| version 1.1, 2000/12/14 13:18:41 |
version 1.2, 2000/12/15 02:44:32 |
|
|
| /* $OpenXM$ */ |
/* $OpenXM: OpenXM/src/k097/lib/restriction/demo.k,v 1.1 2000/12/14 13:18:41 takayama Exp $ */ |
| |
|
| load["restriction.k"];; |
load["restriction.k"];; |
| load("../ox/ox.k");; |
load("../ox/ox.k");; |
| Line 6 load("../ox/ox.k");; |
|
| Line 6 load("../ox/ox.k");; |
|
| def demoSendAsirCommand(a) { |
def demoSendAsirCommand(a) { |
| a.executeString("load(\"bfct\");"); |
a.executeString("load(\"bfct\");"); |
| 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 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 mybfct(F) { return(rtostr(bfct(eval_str(F)))); }; "); |
| } |
} |
| |
|
| Line 49 def asirAnnXYZ(a,f) { |
|
| Line 50 def asirAnnXYZ(a,f) { |
|
| return(b); |
return(b); |
| } |
} |
| |
|
| |
|
| def nonquasi2(p,q) { |
def nonquasi2(p,q) { |
| local s,ans,f; |
local s,ans,f; |
| f = x^p+y^q+x*y^(q-1); |
f = x^p+y^q+x*y^(q-1); |
| Line 71 def nonquasi2(p,q) { |
|
| Line 73 def nonquasi2(p,q) { |
|
| R0 = R[0]; |
R0 = R[0]; |
| Ans=Srestall(Res0, ["x", "y"], ["x", "y"], R0[Length(R0)-1]); |
Ans=Srestall(Res0, ["x", "y"], ["x", "y"], R0[Length(R0)-1]); |
| Print("Answer is "); Println(Ans[0]); |
Print("Answer is "); Println(Ans[0]); |
| |
return(Ans); |
| |
} |
| |
|
| |
def asirAnn0XYZ(a,f) { |
| |
local p,b,b0; |
| |
RingD("x,y,z,s"); /* Fix!! See the definition of myann() */ |
| |
p = ToString(f); |
| |
b = a.rpc("myann0",[p]); |
| |
Print("Annhilating ideal of f^r is "); Println(b); |
| |
return(b); |
| |
} |
| |
|
| |
def DeRham2WithAsir(f) { |
| |
local s; |
| |
s = ToString(f); |
| |
II = asirAnn0XYZ(asssssir,f); |
| |
Print("Step 1: Annhilating ideal (II)"); Println(II); |
| |
sm1(" II { [(x) (y) (Dx) (Dy) ] laplace0 } map /II set "); |
| |
Sweyl("x,y",[["x",-1,"y",-1,"Dx",1,"Dy",1]]); |
| |
pp = Map(II,"Spoly"); |
| |
Res = Sminimal(pp); |
| |
Res0 = Res[0]; |
| |
Print("Step2: (-1,1)-minimal resolution (Res0) "); sm1_pmat(Res0); |
| |
R = BfRoots1(Res0[0],"x,y"); |
| |
Println("Step3: computing the cohomology of the truncated complex."); |
| |
Print("Roots and b-function are "); Println(R); |
| |
R0 = R[0]; |
| |
Ans=Srestall(Res0, ["x", "y"], ["x", "y"],R0[Length(R0)-1] ); |
| |
Print("Answer is ");Println(Ans[0]); |
| |
return(Ans); |
| |
} |
| |
def DeRham3WithAsir(f) { |
| |
local s; |
| |
s = ToString(f); |
| |
II = asirAnn0XYZ(asssssir,f); |
| |
Print("Step 1: Annhilating ideal (II)"); Println(II); |
| |
sm1(" II { [(x) (y) (z) (Dx) (Dy) (Dz)] laplace0 } map /II set "); |
| |
Sweyl("x,y,z",[["x",-1,"y",-1,"z",-1,"Dx",1,"Dy",1,"Dz",1]]); |
| |
pp = Map(II,"Spoly"); |
| |
Res = Sminimal(pp); |
| |
Res0 = Res[0]; |
| |
Print("Step2: (-1,1)-minimal resolution (Res0) "); sm1_pmat(Res0); |
| |
R = BfRoots1(Res0[0],"x,y,z"); |
| |
Println("Step3: computing the cohomology of the truncated complex."); |
| |
Print("Roots and b-function are "); Println(R); |
| |
R0 = R[0]; |
| |
Ans=Srestall(Res0, ["x", "y", "z"], ["x", "y", "z"],R0[Length(R0)-1] ); |
| |
Print("Answer is ");Println(Ans[0]); |
| return(Ans); |
return(Ans); |
| } |
} |
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