OpenXM/src/k097/lib/minimal/minimal.k - diff

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Diff for /OpenXM/src/k097/lib/minimal/minimal.k between version 1.8 and 1.16

-version 1.8, 2000/05/06 10:45:43
+version 1.16, 2000/06/15 07:38:36
 Line 1
 Line 1
 Line 1
- /* $OpenXM: OpenXM/src/k097/lib/minimal/minimal.k,v 1.7 2000/05/06 10:35:33 takayama Exp $ */
+ /* $OpenXM: OpenXM/src/k097/lib/minimal/minimal.k,v 1.15 2000/06/14 07:44:05 takayama Exp $ */
  #define DEBUG 1
  /* #define ORDINARY 1 */
  /* If you run this program on openxm version 1.1.2 (FreeBSD),
 Line 6
 Line 6
 Line 6
     ln -s /usr/bin/cpp /lib/cpp
  */
  #define OFFSET 0
- #define TOTAL_STRATEGY
+ #define TOTAL_STRATEGY 1
  /* #define OFFSET 20*/
  /* Test sequences.
     Use load["minimal.k"];;
 Line 132  sm1(" [(AvoidTheSameRing)] pushEnv
 Line 132  sm1(" [(AvoidTheSameRing)] pushEnv
 Line 132  sm1(" [(AvoidTheSameRing)] pushEnv
        [ [(AvoidTheSameRing) 0] system_variable
          [(gbListTower) tower (list) dc] system_variable
        ] pop popEnv ");
+       /* sm1("(hoge) message show_ring "); */
  }
  def SresolutionFrameWithTower(g,opt) {
    local gbTower, ans, ff, count, startingGB, opts, skelton,withSkel, autof,
-         gbasis;
+         gbasis, nohomog;
+   nohomog = false;
+   count = -1;
    if (Length(Arglist) >= 2) {
-     if (IsInteger(opt)) count = opt;
+     if (IsInteger(opt)) {
+       count = opt;
+     }else if (IsString(opt)) {
+       if (opt == "homogenized") {
+          nohomog = true;
+       }else{
+          Println("Warning: unknown option");
+          Println(opt);
+       }
+     }
    }else{
      count = -1;
    }
-Line 152  def SresolutionFrameWithTower(g,opt) {
+Line 164  def SresolutionFrameWithTower(g,opt) {
 Line 152  def SresolutionFrameWithTower(g,opt) {
 Line 164  def SresolutionFrameWithTower(g,opt) {
    */
    sm1(" (mmLarger) (matrix) switch_function ");
-   g = Map(g,"Shomogenize");
+   if (! nohomog) {
+     Println("Automatic homogenization.");
+     g = Map(g,"Shomogenize");
+   }else{
+     Println("No automatic homogenization.");
+   }
    if (SonAutoReduce) {
      sm1("[ (AutoReduce) ] system_variable /autof set ");
      sm1("[ (AutoReduce) 1 ] system_variable ");
-Line 192  def SresolutionFrameWithTower(g,opt) {
+Line 209  def SresolutionFrameWithTower(g,opt) {
 Line 192  def SresolutionFrameWithTower(g,opt) {
 Line 209  def SresolutionFrameWithTower(g,opt) {
  }
  HelpAdd(["SresolutionFrameWithTower",
  ["It returs [resolution of the initial, gbTower, skelton, gbasis]",
+  "option: \"homogenized\" (no automatic homogenization) ",
   "Example: Sweyl(\"x,y\");",
   "         a=SresolutionFrameWithTower([x^3,x*y,y^3-1]);"]]);
  def SresolutionFrame(f,opt) {
    local ans;
-   ans = SresolutionFrameWithTower(f);
+   ans = SresolutionFrameWithTower(f,opt);
    return(ans[0]);
  }
  /* ---------------------------- */
-Line 291  def Sres0FrameWithSkelton(g) {
+Line 309  def Sres0FrameWithSkelton(g) {
 Line 291  def Sres0FrameWithSkelton(g) {
 Line 309  def Sres0FrameWithSkelton(g) {
  def StotalDegree(f) {
-   sm1(" [(grade) f] gbext (universalNumber) dc /FunctionValue set ");
+   local d0;
+   sm1(" [(grade) f] gbext (universalNumber) dc /d0 set ");
+   /* Print("degree of "); Print(f); Print(" is "); Println(d0); */
+   return(d0);
  }
  /* Sord_w(x^2*Dx*Dy,[x,-1,Dx,1]); */
-Line 359  def Sdegree(f,tower,level) {
+Line 380  def Sdegree(f,tower,level) {
 Line 359  def Sdegree(f,tower,level) {
 Line 380  def Sdegree(f,tower,level) {
  def SgenerateTable(tower) {
    local height, n,i,j, ans, ans_at_each_floor;
+   /*
+   Print("SgenerateTable: tower=");Println(tower);
+   sm1(" print_switch_status "); */
    height = Length(tower);
    ans = NewArray(height);
    for (i=0; i<height; i++) {
-Line 434  def SmaxOfStrategy(a) {
+Line 459  def SmaxOfStrategy(a) {
 Line 434  def SmaxOfStrategy(a) {
 Line 459  def SmaxOfStrategy(a) {
  }
- def SlaScala(g) {
+ def SlaScala(g,opt) {
    local rf, tower, reductionTable, skel, redundantTable, bases,
          strategy, maxOfStrategy, height, level, n, i,
          freeRes,place, f, reducer,pos, redundant_seq,bettiTable,freeResV,ww,
-Line 443  def SlaScala(g) {
+Line 468  def SlaScala(g) {
 Line 443  def SlaScala(g) {
 Line 468  def SlaScala(g) {
    /* extern WeightOfSweyl; */
    ww = WeightOfSweyl;
    Print("WeightOfSweyl="); Println(WeightOfSweyl);
-   rf = SresolutionFrameWithTower(g);
+   rf = SresolutionFrameWithTower(g,opt);
+   Print("rf="); sm1_pmat(rf);
    redundant_seq = 1;   redundant_seq_ordinary = 1;
    tower = rf[1];
+   Println("Generating reduction table which gives an order of reduction.");
+   Print("WeghtOfSweyl="); Println(WeightOfSweyl);
+   Print("tower"); Println(tower);
    reductionTable = SgenerateTable(tower);
+   Print("reductionTable="); sm1_pmat(reductionTable);
    skel = rf[2];
    redundantTable = SnewArrayOfFormat(rf[1]);
    redundantTable_ordinary = SnewArrayOfFormat(rf[1]);
-Line 467  def SlaScala(g) {
+Line 499  def SlaScala(g) {
 Line 467  def SlaScala(g) {
 Line 499  def SlaScala(g) {
          Println([level,i]);
          reductionTable_tmp[i] = -200000;
          if (reductionTable[level,i] == strategy) {
-            Print("Processing "); Print([level,i]);
+            Print("Processing [level,i]= "); Print([level,i]);
             Print("   Strategy = "); Println(strategy);
             if (level == 0) {
               if (IsNull(redundantTable[level,i])) {
-Line 661  def MonomialPart(f) {
+Line 693  def MonomialPart(f) {
 Line 661  def MonomialPart(f) {
 Line 693  def MonomialPart(f) {
    sm1(" [(lmonom) f] gbext /FunctionValue set ");
  }
+ /* WARNING:
+   When you use SwhereInTower, you have to change gbList
+   as below. Ofcourse, you should restrore the gbList
+   SsetTower(StowerOf(tower,level));
+   pos = SwhereInTower(syzHead,tower[level]);
+ */
  def SwhereInTower(f,tower) {
    local i,n,p,q;
    if (f == Poly("0")) return(-1);
-Line 697  def SpairAndReduction(skel,level,ii,freeRes,tower,ww)
+Line 735  def SpairAndReduction(skel,level,ii,freeRes,tower,ww)
 Line 697  def SpairAndReduction(skel,level,ii,freeRes,tower,ww)
 Line 735  def SpairAndReduction(skel,level,ii,freeRes,tower,ww)
    tower2 = StowerOf(tower,level-1);
    SsetTower(tower2);
+   Println(["level=",level]);
+   Println(["tower2=",tower2]);
    /** sm1(" show_ring ");   */
    gi = Stoes_vec(bases[i]);
-Line 730  def SpairAndReduction(skel,level,ii,freeRes,tower,ww)
+Line 770  def SpairAndReduction(skel,level,ii,freeRes,tower,ww)
 Line 730  def SpairAndReduction(skel,level,ii,freeRes,tower,ww)
 Line 770  def SpairAndReduction(skel,level,ii,freeRes,tower,ww)
    sj = sj*tmp[1]+t_syz[j];
    t_syz[i] = si;
    t_syz[j] = sj;
+   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];
    /* pos is the place to put syzygy at level. */
-Line 843  def Sbases_to_vec(bases,size) {
+Line 887  def Sbases_to_vec(bases,size) {
 Line 843  def Sbases_to_vec(bases,size) {
 Line 887  def Sbases_to_vec(bases,size) {
    return(newbases);
  }
- def Sminimal(g) {
+ HelpAdd(["Sminimal",
+ ["It constructs the V-minimal free resolution by LaScala-Stillman's algorithm",
+  "option: \"homogenized\" (no automatic homogenization ",
+  "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);",
+  "         Sweyl(\"x,y\",[[\"x\",-1,\"y\",-1,\"Dx\",1,\"Dy\",1]]);",
+  "         b = ReParse(a[0]); sm1_pmat(b); ",
+  "         IsExact_h(b,[x,y]):",
+  "Note:  a[0] is the V-minimal resolution. a[3] is the Schreyer resolution."]]);
+ def Sminimal(g,opt) {
    local r, freeRes, redundantTable, reducer, maxLevel,
          minRes, seq, maxSeq, level, betti, q, bases, dr,
-         betti_levelplus, newbases, i, j,qq;
+         betti_levelplus, newbases, i, j,qq, tminRes;
-   r = SlaScala(g);
+   if (Length(Arglist) < 2) {
+      opt = null;
+   }
+   ScheckIfSchreyer("Sminimal:0");
+   r = SlaScala(g,opt);
    /* Should I turn off the tower?? */
+   ScheckIfSchreyer("Sminimal:1");
    freeRes = r[0];
    redundantTable = r[1];
    reducer = r[2];
-Line 904  def Sminimal(g) {
+Line 967  def Sminimal(g) {
 Line 904  def Sminimal(g) {
 Line 967  def Sminimal(g) {
        }
      }
     }
-    return([Stetris(minRes,redundantTable),
+    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 */
-Line 1044  def Sannfs2(f) {
+Line 1108  def Sannfs2(f) {
 Line 1044  def Sannfs2(f) {
 Line 1108  def Sannfs2(f) {
    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]]);
    pp = Map(p,"Spoly");
    return(Sminimal_v(pp));
    /* return(Sminimal(pp)); */
  }
+ HelpAdd(["Sannfs2",
+ ["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.",
+  "See also Sminimal_v, Sannfs3.",
+  "Example: a=Sannfs2(\"x^3-y^2\");",
+  "         b=a[0]; sm1_pmat(b);",
+  "         b[1]*b[0]:",
+  "Example: a=Sannfs2(\"x*y*(x-y)*(x+y)\");",
+  "         b=a[0]; sm1_pmat(b);",
+  "         b[1]*b[0]:"
+ ]]);
  /* Do not forget to turn on TOTAL_STRATEGY */
  def Sannfs2_laScala(f) {
    local p,pp;
-Line 1063  def Sannfs2_laScala(f) {
+Line 1140  def Sannfs2_laScala(f) {
 Line 1063  def Sannfs2_laScala(f) {
 Line 1140  def Sannfs2_laScala(f) {
    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) {
    local p,pp;
    p = Sannfs(f,"x,y,z");
-Line 1072  def Sannfs3(f) {
+Line 1160  def Sannfs3(f) {
 Line 1072  def Sannfs3(f) {
 Line 1160  def Sannfs3(f) {
    return(Sminimal_v(pp));
  }
+ HelpAdd(["Sannfs3",
+ ["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.",
+  "See also Sminimal_v, Sannfs2.",
+  "Example: a=Sannfs3(\"x^3-y^2*z^2\");",
+  "         b=a[0]; sm1_pmat(b);",
+  "         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.
-Line 1080  def Sannfs3(f) {
+Line 1176  def Sannfs3(f) {
 Line 1080  def Sannfs3(f) {
 Line 1176  def Sannfs3(f) {
  */
+ 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. */
-Line 1095  def Sschreyer(g) {
+Line 1200  def Sschreyer(g) {
 Line 1095  def Sschreyer(g) {
 Line 1200  def Sschreyer(g) {
    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]);
-Line 1153  def Sschreyer(g) {
+Line 1262  def Sschreyer(g) {
 Line 1153  def Sschreyer(g) {
 Line 1262  def Sschreyer(g) {
                    /* 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);
-Line 1178  def Sschreyer(g) {
+Line 1288  def Sschreyer(g) {
 Line 1178  def Sschreyer(g) {
 Line 1288  def Sschreyer(g) {
                    freeRes[level-1] = bases;
                    Print("New freeRes[level-1] = "); sm1_pmat(freeRes[level-1]);
-                   reducer[level-1,place] = f[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];
-Line 1193  def Sschreyer(g) {
+Line 1319  def Sschreyer(g) {
 Line 1193  def Sschreyer(g) {
 Line 1319  def Sschreyer(g) {
      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[jj] = reducerBase[jj]-reducerBase[jj,ii]*reducerBase[ii];
+                 /* reducerBase[ii,ii] should be always constant. */
+                 reducerBase[jj] = reducerBase[ii,ii]*reducerBase[jj]-reducerBase[jj,ii]*reducerBase[ii];
                }
               }
             }
-Line 1254  def SpairAndReduction2(skel,level,ii,freeRes,tower,ww,
+Line 1383  def SpairAndReduction2(skel,level,ii,freeRes,tower,ww,
 Line 1254  def SpairAndReduction2(skel,level,ii,freeRes,tower,ww,
 Line 1383  def SpairAndReduction2(skel,level,ii,freeRes,tower,ww,
    tower2 = StowerOf(tower,level-1);
    SsetTower(tower2);
+   Println(["level=",level]);
+   Println(["tower2=",tower2]);
    /** sm1(" show_ring ");   */
    gi = Stoes_vec(bases[i]);
-Line 1311  def SpairAndReduction2(skel,level,ii,freeRes,tower,ww,
+Line 1442  def SpairAndReduction2(skel,level,ii,freeRes,tower,ww,
 Line 1311  def SpairAndReduction2(skel,level,ii,freeRes,tower,ww,
 Line 1442  def SpairAndReduction2(skel,level,ii,freeRes,tower,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("  ");
+   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;
+         betti_levelplus, newbases, i, j,qq,tminRes;
    r = Sschreyer(g);
    sm1_pmat(r);
    Debug_Sminimal_v = r;
-Line 1348  def Sminimal_v(g) {
+Line 1507  def Sminimal_v(g) {
 Line 1348  def Sminimal_v(g) {
 Line 1507  def Sminimal_v(g) {
            if (level < maxLevel-1) {
              bases = freeRes[level+1];
              dr = reducer[level,q];
-             dr[q] = -1;
+             /* 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] = bases[i] + bases[i,q]*dr;
+               newbases[i] = dr[q]*bases[i] - bases[i,q]*dr;
              }
              Println(["level, q =", level,q]);
              Println("bases="); sm1_pmat(bases);
-Line 1364  def Sminimal_v(g) {
+Line 1524  def Sminimal_v(g) {
 Line 1364  def Sminimal_v(g) {
 Line 1524  def Sminimal_v(g) {
              minRes[level+1] = newbases;
              freeRes = minRes;
  #ifdef DEBUG
- /*  Do it later.
+             for (qq=q; qq<betti; qq++) {
-             for (qq=0; qq<betti; qq++) {
                  for (i=0; i<betti_levelplus; i++) {
-                   if (!IsZero(newbases[i,qq])) {
+                   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
            }
          }
        }
     }
-    return([Stetris(minRes,redundantTable),
+    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 */
+ /* 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
+   contains 1.
+ */
+ def CopyArray(m) {
+   local ans,i,n;
+   if (IsArray(m)) {
+      n = Length(m);
+      ans = NewArray(n);
+      for (i=0; i<n; i++) {
+        ans[i] = CopyArray(m[i]);
+      }
+      return(ans);
+   }else{
+      return(m);
+   }
+ }
+ HelpAdd(["CopyArray",
+ ["It duplicates the argument array recursively.",
+  "Example: m=[1,[2,3]];",
+  "         a=CopyArray(m); a[1] = \"Hello\";",
+  "         Println(m); Println(a);"]]);
+ def IsZeroVector(m) {
+   local n,i;
+   n = Length(m);
+   for (i=0; i<n; i++) {
+     if (!IsZero(m[i])) {
+       return(false);
+     }
+   }
+   return(true);
+ }
+ def SpruneZeroRow(res) {
+   local minRes, n,i,j,m, base,base2,newbase,newbase2, newMinRes;
+   minRes = CopyArray(res);
+   n = Length(minRes);
+   for (i=0; i<n; i++) {
+     base = minRes[i];
+     m = Length(base);
+     if (i != n-1) {
+       base2 = minRes[i+1];
+       base2 = Transpose(base2);
+     }
+     newbase = [ ];
+     newbase2 = [ ];
+     for (j=0; j<m; j++) {
+       if (!IsZeroVector(base[j])) {
+         newbase = Append(newbase,base[j]);
+         if (i != n-1) {
+           newbase2 = Append(newbase2,base2[j]);
+         }
+       }
+     }
+     minRes[i] = newbase;
+     if (i != n-1) {
+       if (newbase2 == [ ]) {
+         minRes[i+1] = [ ];
+       }else{
+         minRes[i+1] = Transpose(newbase2);
+       }
+     }
+   }
+   newMinRes = [ ];
+   n = Length(minRes);
+   i = 0;
+   while (i < n ) {
+     base = minRes[i];
+     if (base == [ ]) {
+       i = n; /* break; */
+     }else{
+       newMinRes = Append(newMinRes,base);
+     }
+     i++;
+   }
+   return(newMinRes);
+ }
+ def testAnnfs2(f) {
+   local a,i,n;
+   a = Sannfs2(f);
+   b=a[0];
+   n = Length(b);
+   Println("------ V-minimal free resolution -----");
+   sm1_pmat(b);
+   Println("----- Is it complex?  ---------------");
+   for (i=0; i<n-1; i++) {
+     Println(b[i+1]*b[i]);
+   }
+   return(a);
+ }
+ def testAnnfs3(f) {
+   local a,i,n;
+   a = Sannfs3(f);
+   b=a[0];
+   n = Length(b);
+   Println("------ V-minimal free resolution -----");
+   sm1_pmat(b);
+   Println("----- Is it complex?  ---------------");
+   for (i=0; i<n-1; i++) {
+     Println(b[i+1]*b[i]);
+   }
+   return(a);
+ }
+ def ToString_array(p) {
+   local ans;
+   if (IsArray(p)) {
+     ans = Map(p,"ToString_array");
+   }else{
+     ans = ToString(p);
+   }
+   return(ans);
+ }
+ /* sm1_res_div([[x],[y]],[[x^2],[x*y],[y^2]],[x,y]): */
+ def sm1_res_div(I,J,V) {
+   I = ToString_array(I);
+   J = ToString_array(J);
+   V = ToString_array(V);
+   sm1(" [[ I J]  V ] res*div /FunctionValue set ");
+ }
+ /* It has not yet been working */
+ def sm1_res_kernel_image(m,n,v) {
+   m = ToString_array(m);
+   n = ToString_array(n);
+   v = ToString_array(v);
+   sm1(" [m n v] res-kernel-image /FunctionValue set ");
+ }
+ def Skernel(m,v) {
+   m = ToString_array(m);
+   v = ToString_array(v);
+   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) {
+   f =ToString_array(f);
+   v = ToString_array(v);
+   sm1(" [f v] gb /FunctionValue set ");
+ }
+ def SisComplex(a) {
+   local n,i,j,k,b,p,q;
+   n = Length(a);
+   for (i=0; i<n-1; i++) {
+     if (Length(a[i+1]) != 0) {
+       b = a[i+1]*a[i];
+       p = Length(b); q = Length(b[0]);
+       for (j=0; j<p; j++) {
+         for (k=0; k<q; k++) {
+           if (!IsZero(b[j,k])) {
+              Print("Is is not complex at ");
+              Println([i,j,k]);
+              return(false);
+           }
+         }
+       }
+     }
+   }
+   return(true);
+ }
+ def IsExact_h(c,v) {
+   local a;
+   v = ToString_array(v);
+   a = [c,v];
+   sm1(a," isExact_h /FunctionValue set ");
+ }
+ HelpAdd(["IsExact_h",
+ ["IsExact_h(complex,var): bool",
+  "It checks the given complex is exact or not in D<h> (homogenized Weyl algebra)",
+  "cf. ReParse"
+ ]]);
+ def ReParse(a) {
+   local c;
+   if (IsArray(a)) {
+     c = Map(a,"ReParse");
+   }else{
+     sm1(a," toString . /c set");
+   }
+   return(c);
+ }
+ HelpAdd(["ReParse",
+ ["Reparse(obj): obj",
+  "It parses the given object in the current ring.",
+  "Outputs from SlaScala, Sschreyer may cause a trouble in other functions,",
+  "because it uses the Schreyer order.",
+  "In this case, ReParse the outputs from these functions.",
+  "cf. IsExaxt_h"
+ ]]);
+ def ScheckIfSchreyer(s) {
+   local ss;
+   sm1(" (report) (grade) switch_function /ss set ");
+   if (ss != "module1v") {
+      Print("ScheckIfSchreyer: from "); Println(s);
+      Error("grade is not module1v");
+   }
+   /*
+   sm1(" (report) (mmLarger) switch_function /ss set ");
+   if (ss != "tower") {
+      Print("ScheckIfSchreyer: from "); Println(s);
+      Error("mmLarger is not tower");
+   }
+   */
+   sm1(" [(Schreyer)] system_variable (universalNumber) dc /ss set ");
+   if (ss != 1) {
+      Print("ScheckIfSchreyer: from "); Println(s);
+      Error("Schreyer order is not set.");
+   }
+   /* More check will be necessary. */
+   return(true);
+ }

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