lattice_point.h: make sure correct evalues are used
[barvinok/uuh.git] / barvinok_enumerate.cc
blobae5edb43fa902d9e7aba96a4522848b804f1e0ad
1 #include <assert.h>
2 #include <unistd.h>
3 #include <stdlib.h>
4 #include <barvinok/evalue.h>
5 #include <barvinok/util.h>
6 #include <barvinok/barvinok.h>
7 #include "argp.h"
8 #include "progname.h"
9 #include "verify.h"
10 #include "verif_ehrhart.h"
11 #include "verify_series.h"
12 #include "remove_equalities.h"
13 #include "evalue_convert.h"
14 #include "conversion.h"
15 #include "skewed_genfun.h"
17 #undef CS /* for Solaris 10 */
19 using std::cout;
20 using std::endl;
22 /* The input of this example program is the same as that of testehrhart
23 * in the PolyLib distribution, i.e., a polytope in combined
24 * data and parameter space, a context polytope in parameter space
25 * and (optionally) the names of the parameters.
26 * Both polytopes are in PolyLib notation.
29 struct argp_option argp_options[] = {
30 { "size", 'S' },
31 { "series", 's', 0, 0, "compute rational generating function" },
32 { "explicit", 'e', 0, 0, "convert rgf to psp" },
33 { 0 }
36 struct arguments {
37 int size;
38 int series;
39 int function;
40 struct verify_options verify;
41 struct convert_options convert;
44 static error_t parse_opt(int key, char *arg, struct argp_state *state)
46 struct arguments *options = (struct arguments*) state->input;
48 switch (key) {
49 case ARGP_KEY_INIT:
50 state->child_inputs[0] = options->verify.barvinok;
51 state->child_inputs[1] = &options->verify;
52 state->child_inputs[2] = &options->convert;
53 options->size = 0;
54 options->series = 0;
55 options->function = 0;
56 break;
57 case 'S':
58 options->size = 1;
59 break;
60 case 'e':
61 options->function = 1;
62 /* fall through */
63 case 's':
64 options->series = 1;
65 break;
66 default:
67 return ARGP_ERR_UNKNOWN;
69 return 0;
72 static int verify(Polyhedron *P, Polyhedron *C, evalue *EP, skewed_gen_fun *gf,
73 arguments *options)
75 Polyhedron *CS, *S;
76 Vector *p;
77 int result = 0;
79 CS = check_poly_context_scan(P, &C, C->Dimension, &options->verify);
81 p = Vector_Alloc(P->Dimension+2);
82 value_set_si(p->p[P->Dimension+1], 1);
84 /* S = scanning list of polyhedra */
85 S = Polyhedron_Scan(P, C, options->verify.barvinok->MaxRays);
87 check_poly_init(C, &options->verify);
89 /******* CHECK NOW *********/
90 if (S) {
91 if (!options->series || options->function) {
92 if (!check_poly_EP(S, CS, EP, 0, C->Dimension, 0, p->p,
93 &options->verify))
94 result = -1;
95 } else {
96 if (!check_poly_gf(S, CS, gf, 0, C->Dimension, 0, p->p,
97 &options->verify))
98 result = -1;
100 Domain_Free(S);
103 if (result == -1)
104 fprintf(stderr,"Check failed !\n");
106 if (!options->verify.print_all)
107 printf( "\n" );
109 Vector_Free(p);
110 if (CS) {
111 Domain_Free(CS);
112 Domain_Free(C);
115 return result;
118 /* frees M and Minv */
119 static void apply_transformation(Polyhedron **P, Polyhedron **C,
120 bool free_P, bool free_C,
121 Matrix *M, Matrix *Minv, Matrix **inv,
122 barvinok_options *options)
124 Polyhedron *T;
125 Matrix *M2;
127 M2 = align_matrix(M, (*P)->Dimension + 1);
128 T = *P;
129 *P = Polyhedron_Preimage(*P, M2, options->MaxRays);
130 if (free_P)
131 Polyhedron_Free(T);
132 Matrix_Free(M2);
134 T = *C;
135 *C = Polyhedron_Preimage(*C, M, options->MaxRays);
136 if (free_C)
137 Polyhedron_Free(T);
139 Matrix_Free(M);
141 if (*inv) {
142 Matrix *T = *inv;
143 *inv = Matrix_Alloc(Minv->NbRows, T->NbColumns);
144 Matrix_Product(Minv, T, *inv);
145 Matrix_Free(T);
146 Matrix_Free(Minv);
147 } else
148 *inv = Minv;
151 /* Since we have "compressed" the parameters (in case there were
152 * any equalities), the result is independent of the coordinates in the
153 * coordinate subspace spanned by the lines. We can therefore assume
154 * these coordinates are zero and compute the inverse image of the map
155 * from a lower dimensional space that adds zeros in the appropriate
156 * places.
158 static void remove_lines(Polyhedron *C, Matrix **M, Matrix **Minv)
160 Matrix *L = Matrix_Alloc(C->Dimension+1, C->Dimension+1);
161 for (int r = 0; r < C->NbBid; ++r)
162 Vector_Copy(C->Ray[r]+1, L->p[r], C->Dimension);
163 unimodular_complete(L, C->NbBid);
164 assert(value_one_p(L->p[C->Dimension][C->Dimension]));
165 assert(First_Non_Zero(L->p[C->Dimension], C->Dimension) == -1);
166 Matrix_Transposition(L);
167 assert(First_Non_Zero(L->p[C->Dimension], C->Dimension) == -1);
169 *M = Matrix_Alloc(C->Dimension+1, C->Dimension-C->NbBid+1);
170 for (int i = 0; i < C->Dimension+1; ++i)
171 Vector_Copy(L->p[i]+C->NbBid, (*M)->p[i], C->Dimension-C->NbBid+1);
173 Matrix *Linv = Matrix_Alloc(C->Dimension+1, C->Dimension+1);
174 int ok = Matrix_Inverse(L, Linv);
175 assert(ok);
176 Matrix_Free(L);
178 *Minv = Matrix_Alloc(C->Dimension-C->NbBid+1, C->Dimension+1);
179 for (int i = C->NbBid; i < C->Dimension+1; ++i)
180 Vector_AntiScale(Linv->p[i], (*Minv)->p[i-C->NbBid],
181 Linv->p[C->Dimension][C->Dimension], C->Dimension+1);
182 Matrix_Free(Linv);
185 static skewed_gen_fun *series(Polyhedron *P, Polyhedron* C,
186 barvinok_options *options)
188 Polyhedron *C1, *C2;
189 gen_fun *gf;
190 Matrix *inv = NULL;
191 Matrix *eq = NULL;
192 Matrix *div = NULL;
193 Polyhedron *PT = P;
195 /* Compute true context */
196 C1 = Polyhedron_Project(P, C->Dimension);
197 C2 = DomainIntersection(C, C1, options->MaxRays);
198 Polyhedron_Free(C1);
200 POL_ENSURE_VERTICES(C2);
201 if (C2->NbBid != 0) {
202 Polyhedron *T;
203 Matrix *M, *Minv, *M2;
204 Matrix *CP;
205 if (C2->NbEq || P->NbEq) {
206 /* We remove all equalities to be sure all lines are unit vectors */
207 Polyhedron *CT = C2;
208 remove_all_equalities(&PT, &CT, &CP, NULL, C2->Dimension,
209 options->MaxRays);
210 if (CT != C2) {
211 Polyhedron_Free(C2);
212 C2 = CT;
214 if (CP) {
215 inv = left_inverse(CP, &eq);
216 Matrix_Free(CP);
218 int d = 0;
219 Value tmp;
220 value_init(tmp);
221 div = Matrix_Alloc(inv->NbRows-1, inv->NbColumns+1);
222 for (int i = 0; i < inv->NbRows-1; ++i) {
223 Vector_Gcd(inv->p[i], inv->NbColumns, &tmp);
224 if (mpz_divisible_p(tmp,
225 inv->p[inv->NbRows-1][inv->NbColumns-1]))
226 continue;
227 Vector_Copy(inv->p[i], div->p[d], inv->NbColumns);
228 value_assign(div->p[d][inv->NbColumns],
229 inv->p[inv->NbRows-1][inv->NbColumns-1]);
230 ++d;
232 value_clear(tmp);
234 if (!d) {
235 Matrix_Free(div);
236 div = NULL;
237 } else
238 div->NbRows = d;
241 POL_ENSURE_VERTICES(C2);
243 if (C2->NbBid) {
244 Matrix *M, *Minv;
245 remove_lines(C2, &M, &Minv);
246 apply_transformation(&PT, &C2, PT != P, C2 != C, M, Minv, &inv,
247 options);
250 POL_ENSURE_VERTICES(C2);
251 if (!Polyhedron_has_revlex_positive_rays(C2, C2->Dimension)) {
252 Polyhedron *T;
253 Matrix *Constraints;
254 Matrix *H, *Q, *U;
255 Constraints = Matrix_Alloc(C2->NbConstraints, C2->Dimension+1);
256 for (int i = 0; i < C2->NbConstraints; ++i)
257 Vector_Copy(C2->Constraint[i]+1, Constraints->p[i], C2->Dimension);
258 left_hermite(Constraints, &H, &Q, &U);
259 Matrix_Free(Constraints);
260 /* flip rows of Q */
261 for (int i = 0; i < C2->Dimension/2; ++i)
262 Vector_Exchange(Q->p[i], Q->p[C2->Dimension-1-i], C2->Dimension);
263 Matrix_Free(H);
264 Matrix_Free(U);
265 Matrix *M = Matrix_Alloc(C2->Dimension+1, C2->Dimension+1);
266 U = Matrix_Copy(Q);
267 int ok = Matrix_Inverse(U, M);
268 assert(ok);
269 Matrix_Free(U);
271 apply_transformation(&PT, &C2, PT != P, C2 != C, M, Q, &inv, options);
273 gf = barvinok_series_with_options(PT, C2, options);
274 Polyhedron_Free(C2);
275 if (PT != P)
276 Polyhedron_Free(PT);
277 return new skewed_gen_fun(gf, inv, eq, div);
280 int main(int argc, char **argv)
282 Polyhedron *A, *C;
283 Matrix *M;
284 evalue *EP = NULL;
285 skewed_gen_fun *gf = NULL;
286 char **param_name;
287 int print_solution = 1;
288 int result = 0;
289 struct arguments options;
290 static struct argp_child argp_children[] = {
291 { &barvinok_argp, 0, 0, 0 },
292 { &verify_argp, 0, "verification", BV_GRP_LAST+1 },
293 { &convert_argp, 0, "output conversion", BV_GRP_LAST+2 },
294 { 0 }
296 static struct argp argp = { argp_options, parse_opt, 0, 0, argp_children };
297 struct barvinok_options *bv_options = barvinok_options_new_with_defaults();
299 options.verify.barvinok = bv_options;
300 set_program_name(argv[0]);
301 argp_parse(&argp, argc, argv, 0, 0, &options);
303 M = Matrix_Read();
304 assert(M);
305 A = Constraints2Polyhedron(M, bv_options->MaxRays);
306 Matrix_Free(M);
307 M = Matrix_Read();
308 assert(M);
309 C = Constraints2Polyhedron(M, bv_options->MaxRays);
310 Matrix_Free(M);
311 param_name = Read_ParamNames(stdin, C->Dimension);
313 if (options.verify.verify) {
314 verify_options_set_range(&options.verify, A->Dimension);
315 if (!bv_options->verbose)
316 print_solution = 0;
319 if (print_solution && bv_options->verbose) {
320 Polyhedron_Print(stdout, P_VALUE_FMT, A);
321 Polyhedron_Print(stdout, P_VALUE_FMT, C);
324 if (options.series) {
325 gf = series(A, C, bv_options);
326 if (print_solution) {
327 gf->print(cout, C->Dimension, param_name);
328 puts("");
330 if (options.function) {
331 EP = *gf;
332 if (print_solution)
333 print_evalue(stdout, EP, param_name);
335 } else {
336 EP = barvinok_enumerate_with_options(A, C, bv_options);
337 assert(EP);
338 if (evalue_convert(EP, &options.convert, bv_options->verbose,
339 C->Dimension, param_name))
340 print_solution = 0;
341 if (options.size)
342 printf("\nSize: %d\n", evalue_size(EP));
343 if (print_solution)
344 print_evalue(stdout, EP, param_name);
347 if (options.verify.verify) {
348 options.verify.params = param_name;
349 result = verify(A, C, EP, gf, &options);
352 if (gf)
353 delete gf;
354 if (EP)
355 evalue_free(EP);
357 if (options.verify.barvinok->print_stats)
358 barvinok_stats_print(options.verify.barvinok->stats, stdout);
360 Free_ParamNames(param_name, C->Dimension);
361 Polyhedron_Free(A);
362 Polyhedron_Free(C);
363 barvinok_options_free(bv_options);
364 return result;