1 | /////////////////////////////////////////////////////////////////////////////// |
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2 | version="$Id$"; |
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3 | category="Symbolic-numerical solving"; |
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4 | info=" |
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5 | LIBRARY: presolve.lib Pre-Solving of Polynomial Equations |
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6 | AUTHOR: Gert-Martin Greuel, email: greuel@mathematik.uni-kl.de, |
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7 | |
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8 | PROCEDURES: |
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9 | degreepart(id,d1,d2); elements of id of total degree >= d1 and <= d2, and rest |
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10 | elimlinearpart(id); linear part eliminated from id |
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11 | elimpart(id[,n]); partial elimination of vars [among first n vars] |
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12 | elimpartanyr(i,p); factors of p partially eliminated from i in any ring |
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13 | fastelim(i,p[..]); fast elimination of factors of p from i [options] |
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14 | findvars(id[..]); ideal of variables occuring in id [more information] |
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15 | hilbvec(id[,c,o]); intvec of Hilberseries of id [in char c and ord o] |
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16 | linearpart(id); elements of id of total degree <=1 |
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17 | tolessvars(id[,]); maps id to new basering having only vars occuring in id |
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18 | solvelinearpart(id); reduced std-basis of linear part of id |
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19 | sortandmap(id[..]); map to new basering with vars sorted w.r.t. complexity |
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20 | sortvars(id[n1,p1..]); sort vars w.r.t. complexity in id [different blocks] |
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21 | valvars(id[..]); valuation of vars w.r.t. to their complexity in id |
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22 | idealSplit(id,tF,fS); a list of ideals such that their intersection |
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23 | has the same radical as id |
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24 | ( parameters in square brackets [] are optional) |
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25 | "; |
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26 | |
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27 | LIB "inout.lib"; |
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28 | LIB "general.lib"; |
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29 | LIB "matrix.lib"; |
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30 | LIB "ring.lib"; |
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31 | LIB "elim.lib"; |
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32 | /////////////////////////////////////////////////////////////////////////////// |
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33 | proc shortid (id,int n,list #) |
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34 | "USAGE: shortid(id,n[,e]); id= ideal/module, n,e=integers |
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35 | RETURN: - if called with two arguments or e=0: |
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36 | @* same type as id, containing generators of id having <= n terms. |
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37 | @* - if called with three arguments and e!=0: |
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38 | @* a list L: |
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39 | @* L[1]: same type as id, containing generators of id having <= n terms. |
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40 | @* L[2]: number of corresponding generator of id |
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41 | NOTE: May be used to compute partial standard basis in case id is to hard |
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42 | EXAMPLE: example shortid; shows an example |
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43 | " |
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44 | { |
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45 | intvec v; |
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46 | int ii; |
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47 | for(ii=1; ii<=ncols(id); ii++) |
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48 | { |
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49 | if (size(id[ii]) <=n and id[ii]!=0 ) |
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50 | { |
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51 | v=v,ii; |
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52 | } |
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53 | if (size(id[ii]) > n ) |
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54 | { |
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55 | id[ii]=0; |
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56 | } |
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57 | } |
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58 | if( size(v)>1 ) |
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59 | { |
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60 | v = v[2..size(v)]; |
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61 | } |
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62 | id = simplify(id,2); |
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63 | list L = id,v; |
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64 | if ( size(#)==0 ) |
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65 | { |
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66 | return(id); |
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67 | } |
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68 | if ( size(#)!=0 ) |
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69 | { |
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70 | if(#[1]==0) |
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71 | { |
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72 | return(id); |
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73 | } |
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74 | if(#[1]!=0) |
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75 | { |
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76 | return(L); |
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77 | } |
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78 | } |
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79 | } |
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80 | example |
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81 | { "EXAMPLE:"; echo = 2; |
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82 | ring s=0,(x,y,z,w),dp; |
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83 | ideal i = (x3+y2+yw2)^2,(xz+z2)^2,xyz-w2-xzw; |
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84 | shortid(i,3); |
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85 | } |
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86 | /////////////////////////////////////////////////////////////////////////////// |
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87 | |
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88 | proc degreepart (id,int d1,int d2,list #) |
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89 | "USAGE: degreepart(id,d1,d2[,v]); id=ideal/module, d1,d1=integers, v=intvec |
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90 | RETURN: list of size 2, |
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91 | _[1]: generators of id of [v-weighted] total degree >= d1 and <= d2 |
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92 | (default: v = 1,...,1) |
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93 | _[2]: remaining generators of id |
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94 | NOTE: if id is of type int/number/poly it is converted to ideal, if id is |
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95 | of type intmat/matrix/vector to module and then the corresponding |
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96 | generators are computed |
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97 | EXAMPLE: example degreepart; shows an example |
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98 | " |
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99 | { |
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100 | if( typeof(id)=="int" or typeof(id)=="number" |
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101 | or typeof(id)=="ideal" or typeof(id)=="poly" ) |
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102 | { |
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103 | ideal dpart = ideal(id); |
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104 | } |
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105 | if( typeof(id)=="intmat" or typeof(id)=="matrix" |
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106 | or typeof(id)=="module" or typeof(id)=="vector") |
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107 | { |
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108 | module dpart = module(id); |
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109 | } |
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110 | |
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111 | def epart = dpart; |
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112 | int s,ii = ncols(id),0; |
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113 | if ( size(#)==0 ) |
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114 | { |
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115 | for ( ii=1; ii<=s; ii++ ) |
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116 | { |
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117 | dpart[ii] = (jet(id[ii],d1-1)==0)*(id[ii]==jet(id[ii],d2))*id[ii]; |
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118 | epart[ii] = (size(dpart[ii])==0) * id[ii]; |
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119 | } |
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120 | } |
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121 | else |
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122 | { |
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123 | for ( ii=1; ii<=s; ii=ii+1 ) |
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124 | { |
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125 | dpart[ii]=(jet(id[ii],d1-1,#[1])==0)*(id[ii]==jet(id[ii],d2,#[1]))*id[ii]; |
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126 | epart[ii] = (size(dpart[ii])==0)*id[ii]; |
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127 | } |
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128 | } |
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129 | list L = simplify(dpart,2),simplify(epart,2); |
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130 | return(L); |
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131 | } |
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132 | example |
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133 | { "EXAMPLE:"; echo = 2; |
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134 | ring r=0,(x,y,z),dp; |
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135 | ideal i=1+x+x2+x3+x4,3,xz+y3+z8; |
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136 | degreepart(i,0,4); |
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137 | |
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138 | module m=[x,y,z],x*[x3,y2,z],[1,x2,z3,0,1]; |
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139 | intvec v=2,3,6; |
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140 | show(degreepart(m,8,8,v)); |
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141 | } |
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142 | /////////////////////////////////////////////////////////////////////////////// |
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143 | |
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144 | proc linearpart (id) |
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145 | "USAGE: linearpart(id); id=ideal/module |
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146 | RETURN: list of size 2, |
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147 | _[1]: generators of id of total degree <= 1 |
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148 | _[2]: remaining generators of id |
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149 | NOTE: all variables have degree 1 (independent of ordering of basering) |
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150 | EXAMPLE: example linearpart; shows an example |
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151 | " |
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152 | { |
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153 | return(degreepart(id,0,1)); |
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154 | } |
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155 | example |
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156 | { "EXAMPLE:"; echo = 2; |
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157 | ring r=0,(x,y,z),dp; |
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158 | ideal i=1+x+x2+x3,3,x+3y+5z; |
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159 | linearpart(i); |
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160 | |
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161 | module m=[x,y,z],x*[x3,y2,z],[1,x2,z3,0,1]; |
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162 | show(linearpart(m)); |
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163 | } |
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164 | /////////////////////////////////////////////////////////////////////////////// |
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165 | |
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166 | proc elimlinearpart (ideal i,list #) |
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167 | "USAGE: elimlinearpart(i[,n]); i=ideal, n=integer,@* |
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168 | default: n=nvars(basering) |
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169 | RETURN: list L with 5 entries: |
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170 | @format |
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171 | L[1]: ideal obtained from i by substituting from the first n variables those |
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172 | which appear in a linear part of i, by putting this part into triangular |
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173 | form |
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174 | L[2]: ideal of variables which have been substituted |
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175 | L[3]: ideal, j-th element defines substitution of j-th var in [2] |
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176 | L[4]: ideal of variables of basering, eliminated ones are set to 0 |
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177 | L[5]: ideal, describing the map from the basering to itself such that |
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178 | L[1] is the image of i |
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179 | @end format |
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180 | NOTE: the procedure always interreduces the ideal i internally w.r.t. |
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181 | ordering dp. |
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182 | EXAMPLE: example elimlinearpart; shows an example |
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183 | " |
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184 | { |
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185 | int ii,n,k,ringchange; |
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186 | string o; |
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187 | intvec getoption = option(get); |
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188 | option(redSB); |
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189 | def BAS = basering; |
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190 | n = nvars(BAS); |
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191 | list gnirlist = ringlist(basering); |
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192 | list g3 = gnirlist[3]; |
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193 | list g32 = g3[size(g3)]; |
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194 | |
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195 | //---------------------------------- start ------------------------------------ |
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196 | if ( size(#)!=0 ) { n=#[1]; } |
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197 | ideal maxi,rest = maxideal(1),0; |
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198 | if ( n < nvars(BAS) ) |
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199 | { |
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200 | rest = maxi[n+1..nvars(BAS)]; //variables which are not substituted |
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201 | } |
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202 | attrib(rest,"isSB",1); |
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203 | |
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204 | //-------------------- find linear part and reduce rest ---------------------- |
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205 | // Perhaps for big systems, check only those generators of id |
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206 | // which do not contain elements not to be eliminated |
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207 | |
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208 | //ideal id = interred(i); |
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209 | //## gmg, geaendert 9/2008: interred sehr lange z.B. bei Leonard1 in normal, |
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210 | //daher interred ersetzt durch: std nur auf linearpart angewendet |
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211 | //Wechsel zu dp Ordnung (da Lin affin linear) |
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212 | |
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213 | //--------------- replace ordering different from dp by dp ------------------- |
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214 | o = "dp("+string(n)+")"; |
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215 | if( ! find(ordstr(BAS),o) or find(ordstr(BAS),"a") ) |
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216 | { |
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217 | ringchange = 1; //remember change of ring |
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218 | intvec V; |
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219 | V[n]=0; V=V+1; //weights for dp ordering |
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220 | gnirlist[3] = list("dp",V), g32; |
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221 | def newBAS = ring(gnirlist); //change of ring to dp ordering |
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222 | setring newBAS; |
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223 | ideal rest = imap(BAS,rest); |
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224 | attrib(rest,"isSB",1); |
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225 | ideal i = imap(BAS,i); |
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226 | } |
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227 | |
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228 | list Lin = linearpart(i); |
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229 | ideal lin = std(Lin[1]); //SB of ideal generated by polys of i |
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230 | //having at most degree 1 |
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231 | ideal id = Lin[2]; //remaining polys from i, of deg > 1 |
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232 | id = simplify(NF(id,lin),2); //instead of subst |
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233 | ideal id1 = linearpart(id)[1]; |
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234 | while( size(id1) != 0 ) //repeat to find linear parts |
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235 | { |
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236 | lin = lin,id1; |
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237 | lin = std(lin); |
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238 | id = simplify(NF(id,lin),2); //instead of subst, (### is faster) |
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239 | id1 = linearpart(id)[1]; |
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240 | } |
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241 | //------------- check for special case of unit ideal and return --------------- |
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242 | int check; |
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243 | if( lin[1] == 1 ) |
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244 | { |
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245 | check = 1; |
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246 | } |
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247 | else |
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248 | { |
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249 | for (ii=1; ii<=size(id); ii++ ) |
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250 | { |
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251 | if ( id[ii] == 1 ) |
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252 | { |
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253 | check = 1; break; |
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254 | } |
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255 | } |
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256 | } |
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257 | |
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258 | if (check == 1) //case of a unit ideal |
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259 | { |
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260 | setring BAS; |
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261 | list L = ideal(1), ideal(0), ideal(0), maxideal(1), maxideal(1); |
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262 | option(set,getoption); |
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263 | return(L); |
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264 | } |
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265 | //----- remove generators from lin containing vars not to be eliminated ------ |
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266 | if ( n < nvars(BAS) ) |
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267 | { |
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268 | for ( ii=1; ii<=size(lin); ii++ ) |
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269 | { |
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270 | if ( reduce(lead(lin[ii]),rest) == 0 ) |
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271 | { |
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272 | id=lin[ii],id; |
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273 | lin[ii] = 0; |
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274 | } |
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275 | } |
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276 | } |
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277 | lin = simplify(lin,1); |
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278 | ideal eva = lead(lin); //vars to be eliminated |
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279 | attrib(eva,"isSB",1); |
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280 | ideal neva = NF(maxideal(1),eva); //vars not to be eliminated |
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281 | //------------------ go back to original ring end return --------------------- |
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282 | |
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283 | if ( ringchange ) //i.e there was a ring change |
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284 | { |
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285 | setring BAS; |
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286 | ideal id = imap(newBAS,id); |
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287 | ideal eva = imap(newBAS,eva); |
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288 | ideal lin = imap(newBAS,lin); |
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289 | ideal neva = imap(newBAS,neva); |
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290 | } |
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291 | |
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292 | eva = eva[ncols(eva)..1]; // sorting according to variables in basering |
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293 | lin = lin[ncols(lin)..1]; |
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294 | ideal phi = neva; |
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295 | k = 1; |
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296 | for( ii=1; ii<=n; ii++ ) |
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297 | { |
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298 | if( neva[ii] == 0 ) |
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299 | { |
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300 | phi[ii] = eva[k]-lin[k]; |
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301 | k=k+1; |
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302 | } |
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303 | } |
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304 | |
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305 | list L = id, eva, lin, neva, phi; |
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306 | option(set,getoption); |
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307 | return(L); |
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308 | } |
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309 | example |
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310 | { "EXAMPLE:"; echo = 2; |
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311 | ring s=0,(u,x,y,z),dp; |
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312 | ideal i = u3+y3+z-x,x2y2+z3,y+z+1,y+u; |
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313 | elimlinearpart(i); |
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314 | } |
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315 | /////////////////////////////////////////////////////////////////////////////// |
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316 | proc elimpart (ideal i,list #) |
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317 | "USAGE: elimpart(i [,n,e] ); i=ideal, n,e=integers |
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318 | n : only the first n vars are considered for substitution,@* |
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319 | e =0: substitute from linear part of i (same as elimlinearpart)@* |
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320 | e!=0: eliminate also by direct substitution@* |
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321 | (default: n = nvars(basering), e = 1) |
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322 | RETURN: list of 5 objects: |
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323 | @format |
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324 | [1]: ideal obtained by substituting from the first n variables those |
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325 | from i, which appear in the linear part of i (or, if e!=0, which |
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326 | can be expressed directly in the remaining vars) |
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327 | [2]: ideal, variables which have been substituted |
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328 | [3]: ideal, i-th element defines substitution of i-th var in [2] |
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329 | [4]: ideal of variables of basering, substituted ones are set to 0 |
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330 | [5]: ideal, describing the map from the basering, say k[x(1..m)], to |
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331 | itself onto k[..variables from [4]..] and [1] is the image of i |
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332 | @end format |
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333 | The ideal i is generated by [1] and [3] in k[x(1..m)], the map [5] |
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334 | maps [3] to 0, hence induces an isomorphism |
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335 | @format |
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336 | k[x(1..m)]/i -> k[..variables from [4]..]/[1] |
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337 | @end format |
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338 | NOTE: Applying elimpart to interred(i) may result in more substitutions. |
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339 | However, interred may be more expansive than elimpart for big ideals |
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340 | EXAMPLE: example elimpart; shows an example |
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341 | " |
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342 | { |
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343 | def BAS = basering; |
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344 | int n,e = nvars(BAS),1; |
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345 | if ( size(#)==1 ) { n=#[1]; } |
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346 | if ( size(#)==2 ) { n=#[1]; e=#[2];} |
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347 | //----------- interreduce linear part with proc elimlinearpart ---------------- |
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348 | // lin = ideal i after interreduction with linear part |
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349 | // eva = eliminated (substituted) variables |
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350 | // sub = polynomials defining substitution |
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351 | // neva= not eliminated variables |
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352 | // phi = map describing substitution |
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353 | |
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354 | list L = elimlinearpart(i,n); |
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355 | ideal lin, eva, sub, neva, phi = L[1], L[2], L[3], L[4], L[5]; |
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356 | if ( e == 0 ) |
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357 | { |
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358 | return(L); |
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359 | } |
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360 | |
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361 | //-------- direct substitution of variables if possible and if e!=0 ----------- |
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362 | // first find terms lin1 in lin of pure degree 1 in each polynomial of lin |
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363 | // k1 = pure degree 1 part, i.e. nonzero elts of lin1, renumbered |
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364 | // k2 = lin2 (=matrix(lin) - matrix(lin2)), renumbered |
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365 | // kin = matrix(k1)+matrix(k2) = those polys of lin which contained a pure |
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366 | // degree 1 part. |
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367 | /* |
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368 | Alte Version mit interred: |
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369 | // Then go to ring newBAS with ordering c,dp(n) and create a matrix with |
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370 | // size(k1) colums and 2 rows, such that if [f1,f2] is a column of M then f1+f2 |
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371 | // is one of the polys of lin containing a pure degree 1 part and f1 is this |
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372 | // part interreduce this matrix (i.e. Gauss elimination on linear part, with |
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373 | // rest transformed accordingly). |
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374 | //Ist jetzt durch direkte Substitution gemacht (schneller!) |
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375 | //Variante falls wieder interred angewendet werden soll: |
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376 | //ideal k12 = k1,k2; |
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377 | //matrix M = matrix(k12,2,kk); //degree 1 part is now in row 1 |
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378 | //M = interred(M); |
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379 | //### interred zu teuer, muss nicht sein. Wenn interred angewendet |
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380 | //werden soll, vorher in Ring mit Ordnung (c,dp) wechseln! |
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381 | //Abfrage: if( ordstr(BAS) != "c,dp("+string(n)+")" ) |
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382 | //auf KEINEN Fall std (wird zu gross) |
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383 | //l = ncols(M); |
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384 | //k1 = M[1,1..l]; |
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385 | //k2 = M[2,1..l]; |
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386 | Interred ist jetzt ganz weggelassen. Aber es gibt Beispiele wo interred polys |
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387 | mit Grad 1 Teilen produziert, die vorher nicht da waren (aus polys, die einen konstanten Term haben). |
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388 | z.B. i=xy2-xu4-x+y2,x2y2+z3+zy,y+z2+1,y+u2;, interred(i)=z2+y+1,y2-x,u2+y,x3-z |
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389 | -z ergibt ich auch i[2]-z*i[3] mit option(redThrough) |
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390 | statt interred kann man hier auch NF(i,i[3])+i[3] verwenden |
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391 | hier lifert elimpart(i) 2 Substitutionen (x,y) elimpart(interred(i)) |
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392 | aber 3 (x,y,z) |
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393 | Da interred oder NF aber die Laenge der polys vergroessern kann, nicht gemacht |
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394 | */ |
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395 | int ii, kk; |
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396 | ideal k1, k2, lin2; |
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397 | int l = ncols(lin); // lin=i after applying elimlinearpart |
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398 | ideal lin1 = ideal(matrix(jet(lin,1))-matrix(jet(lin,0))); // part of pure degree 1 |
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399 | //Note: If i,i1,i2 are ideals, then i = i1 - i2 is equivalent to |
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400 | //i = ideal(matrix(i1) - matrix(i2)) |
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401 | |
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402 | if (size(lin1) == 0 ) |
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403 | { |
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404 | return(L); |
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405 | } |
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406 | |
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407 | //-------- check candidates for direct substitution of variables ---------- |
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408 | //since lin1 != 0 there are candidates for substituting variables |
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409 | |
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410 | lin2 = matrix(lin) - matrix(lin1); //difference as matrix |
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411 | // rest of lin, part of pure degree 1 substracted from each generator of lin |
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412 | |
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413 | for( ii=1; ii<=l; ii++ ) |
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414 | { |
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415 | if( lin1[ii] != 0 ) |
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416 | { |
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417 | kk = kk+1; |
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418 | k1[kk] = lin1[ii]; // part of pure degree 1, renumbered |
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419 | k2[kk] = lin2[ii]; // rest of those polys which had a degree 1 part |
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420 | lin2[ii] = 0; |
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421 | } |
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422 | } |
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423 | //Now each !=0 generator of lin2 contains only constant terms or terms of |
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424 | //degree >= 2, hence lin 2 can never be used for further substitutions |
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425 | //We have: lin = ideal(matrix(k1)+matrix(k2)), lin2 |
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426 | |
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427 | ideal kin = matrix(k1)+matrix(k2); |
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428 | //kin = polys of lin which contained a pure degree 1 part. |
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429 | kin = simplify(kin,2); |
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430 | l = size(kin); //l != 0 since lin1 != 0 |
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431 | poly p,kip,vip, cand; |
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432 | int count=1; |
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433 | while ( count != 0 ) |
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434 | { |
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435 | count = 0; |
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436 | for ( ii=1; ii<=n; ii++ ) //start direct substitution of var(ii) |
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437 | { |
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438 | for (kk=1; kk<=l; kk++ ) |
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439 | { |
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440 | p = kin[kk]/var(ii); |
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441 | //if ( deg(p) == 0 ) |
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442 | //old test, does not work if some var has deg 0 |
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443 | //geaendert Mai 09 gmg |
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444 | |
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445 | if( p!=0 & p == jet(p,0) ) |
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446 | //this means that kin[kk]= p*var(ii) + h, |
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447 | //with p=const !=0 and h not depending on var(ii) |
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448 | { |
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449 | //we look for the shortest candidate to substitute var(ii) |
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450 | if ( cand == 0 ) |
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451 | { |
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452 | cand = kin[kk]; //candidate for substituting var(ii) |
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453 | } |
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454 | else |
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455 | { |
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456 | if ( size(kin[kk]) < size(cand) ) |
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457 | { |
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458 | cand = kin[kk]; |
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459 | } |
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460 | } |
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461 | } |
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462 | } |
---|
463 | if ( cand != 0 ) |
---|
464 | { |
---|
465 | p = cand/var(ii); |
---|
466 | kip = cand/p; //normalized polynomial of kin w.r.t var(ii) |
---|
467 | eva = eva+var(ii); //var(ii) added to list of elimin. vars |
---|
468 | neva[ii] = 0; |
---|
469 | sub = sub+kip; //polynomial defining substituion |
---|
470 | //## gmg: geaendert 08/2008, map durch subst ersetzt |
---|
471 | //(viel schneller) |
---|
472 | vip = var(ii) - kip; //polynomial to be substituted |
---|
473 | lin = subst(lin, var(ii), vip); //subst in rest |
---|
474 | lin = simplify(lin,2); |
---|
475 | kin = subst(kin, var(ii), vip); //subst in pure dgree 1 part |
---|
476 | kin = simplify(kin,2); |
---|
477 | l = size(kin); |
---|
478 | count = 1; |
---|
479 | } |
---|
480 | cand=0; |
---|
481 | } |
---|
482 | } |
---|
483 | |
---|
484 | lin = kin+lin; |
---|
485 | |
---|
486 | for( ii=1; ii<=size(lin); ii++ ) |
---|
487 | { |
---|
488 | lin[ii] = cleardenom(lin[ii]); |
---|
489 | } |
---|
490 | |
---|
491 | for( ii=1; ii<=n; ii++ ) |
---|
492 | { |
---|
493 | for( kk=1; kk<=size(eva); kk++ ) |
---|
494 | { |
---|
495 | if (phi[ii] == eva[kk] ) |
---|
496 | { phi[ii] = eva[kk]-sub[kk]; break; } |
---|
497 | } |
---|
498 | } |
---|
499 | map psi = BAS,phi; |
---|
500 | ideal phi1 = maxideal(1); |
---|
501 | for(ii=1; ii<=size(eva); ii++) |
---|
502 | { |
---|
503 | phi1=psi(phi1); |
---|
504 | } |
---|
505 | L = lin, eva, sub, neva, phi1; |
---|
506 | return(L); |
---|
507 | } |
---|
508 | example |
---|
509 | { "EXAMPLE:"; echo = 2; |
---|
510 | ring s=0,(u,x,y,z),dp; |
---|
511 | ideal i = xy2-xu4-x+y2,x2y2+z3+zy,y+z2+1,y+u2; |
---|
512 | elimpart(i); |
---|
513 | |
---|
514 | i = interred(i); i; |
---|
515 | elimpart(i); |
---|
516 | |
---|
517 | elimpart(i,2); |
---|
518 | } |
---|
519 | |
---|
520 | /////////////////////////////////////////////////////////////////////////////// |
---|
521 | |
---|
522 | proc elimpartanyr (ideal i, list #) |
---|
523 | "USAGE: elimpartanyr(i [,p,e] ); i=ideal, p=polynomial, e=integer@* |
---|
524 | p: product of vars to be eliminated,@* |
---|
525 | e =0: substitute from linear part of i (same as elimlinearpart)@* |
---|
526 | e!=0: eliminate also by direct substitution@* |
---|
527 | (default: p=product of all vars, e=1) |
---|
528 | RETURN: list of 6 objects: |
---|
529 | @format |
---|
530 | [1]: (interreduced) ideal obtained by substituting from i those vars |
---|
531 | appearing in p, which occur in the linear part of i (or which can |
---|
532 | be expressed directly in the remaining variables, if e!=0) |
---|
533 | [2]: ideal, variables which have been substituted |
---|
534 | [3]: ideal, i-th element defines substitution of i-th var in [2] |
---|
535 | [4]: ideal of variables of basering, substituted ones are set to 0 |
---|
536 | [5]: ideal, describing the map from the basering, say k[x(1..m)], to |
---|
537 | itself onto k[..variables fom [4]..] and [1] is the image of i |
---|
538 | [6]: int, # of vars considered for substitution (= # of factors of p) |
---|
539 | @end format |
---|
540 | The ideal i is generated by [1] and [3] in k[x(1..m)], the map [5] |
---|
541 | maps [3] to 0, hence induces an isomorphism |
---|
542 | @format |
---|
543 | k[x(1..m)]/i -> k[..variables fom [4]..]/[1] |
---|
544 | @end format |
---|
545 | NOTE: the procedure uses @code{execute} to create a ring with ordering dp |
---|
546 | and vars placed correctly and then applies @code{elimpart}. |
---|
547 | EXAMPLE: example elimpartanyr; shows an example |
---|
548 | " |
---|
549 | { |
---|
550 | def P = basering; |
---|
551 | int j,n,e = 0,0,1; |
---|
552 | poly p = product(maxideal(1)); |
---|
553 | if ( size(#)==1 ) { p=#[1]; } |
---|
554 | if ( size(#)==2 ) { p=#[1]; e=#[2]; } |
---|
555 | string a,b; |
---|
556 | for ( j=1; j<=nvars(P); j++ ) |
---|
557 | { |
---|
558 | if (deg(p/var(j))>=0) { a = a+varstr(j)+","; n = n+1; } |
---|
559 | else { b = b+varstr(j)+","; } |
---|
560 | } |
---|
561 | if ( size(b) != 0 ) { b = b[1,size(b)-1]; } |
---|
562 | else { a = a[1,size(a)-1]; } |
---|
563 | execute("ring gnir ="+charstr(P)+",("+a+b+"),dp;"); |
---|
564 | ideal i = imap(P,i); |
---|
565 | list L = elimpart(i,n,e)+list(n); |
---|
566 | setring P; |
---|
567 | list L = imap(gnir,L); |
---|
568 | return(L); |
---|
569 | } |
---|
570 | example |
---|
571 | { "EXAMPLE:"; echo = 2; |
---|
572 | ring s=0,(x,y,z),dp; |
---|
573 | ideal i = x3+y2+z,x2y2+z3,y+z+1; |
---|
574 | elimpartanyr(i,z); |
---|
575 | } |
---|
576 | /////////////////////////////////////////////////////////////////////////////// |
---|
577 | |
---|
578 | proc fastelim (ideal i, poly p, list #) |
---|
579 | "USAGE: fastelim(i,p[h,o,a,b,e,m]); i=ideal, p=polynomial; h,o,a,b,e=integers@* |
---|
580 | p: product of variables to be eliminated;@* |
---|
581 | Optional parameters: |
---|
582 | @format |
---|
583 | - h !=0: use Hilbert-series driven std-basis computation |
---|
584 | - o !=0: use proc @code{valvars} for a - hopefully - optimal ordering of vars |
---|
585 | - a !=0: order vars to be eliminated w.r.t. increasing complexity |
---|
586 | - b !=0: order vars not to be eliminated w.r.t. increasing complexity |
---|
587 | - e !=0: use @code{elimpart} first to eliminate easy part |
---|
588 | - m !=0: compute a minimal system of generators |
---|
589 | @end format |
---|
590 | (default: h,o,a,b,e,m = 0,1,0,0,0,0) |
---|
591 | RETURN: ideal obtained from i by eliminating those variables, which occur in p |
---|
592 | EXAMPLE: example fastelim; shows an example. |
---|
593 | " |
---|
594 | { |
---|
595 | def P = basering; |
---|
596 | int h,o,a,b,e,m = 0,1,0,0,0,0; |
---|
597 | if ( size(#) == 1 ) { h=#[1]; } |
---|
598 | if ( size(#) == 2 ) { h=#[1]; o=#[2]; } |
---|
599 | if ( size(#) == 3 ) { h=#[1]; o=#[2]; a=#[3]; } |
---|
600 | if ( size(#) == 4 ) { h=#[1]; o=#[2]; a=#[3]; b=#[4];} |
---|
601 | if ( size(#) == 5 ) { h=#[1]; o=#[2]; a=#[3]; b=#[4]; e=#[5]; } |
---|
602 | if ( size(#) == 6 ) { h=#[1]; o=#[2]; a=#[3]; b=#[4]; e=#[5]; m=#[6]; } |
---|
603 | list L = elimpartanyr(i,p,e); |
---|
604 | poly q = product(L[2]); //product of vars which are already eliminated |
---|
605 | if ( q==0 ) { q=1; } |
---|
606 | p = p/q; //product of vars which must still be eliminated |
---|
607 | int nu = size(L[5])-size(L[2]); //number of vars which must still be eliminated |
---|
608 | if ( p==1 ) //ready if no vars are left |
---|
609 | { //compute minbase if 3-rd argument !=0 |
---|
610 | if ( m != 0 ) { L[1]=minbase(L[1]); } |
---|
611 | return(L); |
---|
612 | } |
---|
613 | //---------------- create new ring with remaining variables ------------------- |
---|
614 | string newvar = string(L[4]); |
---|
615 | L = L[1],p; |
---|
616 | execute("ring r1=("+charstr(P)+"),("+newvar+"),"+"dp;"); |
---|
617 | list L = imap(P,L); |
---|
618 | //------------------- find "best" ordering of variables ---------------------- |
---|
619 | newvar = string(maxideal(1)); |
---|
620 | if ( o != 0 ) |
---|
621 | { |
---|
622 | list ordevar = valvars(L[1],a,L[2],b); |
---|
623 | intvec v = ordevar[1]; |
---|
624 | newvar=string(sort(maxideal(1),v)[1]); |
---|
625 | //------------ create new ring with "best" ordering of variables -------------- |
---|
626 | def r0=changevar(newvar); |
---|
627 | setring r0; |
---|
628 | list L = imap(r1,L); |
---|
629 | kill r1; |
---|
630 | def r1 = r0; |
---|
631 | kill r0; |
---|
632 | } |
---|
633 | //----------------- h==0: eliminate remaining vars directly ------------------- |
---|
634 | if ( h == 0 ) |
---|
635 | { |
---|
636 | L[1] = eliminate(L[1],L[2]); |
---|
637 | def r2 = r1; |
---|
638 | } |
---|
639 | else |
---|
640 | //------- h!=0: homogenize and compute Hilbert series using hilbvec ---------- |
---|
641 | { |
---|
642 | intvec hi = hilbvec(L[1]); // Hilbert series of i |
---|
643 | execute("ring r2=("+charstr(P)+"),("+varstr(basering)+",@homo),dp;"); |
---|
644 | list L = imap(r1,L); |
---|
645 | L[1] = homog(L[1],@homo); // @homo = homogenizing var |
---|
646 | //---- use Hilbert-series to eliminate variables with Hilbert-driven std ----- |
---|
647 | L[1] = eliminate(L[1],L[2],hi); |
---|
648 | L[1]=subst(L[1],@homo,1); // dehomogenize by setting @homo=1 |
---|
649 | } |
---|
650 | if ( m != 0 ) // compute minbase |
---|
651 | { |
---|
652 | if ( #[1] != 0 ) { L[1] = minbase(L[1]); } |
---|
653 | } |
---|
654 | def id = L[1]; |
---|
655 | setring P; |
---|
656 | return(imap(r2,id)); |
---|
657 | } |
---|
658 | example |
---|
659 | { "EXAMPLE:"; echo = 2; |
---|
660 | ring s=31991,(e,f,x,y,z,t,u,v,w,a,b,c,d),dp; |
---|
661 | ideal i = w2+f2-1, x2+t2+a2-1, y2+u2+b2-1, z2+v2+c2-1, |
---|
662 | d2+e2-1, f4+2u, wa+tf, xy+tu+ab; |
---|
663 | fastelim(i,xytua,1,1); //with hilb,valvars |
---|
664 | fastelim(i,xytua,1,0,1); //with hilb,minbase |
---|
665 | } |
---|
666 | /////////////////////////////////////////////////////////////////////////////// |
---|
667 | |
---|
668 | proc faststd (@id, list #) |
---|
669 | "USAGE: faststd(id [,\"hilb\",\"sort\",\"dec\",o,\"blocks\"]); |
---|
670 | id=ideal/module, o=string (allowed:\"lp\",\"dp\",\"Dp\",\"ls\", |
---|
671 | \"ds\",\"Ds\"), \"hilb\",\"sort\",\"dec\",\"block\" options for |
---|
672 | Hilbert-driven std, and the procedure sortandmap |
---|
673 | RETURN: a ring R, in which an ideal STD_id is stored: @* |
---|
674 | - the ring R differs from the active basering only in the choice |
---|
675 | of monomial ordering and in the sorting of the variables. |
---|
676 | - STD_id is a standard basis for the image (under imap) of the input |
---|
677 | ideal/module id with respect to the new monomial ordering. @* |
---|
678 | NOTE: Using the optional input parameters, we may modify the computations |
---|
679 | performed: @* |
---|
680 | - \"hilb\" : use Hilbert-driven standard basis computation@* |
---|
681 | - \"sort\" : use 'sortandmap' for a best sorting of the variables@* |
---|
682 | - \"dec\" : order vars w.r.t. decreasing complexity (with \"sort\")@* |
---|
683 | - \"block\" : create block ordering, each block having ordstr=o, s.t. |
---|
684 | vars of same complexity are in one block (with \"sort\")@* |
---|
685 | - o : defines the basic ordering of the resulting ring@* |
---|
686 | [default: o=ordering of 1st block of basering (if allowed, else o=\"dp\"], |
---|
687 | \"sort\", if none of the optional parameters is given @* |
---|
688 | This procedure is only useful for hard problems where other methods fail.@* |
---|
689 | \"hilb\" is useful for hard orderings (as \"lp\") or for characteristic 0,@* |
---|
690 | it is correct for \"lp\",\"dp\",\"Dp\" (and for block orderings combining |
---|
691 | these) but not for s-orderings or if the vars have different weights.@* |
---|
692 | There seem to be only few cases in which \"dec\" is fast. |
---|
693 | SEE ALSO: groebner |
---|
694 | EXAMPLE: example faststd; shows an example. |
---|
695 | " |
---|
696 | { |
---|
697 | def @P = basering; |
---|
698 | int @h,@s,@n,@m,@ii = 0,0,0,0,0; |
---|
699 | string @o,@va,@c = ordstr(basering),"",""; |
---|
700 | //-------------------- prepare ordering and set options ----------------------- |
---|
701 | if ( @o[1]=="c" or @o[1]=="C") |
---|
702 | { @o = @o[3,2]; } |
---|
703 | else |
---|
704 | { @o = @o[1,2]; } |
---|
705 | if( @o[1]!="d" and @o[1]!="D" and @o[1]!="l") |
---|
706 | { @o="dp"; } |
---|
707 | |
---|
708 | if (size(#) == 0 ) |
---|
709 | { @s = 1; } |
---|
710 | for ( @ii=1; @ii<=size(#); @ii++ ) |
---|
711 | { |
---|
712 | if ( typeof(#[@ii]) != "string" ) |
---|
713 | { |
---|
714 | "// wrong syntax! type: help faststd"; |
---|
715 | return(); |
---|
716 | } |
---|
717 | else |
---|
718 | { |
---|
719 | if ( #[@ii] == "hilb" ) { @h = 1; } |
---|
720 | if ( #[@ii] == "dec" ) { @n = 1; } |
---|
721 | if ( #[@ii] == "block" ) { @m = 1; } |
---|
722 | if ( #[@ii] == "sort" ) { @s = 1; } |
---|
723 | if ( #[@ii]=="lp" or #[@ii]=="dp" or #[@ii]=="Dp" or #[@ii]=="ls" |
---|
724 | or #[@ii]=="ds" or #[@ii]=="Ds" ) { @o = #[@ii]; } |
---|
725 | } |
---|
726 | } |
---|
727 | if( voice==2 ) { "// chosen options, hilb sort dec block:",@h,@s,@n,@m; } |
---|
728 | |
---|
729 | //-------------------- nosort: create ring with new name ---------------------- |
---|
730 | if ( @s==0 ) |
---|
731 | { |
---|
732 | execute("ring @S1 =("+charstr(@P)+"),("+varstr(@P)+"),("+@o+");"); |
---|
733 | def STD_id = imap(@P,@id); |
---|
734 | if ( @h==0 ) { STD_id = std(STD_id); } |
---|
735 | } |
---|
736 | |
---|
737 | //---------------------- no hilb: compute SB directly ------------------------- |
---|
738 | if ( @s != 0 and @h == 0 ) |
---|
739 | { |
---|
740 | intvec getoption = option(get); |
---|
741 | option(redSB); |
---|
742 | @id = interred(sort(@id)[1]); |
---|
743 | poly @p = product(maxideal(1),1..nvars(@P)); |
---|
744 | def @S1=sortandmap(@id,@n,@p,0,@o,@m); |
---|
745 | setring @S1; |
---|
746 | option(set,getoption); |
---|
747 | def STD_id=imap(@S1,IMAG); |
---|
748 | STD_id = std(STD_id); |
---|
749 | } |
---|
750 | //------- hilb: homogenize and compute Hilbert-series using hilbvec ----------- |
---|
751 | // this uses another standardbasis computation |
---|
752 | if ( @h != 0 ) |
---|
753 | { |
---|
754 | execute("ring @Q=("+charstr(@P)+"),("+varstr(@P)+",@homo),("+@o+");"); |
---|
755 | def @id = imap(@P,@id); |
---|
756 | @id = homog(@id,@homo); // @homo = homogenizing var |
---|
757 | if ( @s != 0 ) |
---|
758 | { |
---|
759 | intvec getoption = option(get); |
---|
760 | option(redSB); |
---|
761 | @id = interred(sort(@id)[1]); |
---|
762 | poly @p = product(maxideal(1),1..(nvars(@Q)-1)); |
---|
763 | def @S1=sortandmap(@id,@n,@p,0,@o,@m); |
---|
764 | setring @S1; |
---|
765 | option(set,getoption); |
---|
766 | kill @Q; |
---|
767 | def @Q= basering; |
---|
768 | def @id = IMAG; |
---|
769 | } |
---|
770 | intvec @hi; // encoding of Hilbert-series of i |
---|
771 | @hi = hilbvec(@id); |
---|
772 | //if ( @s!=0 ) { @hi = hilbvec(@id,"32003",ordstr(@Q)); } |
---|
773 | //else { @hi = hilbvec(@id); } |
---|
774 | //-------------------------- use Hilbert-driven std -------------------------- |
---|
775 | @id = std(@id,@hi); |
---|
776 | @id = subst(@id,@homo,1); // dehomogenize by setting @homo=1 |
---|
777 | @va = varstr(@Q)[1,size(varstr(@Q))-6]; |
---|
778 | if ( @s!=0 ) |
---|
779 | { |
---|
780 | @o = ordstr(@Q); |
---|
781 | if ( @o[1]=="c" or @o[1]=="C") { @o = @o[1,size(@o)-6]; } |
---|
782 | else { @o = @o[1,size(@o)-8] + @o[size(@o)-1,2]; } |
---|
783 | } |
---|
784 | kill @S1; |
---|
785 | execute("ring @S1=("+charstr(@Q)+"),("+@va+"),("+@o+");"); |
---|
786 | def STD_id = imap(@Q,@id); |
---|
787 | } |
---|
788 | attrib(STD_id,"isSB",1); |
---|
789 | export STD_id; |
---|
790 | if (defined(IMAG)) { kill IMAG; } |
---|
791 | setring @P; |
---|
792 | dbprint(printlevel-voice+3," |
---|
793 | // 'faststd' created a ring, in which an object STD_id is stored. |
---|
794 | // To access the object, type (if the name R was assigned to the return value): |
---|
795 | setring R; STD_id; "); |
---|
796 | return(@S1); |
---|
797 | } |
---|
798 | example |
---|
799 | { "EXAMPLE:"; echo = 2; |
---|
800 | system("--ticks-per-sec",100); // show time in 1/100 sec |
---|
801 | ring s = 0,(e,f,x,y,z,t,u,v,w,a,b,c,d),(c,lp); |
---|
802 | ideal i = w2+f2-1, x2+t2+a2-1, y2+u2+b2-1, z2+v2+c2-1, |
---|
803 | d2+e2-1, f4+2u, wa+tf, xy+tu+ab; |
---|
804 | option(prot); timer=1; |
---|
805 | int time = timer; |
---|
806 | ideal j=std(i); |
---|
807 | timer-time; |
---|
808 | dim(j),mult(j); |
---|
809 | |
---|
810 | time = timer; |
---|
811 | def R=faststd(i); // use "best" ordering of vars |
---|
812 | timer-time; |
---|
813 | show(R);setring R;dim(STD_id),mult(STD_id); |
---|
814 | |
---|
815 | setring s;kill R;time = timer; |
---|
816 | def R=faststd(i,"hilb"); // hilb-std only |
---|
817 | timer-time; |
---|
818 | show(R);setring R;dim(STD_id),mult(STD_id); |
---|
819 | |
---|
820 | setring s;kill R;time = timer; |
---|
821 | def R=faststd(i,"hilb","sort"); // hilb-std,"best" ordering |
---|
822 | timer-time; |
---|
823 | show(R);setring R;dim(STD_id),mult(STD_id); |
---|
824 | |
---|
825 | setring s;kill R;time = timer; |
---|
826 | def R=faststd(i,"hilb","sort","block","dec"); // hilb-std,"best",blocks |
---|
827 | timer-time; |
---|
828 | show(R);setring R;dim(STD_id),mult(STD_id); |
---|
829 | |
---|
830 | setring s;kill R;time = timer; |
---|
831 | timer-time;time = timer; |
---|
832 | def R=faststd(i,"sort","block","Dp"); //"best",decreasing,Dp-blocks |
---|
833 | timer-time; |
---|
834 | show(R);setring R;dim(STD_id),mult(STD_id); |
---|
835 | } |
---|
836 | /////////////////////////////////////////////////////////////////////////////// |
---|
837 | |
---|
838 | proc findvars(id, list #) |
---|
839 | "USAGE: findvars(id [,any] ); id=poly/ideal/vector/module/matrix, any=any type |
---|
840 | RETURN: if no second argument is present: ideal of variables occuring in id,@* |
---|
841 | if a second argument is given (of any type): list L with 4 entries: |
---|
842 | @format |
---|
843 | L[1]: ideal of variables occuring in id |
---|
844 | L[2]: intvec of variables occuring in id |
---|
845 | L[3]: ideal of variables not occuring in id |
---|
846 | L[4]: intvec of variables not occuring in id |
---|
847 | @end format |
---|
848 | EXAMPLE: example findvars; shows an example |
---|
849 | " |
---|
850 | { |
---|
851 | int ii,n; |
---|
852 | ideal found, notfound; |
---|
853 | intvec f,nf; |
---|
854 | n = nvars(basering); |
---|
855 | ideal i = simplify(ideal(matrix(id)),10); |
---|
856 | matrix M[ncols(i)][1] = i; |
---|
857 | vector v = module(M)[1]; |
---|
858 | ideal max = maxideal(1); |
---|
859 | |
---|
860 | for (ii=1; ii<=n; ii++) |
---|
861 | { |
---|
862 | if ( v != subst(v,var(ii),0) ) |
---|
863 | { |
---|
864 | found = found+var(ii); |
---|
865 | f = f,ii; |
---|
866 | } |
---|
867 | else |
---|
868 | { |
---|
869 | notfound = notfound+var(ii); |
---|
870 | nf = nf,ii; |
---|
871 | } |
---|
872 | } |
---|
873 | if ( size(f)>1 ) { f = f[2..size(f)]; } //intvec of found vars |
---|
874 | if ( size(nf)>1 ) { nf = nf[2..size(nf)]; } //intvec of vars not found |
---|
875 | if( size(#)==0 ) { return(found); } |
---|
876 | if( size(#)!=0 ) { list L = found,f,notfound,nf; return(L); } |
---|
877 | } |
---|
878 | example |
---|
879 | { "EXAMPLE:"; echo = 2; |
---|
880 | ring s = 0,(e,f,x,y,t,u,v,w,a,d),dp; |
---|
881 | ideal i = w2+f2-1, x2+t2+a2-1; |
---|
882 | findvars(i); |
---|
883 | findvars(i,1); |
---|
884 | } |
---|
885 | /////////////////////////////////////////////////////////////////////////////// |
---|
886 | |
---|
887 | proc hilbvec (@id, list #) |
---|
888 | "USAGE: hilbvec(id[,c,o]); id=poly/ideal/vector/module/matrix, c,o=strings,@* |
---|
889 | c=char, o=ordering used by @code{hilb} (default: c=\"32003\", o=\"dp\") |
---|
890 | RETURN: intvec of 1st Hilbert-series of id, computed in char c and ordering o |
---|
891 | NOTE: id must be homogeneous (i.e. all vars have weight 1) |
---|
892 | EXAMPLE: example hilbvec; shows an example |
---|
893 | " |
---|
894 | { |
---|
895 | def @P = basering; |
---|
896 | string @c,@o = "32003", "dp"; |
---|
897 | if ( size(#) == 1 ) { @c = #[1]; } |
---|
898 | if ( size(#) == 2 ) { @c = #[1]; @o = #[2]; } |
---|
899 | string @si = typeof(@id)+" @i = "+string(@id)+";"; //** weg |
---|
900 | execute("ring @r=("+@c+"),("+varstr(basering)+"),("+@o+");"); |
---|
901 | //**def i = imap(P,@id); |
---|
902 | execute(@si); //** weg |
---|
903 | //show(basering); |
---|
904 | @i = std(@i); |
---|
905 | intvec @hi = hilb(@i,1); // intvec of 1-st Hilbert-series of id |
---|
906 | return(@hi); |
---|
907 | } |
---|
908 | example |
---|
909 | { "EXAMPLE:"; echo = 2; |
---|
910 | ring s = 0,(e,f,x,y,z,t,u,v,w,a,b,c,d,H),dp; |
---|
911 | ideal id = w2+f2-1, x2+t2+a2-1, y2+u2+b2-1, z2+v2+c2-1, |
---|
912 | d2+e2-1, f4+2u, wa+tf, xy+tu+ab; |
---|
913 | id = homog(id,H); |
---|
914 | hilbvec(id); |
---|
915 | } |
---|
916 | /////////////////////////////////////////////////////////////////////////////// |
---|
917 | |
---|
918 | proc tolessvars (id ,list #) |
---|
919 | "USAGE: tolessvars(id [,s1,s2] ); id poly/ideal/vector/module/matrix, |
---|
920 | s1=string (new ordering)@* |
---|
921 | [default: s1=\"dp\" or \"ds\" depending on whether the first block |
---|
922 | of the old ordering is a p- or an s-ordering, respectively] |
---|
923 | RETURN: If id contains all vars of the basering: empty list. @* |
---|
924 | Else: ring R with the same char as the basering, but possibly less |
---|
925 | variables (only those variables which actually occur in id). In R |
---|
926 | an object IMAG (image of id under imap) is stored. |
---|
927 | DISPLAY: If printlevel >=0, display ideal of vars, which have been omitted |
---|
928 | from the old ring. |
---|
929 | EXAMPLE: example tolessvars; shows an example |
---|
930 | " |
---|
931 | { |
---|
932 | //---------------- initialisation and check occurence of vars ----------------- |
---|
933 | int s,ii,n,fp,fs; |
---|
934 | string s2,newvar; |
---|
935 | int pr = printlevel-voice+3; // p = printlevel+1 (default: p=1) |
---|
936 | def P = basering; |
---|
937 | s2 = ordstr(P); |
---|
938 | |
---|
939 | list L = findvars(id,1); |
---|
940 | newvar = string(L[1]); // string of new variables |
---|
941 | n = size(L[1]); // number of new variables |
---|
942 | if( n == 0 ) |
---|
943 | { |
---|
944 | dbprint( pr,"","// no variable occured in "+typeof(id)+", no change of ring!"); |
---|
945 | return(id); |
---|
946 | } |
---|
947 | if( n == nvars(P) ) |
---|
948 | { |
---|
949 | dbprint(printlevel-voice+3," |
---|
950 | // All variables appear in input object. |
---|
951 | // empty list returned. "); |
---|
952 | return(list()); |
---|
953 | } |
---|
954 | //----------------- prepare new ring, map to it and return -------------------- |
---|
955 | if ( size(#) == 0 ) |
---|
956 | { |
---|
957 | fp = find(s2,"p"); |
---|
958 | fs = find(s2,"s"); |
---|
959 | if( fs==0 or (fs>=fp && fp!=0) ) { s2="dp"; } |
---|
960 | else { s2="ds"; } |
---|
961 | } |
---|
962 | if ( size(#) ==1 ) { s2=#[1]; } |
---|
963 | dbprint( pr,"","// variables which did not occur:",L[3] ); |
---|
964 | execute("ring S1=("+charstr(P)+"),("+newvar+"),("+s2+");"); |
---|
965 | def IMAG = imap(P,id); |
---|
966 | export IMAG; |
---|
967 | dbprint(printlevel-voice+3," |
---|
968 | // 'tolessvars' created a ring, in which an object IMAG is stored. |
---|
969 | // To access the object, type (if the name R was assigned to the return value): |
---|
970 | setring R; IMAG; "); |
---|
971 | return(S1); |
---|
972 | } |
---|
973 | example |
---|
974 | { "EXAMPLE:"; echo = 2; |
---|
975 | ring r = 0,(x,y,z),dp; |
---|
976 | ideal i = y2-x3,x-3,y-2x; |
---|
977 | def R_r = tolessvars(i,"lp"); |
---|
978 | setring R_r; |
---|
979 | show(basering); |
---|
980 | IMAG; |
---|
981 | kill R_r; |
---|
982 | } |
---|
983 | /////////////////////////////////////////////////////////////////////////////// |
---|
984 | |
---|
985 | proc solvelinearpart (id,list #) |
---|
986 | "USAGE: solvelinearpart(id [,n] ); id=ideal/module, n=integer (default: n=0) |
---|
987 | RETURN: (interreduced) generators of id of degree <=1 in reduced triangular |
---|
988 | form if n=0 [non-reduced triangular form if n!=0] |
---|
989 | ASSUME: monomial ordering is a global ordering (p-ordering) |
---|
990 | NOTE: may be used to solve a system of linear equations, |
---|
991 | see @code{gauss_row} from 'matrix.lib' for a different method |
---|
992 | WARNING: the result is very likely to be false for 'real' coefficients, use |
---|
993 | char 0 instead! |
---|
994 | EXAMPLE: example solvelinearpart; shows an example |
---|
995 | " |
---|
996 | { |
---|
997 | intvec getoption = option(get); |
---|
998 | option(redSB); |
---|
999 | if ( size(#)!=0 ) |
---|
1000 | { |
---|
1001 | if(#[1]!=0) { option(noredSB); } |
---|
1002 | } |
---|
1003 | def lin = interred(degreepart(id,0,1)[1]); |
---|
1004 | if ( size(#)!=0 ) |
---|
1005 | { |
---|
1006 | if(#[1]!=0) |
---|
1007 | { |
---|
1008 | return(lin); |
---|
1009 | } |
---|
1010 | } |
---|
1011 | option(set,getoption); |
---|
1012 | return(simplify(lin,1)); |
---|
1013 | } |
---|
1014 | example |
---|
1015 | { "EXAMPLE:"; echo = 2; |
---|
1016 | // Solve the system of linear equations: |
---|
1017 | // 3x + y + z - u = 2 |
---|
1018 | // 3x + 8y + 6z - 7u = 1 |
---|
1019 | // 14x + 10y + 6z - 7u = 0 |
---|
1020 | // 7x + 4y + 3z - 3u = 3 |
---|
1021 | ring r = 0,(x,y,z,u),lp; |
---|
1022 | ideal i= 3x + y + z - u, |
---|
1023 | 13x + 8y + 6z - 7u, |
---|
1024 | 14x + 10y + 6z - 7u, |
---|
1025 | 7x + 4y + 3z - 3u; |
---|
1026 | ideal j= 2,1,0,3; |
---|
1027 | j = matrix(i)-matrix(j); // difference of 1x4 matrices |
---|
1028 | // compute reduced triangular form, setting |
---|
1029 | solvelinearpart(j); // the RHS equal 0 gives the solutions! |
---|
1030 | solvelinearpart(j,1); ""; // triangular form, not reduced |
---|
1031 | } |
---|
1032 | /////////////////////////////////////////////////////////////////////////////// |
---|
1033 | |
---|
1034 | proc sortandmap (@id, list #) |
---|
1035 | "USAGE: sortandmap(id [,n1,p1,n2,p2...,o1,m1,o2,m2...]);@* |
---|
1036 | id=poly/ideal/vector/module,@* |
---|
1037 | p1,p2,...= polynomials (product of variables),@* |
---|
1038 | n1,n2,...= integers,@* |
---|
1039 | o1,o2,...= strings,@* |
---|
1040 | m1,m2,...= integers@* |
---|
1041 | (default: p1=product of all vars, n1=0, o1=\"dp\",m1=0) |
---|
1042 | the last pi (containing the remaining vars) may be omitted |
---|
1043 | RETURN: a ring R, in which a poly/ideal/vector/module IMAG is stored: @* |
---|
1044 | - the ring R differs from the active basering only in the choice |
---|
1045 | of monomial ordering and in the sorting of the variables.@* |
---|
1046 | - IMAG is the image (under imap) of the input ideal/module id @* |
---|
1047 | The new monomial ordering and sorting of vars is as follows: |
---|
1048 | @format |
---|
1049 | - each block of vars occuring in pi is sorted w.r.t. its complexity in id, |
---|
1050 | - ni controls the sorting in i-th block (= vars occuring in pi): |
---|
1051 | ni=0 (resp. ni!=0) means that least complex (resp. most complex) vars come |
---|
1052 | first |
---|
1053 | - oi and mi define the monomial ordering of the i-th block: |
---|
1054 | if mi =0, oi=ordstr(i-th block) |
---|
1055 | if mi!=0, the ordering of the i-th block itself is a blockordering, |
---|
1056 | each subblock having ordstr=oi, such that vars of same complexity are |
---|
1057 | in one block |
---|
1058 | @end format |
---|
1059 | Note that only simple ordstrings oi are allowed: \"lp\",\"dp\",\"Dp\", |
---|
1060 | \"ls\",\"ds\",\"Ds\". @* |
---|
1061 | NOTE: We define a variable x to be more complex than y (with respect to id) |
---|
1062 | if val(x) > val(y) lexicographically, where val(x) denotes the |
---|
1063 | valuation vector of x:@* |
---|
1064 | consider id as list of polynomials in x with coefficients in the |
---|
1065 | remaining variables. Then:@* |
---|
1066 | val(x) = (maximal occuring power of x, # of all monomials in leading |
---|
1067 | coefficient, # of all monomials in coefficient of next smaller power |
---|
1068 | of x,...). |
---|
1069 | EXAMPLE: example sortandmap; shows an example |
---|
1070 | " |
---|
1071 | { |
---|
1072 | def @P = basering; |
---|
1073 | int @ii,@jj; |
---|
1074 | intvec @v; |
---|
1075 | string @o; |
---|
1076 | //----------------- find o in # and split # into 2 lists --------------------- |
---|
1077 | # = # +list("dp",0); |
---|
1078 | for ( @ii=1; @ii<=size(#); @ii++) |
---|
1079 | { |
---|
1080 | if ( typeof(#[@ii])=="string" ) break; |
---|
1081 | } |
---|
1082 | if ( @ii==1 ) { list @L1 = list(); } |
---|
1083 | else { list @L1 = #[1..@ii-1]; } |
---|
1084 | list @L2 = #[@ii..size(#)]; |
---|
1085 | list @L = sortvars(@id,@L1); |
---|
1086 | string @va = string(@L[1]); |
---|
1087 | list @l = @L[2]; //e.g. @l[4]=intvec describing permutation of 1-st block |
---|
1088 | //----------------- construct correct ordering with oi and mi ---------------- |
---|
1089 | for ( @ii=4; @ii<=size(@l); @ii=@ii+4 ) |
---|
1090 | { |
---|
1091 | @L2=@L2+list("dp",0); |
---|
1092 | if ( @L2[@ii/2] != 0) |
---|
1093 | { |
---|
1094 | @v = @l[@ii]; |
---|
1095 | for ( @jj=1; @jj<=size(@v); @jj++ ) |
---|
1096 | { |
---|
1097 | @o = @o+@L2[@ii/2 -1]+"("+string(@v[@jj])+"),"; |
---|
1098 | } |
---|
1099 | } |
---|
1100 | else |
---|
1101 | { |
---|
1102 | @o = @o+@L2[@ii/2 -1]+"("+string(size(@l[@ii/2]))+"),"; |
---|
1103 | } |
---|
1104 | } |
---|
1105 | @o=@o[1..size(@o)-1]; |
---|
1106 | execute("ring @S1 =("+charstr(@P)+"),("+@va+"),("+@o+");"); |
---|
1107 | def IMAG = imap(@P,@id); |
---|
1108 | export IMAG; |
---|
1109 | dbprint(printlevel-voice+3," |
---|
1110 | // 'sortandmap' created a ring, in which an object IMAG is stored. |
---|
1111 | // To access the object, type (if the name R was assigned to the return value): |
---|
1112 | setring R; IMAG; "); |
---|
1113 | return(@S1); |
---|
1114 | } |
---|
1115 | example |
---|
1116 | { "EXAMPLE:"; echo = 2; |
---|
1117 | ring s = 32003,(x,y,z),dp; |
---|
1118 | ideal i=x3+y2,xz+z2; |
---|
1119 | def R_r=sortandmap(i); |
---|
1120 | show(R_r); |
---|
1121 | setring R_r; IMAG; |
---|
1122 | kill R_r; setring s; |
---|
1123 | def R_r=sortandmap(i,1,xy,0,z,0,"ds",0,"lp",0); |
---|
1124 | show(R_r); |
---|
1125 | setring R_r; IMAG; |
---|
1126 | kill R_r; |
---|
1127 | } |
---|
1128 | /////////////////////////////////////////////////////////////////////////////// |
---|
1129 | |
---|
1130 | proc sortvars (id, list #) |
---|
1131 | "USAGE: sortvars(id[,n1,p1,n2,p2,...]);@* |
---|
1132 | id=poly/ideal/vector/module,@* |
---|
1133 | p1,p2,...= polynomials (product of vars),@* |
---|
1134 | n1,n2,...= integers@* |
---|
1135 | (default: p1=product of all vars, n1=0) |
---|
1136 | the last pi (containing the remaining vars) may be omitted |
---|
1137 | COMPUTE: sort variables with respect to their complexity in id |
---|
1138 | RETURN: list of two elements, an ideal and a list: |
---|
1139 | @format |
---|
1140 | [1]: ideal, variables of basering sorted w.r.t their complexity in id |
---|
1141 | ni controls the ordering in i-th block (= vars occuring in pi): |
---|
1142 | ni=0 (resp. ni!=0) means that less (resp. more) complex vars come first |
---|
1143 | [2]: a list with 4 entries for each pi: |
---|
1144 | _[1]: ideal ai : vars of pi in correct order, |
---|
1145 | _[2]: intvec vi: permutation vector describing the ordering in ai, |
---|
1146 | _[3]: intmat Mi: valuation matrix of ai, the columns of Mi being the |
---|
1147 | valuation vectors of the vars in ai |
---|
1148 | _[4]: intvec wi: size of 1-st, 2-nd,... block of identical columns of Mi |
---|
1149 | (vars with same valuation) |
---|
1150 | @end format |
---|
1151 | NOTE: We define a variable x to be more complex than y (with respect to id) |
---|
1152 | if val(x) > val(y) lexicographically, where val(x) denotes the |
---|
1153 | valuation vector of x:@* |
---|
1154 | consider id as list of polynomials in x with coefficients in the |
---|
1155 | remaining variables. Then:@* |
---|
1156 | val(x) = (maximal occuring power of x, # of all monomials in leading |
---|
1157 | coefficient, # of all monomials in coefficient of next smaller power |
---|
1158 | of x,...). |
---|
1159 | EXAMPLE: example sortvars; shows an example |
---|
1160 | " |
---|
1161 | { |
---|
1162 | int ii,jj,n,s; |
---|
1163 | list L = valvars(id,#); |
---|
1164 | list L2, L3 = L[2], L[3]; |
---|
1165 | list K; intmat M; intvec v1,v2,w; |
---|
1166 | ideal i = sort(maxideal(1),L[1])[1]; |
---|
1167 | for ( ii=1; ii<=size(L2); ii++ ) |
---|
1168 | { |
---|
1169 | M = transpose(L3[2*ii]); |
---|
1170 | M = M[L2[ii],1..nrows(L3[2*ii])]; |
---|
1171 | w = 0; s = 0; |
---|
1172 | for ( jj=1; jj<=nrows(M)-1; jj++ ) |
---|
1173 | { |
---|
1174 | v1 = M[jj,1..ncols(M)]; |
---|
1175 | v2 = M[jj+1,1..ncols(M)]; |
---|
1176 | if ( v1 != v2 ) { n=jj-s; s=s+n; w = w,n; } |
---|
1177 | } |
---|
1178 | w=w,nrows(M)-s; w=w[2..size(w)]; |
---|
1179 | K = K+sort(L3[2*ii-1],L2[ii])+list(transpose(M))+list(w); |
---|
1180 | } |
---|
1181 | L = i,K; |
---|
1182 | return(L); |
---|
1183 | } |
---|
1184 | example |
---|
1185 | { "EXAMPLE:"; echo = 2; |
---|
1186 | ring s=0,(x,y,z,w),dp; |
---|
1187 | ideal i = x3+y2+yw2,xz+z2,xyz-w2; |
---|
1188 | sortvars(i,0,xy,1,zw); |
---|
1189 | } |
---|
1190 | /////////////////////////////////////////////////////////////////////////////// |
---|
1191 | |
---|
1192 | proc valvars (id, list #) |
---|
1193 | "USAGE: valvars(id[,n1,p1,n2,p2,...]);@* |
---|
1194 | id=poly/ideal/vector/module,@* |
---|
1195 | p1,p2,...= polynomials (product of vars),@* |
---|
1196 | n1,n2,...= integers, |
---|
1197 | |
---|
1198 | ni controls the ordering of vars occuring in pi: ni=0 (resp. ni!=0) |
---|
1199 | means that less (resp. more) complex vars come first (default: p1=product of all vars, n1=0),@* |
---|
1200 | the last pi (containing the remaining vars) may be omitted |
---|
1201 | COMPUTE: valuation (complexity) of variables with respect to id.@* |
---|
1202 | ni controls the ordering of vars occuring in pi:@* |
---|
1203 | ni=0 (resp. ni!=0) means that less (resp. more) complex vars come first. |
---|
1204 | RETURN: list with 3 entries: |
---|
1205 | @format |
---|
1206 | [1]: intvec, say v, describing the permutation such that the permuted |
---|
1207 | ring variables are ordered with respect to their complexity in id |
---|
1208 | [2]: list of intvecs, i-th intvec, say v(i) describing permutation |
---|
1209 | of vars in a(i) such that v=v(1),v(2),... |
---|
1210 | [3]: list of ideals and intmat's, say a(i) and M(i), where |
---|
1211 | a(i): factors of pi, |
---|
1212 | M(i): valuation matrix of a(i), such that the j-th column of M(i) |
---|
1213 | is the valuation vector of j-th generator of a(i) |
---|
1214 | @end format |
---|
1215 | NOTE: Use @code{sortvars} in order to actually sort the variables! |
---|
1216 | We define a variable x to be more complex than y (with respect to id) |
---|
1217 | if val(x) > val(y) lexicographically, where val(x) denotes the |
---|
1218 | valuation vector of x:@* |
---|
1219 | consider id as list of polynomials in x with coefficients in the |
---|
1220 | remaining variables. Then:@* |
---|
1221 | val(x) = (maximal occuring power of x, # of all monomials in leading |
---|
1222 | coefficient, # of all monomials in coefficient of next smaller power |
---|
1223 | of x,...). |
---|
1224 | EXAMPLE: example valvars; shows an example |
---|
1225 | " |
---|
1226 | { |
---|
1227 | //---------------------------- initialization --------------------------------- |
---|
1228 | int ii,jj,kk,n; |
---|
1229 | list L; // list of valuation vectors in one block |
---|
1230 | intvec vec; // describes permutation of vars (in one block) |
---|
1231 | list blockvec; // i-th element = vec of i-th block |
---|
1232 | intvec varvec; // result intvector |
---|
1233 | list Li; // result list of ideals |
---|
1234 | list LM; // result list of intmat's |
---|
1235 | intvec v,w,s; // w valuation vector for one variable |
---|
1236 | matrix C; // coefficient matrix for different variables |
---|
1237 | ideal i = simplify(ideal(matrix(id)),10); |
---|
1238 | |
---|
1239 | //---- for each pii in # create ideal a(ii) intvec v(ii) and list L(ii) ------- |
---|
1240 | // a(ii) = ideal of vars in product, v(ii)[j]=k <=> a(ii)[j]=var(k) |
---|
1241 | |
---|
1242 | v = 1..nvars(basering); |
---|
1243 | int l = size(#); |
---|
1244 | if ( l >= 2 ) |
---|
1245 | { |
---|
1246 | ideal m=maxideal(1); |
---|
1247 | for ( ii=2; ii<=l; ii=ii+2 ) |
---|
1248 | { |
---|
1249 | int n(ii) = #[ii-1]; |
---|
1250 | ideal a(ii); |
---|
1251 | intvec v(ii); |
---|
1252 | for ( jj=1; jj<=nvars(basering); jj++ ) |
---|
1253 | { |
---|
1254 | if ( #[ii]/var(jj) != 0) |
---|
1255 | { |
---|
1256 | a(ii) = a(ii) + var(jj); |
---|
1257 | v(ii)=v(ii),jj; |
---|
1258 | m[jj]=0; |
---|
1259 | v[jj]=0; |
---|
1260 | } |
---|
1261 | } |
---|
1262 | v(ii)=v(ii)[2..size(v(ii))]; |
---|
1263 | } |
---|
1264 | if ( size(m)!=0 ) |
---|
1265 | { |
---|
1266 | l = 2*(l/2)+2; |
---|
1267 | ideal a(l) = simplify(m,2); |
---|
1268 | intvec v(l) = compress(v); |
---|
1269 | int n(l); |
---|
1270 | if ( size(#)==l-1 ) { n(l) = #[l-1]; } |
---|
1271 | } |
---|
1272 | } |
---|
1273 | else |
---|
1274 | { |
---|
1275 | l = 2; |
---|
1276 | ideal a(2) = maxideal(1); |
---|
1277 | intvec v(2) = v; |
---|
1278 | int n(2); |
---|
1279 | if ( size(#)==1 ) { n(2) = #[1]; } |
---|
1280 | } |
---|
1281 | //------------- start loop to order variables in each a(ii) ------------------- |
---|
1282 | |
---|
1283 | for ( kk=2; kk<=l; kk=kk+2 ) |
---|
1284 | { |
---|
1285 | L = list(); |
---|
1286 | n = 0; |
---|
1287 | //---------------- get valuation of all variables in a(kk) -------------------- |
---|
1288 | for ( ii=1; ii<=size(a(kk)); ii++ ) |
---|
1289 | { |
---|
1290 | C = coeffs(i,a(kk)[ii]); |
---|
1291 | w = nrows(C); // =(maximal occuring power of a(kk)[ii])+1 |
---|
1292 | for ( jj=w[1]; jj>1; jj-- ) |
---|
1293 | { |
---|
1294 | s = size(C[jj,1..ncols(C)]); |
---|
1295 | w[w[1]-jj+2] = sum(s); |
---|
1296 | } |
---|
1297 | // w[1] should represent the maximal occuring power of a(kk)[ii] so it |
---|
1298 | // has to be decreased by 1 since otherwise the constant term is also |
---|
1299 | // counted |
---|
1300 | w[1]=w[1]-1; |
---|
1301 | |
---|
1302 | L[ii]=w; |
---|
1303 | n = size(w)*(size(w) > n) + n*(size(w) <= n); |
---|
1304 | } |
---|
1305 | intmat M(kk)[size(a(kk))][n]; |
---|
1306 | for ( ii=1; ii<=size(a(kk)); ii++ ) |
---|
1307 | { |
---|
1308 | if ( n==1 ) { w = L[ii]; M(kk)[ii,1] = w[1]; } |
---|
1309 | else { M(kk)[ii,1..n] = L[ii]; } |
---|
1310 | } |
---|
1311 | LM[kk-1] = a(kk); |
---|
1312 | LM[kk] = transpose(compress(M(kk))); |
---|
1313 | //------------------- compare valuation and insert in vec --------------------- |
---|
1314 | vec = sort(L)[2]; |
---|
1315 | if ( n(kk) != 0 ) { vec = vec[size(vec)..1]; } |
---|
1316 | blockvec[kk/2] = vec; |
---|
1317 | vec = sort(v(kk),vec)[1]; |
---|
1318 | varvec = varvec,vec; |
---|
1319 | } |
---|
1320 | varvec = varvec[2..size(varvec)]; |
---|
1321 | list result = varvec,blockvec,LM; |
---|
1322 | return(result); |
---|
1323 | } |
---|
1324 | example |
---|
1325 | { "EXAMPLE:"; echo = 2; |
---|
1326 | ring s=0,(x,y,z,a,b),dp; |
---|
1327 | ideal i=ax2+ay3-b2x,abz+by2; |
---|
1328 | valvars (i,0,xyz); |
---|
1329 | } |
---|
1330 | /////////////////////////////////////////////////////////////////////////////// |
---|
1331 | proc idealSplit(ideal I,list #) |
---|
1332 | "USAGE: idealSplit(id,timeF,timeS); id ideal and optional |
---|
1333 | timeF, timeS integers to bound the time which can be used |
---|
1334 | for factorization resp. standard basis computation |
---|
1335 | RETURN: a list of ideals such that their intersection |
---|
1336 | has the same radical as id |
---|
1337 | EXAMPLE: example idealSplit; shows an example |
---|
1338 | " |
---|
1339 | { |
---|
1340 | option(redSB); |
---|
1341 | int j,k,e; |
---|
1342 | int i=1; |
---|
1343 | int l=attrib(I,"isSB"); |
---|
1344 | ideal J; |
---|
1345 | int timeF; |
---|
1346 | int timeS; |
---|
1347 | list re,fac,te; |
---|
1348 | |
---|
1349 | if(size(#)==1) |
---|
1350 | { |
---|
1351 | if(typeof(#[1])=="ideal") |
---|
1352 | { |
---|
1353 | re=#; |
---|
1354 | } |
---|
1355 | else |
---|
1356 | { |
---|
1357 | timeF=#[1]; |
---|
1358 | } |
---|
1359 | } |
---|
1360 | if(size(#)==2) |
---|
1361 | { |
---|
1362 | if(typeof(#[1])=="list") |
---|
1363 | { |
---|
1364 | re=#[1]; |
---|
1365 | timeF=#[2]; |
---|
1366 | } |
---|
1367 | else |
---|
1368 | { |
---|
1369 | timeF=#[1]; |
---|
1370 | timeS=#[2]; |
---|
1371 | } |
---|
1372 | } |
---|
1373 | if(size(#)==3){re=#[1];timeF=#[2];timeS=#[3];} |
---|
1374 | |
---|
1375 | fac=timeFactorize(I[1],timeF); |
---|
1376 | |
---|
1377 | while((size(fac[1])==2)&&(i<size(I))) |
---|
1378 | { |
---|
1379 | i++; |
---|
1380 | fac=timeFactorize(I[i],timeF); |
---|
1381 | } |
---|
1382 | if(size(fac[1])>2) |
---|
1383 | { |
---|
1384 | for(j=2;j<=size(fac[1]);j++) |
---|
1385 | { |
---|
1386 | I[i]=fac[1][j]; |
---|
1387 | attrib(I,"isSB",1); |
---|
1388 | e=1; |
---|
1389 | k=0; |
---|
1390 | while(k<size(re)) |
---|
1391 | { |
---|
1392 | k++; |
---|
1393 | if(size(reduce(re[k],I))==0){e=0;break;} |
---|
1394 | attrib(re[k],"isSB",1); |
---|
1395 | if(size(reduce(I,re[k]))==0){re=delete(re,k);k--;} |
---|
1396 | } |
---|
1397 | if(e) |
---|
1398 | { |
---|
1399 | if(l) |
---|
1400 | { |
---|
1401 | J=I; |
---|
1402 | J[i]=0; |
---|
1403 | J=simplify(J,2); |
---|
1404 | attrib(J,"isSB",1); |
---|
1405 | re=idealSplit(std(J,fac[1][j]),re,timeF,timeS); |
---|
1406 | } |
---|
1407 | else |
---|
1408 | { |
---|
1409 | re=idealSplit(timeStd(I,timeS),re,timeF,timeS); |
---|
1410 | } |
---|
1411 | } |
---|
1412 | } |
---|
1413 | return(re); |
---|
1414 | } |
---|
1415 | J=timeStd(I,timeS); |
---|
1416 | attrib(I,"isSB",1); |
---|
1417 | if(size(reduce(J,I))==0){return(re+list(I));} |
---|
1418 | return(re+idealSplit(J,re,timeF,timeS)); |
---|
1419 | } |
---|
1420 | example |
---|
1421 | { "EXAMPLE:"; echo = 2; |
---|
1422 | ring r=32003,(b,s,t,u,v,w,x,y,z),dp; |
---|
1423 | ideal i= |
---|
1424 | bv+su, |
---|
1425 | bw+tu, |
---|
1426 | sw+tv, |
---|
1427 | by+sx, |
---|
1428 | bz+tx, |
---|
1429 | sz+ty, |
---|
1430 | uy+vx, |
---|
1431 | uz+wx, |
---|
1432 | vz+wy, |
---|
1433 | bvz; |
---|
1434 | idealSplit(i); |
---|
1435 | } |
---|
1436 | /////////////////////////////////////////////////////////////////////////////// |
---|
1437 | proc idealSimplify(ideal J,list #) |
---|
1438 | "USAGE: idealSimplify(id); id ideal |
---|
1439 | RETURN: ideal I = eliminate(Id,m) m is a product of variables |
---|
1440 | which are only linearly involved in the generators of id |
---|
1441 | EXAMPLE: example idealSimplify; shows an example |
---|
1442 | " |
---|
1443 | { |
---|
1444 | ideal I=J; |
---|
1445 | if(size(#)!=0){I=#[1];} |
---|
1446 | def R=basering; |
---|
1447 | matrix M=jacob(I); |
---|
1448 | ideal ma=maxideal(1); |
---|
1449 | int i,j,k; |
---|
1450 | map phi; |
---|
1451 | |
---|
1452 | for(i=1;i<=nrows(M);i++) |
---|
1453 | { |
---|
1454 | for(j=1;j<=ncols(M);j++) |
---|
1455 | { |
---|
1456 | if(deg(M[i,j])==0) |
---|
1457 | { |
---|
1458 | ma[j]=(-1/M[i,j])*(I[i]-M[i,j]*var(j)); |
---|
1459 | phi=R,ma; |
---|
1460 | I=phi(I); |
---|
1461 | J=phi(J); |
---|
1462 | for(k=1;k<=ncols(I);k++){I[k]=cleardenom(I[k]);} |
---|
1463 | M=jacob(I); |
---|
1464 | } |
---|
1465 | } |
---|
1466 | } |
---|
1467 | J=simplify(J,2); |
---|
1468 | for(i=1;i<=size(J);i++){J[i]=cleardenom(J[i]);} |
---|
1469 | return(J); |
---|
1470 | } |
---|
1471 | example |
---|
1472 | { "EXAMPLE:"; echo = 2; |
---|
1473 | ring r=0,(x,y,z,w,t),dp; |
---|
1474 | ideal i= |
---|
1475 | t, |
---|
1476 | x3+y2+2z, |
---|
1477 | x2+3y, |
---|
1478 | x2+y2+z2, |
---|
1479 | w2+z; |
---|
1480 | ideal j=idealSimplify(i); |
---|
1481 | ideal k=eliminate(i,zyt); |
---|
1482 | reduce(k,std(j)); |
---|
1483 | reduce(j,std(k)); |
---|
1484 | } |
---|
1485 | |
---|
1486 | /////////////////////////////////////////////////////////////////////////////// |
---|
1487 | |
---|
1488 | /* |
---|
1489 | |
---|
1490 | ring s=31991,(e,f,x,y,z,t,u,v,w,a,b,c,d),dp; |
---|
1491 | ring s=31991,(x,y,z,t,u,v,w,a,b,c,d,f,e,h),dp; //standard |
---|
1492 | ring s1=31991,(y,u,b,c,a,z,t,x,v,d,w,e,f,h),dp; //gut |
---|
1493 | v; |
---|
1494 | 13,12,11,10,8,7,6,5,4,3,2,1,9,14 |
---|
1495 | print(matrix(sort(maxideal(1),v))); |
---|
1496 | f,e,w,d,x,t,z,a,c,b,u,y,v,h |
---|
1497 | print(matrix(maxideal(1))); |
---|
1498 | y,u,b,c,a,z,t,x,v,d,w,e,f,h |
---|
1499 | v0; |
---|
1500 | 14,9,12,11,10,8,7,6,5,4,3,2,1,13 |
---|
1501 | print(matrix(sort(maxideal(1),v0))); |
---|
1502 | h,v,e,w,d,x,t,z,a,c,b,u,y,f |
---|
1503 | v1;v2; |
---|
1504 | 9,12,11,10,8,7,6,5,4,3,2,1,13,14 |
---|
1505 | 13,12,11,10,8,7,6,5,4,3,2,1,9,14 |
---|
1506 | |
---|
1507 | Ev. Gute Ordnung fuer i: |
---|
1508 | ======================== |
---|
1509 | i=ad*x^d+ad-1*x^(d-1)+...+a1*x+a0, ad!=0 |
---|
1510 | mit ar=(ar1,...,ark), k=size(i) |
---|
1511 | arj in K[..x^..] |
---|
1512 | d=deg_x(i) := max{deg_x(i[k]) | k=1..size(i)} |
---|
1513 | size_x(i,deg_x(i)..0) := size(ad),...,size(a0) |
---|
1514 | x>y <== |
---|
1515 | 1. deg_x(i)>deg_y(i) |
---|
1516 | 2. "=" in 1. und size_x lexikographisch |
---|
1517 | |
---|
1518 | hier im Beispiel: |
---|
1519 | f: 5,1,0,1,2 |
---|
1520 | |
---|
1521 | u: 3,1,4 |
---|
1522 | |
---|
1523 | y: 3,1,3 |
---|
1524 | b: 3,1,3 |
---|
1525 | c: 3,1,3 |
---|
1526 | a: 3,1,3 |
---|
1527 | z: 3,1,3 |
---|
1528 | t: 3,1,3 |
---|
1529 | |
---|
1530 | x: 3,1,2 |
---|
1531 | v: 3,1,2 |
---|
1532 | d: 3,1,2 |
---|
1533 | w: 3,1,2 |
---|
1534 | e: 3,1,2 |
---|
1535 | probier mal: |
---|
1536 | ring s=31991,(f,u,y,z,t,a,b,c,v,w,d,e,h),dp; //standard |
---|
1537 | |
---|
1538 | */ |
---|