edomain.cc: avoid use of fdstream
[barvinok.git] / barvinok.cc
blob7e1fbfb09a79ae66f6c569a3621ab42ba6b590db
1 #include <assert.h>
2 #include <iostream>
3 #include <vector>
4 #include <deque>
5 #include <string>
6 #include <sstream>
7 #include <gmp.h>
8 #include <NTL/mat_ZZ.h>
9 #include <NTL/LLL.h>
10 #include <barvinok/util.h>
11 #include <barvinok/evalue.h>
12 extern "C" {
13 #include "piputil.h"
15 #include "config.h"
16 #include <barvinok/barvinok.h>
17 #include <barvinok/genfun.h>
18 #include <barvinok/options.h>
19 #include <barvinok/sample.h>
20 #include "conversion.h"
21 #include "decomposer.h"
22 #include "lattice_point.h"
23 #include "reduce_domain.h"
24 #include "genfun_constructor.h"
25 #include "remove_equalities.h"
26 #include "scale.h"
27 #include "volume.h"
29 #ifdef NTL_STD_CXX
30 using namespace NTL;
31 #endif
32 using std::cerr;
33 using std::cout;
34 using std::endl;
35 using std::vector;
36 using std::deque;
37 using std::string;
38 using std::ostringstream;
40 #define ALLOC(t,p) p = (t*)malloc(sizeof(*p))
42 class dpoly_n {
43 public:
44 Matrix *coeff;
45 ~dpoly_n() {
46 Matrix_Free(coeff);
48 dpoly_n(int d, ZZ& degree_0, ZZ& degree_1, int offset = 0) {
49 Value d0, d1;
50 value_init(d0);
51 value_init(d1);
52 zz2value(degree_0, d0);
53 zz2value(degree_1, d1);
54 coeff = Matrix_Alloc(d+1, d+1+1);
55 value_set_si(coeff->p[0][0], 1);
56 value_set_si(coeff->p[0][d+1], 1);
57 for (int i = 1; i <= d; ++i) {
58 value_multiply(coeff->p[i][0], coeff->p[i-1][0], d0);
59 Vector_Combine(coeff->p[i-1], coeff->p[i-1]+1, coeff->p[i]+1,
60 d1, d0, i);
61 value_set_si(coeff->p[i][d+1], i);
62 value_multiply(coeff->p[i][d+1], coeff->p[i][d+1], coeff->p[i-1][d+1]);
63 value_decrement(d0, d0);
65 value_clear(d0);
66 value_clear(d1);
68 void div(dpoly& d, Vector *count, ZZ& sign) {
69 int len = coeff->NbRows;
70 Matrix * c = Matrix_Alloc(coeff->NbRows, coeff->NbColumns);
71 Value tmp;
72 value_init(tmp);
73 for (int i = 0; i < len; ++i) {
74 Vector_Copy(coeff->p[i], c->p[i], len+1);
75 for (int j = 1; j <= i; ++j) {
76 zz2value(d.coeff[j], tmp);
77 value_multiply(tmp, tmp, c->p[i][len]);
78 value_oppose(tmp, tmp);
79 Vector_Combine(c->p[i], c->p[i-j], c->p[i],
80 c->p[i-j][len], tmp, len);
81 value_multiply(c->p[i][len], c->p[i][len], c->p[i-j][len]);
83 zz2value(d.coeff[0], tmp);
84 value_multiply(c->p[i][len], c->p[i][len], tmp);
86 if (sign == -1) {
87 value_set_si(tmp, -1);
88 Vector_Scale(c->p[len-1], count->p, tmp, len);
89 value_assign(count->p[len], c->p[len-1][len]);
90 } else
91 Vector_Copy(c->p[len-1], count->p, len+1);
92 Vector_Normalize(count->p, len+1);
93 value_clear(tmp);
94 Matrix_Free(c);
98 const int MAX_TRY=10;
100 * Searches for a vector that is not orthogonal to any
101 * of the rays in rays.
103 static void nonorthog(mat_ZZ& rays, vec_ZZ& lambda)
105 int dim = rays.NumCols();
106 bool found = false;
107 lambda.SetLength(dim);
108 if (dim == 0)
109 return;
111 for (int i = 2; !found && i <= 50*dim; i+=4) {
112 for (int j = 0; j < MAX_TRY; ++j) {
113 for (int k = 0; k < dim; ++k) {
114 int r = random_int(i)+2;
115 int v = (2*(r%2)-1) * (r >> 1);
116 lambda[k] = v;
118 int k = 0;
119 for (; k < rays.NumRows(); ++k)
120 if (lambda * rays[k] == 0)
121 break;
122 if (k == rays.NumRows()) {
123 found = true;
124 break;
128 assert(found);
131 static void add_rays(mat_ZZ& rays, Polyhedron *i, int *r, int nvar = -1,
132 bool all = false)
134 unsigned dim = i->Dimension;
135 if (nvar == -1)
136 nvar = dim;
137 for (int k = 0; k < i->NbRays; ++k) {
138 if (!value_zero_p(i->Ray[k][dim+1]))
139 continue;
140 if (!all && nvar != dim && First_Non_Zero(i->Ray[k]+1, nvar) == -1)
141 continue;
142 values2zz(i->Ray[k]+1, rays[(*r)++], nvar);
146 static void mask_r(Matrix *f, int nr, Vector *lcm, int p, Vector *val, evalue *ev)
148 unsigned nparam = lcm->Size;
150 if (p == nparam) {
151 Vector * prod = Vector_Alloc(f->NbRows);
152 Matrix_Vector_Product(f, val->p, prod->p);
153 int isint = 1;
154 for (int i = 0; i < nr; ++i) {
155 value_modulus(prod->p[i], prod->p[i], f->p[i][nparam+1]);
156 isint &= value_zero_p(prod->p[i]);
158 value_set_si(ev->d, 1);
159 value_init(ev->x.n);
160 value_set_si(ev->x.n, isint);
161 Vector_Free(prod);
162 return;
165 Value tmp;
166 value_init(tmp);
167 if (value_one_p(lcm->p[p]))
168 mask_r(f, nr, lcm, p+1, val, ev);
169 else {
170 value_assign(tmp, lcm->p[p]);
171 value_set_si(ev->d, 0);
172 ev->x.p = new_enode(periodic, VALUE_TO_INT(tmp), p+1);
173 do {
174 value_decrement(tmp, tmp);
175 value_assign(val->p[p], tmp);
176 mask_r(f, nr, lcm, p+1, val, &ev->x.p->arr[VALUE_TO_INT(tmp)]);
177 } while (value_pos_p(tmp));
179 value_clear(tmp);
182 static void mask_fractional(Matrix *f, evalue *factor)
184 int nr = f->NbRows, nc = f->NbColumns;
185 int n;
186 bool found = false;
187 for (n = 0; n < nr && value_notzero_p(f->p[n][nc-1]); ++n)
188 if (value_notone_p(f->p[n][nc-1]) &&
189 value_notmone_p(f->p[n][nc-1]))
190 found = true;
191 if (!found)
192 return;
194 evalue EP;
195 nr = n;
197 Value m;
198 value_init(m);
200 evalue EV;
201 value_init(EV.d);
202 value_init(EV.x.n);
203 value_set_si(EV.x.n, 1);
205 for (n = 0; n < nr; ++n) {
206 value_assign(m, f->p[n][nc-1]);
207 if (value_one_p(m) || value_mone_p(m))
208 continue;
210 int j = normal_mod(f->p[n], nc-1, &m);
211 if (j == nc-1) {
212 free_evalue_refs(factor);
213 value_init(factor->d);
214 evalue_set_si(factor, 0, 1);
215 break;
217 vec_ZZ row;
218 values2zz(f->p[n], row, nc-1);
219 ZZ g;
220 value2zz(m, g);
221 if (j < (nc-1)-1 && row[j] > g/2) {
222 for (int k = j; k < (nc-1); ++k)
223 if (row[k] != 0)
224 row[k] = g - row[k];
227 value_init(EP.d);
228 value_set_si(EP.d, 0);
229 EP.x.p = new_enode(relation, 2, 0);
230 value_clear(EP.x.p->arr[1].d);
231 EP.x.p->arr[1] = *factor;
232 evalue *ev = &EP.x.p->arr[0];
233 value_set_si(ev->d, 0);
234 ev->x.p = new_enode(fractional, 3, -1);
235 evalue_set_si(&ev->x.p->arr[1], 0, 1);
236 evalue_set_si(&ev->x.p->arr[2], 1, 1);
237 evalue *E = multi_monom(row);
238 value_assign(EV.d, m);
239 emul(&EV, E);
240 value_clear(ev->x.p->arr[0].d);
241 ev->x.p->arr[0] = *E;
242 delete E;
243 *factor = EP;
246 value_clear(m);
247 free_evalue_refs(&EV);
253 static void mask_table(Matrix *f, evalue *factor)
255 int nr = f->NbRows, nc = f->NbColumns;
256 int n;
257 bool found = false;
258 for (n = 0; n < nr && value_notzero_p(f->p[n][nc-1]); ++n)
259 if (value_notone_p(f->p[n][nc-1]) &&
260 value_notmone_p(f->p[n][nc-1]))
261 found = true;
262 if (!found)
263 return;
265 Value tmp;
266 value_init(tmp);
267 nr = n;
268 unsigned np = nc - 2;
269 Vector *lcm = Vector_Alloc(np);
270 Vector *val = Vector_Alloc(nc);
271 Vector_Set(val->p, 0, nc);
272 value_set_si(val->p[np], 1);
273 Vector_Set(lcm->p, 1, np);
274 for (n = 0; n < nr; ++n) {
275 if (value_one_p(f->p[n][nc-1]) ||
276 value_mone_p(f->p[n][nc-1]))
277 continue;
278 for (int j = 0; j < np; ++j)
279 if (value_notzero_p(f->p[n][j])) {
280 Gcd(f->p[n][j], f->p[n][nc-1], &tmp);
281 value_division(tmp, f->p[n][nc-1], tmp);
282 value_lcm(tmp, lcm->p[j], &lcm->p[j]);
285 evalue EP;
286 value_init(EP.d);
287 mask_r(f, nr, lcm, 0, val, &EP);
288 value_clear(tmp);
289 Vector_Free(val);
290 Vector_Free(lcm);
291 emul(&EP,factor);
292 free_evalue_refs(&EP);
295 static void mask(Matrix *f, evalue *factor, barvinok_options *options)
297 if (options->lookup_table)
298 mask_table(f, factor);
299 else
300 mask_fractional(f, factor);
303 /* This structure encodes the power of the term in a rational generating function.
305 * Either E == NULL or constant = 0
306 * If E != NULL, then the power is E
307 * If E == NULL, then the power is coeff * param[pos] + constant
309 struct term_info {
310 evalue *E;
311 ZZ constant;
312 ZZ coeff;
313 int pos;
316 /* Returns the power of (t+1) in the term of a rational generating function,
317 * i.e., the scalar product of the actual lattice point and lambda.
318 * The lattice point is the unique lattice point in the fundamental parallelepiped
319 * of the unimodual cone i shifted to the parametric vertex V.
321 * PD is the parameter domain, which, if != NULL, may be used to simply the
322 * resulting expression.
324 * The result is returned in term.
326 void lattice_point(Param_Vertices* V, const mat_ZZ& rays, vec_ZZ& lambda,
327 term_info* term, Polyhedron *PD, barvinok_options *options)
329 unsigned nparam = V->Vertex->NbColumns - 2;
330 unsigned dim = rays.NumCols();
331 mat_ZZ vertex;
332 vertex.SetDims(V->Vertex->NbRows, nparam+1);
333 Value lcm, tmp;
334 value_init(lcm);
335 value_init(tmp);
336 value_set_si(lcm, 1);
337 for (int j = 0; j < V->Vertex->NbRows; ++j) {
338 value_lcm(lcm, V->Vertex->p[j][nparam+1], &lcm);
340 if (value_notone_p(lcm)) {
341 Matrix * mv = Matrix_Alloc(dim, nparam+1);
342 for (int j = 0 ; j < dim; ++j) {
343 value_division(tmp, lcm, V->Vertex->p[j][nparam+1]);
344 Vector_Scale(V->Vertex->p[j], mv->p[j], tmp, nparam+1);
347 term->E = lattice_point(rays, lambda, mv, lcm, PD, options);
348 term->constant = 0;
350 Matrix_Free(mv);
351 value_clear(lcm);
352 value_clear(tmp);
353 return;
355 for (int i = 0; i < V->Vertex->NbRows; ++i) {
356 assert(value_one_p(V->Vertex->p[i][nparam+1])); // for now
357 values2zz(V->Vertex->p[i], vertex[i], nparam+1);
360 vec_ZZ num;
361 num = lambda * vertex;
363 int p = -1;
364 int nn = 0;
365 for (int j = 0; j < nparam; ++j)
366 if (num[j] != 0) {
367 ++nn;
368 p = j;
370 if (nn >= 2) {
371 term->E = multi_monom(num);
372 term->constant = 0;
373 } else {
374 term->E = NULL;
375 term->constant = num[nparam];
376 term->pos = p;
377 if (p != -1)
378 term->coeff = num[p];
381 value_clear(lcm);
382 value_clear(tmp);
386 struct counter : public np_base {
387 vec_ZZ lambda;
388 mat_ZZ vertex;
389 vec_ZZ den;
390 ZZ sign;
391 vec_ZZ num;
392 ZZ offset;
393 int j;
394 mpq_t count;
396 counter(unsigned dim) : np_base(dim) {
397 den.SetLength(dim);
398 mpq_init(count);
401 virtual void init(Polyhedron *P) {
402 randomvector(P, lambda, dim);
405 virtual void reset() {
406 mpq_set_si(count, 0, 0);
409 ~counter() {
410 mpq_clear(count);
413 virtual void handle(const mat_ZZ& rays, Value *vertex, const QQ& c,
414 unsigned long det, int *closed, barvinok_options *options);
415 virtual void get_count(Value *result) {
416 assert(value_one_p(&count[0]._mp_den));
417 value_assign(*result, &count[0]._mp_num);
421 void counter::handle(const mat_ZZ& rays, Value *V, const QQ& c, unsigned long det,
422 int *closed, barvinok_options *options)
424 for (int k = 0; k < dim; ++k) {
425 if (lambda * rays[k] == 0)
426 throw Orthogonal;
429 assert(c.d == 1);
430 assert(c.n == 1 || c.n == -1);
431 sign = c.n;
433 lattice_point(V, rays, vertex, det, closed);
434 num = vertex * lambda;
435 den = rays * lambda;
436 offset = 0;
437 normalize(sign, offset, den);
439 num[0] += offset;
440 dpoly d(dim, num[0]);
441 for (int k = 1; k < num.length(); ++k) {
442 num[k] += offset;
443 dpoly term(dim, num[k]);
444 d += term;
446 dpoly n(dim, den[0], 1);
447 for (int k = 1; k < dim; ++k) {
448 dpoly fact(dim, den[k], 1);
449 n *= fact;
451 d.div(n, count, sign);
454 struct bfe_term : public bfc_term_base {
455 vector<evalue *> factors;
457 bfe_term(int len) : bfc_term_base(len) {
460 ~bfe_term() {
461 for (int i = 0; i < factors.size(); ++i) {
462 if (!factors[i])
463 continue;
464 free_evalue_refs(factors[i]);
465 delete factors[i];
470 static void print_int_vector(int *v, int len, char *name)
472 cerr << name << endl;
473 for (int j = 0; j < len; ++j) {
474 cerr << v[j] << " ";
476 cerr << endl;
479 static void print_bfc_terms(mat_ZZ& factors, bfc_vec& v)
481 cerr << endl;
482 cerr << "factors" << endl;
483 cerr << factors << endl;
484 for (int i = 0; i < v.size(); ++i) {
485 cerr << "term: " << i << endl;
486 print_int_vector(v[i]->powers, factors.NumRows(), "powers");
487 cerr << "terms" << endl;
488 cerr << v[i]->terms << endl;
489 bfc_term* bfct = static_cast<bfc_term *>(v[i]);
490 cerr << bfct->c << endl;
494 static void print_bfe_terms(mat_ZZ& factors, bfc_vec& v)
496 cerr << endl;
497 cerr << "factors" << endl;
498 cerr << factors << endl;
499 for (int i = 0; i < v.size(); ++i) {
500 cerr << "term: " << i << endl;
501 print_int_vector(v[i]->powers, factors.NumRows(), "powers");
502 cerr << "terms" << endl;
503 cerr << v[i]->terms << endl;
504 bfe_term* bfet = static_cast<bfe_term *>(v[i]);
505 for (int j = 0; j < v[i]->terms.NumRows(); ++j) {
506 char * test[] = {"a", "b"};
507 print_evalue(stderr, bfet->factors[j], test);
508 fprintf(stderr, "\n");
513 struct bfcounter : public bfcounter_base {
514 mpq_t count;
516 bfcounter(unsigned dim) : bfcounter_base(dim) {
517 mpq_init(count);
518 lower = 1;
520 ~bfcounter() {
521 mpq_clear(count);
523 virtual void base(mat_ZZ& factors, bfc_vec& v);
524 virtual void get_count(Value *result) {
525 assert(value_one_p(&count[0]._mp_den));
526 value_assign(*result, &count[0]._mp_num);
530 void bfcounter::base(mat_ZZ& factors, bfc_vec& v)
532 unsigned nf = factors.NumRows();
534 for (int i = 0; i < v.size(); ++i) {
535 bfc_term* bfct = static_cast<bfc_term *>(v[i]);
536 int total_power = 0;
537 // factor is always positive, so we always
538 // change signs
539 for (int k = 0; k < nf; ++k)
540 total_power += v[i]->powers[k];
542 int j;
543 for (j = 0; j < nf; ++j)
544 if (v[i]->powers[j] > 0)
545 break;
547 dpoly D(total_power, factors[j][0], 1);
548 for (int k = 1; k < v[i]->powers[j]; ++k) {
549 dpoly fact(total_power, factors[j][0], 1);
550 D *= fact;
552 for ( ; ++j < nf; )
553 for (int k = 0; k < v[i]->powers[j]; ++k) {
554 dpoly fact(total_power, factors[j][0], 1);
555 D *= fact;
558 for (int k = 0; k < v[i]->terms.NumRows(); ++k) {
559 dpoly n(total_power, v[i]->terms[k][0]);
560 mpq_set_si(tcount, 0, 1);
561 n.div(D, tcount, one);
562 if (total_power % 2)
563 bfct->c[k].n = -bfct->c[k].n;
564 zz2value(bfct->c[k].n, tn);
565 zz2value(bfct->c[k].d, td);
567 mpz_mul(mpq_numref(tcount), mpq_numref(tcount), tn);
568 mpz_mul(mpq_denref(tcount), mpq_denref(tcount), td);
569 mpq_canonicalize(tcount);
570 mpq_add(count, count, tcount);
572 delete v[i];
577 /* Check whether the polyhedron is unbounded and if so,
578 * check whether it has any (and therefore an infinite number of)
579 * integer points.
580 * If one of the vertices is integer, then we are done.
581 * Otherwise, transform the polyhedron such that one of the rays
582 * is the first unit vector and cut it off at a height that ensures
583 * that if the whole polyhedron has any points, then the remaining part
584 * has integer points. In particular we add the largest coefficient
585 * of a ray to the highest vertex (rounded up).
587 static bool Polyhedron_is_infinite(Polyhedron *P, Value* result,
588 barvinok_options *options)
590 int r = 0;
591 Matrix *M, *M2;
592 Value c, tmp;
593 Value g;
594 bool first;
595 Vector *v;
596 Value offset, size;
597 Polyhedron *R;
599 if (P->NbBid == 0)
600 for (; r < P->NbRays; ++r)
601 if (value_zero_p(P->Ray[r][P->Dimension+1]))
602 break;
603 if (P->NbBid == 0 && r == P->NbRays)
604 return false;
606 if (options->count_sample_infinite) {
607 Vector *sample;
609 sample = Polyhedron_Sample(P, options);
610 if (!sample)
611 value_set_si(*result, 0);
612 else {
613 value_set_si(*result, -1);
614 Vector_Free(sample);
616 return true;
619 for (int i = 0; i < P->NbRays; ++i)
620 if (value_one_p(P->Ray[i][1+P->Dimension])) {
621 value_set_si(*result, -1);
622 return true;
625 value_init(g);
626 v = Vector_Alloc(P->Dimension+1);
627 Vector_Gcd(P->Ray[r]+1, P->Dimension, &g);
628 Vector_AntiScale(P->Ray[r]+1, v->p, g, P->Dimension+1);
629 M = unimodular_complete(v);
630 value_set_si(M->p[P->Dimension][P->Dimension], 1);
631 M2 = Transpose(M);
632 Matrix_Free(M);
633 P = Polyhedron_Preimage(P, M2, 0);
634 Matrix_Free(M2);
635 value_clear(g);
636 Vector_Free(v);
638 first = true;
639 value_init(offset);
640 value_init(size);
641 value_init(tmp);
642 value_set_si(size, 0);
644 for (int i = 0; i < P->NbBid; ++i) {
645 value_absolute(tmp, P->Ray[i][1]);
646 if (value_gt(tmp, size))
647 value_assign(size, tmp);
649 for (int i = P->NbBid; i < P->NbRays; ++i) {
650 if (value_zero_p(P->Ray[i][P->Dimension+1])) {
651 if (value_gt(P->Ray[i][1], size))
652 value_assign(size, P->Ray[i][1]);
653 continue;
655 mpz_cdiv_q(tmp, P->Ray[i][1], P->Ray[i][P->Dimension+1]);
656 if (first || value_gt(tmp, offset)) {
657 value_assign(offset, tmp);
658 first = false;
661 value_addto(offset, offset, size);
662 value_clear(size);
663 value_clear(tmp);
665 v = Vector_Alloc(P->Dimension+2);
666 value_set_si(v->p[0], 1);
667 value_set_si(v->p[1], -1);
668 value_assign(v->p[1+P->Dimension], offset);
669 R = AddConstraints(v->p, 1, P, options->MaxRays);
670 Polyhedron_Free(P);
671 P = R;
673 value_clear(offset);
674 Vector_Free(v);
676 value_init(c);
677 barvinok_count_with_options(P, &c, options);
678 Polyhedron_Free(P);
679 if (value_zero_p(c))
680 value_set_si(*result, 0);
681 else
682 value_set_si(*result, -1);
683 value_clear(c);
685 return true;
688 typedef Polyhedron * Polyhedron_p;
690 static void barvinok_count_f(Polyhedron *P, Value* result,
691 barvinok_options *options);
693 void barvinok_count_with_options(Polyhedron *P, Value* result,
694 struct barvinok_options *options)
696 unsigned dim;
697 int allocated = 0;
698 Polyhedron *Q;
699 bool infinite = false;
701 if (P->next)
702 fprintf(stderr,
703 "barvinok_count: input is a union; only first polyhedron is counted\n");
705 if (emptyQ2(P)) {
706 value_set_si(*result, 0);
707 return;
709 if (P->NbEq != 0) {
710 Q = NULL;
711 do {
712 P = remove_equalities(P);
713 P = DomainConstraintSimplify(P, options->MaxRays);
714 if (Q)
715 Polyhedron_Free(Q);
716 Q = P;
717 } while (!emptyQ(P) && P->NbEq != 0);
718 if (emptyQ(P)) {
719 Polyhedron_Free(P);
720 value_set_si(*result, 0);
721 return;
723 allocated = 1;
725 if (Polyhedron_is_infinite(P, result, options)) {
726 if (allocated)
727 Polyhedron_Free(P);
728 return;
730 if (P->Dimension == 0) {
731 /* Test whether the constraints are satisfied */
732 POL_ENSURE_VERTICES(P);
733 value_set_si(*result, !emptyQ(P));
734 if (allocated)
735 Polyhedron_Free(P);
736 return;
738 Q = Polyhedron_Factor(P, 0, NULL, options->MaxRays);
739 if (Q) {
740 if (allocated)
741 Polyhedron_Free(P);
742 P = Q;
743 allocated = 1;
746 barvinok_count_f(P, result, options);
747 if (value_neg_p(*result))
748 infinite = true;
749 if (Q && P->next && value_notzero_p(*result)) {
750 Value factor;
751 value_init(factor);
753 for (Q = P->next; Q; Q = Q->next) {
754 barvinok_count_f(Q, &factor, options);
755 if (value_neg_p(factor)) {
756 infinite = true;
757 continue;
758 } else if (Q->next && value_zero_p(factor)) {
759 value_set_si(*result, 0);
760 break;
762 value_multiply(*result, *result, factor);
765 value_clear(factor);
768 if (allocated)
769 Domain_Free(P);
770 if (infinite)
771 value_set_si(*result, -1);
774 void barvinok_count(Polyhedron *P, Value* result, unsigned NbMaxCons)
776 barvinok_options *options = barvinok_options_new_with_defaults();
777 options->MaxRays = NbMaxCons;
778 barvinok_count_with_options(P, result, options);
779 barvinok_options_free(options);
782 static void barvinok_count_f(Polyhedron *P, Value* result,
783 barvinok_options *options)
785 if (emptyQ2(P)) {
786 value_set_si(*result, 0);
787 return;
790 if (P->Dimension == 1)
791 return Line_Length(P, result);
793 int c = P->NbConstraints;
794 POL_ENSURE_FACETS(P);
795 if (c != P->NbConstraints || P->NbEq != 0)
796 return barvinok_count_with_options(P, result, options);
798 POL_ENSURE_VERTICES(P);
800 if (Polyhedron_is_infinite(P, result, options))
801 return;
803 np_base *cnt;
804 if (options->incremental_specialization == 2)
805 cnt = new bfcounter(P->Dimension);
806 else if (options->incremental_specialization == 1)
807 cnt = new icounter(P->Dimension);
808 else
809 cnt = new counter(P->Dimension);
810 cnt->start(P, options);
812 cnt->get_count(result);
813 delete cnt;
816 static void uni_polynom(int param, Vector *c, evalue *EP)
818 unsigned dim = c->Size-2;
819 value_init(EP->d);
820 value_set_si(EP->d,0);
821 EP->x.p = new_enode(polynomial, dim+1, param+1);
822 for (int j = 0; j <= dim; ++j)
823 evalue_set(&EP->x.p->arr[j], c->p[j], c->p[dim+1]);
826 static void multi_polynom(Vector *c, evalue* X, evalue *EP)
828 unsigned dim = c->Size-2;
829 evalue EC;
831 value_init(EC.d);
832 evalue_set(&EC, c->p[dim], c->p[dim+1]);
834 value_init(EP->d);
835 evalue_set(EP, c->p[dim], c->p[dim+1]);
837 for (int i = dim-1; i >= 0; --i) {
838 emul(X, EP);
839 value_assign(EC.x.n, c->p[i]);
840 eadd(&EC, EP);
842 free_evalue_refs(&EC);
845 Polyhedron *unfringe (Polyhedron *P, unsigned MaxRays)
847 int len = P->Dimension+2;
848 Polyhedron *T, *R = P;
849 Value g;
850 value_init(g);
851 Vector *row = Vector_Alloc(len);
852 value_set_si(row->p[0], 1);
854 R = DomainConstraintSimplify(Polyhedron_Copy(P), MaxRays);
856 Matrix *M = Matrix_Alloc(2, len-1);
857 value_set_si(M->p[1][len-2], 1);
858 for (int v = 0; v < P->Dimension; ++v) {
859 value_set_si(M->p[0][v], 1);
860 Polyhedron *I = Polyhedron_Image(R, M, 2+1);
861 value_set_si(M->p[0][v], 0);
862 for (int r = 0; r < I->NbConstraints; ++r) {
863 if (value_zero_p(I->Constraint[r][0]))
864 continue;
865 if (value_zero_p(I->Constraint[r][1]))
866 continue;
867 if (value_one_p(I->Constraint[r][1]))
868 continue;
869 if (value_mone_p(I->Constraint[r][1]))
870 continue;
871 value_absolute(g, I->Constraint[r][1]);
872 Vector_Set(row->p+1, 0, len-2);
873 value_division(row->p[1+v], I->Constraint[r][1], g);
874 mpz_fdiv_q(row->p[len-1], I->Constraint[r][2], g);
875 T = R;
876 R = AddConstraints(row->p, 1, R, MaxRays);
877 if (T != P)
878 Polyhedron_Free(T);
880 Polyhedron_Free(I);
882 Matrix_Free(M);
883 Vector_Free(row);
884 value_clear(g);
885 return R;
888 /* Check whether all rays point in the positive directions
889 * for the parameters
891 static bool Polyhedron_has_positive_rays(Polyhedron *P, unsigned nparam)
893 int r;
894 for (r = 0; r < P->NbRays; ++r)
895 if (value_zero_p(P->Ray[r][P->Dimension+1])) {
896 int i;
897 for (i = P->Dimension - nparam; i < P->Dimension; ++i)
898 if (value_neg_p(P->Ray[r][i+1]))
899 return false;
901 return true;
904 typedef evalue * evalue_p;
906 struct enumerator_base {
907 unsigned dim;
908 evalue ** vE;
909 evalue mone;
910 vertex_decomposer *vpd;
912 enumerator_base(unsigned dim, vertex_decomposer *vpd)
914 this->dim = dim;
915 this->vpd = vpd;
917 vE = new evalue_p[vpd->nbV];
918 for (int j = 0; j < vpd->nbV; ++j)
919 vE[j] = 0;
921 value_init(mone.d);
922 evalue_set_si(&mone, -1, 1);
925 void decompose_at(Param_Vertices *V, int _i, barvinok_options *options) {
926 //this->pVD = pVD;
928 vE[_i] = new evalue;
929 value_init(vE[_i]->d);
930 evalue_set_si(vE[_i], 0, 1);
932 vpd->decompose_at_vertex(V, _i, options);
935 virtual ~enumerator_base() {
936 for (int j = 0; j < vpd->nbV; ++j)
937 if (vE[j]) {
938 free_evalue_refs(vE[j]);
939 delete vE[j];
941 delete [] vE;
943 free_evalue_refs(&mone);
946 static enumerator_base *create(Polyhedron *P, unsigned dim, unsigned nbV,
947 barvinok_options *options);
950 struct enumerator : public signed_cone_consumer, public vertex_decomposer,
951 public enumerator_base {
952 vec_ZZ lambda;
953 vec_ZZ den;
954 ZZ sign;
955 term_info num;
956 Vector *c;
957 mpq_t count;
959 enumerator(Polyhedron *P, unsigned dim, unsigned nbV) :
960 vertex_decomposer(P, nbV, *this), enumerator_base(dim, this) {
961 this->P = P;
962 this->nbV = nbV;
963 randomvector(P, lambda, dim);
964 den.SetLength(dim);
965 c = Vector_Alloc(dim+2);
967 mpq_init(count);
970 ~enumerator() {
971 mpq_clear(count);
972 Vector_Free(c);
975 virtual void handle(const signed_cone& sc, barvinok_options *options);
978 void enumerator::handle(const signed_cone& sc, barvinok_options *options)
980 assert(sc.det == 1);
981 assert(!sc.closed);
982 int r = 0;
983 assert(sc.rays.NumRows() == dim);
984 for (int k = 0; k < dim; ++k) {
985 if (lambda * sc.rays[k] == 0)
986 throw Orthogonal;
989 sign = sc.sign;
991 lattice_point(V, sc.rays, lambda, &num, 0, options);
992 den = sc.rays * lambda;
993 normalize(sign, num.constant, den);
995 dpoly n(dim, den[0], 1);
996 for (int k = 1; k < dim; ++k) {
997 dpoly fact(dim, den[k], 1);
998 n *= fact;
1000 if (num.E != NULL) {
1001 ZZ one(INIT_VAL, 1);
1002 dpoly_n d(dim, num.constant, one);
1003 d.div(n, c, sign);
1004 evalue EV;
1005 multi_polynom(c, num.E, &EV);
1006 eadd(&EV , vE[vert]);
1007 free_evalue_refs(&EV);
1008 free_evalue_refs(num.E);
1009 delete num.E;
1010 } else if (num.pos != -1) {
1011 dpoly_n d(dim, num.constant, num.coeff);
1012 d.div(n, c, sign);
1013 evalue EV;
1014 uni_polynom(num.pos, c, &EV);
1015 eadd(&EV , vE[vert]);
1016 free_evalue_refs(&EV);
1017 } else {
1018 mpq_set_si(count, 0, 1);
1019 dpoly d(dim, num.constant);
1020 d.div(n, count, sign);
1021 evalue EV;
1022 value_init(EV.d);
1023 evalue_set(&EV, &count[0]._mp_num, &count[0]._mp_den);
1024 eadd(&EV , vE[vert]);
1025 free_evalue_refs(&EV);
1029 struct ienumerator_base : enumerator_base {
1030 evalue ** E_vertex;
1032 ienumerator_base(unsigned dim, vertex_decomposer *vpd) :
1033 enumerator_base(dim,vpd) {
1034 E_vertex = new evalue_p[dim];
1037 virtual ~ienumerator_base() {
1038 delete [] E_vertex;
1041 evalue *E_num(int i, int d) {
1042 return E_vertex[i + (dim-d)];
1046 struct cumulator {
1047 evalue *factor;
1048 evalue *v;
1049 dpoly_r *r;
1051 cumulator(evalue *factor, evalue *v, dpoly_r *r) :
1052 factor(factor), v(v), r(r) {}
1054 void cumulate(barvinok_options *options);
1056 virtual void add_term(const vector<int>& powers, evalue *f2) = 0;
1057 virtual ~cumulator() {}
1060 void cumulator::cumulate(barvinok_options *options)
1062 evalue cum; // factor * 1 * E_num[0]/1 * (E_num[0]-1)/2 *...
1063 evalue f;
1064 evalue t; // E_num[0] - (m-1)
1065 evalue *cst;
1066 evalue mone;
1068 if (options->lookup_table) {
1069 value_init(mone.d);
1070 evalue_set_si(&mone, -1, 1);
1073 value_init(cum.d);
1074 evalue_copy(&cum, factor);
1075 value_init(f.d);
1076 value_init(f.x.n);
1077 value_set_si(f.d, 1);
1078 value_set_si(f.x.n, 1);
1079 value_init(t.d);
1080 evalue_copy(&t, v);
1082 if (!options->lookup_table) {
1083 for (cst = &t; value_zero_p(cst->d); ) {
1084 if (cst->x.p->type == fractional)
1085 cst = &cst->x.p->arr[1];
1086 else
1087 cst = &cst->x.p->arr[0];
1091 for (int m = 0; m < r->len; ++m) {
1092 if (m > 0) {
1093 if (m > 1) {
1094 value_set_si(f.d, m);
1095 emul(&f, &cum);
1096 if (!options->lookup_table)
1097 value_subtract(cst->x.n, cst->x.n, cst->d);
1098 else
1099 eadd(&mone, &t);
1101 emul(&t, &cum);
1103 dpoly_r_term_list& current = r->c[r->len-1-m];
1104 dpoly_r_term_list::iterator j;
1105 for (j = current.begin(); j != current.end(); ++j) {
1106 if ((*j)->coeff == 0)
1107 continue;
1108 evalue *f2 = new evalue;
1109 value_init(f2->d);
1110 value_init(f2->x.n);
1111 zz2value((*j)->coeff, f2->x.n);
1112 zz2value(r->denom, f2->d);
1113 emul(&cum, f2);
1115 add_term((*j)->powers, f2);
1118 free_evalue_refs(&f);
1119 free_evalue_refs(&t);
1120 free_evalue_refs(&cum);
1121 if (options->lookup_table)
1122 free_evalue_refs(&mone);
1125 struct E_poly_term {
1126 vector<int> powers;
1127 evalue *E;
1130 struct ie_cum : public cumulator {
1131 vector<E_poly_term *> terms;
1133 ie_cum(evalue *factor, evalue *v, dpoly_r *r) : cumulator(factor, v, r) {}
1135 virtual void add_term(const vector<int>& powers, evalue *f2);
1138 void ie_cum::add_term(const vector<int>& powers, evalue *f2)
1140 int k;
1141 for (k = 0; k < terms.size(); ++k) {
1142 if (terms[k]->powers == powers) {
1143 eadd(f2, terms[k]->E);
1144 free_evalue_refs(f2);
1145 delete f2;
1146 break;
1149 if (k >= terms.size()) {
1150 E_poly_term *ET = new E_poly_term;
1151 ET->powers = powers;
1152 ET->E = f2;
1153 terms.push_back(ET);
1157 struct ienumerator : public signed_cone_consumer, public vertex_decomposer,
1158 public ienumerator_base {
1159 //Polyhedron *pVD;
1160 mat_ZZ den;
1161 mat_ZZ vertex;
1162 mpq_t tcount;
1164 ienumerator(Polyhedron *P, unsigned dim, unsigned nbV) :
1165 vertex_decomposer(P, nbV, *this), ienumerator_base(dim, this) {
1166 vertex.SetDims(1, dim);
1168 den.SetDims(dim, dim);
1169 mpq_init(tcount);
1172 ~ienumerator() {
1173 mpq_clear(tcount);
1176 virtual void handle(const signed_cone& sc, barvinok_options *options);
1177 void reduce(evalue *factor, const mat_ZZ& num, const mat_ZZ& den_f,
1178 barvinok_options *options);
1181 void ienumerator::reduce(evalue *factor, const mat_ZZ& num, const mat_ZZ& den_f,
1182 barvinok_options *options)
1184 unsigned len = den_f.NumRows(); // number of factors in den
1185 unsigned dim = num.NumCols();
1186 assert(num.NumRows() == 1);
1188 if (dim == 0) {
1189 eadd(factor, vE[vert]);
1190 return;
1193 vec_ZZ den_s;
1194 mat_ZZ den_r;
1195 vec_ZZ num_s;
1196 mat_ZZ num_p;
1198 split_one(num, num_s, num_p, den_f, den_s, den_r);
1200 vec_ZZ den_p;
1201 den_p.SetLength(len);
1203 ZZ one;
1204 one = 1;
1205 normalize(one, num_s, num_p, den_s, den_p, den_r);
1206 if (one != 1)
1207 emul(&mone, factor);
1209 int only_param = 0;
1210 int no_param = 0;
1211 for (int k = 0; k < len; ++k) {
1212 if (den_p[k] == 0)
1213 ++no_param;
1214 else if (den_s[k] == 0)
1215 ++only_param;
1217 if (no_param == 0) {
1218 reduce(factor, num_p, den_r, options);
1219 } else {
1220 int k, l;
1221 mat_ZZ pden;
1222 pden.SetDims(only_param, dim-1);
1224 for (k = 0, l = 0; k < len; ++k)
1225 if (den_s[k] == 0)
1226 pden[l++] = den_r[k];
1228 for (k = 0; k < len; ++k)
1229 if (den_p[k] == 0)
1230 break;
1232 dpoly n(no_param, num_s[0]);
1233 dpoly D(no_param, den_s[k], 1);
1234 for ( ; ++k < len; )
1235 if (den_p[k] == 0) {
1236 dpoly fact(no_param, den_s[k], 1);
1237 D *= fact;
1240 dpoly_r * r = 0;
1241 // if no_param + only_param == len then all powers
1242 // below will be all zero
1243 if (no_param + only_param == len) {
1244 if (E_num(0, dim) != 0)
1245 r = new dpoly_r(n, len);
1246 else {
1247 mpq_set_si(tcount, 0, 1);
1248 one = 1;
1249 n.div(D, tcount, one);
1251 if (value_notzero_p(mpq_numref(tcount))) {
1252 evalue f;
1253 value_init(f.d);
1254 value_init(f.x.n);
1255 value_assign(f.x.n, mpq_numref(tcount));
1256 value_assign(f.d, mpq_denref(tcount));
1257 emul(&f, factor);
1258 reduce(factor, num_p, pden, options);
1259 free_evalue_refs(&f);
1261 return;
1263 } else {
1264 for (k = 0; k < len; ++k) {
1265 if (den_s[k] == 0 || den_p[k] == 0)
1266 continue;
1268 dpoly pd(no_param-1, den_s[k], 1);
1270 int l;
1271 for (l = 0; l < k; ++l)
1272 if (den_r[l] == den_r[k])
1273 break;
1275 if (r == 0)
1276 r = new dpoly_r(n, pd, l, len);
1277 else {
1278 dpoly_r *nr = new dpoly_r(r, pd, l, len);
1279 delete r;
1280 r = nr;
1284 dpoly_r *rc = r->div(D);
1285 delete r;
1286 r = rc;
1287 if (E_num(0, dim) == 0) {
1288 int common = pden.NumRows();
1289 dpoly_r_term_list& final = r->c[r->len-1];
1290 int rows;
1291 evalue t;
1292 evalue f;
1293 value_init(f.d);
1294 value_init(f.x.n);
1295 zz2value(r->denom, f.d);
1296 dpoly_r_term_list::iterator j;
1297 for (j = final.begin(); j != final.end(); ++j) {
1298 if ((*j)->coeff == 0)
1299 continue;
1300 rows = common;
1301 for (int k = 0; k < r->dim; ++k) {
1302 int n = (*j)->powers[k];
1303 if (n == 0)
1304 continue;
1305 pden.SetDims(rows+n, pden.NumCols());
1306 for (int l = 0; l < n; ++l)
1307 pden[rows+l] = den_r[k];
1308 rows += n;
1310 value_init(t.d);
1311 evalue_copy(&t, factor);
1312 zz2value((*j)->coeff, f.x.n);
1313 emul(&f, &t);
1314 reduce(&t, num_p, pden, options);
1315 free_evalue_refs(&t);
1317 free_evalue_refs(&f);
1318 } else {
1319 ie_cum cum(factor, E_num(0, dim), r);
1320 cum.cumulate(options);
1322 int common = pden.NumRows();
1323 int rows;
1324 for (int j = 0; j < cum.terms.size(); ++j) {
1325 rows = common;
1326 pden.SetDims(rows, pden.NumCols());
1327 for (int k = 0; k < r->dim; ++k) {
1328 int n = cum.terms[j]->powers[k];
1329 if (n == 0)
1330 continue;
1331 pden.SetDims(rows+n, pden.NumCols());
1332 for (int l = 0; l < n; ++l)
1333 pden[rows+l] = den_r[k];
1334 rows += n;
1336 reduce(cum.terms[j]->E, num_p, pden, options);
1337 free_evalue_refs(cum.terms[j]->E);
1338 delete cum.terms[j]->E;
1339 delete cum.terms[j];
1342 delete r;
1346 static int type_offset(enode *p)
1348 return p->type == fractional ? 1 :
1349 p->type == flooring ? 1 : 0;
1352 static int edegree(evalue *e)
1354 int d = 0;
1355 enode *p;
1357 if (value_notzero_p(e->d))
1358 return 0;
1360 p = e->x.p;
1361 int i = type_offset(p);
1362 if (p->size-i-1 > d)
1363 d = p->size - i - 1;
1364 for (; i < p->size; i++) {
1365 int d2 = edegree(&p->arr[i]);
1366 if (d2 > d)
1367 d = d2;
1369 return d;
1372 void ienumerator::handle(const signed_cone& sc, barvinok_options *options)
1374 assert(sc.det == 1);
1375 assert(!sc.closed);
1376 assert(sc.rays.NumRows() == dim);
1378 lattice_point(V, sc.rays, vertex[0], E_vertex, options);
1380 den = sc.rays;
1382 evalue one;
1383 value_init(one.d);
1384 evalue_set_si(&one, sc.sign, 1);
1385 reduce(&one, vertex, den, options);
1386 free_evalue_refs(&one);
1388 for (int i = 0; i < dim; ++i)
1389 if (E_vertex[i]) {
1390 free_evalue_refs(E_vertex[i]);
1391 delete E_vertex[i];
1395 struct bfenumerator : public vertex_decomposer, public bf_base,
1396 public ienumerator_base {
1397 evalue *factor;
1399 bfenumerator(Polyhedron *P, unsigned dim, unsigned nbV) :
1400 vertex_decomposer(P, nbV, *this),
1401 bf_base(dim), ienumerator_base(dim, this) {
1402 lower = 0;
1403 factor = NULL;
1406 ~bfenumerator() {
1409 virtual void handle(const signed_cone& sc, barvinok_options *options);
1410 virtual void base(mat_ZZ& factors, bfc_vec& v);
1412 bfc_term_base* new_bf_term(int len) {
1413 bfe_term* t = new bfe_term(len);
1414 return t;
1417 virtual void set_factor(bfc_term_base *t, int k, int change) {
1418 bfe_term* bfet = static_cast<bfe_term *>(t);
1419 factor = bfet->factors[k];
1420 assert(factor != NULL);
1421 bfet->factors[k] = NULL;
1422 if (change)
1423 emul(&mone, factor);
1426 virtual void set_factor(bfc_term_base *t, int k, mpq_t &q, int change) {
1427 bfe_term* bfet = static_cast<bfe_term *>(t);
1428 factor = bfet->factors[k];
1429 assert(factor != NULL);
1430 bfet->factors[k] = NULL;
1432 evalue f;
1433 value_init(f.d);
1434 value_init(f.x.n);
1435 if (change)
1436 value_oppose(f.x.n, mpq_numref(q));
1437 else
1438 value_assign(f.x.n, mpq_numref(q));
1439 value_assign(f.d, mpq_denref(q));
1440 emul(&f, factor);
1441 free_evalue_refs(&f);
1444 virtual void set_factor(bfc_term_base *t, int k, const QQ& c, int change) {
1445 bfe_term* bfet = static_cast<bfe_term *>(t);
1447 factor = new evalue;
1449 evalue f;
1450 value_init(f.d);
1451 value_init(f.x.n);
1452 zz2value(c.n, f.x.n);
1453 if (change)
1454 value_oppose(f.x.n, f.x.n);
1455 zz2value(c.d, f.d);
1457 value_init(factor->d);
1458 evalue_copy(factor, bfet->factors[k]);
1459 emul(&f, factor);
1460 free_evalue_refs(&f);
1463 void set_factor(evalue *f, int change) {
1464 if (change)
1465 emul(&mone, f);
1466 factor = f;
1469 virtual void insert_term(bfc_term_base *t, int i) {
1470 bfe_term* bfet = static_cast<bfe_term *>(t);
1471 int len = t->terms.NumRows()-1; // already increased by one
1473 bfet->factors.resize(len+1);
1474 for (int j = len; j > i; --j) {
1475 bfet->factors[j] = bfet->factors[j-1];
1476 t->terms[j] = t->terms[j-1];
1478 bfet->factors[i] = factor;
1479 factor = NULL;
1482 virtual void update_term(bfc_term_base *t, int i) {
1483 bfe_term* bfet = static_cast<bfe_term *>(t);
1485 eadd(factor, bfet->factors[i]);
1486 free_evalue_refs(factor);
1487 delete factor;
1490 virtual bool constant_vertex(int dim) { return E_num(0, dim) == 0; }
1492 virtual void cum(bf_reducer *bfr, bfc_term_base *t, int k, dpoly_r *r,
1493 barvinok_options *options);
1496 enumerator_base *enumerator_base::create(Polyhedron *P, unsigned dim, unsigned nbV,
1497 barvinok_options *options)
1499 enumerator_base *eb;
1501 if (options->incremental_specialization == BV_SPECIALIZATION_BF)
1502 eb = new bfenumerator(P, dim, nbV);
1503 else if (options->incremental_specialization == BV_SPECIALIZATION_DF)
1504 eb = new ienumerator(P, dim, nbV);
1505 else
1506 eb = new enumerator(P, dim, nbV);
1508 return eb;
1511 struct bfe_cum : public cumulator {
1512 bfenumerator *bfe;
1513 bfc_term_base *told;
1514 int k;
1515 bf_reducer *bfr;
1517 bfe_cum(evalue *factor, evalue *v, dpoly_r *r, bf_reducer *bfr,
1518 bfc_term_base *t, int k, bfenumerator *e) :
1519 cumulator(factor, v, r), told(t), k(k),
1520 bfr(bfr), bfe(e) {
1523 virtual void add_term(const vector<int>& powers, evalue *f2);
1526 void bfe_cum::add_term(const vector<int>& powers, evalue *f2)
1528 bfr->update_powers(powers);
1530 bfc_term_base * t = bfe->find_bfc_term(bfr->vn, bfr->npowers, bfr->nnf);
1531 bfe->set_factor(f2, bfr->l_changes % 2);
1532 bfe->add_term(t, told->terms[k], bfr->l_extra_num);
1535 void bfenumerator::cum(bf_reducer *bfr, bfc_term_base *t, int k,
1536 dpoly_r *r, barvinok_options *options)
1538 bfe_term* bfet = static_cast<bfe_term *>(t);
1539 bfe_cum cum(bfet->factors[k], E_num(0, bfr->d), r, bfr, t, k, this);
1540 cum.cumulate(options);
1543 void bfenumerator::base(mat_ZZ& factors, bfc_vec& v)
1545 for (int i = 0; i < v.size(); ++i) {
1546 assert(v[i]->terms.NumRows() == 1);
1547 evalue *factor = static_cast<bfe_term *>(v[i])->factors[0];
1548 eadd(factor, vE[vert]);
1549 delete v[i];
1553 void bfenumerator::handle(const signed_cone& sc, barvinok_options *options)
1555 assert(sc.det == 1);
1556 assert(!sc.closed);
1557 assert(sc.rays.NumRows() == enumerator_base::dim);
1559 bfe_term* t = new bfe_term(enumerator_base::dim);
1560 vector< bfc_term_base * > v;
1561 v.push_back(t);
1563 t->factors.resize(1);
1565 t->terms.SetDims(1, enumerator_base::dim);
1566 lattice_point(V, sc.rays, t->terms[0], E_vertex, options);
1568 // the elements of factors are always lexpositive
1569 mat_ZZ factors;
1570 int s = setup_factors(sc.rays, factors, t, sc.sign);
1572 t->factors[0] = new evalue;
1573 value_init(t->factors[0]->d);
1574 evalue_set_si(t->factors[0], s, 1);
1575 reduce(factors, v, options);
1577 for (int i = 0; i < enumerator_base::dim; ++i)
1578 if (E_vertex[i]) {
1579 free_evalue_refs(E_vertex[i]);
1580 delete E_vertex[i];
1584 static inline Param_Polyhedron *Polyhedron2Param_MR(Polyhedron *Din,
1585 Polyhedron *Cin, int WS)
1587 if (WS & POL_NO_DUAL)
1588 WS = 0;
1589 return Polyhedron2Param_Domain(Din, Cin, WS);
1592 static evalue* barvinok_enumerate_ev_f(Polyhedron *P, Polyhedron* C,
1593 barvinok_options *options);
1595 /* Destroys C */
1596 static evalue* barvinok_enumerate_cst(Polyhedron *P, Polyhedron* C,
1597 struct barvinok_options *options)
1599 evalue *eres;
1601 ALLOC(evalue, eres);
1602 value_init(eres->d);
1603 value_set_si(eres->d, 0);
1604 eres->x.p = new_enode(partition, 2, C->Dimension);
1605 EVALUE_SET_DOMAIN(eres->x.p->arr[0],
1606 DomainConstraintSimplify(C, options->MaxRays));
1607 value_set_si(eres->x.p->arr[1].d, 1);
1608 value_init(eres->x.p->arr[1].x.n);
1609 if (emptyQ2(P))
1610 value_set_si(eres->x.p->arr[1].x.n, 0);
1611 else
1612 barvinok_count_with_options(P, &eres->x.p->arr[1].x.n, options);
1614 return eres;
1617 /* frees P */
1618 static evalue* enumerate(Polyhedron *P, Polyhedron* C,
1619 struct barvinok_options *options)
1621 //P = unfringe(P, MaxRays);
1622 Polyhedron *next;
1623 Polyhedron *Corig = C;
1624 Polyhedron *CEq = NULL, *rVD;
1625 int r = 0;
1626 unsigned nparam = C->Dimension;
1627 evalue *eres;
1628 Matrix *CP = NULL;
1630 evalue factor;
1631 value_init(factor.d);
1632 evalue_set_si(&factor, 1, 1);
1634 /* for now */
1635 POL_ENSURE_FACETS(P);
1636 POL_ENSURE_VERTICES(P);
1637 POL_ENSURE_FACETS(C);
1638 POL_ENSURE_VERTICES(C);
1640 if (C->Dimension == 0 || emptyQ(P)) {
1641 constant:
1642 eres = barvinok_enumerate_cst(P, CEq ? CEq : Polyhedron_Copy(C), options);
1643 out:
1644 if (CP) {
1645 evalue_backsubstitute(eres, CP, options->MaxRays);
1646 Matrix_Free(CP);
1649 emul(&factor, eres);
1650 if (options->approximation_method == BV_APPROX_DROP) {
1651 if (options->polynomial_approximation == BV_APPROX_SIGN_UPPER)
1652 evalue_frac2polynomial(eres, 1, options->MaxRays);
1653 if (options->polynomial_approximation == BV_APPROX_SIGN_LOWER)
1654 evalue_frac2polynomial(eres, -1, options->MaxRays);
1655 if (options->polynomial_approximation == BV_APPROX_SIGN_APPROX)
1656 evalue_frac2polynomial(eres, 0, options->MaxRays);
1658 reduce_evalue(eres);
1659 free_evalue_refs(&factor);
1660 Domain_Free(P);
1661 if (C != Corig)
1662 Polyhedron_Free(C);
1664 return eres;
1666 if (Polyhedron_is_unbounded(P, nparam, options->MaxRays))
1667 goto constant;
1669 if (P->NbEq != 0) {
1670 Matrix *f;
1671 P = remove_equalities_p(P, P->Dimension-nparam, &f);
1672 mask(f, &factor, options);
1673 Matrix_Free(f);
1675 if (P->Dimension == nparam) {
1676 CEq = P;
1677 P = Universe_Polyhedron(0);
1678 goto constant;
1680 if (P->NbEq != 0) {
1681 Polyhedron *Q = P;
1682 Polyhedron *D = C;
1683 remove_all_equalities(&Q, &C, &CP, NULL, nparam, options->MaxRays);
1684 if (C != D && D != Corig)
1685 Polyhedron_Free(D);
1686 eres = enumerate(Q, C, options);
1687 goto out;
1690 Polyhedron *T = Polyhedron_Factor(P, nparam, NULL, options->MaxRays);
1691 if (T || (P->Dimension == nparam+1)) {
1692 Polyhedron *Q;
1693 Polyhedron *C2;
1694 for (Q = T ? T : P; Q; Q = Q->next) {
1695 Polyhedron *next = Q->next;
1696 Q->next = NULL;
1698 Polyhedron *QC = Q;
1699 if (Q->Dimension != C->Dimension)
1700 QC = Polyhedron_Project(Q, nparam);
1702 C2 = C;
1703 C = DomainIntersection(C, QC, options->MaxRays);
1704 if (C2 != Corig)
1705 Polyhedron_Free(C2);
1706 if (QC != Q)
1707 Polyhedron_Free(QC);
1709 Q->next = next;
1712 if (T) {
1713 Polyhedron_Free(P);
1714 P = T;
1715 if (T->Dimension == C->Dimension) {
1716 P = T->next;
1717 T->next = NULL;
1718 Polyhedron_Free(T);
1722 next = P->next;
1723 P->next = NULL;
1724 eres = barvinok_enumerate_ev_f(P, C, options);
1725 P->next = next;
1727 if (P->next) {
1728 Polyhedron *Q;
1729 evalue *f;
1731 for (Q = P->next; Q; Q = Q->next) {
1732 Polyhedron *next = Q->next;
1733 Q->next = NULL;
1735 f = barvinok_enumerate_ev_f(Q, C, options);
1736 emul(f, eres);
1737 free_evalue_refs(f);
1738 free(f);
1740 Q->next = next;
1744 goto out;
1747 evalue* barvinok_enumerate_with_options(Polyhedron *P, Polyhedron* C,
1748 struct barvinok_options *options)
1750 Polyhedron *next, *Cnext, *CA;
1751 Polyhedron *Porig = P;
1752 evalue *eres;
1754 if (P->next)
1755 fprintf(stderr,
1756 "barvinok_enumerate: input is a union; only first polyhedron is enumerated\n");
1758 if (C->next)
1759 fprintf(stderr,
1760 "barvinok_enumerate: context is a union; only first polyhedron is considered\n");
1762 Cnext = C->next;
1763 C->next = NULL;
1764 CA = align_context(C, P->Dimension, options->MaxRays);
1765 next = P->next;
1766 P->next = NULL;
1767 P = DomainIntersection(P, CA, options->MaxRays);
1768 Porig->next = next;
1769 Polyhedron_Free(CA);
1771 eres = enumerate(P, C, options);
1773 C->next = Cnext;
1775 return eres;
1778 evalue* barvinok_enumerate_ev(Polyhedron *P, Polyhedron* C, unsigned MaxRays)
1780 evalue *E;
1781 barvinok_options *options = barvinok_options_new_with_defaults();
1782 options->MaxRays = MaxRays;
1783 E = barvinok_enumerate_with_options(P, C, options);
1784 barvinok_options_free(options);
1785 return E;
1788 evalue *Param_Polyhedron_Enumerate(Param_Polyhedron *PP, Polyhedron *P,
1789 Polyhedron *C,
1790 struct barvinok_options *options)
1792 evalue *eres;
1793 Param_Domain *D;
1794 unsigned nparam = C->Dimension;
1795 unsigned dim = P->Dimension - nparam;
1797 ALLOC(evalue, eres);
1798 value_init(eres->d);
1799 value_set_si(eres->d, 0);
1801 int nd;
1802 for (nd = 0, D=PP->D; D; ++nd, D=D->next);
1803 struct section { Polyhedron *D; evalue E; };
1804 section *s = new section[nd];
1806 enumerator_base *et = NULL;
1807 try_again:
1808 if (et)
1809 delete et;
1811 et = enumerator_base::create(P, dim, PP->nbV, options);
1813 Polyhedron *TC = true_context(P, C, options->MaxRays);
1814 FORALL_REDUCED_DOMAIN(PP, TC, nd, options, i, D, rVD)
1815 Param_Vertices *V;
1817 value_init(s[i].E.d);
1818 evalue_set_si(&s[i].E, 0, 1);
1819 s[i].D = rVD;
1821 FORALL_PVertex_in_ParamPolyhedron(V,D,PP) // _i is internal counter
1822 if (!et->vE[_i])
1823 try {
1824 et->decompose_at(V, _i, options);
1825 } catch (OrthogonalException &e) {
1826 FORALL_REDUCED_DOMAIN_RESET;
1827 for (; i >= 0; --i) {
1828 free_evalue_refs(&s[i].E);
1829 Domain_Free(s[i].D);
1831 goto try_again;
1833 eadd(et->vE[_i] , &s[i].E);
1834 END_FORALL_PVertex_in_ParamPolyhedron;
1835 evalue_range_reduction_in_domain(&s[i].E, rVD);
1836 END_FORALL_REDUCED_DOMAIN
1837 Polyhedron_Free(TC);
1839 delete et;
1840 if (nd == 0)
1841 evalue_set_si(eres, 0, 1);
1842 else {
1843 eres->x.p = new_enode(partition, 2*nd, C->Dimension);
1844 for (int j = 0; j < nd; ++j) {
1845 EVALUE_SET_DOMAIN(eres->x.p->arr[2*j], s[j].D);
1846 value_clear(eres->x.p->arr[2*j+1].d);
1847 eres->x.p->arr[2*j+1] = s[j].E;
1850 delete [] s;
1852 return eres;
1855 static evalue* barvinok_enumerate_ev_f(Polyhedron *P, Polyhedron* C,
1856 barvinok_options *options)
1858 unsigned nparam = C->Dimension;
1859 bool do_scale = options->approximation_method == BV_APPROX_SCALE;
1861 if (options->approximation_method == BV_APPROX_VOLUME)
1862 return Param_Polyhedron_Volume(P, C, options);
1864 if (P->Dimension - nparam == 1 && !do_scale)
1865 return ParamLine_Length(P, C, options);
1867 Param_Polyhedron *PP = NULL;
1868 evalue *eres;
1870 if (do_scale) {
1871 eres = scale_bound(P, C, options);
1872 if (eres)
1873 return eres;
1876 PP = Polyhedron2Param_MR(P, C, options->MaxRays);
1878 if (do_scale)
1879 eres = scale(PP, P, C, options);
1880 else
1881 eres = Param_Polyhedron_Enumerate(PP, P, C, options);
1883 if (PP)
1884 Param_Polyhedron_Free(PP);
1886 return eres;
1889 Enumeration* barvinok_enumerate(Polyhedron *P, Polyhedron* C, unsigned MaxRays)
1891 evalue *EP = barvinok_enumerate_ev(P, C, MaxRays);
1893 return partition2enumeration(EP);
1896 static void SwapColumns(Value **V, int n, int i, int j)
1898 for (int r = 0; r < n; ++r)
1899 value_swap(V[r][i], V[r][j]);
1902 static void SwapColumns(Polyhedron *P, int i, int j)
1904 SwapColumns(P->Constraint, P->NbConstraints, i, j);
1905 SwapColumns(P->Ray, P->NbRays, i, j);
1908 /* Construct a constraint c from constraints l and u such that if
1909 * if constraint c holds then for each value of the other variables
1910 * there is at most one value of variable pos (position pos+1 in the constraints).
1912 * Given a lower and an upper bound
1913 * n_l v_i + <c_l,x> + c_l >= 0
1914 * -n_u v_i + <c_u,x> + c_u >= 0
1915 * the constructed constraint is
1917 * -(n_l<c_u,x> + n_u<c_l,x>) + (-n_l c_u - n_u c_l + n_l n_u - 1)
1919 * which is then simplified to remove the content of the non-constant coefficients
1921 * len is the total length of the constraints.
1922 * v is a temporary variable that can be used by this procedure
1924 static void negative_test_constraint(Value *l, Value *u, Value *c, int pos,
1925 int len, Value *v)
1927 value_oppose(*v, u[pos+1]);
1928 Vector_Combine(l+1, u+1, c+1, *v, l[pos+1], len-1);
1929 value_multiply(*v, *v, l[pos+1]);
1930 value_subtract(c[len-1], c[len-1], *v);
1931 value_set_si(*v, -1);
1932 Vector_Scale(c+1, c+1, *v, len-1);
1933 value_decrement(c[len-1], c[len-1]);
1934 ConstraintSimplify(c, c, len, v);
1937 static bool parallel_constraints(Value *l, Value *u, Value *c, int pos,
1938 int len)
1940 bool parallel;
1941 Value g1;
1942 Value g2;
1943 value_init(g1);
1944 value_init(g2);
1946 Vector_Gcd(&l[1+pos], len, &g1);
1947 Vector_Gcd(&u[1+pos], len, &g2);
1948 Vector_Combine(l+1+pos, u+1+pos, c+1, g2, g1, len);
1949 parallel = First_Non_Zero(c+1, len) == -1;
1951 value_clear(g1);
1952 value_clear(g2);
1954 return parallel;
1957 static void negative_test_constraint7(Value *l, Value *u, Value *c, int pos,
1958 int exist, int len, Value *v)
1960 Value g;
1961 value_init(g);
1963 Vector_Gcd(&u[1+pos], exist, v);
1964 Vector_Gcd(&l[1+pos], exist, &g);
1965 Vector_Combine(l+1, u+1, c+1, *v, g, len-1);
1966 value_multiply(*v, *v, g);
1967 value_subtract(c[len-1], c[len-1], *v);
1968 value_set_si(*v, -1);
1969 Vector_Scale(c+1, c+1, *v, len-1);
1970 value_decrement(c[len-1], c[len-1]);
1971 ConstraintSimplify(c, c, len, v);
1973 value_clear(g);
1976 /* Turns a x + b >= 0 into a x + b <= -1
1978 * len is the total length of the constraint.
1979 * v is a temporary variable that can be used by this procedure
1981 static void oppose_constraint(Value *c, int len, Value *v)
1983 value_set_si(*v, -1);
1984 Vector_Scale(c+1, c+1, *v, len-1);
1985 value_decrement(c[len-1], c[len-1]);
1988 /* Split polyhedron P into two polyhedra *pos and *neg, where
1989 * existential variable i has at most one solution for each
1990 * value of the other variables in *neg.
1992 * The splitting is performed using constraints l and u.
1994 * nvar: number of set variables
1995 * row: temporary vector that can be used by this procedure
1996 * f: temporary value that can be used by this procedure
1998 static bool SplitOnConstraint(Polyhedron *P, int i, int l, int u,
1999 int nvar, int MaxRays, Vector *row, Value& f,
2000 Polyhedron **pos, Polyhedron **neg)
2002 negative_test_constraint(P->Constraint[l], P->Constraint[u],
2003 row->p, nvar+i, P->Dimension+2, &f);
2004 *neg = AddConstraints(row->p, 1, P, MaxRays);
2006 /* We found an independent, but useless constraint
2007 * Maybe we should detect this earlier and not
2008 * mark the variable as INDEPENDENT
2010 if (emptyQ((*neg))) {
2011 Polyhedron_Free(*neg);
2012 return false;
2015 oppose_constraint(row->p, P->Dimension+2, &f);
2016 *pos = AddConstraints(row->p, 1, P, MaxRays);
2018 if (emptyQ((*pos))) {
2019 Polyhedron_Free(*neg);
2020 Polyhedron_Free(*pos);
2021 return false;
2024 return true;
2028 * unimodularly transform P such that constraint r is transformed
2029 * into a constraint that involves only a single (the first)
2030 * existential variable
2033 static Polyhedron *rotate_along(Polyhedron *P, int r, int nvar, int exist,
2034 unsigned MaxRays)
2036 Value g;
2037 value_init(g);
2039 Vector *row = Vector_Alloc(exist);
2040 Vector_Copy(P->Constraint[r]+1+nvar, row->p, exist);
2041 Vector_Gcd(row->p, exist, &g);
2042 if (value_notone_p(g))
2043 Vector_AntiScale(row->p, row->p, g, exist);
2044 value_clear(g);
2046 Matrix *M = unimodular_complete(row);
2047 Matrix *M2 = Matrix_Alloc(P->Dimension+1, P->Dimension+1);
2048 for (r = 0; r < nvar; ++r)
2049 value_set_si(M2->p[r][r], 1);
2050 for ( ; r < nvar+exist; ++r)
2051 Vector_Copy(M->p[r-nvar], M2->p[r]+nvar, exist);
2052 for ( ; r < P->Dimension+1; ++r)
2053 value_set_si(M2->p[r][r], 1);
2054 Polyhedron *T = Polyhedron_Image(P, M2, MaxRays);
2056 Matrix_Free(M2);
2057 Matrix_Free(M);
2058 Vector_Free(row);
2060 return T;
2063 /* Split polyhedron P into two polyhedra *pos and *neg, where
2064 * existential variable i has at most one solution for each
2065 * value of the other variables in *neg.
2067 * If independent is set, then the two constraints on which the
2068 * split will be performed need to be independent of the other
2069 * existential variables.
2071 * Return true if an appropriate split could be performed.
2073 * nvar: number of set variables
2074 * exist: number of existential variables
2075 * row: temporary vector that can be used by this procedure
2076 * f: temporary value that can be used by this procedure
2078 static bool SplitOnVar(Polyhedron *P, int i,
2079 int nvar, int exist, int MaxRays,
2080 Vector *row, Value& f, bool independent,
2081 Polyhedron **pos, Polyhedron **neg)
2083 int j;
2085 for (int l = P->NbEq; l < P->NbConstraints; ++l) {
2086 if (value_negz_p(P->Constraint[l][nvar+i+1]))
2087 continue;
2089 if (independent) {
2090 for (j = 0; j < exist; ++j)
2091 if (j != i && value_notzero_p(P->Constraint[l][nvar+j+1]))
2092 break;
2093 if (j < exist)
2094 continue;
2097 for (int u = P->NbEq; u < P->NbConstraints; ++u) {
2098 if (value_posz_p(P->Constraint[u][nvar+i+1]))
2099 continue;
2101 if (independent) {
2102 for (j = 0; j < exist; ++j)
2103 if (j != i && value_notzero_p(P->Constraint[u][nvar+j+1]))
2104 break;
2105 if (j < exist)
2106 continue;
2109 if (SplitOnConstraint(P, i, l, u, nvar, MaxRays, row, f, pos, neg)) {
2110 if (independent) {
2111 if (i != 0)
2112 SwapColumns(*neg, nvar+1, nvar+1+i);
2114 return true;
2119 return false;
2122 static bool double_bound_pair(Polyhedron *P, int nvar, int exist,
2123 int i, int l1, int l2,
2124 Polyhedron **pos, Polyhedron **neg)
2126 Value f;
2127 value_init(f);
2128 Vector *row = Vector_Alloc(P->Dimension+2);
2129 value_set_si(row->p[0], 1);
2130 value_oppose(f, P->Constraint[l1][nvar+i+1]);
2131 Vector_Combine(P->Constraint[l1]+1, P->Constraint[l2]+1,
2132 row->p+1,
2133 P->Constraint[l2][nvar+i+1], f,
2134 P->Dimension+1);
2135 ConstraintSimplify(row->p, row->p, P->Dimension+2, &f);
2136 *pos = AddConstraints(row->p, 1, P, 0);
2137 value_set_si(f, -1);
2138 Vector_Scale(row->p+1, row->p+1, f, P->Dimension+1);
2139 value_decrement(row->p[P->Dimension+1], row->p[P->Dimension+1]);
2140 *neg = AddConstraints(row->p, 1, P, 0);
2141 Vector_Free(row);
2142 value_clear(f);
2144 return !emptyQ((*pos)) && !emptyQ((*neg));
2147 static bool double_bound(Polyhedron *P, int nvar, int exist,
2148 Polyhedron **pos, Polyhedron **neg)
2150 for (int i = 0; i < exist; ++i) {
2151 int l1, l2;
2152 for (l1 = P->NbEq; l1 < P->NbConstraints; ++l1) {
2153 if (value_negz_p(P->Constraint[l1][nvar+i+1]))
2154 continue;
2155 for (l2 = l1 + 1; l2 < P->NbConstraints; ++l2) {
2156 if (value_negz_p(P->Constraint[l2][nvar+i+1]))
2157 continue;
2158 if (double_bound_pair(P, nvar, exist, i, l1, l2, pos, neg))
2159 return true;
2162 for (l1 = P->NbEq; l1 < P->NbConstraints; ++l1) {
2163 if (value_posz_p(P->Constraint[l1][nvar+i+1]))
2164 continue;
2165 if (l1 < P->NbConstraints)
2166 for (l2 = l1 + 1; l2 < P->NbConstraints; ++l2) {
2167 if (value_posz_p(P->Constraint[l2][nvar+i+1]))
2168 continue;
2169 if (double_bound_pair(P, nvar, exist, i, l1, l2, pos, neg))
2170 return true;
2173 return false;
2175 return false;
2178 enum constraint {
2179 ALL_POS = 1 << 0,
2180 ONE_NEG = 1 << 1,
2181 INDEPENDENT = 1 << 2,
2182 ROT_NEG = 1 << 3
2185 static evalue* enumerate_or(Polyhedron *D,
2186 unsigned exist, unsigned nparam, barvinok_options *options)
2188 #ifdef DEBUG_ER
2189 fprintf(stderr, "\nER: Or\n");
2190 #endif /* DEBUG_ER */
2192 Polyhedron *N = D->next;
2193 D->next = 0;
2194 evalue *EP =
2195 barvinok_enumerate_e_with_options(D, exist, nparam, options);
2196 Polyhedron_Free(D);
2198 for (D = N; D; D = N) {
2199 N = D->next;
2200 D->next = 0;
2202 evalue *EN =
2203 barvinok_enumerate_e_with_options(D, exist, nparam, options);
2205 eor(EN, EP);
2206 free_evalue_refs(EN);
2207 free(EN);
2208 Polyhedron_Free(D);
2211 reduce_evalue(EP);
2213 return EP;
2216 static evalue* enumerate_sum(Polyhedron *P,
2217 unsigned exist, unsigned nparam, barvinok_options *options)
2219 int nvar = P->Dimension - exist - nparam;
2220 int toswap = nvar < exist ? nvar : exist;
2221 for (int i = 0; i < toswap; ++i)
2222 SwapColumns(P, 1 + i, nvar+exist - i);
2223 nparam += nvar;
2225 #ifdef DEBUG_ER
2226 fprintf(stderr, "\nER: Sum\n");
2227 #endif /* DEBUG_ER */
2229 evalue *EP = barvinok_enumerate_e_with_options(P, exist, nparam, options);
2231 evalue_split_domains_into_orthants(EP, options->MaxRays);
2232 reduce_evalue(EP);
2233 evalue_range_reduction(EP);
2235 evalue_frac2floor2(EP, 1);
2237 evalue *sum = esum(EP, nvar);
2239 free_evalue_refs(EP);
2240 free(EP);
2241 EP = sum;
2243 evalue_range_reduction(EP);
2245 return EP;
2248 static evalue* split_sure(Polyhedron *P, Polyhedron *S,
2249 unsigned exist, unsigned nparam, barvinok_options *options)
2251 int nvar = P->Dimension - exist - nparam;
2253 Matrix *M = Matrix_Alloc(exist, S->Dimension+2);
2254 for (int i = 0; i < exist; ++i)
2255 value_set_si(M->p[i][nvar+i+1], 1);
2256 Polyhedron *O = S;
2257 S = DomainAddRays(S, M, options->MaxRays);
2258 Polyhedron_Free(O);
2259 Polyhedron *F = DomainAddRays(P, M, options->MaxRays);
2260 Polyhedron *D = DomainDifference(F, S, options->MaxRays);
2261 O = D;
2262 D = Disjoint_Domain(D, 0, options->MaxRays);
2263 Polyhedron_Free(F);
2264 Domain_Free(O);
2265 Matrix_Free(M);
2267 M = Matrix_Alloc(P->Dimension+1-exist, P->Dimension+1);
2268 for (int j = 0; j < nvar; ++j)
2269 value_set_si(M->p[j][j], 1);
2270 for (int j = 0; j < nparam+1; ++j)
2271 value_set_si(M->p[nvar+j][nvar+exist+j], 1);
2272 Polyhedron *T = Polyhedron_Image(S, M, options->MaxRays);
2273 evalue *EP = barvinok_enumerate_e_with_options(T, 0, nparam, options);
2274 Polyhedron_Free(S);
2275 Polyhedron_Free(T);
2276 Matrix_Free(M);
2278 for (Polyhedron *Q = D; Q; Q = Q->next) {
2279 Polyhedron *N = Q->next;
2280 Q->next = 0;
2281 T = DomainIntersection(P, Q, options->MaxRays);
2282 evalue *E = barvinok_enumerate_e_with_options(T, exist, nparam, options);
2283 eadd(E, EP);
2284 free_evalue_refs(E);
2285 free(E);
2286 Polyhedron_Free(T);
2287 Q->next = N;
2289 Domain_Free(D);
2290 return EP;
2293 static evalue* enumerate_sure(Polyhedron *P,
2294 unsigned exist, unsigned nparam, barvinok_options *options)
2296 int i;
2297 Polyhedron *S = P;
2298 int nvar = P->Dimension - exist - nparam;
2299 Value lcm;
2300 Value f;
2301 value_init(lcm);
2302 value_init(f);
2304 for (i = 0; i < exist; ++i) {
2305 Matrix *M = Matrix_Alloc(S->NbConstraints, S->Dimension+2);
2306 int c = 0;
2307 value_set_si(lcm, 1);
2308 for (int j = 0; j < S->NbConstraints; ++j) {
2309 if (value_negz_p(S->Constraint[j][1+nvar+i]))
2310 continue;
2311 if (value_one_p(S->Constraint[j][1+nvar+i]))
2312 continue;
2313 value_lcm(lcm, S->Constraint[j][1+nvar+i], &lcm);
2316 for (int j = 0; j < S->NbConstraints; ++j) {
2317 if (value_negz_p(S->Constraint[j][1+nvar+i]))
2318 continue;
2319 if (value_one_p(S->Constraint[j][1+nvar+i]))
2320 continue;
2321 value_division(f, lcm, S->Constraint[j][1+nvar+i]);
2322 Vector_Scale(S->Constraint[j], M->p[c], f, S->Dimension+2);
2323 value_subtract(M->p[c][S->Dimension+1],
2324 M->p[c][S->Dimension+1],
2325 lcm);
2326 value_increment(M->p[c][S->Dimension+1],
2327 M->p[c][S->Dimension+1]);
2328 ++c;
2330 Polyhedron *O = S;
2331 S = AddConstraints(M->p[0], c, S, options->MaxRays);
2332 if (O != P)
2333 Polyhedron_Free(O);
2334 Matrix_Free(M);
2335 if (emptyQ(S)) {
2336 Polyhedron_Free(S);
2337 value_clear(lcm);
2338 value_clear(f);
2339 return 0;
2342 value_clear(lcm);
2343 value_clear(f);
2345 #ifdef DEBUG_ER
2346 fprintf(stderr, "\nER: Sure\n");
2347 #endif /* DEBUG_ER */
2349 return split_sure(P, S, exist, nparam, options);
2352 static evalue* enumerate_sure2(Polyhedron *P,
2353 unsigned exist, unsigned nparam, barvinok_options *options)
2355 int nvar = P->Dimension - exist - nparam;
2356 int r;
2357 for (r = 0; r < P->NbRays; ++r)
2358 if (value_one_p(P->Ray[r][0]) &&
2359 value_one_p(P->Ray[r][P->Dimension+1]))
2360 break;
2362 if (r >= P->NbRays)
2363 return 0;
2365 Matrix *M = Matrix_Alloc(nvar + 1 + nparam, P->Dimension+2);
2366 for (int i = 0; i < nvar; ++i)
2367 value_set_si(M->p[i][1+i], 1);
2368 for (int i = 0; i < nparam; ++i)
2369 value_set_si(M->p[i+nvar][1+nvar+exist+i], 1);
2370 Vector_Copy(P->Ray[r]+1+nvar, M->p[nvar+nparam]+1+nvar, exist);
2371 value_set_si(M->p[nvar+nparam][0], 1);
2372 value_set_si(M->p[nvar+nparam][P->Dimension+1], 1);
2373 Polyhedron * F = Rays2Polyhedron(M, options->MaxRays);
2374 Matrix_Free(M);
2376 Polyhedron *I = DomainIntersection(F, P, options->MaxRays);
2377 Polyhedron_Free(F);
2379 #ifdef DEBUG_ER
2380 fprintf(stderr, "\nER: Sure2\n");
2381 #endif /* DEBUG_ER */
2383 return split_sure(P, I, exist, nparam, options);
2386 static evalue* enumerate_cyclic(Polyhedron *P,
2387 unsigned exist, unsigned nparam,
2388 evalue * EP, int r, int p, unsigned MaxRays)
2390 int nvar = P->Dimension - exist - nparam;
2392 /* If EP in its fractional maps only contains references
2393 * to the remainder parameter with appropriate coefficients
2394 * then we could in principle avoid adding existentially
2395 * quantified variables to the validity domains.
2396 * We'd have to replace the remainder by m { p/m }
2397 * and multiply with an appropriate factor that is one
2398 * only in the appropriate range.
2399 * This last multiplication can be avoided if EP
2400 * has a single validity domain with no (further)
2401 * constraints on the remainder parameter
2404 Matrix *CT = Matrix_Alloc(nparam+1, nparam+3);
2405 Matrix *M = Matrix_Alloc(1, 1+nparam+3);
2406 for (int j = 0; j < nparam; ++j)
2407 if (j != p)
2408 value_set_si(CT->p[j][j], 1);
2409 value_set_si(CT->p[p][nparam+1], 1);
2410 value_set_si(CT->p[nparam][nparam+2], 1);
2411 value_set_si(M->p[0][1+p], -1);
2412 value_absolute(M->p[0][1+nparam], P->Ray[0][1+nvar+exist+p]);
2413 value_set_si(M->p[0][1+nparam+1], 1);
2414 Polyhedron *CEq = Constraints2Polyhedron(M, 1);
2415 Matrix_Free(M);
2416 addeliminatedparams_enum(EP, CT, CEq, MaxRays, nparam);
2417 Polyhedron_Free(CEq);
2418 Matrix_Free(CT);
2420 return EP;
2423 static void enumerate_vd_add_ray(evalue *EP, Matrix *Rays, unsigned MaxRays)
2425 if (value_notzero_p(EP->d))
2426 return;
2428 assert(EP->x.p->type == partition);
2429 assert(EP->x.p->pos == EVALUE_DOMAIN(EP->x.p->arr[0])->Dimension);
2430 for (int i = 0; i < EP->x.p->size/2; ++i) {
2431 Polyhedron *D = EVALUE_DOMAIN(EP->x.p->arr[2*i]);
2432 Polyhedron *N = DomainAddRays(D, Rays, MaxRays);
2433 EVALUE_SET_DOMAIN(EP->x.p->arr[2*i], N);
2434 Domain_Free(D);
2438 static evalue* enumerate_line(Polyhedron *P,
2439 unsigned exist, unsigned nparam, barvinok_options *options)
2441 if (P->NbBid == 0)
2442 return 0;
2444 #ifdef DEBUG_ER
2445 fprintf(stderr, "\nER: Line\n");
2446 #endif /* DEBUG_ER */
2448 int nvar = P->Dimension - exist - nparam;
2449 int i, j;
2450 for (i = 0; i < nparam; ++i)
2451 if (value_notzero_p(P->Ray[0][1+nvar+exist+i]))
2452 break;
2453 assert(i < nparam);
2454 for (j = i+1; j < nparam; ++j)
2455 if (value_notzero_p(P->Ray[0][1+nvar+exist+i]))
2456 break;
2457 assert(j >= nparam); // for now
2459 Matrix *M = Matrix_Alloc(2, P->Dimension+2);
2460 value_set_si(M->p[0][0], 1);
2461 value_set_si(M->p[0][1+nvar+exist+i], 1);
2462 value_set_si(M->p[1][0], 1);
2463 value_set_si(M->p[1][1+nvar+exist+i], -1);
2464 value_absolute(M->p[1][1+P->Dimension], P->Ray[0][1+nvar+exist+i]);
2465 value_decrement(M->p[1][1+P->Dimension], M->p[1][1+P->Dimension]);
2466 Polyhedron *S = AddConstraints(M->p[0], 2, P, options->MaxRays);
2467 evalue *EP = barvinok_enumerate_e_with_options(S, exist, nparam, options);
2468 Polyhedron_Free(S);
2469 Matrix_Free(M);
2471 return enumerate_cyclic(P, exist, nparam, EP, 0, i, options->MaxRays);
2474 static int single_param_pos(Polyhedron*P, unsigned exist, unsigned nparam,
2475 int r)
2477 int nvar = P->Dimension - exist - nparam;
2478 if (First_Non_Zero(P->Ray[r]+1, nvar) != -1)
2479 return -1;
2480 int i = First_Non_Zero(P->Ray[r]+1+nvar+exist, nparam);
2481 if (i == -1)
2482 return -1;
2483 if (First_Non_Zero(P->Ray[r]+1+nvar+exist+1, nparam-i-1) != -1)
2484 return -1;
2485 return i;
2488 static evalue* enumerate_remove_ray(Polyhedron *P, int r,
2489 unsigned exist, unsigned nparam, barvinok_options *options)
2491 #ifdef DEBUG_ER
2492 fprintf(stderr, "\nER: RedundantRay\n");
2493 #endif /* DEBUG_ER */
2495 Value one;
2496 value_init(one);
2497 value_set_si(one, 1);
2498 int len = P->NbRays-1;
2499 Matrix *M = Matrix_Alloc(2 * len, P->Dimension+2);
2500 Vector_Copy(P->Ray[0], M->p[0], r * (P->Dimension+2));
2501 Vector_Copy(P->Ray[r+1], M->p[r], (len-r) * (P->Dimension+2));
2502 for (int j = 0; j < P->NbRays; ++j) {
2503 if (j == r)
2504 continue;
2505 Vector_Combine(P->Ray[j], P->Ray[r], M->p[len+j-(j>r)],
2506 one, P->Ray[j][P->Dimension+1], P->Dimension+2);
2509 P = Rays2Polyhedron(M, options->MaxRays);
2510 Matrix_Free(M);
2511 evalue *EP = barvinok_enumerate_e_with_options(P, exist, nparam, options);
2512 Polyhedron_Free(P);
2513 value_clear(one);
2515 return EP;
2518 static evalue* enumerate_redundant_ray(Polyhedron *P,
2519 unsigned exist, unsigned nparam, barvinok_options *options)
2521 assert(P->NbBid == 0);
2522 int nvar = P->Dimension - exist - nparam;
2523 Value m;
2524 value_init(m);
2526 for (int r = 0; r < P->NbRays; ++r) {
2527 if (value_notzero_p(P->Ray[r][P->Dimension+1]))
2528 continue;
2529 int i1 = single_param_pos(P, exist, nparam, r);
2530 if (i1 == -1)
2531 continue;
2532 for (int r2 = r+1; r2 < P->NbRays; ++r2) {
2533 if (value_notzero_p(P->Ray[r2][P->Dimension+1]))
2534 continue;
2535 int i2 = single_param_pos(P, exist, nparam, r2);
2536 if (i2 == -1)
2537 continue;
2538 if (i1 != i2)
2539 continue;
2541 value_division(m, P->Ray[r][1+nvar+exist+i1],
2542 P->Ray[r2][1+nvar+exist+i1]);
2543 value_multiply(m, m, P->Ray[r2][1+nvar+exist+i1]);
2544 /* r2 divides r => r redundant */
2545 if (value_eq(m, P->Ray[r][1+nvar+exist+i1])) {
2546 value_clear(m);
2547 return enumerate_remove_ray(P, r, exist, nparam, options);
2550 value_division(m, P->Ray[r2][1+nvar+exist+i1],
2551 P->Ray[r][1+nvar+exist+i1]);
2552 value_multiply(m, m, P->Ray[r][1+nvar+exist+i1]);
2553 /* r divides r2 => r2 redundant */
2554 if (value_eq(m, P->Ray[r2][1+nvar+exist+i1])) {
2555 value_clear(m);
2556 return enumerate_remove_ray(P, r2, exist, nparam, options);
2560 value_clear(m);
2561 return 0;
2564 static Polyhedron *upper_bound(Polyhedron *P,
2565 int pos, Value *max, Polyhedron **R)
2567 Value v;
2568 int r;
2569 value_init(v);
2571 *R = 0;
2572 Polyhedron *N;
2573 Polyhedron *B = 0;
2574 for (Polyhedron *Q = P; Q; Q = N) {
2575 N = Q->next;
2576 for (r = 0; r < P->NbRays; ++r) {
2577 if (value_zero_p(P->Ray[r][P->Dimension+1]) &&
2578 value_pos_p(P->Ray[r][1+pos]))
2579 break;
2581 if (r < P->NbRays) {
2582 Q->next = *R;
2583 *R = Q;
2584 continue;
2585 } else {
2586 Q->next = B;
2587 B = Q;
2589 for (r = 0; r < P->NbRays; ++r) {
2590 if (value_zero_p(P->Ray[r][P->Dimension+1]))
2591 continue;
2592 mpz_fdiv_q(v, P->Ray[r][1+pos], P->Ray[r][1+P->Dimension]);
2593 if ((!Q->next && r == 0) || value_gt(v, *max))
2594 value_assign(*max, v);
2597 value_clear(v);
2598 return B;
2601 static evalue* enumerate_ray(Polyhedron *P,
2602 unsigned exist, unsigned nparam, barvinok_options *options)
2604 assert(P->NbBid == 0);
2605 int nvar = P->Dimension - exist - nparam;
2607 int r;
2608 for (r = 0; r < P->NbRays; ++r)
2609 if (value_zero_p(P->Ray[r][P->Dimension+1]))
2610 break;
2611 if (r >= P->NbRays)
2612 return 0;
2614 int r2;
2615 for (r2 = r+1; r2 < P->NbRays; ++r2)
2616 if (value_zero_p(P->Ray[r2][P->Dimension+1]))
2617 break;
2618 if (r2 < P->NbRays) {
2619 if (nvar > 0)
2620 return enumerate_sum(P, exist, nparam, options);
2623 #ifdef DEBUG_ER
2624 fprintf(stderr, "\nER: Ray\n");
2625 #endif /* DEBUG_ER */
2627 Value m;
2628 Value one;
2629 value_init(m);
2630 value_init(one);
2631 value_set_si(one, 1);
2632 int i = single_param_pos(P, exist, nparam, r);
2633 assert(i != -1); // for now;
2635 Matrix *M = Matrix_Alloc(P->NbRays, P->Dimension+2);
2636 for (int j = 0; j < P->NbRays; ++j) {
2637 Vector_Combine(P->Ray[j], P->Ray[r], M->p[j],
2638 one, P->Ray[j][P->Dimension+1], P->Dimension+2);
2640 Polyhedron *S = Rays2Polyhedron(M, options->MaxRays);
2641 Matrix_Free(M);
2642 Polyhedron *D = DomainDifference(P, S, options->MaxRays);
2643 Polyhedron_Free(S);
2644 // Polyhedron_Print(stderr, P_VALUE_FMT, D);
2645 assert(value_pos_p(P->Ray[r][1+nvar+exist+i])); // for now
2646 Polyhedron *R;
2647 D = upper_bound(D, nvar+exist+i, &m, &R);
2648 assert(D);
2649 Domain_Free(D);
2651 M = Matrix_Alloc(2, P->Dimension+2);
2652 value_set_si(M->p[0][0], 1);
2653 value_set_si(M->p[1][0], 1);
2654 value_set_si(M->p[0][1+nvar+exist+i], -1);
2655 value_set_si(M->p[1][1+nvar+exist+i], 1);
2656 value_assign(M->p[0][1+P->Dimension], m);
2657 value_oppose(M->p[1][1+P->Dimension], m);
2658 value_addto(M->p[1][1+P->Dimension], M->p[1][1+P->Dimension],
2659 P->Ray[r][1+nvar+exist+i]);
2660 value_decrement(M->p[1][1+P->Dimension], M->p[1][1+P->Dimension]);
2661 // Matrix_Print(stderr, P_VALUE_FMT, M);
2662 D = AddConstraints(M->p[0], 2, P, options->MaxRays);
2663 // Polyhedron_Print(stderr, P_VALUE_FMT, D);
2664 value_subtract(M->p[0][1+P->Dimension], M->p[0][1+P->Dimension],
2665 P->Ray[r][1+nvar+exist+i]);
2666 // Matrix_Print(stderr, P_VALUE_FMT, M);
2667 S = AddConstraints(M->p[0], 1, P, options->MaxRays);
2668 // Polyhedron_Print(stderr, P_VALUE_FMT, S);
2669 Matrix_Free(M);
2671 evalue *EP = barvinok_enumerate_e_with_options(D, exist, nparam, options);
2672 Polyhedron_Free(D);
2673 value_clear(one);
2674 value_clear(m);
2676 if (value_notone_p(P->Ray[r][1+nvar+exist+i]))
2677 EP = enumerate_cyclic(P, exist, nparam, EP, r, i, options->MaxRays);
2678 else {
2679 M = Matrix_Alloc(1, nparam+2);
2680 value_set_si(M->p[0][0], 1);
2681 value_set_si(M->p[0][1+i], 1);
2682 enumerate_vd_add_ray(EP, M, options->MaxRays);
2683 Matrix_Free(M);
2686 if (!emptyQ(S)) {
2687 evalue *E = barvinok_enumerate_e_with_options(S, exist, nparam, options);
2688 eadd(E, EP);
2689 free_evalue_refs(E);
2690 free(E);
2692 Polyhedron_Free(S);
2694 if (R) {
2695 assert(nvar == 0);
2696 evalue *ER = enumerate_or(R, exist, nparam, options);
2697 eor(ER, EP);
2698 free_evalue_refs(ER);
2699 free(ER);
2702 return EP;
2705 static evalue* enumerate_vd(Polyhedron **PA,
2706 unsigned exist, unsigned nparam, barvinok_options *options)
2708 Polyhedron *P = *PA;
2709 int nvar = P->Dimension - exist - nparam;
2710 Param_Polyhedron *PP = NULL;
2711 Polyhedron *C = Universe_Polyhedron(nparam);
2712 Polyhedron *CEq;
2713 Matrix *CT;
2714 Polyhedron *PR = P;
2715 PP = Polyhedron2Param_Domain(PR,C, options->MaxRays);
2716 Polyhedron_Free(C);
2718 int nd;
2719 Param_Domain *D, *last;
2720 Value c;
2721 value_init(c);
2722 for (nd = 0, D=PP->D; D; D=D->next, ++nd)
2725 Polyhedron **VD = new Polyhedron_p[nd];
2726 Polyhedron *TC = true_context(P, C, options->MaxRays);
2727 FORALL_REDUCED_DOMAIN(PP, TC, nd, options, i, D, rVD)
2728 VD[nd++] = rVD;
2729 last = D;
2730 END_FORALL_REDUCED_DOMAIN
2731 Polyhedron_Free(TC);
2733 evalue *EP = 0;
2735 if (nd == 0)
2736 EP = evalue_zero();
2738 /* This doesn't seem to have any effect */
2739 if (nd == 1) {
2740 Polyhedron *CA = align_context(VD[0], P->Dimension, options->MaxRays);
2741 Polyhedron *O = P;
2742 P = DomainIntersection(P, CA, options->MaxRays);
2743 if (O != *PA)
2744 Polyhedron_Free(O);
2745 Polyhedron_Free(CA);
2746 if (emptyQ(P))
2747 EP = evalue_zero();
2750 if (PR != *PA)
2751 Polyhedron_Free(PR);
2752 PR = 0;
2754 if (!EP && nd > 1) {
2755 #ifdef DEBUG_ER
2756 fprintf(stderr, "\nER: VD\n");
2757 #endif /* DEBUG_ER */
2758 for (int i = 0; i < nd; ++i) {
2759 Polyhedron *CA = align_context(VD[i], P->Dimension, options->MaxRays);
2760 Polyhedron *I = DomainIntersection(P, CA, options->MaxRays);
2762 if (i == 0)
2763 EP = barvinok_enumerate_e_with_options(I, exist, nparam, options);
2764 else {
2765 evalue *E = barvinok_enumerate_e_with_options(I, exist, nparam,
2766 options);
2767 eadd(E, EP);
2768 free_evalue_refs(E);
2769 free(E);
2771 Polyhedron_Free(I);
2772 Polyhedron_Free(CA);
2776 for (int i = 0; i < nd; ++i)
2777 Polyhedron_Free(VD[i]);
2778 delete [] VD;
2779 value_clear(c);
2781 if (!EP && nvar == 0) {
2782 Value f;
2783 value_init(f);
2784 Param_Vertices *V, *V2;
2785 Matrix* M = Matrix_Alloc(1, P->Dimension+2);
2787 FORALL_PVertex_in_ParamPolyhedron(V, last, PP) {
2788 bool found = false;
2789 FORALL_PVertex_in_ParamPolyhedron(V2, last, PP) {
2790 if (V == V2) {
2791 found = true;
2792 continue;
2794 if (!found)
2795 continue;
2796 for (int i = 0; i < exist; ++i) {
2797 value_oppose(f, V->Vertex->p[i][nparam+1]);
2798 Vector_Combine(V->Vertex->p[i],
2799 V2->Vertex->p[i],
2800 M->p[0] + 1 + nvar + exist,
2801 V2->Vertex->p[i][nparam+1],
2803 nparam+1);
2804 int j;
2805 for (j = 0; j < nparam; ++j)
2806 if (value_notzero_p(M->p[0][1+nvar+exist+j]))
2807 break;
2808 if (j >= nparam)
2809 continue;
2810 ConstraintSimplify(M->p[0], M->p[0],
2811 P->Dimension+2, &f);
2812 value_set_si(M->p[0][0], 0);
2813 Polyhedron *para = AddConstraints(M->p[0], 1, P,
2814 options->MaxRays);
2815 if (emptyQ(para)) {
2816 Polyhedron_Free(para);
2817 continue;
2819 Polyhedron *pos, *neg;
2820 value_set_si(M->p[0][0], 1);
2821 value_decrement(M->p[0][P->Dimension+1],
2822 M->p[0][P->Dimension+1]);
2823 neg = AddConstraints(M->p[0], 1, P, options->MaxRays);
2824 value_set_si(f, -1);
2825 Vector_Scale(M->p[0]+1, M->p[0]+1, f,
2826 P->Dimension+1);
2827 value_decrement(M->p[0][P->Dimension+1],
2828 M->p[0][P->Dimension+1]);
2829 value_decrement(M->p[0][P->Dimension+1],
2830 M->p[0][P->Dimension+1]);
2831 pos = AddConstraints(M->p[0], 1, P, options->MaxRays);
2832 if (emptyQ(neg) && emptyQ(pos)) {
2833 Polyhedron_Free(para);
2834 Polyhedron_Free(pos);
2835 Polyhedron_Free(neg);
2836 continue;
2838 #ifdef DEBUG_ER
2839 fprintf(stderr, "\nER: Order\n");
2840 #endif /* DEBUG_ER */
2841 EP = barvinok_enumerate_e_with_options(para, exist, nparam,
2842 options);
2843 evalue *E;
2844 if (!emptyQ(pos)) {
2845 E = barvinok_enumerate_e_with_options(pos, exist, nparam,
2846 options);
2847 eadd(E, EP);
2848 free_evalue_refs(E);
2849 free(E);
2851 if (!emptyQ(neg)) {
2852 E = barvinok_enumerate_e_with_options(neg, exist, nparam,
2853 options);
2854 eadd(E, EP);
2855 free_evalue_refs(E);
2856 free(E);
2858 Polyhedron_Free(para);
2859 Polyhedron_Free(pos);
2860 Polyhedron_Free(neg);
2861 break;
2863 if (EP)
2864 break;
2865 } END_FORALL_PVertex_in_ParamPolyhedron;
2866 if (EP)
2867 break;
2868 } END_FORALL_PVertex_in_ParamPolyhedron;
2870 if (!EP) {
2871 /* Search for vertex coordinate to split on */
2872 /* First look for one independent of the parameters */
2873 FORALL_PVertex_in_ParamPolyhedron(V, last, PP) {
2874 for (int i = 0; i < exist; ++i) {
2875 int j;
2876 for (j = 0; j < nparam; ++j)
2877 if (value_notzero_p(V->Vertex->p[i][j]))
2878 break;
2879 if (j < nparam)
2880 continue;
2881 value_set_si(M->p[0][0], 1);
2882 Vector_Set(M->p[0]+1, 0, nvar+exist);
2883 Vector_Copy(V->Vertex->p[i],
2884 M->p[0] + 1 + nvar + exist, nparam+1);
2885 value_oppose(M->p[0][1+nvar+i],
2886 V->Vertex->p[i][nparam+1]);
2888 Polyhedron *pos, *neg;
2889 value_set_si(M->p[0][0], 1);
2890 value_decrement(M->p[0][P->Dimension+1],
2891 M->p[0][P->Dimension+1]);
2892 neg = AddConstraints(M->p[0], 1, P, options->MaxRays);
2893 value_set_si(f, -1);
2894 Vector_Scale(M->p[0]+1, M->p[0]+1, f,
2895 P->Dimension+1);
2896 value_decrement(M->p[0][P->Dimension+1],
2897 M->p[0][P->Dimension+1]);
2898 value_decrement(M->p[0][P->Dimension+1],
2899 M->p[0][P->Dimension+1]);
2900 pos = AddConstraints(M->p[0], 1, P, options->MaxRays);
2901 if (emptyQ(neg) || emptyQ(pos)) {
2902 Polyhedron_Free(pos);
2903 Polyhedron_Free(neg);
2904 continue;
2906 Polyhedron_Free(pos);
2907 value_increment(M->p[0][P->Dimension+1],
2908 M->p[0][P->Dimension+1]);
2909 pos = AddConstraints(M->p[0], 1, P, options->MaxRays);
2910 #ifdef DEBUG_ER
2911 fprintf(stderr, "\nER: Vertex\n");
2912 #endif /* DEBUG_ER */
2913 pos->next = neg;
2914 EP = enumerate_or(pos, exist, nparam, options);
2915 break;
2917 if (EP)
2918 break;
2919 } END_FORALL_PVertex_in_ParamPolyhedron;
2922 if (!EP) {
2923 /* Search for vertex coordinate to split on */
2924 /* Now look for one that depends on the parameters */
2925 FORALL_PVertex_in_ParamPolyhedron(V, last, PP) {
2926 for (int i = 0; i < exist; ++i) {
2927 value_set_si(M->p[0][0], 1);
2928 Vector_Set(M->p[0]+1, 0, nvar+exist);
2929 Vector_Copy(V->Vertex->p[i],
2930 M->p[0] + 1 + nvar + exist, nparam+1);
2931 value_oppose(M->p[0][1+nvar+i],
2932 V->Vertex->p[i][nparam+1]);
2934 Polyhedron *pos, *neg;
2935 value_set_si(M->p[0][0], 1);
2936 value_decrement(M->p[0][P->Dimension+1],
2937 M->p[0][P->Dimension+1]);
2938 neg = AddConstraints(M->p[0], 1, P, options->MaxRays);
2939 value_set_si(f, -1);
2940 Vector_Scale(M->p[0]+1, M->p[0]+1, f,
2941 P->Dimension+1);
2942 value_decrement(M->p[0][P->Dimension+1],
2943 M->p[0][P->Dimension+1]);
2944 value_decrement(M->p[0][P->Dimension+1],
2945 M->p[0][P->Dimension+1]);
2946 pos = AddConstraints(M->p[0], 1, P, options->MaxRays);
2947 if (emptyQ(neg) || emptyQ(pos)) {
2948 Polyhedron_Free(pos);
2949 Polyhedron_Free(neg);
2950 continue;
2952 Polyhedron_Free(pos);
2953 value_increment(M->p[0][P->Dimension+1],
2954 M->p[0][P->Dimension+1]);
2955 pos = AddConstraints(M->p[0], 1, P, options->MaxRays);
2956 #ifdef DEBUG_ER
2957 fprintf(stderr, "\nER: ParamVertex\n");
2958 #endif /* DEBUG_ER */
2959 pos->next = neg;
2960 EP = enumerate_or(pos, exist, nparam, options);
2961 break;
2963 if (EP)
2964 break;
2965 } END_FORALL_PVertex_in_ParamPolyhedron;
2968 Matrix_Free(M);
2969 value_clear(f);
2972 if (CEq)
2973 Polyhedron_Free(CEq);
2974 if (CT)
2975 Matrix_Free(CT);
2976 if (PP)
2977 Param_Polyhedron_Free(PP);
2978 *PA = P;
2980 return EP;
2983 evalue* barvinok_enumerate_pip(Polyhedron *P, unsigned exist, unsigned nparam,
2984 unsigned MaxRays)
2986 evalue *E;
2987 barvinok_options *options = barvinok_options_new_with_defaults();
2988 options->MaxRays = MaxRays;
2989 E = barvinok_enumerate_pip_with_options(P, exist, nparam, options);
2990 barvinok_options_free(options);
2991 return E;
2994 #ifndef HAVE_PIPLIB
2995 evalue *barvinok_enumerate_pip_with_options(Polyhedron *P,
2996 unsigned exist, unsigned nparam, struct barvinok_options *options)
2998 return 0;
3000 #else
3001 evalue *barvinok_enumerate_pip_with_options(Polyhedron *P,
3002 unsigned exist, unsigned nparam, struct barvinok_options *options)
3004 int nvar = P->Dimension - exist - nparam;
3005 evalue *EP = evalue_zero();
3006 Polyhedron *Q, *N;
3008 #ifdef DEBUG_ER
3009 fprintf(stderr, "\nER: PIP\n");
3010 #endif /* DEBUG_ER */
3012 Polyhedron *D = pip_projectout(P, nvar, exist, nparam);
3013 for (Q = D; Q; Q = N) {
3014 N = Q->next;
3015 Q->next = 0;
3016 evalue *E;
3017 exist = Q->Dimension - nvar - nparam;
3018 E = barvinok_enumerate_e_with_options(Q, exist, nparam, options);
3019 Polyhedron_Free(Q);
3020 eadd(E, EP);
3021 free_evalue_refs(E);
3022 free(E);
3025 return EP;
3027 #endif
3030 static bool is_single(Value *row, int pos, int len)
3032 return First_Non_Zero(row, pos) == -1 &&
3033 First_Non_Zero(row+pos+1, len-pos-1) == -1;
3036 static evalue* barvinok_enumerate_e_r(Polyhedron *P,
3037 unsigned exist, unsigned nparam, barvinok_options *options);
3039 #ifdef DEBUG_ER
3040 static int er_level = 0;
3042 evalue* barvinok_enumerate_e_with_options(Polyhedron *P,
3043 unsigned exist, unsigned nparam, barvinok_options *options)
3045 fprintf(stderr, "\nER: level %i\n", er_level);
3047 Polyhedron_PrintConstraints(stderr, P_VALUE_FMT, P);
3048 fprintf(stderr, "\nE %d\nP %d\n", exist, nparam);
3049 ++er_level;
3050 P = DomainConstraintSimplify(Polyhedron_Copy(P), options->MaxRays);
3051 evalue *EP = barvinok_enumerate_e_r(P, exist, nparam, options);
3052 Polyhedron_Free(P);
3053 --er_level;
3054 return EP;
3056 #else
3057 evalue* barvinok_enumerate_e_with_options(Polyhedron *P,
3058 unsigned exist, unsigned nparam, barvinok_options *options)
3060 P = DomainConstraintSimplify(Polyhedron_Copy(P), options->MaxRays);
3061 evalue *EP = barvinok_enumerate_e_r(P, exist, nparam, options);
3062 Polyhedron_Free(P);
3063 return EP;
3065 #endif
3067 evalue* barvinok_enumerate_e(Polyhedron *P, unsigned exist, unsigned nparam,
3068 unsigned MaxRays)
3070 evalue *E;
3071 barvinok_options *options = barvinok_options_new_with_defaults();
3072 options->MaxRays = MaxRays;
3073 E = barvinok_enumerate_e_with_options(P, exist, nparam, options);
3074 barvinok_options_free(options);
3075 return E;
3078 static evalue* barvinok_enumerate_e_r(Polyhedron *P,
3079 unsigned exist, unsigned nparam, barvinok_options *options)
3081 if (exist == 0) {
3082 Polyhedron *U = Universe_Polyhedron(nparam);
3083 evalue *EP = barvinok_enumerate_with_options(P, U, options);
3084 //char *param_name[] = {"P", "Q", "R", "S", "T" };
3085 //print_evalue(stdout, EP, param_name);
3086 Polyhedron_Free(U);
3087 return EP;
3090 int nvar = P->Dimension - exist - nparam;
3091 int len = P->Dimension + 2;
3093 /* for now */
3094 POL_ENSURE_FACETS(P);
3095 POL_ENSURE_VERTICES(P);
3097 if (emptyQ(P))
3098 return evalue_zero();
3100 if (nvar == 0 && nparam == 0) {
3101 evalue *EP = evalue_zero();
3102 barvinok_count_with_options(P, &EP->x.n, options);
3103 if (value_pos_p(EP->x.n))
3104 value_set_si(EP->x.n, 1);
3105 return EP;
3108 int r;
3109 for (r = 0; r < P->NbRays; ++r)
3110 if (value_zero_p(P->Ray[r][0]) ||
3111 value_zero_p(P->Ray[r][P->Dimension+1])) {
3112 int i;
3113 for (i = 0; i < nvar; ++i)
3114 if (value_notzero_p(P->Ray[r][i+1]))
3115 break;
3116 if (i >= nvar)
3117 continue;
3118 for (i = nvar + exist; i < nvar + exist + nparam; ++i)
3119 if (value_notzero_p(P->Ray[r][i+1]))
3120 break;
3121 if (i >= nvar + exist + nparam)
3122 break;
3124 if (r < P->NbRays) {
3125 evalue *EP = evalue_zero();
3126 value_set_si(EP->x.n, -1);
3127 return EP;
3130 int first;
3131 for (r = 0; r < P->NbEq; ++r)
3132 if ((first = First_Non_Zero(P->Constraint[r]+1+nvar, exist)) != -1)
3133 break;
3134 if (r < P->NbEq) {
3135 if (First_Non_Zero(P->Constraint[r]+1+nvar+first+1,
3136 exist-first-1) != -1) {
3137 Polyhedron *T = rotate_along(P, r, nvar, exist, options->MaxRays);
3138 #ifdef DEBUG_ER
3139 fprintf(stderr, "\nER: Equality\n");
3140 #endif /* DEBUG_ER */
3141 evalue *EP = barvinok_enumerate_e_with_options(T, exist-1, nparam,
3142 options);
3143 Polyhedron_Free(T);
3144 return EP;
3145 } else {
3146 #ifdef DEBUG_ER
3147 fprintf(stderr, "\nER: Fixed\n");
3148 #endif /* DEBUG_ER */
3149 if (first == 0)
3150 return barvinok_enumerate_e_with_options(P, exist-1, nparam,
3151 options);
3152 else {
3153 Polyhedron *T = Polyhedron_Copy(P);
3154 SwapColumns(T, nvar+1, nvar+1+first);
3155 evalue *EP = barvinok_enumerate_e_with_options(T, exist-1, nparam,
3156 options);
3157 Polyhedron_Free(T);
3158 return EP;
3163 Vector *row = Vector_Alloc(len);
3164 value_set_si(row->p[0], 1);
3166 Value f;
3167 value_init(f);
3169 enum constraint* info = new constraint[exist];
3170 for (int i = 0; i < exist; ++i) {
3171 info[i] = ALL_POS;
3172 for (int l = P->NbEq; l < P->NbConstraints; ++l) {
3173 if (value_negz_p(P->Constraint[l][nvar+i+1]))
3174 continue;
3175 bool l_parallel = is_single(P->Constraint[l]+nvar+1, i, exist);
3176 for (int u = P->NbEq; u < P->NbConstraints; ++u) {
3177 if (value_posz_p(P->Constraint[u][nvar+i+1]))
3178 continue;
3179 bool lu_parallel = l_parallel ||
3180 is_single(P->Constraint[u]+nvar+1, i, exist);
3181 value_oppose(f, P->Constraint[u][nvar+i+1]);
3182 Vector_Combine(P->Constraint[l]+1, P->Constraint[u]+1, row->p+1,
3183 f, P->Constraint[l][nvar+i+1], len-1);
3184 if (!(info[i] & INDEPENDENT)) {
3185 int j;
3186 for (j = 0; j < exist; ++j)
3187 if (j != i && value_notzero_p(row->p[nvar+j+1]))
3188 break;
3189 if (j == exist) {
3190 //printf("independent: i: %d, l: %d, u: %d\n", i, l, u);
3191 info[i] = (constraint)(info[i] | INDEPENDENT);
3194 if (info[i] & ALL_POS) {
3195 value_addto(row->p[len-1], row->p[len-1],
3196 P->Constraint[l][nvar+i+1]);
3197 value_addto(row->p[len-1], row->p[len-1], f);
3198 value_multiply(f, f, P->Constraint[l][nvar+i+1]);
3199 value_subtract(row->p[len-1], row->p[len-1], f);
3200 value_decrement(row->p[len-1], row->p[len-1]);
3201 ConstraintSimplify(row->p, row->p, len, &f);
3202 value_set_si(f, -1);
3203 Vector_Scale(row->p+1, row->p+1, f, len-1);
3204 value_decrement(row->p[len-1], row->p[len-1]);
3205 Polyhedron *T = AddConstraints(row->p, 1, P, options->MaxRays);
3206 if (!emptyQ(T)) {
3207 //printf("not all_pos: i: %d, l: %d, u: %d\n", i, l, u);
3208 info[i] = (constraint)(info[i] ^ ALL_POS);
3210 //puts("pos remainder");
3211 //Polyhedron_Print(stdout, P_VALUE_FMT, T);
3212 Polyhedron_Free(T);
3214 if (!(info[i] & ONE_NEG)) {
3215 if (lu_parallel) {
3216 negative_test_constraint(P->Constraint[l],
3217 P->Constraint[u],
3218 row->p, nvar+i, len, &f);
3219 oppose_constraint(row->p, len, &f);
3220 Polyhedron *T = AddConstraints(row->p, 1, P,
3221 options->MaxRays);
3222 if (emptyQ(T)) {
3223 //printf("one_neg i: %d, l: %d, u: %d\n", i, l, u);
3224 info[i] = (constraint)(info[i] | ONE_NEG);
3226 //puts("neg remainder");
3227 //Polyhedron_Print(stdout, P_VALUE_FMT, T);
3228 Polyhedron_Free(T);
3229 } else if (!(info[i] & ROT_NEG)) {
3230 if (parallel_constraints(P->Constraint[l],
3231 P->Constraint[u],
3232 row->p, nvar, exist)) {
3233 negative_test_constraint7(P->Constraint[l],
3234 P->Constraint[u],
3235 row->p, nvar, exist,
3236 len, &f);
3237 oppose_constraint(row->p, len, &f);
3238 Polyhedron *T = AddConstraints(row->p, 1, P,
3239 options->MaxRays);
3240 if (emptyQ(T)) {
3241 // printf("rot_neg i: %d, l: %d, u: %d\n", i, l, u);
3242 info[i] = (constraint)(info[i] | ROT_NEG);
3243 r = l;
3245 //puts("neg remainder");
3246 //Polyhedron_Print(stdout, P_VALUE_FMT, T);
3247 Polyhedron_Free(T);
3251 if (!(info[i] & ALL_POS) && (info[i] & (ONE_NEG | ROT_NEG)))
3252 goto next;
3255 if (info[i] & ALL_POS)
3256 break;
3257 next:
3262 for (int i = 0; i < exist; ++i)
3263 printf("%i: %i\n", i, info[i]);
3265 for (int i = 0; i < exist; ++i)
3266 if (info[i] & ALL_POS) {
3267 #ifdef DEBUG_ER
3268 fprintf(stderr, "\nER: Positive\n");
3269 #endif /* DEBUG_ER */
3270 // Eliminate
3271 // Maybe we should chew off some of the fat here
3272 Matrix *M = Matrix_Alloc(P->Dimension, P->Dimension+1);
3273 for (int j = 0; j < P->Dimension; ++j)
3274 value_set_si(M->p[j][j + (j >= i+nvar)], 1);
3275 Polyhedron *T = Polyhedron_Image(P, M, options->MaxRays);
3276 Matrix_Free(M);
3277 evalue *EP = barvinok_enumerate_e_with_options(T, exist-1, nparam,
3278 options);
3279 Polyhedron_Free(T);
3280 value_clear(f);
3281 Vector_Free(row);
3282 delete [] info;
3283 return EP;
3285 for (int i = 0; i < exist; ++i)
3286 if (info[i] & ONE_NEG) {
3287 #ifdef DEBUG_ER
3288 fprintf(stderr, "\nER: Negative\n");
3289 #endif /* DEBUG_ER */
3290 Vector_Free(row);
3291 value_clear(f);
3292 delete [] info;
3293 if (i == 0)
3294 return barvinok_enumerate_e_with_options(P, exist-1, nparam,
3295 options);
3296 else {
3297 Polyhedron *T = Polyhedron_Copy(P);
3298 SwapColumns(T, nvar+1, nvar+1+i);
3299 evalue *EP = barvinok_enumerate_e_with_options(T, exist-1, nparam,
3300 options);
3301 Polyhedron_Free(T);
3302 return EP;
3305 for (int i = 0; i < exist; ++i)
3306 if (info[i] & ROT_NEG) {
3307 #ifdef DEBUG_ER
3308 fprintf(stderr, "\nER: Rotate\n");
3309 #endif /* DEBUG_ER */
3310 Vector_Free(row);
3311 value_clear(f);
3312 delete [] info;
3313 Polyhedron *T = rotate_along(P, r, nvar, exist, options->MaxRays);
3314 evalue *EP = barvinok_enumerate_e_with_options(T, exist-1, nparam,
3315 options);
3316 Polyhedron_Free(T);
3317 return EP;
3319 for (int i = 0; i < exist; ++i)
3320 if (info[i] & INDEPENDENT) {
3321 Polyhedron *pos, *neg;
3323 /* Find constraint again and split off negative part */
3325 if (SplitOnVar(P, i, nvar, exist, options->MaxRays,
3326 row, f, true, &pos, &neg)) {
3327 #ifdef DEBUG_ER
3328 fprintf(stderr, "\nER: Split\n");
3329 #endif /* DEBUG_ER */
3331 evalue *EP =
3332 barvinok_enumerate_e_with_options(neg, exist-1, nparam, options);
3333 evalue *E =
3334 barvinok_enumerate_e_with_options(pos, exist, nparam, options);
3335 eadd(E, EP);
3336 free_evalue_refs(E);
3337 free(E);
3338 Polyhedron_Free(neg);
3339 Polyhedron_Free(pos);
3340 value_clear(f);
3341 Vector_Free(row);
3342 delete [] info;
3343 return EP;
3346 delete [] info;
3348 Polyhedron *O = P;
3349 Polyhedron *F;
3351 evalue *EP;
3353 EP = enumerate_line(P, exist, nparam, options);
3354 if (EP)
3355 goto out;
3357 EP = barvinok_enumerate_pip_with_options(P, exist, nparam, options);
3358 if (EP)
3359 goto out;
3361 EP = enumerate_redundant_ray(P, exist, nparam, options);
3362 if (EP)
3363 goto out;
3365 EP = enumerate_sure(P, exist, nparam, options);
3366 if (EP)
3367 goto out;
3369 EP = enumerate_ray(P, exist, nparam, options);
3370 if (EP)
3371 goto out;
3373 EP = enumerate_sure2(P, exist, nparam, options);
3374 if (EP)
3375 goto out;
3377 F = unfringe(P, options->MaxRays);
3378 if (!PolyhedronIncludes(F, P)) {
3379 #ifdef DEBUG_ER
3380 fprintf(stderr, "\nER: Fringed\n");
3381 #endif /* DEBUG_ER */
3382 EP = barvinok_enumerate_e_with_options(F, exist, nparam, options);
3383 Polyhedron_Free(F);
3384 goto out;
3386 Polyhedron_Free(F);
3388 if (nparam)
3389 EP = enumerate_vd(&P, exist, nparam, options);
3390 if (EP)
3391 goto out2;
3393 if (nvar != 0) {
3394 EP = enumerate_sum(P, exist, nparam, options);
3395 goto out2;
3398 assert(nvar == 0);
3400 int i;
3401 Polyhedron *pos, *neg;
3402 for (i = 0; i < exist; ++i)
3403 if (SplitOnVar(P, i, nvar, exist, options->MaxRays,
3404 row, f, false, &pos, &neg))
3405 break;
3407 assert (i < exist);
3409 pos->next = neg;
3410 EP = enumerate_or(pos, exist, nparam, options);
3412 out2:
3413 if (O != P)
3414 Polyhedron_Free(P);
3416 out:
3417 value_clear(f);
3418 Vector_Free(row);
3419 return EP;
3423 * remove equalities that require a "compression" of the parameters
3425 static Polyhedron *remove_more_equalities(Polyhedron *P, unsigned nparam,
3426 Matrix **CP, unsigned MaxRays)
3428 Polyhedron *Q = P;
3429 remove_all_equalities(&P, NULL, CP, NULL, nparam, MaxRays);
3430 if (P != Q)
3431 Polyhedron_Free(Q);
3432 return P;
3435 /* frees P */
3436 static gen_fun *series(Polyhedron *P, unsigned nparam, barvinok_options *options)
3438 Matrix *CP = NULL;
3439 gen_fun *gf;
3441 if (emptyQ2(P)) {
3442 Polyhedron_Free(P);
3443 return new gen_fun;
3446 assert(!Polyhedron_is_unbounded(P, nparam, options->MaxRays));
3447 assert(P->NbBid == 0);
3448 assert(Polyhedron_has_revlex_positive_rays(P, nparam));
3449 if (P->NbEq != 0)
3450 P = remove_more_equalities(P, nparam, &CP, options->MaxRays);
3451 assert(P->NbEq == 0);
3452 if (CP)
3453 nparam = CP->NbColumns-1;
3455 if (nparam == 0) {
3456 Value c;
3457 value_init(c);
3458 barvinok_count_with_options(P, &c, options);
3459 gf = new gen_fun(c);
3460 value_clear(c);
3461 } else {
3462 gf_base *red;
3463 red = gf_base::create(Polyhedron_Project(P, nparam),
3464 P->Dimension, nparam, options);
3465 POL_ENSURE_VERTICES(P);
3466 red->start_gf(P, options);
3467 gf = red->gf;
3468 delete red;
3470 if (CP) {
3471 gf->substitute(CP);
3472 Matrix_Free(CP);
3474 Polyhedron_Free(P);
3475 return gf;
3478 gen_fun * barvinok_series_with_options(Polyhedron *P, Polyhedron* C,
3479 barvinok_options *options)
3481 Polyhedron *CA;
3482 unsigned nparam = C->Dimension;
3483 gen_fun *gf;
3485 CA = align_context(C, P->Dimension, options->MaxRays);
3486 P = DomainIntersection(P, CA, options->MaxRays);
3487 Polyhedron_Free(CA);
3489 gf = series(P, nparam, options);
3491 return gf;
3494 gen_fun * barvinok_series(Polyhedron *P, Polyhedron* C, unsigned MaxRays)
3496 gen_fun *gf;
3497 barvinok_options *options = barvinok_options_new_with_defaults();
3498 options->MaxRays = MaxRays;
3499 gf = barvinok_series_with_options(P, C, options);
3500 barvinok_options_free(options);
3501 return gf;
3504 static Polyhedron *skew_into_positive_orthant(Polyhedron *D, unsigned nparam,
3505 unsigned MaxRays)
3507 Matrix *M = NULL;
3508 Value tmp;
3509 value_init(tmp);
3510 for (Polyhedron *P = D; P; P = P->next) {
3511 POL_ENSURE_VERTICES(P);
3512 assert(!Polyhedron_is_unbounded(P, nparam, MaxRays));
3513 assert(P->NbBid == 0);
3514 assert(Polyhedron_has_positive_rays(P, nparam));
3516 for (int r = 0; r < P->NbRays; ++r) {
3517 if (value_notzero_p(P->Ray[r][P->Dimension+1]))
3518 continue;
3519 for (int i = 0; i < nparam; ++i) {
3520 int j;
3521 if (value_posz_p(P->Ray[r][i+1]))
3522 continue;
3523 if (!M) {
3524 M = Matrix_Alloc(D->Dimension+1, D->Dimension+1);
3525 for (int i = 0; i < D->Dimension+1; ++i)
3526 value_set_si(M->p[i][i], 1);
3527 } else {
3528 Inner_Product(P->Ray[r]+1, M->p[i], D->Dimension+1, &tmp);
3529 if (value_posz_p(tmp))
3530 continue;
3532 for (j = P->Dimension - nparam; j < P->Dimension; ++j)
3533 if (value_pos_p(P->Ray[r][j+1]))
3534 break;
3535 assert(j < P->Dimension);
3536 value_pdivision(tmp, P->Ray[r][j+1], P->Ray[r][i+1]);
3537 value_subtract(M->p[i][j], M->p[i][j], tmp);
3541 value_clear(tmp);
3542 if (M) {
3543 D = DomainImage(D, M, MaxRays);
3544 Matrix_Free(M);
3546 return D;
3549 gen_fun* barvinok_enumerate_union_series_with_options(Polyhedron *D, Polyhedron* C,
3550 barvinok_options *options)
3552 Polyhedron *conv, *D2;
3553 Polyhedron *CA;
3554 gen_fun *gf = NULL, *gf2;
3555 unsigned nparam = C->Dimension;
3556 ZZ one, mone;
3557 one = 1;
3558 mone = -1;
3560 CA = align_context(C, D->Dimension, options->MaxRays);
3561 D = DomainIntersection(D, CA, options->MaxRays);
3562 Polyhedron_Free(CA);
3564 D2 = skew_into_positive_orthant(D, nparam, options->MaxRays);
3565 for (Polyhedron *P = D2; P; P = P->next) {
3566 assert(P->Dimension == D2->Dimension);
3567 gen_fun *P_gf;
3569 P_gf = series(Polyhedron_Copy(P), nparam, options);
3570 if (!gf)
3571 gf = P_gf;
3572 else {
3573 gf->add_union(P_gf, options);
3574 delete P_gf;
3577 /* we actually only need the convex union of the parameter space
3578 * but the reducer classes currently expect a polyhedron in
3579 * the combined space
3581 Polyhedron_Free(gf->context);
3582 gf->context = DomainConvex(D2, options->MaxRays);
3584 gf2 = gf->summate(D2->Dimension - nparam, options);
3586 delete gf;
3587 if (D != D2)
3588 Domain_Free(D2);
3589 Domain_Free(D);
3590 return gf2;
3593 gen_fun* barvinok_enumerate_union_series(Polyhedron *D, Polyhedron* C,
3594 unsigned MaxRays)
3596 gen_fun *gf;
3597 barvinok_options *options = barvinok_options_new_with_defaults();
3598 options->MaxRays = MaxRays;
3599 gf = barvinok_enumerate_union_series_with_options(D, C, options);
3600 barvinok_options_free(options);
3601 return gf;
3604 evalue* barvinok_enumerate_union(Polyhedron *D, Polyhedron* C, unsigned MaxRays)
3606 evalue *EP;
3607 gen_fun *gf = barvinok_enumerate_union_series(D, C, MaxRays);
3608 EP = *gf;
3609 delete gf;
3610 return EP;