on a common
361 if (Vector_Equal(width_dirs
->wd
[j
-1].width
->p
,
362 width_dirs
->wd
[i
].width
->p
, nparam
+2))
363 clear_width_direction(&width_dirs
->wd
[i
]);
365 width_dirs
->wd
[j
++] = width_dirs
->wd
[i
];
369 for (i
= 0, k
= 0; i
< width_dirs
->n
; ++i
) {
370 Matrix
*M
= Matrix_Alloc(TC
->NbConstraints
+width_dirs
->n
-(i
-k
)-1, nparam
+2);
371 for (j
= 0; j
< TC
->NbConstraints
; ++j
)
372 Vector_Copy(TC
->Constraint
[j
], M
->p
[j
], nparam
+2);
373 for (j
= 0; j
< width_dirs
->n
; ++j
) {
375 if (k
<= j
&& j
<= i
)
378 pos
= TC
->NbConstraints
+ j
;
380 pos
= TC
->NbConstraints
+ j
- (i
-k
) - 1;
381 Vector_Subtract(width_dirs
->wd
[j
].width
->p
,
382 width_dirs
->wd
[j
].width
->p
[nparam
+1],
383 width_dirs
->wd
[i
].width
->p
,
384 width_dirs
->wd
[i
].width
->p
[nparam
+1],
385 M
->p
[pos
]+1, M
->p
[pos
], nparam
+1);
386 value_set_si(M
->p
[pos
][0], 1);
387 Vector_Normalize(M
->p
[pos
]+1, nparam
+1);
388 if (!is_internal(inner
, M
->p
[pos
]))
389 value_decrement(M
->p
[pos
][nparam
+1], M
->p
[pos
][nparam
+1]);
391 width_dirs
->wd
[i
].domain
= Constraints2Polyhedron(M
, options
->MaxRays
);
392 if (emptyQ(width_dirs
->wd
[i
].domain
))
393 clear_width_direction(&width_dirs
->wd
[i
]);
395 width_dirs
->wd
[k
++] = width_dirs
->wd
[i
];
405 /* Construct evalue of chambers with their associated widths */
406 evalue
*Polyhedron_Lattice_Width(Polyhedron
*P
, Polyhedron
*C
,
407 struct barvinok_options
*options
)
410 struct evalue_section
*s
;
411 struct width_direction_array
*width_dirs
;
413 unsigned nparam
= C
->Dimension
;
415 width_dirs
= Polyhedron_Lattice_Width_Directions(P
, C
, options
);
416 s
= ALLOCN(struct evalue_section
, width_dirs
->n
);
417 for (i
= 0; i
< width_dirs
->n
; ++i
) {
418 s
[i
].D
= width_dirs
->wd
[i
].domain
;
419 width_dirs
->wd
[i
].domain
= NULL
;
420 s
[i
].E
= affine2evalue(width_dirs
->wd
[i
].width
->p
,
421 width_dirs
->wd
[i
].width
->p
[nparam
+1],
424 free_width_direction_array(width_dirs
);
426 width
= evalue_from_section_array(s
, i
);
432 static __isl_give isl_pw_qpolynomial
*basic_set_lattice_width(
433 __isl_take isl_basic_set
*bset
)
437 isl_pw_qpolynomial
*pwqp
;
442 struct barvinok_options
*options
;
443 int options_allocated
= 0;
448 ctx
= isl_basic_set_get_ctx(bset
);
449 options
= isl_ctx_peek_barvinok_options(ctx
);
451 options
= barvinok_options_new_with_defaults();
452 options_allocated
= 1;
455 nparam
= isl_basic_set_dim(bset
, isl_dim_param
);
456 space
= isl_basic_set_get_space(bset
);
457 space
= isl_space_params(space
);
459 U
= Universe_Polyhedron(nparam
);
460 P
= isl_basic_set_to_polylib(bset
);
462 E
= Polyhedron_Lattice_Width(P
, U
, options
);
464 pwqp
= isl_pw_qpolynomial_from_evalue(space
, E
);
465 isl_basic_set_free(bset
);
470 if (options_allocated
)
471 barvinok_options_free(options
);
476 __isl_give isl_pw_qpolynomial
*isl_set_lattice_width(__isl_take isl_set
*set
)
481 if (isl_set_plain_is_empty(set
)) {
483 space
= isl_set_get_space(set
);
484 space
= isl_space_domain(isl_space_from_range(space
));
486 return isl_pw_qpolynomial_zero(space
);
489 if (isl_set_n_basic_set(set
) != 1)
490 isl_die(isl_set_get_ctx(set
), isl_error_unsupported
,
491 "unions not supported (yet)", goto error
);
493 return basic_set_lattice_width(isl_set_simple_hull(set
));
499 static isl_stat
set_lw(__isl_take isl_set
*set
, void *user
)
501 isl_union_pw_qpolynomial
**res
= (isl_union_pw_qpolynomial
**)user
;
502 isl_pw_qpolynomial
*pwqp
;
504 pwqp
= isl_set_lattice_width(set
);
505 *res
= isl_union_pw_qpolynomial_add_pw_qpolynomial(*res
, pwqp
);
510 __isl_give isl_union_pw_qpolynomial
*isl_union_set_lattice_width(
511 __isl_take isl_union_set
*uset
)
514 isl_union_pw_qpolynomial
*res
;
516 space
= isl_union_set_get_space(uset
);
517 res
= isl_union_pw_qpolynomial_zero(space
);
518 if (isl_union_set_n_set(uset
) > 1)
519 isl_die(isl_union_set_get_ctx(uset
), isl_error_unsupported
,
520 "unions not supported (yet)", goto error
);
521 if (isl_union_set_foreach_set(uset
, &set_lw
, &res
) < 0)
523 isl_union_set_free(uset
);
527 isl_union_set_free(uset
);
528 isl_union_pw_qpolynomial_free(res
);