OpenXM/src/k097/lib/restriction/demo.k - diff

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Diff for /OpenXM/src/k097/lib/restriction/demo.k between version 1.2 and 1.5

version 1.2, 2000/12/15 02:44:32

version 1.5, 2000/12/28 00:08:14

Line 1

/* $OpenXM: OpenXM/src/k097/lib/restriction/demo.k,v 1.1 2000/12/14 13:18:41 takayama Exp $ */

/* $OpenXM: OpenXM/src/k097/lib/restriction/demo.k,v 1.4 2000/12/27 10:16:13 takayama Exp $ */

load["restriction.k"];;

load("../ox/ox.k");;

Line 8 def demoSendAsirCommand(a) {

a.executeString(" def myann(F) { B=ann(eval_str(F)); print(B); return(map(dp_ptod,B,[hoge,x,y,z,s,hh,ee,dx,dy,dz,ds,dhh])); }; ");

a.executeString(" def myann0(F) { B=ann0(eval_str(F)); print(B); return(map(dp_ptod,B[1],[hoge,x,y,z,s,hh,ee,dx,dy,dz,ds,dhh])); }; ");

a.executeString(" def mybfct(F) { return(rtostr(bfct(eval_str(F)))); }; ");

a.executeString(" def mygeneric_bfct(F,VV,DD,WW) { print([F,VV,DD,WW]); return(generic_bfct(F,VV,DD,WW));}; ");

}

as = startAsir();

Line 32 def asirAnnfsXYZ(a,f) {

Line 33 def asirAnnfsXYZ(a,f) {

return(b);

}

def asir_generic_bfct(a,ii,vv,dd,ww) {

local ans;

ans = a.rpc_str("mygeneric_bfct",[ii,vv,dd,ww]);

return(ans);

}

/* a=startAsir();

asir_generic_bfct(a,[Dx^2+Dy^2-1,Dx*Dy-4],[x,y],[Dx,Dy],[1,1]): */

/* usage: misc/tmp/complex-ja.texi */

def changeRing(f) {

local r;

r = GetRing(f);

if (Tag(r) == 14) {

SetRing(r);

return(true);

}else{

return(false);

}

def asir_BfRoots2(G) {

local bb,ans,ss;

sm1(" G flatten {dehomogenize} map /G set ");

changeRing(G);

ss = asir_generic_bfct(asssssir,G,[x,y],[Dx,Dy],[1,1]);

bb = [ss];

sm1(" bb 0 get findIntegralRoots { (universalNumber) dc } map /ans set ");

return([ans, bb]);

}

def asir_BfRoots3(G) {

local bb,ans,ss;

sm1(" G flatten {dehomogenize} map /G set ");

changeRing(G);

ss = asir_generic_bfct(asssssir,G,[x,y,z],[Dx,Dy,Dz],[1,1,1]);

bb = [ss];

sm1(" bb 0 get findIntegralRoots { (universalNumber) dc } map /ans set ");

return([ans, bb]);

}

def findMinSol(f) {

sm1(" f (string) dc findIntegralRoots 0 get (universalNumber) dc /FunctionValue set ");

}

Line 67 def nonquasi2(p,q) {

Line 108 def nonquasi2(p,q) {

Res = Sminimal(pp);

Res0 = Res[0];

Println("Step2: (-1,1)-minimal resolution (Res0) "); sm1_pmat(Res0);

R = BfRoots1(Res0[0],"x,y");

/* R = BfRoots1(Res0[0],"x,y"); */

R = asir_BfRoots2(Res0[0]);

Println("Step3: computing the cohomology of the truncated complex.");

Print("Roots and b-function are "); Println(R);

R0 = R[0];

Line 96 def DeRham2WithAsir(f) {

Line 138 def DeRham2WithAsir(f) {

Res = Sminimal(pp);

Res0 = Res[0];

Print("Step2: (-1,1)-minimal resolution (Res0) "); sm1_pmat(Res0);

R = BfRoots1(Res0[0],"x,y");

/* R = BfRoots1(Res0[0],"x,y"); */

R = asir_BfRoots2(Res0[0]);

Println("Step3: computing the cohomology of the truncated complex.");

Print("Roots and b-function are "); Println(R);

R0 = R[0];

Line 115 def DeRham3WithAsir(f) {

Line 158 def DeRham3WithAsir(f) {

Res = Sminimal(pp);

Res0 = Res[0];

Print("Step2: (-1,1)-minimal resolution (Res0) "); sm1_pmat(Res0);

R = BfRoots1(Res0[0],"x,y,z");

/* R = BfRoots1(Res0[0],"x,y,z"); */

R = asir_BfRoots3(Res0[0]);

Println("Step3: computing the cohomology of the truncated complex.");

Print("Roots and b-function are "); Println(R);

R0 = R[0];

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