version 1.16, 2000/06/15 07:38:36 |
version 1.30, 2000/11/19 05:50:30 |
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/* $OpenXM: OpenXM/src/k097/lib/minimal/minimal.k,v 1.15 2000/06/14 07:44:05 takayama Exp $ */ |
/* $OpenXM: OpenXM/src/k097/lib/minimal/minimal.k,v 1.29 2000/08/22 05:34:06 takayama Exp $ */ |
#define DEBUG 1 |
#define DEBUG 1 |
/* #define ORDINARY 1 */ |
Sordinary = false; |
/* If you run this program on openxm version 1.1.2 (FreeBSD), |
/* If you run this program on openxm version 1.1.2 (FreeBSD), |
make a symbolic link by the command |
make a symbolic link by the command |
ln -s /usr/bin/cpp /lib/cpp |
ln -s /usr/bin/cpp /lib/cpp |
*/ |
*/ |
#define OFFSET 0 |
#define OFFSET 0 |
#define TOTAL_STRATEGY 1 |
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/* #define OFFSET 20*/ |
/* #define OFFSET 20*/ |
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Sverbose = false; /* Be extreamly verbose */ |
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Sverbose2 = true; /* Don't be quiet and show minimal information */ |
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def Sprintln(s) { |
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if (Sverbose) Println(s); |
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} |
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def Sprint(s) { |
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if (Sverbose) Print(s); |
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} |
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def Sprintln2(s) { |
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if (Sverbose2) Println(s); |
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} |
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def Sprint2(s) { |
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if (Sverbose2) Print(s); |
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sm1(" [(flush)] extension "); |
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} |
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/* Test sequences. |
/* Test sequences. |
Use load["minimal.k"];; |
Use load["minimal.k"];; |
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Line 35 def load_tower() { |
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Line 50 def load_tower() { |
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if (Boundp("k0-tower.sm1.loaded")) { |
if (Boundp("k0-tower.sm1.loaded")) { |
}else{ |
}else{ |
sm1(" [(parse) (k0-tower.sm1) pushfile ] extension "); |
sm1(" [(parse) (k0-tower.sm1) pushfile ] extension "); |
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sm1(" [(parse) (new.sm1) pushfile ] extension "); |
sm1(" /k0-tower.sm1.loaded 1 def "); |
sm1(" /k0-tower.sm1.loaded 1 def "); |
} |
} |
sm1(" oxNoX "); |
sm1(" oxNoX "); |
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def Sgroebner(f) { |
def Sgroebner(f) { |
sm1(" [f] groebner /FunctionValue set"); |
sm1(" [f] groebner /FunctionValue set"); |
} |
} |
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def Sinvolutive(f,w) { |
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local g,m; |
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if (IsArray(f[0])) { |
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m = NewArray(Length(f[0])); |
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}else{ |
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m = [0]; |
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} |
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g = Sgroebner(f); |
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/* This is a temporary code. */ |
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sm1(" g 0 get { w m init_w<m>} map /FunctionValue set "); |
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} |
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def Error(s) { |
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sm1(" s error "); |
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} |
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def IsNull(s) { |
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if (Stag(s) == 0) return(true); |
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else return(false); |
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} |
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def MonomialPart(f) { |
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sm1(" [(lmonom) f] gbext /FunctionValue set "); |
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} |
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def Warning(s) { |
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Print("Warning: "); |
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Println(s); |
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} |
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def RingOf(f) { |
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local r; |
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if (IsPolynomial(f)) { |
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if (f != Poly("0")) { |
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sm1(f," (ring) dc /r set "); |
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}else{ |
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sm1(" [(CurrentRingp)] system_variable /r set "); |
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} |
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}else{ |
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Warning("RingOf(f): the argument f must be a polynomial. Return the current ring."); |
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sm1(" [(CurrentRingp)] system_variable /r set "); |
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} |
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return(r); |
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} |
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def Ord_w_m(f,w,m) { |
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sm1(" f w m ord_w<m> { (universalNumber) dc } map /FunctionValue set "); |
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} |
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HelpAdd(["Ord_w_m", |
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["Ord_w_m(f,w,m) returns the order of f with respect to w with the shift m.", |
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"Note that the order of the ring and the weight w must be the same.", |
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"When f is zero, it returns -intInfinity = -999999999.", |
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"Example: Sweyl(\"x,y\",[[\"x\",-1,\"Dx\",1]]); ", |
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" Ord_w_m([x*Dx+1,Dx^2+x^5],[\"x\",-1,\"Dx\",1],[2,0]):"]]); |
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def Init_w_m(f,w,m) { |
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sm1(" f w m init_w<m> /FunctionValue set "); |
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} |
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HelpAdd(["Init_w_m", |
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["Init_w_m(f,w,m) returns the initial of f with respect to w with the shift m.", |
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"Note that the order of the ring and the weight w must be the same.", |
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"Example: Sweyl(\"x,y\",[[\"x\",-1,\"Dx\",1]]); ", |
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" Init_w_m([x*Dx+1,Dx^2+x^5],[\"x\",-1,\"Dx\",1],[2,0]):"]]); |
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def Max(v) { |
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local i,t,n; |
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n = Length(v); |
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if (n == 0) return(null); |
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t = v[0]; |
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for (i=0; i<n; i++) { |
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if (v[i] > t) { t = v[i];} |
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} |
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return(t); |
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} |
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HelpAdd(["Max", |
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["Max(v) returns the maximal element in v."]]); |
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def Kernel(f) { |
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sm1(" [f] syz /FunctionValue set "); |
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} |
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def Syz(f) { |
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sm1(" [f] syz /FunctionValue set "); |
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} |
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HelpAdd(["Kernel", |
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["Kernel(f) returns the syzygy of f.", |
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"Return value [b, c]: b is a set of generators of the syzygies of f", |
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" : c=[gb, backward transformation, syzygy without", |
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" dehomogenization", |
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"Example: Weyl(\"x,y\",[[\"x\",-1,\"Dx\",1]]); ", |
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" s=Kernel([x*Dx+1,Dx^2+x^5]); s[0]:"]]); |
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/* cf. sm1_syz in cohom.k */ |
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def Gb(f) { |
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sm1(" [f] gb /FunctionValue set "); |
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} |
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HelpAdd(["Gb", |
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["Gb(f) returns the Groebner basis of f.", |
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"cf. Kernel, Weyl."]]); |
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/* End of standard functions that should be moved to standard libraries. */ |
def test0() { |
def test0() { |
local f; |
local f; |
Sweyl("x,y,z"); |
Sweyl("x,y,z"); |
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} |
} |
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def Sweyl(v,w) { |
def Sweyl(v,w) { |
/* extern WeightOfSweyl ; */ |
/* extern WeightOfSweyl ; */ |
local ww,i,n; |
local ww,i,n; |
Line 137 sm1(" [(AvoidTheSameRing)] pushEnv |
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Line 254 sm1(" [(AvoidTheSameRing)] pushEnv |
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def SresolutionFrameWithTower(g,opt) { |
def SresolutionFrameWithTower(g,opt) { |
local gbTower, ans, ff, count, startingGB, opts, skelton,withSkel, autof, |
local gbTower, ans, ff, count, startingGB, opts, skelton,withSkel, autof, |
gbasis, nohomog; |
gbasis, nohomog,i,n; |
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/* extern Sordinary */ |
nohomog = false; |
nohomog = false; |
count = -1; |
count = -1; Sordinary = false; /* default value for options. */ |
if (Length(Arglist) >= 2) { |
if (Length(Arglist) >= 2) { |
if (IsInteger(opt)) { |
if (IsArray(opt)) { |
count = opt; |
n = Length(opt); |
}else if (IsString(opt)) { |
for (i=0; i<n; i++) { |
if (opt == "homogenized") { |
if (IsInteger(opt[i])) { |
nohomog = true; |
count = opt[i]; |
}else{ |
} |
Println("Warning: unknown option"); |
if (IsString(opt[i])) { |
Println(opt); |
if (opt[i] == "homogenized") { |
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nohomog = true; |
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}else if (opt[i] == "Sordinary") { |
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Sordinary = true; |
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}else{ |
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Println("Warning: unknown option"); |
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Println(opt); |
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} |
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} |
} |
} |
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} else if (IsNull(opt)){ |
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} else { |
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Println("Warning: option should be given by an array."); |
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Println(opt); |
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Println("--------------------------------------------"); |
} |
} |
}else{ |
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count = -1; |
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} |
} |
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sm1(" setupEnvForResolution "); |
sm1(" setupEnvForResolution "); |
Line 186 def SresolutionFrameWithTower(g,opt) { |
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Line 315 def SresolutionFrameWithTower(g,opt) { |
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/* -sugar is fine? */ |
/* -sugar is fine? */ |
sm1(" setupEnvForResolution "); |
sm1(" setupEnvForResolution "); |
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Println(g); |
Sprintln(g); |
startingGB = g; |
startingGB = g; |
/* ans = [ SzeroMap(g) ]; It has not been implemented. see resol1.withZeroMap */ |
/* ans = [ SzeroMap(g) ]; It has not been implemented. see resol1.withZeroMap */ |
ans = [ ]; |
ans = [ ]; |
Line 230 def NewPolynomialVector(size) { |
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Line 359 def NewPolynomialVector(size) { |
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def SturnOffHomogenization() { |
def SturnOffHomogenization() { |
sm1(" |
sm1(" |
[(Homogenize)] system_variable 1 eq |
[(Homogenize)] system_variable 1 eq |
{ (Warning: Homogenization and ReduceLowerTerms options are automatically turned off.) message |
{ Sverbose { |
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(Warning: Homogenization and ReduceLowerTerms options are automatically turned off.) message } { } ifelse |
[(Homogenize) 0] system_variable |
[(Homogenize) 0] system_variable |
[(ReduceLowerTerms) 0] system_variable |
[(ReduceLowerTerms) 0] system_variable |
} { } ifelse |
} { } ifelse |
"); |
"); |
} |
} |
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/* NOTE!!! Be careful these changes of global environmental variables. |
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We should make a standard set of values and restore these values |
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after computation and interruption. August 15, 2000. |
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*/ |
def SturnOnHomogenization() { |
def SturnOnHomogenization() { |
sm1(" |
sm1(" |
[(Homogenize)] system_variable 0 eq |
[(Homogenize)] system_variable 0 eq |
{ (Warning: Homogenization and ReduceLowerTerms options are automatically turned ON.) message |
{ Sverbose { |
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(Warning: Homogenization and ReduceLowerTerms options are automatically turned ON.) message } { } ifelse |
[(Homogenize) 1] system_variable |
[(Homogenize) 1] system_variable |
[(ReduceLowerTerms) 1] system_variable |
[(ReduceLowerTerms) 1] system_variable |
} { } ifelse |
} { } ifelse |
Line 287 def Sres0FrameWithSkelton(g) { |
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Line 422 def Sres0FrameWithSkelton(g) { |
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si = pair[1,0]; |
si = pair[1,0]; |
sj = pair[1,1]; |
sj = pair[1,1]; |
/* si g[i] + sj g[j] + \sum tmp[2][k] g[k] = 0 in res0 */ |
/* si g[i] + sj g[j] + \sum tmp[2][k] g[k] = 0 in res0 */ |
Print("."); |
Sprint("."); |
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t_syz = NewPolynomialVector(gLength); |
t_syz = NewPolynomialVector(gLength); |
t_syz[i] = si; |
t_syz[i] = si; |
Line 295 def Sres0FrameWithSkelton(g) { |
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Line 430 def Sres0FrameWithSkelton(g) { |
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syzAll[k] = t_syz; |
syzAll[k] = t_syz; |
} |
} |
t_syz = syzAll; |
t_syz = syzAll; |
Print("Done. betti="); Println(betti); |
Sprint("Done. betti="); Sprintln(betti); |
/* Println(g); g is in a format such as |
/* Println(g); g is in a format such as |
[e_*x^2 , e_*x*y , 2*x*Dx*h , ...] |
[e_*x^2 , e_*x*y , 2*x*Dx*h , ...] |
[e_*x^2 , e_*x*y , 2*x*Dx*h , ...] |
[e_*x^2 , e_*x*y , 2*x*Dx*h , ...] |
Line 315 def StotalDegree(f) { |
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Line 450 def StotalDegree(f) { |
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return(d0); |
return(d0); |
} |
} |
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HelpAdd(["Sord_w", |
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["Sord_w(f,w) returns the w-order of f", |
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"Example: Sord_w(x^2*Dx*Dy,[x,-1,Dx,1]):"]]); |
/* Sord_w(x^2*Dx*Dy,[x,-1,Dx,1]); */ |
/* Sord_w(x^2*Dx*Dy,[x,-1,Dx,1]); */ |
def Sord_w(f,w) { |
def Sord_w(f,w) { |
local neww,i,n; |
local neww,i,n; |
Line 348 def test_SinitOfArray() { |
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Line 486 def test_SinitOfArray() { |
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f = [x^2+y^2+z^2, x*y+x*z+y*z, x*z^2+y*z^2, y^3-x^2*z - x*y*z+y*z^2, |
f = [x^2+y^2+z^2, x*y+x*z+y*z, x*z^2+y*z^2, y^3-x^2*z - x*y*z+y*z^2, |
-y^2*z^2 + x*z^3 + y*z^3, -z^4]; |
-y^2*z^2 + x*z^3 + y*z^3, -z^4]; |
p=SresolutionFrameWithTower(f); |
p=SresolutionFrameWithTower(f); |
sm1_pmat(p); |
if (Sverbose) { |
sm1_pmat(SgenerateTable(p[1])); |
sm1_pmat(p); |
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sm1_pmat(SgenerateTable(p[1])); |
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} |
return(p); |
return(p); |
frame = p[0]; |
frame = p[0]; |
sm1_pmat(p[1]); |
sm1_pmat(p[1]); |
Line 367 def Sdegree(f,tower,level) { |
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Line 507 def Sdegree(f,tower,level) { |
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f = Init(f); |
f = Init(f); |
if (level <= 1) return(StotalDegree(f)); |
if (level <= 1) return(StotalDegree(f)); |
i = Degree(f,es); |
i = Degree(f,es); |
#ifdef TOTAL_STRATEGY |
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return(StotalDegree(f)+Sdegree(tower[level-2,i],tower,level-1)); |
return(StotalDegree(f)+Sdegree(tower[level-2,i],tower,level-1)); |
#endif |
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/* Strategy must be compatible with ordering. */ |
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/* Weight vector must be non-negative, too. */ |
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/* See Sdegree, SgenerateTable, reductionTable. */ |
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wd = Sord_w(f,ww); |
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return(wd+Sdegree(tower[level-2,i],tower,level-1)); |
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} |
} |
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Line 382 def SgenerateTable(tower) { |
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Line 515 def SgenerateTable(tower) { |
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local height, n,i,j, ans, ans_at_each_floor; |
local height, n,i,j, ans, ans_at_each_floor; |
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/* |
/* |
Print("SgenerateTable: tower=");Println(tower); |
Sprint("SgenerateTable: tower=");Sprintln(tower); |
sm1(" print_switch_status "); */ |
sm1(" print_switch_status "); */ |
height = Length(tower); |
height = Length(tower); |
ans = NewArray(height); |
ans = NewArray(height); |
Line 467 def SlaScala(g,opt) { |
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Line 600 def SlaScala(g,opt) { |
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reductionTable_tmp; |
reductionTable_tmp; |
/* extern WeightOfSweyl; */ |
/* extern WeightOfSweyl; */ |
ww = WeightOfSweyl; |
ww = WeightOfSweyl; |
Print("WeightOfSweyl="); Println(WeightOfSweyl); |
Sprint("WeightOfSweyl="); Sprintln(WeightOfSweyl); |
rf = SresolutionFrameWithTower(g,opt); |
rf = SresolutionFrameWithTower(g,opt); |
Print("rf="); sm1_pmat(rf); |
Sprint("rf="); if (Sverbose) {sm1_pmat(rf);} |
redundant_seq = 1; redundant_seq_ordinary = 1; |
redundant_seq = 1; redundant_seq_ordinary = 1; |
tower = rf[1]; |
tower = rf[1]; |
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Println("Generating reduction table which gives an order of reduction."); |
Sprintln("Generating reduction table which gives an order of reduction."); |
Print("WeghtOfSweyl="); Println(WeightOfSweyl); |
Sprint("WeghtOfSweyl="); Sprintln(WeightOfSweyl); |
Print("tower"); Println(tower); |
Sprint2("tower="); Sprintln2(tower); |
reductionTable = SgenerateTable(tower); |
reductionTable = SgenerateTable(tower); |
Print("reductionTable="); sm1_pmat(reductionTable); |
Sprint2("reductionTable="); |
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if (Sverbose || Sverbose2) {sm1_pmat(reductionTable);} |
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skel = rf[2]; |
skel = rf[2]; |
redundantTable = SnewArrayOfFormat(rf[1]); |
redundantTable = SnewArrayOfFormat(rf[1]); |
Line 496 def SlaScala(g,opt) { |
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Line 630 def SlaScala(g,opt) { |
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while (SthereIs(reductionTable_tmp,strategy)) { |
while (SthereIs(reductionTable_tmp,strategy)) { |
i = SnextI(reductionTable_tmp,strategy,redundantTable, |
i = SnextI(reductionTable_tmp,strategy,redundantTable, |
skel,level,freeRes); |
skel,level,freeRes); |
Println([level,i]); |
Sprintln([level,i]); |
reductionTable_tmp[i] = -200000; |
reductionTable_tmp[i] = -200000; |
if (reductionTable[level,i] == strategy) { |
if (reductionTable[level,i] == strategy) { |
Print("Processing [level,i]= "); Print([level,i]); |
Sprint("Processing [level,i]= "); Sprint([level,i]); |
Print(" Strategy = "); Println(strategy); |
Sprint(" Strategy = "); Sprintln(strategy); |
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Sprint2(strategy); |
if (level == 0) { |
if (level == 0) { |
if (IsNull(redundantTable[level,i])) { |
if (IsNull(redundantTable[level,i])) { |
bases = freeRes[level]; |
bases = freeRes[level]; |
Line 520 def SlaScala(g,opt) { |
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Line 655 def SlaScala(g,opt) { |
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place = f[3]; |
place = f[3]; |
/* (level-1, place) is the place for f[0], |
/* (level-1, place) is the place for f[0], |
which is a newly obtained GB. */ |
which is a newly obtained GB. */ |
#ifdef ORDINARY |
if (Sordinary) { |
redundantTable[level-1,place] = redundant_seq; |
redundantTable[level-1,place] = redundant_seq; |
redundant_seq++; |
redundant_seq++; |
#else |
}else{ |
if (f[4] > f[5]) { |
if (f[4] > f[5]) { |
/* Zero in the gr-module */ |
/* Zero in the gr-module */ |
Print("v-degree of [org,remainder] = "); |
Sprint("v-degree of [org,remainder] = "); |
Println([f[4],f[5]]); |
Sprintln([f[4],f[5]]); |
Print("[level,i] = "); Println([level,i]); |
Sprint("[level,i] = "); Sprintln([level,i]); |
redundantTable[level-1,place] = 0; |
redundantTable[level-1,place] = 0; |
}else{ |
}else{ |
redundantTable[level-1,place] = redundant_seq; |
redundantTable[level-1,place] = redundant_seq; |
redundant_seq++; |
redundant_seq++; |
} |
} |
#endif |
} |
redundantTable_ordinary[level-1,place] |
redundantTable_ordinary[level-1,place] |
=redundant_seq_ordinary; |
=redundant_seq_ordinary; |
redundant_seq_ordinary++; |
redundant_seq_ordinary++; |
Line 560 def SlaScala(g,opt) { |
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Line 695 def SlaScala(g,opt) { |
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} |
} |
strategy++; |
strategy++; |
} |
} |
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Sprintln2(" "); |
n = Length(freeRes); |
n = Length(freeRes); |
freeResV = SnewArrayOfFormat(freeRes); |
freeResV = SnewArrayOfFormat(freeRes); |
for (i=0; i<n; i++) { |
for (i=0; i<n; i++) { |
Line 567 def SlaScala(g,opt) { |
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Line 703 def SlaScala(g,opt) { |
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bases = Sbases_to_vec(bases,bettiTable[i]); |
bases = Sbases_to_vec(bases,bettiTable[i]); |
freeResV[i] = bases; |
freeResV[i] = bases; |
} |
} |
return([freeResV, redundantTable,reducer,bettiTable,redundantTable_ordinary]); |
return([freeResV, redundantTable,reducer,bettiTable,redundantTable_ordinary,rf]); |
} |
} |
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def SthereIs(reductionTable_tmp,strategy) { |
def SthereIs(reductionTable_tmp,strategy) { |
Line 607 def SnextI(reductionTable_tmp,strategy,redundantTable, |
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Line 743 def SnextI(reductionTable_tmp,strategy,redundantTable, |
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} |
} |
} |
} |
} |
} |
Print("reductionTable_tmp="); |
Sprint("reductionTable_tmp="); |
Println(reductionTable_tmp); |
Sprintln(reductionTable_tmp); |
Println("See also reductionTable, strategy, level,i"); |
Sprintln("See also reductionTable, strategy, level,i"); |
Error("SnextI: bases[i] or bases[j] is null for all combinations."); |
Error("SnextI: bases[i] or bases[j] is null for all combinations."); |
} |
} |
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Line 643 def SwhereInGB(f,tower) { |
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Line 779 def SwhereInGB(f,tower) { |
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q = MonomialPart(f); |
q = MonomialPart(f); |
if (p == q) return(i); |
if (p == q) return(i); |
} |
} |
Println([f,tower]); |
Sprintln([f,tower]); |
Error("whereInGB : [f,myset]: f could not be found in the myset."); |
Error("whereInGB : [f,myset]: f could not be found in the myset."); |
} |
} |
def SunitOfFormat(pos,forms) { |
def SunitOfFormat(pos,forms) { |
Line 660 def SunitOfFormat(pos,forms) { |
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Line 796 def SunitOfFormat(pos,forms) { |
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return(ans); |
return(ans); |
} |
} |
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def Error(s) { |
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sm1(" s error "); |
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} |
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def IsNull(s) { |
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if (Stag(s) == 0) return(true); |
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else return(false); |
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} |
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def StowerOf(tower,level) { |
def StowerOf(tower,level) { |
local ans,i; |
local ans,i; |
ans = [ ]; |
ans = [ ]; |
Line 689 def Sspolynomial(f,g) { |
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Line 817 def Sspolynomial(f,g) { |
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sm1("f g spol /FunctionValue set"); |
sm1("f g spol /FunctionValue set"); |
} |
} |
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def MonomialPart(f) { |
|
sm1(" [(lmonom) f] gbext /FunctionValue set "); |
|
} |
|
|
|
/* WARNING: |
/* WARNING: |
When you use SwhereInTower, you have to change gbList |
When you use SwhereInTower, you have to change gbList |
Line 708 def SwhereInTower(f,tower) { |
|
Line 833 def SwhereInTower(f,tower) { |
|
q = MonomialPart(f); |
q = MonomialPart(f); |
if (p == q) return(i); |
if (p == q) return(i); |
} |
} |
Println([f,tower]); |
Sprintln([f,tower]); |
Error("[f,tower]: f could not be found in the tower."); |
Error("[f,tower]: f could not be found in the tower."); |
} |
} |
|
|
Line 720 def SpairAndReduction(skel,level,ii,freeRes,tower,ww) |
|
Line 845 def SpairAndReduction(skel,level,ii,freeRes,tower,ww) |
|
local i, j, myindex, p, bases, tower2, gi, gj, |
local i, j, myindex, p, bases, tower2, gi, gj, |
si, sj, tmp, t_syz, pos, ans, ssp, syzHead,pos2, |
si, sj, tmp, t_syz, pos, ans, ssp, syzHead,pos2, |
vdeg,vdeg_reduced; |
vdeg,vdeg_reduced; |
Println("SpairAndReduction:"); |
Sprintln("SpairAndReduction:"); |
|
|
if (level < 1) Error("level should be >= 1 in SpairAndReduction."); |
if (level < 1) Error("level should be >= 1 in SpairAndReduction."); |
p = skel[level,ii]; |
p = skel[level,ii]; |
myindex = p[0]; |
myindex = p[0]; |
i = myindex[0]; j = myindex[1]; |
i = myindex[0]; j = myindex[1]; |
bases = freeRes[level-1]; |
bases = freeRes[level-1]; |
Println(["p and bases ",p,bases]); |
Sprintln(["p and bases ",p,bases]); |
if (IsNull(bases[i]) || IsNull(bases[j])) { |
if (IsNull(bases[i]) || IsNull(bases[j])) { |
Println([level,i,j,bases[i],bases[j]]); |
Sprintln([level,i,j,bases[i],bases[j]]); |
Error("level, i, j : bases[i], bases[j] must not be NULL."); |
Error("level, i, j : bases[i], bases[j] must not be NULL."); |
} |
} |
|
|
tower2 = StowerOf(tower,level-1); |
tower2 = StowerOf(tower,level-1); |
SsetTower(tower2); |
SsetTower(tower2); |
Println(["level=",level]); |
Sprintln(["level=",level]); |
Println(["tower2=",tower2]); |
Sprintln(["tower2=",tower2]); |
/** sm1(" show_ring "); */ |
/** sm1(" show_ring "); */ |
|
|
gi = Stoes_vec(bases[i]); |
gi = Stoes_vec(bases[i]); |
Line 747 def SpairAndReduction(skel,level,ii,freeRes,tower,ww) |
|
Line 872 def SpairAndReduction(skel,level,ii,freeRes,tower,ww) |
|
sj = ssp[0,1]; |
sj = ssp[0,1]; |
syzHead = si*es^i; |
syzHead = si*es^i; |
/* This will be the head term, I think. But, double check. */ |
/* This will be the head term, I think. But, double check. */ |
Println([si*es^i,sj*es^j]); |
Sprintln([si*es^i,sj*es^j]); |
|
|
Print("[gi, gj] = "); Println([gi,gj]); |
Sprint("[gi, gj] = "); Sprintln([gi,gj]); |
sm1(" [(Homogenize)] system_variable message "); |
sm1(" [(Homogenize)] system_variable "); |
Print("Reduce the element "); Println(si*gi+sj*gj); |
Sprint("Reduce the element "); Sprintln(si*gi+sj*gj); |
Print("by "); Println(bases); |
Sprint("by "); Sprintln(bases); |
|
|
tmp = Sreduction(si*gi+sj*gj, bases); |
tmp = Sreduction(si*gi+sj*gj, bases); |
|
|
Print("result is "); Println(tmp); |
Sprint("result is "); Sprintln(tmp); |
|
|
/* This is essential part for V-minimal resolution. */ |
/* This is essential part for V-minimal resolution. */ |
/* vdeg = SvDegree(si*gi+sj*gj,tower,level-1,ww); */ |
/* vdeg = SvDegree(si*gi+sj*gj,tower,level-1,ww); */ |
vdeg = SvDegree(si*gi,tower,level-1,ww); |
vdeg = SvDegree(si*gi,tower,level-1,ww); |
vdeg_reduced = SvDegree(tmp[0],tower,level-1,ww); |
vdeg_reduced = SvDegree(tmp[0],tower,level-1,ww); |
Print("vdegree of the original = "); Println(vdeg); |
Sprint("vdegree of the original = "); Sprintln(vdeg); |
Print("vdegree of the remainder = "); Println(vdeg_reduced); |
Sprint("vdegree of the remainder = "); Sprintln(vdeg_reduced); |
|
|
t_syz = tmp[2]; |
t_syz = tmp[2]; |
si = si*tmp[1]+t_syz[i]; |
si = si*tmp[1]+t_syz[i]; |
Line 779 def SpairAndReduction(skel,level,ii,freeRes,tower,ww) |
|
Line 904 def SpairAndReduction(skel,level,ii,freeRes,tower,ww) |
|
ans = [tmp[0],t_syz,pos,pos2,vdeg,vdeg_reduced]; |
ans = [tmp[0],t_syz,pos,pos2,vdeg,vdeg_reduced]; |
/* pos is the place to put syzygy at level. */ |
/* pos is the place to put syzygy at level. */ |
/* pos2 is the place to put a new GB at level-1. */ |
/* pos2 is the place to put a new GB at level-1. */ |
Println(ans); |
Sprintln(ans); |
return(ans); |
return(ans); |
} |
} |
|
|
Line 812 def Sreduction(f,myset) { |
|
Line 937 def Sreduction(f,myset) { |
|
return([tmp[0],tmp[1],t_syz]); |
return([tmp[0],tmp[1],t_syz]); |
} |
} |
|
|
def Warning(s) { |
|
Print("Warning: "); |
|
Println(s); |
|
} |
|
def RingOf(f) { |
|
local r; |
|
if (IsPolynomial(f)) { |
|
if (f != Poly("0")) { |
|
sm1(f," (ring) dc /r set "); |
|
}else{ |
|
sm1(" [(CurrentRingp)] system_variable /r set "); |
|
} |
|
}else{ |
|
Warning("RingOf(f): the argument f must be a polynomial. Return the current ring."); |
|
sm1(" [(CurrentRingp)] system_variable /r set "); |
|
} |
|
return(r); |
|
} |
|
|
|
def Sfrom_es(f,size) { |
def Sfrom_es(f,size) { |
local c,ans, i, d, myes, myee, j,n,r,ans2; |
local c,ans, i, d, myes, myee, j,n,r,ans2; |
Line 888 def Sbases_to_vec(bases,size) { |
|
Line 995 def Sbases_to_vec(bases,size) { |
|
} |
} |
|
|
HelpAdd(["Sminimal", |
HelpAdd(["Sminimal", |
["It constructs the V-minimal free resolution by LaScala-Stillman's algorithm", |
["It constructs the V-minimal free resolution by LaScala's algorithm", |
"option: \"homogenized\" (no automatic homogenization ", |
"option: \"homogenized\" (no automatic homogenization)", |
|
" : \"Sordinary\" (no (u,v)-minimal resolution)", |
|
"Options should be given as an array.", |
"Example: Sweyl(\"x,y\",[[\"x\",-1,\"y\",-1,\"Dx\",1,\"Dy\",1]]);", |
"Example: Sweyl(\"x,y\",[[\"x\",-1,\"y\",-1,\"Dx\",1,\"Dy\",1]]);", |
" v=[[2*x*Dx + 3*y*Dy+6, 0],", |
" v=[[2*x*Dx + 3*y*Dy+6, 0],", |
" [3*x^2*Dy + 2*y*Dx, 0],", |
" [3*x^2*Dy + 2*y*Dx, 0],", |
Line 904 HelpAdd(["Sminimal", |
|
Line 1013 HelpAdd(["Sminimal", |
|
def Sminimal(g,opt) { |
def Sminimal(g,opt) { |
local r, freeRes, redundantTable, reducer, maxLevel, |
local r, freeRes, redundantTable, reducer, maxLevel, |
minRes, seq, maxSeq, level, betti, q, bases, dr, |
minRes, seq, maxSeq, level, betti, q, bases, dr, |
betti_levelplus, newbases, i, j,qq, tminRes; |
betti_levelplus, newbases, i, j,qq, tminRes,bettiTable, ansSminimal; |
if (Length(Arglist) < 2) { |
if (Length(Arglist) < 2) { |
opt = null; |
opt = null; |
} |
} |
|
/* Sordinary is set in SlaScala(g,opt) --> SresolutionFrameWithTower */ |
|
|
ScheckIfSchreyer("Sminimal:0"); |
ScheckIfSchreyer("Sminimal:0"); |
r = SlaScala(g,opt); |
r = SlaScala(g,opt); |
/* Should I turn off the tower?? */ |
/* Should I turn off the tower?? */ |
Line 915 def Sminimal(g,opt) { |
|
Line 1026 def Sminimal(g,opt) { |
|
freeRes = r[0]; |
freeRes = r[0]; |
redundantTable = r[1]; |
redundantTable = r[1]; |
reducer = r[2]; |
reducer = r[2]; |
|
bettiTable = SbettiTable(redundantTable); |
|
Sprintln2("BettiTable ------"); |
|
if (Sverbose || Sverbose2) {sm1_pmat(bettiTable);} |
minRes = SnewArrayOfFormat(freeRes); |
minRes = SnewArrayOfFormat(freeRes); |
seq = 0; |
seq = 0; |
maxSeq = SgetMaxSeq(redundantTable); |
maxSeq = SgetMaxSeq(redundantTable); |
Line 924 def Sminimal(g,opt) { |
|
Line 1038 def Sminimal(g,opt) { |
|
} |
} |
seq=maxSeq+1; |
seq=maxSeq+1; |
while (seq > 1) { |
while (seq > 1) { |
seq--; |
seq--; Sprint2(seq); |
for (level = 0; level < maxLevel; level++) { |
for (level = 0; level < maxLevel; level++) { |
betti = Length(freeRes[level]); |
betti = Length(freeRes[level]); |
for (q = 0; q<betti; q++) { |
for (q = 0; q<betti; q++) { |
if (redundantTable[level,q] == seq) { |
if (redundantTable[level,q] == seq) { |
Print("[seq,level,q]="); Println([seq,level,q]); |
Sprint("[seq,level,q]="); Sprintln([seq,level,q]); |
if (level < maxLevel-1) { |
if (level < maxLevel-1) { |
bases = freeRes[level+1]; |
bases = freeRes[level+1]; |
dr = reducer[level,q]; |
dr = reducer[level,q]; |
Line 942 def Sminimal(g,opt) { |
|
Line 1056 def Sminimal(g,opt) { |
|
for (i=0; i<betti_levelplus; i++) { |
for (i=0; i<betti_levelplus; i++) { |
newbases[i] = bases[i] + bases[i,q]*dr; |
newbases[i] = bases[i] + bases[i,q]*dr; |
} |
} |
Println(["level, q =", level,q]); |
Sprintln(["level, q =", level,q]); |
Println("bases="); sm1_pmat(bases); |
Sprintln("bases="); if (Sverbose) {sm1_pmat(bases); } |
Println("dr="); sm1_pmat(dr); |
Sprintln("dr="); if (Sverbose) {sm1_pmat(dr);} |
Println("newbases="); sm1_pmat(newbases); |
Sprintln("newbases="); if (Sverbose) {sm1_pmat(newbases);} |
minRes[level+1] = newbases; |
minRes[level+1] = newbases; |
freeRes = minRes; |
freeRes = minRes; |
#ifdef DEBUG |
#ifdef DEBUG |
Line 955 def Sminimal(g,opt) { |
|
Line 1069 def Sminimal(g,opt) { |
|
for (i=0; i<betti_levelplus; i++) { |
for (i=0; i<betti_levelplus; i++) { |
if (!IsZero(newbases[i,qq])) { |
if (!IsZero(newbases[i,qq])) { |
Println(["[i,qq]=",[i,qq]," is not zero in newbases."]); |
Println(["[i,qq]=",[i,qq]," is not zero in newbases."]); |
Print("redundantTable ="); sm1_pmat(redundantTable[level]); |
Sprint("redundantTable ="); sm1_pmat(redundantTable[level]); |
Error("Stop in Sminimal for debugging."); |
Error("Stop in Sminimal for debugging."); |
} |
} |
} |
} |
Line 968 def Sminimal(g,opt) { |
|
Line 1082 def Sminimal(g,opt) { |
|
} |
} |
} |
} |
tminRes = Stetris(minRes,redundantTable); |
tminRes = Stetris(minRes,redundantTable); |
return([SpruneZeroRow(tminRes), tminRes, |
ansSminimal = [SpruneZeroRow(tminRes), tminRes, |
[ minRes, redundantTable, reducer,r[3],r[4]],r[0]]); |
[ minRes, redundantTable, reducer,r[3],r[4]],r[0],r[5]]; |
|
Sprintln2(" "); |
|
Println("------------ Note -----------------------------"); |
|
Println("To get shift vectors, use Reparse and SgetShifts(resmat,w)"); |
|
Println("To get initial of the complex, use Reparse and Sinit_w(resmat,w)"); |
|
Println("0: minimal resolution, 3: Schreyer resolution "); |
|
Println("------------ Resolution Summary --------------"); |
|
Print("Betti numbers : "); |
|
Println(Join([Length(ansSminimal[0,0,0])],Map(ansSminimal[0],"Length"))); |
|
Print("Betti numbers of the Schreyer frame: "); |
|
Println(Join([Length(ansSminimal[3,0,0])],Map(ansSminimal[3],"Length"))); |
|
Println("-----------------------------------------------"); |
|
|
|
sm1(" restoreEnvAfterResolution "); |
|
Sordinary = false; |
|
|
|
return(ansSminimal); |
/* r[4] is the redundantTable_ordinary */ |
/* r[4] is the redundantTable_ordinary */ |
/* r[0] is the freeResolution */ |
/* r[0] is the freeResolution */ |
|
/* r[5] is the skelton */ |
} |
} |
|
|
|
|
Line 1040 def Stetris(freeRes,redundantTable) { |
|
Line 1171 def Stetris(freeRes,redundantTable) { |
|
}else{ |
}else{ |
newbases = bases; |
newbases = bases; |
} |
} |
Println(["level=", level]); |
Sprintln(["level=", level]); |
sm1_pmat(bases); |
if (Sverbose){ |
sm1_pmat(newbases); |
sm1_pmat(bases); |
|
sm1_pmat(newbases); |
|
} |
|
|
minRes[level] = newbases; |
minRes[level] = newbases; |
} |
} |
Line 1104 def Sannfs2(f) { |
|
Line 1237 def Sannfs2(f) { |
|
local p,pp; |
local p,pp; |
p = Sannfs(f,"x,y"); |
p = Sannfs(f,"x,y"); |
sm1(" p 0 get { [(x) (y) (Dx) (Dy)] laplace0 } map /p set "); |
sm1(" p 0 get { [(x) (y) (Dx) (Dy)] laplace0 } map /p set "); |
/* |
|
Sweyl("x,y",[["x",1,"y",1,"Dx",1,"Dy",1,"h",1], |
|
["x",-1,"y",-1,"Dx",1,"Dy",1]]); */ |
|
/* Sweyl("x,y",[["x",1,"y",1,"Dx",1,"Dy",1,"h",1]]); */ |
|
|
|
Sweyl("x,y",[["x",-1,"y",-1,"Dx",1,"Dy",1]]); |
Sweyl("x,y",[["x",-1,"y",-1,"Dx",1,"Dy",1]]); |
pp = Map(p,"Spoly"); |
pp = Map(p,"Spoly"); |
return(Sminimal_v(pp)); |
return(Sminimal(pp)); |
/* return(Sminimal(pp)); */ |
|
} |
} |
|
|
HelpAdd(["Sannfs2", |
HelpAdd(["Sannfs2", |
["Sannfs2(f) constructs the V-minimal free resolution for the weight (-1,1)", |
["Sannfs2(f) constructs the V-minimal free resolution for the weight (-1,1)", |
"of the Laplace transform of the annihilating ideal of the polynomial f in x,y.", |
"of the Laplace transform of the annihilating ideal of the polynomial f in x,y.", |
"See also Sminimal_v, Sannfs3.", |
"See also Sminimal, Sannfs3.", |
"Example: a=Sannfs2(\"x^3-y^2\");", |
"Example: a=Sannfs2(\"x^3-y^2\");", |
" b=a[0]; sm1_pmat(b);", |
" b=a[0]; sm1_pmat(b);", |
" b[1]*b[0]:", |
" b[1]*b[0]:", |
Line 1126 HelpAdd(["Sannfs2", |
|
Line 1253 HelpAdd(["Sannfs2", |
|
" b=a[0]; sm1_pmat(b);", |
" b=a[0]; sm1_pmat(b);", |
" b[1]*b[0]:" |
" b[1]*b[0]:" |
]]); |
]]); |
|
/* Some samples. |
|
The betti numbers of most examples are 2,1. (0-th and 1-th). |
|
a=Sannfs2("x*y*(x+y-1)"); ==> The betti numbers are 3, 2. |
|
a=Sannfs2("x^3-y^2-x"); |
|
a=Sannfs2("x*y*(x-y)"); |
|
*/ |
|
|
/* Do not forget to turn on TOTAL_STRATEGY */ |
|
def Sannfs2_laScala(f) { |
|
local p,pp; |
|
p = Sannfs(f,"x,y"); |
|
/* Do not make laplace transform. |
|
sm1(" p 0 get { [(x) (y) (Dx) (Dy)] laplace0 } map /p set "); |
|
p = [p]; |
|
*/ |
|
Sweyl("x,y",[["x",-1,"y",-1,"Dx",1,"Dy",1]]); |
|
pp = Map(p[0],"Spoly"); |
|
return(Sminimal(pp)); |
|
} |
|
|
|
def Sannfs2_laScala2(f) { |
|
local p,pp; |
|
p = Sannfs(f,"x,y"); |
|
sm1(" p 0 get { [(x) (y) (Dx) (Dy)] laplace0 } map /p set "); |
|
p = [p]; |
|
Sweyl("x,y",[["x",1,"y",1,"Dx",1,"Dy",1,"h",1], |
|
["x",-1,"y",-1,"Dx",1,"Dy",1]]); |
|
pp = Map(p[0],"Spoly"); |
|
return(Sminimal(pp)); |
|
} |
|
|
|
def Sannfs3(f) { |
def Sannfs3(f) { |
local p,pp; |
local p,pp; |
p = Sannfs(f,"x,y,z"); |
p = Sannfs(f,"x,y,z"); |
sm1(" p 0 get { [(x) (y) (z) (Dx) (Dy) (Dz)] laplace0 } map /p set "); |
sm1(" p 0 get { [(x) (y) (z) (Dx) (Dy) (Dz)] laplace0 } map /p set "); |
Sweyl("x,y,z",[["x",-1,"y",-1,"z",-1,"Dx",1,"Dy",1,"Dz",1]]); |
Sweyl("x,y,z",[["x",-1,"y",-1,"z",-1,"Dx",1,"Dy",1,"Dz",1]]); |
pp = Map(p,"Spoly"); |
pp = Map(p,"Spoly"); |
return(Sminimal_v(pp)); |
return(Sminimal(pp)); |
} |
} |
|
|
HelpAdd(["Sannfs3", |
HelpAdd(["Sannfs3", |
["Sannfs3(f) constructs the V-minimal free resolution for the weight (-1,1)", |
["Sannfs3(f) constructs the V-minimal free resolution for the weight (-1,1)", |
"of the Laplace transform of the annihilating ideal of the polynomial f in x,y,z.", |
"of the Laplace transform of the annihilating ideal of the polynomial f in x,y,z.", |
"See also Sminimal_v, Sannfs2.", |
"See also Sminimal, Sannfs2.", |
"Example: a=Sannfs3(\"x^3-y^2*z^2\");", |
"Example: a=Sannfs3(\"x^3-y^2*z^2\");", |
" b=a[0]; sm1_pmat(b);", |
" b=a[0]; sm1_pmat(b);", |
" b[1]*b[0]: b[2]*b[1]:"]]); |
" b[1]*b[0]: b[2]*b[1]:"]]); |
|
|
/* |
|
The betti numbers of most examples are 2,1. (0-th and 1-th). |
|
a=Sannfs2("x*y*(x+y-1)"); ==> The betti numbers are 3, 2. |
|
a=Sannfs2("x^3-y^2-x"); : it causes an error. It should be fixed. |
|
a=Sannfs2("x*y*(x-y)"); : it causes an error. It should be fixed. |
|
|
|
*/ |
|
|
|
def Sannfs3_laScala2(f) { |
|
local p,pp; |
|
p = Sannfs(f,"x,y,z"); |
|
sm1(" p 0 get { [(x) (y) (z) (Dx) (Dy) (Dz)] laplace0 } map /p set "); |
|
Sweyl("x,y,z",[["x",1,"y",1,"z",1,"Dx",1,"Dy",1,"Dz",1,"h",1], |
|
["x",-1,"y",-1,"z",-1,"Dx",1,"Dy",1,"Dz",1]]); |
|
pp = Map(p,"Spoly"); |
|
return(Sminimal(pp)); |
|
} |
|
|
|
|
|
/* The below does not use LaScala-Stillman's algorithm. */ |
|
def Sschreyer(g) { |
|
local rf, tower, reductionTable, skel, redundantTable, bases, |
|
strategy, maxOfStrategy, height, level, n, i, |
|
freeRes,place, f, reducer,pos, redundant_seq,bettiTable,freeResV,ww, |
|
redundantTable_ordinary, redundant_seq_ordinary, |
|
reductionTable_tmp,c2,ii,nn, m,ii, jj, reducerBase; |
|
/* extern WeightOfSweyl; */ |
|
ww = WeightOfSweyl; |
|
Print("WeghtOfSweyl="); Println(WeightOfSweyl); |
|
rf = SresolutionFrameWithTower(g); |
|
redundant_seq = 1; redundant_seq_ordinary = 1; |
|
tower = rf[1]; |
|
Println("Generating reduction table which gives an order of reduction."); |
|
Println("But, you are in Sschreyer...., you may not use LaScala-Stillman"); |
|
Print("WeghtOfSweyl="); Println(WeightOfSweyl); |
|
Print("tower"); Println(tower); |
|
reductionTable = SgenerateTable(tower); |
|
skel = rf[2]; |
|
redundantTable = SnewArrayOfFormat(rf[1]); |
|
redundantTable_ordinary = SnewArrayOfFormat(rf[1]); |
|
reducer = SnewArrayOfFormat(rf[1]); |
|
freeRes = SnewArrayOfFormat(rf[1]); |
|
bettiTable = SsetBettiTable(rf[1],g); |
|
|
|
height = Length(reductionTable); |
|
for (level = 0; level < height; level++) { |
|
n = Length(reductionTable[level]); |
|
for (i=0; i<n; i++) { |
|
Println([level,i]); |
|
Print("Processing "); Print([level,i]); |
|
if (level == 0) { |
|
if (IsNull(redundantTable[level,i])) { |
|
bases = freeRes[level]; |
|
/* Println(["At floor : GB=",i,bases,tower[0,i]]); */ |
|
pos = SwhereInGB(tower[0,i],rf[3,0]); |
|
bases[i] = rf[3,0,pos]; |
|
/* redundantTable[level,i] = 0; |
|
redundantTable_ordinary[level,i] = 0; */ |
|
freeRes[level] = bases; |
|
/* Println(["GB=",i,bases,tower[0,i]]); */ |
|
} |
|
}else{ /* level >= 1 */ |
|
if (IsNull(redundantTable[level,i])) { |
|
bases = freeRes[level]; |
|
f = SpairAndReduction2(skel,level,i,freeRes,tower, |
|
ww,redundantTable); |
|
if (f[0] != Poly("0")) { |
|
place = f[3]; |
|
/* (level-1, place) is the place for f[0], |
|
which is a newly obtained GB. */ |
|
#ifdef ORDINARY |
|
redundantTable[level-1,place] = redundant_seq; |
|
redundant_seq++; |
|
#else |
|
if (f[4] > f[5]) { |
|
/* Zero in the gr-module */ |
|
Print("v-degree of [org,remainder] = "); |
|
Println([f[4],f[5]]); |
|
Print("[level,i] = "); Println([level,i]); |
|
redundantTable[level-1,place] = 0; |
|
}else{ |
|
redundantTable[level-1,place] = redundant_seq; |
|
redundant_seq++; |
|
} |
|
#endif |
|
redundantTable_ordinary[level-1,place] |
|
=redundant_seq_ordinary; |
|
redundant_seq_ordinary++; |
|
bases[i] = SunitOfFormat(place,f[1])-f[1]; /* syzygy */ |
|
/* redundantTable[level,i] = 0; |
|
redundantTable_ordinary[level,i] = 0; */ |
|
/* i must be equal to f[2], I think. Double check. */ |
|
|
|
/* Correction Of Constant */ |
|
/* Correction of syzygy */ |
|
c2 = f[6]; /* or -f[6]? Double check. */ |
|
Print("c2="); Println(c2); |
|
nn = Length(bases); |
|
for (ii=0; ii<nn;ii++) { |
|
if ((ii != i) && (! IsNull(bases[ii]))) { |
|
m = Length(bases[ii]); |
|
for (jj=0; jj<m; jj++) { |
|
if (jj != place) { |
|
bases[ii,jj] = bases[ii,jj]*c2; |
|
} |
|
} |
|
} |
|
} |
|
|
|
Print("Old freeRes[level] = "); sm1_pmat(freeRes[level]); |
|
freeRes[level] = bases; |
|
Print("New freeRes[level] = "); sm1_pmat(freeRes[level]); |
|
|
|
/* Update the freeRes[level-1] */ |
|
Print("Old freeRes[level-1] = "); sm1_pmat(freeRes[level-1]); |
|
bases = freeRes[level-1]; |
|
bases[place] = f[0]; |
|
freeRes[level-1] = bases; |
|
Print("New freeRes[level-1] = "); sm1_pmat(freeRes[level-1]); |
|
|
|
reducer[level-1,place] = f[1]-SunitOfFormat(place,f[1]); |
|
/* This reducer is different from that of SlaScala(). */ |
|
|
|
reducerBasis = reducer[level-1]; |
|
nn = Length(reducerBasis); |
|
for (ii=0; ii<nn;ii++) { |
|
if ((ii != place) && (! IsNull(reducerBasis[ii]))) { |
|
m = Length(reducerBasis[ii]); |
|
for (jj=0; jj<m; jj++) { |
|
if (jj != place) { |
|
reducerBasis[ii,jj] = reducerBasis[ii,jj]*c2; |
|
} |
|
} |
|
} |
|
} |
|
reducer[level-1] = reducerBasis; |
|
|
|
}else{ |
|
/* redundantTable[level,i] = 0; */ |
|
bases = freeRes[level]; |
|
bases[i] = f[1]; /* Put the syzygy. */ |
|
freeRes[level] = bases; |
|
} |
|
} /* end of level >= 1 */ |
|
} |
|
} /* i loop */ |
|
|
|
/* Triangulate reducer */ |
|
if (level >= 1) { |
|
Println(" "); |
|
Print("Triangulating reducer at level "); Println(level-1); |
|
Println("freeRes[level]="); sm1_pmat(freeRes[level]); |
|
reducerBase = reducer[level-1]; |
|
Print("reducerBase="); Println(reducerBase); |
|
Println("Compare freeRes[level] and reducerBase (put -1)"); |
|
m = Length(reducerBase); |
|
for (ii=m-1; ii>=0; ii--) { |
|
if (!IsNull(reducerBase[ii])) { |
|
for (jj=ii-1; jj>=0; jj--) { |
|
if (!IsNull(reducerBase[jj])) { |
|
if (!IsZero(reducerBase[jj,ii])) { |
|
/* reducerBase[ii,ii] should be always constant. */ |
|
reducerBase[jj] = reducerBase[ii,ii]*reducerBase[jj]-reducerBase[jj,ii]*reducerBase[ii]; |
|
} |
|
} |
|
} |
|
} |
|
} |
|
Println("New reducer"); |
|
sm1_pmat(reducerBase); |
|
reducer[level-1] = reducerBase; |
|
} |
|
|
|
} /* level loop */ |
|
n = Length(freeRes); |
|
freeResV = SnewArrayOfFormat(freeRes); |
|
for (i=0; i<n; i++) { |
|
bases = freeRes[i]; |
|
bases = Sbases_to_vec(bases,bettiTable[i]); |
|
freeResV[i] = bases; |
|
} |
|
|
|
/* Mark the non-redundant elements. */ |
|
for (i=0; i<n; i++) { |
|
m = Length(redundantTable[i]); |
|
for (jj=0; jj<m; jj++) { |
|
if (IsNull(redundantTable[i,jj])) { |
|
redundantTable[i,jj] = 0; |
|
} |
|
} |
|
} |
|
|
|
|
|
return([freeResV, redundantTable,reducer,bettiTable,redundantTable_ordinary]); |
|
} |
|
|
|
def SpairAndReduction2(skel,level,ii,freeRes,tower,ww,redundantTable) { |
|
local i, j, myindex, p, bases, tower2, gi, gj, |
|
si, sj, tmp, t_syz, pos, ans, ssp, syzHead,pos2, |
|
vdeg,vdeg_reduced,n,c2; |
|
Println("SpairAndReduction2 : -------------------------"); |
|
|
|
if (level < 1) Error("level should be >= 1 in SpairAndReduction."); |
|
p = skel[level,ii]; |
|
myindex = p[0]; |
|
i = myindex[0]; j = myindex[1]; |
|
bases = freeRes[level-1]; |
|
Println(["p and bases ",p,bases]); |
|
if (IsNull(bases[i]) || IsNull(bases[j])) { |
|
Println([level,i,j,bases[i],bases[j]]); |
|
Error("level, i, j : bases[i], bases[j] must not be NULL."); |
|
} |
|
|
|
tower2 = StowerOf(tower,level-1); |
|
SsetTower(tower2); |
|
Println(["level=",level]); |
|
Println(["tower2=",tower2]); |
|
/** sm1(" show_ring "); */ |
|
|
|
gi = Stoes_vec(bases[i]); |
|
gj = Stoes_vec(bases[j]); |
|
|
|
ssp = Sspolynomial(gi,gj); |
|
si = ssp[0,0]; |
|
sj = ssp[0,1]; |
|
syzHead = si*es^i; |
|
/* This will be the head term, I think. But, double check. */ |
|
Println([si*es^i,sj*es^j]); |
|
|
|
Print("[gi, gj] = "); Println([gi,gj]); |
|
sm1(" [(Homogenize)] system_variable message "); |
|
Print("Reduce the element "); Println(si*gi+sj*gj); |
|
Print("by "); Println(bases); |
|
|
|
tmp = Sreduction(si*gi+sj*gj, bases); |
|
|
|
Print("result is "); Println(tmp); |
|
if (!IsZero(tmp[0])) { |
|
Print("Error: base = "); |
|
Println(Map(bases,"Stoes_vec")); |
|
Error("SpairAndReduction2: the remainder should be zero. See tmp. tower2. show_ring."); |
|
} |
|
t_syz = tmp[2]; |
|
si = si*tmp[1]+t_syz[i]; |
|
sj = sj*tmp[1]+t_syz[j]; |
|
t_syz[i] = si; |
|
t_syz[j] = sj; |
|
|
|
c2 = null; |
|
/* tmp[0] must be zero */ |
|
n = Length(t_syz); |
|
for (i=0; i<n; i++) { |
|
if (IsConstant(t_syz[i])){ |
|
if (!IsZero(t_syz[i])) { |
|
if (IsNull(redundantTable[level-1,i])) { |
|
/* i must equal to pos2 below. */ |
|
c2 = -t_syz[i]; |
|
tmp[0] = c2*Stoes_vec(freeRes[level-1,i]); |
|
t_syz[i] = 0; |
|
/* tmp[0] = t_syz . g */ |
|
/* break; does not work. Use */ |
|
i = n; |
|
} |
|
} |
|
} |
|
} |
|
|
|
/* This is essential part for V-minimal resolution. */ |
|
/* vdeg = SvDegree(si*gi+sj*gj,tower,level-1,ww); */ |
|
vdeg = SvDegree(si*gi,tower,level-1,ww); |
|
vdeg_reduced = SvDegree(tmp[0],tower,level-1,ww); |
|
Print("vdegree of the original = "); Println(vdeg); |
|
Print("vdegree of the remainder = "); Println(vdeg_reduced); |
|
|
|
if (!IsNull(vdeg_reduced)) { |
|
if (vdeg_reduced < vdeg) { |
|
Println("--- Special in V-minimal!"); |
|
Println(tmp[0]); |
|
Println("syzygy="); sm1_pmat(t_syz); |
|
Print("[vdeg, vdeg_reduced] = "); Println([vdeg,vdeg_reduced]); |
|
} |
|
} |
|
|
|
SsetTower(StowerOf(tower,level)); |
|
pos = SwhereInTower(syzHead,tower[level]); |
|
|
|
SsetTower(StowerOf(tower,level-1)); |
|
pos2 = SwhereInTower(tmp[0],tower[level-1]); |
|
ans = [tmp[0],t_syz,pos,pos2,vdeg,vdeg_reduced,c2]; |
|
/* pos is the place to put syzygy at level. */ |
|
/* pos2 is the place to put a new GB at level-1. */ |
|
Println(ans); |
|
Println("--- end of SpairAndReduction2 "); |
|
return(ans); |
|
} |
|
|
|
HelpAdd(["Sminimal_v", |
|
["It constructs the V-minimal free resolution from the Schreyer resolution", |
|
"step by step.", |
|
"This code still contains bugs. It sometimes outputs wrong answer.", |
|
"Example: Sweyl(\"x,y\",[[\"x\",-1,\"y\",-1,\"Dx\",1,\"Dy\",1]]);", |
|
" v=[[2*x*Dx + 3*y*Dy+6, 0],", |
|
" [3*x^2*Dy + 2*y*Dx, 0],", |
|
" [0, x^2+y^2],", |
|
" [0, x*y]];", |
|
" a=Sminimal_v(v);", |
|
" sm1_pmat(a[0]); b=a[0]; b[1]*b[0]:", |
|
"Note: a[0] is the V-minimal resolution. a[3] is the Schreyer resolution."]]); |
|
|
|
/* This code still contains bugs. It sometimes outputs wrong answer. */ |
|
/* See test12() in minimal-test.k. */ |
|
/* There may be remaining 1, too */ |
|
def Sminimal_v(g) { |
|
local r, freeRes, redundantTable, reducer, maxLevel, |
|
minRes, seq, maxSeq, level, betti, q, bases, dr, |
|
betti_levelplus, newbases, i, j,qq,tminRes; |
|
r = Sschreyer(g); |
|
sm1_pmat(r); |
|
Debug_Sminimal_v = r; |
|
Println(" Return value of Schreyer(g) is set to Debug_Sminimal_v"); |
|
/* Should I turn off the tower?? */ |
|
freeRes = r[0]; |
|
redundantTable = r[1]; |
|
reducer = r[2]; |
|
minRes = SnewArrayOfFormat(freeRes); |
|
seq = 0; |
|
maxSeq = SgetMaxSeq(redundantTable); |
|
maxLevel = Length(freeRes); |
|
for (level = 0; level < maxLevel; level++) { |
|
minRes[level] = freeRes[level]; |
|
} |
|
for (level = 0; level < maxLevel; level++) { |
|
betti = Length(freeRes[level]); |
|
for (q = betti-1; q>=0; q--) { |
|
if (redundantTable[level,q] > 0) { |
|
Print("[seq,level,q]="); Println([seq,level,q]); |
|
if (level < maxLevel-1) { |
|
bases = freeRes[level+1]; |
|
dr = reducer[level,q]; |
|
/* dr[q] = -1; We do not need this in our reducer format. */ |
|
/* dr[q] should be a non-zero constant. */ |
|
newbases = SnewArrayOfFormat(bases); |
|
betti_levelplus = Length(bases); |
|
/* |
|
bases[i,j] ---> bases[i,j]+bases[i,q]*dr[j] |
|
*/ |
|
for (i=0; i<betti_levelplus; i++) { |
|
newbases[i] = dr[q]*bases[i] - bases[i,q]*dr; |
|
} |
|
Println(["level, q =", level,q]); |
|
Println("bases="); sm1_pmat(bases); |
|
Println("dr="); sm1_pmat(dr); |
|
Println("newbases="); sm1_pmat(newbases); |
|
minRes[level+1] = newbases; |
|
freeRes = minRes; |
|
#ifdef DEBUG |
|
for (qq=q; qq<betti; qq++) { |
|
for (i=0; i<betti_levelplus; i++) { |
|
if ((!IsZero(newbases[i,qq])) && (redundantTable[level,qq] >0)) { |
|
Println(["[i,qq]=",[i,qq]," is not zero in newbases."]); |
|
Print("redundantTable ="); sm1_pmat(redundantTable[level]); |
|
Error("Stop in Sminimal for debugging."); |
|
} |
|
} |
|
} |
|
#endif |
|
} |
|
} |
|
} |
|
} |
|
tminRes = Stetris(minRes,redundantTable); |
|
return([SpruneZeroRow(tminRes), tminRes, |
|
[ minRes, redundantTable, reducer,r[3],r[4]],r[0]]); |
|
/* r[4] is the redundantTable_ordinary */ |
|
/* r[0] is the freeResolution */ |
|
} |
|
|
|
/* Sannfs2("x*y*(x-y)*(x+y)"); is a test problem */ |
/* Sannfs2("x*y*(x-y)*(x+y)"); is a test problem */ |
/* x y (x+y-1)(x-2), x^3-y^2, x^3 - y^2 z^2, |
/* x y (x+y-1)(x-2), x^3-y^2, x^3 - y^2 z^2, |
x y z (x+y+z-1) seems to be interesting, because the first syzygy |
x y z (x+y+z-1) seems to be interesting, because the first syzygy |
Line 1687 def Skernel(m,v) { |
|
Line 1422 def Skernel(m,v) { |
|
sm1(" [ m v ] syz /FunctionValue set "); |
sm1(" [ m v ] syz /FunctionValue set "); |
} |
} |
|
|
def test3() { |
|
local a1,a2,b1,b2; |
|
a1 = Sannfs3("x^3-y^2*z^2"); |
|
a1 = a1[0]; |
|
a2 = Sannfs3_laScala2("x^3-y^2*z^2"); |
|
a2 = a2[0]; |
|
b1 = a1[1]; |
|
b2 = a2[1]; |
|
sm1_pmat(b2); |
|
Println(" OVER "); |
|
sm1_pmat(b1); |
|
return([sm1_res_div(b2,b1,["x","y","z"]),b2,b1,a2,a1]); |
|
} |
|
|
|
def test4() { |
|
local a,b; |
|
a = Sannfs3_laScala2("x^3-y^2*z^2"); |
|
b = a[0]; |
|
sm1_pmat( sm1_res_kernel_image(b[0],b[1],[x,y,z])); |
|
sm1_pmat( sm1_res_kernel_image(b[1],b[2],[x,y,z])); |
|
return(a); |
|
} |
|
|
|
def sm1_gb(f,v) { |
def sm1_gb(f,v) { |
f =ToString_array(f); |
f =ToString_array(f); |
v = ToString_array(v); |
v = ToString_array(v); |
Line 1750 HelpAdd(["IsExact_h", |
|
Line 1463 HelpAdd(["IsExact_h", |
|
"cf. ReParse" |
"cf. ReParse" |
]]); |
]]); |
|
|
|
def IsSameIdeal_h(ii,jj,v) { |
|
local a; |
|
v = ToString_array(v); |
|
a = [ii,jj,v]; |
|
sm1(a," isSameIdeal_h /FunctionValue set "); |
|
} |
|
HelpAdd(["IsSameIdeal_h", |
|
["IsSameIdeal_h(ii,jj,var): bool", |
|
"It checks the given ideals are the same or not in D<h> (homogenized Weyl algebra)", |
|
"cf. ReParse" |
|
]]); |
|
|
def ReParse(a) { |
def ReParse(a) { |
local c; |
local c; |
if (IsArray(a)) { |
if (IsArray(a)) { |
Line 1784 def ScheckIfSchreyer(s) { |
|
Line 1509 def ScheckIfSchreyer(s) { |
|
*/ |
*/ |
sm1(" [(Schreyer)] system_variable (universalNumber) dc /ss set "); |
sm1(" [(Schreyer)] system_variable (universalNumber) dc /ss set "); |
if (ss != 1) { |
if (ss != 1) { |
Print("ScheckIfSchreyer: from "); Println(s); |
Print("ScheckIfSchreyer: from "); Printl(s); |
Error("Schreyer order is not set."); |
Error("Schreyer order is not set."); |
} |
} |
/* More check will be necessary. */ |
/* More check will be necessary. */ |
return(true); |
return(true); |
} |
|
|
|
|
} |
|
|
|
def SgetShift(mat,w,m) { |
|
local omat; |
|
sm1(" mat { w m ord_w<m> {(universalNumber) dc}map } map /omat set"); |
|
return(Map(omat,"Max")); |
|
} |
|
HelpAdd(["SgetShift", |
|
["SgetShift(mat,w,m) returns the shift vector of mat with respect to w with the shift m.", |
|
"Note that the order of the ring and the weight w must be the same.", |
|
"Example: Sweyl(\"x,y\",[[\"x\",-1,\"Dx\",1]]); ", |
|
" SgetShift([[x*Dx+1,Dx^2+x^5],[Poly(\"0\"),x],[x,x]],[\"x\",-1,\"Dx\",1],[2,0]):"]]); |
|
|
|
def SgetShifts(resmat,w) { |
|
local i,n,ans,m0; |
|
n = Length(resmat); |
|
ans = NewArray(n+1); |
|
m0 = NewArray(Length(resmat[0,0])); |
|
ans[0] = m0; |
|
for (i=0; i<n; i++) { |
|
ans[i+1] = SgetShift(resmat[i],w,m0); |
|
m0 = ans[i+1]; |
|
} |
|
return(ans); |
|
} |
|
HelpAdd(["SgetShifts", |
|
["SgetShifts(resmat,w) returns the shift vectors of the resolution resmat", |
|
" with respect to w with the shift m.", |
|
"Note that the order of the ring and the weight w must be the same.", |
|
"Zero row is not allowed.", |
|
"Example: a=Sannfs2(\"x^3-y^2\");", |
|
" b=a[0]; w = [\"x\",-1,\"y\",-1,\"Dx\",1,\"Dy\",1];", |
|
" Sweyl(\"x,y\",[w]); b = Reparse(b);", |
|
" SgetShifts(b,w):"]]); |
|
|
|
def Sinit_w(resmat,w) { |
|
local shifts,ans,n,i,m,mat,j; |
|
shifts = SgetShifts(resmat,w); |
|
n = Length(resmat); |
|
ans = NewArray(n); |
|
for (i=0; i<n; i++) { |
|
m = shifts[i]; |
|
mat = ScopyArray(resmat[i]); |
|
for (j=0; j<Length(mat); j++) { |
|
mat[j] = Init_w_m(mat[j],w,m); |
|
} |
|
ans[i] = mat; |
|
} |
|
return(ans); |
|
} |
|
HelpAdd(["Sinit_w", |
|
["Sinit_w(resmat,w) returns the initial of the complex resmat with respect to the weight w.", |
|
"Example: a=Sannfs2(\"x^3-y^2\");", |
|
" b=a[0]; w = [\"x\",-1,\"y\",-1,\"Dx\",1,\"Dy\",1];", |
|
" Sweyl(\"x,y\",[w]); b = Reparse(b);", |
|
" c=Sinit_w(b,w); c:" |
|
]]); |
|
|
|
/* This method does not work, because we have zero rows. |
|
Think about it later. */ |
|
def SbettiTable(rtable) { |
|
local ans,i,j,pp; |
|
ans = SnewArrayOfFormat(rtable); |
|
for (i=0; i<Length(rtable); i++) { |
|
pp = 0; |
|
for (j=0; j<Length(rtable[i]); j++) { |
|
if (rtable[i,j] != 0) {pp = pp+1;} |
|
} |
|
ans[i] = pp; |
|
} |
|
return(ans); |
|
} |
|
|
|
def BfRoots1(G,V) { |
|
local bb,ans; |
|
sm1(" /BFparlist [ ] def "); |
|
if (IsString(V)) { |
|
sm1(" [ V to_records pop ] /V set "); |
|
}else { |
|
sm1(" V { toString } map /V set "); |
|
} |
|
sm1(" /BFvarlist V def "); |
|
|
|
sm1(" G flatten { toString } map /G set "); |
|
sm1(" G V bfm /bb set "); |
|
if (IsSm1Integer(bb)) { |
|
return([ ]); |
|
} |
|
sm1(" bb 0 get findIntegralRoots { (universalNumber) dc } map /ans set "); |
|
return([ans, bb]); |
|
} |
|
|
|
HelpAdd(["BfRoots1", |
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["BfRoots1(g,v) returns the integral roots of g with respect to the weight", |
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"vector (1,1,...,1) and the b-function itself", |
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"Example: BfRoots1([x*Dx-2, y*Dy-3],[x,y]);" |
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]]); |
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