OpenXM_contrib2/asir2000/lib/primdec_mod - diff

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Diff for /OpenXM_contrib2/asir2000/lib/primdec_mod between version 1.1 and 1.5

version 1.1, 2003/04/20 02:42:08

version 1.5, 2003/04/21 01:44:31

Line 4 extern T_GRF,T_INT,T_PD,T_MP$

extern BuchbergerMinipoly,PartialDecompByLex,ParallelMinipoly$

extern B_Win,D_Win$

extern COMMONCHECK_SF,CID_SF$

extern LIBRARY_GR_LOADED$

extern LIBRARY_FFF_LOADED$

if(!LIBRARY_FFF_LOADED) load("fff"); else ; LIBRARY_FFF_LOADED = 1$

if(!LIBRARY_GR_LOADED) load("gr"); else ; LIBRARY_GR_LOADED = 1$

/*==============================================*/

/* prime decomposition of ideals over */

/* finite fields */

Line 337 def coefficientfrobeniuskernel_main(Poly)

Line 342 def coefficientfrobeniuskernel_main(Poly)

Vars=vars(Poly);

QP=dp_ptod(Poly,Vars);

ANS=0;

FOrd=deg(setmod_ff()[1],x);

FOrd=deg(setmod_ff()[1],var(setmod_ff()[1]));

Char=setmod_ff()[0];

Pow=Char^(FOrd-1);

Line 921 def primedec_sf(P,VSet,Ord,Strategy)

Line 926 def primedec_sf(P,VSet,Ord,Strategy)

REM[I]=[];

}

print("The dimension of the ideal is ",2);print(ORIGINALDIMENSION,2);

if ( dp_gr_print() ) {

print(". ");

print("The dimension of the ideal is ",2);print(ORIGINALDIMENSION,2);

print(". ");

}

if ( ORIGINALDIMENSION == 0 )

{

Line 932 def primedec_sf(P,VSet,Ord,Strategy)

Line 939 def primedec_sf(P,VSet,Ord,Strategy)

ANS=gr_fctr_sf([ORIGINAL],VSet,Ord);

NANS=length(ANS);

print("There are ",2);print(NANS,2);print(" partial components. ");

if ( dp_gr_print() ) {

print("There are ",2);print(NANS,2);print(" partial components. ");

}

for (I=0;I<NANS;I++)

{

TempI=ANS[I];

Line 958 def primedec_sf(P,VSet,Ord,Strategy)

Line 966 def primedec_sf(P,VSet,Ord,Strategy)

{

DIVLIST = prime_irred_sf_by_first(DIVLIST,VSet,0);

DIVLIST = monic_sf_first(DIVLIST,VSet);

print("We finish the computation. ");

if ( dp_gr_print() ) {

T_TOTAL = time()[3]-T0[3];

print("We finish the computation. ");

print(["T_TOTAL",T_TOTAL,"T_GRF",T_GRF,"T_PD",T_PD,"T_MP",T_MP,"T_INT",T_INT,"B_Win",B_Win,"D_Win",D_Win]);

T_TOTAL = time()[3]-T0[3];

print(["T_TOTAL",T_TOTAL,"T_GRF",T_GRF,"T_PD",T_PD,"T_MP",T_MP,"T_INT",T_INT,"B_Win",B_Win,"D_Win",D_Win]);

}

return 0;

}

Line 970 def primedec_sf(P,VSet,Ord,Strategy)

Line 980 def primedec_sf(P,VSet,Ord,Strategy)

DIVLIST = prime_irred_sf_by_first(DIVLIST,VSet,0);

DIVLIST = monic_sf_first(DIVLIST,VSet);

T_TOTAL = time()[3]-T0[3];

print(["T_TOTAL",T_TOTAL,"T_GRF",T_GRF,"T_PD",T_PD,"T_MP",T_MP,"T_INT",T_INT,"B_Win",B_Win,"D_Win",D_Win]);

if ( dp_gr_print() ) {

print(["T_TOTAL",T_TOTAL,"T_GRF",T_GRF,"T_PD",T_PD,"T_MP",T_MP,"T_INT",T_INT,"B_Win",B_Win,"D_Win",D_Win]);

}

return 0;

}

Line 1108 def primedecomposition(P,VSet,Ord,COUNTER,Strategy)

Line 1120 def primedecomposition(P,VSet,Ord,COUNTER,Strategy)

Dimension=Dimeset[0];

MSI=Dimeset[1];

print("The dimension of the ideal is ",2); print(Dimension,2);

if ( dp_gr_print() ) {

print(".");

print("The dimension of the ideal is ",2); print(Dimension,2);

print(".");

}

TargetVSet=setminus(VSet,MSI);

NewGP=dp_gr_f_main(GP,TargetVSet,Hom,Ord);

Line 1121 def primedecomposition(P,VSet,Ord,COUNTER,Strategy)

Line 1134 def primedecomposition(P,VSet,Ord,COUNTER,Strategy)

/* Then the ideal is 0-dimension in K[TargetVSet]. */

print("We enter Zero-dimension Prime Decomposition. ",2);

if ( dp_gr_print() ) {

print("We enter Zero-dimension Prime Decomposition. ",2);

}

QP=zeroprimedecomposition(NewGP,TargetVSet,VSet);

ANS=[];

NQP=length(QP);

print("The number of the newly found component is ",2);

if ( dp_gr_print() ) {

print(NQP,2);print(". ",2);

print("The number of the newly found component is ",2);

print(NQP,2);print(". ",2);

}

for (I=0;I<NQP;I++)

{

ZPrimeideal=QP[I];

Line 1168 def primedecomposition(P,VSet,Ord,COUNTER,Strategy)

Line 1184 def primedecomposition(P,VSet,Ord,COUNTER,Strategy)

if (CHECK==1)

{

print("We already obtain all divisor. ");

if ( dp_gr_print() ) {

print("We already obtain all divisor. ");

}

STOP = 1;

return 0;

}

Line 1200 def primedecomposition(P,VSet,Ord,COUNTER,Strategy)

Line 1218 def primedecomposition(P,VSet,Ord,COUNTER,Strategy)

if ( CHECKADD != 0 )

{

print("Avoid unnecessary computation. ",2);

if ( dp_gr_print() ) {

print("Avoid unnecessary computation. ",2);

}

continue;

}

Line 1291 def zeroprimedecomposition(P,TargetVSet,VSet)

Line 1311 def zeroprimedecomposition(P,TargetVSet,VSet)

ZDecomp=[PDiv];

print("An intermediate ideal is of generic type. ");

if ( dp_gr_print() ) {

print("An intermediate ideal is of generic type. ");

}

else

{

print("An intermediate ideal is not of generic type. ",2);

if ( dp_gr_print() ) {

print("An intermediate ideal is not of generic type. ",2);

}

/* We compute the separable closure of <P> by using minimal polynomails.*/

/* separableclosure outputs */

Line 1311 def zeroprimedecomposition(P,TargetVSet,VSet)

Line 1335 def zeroprimedecomposition(P,TargetVSet,VSet)

if ( Sep[1] != 0 )

{

print("The ideal is inseparable. ",2);

if ( dp_gr_print() ) {

print("The ideal is inseparable. ",2);

}

CHECK2=checkgeneric2(Sep[2]);

}

else

{

print("The ideal is already separable. ",2);

if ( dp_gr_print() ) {

print("The ideal is already separable. ",2);

}

if ( Sep[1] !=0 && CHECK2 == 1 )

{

print("The separable closure is of generic type. ",2);

if ( dp_gr_print() ) {

print("So, the intermediate ideal is prime or primary. ",2);

print("The separable closure is of generic type. ",2);

print("So, the intermediate ideal is prime or primary. ",2);

}

PDiv=convertdivisor(Sep[0],TargetVSet,VSet,Sep[1]);

if ( TargetVSet != VSet )

{

Line 1414 def zeroseparableprimedecomposition(P,TargetVSet,VSet)

Line 1443 def zeroseparableprimedecomposition(P,TargetVSet,VSet)

/* Generic=[f, minimal polynomial of f in newt, newt], */

/* where newt (X) is a newly introduced variable. */

print("We search for a linear sum of variables in generic position. ",2);

if ( dp_gr_print() ) {

print("We search for a linear sum of variables in generic position. ",2);

}

Generic=findgeneric(NewGP,TargetVSet,VSet);

X=Generic[2]; /* newly introduced variable */

Line 1596 def separableclosure(CP,TargetVSet,VSet)

Line 1626 def separableclosure(CP,TargetVSet,VSet)

if ( CHECK == 1 )

{

print("This is already a separable ideal.", 2);

if ( dp_gr_print() ) {

print("This is already a separable ideal.", 2);

}

return [CP[0],0];

}

print("This is not a separable ideal, so we make its separable closure.", 2);

if ( dp_gr_print() ) {

print("This is not a separable ideal, so we make its separable closure.", 2);

}

WSet=makecounterpart(TargetVSet);

Char=setmod_ff()[0];

Line 1762 def findgeneric(P,TargetVSet,VSet)

Line 1795 def findgeneric(P,TargetVSet,VSet)

}

#endif

print("Extend the ground field. ",2);

if ( dp_gr_print() ) {

print("Extend the ground field. ",2);

}

error();

}

Line 2048 def convertsmallfield(PP,VSet,Ord)

Line 2083 def convertsmallfield(PP,VSet,Ord)

dp_ord(Ord);

NVSet=length(VSet);

Char=setmod_ff()[0];

ExtDeg=deg(setmod_ff()[1],x);

ExtDeg=deg(setmod_ff()[1],var(setmod_ff()[1]));

NewV=pg;

NewV=pgpgpgpgpgpgpg;

MPP=map(monic_hc,PP,VSet);

MPP=map(sfptopsfp,MPP,NewV);

MinPoly=subst(setmod_ff()[1],x,NewV);

MinPoly=subst(setmod_ff()[1],var(setmod_ff()[1]),NewV);

XSet=cons(NewV,VSet);

Ord1=[[0,1],[Ord,NVSet]];

Line 2074 def checkgaloisorbit(PP,VSet,Ord,Flag)

Line 2109 def checkgaloisorbit(PP,VSet,Ord,Flag)

{

NPP=length(PP);

TmpPP=PP;

ExtDeg=deg(setmod_ff()[1],x);

ExtDeg=deg(setmod_ff()[1],var(setmod_ff()[1]));

ANS=[];

BNS=[];

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