version 1.16, 2001/01/18 00:52:32 |
version 1.22, 2003/04/20 08:54:28 |
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* DEVELOPER SHALL HAVE NO LIABILITY IN CONNECTION WITH THE USE, |
* DEVELOPER SHALL HAVE NO LIABILITY IN CONNECTION WITH THE USE, |
* PERFORMANCE OR NON-PERFORMANCE OF THE SOFTWARE. |
* PERFORMANCE OR NON-PERFORMANCE OF THE SOFTWARE. |
* |
* |
* $OpenXM: OpenXM_contrib2/asir2000/lib/bfct,v 1.15 2001/01/11 08:43:23 noro Exp $ |
* $OpenXM: OpenXM_contrib2/asir2000/lib/bfct,v 1.21 2002/01/30 02:12:58 noro Exp $ |
*/ |
*/ |
/* requires 'primdec' */ |
/* requires 'primdec' */ |
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extern LIBRARY_GR_LOADED$ |
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extern LIBRARY_PRIMDEC_LOADED$ |
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if(!LIBRARY_GR_LOADED) load("gr"); else ; LIBRARY_GR_LOADED = 1$ |
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if(!LIBRARY_PRIMDEC_LOADED) load("primdec"); else ; LIBRARY_PRIMDEC_LOADED = 1$ |
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/* toplevel */ |
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def bfunction(F) |
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{ |
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V = vars(F); |
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N = length(V); |
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D = newvect(N); |
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for ( I = 0; I < N; I++ ) |
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D[I] = [deg(F,V[I]),V[I]]; |
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qsort(D,compare_first); |
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for ( V = [], I = 0; I < N; I++ ) |
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V = cons(D[I][1],V); |
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return bfct_via_gbfct_weight(F,V); |
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} |
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/* annihilating ideal of F^s */ |
/* annihilating ideal of F^s */ |
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def ann(F) |
def ann(F) |
Line 270 def generic_bfct(F,V,DV,W) |
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Line 292 def generic_bfct(F,V,DV,W) |
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return B; |
return B; |
} |
} |
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/* all term reduction + interreduce */ |
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def generic_bfct_1(F,V,DV,W) |
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{ |
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N = length(V); |
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N2 = N*2; |
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/* If W is a list, convert it to a vector */ |
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if ( type(W) == 4 ) |
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W = newvect(length(W),W); |
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dp_weyl_set_weight(W); |
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/* create a term order M in D<x,d> (DRL) */ |
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M = newmat(N2,N2); |
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for ( J = 0; J < N2; J++ ) |
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M[0][J] = 1; |
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for ( I = 1; I < N2; I++ ) |
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M[I][N2-I] = -1; |
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VDV = append(V,DV); |
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/* create a non-term order MW in D<x,d> */ |
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MW = newmat(N2+1,N2); |
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for ( J = 0; J < N; J++ ) |
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MW[0][J] = -W[J]; |
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for ( ; J < N2; J++ ) |
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MW[0][J] = W[J-N]; |
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for ( I = 1; I <= N2; I++ ) |
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for ( J = 0; J < N2; J++ ) |
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MW[I][J] = M[I-1][J]; |
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/* create a homogenized term order MWH in D<x,d,h> */ |
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MWH = newmat(N2+2,N2+1); |
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for ( J = 0; J <= N2; J++ ) |
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MWH[0][J] = 1; |
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for ( I = 1; I <= N2+1; I++ ) |
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for ( J = 0; J < N2; J++ ) |
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MWH[I][J] = MW[I-1][J]; |
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/* homogenize F */ |
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VDVH = append(VDV,[h]); |
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FH = map(dp_dtop,map(dp_homo,map(dp_ptod,F,VDV)),VDVH); |
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/* compute a groebner basis of FH w.r.t. MWH */ |
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/* dp_gr_flags(["Top",1,"NoRA",1]); */ |
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GH = dp_weyl_gr_main(FH,VDVH,0,1,11); |
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/* dp_gr_flags(["Top",0,"NoRA",0]); */ |
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/* dehomigenize GH */ |
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G = map(subst,GH,h,1); |
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/* G is a groebner basis w.r.t. a non term order MW */ |
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/* take the initial part w.r.t. (-W,W) */ |
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GIN = map(initial_part,G,VDV,MW,W); |
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/* GIN is a groebner basis w.r.t. a term order M */ |
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/* As -W+W=0, gr_(-W,W)(D<x,d>) = D<x,d> */ |
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/* find b(W1*x1*d1+...+WN*xN*dN) in Id(GIN) */ |
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for ( I = 0, T = 0; I < N; I++ ) |
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T += W[I]*V[I]*DV[I]; |
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B = weyl_minipoly(GIN,VDV,0,T); /* M represents DRL order */ |
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return B; |
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} |
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def initial_part(F,V,MW,W) |
def initial_part(F,V,MW,W) |
{ |
{ |
N2 = length(V); |
N2 = length(V); |
Line 351 def bfct_via_gbfct(F) |
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Line 437 def bfct_via_gbfct(F) |
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return subst(R,s,-s-1); |
return subst(R,s,-s-1); |
} |
} |
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/* use an order s.t. [t,x,y,z,...,dt,dx,dy,dz,...,h] */ |
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def bfct_via_gbfct_weight(F,V) |
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{ |
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N = length(V); |
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D = newvect(N); |
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Wt = getopt(weight); |
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if ( type(Wt) != 4 ) { |
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for ( I = 0, Wt = []; I < N; I++ ) |
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Wt = cons(1,Wt); |
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} |
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Tdeg = w_tdeg(F,V,Wt); |
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WtV = newvect(2*(N+1)+1); |
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WtV[0] = Tdeg; |
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WtV[N+1] = 1; |
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/* wdeg(V[I])=Wt[I], wdeg(DV[I])=Tdeg-Wt[I]+1 */ |
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for ( I = 1; I <= N; I++ ) { |
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WtV[I] = Wt[I-1]; |
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WtV[N+1+I] = Tdeg-Wt[I-1]+1; |
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} |
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WtV[2*(N+1)] = 1; |
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dp_set_weight(WtV); |
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for ( I = N-1, DV = []; I >= 0; I-- ) |
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DV = cons(strtov("d"+rtostr(V[I])),DV); |
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B = [t-F]; |
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for ( I = 0; I < N; I++ ) { |
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B = cons(DV[I]+diff(F,V[I])*dt,B); |
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} |
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V1 = cons(t,V); DV1 = cons(dt,DV); |
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W = newvect(N+1); |
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W[0] = 1; |
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R = generic_bfct_1(B,V1,DV1,W); |
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dp_set_weight(0); |
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return subst(R,s,-s-1); |
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} |
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/* use an order s.t. [x,y,z,...,t,dx,dy,dz,...,dt,h] */ |
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def bfct_via_gbfct_weight_1(F,V) |
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{ |
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N = length(V); |
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D = newvect(N); |
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Wt = getopt(weight); |
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if ( type(Wt) != 4 ) { |
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for ( I = 0, Wt = []; I < N; I++ ) |
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Wt = cons(1,Wt); |
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} |
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Tdeg = w_tdeg(F,V,Wt); |
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WtV = newvect(2*(N+1)+1); |
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/* wdeg(V[I])=Wt[I], wdeg(DV[I])=Tdeg-Wt[I]+1 */ |
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for ( I = 0; I < N; I++ ) { |
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WtV[I] = Wt[I]; |
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WtV[N+1+I] = Tdeg-Wt[I]+1; |
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} |
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WtV[N] = Tdeg; |
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WtV[2*N+1] = 1; |
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WtV[2*(N+1)] = 1; |
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dp_set_weight(WtV); |
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for ( I = N-1, DV = []; I >= 0; I-- ) |
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DV = cons(strtov("d"+rtostr(V[I])),DV); |
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B = [t-F]; |
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for ( I = 0; I < N; I++ ) { |
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B = cons(DV[I]+diff(F,V[I])*dt,B); |
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} |
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V1 = append(V,[t]); DV1 = append(DV,[dt]); |
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W = newvect(N+1); |
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W[N] = 1; |
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R = generic_bfct_1(B,V1,DV1,W); |
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dp_set_weight(0); |
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return subst(R,s,-s-1); |
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} |
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def bfct_via_gbfct_weight_2(F,V) |
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{ |
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N = length(V); |
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D = newvect(N); |
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Wt = getopt(weight); |
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if ( type(Wt) != 4 ) { |
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for ( I = 0, Wt = []; I < N; I++ ) |
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Wt = cons(1,Wt); |
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} |
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Tdeg = w_tdeg(F,V,Wt); |
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/* a weight for the first GB computation */ |
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/* [t,x1,...,xn,dt,dx1,...,dxn,h] */ |
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WtV = newvect(2*(N+1)+1); |
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WtV[0] = Tdeg; |
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WtV[N+1] = 1; |
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WtV[2*(N+1)] = 1; |
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/* wdeg(V[I])=Wt[I], wdeg(DV[I])=Tdeg-Wt[I]+1 */ |
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for ( I = 1; I <= N; I++ ) { |
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WtV[I] = Wt[I-1]; |
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WtV[N+1+I] = Tdeg-Wt[I-1]+1; |
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} |
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dp_set_weight(WtV); |
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/* a weight for the second GB computation */ |
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/* [x1,...,xn,t,dx1,...,dxn,dt,h] */ |
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WtV2 = newvect(2*(N+1)+1); |
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WtV2[N] = Tdeg; |
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WtV2[2*N+1] = 1; |
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WtV2[2*(N+1)] = 1; |
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for ( I = 0; I < N; I++ ) { |
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WtV2[I] = Wt[I]; |
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WtV2[N+1+I] = Tdeg-Wt[I]+1; |
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} |
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for ( I = N-1, DV = []; I >= 0; I-- ) |
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DV = cons(strtov("d"+rtostr(V[I])),DV); |
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B = [t-F]; |
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for ( I = 0; I < N; I++ ) { |
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B = cons(DV[I]+diff(F,V[I])*dt,B); |
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} |
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V1 = cons(t,V); DV1 = cons(dt,DV); |
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V2 = append(V,[t]); DV2 = append(DV,[dt]); |
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W = newvect(N+1,[1]); |
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dp_weyl_set_weight(W); |
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VDV = append(V1,DV1); |
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N1 = length(V1); |
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N2 = N1*2; |
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/* create a non-term order MW in D<x,d> */ |
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MW = newmat(N2+1,N2); |
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for ( J = 0; J < N1; J++ ) { |
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MW[0][J] = -W[J]; MW[0][N1+J] = W[J]; |
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} |
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for ( J = 0; J < N2; J++ ) MW[1][J] = 1; |
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for ( I = 2; I <= N2; I++ ) MW[I][N2-I+1] = -1; |
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/* homogenize F */ |
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VDVH = append(VDV,[h]); |
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FH = map(dp_dtop,map(dp_homo,map(dp_ptod,B,VDV)),VDVH); |
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/* compute a groebner basis of FH w.r.t. MWH */ |
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GH = dp_weyl_gr_main(FH,VDVH,0,1,11); |
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/* dehomigenize GH */ |
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G = map(subst,GH,h,1); |
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/* G is a groebner basis w.r.t. a non term order MW */ |
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/* take the initial part w.r.t. (-W,W) */ |
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GIN = map(initial_part,G,VDV,MW,W); |
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/* GIN is a groebner basis w.r.t. a term order M */ |
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/* As -W+W=0, gr_(-W,W)(D<x,d>) = D<x,d> */ |
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/* find b(W1*x1*d1+...+WN*xN*dN) in Id(GIN) */ |
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for ( I = 0, T = 0; I < N1; I++ ) |
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T += W[I]*V1[I]*DV1[I]; |
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/* change of ordering from VDV to VDV2 */ |
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VDV2 = append(V2,DV2); |
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dp_set_weight(WtV2); |
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for ( Pind = 0; ; Pind++ ) { |
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Prime = lprime(Pind); |
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GIN2 = dp_weyl_gr_main(GIN,VDV2,0,-Prime,0); |
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if ( GIN2 ) break; |
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} |
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R = weyl_minipoly(GIN2,VDV2,0,T); /* M represents DRL order */ |
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dp_set_weight(0); |
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return subst(R,s,-s-1); |
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} |
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def weyl_minipolym(G,V,O,M,V0) |
def weyl_minipolym(G,V,O,M,V0) |
{ |
{ |
N = length(V); |
N = length(V); |
Line 369 def weyl_minipolym(G,V,O,M,V0) |
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Line 623 def weyl_minipolym(G,V,O,M,V0) |
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GI = cons(I,GI); |
GI = cons(I,GI); |
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U = dp_mod(dp_ptod(V0,V),M,[]); |
U = dp_mod(dp_ptod(V0,V),M,[]); |
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U = dp_weyl_nf_mod(GI,U,PS,1,M); |
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T = dp_mod(<<0>>,M,[]); |
T = dp_mod(<<0>>,M,[]); |
TT = dp_mod(dp_ptod(1,V),M,[]); |
TT = dp_mod(dp_ptod(1,V),M,[]); |
Line 403 def weyl_minipoly(G0,V0,O0,P) |
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Line 658 def weyl_minipoly(G0,V0,O0,P) |
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PS[I] = dp_ptod(car(T),V0); |
PS[I] = dp_ptod(car(T),V0); |
for ( I = Len - 1, GI = []; I >= 0; I-- ) |
for ( I = Len - 1, GI = []; I >= 0; I-- ) |
GI = cons(I,GI); |
GI = cons(I,GI); |
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PSM = newvect(Len); |
DP = dp_ptod(P,V0); |
DP = dp_ptod(P,V0); |
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for ( I = 0; ; I++ ) { |
for ( Pind = 0; ; Pind++ ) { |
Prime = lprime(I); |
Prime = lprime(Pind); |
if ( !valid_modulus(HM,Prime) ) |
if ( !valid_modulus(HM,Prime) ) |
continue; |
continue; |
MP = weyl_minipolym(G0,V0,O0,Prime,P); |
setmod(Prime); |
D = deg(MP,var(MP)); |
for ( I = 0, T = G0, HL = []; T != []; T = cdr(T), I++ ) |
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PSM[I] = dp_mod(dp_ptod(car(T),V0),Prime,[]); |
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NFP = weyl_nf(GI,DP,1,PS); |
NFP = weyl_nf(GI,DP,1,PS); |
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NFPM = dp_mod(NFP[0],Prime,[])/ptomp(NFP[1],Prime); |
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NF = [[dp_ptod(1,V0),1]]; |
NF = [[dp_ptod(1,V0),1]]; |
LCM = 1; |
LCM = 1; |
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for ( J = 1; J <= D; J++ ) { |
TM = dp_mod(<<0>>,Prime,[]); |
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TTM = dp_mod(dp_ptod(1,V0),Prime,[]); |
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GM = NFM = [[TTM,TM]]; |
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for ( D = 1; ; D++ ) { |
if ( dp_gr_print() ) |
if ( dp_gr_print() ) |
print(".",2); |
print(".",2); |
NFPrev = car(NF); |
NFPrev = car(NF); |
Line 425 def weyl_minipoly(G0,V0,O0,P) |
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Line 688 def weyl_minipoly(G0,V0,O0,P) |
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NFJ = remove_cont(NFJ); |
NFJ = remove_cont(NFJ); |
NF = cons(NFJ,NF); |
NF = cons(NFJ,NF); |
LCM = ilcm(LCM,NFJ[1]); |
LCM = ilcm(LCM,NFJ[1]); |
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/* modular computation */ |
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TM = dp_mod(<<D>>,Prime,[]); |
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TTM = dp_mod(NFJ[0],Prime,[])/ptomp(NFJ[1],Prime); |
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NFM = cons([TTM,TM],NFM); |
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LM = dp_lnf_mod([TTM,TM],GM,Prime); |
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if ( !LM[0] ) |
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break; |
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else |
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GM = insert(GM,LM); |
} |
} |
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if ( dp_gr_print() ) |
if ( dp_gr_print() ) |
print(""); |
print(""); |
U = NF[0][0]*idiv(LCM,NF[0][1]); |
U = NF[0][0]*idiv(LCM,NF[0][1]); |
Line 548 def v_factorial(V,N) |
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Line 822 def v_factorial(V,N) |
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{ |
{ |
for ( J = N-1, R = 1; J >= 0; J-- ) |
for ( J = N-1, R = 1; J >= 0; J-- ) |
R *= V-J; |
R *= V-J; |
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return R; |
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} |
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def w_tdeg(F,V,W) |
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{ |
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dp_set_weight(newvect(length(W),W)); |
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T = dp_ptod(F,V); |
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for ( R = 0; T; T = cdr(T) ) { |
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D = dp_td(T); |
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if ( D > R ) R = D; |
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} |
return R; |
return R; |
} |
} |
end$ |
end$ |