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Up to [local] / OpenXM_contrib2 / asir2000 / lib

Imported asir2000 as OpenXM_contrib2/asir2000.

/* $OpenXM: OpenXM_contrib2/asir2000/lib/solve,v 1.1.1.1 1999/12/03 07:39:11 noro Exp $ */
def kenzan(El,Sl)
{
	for ( Tl = El; Tl != []; Tl = cdr(Tl) ) {
		if ( substv(car(Tl),Sl) ) {
			print("kenzan : error");
			return 0;
		}
	}
	print("kenzan : ok");
	return 1;
}

def substv(P,Sl)
{
	for ( A = P; Sl != []; Sl = cdr(Sl) ) 
		A = subst(A,car(car(Sl)),car(cdr(car(Sl))));
	return A;
}
			
def co(X,V,D)
{
	for ( I = 0; I < D; I++ )
		X = diff(X,V);
	return sdiv(subst(X,V,0),fac(D));
}

def solve(El,Vl)
/*
 * El : list of linear forms
 * Vl : list of variable
 */
{
	N = length(El); M = length(Vl);
	Mat = newmat(N,M+1); 
	W = newvect(M+1); Index = newvect(N); Vs = newvect(M);
	for ( I = 0, Tl = Vl; I < M; Tl = cdr(Tl), I++ )
		Vs[I] = car(Tl);
	for ( I = 0, Tl = El; I < N; Tl = cdr(Tl), I++ ) {
		ltov(car(Tl),Vl,W);
		for ( J = 0; J <= M; J++ )
			Mat[I][J] = W[J];
	}
	Tl = solvemain(Mat,Index,N,M); L = car(Tl); D = car(cdr(Tl));
	if ( L < 0 )
		return [];
	for ( I = L - 1, S = []; I >= 0; I-- ) {
		for ( J = Index[I]+1, A = 0; J < M; J++ ) {
			A += Mat[I][J]*Vs[J];
		}
		S = cons([Vs[Index[I]],-red((A+Mat[I][M])/D)],S);
	}
	if ( kenzan(El,S) )
		return S;
	else
		return [];
	return S;
}

def solvemain(Mat,Index,N,M) 
/* 
 *	Mat : matrix of size Nx(M+1)
 *	Index : vector of length N
 */
{
	for ( J = 0, L = 0, D = 1; J < M; J++ ) {
		for ( I = L; I < N && !Mat[I][J]; I++ );
		if ( I == N )
			continue;
		Index[L] = J;
		for ( K = 0; K <= M; K++ ) {
			T = Mat[I][K]; Mat[I][K] = Mat[L][K]; Mat[L][K] = T;
		}
		for ( I = L + 1, V = Mat[L][J]; I < N; I++ )
			for ( K = J, U = Mat[I][J]; K <= M; K++ )
				Mat[I][K] = sdiv(Mat[I][K]*V-Mat[L][K]*U,D);
		D = V; L++;
	}
	for ( I = L; I < N; I++ )
		for ( J = 0; J <= M; J++ )
			if ( Mat[I][J] )
				return -1;
	for ( I = L - 2, W = newvect(M+1); I >= 0; I-- ) {
		for ( J = 0; J <= M; J++ )
			W[J] = 0;
		for ( G = I + 1; G < L; G++ )
			for ( H = Index[G], U = Mat[I][H]; H <= M; H++ )
				W[H] += Mat[G][H]*U;
		for ( J = Index[I], U = Mat[I][J]; J <= M; J++ )
			Mat[I][J] = sdiv(Mat[I][J]*D-W[J],U);
	}
	return [L,D];
}

def length(L)
{
	for ( I = 0; L != []; L = cdr(L), I++ );
	return I;
}

def ltov(P,VL,W)
{
	for ( I = 0, L = VL; L != []; L = cdr(L), I++ ) {
		W[I] = co(P,car(L),1); P -= W[I]*car(L);
	}
	W[I] = P;
}
end$