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Diff for /OpenXM_contrib2/asir2000/lib/sp between version 1.1 and 1.10

version 1.1, 1999/12/03 07:39:11

version 1.10, 2002/06/21 00:34:21

Line 1

/* $OpenXM: OpenXM/src/asir99/lib/sp,v 1.1.1.1 1999/11/10 08:12:30 noro Exp $ */

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* $OpenXM: OpenXM_contrib2/asir2000/lib/sp,v 1.9 2001/10/12 06:07:05 noro Exp $

sp : functions related to algebraic number fields

Revision History:

99/08/24 noro modified for 1999 release version

2001/10/12 noro if USE_PARI_FACTOR is nonzero, pari factor is called

2000/03/10 noro fixed several bugs around gathering algebraic numbers

1999/08/24 noro modified for 1999 release version

#include "defs.h"

extern ASCENT,GCDTIME,UFTIME,RESTIME,SQTIME,PRINT$

extern Ord$

extern USE_PARI_FACTOR$

def sp(P)

{

Line 39 def sp(P)

Line 90 def sp(P)

}

Input:

F=F(x,a1,...,an)

DL = [[an,dn(an,...,a1)],...,[a2,d2(a2,a1)],[a1,d1(a1)]]

'ai' denotes a root of di(t).

Output:

irreducible factorization of F over Q(a1,...,an)

[[F1(x,a1,...,an),e1],...,[Fk(x,a1,...,an),ek]]

'ej' denotes the multiplicity of Fj.

def af_noalg(F,DL)

{

DL = reverse(DL);

N = length(DL);

Tab = newvect(N);

/* Tab = [[a1,r1],...]; ri is a root of di(t,r(i-1),...,r1). */

AL = [];

for ( I = 0; I < N; I++ ) {

T = DL[I];

for ( J = 0, DP = T[1]; J < I; J++ )

DP = subst(DP,Tab[J][0],Tab[J][1]);

B = newalg(DP);

Tab[I] = [T[0],B];

F = subst(F,T[0],B);

AL = cons(B,AL);

}

FL = af(F,AL);

for ( T = FL, R = []; T != []; T = cdr(T) )

R = cons([conv_noalg(T[0][0],Tab),T[0][1]],R);

return reverse(R);

}

Input:

F=F(x) univariate polynomial over the rationals

Output:

[FL,DL]

DL = [[an,dn(an,...,a1)],...,[a2,d2(a2,a1)],[a1,d1(a1)]]

'ai' denotes a root of di(t).

FL = [F1,F2,...]

irreducible factors of F over Q(a1,...,an)

def sp_noalg(F)

{

L = sp(F);

FL = map(algptorat,L[0]);

for ( T = L[1], DL = []; T != []; T = cdr(T) )

DL = cons([algtorat(T[0][0]),T[0][1]],DL);

return [FL,reverse(DL)];

}

def conv_noalg(F,Tab)

{

N = size(Tab)[0];

F = algptorat(F);

for ( I = N-1; I >= 0; I-- )

F = subst(F,algtorat(Tab[I][1]),Tab[I][0]);

return F;

}

def aflist(L,AL)

{

for ( DC = []; L != []; L = cdr(L) ) {

Line 84 def flatmf(L) {

Line 197 def flatmf(L) {

def af(P,AL)

{

RESTIME=UFTIME=GCDTIME=SQTIME=0;

S = reverse(asq(P,AL));

S = reverse(asq(P));

for ( L = []; S != []; S = cdr(S) ) {

FM = car(S); F = FM[0]; M = FM[1];

G = af_sp(F,AL,1);

Line 124 def af_spmain(P,AL,INIT,HINT,PP,SHIFT)

Line 237 def af_spmain(P,AL,INIT,HINT,PP,SHIFT)

N = simpcoef(sp_norm(A0,V,subst(P,V,V-INIT*A0),AL));

RESTIME+=time()[0]-TTT;

TTT = time()[0];

DCSQ = sortfs(asq(N,AL));

DCSQ = sortfs(asq(N));

SQTIME+=time()[0]-TTT;

for ( G = P, A = V+INIT*A0, DCR = []; DCSQ != []; DCSQ = cdr(DCSQ) ) {

C = TT(DCSQ); D = TS(DCSQ);

Line 142 def af_spmain(P,AL,INIT,HINT,PP,SHIFT)

Line 255 def af_spmain(P,AL,INIT,HINT,PP,SHIFT)

else {

S = subst(car(DCT),V,A);

if ( pra(G,S,AL) )

U = cr_gcda(S,G,AL);

U = cr_gcda(S,G);

else

U = S;

}

Line 270 def getalgp(P) {

Line 383 def getalgp(P) {

else {

for ( V = var(P), I = deg(P,V), T = []; I >= 0; I-- )

if ( C = coef(P,I) )

T = union(T,getalgp(C));

T = union_sort(T,getalgp(C));

return T;

}

def union(A,B)

def getalgtreep(P) {

{

if ( type(P) <= 1 )

for ( T = B; T != []; T = cdr(T) )

return getalgtree(P);

A = union1(A,car(T));

else {

return A;

for ( V = var(P), I = deg(P,V), T = []; I >= 0; I-- )

if ( C = coef(P,I) )

T = union_sort(T,getalgtreep(C));

return T;

}

def union1(A,E)

/* C = union of A and B; A and B is sorted. C should also be sorted. */

def union_sort(A,B)

{

if ( A == [] )

return [E];

return B;

else if ( car(A) == E )

else if ( B == [] )

return A;

else

else {

return cons(car(A),union1(cdr(A),E));

A0 = car(A);

B0 = car(B);

if ( A0 == B0 )

return cons(A0,union_sort(cdr(A),cdr(B)));

else if ( A0 > B0 )

return cons(A0,union_sort(cdr(A),B));

else

return cons(B0,union_sort(A,cdr(B)));

}

def invalgp(A)

Line 359 def sortfs(L)

Line 486 def sortfs(L)

def pdiva(P1,P2)

{

A = union(getalgp(P1),getalgp(P2));

A = union_sort(getalgp(P1),getalgp(P2));

P1 = algptorat(P1); P2 = algptorat(P2);

return simpalg(rattoalgp(sdiv(P1*LCOEF(P2)^(DEG(P1)-DEG(P2)+1),P2),A));

}

Line 371 def pqra(P1,P2)

Line 498 def pqra(P1,P2)

else if ( (type(P1) != POLY) || (deg(P1,var(P1)) < deg(P2,var(P1))) )

return [0,P1];

else {

A = union(getalgp(P1),getalgp(P2));

A = union_sort(getalgp(P1),getalgp(P2));

P1 = algptorat(P1); P2 = algptorat(P2);

L = sqr(P1*LCOEF(P2)^(DEG(P1)-DEG(P2)+1),P2);

return [simpalg(rattoalgp(L[0],A)),simpalg(rattoalgp(L[1],A))];

Line 410 def sort_alg(VL)

Line 537 def sort_alg(VL)

return L;

}

def asq(P,AL)

def asq(P)

{

P = simpalg(P);

if ( type(P) == NUM )

Line 423 def asq(P,AL)

Line 550 def asq(P,AL)

if ( type(F) == NUM )

break;

F1 = diff(F,V);

GCD = cr_gcda(F,F1,AL);

GCD = cr_gcda(F,F1);

FLAT = pdiva(F,GCD);

if ( type(GCD) == NUM ) {

A[I] = F; B[I] = 1;

Line 467 def simpcoef(P) {

Line 594 def simpcoef(P) {

}

def ufctrhint_heuristic(P,HINT,PP,SHIFT) {

if ( USE_PARI_FACTOR )

return pari_ufctr(P);

else

return asir_ufctrhint_heuristic(P,HINT,PP,SHIFT);

}

def pari_ufctr(P) {

F = pari(factor,P);

S = size(F);

for ( I = S[0]-1, R = []; I >= 0; I-- )

R = cons(vtol(F[I]),R);

return cons([1,1],R);

}

def asir_ufctrhint_heuristic(P,HINT,PP,SHIFT) {

V = var(P); D = deg(P,V);

if ( D == HINT )

return [[P,1]];

Line 479 def ufctrhint_heuristic(P,HINT,PP,SHIFT) {

Line 621 def ufctrhint_heuristic(P,HINT,PP,SHIFT) {

G = igcd(G,DT=deg(T,V));

if ( G == 1 ) {

if ( K*deg(PPP,V) != deg(P,V) )

PPP = cr_gcda(PPP,P,AL);

PPP = cr_gcda(PPP,P);

return ufctrhint2(P,HINT,PPP,AL);

} else {

for ( S = 0, T = P; T; T -= coef(T,DT)*V^DT ) {

Line 489 def ufctrhint_heuristic(P,HINT,PP,SHIFT) {

Line 631 def ufctrhint_heuristic(P,HINT,PP,SHIFT) {

L = fctr(S);

for ( DC = [car(L)], L = cdr(L); L != []; L = cdr(L) ) {

H = subst(car(car(L)),V,V^G);

HH = cr_gcda(PPP,H,AL);

HH = cr_gcda(PPP,H);

T = ufctrhint2(H,HINT,HH,AL);

DC = append(DC,T);

}

Line 645 def norm_ch_lag(V,VM,P,P0) {

Line 787 def norm_ch_lag(V,VM,P,P0) {

return S;

}

def cr_gcda(P1,P2,EXT)

def cr_gcda(P1,P2)

{

if ( !(V = var(P1)) || !var(P2) )

return 1;

AL = union(getalgp(P1),getalgp(P2));

EXT = union_sort(getalgtreep(P1),getalgtreep(P2));

if ( AL == [] )

if ( EXT == [] )

return gcd(P1,P2);

T = newvect(length(EXT));

for ( TAL = AL; TAL != []; TAL = cdr(TAL) ) {

A = getalg(car(TAL));

for ( TA = A; TA != []; TA = cdr(TA) ) {

B = car(TA);

for ( TEXT = EXT, I = 0; TEXT != []; TEXT = cdr(TEXT), I++ )

if ( car(TEXT) == B )

T[I] = B;

}

for ( I = length(EXT)-1, S = []; I >= 0; I-- )

if ( T[I] )

S = cons(T[I],S);

EXT = S;

NEXT = length(EXT);

if ( deg(P1,V) < deg(P2,V) ) {

T = P1; P1 = P2; P2 = T;

Line 747 def member(E,L)

Line 875 def member(E,L)

return 0;

}

def getallalg(A)

{

T = cdr(vars(defpoly(A)));

if ( T == [] )

return [A];

else {

for ( S = [A]; T != []; T = cdr(T) )

S = union(S,getallalg(rattoalg(car(T))));

return S;

}

def discr(P) {

V = var(P);

return res(V,P,diff(P,V));

Line 1211 def resfctr(F,L,V,N)

Line 1327 def resfctr(F,L,V,N)

N = ptozp(N);

V0 = var(N);

DN = diff(N,V0);

LC = coef(N,deg(N,V0),V0);

LCD = coef(DN,deg(DN,V0),V0);

for ( I = 0, J = 2, Len = deg(N,V0)+1; I < 5; J++ ) {

M = prime(J);

if ( !(LC%M) || !(LCD%M))

continue;

G = gcd(N,DN,M);

if ( !deg(G,V0) ) {

I++;

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