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source: git/kernel/numeric/mpr_base.cc @ 06b685

spielwiese

Last change on this file since 06b685 was cec9624, checked in by Hans Schoenemann <hannes@…>, 5 years ago
add: pp_DivideM, pp_Divide
Property mode set to `100644`
File size: 73.9 KB

Line
1	/****************************************
2	* Computer Algebra System SINGULAR *
3	****************************************/
4
5	/*
6	* ABSTRACT - multipolynomial resultants - resultant matrices
7	* ( sparse, dense, u-resultant solver )
8	*/
9
10	//-> includes
11
12
13
14	#include "kernel/mod2.h"
15
16	#include "misc/mylimits.h"
17	#include "misc/options.h"
18	#include "misc/intvec.h"
19	#include "misc/sirandom.h"
20
21	#include "coeffs/numbers.h"
22	#include "coeffs/mpr_global.h"
23
24	#include "polys/matpol.h"
25	#include "polys/sparsmat.h"
26
27	#include "polys/clapsing.h"
28
29	#include "kernel/polys.h"
30	#include "kernel/ideals.h"
31
32	#include "mpr_base.h"
33	#include "mpr_numeric.h"
34
35	#include <cmath>
36	//<-
37
38	//%s
39	//-----------------------------------------------------------------------------
40	//-------------- sparse resultant matrix --------------------------------------
41	//-----------------------------------------------------------------------------
42
43	//-> definitions
44
45	//#define mprTEST
46	//#define mprMINKSUM
47
48	#define MAXPOINTS 10000
49	#define MAXINITELEMS 256
50	#define LIFT_COOR 50000 // siRand() % LIFT_COOR gives random lift value
51	#define SCALEDOWN 100.0 // lift value scale down for linear program
52	#define MINVDIST 0.0
53	#define RVMULT 0.0001 // multiplicator for random shift vector
54	#define MAXRVVAL 50000
55	#define MAXVARS 100
56	//<-
57
58	//-> sparse resultant matrix
59
60	/* set of points */
61	class pointSet;
62
63
64
65	/* sparse resultant matrix class */
66	class resMatrixSparse : virtual public resMatrixBase
67	{
68	public:
69	resMatrixSparse( const ideal _gls, const int special = SNONE );
70	~resMatrixSparse();
71
72	// public interface according to base class resMatrixBase
73	ideal getMatrix();
74
75	/** Fills in resMat[][] with evpoint[] and gets determinant
76	* uRPos[i][1]: row of matrix
77	* uRPos[i][idelem+1]: col of u(0)
78	* uRPos[i][2..idelem]: col of u(1) .. u(n)
79	* i= 1 .. numSet0
80	*/
81	number getDetAt( const number* evpoint );
82
83	poly getUDet( const number* evpoint );
84
85	private:
86	resMatrixSparse( const resMatrixSparse & );
87
88	void randomVector( const int dim, mprfloat shift[] );
89
90	/** Row Content Function
91	* Finds the largest i such that F[i] is a point, F[i]= a[ij] in A[i] for some j.
92	* Returns -1 iff the point vert does not lie in a cell
93	*/
94	int RC( pointSet *pQ, pointSet E, int vert, mprfloat shift[] );
95
96	/* Remaps a result of LP to the according point set Qi.
97	* Returns false iff remaping was not possible, otherwise true.
98	*/
99	bool remapXiToPoint( const int indx, pointSet *pQ, int set, int *vtx );
100
101	/** create coeff matrix
102	* uRPos[i][1]: row of matrix
103	* uRPos[i][idelem+1]: col of u(0)
104	* uRPos[i][2..idelem]: col of u(1) .. u(n)
105	* i= 1 .. numSet0
106	* Returns the dimension of the matrix or -1 in case of an error
107	*/
108	int createMatrix( pointSet *E );
109
110	pointSet * minkSumAll( pointSet **pQ, int numq, int dim );
111	pointSet * minkSumTwo( pointSet Q1, pointSet Q2, int dim );
112
113	private:
114	ideal gls;
115
116	int n, idelem; // number of variables, polynoms
117	int numSet0; // number of elements in S0
118	int msize; // size of matrix
119
120	intvec *uRPos;
121
122	ideal rmat; // sparse matrix representation
123
124	simplex * LP; // linear programming stuff
125	};
126	//<-
127
128	//-> typedefs and structs
129	poly monomAt( poly p, int i );
130
131	typedef unsigned int Coord_t;
132
133	struct setID
134	{
135	int set;
136	int pnt;
137	};
138
139	struct onePoint
140	{
141	Coord_t * point; // point[0] is unused, maxial dimension is MAXVARS+1
142	setID rc; // filled in by Row Content Function
143	struct onePoint * rcPnt; // filled in by Row Content Function
144	};
145
146	typedef struct onePoint * onePointP;
147
148	/* sparse matrix entry */
149	struct _entry
150	{
151	number num;
152	int col;
153	struct _entry * next;
154	};
155
156	typedef struct _entry * entry;
157	//<-
158
159	//-> class pointSet
160	class pointSet
161	{
162	private:
163	onePointP *points; // set of onePoint's, index [1..num], supports of monoms
164	bool lifted;
165
166	public:
167	int num; // number of elements in points
168	int max; // maximal entries in points, i.e. allocated mem
169	int dim; // dimension, i.e. valid coord entries in point
170	int index; // should hold unique identifier of point set
171
172	pointSet( const int _dim, const int _index= 0, const int count= MAXINITELEMS );
173	~pointSet();
174
175	// pointSet.points[i] equals pointSet[i]
176	inline onePointP operator[] ( const int index );
177
178	/** Adds a point to pointSet, copy vert[0,...,dim] ot point[num+1][0,...,dim].
179	* Returns false, iff additional memory was allocated ( i.e. num >= max )
180	* else returns true
181	*/
182	bool addPoint( const onePointP vert );
183
184	/** Adds a point to pointSet, copy vert[0,...,dim] ot point[num+1][0,...,dim].
185	* Returns false, iff additional memory was allocated ( i.e. num >= max )
186	* else returns true
187	*/
188	bool addPoint( const int * vert );
189
190	/** Adds a point to pointSet, copy vert[0,...,dim] ot point[num+1][0,...,dim].
191	* Returns false, iff additional memory was allocated ( i.e. num >= max )
192	* else returns true
193	*/
194	bool addPoint( const Coord_t * vert );
195
196	/* Removes the point at intex indx */
197	bool removePoint( const int indx );
198
199	/** Adds point to pointSet, iff pointSet \cap point = \emptyset.
200	* Returns true, iff added, else false.
201	*/
202	bool mergeWithExp( const onePointP vert );
203
204	/** Adds point to pointSet, iff pointSet \cap point = \emptyset.
205	* Returns true, iff added, else false.
206	*/
207	bool mergeWithExp( const int * vert );
208
209	/* Adds support of poly p to pointSet, iff pointSet \cap point = \emptyset. */
210	void mergeWithPoly( const poly p );
211
212	/* Returns the row polynom multiplicator in vert[] */
213	void getRowMP( const int indx, int * vert );
214
215	/* Returns index of supp(LT(p)) in pointSet. */
216	int getExpPos( const poly p );
217
218	/** sort lex
219	*/
220	void sort();
221
222	/** Lifts the point set using sufficiently generic linear lifting
223	* homogeneous forms l[1]..l[dim] in Z. Every l[i] is of the form
224	* L1x1+...+Lnxn, for generic L1..Ln in Z.
225	*
226	* Lifting raises dimension by one!
227	*/
228	void lift( int *l= NULL ); // !! increments dim by 1
229	void unlift() { dim--; lifted= false; }
230
231	private:
232	pointSet( const pointSet & );
233
234	/** points[a] < points[b] ? */
235	inline bool smaller( int, int );
236
237	/** points[a] > points[b] ? */
238	inline bool larger( int, int );
239
240	/** Checks, if more mem is needed ( i.e. num >= max ),
241	* returns false, if more mem was allocated, else true
242	*/
243	inline bool checkMem();
244	};
245	//<-
246
247	//-> class convexHull
248	/* Compute convex hull of given exponent set */
249	class convexHull
250	{
251	public:
252	convexHull( simplex * _pLP ) : pLP(_pLP) {}
253	~convexHull() {}
254
255	/** Computes the point sets of the convex hulls of the supports given
256	* by the polynoms in gls.
257	* Returns Q[].
258	*/
259	pointSet ** newtonPolytopesP( const ideal gls );
260	ideal newtonPolytopesI( const ideal gls );
261
262	private:
263	/** Returns true iff the support of poly pointPoly is inside the
264	* convex hull of all points given by the support of poly p.
265	*/
266	bool inHull(poly p, poly pointPoly, int m, int site);
267
268	private:
269	pointSet **Q;
270	int n;
271	simplex * pLP;
272	};
273	//<-
274
275	//-> class mayanPyramidAlg
276	/* Compute all lattice points in a given convex hull */
277	class mayanPyramidAlg
278	{
279	public:
280	mayanPyramidAlg( simplex * _pLP ) : n((currRing->N)), pLP(_pLP) {}
281	~mayanPyramidAlg() {}
282
283	/** Drive Mayan Pyramid Algorithm.
284	* The Alg computes conv(Qi[]+shift[]).
285	*/
286	pointSet * getInnerPoints( pointSet **_q_i, mprfloat _shift[] );
287
288	private:
289
290	/** Recursive Mayan Pyramid algorithm for directly computing MinkowskiSum
291	* lattice points for (n+1)-fold MinkowskiSum of given point sets Qi[].
292	* Recursively for range of dim: dim in [0..n); acoords[0..var) fixed.
293	* Stores only MinkowskiSum points of udist > 0: done by storeMinkowskiSumPoints.
294	*/
295	void runMayanPyramid( int dim );
296
297	/** Compute v-distance via Linear Programing
298	* Linear Program finds the v-distance of the point in accords[].
299	* The v-distance is the distance along the direction v to boundary of
300	* Minkowski Sum of Qi (here vector v is represented by shift[]).
301	* Returns the v-distance or -1.0 if an error occurred.
302	*/
303	mprfloat vDistance( Coord_t * acoords, int dim );
304
305	/** LP for finding min/max coord in MinkowskiSum, given previous coors.
306	* Assume MinkowskiSum in non-negative quadrants
307	* coor in [0,n); fixed coords in acoords[0..coor)
308	*/
309	void mn_mx_MinkowskiSum( int dim, Coord_t minR, Coord_t maxR );
310
311	/** Stores point in E->points[pt], iff v-distance != 0
312	* Returns true iff point was stored, else flase
313	*/
314	bool storeMinkowskiSumPoint();
315
316	private:
317	pointSet **Qi;
318	pointSet *E;
319	mprfloat *shift;
320
321	int n,idelem;
322
323	Coord_t acoords[MAXVARS+2];
324
325	simplex * pLP;
326	};
327	//<-
328
329	//-> debug output stuff
330	#if defined(mprDEBUG_PROT) \|\| defined(mprDEBUG_ALL)
331	void print_mat(mprfloat **a, int maxrow, int maxcol)
332	{
333	int i, j;
334
335	for (i = 1; i <= maxrow; i++)
336	{
337	PrintS("[");
338	for (j = 1; j <= maxcol; j++) Print("% 7.2f, ", a[i][j]);
339	PrintS("],\n");
340	}
341	}
342	void print_bmat(mprfloat *a, int nrows, int ncols, int N, int iposv)
343	{
344	int i, j;
345
346	printf("Output matrix from LinProg");
347	for (i = 1; i <= nrows; i++)
348	{
349	printf("\n[ ");
350	if (i == 1) printf(" ");
351	else if (iposv[i-1] <= N) printf("X%d", iposv[i-1]);
352	else printf("Y%d", iposv[i-1]-N+1);
353	for (j = 1; j <= ncols; j++) printf(" %7.2f ",(double)a[i][j]);
354	printf(" ]");
355	} printf("\n");
356	fflush(stdout);
357	}
358
359	void print_exp( const onePointP vert, int n )
360	{
361	int i;
362	for ( i= 1; i <= n; i++ )
363	{
364	Print(" %d",vert->point[i] );
365	#ifdef LONG_OUTPUT
366	if ( i < n ) PrintS(", ");
367	#endif
368	}
369	}
370	void print_matrix( matrix omat )
371	{
372	int i,j;
373	int val;
374	Print(" matrix m[%d][%d]=(\n",MATROWS( omat ),MATCOLS( omat ));
375	for ( i= 1; i <= MATROWS( omat ); i++ )
376	{
377	for ( j= 1; j <= MATCOLS( omat ); j++ )
378	{
379	if ( (MATELEM( omat, i, j)!=NULL)
380	&& (!nIsZero(pGetCoeff( MATELEM( omat, i, j)))))
381	{
382	val= n_Int(pGetCoeff( MATELEM( omat, i, j) ), currRing->cf);
383	if ( i==MATROWS(omat) && j==MATCOLS(omat) )
384	{
385	Print("%d ",val);
386	}
387	else
388	{
389	Print("%d, ",val);
390	}
391	}
392	else
393	{
394	if ( i==MATROWS(omat) && j==MATCOLS(omat) )
395	{
396	PrintS(" 0");
397	}
398	else
399	{
400	PrintS(" 0, ");
401	}
402	}
403	}
404	PrintLn();
405	}
406	PrintS(");\n");
407	}
408	#endif
409	//<-
410
411	//-> pointSet::*
412	pointSet::pointSet( const int _dim, const int _index, const int count )
413	: num(0), max(count), dim(_dim), index(_index)
414	{
415	int i;
416	points = (onePointP )omAlloc( (count+1) sizeof(onePointP) );
417	for ( i= 0; i <= max; i++ )
418	{
419	points[i]= (onePointP)omAlloc( sizeof(onePoint) );
420	points[i]->point= (Coord_t )omAlloc0( (dim+2) sizeof(Coord_t) );
421	}
422	lifted= false;
423	}
424
425	pointSet::~pointSet()
426	{
427	int i;
428	int fdim= lifted ? dim+1 : dim+2;
429	for ( i= 0; i <= max; i++ )
430	{
431	omFreeSize( (void ) points[i]->point, fdim sizeof(Coord_t) );
432	omFreeSize( (void *) points[i], sizeof(onePoint) );
433	}
434	omFreeSize( (void ) points, (max+1) sizeof(onePointP) );
435	}
436
437	inline onePointP pointSet::operator[] ( const int index_i )
438	{
439	assume( index_i > 0 && index_i <= num );
440	return points[index_i];
441	}
442
443	inline bool pointSet::checkMem()
444	{
445	if ( num >= max )
446	{
447	int i;
448	int fdim= lifted ? dim+1 : dim+2;
449	points= (onePointP*)omReallocSize( points,
450	(max+1) * sizeof(onePointP),
451	(2max + 1) sizeof(onePointP) );
452	for ( i= max+1; i <= max*2; i++ )
453	{
454	points[i]= (onePointP)omAlloc( sizeof(struct onePoint) );
455	points[i]->point= (Coord_t )omAlloc0( fdim sizeof(Coord_t) );
456	}
457	max*= 2;
458	mprSTICKYPROT(ST_SPARSE_MEM);
459	return false;
460	}
461	return true;
462	}
463
464	bool pointSet::addPoint( const onePointP vert )
465	{
466	int i;
467	bool ret;
468	num++;
469	ret= checkMem();
470	points[num]->rcPnt= NULL;
471	for ( i= 1; i <= dim; i++ ) points[num]->point[i]= vert->point[i];
472	return ret;
473	}
474
475	bool pointSet::addPoint( const int * vert )
476	{
477	int i;
478	bool ret;
479	num++;
480	ret= checkMem();
481	points[num]->rcPnt= NULL;
482	for ( i= 1; i <= dim; i++ ) points[num]->point[i]= (Coord_t) vert[i];
483	return ret;
484	}
485
486	bool pointSet::addPoint( const Coord_t * vert )
487	{
488	int i;
489	bool ret;
490	num++;
491	ret= checkMem();
492	points[num]->rcPnt= NULL;
493	for ( i= 0; i < dim; i++ ) points[num]->point[i+1]= vert[i];
494	return ret;
495	}
496
497	bool pointSet::removePoint( const int indx )
498	{
499	assume( indx > 0 && indx <= num );
500	if ( indx != num )
501	{
502	onePointP tmp;
503	tmp= points[indx];
504	points[indx]= points[num];
505	points[num]= tmp;
506	}
507	num--;
508
509	return true;
510	}
511
512	bool pointSet::mergeWithExp( const onePointP vert )
513	{
514	int i,j;
515
516	for ( i= 1; i <= num; i++ )
517	{
518	for ( j= 1; j <= dim; j++ )
519	if ( points[i]->point[j] != vert->point[j] ) break;
520	if ( j > dim ) break;
521	}
522
523	if ( i > num )
524	{
525	addPoint( vert );
526	return true;
527	}
528	return false;
529	}
530
531	bool pointSet::mergeWithExp( const int * vert )
532	{
533	int i,j;
534
535	for ( i= 1; i <= num; i++ )
536	{
537	for ( j= 1; j <= dim; j++ )
538	if ( points[i]->point[j] != (Coord_t) vert[j] ) break;
539	if ( j > dim ) break;
540	}
541
542	if ( i > num )
543	{
544	addPoint( vert );
545	return true;
546	}
547	return false;
548	}
549
550	void pointSet::mergeWithPoly( const poly p )
551	{
552	int i,j;
553	poly piter= p;
554	int * vert;
555	vert= (int )omAlloc( (dim+1) sizeof(int) );
556
557	while ( piter )
558	{
559	p_GetExpV( piter, vert, currRing );
560
561	for ( i= 1; i <= num; i++ )
562	{
563	for ( j= 1; j <= dim; j++ )
564	if ( points[i]->point[j] != (Coord_t) vert[j] ) break;
565	if ( j > dim ) break;
566	}
567
568	if ( i > num )
569	{
570	addPoint( vert );
571	}
572
573	pIter( piter );
574	}
575	omFreeSize( (void ) vert, (dim+1) sizeof(int) );
576	}
577
578	int pointSet::getExpPos( const poly p )
579	{
580	int * vert;
581	int i,j;
582
583	// hier unschoen...
584	vert= (int )omAlloc( (dim+1) sizeof(int) );
585
586	p_GetExpV( p, vert, currRing );
587	for ( i= 1; i <= num; i++ )
588	{
589	for ( j= 1; j <= dim; j++ )
590	if ( points[i]->point[j] != (Coord_t) vert[j] ) break;
591	if ( j > dim ) break;
592	}
593	omFreeSize( (void ) vert, (dim+1) sizeof(int) );
594
595	if ( i > num ) return 0;
596	else return i;
597	}
598
599	void pointSet::getRowMP( const int indx, int * vert )
600	{
601	assume( indx > 0 && indx <= num && points[indx]->rcPnt );
602	int i;
603
604	vert[0]= 0;
605	for ( i= 1; i <= dim; i++ )
606	vert[i]= (int)(points[indx]->point[i] - points[indx]->rcPnt->point[i]);
607	}
608
609	inline bool pointSet::smaller( int a, int b )
610	{
611	int i;
612
613	for ( i= 1; i <= dim; i++ )
614	{
615	if ( points[a]->point[i] > points[b]->point[i] )
616	{
617	return false;
618	}
619	if ( points[a]->point[i] < points[b]->point[i] )
620	{
621	return true;
622	}
623	}
624
625	return false; // they are equal
626	}
627
628	inline bool pointSet::larger( int a, int b )
629	{
630	int i;
631
632	for ( i= 1; i <= dim; i++ )
633	{
634	if ( points[a]->point[i] < points[b]->point[i] )
635	{
636	return false;
637	}
638	if ( points[a]->point[i] > points[b]->point[i] )
639	{
640	return true;
641	}
642	}
643
644	return false; // they are equal
645	}
646
647	void pointSet::sort()
648	{
649	int i;
650	bool found= true;
651	onePointP tmp;
652
653	while ( found )
654	{
655	found= false;
656	for ( i= 1; i < num; i++ )
657	{
658	if ( larger( i, i+1 ) )
659	{
660	tmp= points[i];
661	points[i]= points[i+1];
662	points[i+1]= tmp;
663
664	found= true;
665	}
666	}
667	}
668	}
669
670	void pointSet::lift( int l[] )
671	{
672	bool outerL= true;
673	int i, j;
674	int sum;
675
676	dim++;
677
678	if ( l==NULL )
679	{
680	outerL= false;
681	l= (int )omAlloc( (dim+1) sizeof(int) ); // [1..dim-1]
682
683	for(i = 1; i < dim; i++)
684	{
685	l[i]= 1 + siRand() % LIFT_COOR;
686	}
687	}
688	for ( j=1; j <= num; j++ )
689	{
690	sum= 0;
691	for ( i=1; i < dim; i++ )
692	{
693	sum += (int)points[j]->point[i] * l[i];
694	}
695	points[j]->point[dim]= sum;
696	}
697
698	#ifdef mprDEBUG_ALL
699	PrintS(" lift vector: ");
700	for ( j=1; j < dim; j++ ) Print(" %d ",l[j] );
701	PrintLn();
702	#ifdef mprDEBUG_ALL
703	PrintS(" lifted points: \n");
704	for ( j=1; j <= num; j++ )
705	{
706	Print("%d: <",j);print_exp(points[j],dim);PrintS(">\n");
707	}
708	PrintLn();
709	#endif
710	#endif
711
712	lifted= true;
713
714	if ( !outerL ) omFreeSize( (void ) l, (dim+1) sizeof(int) );
715	}
716	//<-
717
718	//-> global functions
719	// Returns the monom at pos i in poly p
720	poly monomAt( poly p, int i )
721	{
722	assume( i > 0 );
723	poly iter= p;
724	for ( int j= 1; (j < i) && (iter!=NULL); j++ ) pIter(iter);
725	return iter;
726	}
727	//<-
728
729	//-> convexHull::*
730	bool convexHull::inHull(poly p, poly pointPoly, int m, int site)
731	{
732	int i, j, col;
733
734	pLP->m = n+1;
735	pLP->n = m; // this includes col of cts
736
737	pLP->LiPM[1][1] = +0.0;
738	pLP->LiPM[1][2] = +1.0; // optimize (arbitrary) var
739	pLP->LiPM[2][1] = +1.0;
740	pLP->LiPM[2][2] = -1.0; // lambda vars sum up to 1
741
742	for ( j=3; j <= pLP->n; j++)
743	{
744	pLP->LiPM[1][j] = +0.0;
745	pLP->LiPM[2][j] = -1.0;
746	}
747
748	for( i= 1; i <= n; i++) { // each row constraints one coor
749	pLP->LiPM[i+2][1] = (mprfloat)pGetExp(pointPoly,i);
750	col = 2;
751	for( j= 1; j <= m; j++ )
752	{
753	if( j != site )
754	{
755	pLP->LiPM[i+2][col] = -(mprfloat)pGetExp( monomAt(p,j), i );
756	col++;
757	}
758	}
759	}
760
761	#ifdef mprDEBUG_ALL
762	PrintS("Matrix of Linear Programming\n");
763	print_mat( pLP->LiPM, pLP->m+1,pLP->n);
764	#endif
765
766	pLP->m3= pLP->m;
767
768	pLP->compute();
769
770	return (pLP->icase == 0);
771	}
772
773	// mprSTICKYPROT:
774	// ST_SPARSE_VADD: new vertex of convex hull added
775	// ST_SPARSE_VREJ: point rejected (-> inside hull)
776	pointSet ** convexHull::newtonPolytopesP( const ideal gls )
777	{
778	int i, j, k;
779	int m; // Anzahl der Exponentvektoren im i-ten Polynom (gls->m)[i] des Ideals gls
780	int idelem= IDELEMS(gls);
781	int * vert;
782
783	n= (currRing->N);
784	vert= (int )omAlloc( (idelem+1) sizeof(int) );
785
786	Q = (pointSet *)omAlloc( idelem sizeof(pointSet*) ); // support hulls
787	for ( i= 0; i < idelem; i++ )
788	Q[i] = new pointSet( (currRing->N), i+1, pLength((gls->m)[i])+1 );
789
790	for( i= 0; i < idelem; i++ )
791	{
792	k=1;
793	m = pLength( (gls->m)[i] );
794
795	poly p= (gls->m)[i];
796	for( j= 1; j <= m; j++) { // für jeden Exponentvektor
797	if( !inHull( (gls->m)[i], p, m, j ) )
798	{
799	p_GetExpV( p, vert, currRing );
800	Q[i]->addPoint( vert );
801	k++;
802	mprSTICKYPROT(ST_SPARSE_VADD);
803	}
804	else
805	{
806	mprSTICKYPROT(ST_SPARSE_VREJ);
807	}
808	pIter( p );
809	} // j
810	mprSTICKYPROT("\n");
811	} // i
812
813	omFreeSize( (void ) vert, (idelem+1) sizeof(int) );
814
815	#ifdef mprDEBUG_PROT
816	PrintLn();
817	for( i= 0; i < idelem; i++ )
818	{
819	Print(" \\Conv(Qi[%d]): #%d\n", i,Q[i]->num );
820	for ( j=1; j <= Q[i]->num; j++ )
821	{
822	Print("%d: <",j);print_exp( (*Q[i])[j] , (currRing->N) );PrintS(">\n");
823	}
824	PrintLn();
825	}
826	#endif
827
828	return Q;
829	}
830
831	// mprSTICKYPROT:
832	// ST_SPARSE_VADD: new vertex of convex hull added
833	// ST_SPARSE_VREJ: point rejected (-> inside hull)
834	ideal convexHull::newtonPolytopesI( const ideal gls )
835	{
836	int i, j;
837	int m; // Anzahl der Exponentvektoren im i-ten Polynom (gls->m)[i] des Ideals gls
838	int idelem= IDELEMS(gls);
839	ideal id;
840	poly p,pid;
841	int * vert;
842
843	n= (currRing->N);
844	vert= (int )omAlloc( (idelem+1) sizeof(int) );
845	id= idInit( idelem, 1 );
846
847	for( i= 0; i < idelem; i++ )
848	{
849	m = pLength( (gls->m)[i] );
850
851	p= (gls->m)[i];
852	for( j= 1; j <= m; j++) { // für jeden Exponentvektor
853	if( !inHull( (gls->m)[i], p, m, j ) )
854	{
855	if ( (id->m)[i] == NULL )
856	{
857	(id->m)[i]= pHead(p);
858	pid=(id->m)[i];
859	}
860	else
861	{
862	pNext(pid)= pHead(p);
863	pIter(pid);
864	pNext(pid)= NULL;
865	}
866	mprSTICKYPROT(ST_SPARSE_VADD);
867	}
868	else
869	{
870	mprSTICKYPROT(ST_SPARSE_VREJ);
871	}
872	pIter( p );
873	} // j
874	mprSTICKYPROT("\n");
875	} // i
876
877	omFreeSize( (void ) vert, (idelem+1) sizeof(int) );
878
879	#ifdef mprDEBUG_PROT
880	PrintLn();
881	for( i= 0; i < idelem; i++ )
882	{
883	}
884	#endif
885
886	return id;
887	}
888	//<-
889
890	//-> mayanPyramidAlg::*
891	pointSet * mayanPyramidAlg::getInnerPoints( pointSet **_q_i, mprfloat _shift[] )
892	{
893	int i;
894
895	Qi= _q_i;
896	shift= _shift;
897
898	E= new pointSet( Qi[0]->dim ); // E has same dim as Qi[...]
899
900	for ( i= 0; i < MAXVARS+2; i++ ) acoords[i]= 0;
901
902	runMayanPyramid(0);
903
904	mprSTICKYPROT("\n");
905
906	return E;
907	}
908
909	mprfloat mayanPyramidAlg::vDistance( Coord_t * acoords_a, int dim )
910	{
911	int i, ii, j, k, col, r;
912	int numverts, cols;
913
914	numverts = 0;
915	for( i=0; i<=n; i++)
916	{
917	numverts += Qi[i]->num;
918	}
919	cols = numverts + 2;
920
921	//if( dim < 1 \|\| dim > n )
922	// WerrorS("mayanPyramidAlg::vDistance: Known coords dim off range");
923
924	pLP->LiPM[1][1] = 0.0;
925	pLP->LiPM[1][2] = 1.0; // maximize
926	for( j=3; j<=cols; j++) pLP->LiPM[1][j] = 0.0;
927
928	for( i=0; i <= n; i++ )
929	{
930	pLP->LiPM[i+2][1] = 1.0;
931	pLP->LiPM[i+2][2] = 0.0;
932	}
933	for( i=1; i<=dim; i++)
934	{
935	pLP->LiPM[n+2+i][1] = (mprfloat)(acoords_a[i-1]);
936	pLP->LiPM[n+2+i][2] = -shift[i];
937	}
938
939	ii = -1;
940	col = 2;
941	for ( i= 0; i <= n; i++ )
942	{
943	ii++;
944	for( k= 1; k <= Qi[ii]->num; k++ )
945	{
946	col++;
947	for ( r= 0; r <= n; r++ )
948	{
949	if ( r == i ) pLP->LiPM[r+2][col] = -1.0;
950	else pLP->LiPM[r+2][col] = 0.0;
951	}
952	for( r= 1; r <= dim; r++ )
953	pLP->LiPM[r+n+2][col] = -(mprfloat)((*Qi[ii])[k]->point[r]);
954	}
955	}
956
957	if( col != cols)
958	Werror("mayanPyramidAlg::vDistance:"
959	"setting up matrix for udist: col %d != cols %d",col,cols);
960
961	pLP->m = n+dim+1;
962	pLP->m3= pLP->m;
963	pLP->n=cols-1;
964
965	#ifdef mprDEBUG_ALL
966	Print("vDistance LP, known koords dim=%d, constr %d, cols %d, acoords= ",
967	dim,pLP->m,cols);
968	for( i= 0; i < dim; i++ )
969	Print(" %d",acoords_a[i]);
970	PrintLn();
971	print_mat( pLP->LiPM, pLP->m+1, cols);
972	#endif
973
974	pLP->compute();
975
976	#ifdef mprDEBUG_ALL
977	PrintS("LP returns matrix\n");
978	print_bmat( pLP->LiPM, pLP->m+1, cols+1-pLP->m, cols, pLP->iposv);
979	#endif
980
981	if( pLP->icase != 0 )
982	{ // check for errors
983	WerrorS("mayanPyramidAlg::vDistance:");
984	if( pLP->icase == 1 )
985	WerrorS(" Unbounded v-distance: probably 1st v-coor=0");
986	else if( pLP->icase == -1 )
987	WerrorS(" Infeasible v-distance");
988	else
989	WerrorS(" Unknown error");
990	return -1.0;
991	}
992
993	return pLP->LiPM[1][1];
994	}
995
996	void mayanPyramidAlg::mn_mx_MinkowskiSum( int dim, Coord_t minR, Coord_t maxR )
997	{
998	int i, j, k, cols, cons;
999	int la_cons_row;
1000
1001	cons = n+dim+2;
1002
1003	// first, compute minimum
1004	//
1005
1006	// common part of the matrix
1007	pLP->LiPM[1][1] = 0.0;
1008	for( i=2; i<=n+2; i++)
1009	{
1010	pLP->LiPM[i][1] = 1.0; // 1st col
1011	pLP->LiPM[i][2] = 0.0; // 2nd col
1012	}
1013
1014	la_cons_row = 1;
1015	cols = 2;
1016	for( i=0; i<=n; i++)
1017	{
1018	la_cons_row++;
1019	for( j=1; j<= Qi[i]->num; j++)
1020	{
1021	cols++;
1022	pLP->LiPM[1][cols] = 0.0; // set 1st row 0
1023	for( k=2; k<=n+2; k++)
1024	{ // lambdas sum up to 1
1025	if( k != la_cons_row) pLP->LiPM[k][cols] = 0.0;
1026	else pLP->LiPM[k][cols] = -1.0;
1027	}
1028	for( k=1; k<=n; k++)
1029	pLP->LiPM[k+n+2][cols] = -(mprfloat)((*Qi[i])[j]->point[k]);
1030	} // j
1031	} // i
1032
1033	for( i= 0; i < dim; i++ )
1034	{ // fixed coords
1035	pLP->LiPM[i+n+3][1] = acoords[i];
1036	pLP->LiPM[i+n+3][2] = 0.0;
1037	}
1038	pLP->LiPM[dim+n+3][1] = 0.0;
1039
1040
1041	pLP->LiPM[1][2] = -1.0; // minimize
1042	pLP->LiPM[dim+n+3][2] = 1.0;
1043
1044	#ifdef mprDEBUG_ALL
1045	Print("\nThats the matrix for minR, dim= %d, acoords= ",dim);
1046	for( i= 0; i < dim; i++ )
1047	Print(" %d",acoords[i]);
1048	PrintLn();
1049	print_mat( pLP->LiPM, cons+1, cols);
1050	#endif
1051
1052	// simplx finds MIN for obj.fnc, puts it in [1,1]
1053	pLP->m= cons;
1054	pLP->n= cols-1;
1055	pLP->m3= cons;
1056
1057	pLP->compute();
1058
1059	if ( pLP->icase != 0 )
1060	{ // check for errors
1061	if( pLP->icase < 0)
1062	WerrorS(" mn_mx_MinkowskiSum: LinearProgram: minR: infeasible");
1063	else if( pLP->icase > 0)
1064	WerrorS(" mn_mx_MinkowskiSum: LinearProgram: minR: unbounded");
1065	}
1066
1067	*minR = (Coord_t)( -pLP->LiPM[1][1] + 1.0 - SIMPLEX_EPS );
1068
1069	// now compute maximum
1070	//
1071
1072	// common part of the matrix again
1073	pLP->LiPM[1][1] = 0.0;
1074	for( i=2; i<=n+2; i++)
1075	{
1076	pLP->LiPM[i][1] = 1.0;
1077	pLP->LiPM[i][2] = 0.0;
1078	}
1079	la_cons_row = 1;
1080	cols = 2;
1081	for( i=0; i<=n; i++)
1082	{
1083	la_cons_row++;
1084	for( j=1; j<=Qi[i]->num; j++)
1085	{
1086	cols++;
1087	pLP->LiPM[1][cols] = 0.0;
1088	for( k=2; k<=n+2; k++)
1089	{
1090	if( k != la_cons_row) pLP->LiPM[k][cols] = 0.0;
1091	else pLP->LiPM[k][cols] = -1.0;
1092	}
1093	for( k=1; k<=n; k++)
1094	pLP->LiPM[k+n+2][cols] = -(mprfloat)((*Qi[i])[j]->point[k]);
1095	} // j
1096	} // i
1097
1098	for( i= 0; i < dim; i++ )
1099	{ // fixed coords
1100	pLP->LiPM[i+n+3][1] = acoords[i];
1101	pLP->LiPM[i+n+3][2] = 0.0;
1102	}
1103	pLP->LiPM[dim+n+3][1] = 0.0;
1104
1105	pLP->LiPM[1][2] = 1.0; // maximize
1106	pLP->LiPM[dim+n+3][2] = 1.0; // var = sum of pnt coords
1107
1108	#ifdef mprDEBUG_ALL
1109	Print("\nThats the matrix for maxR, dim= %d\n",dim);
1110	print_mat( pLP->LiPM, cons+1, cols);
1111	#endif
1112
1113	pLP->m= cons;
1114	pLP->n= cols-1;
1115	pLP->m3= cons;
1116
1117	// simplx finds MAX for obj.fnc, puts it in [1,1]
1118	pLP->compute();
1119
1120	if ( pLP->icase != 0 )
1121	{
1122	if( pLP->icase < 0)
1123	WerrorS(" mn_mx_MinkowskiSum: LinearProgram: maxR: infeasible");
1124	else if( pLP->icase > 0)
1125	WerrorS(" mn_mx_MinkowskiSum: LinearProgram: maxR: unbounded");
1126	}
1127
1128	*maxR = (Coord_t)( pLP->LiPM[1][1] + SIMPLEX_EPS );
1129
1130	#ifdef mprDEBUG_ALL
1131	Print(" Range for dim=%d: [%d,%d]\n", dim, minR, maxR);
1132	#endif
1133	}
1134
1135	// mprSTICKYPROT:
1136	// ST_SPARSE_VREJ: rejected point
1137	// ST_SPARSE_VADD: added point to set
1138	bool mayanPyramidAlg::storeMinkowskiSumPoint()
1139	{
1140	mprfloat dist;
1141
1142	// determine v-distance of point pt
1143	dist= vDistance( &(acoords[0]), n );
1144
1145	// store only points with v-distance > minVdist
1146	if( dist <= MINVDIST + SIMPLEX_EPS )
1147	{
1148	mprSTICKYPROT(ST_SPARSE_VREJ);
1149	return false;
1150	}
1151
1152	E->addPoint( &(acoords[0]) );
1153	mprSTICKYPROT(ST_SPARSE_VADD);
1154
1155	return true;
1156	}
1157
1158	// mprSTICKYPROT:
1159	// ST_SPARSE_MREC1: recurse
1160	// ST_SPARSE_MREC2: recurse with extra points
1161	// ST_SPARSE_MPEND: end
1162	void mayanPyramidAlg::runMayanPyramid( int dim )
1163	{
1164	Coord_t minR, maxR;
1165	mprfloat dist;
1166
1167	// step 3
1168	mn_mx_MinkowskiSum( dim, &minR, &maxR );
1169
1170	#ifdef mprDEBUG_ALL
1171	int i;
1172	for( i=0; i <= dim; i++) Print("acoords[%d]=%d ",i,(int)acoords[i]);
1173	Print(":: [%d,%d]\n", minR, maxR);
1174	#endif
1175
1176	// step 5 -> terminate
1177	if( dim == n-1 )
1178	{
1179	int lastKilled = 0;
1180	// insert points
1181	acoords[dim] = minR;
1182	while( acoords[dim] <= maxR )
1183	{
1184	if( !storeMinkowskiSumPoint() )
1185	lastKilled++;
1186	acoords[dim]++;
1187	}
1188	mprSTICKYPROT(ST_SPARSE_MPEND);
1189	return;
1190	}
1191
1192	// step 4 -> recurse at step 3
1193	acoords[dim] = minR;
1194	while ( acoords[dim] <= maxR )
1195	{
1196	if ( (acoords[dim] > minR) && (acoords[dim] <= maxR) )
1197	{ // acoords[dim] >= minR ??
1198	mprSTICKYPROT(ST_SPARSE_MREC1);
1199	runMayanPyramid( dim + 1 ); // recurse with higer dimension
1200	}
1201	else
1202	{
1203	// get v-distance of pt
1204	dist= vDistance( &(acoords[0]), dim + 1 );// dim+1 == known coordinates
1205
1206	if( dist >= SIMPLEX_EPS )
1207	{
1208	mprSTICKYPROT(ST_SPARSE_MREC2);
1209	runMayanPyramid( dim + 1 ); // recurse with higer dimension
1210	}
1211	}
1212	acoords[dim]++;
1213	} // while
1214	}
1215	//<-
1216
1217	//-> resMatrixSparse::*
1218	bool resMatrixSparse::remapXiToPoint( const int indx, pointSet *pQ, int set, int *pnt )
1219	{
1220	int i,nn= (currRing->N);
1221	int loffset= 0;
1222	for ( i= 0; i <= nn; i++ )
1223	{
1224	if ( (loffset < indx) && (indx <= pQ[i]->num + loffset) )
1225	{
1226	*set= i;
1227	*pnt= indx-loffset;
1228	return true;
1229	}
1230	else loffset+= pQ[i]->num;
1231	}
1232	return false;
1233	}
1234
1235	// mprSTICKYPROT
1236	// ST_SPARSE_RC: point added
1237	int resMatrixSparse::RC( pointSet *pQ, pointSet E, int vert, mprfloat shift[] )
1238	{
1239	int i, j, k,c ;
1240	int size;
1241	bool found= true;
1242	mprfloat cd;
1243	int onum;
1244	int bucket[MAXVARS+2];
1245	setID *optSum;
1246
1247	LP->n = 1;
1248	LP->m = n + n + 1; // number of constrains
1249
1250	// fill in LP matrix
1251	for ( i= 0; i <= n; i++ )
1252	{
1253	size= pQ[i]->num;
1254	for ( k= 1; k <= size; k++ )
1255	{
1256	LP->n++;
1257
1258	// objective funtion, minimize
1259	LP->LiPM[1][LP->n] = - ( (mprfloat) (*pQ[i])[k]->point[pQ[i]->dim] / SCALEDOWN );
1260
1261	// lambdas sum up to 1
1262	for ( j = 0; j <= n; j++ )
1263	{
1264	if ( i==j )
1265	LP->LiPM[j+2][LP->n] = -1.0;
1266	else
1267	LP->LiPM[j+2][LP->n] = 0.0;
1268	}
1269
1270	// the points
1271	for ( j = 1; j <= n; j++ )
1272	{
1273	LP->LiPM[j+n+2][LP->n] = - ( (mprfloat) (*pQ[i])[k]->point[j] );
1274	}
1275	}
1276	}
1277
1278	for ( j = 0; j <= n; j++ ) LP->LiPM[j+2][1] = 1.0;
1279	for ( j= 1; j <= n; j++ )
1280	{
1281	LP->LiPM[j+n+2][1]= (mprfloat)(*E)[vert]->point[j] - shift[j];
1282	}
1283	LP->n--;
1284
1285	LP->LiPM[1][1] = 0.0;
1286
1287	#ifdef mprDEBUG_ALL
1288	PrintLn();
1289	Print(" n= %d, LP->m=M= %d, LP->n=N= %d\n",n,LP->m,LP->n);
1290	print_mat(LP->LiPM, LP->m+1, LP->n+1);
1291	#endif
1292
1293	LP->m3= LP->m;
1294
1295	LP->compute();
1296
1297	if ( LP->icase < 0 )
1298	{
1299	// infeasibility: the point does not lie in a cell -> remove it
1300	return -1;
1301	}
1302
1303	// store result
1304	(E)[vert]->point[E->dim]= (int)(-LP->LiPM[1][1] SCALEDOWN);
1305
1306	#ifdef mprDEBUG_ALL
1307	Print(" simplx returned %d, Objective value = %f\n", LP->icase, LP->LiPM[1][1]);
1308	//print_bmat(LP->LiPM, NumCons + 1, LP->n+1-NumCons, LP->n+1, LP->iposv); // ( rows= M+1, cols= N+1-m3 )
1309	//print_mat(LP->LiPM, NumCons+1, LP->n);
1310	#endif
1311
1312	#if 1
1313	// sort LP results
1314	while (found)
1315	{
1316	found=false;
1317	for ( i= 1; i < LP->m; i++ )
1318	{
1319	if ( LP->iposv[i] > LP->iposv[i+1] )
1320	{
1321
1322	c= LP->iposv[i];
1323	LP->iposv[i]=LP->iposv[i+1];
1324	LP->iposv[i+1]=c;
1325
1326	cd=LP->LiPM[i+1][1];
1327	LP->LiPM[i+1][1]=LP->LiPM[i+2][1];
1328	LP->LiPM[i+2][1]=cd;
1329
1330	found= true;
1331	}
1332	}
1333	}
1334	#endif
1335
1336	#ifdef mprDEBUG_ALL
1337	print_bmat(LP->LiPM, LP->m + 1, LP->n+1-LP->m, LP->n+1, LP->iposv);
1338	PrintS(" now split into sets\n");
1339	#endif
1340
1341
1342	// init bucket
1343	for ( i= 0; i <= E->dim; i++ ) bucket[i]= 0;
1344	// remap results of LP to sets Qi
1345	c=0;
1346	optSum= (setID)omAlloc( (LP->m) sizeof(struct setID) );
1347	for ( i= 0; i < LP->m; i++ )
1348	{
1349	//Print("% .15f\n",LP->LiPM[i+2][1]);
1350	if ( LP->LiPM[i+2][1] > 1e-12 )
1351	{
1352	if ( !remapXiToPoint( LP->iposv[i+1], pQ, &(optSum[c].set), &(optSum[c].pnt) ) )
1353	{
1354	Werror(" resMatrixSparse::RC: Found bad solution in LP: %d!",LP->iposv[i+1]);
1355	WerrorS(" resMatrixSparse::RC: remapXiToPoint failed!");
1356	return -1;
1357	}
1358	bucket[optSum[c].set]++;
1359	c++;
1360	}
1361	}
1362
1363	onum= c;
1364	// find last min in bucket[]: maximum i such that Fi is a point
1365	c= 0;
1366	for ( i= 1; i < E->dim; i++ )
1367	{
1368	if ( bucket[c] >= bucket[i] )
1369	{
1370	c= i;
1371	}
1372	}
1373	// find matching point set
1374	for ( i= onum - 1; i >= 0; i-- )
1375	{
1376	if ( optSum[i].set == c )
1377	break;
1378	}
1379	// store
1380	(*E)[vert]->rc.set= c;
1381	(*E)[vert]->rc.pnt= optSum[i].pnt;
1382	(E)[vert]->rcPnt= (pQ[c])[optSum[i].pnt];
1383	// count
1384	if ( (*E)[vert]->rc.set == linPolyS ) numSet0++;
1385
1386	#ifdef mprDEBUG_PROT
1387	Print("\n Point E[%d] was <",vert);print_exp((*E)[vert],E->dim-1);Print(">, bucket={");
1388	for ( j= 0; j < E->dim; j++ )
1389	{
1390	Print(" %d",bucket[j]);
1391	}
1392	PrintS(" }\n optimal Sum: Qi ");
1393	for ( j= 0; j < LP->m; j++ )
1394	{
1395	Print(" [ %d, %d ]",optSum[j].set,optSum[j].pnt);
1396	}
1397	Print(" -> i= %d, j = %d\n",(*E)[vert]->rc.set,optSum[i].pnt);
1398	#endif
1399
1400	// clean up
1401	omFreeSize( (void ) optSum, (LP->m) sizeof(struct setID) );
1402
1403	mprSTICKYPROT(ST_SPARSE_RC);
1404
1405	return (int)(-LP->LiPM[1][1] * SCALEDOWN);
1406	}
1407
1408	// create coeff matrix
1409	int resMatrixSparse::createMatrix( pointSet *E )
1410	{
1411	// sparse matrix
1412	// uRPos[i][1]: row of matrix
1413	// uRPos[i][idelem+1]: col of u(0)
1414	// uRPos[i][2..idelem]: col of u(1) .. u(n)
1415	// i= 1 .. numSet0
1416	int i,epos;
1417	int rp,cp;
1418	poly rowp,epp;
1419	poly iterp;
1420	int epp_mon, eexp;
1421
1422	epp_mon= (int )omAlloc( (n+2) sizeof(int) );
1423	eexp= (int )omAlloc0(((currRing->N)+1)sizeof(int));
1424
1425	totDeg= numSet0;
1426
1427	mprSTICKYPROT2(" size of matrix: %d\n", E->num);
1428	mprSTICKYPROT2(" resultant deg: %d\n", numSet0);
1429
1430	uRPos= new intvec( numSet0, pLength((gls->m)[0])+1, 0 );
1431
1432	// sparse Matrix represented as a module where
1433	// each poly is column vector ( pSetComp(p,k) gives the row )
1434	rmat= idInit( E->num, E->num ); // cols, rank= number of rows
1435	msize= E->num;
1436
1437	rp= 1;
1438	rowp= NULL;
1439	epp= pOne();
1440	for ( i= 1; i <= E->num; i++ )
1441	{ // for every row
1442	E->getRowMP( i, epp_mon ); // compute (p-a[ij]), (i,j) = RC(p)
1443	pSetExpV( epp, epp_mon );
1444
1445	//
1446	rowp= ppMult_qq( epp, (gls->m)[(E)[i]->rc.set] ); // x^(p-a[ij]) f(i)
1447
1448	cp= 2;
1449	// get column for every monomial in rowp and store it
1450	iterp= rowp;
1451	while ( iterp!=NULL )
1452	{
1453	epos= E->getExpPos( iterp );
1454	if ( epos == 0 )
1455	{
1456	// this can happen, if the shift vektor or the lift funktions
1457	// are not generically chosen.
1458	Werror("resMatrixSparse::createMatrix: Found exponent not in E, id %d, set [%d, %d]!",
1459	i,(E)[i]->rc.set,(E)[i]->rc.pnt);
1460	return i;
1461	}
1462	pSetExpV(iterp,eexp);
1463	pSetComp(iterp, epos );
1464	pSetm(iterp);
1465	if ( (*E)[i]->rc.set == linPolyS )
1466	{ // store coeff positions
1467	IMATELEM(*uRPos,rp,cp)= epos;
1468	cp++;
1469	}
1470	pIter( iterp );
1471	} // while
1472	if ( (*E)[i]->rc.set == linPolyS )
1473	{ // store row
1474	IMATELEM(*uRPos,rp,1)= i-1;
1475	rp++;
1476	}
1477	(rmat->m)[i-1]= rowp;
1478	} // for
1479
1480	pDelete( &epp );
1481	omFreeSize( (void ) epp_mon, (n+2) sizeof(int) );
1482	omFreeSize( (void ) eexp, ((currRing->N)+1)sizeof(int));
1483
1484	#ifdef mprDEBUG_ALL
1485	if ( E->num <= 40 )
1486	{
1487	matrix mout= idModule2Matrix( idCopy(rmat) );
1488	print_matrix(mout);
1489	}
1490	for ( i= 1; i <= numSet0; i++ )
1491	{
1492	Print(" row %d contains coeffs of f_%d\n",IMATELEM(*uRPos,i,1),linPolyS);
1493	}
1494	PrintS(" Sparse Matrix done\n");
1495	#endif
1496
1497	return E->num;
1498	}
1499
1500	// find a sufficiently generic and small vector
1501	void resMatrixSparse::randomVector( const int dim, mprfloat shift[] )
1502	{
1503	int i,j;
1504	i= 1;
1505
1506	while ( i <= dim )
1507	{
1508	shift[i]= (mprfloat) (RVMULT*(siRand()%MAXRVVAL)/(mprfloat)MAXRVVAL);
1509	i++;
1510	for ( j= 1; j < i-1; j++ )
1511	{
1512	if ( (shift[j] < shift[i-1] + SIMPLEX_EPS) && (shift[j] > shift[i-1] - SIMPLEX_EPS) )
1513	{
1514	i--;
1515	break;
1516	}
1517	}
1518	}
1519	}
1520
1521	pointSet * resMatrixSparse::minkSumTwo( pointSet Q1, pointSet Q2, int dim )
1522	{
1523	pointSet *vs;
1524	onePoint vert;
1525	int j,k,l;
1526
1527	vert.point=(Coord_t)omAlloc( ((currRing->N)+2) sizeof(Coord_t) );
1528
1529	vs= new pointSet( dim );
1530
1531	for ( j= 1; j <= Q1->num; j++ )
1532	{
1533	for ( k= 1; k <= Q2->num; k++ )
1534	{
1535	for ( l= 1; l <= dim; l++ )
1536	{
1537	vert.point[l]= (Q1)[j]->point[l] + (Q2)[k]->point[l];
1538	}
1539	vs->mergeWithExp( &vert );
1540	//vs->addPoint( &vert );
1541	}
1542	}
1543
1544	omFreeSize( (void ) vert.point, ((currRing->N)+2) sizeof(Coord_t) );
1545
1546	return vs;
1547	}
1548
1549	pointSet * resMatrixSparse::minkSumAll( pointSet **pQ, int numq, int dim )
1550	{
1551	pointSet vs,vs_old;
1552	int j;
1553
1554	vs= new pointSet( dim );
1555
1556	for ( j= 1; j <= pQ[0]->num; j++ ) vs->addPoint( (*pQ[0])[j] );
1557
1558	for ( j= 1; j < numq; j++ )
1559	{
1560	vs_old= vs;
1561	vs= minkSumTwo( vs_old, pQ[j], dim );
1562
1563	delete vs_old;
1564	}
1565
1566	return vs;
1567	}
1568
1569	//----------------------------------------------------------------------------------------
1570
1571	resMatrixSparse::resMatrixSparse( const ideal _gls, const int special )
1572	: resMatrixBase(), gls( _gls )
1573	{
1574	pointSet **Qi; // vertices sets of Conv(Supp(f_i)), i=0..idelem
1575	pointSet *E; // all integer lattice points of the minkowski sum of Q0...Qn
1576	int i,k;
1577	int pnt;
1578	int totverts; // total number of exponent vectors in ideal gls
1579	mprfloat shift[MAXVARS+2]; // shiftvector delta, index [1..dim]
1580
1581	if ( (currRing->N) > MAXVARS )
1582	{
1583	WerrorS("resMatrixSparse::resMatrixSparse: Too many variables!");
1584	return;
1585	}
1586
1587	rmat= NULL;
1588	numSet0= 0;
1589
1590	if ( special == SNONE ) linPolyS= 0;
1591	else linPolyS= special;
1592
1593	istate= resMatrixBase::ready;
1594
1595	n= (currRing->N);
1596	idelem= IDELEMS(gls); // should be n+1
1597
1598	// prepare matrix LP->LiPM for Linear Programming
1599	totverts = 0;
1600	for( i=0; i < idelem; i++) totverts += pLength( (gls->m)[i] );
1601
1602	LP = new simplex( idelem+totverts*2+5, totverts+5 ); // rows, cols
1603
1604	// get shift vector
1605	#ifdef mprTEST
1606	shift[0]=0.005; shift[1]=0.003; shift[2]=0.008; shift[3]=0.005; shift[4]=0.002;
1607	shift[5]=0.1; shift[6]=0.3; shift[7]=0.2; shift[8]=0.4; shift[9]=0.2;
1608	#else
1609	randomVector( idelem, shift );
1610	#endif
1611	#ifdef mprDEBUG_PROT
1612	PrintS(" shift vector: ");
1613	for ( i= 1; i <= idelem; i++ ) Print(" %.12f ",(double)shift[i]);
1614	PrintLn();
1615	#endif
1616
1617	// evaluate convex hull for supports of gls
1618	convexHull chnp( LP );
1619	Qi= chnp.newtonPolytopesP( gls );
1620
1621	#ifdef mprMINKSUM
1622	E= minkSumAll( Qi, n+1, n);
1623	#else
1624	// get inner points
1625	mayanPyramidAlg mpa( LP );
1626	E= mpa.getInnerPoints( Qi, shift );
1627	#endif
1628
1629	#ifdef mprDEBUG_PROT
1630	#ifdef mprMINKSUM
1631	PrintS("(MinkSum)");
1632	#endif
1633	PrintS("\n E = (Q_0 + ... + Q_n) \\cap \\N :\n");
1634	for ( pnt= 1; pnt <= E->num; pnt++ )
1635	{
1636	Print("%d: <",pnt);print_exp( (*E)[pnt], E->dim );PrintS(">\n");
1637	}
1638	PrintLn();
1639	#endif
1640
1641	#ifdef mprTEST
1642	int lift[5][5];
1643	lift[0][1]=3; lift[0][2]=4; lift[0][3]=8; lift[0][4]=2;
1644	lift[1][1]=6; lift[1][2]=1; lift[1][3]=7; lift[1][4]=4;
1645	lift[2][1]=2; lift[2][2]=5; lift[2][3]=9; lift[2][4]=6;
1646	lift[3][1]=2; lift[3][2]=1; lift[3][3]=9; lift[3][4]=5;
1647	lift[4][1]=3; lift[4][2]=7; lift[4][3]=1; lift[4][4]=5;
1648	// now lift everything
1649	for ( i= 0; i <= n; i++ ) Qi[i]->lift( lift[i] );
1650	#else
1651	// now lift everything
1652	for ( i= 0; i <= n; i++ ) Qi[i]->lift();
1653	#endif
1654	E->dim++;
1655
1656	// run Row Content Function for every point in E
1657	for ( pnt= 1; pnt <= E->num; pnt++ )
1658	{
1659	RC( Qi, E, pnt, shift );
1660	}
1661
1662	// remove points not in cells
1663	k= E->num;
1664	for ( pnt= k; pnt > 0; pnt-- )
1665	{
1666	if ( (*E)[pnt]->rcPnt == NULL )
1667	{
1668	E->removePoint(pnt);
1669	mprSTICKYPROT(ST_SPARSE_RCRJ);
1670	}
1671	}
1672	mprSTICKYPROT("\n");
1673
1674	#ifdef mprDEBUG_PROT
1675	PrintS(" points which lie in a cell:\n");
1676	for ( pnt= 1; pnt <= E->num; pnt++ )
1677	{
1678	Print("%d: <",pnt);print_exp( (*E)[pnt], E->dim );PrintS(">\n");
1679	}
1680	PrintLn();
1681	#endif
1682
1683	// unlift to old dimension, sort
1684	for ( i= 0; i <= n; i++ ) Qi[i]->unlift();
1685	E->unlift();
1686	E->sort();
1687
1688	#ifdef mprDEBUG_PROT
1689	Print(" points with a[ij] (%d):\n",E->num);
1690	for ( pnt= 1; pnt <= E->num; pnt++ )
1691	{
1692	Print("Punkt p \\in E[%d]: <",pnt);print_exp( (*E)[pnt], E->dim );
1693	Print(">, RC(p) = (i:%d, j:%d), a[i,j] = <",(E)[pnt]->rc.set,(E)[pnt]->rc.pnt);
1694	//print_exp( (Qi[(E)[pnt]->rc.set])[(E)[pnt]->rc.pnt], E->dim );PrintS("> = <");
1695	print_exp( (*E)[pnt]->rcPnt, E->dim );PrintS(">\n");
1696	}
1697	#endif
1698
1699	// now create matrix
1700	if (E->num <1)
1701	{
1702	WerrorS("could not handle a degenerate situation: no inner points found");
1703	goto theEnd;
1704	}
1705	if ( createMatrix( E ) != E->num )
1706	{
1707	// this can happen if the shiftvector shift is to large or not generic
1708	istate= resMatrixBase::fatalError;
1709	WerrorS("resMatrixSparse::resMatrixSparse: Error in resMatrixSparse::createMatrix!");
1710	goto theEnd;
1711	}
1712
1713	theEnd:
1714	// clean up
1715	for ( i= 0; i < idelem; i++ )
1716	{
1717	delete Qi[i];
1718	}
1719	omFreeSize( (void ) Qi, idelem sizeof(pointSet*) );
1720
1721	delete E;
1722
1723	delete LP;
1724	}
1725
1726	//----------------------------------------------------------------------------------------
1727
1728	resMatrixSparse::~resMatrixSparse()
1729	{
1730	delete uRPos;
1731	idDelete( &rmat );
1732	}
1733
1734	ideal resMatrixSparse::getMatrix()
1735	{
1736	int i,/j,/cp;
1737	poly pp,phelp,piter,pgls;
1738
1739	// copy original sparse res matrix
1740	ideal rmat_out= idCopy(rmat);
1741
1742	// now fill in coeffs of f0
1743	for ( i= 1; i <= numSet0; i++ )
1744	{
1745
1746	pgls= (gls->m)[0]; // f0
1747
1748	// get matrix row and delete it
1749	pp= (rmat_out->m)[IMATELEM(*uRPos,i,1)];
1750	pDelete( &pp );
1751	pp= NULL;
1752	phelp= pp;
1753	piter= NULL;
1754
1755	// u_1,..,u_k
1756	cp=2;
1757	while ( pNext(pgls)!=NULL )
1758	{
1759	phelp= pOne();
1760	pSetCoeff( phelp, nCopy(pGetCoeff(pgls)) );
1761	pSetComp( phelp, IMATELEM(*uRPos,i,cp) );
1762	pSetmComp( phelp );
1763	if ( piter!=NULL )
1764	{
1765	pNext(piter)= phelp;
1766	piter= phelp;
1767	}
1768	else
1769	{
1770	pp= phelp;
1771	piter= phelp;
1772	}
1773	cp++;
1774	pIter( pgls );
1775	}
1776	// u0, now pgls points to last monom
1777	phelp= pOne();
1778	pSetCoeff( phelp, nCopy(pGetCoeff(pgls)) );
1779	//pSetComp( phelp, IMATELEM(*uRPos,i,idelem+1) );
1780	pSetComp( phelp, IMATELEM(*uRPos,i,pLength((gls->m)[0])+1) );
1781	pSetmComp( phelp );
1782	if (piter!=NULL) pNext(piter)= phelp;
1783	else pp= phelp;
1784	(rmat_out->m)[IMATELEM(*uRPos,i,1)]= pp;
1785	}
1786
1787	return rmat_out;
1788	}
1789
1790	// Fills in resMat[][] with evpoint[] and gets determinant
1791	// uRPos[i][1]: row of matrix
1792	// uRPos[i][idelem+1]: col of u(0)
1793	// uRPos[i][2..idelem]: col of u(1) .. u(n)
1794	// i= 1 .. numSet0
1795	number resMatrixSparse::getDetAt( const number* evpoint )
1796	{
1797	int i,cp;
1798	poly pp,phelp,piter;
1799
1800	mprPROTnl("smCallDet");
1801
1802	for ( i= 1; i <= numSet0; i++ )
1803	{
1804	pp= (rmat->m)[IMATELEM(*uRPos,i,1)];
1805	pDelete( &pp );
1806	pp= NULL;
1807	phelp= pp;
1808	piter= NULL;
1809	// u_1,..,u_n
1810	for ( cp= 2; cp <= idelem; cp++ )
1811	{
1812	if ( !nIsZero(evpoint[cp-1]) )
1813	{
1814	phelp= pOne();
1815	pSetCoeff( phelp, nCopy(evpoint[cp-1]) );
1816	pSetComp( phelp, IMATELEM(*uRPos,i,cp) );
1817	pSetmComp( phelp );
1818	if ( piter )
1819	{
1820	pNext(piter)= phelp;
1821	piter= phelp;
1822	}
1823	else
1824	{
1825	pp= phelp;
1826	piter= phelp;
1827	}
1828	}
1829	}
1830	// u0
1831	phelp= pOne();
1832	pSetCoeff( phelp, nCopy(evpoint[0]) );
1833	pSetComp( phelp, IMATELEM(*uRPos,i,idelem+1) );
1834	pSetmComp( phelp );
1835	pNext(piter)= phelp;
1836	(rmat->m)[IMATELEM(*uRPos,i,1)]= pp;
1837	}
1838
1839	mprSTICKYPROT(ST__DET); // 1
1840
1841	poly pres= sm_CallDet( rmat, currRing );
1842	number numres= nCopy( pGetCoeff( pres ) );
1843	pDelete( &pres );
1844
1845	mprSTICKYPROT(ST__DET); // 2
1846
1847	return ( numres );
1848	}
1849
1850	// Fills in resMat[][] with evpoint[] and gets determinant
1851	// uRPos[i][1]: row of matrix
1852	// uRPos[i][idelem+1]: col of u(0)
1853	// uRPos[i][2..idelem]: col of u(1) .. u(n)
1854	// i= 1 .. numSet0
1855	poly resMatrixSparse::getUDet( const number* evpoint )
1856	{
1857	int i,cp;
1858	poly pp,phelp/,piter/;
1859
1860	mprPROTnl("smCallDet");
1861
1862	for ( i= 1; i <= numSet0; i++ )
1863	{
1864	pp= (rmat->m)[IMATELEM(*uRPos,i,1)];
1865	pDelete( &pp );
1866	phelp= NULL;
1867	// piter= NULL;
1868	for ( cp= 2; cp <= idelem; cp++ )
1869	{ // u1 .. un
1870	if ( !nIsZero(evpoint[cp-1]) )
1871	{
1872	phelp= pOne();
1873	pSetCoeff( phelp, nCopy(evpoint[cp-1]) );
1874	pSetComp( phelp, IMATELEM(*uRPos,i,cp) );
1875	//pSetmComp( phelp );
1876	pSetm( phelp );
1877	//Print("comp %d\n",IMATELEM(*uRPos,i,cp));
1878	#if 0
1879	if ( piter!=NULL )
1880	{
1881	pNext(piter)= phelp;
1882	piter= phelp;
1883	}
1884	else
1885	{
1886	pp= phelp;
1887	piter= phelp;
1888	}
1889	#else
1890	pp=pAdd(pp,phelp);
1891	#endif
1892	}
1893	}
1894	// u0
1895	phelp= pOne();
1896	pSetExp(phelp,1,1);
1897	pSetComp( phelp, IMATELEM(*uRPos,i,idelem+1) );
1898	// Print("comp %d\n",IMATELEM(*uRPos,i,idelem+1));
1899	pSetm( phelp );
1900	#if 0
1901	pNext(piter)= phelp;
1902	#else
1903	pp=pAdd(pp,phelp);
1904	#endif
1905	pTest(pp);
1906	(rmat->m)[IMATELEM(*uRPos,i,1)]= pp;
1907	}
1908
1909	mprSTICKYPROT(ST__DET); // 1
1910
1911	poly pres= sm_CallDet( rmat, currRing );
1912
1913	mprSTICKYPROT(ST__DET); // 2
1914
1915	return ( pres );
1916	}
1917	//<-
1918
1919	//-----------------------------------------------------------------------------
1920	//-------------- dense resultant matrix ---------------------------------------
1921	//-----------------------------------------------------------------------------
1922
1923	//-> dense resultant matrix
1924	//
1925	struct resVector;
1926
1927	/* dense resultant matrix */
1928	class resMatrixDense : virtual public resMatrixBase
1929	{
1930	public:
1931	/**
1932	* _gls: system of multivariate polynoms
1933	* special: -1 -> resMatrixDense is a symbolic matrix
1934	* 0,1, ... -> resMatrixDense ist eine u-Resultante, wobei special das
1935	* lineare u-Polynom angibt
1936	*/
1937	resMatrixDense( const ideal _gls, const int special = SNONE );
1938	~resMatrixDense();
1939
1940	/** column vector of matrix, index von 0 ... numVectors-1 */
1941	resVector *getMVector( const int i );
1942
1943	/** Returns the matrix M in an usable presentation */
1944	ideal getMatrix();
1945
1946	/** Returns the submatrix M' of M in an usable presentation */
1947	ideal getSubMatrix();
1948
1949	/** Evaluate the determinant of the matrix M at the point evpoint
1950	* where the ui's are replaced by the components of evpoint.
1951	* Uses singclap_det from factory.
1952	*/
1953	number getDetAt( const number* evpoint );
1954
1955	/** Evaluates the determinant of the submatrix M'.
1956	* Since the matrix is numerically, no evaluation point is needed.
1957	* Uses singclap_det from factory.
1958	*/
1959	number getSubDet();
1960
1961	private:
1962	/** deactivated copy constructor */
1963	resMatrixDense( const resMatrixDense & );
1964
1965	/** Generate the "matrix" M. Each column is presented by a resVector
1966	* holding all entries for this column.
1967	*/
1968	void generateBaseData();
1969
1970	/** Generates needed set of monoms, split them into sets S0, ... Sn and
1971	* check if reduced/nonreduced and calculate size of submatrix.
1972	*/
1973	void generateMonomData( int deg, intvec* polyDegs , intvec* iVO );
1974
1975	/** Recursively generate all homogeneous monoms of
1976	* (currRing->N) variables of degree deg.
1977	*/
1978	void generateMonoms( poly m, int var, int deg );
1979
1980	/** Creates quadratic matrix M of size numVectors for later use.
1981	* u0, u1, ...,un are replaced by 0.
1982	* Entries equal to 0 are not initialized ( == NULL)
1983	*/
1984	void createMatrix();
1985
1986	private:
1987	resVector *resVectorList;
1988
1989	int veclistmax;
1990	int veclistblock;
1991	int numVectors;
1992	int subSize;
1993
1994	matrix m;
1995	};
1996	//<-
1997
1998	//-> struct resVector
1999	/* Holds a row vector of the dense resultant matrix */
2000	struct resVector
2001	{
2002	public:
2003	void init()
2004	{
2005	isReduced = FALSE;
2006	elementOfS = SFREE;
2007	mon = NULL;
2008	}
2009	void init( const poly m )
2010	{
2011	isReduced = FALSE;
2012	elementOfS = SFREE;
2013	mon = m;
2014	}
2015
2016	/** index von 0 ... numVectors-1 */
2017	poly getElem( const int i );
2018
2019	/** index von 0 ... numVectors-1 */
2020	number getElemNum( const int i );
2021
2022	// variables
2023	poly mon;
2024	poly dividedBy;
2025	bool isReduced;
2026
2027	/** number of the set S mon is element of */
2028	int elementOfS;
2029
2030	/** holds the index of u0, u1, ..., un, if (elementOfS == linPolyS)
2031	* the size is given by (currRing->N)
2032	*/
2033	int *numColParNr;
2034
2035	/** holds the column vector if (elementOfS != linPolyS) */
2036	number *numColVector;
2037
2038	/** size of numColVector */
2039	int numColVectorSize;
2040
2041	number *numColVecCopy;
2042	};
2043	//<-
2044
2045	//-> resVector::*
2046	poly resVector::getElem( const int i ) // inline ???
2047	{
2048	assume( 0 < i \|\| i > numColVectorSize );
2049	poly out= pOne();
2050	pSetCoeff( out, numColVector[i] );
2051	pTest( out );
2052	return( out );
2053	}
2054
2055	number resVector::getElemNum( const int i ) // inline ??
2056	{
2057	assume( i >= 0 && i < numColVectorSize );
2058	return( numColVector[i] );
2059	}
2060	//<-
2061
2062	//-> resMatrixDense::*
2063	resMatrixDense::resMatrixDense( const ideal _gls, const int special )
2064	: resMatrixBase()
2065	{
2066	int i;
2067
2068	sourceRing=currRing;
2069	gls= idCopy( _gls );
2070	linPolyS= special;
2071	m=NULL;
2072
2073	// init all
2074	generateBaseData();
2075
2076	totDeg= 1;
2077	for ( i= 0; i < IDELEMS(gls); i++ )
2078	{
2079	totDeg*=pTotaldegree( (gls->m)[i] );
2080	}
2081
2082	mprSTICKYPROT2(" resultant deg: %d\n",totDeg);
2083
2084	istate= resMatrixBase::ready;
2085	}
2086
2087	resMatrixDense::~resMatrixDense()
2088	{
2089	int i,j;
2090	for (i=0; i < numVectors; i++)
2091	{
2092	pDelete( &resVectorList[i].mon );
2093	pDelete( &resVectorList[i].dividedBy );
2094	for ( j=0; j < resVectorList[i].numColVectorSize; j++ )
2095	{
2096	nDelete( resVectorList[i].numColVector+j );
2097	}
2098	// OB: ????? (solve_s.tst)
2099	if (resVectorList[i].numColVector!=NULL)
2100	omfreeSize( (void *)resVectorList[i].numColVector,
2101	numVectors * sizeof( number ) );
2102	if (resVectorList[i].numColParNr!=NULL)
2103	omfreeSize( (void *)resVectorList[i].numColParNr,
2104	((currRing->N)+1) * sizeof(int) );
2105	}
2106
2107	omFreeSize( (void )resVectorList, veclistmaxsizeof( resVector ) );
2108
2109	// free matrix m
2110	if ( m != NULL )
2111	{
2112	idDelete((ideal *)&m);
2113	}
2114	}
2115
2116	// mprSTICKYPROT:
2117	// ST_DENSE_FR: found row S0
2118	// ST_DENSE_NR: normal row
2119	void resMatrixDense::createMatrix()
2120	{
2121	int k,i,j;
2122	resVector *vecp;
2123
2124	m= mpNew( numVectors, numVectors );
2125
2126	for ( i= 1; i <= MATROWS( m ); i++ )
2127	for ( j= 1; j <= MATCOLS( m ); j++ )
2128	{
2129	MATELEM(m,i,j)= pInit();
2130	pSetCoeff0( MATELEM(m,i,j), nInit(0) );
2131	}
2132
2133
2134	for ( k= 0; k <= numVectors - 1; k++ )
2135	{
2136	if ( linPolyS == getMVector(k)->elementOfS )
2137	{
2138	mprSTICKYPROT(ST_DENSE_FR);
2139	for ( i= 0; i < (currRing->N); i++ )
2140	{
2141	MATELEM(m,numVectors-k,numVectors-(getMVector(k)->numColParNr)[i])= pInit();
2142	}
2143	}
2144	else
2145	{
2146	mprSTICKYPROT(ST_DENSE_NR);
2147	vecp= getMVector(k);
2148	for ( i= 0; i < numVectors; i++)
2149	{
2150	if ( !nIsZero( vecp->getElemNum(i) ) )
2151	{
2152	MATELEM(m,numVectors - k,i + 1)= pInit();
2153	pSetCoeff0( MATELEM(m,numVectors - k,i + 1), nCopy(vecp->getElemNum(i)) );
2154	}
2155	}
2156	}
2157	} // for
2158	mprSTICKYPROT("\n");
2159
2160	#ifdef mprDEBUG_ALL
2161	for ( k= numVectors - 1; k >= 0; k-- )
2162	{
2163	if ( linPolyS == getMVector(k)->elementOfS )
2164	{
2165	for ( i=0; i < (currRing->N); i++ )
2166	{
2167	Print(" %d ",(getMVector(k)->numColParNr)[i]);
2168	}
2169	PrintLn();
2170	}
2171	}
2172	for (i=1; i <= numVectors; i++)
2173	{
2174	for (j=1; j <= numVectors; j++ )
2175	{
2176	pWrite0(MATELEM(m,i,j));PrintS(" ");
2177	}
2178	PrintLn();
2179	}
2180	#endif
2181	}
2182
2183	// mprSTICKYPROT:
2184	// ST_DENSE_MEM: more mem allocated
2185	// ST_DENSE_NMON: new monom added
2186	void resMatrixDense::generateMonoms( poly mm, int var, int deg )
2187	{
2188	if ( deg == 0 )
2189	{
2190	poly mon = pCopy( mm );
2191
2192	if ( numVectors == veclistmax )
2193	{
2194	resVectorList= (resVector * )omReallocSize( resVectorList,
2195	(veclistmax) * sizeof( resVector ),
2196	(veclistmax + veclistblock) * sizeof( resVector ) );
2197	int k;
2198	for ( k= veclistmax; k < (veclistmax + veclistblock); k++ )
2199	resVectorList[k].init();
2200	veclistmax+= veclistblock;
2201	mprSTICKYPROT(ST_DENSE_MEM);
2202
2203	}
2204	resVectorList[numVectors].init( mon );
2205	numVectors++;
2206	mprSTICKYPROT(ST_DENSE_NMON);
2207	return;
2208	}
2209	else
2210	{
2211	if ( var == (currRing->N)+1 ) return;
2212	poly newm = pCopy( mm );
2213	while ( deg >= 0 )
2214	{
2215	generateMonoms( newm, var+1, deg );
2216	pIncrExp( newm, var );
2217	pSetm( newm );
2218	deg--;
2219	}
2220	pDelete( & newm );
2221	}
2222
2223	return;
2224	}
2225
2226	void resMatrixDense::generateMonomData( int deg, intvec* polyDegs , intvec* iVO )
2227	{
2228	int i,j,k;
2229
2230	// init monomData
2231	veclistblock= 512;
2232	veclistmax= veclistblock;
2233	resVectorList= (resVector )omAlloc( veclistmaxsizeof( resVector ) );
2234
2235	// Init resVector()s
2236	for ( j= veclistmax - 1; j >= 0; j-- ) resVectorList[j].init();
2237	numVectors= 0;
2238
2239	// Generate all monoms of degree deg
2240	poly start= pOne();
2241	generateMonoms( start, 1, deg );
2242	pDelete( & start );
2243
2244	mprSTICKYPROT("\n");
2245
2246	// Check for reduced monoms
2247	// First generate polyDegs.rows() monoms
2248	// x(k)^(polyDegs[k]), 0 <= k < polyDegs.rows()
2249	ideal pDegDiv= idInit( polyDegs->rows(), 1 );
2250	for ( k= 0; k < polyDegs->rows(); k++ )
2251	{
2252	poly p= pOne();
2253	pSetExp( p, k + 1, (*polyDegs)[k] );
2254	pSetm( p );
2255	(pDegDiv->m)[k]= p;
2256	}
2257
2258	// Now check each monom if it is reduced.
2259	// A monom monom is called reduced if there exists
2260	// exactly one x(k)^(polyDegs[k]) that divides the monom.
2261	int divCount;
2262	for ( j= numVectors - 1; j >= 0; j-- )
2263	{
2264	divCount= 0;
2265	for ( k= 0; k < IDELEMS(pDegDiv); k++ )
2266	if ( pLmDivisibleByNoComp( (pDegDiv->m)[k], resVectorList[j].mon ) )
2267	divCount++;
2268	resVectorList[j].isReduced= (divCount == 1);
2269	}
2270
2271	// create the sets S(k)s
2272	// a monom x(i)^deg, deg given, is element of the set S(i)
2273	// if all x(0)^(polyDegs[0]) ... x(i-1)^(polyDegs[i-1]) DONT divide
2274	// x(i)^deg and only x(i)^(polyDegs[i]) divides x(i)^deg
2275	bool doInsert;
2276	for ( k= 0; k < iVO->rows(); k++)
2277	{
2278	//mprPROTInl(" ------------ var:",(*iVO)[k]);
2279	for ( j= numVectors - 1; j >= 0; j-- )
2280	{
2281	//mprPROTPnl("testing monom",resVectorList[j].mon);
2282	if ( resVectorList[j].elementOfS == SFREE )
2283	{
2284	//mprPROTnl("\tfree");
2285	if ( pLmDivisibleByNoComp( (pDegDiv->m)[ (*iVO)[k] ], resVectorList[j].mon ) )
2286	{
2287	//mprPROTPnl("\tdivisible by ",(pDegDiv->m)[ (*iVO)[k] ]);
2288	doInsert=TRUE;
2289	for ( i= 0; i < k; i++ )
2290	{
2291	//mprPROTPnl("\tchecking db ",(pDegDiv->m)[ (*iVO)[i] ]);
2292	if ( pLmDivisibleByNoComp( (pDegDiv->m)[ (*iVO)[i] ], resVectorList[j].mon ) )
2293	{
2294	//mprPROTPnl("\t and divisible by",(pDegDiv->m)[ (*iVO)[i] ]);
2295	doInsert=FALSE;
2296	break;
2297	}
2298	}
2299	if ( doInsert )
2300	{
2301	//mprPROTInl("\t------------------> S ",(*iVO)[k]);
2302	resVectorList[j].elementOfS= (*iVO)[k];
2303	resVectorList[j].dividedBy= pCopy( (pDegDiv->m)[ (*iVO)[i] ] );
2304	}
2305	}
2306	}
2307	}
2308	}
2309
2310	// size of submatrix M', equal to number of nonreduced monoms
2311	// (size of matrix M is equal to number of monoms=numVectors)
2312	subSize= 0;
2313	int sub;
2314	for ( i= 0; i < polyDegs->rows(); i++ )
2315	{
2316	sub= 1;
2317	for ( k= 0; k < polyDegs->rows(); k++ )
2318	if ( i != k ) sub= (polyDegs)[k];
2319	subSize+= sub;
2320	}
2321	subSize= numVectors - subSize;
2322
2323	// pDegDiv wieder freigeben!
2324	idDelete( &pDegDiv );
2325
2326	#ifdef mprDEBUG_ALL
2327	// Print a list of monoms and their properties
2328	PrintS("// \n");
2329	for ( j= numVectors - 1; j >= 0; j-- )
2330	{
2331	Print("// %s, S(%d), db ",
2332	resVectorList[j].isReduced?"reduced":"nonreduced",
2333	resVectorList[j].elementOfS);
2334	pWrite0(resVectorList[j].dividedBy);
2335	PrintS(" monom ");
2336	pWrite(resVectorList[j].mon);
2337	}
2338	Print("// size: %d, subSize: %d\n",numVectors,subSize);
2339	#endif
2340	}
2341
2342	void resMatrixDense::generateBaseData()
2343	{
2344	int k,j,i;
2345	number matEntry;
2346	poly pmatchPos;
2347	poly pi,factor,pmp;
2348
2349	// holds the degrees of F0, F1, ..., Fn
2350	intvec polyDegs( IDELEMS(gls) );
2351	for ( k= 0; k < IDELEMS(gls); k++ )
2352	polyDegs[k]= pTotaldegree( (gls->m)[k] );
2353
2354	// the internal Variable Ordering
2355	// make sure that the homogenization variable goes last!
2356	intvec iVO( (currRing->N) );
2357	if ( linPolyS != SNONE )
2358	{
2359	iVO[(currRing->N) - 1]= linPolyS;
2360	int p=0;
2361	for ( k= (currRing->N) - 1; k >= 0; k-- )
2362	{
2363	if ( k != linPolyS )
2364	{
2365	iVO[p]= k;
2366	p++;
2367	}
2368	}
2369	}
2370	else
2371	{
2372	linPolyS= 0;
2373	for ( k= 0; k < (currRing->N); k++ )
2374	iVO[k]= (currRing->N) - k - 1;
2375	}
2376
2377	// the critical degree d= sum( deg(Fi) ) - n
2378	int sumDeg= 0;
2379	for ( k= 0; k < polyDegs.rows(); k++ )
2380	sumDeg+= polyDegs[k];
2381	sumDeg-= polyDegs.rows() - 1;
2382
2383	// generate the base data
2384	generateMonomData( sumDeg, &polyDegs, &iVO );
2385
2386	// generate "matrix"
2387	for ( k= numVectors - 1; k >= 0; k-- )
2388	{
2389	if ( resVectorList[k].elementOfS != linPolyS )
2390	{
2391	// column k is a normal column with numerical or symbolic entries
2392	// init stuff
2393	resVectorList[k].numColParNr= NULL;
2394	resVectorList[k].numColVectorSize= numVectors;
2395	resVectorList[k].numColVector= (number )omAlloc( numVectorssizeof( number ) );
2396	for ( i= 0; i < numVectors; i++ ) resVectorList[k].numColVector[i]= nInit(0);
2397
2398	// compute row poly
2399	poly pi= ppMult_qq( (gls->m)[ resVectorList[k].elementOfS ] , resVectorList[k].mon );
2400	pi= pp_DivideM( pi, resVectorList[k].dividedBy, currRing );
2401
2402	// fill in "matrix"
2403	while ( pi != NULL )
2404	{
2405	matEntry= nCopy(pGetCoeff(pi));
2406	pmatchPos= pLmInit( pi );
2407	pSetCoeff0( pmatchPos, nInit(1) );
2408
2409	for ( i= 0; i < numVectors; i++)
2410	if ( pLmEqual( pmatchPos, resVectorList[i].mon ) )
2411	break;
2412
2413	resVectorList[k].numColVector[numVectors - i - 1] = nCopy(matEntry);
2414
2415	pDelete( &pmatchPos );
2416	nDelete( &matEntry );
2417
2418	pIter( pi );
2419	}
2420	pDelete( &pi );
2421	}
2422	else
2423	{
2424	// column is a special column, i.e. is generated by S0 and F0
2425	// safe only the positions of the ui's in the column
2426	//mprPROTInl(" setup of numColParNr ",k);
2427	resVectorList[k].numColVectorSize= 0;
2428	resVectorList[k].numColVector= NULL;
2429	resVectorList[k].numColParNr= (int )omAlloc0( ((currRing->N)+1) sizeof(int) );
2430
2431	pi= (gls->m)[ resVectorList[k].elementOfS ];
2432	factor= pp_DivideM( resVectorList[k].mon, resVectorList[k].dividedBy, currRing );
2433
2434	j=0;
2435	while ( pi != NULL )
2436	{ // fill in "matrix"
2437	pmp= pMult( pCopy( factor ), pHead( pi ) );
2438	pTest( pmp );
2439
2440	for ( i= 0; i < numVectors; i++)
2441	if ( pLmEqual( pmp, resVectorList[i].mon ) )
2442	break;
2443
2444	resVectorList[k].numColParNr[j]= i;
2445	pDelete( &pmp );
2446	pIter( pi );
2447	j++;
2448	}
2449	pDelete( &pi );
2450	pDelete( &factor );
2451	}
2452	} // for ( k= numVectors - 1; k >= 0; k-- )
2453
2454	mprSTICKYPROT2(" size of matrix: %d\n",numVectors);
2455	mprSTICKYPROT2(" size of submatrix: %d\n",subSize);
2456
2457	// create the matrix M
2458	createMatrix();
2459
2460	}
2461
2462	resVector *resMatrixDense::getMVector(const int i)
2463	{
2464	assume( i >= 0 && i < numVectors );
2465	return &resVectorList[i];
2466	}
2467
2468	ideal resMatrixDense::getMatrix()
2469	{
2470	int i,j;
2471
2472	// copy matrix
2473	matrix resmat= mpNew(numVectors,numVectors);
2474	poly p;
2475	for (i=1; i <= numVectors; i++)
2476	{
2477	for (j=1; j <= numVectors; j++ )
2478	{
2479	p=MATELEM(m,i,j);
2480	if (( p!=NULL)
2481	&& (!nIsZero(pGetCoeff(p)))
2482	&& (pGetCoeff(p)!=NULL)
2483	)
2484	{
2485	MATELEM(resmat,i,j)= pCopy( p );
2486	}
2487	}
2488	}
2489	for (i=0; i < numVectors; i++)
2490	{
2491	if ( resVectorList[i].elementOfS == linPolyS )
2492	{
2493	for (j=1; j <= (currRing->N); j++ )
2494	{
2495	if ( MATELEM(resmat,numVectors-i,
2496	numVectors-resVectorList[i].numColParNr[j-1])!=NULL )
2497	pDelete( &MATELEM(resmat,numVectors-i,numVectors-resVectorList[i].numColParNr[j-1]) );
2498	MATELEM(resmat,numVectors-i,numVectors-resVectorList[i].numColParNr[j-1])= pOne();
2499	// FIX ME
2500	if ( FALSE )
2501	{
2502	pSetCoeff( MATELEM(resmat,numVectors-i,numVectors-resVectorList[i].numColParNr[j-1]), n_Param(j,currRing) );
2503	}
2504	else
2505	{
2506	pSetExp( MATELEM(resmat,numVectors-i,numVectors-resVectorList[i].numColParNr[j-1]), j, 1 );
2507	pSetm(MATELEM(resmat,numVectors-i,numVectors-resVectorList[i].numColParNr[j-1]));
2508	}
2509	}
2510	}
2511	}
2512
2513	// obachman: idMatrix2Module frees resmat !!
2514	ideal resmod= id_Matrix2Module(resmat,currRing);
2515	return resmod;
2516	}
2517
2518	ideal resMatrixDense::getSubMatrix()
2519	{
2520	int k,i,j,l;
2521	resVector *vecp;
2522
2523	// generate quadratic matrix resmat of size subSize
2524	matrix resmat= mpNew( subSize, subSize );
2525
2526	j=1;
2527	for ( k= numVectors - 1; k >= 0; k-- )
2528	{
2529	vecp= getMVector(k);
2530	if ( vecp->isReduced ) continue;
2531	l=1;
2532	for ( i= numVectors - 1; i >= 0; i-- )
2533	{
2534	if ( getMVector(i)->isReduced ) continue;
2535	if ( !nIsZero(vecp->getElemNum(numVectors - i - 1)) )
2536	{
2537	MATELEM(resmat,j,l)= pCopy( vecp->getElem(numVectors-i-1) );
2538	}
2539	l++;
2540	}
2541	j++;
2542	}
2543
2544	// obachman: idMatrix2Module frees resmat !!
2545	ideal resmod= id_Matrix2Module(resmat,currRing);
2546	return resmod;
2547	}
2548
2549	number resMatrixDense::getDetAt( const number* evpoint )
2550	{
2551	int k,i;
2552
2553	// copy evaluation point into matrix
2554	// p0, p1, ..., pn replace u0, u1, ..., un
2555	for ( k= numVectors - 1; k >= 0; k-- )
2556	{
2557	if ( linPolyS == getMVector(k)->elementOfS )
2558	{
2559	for ( i= 0; i < (currRing->N); i++ )
2560	{
2561	number np=pGetCoeff(MATELEM(m,numVectors-k,numVectors-(getMVector(k)->numColParNr)[i]));
2562	if (np!=NULL) nDelete(&np);
2563	pSetCoeff0( MATELEM(m,numVectors-k,numVectors-(getMVector(k)->numColParNr)[i]),
2564	nCopy(evpoint[i]) );
2565	}
2566	}
2567	}
2568
2569	mprSTICKYPROT(ST__DET);
2570
2571	// evaluate determinant of matrix m using factory singclap_det
2572	poly res= singclap_det( m, currRing );
2573
2574	// avoid errors for det==0
2575	number numres;
2576	if ( (res!=NULL) && (!nIsZero(pGetCoeff( res ))) )
2577	{
2578	numres= nCopy( pGetCoeff( res ) );
2579	}
2580	else
2581	{
2582	numres= nInit(0);
2583	mprPROT("0");
2584	}
2585	pDelete( &res );
2586
2587	mprSTICKYPROT(ST__DET);
2588
2589	return( numres );
2590	}
2591
2592	number resMatrixDense::getSubDet()
2593	{
2594	int k,i,j,l;
2595	resVector *vecp;
2596
2597	// generate quadratic matrix mat of size subSize
2598	matrix mat= mpNew( subSize, subSize );
2599
2600	for ( i= 1; i <= MATROWS( mat ); i++ )
2601	{
2602	for ( j= 1; j <= MATCOLS( mat ); j++ )
2603	{
2604	MATELEM(mat,i,j)= pInit();
2605	pSetCoeff0( MATELEM(mat,i,j), nInit(0) );
2606	}
2607	}
2608	j=1;
2609	for ( k= numVectors - 1; k >= 0; k-- )
2610	{
2611	vecp= getMVector(k);
2612	if ( vecp->isReduced ) continue;
2613	l=1;
2614	for ( i= numVectors - 1; i >= 0; i-- )
2615	{
2616	if ( getMVector(i)->isReduced ) continue;
2617	if ( vecp->getElemNum(numVectors - i - 1) && !nIsZero(vecp->getElemNum(numVectors - i - 1)) )
2618	{
2619	pSetCoeff(MATELEM(mat, j , l ), nCopy(vecp->getElemNum(numVectors - i - 1)));
2620	}
2621	/* else
2622	{
2623	MATELEM(mat, j , l )= pOne();
2624	pSetCoeff(MATELEM(mat, j , l ), nInit(0) );
2625	}
2626	*/
2627	l++;
2628	}
2629	j++;
2630	}
2631
2632	poly res= singclap_det( mat, currRing );
2633
2634	number numres;
2635	if ((res != NULL) && (!nIsZero(pGetCoeff( res ))) )
2636	{
2637	numres= nCopy(pGetCoeff( res ));
2638	}
2639	else
2640	{
2641	numres= nInit(0);
2642	}
2643	pDelete( &res );
2644	return numres;
2645	}
2646	//<--
2647
2648	//-----------------------------------------------------------------------------
2649	//-------------- uResultant ---------------------------------------------------
2650	//-----------------------------------------------------------------------------
2651
2652	#define MAXEVPOINT 1000000 // 0x7fffffff
2653	//#define MPR_MASI
2654
2655	//-> unsigned long over(unsigned long n,unsigned long d)
2656	// Calculates (n+d \over d) using gmp functionality
2657	//
2658	unsigned long over( const unsigned long n , const unsigned long d )
2659	{ // (d+n)! / ( d! n! )
2660	mpz_t res;
2661	mpz_init(res);
2662	mpz_t m,md,mn;
2663	mpz_init(m);mpz_set_ui(m,1);
2664	mpz_init(md);mpz_set_ui(md,1);
2665	mpz_init(mn);mpz_set_ui(mn,1);
2666
2667	mpz_fac_ui(m,n+d);
2668	mpz_fac_ui(md,d);
2669	mpz_fac_ui(mn,n);
2670
2671	mpz_mul(res,md,mn);
2672	mpz_tdiv_q(res,m,res);
2673
2674	mpz_clear(m);mpz_clear(md);mpz_clear(mn);
2675
2676	unsigned long result = mpz_get_ui(res);
2677	mpz_clear(res);
2678
2679	return result;
2680	}
2681	//<-
2682
2683	//-> uResultant::*
2684	uResultant::uResultant( const ideal _gls, const resMatType _rmt, BOOLEAN extIdeal )
2685	: rmt( _rmt )
2686	{
2687	if ( extIdeal )
2688	{
2689	// extend given ideal by linear poly F0=u0x0 + u1x1 +...+ unxn
2690	gls= extendIdeal( _gls, linearPoly( rmt ), rmt );
2691	n= IDELEMS( gls );
2692	}
2693	else
2694	gls= idCopy( _gls );
2695
2696	switch ( rmt )
2697	{
2698	case sparseResMat:
2699	resMat= new resMatrixSparse( gls );
2700	break;
2701	case denseResMat:
2702	resMat= new resMatrixDense( gls );
2703	break;
2704	default:
2705	WerrorS("uResultant::uResultant: Unknown chosen resultant matrix type!");
2706	}
2707	}
2708
2709	uResultant::~uResultant( )
2710	{
2711	delete resMat;
2712	}
2713
2714	ideal uResultant::extendIdeal( const ideal igls, poly linPoly, const resMatType rrmt )
2715	{
2716	ideal newGls= idCopy( igls );
2717	newGls->m= (poly *)omReallocSize( newGls->m,
2718	IDELEMS(igls) * sizeof(poly),
2719	(IDELEMS(igls) + 1) * sizeof(poly) );
2720	IDELEMS(newGls)++;
2721
2722	switch ( rrmt )
2723	{
2724	case sparseResMat:
2725	case denseResMat:
2726	{
2727	int i;
2728	for ( i= IDELEMS(newGls)-1; i > 0; i-- )
2729	{
2730	newGls->m[i]= newGls->m[i-1];
2731	}
2732	newGls->m[0]= linPoly;
2733	}
2734	break;
2735	default:
2736	WerrorS("uResultant::extendIdeal: Unknown chosen resultant matrix type!");
2737	}
2738
2739	return( newGls );
2740	}
2741
2742	poly uResultant::linearPoly( const resMatType rrmt )
2743	{
2744	int i;
2745
2746	poly newlp= pOne();
2747	poly actlp, rootlp= newlp;
2748
2749	for ( i= 1; i <= (currRing->N); i++ )
2750	{
2751	actlp= newlp;
2752	pSetExp( actlp, i, 1 );
2753	pSetm( actlp );
2754	newlp= pOne();
2755	actlp->next= newlp;
2756	}
2757	actlp->next= NULL;
2758	pDelete( &newlp );
2759
2760	if ( rrmt == sparseResMat )
2761	{
2762	newlp= pOne();
2763	actlp->next= newlp;
2764	newlp->next= NULL;
2765	}
2766	return ( rootlp );
2767	}
2768
2769	poly uResultant::interpolateDense( const number subDetVal )
2770	{
2771	int i,j,p;
2772	long tdg;
2773
2774	// D is a Polynom homogeneous in the coeffs of F0 and of degree tdg = d0d1...*dn
2775	tdg= resMat->getDetDeg();
2776
2777	// maximum number of terms in polynom D (homogeneous, of degree tdg)
2778	// long mdg= (facul(tdg+n-1) / facul( tdg )) / facul( n - 1 );
2779	long mdg= over( n-1, tdg );
2780
2781	// maximal number of terms in a polynom of degree tdg
2782	long l=(long)pow( (double)(tdg+1), n );
2783
2784	#ifdef mprDEBUG_PROT
2785	Print("// total deg of D: tdg %ld\n",tdg);
2786	Print("// maximum number of terms in D: mdg: %ld\n",mdg);
2787	Print("// maximum number of terms in polynom of deg tdg: l %ld\n",l);
2788	#endif
2789
2790	// we need mdg results of D(p0,p1,...,pn)
2791	number *presults;
2792	presults= (number )omAlloc( mdg sizeof( number ) );
2793	for (i=0; i < mdg; i++) presults[i]= nInit(0);
2794
2795	number pevpoint= (number )omAlloc( n * sizeof( number ) );
2796	number pev= (number )omAlloc( n * sizeof( number ) );
2797	for (i=0; i < n; i++) pev[i]= nInit(0);
2798
2799	mprPROTnl("// initial evaluation point: ");
2800	// initial evaluatoin point
2801	p=1;
2802	for (i=0; i < n; i++)
2803	{
2804	// init pevpoint with primes 3,5,7,11, ...
2805	p= nextPrime( p );
2806	pevpoint[i]=nInit( p );
2807	nTest(pevpoint[i]);
2808	mprPROTNnl(" ",pevpoint[i]);
2809	}
2810
2811	// evaluate the determinant in the points pev^0, pev^1, ..., pev^mdg
2812	mprPROTnl("// evaluating:");
2813	for ( i=0; i < mdg; i++ )
2814	{
2815	for (j=0; j < n; j++)
2816	{
2817	nDelete( &pev[j] );
2818	nPower(pevpoint[j],i,&pev[j]);
2819	mprPROTN(" ",pev[j]);
2820	}
2821	mprPROTnl("");
2822
2823	nDelete( &presults[i] );
2824	presults[i]=resMat->getDetAt( pev );
2825
2826	mprSTICKYPROT(ST_BASE_EV);
2827	}
2828	mprSTICKYPROT("\n");
2829
2830	// now interpolate using vandermode interpolation
2831	mprPROTnl("// interpolating:");
2832	number *ncpoly;
2833	{
2834	vandermonde vm( mdg, n, tdg, pevpoint );
2835	ncpoly= vm.interpolateDense( presults );
2836	}
2837
2838	if ( subDetVal != NULL )
2839	{ // divide by common factor
2840	number detdiv;
2841	for ( i= 0; i <= mdg; i++ )
2842	{
2843	detdiv= nDiv( ncpoly[i], subDetVal );
2844	nNormalize( detdiv );
2845	nDelete( &ncpoly[i] );
2846	ncpoly[i]= detdiv;
2847	}
2848	}
2849
2850	#ifdef mprDEBUG_ALL
2851	PrintLn();
2852	for ( i=0; i < mdg; i++ )
2853	{
2854	nPrint(ncpoly[i]); PrintS(" --- ");
2855	}
2856	PrintLn();
2857	#endif
2858
2859	// prepare ncpoly for later use
2860	number nn=nInit(0);
2861	for ( i=0; i < mdg; i++ )
2862	{
2863	if ( nEqual(ncpoly[i],nn) )
2864	{
2865	nDelete( &ncpoly[i] );
2866	ncpoly[i]=NULL;
2867	}
2868	}
2869	nDelete( &nn );
2870
2871	// create poly presenting the determinat of the uResultant
2872	intvec exp( n );
2873	for ( i= 0; i < n; i++ ) exp[i]=0;
2874
2875	poly result= NULL;
2876
2877	long sum=0;
2878	long c=0;
2879
2880	for ( i=0; i < l; i++ )
2881	{
2882	if ( sum == tdg )
2883	{
2884	if ( !nIsZero(ncpoly[c]) )
2885	{
2886	poly p= pOne();
2887	if ( rmt == denseResMat )
2888	{
2889	for ( j= 0; j < n; j++ ) pSetExp( p, j+1, exp[j] );
2890	}
2891	else if ( rmt == sparseResMat )
2892	{
2893	for ( j= 1; j < n; j++ ) pSetExp( p, j, exp[j] );
2894	}
2895	pSetCoeff( p, ncpoly[c] );
2896	pSetm( p );
2897	if (result!=NULL) result= pAdd( result, p );
2898	else result= p;
2899	}
2900	c++;
2901	}
2902	sum=0;
2903	exp[0]++;
2904	for ( j= 0; j < n - 1; j++ )
2905	{
2906	if ( exp[j] > tdg )
2907	{
2908	exp[j]= 0;
2909	exp[j + 1]++;
2910	}
2911	sum+=exp[j];
2912	}
2913	sum+=exp[n-1];
2914	}
2915
2916	pTest( result );
2917
2918	return result;
2919	}
2920
2921	rootContainer ** uResultant::interpolateDenseSP( BOOLEAN matchUp, const number subDetVal )
2922	{
2923	int i,p,uvar;
2924	long tdg;
2925	int loops= (matchUp?n-2:n-1);
2926
2927	mprPROTnl("uResultant::interpolateDenseSP");
2928
2929	tdg= resMat->getDetDeg();
2930
2931	// evaluate D in tdg+1 distinct points, so
2932	// we need tdg+1 results of D(p0,1,0,...,0) =
2933	// c(0)u0^tdg + c(1)u0^tdg-1 + ... + c(tdg-1)*u0 + c(tdg)
2934	number *presults;
2935	presults= (number )omAlloc( (tdg + 1) sizeof( number ) );
2936	for ( i=0; i <= tdg; i++ ) presults[i]= nInit(0);
2937
2938	rootContainer ** roots;
2939	roots= (rootContainer *) omAlloc( loops sizeof(rootContainer*) );
2940	for ( i=0; i < loops; i++ ) roots[i]= new rootContainer(); // 0..n-2
2941
2942	number pevpoint= (number )omAlloc( n * sizeof( number ) );
2943	for (i=0; i < n; i++) pevpoint[i]= nInit(0);
2944
2945	number pev= (number )omAlloc( n * sizeof( number ) );
2946	for (i=0; i < n; i++) pev[i]= nInit(0);
2947
2948	// now we evaluate D(u0,-1,0,...0), D(u0,0,-1,0,...,0), ..., D(u0,0,..,0,-1)
2949	// or D(u0,k1,k2,0,...,0), D(u0,k1,k2,k3,0,...,0), ..., D(u0,k1,k2,k3,...,kn)
2950	// this gives us n-1 evaluations
2951	p=3;
2952	for ( uvar= 0; uvar < loops; uvar++ )
2953	{
2954	// generate initial evaluation point
2955	if ( matchUp )
2956	{
2957	for (i=0; i < n; i++)
2958	{
2959	// prime(random number) between 1 and MAXEVPOINT
2960	nDelete( &pevpoint[i] );
2961	if ( i == 0 )
2962	{
2963	//p= nextPrime( p );
2964	pevpoint[i]= nInit( p );
2965	}
2966	else if ( i <= uvar + 2 )
2967	{
2968	pevpoint[i]=nInit(1+siRand()%MAXEVPOINT);
2969	//pevpoint[i]=nInit(383);
2970	}
2971	else
2972	pevpoint[i]=nInit(0);
2973	mprPROTNnl(" ",pevpoint[i]);
2974	}
2975	}
2976	else
2977	{
2978	for (i=0; i < n; i++)
2979	{
2980	// init pevpoint with prime,0,...0,1,0,...,0
2981	nDelete( &pevpoint[i] );
2982	if ( i == 0 )
2983	{
2984	//p=nextPrime( p );
2985	pevpoint[i]=nInit( p );
2986	}
2987	else
2988	{
2989	if ( i == (uvar + 1) ) pevpoint[i]= nInit(-1);
2990	else pevpoint[i]= nInit(0);
2991	}
2992	mprPROTNnl(" ",pevpoint[i]);
2993	}
2994	}
2995
2996	// prepare aktual evaluation point
2997	for (i=0; i < n; i++)
2998	{
2999	nDelete( &pev[i] );
3000	pev[i]= nCopy( pevpoint[i] );
3001	}
3002	// evaluate the determinant in the points pev^0, pev^1, ..., pev^tdg
3003	for ( i=0; i <= tdg; i++ )
3004	{
3005	nDelete( &pev[0] );
3006	nPower(pevpoint[0],i,&pev[0]); // new evpoint
3007
3008	nDelete( &presults[i] );
3009	presults[i]=resMat->getDetAt( pev ); // evaluate det at point evpoint
3010
3011	mprPROTNnl("",presults[i]);
3012
3013	mprSTICKYPROT(ST_BASE_EV);
3014	mprPROTL("",tdg-i);
3015	}
3016	mprSTICKYPROT("\n");
3017
3018	// now interpolate
3019	vandermonde vm( tdg + 1, 1, tdg, pevpoint, FALSE );
3020	number *ncpoly= vm.interpolateDense( presults );
3021
3022	if ( subDetVal != NULL )
3023	{ // divide by common factor
3024	number detdiv;
3025	for ( i= 0; i <= tdg; i++ )
3026	{
3027	detdiv= nDiv( ncpoly[i], subDetVal );
3028	nNormalize( detdiv );
3029	nDelete( &ncpoly[i] );
3030	ncpoly[i]= detdiv;
3031	}
3032	}
3033
3034	#ifdef mprDEBUG_ALL
3035	PrintLn();
3036	for ( i=0; i <= tdg; i++ )
3037	{
3038	nPrint(ncpoly[i]); PrintS(" --- ");
3039	}
3040	PrintLn();
3041	#endif
3042
3043	// save results
3044	roots[uvar]->fillContainer( ncpoly, pevpoint, uvar+1, tdg,
3045	(matchUp?rootContainer::cspecialmu:rootContainer::cspecial),
3046	loops );
3047	}
3048
3049	// free some stuff: pev, presult
3050	for ( i=0; i < n; i++ ) nDelete( pev + i );
3051	omFreeSize( (void )pev, n sizeof( number ) );
3052
3053	for ( i=0; i <= tdg; i++ ) nDelete( presults+i );
3054	omFreeSize( (void )presults, (tdg + 1) sizeof( number ) );
3055
3056	return roots;
3057	}
3058
3059	rootContainer ** uResultant::specializeInU( BOOLEAN matchUp, const number subDetVal )
3060	{
3061	int i,/p,/uvar;
3062	long tdg;
3063	poly pures,piter;
3064	int loops=(matchUp?n-2:n-1);
3065	int nn=n;
3066	if (loops==0) { loops=1;nn++;}
3067
3068	mprPROTnl("uResultant::specializeInU");
3069
3070	tdg= resMat->getDetDeg();
3071
3072	rootContainer ** roots;
3073	roots= (rootContainer *) omAlloc( loops sizeof(rootContainer*) );
3074	for ( i=0; i < loops; i++ ) roots[i]= new rootContainer(); // 0..n-2
3075
3076	number pevpoint= (number )omAlloc( nn * sizeof( number ) );
3077	for (i=0; i < nn; i++) pevpoint[i]= nInit(0);
3078
3079	// now we evaluate D(u0,-1,0,...0), D(u0,0,-1,0,...,0), ..., D(u0,0,..,0,-1)
3080	// or D(u0,k1,k2,0,...,0), D(u0,k1,k2,k3,0,...,0), ..., D(u0,k1,k2,k3,...,kn)
3081	// p=3;
3082	for ( uvar= 0; uvar < loops; uvar++ )
3083	{
3084	// generate initial evaluation point
3085	if ( matchUp )
3086	{
3087	for (i=0; i < n; i++)
3088	{
3089	// prime(random number) between 1 and MAXEVPOINT
3090	nDelete( &pevpoint[i] );
3091	if ( i <= uvar + 2 )
3092	{
3093	pevpoint[i]=nInit(1+siRand()%MAXEVPOINT);
3094	//pevpoint[i]=nInit(383);
3095	}
3096	else pevpoint[i]=nInit(0);
3097	mprPROTNnl(" ",pevpoint[i]);
3098	}
3099	}
3100	else
3101	{
3102	for (i=0; i < n; i++)
3103	{
3104	// init pevpoint with prime,0,...0,-1,0,...,0
3105	nDelete( &(pevpoint[i]) );
3106	if ( i == (uvar + 1) ) pevpoint[i]= nInit(-1);
3107	else pevpoint[i]= nInit(0);
3108	mprPROTNnl(" ",pevpoint[i]);
3109	}
3110	}
3111
3112	pures= resMat->getUDet( pevpoint );
3113
3114	number ncpoly= (number )omAlloc( (tdg+1) * sizeof(number) );
3115
3116	#ifdef MPR_MASI
3117	BOOLEAN masi=true;
3118	#endif
3119
3120	piter= pures;
3121	for ( i= tdg; i >= 0; i-- )
3122	{
3123	if ( piter && pTotaldegree(piter) == i )
3124	{
3125	ncpoly[i]= nCopy( pGetCoeff( piter ) );
3126	pIter( piter );
3127	#ifdef MPR_MASI
3128	masi=false;
3129	#endif
3130	}
3131	else
3132	{
3133	ncpoly[i]= nInit(0);
3134	}
3135	mprPROTNnl("", ncpoly[i] );
3136	}
3137	#ifdef MPR_MASI
3138	if ( masi ) mprSTICKYPROT("MASI");
3139	#endif
3140
3141	mprSTICKYPROT(ST_BASE_EV); // .
3142
3143	if ( subDetVal != NULL ) // divide by common factor
3144	{
3145	number detdiv;
3146	for ( i= 0; i <= tdg; i++ )
3147	{
3148	detdiv= nDiv( ncpoly[i], subDetVal );
3149	nNormalize( detdiv );
3150	nDelete( &ncpoly[i] );
3151	ncpoly[i]= detdiv;
3152	}
3153	}
3154
3155	pDelete( &pures );
3156
3157	// save results
3158	roots[uvar]->fillContainer( ncpoly, pevpoint, uvar+1, tdg,
3159	(matchUp?rootContainer::cspecialmu:rootContainer::cspecial),
3160	loops );
3161	}
3162
3163	mprSTICKYPROT("\n");
3164
3165	// free some stuff: pev, presult
3166	for ( i=0; i < n; i++ ) nDelete( pevpoint + i );
3167	omFreeSize( (void )pevpoint, n sizeof( number ) );
3168
3169	return roots;
3170	}
3171
3172	int uResultant::nextPrime( const int i )
3173	{
3174	int init=i;
3175	int ii=i+2;
3176	extern int IsPrime(int p); // from Singular/ipshell.{h,cc}
3177	int j= IsPrime( ii );
3178	while ( j <= init )
3179	{
3180	ii+=2;
3181	j= IsPrime( ii );
3182	}
3183	return j;
3184	}
3185	//<-
3186
3187	//-----------------------------------------------------------------------------
3188
3189	//-> loNewtonPolytope(...)
3190	ideal loNewtonPolytope( const ideal id )
3191	{
3192	simplex * LP;
3193	int i;
3194	int /n,/totverts,idelem;
3195	ideal idr;
3196
3197	// n= (currRing->N);
3198	idelem= IDELEMS(id); // should be n+1
3199
3200	totverts = 0;
3201	for( i=0; i < idelem; i++) totverts += pLength( (id->m)[i] );
3202
3203	LP = new simplex( idelem+totverts*2+5, totverts+5 ); // rows, cols
3204
3205	// evaluate convex hull for supports of id
3206	convexHull chnp( LP );
3207	idr = chnp.newtonPolytopesI( id );
3208
3209	delete LP;
3210
3211	return idr;
3212	}
3213	//<-
3214
3215	//%e
3216
3217	//-----------------------------------------------------------------------------
3218
3219	// local Variables: ***
3220	// folded-file: t ***
3221	// compile-command-1: "make installg" ***
3222	// compile-command-2: "make install" ***
3223	// End: ***
3224
3225	// in folding: C-c x
3226	// leave fold: C-c y
3227	// foldmode: F10

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