| version 1.8, 2010/06/09 08:28:57 |
version 1.12, 2014/09/05 11:55:19 |
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|
| |
/* $OpenXM: OpenXM/src/asir-contrib/testing/noro/pd.rr,v 1.11 2010/08/20 04:21:18 noro Exp $ */ |
| import("gr")$ |
import("gr")$ |
| module noro_pd$ |
module noro_pd$ |
| |
|
| static GBCheck,F4,Procs,SatHomo$ |
static GBCheck,F4,Procs,SatHomo$ |
| |
|
| localf init_procs, kill_procs, syca_dec, syc_dec, find_separating_ideal0$ |
localf init_procs, kill_procs, syca_dec, syc_dec, find_separating_ideal0$ |
|
|
| Ok = find_separating_ideal1(C,G,IntQ,IntP,V,Ord|mod=Mod); |
Ok = find_separating_ideal1(C,G,IntQ,IntP,V,Ord|mod=Mod); |
| else if ( SepIdeal == 2 ) |
else if ( SepIdeal == 2 ) |
| Ok = find_separating_ideal2(C,G,IntQ,IntP,V,Ord|mod=Mod); |
Ok = find_separating_ideal2(C,G,IntQ,IntP,V,Ord|mod=Mod); |
| else if ( SepIdeal == 3 ) |
|
| Ok = find_separating_ideal2(C,G,IntQ,IntP,V,Ord|mod=Mod,complete=1); |
|
| G1 = append(Ok,G); |
G1 = append(Ok,G); |
| Gt1 = incremental_gb(G1,V,Ord|mod=Mod); |
Gt1 = incremental_gb(G1,V,Ord|mod=Mod); |
| T1 = time(); Tsep += T1[0]-T0[0]+T1[1]-T0[1]; Rsep += T1[3]-T0[3]; |
T1 = time(); Tsep += T1[0]-T0[0]+T1[1]-T0[1]; Rsep += T1[3]-T0[3]; |
|
|
| Ok = find_separating_ideal1(C,Gt,IntQt,IntPt,V,Ord|mod=Mod); |
Ok = find_separating_ideal1(C,Gt,IntQt,IntPt,V,Ord|mod=Mod); |
| else if ( SepIdeal == 2 ) |
else if ( SepIdeal == 2 ) |
| Ok = find_separating_ideal2(C,Gt,IntQt,IntPt,V,Ord|mod=Mod); |
Ok = find_separating_ideal2(C,Gt,IntQt,IntPt,V,Ord|mod=Mod); |
| else if ( SepIdeal == 3 ) |
|
| Ok = find_separating_ideal2(C,Gt,IntQt,IntPt,V,Ord|mod=Mod,complete=1); |
|
| G1 = append(Ok,Gt); |
G1 = append(Ok,Gt); |
| Gt = incremental_gb(G1,V,Ord|mod=Mod); |
Gt = incremental_gb(G1,V,Ord|mod=Mod); |
| T1 = time(); Tsep += T1[0]-T0[0]+T1[1]-T0[1]; Rsep += T1[3]-T0[3]; |
T1 = time(); Tsep += T1[0]-T0[0]+T1[1]-T0[1]; Rsep += T1[3]-T0[3]; |
| Line 280 def find_separating_ideal1(C,G,Q,Rad,V,Ord) { |
|
| Line 276 def find_separating_ideal1(C,G,Q,Rad,V,Ord) { |
|
| /* check whether (Q cap (G+S)) = G */ |
/* check whether (Q cap (G+S)) = G */ |
| if ( gen_gb_comp(Int,G,Mod) ) return reverse(S); |
if ( gen_gb_comp(Int,G,Mod) ) return reverse(S); |
| |
|
| /* or qsort(C,comp_tdeg) */ |
/* or qsort(C,noro_pd.comp_tdeg) */ |
| C = qsort(S,comp_tdeg); |
C = qsort(S,noro_pd.comp_tdeg); |
| |
|
| Tmp = ttttt; TV = cons(Tmp,V); Ord1 = [[0,1],[Ord,length(V)]]; |
Tmp = ttttt; TV = cons(Tmp,V); Ord1 = [[0,1],[Ord,length(V)]]; |
| Int0 = incremental_gb(append(vtol(ltov(G)*Tmp),vtol(ltov(Q)*(1-Tmp))), |
Int0 = incremental_gb(append(vtol(ltov(G)*Tmp),vtol(ltov(Q)*(1-Tmp))), |
| Line 315 def find_separating_ideal1(C,G,Q,Rad,V,Ord) { |
|
| Line 311 def find_separating_ideal1(C,G,Q,Rad,V,Ord) { |
|
| |
|
| def find_separating_ideal2(C,G,Q,Rad,V,Ord) { |
def find_separating_ideal2(C,G,Q,Rad,V,Ord) { |
| if ( type(Mod=getopt(mod)) == -1 ) Mod = 0; |
if ( type(Mod=getopt(mod)) == -1 ) Mod = 0; |
| if ( type(Complete=getopt(complete)) == -1 ) Complete = 0; |
|
| for ( T = C, S = []; T != []; T = cdr(T) ) |
for ( T = C, S = []; T != []; T = cdr(T) ) |
| if ( gen_nf(car(T),Q,V,Ord,Mod) ) S = cons(car(T),S); |
if ( gen_nf(car(T),Q,V,Ord,Mod) ) S = cons(car(T),S); |
| if ( S == [] ) |
if ( S == [] ) |
| Line 325 def find_separating_ideal2(C,G,Q,Rad,V,Ord) { |
|
| Line 320 def find_separating_ideal2(C,G,Q,Rad,V,Ord) { |
|
| /* check whether (Q cap (G+S)) = G */ |
/* check whether (Q cap (G+S)) = G */ |
| if ( gen_gb_comp(Int,G,Mod) ) return reverse(S); |
if ( gen_gb_comp(Int,G,Mod) ) return reverse(S); |
| |
|
| /* or qsort(S,comp_tdeg) */ |
/* or qsort(S,noro_pd.comp_tdeg) */ |
| C = qsort(C,comp_tdeg); |
C = qsort(C,noro_pd.comp_tdeg); |
| Dp = dp_gr_print(); dp_gr_print(0); |
Dp = dp_gr_print(); dp_gr_print(0); |
| for ( T = C, S = []; T != []; T = cdr(T) ) { |
for ( T = C, S = []; T != []; T = cdr(T) ) { |
| if ( !gen_nf(car(T),Rad,V,Ord,Mod) ) continue; |
if ( !gen_nf(car(T),Rad,V,Ord,Mod) ) continue; |
| Line 343 def find_separating_ideal2(C,G,Q,Rad,V,Ord) { |
|
| Line 338 def find_separating_ideal2(C,G,Q,Rad,V,Ord) { |
|
| S = cons(Ui,S); |
S = cons(Ui,S); |
| } |
} |
| print(""); |
print(""); |
| #if 1 |
S = qsort(S,noro_pd.comp_tdeg); |
| S = qsort(S,comp_tdeg); |
|
| #else |
|
| S = reverse(S); |
|
| #endif |
|
| End = Len = length(S); |
End = Len = length(S); |
| |
|
| Tmp = ttttt; TV = cons(Tmp,V); Ord1 = [[0,1],[Ord,length(V)]]; |
Tmp = ttttt; TV = cons(Tmp,V); Ord1 = [[0,1],[Ord,length(V)]]; |
| Line 376 def find_separating_ideal2(C,G,Q,Rad,V,Ord) { |
|
| Line 367 def find_separating_ideal2(C,G,Q,Rad,V,Ord) { |
|
| } else |
} else |
| St = [S[0]]; |
St = [S[0]]; |
| print(""); |
print(""); |
| |
for ( I = Prev; I < Len; I++ ) { |
| if ( Complete ) { |
Int1 = incremental_gb(append(Int0,[Tmp*S[I]]),TV,Ord1 |
| for ( I = Prev; I < Len; I++ ) { |
|gbblock=[[0,length(Int0)]],mod=Mod); |
| Int1 = incremental_gb(append(Int0,[Tmp*S[I]]),TV,Ord1 |
Int = elimination(Int1,V); |
| |gbblock=[[0,length(Int0)]],mod=Mod); |
if ( gen_gb_comp(Int,G,Mod) ) { |
| Int = elimination(Int1,V); |
print([I],2); |
| if ( gen_gb_comp(Int,G,Mod) ) { |
St = cons(S[I],St); |
| print([I],2); |
Int0 = Int1; |
| St = cons(S[I],St); |
|
| Int0 = Int1; |
|
| } |
|
| } |
} |
| } |
} |
| Ok = reverse(St); |
Ok = reverse(St); |
| Line 448 def pseudo_dec(G,L,V,Ord) |
|
| Line 436 def pseudo_dec(G,L,V,Ord) |
|
| for ( I = 0; I < N; I++ ) { |
for ( I = 0; I < N; I++ ) { |
| LI = setminus(L0,[L0[I]]); |
LI = setminus(L0,[L0[I]]); |
| PI = ideal_list_intersection(LI,V,Ord|mod=Mod); |
PI = ideal_list_intersection(LI,V,Ord|mod=Mod); |
| PI = qsort(PI,comp_tdeg); |
PI = qsort(PI,noro_pd.comp_tdeg); |
| for ( T = PI; T != []; T = cdr(T) ) |
for ( T = PI; T != []; T = cdr(T) ) |
| if ( gen_nf(car(T),L0[I],V,Ord,Mod) ) break; |
if ( gen_nf(car(T),L0[I],V,Ord,Mod) ) break; |
| if ( T == [] ) error("separator : cannot happen"); |
if ( T == [] ) error("separator : cannot happen"); |
| SI = satind(G,car(T),V|mod=Mod); |
SI = sat_ind(G,car(T),V|mod=Mod); |
| QI = SI[0]; |
QI = SI[0]; |
| S[I] = car(T)^SI[1]; |
S[I] = car(T)^SI[1]; |
| PV = L[I][1]; |
PV = L[I][1]; |
| Line 466 def pseudo_dec(G,L,V,Ord) |
|
| Line 454 def pseudo_dec(G,L,V,Ord) |
|
| #endif |
#endif |
| LCFI = lcfactor(GI,V0,Ord,Mod); |
LCFI = lcfactor(GI,V0,Ord,Mod); |
| for ( F = 1, T = LCFI, Gt = QI; T != []; T = cdr(T) ) { |
for ( F = 1, T = LCFI, Gt = QI; T != []; T = cdr(T) ) { |
| St = satind(Gt,T[0],V|mod=Mod); |
St = sat_ind(Gt,T[0],V|mod=Mod); |
| Gt = St[0]; F *= T[0]^St[1]; |
Gt = St[0]; F *= T[0]^St[1]; |
| } |
} |
| Q[I] = [Gt,L0[I]]; |
Q[I] = [Gt,L0[I]]; |
| Line 522 def prima_dec(B,V) |
|
| Line 510 def prima_dec(B,V) |
|
| L = zprimacomp(G,V0|mod=Mod); |
L = zprimacomp(G,V0|mod=Mod); |
| F = 1; |
F = 1; |
| for ( T = LCF, G2 = G; T != []; T = cdr(T) ) { |
for ( T = LCF, G2 = G; T != []; T = cdr(T) ) { |
| S = satind(G2,T[0],V1|mod=Mod); |
S = sat_ind(G2,T[0],V1|mod=Mod); |
| G2 = S[0]; F *= T[0]^S[1]; |
G2 = S[0]; F *= T[0]^S[1]; |
| } |
} |
| for ( T = L, QL = []; T != []; T = cdr(T) ) |
for ( T = L, QL = []; T != []; T = cdr(T) ) |
| Line 1229 def ideal_product(A,B,V) |
|
| Line 1217 def ideal_product(A,B,V) |
|
| for ( T = PA; T != []; T = cdr(T) ) |
for ( T = PA; T != []; T = cdr(T) ) |
| for ( S = PB; S != []; S = cdr(S) ) |
for ( S = PB; S != []; S = cdr(S) ) |
| R = cons([car(T)[0]*car(S)[0],car(T)[1]+car(S)[1]],R); |
R = cons([car(T)[0]*car(S)[0],car(T)[1]+car(S)[1]],R); |
| T = qsort(R,comp_by_second); |
T = qsort(R,noro_pd.comp_by_second); |
| T = map(first_element,T); |
T = map(first_element,T); |
| Len = length(A)>length(B)?length(A):length(B); |
Len = length(A)>length(B)?length(A):length(B); |
| Len *= 2; |
Len *= 2; |
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