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source: git/kernel/linear_algebra/interpolation.cc @ 6cf934

spielwiese

Last change on this file since 6cf934 was 6cf934, checked in by Frédéric Chapoton <chapoton@…>, 4 months ago
more typos fixed in kernel
Property mode set to `100644`
File size: 49.2 KB

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1	/****************************************
2	* Computer Algebra System SINGULAR *
3	****************************************/
4
5	#include "kernel/mod2.h"
6
7	#include "factory/factory.h"
8
9	#include "misc/options.h"
10	#include "misc/intvec.h"
11
12	#include "coeffs/longrat.h" // snumber ...
13
14	#include "polys/monomials/ring.h"
15
16	#include "kernel/polys.h"
17	#include "kernel/ideals.h"
18
19	#include "interpolation.h"
20
21	// parameters to debug
22	//#define shmat
23	//#define checksize
24	//#define writemsg
25
26	// possible strategies
27	#define unsortedmatrix
28	//#define integerstrategy
29
30	#define modp_number int
31	#define exponent int
32
33	STATIC_VAR modp_number myp; // all modp computation done mod myp
34	STATIC_VAR int myp_index; // index of small prime in Singular table of primes
35
36	static inline modp_number modp_mul (modp_number x,modp_number y)
37	{
38	// return (x*y)%myp;
39	return (modp_number)(((unsigned long)x)*((unsigned long)y)%((unsigned long)myp));
40	}
41	static inline modp_number modp_sub (modp_number x,modp_number y)
42	{
43	// if (x>=y) return x-y; else return x+myp-y;
44	return (x+myp-y)%myp;
45	}
46
47	typedef exponent *mono_type;
48	typedef struct {mono_type mon; unsigned int point_ref;} condition_type;
49	typedef modp_number *coordinate_products;
50	typedef coordinate_products *coordinates;
51
52	struct mon_list_entry_struct {mono_type mon;
53	struct mon_list_entry_struct *next;};
54	typedef struct mon_list_entry_struct mon_list_entry;
55
56	struct row_list_entry_struct {modp_number *row_matrix;
57	modp_number *row_solve;
58	int first_col;
59	struct row_list_entry_struct *next;};
60
61	typedef struct row_list_entry_struct row_list_entry;
62
63	struct generator_struct {modp_number *coef;
64	mono_type lt;
65	modp_number ltcoef;
66	struct generator_struct *next;};
67
68	typedef struct generator_struct generator_entry;
69
70	struct modp_result_struct {modp_number p;
71	generator_entry *generator;
72	int n_generators;
73	struct modp_result_struct *next;
74	struct modp_result_struct *prev;};
75
76	typedef struct modp_result_struct modp_result_entry;
77
78	typedef modp_number *modp_coordinates;
79	typedef mpq_t *q_coordinates;
80	typedef mpz_t *int_coordinates;
81	typedef bool *coord_exist_table;
82
83	STATIC_VAR int final_base_dim; // dimension of the quotient space, known from the beginning
84	STATIC_VAR int last_solve_column; // last non-zero column in "solve" part of matrix, used for speed up
85	STATIC_VAR int n_points; // modp_number of ideals (points)
86	STATIC_VAR int *multiplicity; // multiplicities of points
87	STATIC_VAR int variables; // modp_number of variables
88	STATIC_VAR int max_coord; // maximal possible coordinate product used during Evaluation
89	STATIC_VAR bool only_modp; // perform only one modp computations
90
91	STATIC_VAR modp_coordinates *modp_points; // coordinates of points for modp problem - used by Evaluate (this is also initial data for only modp)
92	STATIC_VAR q_coordinates *q_points; // coordinates of points for rational data (not used for modp)
93	STATIC_VAR int_coordinates *int_points; // coordinates of points for integer data - used to check generators (not used for modp)
94	STATIC_VAR coord_exist_table *coord_exist; // checks whether all coordinates has been initialized
95	STATIC_VAR mon_list_entry *check_list; // monomials to be checked in next stages
96	STATIC_VAR coordinates *points; // power products of coordinates of points used in modp cycles
97	STATIC_VAR condition_type *condition_list; // conditions stored in an array
98	STATIC_VAR mon_list_entry *lt_list; // leading terms found so far
99	STATIC_VAR mon_list_entry *base_list; // standard monomials found so far
100	STATIC_VAR row_list_entry *row_list; // rows of the matrix (both parts)
101	STATIC_VAR modp_number *my_row; // one special row to perform operations
102	STATIC_VAR modp_number *my_solve_row; // one special row to find the linear dependence ("solve" part)
103	STATIC_VAR mono_type *column_name; // monomials assigned to columns in solve_row
104
105	STATIC_VAR int n_results; // modp_number of performed modp computations (not discarded)
106	STATIC_VAR modp_number modp_denom; // denominator of mod p computations
107	STATIC_VAR modp_result_entry *modp_result; // list of results for various mod p calculations (used for modp - first result is the desired one)
108	STATIC_VAR modp_result_entry *cur_result; // pointer to current result (as before)
109	STATIC_VAR modp_number *congr; // primes used in computations (chinese remainder theorem) (not used for modp)
110	STATIC_VAR modp_number *in_gamma; // inverts used in chinese remainder theorem (not used for modp)
111	STATIC_VAR mpz_t bigcongr; // result, in fact, is given in mod bigcongr (not used for modp)
112
113	STATIC_VAR mpz_t *polycoef; // polynomial integercoefficients (not used for modp)
114	STATIC_VAR mono_type *polyexp; // polynomial exponents
115
116	struct gen_list_struct {mpz_t *polycoef;
117	mono_type *polyexp;
118	struct gen_list_struct *next;};
119	typedef struct gen_list_struct gen_list_entry;
120
121	STATIC_VAR gen_list_entry *gen_list=NULL; // list of resulting generators - output data (integer version)
122
123	STATIC_VAR int generic_n_generators; // modp_number of generators - should be the same for all modp comp (not used for modp)
124	STATIC_VAR mono_type *generic_column_name; // monomials assigned to columns in solve_row - should be the same for all modp comp (!!! used for modp)
125	STATIC_VAR mon_list_entry *generic_lt=NULL; // leading terms for ordered generators - should be the same for all modp comp (not used for modp)
126	STATIC_VAR int good_primes; // modp_number of good primes so far;
127	STATIC_VAR int bad_primes; // modp_number of bad primes so far;
128	STATIC_VAR mpz_t common_denom; // common denominator used to force points coordinates to Z (not used for modp)
129	STATIC_VAR bool denom_divisible; // common denominator is divisible by p (not used for modp)
130
131	STATIC_VAR poly comparizon_p1; //polynomials used to do comparisons by Singular
132	STATIC_VAR poly comparizon_p2;
133
134	STATIC_VAR modp_number *modp_Reverse; // reverses in mod p
135
136	STATIC_VAR bool protocol; // true to show the protocol
137
138	#ifdef checksize
139	STATIC_VAR int maximal_size=0;
140	#endif
141
142	#if 0 /* only for debuggig*/
143	void WriteMono (mono_type m) // Writes a monomial on the screen - only for debug
144	{
145	int i;
146	for (i=0;i<variables;i++) Print("_%d", m[i]);
147	PrintS(" ");
148	}
149
150	void WriteMonoList (mon_list_entry *list)
151	{
152	mon_list_entry *ptr;
153	ptr=list;
154	while (ptr!=NULL)
155	{
156	WriteMono(ptr->mon);
157	ptr=ptr->next;
158	}
159	}
160
161	void Info ()
162	{
163	int i;
164	row_list_entry *curptr;
165	modp_number *row;
166	modp_number *solve;
167	char ch;
168	cout << endl << "quotient basis: ";
169	WriteMonoList (base_list);
170	cout << endl << "leading terms: ";
171	WriteMonoList (lt_list);
172	cout << endl << "to be checked: ";
173	WriteMonoList (check_list);
174	#ifdef shmat
175	cout << endl << "Matrix:" << endl;
176	cout << " ";
177	for (i=0;i<final_base_dim;i++)
178	{
179	WriteMono (column_name[i]);
180	}
181	cout << endl;
182	curptr=row_list;
183	while (curptr!=NULL)
184	{
185	row=curptr->row_matrix;
186	solve=curptr->row_solve;
187	for (i=0;i<final_base_dim;i++)
188	{
189	cout << *row << " , ";
190	row++;
191	}
192	cout << " ";
193	for (i=0;i<final_base_dim;i++)
194	{
195	cout << *solve << " , ";
196	solve++;
197	}
198	curptr=curptr->next;
199	cout << endl;}
200	cout << "Special row: Solve row:" << endl;
201	row=my_row;
202	for (i=0;i<final_base_dim;i++)
203	{
204	cout << *row << " , ";
205	row++;
206	}
207	cout << " ";
208	row=my_solve_row;
209	for (i=0;i<final_base_dim;i++)
210	{
211	cout << *row << " , ";
212	row++;
213	}
214	#endif
215	cout << endl;
216	cin >> ch;
217	cout << endl << endl;
218	}
219	#endif
220
221	static modp_number OneInverse(modp_number a,modp_number p) // computes inverse of d mod p without using tables
222	{
223	long u, v, u0, u1, u2, q, r;
224	u1=1; u2=0;
225	u = a; v = p;
226	while (v != 0)
227	{
228	q = u / v;
229	r = u % v;
230	u = v;
231	v = r;
232	u0 = u2;
233	u2 = u1 - q*u2;
234	u1 = u0;
235	}
236	if (u1 < 0) u1=u1+p;
237	// now it should be ok, but for any case...
238	if ((u1<0)\|\|((u1*a)%p!=1))
239	{
240	PrintS("?");
241	modp_number i;
242	for (i=1;i<p;i++)
243	{
244	if ((a*i)%p==1) return i;
245	}
246	}
247	return (modp_number)u1;
248	}
249
250	static int CalcBaseDim () // returns the maximal (expected) dimension of quotient space
251	{
252	int c;
253	int i,j;
254	int s=0;
255	max_coord=1;
256	for (i=0;i<n_points;i++) max_coord=max_coord+multiplicity[i];
257	for (j=0;j<n_points;j++)
258	{
259	c=1;
260	for (i=1;i<=variables;i++)
261	{
262	c=(c*(multiplicity[j]+i-1))/i;
263	}
264	s=s+c;
265	}
266	return s;
267	}
268
269	static bool EqualMon (mono_type m1, mono_type m2) // compares two monomials, true if equal, false otherwise
270	{
271	int i;
272	for (i=0;i<variables;i++)
273	if (m1[i]!=m2[i]) return false;;
274	return true;
275	}
276
277	static exponent MonDegree (mono_type mon) // computes the degree of a monomial
278	{
279	exponent v=0;
280	int i;
281	for (i=0;i<variables;i++) v=v+mon[i];
282	return v;
283	}
284
285	static bool Greater (mono_type m1, mono_type m2) // true if m1 > m2, false otherwise. uses Singular comparing function
286	{
287	for (int j = variables; j; j--)
288	{
289	pSetExp(comparizon_p1, j, m1[j-1]);
290	pSetExp(comparizon_p2, j, m2[j-1]);
291	}
292	pSetm(comparizon_p1);
293	pSetm(comparizon_p2);
294	bool res=(pLmCmp(comparizon_p1,comparizon_p2)>0);
295	return res;
296	}
297
298	static mon_list_entry* MonListAdd (mon_list_entry *list, mono_type mon) // adds one entry to the list of monomials structure
299	{
300	mon_list_entry *curptr=list;
301	mon_list_entry *prevptr=NULL;
302	mon_list_entry *temp;
303
304	while (curptr!=NULL)
305	{
306	if (EqualMon (mon,(*curptr).mon)) return list;
307	if (Greater ((*curptr).mon,mon)) break;
308	prevptr=curptr;
309	curptr=curptr->next;
310	}
311	temp=(mon_list_entry*)omAlloc0(sizeof(mon_list_entry));
312	(*temp).next=curptr;
313	(temp).mon=(exponent)omAlloc(sizeof(exponent)*variables);
314	memcpy(temp->mon,mon,sizeof(exponent)*variables);
315	if (prevptr==NULL) return temp;
316	else
317	{
318	prevptr->next=temp;
319	return list;
320	}
321	}
322
323	static mono_type MonListElement (mon_list_entry *list, int n) // returns ith element from list of monomials - no error checking!
324	{
325	mon_list_entry *cur=list;
326	int i;
327	for (i=0;i<n;i++) cur=cur->next;
328	return cur->mon;
329	}
330
331	static mono_type ZeroMonomial () // allocates memory for new monomial with all enries equal 0
332	{
333	mono_type m;
334	m=(exponent)omAlloc0(sizeof(exponent)variables);
335	return m;
336	}
337
338	static void GeneralInit () // general initialization
339	{
340	int i,j;
341	points=(coordinates)omAlloc(sizeof(coordinates)n_points);
342	for (i=0;i<n_points;i++)
343	{
344	points[i]=(coordinate_products)omAlloc(sizeof(coordinate_products)variables);
345	for (j=0;j<variables;j++) points[i][j]=(modp_number)omAlloc0(sizeof(modp_number)(max_coord));
346	}
347	condition_list=(condition_type)omAlloc0(sizeof(condition_type)final_base_dim);
348	for (i=0;i<final_base_dim;i++) condition_list[i].mon=(exponent)omAlloc0(sizeof(exponent)variables);
349	modp_points=(modp_coordinates)omAlloc(sizeof(modp_coordinates)n_points);
350	for (i=0;i<n_points;i++) modp_points[i]=(modp_number)omAlloc0(sizeof(modp_number)variables);
351	if (!only_modp)
352	{
353	q_points=(q_coordinates)omAlloc0(sizeof(q_coordinates)n_points);
354	for (i=0;i<n_points;i++)
355	{
356	q_points[i]=(mpq_t)omAlloc(sizeof(mpq_t)variables);
357	for (j=0;j<variables;j++) mpq_init(q_points[i][j]);
358	}
359	int_points=(int_coordinates)omAlloc0(sizeof(int_coordinates)n_points);
360	for (i=0;i<n_points;i++)
361	{
362	int_points[i]=(mpz_t)omAlloc(sizeof(mpz_t)variables);
363	for (j=0;j<variables;j++) mpz_init(int_points[i][j]);
364	}
365	}
366	coord_exist=(coord_exist_table)omAlloc(sizeof(coord_exist_table)n_points);
367	for (i=0;i<n_points;i++)
368	{
369	coord_exist[i]=(bool)omAlloc0(sizeof(bool)variables);
370	}
371	generic_column_name=(mono_type)omAlloc(sizeof(mono_type)final_base_dim);
372	for (i=0;i<final_base_dim;i++) generic_column_name[i]=ZeroMonomial ();
373	good_primes=0;
374	bad_primes=1;
375	generic_n_generators=0;
376	if (!only_modp)
377	{
378	polycoef=(mpz_t)omAlloc(sizeof(mpz_t)(final_base_dim+1));
379	polyexp=(mono_type)omAlloc(sizeof(mono_type)(final_base_dim+1));
380	for (i=0;i<=final_base_dim;i++)
381	{
382	mpz_init(polycoef[i]);
383	polyexp[i]=ZeroMonomial ();
384	}
385	mpz_init(common_denom);
386	}
387
388	// set all globally used lists to be initially empty
389	modp_result=NULL;
390	cur_result=NULL;
391	gen_list=NULL;
392	n_results=0;
393
394	// creates polynomials to compare by Singular
395	comparizon_p1=pOne();
396	comparizon_p2=pOne();
397	}
398
399	static void InitProcData () // initialization for procedures which do computations mod p
400	{
401	int i;
402	check_list=MonListAdd (check_list,ZeroMonomial ());
403	my_row=(modp_number)omAlloc0(sizeof(modp_number)final_base_dim);
404	my_solve_row=(modp_number)omAlloc0(sizeof(modp_number)final_base_dim);
405	column_name=(mono_type)omAlloc(sizeof(mono_type)final_base_dim);
406	for (i=0;i<final_base_dim;i++) column_name[i]=ZeroMonomial ();
407	last_solve_column=0;
408	modp_number *gen_table;
409	modp_number pos_gen;
410	bool gen_ok;
411	modp_Reverse=(modp_number)omAlloc0(sizeof(modp_number)myp);
412
413	// produces table of modp inverts by finding a generator of (Z_myp,)
414	gen_table=(modp_number)omAlloc(sizeof(modp_number)myp);
415	gen_table[1]=1;
416	for (pos_gen=2;pos_gen<myp;pos_gen++)
417	{
418	gen_ok=true;
419	for (i=2;i<myp;i++)
420	{
421	gen_table[i]=modp_mul(gen_table[i-1],pos_gen);
422	if (gen_table[i]==1)
423	{
424	gen_ok=false;
425	break;
426	}
427	}
428	if (gen_ok) break;
429	}
430	for (i=2;i<myp;i++) modp_Reverse[gen_table[i]]=gen_table[myp-i+1];
431	modp_Reverse[1]=1;
432	omFree(gen_table);
433	}
434
435	static mon_list_entry* FreeMonList (mon_list_entry *list) // destroys a list of monomials, returns NULL pointer
436	{
437	mon_list_entry *ptr;
438	mon_list_entry *pptr;
439	ptr=list;
440	while (ptr!=NULL)
441	{
442	pptr=ptr->next;
443	omFree(ptr->mon);
444	omFree(ptr);
445	ptr=pptr;}
446	return NULL;
447	}
448
449	static void GeneralDone () // to be called before exit to free memory
450	{
451	int i,j;
452	for (i=0;i<n_points;i++)
453	{
454	for (j=0;j<variables;j++)
455	{
456	omFree(points[i][j]);
457	}
458	omFree(points[i]);
459	}
460	omFree(points);
461	for (i=0;i<final_base_dim;i++) omFree(condition_list[i].mon);
462	omFree(condition_list);
463	for (i=0;i<n_points;i++) omFree(modp_points[i]);
464	omFree(modp_points);
465	if (!only_modp)
466	{
467	for (i=0;i<n_points;i++)
468	{
469	for (j=0;j<variables;j++) mpq_clear(q_points[i][j]);
470	omFree(q_points[i]);
471	}
472	omFree(q_points);
473	for (i=0;i<n_points;i++)
474	{
475	for (j=0;j<variables;j++) mpz_clear(int_points[i][j]);
476	omFree(int_points[i]);
477	}
478	omFree(int_points);
479	generic_lt=FreeMonList (generic_lt);
480	for (i=0;i<=final_base_dim;i++)
481	{
482	mpz_clear(polycoef[i]);
483	omFree(polyexp[i]);
484	}
485	omFree(polycoef);
486	omFree(polyexp);
487	if (!only_modp) mpz_clear(common_denom);
488	}
489	for (i=0;i<final_base_dim;i++)
490	{
491	omFree(generic_column_name[i]);
492	}
493	omFree(generic_column_name);
494	for (i=0;i<n_points;i++) omFree(coord_exist[i]);
495	omFree(coord_exist);
496	pDelete(&comparizon_p1);
497	pDelete(&comparizon_p2);
498	omFree(multiplicity);
499	}
500
501	static void FreeProcData () // to be called after one modp computation to free memory
502	{
503	int i;
504	row_list_entry *ptr;
505	row_list_entry *pptr;
506	check_list=FreeMonList (check_list);
507	lt_list=FreeMonList (lt_list);
508	base_list=FreeMonList (base_list);
509	omFree(my_row);
510	my_row=NULL;
511	omFree(my_solve_row);
512	my_solve_row=NULL;
513	ptr=row_list;
514	while (ptr!=NULL)
515	{
516	pptr=ptr->next;
517	omFree(ptr->row_matrix);
518	omFree(ptr->row_solve);
519	omFree(ptr);
520	ptr=pptr;
521	}
522	row_list=NULL;
523	for (i=0;i<final_base_dim;i++) omFree(column_name[i]);
524	omFree(column_name);
525	omFree(modp_Reverse);
526	}
527
528	static void modp_Evaluate(modp_number *ev, mono_type mon, condition_type con) // evaluates monomial on condition (modp)
529	{
530	int i;
531	*ev=0;
532	for (i=0;i<variables;i++)
533	if (con.mon[i] > mon[i]) return ;;
534	*ev=1;
535	int j,k;
536	mono_type mn;
537	mn=(exponent)omAlloc(sizeof(exponent)variables);
538	memcpy(mn,mon,sizeof(exponent)*variables);
539	for (k=0;k<variables;k++)
540	{
541	for (j=1;j<=con.mon[k];j++) // this loop computes the coefficient from derivation
542	{
543	ev=modp_mul(ev,mn[k]);
544	mn[k]--;
545	}
546	ev=modp_mul(ev,points[con.point_ref][k][mn[k]]);
547	}
548	omFree(mn);
549	}
550
551	static void int_Evaluate(mpz_t ev, mono_type mon, condition_type con) // (***) evaluates monomial on condition for integer numbers
552	{
553	int i;
554	mpz_set_ui(ev,0);
555	for (i=0;i<variables;i++)
556	if (con.mon[i] > mon[i]) return ;;
557	mpz_set_ui(ev,1);
558	mpz_t mon_conv;
559	mpz_init(mon_conv);
560	int j,k;
561	mono_type mn;
562	mn=(exponent)omAlloc(sizeof(exponent)variables);
563	memcpy(mn,mon,sizeof(exponent)*variables);
564	for (k=0;k<variables;k++)
565	{
566	for (j=1;j<=con.mon[k];j++) // this loop computes the coefficient from derivation
567	{
568	mpz_set_si(mon_conv,mn[k]); // (***)
569	mpz_mul(ev,ev,mon_conv);
570	mn[k]--;
571	}
572	for (j=1;j<=mn[k];j++) mpz_mul(ev,ev,int_points[con.point_ref][k]); // this loop computes the product of coordinate
573	}
574	omFree(mn);
575	mpz_clear(mon_conv);
576	}
577
578	static void ProduceRow(mono_type mon) // produces a row for monomial - first part is an evaluated part, second 0 to obtain the coefs of dependence
579	{
580	modp_number *row;
581	condition_type *con;
582	int i;
583	row=my_row;
584	con=condition_list;
585	for (i=0;i<final_base_dim;i++)
586	{
587	modp_Evaluate (row, mon, *con);
588	row++;
589	con++;
590	}
591	row=my_solve_row;
592	for (i=0;i<final_base_dim;i++)
593	{
594	*row=0;
595	row++;
596	}
597	}
598
599	static void IntegerPoints () // produces integer points from rationals by scaling the coordinate system
600	{
601	int i,j;
602	mpz_set_ui(common_denom,1); // this is common scaling factor
603	for (i=0;i<n_points;i++)
604	{
605	for (j=0;j<variables;j++)
606	{
607	mpz_lcm(common_denom,common_denom,mpq_denref(q_points[i][j]));
608	}
609	}
610	mpq_t temp;
611	mpq_init(temp);
612	mpq_t denom_q;
613	mpq_init(denom_q);
614	mpq_set_z(denom_q,common_denom);
615	for (i=0;i<n_points;i++)
616	{
617	for (j=0;j<variables;j++)
618	{
619	mpq_mul(temp,q_points[i][j],denom_q); // multiplies by common denominator
620	mpz_set(int_points[i][j],mpq_numref(temp)); // and changes into integer
621	}
622	}
623	mpq_clear(temp);
624	mpq_clear(denom_q);
625	}
626
627	static void int_PrepareProducts () // prepares coordinates of points and products for modp case (from integer coefs)
628	{
629	int i,j,k;
630	mpz_t big_myp;
631	mpz_init(big_myp);
632	mpz_set_si(big_myp,myp);
633	mpz_t temp;
634	mpz_init(temp);
635	for (i=0;i<n_points;i++)
636	{
637	for (j=0;j<variables;j++)
638	{
639	mpz_mod(temp,int_points[i][j],big_myp); // coordinate is now modulo myp
640	points[i][j][1]=mpz_get_ui(temp);
641	points[i][j][0]=1;
642	for (k=2;k<max_coord;k++) points[i][j][k]=modp_mul(points[i][j][k-1],points[i][j][1]);
643	}
644	}
645	mpz_mod(temp,common_denom,big_myp); // computes the common denominator (from rational data) modulo myp
646	denom_divisible=(mpz_sgn(temp)==0); // checks whether it is divisible by modp
647	mpz_clear(temp);
648	mpz_clear(big_myp);
649	}
650
651	static void modp_PrepareProducts () // prepares products for modp computation from modp data
652	{
653	int i,j,k;
654	for (i=0;i<n_points;i++)
655	{
656	for (j=0;j<variables;j++)
657	{
658	points[i][j][1]=modp_points[i][j];
659	points[i][j][0]=1;
660	for (k=2;k<max_coord;k++) points[i][j][k]=modp_mul(points[i][j][k-1],points[i][j][1]);
661	}
662	}
663	}
664
665	static void MakeConditions () // prepares a list of conditions from list of multiplicities
666	{
667	condition_type *con;
668	int n,i,k;
669	mono_type mon;
670	mon=ZeroMonomial ();
671	con=condition_list;
672	for (n=0;n<n_points;n++)
673	{
674	for (i=0;i<variables;i++) mon[i]=0;
675	while (mon[0]<multiplicity[n])
676	{
677	if (MonDegree (mon) < multiplicity[n])
678	{
679	memcpy(con->mon,mon,sizeof(exponent)*variables);
680	con->point_ref=n;
681	con++;
682	}
683	k=variables-1;
684	mon[k]++;
685	while ((k>0)&&(mon[k]>=multiplicity[n]))
686	{
687	mon[k]=0;
688	k--;
689	mon[k]++;
690	}
691	}
692	}
693	omFree(mon);
694	}
695
696	static void ReduceRow () // reduces my_row by previous rows, does the same for solve row
697	{
698	if (row_list==NULL) return ;
699	row_list_entry *row_ptr;
700	modp_number *cur_row_ptr;
701	modp_number *solve_row_ptr;
702	modp_number *my_row_ptr;
703	modp_number *my_solve_row_ptr;
704	int first_col;
705	int i;
706	modp_number red_val;
707	modp_number mul_val;
708	#ifdef integerstrategy
709	modp_number *m_row_ptr;
710	modp_number prep_val;
711	#endif
712	row_ptr=row_list;
713	while (row_ptr!=NULL)
714	{
715	cur_row_ptr=row_ptr->row_matrix;
716	solve_row_ptr=row_ptr->row_solve;
717	my_row_ptr=my_row;
718	my_solve_row_ptr=my_solve_row;
719	first_col=row_ptr->first_col;
720	cur_row_ptr=cur_row_ptr+first_col; // reduction begins at first_col position
721	my_row_ptr=my_row_ptr+first_col;
722	red_val=*my_row_ptr;
723	if (red_val!=0)
724	{
725	#ifdef integerstrategy
726	prep_val=*cur_row_ptr;
727	if (prep_val!=1)
728	{
729	m_row_ptr=my_row;
730	for (i=0;i<final_base_dim;i++)
731	{
732	if (m_row_ptr!=0) m_row_ptr=modp_mul(*m_row_ptr,prep_val);
733	m_row_ptr++;
734	}
735	m_row_ptr=my_solve_row;
736	for (i=0;i<last_solve_column;i++)
737	{
738	if (m_row_ptr!=0) m_row_ptr=modp_mul(*m_row_ptr,prep_val);
739	m_row_ptr++;
740	}
741	}
742	#endif
743	for (i=first_col;i<final_base_dim;i++)
744	{
745	if (*cur_row_ptr!=0)
746	{
747	mul_val=modp_mul(*cur_row_ptr,red_val);
748	my_row_ptr=modp_sub(my_row_ptr,mul_val);
749	}
750	my_row_ptr++;
751	cur_row_ptr++;
752	}
753	for (i=0;i<=last_solve_column;i++) // last_solve_column stores the last non-enmpty entry in solve matrix
754	{
755	if (*solve_row_ptr!=0)
756	{
757	mul_val=modp_mul(*solve_row_ptr,red_val);
758	my_solve_row_ptr=modp_sub(my_solve_row_ptr,mul_val);
759	}
760	solve_row_ptr++;
761	my_solve_row_ptr++;
762	}
763	}
764	row_ptr=row_ptr->next;
765	#if 0 /* only debugging */
766	PrintS("reduction by row ");
767	Info ();
768	#endif
769	}
770	}
771
772	static bool RowIsZero () // check whether a row is zero
773	{
774	bool zero=1;
775	int i;
776	modp_number *row;
777	row=my_row;
778	for (i=0;i<final_base_dim;i++)
779	{
780	if (*row!=0) {zero=0; break;}
781	row++;
782	}
783	return zero;
784	}
785
786	static bool DivisibleMon (mono_type m1, mono_type m2) // checks whether m1 is divisible by m2
787	{
788	int i;
789	for (i=0;i<variables;i++)
790	if (m1[i]>m2[i]) return false;;
791	return true;
792	}
793
794	static void ReduceCheckListByMon (mono_type m) // from check_list monomials divisible by m are thrown out
795	{
796	mon_list_entry *c_ptr;
797	mon_list_entry *p_ptr;
798	mon_list_entry *n_ptr;
799	c_ptr=check_list;
800	p_ptr=NULL;
801	while (c_ptr!=NULL)
802	{
803	if (DivisibleMon (m,c_ptr->mon))
804	{
805	if (p_ptr==NULL)
806	check_list=c_ptr->next;
807	else
808	p_ptr->next=c_ptr->next;
809	n_ptr=c_ptr->next;
810	omFree(c_ptr->mon);
811	omFree(c_ptr);
812	c_ptr=n_ptr;
813	}
814	else
815	{
816	p_ptr=c_ptr;
817	c_ptr=c_ptr->next;
818	}
819	}
820	}
821
822	static void TakeNextMonomial (mono_type mon) // reads first monomial from check_list, then it is deleted
823	{
824	mon_list_entry *n_check_list;
825	if (check_list!=NULL)
826	{
827	memcpy(mon,check_list->mon,sizeof(exponent)*variables);
828	n_check_list=check_list->next;
829	omFree(check_list->mon);
830	omFree(check_list);
831	check_list=n_check_list;
832	}
833	}
834
835	static void UpdateCheckList (mono_type m) // adds all monomials which are "next" to m (divisible by m and degree +1)
836	{
837	int i;
838	for (i=0;i<variables;i++)
839	{
840	m[i]++;
841	check_list=MonListAdd (check_list,m);
842	m[i]--;
843	}
844	}
845
846	static void ReduceCheckListByLTs () // deletes all monomials from check_list which are divisible by one of the leading terms
847	{
848	mon_list_entry *ptr;
849	ptr=lt_list;
850	while (ptr!=NULL)
851	{
852	ReduceCheckListByMon (ptr->mon);
853	ptr=ptr->next;
854	}
855	}
856
857	static void RowListAdd (int first_col, mono_type mon) // puts a row into matrix
858	{
859	row_list_entry *ptr;
860	row_list_entry *pptr;
861	row_list_entry *temp;
862	ptr=row_list;
863	pptr=NULL;
864	while (ptr!=NULL)
865	{
866	#ifndef unsortedmatrix
867	if ( first_col <= ptr->first_col ) break;
868	#endif
869	pptr=ptr;
870	ptr=ptr->next;
871	}
872	temp=(row_list_entry*)omAlloc0(sizeof(row_list_entry));
873	(temp).row_matrix=(modp_number)omAlloc0(sizeof(modp_number)*final_base_dim);
874	memcpy((temp).row_matrix,my_row,sizeof(modp_number)(final_base_dim));
875	(temp).row_solve=(modp_number)omAlloc0(sizeof(modp_number)*final_base_dim);
876	memcpy((temp).row_solve,my_solve_row,sizeof(modp_number)(final_base_dim));
877	(*temp).first_col=first_col;
878	temp->next=ptr;
879	if (pptr==NULL) row_list=temp; else pptr->next=temp;
880	memcpy(column_name[first_col],mon,sizeof(exponent)*variables);
881	}
882
883
884	static void PrepareRow (mono_type mon) // prepares a row and puts it into matrix
885	{
886	modp_number *row;
887	int first_col=-1;
888	int col;
889	modp_number red_val=1;
890	row=my_row;
891	#ifdef integerstrategy
892	for (col=0;col<final_base_dim;col++)
893	{
894	if (*row!=0)
895	{
896	first_col=col;
897	break;
898	}
899	row++;
900	}
901	my_solve_row[first_col]=1;
902	if (first_col > last_solve_column) last_solve_column=first_col;
903	#else
904	for (col=0;col<final_base_dim;col++)
905	{
906	if (*row!=0)
907	{
908	first_col=col;
909	red_val=modp_Reverse[*row]; // first non-zero entry, should multiply all row by inverse to obtain 1
910	modp_denom=modp_mul(modp_denom,*row); // remembers the divisor
911	*row=1;
912	break;
913	}
914	row++;
915	}
916	my_solve_row[first_col]=1;
917	if (first_col > last_solve_column) last_solve_column=first_col;
918	if (red_val!=1)
919	{
920	row++;
921	for (col=first_col+1;col<final_base_dim;col++)
922	{
923	if (row!=0) row=modp_mul(*row,red_val);
924	row++;
925	}
926	row=my_solve_row;
927	for (col=0;col<=last_solve_column;col++)
928	{
929	if (row!=0) row=modp_mul(*row,red_val);
930	row++;
931	}
932	}
933	#endif
934	RowListAdd (first_col, mon);
935	}
936
937	static void NewResultEntry () // creates an entry for new modp result
938	{
939	modp_result_entry *temp;
940	temp=(modp_result_entry*)omAlloc0(sizeof(modp_result_entry));
941	if (cur_result==NULL)
942	{
943	modp_result=temp;
944	temp->prev=NULL;
945	}
946	else
947	{
948	temp->prev=cur_result;
949	cur_result->next=temp;
950	}
951	cur_result=temp;
952	cur_result->next=NULL;
953	cur_result->p=myp;
954	cur_result->generator=NULL;
955	cur_result->n_generators=0;
956	n_results++;
957	}
958
959	static void FreeResultEntry (modp_result_entry *e) // destroys the result entry, without worrying about where it is
960	{
961	generator_entry *cur_gen;
962	generator_entry *next_gen;
963	cur_gen=e->generator;
964	while (cur_gen!=NULL)
965	{
966	next_gen=cur_gen->next;
967	omFree(cur_gen->coef);
968	omFree(cur_gen->lt);
969	omFree(cur_gen);
970	cur_gen=next_gen;
971	}
972	omFree(e);
973	}
974
975
976	static void NewGenerator (mono_type mon) // new generator in modp comp found, should be stored on the list
977	{
978	generator_entry *cur_ptr;
979	generator_entry *prev_ptr;
980	generator_entry *temp;
981	cur_ptr=cur_result->generator;
982	prev_ptr=NULL;
983	while (cur_ptr!=NULL)
984	{
985	prev_ptr=cur_ptr;
986	cur_ptr=cur_ptr->next;
987	}
988	temp=(generator_entry*)omAlloc0(sizeof(generator_entry));
989	if (prev_ptr==NULL) cur_result->generator=temp;
990	else prev_ptr->next=temp;
991	temp->next=NULL;
992	temp->coef=(modp_number)omAlloc0(sizeof(modp_number)final_base_dim);
993	memcpy(temp->coef,my_solve_row,sizeof(modp_number)*final_base_dim);
994	temp->lt=ZeroMonomial ();
995	memcpy(temp->lt,mon,sizeof(exponent)*variables);
996	temp->ltcoef=1;
997	cur_result->n_generators++;
998	}
999
1000	static void MultGenerators () // before reconstructing, all denominators must be cancelled
1001	{
1002	#ifndef integerstrategy
1003	int i;
1004	generator_entry *cur_ptr;
1005	cur_ptr=cur_result->generator;
1006	while (cur_ptr!=NULL)
1007	{
1008	for (i=0;i<final_base_dim;i++)
1009	cur_ptr->coef[i]=modp_mul(cur_ptr->coef[i],modp_denom);
1010	cur_ptr->ltcoef=modp_denom;
1011	cur_ptr=cur_ptr->next;
1012	}
1013	#endif
1014	}
1015	#if 0 /* only debbuging */
1016	void PresentGenerator (int i) // only for debugging, writes a generator in its form in program
1017	{
1018	int j;
1019	modp_result_entry *cur_ptr;
1020	generator_entry *cur_gen;
1021	cur_ptr=modp_result;
1022	while (cur_ptr!=NULL)
1023	{
1024	cur_gen=cur_ptr->generator;
1025	for (j=0;j<i;j++) cur_gen=cur_gen->next;
1026	for (j=0;j<final_base_dim;j++)
1027	{
1028	Print("%d;", cur_gen->coef[j]);
1029	}
1030	PrintS(" and LT = ");
1031	WriteMono (cur_gen->lt);
1032	Print(" ( %d ) prime = %d\n", cur_gen->ltcoef, cur_ptr->p);
1033	cur_ptr=cur_ptr->next;
1034	}
1035	}
1036	#endif
1037
1038	static modp_number TakePrime (modp_number /p/) // takes "previous" (smaller) prime
1039	{
1040	myp_index--;
1041	return cf_getSmallPrime(myp_index);
1042	}
1043
1044	static void PrepareChinese (int n) // initialization for CRA
1045	{
1046	int i,k;
1047	modp_result_entry *cur_ptr;
1048	cur_ptr=modp_result;
1049	modp_number *congr_ptr;
1050	modp_number prod;
1051	in_gamma=(modp_number)omAlloc0(sizeof(modp_number)n);
1052	congr=(modp_number)omAlloc0(sizeof(modp_number)n);
1053	congr_ptr=congr;
1054	while (cur_ptr!=NULL)
1055	{
1056	*congr_ptr=cur_ptr->p;
1057	cur_ptr=cur_ptr->next;
1058	congr_ptr++;
1059	}
1060	for (k=1;k<n;k++)
1061	{
1062	prod=congr[0]%congr[k];
1063	for (i=1;i<=k-1;i++) prod=(prod*congr[i])%congr[k];
1064	in_gamma[i]=OneInverse(prod,congr[k]);
1065	}
1066	mpz_init(bigcongr);
1067	mpz_set_si(bigcongr,congr[0]);
1068	for (k=1;k<n;k++) mpz_mul_ui(bigcongr,bigcongr,congr[k]);
1069	}
1070
1071	static void CloseChinese () // after CRA
1072	{
1073	omFree(in_gamma);
1074	omFree(congr);
1075	mpz_clear(bigcongr);
1076	}
1077
1078	static void ClearGCD () // divides polynomials in basis by gcd of coefficients
1079	{
1080	bool first_gcd=true;
1081	int i;
1082	mpz_t g;
1083	mpz_init(g);
1084	for (i=0;i<=final_base_dim;i++)
1085	{
1086	if (mpz_sgn(polycoef[i])!=0)
1087	{
1088	if (first_gcd)
1089	{
1090	first_gcd=false;
1091	mpz_set(g,polycoef[i]);
1092	}
1093	else
1094	mpz_gcd(g,g,polycoef[i]);
1095	}
1096	}
1097	for (i=0;i<=final_base_dim;i++) mpz_divexact(polycoef[i],polycoef[i],g);
1098	mpz_clear(g);
1099	}
1100
1101	static void ReconstructGenerator (int ngen,int n) // recostruction of generator from various modp comp
1102	{
1103	int i,j,k;
1104	int coef;
1105	char *str=NULL;
1106	str=(char)omAlloc0(sizeof(char)1000);
1107	modp_result_entry *cur_ptr;
1108	generator_entry *cur_gen;
1109	modp_number *u;
1110	modp_number *v;
1111	modp_number temp;
1112	mpz_t sol;
1113	mpz_t nsol;
1114	mpz_init(sol);
1115	mpz_init(nsol);
1116	u=(modp_number)omAlloc0(sizeof(modp_number)n);
1117	v=(modp_number)omAlloc0(sizeof(modp_number)n);
1118	for (coef=0;coef<=final_base_dim;coef++)
1119	{
1120	i=0;
1121	cur_ptr=modp_result;
1122	while (cur_ptr!=NULL)
1123	{
1124	cur_gen=cur_ptr->generator;
1125	for (j=0;j<ngen;j++) cur_gen=cur_gen->next; // we have to take jth generator
1126	if (coef<final_base_dim) u[i]=cur_gen->coef[coef]; else u[i]=cur_gen->ltcoef;
1127	cur_ptr=cur_ptr->next;
1128	i++;
1129	}
1130	v[0]=u[0]; // now CRA begins
1131	for (k=1;k<n;k++)
1132	{
1133	temp=v[k-1];
1134	for (j=k-2;j>=0;j--) temp=(temp*congr[j]+v[j])%congr[k];
1135	temp=u[k]-temp;
1136	if (temp<0) temp=temp+congr[k];
1137	v[k]=(temp*in_gamma[k])%congr[k];
1138	}
1139	mpz_set_si(sol,v[n-1]);
1140	for (k=n-2;k>=0;k--)
1141	{
1142	mpz_mul_ui(sol,sol,congr[k]);
1143	mpz_add_ui(sol,sol,v[k]);
1144	} // now CRA ends
1145	mpz_sub(nsol,sol,bigcongr);
1146	int s=mpz_cmpabs(sol,nsol);
1147	if (s>0) mpz_set(sol,nsol); // chooses representation closer to 0
1148	mpz_set(polycoef[coef],sol);
1149	if (coef<final_base_dim)
1150	memcpy(polyexp[coef],generic_column_name[coef],sizeof(exponent)*variables);
1151	else
1152	memcpy(polyexp[coef],MonListElement (generic_lt,ngen),sizeof(exponent)*variables);
1153	#ifdef checksize
1154	size=mpz_sizeinbase(sol,10);
1155	if (size>maximal_size) maximal_size=size;
1156	#endif
1157	}
1158	omFree(u);
1159	omFree(v);
1160	omFree(str);
1161	ClearGCD ();
1162	mpz_clear(sol);
1163	mpz_clear(nsol);
1164	}
1165
1166	static void Discard () // some unlucky prime occurs
1167	{
1168	modp_result_entry *temp;
1169	#ifdef writemsg
1170	Print(", prime=%d", cur_result->p);
1171	#endif
1172	bad_primes++;
1173	if (good_primes>bad_primes)
1174	{
1175	#ifdef writemsg
1176	Print("-discarding this comp (%dth)\n", n_results);
1177	#endif
1178	temp=cur_result;
1179	cur_result=cur_result->prev;
1180	cur_result->next=NULL;
1181	n_results--;
1182	FreeResultEntry (temp);
1183	}
1184	else
1185	{
1186	#ifdef writemsg
1187	PrintS("-discarding ALL.\n");
1188	#endif
1189	int i;
1190	modp_result_entry *ntfree;
1191	generator_entry *cur_gen;
1192	temp=cur_result->prev;
1193	while (temp!=NULL)
1194	{
1195	ntfree=temp->prev;
1196	FreeResultEntry (temp);
1197	temp=ntfree;
1198	}
1199	modp_result=cur_result;
1200	cur_result->prev=NULL;
1201	n_results=1;
1202	good_primes=1;
1203	bad_primes=0;
1204	generic_n_generators=cur_result->n_generators;
1205	cur_gen=cur_result->generator;
1206	generic_lt=FreeMonList (generic_lt);
1207	for (i=0;i<generic_n_generators;i++)
1208	{
1209	generic_lt=MonListAdd (generic_lt,cur_gen->lt);
1210	cur_gen=cur_gen->next;
1211	}
1212	for (i=0;i<final_base_dim;i++) memcpy(generic_column_name[i],column_name[i],sizeof(exponent)*variables);
1213	}
1214	}
1215
1216	static void modp_SetColumnNames () // used by modp - sets column names, the old table will be destroyed
1217	{
1218	int i;
1219	for (i=0;i<final_base_dim;i++) memcpy(generic_column_name[i],column_name[i],sizeof(exponent)*variables);
1220	}
1221
1222	static void CheckColumnSequence () // checks if scheme of computations is as generic one
1223	{
1224	int i;
1225	if (cur_result->n_generators!=generic_n_generators)
1226	{
1227	#ifdef writemsg
1228	PrintS("wrong number of generators occurred");
1229	#else
1230	if (protocol) PrintS("ng");
1231	#endif
1232	Discard ();
1233	return;
1234	}
1235	if (denom_divisible)
1236	{
1237	#ifdef writemsg
1238	PrintS("denom of coef divisible by p");
1239	#else
1240	if (protocol) PrintS("dp");
1241	#endif
1242	Discard ();
1243	return;
1244	}
1245	generator_entry *cur_gen;
1246	mon_list_entry *cur_mon;
1247	cur_gen=cur_result->generator;
1248	cur_mon=generic_lt;
1249	for (i=0;i<generic_n_generators;i++)
1250	{
1251	if (!EqualMon(cur_mon->mon,cur_gen->lt))
1252	{
1253	#ifdef writemsg
1254	PrintS("wrong leading term occurred");
1255	#else
1256	if (protocol) PrintS("lt");
1257	#endif
1258	Discard ();
1259	return;
1260	}
1261	cur_gen=cur_gen->next;
1262	cur_mon=cur_mon->next;
1263	}
1264	for (i=0;i<final_base_dim;i++)
1265	{
1266	if (!EqualMon(generic_column_name[i],column_name[i]))
1267	{
1268	#ifdef writemsg
1269	PrintS("wrong seq of cols occurred");
1270	#else
1271	if (protocol) PrintS("sc");
1272	#endif
1273	Discard ();
1274	return;
1275	}
1276	}
1277	good_primes++;
1278	}
1279	#if 0 /* only debuggig */
1280	void WriteGenerator () // writes generator (only for debugging)
1281	{
1282	char *str;
1283	str=(char)omAlloc0(sizeof(char)1000);
1284	int i;
1285	for (i=0;i<=final_base_dim;i++)
1286	{
1287	str=mpz_get_str(str,10,polycoef[i]);
1288	PrintS(str);
1289	PrintS("*");
1290	WriteMono(polyexp[i]);
1291	PrintS(" ");
1292	}
1293	omFree(str);
1294	PrintLn();
1295	}
1296	#endif
1297
1298	static bool CheckGenerator () // evaluates generator to check whether it is good
1299	{
1300	mpz_t val,sum;
1301	int con,i;
1302	mpz_init(val);
1303	mpz_init(sum);
1304	for (con=0;con<final_base_dim;con++)
1305	{
1306	mpz_set_ui(sum,0);
1307	for (i=0;i<=final_base_dim;i++)
1308	{
1309	int_Evaluate(val, polyexp[i], condition_list[con]);
1310	mpz_mul(val,val,polycoef[i]);
1311	mpz_add(sum,sum,val);
1312	}
1313	if (mpz_sgn(sum)!=0)
1314	{
1315	mpz_clear(val);
1316	mpz_clear(sum);
1317	return false;
1318	}
1319	}
1320	mpz_clear(val);
1321	mpz_clear(sum);
1322	return true;
1323	}
1324
1325	static void ClearGenList ()
1326	{
1327	gen_list_entry *temp;
1328	int i;
1329	while (gen_list!=NULL)
1330	{
1331	temp=gen_list->next;
1332	for (i=0;i<=final_base_dim;i++)
1333	{
1334	mpz_clear(gen_list->polycoef[i]);
1335	omFree(gen_list->polyexp[i]);
1336	}
1337	omFree(gen_list->polycoef);
1338	omFree(gen_list->polyexp);
1339	omFree(gen_list);
1340	gen_list=temp;
1341	}
1342	}
1343
1344	static void UpdateGenList ()
1345	{
1346	gen_list_entry temp,prev;
1347	int i,j;
1348	prev=NULL;
1349	temp=gen_list;
1350	exponent deg;
1351	for (i=0;i<=final_base_dim;i++)
1352	{
1353	deg=MonDegree(polyexp[i]);
1354	for (j=0;j<deg;j++)
1355	{
1356	mpz_mul(polycoef[i],polycoef[i],common_denom);
1357	}
1358	}
1359	ClearGCD ();
1360	while (temp!=NULL)
1361	{
1362	prev=temp;
1363	temp=temp->next;
1364	}
1365	temp=(gen_list_entry*)omAlloc0(sizeof(gen_list_entry));
1366	if (prev==NULL) gen_list=temp; else prev->next=temp;
1367	temp->next=NULL;
1368	temp->polycoef=(mpz_t)omAlloc(sizeof(mpz_t)(final_base_dim+1));
1369	temp->polyexp=(mono_type)omAlloc(sizeof(mono_type)(final_base_dim+1));
1370	for (i=0;i<=final_base_dim;i++)
1371	{
1372	mpz_init(temp->polycoef[i]);
1373	mpz_set(temp->polycoef[i],polycoef[i]);
1374	temp->polyexp[i]=ZeroMonomial ();
1375	memcpy(temp->polyexp[i],polyexp[i],sizeof(exponent)*variables);
1376	}
1377	}
1378
1379	#if 0 /* only debugging */
1380	void ShowGenList ()
1381	{
1382	gen_list_entry *temp;
1383	int i;
1384	char *str;
1385	str=(char)omAlloc0(sizeof(char)1000);
1386	temp=gen_list;
1387	while (temp!=NULL)
1388	{
1389	PrintS("generator: ");
1390	for (i=0;i<=final_base_dim;i++)
1391	{
1392	str=mpz_get_str(str,10,temp->polycoef[i]);
1393	PrintS(str);
1394	PrintS("*");
1395	WriteMono(temp->polyexp[i]);
1396	}
1397	PrintLn();
1398	temp=temp->next;
1399	}
1400	omFree(str);
1401	}
1402	#endif
1403
1404
1405	static void modp_Main ()
1406	{
1407	mono_type cur_mon;
1408	cur_mon= ZeroMonomial ();
1409	modp_denom=1;
1410	bool row_is_zero;
1411
1412	#if 0 /* only debugging */
1413	Info ();
1414	#endif
1415
1416	while (check_list!=NULL)
1417	{
1418	TakeNextMonomial (cur_mon);
1419	ProduceRow (cur_mon);
1420	#if 0 /* only debugging */
1421	cout << "row produced for monomial ";
1422	WriteMono (cur_mon);
1423	cout << endl;
1424	Info ();
1425	#endif
1426	ReduceRow ();
1427	row_is_zero = RowIsZero ();
1428	if (row_is_zero)
1429	{
1430	lt_list=MonListAdd (lt_list,cur_mon);
1431	ReduceCheckListByMon (cur_mon);
1432	NewGenerator (cur_mon);
1433	#if 0 /* only debugging */
1434	cout << "row is zero - linear dependence found (should be seen in my_solve_row)" << endl;
1435	cout << "monomial added to leading terms list" << endl;
1436	cout << "check list updated" << endl;
1437	Info ();
1438	#endif
1439	}
1440	else
1441	{
1442	base_list= MonListAdd (base_list,cur_mon);
1443	UpdateCheckList (cur_mon);
1444	ReduceCheckListByLTs ();
1445	#if 0 /* only debugging */
1446	cout << "row is non-zero" << endl;
1447	cout << "monomial added to quotient basis list" << endl;
1448	cout << "new monomials added to check list" << endl;
1449	cout << "check list reduced by monomials from leading term list" << endl;
1450	Info ();
1451	#endif
1452	PrepareRow (cur_mon);
1453	#if 0 /* only debugging */
1454	cout << "row prepared and put into matrix" << endl;
1455	Info ();
1456	#endif
1457	}
1458	}
1459	omFree(cur_mon);
1460	}
1461
1462	static void ResolveCoeff (mpq_t c, number m)
1463	{
1464	if ((long)m & SR_INT)
1465	{
1466	long m_val=SR_TO_INT(m);
1467	mpq_set_si(c,m_val,1);
1468	}
1469	else
1470	{
1471	if (m->s<2)
1472	{
1473	mpz_set(mpq_numref(c),m->z);
1474	mpz_set(mpq_denref(c),m->n);
1475	mpq_canonicalize(c);
1476	}
1477	else
1478	{
1479	mpq_set_z(c,m->z);
1480	}
1481	}
1482	}
1483
1484	ideal interpolation(const std::vector<ideal>& L, intvec *v)
1485	{
1486	protocol=TEST_OPT_PROT; // should be set if option(prot) is enabled
1487
1488	bool data_ok=true;
1489
1490	// reading the ring data ***************************************************
1491	if ((currRing==NULL) \|\| ((!rField_is_Zp (currRing))&&(!rField_is_Q (currRing))))
1492	{
1493	WerrorS("coefficient field should be Zp or Q!");
1494	return NULL;
1495	}
1496	if ((currRing->qideal)!=NULL)
1497	{
1498	WerrorS("quotient ring not supported!");
1499	return NULL;
1500	}
1501	if ((currRing->OrdSgn)!=1)
1502	{
1503	WerrorS("ordering must be global!");
1504	return NULL;
1505	}
1506	n_points=v->length ();
1507	if (n_points!=L.size())
1508	{
1509	WerrorS("list and intvec must have the same length!");
1510	return NULL;
1511	}
1512	assume( n_points > 0 );
1513	variables=currRing->N;
1514	only_modp=rField_is_Zp(currRing);
1515	if (only_modp) myp=rChar(currRing);
1516	// ring data read **********************************************************
1517
1518
1519	multiplicity=(int)omAlloc(sizeof(int)n_points);
1520	int i;
1521	for (i=0;i<n_points;i++) multiplicity[i]=(*v)[i];
1522
1523	final_base_dim = CalcBaseDim ();
1524
1525	#ifdef writemsg
1526	Print("number of variables: %d\n", variables);
1527	Print("number of points: %d\n", n_points);
1528	PrintS("multiplicities: ");
1529	for (i=0;i<n_points;i++) Print("%d ", multiplicity[i]);
1530	PrintLn();
1531	Print("general initialization for dimension %d ...\n", final_base_dim);
1532	#endif
1533
1534	GeneralInit ();
1535
1536	// reading coordinates of points from ideals **********************************
1537	mpq_t divisor;
1538	if (!only_modp) mpq_init(divisor);
1539	int j;
1540	for(i=0; i<L.size();i++)
1541	{
1542	ideal I = L[i];
1543	for(j=0;j<IDELEMS(I);j++)
1544	{
1545	poly p=I->m[j];
1546	if (p!=NULL)
1547	{
1548	poly ph=pHead(p);
1549	int pcvar=pVar(ph);
1550	if (pcvar!=0)
1551	{
1552	pcvar--;
1553	if (coord_exist[i][pcvar])
1554	{
1555	Print("coordinate %d for point %d initialized twice!\n",pcvar+1,i+1);
1556	data_ok=false;
1557	}
1558	number m;
1559	m=pGetCoeff(p); // possible coefficient standing by a leading monomial
1560	if (!only_modp) ResolveCoeff (divisor,m);
1561	number n;
1562	if (pNext(p)!=NULL) n=pGetCoeff(pNext(p));
1563	else n=nInit(0);
1564	if (only_modp)
1565	{
1566	n=nInpNeg(n);
1567	n=nDiv(n,m);
1568	modp_points[i][pcvar]=(int)((long)n);
1569	}
1570	else
1571	{
1572	ResolveCoeff (q_points[i][pcvar],n);
1573	mpq_neg(q_points[i][pcvar],q_points[i][pcvar]);
1574	mpq_div(q_points[i][pcvar],q_points[i][pcvar],divisor);
1575	}
1576	coord_exist[i][pcvar]=true;
1577	}
1578	else
1579	{
1580	PrintS("not a variable? ");
1581	wrp(p);
1582	PrintLn();
1583	data_ok=false;
1584	}
1585	pDelete(&ph);
1586	}
1587	}
1588	}
1589	if (!only_modp) mpq_clear(divisor);
1590	// data from ideal read *******************************************************
1591
1592	// ckecking if all coordinates are initialized
1593	for (i=0;i<n_points;i++)
1594	{
1595	for (j=0;j<variables;j++)
1596	{
1597	if (!coord_exist[i][j])
1598	{
1599	Print("coordinate %d for point %d not known!\n",j+1,i+1);
1600	data_ok=false;
1601	}
1602	}
1603	}
1604
1605	if (!data_ok)
1606	{
1607	GeneralDone();
1608	WerrorS("data structure is invalid");
1609	return NULL;
1610	}
1611
1612	if (!only_modp) IntegerPoints ();
1613	MakeConditions ();
1614	#ifdef writemsg
1615	PrintS("done.\n");
1616	#else
1617	if (protocol) Print("[vdim %d]",final_base_dim);
1618	#endif
1619
1620
1621	// main procedure *********************************************************************
1622	int modp_cycles=10;
1623	bool correct_gen=false;
1624	if (only_modp) modp_cycles=1;
1625	myp_index=cf_getNumSmallPrimes ();
1626
1627	while ((!correct_gen)&&(myp_index>1))
1628	{
1629	#ifdef writemsg
1630	Print("trying %d cycles mod p...\n",modp_cycles);
1631	#else
1632	if (protocol) Print("(%d)",modp_cycles);
1633	#endif
1634	while ((n_results<modp_cycles)&&(myp_index>1)) // some computations mod p
1635	{
1636	if (!only_modp) myp=TakePrime (myp);
1637	NewResultEntry ();
1638	InitProcData ();
1639	if (only_modp) modp_PrepareProducts (); else int_PrepareProducts ();
1640
1641	modp_Main ();
1642
1643	if (!only_modp)
1644	{
1645	MultGenerators ();
1646	CheckColumnSequence ();
1647	}
1648	else
1649	{
1650	modp_SetColumnNames ();
1651	}
1652	FreeProcData ();
1653	}
1654
1655	if (!only_modp)
1656	{
1657	PrepareChinese (modp_cycles);
1658	correct_gen=true;
1659	for (i=0;i<generic_n_generators;i++)
1660	{
1661	ReconstructGenerator (i,modp_cycles);
1662	correct_gen=CheckGenerator ();
1663	if (!correct_gen)
1664	{
1665	#ifdef writemsg
1666	PrintS("wrong generator!\n");
1667	#else
1668	// if (protocol) PrintS("!g");
1669	#endif
1670	ClearGenList ();
1671	break;
1672	}
1673	else
1674	{
1675	UpdateGenList ();
1676	}
1677	}
1678	#ifdef checksize
1679	Print("maximal size of output: %d, precision bound: %d.\n",maximalsize,mpz_sizeinbase(bigcongr,10));
1680	#endif
1681	CloseChinese ();
1682	modp_cycles=modp_cycles+10;
1683	}
1684	else
1685	{
1686	correct_gen=true;
1687	}
1688	}
1689	// end of main procedure ************************************************************************************
1690
1691	#ifdef writemsg
1692	PrintS("computations finished.\n");
1693	#else
1694	if (protocol) PrintLn();
1695	#endif
1696
1697	if (!correct_gen)
1698	{
1699	GeneralDone ();
1700	ClearGenList ();
1701	WerrorS("internal error - coefficient too big!");
1702	return NULL;
1703	}
1704
1705	// passing data to ideal *************************************************************************************
1706	ideal ret;
1707
1708	if (only_modp)
1709	{
1710	mono_type mon;
1711	ret=idInit(modp_result->n_generators,1);
1712	generator_entry *cur_gen=modp_result->generator;
1713	for(i=0;i<IDELEMS(ret);i++)
1714	{
1715	poly p,sum;
1716	sum=NULL;
1717	int a;
1718	int cf;
1719	for (a=final_base_dim;a>=0;a--)
1720	{
1721	if (a==final_base_dim) cf=cur_gen->ltcoef; else cf=cur_gen->coef[a];
1722	if (cf!=0)
1723	{
1724	p=pISet(cf);
1725	if (a==final_base_dim) mon=cur_gen->lt; else mon=generic_column_name[a];
1726	for (j=0;j<variables;j++) pSetExp(p,j+1,mon[j]);
1727	pSetm(p);
1728	sum=pAdd(sum,p);
1729	}
1730	}
1731	ret->m[i]=sum;
1732	cur_gen=cur_gen->next;
1733	}
1734	}
1735	else
1736	{
1737	ret=idInit(generic_n_generators,1);
1738	gen_list_entry *temp=gen_list;
1739	for(i=0;i<IDELEMS(ret);i++)
1740	{
1741	poly p,sum;
1742	sum=NULL;
1743	int a;
1744	for (a=final_base_dim;a>=0;a--) // build one polynomial
1745	{
1746	if (mpz_sgn(temp->polycoef[a])!=0)
1747	{
1748	number n=ALLOC_RNUMBER();
1749	#ifdef LDEBUG
1750	n->debug=123456;
1751	#endif
1752	mpz_init_set(n->z,temp->polycoef[a]);
1753	n->s=3;
1754	n_Normalize(n, currRing->cf);
1755	p=pNSet(n); //a monomial
1756	for (j=0;j<variables;j++) pSetExp(p,j+1,temp->polyexp[a][j]);
1757	pSetm(p); // after all pSetExp
1758	sum=pAdd(sum,p);
1759	}
1760	}
1761	ret->m[i]=sum;
1762	temp=temp->next;
1763	}
1764	}
1765	// data transferred ****************************************************************************
1766
1767
1768	GeneralDone ();
1769	ClearGenList ();
1770	return ret;
1771	}
1772
1773

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