| version 1.19, 2002/01/29 02:03:41 |
version 1.20, 2002/01/29 05:37:12 |
|
|
| * 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 1.18 2002/01/28 02:42:27 noro Exp $ |
* $OpenXM: OpenXM_contrib2/asir2000/lib/bfct,v 1.19 2002/01/29 02:03:41 noro Exp $ |
| */ |
*/ |
| /* requires 'primdec' */ |
/* requires 'primdec' */ |
| |
|
| Line 249 def generic_bfct(F,V,DV,W) |
|
| Line 249 def generic_bfct(F,V,DV,W) |
|
| FH = map(dp_dtop,map(dp_homo,map(dp_ptod,F,VDV)),VDVH); |
FH = map(dp_dtop,map(dp_homo,map(dp_ptod,F,VDV)),VDVH); |
| |
|
| /* compute a groebner basis of FH w.r.t. MWH */ |
/* compute a groebner basis of FH w.r.t. MWH */ |
| dp_gr_flags(["Top",1,"NoRA",1]); |
dp_gr_flags(["Top",1]); |
| GH = dp_weyl_gr_main(FH,VDVH,0,1,11); |
GH = dp_weyl_gr_main(FH,VDVH,0,1,11); |
| dp_gr_flags(["Top",0,"NoRA",0]); |
dp_gr_flags(["Top",0]); |
| |
|
| /* dehomigenize GH */ |
/* dehomigenize GH */ |
| G = map(subst,GH,h,1); |
G = map(subst,GH,h,1); |
| Line 572 def bfct_via_gbfct_weight_2(F,V) |
|
| Line 572 def bfct_via_gbfct_weight_2(F,V) |
|
| /* change of ordering from VDV to VDV2 */ |
/* change of ordering from VDV to VDV2 */ |
| VDV2 = append(V2,DV2); |
VDV2 = append(V2,DV2); |
| dp_set_weight(WtV2); |
dp_set_weight(WtV2); |
| GIN2 = dp_weyl_gr_main(GIN,VDV2,0,-1,0); |
for ( Pind = 0; ; Pind++ ) { |
| |
Prime = lprime(Pind); |
| |
GIN2 = dp_weyl_gr_main(GIN,VDV2,0,-Prime,0); |
| |
if ( GIN2 ) break; |
| |
} |
| |
|
| R = weyl_minipoly(GIN2,VDV2,0,T); /* M represents DRL order */ |
R = weyl_minipoly(GIN2,VDV2,0,T); /* M represents DRL order */ |
| dp_set_weight(0); |
dp_set_weight(0); |
| Line 632 def weyl_minipoly(G0,V0,O0,P) |
|
| Line 636 def weyl_minipoly(G0,V0,O0,P) |
|
| 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); |
| |
PSM = newvect(Len); |
| DP = dp_ptod(P,V0); |
DP = dp_ptod(P,V0); |
| |
|
| 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++ ) |
| |
PSM[I] = dp_mod(dp_ptod(car(T),V0),Prime,[]); |
| |
|
| NFP = weyl_nf(GI,DP,1,PS); |
NFP = weyl_nf(GI,DP,1,PS); |
| |
NFPM = dp_mod(NFP[0],Prime,[])/ptomp(NFP[1],Prime); |
| |
|
| NF = [[dp_ptod(1,V0),1]]; |
NF = [[dp_ptod(1,V0),1]]; |
| LCM = 1; |
LCM = 1; |
| |
|
| for ( J = 1; J <= D; J++ ) { |
TM = dp_mod(<<0>>,Prime,[]); |
| |
TTM = dp_mod(dp_ptod(1,V0),Prime,[]); |
| |
GM = NFM = [[TTM,TM]]; |
| |
|
| |
for ( D = 1; ; D++ ) { |
| if ( dp_gr_print() ) |
if ( dp_gr_print() ) |
| print(".",2); |
print(".",2); |
| NFPrev = car(NF); |
NFPrev = car(NF); |
| Line 654 def weyl_minipoly(G0,V0,O0,P) |
|
| Line 666 def weyl_minipoly(G0,V0,O0,P) |
|
| 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]); |
| |
|
| |
/* modular computation */ |
| |
TM = dp_mod(<<D>>,Prime,[]); |
| |
TTM = dp_mod(NFJ[0],Prime,[])/ptomp(NFJ[1],Prime); |
| |
NFM = cons([TTM,TM],NFM); |
| |
LM = dp_lnf_mod([TTM,TM],GM,Prime); |
| |
if ( !LM[0] ) |
| |
break; |
| |
else |
| |
GM = insert(GM,LM); |
| } |
} |
| |
|
| 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]); |
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