| version 1.1, 2000/12/14 13:18:41 |
version 1.8, 2001/09/20 00:48:17 |
|
|
| /* $OpenXM$ */ |
/* $OpenXM: OpenXM/src/k097/lib/restriction/demo.k,v 1.7 2001/01/26 12:24:57 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)))); }; "); |
| |
a.executeString(" def mygeneric_bfct(F,VV,DD,WW) { print([F,VV,DD,WW]); return(generic_bfct(F,VV,DD,WW));}; "); |
| } |
} |
| |
|
| as = startAsir(); |
if (Boundp("NoX")) { |
| |
as = Asir.generate(false); |
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}else{ |
| |
as = Asir.generate(); |
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} |
| |
|
| asssssir = as; |
asssssir = as; |
| demoSendAsirCommand(as); |
demoSendAsirCommand(as); |
| RingD("x,y,z,s"); |
RingD("x,y,z,s"); |
| Line 31 def asirAnnfsXYZ(a,f) { |
|
| Line 38 def asirAnnfsXYZ(a,f) { |
|
| return(b); |
return(b); |
| } |
} |
| |
|
| |
|
| |
def asir_generic_bfct(a,ii,vv,dd,ww) { |
| |
local ans; |
| |
ans = a.rpc_str("mygeneric_bfct",[ii,vv,dd,ww]); |
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return(ans); |
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} |
| |
/* a=startAsir(); |
| |
asir_generic_bfct(a,[Dx^2+Dy^2-1,Dx*Dy-4],[x,y],[Dx,Dy],[1,1]): */ |
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|
| |
/* usage: misc/tmp/complex-ja.texi */ |
| |
def ChangeRing(f) { |
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local r; |
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r = GetRing(f); |
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if (Tag(r) == 14) { |
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SetRing(r); |
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return(true); |
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}else{ |
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return(false); |
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} |
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} |
| |
|
| |
def asir_BfRoots2(G) { |
| |
local bb,ans,ss; |
| |
sm1(" G flatten {dehomogenize} map /G set "); |
| |
ChangeRing(G); |
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ss = asir_generic_bfct(asssssir,G,[x,y],[Dx,Dy],[1,1]); |
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bb = [ss]; |
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sm1(" bb 0 get findIntegralRoots { (universalNumber) dc } map /ans set "); |
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return([ans, bb]); |
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} |
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def asir_BfRoots3(G) { |
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local bb,ans,ss; |
| |
sm1(" G flatten {dehomogenize} map /G set "); |
| |
ChangeRing(G); |
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ss = asir_generic_bfct(asssssir,G,[x,y,z],[Dx,Dy,Dz],[1,1,1]); |
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bb = [ss]; |
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sm1(" bb 0 get findIntegralRoots { (universalNumber) dc } map /ans set "); |
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return([ans, bb]); |
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} |
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|
| |
def asir_BfRoots4(G) { |
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local bb,ans,ss; |
| |
sm1(" G flatten {dehomogenize} map /G set "); |
| |
ChangeRing(G); |
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ss = asir_generic_bfct(asssssir,G,[x,y,z,vv],[Dx,Dy,Dz,Dvv],[0,0,0,1]); |
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bb = [ss]; |
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sm1(" bb 0 get findIntegralRoots { (universalNumber) dc } map /ans set "); |
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return([ans, bb]); |
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} |
| |
|
| def findMinSol(f) { |
def findMinSol(f) { |
| sm1(" f (string) dc findIntegralRoots 0 get (universalNumber) dc /FunctionValue set "); |
sm1(" f (string) dc findIntegralRoots 0 get (universalNumber) dc /FunctionValue set "); |
| } |
} |
| Line 49 def asirAnnXYZ(a,f) { |
|
| Line 106 def asirAnnXYZ(a,f) { |
|
| return(b); |
return(b); |
| } |
} |
| |
|
| |
|
| def nonquasi2(p,q) { |
def nonquasi2(p,q) { |
| local s,ans,f; |
local s,ans,f; |
| |
|
| |
sm1("0 set_timer "); sm1(" oxNoX "); |
| |
asssssir.OnTimer(); |
| |
|
| f = x^p+y^q+x*y^(q-1); |
f = x^p+y^q+x*y^(q-1); |
| Print("f=");Println(f); |
Print("f=");Println(f); |
| s = ToString(f); |
s = ToString(f); |
| Line 65 def nonquasi2(p,q) { |
|
| Line 127 def nonquasi2(p,q) { |
|
| Res = Sminimal(pp); |
Res = Sminimal(pp); |
| Res0 = Res[0]; |
Res0 = Res[0]; |
| Println("Step2: (-1,1)-minimal resolution (Res0) "); sm1_pmat(Res0); |
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."); |
Println("Step3: computing the cohomology of the truncated complex."); |
| Print("Roots and b-function are "); Println(R); |
Print("Roots and b-function are "); Println(R); |
| 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]); |
| |
|
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Println("Timing data: sm1 "); sm1(" 1 set_timer "); |
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Print(" ox_asir [CPU,GC]: ");Println(asssssir.OffTimer()); |
| |
|
| Print("Answer is "); Println(Ans[0]); |
Print("Answer is "); Println(Ans[0]); |
| return(Ans); |
return(Ans); |
| |
} |
| |
|
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def asirAnn0XYZ(a,f) { |
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local p,b,b0; |
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RingD("x,y,z,s"); /* Fix!! See the definition of myann() */ |
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p = ToString(f); |
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b = a.rpc("myann0",[p]); |
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Print("Annhilating ideal of f^r is "); Println(b); |
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return(b); |
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} |
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|
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def DeRham2WithAsir(f) { |
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local s; |
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|
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sm1("0 set_timer "); sm1(" oxNoX "); |
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asssssir.OnTimer(); |
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|
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s = ToString(f); |
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II = asirAnn0XYZ(asssssir,f); |
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Print("Step 1: Annhilating ideal (II)"); Println(II); |
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sm1(" II { [(x) (y) (Dx) (Dy) ] laplace0 } map /II set "); |
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Sweyl("x,y",[["x",-1,"y",-1,"Dx",1,"Dy",1]]); |
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pp = Map(II,"Spoly"); |
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Res = Sminimal(pp); |
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Res0 = Res[0]; |
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Print("Step2: (-1,1)-minimal resolution (Res0) "); sm1_pmat(Res0); |
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/* R = BfRoots1(Res0[0],"x,y"); */ |
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R = asir_BfRoots2(Res0[0]); |
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Println("Step3: computing the cohomology of the truncated complex."); |
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Print("Roots and b-function are "); Println(R); |
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R0 = R[0]; |
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Ans=Srestall(Res0, ["x", "y"], ["x", "y"],R0[Length(R0)-1] ); |
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|
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Println("Timing data: sm1 "); sm1(" 1 set_timer "); |
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Print(" ox_asir [CPU,GC]: ");Println(asssssir.OffTimer()); |
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|
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Print("Answer is ");Println(Ans[0]); |
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return(Ans); |
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} |
| |
def DeRham3WithAsir(f) { |
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local s; |
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|
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sm1("0 set_timer "); sm1(" oxNoX "); |
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asssssir.OnTimer(); |
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|
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s = ToString(f); |
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II = asirAnn0XYZ(asssssir,f); |
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Print("Step 1: Annhilating ideal (II)"); Println(II); |
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sm1(" II { [(x) (y) (z) (Dx) (Dy) (Dz)] laplace0 } map /II set "); |
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Sweyl("x,y,z",[["x",-1,"y",-1,"z",-1,"Dx",1,"Dy",1,"Dz",1]]); |
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pp = Map(II,"Spoly"); |
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Res = Sminimal(pp); |
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Res0 = Res[0]; |
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Print("Step2: (-1,1)-minimal resolution (Res0) "); sm1_pmat(Res0); |
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/* R = BfRoots1(Res0[0],"x,y,z"); */ |
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R = asir_BfRoots3(Res0[0]); |
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Println("Step3: computing the cohomology of the truncated complex."); |
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Print("Roots and b-function are "); Println(R); |
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R0 = R[0]; |
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Ans=Srestall(Res0, ["x", "y", "z"], ["x", "y", "z"],R0[Length(R0)-1] ); |
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|
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Println("Timing data: sm1 "); sm1(" 1 set_timer "); |
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Print(" ox_asir [CPU,GC]: ");Println(asssssir.OffTimer()); |
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|
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Print("Answer is ");Println(Ans[0]); |
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return(Ans); |
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} |
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|
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/* test data |
| |
|
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NoX=true; |
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nonquasi2(4,5); |
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nonquasi2(4,6); |
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nonquasi2(4,7); |
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nonquasi2(4,8); |
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nonquasi2(4,9); |
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nonquasi2(4,10); |
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|
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nonquasi2(5,6); |
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nonquasi2(6,7); |
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nonquasi2(7,8); |
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nonquasi2(8,9); |
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nonquasi2(9,10); |
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*/ |
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|
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P2 = [ |
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"x^3-y^2", |
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"y^2-x^3-x-1", |
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"y^2-x^5-x-1", |
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"y^2-x^7-x-1", |
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"y^2-x^9-x-1", |
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"y^2-x^11-x-1" |
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]; |
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|
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P3 = [ |
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"x^3-y^2*z^2", |
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"x^2*z+y^3+y^2*z+z^3", |
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"y*z^2+x^3+x^2*y^2+y^6", |
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"x*z^2+x^2*y+x*y^3+y^5" |
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]; |
| |
|
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|
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def diff_tmp(ff,xx) { |
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local g; |
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g = xx*ff; |
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return( Replace(g,[[xx,Poly("0")],[h,Poly("1")]])); |
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} |
| |
|
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def Localize3WithAsir(I,f) { |
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local s; |
| |
|
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sm1("0 set_timer "); sm1(" oxNoX "); |
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asssssir.OnTimer(); |
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|
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RingD("x,y,z,vv"); |
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/* BUG: use of RingD("x,y,z,v") causes an expected error. |
| |
[x2,x3,x4,x4] in mygeneric_bfct. (should be [x2,x3,x4,x5]). |
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*/ |
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f = ReParse(f); |
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I = ReParse(I); |
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/* Test data. */ |
| |
/* |
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f = x^3-y^2*z^2; |
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I = [f^2*Dx-3*x^2, f^2*Dy-2*y*z^2, f^2*Dz-2*y^2*z]; |
| |
|
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f = x^3-y^2; |
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I = [f^2*Dx-diff_tmp(f,Dx), f^2*Dy-diff_tmp(f,Dy), Dz]; |
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*/ |
| |
|
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r1 = Dx-vv^2*diff_tmp(f,Dx)*Dvv; |
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r2 = Dy-vv^2*diff_tmp(f,Dy)*Dvv; |
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r3 = Dz-vv^2*diff_tmp(f,Dz)*Dvv; |
| |
II = ReParse(I); |
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sm1(" II { [[(Dx). r1] [(Dy). r2] [(Dz). r3]] replace } map dehomogenize /II set "); |
| |
|
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Print("Step 1: phi(J)"); Println(II); |
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II = Join(II,[vv*f-1]); |
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Print("Step 2: <phi(J),vf-1>"); Println(II); |
| |
|
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Println("Step3: computing the integral."); |
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sm1(" II { [(x) (y) (z) (vv) (Dx) (Dy) (Dz) (Dvv)] laplace0 } map /JJ set "); |
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Sweyl("x,y,z,vv",[["vv",-1,"Dvv",1]]); |
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pp = Map(JJ,"Spoly"); |
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R = asir_BfRoots4(pp); |
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Print("Roots and b-function are "); Println(R); |
| |
|
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R0 = R[0]; |
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k1 = R0[Length(R0)-1]; |
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sm1(" [(parse) (intw.sm1) pushfile] extension /intw.verbose 1 def "); |
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sm1(" [II [(vv) (x) (y) (z)] [(vv) -1 (Dvv) 1] k1 (integer) dc] integral-k1 /Ans set "); |
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|
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Println("Timing data: sm1 "); sm1(" 1 set_timer "); |
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Print(" ox_asir [CPU,GC]: ");Println(asssssir.OffTimer()); |
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|
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Print("Answer is ");Println(Ans); |
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return(Ans); |
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} |
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|
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|
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def Ltest2() { |
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RingD("x,y,z"); |
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f = x^3-y^2; |
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I = [f^2*Dx-diff_tmp(f,Dx), f^2*Dy-diff_tmp(f,Dy), Dz]; |
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return( Localize3WithAsir(I,f) ); |
| } |
} |
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