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linalg.lib @ 6fe9a5

fieker-DuValspielwiese

Last change on this file since 6fe9a5 was 62dc18e, checked in by Hans Schoenemann <hannes@…>, 13 years ago
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1	//////////////////////////////////////////////////////////////////////////////
2	version="$Id$";
3	category="Linear Algebra";
4	info="
5	LIBRARY: linalg.lib Algorithmic Linear Algebra
6	AUTHORS: Ivor Saynisch (ivs@math.tu-cottbus.de)
7	@* Mathias Schulze (mschulze@mathematik.uni-kl.de)
8
9	PROCEDURES:
10	inverse(A); matrix, the inverse of A
11	inverse_B(A); list(matrix Inv,poly p),InvA=pEn ( using busadj(A) )
12	inverse_L(A); list(matrix Inv,poly p),InvA=pEn ( using lift )
13	sym_gauss(A); symmetric gaussian algorithm
14	orthogonalize(A); Gram-Schmidt orthogonalization
15	diag_test(A); test whether A can be diagnolized
16	busadj(A); coefficients of Adj(Et-A) and coefficients of det(Et-A)
17	charpoly(A,v); characteristic polynomial of A ( using busadj(A) )
18	adjoint(A); adjoint of A ( using busadj(A) )
19	det_B(A); determinant of A ( using busadj(A) )
20	gaussred(A); gaussian reduction: PA=US, S a row reduced form of A
21	gaussred_pivot(A); gaussian reduction: PA=US, uses row pivoting
22	gauss_nf(A); gaussian normal form of A
23	mat_rk(A); rank of constant matrix A
24	U_D_O(A); PA=UD*O, P,D,U,O=permutaion,diag,lower-,upper-triang
25	pos_def(A,i); test symmetric matrix for positive definiteness
26	hessenberg(M); Hessenberg form of M
27	eigenvals(M); eigenvalues with multiplicities of M
28	minipoly(M); minimal polynomial of M
29	spnf(sp); normal form of spectrum sp
30	spprint(sp); print spectrum sp
31	jordan(M); Jordan data of M
32	jordanbasis(M); Jordan basis and weight filtration of M
33	jordanmatrix(jd); Jordan matrix with Jordan data jd
34	jordannf(M); Jordan normal form of M
35	";
36
37	LIB "matrix.lib";
38	LIB "ring.lib";
39	LIB "elim.lib";
40	LIB "general.lib";
41	//////////////////////////////////////////////////////////////////////////////
42	// help functions
43	//////////////////////////////////////////////////////////////////////////////
44	static proc const_mat(matrix A)
45	"RETURN: 1 (0) if A is (is not) a constant matrix"
46	{
47	int i;
48	int n=ncols(A);
49	def BR=basering;
50	def @R=changeord("dp,c",BR);
51	setring @R;
52	matrix A=fetch(BR,A);
53	for(i=1;i<=n;i=i+1){
54	if(deg(lead(A)[i])>=1){
55	//"input is not a constant matrix";
56	kill @R;
57	setring BR;
58	return(0);
59	}
60	}
61	kill @R;
62	setring BR;
63	return(1);
64	}
65	//////////////////////////////////////////////////////////////////////////////
66	static proc red(matrix A,int i,int j)
67	"USAGE: red(A,i,j); A = constant matrix
68	reduces column j with respect to A[i,i] and column i
69	reduces row j with respect to A[i,i] and row i
70	RETURN: matrix
71	"
72	{
73	module m=module(A);
74
75	if(A[i,i]==0){
76	m[i]=m[i]+m[j];
77	m=module(transpose(matrix(m)));
78	m[i]=m[i]+m[j];
79	m=module(transpose(matrix(m)));
80	}
81
82	A=matrix(m);
83	m[j]=m[j]-(A[i,j]/A[i,i])*m[i];
84	m=module(transpose(matrix(m)));
85	m[j]=m[j]-(A[i,j]/A[i,i])*m[i];
86	m=module(transpose(matrix(m)));
87
88	return(matrix(m));
89	}
90
91	//////////////////////////////////////////////////////////////////////////////
92	proc inner_product(vector v1,vector v2)
93	"RETURN: inner product <v1,v2> "
94	{
95	int k;
96	if (nrows(v2)>nrows(v1)) { k=nrows(v2); } else { k=nrows(v1); }
97	return ((transpose(matrix(v1,k,1))*matrix(v2,k,1))[1,1]);
98	}
99
100	/////////////////////////////////////////////////////////////////////////////
101	// user functions
102	/////////////////////////////////////////////////////////////////////////////
103
104	proc inverse(matrix A, list #)
105	"USAGE: inverse(A [,opt]); A a square matrix, opt integer
106	RETURN:
107	@format
108	a matrix:
109	- the inverse matrix of A, if A is invertible;
110	- the 1x1 0-matrix if A is not invertible (in the polynomial ring!).
111	There are the following options:
112	- opt=0 or not given: heuristically best option from below
113	- opt=1 : apply std to (transpose(E,A)), ordering (C,dp).
114	- opt=2 : apply interred (transpose(E,A)), ordering (C,dp).
115	- opt=3 : apply lift(A,E), ordering (C,dp).
116	@end format
117	NOTE: parameters and minpoly are allowed; opt=2 is only correct for
118	matrices with entries in a field
119	SEE ALSO: inverse_B, inverse_L
120	EXAMPLE: example inverse; shows an example
121	"
122	{
123	//--------------------------- initialization and check ------------------------
124	int ii,u,notInvertible,opt;
125	matrix invA;
126	int db = printlevel-voice+3; //used for comments
127	def R=basering;
128	string mp = string(minpoly);
129	int n = nrows(A);
130	module M = A;
131	intvec v = option(get); //get options to reset it later
132	if ( ncols(A)!=n )
133	{
134	ERROR("// ** no square matrix");
135	}
136	//----------------------- choose heurisitically best option ------------------
137	// This may change later, depending on improvements of the implemantation
138	// at the monent we use if opt=0 or opt not given:
139	// opt = 1 (std) for everything
140	// opt = 2 (interred) for nothing, NOTE: interred is ok for constant matricea
141	// opt = 3 (lift) for nothing
142	// NOTE: interred is ok for constant matrices only (Beispiele am Ende der lib)
143	if(size(#) != 0) {opt = #[1];}
144	if(opt == 0)
145	{
146	if(npars(R) == 0) //no parameters
147	{
148	if( size(ideal(A-jet(A,0))) == 0 ) //constant matrix
149	{opt = 1;}
150	else
151	{opt = 1;}
152	}
153	else {opt = 1;}
154	}
155	//------------------------- change ring if necessary -------------------------
156	if( ordstr(R) != "C,dp(nvars(R))" )
157	{
158	u=1;
159	def @R=changeord("C,dp",R);
160	setring @R;
161	module M = fetch(R,M);
162	execute("minpoly="+mp+";");
163	}
164	//----------------------------- opt=3: use lift ------------------------------
165	if( opt==3 )
166	{
167	module D2;
168	D2 = lift(M,freemodule(n));
169	if (size(ideal(D2))==0)
170	{ //catch error in lift
171	dbprint(db,"// ** matrix is not invertible");
172	setring R;
173	if (u==1) { kill @R;}
174	return(invA);
175	}
176	}
177	//-------------- opt = 1 resp. opt = 2: use std resp. interred --------------
178	if( opt==1 or opt==2 )
179	{
180	option(redSB);
181	module B = freemodule(n),M;
182	if(opt == 2)
183	{
184	module D = interred(transpose(B));
185	D = transpose(simplify(D,1));
186	}
187	if(opt == 1)
188	{
189	module D = std(transpose(B));
190	D = transpose(simplify(D,1));
191	}
192	module D2 = D[1..n];
193	module D1 = D[n+1..2*n];
194	//----------------------- check if matrix is invertible ----------------------
195	for (ii=1; ii<=n; ii++)
196	{
197	if ( D1[ii] != gen(ii) )
198	{
199	notInvertible = 1;
200	break;
201	}
202	}
203	}
204	option(set,v);
205	//------------------ return to basering and return result ---------------------
206	if ( u==1 )
207	{
208	setring R;
209	module D2 = fetch(@R,D2);
210	if( opt==1 or opt==2 )
211	{ module D1 = fetch(@R,D1);}
212	kill @R;
213	}
214	if( notInvertible == 1 )
215	{
216	// The matrix A seems to be non-invertible.
217	// Note that there are examples, where this is not true but only due to
218	// inexact computations in the field of reals or complex numbers:
219	// ring r = complex, x, dp;
220	// The following matrix has non-zero determinante but seems non-invertible:
221	// matrix A[3][3] = 1,i,i,0,1,2,1,0,1+i;
222	// For this example, inverse_B yields the correct answer.
223	// So, let's use this as a workaround whenever we have this situation:
224	list myList = inverse_B(A);
225	matrix Try = inverse_B(A)[1];
226	if (myList[2] == poly(1)) { return (Try); }
227	else
228	{
229	dbprint(db,"// ** matrix is not invertible");
230	return(invA);
231	}
232	}
233	else { return(matrix(D2)); } //matrix invertible with inverse D2
234
235	}
236	example
237	{ "EXAMPLE:"; echo = 2;
238	ring r=0,(x,y,z),lp;
239	matrix A[3][3]=
240	1,4,3,
241	1,5,7,
242	0,4,17;
243	print(inverse(A));"";
244	matrix B[3][3]=
245	y+1, x+y, y,
246	z, z+1, z,
247	y+z+2,x+y+z+2,y+z+1;
248	print(inverse(B));
249	print(B*inverse(B));
250	}
251
252	//////////////////////////////////////////////////////////////////////////////
253	proc sym_gauss(matrix A)
254	"USAGE: sym_gauss(A); A = symmetric matrix
255	RETURN: matrix, diagonalisation of A with symmetric gauss algorithm
256	EXAMPLE: example sym_gauss; shows an example"
257	{
258	int i,j;
259	int n=nrows(A);
260
261	if (ncols(A)!=n){
262	"// ** input is not a square matrix";;
263	return(A);
264	}
265
266	if(!const_mat(A)){
267	"// ** input is not a constant matrix";
268	return(A);
269	}
270
271	if(deg(std(A-transpose(A))[1])!=-1){
272	"// ** input is not a symmetric matrix";
273	return(A);
274	}
275
276	for(i=1; i<n; i++){
277	for(j=i+1; j<=n; j++){
278	if(A[i,j]!=0){ A=red(A,i,j); }
279	}
280	}
281
282	return(A);
283	}
284	example
285	{"EXAMPLE:"; echo = 2;
286	ring r=0,(x),lp;
287	matrix A[2][2]=1,4,4,15;
288	print(A);
289	print(sym_gauss(A));
290	}
291
292	//////////////////////////////////////////////////////////////////////////////
293	proc orthogonalize(matrix A)
294	"USAGE: orthogonalize(A); A = matrix of constants
295	RETURN: matrix, orthogonal basis of the colum space of A
296	EXAMPLE: example orthogonalize; shows an example "
297	{
298	int i,j;
299	int n=ncols(A);
300	poly k;
301
302	if(!const_mat(A)){
303	"// ** input is not a constant matrix";
304	matrix B;
305	return(B);
306	}
307
308	module B=module(interred(A));
309
310	for(i=1;i<=n;i=i+1) {
311	for(j=1;j<i;j=j+1) {
312	k=inner_product(B[j],B[j]);
313	if (k==0) { "Error: vector of length zero"; return(matrix(B)); }
314	B[i]=B[i]-(inner_product(B[i],B[j])/k)*B[j];
315	}
316	}
317
318	return(matrix(B));
319	}
320	example
321	{ "EXAMPLE:"; echo = 2;
322	ring r=0,(x),lp;
323	matrix A[4][4]=5,6,12,4,7,3,2,6,12,1,1,2,6,4,2,10;
324	print(A);
325	print(orthogonalize(A));
326	}
327
328	////////////////////////////////////////////////////////////////////////////
329	proc diag_test(matrix A)
330	"USAGE: diag_test(A); A = const square matrix
331	RETURN: int, 1 if A is diagonalizable,@*
332	0 if not@*
333	-1 if no statement is possible, since A does not split.
334	NOTE: The test works only for split matrices, i.e if eigenvalues of A
335	are in the ground field.
336	Does not work with parameters (uses factorize,gcd).
337	EXAMPLE: example diag_test; shows an example"
338	{
339	int i,j;
340	int n = nrows(A);
341	string mp = string(minpoly);
342	string cs = charstr(basering);
343	int np=0;
344
345	if(ncols(A) != n) {
346	"// input is not a square matrix";
347	return(-1);
348	}
349
350	if(!const_mat(A)){
351	"// input is not a constant matrix";
352	return(-1);
353	}
354
355	//Parameterring wegen factorize nicht erlaubt
356	for(i=1;i<size(cs);i=i+1){
357	if(cs[i]==","){np=np+1;} //Anzahl der Parameter
358	}
359	if(np>0){
360	"// rings with parameters not allowed";
361	return(-1);
362	}
363
364	//speichern des aktuellen Rings
365	def BR=basering;
366	//setze R[t]
367	execute("ring rt=("+charstr(basering)+"),(@t,"+varstr(basering)+"),lp;");
368	execute("minpoly="+mp+";");
369	matrix A=imap(BR,A);
370
371	intvec z;
372	intvec s;
373	poly X; //characteristisches Polynom
374	poly dXdt; //Ableitung von X nach t
375	ideal g; //ggT(X,dXdt)
376	poly b; //Komponente der Busadjunkten-Matrix
377	matrix E[n][n]; //Einheitsmatrix
378
379	E=E+1;
380	A=E*@t-A;
381	X=det(A);
382
383	matrix Xfactors=matrix(factorize(X,1)); //zerfaellt die Matrtix ?
384	int nf=ncols(Xfactors);
385
386	for(i=1;i<=nf;i++){
387	if(lead(Xfactors[1,i])>=@t^2){
388	//" matrix does not split";
389	setring BR;
390	return(-1);
391	}
392	}
393
394	dXdt=diff(X,@t);
395	g=std(ideal(gcd(X,dXdt)));
396
397	//Busadjunkte
398	z=2..n;
399	for(i=1;i<=n;i++){
400	s=2..n;
401	for(j=1;j<=n;j++){
402	b=det(submat(A,z,s));
403
404	if(0!=reduce(b,g)){
405	//" matrix not diagonalizable";
406	setring BR;
407	return(0);
408	}
409
410	s[j]=j;
411	}
412	z[i]=i;
413	}
414
415	//"Die Matrix ist diagonalisierbar";
416	setring BR;
417	return(1);
418	}
419	example
420	{ "EXAMPLE:"; echo = 2;
421	ring r=0,(x),dp;
422	matrix A[4][4]=6,0,0,0,0,0,6,0,0,6,0,0,0,0,0,6;
423	print(A);
424	diag_test(A);
425	}
426
427	//////////////////////////////////////////////////////////////////////////////
428	proc busadj(matrix A)
429	"USAGE: busadj(A); A = square matrix (of size nxn)
430	RETURN: list L:
431	@format
432	L[1] contains the (n+1) coefficients of the characteristic
433	polynomial X of A, i.e.
434	X = L[1][1]+..+L[1][k]t^(k-1)+..+(L[1][n+1])t^n
435	L[2] contains the n (nxn)-matrices Hk which are the coefficients of
436	the busadjoint bA = adjoint(E*t-A) of A, i.e.
437	bA = (Hn-1)t^(n-1)+...+Hkt^k+...+H0, ( Hk=L[2][k+1] )
438	@end format
439	EXAMPLE: example busadj; shows an example"
440	{
441	int k;
442	int n = nrows(A);
443	matrix E = unitmat(n);
444	matrix H[n][n];
445	matrix B[n][n];
446	list bA, X, L;
447	poly a;
448
449	if(ncols(A) != n) {
450	"input is not a square matrix";
451	return(L);
452	}
453
454	bA = E;
455	X[1] = 1;
456	for(k=1; k<n; k++){
457	B = A*bA[1]; //bA[1] is the last H
458	a = -trace(B)/k;
459	H = B+a*E;
460	bA = insert(bA,H);
461	X = insert(X,a);
462	}
463	B = A*bA[1];
464	a = -trace(B)/n;
465	X = insert(X,a);
466
467	L = insert(L,bA);
468	L = insert(L,X);
469	return(L);
470	}
471	example
472	{ "EXAMPLE"; echo = 2;
473	ring r = 0,(t,x),lp;
474	matrix A[2][2] = 1,x2,x,x2+3x;
475	print(A);
476	list L = busadj(A);
477	poly X = L[1][1]+L[1][2]t+L[1][3]t2; X;
478	matrix bA[2][2] = L[2][1]+L[2][2]*t;
479	print(bA); //the busadjoint of A;
480	print(bA(tunitmat(2)-A));
481	}
482
483	//////////////////////////////////////////////////////////////////////////////
484	proc charpoly(matrix A, list #)
485	"USAGE: charpoly(A[,v]); A square matrix, v string, name of a variable
486	RETURN: poly, the characteristic polynomial det(E*v-A)
487	(default: v=name of last variable)
488	NOTE: A must be independent of the variable v. The computation uses det.
489	If printlevel>0, det(E*v-A) is diplayed recursively.
490	EXAMPLE: example charpoly; shows an example"
491	{
492	int n = nrows(A);
493	int z = nvars(basering);
494	int i,j;
495	string v;
496	poly X;
497	if(ncols(A) != n)
498	{
499	"// input is not a square matrix";
500	return(X);
501	}
502	//---------------------- test for correct variable -------------------------
503	if( size(#)==0 ){
504	#[1] = varstr(z);
505	}
506	if( typeof(#[1]) == "string") { v = #[1]; }
507	else
508	{
509	"// 2nd argument must be a name of a variable not contained in the matrix";
510	return(X);
511	}
512	j=-1;
513	for(i=1; i<=z; i++)
514	{
515	if(varstr(i)==v){j=i;}
516	}
517	if(j==-1)
518	{
519	"// "+v+" is not a variable in the basering";
520	return(X);
521	}
522	if ( size(select1(module(A),j)) != 0 )
523	{
524	"// matrix must not contain the variable "+v;
525	"// change to a ring with an extra variable, if necessary."
526	return(X);
527	}
528	//-------------------------- compute charpoly ------------------------------
529	X = det(var(j)*unitmat(n)-A);
530	if( printlevel-voice+2 >0) { showrecursive(X,var(j));}
531	return(X);
532	}
533	example
534	{ "EXAMPLE"; echo=2;
535	ring r=0,(x,t),dp;
536	matrix A[3][3]=1,x2,x,x2,6,4,x,4,1;
537	print(A);
538	charpoly(A,"t");
539	}
540
541	//////////////////////////////////////////////////////////////////////////////
542	proc charpoly_B(matrix A, list #)
543	"USAGE: charpoly_B(A[,v]); A square matrix, v string, name of a variable
544	RETURN: poly, the characteristic polynomial det(E*v-A)
545	(default: v=name of last variable)
546	NOTE: A must be constant in the variable v. The computation uses busadj(A).
547	EXAMPLE: example charpoly_B; shows an example"
548	{
549	int i,j;
550	string s,v;
551	list L;
552	int n = nrows(A);
553	poly X = 0;
554	def BR = basering;
555	string mp = string(minpoly);
556
557	if(ncols(A) != n){
558	"// input is not a square matrix";
559	return(X);
560	}
561
562	//test for correct variable
563	if( size(#)==0 ){
564	#[1] = varstr(nvars(BR));
565	}
566	if( typeof(#[1]) == "string"){
567	v = #[1];
568	}
569	else{
570	"// 2nd argument must be a name of a variable not contained in the matrix";
571	return(X);
572	}
573
574	j=-1;
575	for(i=1; i<=nvars(BR); i++){
576	if(varstr(i)==v){j=i;}
577	}
578	if(j==-1){
579	"// "+v+" is not a variable in the basering";
580	return(X);
581	}
582
583	//var cannot be in A
584	s="Wp(";
585	for( i=1; i<=nvars(BR); i++ ){
586	if(i!=j){ s=s+"0";}
587	else{ s=s+"1";}
588	if( i<nvars(BR)) {s=s+",";}
589	}
590	s=s+")";
591
592	def @R=changeord(s);
593	setring @R;
594	execute("minpoly="+mp+";");
595	matrix A = imap(BR,A);
596	for(i=1; i<=n; i++){
597	if(deg(lead(A)[i])>=1){
598	"// matrix must not contain the variable "+v;
599	kill @R;
600	setring BR;
601	return(X);
602	}
603	}
604
605	//get coefficients and build the char. poly
606	kill @R;
607	setring BR;
608	L = busadj(A);
609	for(i=1; i<=n+1; i++){
610	execute("X=X+L[1][i]*"+v+"^"+string(i-1)+";");
611	}
612
613	return(X);
614	}
615	example
616	{ "EXAMPLE"; echo=2;
617	ring r=0,(x,t),dp;
618	matrix A[3][3]=1,x2,x,x2,6,4,x,4,1;
619	print(A);
620	charpoly_B(A,"t");
621	}
622
623	//////////////////////////////////////////////////////////////////////////////
624	proc adjoint(matrix A)
625	"USAGE: adjoint(A); A = square matrix
626	RETURN: adjoint matrix of A, i.e. AdjA=det(A)E
627	NOTE: computation uses busadj(A)
628	EXAMPLE: example adjoint; shows an example"
629	{
630	int n=nrows(A);
631	matrix Adj[n][n];
632	list L;
633
634	if(ncols(A) != n) {
635	"// input is not a square matrix";
636	return(Adj);
637	}
638
639	L = busadj(A);
640	Adj= (-1)^(n-1)*L[2][1];
641	return(Adj);
642
643	}
644	example
645	{ "EXAMPLE"; echo=2;
646	ring r=0,(t,x),lp;
647	matrix A[2][2]=1,x2,x,x2+3x;
648	print(A);
649	matrix Adj[2][2]=adjoint(A);
650	print(Adj); //AdjA=det(A)E
651	print(Adj*A);
652	}
653
654	//////////////////////////////////////////////////////////////////////////////
655	proc inverse_B(matrix A)
656	"USAGE: inverse_B(A); A = square matrix
657	RETURN: list Inv with
658	- Inv[1] = matrix I and
659	- Inv[2] = poly p
660	such that IA = unitmat(n)p;
661	NOTE: p=1 if 1/det(A) is computable and p=det(A) if not;
662	the computation uses busadj.
663	SEE ALSO: inverse, inverse_L
664	EXAMPLE: example inverse_B; shows an example"
665	{
666	int i;
667	int n=nrows(A);
668	matrix I[n][n];
669	poly factor;
670	list L;
671	list Inv;
672
673	if(ncols(A) != n) {
674	"input is not a square matrix";
675	return(I);
676	}
677
678	L=busadj(A);
679	I=module(-L[2][1]); //+-Adj(A)
680
681	if(reduce(1,std(L[1][1]))==0){
682	I=I*lift(L[1][1],1)[1][1];
683	factor=1;
684	}
685	else{ factor=L[1][1];} //=+-det(A) or 1
686	Inv=insert(Inv,factor);
687	Inv=insert(Inv,matrix(I));
688
689	return(Inv);
690	}
691	example
692	{ "EXAMPLE"; echo=2;
693	ring r=0,(x,y),lp;
694	matrix A[3][3]=x,y,1,1,x2,y,x,6,0;
695	print(A);
696	list Inv=inverse_B(A);
697	print(Inv[1]);
698	print(Inv[2]);
699	print(Inv[1]*A);
700	}
701
702	//////////////////////////////////////////////////////////////////////////////
703	proc det_B(matrix A)
704	"USAGE: det_B(A); A any matrix
705	RETURN: returns the determinant of A
706	NOTE: the computation uses the busadj algorithm
707	EXAMPLE: example det_B; shows an example"
708	{
709	int n=nrows(A);
710	list L;
711
712	if(ncols(A) != n){ return(0);}
713
714	L=busadj(A);
715	return((-1)^n*L[1][1]);
716	}
717	example
718	{ "EXAMPLE"; echo=2;
719	ring r=0,(x),dp;
720	matrix A[10][10]=random(2,10,10)+unitmat(10)*x;
721	print(A);
722	det_B(A);
723	}
724
725	//////////////////////////////////////////////////////////////////////////////
726	proc inverse_L(matrix A)
727	"USAGE: inverse_L(A); A = square matrix
728	RETURN: list Inv representing a left inverse of A, i.e
729	- Inv[1] = matrix I and
730	- Inv[2] = poly p
731	such that IA = unitmat(n)p;
732	NOTE: p=1 if 1/det(A) is computable and p=det(A) if not;
733	the computation computes first det(A) and then uses lift
734	SEE ALSO: inverse, inverse_B
735	EXAMPLE: example inverse_L; shows an example"
736	{
737	int n=nrows(A);
738	matrix I;
739	matrix E[n][n]=unitmat(n);
740	poly factor;
741	poly d=1;
742	list Inv;
743
744	if (ncols(A)!=n){
745	"// input is not a square matrix";
746	return(I);
747	}
748
749	d=det(A);
750	if(d==0){
751	"// matrix is not invertible";
752	return(Inv);
753	}
754
755	// test if 1/det(A) exists
756	if(reduce(1,std(d))!=0){ E=E*d;}
757
758	I=lift(A,E);
759	if(I==unitmat(n)-unitmat(n)){ //catch error in lift
760	"// matrix is not invertible";
761	return(Inv);
762	}
763
764	factor=d; //=det(A) or 1
765	Inv=insert(Inv,factor);
766	Inv=insert(Inv,I);
767
768	return(Inv);
769	}
770	example
771	{ "EXAMPLE"; echo=2;
772	ring r=0,(x,y),lp;
773	matrix A[3][3]=x,y,1,1,x2,y,x,6,0;
774	print(A);
775	list Inv=inverse_L(A);
776	print(Inv[1]);
777	print(Inv[2]);
778	print(Inv[1]*A);
779	}
780
781	//////////////////////////////////////////////////////////////////////////////
782	proc gaussred(matrix A)
783	"USAGE: gaussred(A); A any constant matrix
784	RETURN: list Z: Z[1]=P , Z[2]=U , Z[3]=S , Z[4]=rank(A)
785	gives a row reduced matrix S, a permutation matrix P and a
786	normalized lower triangular matrix U, with PA=US
787	NOTE: This procedure is designed for teaching purposes mainly.
788	The straight forward implementation in the interpreted library
789	is not very efficient (no standard basis computation).
790	EXAMPLE: example gaussred; shows an example"
791	{
792	int i,j,l,k,jp,rang;
793	poly c,pivo;
794	list Z;
795	int n = nrows(A);
796	int m = ncols(A);
797	int mr= n; //max. rang
798	matrix P[n][n] = unitmat(n);
799	matrix U[n][n] = P;
800
801	if(!const_mat(A)){
802	"// input is not a constant matrix";
803	return(Z);
804	}
805
806	if(n>m){mr=m;} //max. rang
807
808	for(i=1;i<=mr;i=i+1){
809	if((i+k)>m){break;}
810
811	//Test: Diagonalelement=0
812	if(A[i,i+k]==0){
813	jp=i;pivo=0;
814	for(j=i+1;j<=n;j=j+1){
815	c=absValue(A[j,i+k]);
816	if(pivo<c){ pivo=c;jp=j;}
817	}
818	if(jp != i){ //Zeilentausch
819	for(j=1;j<=m;j=j+1){ //Zeilentausch in A (und U) (i-te mit jp-ter)
820	c=A[i,j];
821	A[i,j]=A[jp,j];
822	A[jp,j]=c;
823	}
824	for(j=1;j<=n;j=j+1){ //Zeilentausch in P
825	c=P[i,j];
826	P[i,j]=P[jp,j];
827	P[jp,j]=c;
828	}
829	}
830	if(pivo==0){k++;continue;} //eine von selbst auftauchende Stufe !
831	} //i sollte im naechsten Lauf nicht erhoeht sein
832
833	//Eliminationsschritt
834	for(j=i+1;j<=n;j=j+1){
835	c=A[j,i+k]/A[i,i+k];
836	for(l=i+k+1;l<=m;l=l+1){
837	A[j,l]=A[j,l]-A[i,l]*c;
838	}
839	A[j,i+k]=0; // nur wichtig falls k>0 ist
840	A[j,i]=c; // bildet U
841	}
842	rang=i;
843	}
844
845	for(i=1;i<=mr;i=i+1){
846	for(j=i+1;j<=n;j=j+1){
847	U[j,i]=A[j,i];
848	A[j,i]=0;
849	}
850	}
851
852	Z=insert(Z,rang);
853	Z=insert(Z,A);
854	Z=insert(Z,U);
855	Z=insert(Z,P);
856
857	return(Z);
858	}
859	example
860	{ "EXAMPLE";echo=2;
861	ring r=0,(x),dp;
862	matrix A[5][4]=1,3,-1,4,2,5,-1,3,1,3,-1,4,0,4,-3,1,-3,1,-5,-2;
863	print(A);
864	list Z=gaussred(A); //construct P,U,S s.t. PA=US
865	print(Z[1]); //P
866	print(Z[2]); //U
867	print(Z[3]); //S
868	print(Z[4]); //rank
869	print(Z[1]A); //PA
870	print(Z[2]Z[3]); //US
871	}
872
873	//////////////////////////////////////////////////////////////////////////////
874	proc gaussred_pivot(matrix A)
875	"USAGE: gaussred_pivot(A); A any constant matrix
876	RETURN: list Z: Z[1]=P , Z[2]=U , Z[3]=S , Z[4]=rank(A)
877	gives a row reduced matrix S, a permutation matrix P and a
878	normalized lower triangular matrix U, with PA=US
879	NOTE: with row pivoting
880	EXAMPLE: example gaussred_pivot; shows an example"
881	{
882	int i,j,l,k,jp,rang;
883	poly c,pivo;
884	list Z;
885	int n=nrows(A);
886	int m=ncols(A);
887	int mr=n; //max. rang
888	matrix P[n][n]=unitmat(n);
889	matrix U[n][n]=P;
890
891	if(!const_mat(A)){
892	"// input is not a constant matrix";
893	return(Z);
894	}
895
896	if(n>m){mr=m;} //max. rang
897
898	for(i=1;i<=mr;i=i+1){
899	if((i+k)>m){break;}
900
901	//Pivotisierung
902	pivo=absValue(A[i,i+k]);jp=i;
903	for(j=i+1;j<=n;j=j+1){
904	c=absValue(A[j,i+k]);
905	if(pivo<c){ pivo=c;jp=j;}
906	}
907	if(jp != i){ //Zeilentausch
908	for(j=1;j<=m;j=j+1){ //Zeilentausch in A (und U) (i-te mit jp-ter)
909	c=A[i,j];
910	A[i,j]=A[jp,j];
911	A[jp,j]=c;
912	}
913	for(j=1;j<=n;j=j+1){ //Zeilentausch in P
914	c=P[i,j];
915	P[i,j]=P[jp,j];
916	P[jp,j]=c;
917	}
918	}
919	if(pivo==0){k++;continue;} //eine von selbst auftauchende Stufe !
920	//i sollte im naechsten Lauf nicht erhoeht sein
921	//Eliminationsschritt
922	for(j=i+1;j<=n;j=j+1){
923	c=A[j,i+k]/A[i,i+k];
924	for(l=i+k+1;l<=m;l=l+1){
925	A[j,l]=A[j,l]-A[i,l]*c;
926	}
927	A[j,i+k]=0; // nur wichtig falls k>0 ist
928	A[j,i]=c; // bildet U
929	}
930	rang=i;
931	}
932
933	for(i=1;i<=mr;i=i+1){
934	for(j=i+1;j<=n;j=j+1){
935	U[j,i]=A[j,i];
936	A[j,i]=0;
937	}
938	}
939
940	Z=insert(Z,rang);
941	Z=insert(Z,A);
942	Z=insert(Z,U);
943	Z=insert(Z,P);
944
945	return(Z);
946	}
947	example
948	{ "EXAMPLE";echo=2;
949	ring r=0,(x),dp;
950	matrix A[5][4] = 1, 3,-1,4,
951	2, 5,-1,3,
952	1, 3,-1,4,
953	0, 4,-3,1,
954	-3,1,-5,-2;
955	list Z=gaussred_pivot(A); //construct P,U,S s.t. PA=US
956	print(Z[1]); //P
957	print(Z[2]); //U
958	print(Z[3]); //S
959	print(Z[4]); //rank
960	print(Z[1]A); //PA
961	print(Z[2]Z[3]); //US
962	}
963
964	//////////////////////////////////////////////////////////////////////////////
965	proc gauss_nf(matrix A)
966	"USAGE: gauss_nf(A); A any constant matrix
967	RETURN: matrix; gauss normal form of A (uses gaussred)
968	EXAMPLE: example gauss_nf; shows an example"
969	{
970	list Z;
971	if(!const_mat(A)){
972	"// input is not a constant matrix";
973	return(A);
974	}
975	Z = gaussred(A);
976	return(Z[3]);
977	}
978	example
979	{ "EXAMPLE";echo=2;
980	ring r = 0,(x),dp;
981	matrix A[4][4] = 1,4,4,7,2,5,5,4,4,1,1,3,0,2,2,7;
982	print(gauss_nf(A));
983	}
984
985	//////////////////////////////////////////////////////////////////////////////
986	proc mat_rk(matrix A)
987	"USAGE: mat_rk(A); A any constant matrix
988	RETURN: int, rank of A
989	EXAMPLE: example mat_rk; shows an example"
990	{
991	list Z;
992	if(!const_mat(A)){
993	"// input is not a constant matrix";
994	return(-1);
995	}
996	Z = gaussred(A);
997	return(Z[4]);
998	}
999	example
1000	{ "EXAMPLE";echo=2;
1001	ring r = 0,(x),dp;
1002	matrix A[4][4] = 1,4,4,7,2,5,5,4,4,1,1,3,0,2,2,7;
1003	mat_rk(A);
1004	}
1005
1006	//////////////////////////////////////////////////////////////////////////////
1007	proc U_D_O(matrix A)
1008	"USAGE: U_D_O(A); constant invertible matrix A
1009	RETURN: list Z: Z[1]=P , Z[2]=U , Z[3]=D , Z[4]=O
1010	gives a permutation matrix P,
1011	a normalized lower triangular matrix U ,
1012	a diagonal matrix D, and
1013	a normalized upper triangular matrix O
1014	with PA=UD*O
1015	NOTE: Z[1]=-1 means that A is not regular (proc uses gaussred)
1016	EXAMPLE: example U_D_O; shows an example"
1017	{
1018	int i,j;
1019	list Z,L;
1020	int n=nrows(A);
1021	matrix O[n][n]=unitmat(n);
1022	matrix D[n][n];
1023
1024	if (ncols(A)!=n){
1025	"// input is not a square matrix";
1026	return(Z);
1027	}
1028	if(!const_mat(A)){
1029	"// input is not a constant matrix";
1030	return(Z);
1031	}
1032
1033	L=gaussred(A);
1034
1035	if(L[4]!=n){
1036	"// input is not an invertible matrix";
1037	Z=insert(Z,-1); //hint for calling procedures
1038	return(Z);
1039	}
1040
1041	D=L[3];
1042
1043	for(i=1; i<=n; i++){
1044	for(j=i+1; j<=n; j++){
1045	O[i,j] = D[i,j]/D[i,i];
1046	D[i,j] = 0;
1047	}
1048	}
1049
1050	Z=insert(Z,O);
1051	Z=insert(Z,D);
1052	Z=insert(Z,L[2]);
1053	Z=insert(Z,L[1]);
1054	return(Z);
1055	}
1056	example
1057	{ "EXAMPLE";echo=2;
1058	ring r = 0,(x),dp;
1059	matrix A[5][5] = 10, 4, 0, -9, 8,
1060	-3, 6, -6, -4, 9,
1061	0, 3, -1, -9, -8,
1062	-4,-2, -6, -10,10,
1063	-9, 5, -1, -6, 5;
1064	list Z = U_D_O(A); //construct P,U,D,O s.t. PA=UD*O
1065	print(Z[1]); //P
1066	print(Z[2]); //U
1067	print(Z[3]); //D
1068	print(Z[4]); //O
1069	print(Z[1]A); //PA
1070	print(Z[2]Z[3]Z[4]); //UDO
1071	}
1072
1073	//////////////////////////////////////////////////////////////////////////////
1074	proc pos_def(matrix A)
1075	"USAGE: pos_def(A); A = constant, symmetric square matrix
1076	RETURN: int:
1077	1 if A is positive definit ,
1078	0 if not,
1079	-1 if unknown
1080	EXAMPLE: example pos_def; shows an example"
1081	{
1082	int j;
1083	list Z;
1084	int n = nrows(A);
1085	matrix H[n][n];
1086
1087	if (ncols(A)!=n){
1088	"// input is not a square matrix";
1089	return(0);
1090	}
1091	if(!const_mat(A)){
1092	"// input is not a constant matrix";
1093	return(-1);
1094	}
1095	if(deg(std(A-transpose(A))[1])!=-1){
1096	"// input is not a hermitian (symmetric) matrix";
1097	return(-1);
1098	}
1099
1100	Z=U_D_O(A);
1101
1102	if(Z[1]==-1){
1103	return(0);
1104	} //A not regular, therefore not pos. definit
1105
1106	H=Z[1];
1107	//es fand Zeilentausch statt: also nicht positiv definit
1108	if(deg(std(H-unitmat(n))[1])!=-1){
1109	return(0);
1110	}
1111
1112	H=Z[3];
1113
1114	for(j=1;j<=n;j=j+1){
1115	if(H[j,j]<=0){
1116	return(0);
1117	} //eigenvalue<=0, not pos.definit
1118	}
1119
1120	return(1); //positiv definit;
1121	}
1122	example
1123	{ "EXAMPLE"; echo=2;
1124	ring r = 0,(x),dp;
1125	matrix A[5][5] = 20, 4, 0, -9, 8,
1126	4, 12, -6, -4, 9,
1127	0, -6, -2, -9, -8,
1128	-9, -4, -9, -20, 10,
1129	8, 9, -8, 10, 10;
1130	pos_def(A);
1131	matrix B[3][3] = 3, 2, 0,
1132	2, 12, 4,
1133	0, 4, 2;
1134	pos_def(B);
1135	}
1136
1137	//////////////////////////////////////////////////////////////////////////////
1138	proc linsolve(matrix A, matrix b)
1139	"USAGE: linsolve(A,b); A a constant nxm-matrix, b a constant nx1-matrix
1140	RETURN: a 1xm matrix X, solution of inhomogeneous linear system A*X = b
1141	return the 0-matrix if system is not solvable
1142	NOTE: uses gaussred
1143	EXAMPLE: example linsolve; shows an example"
1144	{
1145	int i,j,k,rc,r;
1146	poly c;
1147	list Z;
1148	int n = nrows(A);
1149	int m = ncols(A);
1150	int n_b= nrows(b);
1151	matrix Ab[n][m+1];
1152	matrix X[m][1];
1153
1154	if(ncols(b)!=1){
1155	"// right hand side b is not a nx1 matrix";
1156	return(X);
1157	}
1158
1159	if(!const_mat(A)){
1160	"// input hand is not a constant matrix";
1161	return(X);
1162	}
1163
1164	if(n_b>n){
1165	for(i=n; i<=n_b; i++){
1166	if(b[i,1]!=0){
1167	"// right hand side b not in Image(A)";
1168	return X;
1169	}
1170	}
1171	}
1172
1173	if(n_b<n){
1174	matrix copy[n_b][1]=b;
1175	matrix b[n][1]=0;
1176	for(i=1;i<=n_b;i=i+1){
1177	b[i,1]=copy[i,1];
1178	}
1179	}
1180
1181	r=mat_rk(A);
1182
1183	//1. b constant vector
1184	if(const_mat(b)){
1185	//extend A with b
1186	for(i=1; i<=n; i++){
1187	for(j=1; j<=m; j++){
1188	Ab[i,j]=A[i,j];
1189	}
1190	Ab[i,m+1]=b[i,1];
1191	}
1192
1193	//Gauss reduction
1194	Z = gaussred(Ab);
1195	Ab = Z[3]; //normal form
1196	rc = Z[4]; //rank(Ab)
1197	//print(Ab);
1198
1199	if(r<rc){
1200	"// no solution";
1201	return(X);
1202	}
1203	k=m;
1204	for(i=r;i>=1;i=i-1){
1205
1206	j=1;
1207	while(Ab[i,j]==0){j=j+1;}// suche Ecke
1208
1209	for(;k>j;k=k-1){ X[k]=0;}//springe zur Ecke
1210
1211
1212	c=Ab[i,m+1]; //i-te Komponene von b
1213	for(j=m;j>k;j=j-1){
1214	c=c-X[j,1]*Ab[i,j];
1215	}
1216	if(Ab[i,k]==0){
1217	X[k,1]=1; //willkuerlich
1218	}
1219	else{
1220	X[k,1]=c/Ab[i,k];
1221	}
1222	k=k-1;
1223	if(k==0){break;}
1224	}
1225
1226
1227	}//endif (const b)
1228	else{ //b not constant
1229	"// !not implemented!";
1230
1231	}
1232
1233	return(X);
1234	}
1235	example
1236	{ "EXAMPLE";echo=2;
1237	ring r=0,(x),dp;
1238	matrix A[3][2] = -4,-6,
1239	2, 3,
1240	-5, 7;
1241	matrix b[3][1] = 10,
1242	-5,
1243	2;
1244	matrix X = linsolve(A,b);
1245	print(X);
1246	print(A*X);
1247	}
1248	//////////////////////////////////////////////////////////////////////////////
1249
1250	///////////////////////////////////////////////////////////////////////////////
1251	// PROCEDURES for Jordan normal form
1252	// AUTHOR: Mathias Schulze, email: mschulze@mathematik.uni-kl.de
1253	///////////////////////////////////////////////////////////////////////////////
1254
1255	static proc rowcolswap(matrix M,int i,int j)
1256	{
1257	if(i==j)
1258	{
1259	return(M);
1260	}
1261	poly p;
1262	for(int k=1;k<=nrows(M);k++)
1263	{
1264	p=M[i,k];
1265	M[i,k]=M[j,k];
1266	M[j,k]=p;
1267	}
1268	for(k=1;k<=ncols(M);k++)
1269	{
1270	p=M[k,i];
1271	M[k,i]=M[k,j];
1272	M[k,j]=p;
1273	}
1274	return(M);
1275	}
1276	//////////////////////////////////////////////////////////////////////////////
1277
1278	static proc rowelim(matrix M,int i,int j,int k)
1279	{
1280	if(jet(M[i,k],0)==0\|\|jet(M[j,k],0)==0)
1281	{
1282	return(M);
1283	}
1284	number n=number(jet(M[i,k],0))/number(jet(M[j,k],0));
1285	for(int l=1;l<=ncols(M);l++)
1286	{
1287	M[i,l]=M[i,l]-n*M[j,l];
1288	}
1289	for(l=1;l<=nrows(M);l++)
1290	{
1291	M[l,j]=M[l,j]+n*M[l,i];
1292	}
1293	return(M);
1294	}
1295	///////////////////////////////////////////////////////////////////////////////
1296
1297	static proc colelim(matrix M,int i,int j,int k)
1298	{
1299	if(jet(M[k,i],0)==0\|\|jet(M[k,j],0)==0)
1300	{
1301	return(M);
1302	}
1303	number n=number(jet(M[k,i],0))/number(jet(M[k,j],0));
1304	for(int l=1;l<=nrows(M);l++)
1305	{
1306	M[l,i]=M[l,i]-n*M[l,j];
1307	}
1308	for(l=1;l<=ncols(M);l++)
1309	{
1310	M[j,l]=M[j,l]+n*M[i,l];
1311	}
1312	return(M);
1313	}
1314	///////////////////////////////////////////////////////////////////////////////
1315
1316	proc hessenberg(matrix M)
1317	"USAGE: hessenberg(M); matrix M
1318	ASSUME: M constant square matrix
1319	RETURN: matrix H; Hessenberg form of M
1320	EXAMPLE: example hessenberg; shows examples
1321	"
1322	{
1323	if(system("with","eigenval"))
1324	{
1325	return(system("hessenberg",M));
1326	}
1327
1328	int n=ncols(M);
1329	int i,j;
1330	for(int k=1;k<n-1;k++)
1331	{
1332	j=k+1;
1333	while(j<n&&jet(M[j,k],0)==0)
1334	{
1335	j++;
1336	}
1337	if(jet(M[j,k],0)!=0)
1338	{
1339	M=rowcolswap(M,j,k+1);
1340	for(i=j+1;i<=n;i++)
1341	{
1342	M=rowelim(M,i,k+1,k);
1343	}
1344	}
1345	}
1346	return(M);
1347	}
1348	example
1349	{ "EXAMPLE:"; echo=2;
1350	ring R=0,x,dp;
1351	matrix M[3][3]=3,2,1,0,2,1,0,0,3;
1352	print(M);
1353	print(hessenberg(M));
1354	}
1355	///////////////////////////////////////////////////////////////////////////////
1356
1357	proc eigenvals(matrix M)
1358	"USAGE: eigenvals(M); matrix M
1359	ASSUME: eigenvalues of M in basefield
1360	RETURN:
1361	@format
1362	list l;
1363	ideal l[1];
1364	number l[1][i]; i-th eigenvalue of M
1365	intvec l[2];
1366	int l[2][i]; multiplicity of i-th eigenvalue of M
1367	@end format
1368	EXAMPLE: example eigenvals; shows examples
1369	"
1370	{
1371	if(system("with","eigenval"))
1372	{
1373	return(system("eigenvals",jet(M,0)));
1374	}
1375
1376	M=jet(hessenberg(M),0);
1377	int n=ncols(M);
1378	int k;
1379	ideal e;
1380	intvec m;
1381	number e0;
1382	intvec v;
1383	list l;
1384	int i,j;
1385	j=1;
1386	while(j<=n)
1387	{
1388	v=j;
1389	j++;
1390	if(j<=n)
1391	{
1392	while(j<n&&M[j,j-1]!=0)
1393	{
1394	v=v,j;
1395	j++;
1396	}
1397	if(M[j,j-1]!=0)
1398	{
1399	v=v,j;
1400	j++;
1401	}
1402	}
1403	if(size(v)==1)
1404	{
1405	k++;
1406	e[k]=M[v,v];
1407	m[k]=1;
1408	}
1409	else
1410	{
1411	l=factorize(det(submat(M,v,v)-var(1)));
1412	for(i=size(l[1]);i>=1;i--)
1413	{
1414	e0=number(jet(l[1][i]/var(1),0));
1415	if(e0!=0)
1416	{
1417	k++;
1418	e[k]=(e0*var(1)-l[1][i])/e0;
1419	m[k]=l[2][i];
1420	}
1421	}
1422	}
1423	}
1424	return(spnf(list(e,m)));
1425	}
1426	example
1427	{ "EXAMPLE:"; echo=2;
1428	ring R=0,x,dp;
1429	matrix M[3][3]=3,2,1,0,2,1,0,0,3;
1430	print(M);
1431	eigenvals(M);
1432	}
1433	///////////////////////////////////////////////////////////////////////////////
1434
1435	proc minipoly(matrix M,list #)
1436	"USAGE: minipoly(M); matrix M
1437	ASSUME: eigenvalues of M in basefield
1438	RETURN:
1439	@format
1440	list l; minimal polynomial of M
1441	ideal l[1];
1442	number l[1][i]; i-th root of minimal polynomial of M
1443	intvec l[2];
1444	int l[2][i]; multiplicity of i-th root of minimal polynomial of M
1445	@end format
1446	EXAMPLE: example minipoly; shows examples
1447	"
1448	{
1449	if(nrows(M)==0)
1450	{
1451	ERROR("non empty expected");
1452	}
1453	if(ncols(M)!=nrows(M))
1454	{
1455	ERROR("square matrix expected");
1456	}
1457
1458	M=jet(M,0);
1459
1460	if(size(#)==0)
1461	{
1462	#=eigenvals(M);
1463	}
1464	def e0,m0=#[1..2];
1465
1466	intvec m1;
1467	matrix N0,N1;
1468	for(int i=1;i<=ncols(e0);i++)
1469	{
1470	m1[i]=1;
1471	N0=M-e0[i];
1472	N1=N0;
1473	while(size(syz(N1))<m0[i])
1474	{
1475	m1[i]=m1[i]+1;
1476	N1=N1*N0;
1477	}
1478	}
1479
1480	return(list(e0,m1));
1481	}
1482	example
1483	{ "EXAMPLE:"; echo=2;
1484	ring R=0,x,dp;
1485	matrix M[3][3]=3,2,1,0,2,1,0,0,3;
1486	print(M);
1487	minipoly(M);
1488	}
1489	///////////////////////////////////////////////////////////////////////////////
1490
1491	proc spnf(list #)
1492	"USAGE: spnf(list(a[,m])); ideal a, intvec m
1493	ASSUME: ncols(a)==size(m)
1494	RETURN: list l:
1495	l[1] an ideal, the generators of a; sorted and with multiple entries displayed only once@*
1496	l[2] and intvec, l[2][i] provides the multiplicity of l[1][i]
1497	EXAMPLE: example spnf; shows examples
1498	"
1499	{
1500	list sp=#;
1501	ideal a=sp[1];
1502	int n=ncols(a);
1503	intvec m;
1504	list V;
1505	module v;
1506	int i,j;
1507	for(i=2;i<=size(sp);i++)
1508	{
1509	if(typeof(sp[i])=="intvec")
1510	{
1511	m=sp[i];
1512	}
1513	if(typeof(sp[i])=="module")
1514	{
1515	v=sp[i];
1516	for(j=n;j>=1;j--)
1517	{
1518	V[j]=module(v[j]);
1519	}
1520	}
1521	if(typeof(sp[i])=="list")
1522	{
1523	V=sp[i];
1524	}
1525	}
1526	if(m==0)
1527	{
1528	for(i=n;i>=1;i--)
1529	{
1530	m[i]=1;
1531	}
1532	}
1533
1534	int k;
1535	ideal a0;
1536	intvec m0;
1537	list V0;
1538	number a1;
1539	int m1;
1540	for(i=n;i>=1;i--)
1541	{
1542	if(m[i]!=0)
1543	{
1544	for(j=i-1;j>=1;j--)
1545	{
1546	if(m[j]!=0)
1547	{
1548	if(number(a[i])>number(a[j]))
1549	{
1550	a1=number(a[i]);
1551	a[i]=a[j];
1552	a[j]=a1;
1553	m1=m[i];
1554	m[i]=m[j];
1555	m[j]=m1;
1556	if(size(V)>0)
1557	{
1558	v=V[i];
1559	V[i]=V[j];
1560	V[j]=v;
1561	}
1562	}
1563	if(number(a[i])==number(a[j]))
1564	{
1565	m[i]=m[i]+m[j];
1566	m[j]=0;
1567	if(size(V)>0)
1568	{
1569	V[i]=V[i]+V[j];
1570	}
1571	}
1572	}
1573	}
1574	k++;
1575	a0[k]=a[i];
1576	m0[k]=m[i];
1577	if(size(V)>0)
1578	{
1579	V0[k]=V[i];
1580	}
1581	}
1582	}
1583
1584	if(size(V0)>0)
1585	{
1586	n=size(V0);
1587	module U=std(V0[n]);
1588	for(i=n-1;i>=1;i--)
1589	{
1590	V0[i]=simplify(reduce(V0[i],U),1);
1591	if(i>=2)
1592	{
1593	U=std(U+V0[i]);
1594	}
1595	}
1596	}
1597
1598	if(k>0)
1599	{
1600	sp=a0,m0;
1601	if(size(V0)>0)
1602	{
1603	sp[3]=V0;
1604	}
1605	}
1606	return(sp);
1607	}
1608	example
1609	{ "EXAMPLE:"; echo=2;
1610	ring R=0,(x,y),ds;
1611	list sp=list(ideal(-1/2,-3/10,-3/10,-1/10,-1/10,0,1/10,1/10,3/10,3/10,1/2));
1612	spprint(spnf(sp));
1613	}
1614	///////////////////////////////////////////////////////////////////////////////
1615
1616	proc spprint(list sp)
1617	"USAGE: spprint(sp); list sp (helper routine for spnf)
1618	RETURN: string s; spectrum sp
1619	EXAMPLE: example spprint; shows examples
1620	SEE ALSO: gmssing_lib, spnf
1621	"
1622	{
1623	string s;
1624	for(int i=1;i<size(sp[2]);i++)
1625	{
1626	s=s+"("+string(sp[1][i])+","+string(sp[2][i])+"),";
1627	}
1628	s=s+"("+string(sp[1][i])+","+string(sp[2][i])+")";
1629	return(s);
1630	}
1631	example
1632	{ "EXAMPLE:"; echo=2;
1633	ring R=0,(x,y),ds;
1634	list sp=list(ideal(-1/2,-3/10,-1/10,0,1/10,3/10,1/2),intvec(1,2,2,1,2,2,1));
1635	spprint(sp);
1636	}
1637	///////////////////////////////////////////////////////////////////////////////
1638
1639	proc jordan(matrix M,list #)
1640	"USAGE: jordan(M); matrix M
1641	ASSUME: eigenvalues of M in basefield
1642	RETURN:
1643	@format
1644	list l; Jordan data of M
1645	ideal l[1];
1646	number l[1][i]; eigenvalue of i-th Jordan block of M
1647	intvec l[2];
1648	int l[2][i]; size of i-th Jordan block of M
1649	intvec l[3];
1650	int l[3][i]; multiplicity of i-th Jordan block of M
1651	@end format
1652	EXAMPLE: example jordan; shows examples
1653	"
1654	{
1655	if(nrows(M)==0)
1656	{
1657	ERROR("non empty expected");
1658	}
1659	if(ncols(M)!=nrows(M))
1660	{
1661	ERROR("square matrix expected");
1662	}
1663
1664	M=jet(M,0);
1665
1666	if(size(#)==0)
1667	{
1668	#=eigenvals(M);
1669	}
1670	def e0,m0=#[1..2];
1671
1672	int i;
1673	for(i=1;i<=ncols(e0);i++)
1674	{
1675	if(deg(e0[i])>0)
1676	{
1677
1678	ERROR("eigenvalues in coefficient field expected");
1679	return(list());
1680	}
1681	}
1682
1683	int j,k;
1684	matrix N0,N1;
1685	module K0;
1686	list K;
1687	ideal e;
1688	intvec s,m;
1689
1690	for(i=1;i<=ncols(e0);i++)
1691	{
1692	N0=M-e0[i]*matrix(freemodule(ncols(M)));
1693
1694	N1=N0;
1695	K0=0;
1696	K=module();
1697	while(size(K0)<m0[i])
1698	{
1699	K0=syz(N1);
1700	K=K+list(K0);
1701	N1=N1*N0;
1702	}
1703
1704	for(j=2;j<size(K);j++)
1705	{
1706	if(2*size(K[j])-size(K[j-1])-size(K[j+1])>0)
1707	{
1708	k++;
1709	e[k]=e0[i];
1710	s[k]=j-1;
1711	m[k]=2*size(K[j])-size(K[j-1])-size(K[j+1]);
1712	}
1713	}
1714	if(size(K[j])-size(K[j-1])>0)
1715	{
1716	k++;
1717	e[k]=e0[i];
1718	s[k]=j-1;
1719	m[k]=size(K[j])-size(K[j-1]);
1720	}
1721	}
1722
1723	return(list(e,s,m));
1724	}
1725	example
1726	{ "EXAMPLE:"; echo=2;
1727	ring R=0,x,dp;
1728	matrix M[3][3]=3,2,1,0,2,1,0,0,3;
1729	print(M);
1730	jordan(M);
1731	}
1732	///////////////////////////////////////////////////////////////////////////////
1733
1734	proc jordanbasis(matrix M,list #)
1735	"USAGE: jordanbasis(M); matrix M
1736	ASSUME: eigenvalues of M in basefield
1737	RETURN:
1738	@format
1739	list l:
1740	module l[1]; inverse(l[1])Ml[1] in Jordan normal form
1741	intvec l[2];
1742	int l[2][i]; weight filtration index of l[1][i]
1743	@end format
1744	EXAMPLE: example jordanbasis; shows examples
1745	"
1746	{
1747	if(nrows(M)==0)
1748	{
1749	ERROR("non empty matrix expected");
1750	}
1751	if(ncols(M)!=nrows(M))
1752	{
1753	ERROR("square matrix expected");
1754	}
1755
1756	M=jet(M,0);
1757
1758	if(size(#)==0)
1759	{
1760	#=eigenvals(M);
1761	}
1762	def e,m=#[1..2];
1763
1764	for(int i=1;i<=ncols(e);i++)
1765	{
1766	if(deg(e[i])>0)
1767	{
1768	ERROR("eigenvalues in coefficient field expected");
1769	return(freemodule(ncols(M)));
1770	}
1771	}
1772
1773	int j,k,l,n;
1774	matrix N0,N1;
1775	module K0,K1;
1776	list K;
1777	matrix u[ncols(M)][1];
1778	module U;
1779	intvec w;
1780
1781	for(i=1;i<=ncols(e);i++)
1782	{
1783	N0=M-e[i]*matrix(freemodule(ncols(M)));
1784
1785	N1=N0;
1786	K0=0;
1787	K=list();
1788	while(size(K0)<m[i])
1789	{
1790	K0=syz(N1);
1791	K=K+list(K0);
1792	N1=N1*N0;
1793	}
1794
1795	K1=0;
1796	for(j=1;j<size(K);j++)
1797	{
1798	K0=K[j];
1799	K[j]=interred(reduce(K[j],std(K1+module(N0*K[j+1]))));
1800	K1=K0;
1801	}
1802	K[j]=interred(reduce(K[j],std(K1)));
1803
1804	for(l=size(K);l>=1;l--)
1805	{
1806	for(k=size(K[l]);k>0;k--)
1807	{
1808	u=K[l][k];
1809	for(j=l;j>=1;j--)
1810	{
1811	U=U+module(u);
1812	n++;
1813	w[n]=2*j-l-1;
1814	u=N0*u;
1815	}
1816	}
1817	}
1818	}
1819
1820	return(list(U,w));
1821	}
1822	example
1823	{ "EXAMPLE:"; echo=2;
1824	ring R=0,x,dp;
1825	matrix M[3][3]=3,2,1,0,2,1,0,0,3;
1826	print(M);
1827	list l=jordanbasis(M);
1828	print(l[1]);
1829	print(l[2]);
1830	print(inverse(l[1])Ml[1]);
1831	}
1832	///////////////////////////////////////////////////////////////////////////////
1833
1834	proc jordanmatrix(list jd)
1835	"USAGE: jordanmatrix(list(e,s,m)); ideal e, intvec s, intvec m
1836	ASSUME: ncols(e)==size(s)==size(m)
1837	RETURN:
1838	@format
1839	matrix J; Jordan matrix with list(e,s,m)==jordan(J)
1840	@end format
1841	EXAMPLE: example jordanmatrix; shows examples
1842	"
1843	{
1844	ideal e=jd[1];
1845	intvec s=jd[2];
1846	intvec m=jd[3];
1847	if(ncols(e)!=size(s)\|\|ncols(e)!=size(m))
1848	{
1849	ERROR("arguments of equal size expected");
1850	}
1851
1852	int i,j,k,l;
1853	int n=int((transpose(matrix(s))*matrix(m))[1,1]);
1854	matrix J[n][n];
1855	for(k=1;k<=ncols(e);k++)
1856	{
1857	for(l=1;l<=m[k];l++)
1858	{
1859	j++;
1860	J[j,j]=e[k];
1861	for(i=s[k];i>=2;i--)
1862	{
1863	J[j+1,j]=1;
1864	j++;
1865	J[j,j]=e[k];
1866	}
1867	}
1868	}
1869
1870	return(J);
1871	}
1872	example
1873	{ "EXAMPLE:"; echo=2;
1874	ring R=0,x,dp;
1875	ideal e=ideal(2,3);
1876	intvec s=1,2;
1877	intvec m=1,1;
1878	print(jordanmatrix(list(e,s,m)));
1879	}
1880	///////////////////////////////////////////////////////////////////////////////
1881
1882	proc jordannf(matrix M,list #)
1883	"USAGE: jordannf(M); matrix M
1884	ASSUME: eigenvalues of M in basefield
1885	RETURN: matrix J; Jordan normal form of M
1886	EXAMPLE: example jordannf; shows examples
1887	"
1888	{
1889	return(jordanmatrix(jordan(M,#)));
1890	}
1891	example
1892	{ "EXAMPLE:"; echo=2;
1893	ring R=0,x,dp;
1894	matrix M[3][3]=3,2,1,0,2,1,0,0,3;
1895	print(M);
1896	print(jordannf(M));
1897	}
1898
1899	///////////////////////////////////////////////////////////////////////////////
1900
1901	/*
1902	///////////////////////////////////////////////////////////////////////////////
1903	// Auskommentierte zusaetzliche Beispiele
1904	//
1905	///////////////////////////////////////////////////////////////////////////////
1906	// Singular for ix86-Linux version 1-3-10 (2000121517) Dec 15 2000 17:55:12
1907	// Rechnungen auf AMD700 mit 632 MB
1908
1909	LIB "linalg.lib";
1910
1911	1. Sparse integer Matrizen
1912	--------------------------
1913	ring r1=0,(x),dp;
1914	system("--random", 12345678);
1915	int n = 70;
1916	matrix m = sparsemat(n,n,50,100);
1917	option(prot,mem);
1918
1919	int t=timer;
1920	matrix im = inverse(m,1)[1];
1921	timer-t;
1922	print(im*m);
1923	//list l0 = watchdog(100,"inverse("+"m"+",3)");
1924	//bricht bei 100 sec ab und gibt l0[1]: string Killed zurueck
1925
1926	//inverse(m,1): std 5sec 5,5 MB
1927	//inverse(m,2): interred 12sec
1928	//inverse(m,2): lift nach 180 sec 13MB abgebrochen
1929	//n=60: linalgorig: 3 linalg: 5
1930	//n=70: linalgorig: 6,7 linalg: 11,12
1931	// aber linalgorig rechnet falsch!
1932
1933	2. Sparse poly Matrizen
1934	-----------------------
1935	ring r=(0),(a,b,c),dp;
1936	system("--random", 12345678);
1937	int n=6;
1938	matrix m = sparsematrix(n,n,2,0,50,50,9); //matrix of polys of deg <=2
1939	option(prot,mem);
1940
1941	int t=timer;
1942	matrix im = inverse(m);
1943	timer-t;
1944	print(im*m);
1945	//inverse(m,1): std 0sec 1MB
1946	//inverse(m,2): interred 0sec 1MB
1947	//inverse(m,2): lift nach 2000 sec 33MB abgebrochen
1948
1949	3. Sparse Matrizen mit Parametern
1950	---------------------------------
1951	//liborig rechnet hier falsch!
1952	ring r=(0),(a,b),dp;
1953	system("--random", 12345678);
1954	int n=7;
1955	matrix m = sparsematrix(n,n,1,0,40,50,9);
1956	ring r1 = (0,a,b),(x),dp;
1957	matrix m = imap(r,m);
1958	option(prot,mem);
1959
1960	int t=timer;
1961	matrix im = inverse(m);
1962	timer-t;
1963	print(im*m);
1964	//inverse(m)=inverse(m,3):15 sec inverse(m,1)=1sec inverse(m,2):>120sec
1965	//Bei Parametern vergeht die Zeit beim Normieren!
1966
1967	3. Sparse Matrizen mit Variablen und Parametern
1968	-----------------------------------------------
1969	ring r=(0),(a,b),dp;
1970	system("--random", 12345678);
1971	int n=6;
1972	matrix m = sparsematrix(n,n,1,0,35,50,9);
1973	ring r1 = (0,a),(b),dp;
1974	matrix m = imap(r,m);
1975	option(prot,mem);
1976
1977	int t=timer;
1978	matrix im = inverse(m,3);
1979	timer-t;
1980	print(im*m);
1981	//n=7: inverse(m,3):lange sec inverse(m,1)=1sec inverse(m,2):1sec
1982
1983	4. Ueber Polynomring invertierbare Matrizen
1984	-------------------------------------------
1985	LIB"random.lib"; LIB"linalg.lib";
1986	system("--random", 12345678);
1987	int n =3;
1988	ring r= 0,(x,y,z),(C,dp);
1989	matrix A=triagmatrix(n,n,1,0,0,50,2);
1990	intmat B=sparsetriag(n,n,20,1);
1991	matrix M = A*transpose(B);
1992	M=M*transpose(M);
1993	M[1,1..ncols(M)]=M[1,1..n]+xyz*M[n,1..ncols(M)];
1994	print(M);
1995	//M hat det=1 nach Konstruktion
1996
1997	int t=timer;
1998	matrix iM=inverse(M);
1999	timer-t;
2000	print(iM*M); //test
2001
2002	//ACHTUNG: Interred liefert i.A. keine Inverse, Gegenbeispiel z.B.
2003	//mit n=3
2004	//eifacheres Gegenbeispiel:
2005	matrix M =
2006	9yz+3y+3z+2, 9y2+6y+1,
2007	9xyz+3xy+3xz-9z2+2x-6z-1,9xy2+6xy-9yz+x-3y-3z
2008	//det M=1, inverse(M,2); ->// ** matrix is not invertible
2009	//lead(M); 9xyzgen(2) 9xy2gen(2) nicht teilbar!
2010
2011	5. charpoly:
2012	-----------
2013	//ring rp=(0,A,B,C),(x),dp;
2014	ring r=0,(A,B,C,x),dp;
2015	matrix m[12][12]=
2016	AC,BC,-3BC,0,-A2+B2,-3AC+1,B2, B2, 1, 0, -C2+1,0,
2017	1, 1, 2C, 0,0, B, -A, -4C, 2A+1,0, 0, 0,
2018	0, 0, 0, 1,0, 2C+1, -4C+1,-A, B+1, 0, B+1, 3B,
2019	AB,B2,0, 1,0, 1, 0, 1, A, 0, 1, B+1,
2020	1, 0, 1, 0,0, 1, 0, -C2, 0, 1, 0, 1,
2021	0, 0, 2, 1,2A, 1, 0, 0, 0, 0, 1, 1,
2022	0, 1, 0, 1,1, 2, A, 3B+1,1, B2,1, 1,
2023	0, 1, 0, 1,1, 1, 1, 1, 2, 0, 0, 0,
2024	1, 0, 1, 0,0, 0, 1, 0, 1, 1, 0, 3,
2025	1, 3B,B2+1,0,0, 1, 0, 1, 0, 0, 1, 0,
2026	0, 0, 1, 0,0, 0, 0, 1, 0, 0, 0, 0,
2027	0, 1, 0, 1,1, 3, 3B+1, 0, 1, 1, 1, 0;
2028	option(prot,mem);
2029
2030	int t=timer;
2031	poly q=charpoly(m,"x"); //1sec, charpoly_B 1sec, 16MB
2032	timer-t;
2033	//1sec, charpoly_B 1sec, 16MB (gleich in r und rp)
2034
2035	*/

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