Annotation of OpenXM/src/asir-doc/parts/groebner.texi, Revision 1.21
1.21 ! takayama 1: @comment $OpenXM: OpenXM/src/asir-doc/parts/groebner.texi,v 1.20 2017/08/31 04:54:36 takayama Exp $
1.2 noro 2: \BJP
1.1 noro 3: @node �$B%0%l%V%J4pDl$N7W;;�(B,,, Top
4: @chapter �$B%0%l%V%J4pDl$N7W;;�(B
1.2 noro 5: \E
6: \BEG
7: @node Groebner basis computation,,, Top
8: @chapter Groebner basis computation
9: \E
1.1 noro 10:
11: @menu
1.2 noro 12: \BJP
1.1 noro 13: * �$BJ,;6I=8=B?9`<0�(B::
14: * �$B%U%!%$%k$NFI$_9~$_�(B::
15: * �$B4pK\E*$JH!?t�(B::
16: * �$B7W;;$*$h$SI=<($N@)8f�(B::
17: * �$B9`=g=x$N@_Dj�(B::
1.13 noro 18: * Weight::
1.1 noro 19: * �$BM-M}<0$r78?t$H$9$k%0%l%V%J4pDl7W;;�(B::
20: * �$B4pDlJQ49�(B::
1.5 noro 21: * Weyl �$BBe?t�(B::
1.1 noro 22: * �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B::
1.2 noro 23: \E
24: \BEG
25: * Distributed polynomial::
26: * Reading files::
27: * Fundamental functions::
28: * Controlling Groebner basis computations::
29: * Setting term orderings::
1.13 noro 30: * Weight::
1.2 noro 31: * Groebner basis computation with rational function coefficients::
32: * Change of ordering::
1.5 noro 33: * Weyl algebra::
1.2 noro 34: * Functions for Groebner basis computation::
35: \E
1.1 noro 36: @end menu
37:
1.2 noro 38: \BJP
1.1 noro 39: @node �$BJ,;6I=8=B?9`<0�(B,,, �$B%0%l%V%J4pDl$N7W;;�(B
40: @section �$BJ,;6I=8=B?9`<0�(B
1.2 noro 41: \E
42: \BEG
43: @node Distributed polynomial,,, Groebner basis computation
44: @section Distributed polynomial
45: \E
1.1 noro 46:
47: @noindent
1.2 noro 48: \BJP
1.1 noro 49: �$BJ,;6I=8=B?9`<0$H$O�(B, �$BB?9`<0$NFbIt7A<0$N0l$D$G$"$k�(B. �$BDL>o$NB?9`<0�(B
50: (@code{type} �$B$,�(B 2) �$B$O�(B, �$B:F5"I=8=$H8F$P$l$k7A<0$GI=8=$5$l$F$$$k�(B. �$B$9$J$o�(B
51: �$B$A�(B, �$BFCDj$NJQ?t$r<gJQ?t$H$9$k�(B 1 �$BJQ?tB?9`<0$G�(B, �$B$=$NB>$NJQ?t$O�(B, �$B$=$N�(B 1 �$BJQ�(B
52: �$B?tB?9`<0$N78?t$K�(B, �$B<gJQ?t$r4^$^$J$$B?9`<0$H$7$F8=$l$k�(B. �$B$3$N78?t$,�(B, �$B$^$?�(B,
53: �$B$"$kJQ?t$r<gJQ?t$H$9$kB?9`<0$H$J$C$F$$$k$3$H$+$i:F5"I=8=$H8F$P$l$k�(B.
1.2 noro 54: \E
55: \BEG
56: A distributed polynomial is a polynomial with a special internal
57: representation different from the ordinary one.
58:
59: An ordinary polynomial (having @code{type} 2) is internally represented
60: in a format, called recursive representation.
61: In fact, it is represented as an uni-variate polynomial with respect to
62: a fixed variable, called main variable of that polynomial,
63: where the other variables appear in the coefficients which may again
64: polynomials in such variables other than the previous main variable.
65: A polynomial in the coefficients is again represented as
66: an uni-variate polynomial in a certain fixed variable,
67: the main variable. Thus, by this recursive structure of polynomial
68: representation, it is called the `recursive representation.'
69: \E
1.1 noro 70:
71: @iftex
72: @tex
1.2 noro 73: \JP $(x+y+z)^2 = 1 \cdot x^2 + (2 \cdot y + (2 \cdot z)) \cdot x + ((2 \cdot z) \cdot y + (1 \cdot z^2 ))$
74: \EG $(x+y+z)^2 = 1 \cdot x^2 + (2 \cdot y + (2 \cdot z)) \cdot x + ((2 \cdot z) \cdot y + (1 \cdot z^2 ))$
1.1 noro 75: @end tex
76: @end iftex
77: @ifinfo
78: @example
79: (x+y+z)^2 = 1 x^2 + (2 y + (2 z)) x + ((2 z) y + (1 z^2 ))
80: @end example
81: @end ifinfo
82:
83: @noindent
1.2 noro 84: \BJP
1.1 noro 85: �$B$3$l$KBP$7�(B, �$BB?9`<0$r�(B, �$BJQ?t$NQQ@Q$H78?t$N@Q$NOB$H$7$FI=8=$7$?$b$N$rJ,;6�(B
86: �$BI=8=$H8F$V�(B.
1.2 noro 87: \E
88: \BEG
89: On the other hand,
90: we call a representation the distributed representation of a polynomial,
91: if a polynomial is represented, according to its original meaning,
92: as a sum of monomials,
93: where a monomial is the product of power product of variables
94: and a coefficient. We call a polynomial, represented in such an
95: internal format, a distributed polynomial. (This naming may sounds
96: something strange.)
97: \E
1.1 noro 98:
99: @iftex
100: @tex
1.2 noro 101: \JP $(x+y+z)^2 = 1 \cdot x^2 + 2 \cdot xy + 2 \cdot xz + 1 \cdot y^2 + 2 \cdot yz +1 \cdot z^2$
102: \EG $(x+y+z)^2 = 1 \cdot x^2 + 2 \cdot xy + 2 \cdot xz + 1 \cdot y^2 + 2 \cdot yz +1 \cdot z^2$
1.1 noro 103: @end tex
104: @end iftex
105: @ifinfo
106: @example
107: (x+y+z)^2 = 1 x^2 + 2 xy + 2 xz + 1 y^2 + 2 yz +1 z^2$
108: @end example
109: @end ifinfo
110:
111: @noindent
1.2 noro 112: \BJP
1.1 noro 113: �$B%0%l%V%J4pDl7W;;$K$*$$$F$O�(B, �$BC19`<0$KCmL\$7$FA`:n$r9T$&$?$aB?9`<0$,J,;6I=8=�(B
114: �$B$5$l$F$$$kJ}$,$h$j8zN($N$h$$1i;;$,2DG=$K$J$k�(B. �$B$3$N$?$a�(B, �$BJ,;6I=8=B?9`<0$,�(B,
115: �$B<1JL;R�(B 9 �$B$N7?$H$7$F�(B @b{Asir} �$B$N%H%C%W%l%Y%k$+$iMxMQ2DG=$H$J$C$F$$$k�(B.
116: �$B$3$3$G�(B, �$B8e$N@bL@$N$?$a$K�(B, �$B$$$/$D$+$N8@MU$rDj5A$7$F$*$/�(B.
1.2 noro 117: \E
118: \BEG
119: For computation of Groebner basis, efficient operation is expected if
120: polynomials are represented in a distributed representation,
121: because major operations for Groebner basis are performed with respect
122: to monomials.
123: From this view point, we provide the object type distributed polynomial
124: with its object identification number 9, and objects having such a type
125: are available by @b{Asir} language.
126:
127: Here, we provide several definitions for the later description.
128: \E
1.1 noro 129:
130: @table @b
1.2 noro 131: \BJP
1.1 noro 132: @item �$B9`�(B (term)
133: �$BJQ?t$NQQ@Q�(B. �$B$9$J$o$A�(B, �$B78?t�(B 1 �$B$NC19`<0$N$3$H�(B. @b{Asir} �$B$K$*$$$F$O�(B,
1.2 noro 134: \E
135: \BEG
136: @item term
137: The power product of variables, i.e., a monomial with coefficient 1.
138: In an @b{Asir} session, it is displayed in the form like
139: \E
1.1 noro 140:
141: @example
142: <<0,1,2,3,4>>
143: @end example
144:
1.2 noro 145: \BJP
1.1 noro 146: �$B$H$$$&7A$GI=<($5$l�(B, �$B$^$?�(B, �$B$3$N7A$GF~NO2DG=$G$"$k�(B. �$B$3$NNc$O�(B, 5 �$BJQ?t$N9`�(B
147: �$B$r<($9�(B. �$B3FJQ?t$r�(B @code{a}, @code{b}, @code{c}, @code{d}, @code{e} �$B$H$9$k$H�(B
148: �$B$3$N9`$O�(B @code{b*c^2*d^3*e^4} �$B$rI=$9�(B.
1.2 noro 149: \E
150: \BEG
151: and also can be input in such a form.
152: This example shows a term in 5 variables. If we assume the 5 variables
153: as @code{a}, @code{b}, @code{c}, @code{d}, and @code{e},
154: the term represents @code{b*c^2*d^3*e^4} in the ordinary expression.
155: \E
1.1 noro 156:
1.2 noro 157: \BJP
1.1 noro 158: @item �$B9`=g=x�(B (term order)
159: �$BJ,;6I=8=B?9`<0$K$*$1$k9`$O�(B, �$B<!$N@-<A$rK~$?$9A4=g=x$K$h$j@0Ns$5$l$k�(B.
1.2 noro 160: \E
161: \BEG
162: @item term order
163: Terms are ordered according to a total order with the following properties.
164: \E
1.1 noro 165:
166: @enumerate
167: @item
1.2 noro 168: \JP �$BG$0U$N9`�(B @code{t} �$B$KBP$7�(B @code{t} > 1
169: \EG For all @code{t} @code{t} > 1.
1.1 noro 170:
171: @item
1.2 noro 172: \JP @code{t}, @code{s}, @code{u} �$B$r9`$H$9$k;~�(B, @code{t} > @code{s} �$B$J$i$P�(B @code{tu} > @code{su}
173: \EG For all @code{t}, @code{s}, @code{u} @code{t} > @code{s} implies @code{tu} > @code{su}.
1.1 noro 174: @end enumerate
175:
1.2 noro 176: \BJP
1.1 noro 177: �$B$3$N@-<A$rK~$?$9A4=g=x$r9`=g=x$H8F$V�(B. �$B$3$N=g=x$OJQ?t=g=x�(B (�$BJQ?t$N%j%9%H�(B)
178: �$B$H9`=g=x7?�(B (�$B?t�(B, �$B%j%9%H$^$?$O9TNs�(B) �$B$K$h$j;XDj$5$l$k�(B.
1.2 noro 179: \E
180: \BEG
181: Such a total order is called a term ordering. A term ordering is specified
182: by a variable ordering (a list of variables) and a type of term ordering
183: (an integer, a list or a matrix).
184: \E
1.1 noro 185:
1.2 noro 186: \BJP
1.1 noro 187: @item �$BC19`<0�(B (monomial)
188: �$B9`$H78?t$N@Q�(B.
1.2 noro 189: \E
190: \BEG
191: @item monomial
192: The product of a term and a coefficient.
193: In an @b{Asir} session, it is displayed in the form like
194: \E
1.1 noro 195:
196: @example
197: 2*<<0,1,2,3,4>>
198: @end example
199:
1.2 noro 200: \JP �$B$H$$$&7A$GI=<($5$l�(B, �$B$^$?�(B, �$B$3$N7A$GF~NO2DG=$G$"$k�(B.
201: \EG and also can be input in such a form.
1.1 noro 202:
1.2 noro 203: \BJP
1.19 noro 204: @item �$BF,9`�(B (head term)
1.1 noro 205: @itemx �$BF,C19`<0�(B (head monomial)
206: @itemx �$BF,78?t�(B (head coefficient)
207: �$BJ,;6I=8=B?9`<0$K$*$1$k3FC19`<0$O�(B, �$B9`=g=x$K$h$j@0Ns$5$l$k�(B. �$B$3$N;~=g�(B
208: �$B=x:GBg$NC19`<0$rF,C19`<0�(B, �$B$=$l$K8=$l$k9`�(B, �$B78?t$r$=$l$>$lF,9`�(B, �$BF,78?t�(B
209: �$B$H8F$V�(B.
1.2 noro 210: \E
211: \BEG
1.19 noro 212: @item head term
1.2 noro 213: @itemx head monomial
214: @itemx head coefficient
215:
216: Monomials in a distributed polynomial is sorted by a total order.
217: In such representation, we call the monomial that is maximum
218: with respect to the order the head monomial, and its term and coefficient
219: the head term and the head coefficient respectively.
220: \E
1.1 noro 221: @end table
222:
1.20 takayama 223: @noindent
224: ChangeLog
225: @itemize @bullet
226: \BJP
227: @item �$BJ,;6I=8=B?9`<0$OG$0U$N%*%V%8%'%/%H$r78?t$K$b$F$k$h$&$K$J$C$?�(B.
228: �$B$^$?2C72$N�(Bk�$B@.J,$NMWAG$r<!$N7A<0�(B <<d0,d1,...:k>> �$B$GI=8=$9$k$h$&$K$J$C$?�(B (2017-08-31).
229: \E
230: \BEG
231: @item Distributed polynomials accept objects as coefficients.
232: The k-th element of a free module is expressed as <<d0,d1,...:k>> (2017-08-31).
233: \E
234: @item
235: 1.15 algnum.c,
236: 1.53 ctrl.c,
237: 1.66 dp-supp.c,
238: 1.105 dp.c,
239: 1.73 gr.c,
240: 1.4 reduct.c,
241: 1.16 _distm.c,
242: 1.17 dalg.c,
243: 1.52 dist.c,
244: 1.20 distm.c,
245: 1.8 gmpq.c,
246: 1.238 engine/nd.c,
247: 1.102 ca.h,
248: 1.411 version.h,
249: 1.28 cpexpr.c,
250: 1.42 pexpr.c,
251: 1.20 pexpr_body.c,
252: 1.40 spexpr.c,
253: 1.27 arith.c,
254: 1.77 eval.c,
255: 1.56 parse.h,
256: 1.37 parse.y,
257: 1.8 stdio.c,
258: 1.31 plotf.c
259: @end itemize
260:
1.2 noro 261: \BJP
1.1 noro 262: @node �$B%U%!%$%k$NFI$_9~$_�(B,,, �$B%0%l%V%J4pDl$N7W;;�(B
263: @section �$B%U%!%$%k$NFI$_9~$_�(B
1.2 noro 264: \E
265: \BEG
266: @node Reading files,,, Groebner basis computation
267: @section Reading files
268: \E
1.1 noro 269:
270: @noindent
1.2 noro 271: \BJP
1.1 noro 272: �$B%0%l%V%J4pDl$r7W;;$9$k$?$a$N4pK\E*$JH!?t$O�(B @code{dp_gr_main()} �$B$*$h$S�(B
1.5 noro 273: @code{dp_gr_mod_main()}, @code{dp_gr_f_main()}
274: �$B$J$k�(B 3 �$B$D$NAH$_9~$_H!?t$G$"$k$,�(B, �$BDL>o$O�(B, �$B%Q%i%a%?�(B
1.1 noro 275: �$B@_Dj$J$I$r9T$C$?$N$A$3$l$i$r8F$S=P$9%f!<%6H!?t$rMQ$$$k$N$,JXMx$G$"$k�(B.
276: �$B$3$l$i$N%f!<%6H!?t$O�(B, �$B%U%!%$%k�(B @samp{gr} �$B$r�(B @code{load()} �$B$K$h$jFI�(B
277: �$B$_9~$`$3$H$K$h$j;HMQ2DG=$H$J$k�(B. @samp{gr} �$B$O�(B, @b{Asir} �$B$NI8=`�(B
1.5 noro 278: �$B%i%$%V%i%j%G%#%l%/%H%j$KCV$+$l$F$$$k�(B.
1.2 noro 279: \E
280: \BEG
1.5 noro 281: Facilities for computing Groebner bases are
282: @code{dp_gr_main()}, @code{dp_gr_mod_main()}and @code{dp_gr_f_main()}.
283: To call these functions,
284: it is necessary to set several parameters correctly and it is convenient
285: to use a set of interface functions provided in the library file
286: @samp{gr}.
1.2 noro 287: The facilities will be ready to use after you load the package by
288: @code{load()}. The package @samp{gr} is placed in the standard library
1.5 noro 289: directory of @b{Asir}.
1.2 noro 290: \E
1.1 noro 291:
292: @example
293: [0] load("gr")$
294: @end example
295:
1.2 noro 296: \BJP
1.1 noro 297: @node �$B4pK\E*$JH!?t�(B,,, �$B%0%l%V%J4pDl$N7W;;�(B
298: @section �$B4pK\E*$JH!?t�(B
1.2 noro 299: \E
300: \BEG
301: @node Fundamental functions,,, Groebner basis computation
302: @section Fundamental functions
303: \E
1.1 noro 304:
305: @noindent
1.2 noro 306: \BJP
1.1 noro 307: @samp{gr} �$B$G$O?tB?$/$NH!?t$,Dj5A$5$l$F$$$k$,�(B, �$BD>@\�(B
308: �$B%0%l%V%J4pDl$r7W;;$9$k$?$a$N%H%C%W%l%Y%k$O<!$N�(B 3 �$B$D$G$"$k�(B.
309: �$B0J2<$G�(B, @var{plist} �$B$OB?9`<0$N%j%9%H�(B, @var{vlist} �$B$OJQ?t�(B (�$BITDj85�(B) �$B$N%j%9%H�(B,
310: @var{order} �$B$OJQ?t=g=x7?�(B, @var{p} �$B$O�(B @code{2^27} �$BL$K~$NAG?t$G$"$k�(B.
1.2 noro 311: \E
312: \BEG
313: There are many functions and options defined in the package @samp{gr}.
314: Usually not so many of them are used. Top level functions for Groebner
315: basis computation are the following three functions.
316:
317: In the following description, @var{plist}, @var{vlist}, @var{order}
318: and @var{p} stand for a list of polynomials, a list of variables
319: (indeterminates), a type of term ordering and a prime less than
320: @code{2^27} respectively.
321: \E
1.1 noro 322:
323: @table @code
324: @item gr(@var{plist},@var{vlist},@var{order})
325:
1.2 noro 326: \BJP
1.1 noro 327: Gebauer-Moeller �$B$K$h$k�(B useless pair elimination criteria, sugar
328: strategy �$B$*$h$S�(B Traverso �$B$K$h$k�(B trace-lifting �$B$rMQ$$$?�(B Buchberger �$B%"%k�(B
329: �$B%4%j%:%`$K$h$kM-M}?t78?t%0%l%V%J4pDl7W;;H!?t�(B. �$B0lHL$K$O$3$NH!?t$rMQ$$$k�(B.
1.2 noro 330: \E
331: \BEG
332: Function that computes Groebner bases over the rationals. The
333: algorithm is Buchberger algorithm with useless pair elimination
334: criteria by Gebauer-Moeller, sugar strategy and trace-lifting by
335: Traverso. For ordinary computation, this function is used.
336: \E
1.1 noro 337:
338: @item hgr(@var{plist},@var{vlist},@var{order})
339:
1.2 noro 340: \BJP
1.1 noro 341: �$BF~NOB?9`<0$r@F<!2=$7$?8e�(B @code{gr()} �$B$N%0%l%V%J4pDl8uJd@8@.It$K$h$j8u�(B
342: �$BJd@8@.$7�(B, �$BHs@F<!2=�(B, interreduce �$B$7$?$b$N$r�(B @code{gr()} �$B$N%0%l%V%J4pDl�(B
343: �$B%A%'%C%/It$G%A%'%C%/$9$k�(B. 0 �$B<!85%7%9%F%`�(B (�$B2r$N8D?t$,M-8B8D$NJ}Dx<07O�(B)
344: �$B$N>l9g�(B, sugar strategy �$B$,78?tKDD%$r0z$-5/$3$9>l9g$,$"$k�(B. �$B$3$N$h$&$J>l�(B
345: �$B9g�(B, strategy �$B$r@F<!2=$K$h$k�(B strategy �$B$KCV$-49$($k$3$H$K$h$j78?tKDD%$r�(B
346: �$BM^@)$9$k$3$H$,$G$-$k>l9g$,B?$$�(B.
1.2 noro 347: \E
348: \BEG
349: After homogenizing the input polynomials a candidate of the \gr basis
350: is computed by trace-lifting. Then the candidate is dehomogenized and
351: checked whether it is indeed a Groebner basis of the input. Sugar
352: strategy often causes intermediate coefficient swells. It is
353: empirically known that the combination of homogenization and supresses
354: the swells for such cases.
355: \E
1.1 noro 356:
357: @item gr_mod(@var{plist},@var{vlist},@var{order},@var{p})
358:
1.2 noro 359: \BJP
1.1 noro 360: Gebauer-Moeller �$B$K$h$k�(B useless pair elimination criteria, sugar
361: strategy �$B$*$h$S�(B Buchberger �$B%"%k%4%j%:%`$K$h$k�(B GF(p) �$B78?t%0%l%V%J4pDl7W�(B
362: �$B;;H!?t�(B.
1.2 noro 363: \E
364: \BEG
365: Function that computes Groebner bases over GF(@var{p}). The same
366: algorithm as @code{gr()} is used.
367: \E
1.1 noro 368:
369: @end table
370:
1.2 noro 371: \BJP
1.1 noro 372: @node �$B7W;;$*$h$SI=<($N@)8f�(B,,, �$B%0%l%V%J4pDl$N7W;;�(B
373: @section �$B7W;;$*$h$SI=<($N@)8f�(B
1.2 noro 374: \E
375: \BEG
376: @node Controlling Groebner basis computations,,, Groebner basis computation
377: @section Controlling Groebner basis computations
378: \E
1.1 noro 379:
380: @noindent
1.2 noro 381: \BJP
1.1 noro 382: �$B%0%l%V%J4pDl$N7W;;$K$*$$$F�(B, �$B$5$^$6$^$J%Q%i%a%?@_Dj$r9T$&$3$H$K$h$j7W;;�(B,
383: �$BI=<($r@)8f$9$k$3$H$,$G$-$k�(B. �$B$3$l$i$O�(B, �$BAH$_9~$_H!?t�(B @code{dp_gr_flags()}
384: �$B$K$h$j@_Dj;2>H$9$k$3$H$,$G$-$k�(B. �$BL50z?t$G�(B @code{dp_gr_flags()} �$B$r<B9T$9$k�(B
385: �$B$H�(B, �$B8=:_@_Dj$5$l$F$$$k%Q%i%a%?$,�(B, �$BL>A0$HCM$N%j%9%H$GJV$5$l$k�(B.
1.2 noro 386: \E
387: \BEG
388: One can cotrol a Groebner basis computation by setting various parameters.
389: These parameters can be set and examined by a built-in function
390: @code{dp_gr_flags()}. Without argument it returns the current settings.
391: \E
1.1 noro 392:
393: @example
394: [100] dp_gr_flags();
1.5 noro 395: [Demand,0,NoSugar,0,NoCriB,0,NoGC,0,NoMC,0,NoRA,0,NoGCD,0,Top,0,
396: ShowMag,1,Print,1,Stat,0,Reverse,0,InterReduce,0,Multiple,0]
1.1 noro 397: [101]
398: @end example
399:
1.2 noro 400: \BJP
1.1 noro 401: �$B0J2<$G�(B, �$B3F%Q%i%a%?$N0UL#$r@bL@$9$k�(B. on �$B$N>l9g$H$O�(B, �$B%Q%i%a%?$,�(B 0 �$B$G$J$$>l9g$r�(B
402: �$B$$$&�(B. �$B$3$l$i$N%Q%i%a%?$N=i4|CM$OA4$F�(B 0 (off) �$B$G$"$k�(B.
1.2 noro 403: \E
404: \BEG
405: The return value is a list which contains the names of parameters and their
406: values. The meaning of the parameters are as follows. `on' means that the
407: parameter is not zero.
408: \E
1.1 noro 409:
410: @table @code
411: @item NoSugar
1.2 noro 412: \BJP
1.1 noro 413: on �$B$N>l9g�(B, sugar strategy �$B$NBe$o$j$K�(B Buchberger�$B$N�(B normal strategy �$B$,MQ�(B
414: �$B$$$i$l$k�(B.
1.2 noro 415: \E
416: \BEG
417: If `on', Buchberger's normal strategy is used instead of sugar strategy.
418: \E
1.1 noro 419:
420: @item NoCriB
1.2 noro 421: \JP on �$B$N>l9g�(B, �$BITI,MWBP8!=P5,=`$N$&$A�(B, �$B5,=`�(B B �$B$rE,MQ$7$J$$�(B.
422: \EG If `on', criterion B among the Gebauer-Moeller's criteria is not applied.
1.1 noro 423:
424: @item NoGC
1.2 noro 425: \JP on �$B$N>l9g�(B, �$B7k2L$,%0%l%V%J4pDl$K$J$C$F$$$k$+$I$&$+$N%A%'%C%/$r9T$o$J$$�(B.
426: \BEG
427: If `on', the check that a Groebner basis candidate is indeed a Groebner basis,
428: is not executed.
429: \E
1.1 noro 430:
431: @item NoMC
1.2 noro 432: \BJP
1.1 noro 433: on �$B$N>l9g�(B, �$B7k2L$,F~NO%$%G%"%k$HF1Ey$N%$%G%"%k$G$"$k$+$I$&$+$N%A%'%C%/�(B
434: �$B$r9T$o$J$$�(B.
1.2 noro 435: \E
436: \BEG
437: If `on', the check that the resulting polynomials generates the same ideal as
438: the ideal generated by the input, is not executed.
439: \E
1.1 noro 440:
441: @item NoRA
1.2 noro 442: \BJP
1.1 noro 443: on �$B$N>l9g�(B, �$B7k2L$r�(B reduced �$B%0%l%V%J4pDl$K$9$k$?$a$N�(B
444: interreduce �$B$r9T$o$J$$�(B.
1.2 noro 445: \E
446: \BEG
447: If `on', the interreduction, which makes the Groebner basis reduced, is not
448: executed.
449: \E
1.1 noro 450:
451: @item NoGCD
1.2 noro 452: \BJP
1.1 noro 453: on �$B$N>l9g�(B, �$BM-M}<078?t$N%0%l%V%J4pDl7W;;$K$*$$$F�(B, �$B@8@.$5$l$?B?9`<0$N�(B,
454: �$B78?t$N�(B content �$B$r$H$i$J$$�(B.
1.2 noro 455: \E
456: \BEG
457: If `on', content removals are not executed during a Groebner basis computation
458: over a rational function field.
459: \E
1.1 noro 460:
461: @item Top
1.2 noro 462: \JP on �$B$N>l9g�(B, normal form �$B7W;;$K$*$$$FF,9`>C5n$N$_$r9T$&�(B.
463: \EG If `on', Only the head term of the polynomial being reduced is reduced.
1.1 noro 464:
1.2 noro 465: @comment @item Interreduce
466: @comment \BJP
467: @comment on �$B$N>l9g�(B, �$BB?9`<0$r@8@.$9$kKh$K�(B, �$B$=$l$^$G@8@.$5$l$?4pDl$r$=$NB?9`<0$K�(B
468: @comment �$B$h$k�(B normal form �$B$GCV$-49$($k�(B.
469: @comment \E
470: @comment \BEG
471: @comment If `on', intermediate basis elements are reduced by using a newly generated
472: @comment basis element.
473: @comment \E
1.1 noro 474:
475: @item Reverse
1.2 noro 476: \BJP
1.1 noro 477: on �$B$N>l9g�(B, normal form �$B7W;;$N:]$N�(B reducer �$B$r�(B, �$B?7$7$/@8@.$5$l$?$b$N$rM%�(B
478: �$B@h$7$FA*$V�(B.
1.2 noro 479: \E
480: \BEG
481: If `on', the selection strategy of reducer in a normal form computation
482: is such that a newer reducer is used first.
483: \E
1.1 noro 484:
485: @item Print
1.2 noro 486: \JP on �$B$N>l9g�(B, �$B%0%l%V%J4pDl7W;;$NESCf$K$*$1$k$5$^$6$^$J>pJs$rI=<($9$k�(B.
487: \BEG
488: If `on', various informations during a Groebner basis computation is
489: displayed.
490: \E
1.1 noro 491:
1.7 noro 492: @item PrintShort
493: \JP on �$B$G!"�(BPrint �$B$,�(B off �$B$N>l9g�(B, �$B%0%l%V%J4pDl7W;;$NESCf$N>pJs$rC;=L7A$GI=<($9$k�(B.
494: \BEG
495: If `on' and Print is `off', short information during a Groebner basis computation is
496: displayed.
497: \E
498:
1.1 noro 499: @item Stat
1.2 noro 500: \BJP
1.1 noro 501: on �$B$G�(B @code{Print} �$B$,�(B off �$B$J$i$P�(B, @code{Print} �$B$,�(B on �$B$N$H$-I=<($5�(B
502: �$B$l$k%G!<%?$NFb�(B, �$B=87W%G!<%?$N$_$,I=<($5$l$k�(B.
1.2 noro 503: \E
504: \BEG
505: If `on', a summary of informations is shown after a Groebner basis
506: computation. Note that the summary is always shown if @code{Print} is `on'.
507: \E
1.1 noro 508:
509: @item ShowMag
1.2 noro 510: \BJP
1.1 noro 511: on �$B$G�(B @code{Print} �$B$,�(B on �$B$J$i$P�(B, �$B@8@.$,@8@.$5$l$kKh$K�(B, �$B$=$NB?9`<0$N�(B
512: �$B78?t$N%S%C%HD9$NOB$rI=<($7�(B, �$B:G8e$K�(B, �$B$=$l$i$NOB$N:GBgCM$rI=<($9$k�(B.
1.2 noro 513: \E
514: \BEG
515: If `on' and @code{Print} is `on', the sum of bit length of
516: coefficients of a generated basis element, which we call @var{magnitude},
517: is shown after every normal computation. After comleting the
518: computation the maximal value among the sums is shown.
519: \E
1.1 noro 520:
1.7 noro 521: @item Content
522: @itemx Multiple
1.2 noro 523: \BJP
1.7 noro 524: 0 �$B$G$J$$M-M}?t$N;~�(B, �$BM-M}?t>e$N@55,7A7W;;$K$*$$$F�(B, �$B78?t$N%S%C%HD9$NOB$,�(B
525: @code{Content} �$BG\$K$J$k$4$H$K78?tA4BN$N�(B GCD �$B$,7W;;$5$l�(B, �$B$=$N�(B GCD �$B$G�(B
526: �$B3d$C$?B?9`<0$r4JLs$9$k�(B. @code{Content} �$B$,�(B 1 �$B$J$i$P�(B, �$B4JLs$9$k$4$H$K�(B
527: GCD �$B7W;;$,9T$o$l0lHL$K$O8zN($,0-$/$J$k$,�(B, @code{Content} �$B$r�(B 2 �$BDxEY�(B
1.1 noro 528: �$B$H$9$k$H�(B, �$B5pBg$J@0?t$,78?t$K8=$l$k>l9g�(B, �$B8zN($,NI$/$J$k>l9g$,$"$k�(B.
1.7 noro 529: backward compatibility �$B$N$?$a!"�(B@code{Multiple} �$B$G@0?tCM$r;XDj$G$-$k�(B.
1.2 noro 530: \E
531: \BEG
1.7 noro 532: If a non-zero rational number, in a normal form computation
1.2 noro 533: over the rationals, the integer content of the polynomial being
1.7 noro 534: reduced is removed when its magnitude becomes @code{Content} times
1.2 noro 535: larger than a registered value, which is set to the magnitude of the
536: input polynomial. After each content removal the registered value is
1.7 noro 537: set to the magnitude of the resulting polynomial. @code{Content} is
1.2 noro 538: equal to 1, the simiplification is done after every normal form computation.
1.7 noro 539: It is empirically known that it is often efficient to set @code{Content} to 2
1.2 noro 540: for the case where large integers appear during the computation.
1.7 noro 541: An integer value can be set by the keyword @code{Multiple} for
542: backward compatibility.
1.2 noro 543: \E
1.1 noro 544:
545: @item Demand
1.2 noro 546:
547: \BJP
1.1 noro 548: �$B@5Ev$J%G%#%l%/%H%jL>�(B (�$BJ8;zNs�(B) �$B$rCM$K;}$D$H$-�(B, �$B@8@.$5$l$?B?9`<0$O%a%b%j�(B
549: �$BCf$K$*$+$l$:�(B, �$B$=$N%G%#%l%/%H%jCf$K%P%$%J%j%G!<%?$H$7$FCV$+$l�(B, �$B$=$NB?9`�(B
550: �$B<0$rMQ$$$k�(B normal form �$B7W;;$N:]�(B, �$B<+F0E*$K%a%b%jCf$K%m!<%I$5$l$k�(B. �$B3FB?�(B
551: �$B9`<0$O�(B, �$BFbIt$G$N%$%s%G%C%/%9$r%U%!%$%kL>$K;}$D%U%!%$%k$K3JG<$5$l$k�(B.
552: �$B$3$3$G;XDj$5$l$?%G%#%l%/%H%j$K=q$+$l$?%U%!%$%k$O<+F0E*$K$O>C5n$5$l$J$$�(B
553: �$B$?$a�(B, �$B%f!<%6$,@UG$$r;}$C$F>C5n$9$kI,MW$,$"$k�(B.
1.2 noro 554: \E
555: \BEG
556: If the value (a character string) is a valid directory name, then
557: generated basis elements are put in the directory and are loaded on
558: demand during normal form computations. Each elements is saved in the
559: binary form and its name coincides with the index internally used in
560: the computation. These binary files are not removed automatically
561: and one should remove them by hand.
562: \E
1.1 noro 563: @end table
564:
565: @noindent
1.2 noro 566: \JP @code{Print} �$B$,�(B 0 �$B$G$J$$>l9g<!$N$h$&$J%G!<%?$,I=<($5$l$k�(B.
567: \EG If @code{Print} is `on', the following informations are shown.
1.1 noro 568:
569: @example
570: [93] gr(cyclic(4),[c0,c1,c2,c3],0)$
571: mod= 99999989, eval = []
572: (0)(0)<<0,2,0,0>>(2,3),nb=2,nab=5,rp=2,sugar=2,mag=4
573: (0)(0)<<0,1,2,0>>(1,2),nb=3,nab=6,rp=2,sugar=3,mag=4
574: (0)(0)<<0,1,1,2>>(0,1),nb=4,nab=7,rp=3,sugar=4,mag=6
575: .
576: (0)(0)<<0,0,3,2>>(5,6),nb=5,nab=8,rp=2,sugar=5,mag=4
577: (0)(0)<<0,1,0,4>>(4,6),nb=6,nab=9,rp=3,sugar=5,mag=4
578: (0)(0)<<0,0,2,4>>(6,8),nb=7,nab=10,rp=4,sugar=6,mag=6
579: ....gb done
580: reduceall
581: .......
582: membercheck
583: (0,0)(0,0)(0,0)(0,0)
584: gbcheck total 8 pairs
585: ........
1.5 noro 586: UP=(0,0)SP=(0,0)SPM=(0,0)NF=(0,0)NFM=(0.010002,0)ZNFM=(0.010002,0)
587: PZ=(0,0)NP=(0,0)MP=(0,0)RA=(0,0)MC=(0,0)GC=(0,0)T=40,B=0 M=8 F=6
588: D=12 ZR=5 NZR=6 Max_mag=6
1.1 noro 589: [94]
590: @end example
591:
592: @noindent
1.2 noro 593: \BJP
1.1 noro 594: �$B:G=i$KI=<($5$l$k�(B @code{mod}, @code{eval} �$B$O�(B, trace-lifting �$B$GMQ$$$i$l$kK!�(B
595: �$B$G$"$k�(B. @code{mod} �$B$OAG?t�(B, @code{eval} �$B$OM-M}<078?t$N>l9g$KMQ$$$i$l$k�(B
596: �$B?t$N%j%9%H$G$"$k�(B.
1.2 noro 597: \E
598: \BEG
599: In this example @code{mod} and @code{eval} indicate moduli used in
600: trace-lifting. @code{mod} is a prime and @code{eval} is a list of integers
601: used for evaluation when the ground field is a field of rational functions.
602: \E
1.1 noro 603:
604: @noindent
1.2 noro 605: \JP �$B7W;;ESCf$GB?9`<0$,@8@.$5$l$kKh$K<!$N7A$N%G!<%?$,I=<($5$l$k�(B.
606: \EG The following information is shown after every normal form computation.
1.1 noro 607:
608: @example
609: (TNF)(TCONT)HT(INDEX),nb=NB,nab=NAB,rp=RP,sugar=S,mag=M
610: @end example
611:
612: @noindent
1.2 noro 613: \JP �$B$=$l$i$N0UL#$O<!$NDL$j�(B.
614: \EG Meaning of each component is as follows.
1.1 noro 615:
616: @table @code
1.2 noro 617: \BJP
1.1 noro 618: @item TNF
1.2 noro 619:
1.1 noro 620: normal form �$B7W;;;~4V�(B (�$BIC�(B)
621:
622: @item TCONT
1.2 noro 623:
1.1 noro 624: content �$B7W;;;~4V�(B (�$BIC�(B)
625:
626: @item HT
1.2 noro 627:
1.1 noro 628: �$B@8@.$5$l$?B?9`<0$NF,9`�(B
629:
630: @item INDEX
1.2 noro 631:
1.1 noro 632: S-�$BB?9`<0$r9=@.$9$kB?9`<0$N%$%s%G%C%/%9$N%Z%"�(B
633:
634: @item NB
1.2 noro 635:
1.1 noro 636: �$B8=:_$N�(B, �$B>iD9@-$r=|$$$?4pDl$N?t�(B
637:
638: @item NAB
1.2 noro 639:
1.1 noro 640: �$B8=:_$^$G$K@8@.$5$l$?4pDl$N?t�(B
641:
642: @item RP
1.2 noro 643:
1.1 noro 644: �$B;D$j$N%Z%"$N?t�(B
645:
646: @item S
1.2 noro 647:
1.1 noro 648: �$B@8@.$5$l$?B?9`<0$N�(B sugar �$B$NCM�(B
649:
650: @item M
1.2 noro 651:
1.1 noro 652: �$B@8@.$5$l$?B?9`<0$N78?t$N%S%C%HD9$NOB�(B (@code{ShowMag} �$B$,�(B on �$B$N;~$KI=<($5$l$k�(B. )
1.2 noro 653: \E
654: \BEG
655: @item TNF
656:
657: CPU time for normal form computation (second)
658:
659: @item TCONT
660:
661: CPU time for content removal(second)
662:
663: @item HT
664:
665: Head term of the generated basis element
666:
667: @item INDEX
668:
669: Pair of indices which corresponds to the reduced S-polynomial
670:
671: @item NB
672:
673: Number of basis elements after removing redundancy
674:
675: @item NAB
676:
677: Number of all the basis elements
678:
679: @item RP
680:
681: Number of remaining pairs
682:
683: @item S
684:
685: Sugar of the generated basis element
686:
687: @item M
688:
689: Magnitude of the genrated basis element (shown if @code{ShowMag} is `on'.)
690: \E
1.1 noro 691: @end table
692:
693: @noindent
1.2 noro 694: \BJP
1.1 noro 695: �$B:G8e$K�(B, �$B=87W%G!<%?$,I=<($5$l$k�(B. �$B0UL#$O<!$NDL$j�(B.
696: (�$B;~4V$NI=<($K$*$$$F�(B, �$B?t;z$,�(B 2 �$B$D$"$k$b$N$O�(B, �$B7W;;;~4V$H�(B GC �$B;~4V$N%Z%"$G$"$k�(B.)
1.2 noro 697: \E
698: \BEG
699: The summary of the informations shown after a Groebner basis
700: computation is as follows. If a component shows timings and it
701: contains two numbers, they are a pair of time for computation and time
702: for garbage colection.
703: \E
1.1 noro 704:
705: @table @code
1.2 noro 706: \BJP
1.1 noro 707: @item UP
1.2 noro 708:
1.1 noro 709: �$B%Z%"$N%j%9%H$NA`:n$K$+$+$C$?;~4V�(B
710:
711: @item SP
1.2 noro 712:
1.1 noro 713: �$BM-M}?t>e$N�(B S-�$BB?9`<07W;;;~4V�(B
714:
715: @item SPM
1.2 noro 716:
1.1 noro 717: �$BM-8BBN>e$N�(B S-�$BB?9`<07W;;;~4V�(B
718:
719: @item NF
1.2 noro 720:
1.1 noro 721: �$BM-M}?t>e$N�(B normal form �$B7W;;;~4V�(B
722:
723: @item NFM
1.2 noro 724:
1.1 noro 725: �$BM-8BBN>e$N�(B normal form �$B7W;;;~4V�(B
726:
727: @item ZNFM
1.2 noro 728:
1.1 noro 729: @code{NFM} �$B$NFb�(B, 0 �$B$X$N�(B reduction �$B$K$+$+$C$?;~4V�(B
730:
731: @item PZ
1.2 noro 732:
1.1 noro 733: content �$B7W;;;~4V�(B
734:
735: @item NP
1.2 noro 736:
1.1 noro 737: �$BM-M}?t78?tB?9`<0$N78?t$KBP$9$k>jM>1i;;$N7W;;;~4V�(B
738:
739: @item MP
1.2 noro 740:
1.1 noro 741: S-�$BB?9`<0$r@8@.$9$k%Z%"$NA*Br$K$+$+$C$?;~4V�(B
742:
743: @item RA
1.2 noro 744:
1.1 noro 745: interreduce �$B7W;;;~4V�(B
746:
747: @item MC
1.2 noro 748:
1.1 noro 749: trace-lifting �$B$K$*$1$k�(B, �$BF~NOB?9`<0$N%a%s%P%7%C%W7W;;;~4V�(B
750:
751: @item GC
1.2 noro 752:
1.1 noro 753: �$B7k2L$N%0%l%V%J4pDl8uJd$N%0%l%V%J4pDl%A%'%C%/;~4V�(B
754:
755: @item T
1.2 noro 756:
1.1 noro 757: �$B@8@.$5$l$?%Z%"$N?t�(B
758:
759: @item B, M, F, D
1.2 noro 760:
1.1 noro 761: �$B3F�(B criterion �$B$K$h$j=|$+$l$?%Z%"$N?t�(B
762:
763: @item ZR
1.2 noro 764:
1.1 noro 765: 0 �$B$K�(B reduce �$B$5$l$?%Z%"$N?t�(B
766:
767: @item NZR
1.2 noro 768:
1.1 noro 769: 0 �$B$G$J$$B?9`<0$K�(B reduce �$B$5$l$?%Z%"$N?t�(B
770:
771: @item Max_mag
1.2 noro 772:
1.1 noro 773: �$B@8@.$5$l$?B?9`<0$N�(B, �$B78?t$N%S%C%HD9$NOB$N:GBgCM�(B
1.2 noro 774: \E
775: \BEG
776: @item UP
777:
778: Time to manipulate the list of critical pairs
779:
780: @item SP
781:
782: Time to compute S-polynomials over the rationals
783:
784: @item SPM
785:
786: Time to compute S-polynomials over a finite field
787:
788: @item NF
789:
790: Time to compute normal forms over the rationals
791:
792: @item NFM
793:
794: Time to compute normal forms over a finite field
795:
796: @item ZNFM
797:
798: Time for zero reductions in @code{NFM}
799:
800: @item PZ
801:
802: Time to remove integer contets
803:
804: @item NP
805:
806: Time to compute remainders for coefficients of polynomials with coeffieints
807: in the rationals
808:
809: @item MP
810:
811: Time to select pairs from which S-polynomials are computed
812:
813: @item RA
814:
815: Time to interreduce the Groebner basis candidate
816:
817: @item MC
1.1 noro 818:
1.2 noro 819: Time to check that each input polynomial is a member of the ideal
820: generated by the Groebner basis candidate.
821:
822: @item GC
823:
824: Time to check that the Groebner basis candidate is a Groebner basis
825:
826: @item T
827:
828: Number of critical pairs generated
829:
830: @item B, M, F, D
831:
832: Number of critical pairs removed by using each criterion
833:
834: @item ZR
835:
836: Number of S-polynomials reduced to 0
837:
838: @item NZR
839:
840: Number of S-polynomials reduced to non-zero results
841:
842: @item Max_mag
843:
844: Maximal magnitude among all the generated polynomials
845: \E
1.1 noro 846: @end table
847:
1.2 noro 848: \BJP
1.1 noro 849: @node �$B9`=g=x$N@_Dj�(B,,, �$B%0%l%V%J4pDl$N7W;;�(B
850: @section �$B9`=g=x$N@_Dj�(B
1.2 noro 851: \E
852: \BEG
853: @node Setting term orderings,,, Groebner basis computation
854: @section Setting term orderings
855: \E
1.1 noro 856:
857: @noindent
1.2 noro 858: \BJP
1.1 noro 859: �$B9`$OFbIt$G$O�(B, �$B3FJQ?t$K4X$9$k;X?t$r@.J,$H$9$k@0?t%Y%/%H%k$H$7$FI=8=$5$l�(B
860: �$B$k�(B. �$BB?9`<0$rJ,;6I=8=B?9`<0$KJQ49$9$k:]�(B, �$B3FJQ?t$,$I$N@.J,$KBP1~$9$k$+$r�(B
861: �$B;XDj$9$k$N$,�(B, �$BJQ?t%j%9%H$G$"$k�(B. �$B$5$i$K�(B, �$B$=$l$i@0?t%Y%/%H%k$NA4=g=x$r�(B
862: �$B;XDj$9$k$N$,9`=g=x$N7?$G$"$k�(B. �$B9`=g=x7?$O�(B, �$B?t�(B, �$B?t$N%j%9%H$"$k$$$O�(B
863: �$B9TNs$GI=8=$5$l$k�(B.
1.2 noro 864: \E
865: \BEG
866: A term is internally represented as an integer vector whose components
867: are exponents with respect to variables. A variable list specifies the
868: correspondences between variables and components. A type of term ordering
869: specifies a total order for integer vectors. A type of term ordering is
870: represented by an integer, a list of integer or matrices.
871: \E
1.1 noro 872:
873: @noindent
1.2 noro 874: \JP �$B4pK\E*$J9`=g=x7?$H$7$F<!$N�(B 3 �$B$D$,$"$k�(B.
875: \EG There are following three fundamental types.
1.1 noro 876:
877: @table @code
1.2 noro 878: \JP @item 0 (DegRevLex; @b{�$BA4<!?t5U<-=q<0=g=x�(B})
879: \EG @item 0 (DegRevLex; @b{total degree reverse lexicographic ordering})
1.1 noro 880:
1.2 noro 881: \BJP
1.1 noro 882: �$B0lHL$K�(B, �$B$3$N=g=x$K$h$k%0%l%V%J4pDl7W;;$,:G$b9bB.$G$"$k�(B. �$B$?$@$7�(B,
883: �$BJ}Dx<0$r2r$/$H$$$&L\E*$KMQ$$$k$3$H$O�(B, �$B0lHL$K$O$G$-$J$$�(B. �$B$3$N�(B
884: �$B=g=x$K$h$k%0%l%V%J4pDl$O�(B, �$B2r$N8D?t$N7W;;�(B, �$B%$%G%"%k$N%a%s%P%7%C%W$d�(B,
885: �$BB>$NJQ?t=g=x$X$N4pDlJQ49$N$?$a$N%=!<%9$H$7$FMQ$$$i$l$k�(B.
1.2 noro 886: \E
887: \BEG
888: In general, computation by this ordering shows the fastest speed
889: in most Groebner basis computations.
890: However, for the purpose to solve polynomial equations, this type
891: of ordering is, in general, not so suitable.
892: The Groebner bases obtained by this ordering is used for computing
893: the number of solutions, solving ideal membership problem and seeds
894: for conversion to other Groebner bases under different ordering.
895: \E
1.1 noro 896:
1.2 noro 897: \JP @item 1 (DegLex; @b{�$BA4<!?t<-=q<0=g=x�(B})
898: \EG @item 1 (DegLex; @b{total degree lexicographic ordering})
1.1 noro 899:
1.2 noro 900: \BJP
1.1 noro 901: �$B$3$N=g=x$b�(B, �$B<-=q<0=g=x$KHf$Y$F9bB.$K%0%l%V%J4pDl$r5a$a$k$3$H$,$G$-$k$,�(B,
902: @code{DegRevLex} �$B$HF1MMD>@\$=$N7k2L$rMQ$$$k$3$H$O:$Fq$G$"$k�(B. �$B$7$+$7�(B,
903: �$B<-=q<0=g=x$N%0%l%V%J4pDl$r5a$a$k:]$K�(B, �$B@F<!2=8e$K$3$N=g=x$G%0%l%V%J4pDl�(B
904: �$B$r5a$a$F$$$k�(B.
1.2 noro 905: \E
906: \BEG
907: By this type term ordering, Groebner bases are obtained fairly faster
908: than Lex (lexicographic) ordering, too.
909: Alike the @code{DegRevLex} ordering, the result, in general, cannot directly
910: be used for solving polynomial equations.
911: It is used, however, in such a way
912: that a Groebner basis is computed in this ordering after homogenization
913: to obtain the final lexicographic Groebner basis.
914: \E
1.1 noro 915:
1.2 noro 916: \JP @item 2 (Lex; @b{�$B<-=q<0=g=x�(B})
917: \EG @item 2 (Lex; @b{lexicographic ordering})
1.1 noro 918:
1.2 noro 919: \BJP
1.1 noro 920: �$B$3$N=g=x$K$h$k%0%l%V%J4pDl$O�(B, �$BJ}Dx<0$r2r$/>l9g$K:GE,$N7A$N4pDl$rM?$($k$,�(B
921: �$B7W;;;~4V$,$+$+$j2a$.$k$N$,FqE@$G$"$k�(B. �$BFC$K�(B, �$B2r$,M-8B8D$N>l9g�(B, �$B7k2L$N�(B
922: �$B78?t$,6K$a$FD9Bg$JB?G\D9?t$K$J$k>l9g$,B?$$�(B. �$B$3$N>l9g�(B, @code{gr()},
923: @code{hgr()} �$B$K$h$k7W;;$,6K$a$FM-8z$K$J$k>l9g$,B?$$�(B.
1.2 noro 924: \E
925: \BEG
926: Groebner bases computed by this ordering give the most convenient
927: Groebner bases for solving the polynomial equations.
928: The only and serious shortcoming is the enormously long computation
929: time.
930: It is often observed that the number coefficients of the result becomes
931: very very long integers, especially if the ideal is 0-dimensional.
932: For such a case, it is empirically true for many cases
933: that i.e., computation by
934: @code{gr()} and/or @code{hgr()} may be quite effective.
935: \E
1.1 noro 936: @end table
937:
938: @noindent
1.2 noro 939: \BJP
1.1 noro 940: �$B$3$l$i$rAH$_9g$o$;$F%j%9%H$G;XDj$9$k$3$H$K$h$j�(B, �$BMM!9$J>C5n=g=x$,;XDj$G$-$k�(B.
941: �$B$3$l$O�(B,
1.2 noro 942: \E
943: \BEG
944: By combining these fundamental orderingl into a list, one can make
945: various term ordering called elimination orderings.
946: \E
1.1 noro 947:
948: @code{[[O1,L1],[O2,L2],...]}
949:
950: @noindent
1.2 noro 951: \BJP
1.1 noro 952: �$B$G;XDj$5$l$k�(B. @code{Oi} �$B$O�(B 0, 1, 2 �$B$N$$$:$l$+$G�(B, @code{Li} �$B$OJQ?t$N8D�(B
953: �$B?t$rI=$9�(B. �$B$3$N;XDj$O�(B, �$BJQ?t$r@hF,$+$i�(B @code{L1}, @code{L2} , ...�$B8D�(B
954: �$B$:$D$NAH$KJ,$1�(B, �$B$=$l$>$l$NJQ?t$K4X$7�(B, �$B=g$K�(B @code{O1}, @code{O2},
955: ...�$B$N9`=g=x7?$GBg>.$,7hDj$9$k$^$GHf3S$9$k$3$H$r0UL#$9$k�(B. �$B$3$N7?$N�(B
956: �$B=g=x$O0lHL$K>C5n=g=x$H8F$P$l$k�(B.
1.2 noro 957: \E
958: \BEG
959: In this example @code{Oi} indicates 0, 1 or 2 and @code{Li} indicates
960: the number of variables subject to the correspoinding orderings.
961: This specification means the following.
962:
963: The variable list is separated into sub lists from left to right where
964: the @code{i}-th list contains @code{Li} members and it corresponds to
965: the ordering of type @code{Oi}. The result of a comparison is equal
966: to that for the leftmost different sub components. This type of ordering
967: is called an elimination ordering.
968: \E
1.1 noro 969:
970: @noindent
1.2 noro 971: \BJP
1.1 noro 972: �$B$5$i$K�(B, �$B9TNs$K$h$j9`=g=x$r;XDj$9$k$3$H$,$G$-$k�(B. �$B0lHL$K�(B, @code{n} �$B9T�(B
973: @code{m} �$BNs$N<B?t9TNs�(B @code{M} �$B$,<!$N@-<A$r;}$D$H$9$k�(B.
1.2 noro 974: \E
975: \BEG
976: Furthermore one can specify a term ordering by a matix.
977: Suppose that a real @code{n}, @code{m} matrix @code{M} has the
978: following properties.
979: \E
1.1 noro 980:
981: @enumerate
982: @item
1.2 noro 983: \JP �$BD9$5�(B @code{m} �$B$N@0?t%Y%/%H%k�(B @code{v} �$B$KBP$7�(B @code{Mv=0} �$B$H�(B @code{v=0} �$B$OF1CM�(B.
984: \BEG
985: For all integer verctors @code{v} of length @code{m} @code{Mv=0} is equivalent
986: to @code{v=0}.
987: \E
1.1 noro 988:
989: @item
1.2 noro 990: \BJP
1.1 noro 991: �$BHsIi@.J,$r;}$DD9$5�(B @code{m} �$B$N�(B 0 �$B$G$J$$@0?t%Y%/%H%k�(B @code{v} �$B$KBP$7�(B,
992: @code{Mv} �$B$N�(B 0 �$B$G$J$$:G=i$N@.J,$OHsIi�(B.
1.2 noro 993: \E
994: \BEG
995: For all non-negative integer vectors @code{v} the first non-zero component
996: of @code{Mv} is non-negative.
997: \E
1.1 noro 998: @end enumerate
999:
1000: @noindent
1.2 noro 1001: \BJP
1.1 noro 1002: �$B$3$N;~�(B, 2 �$B$D$N%Y%/%H%k�(B @code{t}, @code{s} �$B$KBP$7�(B,
1003: @code{t>s} �$B$r�(B, @code{M(t-s)} �$B$N�(B 0 �$B$G$J$$:G=i$N@.J,$,HsIi�(B,
1004: �$B$GDj5A$9$k$3$H$K$h$j9`=g=x$,Dj5A$G$-$k�(B.
1.2 noro 1005: \E
1006: \BEG
1007: Then we can define a term ordering such that, for two vectors
1008: @code{t}, @code{s}, @code{t>s} means that the first non-zero component
1009: of @code{M(t-s)} is non-negative.
1010: \E
1.1 noro 1011:
1012: @noindent
1.2 noro 1013: \BJP
1.1 noro 1014: �$B9`=g=x7?$O�(B, @code{gr()} �$B$J$I$N0z?t$H$7$F;XDj$5$l$kB>�(B, �$BAH$_9~$_H!?t�(B
1015: @code{dp_ord()} �$B$G;XDj$5$l�(B, �$B$5$^$6$^$JH!?t$N<B9T$N:]$K;2>H$5$l$k�(B.
1.2 noro 1016: \E
1017: \BEG
1018: Types of term orderings are used as arguments of functions such as
1019: @code{gr()}. It is also set internally by @code{dp_ord()} and is used
1020: during executions of various functions.
1021: \E
1.1 noro 1022:
1023: @noindent
1.2 noro 1024: \BJP
1.1 noro 1025: �$B$3$l$i$N=g=x$N6qBNE*$JDj5A$*$h$S%0%l%V%J4pDl$K4X$9$k99$K>\$7$$2r@b$O�(B
1026: @code{[Becker,Weispfenning]} �$B$J$I$r;2>H$N$3$H�(B.
1.2 noro 1027: \E
1028: \BEG
1029: For concrete definitions of term ordering and more information
1030: about Groebner basis, refer to, for example, the book
1031: @code{[Becker,Weispfenning]}.
1032: \E
1.1 noro 1033:
1034: @noindent
1.2 noro 1035: \JP �$B9`=g=x7?$N@_Dj$NB>$K�(B, �$BJQ?t$N=g=x<+BN$b7W;;;~4V$KBg$-$J1F6A$rM?$($k�(B.
1036: \BEG
1037: Note that the variable ordering have strong effects on the computation
1038: time as well as the choice of types of term orderings.
1039: \E
1.1 noro 1040:
1041: @example
1042: [90] B=[x^10-t,x^8-z,x^31-x^6-x-y]$
1043: [91] gr(B,[x,y,z,t],2);
1044: [x^2-2*y^7+(-41*t^2-13*t-1)*y^2+(2*t^17-12*t^14+42*t^12+30*t^11-168*t^9
1045: -40*t^8+70*t^7+252*t^6+30*t^5-140*t^4-168*t^3+2*t^2-12*t+16)*z^2*y
1046: +(-12*t^16+72*t^13-28*t^11-180*t^10+112*t^8+240*t^7+28*t^6-127*t^5
1047: -167*t^4-55*t^3+30*t^2+58*t-15)*z^4,
1.5 noro 1048: (y+t^2*z^2)*x+y^7+(20*t^2+6*t+1)*y^2+(-t^17+6*t^14-21*t^12-15*t^11
1049: +84*t^9+20*t^8-35*t^7-126*t^6-15*t^5+70*t^4+84*t^3-t^2+5*t-9)*z^2*y
1050: +(6*t^16-36*t^13+14*t^11+90*t^10-56*t^8-120*t^7-14*t^6+64*t^5+84*t^4
1051: +27*t^3-16*t^2-30*t+7)*z^4,
1052: (t^3-1)*x-y^6+(-6*t^13+24*t^10-20*t^8-36*t^7+40*t^5+24*t^4-6*t^3-20*t^2
1053: -6*t-1)*y+(t^17-6*t^14+9*t^12+15*t^11-36*t^9-20*t^8-5*t^7+54*t^6+15*t^5
1054: +10*t^4-36*t^3-11*t^2-5*t+9)*z^2,
1.1 noro 1055: -y^8-8*t*y^3+16*z^2*y^2+(-8*t^16+48*t^13-56*t^11-120*t^10+224*t^8+160*t^7
1.5 noro 1056: -56*t^6-336*t^5-112*t^4+112*t^3+224*t^2+24*t-56)*z^4*y+(t^24-8*t^21
1057: +20*t^19+28*t^18-120*t^16-56*t^15+14*t^14+300*t^13+70*t^12-56*t^11
1058: -400*t^10-84*t^9+84*t^8+268*t^7+84*t^6-56*t^5-63*t^4-36*t^3+46*t^2
1059: -12*t+1)*z,2*t*y^5+z*y^2+(-2*t^11+8*t^8-20*t^6-12*t^5+40*t^3+8*t^2
1060: -10*t-20)*z^3*y+8*t^14-32*t^11+48*t^8-t^7-32*t^5-6*t^4+9*t^2-t,
1.1 noro 1061: -z*y^3+(t^7-2*t^4+3*t^2+t)*y+(-2*t^6+4*t^3+2*t-2)*z^2,
1.5 noro 1062: 2*t^2*y^3+z^2*y^2+(-2*t^5+4*t^2-6)*z^4*y
1063: +(4*t^8-t^7-8*t^5+2*t^4-4*t^3+5*t^2-t)*z,
1.1 noro 1064: z^3*y^2+2*t^3*y+(-t^7+2*t^4+t^2-t)*z^2,
1065: -t*z*y^2-2*z^3*y+t^8-2*t^5-t^3+t^2,
1.5 noro 1066: -t^3*y^2-2*t^2*z^2*y+(t^6-2*t^3-t+1)*z^4,z^5-t^4]
1.1 noro 1067: [93] gr(B,[t,z,y,x],2);
1068: [x^10-t,x^8-z,x^31-x^6-x-y]
1069: @end example
1070:
1071: @noindent
1.2 noro 1072: \BJP
1.1 noro 1073: �$BJQ?t=g=x�(B @code{[x,y,z,t]} �$B$K$*$1$k%0%l%V%J4pDl$O�(B, �$B4pDl$N?t$bB?$/�(B, �$B$=$l$>$l$N�(B
1074: �$B<0$bBg$-$$�(B. �$B$7$+$7�(B, �$B=g=x�(B @code{[t,z,y,x]} �$B$K$b$H$G$O�(B, @code{B} �$B$,$9$G$K�(B
1075: �$B%0%l%V%J4pDl$H$J$C$F$$$k�(B. �$BBg;(GD$K$$$($P�(B, �$B<-=q<0=g=x$G%0%l%V%J4pDl$r5a$a$k�(B
1076: �$B$3$H$O�(B, �$B:8B&$N�(B (�$B=g=x$N9b$$�(B) �$BJQ?t$r�(B, �$B1&B&$N�(B (�$B=g=x$NDc$$�(B) �$BJQ?t$G=q$-I=$9�(B
1077: �$B$3$H$G$"$j�(B, �$B$3$NNc$N>l9g$O�(B, @code{t}, @code{z}, @code{y} �$B$,4{$K�(B
1078: @code{x} �$B$GI=$5$l$F$$$k$3$H$+$i$3$N$h$&$J6KC<$J7k2L$H$J$C$?$o$1$G$"$k�(B.
1079: �$B<B:]$K8=$l$k7W;;$K$*$$$F$O�(B, �$B$3$N$h$&$KA*$V$Y$-JQ?t=g=x$,L@$i$+$G$"$k�(B
1080: �$B$3$H$O>/$J$/�(B, �$B;n9T:x8m$,I,MW$J>l9g$b$"$k�(B.
1.2 noro 1081: \E
1082: \BEG
1083: As you see in the above example, the Groebner base under variable
1084: ordering @code{[x,y,z,t]} has a lot of bases and each base itself is
1085: large. Under variable ordering @code{[t,z,y,x]}, however, @code{B} itself
1086: is already the Groebner basis.
1087: Roughly speaking, to obtain a Groebner base under the lexicographic
1088: ordering is to express the variables on the left (having higher order)
1089: in terms of variables on the right (having lower order).
1090: In the example, variables @code{t}, @code{z}, and @code{y} are already
1091: expressed by variable @code{x}, and the above explanation justifies
1092: such a drastic experimental results.
1093: In practice, however, optimum ordering for variables may not known
1094: beforehand, and some heuristic trial may be inevitable.
1.13 noro 1095: \E
1096:
1097: \BJP
1098: @node Weight ,,, �$B%0%l%V%J4pDl$N7W;;�(B
1099: @section Weight
1100: \E
1101: \BEG
1102: @node Weight,,, Groebner basis computation
1103: @section Weight
1104: \E
1105: \BJP
1106: �$BA0@a$G>R2p$7$?9`=g=x$O�(B, �$B3FJQ?t$K�(B weight (�$B=E$_�(B) �$B$r@_Dj$9$k$3$H$G�(B
1107: �$B$h$j0lHLE*$J$b$N$H$J$k�(B.
1108: \E
1109: \BEG
1.14 noro 1110: Term orderings introduced in the previous section can be generalized
1.13 noro 1111: by setting a weight for each variable.
1112: \E
1113: @example
1114: [0] dp_td(<<1,1,1>>);
1115: 3
1116: [1] dp_set_weight([1,2,3])$
1117: [2] dp_td(<<1,1,1>>);
1118: 6
1119: @end example
1120: \BJP
1121: �$BC19`<0$NA4<!?t$r7W;;$9$k:]�(B, �$B%G%U%)%k%H$G$O�(B
1122: �$B3FJQ?t$N;X?t$NOB$rA4<!?t$H$9$k�(B. �$B$3$l$O3FJQ?t$N�(B weight �$B$r�(B 1 �$B$H�(B
1123: �$B9M$($F$$$k$3$H$KAjEv$9$k�(B. �$B$3$NNc$G$O�(B, �$BBh0l�(B, �$BBhFs�(B, �$BBh;0JQ?t$N�(B
1124: weight �$B$r$=$l$>$l�(B 1,2,3 �$B$H;XDj$7$F$$$k�(B. �$B$3$N$?$a�(B, @code{<<1,1,1>>}
1125: �$B$NA4<!?t�(B (�$B0J2<$G$O$3$l$rC19`<0$N�(B weight �$B$H8F$V�(B) �$B$,�(B @code{1*1+1*2+1*3=6} �$B$H$J$k�(B.
1126: weight �$B$r@_Dj$9$k$3$H$G�(B, �$BF1$89`=g=x7?$N$b$H$G0[$J$k9`=g=x$,Dj5A$G$-$k�(B.
1127: �$BNc$($P�(B, weight �$B$r$&$^$/@_Dj$9$k$3$H$G�(B, �$BB?9`<0$r�(B weighted homogeneous
1128: �$B$K$9$k$3$H$,$G$-$k>l9g$,$"$k�(B.
1129: \E
1130: \BEG
1131: By default, the total degree of a monomial is equal to
1132: the sum of all exponents. This means that the weight for each variable
1133: is set to 1.
1134: In this example, the weights for the first, the second and the third
1135: variable are set to 1, 2 and 3 respectively.
1136: Therefore the total degree of @code{<<1,1,1>>} under this weight,
1137: which is called the weight of the monomial, is @code{1*1+1*2+1*3=6}.
1.14 noro 1138: By setting weights, different term orderings can be set under a type of
1139: term ordeing. In some case a polynomial can
1140: be made weighted homogeneous by setting an appropriate weight.
1.13 noro 1141: \E
1142:
1143: \BJP
1144: �$B3FJQ?t$KBP$9$k�(B weight �$B$r$^$H$a$?$b$N$r�(B weight vector �$B$H8F$V�(B.
1145: �$B$9$Y$F$N@.J,$,@5$G$"$j�(B, �$B%0%l%V%J4pDl7W;;$K$*$$$F�(B, �$BA4<!?t$N�(B
1146: �$BBe$o$j$KMQ$$$i$l$k$b$N$rFC$K�(B sugar weight �$B$H8F$V$3$H$K$9$k�(B.
1147: sugar strategy �$B$K$*$$$F�(B, �$BA4<!?t$NBe$o$j$K;H$o$l$k$+$i$G$"$k�(B.
1148: �$B0lJ}$G�(B, �$B3F@.J,$,I,$:$7$b@5$H$O8B$i$J$$�(B weight vector �$B$O�(B,
1149: sugar weight �$B$H$7$F@_Dj$9$k$3$H$O$G$-$J$$$,�(B, �$B9`=g=x$N0lHL2=$K$O�(B
1150: �$BM-MQ$G$"$k�(B. �$B$3$l$i$O�(B, �$B9TNs$K$h$k9`=g=x$N@_Dj$K$9$G$K8=$l$F�(B
1151: �$B$$$k�(B. �$B$9$J$o$A�(B, �$B9`=g=x$rDj5A$9$k9TNs$N3F9T$,�(B, �$B0l$D$N�(B weight vector
1152: �$B$H8+$J$5$l$k�(B. �$B$^$?�(B, �$B%V%m%C%/=g=x$O�(B, �$B3F%V%m%C%/$N�(B
1153: �$BJQ?t$KBP1~$9$k@.J,$N$_�(B 1 �$B$GB>$O�(B 0 �$B$N�(B weight vector �$B$K$h$kHf3S$r�(B
1154: �$B:G=i$K9T$C$F$+$i�(B, �$B3F%V%m%C%/Kh$N�(B tie breaking �$B$r9T$&$3$H$KAjEv$9$k�(B.
1155: \E
1156:
1157: \BEG
1158: A list of weights for all variables is called a weight vector.
1159: A weight vector is called a sugar weight vector if
1160: its elements are all positive and it is used for computing
1161: a weighted total degree of a monomial, because such a weight
1162: is used instead of total degree in sugar strategy.
1163: On the other hand, a weight vector whose elements are not necessarily
1164: positive cannot be set as a sugar weight, but it is useful for
1165: generalizing term order. In fact, such a weight vector already
1166: appeared in a matrix order. That is, each row of a matrix defining
1167: a term order is regarded as a weight vector. A block order
1168: is also considered as a refinement of comparison by weight vectors.
1169: It compares two terms by using a weight vector whose elements
1170: corresponding to variables in a block is 1 and 0 otherwise,
1171: then it applies a tie breaker.
1.14 noro 1172: \E
1173:
1174: \BJP
1175: weight vector �$B$N@_Dj$O�(B @code{dp_set_weight()} �$B$G9T$&$3$H$,$G$-$k�(B
1176: �$B$,�(B, �$B9`=g=x$r;XDj$9$k:]$NB>$N%Q%i%a%?�(B (�$B9`=g=x7?�(B, �$BJQ?t=g=x�(B) �$B$H�(B
1177: �$B$^$H$a$F@_Dj$G$-$k$3$H$,K>$^$7$$�(B. �$B$3$N$?$a�(B, �$B<!$N$h$&$J7A$G$b�(B
1178: �$B9`=g=x$,;XDj$G$-$k�(B.
1179: \E
1180: \BEG
1181: A weight vector can be set by using @code{dp_set_weight()}.
1182: However it is more preferable if a weight vector can be set
1183: together with other parapmeters such as a type of term ordering
1184: and a variable order. This is realized as follows.
1185: \E
1.13 noro 1186:
1.14 noro 1187: @example
1188: [64] B=[x+y+z-6,x*y+y*z+z*x-11,x*y*z-6]$
1189: [65] dp_gr_main(B|v=[x,y,z],sugarweight=[3,2,1],order=0);
1190: [z^3-6*z^2+11*z-6,x+y+z-6,-y^2+(-z+6)*y-z^2+6*z-11]
1191: [66] dp_gr_main(B|v=[y,z,x],order=[[1,1,0],[0,1,0],[0,0,1]]);
1192: [x^3-6*x^2+11*x-6,x+y+z-6,-x^2+(-y+6)*x-y^2+6*y-11]
1193: [67] dp_gr_main(B|v=[y,z,x],order=[[x,1,y,2,z,3]]);
1194: [x+y+z-6,x^3-6*x^2+11*x-6,-x^2+(-y+6)*x-y^2+6*y-11]
1195: @end example
1196:
1197: \BJP
1198: �$B$$$:$l$NNc$K$*$$$F$b�(B, �$B9`=g=x$O�(B option �$B$H$7$F;XDj$5$l$F$$$k�(B.
1199: �$B:G=i$NNc$G$O�(B @code{v} �$B$K$h$jJQ?t=g=x$r�(B, @code{sugarweight} �$B$K$h$j�(B
1200: sugar weight vector �$B$r�(B, @code{order}�$B$K$h$j9`=g=x7?$r;XDj$7$F$$$k�(B.
1201: �$BFs$DL\$NNc$K$*$1$k�(B @code{order} �$B$N;XDj$O�(B matrix order �$B$HF1MM$G$"$k�(B.
1202: �$B$9$J$o$A�(B, �$B;XDj$5$l$?�(B weight vector �$B$r:8$+$i=g$K;H$C$F�(B weight �$B$NHf3S�(B
1203: �$B$r9T$&�(B. �$B;0$DL\$NNc$bF1MM$G$"$k$,�(B, �$B$3$3$G$O�(B weight vector �$B$NMWAG$r�(B
1204: �$BJQ?tKh$K;XDj$7$F$$$k�(B. �$B;XDj$,$J$$$b$N$O�(B 0 �$B$H$J$k�(B. �$B;0$DL\$NNc$G$O�(B,
1205: @code{order} �$B$K$h$k;XDj$G$O9`=g=x$,7hDj$7$J$$�(B. �$B$3$N>l9g$K$O�(B,
1206: tie breaker �$B$H$7$FA4<!?t5U<-=q<0=g=x$,<+F0E*$K@_Dj$5$l$k�(B.
1207: �$B$3$N;XDjJ}K!$O�(B, @code{dp_gr_main}, @code{dp_gr_mod_main} �$B$J$I�(B
1208: �$B$NAH$_9~$_4X?t$G$N$_2DG=$G$"$j�(B, @code{gr} �$B$J$I$N%f!<%6Dj5A4X?t�(B
1209: �$B$G$OL$BP1~$G$"$k�(B.
1210: \E
1211: \BEG
1212: In each example, a term ordering is specified as options.
1213: In the first example, a variable order, a sugar weight vector
1214: and a type of term ordering are specified by options @code{v},
1215: @code{sugarweight} and @code{order} respectively.
1216: In the second example, an option @code{order} is used
1217: to set a matrix ordering. That is, the specified weight vectors
1218: are used from left to right for comparing terms.
1219: The third example shows a variant of specifying a weight vector,
1220: where each component of a weight vector is specified variable by variable,
1221: and unspecified components are set to zero. In this example,
1222: a term order is not determined only by the specified weight vector.
1223: In such a case a tie breaker by the graded reverse lexicographic ordering
1224: is set automatically.
1225: This type of a term ordering specification can be applied only to builtin
1226: functions such as @code{dp_gr_main()}, @code{dp_gr_mod_main()}, not to
1227: user defined functions such as @code{gr()}.
1.2 noro 1228: \E
1.1 noro 1229:
1.2 noro 1230: \BJP
1.1 noro 1231: @node �$BM-M}<0$r78?t$H$9$k%0%l%V%J4pDl7W;;�(B,,, �$B%0%l%V%J4pDl$N7W;;�(B
1232: @section �$BM-M}<0$r78?t$H$9$k%0%l%V%J4pDl7W;;�(B
1.2 noro 1233: \E
1234: \BEG
1235: @node Groebner basis computation with rational function coefficients,,, Groebner basis computation
1236: @section Groebner basis computation with rational function coefficients
1237: \E
1.1 noro 1238:
1239: @noindent
1.2 noro 1240: \BJP
1.1 noro 1241: @code{gr()} �$B$J$I$N%H%C%W%l%Y%kH!?t$O�(B, �$B$$$:$l$b�(B, �$BF~NOB?9`<0%j%9%H$K�(B
1242: �$B8=$l$kJQ?t�(B (�$BITDj85�(B) �$B$H�(B, �$BJQ?t%j%9%H$K8=$l$kJQ?t$rHf3S$7$F�(B, �$BJQ?t%j%9%H$K�(B
1243: �$B$J$$JQ?t$,F~NOB?9`<0$K8=$l$F$$$k>l9g$K$O�(B, �$B<+F0E*$K�(B, �$B$=$NJQ?t$r�(B, �$B78?t�(B
1244: �$BBN$N85$H$7$F07$&�(B.
1.2 noro 1245: \E
1246: \BEG
1247: Such variables that appear within the input polynomials but
1248: not appearing in the input variable list are automatically treated
1249: as elements in the coefficient field
1250: by top level functions, such as @code{gr()}.
1251: \E
1.1 noro 1252:
1253: @example
1254: [64] gr([a*x+b*y-c,d*x+e*y-f],[x,y],2);
1255: [(-e*a+d*b)*x-f*b+e*c,(-e*a+d*b)*y+f*a-d*c]
1256: @end example
1257:
1258: @noindent
1.2 noro 1259: \BJP
1.1 noro 1260: �$B$3$NNc$G$O�(B, @code{a}, @code{b}, @code{c}, @code{d} �$B$,78?tBN$N85$H$7$F�(B
1261: �$B07$o$l$k�(B. �$B$9$J$o$A�(B, �$BM-M}H!?tBN�(B
1262: @b{F} = @b{Q}(@code{a},@code{b},@code{c},@code{d}) �$B>e$N�(B 2 �$BJQ?tB?9`<04D�(B
1263: @b{F}[@code{x},@code{y}] �$B$K$*$1$k%0%l%V%J4pDl$r5a$a$k$3$H$K$J$k�(B.
1264: �$BCm0U$9$Y$-$3$H$O�(B,
1265: �$B78?t$,BN$H$7$F07$o$l$F$$$k$3$H$G$"$k�(B. �$B$9$J$o$A�(B, �$B78?t$N4V$KB?9`<0�(B
1266: �$B$H$7$F$N6&DL0x;R$,$"$C$?>l9g$K$O�(B, �$B7k2L$+$i$=$N0x;R$O=|$+$l$F$$$k�(B
1267: �$B$?$a�(B, �$BM-M}?tBN>e$NB?9`<04D>e$NLdBj$H$7$F9M$($?>l9g$N7k2L$H$O0lHL�(B
1268: �$B$K$O0[$J$k�(B. �$B$^$?�(B, �$B<g$H$7$F7W;;8zN(>e$NLdBj$N$?$a�(B, �$BJ,;6I=8=B?9`<0�(B
1269: �$B$N78?t$H$7$F<B:]$K5v$5$l$k$N$OB?9`<0$^$G$G$"$k�(B. �$B$9$J$o$A�(B, �$BJ,Jl$r�(B
1270: �$B;}$DM-M}<0$OJ,;6I=8=B?9`<0$N78?t$H$7$F$O5v$5$l$J$$�(B.
1.2 noro 1271: \E
1272: \BEG
1273: In this example, variables @code{a}, @code{b}, @code{c}, and @code{d}
1274: are treated as elements in the coefficient field.
1275: In this case, a Groebner basis is computed
1276: on a bi-variate polynomial ring
1277: @b{F}[@code{x},@code{y}]
1278: over rational function field
1279: @b{F} = @b{Q}(@code{a},@code{b},@code{c},@code{d}).
1280: Notice that coefficients are considered as a member in a field.
1281: As a consequence, polynomial factors common to the coefficients
1282: are removed so that the result, in general, is different from
1283: the result that would be obtained when the problem is considered
1284: as a computation of Groebner basis over a polynomial ring
1285: with rational function coefficients.
1286: And note that coefficients of a distributed polynomial are limited
1287: to numbers and polynomials because of efficiency.
1288: \E
1.1 noro 1289:
1.2 noro 1290: \BJP
1.1 noro 1291: @node �$B4pDlJQ49�(B,,, �$B%0%l%V%J4pDl$N7W;;�(B
1292: @section �$B4pDlJQ49�(B
1.2 noro 1293: \E
1294: \BEG
1295: @node Change of ordering,,, Groebner basis computation
1296: @section Change of orderng
1297: \E
1.1 noro 1298:
1299: @noindent
1.2 noro 1300: \BJP
1.1 noro 1301: �$B<-=q<0=g=x$N%0%l%V%J4pDl$r5a$a$k>l9g�(B, �$BD>@\�(B @code{gr()} �$B$J$I$r5/F0$9$k�(B
1302: �$B$h$j�(B, �$B0lC6B>$N=g=x�(B (�$BNc$($PA4<!?t5U<-=q<0=g=x�(B) �$B$N%0%l%V%J4pDl$r7W;;$7$F�(B,
1303: �$B$=$l$rF~NO$H$7$F<-=q<0=g=x$N%0%l%V%J4pDl$r7W;;$9$kJ}$,8zN($,$h$$>l9g�(B
1304: �$B$,$"$k�(B. �$B$^$?�(B, �$BF~NO$,2?$i$+$N=g=x$G$N%0%l%V%J4pDl$K$J$C$F$$$k>l9g�(B, �$B4pDl�(B
1305: �$BJQ49$H8F$P$l$kJ}K!$K$h$j�(B, Buchberger �$B%"%k%4%j%:%`$K$h$i$:$K8zN(NI$/�(B
1306: �$B<-=q<0=g=x$N%0%l%V%J4pDl$,7W;;$G$-$k>l9g$,$"$k�(B. �$B$3$N$h$&$JL\E*$N$?$a$N�(B
1307: �$BH!?t$,�(B, �$B%f!<%6Dj5AH!?t$H$7$F�(B @samp{gr} �$B$K$$$/$D$+Dj5A$5$l$F$$$k�(B.
1308: �$B0J2<$N�(B 2 �$B$D$NH!?t$O�(B, �$BJQ?t=g=x�(B @var{vlist1}, �$B9`=g=x7?�(B @var{order} �$B$G�(B
1309: �$B4{$K%0%l%V%J4pDl$H$J$C$F$$$kB?9`<0%j%9%H�(B @var{gbase} �$B$r�(B, �$BJQ?t=g=x�(B
1310: @var{vlist2} �$B$K$*$1$k<-=q<0=g=x$N%0%l%V%J4pDl$KJQ49$9$kH!?t$G$"$k�(B.
1.2 noro 1311: \E
1312: \BEG
1313: When we compute a lex order Groebner basis, it is often efficient to
1314: compute it via Groebner basis with respect to another order such as
1315: degree reverse lex order, rather than to compute it directory by
1316: @code{gr()} etc. If we know that an input is a Groebner basis with
1317: respect to an order, we can apply special methods called change of
1318: ordering for a Groebner basis computation with respect to another
1319: order, without using Buchberger algorithm. The following two functions
1320: are ones for change of ordering such that they convert a Groebner
1321: basis @var{gbase} with respect to the variable order @var{vlist1} and
1322: the order type @var{order} into a lex Groebner basis with respect
1323: to the variable order @var{vlist2}.
1324: \E
1.1 noro 1325:
1326: @table @code
1327: @item tolex(@var{gbase},@var{vlist1},@var{order},@var{vlist2})
1328:
1.2 noro 1329: \BJP
1.1 noro 1330: �$B$3$NH!?t$O�(B, @var{gbase} �$B$,M-M}?tBN>e$N%7%9%F%`$N>l9g$K$N$_;HMQ2DG=$G$"$k�(B.
1331: �$B$3$NH!?t$O�(B, �$B<-=q<0=g=x$N%0%l%V%J4pDl$r�(B, �$BM-8BBN>e$G7W;;$5$l$?%0%l%V%J4pDl�(B
1332: �$B$r?w7?$H$7$F�(B, �$BL$Dj78?tK!$*$h$S�(B Hensel �$B9=@.$K$h$j5a$a$k$b$N$G$"$k�(B.
1.2 noro 1333: \E
1334: \BEG
1335: This function can be used only when @var{gbase} is an ideal over the
1336: rationals. The input @var{gbase} must be a Groebner basis with respect
1337: to the variable order @var{vlist1} and the order type @var{order}. Moreover
1338: the ideal generated by @var{gbase} must be zero-dimensional.
1339: This computes the lex Groebner basis of @var{gbase}
1340: by using the modular change of ordering algorithm. The algorithm first
1341: computes the lex Groebner basis over a finite field. Then each element
1342: in the lex Groebner basis over the rationals is computed with undetermined
1343: coefficient method and linear equation solving by Hensel lifting.
1344: \E
1.1 noro 1345:
1346: @item tolex_tl(@var{gbase},@var{vlist1},@var{order},@var{vlist2},@var{homo})
1347:
1.2 noro 1348: \BJP
1.1 noro 1349: �$B$3$NH!?t$O�(B, �$B<-=q<0=g=x$N%0%l%V%J4pDl$r�(B Buchberger �$B%"%k%4%j%:%`$K$h$j5a�(B
1350: �$B$a$k$b$N$G$"$k$,�(B, �$BF~NO$,$"$k=g=x$K$*$1$k%0%l%V%J4pDl$G$"$k>l9g$N�(B
1351: trace-lifting�$B$K$*$1$k%0%l%V%J4pDl8uJd$NF,9`�(B, �$BF,78?t$N@-<A$rMxMQ$7$F�(B,
1352: �$B:G=*E*$J%0%l%V%J4pDl%A%'%C%/�(B, �$B%$%G%"%k%a%s%P%7%C%W%A%'%C%/$r>JN,$7$F$$�(B
1353: �$B$k$?$a�(B, �$BC1$K�(BBuchberger �$B%"%k%4%j%:%`$r7+$jJV$9$h$j8zN($h$/7W;;$G$-$k�(B.
1354: �$B99$K�(B, �$BF~NO$,�(B 0 �$B<!85%7%9%F%`$N>l9g�(B, �$B<+F0E*$K$b$&�(B 1 �$B$D$NCf4VE*$J9`=g=x$r�(B
1355: �$B7PM3$7$F<-=q<0=g=x$N%0%l%V%J4pDl$r7W;;$9$k�(B. �$BB?$/$N>l9g�(B, �$B$3$NJ}K!$O�(B,
1356: �$BD>@\<-=q<0=g=x$N7W;;$r9T$&$h$j8zN($,$h$$�(B. (�$B$b$A$m$sNc30$"$j�(B. )
1357: �$B0z?t�(B @var{homo} �$B$,�(B 0 �$B$G$J$$;~�(B, @code{hgr()} �$B$HF1MM$K@F<!2=$r7PM3$7$F�(B
1358: �$B7W;;$r9T$&�(B.
1.2 noro 1359: \E
1360: \BEG
1361: This function computes the lex Groebner basis of @var{gbase}. The
1362: input @var{gbase} must be a Groebner basis with respect to the
1363: variable order @var{vlist1} and the order type @var{order}.
1364: Buchberger algorithm with trace lifting is used to compute the lex
1365: Groebner basis, however the Groebner basis check and the ideal
1366: membership check can be omitted by using several properties derived
1367: from the fact that the input is a Groebner basis. So it is more
1368: efficient than simple repetition of Buchberger algorithm. If the input
1369: is zero-dimensional, this function inserts automatically a computation
1370: of Groebner basis with respect to an elimination order, which makes
1371: the whole computation more efficient for many cases. If @var{homo} is
1372: not equal to 0, homogenization is used in each step.
1373: \E
1.1 noro 1374: @end table
1375:
1376: @noindent
1.2 noro 1377: \BJP
1.1 noro 1378: �$B$=$NB>�(B, 0 �$B<!85%7%9%F%`$KBP$7�(B, �$BM?$($i$l$?B?9`<0$N:G>.B?9`<0$r5a$a$k�(B
1379: �$BH!?t�(B, 0 �$B<!85%7%9%F%`$N2r$r�(B, �$B$h$j%3%s%Q%/%H$KI=8=$9$k$?$a$NH!?t$J$I$,�(B
1380: @samp{gr} �$B$GDj5A$5$l$F$$$k�(B. �$B$3$l$i$K$D$$$F$O8D!9$NH!?t$N@bL@$r;2>H$N$3$H�(B.
1.2 noro 1381: \E
1382: \BEG
1383: For zero-dimensional systems, there are several fuctions to
1384: compute the minimal polynomial of a polynomial and or a more compact
1385: representation for zeros of the system. They are all defined in @samp{gr}.
1386: Refer to the sections for each functions.
1387: \E
1.1 noro 1388:
1.2 noro 1389: \BJP
1.6 noro 1390: @node Weyl �$BBe?t�(B,,, �$B%0%l%V%J4pDl$N7W;;�(B
1391: @section Weyl �$BBe?t�(B
1392: \E
1393: \BEG
1394: @node Weyl algebra,,, Groebner basis computation
1395: @section Weyl algebra
1396: \E
1397:
1398: @noindent
1399:
1400: \BJP
1401: �$B$3$l$^$G$O�(B, �$BDL>o$N2D49$JB?9`<04D$K$*$1$k%0%l%V%J4pDl7W;;$K$D$$$F�(B
1402: �$B=R$Y$F$-$?$,�(B, �$B%0%l%V%J4pDl$NM}O@$O�(B, �$B$"$k>r7o$rK~$?$9Hs2D49$J�(B
1403: �$B4D$K$b3HD%$G$-$k�(B. �$B$3$N$h$&$J4D$NCf$G�(B, �$B1~MQ>e$b=EMW$J�(B,
1404: Weyl �$BBe?t�(B, �$B$9$J$o$AB?9`<04D>e$NHyJ,:nMQAG4D$N1i;;$*$h$S�(B
1405: �$B%0%l%V%J4pDl7W;;$,�(B Risa/Asir �$B$K<BAu$5$l$F$$$k�(B.
1406:
1407: �$BBN�(B @code{K} �$B>e$N�(B @code{n} �$B<!85�(B Weyl �$BBe?t�(B
1408: @code{D=K<x1,@dots{},xn,D1,@dots{},Dn>} �$B$O�(B
1409: \E
1410:
1411: \BEG
1412: So far we have explained Groebner basis computation in
1413: commutative polynomial rings. However Groebner basis can be
1414: considered in more general non-commutative rings.
1415: Weyl algebra is one of such rings and
1416: Risa/Asir implements fundamental operations
1417: in Weyl algebra and Groebner basis computation in Weyl algebra.
1418:
1419: The @code{n} dimensional Weyl algebra over a field @code{K},
1420: @code{D=K<x1,@dots{},xn,D1,@dots{},Dn>} is a non-commutative
1421: algebra which has the following fundamental relations:
1422: \E
1423:
1424: @code{xi*xj-xj*xi=0}, @code{Di*Dj-Dj*Di=0}, @code{Di*xj-xj*Di=0} (@code{i!=j}),
1425: @code{Di*xi-xi*Di=1}
1426:
1427: \BJP
1428: �$B$H$$$&4pK\4X78$r;}$D4D$G$"$k�(B. @code{D} �$B$O�(B �$BB?9`<04D�(B @code{K[x1,@dots{},xn]} �$B$r78?t�(B
1429: �$B$H$9$kHyJ,:nMQAG4D$G�(B, @code{Di} �$B$O�(B @code{xi} �$B$K$h$kHyJ,$rI=$9�(B. �$B8r494X78$K$h$j�(B,
1430: @code{D} �$B$N85$O�(B, @code{x1^i1*@dots{}*xn^in*D1^j1*@dots{}*Dn^jn} �$B$J$kC19`�(B
1431: �$B<0$N�(B @code{K} �$B@~7A7k9g$H$7$F=q$-I=$9$3$H$,$G$-$k�(B.
1432: Risa/Asir �$B$K$*$$$F$O�(B, �$B$3$NC19`<0$r�(B, �$B2D49$JB?9`<0$HF1MM$K�(B
1433: @code{<<i1,@dots{},in,j1,@dots{},jn>>} �$B$GI=$9�(B. �$B$9$J$o$A�(B, @code{D} �$B$N85$b�(B
1434: �$BJ,;6I=8=B?9`<0$H$7$FI=$5$l$k�(B. �$B2C8:;;$O�(B, �$B2D49$N>l9g$HF1MM$K�(B, @code{+}, @code{-}
1435: �$B$K$h$j�(B
1436: �$B<B9T$G$-$k$,�(B, �$B>h;;$O�(B, �$BHs2D49@-$r9MN8$7$F�(B @code{dp_weyl_mul()} �$B$H$$$&4X?t�(B
1437: �$B$K$h$j<B9T$9$k�(B.
1438: \E
1439:
1440: \BEG
1441: @code{D} is the ring of differential operators whose coefficients
1442: are polynomials in @code{K[x1,@dots{},xn]} and
1443: @code{Di} denotes the differentiation with respect to @code{xi}.
1444: According to the commutation relation,
1445: elements of @code{D} can be represented as a @code{K}-linear combination
1446: of monomials @code{x1^i1*@dots{}*xn^in*D1^j1*@dots{}*Dn^jn}.
1447: In Risa/Asir, this type of monomial is represented
1448: by @code{<<i1,@dots{},in,j1,@dots{},jn>>} as in the case of commutative
1449: polynomial.
1450: That is, elements of @code{D} are represented by distributed polynomials.
1451: Addition and subtraction can be done by @code{+}, @code{-},
1452: but multiplication is done by calling @code{dp_weyl_mul()} because of
1453: the non-commutativity of @code{D}.
1454: \E
1455:
1456: @example
1457: [0] A=<<1,2,2,1>>;
1458: (1)*<<1,2,2,1>>
1459: [1] B=<<2,1,1,2>>;
1460: (1)*<<2,1,1,2>>
1461: [2] A*B;
1462: (1)*<<3,3,3,3>>
1463: [3] dp_weyl_mul(A,B);
1464: (1)*<<3,3,3,3>>+(1)*<<3,2,3,2>>+(4)*<<2,3,2,3>>+(4)*<<2,2,2,2>>
1465: +(2)*<<1,3,1,3>>+(2)*<<1,2,1,2>>
1466: @end example
1467:
1468: \BJP
1469: �$B%0%l%V%J4pDl7W;;$K$D$$$F$b�(B, Weyl �$BBe?t@lMQ$N4X?t$H$7$F�(B,
1470: �$B<!$N4X?t$,MQ0U$7$F$"$k�(B.
1471: \E
1472: \BEG
1473: The following functions are avilable for Groebner basis computation
1474: in Weyl algebra:
1475: \E
1476: @code{dp_weyl_gr_main()},
1477: @code{dp_weyl_gr_mod_main()},
1478: @code{dp_weyl_gr_f_main()},
1479: @code{dp_weyl_f4_main()},
1480: @code{dp_weyl_f4_mod_main()}.
1481: \BJP
1482: �$B$^$?�(B, �$B1~MQ$H$7$F�(B, global b �$B4X?t$N7W;;$,<BAu$5$l$F$$$k�(B.
1483: \E
1484: \BEG
1485: Computation of the global b function is implemented as an application.
1486: \E
1487:
1488: \BJP
1.1 noro 1489: @node �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B,,, �$B%0%l%V%J4pDl$N7W;;�(B
1490: @section �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
1.2 noro 1491: \E
1492: \BEG
1493: @node Functions for Groebner basis computation,,, Groebner basis computation
1494: @section Functions for Groebner basis computation
1495: \E
1.1 noro 1496:
1497: @menu
1498: * gr hgr gr_mod::
1499: * lex_hensel lex_tl tolex tolex_d tolex_tl::
1500: * lex_hensel_gsl tolex_gsl tolex_gsl_d::
1501: * gr_minipoly minipoly::
1502: * tolexm minipolym::
1.6 noro 1503: * dp_gr_main dp_gr_mod_main dp_gr_f_main dp_weyl_gr_main dp_weyl_gr_mod_main dp_weyl_gr_f_main::
1504: * dp_f4_main dp_f4_mod_main dp_weyl_f4_main dp_weyl_f4_mod_main::
1.17 noro 1505: * nd_gr nd_gr_trace nd_f4 nd_f4_trace nd_weyl_gr nd_weyl_gr_trace::
1.1 noro 1506: * dp_gr_flags dp_gr_print::
1507: * dp_ord::
1.18 noro 1508: * dp_set_weight dp_set_top_weight dp_weyl_set_weight::
1.1 noro 1509: * dp_ptod::
1510: * dp_dtop::
1511: * dp_mod dp_rat::
1512: * dp_homo dp_dehomo::
1513: * dp_ptozp dp_prim::
1.18 noro 1514: * dp_nf dp_nf_mod dp_true_nf dp_true_nf_mod dp_weyl_nf dp_weyl_nf_mod::
1.1 noro 1515: * dp_hm dp_ht dp_hc dp_rest::
1516: * dp_td dp_sugar::
1517: * dp_lcm::
1518: * dp_redble::
1519: * dp_subd::
1520: * dp_mbase::
1521: * dp_mag::
1522: * dp_red dp_red_mod::
1523: * dp_sp dp_sp_mod::
1524: * p_nf p_nf_mod p_true_nf p_true_nf_mod ::
1525: * p_terms::
1526: * gb_comp::
1527: * katsura hkatsura cyclic hcyclic::
1528: * dp_vtoe dp_etov::
1529: * lex_hensel_gsl tolex_gsl tolex_gsl_d::
1.3 noro 1530: * primadec primedec::
1.5 noro 1531: * primedec_mod::
1.10 noro 1532: * bfunction bfct generic_bfct ann ann0::
1.1 noro 1533: @end menu
1534:
1.2 noro 1535: \JP @node gr hgr gr_mod,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
1536: \EG @node gr hgr gr_mod,,, Functions for Groebner basis computation
1.1 noro 1537: @subsection @code{gr}, @code{hgr}, @code{gr_mod}, @code{dgr}
1538: @findex gr
1539: @findex hgr
1540: @findex gr_mod
1541: @findex dgr
1542:
1543: @table @t
1544: @item gr(@var{plist},@var{vlist},@var{order})
1545: @itemx hgr(@var{plist},@var{vlist},@var{order})
1546: @itemx gr_mod(@var{plist},@var{vlist},@var{order},@var{p})
1547: @itemx dgr(@var{plist},@var{vlist},@var{order},@var{procs})
1.2 noro 1548: \JP :: �$B%0%l%V%J4pDl$N7W;;�(B
1549: \EG :: Groebner basis computation
1.1 noro 1550: @end table
1551:
1552: @table @var
1553: @item return
1.2 noro 1554: \JP �$B%j%9%H�(B
1555: \EG list
1.4 noro 1556: @item plist vlist procs
1.2 noro 1557: \JP �$B%j%9%H�(B
1558: \EG list
1.1 noro 1559: @item order
1.2 noro 1560: \JP �$B?t�(B, �$B%j%9%H$^$?$O9TNs�(B
1561: \EG number, list or matrix
1.1 noro 1562: @item p
1.2 noro 1563: \JP 2^27 �$BL$K~$NAG?t�(B
1564: \EG prime less than 2^27
1.1 noro 1565: @end table
1566:
1567: @itemize @bullet
1.2 noro 1568: \BJP
1.1 noro 1569: @item
1570: �$BI8=`%i%$%V%i%j$N�(B @samp{gr} �$B$GDj5A$5$l$F$$$k�(B.
1571: @item
1.21 ! takayama 1572: gr �$B$rL>A0$K4^$`4X?t$O8=:_%a%s%F$5$l$F$$$J$$�(B. @code{nd_gr}�$B7O$N4X?t$rBe$o$j$KMxMQ$9$Y$-$G$"$k�(B(@fref{nd_gr nd_gr_trace nd_f4 nd_f4_trace nd_weyl_gr nd_weyl_gr_trace}).
! 1573: @item
1.1 noro 1574: �$B$$$:$l$b�(B, �$BB?9`<0%j%9%H�(B @var{plist} �$B$N�(B, �$BJQ?t=g=x�(B @var{vlist}, �$B9`=g=x7?�(B
1575: @var{order} �$B$K4X$9$k%0%l%V%J4pDl$r5a$a$k�(B. @code{gr()}, @code{hgr()}
1576: �$B$O�(B �$BM-M}?t78?t�(B, @code{gr_mod()} �$B$O�(B GF(@var{p}) �$B78?t$H$7$F7W;;$9$k�(B.
1577: @item
1578: @var{vlist} �$B$OITDj85$N%j%9%H�(B. @var{vlist} �$B$K8=$l$J$$ITDj85$O�(B,
1579: �$B78?tBN$KB0$9$k$H8+$J$5$l$k�(B.
1580: @item
1581: @code{gr()}, trace-lifting (�$B%b%8%e%i1i;;$rMQ$$$?9bB.2=�(B) �$B$*$h$S�(B sugar
1582: strategy �$B$K$h$k7W;;�(B, @code{hgr()} �$B$O�(B trace-lifting �$B$*$h$S�(B
1583: �$B@F<!2=$K$h$k�(B �$B6:@5$5$l$?�(B sugar strategy �$B$K$h$k7W;;$r9T$&�(B.
1584: @item
1.16 fujiwara 1585: @code{dgr()} �$B$O�(B, @code{gr()}, @code{hgr()} �$B$r�(B
1.1 noro 1586: �$B;R%W%m%;%9%j%9%H�(B @var{procs} �$B$N�(B 2 �$B$D$N%W%m%;%9$K$h$jF1;~$K7W;;$5$;�(B,
1587: �$B@h$K7k2L$rJV$7$?J}$N7k2L$rJV$9�(B. �$B7k2L$OF10l$G$"$k$,�(B, �$B$I$A$i$NJ}K!$,�(B
1588: �$B9bB.$+0lHL$K$OITL@$N$?$a�(B, �$B<B:]$N7P2a;~4V$rC;=L$9$k$N$KM-8z$G$"$k�(B.
1589: @item
1590: @code{dgr()} �$B$GI=<($5$l$k;~4V$O�(B, �$B$3$NH!?t$,<B9T$5$l$F$$$k%W%m%;%9$G$N�(B
1591: CPU �$B;~4V$G$"$j�(B, �$B$3$NH!?t$N>l9g$O$[$H$s$IDL?.$N$?$a$N;~4V$G$"$k�(B.
1.12 takayama 1592: @item
1593: �$BB?9`<0%j%9%H�(B @var{plist} �$B$NMWAG$,J,;6I=8=B?9`<0$N>l9g$O�(B
1594: �$B7k2L$bJ,;6I=8=B?9`<0$N%j%9%H$G$"$k�(B.
1595: �$B$3$N>l9g�(B, �$B0z?t$NJ,;6B?9`<0$OM?$($i$l$?=g=x$K=>$$�(B @code{dp_sort} �$B$G�(B
1596: �$B%=!<%H$5$l$F$+$i7W;;$5$l$k�(B.
1597: �$BB?9`<0%j%9%H$NMWAG$,J,;6I=8=B?9`<0$N>l9g$b�(B
1598: �$BJQ?t$N?tJ,$NITDj85$N%j%9%H$r�(B @var{vlist} �$B0z?t$H$7$FM?$($J$$$H$$$1$J$$�(B
1599: (�$B%@%_!<�(B).
1.2 noro 1600: \E
1601: \BEG
1602: @item
1603: These functions are defined in @samp{gr} in the standard library
1604: directory.
1.21 ! takayama 1605: @item
! 1606: Functions of which names contains gr are obsolted.
! 1607: Functions of @code{nd_gr} families should be used (@fref{nd_gr nd_gr_trace nd_f4 nd_f4_trace nd_weyl_gr nd_weyl_gr_trace}).
1.2 noro 1608: @item
1609: They compute a Groebner basis of a polynomial list @var{plist} with
1610: respect to the variable order @var{vlist} and the order type @var{order}.
1611: @code{gr()} and @code{hgr()} compute a Groebner basis over the rationals
1612: and @code{gr_mod} computes over GF(@var{p}).
1613: @item
1614: Variables not included in @var{vlist} are regarded as
1615: included in the ground field.
1616: @item
1617: @code{gr()} uses trace-lifting (an improvement by modular computation)
1618: and sugar strategy.
1619: @code{hgr()} uses trace-lifting and a cured sugar strategy
1620: by using homogenization.
1621: @item
1622: @code{dgr()} executes @code{gr()}, @code{dgr()} simultaneously on
1623: two process in a child process list @var{procs} and returns
1624: the result obtained first. The results returned from both the process
1625: should be equal, but it is not known in advance which method is faster.
1626: Therefore this function is useful to reduce the actual elapsed time.
1627: @item
1628: The CPU time shown after an exection of @code{dgr()} indicates
1629: that of the master process, and most of the time corresponds to the time
1630: for communication.
1.12 takayama 1631: @item
1632: When the elements of @var{plist} are distributed polynomials,
1633: the result is also a list of distributed polynomials.
1634: In this case, firstly the elements of @var{plist} is sorted by @code{dp_sort}
1635: and the Grobner basis computation is started.
1636: Variables must be given in @var{vlist} even in this case
1637: (these variables are dummy).
1.2 noro 1638: \E
1.1 noro 1639: @end itemize
1640:
1641: @example
1642: [0] load("gr")$
1643: [64] load("cyclic")$
1644: [74] G=gr(cyclic(5),[c0,c1,c2,c3,c4],2);
1645: [c4^15+122*c4^10-122*c4^5-1,...]
1646: [75] GM=gr_mod(cyclic(5),[c0,c1,c2,c3,c4],2,31991)$
1647: 24628*c4^15+29453*c4^10+2538*c4^5+7363
1648: [76] (G[0]*24628-GM[0])%31991;
1649: 0
1650: @end example
1651:
1652: @table @t
1.2 noro 1653: \JP @item �$B;2>H�(B
1654: \EG @item References
1.6 noro 1655: @fref{dp_gr_main dp_gr_mod_main dp_gr_f_main dp_weyl_gr_main dp_weyl_gr_mod_main dp_weyl_gr_f_main},
1.1 noro 1656: @fref{dp_ord}.
1657: @end table
1658:
1.2 noro 1659: \JP @node lex_hensel lex_tl tolex tolex_d tolex_tl,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
1660: \EG @node lex_hensel lex_tl tolex tolex_d tolex_tl,,, Functions for Groebner basis computation
1.1 noro 1661: @subsection @code{lex_hensel}, @code{lex_tl}, @code{tolex}, @code{tolex_d}, @code{tolex_tl}
1662: @findex lex_hensel
1663: @findex lex_tl
1664: @findex tolex
1665: @findex tolex_d
1666: @findex tolex_tl
1667:
1668: @table @t
1669: @item lex_hensel(@var{plist},@var{vlist1},@var{order},@var{vlist2},@var{homo})
1670: @itemx lex_tl(@var{plist},@var{vlist1},@var{order},@var{vlist2},@var{homo})
1.2 noro 1671: \JP :: �$B4pDlJQ49$K$h$k<-=q<0=g=x%0%l%V%J4pDl$N7W;;�(B
1672: \EG:: Groebner basis computation with respect to a lex order by change of ordering
1.1 noro 1673: @item tolex(@var{plist},@var{vlist1},@var{order},@var{vlist2})
1674: @itemx tolex_d(@var{plist},@var{vlist1},@var{order},@var{vlist2},@var{procs})
1675: @itemx tolex_tl(@var{plist},@var{vlist1},@var{order},@var{vlist2},@var{homo})
1.2 noro 1676: \JP :: �$B%0%l%V%J4pDl$rF~NO$H$9$k�(B, �$B4pDlJQ49$K$h$k<-=q<0=g=x%0%l%V%J4pDl$N7W;;�(B
1677: \EG :: Groebner basis computation with respect to a lex order by change of ordering, starting from a Groebner basis
1.1 noro 1678: @end table
1679:
1680: @table @var
1681: @item return
1.2 noro 1682: \JP �$B%j%9%H�(B
1683: \EG list
1.4 noro 1684: @item plist vlist1 vlist2 procs
1.2 noro 1685: \JP �$B%j%9%H�(B
1686: \EG list
1.1 noro 1687: @item order
1.2 noro 1688: \JP �$B?t�(B, �$B%j%9%H$^$?$O9TNs�(B
1689: \EG number, list or matrix
1.1 noro 1690: @item homo
1.2 noro 1691: \JP �$B%U%i%0�(B
1692: \EG flag
1.1 noro 1693: @end table
1694:
1695: @itemize @bullet
1.2 noro 1696: \BJP
1.1 noro 1697: @item
1698: �$BI8=`%i%$%V%i%j$N�(B @samp{gr} �$B$GDj5A$5$l$F$$$k�(B.
1699: @item
1700: @code{lex_hensel()}, @code{lex_tl()} �$B$O�(B,
1701: �$BB?9`<0%j%9%H�(B @var{plist} �$B$N�(B, �$BJQ?t=g=x�(B @var{vlist1}, �$B9`=g=x7?�(B
1702: @var{order} �$B$K4X$9$k%0%l%V%J4pDl$r5a$a�(B, �$B$=$l$r�(B, �$BJQ?t=g=x�(B @var{vlist2}
1703: �$B$N<-=q<0=g=x%0%l%V%J4pDl$KJQ49$9$k�(B.
1704: @item
1705: @code{tolex()}, @code{tolex_tl()} �$B$O�(B,
1706: �$BJQ?t=g=x�(B @var{vlist1}, �$B9`=g=x7?�(B @var{order} �$B$K4X$9$k%0%l%V%J4pDl$G$"$k�(B
1707: �$BB?9`<0%j%9%H�(B @var{plist} �$B$rJQ?t=g=x�(B @var{vlist2} �$B$N<-=q<0=g=x%0%l%V%J�(B
1708: �$B4pDl$KJQ49$9$k�(B.
1709: @code{tolex_d()} �$B$O�(B, @code{tolex()} �$B$K$*$1$k�(B, �$B3F4pDl$N7W;;$r�(B, �$B;R%W%m%;%9�(B
1710: �$B%j%9%H�(B @var{procs} �$B$N3F%W%m%;%9$KJ,;67W;;$5$;$k�(B.
1711: @item
1712: @code{lex_hensel()}, @code{lex_tl()} �$B$K$*$$$F$O�(B, �$B<-=q<0=g=x%0%l%V%J4pDl$N�(B
1713: �$B7W;;$O<!$N$h$&$K9T$o$l$k�(B. (@code{[Noro,Yokoyama]} �$B;2>H�(B.)
1714: @enumerate
1715: @item
1716: @var{vlist1}, @var{order} �$B$K4X$9$k%0%l%V%J4pDl�(B @var{G0} �$B$r7W;;$9$k�(B.
1717: (@code{lex_hensel()} �$B$N$_�(B. )
1718: @item
1719: @var{G0} �$B$N3F85$N�(B @var{vlist2} �$B$K4X$9$k<-=q<0=g=x$K$*$1$kF,78?t$r3d$i$J$$�(B
1720: �$B$h$&$JAG?t�(B @var{p} �$B$rA*$S�(B, GF(@var{p}) �$B>e$G$N<-=q<0=g=x%0%l%V%J4pDl�(B
1721: @var{Gp} �$B$r7W;;$9$k�(B.
1722: @item
1723: @var{Gp} �$B$K8=$l$k$9$Y$F$N9`$N�(B, @var{G0} �$B$K4X$9$k@55,7A�(B @var{NF} �$B$r7W;;$9$k�(B.
1724: @item
1725: @var{Gp} �$B$N3F85�(B @var{f} �$B$K$D$-�(B, @var{f} �$B$N78?t$rL$Dj78?t$G�(B,
1726: @var{f} �$B$N3F9`$rBP1~$9$k�(B @var{NF} �$B$N85$GCV$-49$(�(B, �$B3F9`$N78?t$r�(B 0 �$B$HCV$$$?�(B,
1727: �$BL$Dj78?t$K4X$9$k@~7AJ}Dx<07O�(B @var{Lf} �$B$r:n$k�(B.
1728: @item
1729: @var{Lf} �$B$,�(B, �$BK!�(B @var{p} �$B$G0l0U2r$r;}$D$3$H$rMQ$$$F�(B @var{Lf} �$B$N2r$r�(B
1730: �$BK!�(B @var{p}�$B$N2r$+$i�(B Hensel �$B9=@.$K$h$j5a$a$k�(B.
1731: @item
1732: �$B$9$Y$F$N�(B @var{Gp} �$B$N85$K$D$-@~7AJ}Dx<0$,2r$1$?$i$=$N2rA4BN$,5a$a$k�(B
1733: �$B<-=q<0=g=x$G$N%0%l%V%J4pDl�(B. �$B$b$7$I$l$+$N@~7AJ}Dx<0$N5a2r$K<:GT$7$?$i�(B,
1734: @var{p} �$B$r$H$jD>$7$F$d$jD>$9�(B.
1735: @end enumerate
1736:
1737: @item
1738: @code{lex_tl()}, @code{tolex_tl()} �$B$K$*$$$F$O�(B, �$B<-=q<0=g=x%0%l%V%J4pDl$N�(B
1739: �$B7W;;$O<!$N$h$&$K9T$o$l$k�(B.
1740:
1741: @enumerate
1742: @item
1743: @var{vlist1}, @var{order} �$B$K4X$9$k%0%l%V%J4pDl�(B @var{G0} �$B$r7W;;$9$k�(B.
1744: (@code{lex_hensel()} �$B$N$_�(B. )
1745: @item
1746: @var{G0} �$B$,�(B 0 �$B<!85%7%9%F%`$G$J$$$H$-�(B, @var{G0} �$B$rF~NO$H$7$F�(B,
1747: @var{G0} �$B$N3F85$N�(B @var{vlist2} �$B$K4X$9$k<-=q<0=g=x$K$*$1$kF,78?t$r3d$i$J$$�(B
1748: �$B$h$&$JAG?t�(B @var{p} �$B$rA*$S�(B, @var{p} �$B$rMQ$$$?�(B trace-lifting �$B$K$h$j<-=q<0�(B
1749: �$B=g=x$N%0%l%V%J4pDl8uJd$r5a$a�(B, �$B$b$75a$^$C$?$J$i%A%'%C%/$J$7$K$=$l$,5a$a$k�(B
1750: �$B%0%l%V%J4pDl$H$J$k�(B. �$B$b$7<:GT$7$?$i�(B, @var{p} �$B$r$H$jD>$7$F$d$jD>$9�(B.
1751: @item
1752: @var{G0} �$B$,�(B 0 �$B<!85%7%9%F%`$N$H$-�(B, @var{G0} �$B$rF~NO$H$7$F�(B,
1753: �$B$^$:�(B, @var{vlist2} �$B$N:G8e$NJQ?t0J30$r>C5n$9$k>C5n=g=x$K$h$j�(B
1754: �$B%0%l%V%J4pDl�(B @var{G1} �$B$r7W;;$7�(B, �$B$=$l$+$i<-=q<0=g=x$N%0%l%V%J4pDl$r�(B
1755: �$B7W;;$9$k�(B. �$B$=$N:]�(B, �$B3F%9%F%C%W$G$O�(B, �$BF~NO$N3F85$N�(B, �$B5a$a$k=g=x$K$*$1$k�(B
1756: �$BF,78?t$r3d$i$J$$AG?t$rMQ$$$?�(B trace-lifting �$B$G%0%l%V%J4pDl8uJd$r5a$a�(B,
1757: �$B$b$75a$^$C$?$i%A%'%C%/$J$7$K$=$l$,$=$N=g=x$G$N%0%l%V%J4pDl$H$J$k�(B.
1758: @end enumerate
1759:
1760: @item
1761: �$BM-M}<078?t$N7W;;$O�(B, @code{lex_tl()}, @code{tolex_tl()} �$B$N$_<u$1IU$1$k�(B.
1762: @item
1763: @code{homo} �$B$,�(B 0 �$B$G$J$$>l9g�(B, �$BFbIt$G5/F0$5$l$k�(B Buchberger �$B%"%k%4%j%:%`$K�(B
1764: �$B$*$$$F�(B, �$B@F<!2=$,9T$o$l$k�(B.
1765: @item
1766: @code{tolex_d()} �$B$GI=<($5$l$k;~4V$O�(B, �$B$3$NH!?t$,<B9T$5$l$F$$$k%W%m%;%9$K�(B
1767: �$B$*$$$F9T$o$l$?7W;;$KBP1~$7$F$$$F�(B, �$B;R%W%m%;%9$K$*$1$k;~4V$O4^$^$l$J$$�(B.
1.2 noro 1768: \E
1769: \BEG
1770: @item
1771: These functions are defined in @samp{gr} in the standard library
1772: directory.
1773: @item
1774: @code{lex_hensel()} and @code{lex_tl()} first compute a Groebner basis
1775: with respect to the variable order @var{vlist1} and the order type @var{order}.
1776: Then the Groebner basis is converted into a lex order Groebner basis
1777: with respect to the varable order @var{vlist2}.
1778: @item
1779: @code{tolex()} and @code{tolex_tl()} convert a Groebner basis @var{plist}
1780: with respect to the variable order @var{vlist1} and the order type @var{order}
1781: into a lex order Groebner basis
1782: with respect to the varable order @var{vlist2}.
1783: @code{tolex_d()} does computations of basis elements in @code{tolex()}
1784: in parallel on the processes in a child process list @var{procs}.
1785: @item
1786: In @code{lex_hensel()} and @code{tolex_hensel()} a lex order Groebner basis
1787: is computed as follows.(Refer to @code{[Noro,Yokoyama]}.)
1788: @enumerate
1789: @item
1790: Compute a Groebner basis @var{G0} with respect to @var{vlist1} and @var{order}.
1791: (Only in @code{lex_hensel()}. )
1792: @item
1793: Choose a prime which does not divide head coefficients of elements in @var{G0}
1794: with respect to @var{vlist1} and @var{order}. Then compute a lex order
1795: Groebner basis @var{Gp} over GF(@var{p}) with respect to @var{vlist2}.
1796: @item
1797: Compute @var{NF}, the set of all the normal forms with respect to
1798: @var{G0} of terms appearing in @var{Gp}.
1799: @item
1800: For each element @var{f} in @var{Gp}, replace coefficients and terms in @var{f}
1801: with undetermined coefficients and the corresponding polynomials in @var{NF}
1802: respectively, and generate a system of liear equation @var{Lf} by equating
1803: the coefficients of terms in the replaced polynomial with 0.
1804: @item
1805: Solve @var{Lf} by Hensel lifting, starting from the unique mod @var{p}
1806: solution.
1807: @item
1808: If all the linear equations generated from the elements in @var{Gp}
1809: could be solved, then the set of solutions corresponds to a lex order
1810: Groebner basis. Otherwise redo the whole process with another @var{p}.
1811: @end enumerate
1812:
1813: @item
1814: In @code{lex_tl()} and @code{tolex_tl()} a lex order Groebner basis
1815: is computed as follows.(Refer to @code{[Noro,Yokoyama]}.)
1816:
1817: @enumerate
1818: @item
1819: Compute a Groebner basis @var{G0} with respect to @var{vlist1} and @var{order}.
1820: (Only in @code{lex_tl()}. )
1821: @item
1822: If @var{G0} is not zero-dimensional, choose a prime which does not divide
1823: head coefficients of elements in @var{G0} with respect to @var{vlist1} and
1824: @var{order}. Then compute a candidate of a lex order Groebner basis
1825: via trace lifting with @var{p}. If it succeeds the candidate is indeed
1826: a lex order Groebner basis without any check. Otherwise redo the whole
1827: process with another @var{p}.
1828: @item
1829:
1830: If @var{G0} is zero-dimensional, starting from @var{G0},
1831: compute a Groebner basis @var{G1} with respect to an elimination order
1832: to eliminate variables other than the last varibale in @var{vlist2}.
1833: Then compute a lex order Groebner basis stating from @var{G1}. These
1834: computations are done by trace lifting and the selection of a mudulus
1835: @var{p} is the same as in non zero-dimensional cases.
1836: @end enumerate
1837:
1838: @item
1839: Computations with rational function coefficients can be done only by
1840: @code{lex_tl()} and @code{tolex_tl()}.
1841: @item
1842: If @code{homo} is not equal to 0, homogenization is used in Buchberger
1843: algorithm.
1844: @item
1845: The CPU time shown after an execution of @code{tolex_d()} indicates
1846: that of the master process, and it does not include the time in child
1847: processes.
1848: \E
1.1 noro 1849: @end itemize
1850:
1851: @example
1852: [78] K=katsura(5)$
1853: 30msec + gc : 20msec
1854: [79] V=[u5,u4,u3,u2,u1,u0]$
1855: 0msec
1856: [80] G0=hgr(K,V,2)$
1857: 91.558sec + gc : 15.583sec
1858: [81] G1=lex_hensel(K,V,0,V,0)$
1859: 49.049sec + gc : 9.961sec
1860: [82] G2=lex_tl(K,V,0,V,1)$
1861: 31.186sec + gc : 3.500sec
1862: [83] gb_comp(G0,G1);
1863: 1
1864: 10msec
1865: [84] gb_comp(G0,G2);
1866: 1
1867: @end example
1868:
1869: @table @t
1.2 noro 1870: \JP @item �$B;2>H�(B
1871: \EG @item References
1.6 noro 1872: @fref{dp_gr_main dp_gr_mod_main dp_gr_f_main dp_weyl_gr_main dp_weyl_gr_mod_main dp_weyl_gr_f_main},
1.2 noro 1873: \JP @fref{dp_ord}, @fref{�$BJ,;67W;;�(B}
1874: \EG @fref{dp_ord}, @fref{Distributed computation}
1.1 noro 1875: @end table
1876:
1.2 noro 1877: \JP @node lex_hensel_gsl tolex_gsl tolex_gsl_d,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
1878: \EG @node lex_hensel_gsl tolex_gsl tolex_gsl_d,,, Functions for Groebner basis computation
1.1 noro 1879: @subsection @code{lex_hensel_gsl}, @code{tolex_gsl}, @code{tolex_gsl_d}
1880: @findex lex_hensel_gsl
1881: @findex tolex_gsl
1882: @findex tolex_gsl_d
1883:
1884: @table @t
1885: @item lex_hensel_gsl(@var{plist},@var{vlist1},@var{order},@var{vlist2},@var{homo})
1.2 noro 1886: \JP :: GSL �$B7A<0$N%$%G%"%k4pDl$N7W;;�(B
1887: \EG ::Computation of an GSL form ideal basis
1.8 noro 1888: @item tolex_gsl(@var{plist},@var{vlist1},@var{order},@var{vlist2})
1889: @itemx tolex_gsl_d(@var{plist},@var{vlist1},@var{order},@var{vlist2},@var{procs})
1.2 noro 1890: \JP :: �$B%0%l%V%J4pDl$rF~NO$H$9$k�(B, GSL �$B7A<0$N%$%G%"%k4pDl$N7W;;�(B
1891: \EG :: Computation of an GSL form ideal basis stating from a Groebner basis
1.1 noro 1892: @end table
1893:
1894: @table @var
1895: @item return
1.2 noro 1896: \JP �$B%j%9%H�(B
1897: \EG list
1.4 noro 1898: @item plist vlist1 vlist2 procs
1.2 noro 1899: \JP �$B%j%9%H�(B
1900: \EG list
1.1 noro 1901: @item order
1.2 noro 1902: \JP �$B?t�(B, �$B%j%9%H$^$?$O9TNs�(B
1903: \EG number, list or matrix
1.1 noro 1904: @item homo
1.2 noro 1905: \JP �$B%U%i%0�(B
1906: \EG flag
1.1 noro 1907: @end table
1908:
1909: @itemize @bullet
1.2 noro 1910: \BJP
1.1 noro 1911: @item
1912: @code{lex_hensel_gsl()} �$B$O�(B @code{lex_hensel()} �$B$N�(B, @code{tolex_gsl()} �$B$O�(B
1913: @code{tolex()} �$B$NJQ<o$G�(B, �$B7k2L$N$_$,0[$J$k�(B.
1914: @code{tolex_gsl_d()} �$B$O�(B, �$B4pDl7W;;$r�(B, @code{procs} �$B$G;XDj$5$l$k;R%W%m%;%9$K�(B
1915: �$BJ,;67W;;$5$;$k�(B.
1916: @item
1917: �$BF~NO$,�(B 0 �$B<!85%7%9%F%`$G�(B, �$B$=$N<-=q<0=g=x%0%l%V%J4pDl$,�(B
1918: @code{[f0,x1-f1,...,xn-fn]} (@code{f0},...,@code{fn} �$B$O�(B
1919: @code{x0} �$B$N�(B 1 �$BJQ?tB?9`<0�(B) �$B$J$k7A�(B (�$B$3$l$r�(B SL �$B7A<0$H8F$V�(B) �$B$r;}$D>l9g�(B,
1920: @code{[[x1,g1,d1],...,[xn,gn,dn],[x0,f0,f0']]} �$B$J$k%j%9%H�(B (�$B$3$l$r�(B GSL �$B7A<0$H8F$V�(B)
1921: �$B$rJV$9�(B.
1.2 noro 1922: �$B$3$3$G�(B, @code{gi} �$B$O�(B, @code{di*f0'*fi-gi} �$B$,�(B @code{f0} �$B$G3d$j@Z$l$k$h$&$J�(B
1.1 noro 1923: @code{x0} �$B$N�(B1 �$BJQ?tB?9`<0$G�(B,
1924: �$B2r$O�(B @code{f0(x0)=0} �$B$J$k�(B @code{x0} �$B$KBP$7�(B, @code{[x1=g1/(d1*f0'),...,xn=gn/(dn*f0')]}
1925: �$B$H$J$k�(B. �$B<-=q<0=g=x%0%l%V%J4pDl$,>e$N$h$&$J7A$G$J$$>l9g�(B, @code{tolex()} �$B$K�(B
1926: �$B$h$kDL>o$N%0%l%V%J4pDl$rJV$9�(B.
1927: @item
1928: GSL �$B7A<0$K$h$jI=$5$l$k4pDl$O%0%l%V%J4pDl$G$O$J$$$,�(B, �$B0lHL$K78?t$,�(B SL �$B7A<0�(B
1929: �$B$N%0%l%V%J4pDl$h$jHs>o$K>.$5$$$?$a7W;;$bB.$/�(B, �$B2r$b5a$a$d$9$$�(B.
1930: @code{tolex_gsl_d()} �$B$GI=<($5$l$k;~4V$O�(B, �$B$3$NH!?t$,<B9T$5$l$F$$$k%W%m%;%9$K�(B
1931: �$B$*$$$F9T$o$l$?7W;;$KBP1~$7$F$$$F�(B, �$B;R%W%m%;%9$K$*$1$k;~4V$O4^$^$l$J$$�(B.
1.2 noro 1932: \E
1933: \BEG
1934: @item
1935: @code{lex_hensel_gsl()} and @code{lex_hensel()} are variants of
1936: @code{tolex_gsl()} and @code{tolex()} respectively. The results are
1937: Groebner basis or a kind of ideal basis, called GSL form.
1938: @code{tolex_gsl_d()} does basis computations in parallel on child
1939: processes specified in @code{procs}.
1940:
1941: @item
1942: If the input is zero-dimensional and a lex order Groebner basis has
1943: the form @code{[f0,x1-f1,...,xn-fn]} (@code{f0},...,@code{fn} are
1944: univariate polynomials of @code{x0}; SL form), then this these
1945: functions return a list such as
1946: @code{[[x1,g1,d1],...,[xn,gn,dn],[x0,f0,f0']]} (GSL form). In this list
1947: @code{gi} is a univariate polynomial of @code{x0} such that
1948: @code{di*f0'*fi-gi} divides @code{f0} and the roots of the input ideal is
1949: @code{[x1=g1/(d1*f0'),...,xn=gn/(dn*f0')]} for @code{x0}
1950: such that @code{f0(x0)=0}.
1951: If the lex order Groebner basis does not have the above form,
1952: these functions return
1953: a lex order Groebner basis computed by @code{tolex()}.
1954: @item
1955: Though an ideal basis represented as GSL form is not a Groebner basis
1956: we can expect that the coefficients are much smaller than those in a Groebner
1957: basis and that the computation is efficient.
1958: The CPU time shown after an execution of @code{tolex_gsl_d()} indicates
1959: that of the master process, and it does not include the time in child
1960: processes.
1961: \E
1.1 noro 1962: @end itemize
1963:
1964: @example
1965: [103] K=katsura(5)$
1966: [104] V=[u5,u4,u3,u2,u1,u0]$
1967: [105] G0=gr(K,V,0)$
1968: [106] GSL=tolex_gsl(G0,V,0,V)$
1969: [107] GSL[0];
1970: [u1,8635837421130477667200000000*u0^31-...]
1971: [108] GSL[1];
1972: [u2,10352277157007342793600000000*u0^31-...]
1973: [109] GSL[5];
1.5 noro 1974: [u0,11771021876193064124640000000*u0^32-...,
1975: 376672700038178051988480000000*u0^31-...]
1.1 noro 1976: @end example
1977:
1978: @table @t
1.2 noro 1979: \JP @item �$B;2>H�(B
1980: \EG @item References
1.1 noro 1981: @fref{lex_hensel lex_tl tolex tolex_d tolex_tl},
1.2 noro 1982: \JP @fref{�$BJ,;67W;;�(B}
1983: \EG @fref{Distributed computation}
1.1 noro 1984: @end table
1985:
1.2 noro 1986: \JP @node gr_minipoly minipoly,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
1987: \EG @node gr_minipoly minipoly,,, Functions for Groebner basis computation
1.1 noro 1988: @subsection @code{gr_minipoly}, @code{minipoly}
1989: @findex gr_minipoly
1990: @findex minipoly
1991:
1992: @table @t
1993: @item gr_minipoly(@var{plist},@var{vlist},@var{order},@var{poly},@var{v},@var{homo})
1.2 noro 1994: \JP :: �$BB?9`<0$N�(B, �$B%$%G%"%k$rK!$H$7$?:G>.B?9`<0$N7W;;�(B
1995: \EG :: Computation of the minimal polynomial of a polynomial modulo an ideal
1.1 noro 1996: @item minipoly(@var{plist},@var{vlist},@var{order},@var{poly},@var{v})
1.2 noro 1997: \JP :: �$B%0%l%V%J4pDl$rF~NO$H$9$k�(B, �$BB?9`<0$N:G>.B?9`<0$N7W;;�(B
1998: \EG :: Computation of the minimal polynomial of a polynomial modulo an ideal
1.1 noro 1999: @end table
2000:
2001: @table @var
2002: @item return
1.2 noro 2003: \JP �$BB?9`<0�(B
2004: \EG polynomial
1.4 noro 2005: @item plist vlist
1.2 noro 2006: \JP �$B%j%9%H�(B
2007: \EG list
1.1 noro 2008: @item order
1.2 noro 2009: \JP �$B?t�(B, �$B%j%9%H$^$?$O9TNs�(B
2010: \EG number, list or matrix
1.1 noro 2011: @item poly
1.2 noro 2012: \JP �$BB?9`<0�(B
2013: \EG polynomial
1.1 noro 2014: @item v
1.2 noro 2015: \JP �$BITDj85�(B
2016: \EG indeterminate
1.1 noro 2017: @item homo
1.2 noro 2018: \JP �$B%U%i%0�(B
2019: \EG flag
1.1 noro 2020: @end table
2021:
2022: @itemize @bullet
1.2 noro 2023: \BJP
1.1 noro 2024: @item
2025: @code{gr_minipoly()} �$B$O%0%l%V%J4pDl$N7W;;$+$i9T$$�(B, @code{minipoly()} �$B$O�(B
2026: �$BF~NO$r%0%l%V%J4pDl$H$_$J$9�(B.
2027: @item
2028: �$B%$%G%"%k�(B I �$B$,BN�(B K �$B>e$NB?9`<04D�(B K[X] �$B$N�(B 0 �$B<!85%$%G%"%k$N;~�(B,
2029: K[@var{v}] �$B$N85�(B f(@var{v}) �$B$K�(B f(@var{p}) mod I �$B$rBP1~$5$;$k�(B
2030: �$B4D=`F17?$N3K$O�(B 0 �$B$G$J$$B?9`<0$K$h$j@8@.$5$l$k�(B. �$B$3$N@8@.85$r�(B @var{p}
2031: �$B$N�(B, �$BK!�(B @var{I} �$B$G$N:G>.B?9`<0$H8F$V�(B.
2032: @item
2033: @code{gr_minipoly()}, @code{minipoly()} �$B$O�(B, �$BB?9`<0�(B @var{p} �$B$N:G>.B?9`<0�(B
2034: �$B$r5a$a�(B, @var{v} �$B$rJQ?t$H$9$kB?9`<0$H$7$FJV$9�(B.
2035: @item
2036: �$B:G>.B?9`<0$O�(B, �$B%0%l%V%J4pDl$N�(B 1 �$B$D$N85$H$7$F7W;;$9$k$3$H$b$G$-$k$,�(B,
2037: �$B:G>.B?9`<0$N$_$r5a$a$?$$>l9g�(B, @code{minipoly()}, @code{gr_minipoly()} �$B$O�(B
2038: �$B%0%l%V%J4pDl$rMQ$$$kJ}K!$KHf$Y$F8zN($,$h$$�(B.
2039: @item
2040: @code{gr_minipoly()} �$B$K;XDj$9$k9`=g=x$H$7$F$O�(B, �$BDL>oA4<!?t5U<-=q<0=g=x$r�(B
2041: �$BMQ$$$k�(B.
1.2 noro 2042: \E
2043: \BEG
2044: @item
2045: @code{gr_minipoly()} begins by computing a Groebner basis.
2046: @code{minipoly()} regards an input as a Groebner basis with respect to
2047: the variable order @var{vlist} and the order type @var{order}.
2048: @item
2049: Let K be a field. If an ideal @var{I} in K[X] is zero-dimensional, then, for
2050: a polynomial @var{p} in K[X], the kernel of a homomorphism from
2051: K[@var{v}] to K[X]/@var{I} which maps f(@var{v}) to f(@var{p}) mod @var{I}
2052: is generated by a polynomial. The generator is called the minimal polynomial
2053: of @var{p} modulo @var{I}.
2054: @item
2055: @code{gr_minipoly()} and @code{minipoly()} computes the minimal polynomial
2056: of a polynomial @var{p} and returns it as a polynomial of @var{v}.
2057: @item
2058: The minimal polynomial can be computed as an element of a Groebner basis.
2059: But if we are only interested in the minimal polynomial,
2060: @code{minipoly()} and @code{gr_minipoly()} can compute it more efficiently
2061: than methods using Groebner basis computation.
2062: @item
2063: It is recommended to use a degree reverse lex order as a term order
2064: for @code{gr_minipoly()}.
2065: \E
1.1 noro 2066: @end itemize
2067:
2068: @example
2069: [117] G=tolex(G0,V,0,V)$
2070: 43.818sec + gc : 11.202sec
2071: [118] GSL=tolex_gsl(G0,V,0,V)$
2072: 17.123sec + gc : 2.590sec
2073: [119] MP=minipoly(G0,V,0,u0,z)$
2074: 4.370sec + gc : 780msec
2075: @end example
2076:
2077: @table @t
1.2 noro 2078: \JP @item �$B;2>H�(B
2079: \EG @item References
1.1 noro 2080: @fref{lex_hensel lex_tl tolex tolex_d tolex_tl}.
2081: @end table
2082:
1.2 noro 2083: \JP @node tolexm minipolym,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
2084: \EG @node tolexm minipolym,,, Functions for Groebner basis computation
1.1 noro 2085: @subsection @code{tolexm}, @code{minipolym}
2086: @findex tolexm
2087: @findex minipolym
2088:
2089: @table @t
2090: @item tolexm(@var{plist},@var{vlist1},@var{order},@var{vlist2},@var{mod})
1.2 noro 2091: \JP :: �$BK!�(B @var{mod} �$B$G$N4pDlJQ49$K$h$k%0%l%V%J4pDl7W;;�(B
2092: \EG :: Groebner basis computation modulo @var{mod} by change of ordering.
1.1 noro 2093: @item minipolym(@var{plist},@var{vlist1},@var{order},@var{poly},@var{v},@var{mod})
1.2 noro 2094: \JP :: �$BK!�(B @var{mod} �$B$G$N%0%l%V%J4pDl$K$h$kB?9`<0$N:G>.B?9`<0$N7W;;�(B
2095: \EG :: Minimal polynomial computation modulo @var{mod} the same method as
1.1 noro 2096: @end table
2097:
2098: @table @var
2099: @item return
1.2 noro 2100: \JP @code{tolexm()} : �$B%j%9%H�(B, @code{minipolym()} : �$BB?9`<0�(B
2101: \EG @code{tolexm()} : list, @code{minipolym()} : polynomial
1.4 noro 2102: @item plist vlist1 vlist2
1.2 noro 2103: \JP �$B%j%9%H�(B
2104: \EG list
1.1 noro 2105: @item order
1.2 noro 2106: \JP �$B?t�(B, �$B%j%9%H$^$?$O9TNs�(B
2107: \EG number, list or matrix
1.1 noro 2108: @item mod
1.2 noro 2109: \JP �$BAG?t�(B
2110: \EG prime
1.1 noro 2111: @end table
2112:
2113: @itemize @bullet
1.2 noro 2114: \BJP
1.1 noro 2115: @item
2116: �$BF~NO�(B @var{plist} �$B$O$$$:$l$b�(B �$BJQ?t=g=x�(B @var{vlist1}, �$B9`=g=x7?�(B @var{order},
2117: �$BK!�(B @var{mod} �$B$K$*$1$k%0%l%V%J4pDl$G$J$1$l$P$J$i$J$$�(B.
2118: @item
2119: @code{minipolym()} �$B$O�(B @code{minipoly} �$B$KBP1~$9$k7W;;$rK!�(B @var{mod}�$B$G9T$&�(B.
2120: @item
2121: @code{tolexm()} �$B$O�(B FGLM �$BK!$K$h$k4pDlJQ49$K$h$j�(B @var{vlist2},
2122: �$B<-=q<0=g=x$K$h$k%0%l%V%J4pDl$r7W;;$9$k�(B.
1.2 noro 2123: \E
2124: \BEG
2125: @item
2126: An input @var{plist} must be a Groebner basis modulo @var{mod}
2127: with respect to the variable order @var{vlist1} and the order type @var{order}.
2128: @item
2129: @code{minipolym()} executes the same computation as in @code{minipoly}.
2130: @item
2131: @code{tolexm()} computes a lex order Groebner basis modulo @var{mod}
2132: with respect to the variable order @var{vlist2}, by using FGLM algorithm.
2133: \E
1.1 noro 2134: @end itemize
2135:
2136: @example
2137: [197] tolexm(G0,V,0,V,31991);
2138: [8271*u0^31+10435*u0^30+816*u0^29+26809*u0^28+...,...]
2139: [198] minipolym(G0,V,0,u0,z,31991);
2140: z^32+11405*z^31+20868*z^30+21602*z^29+...
2141: @end example
2142:
2143: @table @t
1.2 noro 2144: \JP @item �$B;2>H�(B
2145: \EG @item References
1.1 noro 2146: @fref{lex_hensel lex_tl tolex tolex_d tolex_tl},
2147: @fref{gr_minipoly minipoly}.
2148: @end table
2149:
1.6 noro 2150: \JP @node dp_gr_main dp_gr_mod_main dp_gr_f_main dp_weyl_gr_main dp_weyl_gr_mod_main dp_weyl_gr_f_main,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
2151: \EG @node dp_gr_main dp_gr_mod_main dp_gr_f_main dp_weyl_gr_main dp_weyl_gr_mod_main dp_weyl_gr_f_main,,, Functions for Groebner basis computation
2152: @subsection @code{dp_gr_main}, @code{dp_gr_mod_main}, @code{dp_gr_f_main}, @code{dp_weyl_gr_main}, @code{dp_weyl_gr_mod_main}, @code{dp_weyl_gr_f_main}
1.1 noro 2153: @findex dp_gr_main
2154: @findex dp_gr_mod_main
1.5 noro 2155: @findex dp_gr_f_main
1.6 noro 2156: @findex dp_weyl_gr_main
2157: @findex dp_weyl_gr_mod_main
2158: @findex dp_weyl_gr_f_main
1.1 noro 2159:
2160: @table @t
2161: @item dp_gr_main(@var{plist},@var{vlist},@var{homo},@var{modular},@var{order})
2162: @itemx dp_gr_mod_main(@var{plist},@var{vlist},@var{homo},@var{modular},@var{order})
1.5 noro 2163: @itemx dp_gr_f_main(@var{plist},@var{vlist},@var{homo},@var{order})
1.6 noro 2164: @itemx dp_weyl_gr_main(@var{plist},@var{vlist},@var{homo},@var{modular},@var{order})
2165: @itemx dp_weyl_gr_mod_main(@var{plist},@var{vlist},@var{homo},@var{modular},@var{order})
2166: @itemx dp_weyl_gr_f_main(@var{plist},@var{vlist},@var{homo},@var{order})
1.2 noro 2167: \JP :: �$B%0%l%V%J4pDl$N7W;;�(B (�$BAH$_9~$_H!?t�(B)
2168: \EG :: Groebner basis computation (built-in functions)
1.1 noro 2169: @end table
2170:
2171: @table @var
2172: @item return
1.2 noro 2173: \JP �$B%j%9%H�(B
2174: \EG list
1.4 noro 2175: @item plist vlist
1.2 noro 2176: \JP �$B%j%9%H�(B
2177: \EG list
1.1 noro 2178: @item order
1.2 noro 2179: \JP �$B?t�(B, �$B%j%9%H$^$?$O9TNs�(B
2180: \EG number, list or matrix
1.1 noro 2181: @item homo
1.2 noro 2182: \JP �$B%U%i%0�(B
2183: \EG flag
1.1 noro 2184: @item modular
1.2 noro 2185: \JP �$B%U%i%0$^$?$OAG?t�(B
2186: \EG flag or prime
1.1 noro 2187: @end table
2188:
2189: @itemize @bullet
1.2 noro 2190: \BJP
1.1 noro 2191: @item
2192: �$B$3$l$i$NH!?t$O�(B, �$B%0%l%V%J4pDl7W;;$N4pK\E*AH$_9~$_H!?t$G$"$j�(B, @code{gr()},
2193: @code{hgr()}, @code{gr_mod()} �$B$J$I$O$9$Y$F$3$l$i$NH!?t$r8F$S=P$7$F7W;;�(B
1.6 noro 2194: �$B$r9T$C$F$$$k�(B. �$B4X?tL>$K�(B weyl �$B$,F~$C$F$$$k$b$N$O�(B, Weyl �$BBe?t>e$N7W;;�(B
2195: �$B$N$?$a$N4X?t$G$"$k�(B.
1.1 noro 2196: @item
1.6 noro 2197: @code{dp_gr_f_main()}, @code{dp_weyl_f_main()} �$B$O�(B, �$B<o!9$NM-8BBN>e$N%0%l%V%J4pDl$r7W;;$9$k�(B
1.5 noro 2198: �$B>l9g$KMQ$$$k�(B. �$BF~NO$O�(B, �$B$"$i$+$8$a�(B, @code{simp_ff()} �$B$J$I$G�(B,
2199: �$B9M$($kM-8BBN>e$K<M1F$5$l$F$$$kI,MW$,$"$k�(B.
2200: @item
1.1 noro 2201: �$B%U%i%0�(B @var{homo} �$B$,�(B 0 �$B$G$J$$;~�(B, �$BF~NO$r@F<!2=$7$F$+$i�(B Buchberger �$B%"%k%4%j%:%`�(B
2202: �$B$r<B9T$9$k�(B.
2203: @item
2204: @code{dp_gr_mod_main()} �$B$KBP$7$F$O�(B, @var{modular} �$B$O�(B, GF(@var{modular}) �$B>e�(B
2205: �$B$G$N7W;;$r0UL#$9$k�(B.
2206: @code{dp_gr_main()} �$B$KBP$7$F$O�(B, @var{modular} �$B$O<!$N$h$&$J0UL#$r;}$D�(B.
2207: @enumerate
2208: @item
2209: @var{modular} �$B$,�(B 1 �$B$N;~�(B, trace-lifting �$B$K$h$k7W;;$r9T$&�(B. �$BAG?t$O�(B
2210: @code{lprime(0)} �$B$+$i=g$K@.8y$9$k$^$G�(B @code{lprime()} �$B$r8F$S=P$7$F@8@.$9$k�(B.
2211: @item
2212: @var{modular} �$B$,�(B 2 �$B0J>e$N<+A3?t$N;~�(B, �$B$=$NCM$rAG?t$H$_$J$7$F�(B trace-lifting
2213: �$B$r9T$&�(B. �$B$=$NAG?t$G<:GT$7$?>l9g�(B, 0 �$B$rJV$9�(B.
2214: @item
2215: @var{modular} �$B$,Ii$N>l9g�(B,
2216: @var{-modular} �$B$KBP$7$F>e=R$N5,B'$,E,MQ$5$l$k$,�(B, trace-lifting �$B$N:G=*�(B
2217: �$BCJ3,$N%0%l%V%J4pDl%A%'%C%/$H%$%G%"%k%a%s%P%7%C%W%A%'%C%/$,>JN,$5$l$k�(B.
2218: @end enumerate
2219:
2220: @item
2221: @code{gr(P,V,O)} �$B$O�(B @code{dp_gr_main(P,V,0,1,O)}, @code{hgr(P,V,O)} �$B$O�(B
2222: @code{dp_gr_main(P,V,1,1,O)}, @code{gr_mod(P,V,O,M)} �$B$O�(B
2223: @code{dp_gr_mod_main(P,V,0,M,O)} �$B$r$=$l$>$l<B9T$9$k�(B.
2224: @item
2225: @var{homo}, @var{modular} �$B$NB>$K�(B, @code{dp_gr_flags()} �$B$G@_Dj$5$l$k�(B
2226: �$B$5$^$6$^$J%U%i%0$K$h$j7W;;$,@)8f$5$l$k�(B.
1.2 noro 2227: \E
2228: \BEG
2229: @item
2230: These functions are fundamental built-in functions for Groebner basis
2231: computation and @code{gr()},@code{hgr()} and @code{gr_mod()}
1.6 noro 2232: are all interfaces to these functions. Functions whose names
2233: contain weyl are those for computation in Weyl algebra.
1.2 noro 2234: @item
1.6 noro 2235: @code{dp_gr_f_main()} and @code{dp_weyl_gr_f_main()}
2236: are functions for Groebner basis computation
1.5 noro 2237: over various finite fields. Coefficients of input polynomials
2238: must be converted to elements of a finite field
2239: currently specified by @code{setmod_ff()}.
2240: @item
1.2 noro 2241: If @var{homo} is not equal to 0, homogenization is applied before entering
2242: Buchberger algorithm
2243: @item
2244: For @code{dp_gr_mod_main()}, @var{modular} means a computation over
2245: GF(@var{modular}).
2246: For @code{dp_gr_main()}, @var{modular} has the following mean.
2247: @enumerate
2248: @item
2249: If @var{modular} is 1 , trace lifting is used. Primes for trace lifting
2250: are generated by @code{lprime()}, starting from @code{lprime(0)}, until
2251: the computation succeeds.
2252: @item
2253: If @var{modular} is an integer greater than 1, the integer is regarded as a
2254: prime and trace lifting is executed by using the prime. If the computation
2255: fails then 0 is returned.
2256: @item
2257: If @var{modular} is negative, the above rule is applied for @var{-modular}
2258: but the Groebner basis check and ideal-membership check are omitted in
2259: the last stage of trace lifting.
2260: @end enumerate
2261:
2262: @item
2263: @code{gr(P,V,O)}, @code{hgr(P,V,O)} and @code{gr_mod(P,V,O,M)} execute
2264: @code{dp_gr_main(P,V,0,1,O)}, @code{dp_gr_main(P,V,1,1,O)}
2265: and @code{dp_gr_mod_main(P,V,0,M,O)} respectively.
2266: @item
2267: Actual computation is controlled by various parameters set by
2268: @code{dp_gr_flags()}, other then by @var{homo} and @var{modular}.
2269: \E
1.1 noro 2270: @end itemize
2271:
2272: @table @t
1.2 noro 2273: \JP @item �$B;2>H�(B
2274: \EG @item References
1.1 noro 2275: @fref{dp_ord},
2276: @fref{dp_gr_flags dp_gr_print},
2277: @fref{gr hgr gr_mod},
1.5 noro 2278: @fref{setmod_ff},
1.2 noro 2279: \JP @fref{�$B7W;;$*$h$SI=<($N@)8f�(B}.
2280: \EG @fref{Controlling Groebner basis computations}
1.1 noro 2281: @end table
2282:
1.6 noro 2283: \JP @node dp_f4_main dp_f4_mod_main dp_weyl_f4_main dp_weyl_f4_mod_main,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
2284: \EG @node dp_f4_main dp_f4_mod_main dp_weyl_f4_main dp_weyl_f4_mod_main,,, Functions for Groebner basis computation
2285: @subsection @code{dp_f4_main}, @code{dp_f4_mod_main}, @code{dp_weyl_f4_main}, @code{dp_weyl_f4_mod_main}
1.1 noro 2286: @findex dp_f4_main
2287: @findex dp_f4_mod_main
1.6 noro 2288: @findex dp_weyl_f4_main
2289: @findex dp_weyl_f4_mod_main
1.1 noro 2290:
2291: @table @t
2292: @item dp_f4_main(@var{plist},@var{vlist},@var{order})
2293: @itemx dp_f4_mod_main(@var{plist},@var{vlist},@var{order})
1.6 noro 2294: @itemx dp_weyl_f4_main(@var{plist},@var{vlist},@var{order})
2295: @itemx dp_weyl_f4_mod_main(@var{plist},@var{vlist},@var{order})
1.2 noro 2296: \JP :: F4 �$B%"%k%4%j%:%`$K$h$k%0%l%V%J4pDl$N7W;;�(B (�$BAH$_9~$_H!?t�(B)
2297: \EG :: Groebner basis computation by F4 algorithm (built-in functions)
1.1 noro 2298: @end table
2299:
2300: @table @var
2301: @item return
1.2 noro 2302: \JP �$B%j%9%H�(B
2303: \EG list
1.4 noro 2304: @item plist vlist
1.2 noro 2305: \JP �$B%j%9%H�(B
2306: \EG list
1.1 noro 2307: @item order
1.2 noro 2308: \JP �$B?t�(B, �$B%j%9%H$^$?$O9TNs�(B
2309: \EG number, list or matrix
1.1 noro 2310: @end table
2311:
2312: @itemize @bullet
1.2 noro 2313: \BJP
1.1 noro 2314: @item
2315: F4 �$B%"%k%4%j%:%`$K$h$j%0%l%V%J4pDl$N7W;;$r9T$&�(B.
2316: @item
2317: F4 �$B%"%k%4%j%:%`$O�(B, J.C. Faugere �$B$K$h$jDs>'$5$l$??7@$Be%0%l%V%J4pDl�(B
2318: �$B;;K!$G$"$j�(B, �$BK\<BAu$O�(B, �$BCf9q>jM>DjM}$K$h$k@~7AJ}Dx<05a2r$rMQ$$$?�(B
2319: �$B;n83E*$J<BAu$G$"$k�(B.
2320: @item
1.6 noro 2321: �$B@F<!2=$N0z?t$,$J$$$3$H$r=|$1$P�(B, �$B0z?t$*$h$SF0:n$O$=$l$>$l�(B
2322: @code{dp_gr_main()}, @code{dp_gr_mod_main()},
2323: @code{dp_weyl_gr_main()}, @code{dp_weyl_gr_mod_main()}
1.1 noro 2324: �$B$HF1MM$G$"$k�(B.
1.2 noro 2325: \E
2326: \BEG
2327: @item
2328: These functions compute Groebner bases by F4 algorithm.
2329: @item
2330: F4 is a new generation algorithm for Groebner basis computation
2331: invented by J.C. Faugere. The current implementation of @code{dp_f4_main()}
2332: uses Chinese Remainder theorem and not highly optimized.
2333: @item
2334: Arguments and actions are the same as those of
1.6 noro 2335: @code{dp_gr_main()}, @code{dp_gr_mod_main()},
2336: @code{dp_weyl_gr_main()}, @code{dp_weyl_gr_mod_main()},
2337: except for lack of the argument for controlling homogenization.
1.2 noro 2338: \E
1.1 noro 2339: @end itemize
2340:
2341: @table @t
1.2 noro 2342: \JP @item �$B;2>H�(B
2343: \EG @item References
1.1 noro 2344: @fref{dp_ord},
2345: @fref{dp_gr_flags dp_gr_print},
2346: @fref{gr hgr gr_mod},
1.15 noro 2347: \JP @fref{�$B7W;;$*$h$SI=<($N@)8f�(B}.
2348: \EG @fref{Controlling Groebner basis computations}
2349: @end table
2350:
1.17 noro 2351: \JP @node nd_gr nd_gr_trace nd_f4 nd_f4_trace nd_weyl_gr nd_weyl_gr_trace,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
2352: \EG @node nd_gr nd_gr_trace nd_f4 nd_f4_trace nd_weyl_gr nd_weyl_gr_trace,,, Functions for Groebner basis computation
2353: @subsection @code{nd_gr}, @code{nd_gr_trace}, @code{nd_f4}, @code{nd_f4_trace}, @code{nd_weyl_gr}, @code{nd_weyl_gr_trace}
1.15 noro 2354: @findex nd_gr
2355: @findex nd_gr_trace
2356: @findex nd_f4
1.17 noro 2357: @findex nd_f4_trace
1.15 noro 2358: @findex nd_weyl_gr
2359: @findex nd_weyl_gr_trace
2360:
2361: @table @t
2362: @item nd_gr(@var{plist},@var{vlist},@var{p},@var{order})
2363: @itemx nd_gr_trace(@var{plist},@var{vlist},@var{homo},@var{p},@var{order})
2364: @itemx nd_f4(@var{plist},@var{vlist},@var{modular},@var{order})
1.17 noro 2365: @itemx nd_f4_trace(@var{plist},@var{vlist},@var{homo},@var{p},@var{order})
1.19 noro 2366: @itemx nd_weyl_gr(@var{plist},@var{vlist},@var{p},@var{order})
1.15 noro 2367: @itemx nd_weyl_gr_trace(@var{plist},@var{vlist},@var{homo},@var{p},@var{order})
2368: \JP :: �$B%0%l%V%J4pDl$N7W;;�(B (�$BAH$_9~$_H!?t�(B)
2369: \EG :: Groebner basis computation (built-in functions)
2370: @end table
2371:
2372: @table @var
2373: @item return
2374: \JP �$B%j%9%H�(B
2375: \EG list
2376: @item plist vlist
2377: \JP �$B%j%9%H�(B
2378: \EG list
2379: @item order
2380: \JP �$B?t�(B, �$B%j%9%H$^$?$O9TNs�(B
2381: \EG number, list or matrix
2382: @item homo
2383: \JP �$B%U%i%0�(B
2384: \EG flag
2385: @item modular
2386: \JP �$B%U%i%0$^$?$OAG?t�(B
2387: \EG flag or prime
2388: @end table
2389:
2390: \BJP
2391: @itemize @bullet
2392: @item
2393: �$B$3$l$i$NH!?t$O�(B, �$B%0%l%V%J4pDl7W;;AH$_9~$_4X?t$N?7<BAu$G$"$k�(B.
2394: @item @code{nd_gr} �$B$O�(B, @code{p} �$B$,�(B 0 �$B$N$H$-M-M}?tBN>e$N�(B Buchberger
2395: �$B%"%k%4%j%:%`$r<B9T$9$k�(B. @code{p} �$B$,�(B 2 �$B0J>e$N<+A3?t$N$H$-�(B, GF(p) �$B>e$N�(B
2396: Buchberger �$B%"%k%4%j%:%`$r<B9T$9$k�(B.
1.17 noro 2397: @item @code{nd_gr_trace} �$B$*$h$S�(B @code{nd_f4_trace}
2398: �$B$OM-M}?tBN>e$G�(B trace �$B%"%k%4%j%:%`$r<B9T$9$k�(B.
1.18 noro 2399: @var{p} �$B$,�(B 0 �$B$^$?$O�(B 1 �$B$N$H$-�(B, �$B<+F0E*$KA*$P$l$?AG?t$rMQ$$$F�(B, �$B@.8y$9$k�(B
1.15 noro 2400: �$B$^$G�(B trace �$B%"%k%4%j%:%`$r<B9T$9$k�(B.
1.18 noro 2401: @var{p} �$B$,�(B 2 �$B0J>e$N$H$-�(B, trace �$B$O�(BGF(p) �$B>e$G7W;;$5$l$k�(B. trace �$B%"%k%4%j%:%`�(B
2402: �$B$,<:GT$7$?>l9g�(B 0 �$B$,JV$5$l$k�(B. @var{p} �$B$,Ii$N>l9g�(B, �$B%0%l%V%J4pDl%A%'%C%/$O�(B
2403: �$B9T$o$J$$�(B. �$B$3$N>l9g�(B, @var{p} �$B$,�(B -1 �$B$J$i$P<+F0E*$KA*$P$l$?AG?t$,�(B,
1.17 noro 2404: �$B$=$l0J30$O;XDj$5$l$?AG?t$rMQ$$$F%0%l%V%J4pDl8uJd$N7W;;$,9T$o$l$k�(B.
2405: @code{nd_f4_trace} �$B$O�(B, �$B3FA4<!?t$K$D$$$F�(B, �$B$"$kM-8BBN>e$G�(B F4 �$B%"%k%4%j%:%`�(B
2406: �$B$G9T$C$?7k2L$r$b$H$K�(B, �$B$=$NM-8BBN>e$G�(B 0 �$B$G$J$$4pDl$rM?$($k�(B S-�$BB?9`<0$N$_$r�(B
2407: �$BMQ$$$F9TNs@8@.$r9T$$�(B, �$B$=$NA4<!?t$K$*$1$k4pDl$r@8@.$9$kJ}K!$G$"$k�(B. �$BF@$i$l$k�(B
2408: �$BB?9`<0=89g$O$d$O$j%0%l%V%J4pDl8uJd$G$"$j�(B, @code{nd_gr_trace} �$B$HF1MM$N�(B
2409: �$B%A%'%C%/$,9T$o$l$k�(B.
1.15 noro 2410: @item
1.17 noro 2411: @code{nd_f4} �$B$O�(B @code{modular} �$B$,�(B 0 �$B$N$H$-M-M}?tBN>e$N�(B, @code{modular} �$B$,�(B
2412: �$B%^%7%s%5%$%:AG?t$N$H$-M-8BBN>e$N�(B F4 �$B%"%k%4%j%:%`$r<B9T$9$k�(B.
1.15 noro 2413: @item
1.18 noro 2414: @var{plist} �$B$,B?9`<0%j%9%H$N>l9g�(B, @var{plist}�$B$G@8@.$5$l$k%$%G%"%k$N%0%l%V%J!<4pDl$,�(B
2415: �$B7W;;$5$l$k�(B. @var{plist} �$B$,B?9`<0%j%9%H$N%j%9%H$N>l9g�(B, �$B3FMWAG$OB?9`<04D>e$N<+M32C72$N85$H8+$J$5$l�(B,
2416: �$B$3$l$i$,@8@.$9$kItJ,2C72$N%0%l%V%J!<4pDl$,7W;;$5$l$k�(B. �$B8e<T$N>l9g�(B, �$B9`=g=x$O2C72$KBP$9$k9`=g=x$r�(B
2417: �$B;XDj$9$kI,MW$,$"$k�(B. �$B$3$l$O�(B @var{[s,ord]} �$B$N7A$G;XDj$9$k�(B. @var{s} �$B$,�(B 0 �$B$J$i$P�(B TOP (Term Over Position),
2418: 1 �$B$J$i$P�(B POT (Position Over Term) �$B$r0UL#$7�(B, @var{ord} �$B$OB?9`<04D$NC19`<0$KBP$9$k9`=g=x$G$"$k�(B.
2419: @item
1.15 noro 2420: @code{nd_weyl_gr}, @code{nd_weyl_gr_trace} �$B$O�(B Weyl �$BBe?tMQ$G$"$k�(B.
2421: @item
1.18 noro 2422: @code{f4} �$B7O4X?t0J30$O$9$Y$FM-M}4X?t78?t$N7W;;$,2DG=$G$"$k�(B.
1.15 noro 2423: @item
2424: �$B0lHL$K�(B @code{dp_gr_main}, @code{dp_gr_mod_main} �$B$h$j9bB.$G$"$k$,�(B,
2425: �$BFC$KM-8BBN>e$N>l9g82Cx$G$"$k�(B.
2426: @end itemize
2427: \E
2428:
2429: \BEG
2430: @itemize @bullet
2431: @item
2432: These functions are new implementations for computing Groebner bases.
2433: @item @code{nd_gr} executes Buchberger algorithm over the rationals
2434: if @code{p} is 0, and that over GF(p) if @code{p} is a prime.
2435: @item @code{nd_gr_trace} executes the trace algorithm over the rationals.
2436: If @code{p} is 0 or 1, the trace algorithm is executed until it succeeds
2437: by using automatically chosen primes.
2438: If @code{p} a positive prime,
2439: the trace is comuted over GF(p).
2440: If the trace algorithm fails 0 is returned.
2441: If @code{p} is negative,
2442: the Groebner basis check and ideal-membership check are omitted.
2443: In this case, an automatically chosen prime if @code{p} is 1,
2444: otherwise the specified prime is used to compute a Groebner basis
2445: candidate.
1.17 noro 2446: Execution of @code{nd_f4_trace} is done as follows:
2447: For each total degree, an F4-reduction of S-polynomials over a finite field
2448: is done, and S-polynomials which give non-zero basis elements are gathered.
2449: Then F4-reduction over Q is done for the gathered S-polynomials.
2450: The obtained polynomial set is a Groebner basis candidate and the same
2451: check procedure as in the case of @code{nd_gr_trace} is done.
2452: @item
2453: @code{nd_f4} executes F4 algorithm over Q if @code{modular} is equal to 0,
2454: or over a finite field GF(@code{modular})
2455: if @code{modular} is a prime number of machine size (<2^29).
1.18 noro 2456: If @var{plist} is a list of polynomials, then a Groebner basis of the ideal generated by @var{plist}
2457: is computed. If @var{plist} is a list of lists of polynomials, then each list of polynomials are regarded
2458: as an element of a free module over a polynomial ring and a Groebner basis of the sub-module generated by @var{plist}
2459: in the free module. In the latter case a term order in the free module should be specified.
2460: This is specified by @var{[s,ord]}. If @var{s} is 0 then it means TOP (Term Over Position).
2461: If @var{s} is 1 then it means POT 1 (Position Over Term). @var{ord} is a term order in the base polynomial ring.
1.15 noro 2462: @item
2463: @code{nd_weyl_gr}, @code{nd_weyl_gr_trace} are for Weyl algebra computation.
2464: @item
1.18 noro 2465: Functions except for F4 related ones can handle rational coeffient cases.
1.15 noro 2466: @item
2467: In general these functions are more efficient than
2468: @code{dp_gr_main}, @code{dp_gr_mod_main}, especially over finite fields.
2469: @end itemize
2470: \E
2471:
2472: @example
2473: [38] load("cyclic")$
2474: [49] C=cyclic(7)$
2475: [50] V=vars(C)$
2476: [51] cputime(1)$
2477: [52] dp_gr_mod_main(C,V,0,31991,0)$
2478: 26.06sec + gc : 0.313sec(26.4sec)
2479: [53] nd_gr(C,V,31991,0)$
2480: ndv_alloc=1477188
2481: 5.737sec + gc : 0.1837sec(5.921sec)
2482: [54] dp_f4_mod_main(C,V,31991,0)$
2483: 3.51sec + gc : 0.7109sec(4.221sec)
2484: [55] nd_f4(C,V,31991,0)$
2485: 1.906sec + gc : 0.126sec(2.032sec)
2486: @end example
2487:
2488: @table @t
2489: \JP @item �$B;2>H�(B
2490: \EG @item References
2491: @fref{dp_ord},
2492: @fref{dp_gr_flags dp_gr_print},
1.2 noro 2493: \JP @fref{�$B7W;;$*$h$SI=<($N@)8f�(B}.
2494: \EG @fref{Controlling Groebner basis computations}
1.1 noro 2495: @end table
2496:
1.2 noro 2497: \JP @node dp_gr_flags dp_gr_print,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
2498: \EG @node dp_gr_flags dp_gr_print,,, Functions for Groebner basis computation
1.1 noro 2499: @subsection @code{dp_gr_flags}, @code{dp_gr_print}
2500: @findex dp_gr_flags
2501: @findex dp_gr_print
2502:
2503: @table @t
2504: @item dp_gr_flags([@var{list}])
1.7 noro 2505: @itemx dp_gr_print([@var{i}])
1.2 noro 2506: \JP :: �$B7W;;$*$h$SI=<(MQ%Q%i%a%?$N@_Dj�(B, �$B;2>H�(B
2507: \BEG :: Set and show various parameters for cotrolling computations
2508: and showing informations.
2509: \E
1.1 noro 2510: @end table
2511:
2512: @table @var
2513: @item return
1.2 noro 2514: \JP �$B@_DjCM�(B
2515: \EG value currently set
1.1 noro 2516: @item list
1.2 noro 2517: \JP �$B%j%9%H�(B
2518: \EG list
1.7 noro 2519: @item i
2520: \JP �$B@0?t�(B
2521: \EG integer
1.1 noro 2522: @end table
2523:
2524: @itemize @bullet
1.2 noro 2525: \BJP
1.1 noro 2526: @item
1.5 noro 2527: @code{dp_gr_main()}, @code{dp_gr_mod_main()}, @code{dp_gr_f_main()} �$B<B9T;~$K$*$1$k$5$^$6$^�(B
1.1 noro 2528: �$B$J%Q%i%a%?$r@_Dj�(B, �$B;2>H$9$k�(B.
2529: @item
2530: �$B0z?t$,$J$$>l9g�(B, �$B8=:_$N@_Dj$,JV$5$l$k�(B.
2531: @item
2532: �$B0z?t$O�(B, @code{["Print",1,"NoSugar",1,...]} �$B$J$k7A$N%j%9%H$G�(B, �$B:8$+$i=g$K�(B
2533: �$B@_Dj$5$l$k�(B. �$B%Q%i%a%?L>$OJ8;zNs$GM?$($kI,MW$,$"$k�(B.
2534: @item
1.7 noro 2535: @code{dp_gr_print()} �$B$O�(B, �$BFC$K%Q%i%a%?�(B @code{Print}, @code{PrintShort} �$B$NCM$rD>@\@_Dj�(B, �$B;2>H�(B
2536: �$B$G$-$k�(B. �$B@_Dj$5$l$kCM$O<!$NDL$j$G$"$k!#�(B
2537: @table @var
2538: @item i=0
2539: @code{Print=0}, @code{PrintShort=0}
2540: @item i=1
2541: @code{Print=1}, @code{PrintShort=0}
2542: @item i=2
2543: @code{Print=0}, @code{PrintShort=1}
2544: @end table
2545: �$B$3$l$O�(B, @code{dp_gr_main()} �$B$J$I$r%5%V%k!<%A%s$H$7$FMQ$$$k%f!<%6�(B
2546: �$BH!?t$K$*$$$F�(B, �$B$=$N%5%V%k!<%A%s$,Cf4V>pJs$NI=<(�(B
1.1 noro 2547: �$B$r9T$&:]$K�(B, �$B?WB.$K%U%i%0$r8+$k$3$H$,$G$-$k$h$&$KMQ0U$5$l$F$$$k�(B.
1.2 noro 2548: \E
2549: \BEG
2550: @item
2551: @code{dp_gr_flags()} sets and shows various parameters for Groebner basis
2552: computation.
2553: @item
2554: If no argument is specified the current settings are returned.
2555: @item
2556: Arguments must be specified as a list such as
2557: @code{["Print",1,"NoSugar",1,...]}. Names of parameters must be character
2558: strings.
2559: @item
2560: @code{dp_gr_print()} is used to set and show the value of a parameter
1.7 noro 2561: @code{Print} and @code{PrintShort}.
2562: @table @var
2563: @item i=0
2564: @code{Print=0}, @code{PrintShort=0}
2565: @item i=1
2566: @code{Print=1}, @code{PrintShort=0}
2567: @item i=2
2568: @code{Print=0}, @code{PrintShort=1}
2569: @end table
2570: This functions is prepared to get quickly the value
2571: when a user defined function calling @code{dp_gr_main()} etc.
1.2 noro 2572: uses the value as a flag for showing intermediate informations.
2573: \E
1.1 noro 2574: @end itemize
2575:
2576: @table @t
1.2 noro 2577: \JP @item �$B;2>H�(B
2578: \EG @item References
2579: \JP @fref{�$B7W;;$*$h$SI=<($N@)8f�(B}
2580: \EG @fref{Controlling Groebner basis computations}
1.1 noro 2581: @end table
2582:
1.2 noro 2583: \JP @node dp_ord,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
2584: \EG @node dp_ord,,, Functions for Groebner basis computation
1.1 noro 2585: @subsection @code{dp_ord}
2586: @findex dp_ord
2587:
2588: @table @t
2589: @item dp_ord([@var{order}])
1.2 noro 2590: \JP :: �$BJQ?t=g=x7?$N@_Dj�(B, �$B;2>H�(B
2591: \EG :: Set and show the ordering type.
1.1 noro 2592: @end table
2593:
2594: @table @var
2595: @item return
1.2 noro 2596: \JP �$BJQ?t=g=x7?�(B (�$B?t�(B, �$B%j%9%H$^$?$O9TNs�(B)
2597: \EG ordering type (number, list or matrix)
1.1 noro 2598: @item order
1.2 noro 2599: \JP �$B?t�(B, �$B%j%9%H$^$?$O9TNs�(B
2600: \EG number, list or matrix
1.1 noro 2601: @end table
2602:
2603: @itemize @bullet
1.2 noro 2604: \BJP
1.1 noro 2605: @item
2606: �$B0z?t$,$"$k;~�(B, �$BJQ?t=g=x7?$r�(B @var{order} �$B$K@_Dj$9$k�(B. �$B0z?t$,$J$$;~�(B,
2607: �$B8=:_@_Dj$5$l$F$$$kJQ?t=g=x7?$rJV$9�(B.
2608:
2609: @item
2610: �$BJ,;6I=8=B?9`<0$K4X$9$kH!?t�(B, �$B1i;;$O0z?t$H$7$FJQ?t=g=x7?$r$H$k$b$N$H$H$i$J$$$b$N�(B
2611: �$B$,$"$j�(B, �$B$H$i$J$$$b$N$K4X$7$F$O�(B, �$B$=$N;~E@$G@_Dj$5$l$F$$$kCM$rMQ$$$F7W;;$,�(B
2612: �$B9T$o$l$k�(B.
2613:
2614: @item
2615: @code{gr()} �$B$J$I�(B, �$B0z?t$H$7$FJQ?t=g=x7?$r$H$k$b$N$O�(B, �$BFbIt$G�(B @code{dp_ord()}
2616: �$B$r8F$S=P$7�(B, �$BJQ?t=g=x7?$r@_Dj$9$k�(B. �$B$3$N@_Dj$O�(B, �$B7W;;=*N;8e$b@8$-;D$k�(B.
2617:
2618: @item
2619: �$BJ,;6I=8=B?9`<0$N;MB'1i;;$b�(B, �$B@_Dj$5$l$F$$$kCM$rMQ$$$F7W;;$5$l$k�(B. �$B=>$C$F�(B,
2620: �$B$=$NB?9`<0$,@8@.$5$l$?;~E@$K$*$1$kJQ?t=g=x7?$,�(B, �$B;MB'1i;;;~$K@5$7$/@_Dj�(B
2621: �$B$5$l$F$$$J$1$l$P$J$i$J$$�(B. �$B$^$?�(B, �$B1i;;BP>]$H$J$kB?9`<0$O�(B, �$BF10l$NJQ?t=g=x�(B
2622: �$B7?$K4p$E$$$F@8@.$5$l$?$b$N$G$J$1$l$P$J$i$J$$�(B.
2623:
2624: @item
2625: �$B%H%C%W%l%Y%kH!?t0J30$NH!?t$rD>@\8F$S=P$9>l9g$K$O�(B, �$B$3$NH!?t$K$h$j�(B
2626: �$BJQ?t=g=x7?$r@5$7$/@_Dj$7$J$1$l$P$J$i$J$$�(B.
1.2 noro 2627: \E
2628: \BEG
2629: @item
2630: If an argument is specified, the function
2631: sets the current ordering type to @var{order}.
2632: If no argument is specified, the function returns the ordering
2633: type currently set.
2634:
2635: @item
2636: There are two types of functions concerning distributed polynomial,
2637: functions which take a ordering type and those which don't take it.
2638: The latter ones use the current setting.
2639:
2640: @item
2641: Functions such as @code{gr()}, which need a ordering type as an argument,
2642: call @code{dp_ord()} internally during the execution.
2643: The setting remains after the execution.
2644:
2645: Fundamental arithmetics for distributed polynomial also use the current
2646: setting. Therefore, when such arithmetics for distributed polynomials
2647: are done, the current setting must coincide with the ordering type
2648: which was used upon the creation of the polynomials. It is assumed
2649: that such polynomials were generated under the same ordering type.
2650:
2651: @item
2652: Type of term ordering must be correctly set by this function
2653: when functions other than top level functions are called directly.
2654: \E
1.1 noro 2655: @end itemize
2656:
2657: @example
2658: [19] dp_ord(0)$
2659: [20] <<1,2,3>>+<<3,1,1>>;
2660: (1)*<<1,2,3>>+(1)*<<3,1,1>>
2661: [21] dp_ord(2)$
2662: [22] <<1,2,3>>+<<3,1,1>>;
2663: (1)*<<3,1,1>>+(1)*<<1,2,3>>
2664: @end example
2665:
2666: @table @t
1.2 noro 2667: \JP @item �$B;2>H�(B
2668: \EG @item References
2669: \JP @fref{�$B9`=g=x$N@_Dj�(B}
2670: \EG @fref{Setting term orderings}
1.1 noro 2671: @end table
2672:
1.18 noro 2673: \JP @node dp_set_weight dp_set_top_weight dp_weyl_set_weight,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
2674: \EG @node dp_set_weight dp_set_top_weight dp_weyl_set_weight,,, Functions for Groebner basis computation
2675: @subsection @code{dp_set_weight}, @code{dp_set_top_weight}, @code{dp_weyl_set_weight}
2676: @findex dp_set_weight
2677: @findex dp_set_top_weight
2678: @findex dp_weyl_set_weight
2679:
2680: @table @t
2681: @item dp_set_weight([@var{weight}])
2682: \JP :: sugar weight �$B$N@_Dj�(B, �$B;2>H�(B
2683: \EG :: Set and show the sugar weight.
2684: @item dp_set_top_weight([@var{weight}])
2685: \JP :: top weight �$B$N@_Dj�(B, �$B;2>H�(B
2686: \EG :: Set and show the top weight.
2687: @item dp_weyl_set_weight([@var{weight}])
2688: \JP :: weyl weight �$B$N@_Dj�(B, �$B;2>H�(B
2689: \EG :: Set and show the weyl weight.
2690: @end table
2691:
2692: @table @var
2693: @item return
2694: \JP �$B%Y%/%H%k�(B
2695: \EG a vector
2696: @item weight
2697: \JP �$B@0?t$N%j%9%H$^$?$O%Y%/%H%k�(B
2698: \EG a list or vector of integers
2699: @end table
2700:
2701: @itemize @bullet
2702: \BJP
2703: @item
2704: @code{dp_set_weight} �$B$O�(B sugar weight �$B$r�(B @var{weight} �$B$K@_Dj$9$k�(B. �$B0z?t$,$J$$;~�(B,
2705: �$B8=:_@_Dj$5$l$F$$$k�(B sugar weight �$B$rJV$9�(B. sugar weight �$B$O@5@0?t$r@.J,$H$9$k%Y%/%H%k$G�(B,
2706: �$B3FJQ?t$N=E$_$rI=$9�(B. �$B<!?t$D$-=g=x$K$*$$$F�(B, �$BC19`<0$N<!?t$r7W;;$9$k:]$KMQ$$$i$l$k�(B.
2707: �$B@F<!2=JQ?tMQ$K�(B, �$BKvHx$K�(B 1 �$B$rIU$12C$($F$*$/$H0BA4$G$"$k�(B.
2708: @item
2709: @code{dp_set_top_weight} �$B$O�(B top weight �$B$r�(B @var{weight} �$B$K@_Dj$9$k�(B. �$B0z?t$,$J$$;~�(B,
2710: �$B8=:_@_Dj$5$l$F$$$k�(B top weight �$B$rJV$9�(B. top weight �$B$,@_Dj$5$l$F$$$k$H$-�(B,
2711: �$B$^$:�(B top weight �$B$K$h$kC19`<0Hf3S$r@h$K9T$&�(B. tie breaker �$B$H$7$F8=:_@_Dj$5$l$F$$$k�(B
2712: �$B9`=g=x$,MQ$$$i$l$k$,�(B, �$B$3$NHf3S$K$O�(B top weight �$B$OMQ$$$i$l$J$$�(B.
2713:
2714: @item
2715: @code{dp_weyl_set_weight} �$B$O�(B weyl weight �$B$r�(B @var{weight} �$B$K@_Dj$9$k�(B. �$B0z?t$,$J$$;~�(B,
2716: �$B8=:_@_Dj$5$l$F$$$k�(B weyl weight �$B$rJV$9�(B. weyl weight w �$B$r@_Dj$9$k$H�(B,
2717: �$B9`=g=x7?�(B 11 �$B$G$N7W;;$K$*$$$F�(B, (-w,w) �$B$r�(B top weight, tie breaker �$B$r�(B graded reverse lex
2718: �$B$H$7$?9`=g=x$,@_Dj$5$l$k�(B.
2719: \E
2720: \BEG
2721: @item
2722: @code{dp_set_weight} sets the sugar weight=@var{weight}. It returns the current sugar weight.
2723: A sugar weight is a vector with positive integer components and it represents the weights of variables.
2724: It is used for computing the weight of a monomial in a graded ordering.
2725: It is recommended to append a component 1 at the end of the weight vector for a homogenizing variable.
2726: @item
2727: @code{dp_set_top_weight} sets the top weight=@var{weight}. It returns the current top weight.
2728: It a top weight is set, the weights of monomials under the top weight are firstly compared.
2729: If the the weights are equal then the current term ordering is applied as a tie breaker, but
2730: the top weight is not used in the tie breaker.
2731:
2732: @item
2733: @code{dp_weyl_set_weight} sets the weyl weigh=@var{weight}. It returns the current weyl weight.
2734: If a weyl weight w is set, in the comparsion by the term order type 11, a term order with
2735: the top weight=(-w,w) and the tie breaker=graded reverse lex is applied.
2736: \E
2737: @end itemize
2738:
2739: @table @t
2740: \JP @item �$B;2>H�(B
2741: \EG @item References
2742: @fref{Weight}
2743: @end table
2744:
2745:
1.2 noro 2746: \JP @node dp_ptod,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
2747: \EG @node dp_ptod,,, Functions for Groebner basis computation
1.1 noro 2748: @subsection @code{dp_ptod}
2749: @findex dp_ptod
2750:
2751: @table @t
2752: @item dp_ptod(@var{poly},@var{vlist})
1.2 noro 2753: \JP :: �$BB?9`<0$rJ,;6I=8=B?9`<0$KJQ49$9$k�(B.
2754: \EG :: Converts an ordinary polynomial into a distributed polynomial.
1.1 noro 2755: @end table
2756:
2757: @table @var
2758: @item return
1.2 noro 2759: \JP �$BJ,;6I=8=B?9`<0�(B
2760: \EG distributed polynomial
1.1 noro 2761: @item poly
1.2 noro 2762: \JP �$BB?9`<0�(B
2763: \EG polynomial
1.1 noro 2764: @item vlist
1.2 noro 2765: \JP �$B%j%9%H�(B
2766: \EG list
1.1 noro 2767: @end table
2768:
2769: @itemize @bullet
1.2 noro 2770: \BJP
1.1 noro 2771: @item
2772: �$BJQ?t=g=x�(B @var{vlist} �$B$*$h$S8=:_$NJQ?t=g=x7?$K=>$C$FJ,;6I=8=B?9`<0$KJQ49$9$k�(B.
2773: @item
2774: @var{vlist} �$B$K4^$^$l$J$$ITDj85$O�(B, �$B78?tBN$KB0$9$k$H$7$FJQ49$5$l$k�(B.
1.2 noro 2775: \E
2776: \BEG
2777: @item
2778: According to the variable ordering @var{vlist} and current
2779: type of term ordering, this function converts an ordinary
2780: polynomial into a distributed polynomial.
2781: @item
2782: Indeterminates not included in @var{vlist} are regarded to belong to
2783: the coefficient field.
2784: \E
1.1 noro 2785: @end itemize
2786:
2787: @example
2788: [50] dp_ord(0);
2789: 1
2790: [51] dp_ptod((x+y+z)^2,[x,y,z]);
2791: (1)*<<2,0,0>>+(2)*<<1,1,0>>+(1)*<<0,2,0>>+(2)*<<1,0,1>>+(2)*<<0,1,1>>
2792: +(1)*<<0,0,2>>
2793: [52] dp_ptod((x+y+z)^2,[x,y]);
1.5 noro 2794: (1)*<<2,0>>+(2)*<<1,1>>+(1)*<<0,2>>+(2*z)*<<1,0>>+(2*z)*<<0,1>>
2795: +(z^2)*<<0,0>>
1.1 noro 2796: @end example
2797:
2798: @table @t
1.2 noro 2799: \JP @item �$B;2>H�(B
2800: \EG @item References
1.1 noro 2801: @fref{dp_dtop},
2802: @fref{dp_ord}.
2803: @end table
2804:
1.2 noro 2805: \JP @node dp_dtop,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
2806: \EG @node dp_dtop,,, Functions for Groebner basis computation
1.1 noro 2807: @subsection @code{dp_dtop}
2808: @findex dp_dtop
2809:
2810: @table @t
2811: @item dp_dtop(@var{dpoly},@var{vlist})
1.2 noro 2812: \JP :: �$BJ,;6I=8=B?9`<0$rB?9`<0$KJQ49$9$k�(B.
2813: \EG :: Converts a distributed polynomial into an ordinary polynomial.
1.1 noro 2814: @end table
2815:
2816: @table @var
2817: @item return
1.2 noro 2818: \JP �$BB?9`<0�(B
2819: \EG polynomial
1.1 noro 2820: @item dpoly
1.2 noro 2821: \JP �$BJ,;6I=8=B?9`<0�(B
2822: \EG distributed polynomial
1.1 noro 2823: @item vlist
1.2 noro 2824: \JP �$B%j%9%H�(B
2825: \EG list
1.1 noro 2826: @end table
2827:
2828: @itemize @bullet
1.2 noro 2829: \BJP
1.1 noro 2830: @item
2831: �$BJ,;6I=8=B?9`<0$r�(B, �$BM?$($i$l$?ITDj85%j%9%H$rMQ$$$FB?9`<0$KJQ49$9$k�(B.
2832: @item
2833: �$BITDj85%j%9%H$O�(B, �$BD9$5J,;6I=8=B?9`<0$NJQ?t$N8D?t$H0lCW$7$F$$$l$P2?$G$b$h$$�(B.
1.2 noro 2834: \E
2835: \BEG
2836: @item
2837: This function converts a distributed polynomial into an ordinary polynomial
2838: according to a list of indeterminates @var{vlist}.
2839: @item
2840: @var{vlist} is such a list that its length coincides with the number of
2841: variables of @var{dpoly}.
2842: \E
1.1 noro 2843: @end itemize
2844:
2845: @example
2846: [53] T=dp_ptod((x+y+z)^2,[x,y]);
1.5 noro 2847: (1)*<<2,0>>+(2)*<<1,1>>+(1)*<<0,2>>+(2*z)*<<1,0>>+(2*z)*<<0,1>>
2848: +(z^2)*<<0,0>>
1.1 noro 2849: [54] P=dp_dtop(T,[a,b]);
2850: z^2+(2*a+2*b)*z+a^2+2*b*a+b^2
2851: @end example
2852:
1.2 noro 2853: \JP @node dp_mod dp_rat,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
2854: \EG @node dp_mod dp_rat,,, Functions for Groebner basis computation
1.1 noro 2855: @subsection @code{dp_mod}, @code{dp_rat}
2856: @findex dp_mod
2857: @findex dp_rat
2858:
2859: @table @t
2860: @item dp_mod(@var{p},@var{mod},@var{subst})
1.2 noro 2861: \JP :: �$BM-M}?t78?tJ,;6I=8=B?9`<0$NM-8BBN78?t$X$NJQ49�(B
2862: \EG :: Converts a disributed polynomial into one with coefficients in a finite field.
1.1 noro 2863: @item dp_rat(@var{p})
1.2 noro 2864: \JP :: �$BM-8BBN78?tJ,;6I=8=B?9`<0$NM-M}?t78?t$X$NJQ49�(B
2865: \BEG
2866: :: Converts a distributed polynomial with coefficients in a finite field into
2867: one with coefficients in the rationals.
2868: \E
1.1 noro 2869: @end table
2870:
2871: @table @var
2872: @item return
1.2 noro 2873: \JP �$BJ,;6I=8=B?9`<0�(B
2874: \EG distributed polynomial
1.1 noro 2875: @item p
1.2 noro 2876: \JP �$BJ,;6I=8=B?9`<0�(B
2877: \EG distributed polynomial
1.1 noro 2878: @item mod
1.2 noro 2879: \JP �$BAG?t�(B
2880: \EG prime
1.1 noro 2881: @item subst
1.2 noro 2882: \JP �$B%j%9%H�(B
2883: \EG list
1.1 noro 2884: @end table
2885:
2886: @itemize @bullet
1.2 noro 2887: \BJP
1.1 noro 2888: @item
2889: @code{dp_nf_mod()}, @code{dp_true_nf_mod()} �$B$O�(B, �$BF~NO$H$7$FM-8BBN78?t$N�(B
2890: �$BJ,;6I=8=B?9`<0$rI,MW$H$9$k�(B. �$B$3$N$h$&$J>l9g�(B, @code{dp_mod()} �$B$K$h$j�(B
2891: �$BM-M}?t78?tJ,;6I=8=B?9`<0$rJQ49$7$FMQ$$$k$3$H$,$G$-$k�(B. �$B$^$?�(B, �$BF@$i$l$?�(B
2892: �$B7k2L$O�(B, �$BM-8BBN78?tB?9`<0$H$O1i;;$G$-$k$,�(B, �$BM-M}?t78?tB?9`<0$H$O1i;;$G$-$J$$�(B
2893: �$B$?$a�(B, @code{dp_rat()} �$B$K$h$jJQ49$9$kI,MW$,$"$k�(B.
2894: @item
2895: �$BM-8BBN78?t$N1i;;$K$*$$$F$O�(B, �$B$"$i$+$8$a�(B @code{setmod()} �$B$K$h$jM-8BBN$N85$N�(B
2896: �$B8D?t$r;XDj$7$F$*$/I,MW$,$"$k�(B.
2897: @item
2898: @var{subst} �$B$O�(B, �$B78?t$,M-M}<0$N>l9g�(B, �$B$=$NM-M}<0$NJQ?t$K$"$i$+$8$a?t$rBeF~�(B
2899: �$B$7$?8eM-8BBN78?t$KJQ49$9$k$H$$$&A`:n$r9T$&:]$N�(B, �$BBeF~CM$r;XDj$9$k$b$N$G�(B,
2900: @code{[[@var{var},@var{value}],...]} �$B$N7A$N%j%9%H$G$"$k�(B.
1.2 noro 2901: \E
2902: \BEG
2903: @item
2904: @code{dp_nf_mod()} and @code{dp_true_nf_mod()} require
2905: distributed polynomials with coefficients in a finite field as arguments.
2906: @code{dp_mod()} is used to convert distributed polynomials with rational
2907: number coefficients into appropriate ones.
2908: Polynomials with coefficients in a finite field
2909: cannot be used as inputs of operations with polynomials
2910: with rational number coefficients. @code{dp_rat()} is used for such cases.
2911: @item
2912: The ground finite field must be set in advance by using @code{setmod()}.
2913: @item
2914: @var{subst} is such a list as @code{[[@var{var},@var{value}],...]}.
2915: This is valid when the ground field of the input polynomial is a
2916: rational function field. @var{var}'s are variables in the ground field and
2917: the list means that @var{value} is substituted for @var{var} before
2918: converting the coefficients into elements of a finite field.
2919: \E
1.1 noro 2920: @end itemize
2921:
2922: @example
2923: @end example
2924:
2925: @table @t
1.2 noro 2926: \JP @item �$B;2>H�(B
2927: \EG @item References
1.18 noro 2928: @fref{dp_nf dp_nf_mod dp_true_nf dp_true_nf_mod dp_weyl_nf dp_weyl_nf_mod},
1.1 noro 2929: @fref{subst psubst},
2930: @fref{setmod}.
2931: @end table
2932:
1.2 noro 2933: \JP @node dp_homo dp_dehomo,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
2934: \EG @node dp_homo dp_dehomo,,, Functions for Groebner basis computation
1.1 noro 2935: @subsection @code{dp_homo}, @code{dp_dehomo}
2936: @findex dp_homo
2937: @findex dp_dehomo
2938:
2939: @table @t
2940: @item dp_homo(@var{dpoly})
1.2 noro 2941: \JP :: �$BJ,;6I=8=B?9`<0$N@F<!2=�(B
2942: \EG :: Homogenize a distributed polynomial
1.1 noro 2943: @item dp_dehomo(@var{dpoly})
1.2 noro 2944: \JP :: �$B@F<!J,;6I=8=B?9`<0$NHs@F<!2=�(B
2945: \EG :: Dehomogenize a homogenious distributed polynomial
1.1 noro 2946: @end table
2947:
2948: @table @var
2949: @item return
1.2 noro 2950: \JP �$BJ,;6I=8=B?9`<0�(B
2951: \EG distributed polynomial
1.1 noro 2952: @item dpoly
1.2 noro 2953: \JP �$BJ,;6I=8=B?9`<0�(B
2954: \EG distributed polynomial
1.1 noro 2955: @end table
2956:
2957: @itemize @bullet
1.2 noro 2958: \BJP
1.1 noro 2959: @item
2960: @code{dp_homo()} �$B$O�(B, @var{dpoly} �$B$N�(B �$B3F9`�(B @var{t} �$B$K$D$$$F�(B, �$B;X?t%Y%/%H%k$ND9$5$r�(B
2961: 1 �$B?-$P$7�(B, �$B:G8e$N@.J,$NCM$r�(B @var{d}-@code{deg(@var{t})}
2962: (@var{d} �$B$O�(B @var{dpoly} �$B$NA4<!?t�(B) �$B$H$7$?J,;6I=8=B?9`<0$rJV$9�(B.
2963: @item
2964: @code{dp_dehomo()} �$B$O�(B, @var{dpoly} �$B$N3F9`$K$D$$$F�(B, �$B;X?t%Y%/%H%k$N:G8e$N@.J,�(B
2965: �$B$r<h$j=|$$$?J,;6B?9`<0$rJV$9�(B.
2966: @item
2967: �$B$$$:$l$b�(B, �$B@8@.$5$l$?B?9`<0$rMQ$$$?1i;;$r9T$&>l9g�(B, �$B$=$l$i$KE,9g$9$k9`=g=x$r�(B
2968: �$B@5$7$/@_Dj$9$kI,MW$,$"$k�(B.
2969: @item
2970: @code{hgr()} �$B$J$I$K$*$$$F�(B, �$BFbItE*$KMQ$$$i$l$F$$$k�(B.
1.2 noro 2971: \E
2972: \BEG
2973: @item
2974: @code{dp_homo()} makes a copy of @var{dpoly}, extends
2975: the length of the exponent vector of each term @var{t} in the copy by 1,
2976: and sets the value of the newly appended
2977: component to @var{d}-@code{deg(@var{t})}, where @var{d} is the total
2978: degree of @var{dpoly}.
2979: @item
2980: @code{dp_dehomo()} make a copy of @var{dpoly} and removes the last component
2981: of each terms in the copy.
2982: @item
2983: Appropriate term orderings must be set when the results are used as inputs
2984: of some operations.
2985: @item
2986: These are used internally in @code{hgr()} etc.
2987: \E
1.1 noro 2988: @end itemize
2989:
2990: @example
2991: [202] X=<<1,2,3>>+3*<<1,2,1>>;
2992: (1)*<<1,2,3>>+(3)*<<1,2,1>>
2993: [203] dp_homo(X);
2994: (1)*<<1,2,3,0>>+(3)*<<1,2,1,2>>
2995: [204] dp_dehomo(@@);
2996: (1)*<<1,2,3>>+(3)*<<1,2,1>>
2997: @end example
2998:
2999: @table @t
1.2 noro 3000: \JP @item �$B;2>H�(B
3001: \EG @item References
1.1 noro 3002: @fref{gr hgr gr_mod}.
3003: @end table
3004:
1.2 noro 3005: \JP @node dp_ptozp dp_prim,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
3006: \EG @node dp_ptozp dp_prim,,, Functions for Groebner basis computation
1.1 noro 3007: @subsection @code{dp_ptozp}, @code{dp_prim}
3008: @findex dp_ptozp
3009: @findex dp_prim
3010:
3011: @table @t
3012: @item dp_ptozp(@var{dpoly})
1.2 noro 3013: \JP :: �$BDj?tG\$7$F78?t$r@0?t78?t$+$D78?t$N@0?t�(B GCD �$B$r�(B 1 �$B$K$9$k�(B.
3014: \BEG
3015: :: Converts a distributed polynomial @var{poly} with rational coefficients
3016: into an integral distributed polynomial such that GCD of all its coefficients
3017: is 1.
3018: \E
1.19 noro 3019: @item dp_prim(@var{dpoly})
1.2 noro 3020: \JP :: �$BM-M}<0G\$7$F78?t$r@0?t78?tB?9`<078?t$+$D78?t$NB?9`<0�(B GCD �$B$r�(B 1 �$B$K$9$k�(B.
3021: \BEG
3022: :: Converts a distributed polynomial @var{poly} with rational function
3023: coefficients into an integral distributed polynomial such that polynomial
3024: GCD of all its coefficients is 1.
3025: \E
1.1 noro 3026: @end table
3027:
3028: @table @var
3029: @item return
1.2 noro 3030: \JP �$BJ,;6I=8=B?9`<0�(B
3031: \EG distributed polynomial
1.1 noro 3032: @item dpoly
1.2 noro 3033: \JP �$BJ,;6I=8=B?9`<0�(B
3034: \EG distributed polynomial
1.1 noro 3035: @end table
3036:
3037: @itemize @bullet
1.2 noro 3038: \BJP
1.1 noro 3039: @item
3040: @code{dp_ptozp()} �$B$O�(B, @code{ptozp()} �$B$KAjEv$9$kA`:n$rJ,;6I=8=B?9`<0$K�(B
3041: �$BBP$7$F9T$&�(B. �$B78?t$,B?9`<0$r4^$`>l9g�(B, �$B78?t$K4^$^$l$kB?9`<06&DL0x;R$O�(B
3042: �$B<h$j=|$+$J$$�(B.
3043: @item
3044: @code{dp_prim()} �$B$O�(B, �$B78?t$,B?9`<0$r4^$`>l9g�(B, �$B78?t$K4^$^$l$kB?9`<06&DL0x;R�(B
3045: �$B$r<h$j=|$/�(B.
1.2 noro 3046: \E
3047: \BEG
3048: @item
3049: @code{dp_ptozp()} executes the same operation as @code{ptozp()} for
3050: a distributed polynomial. If the coefficients include polynomials,
3051: polynomial contents included in the coefficients are not removed.
3052: @item
3053: @code{dp_prim()} removes polynomial contents.
3054: \E
1.1 noro 3055: @end itemize
3056:
3057: @example
3058: [208] X=dp_ptod(3*(x-y)*(y-z)*(z-x),[x]);
3059: (-3*y+3*z)*<<2>>+(3*y^2-3*z^2)*<<1>>+(-3*z*y^2+3*z^2*y)*<<0>>
3060: [209] dp_ptozp(X);
3061: (-y+z)*<<2>>+(y^2-z^2)*<<1>>+(-z*y^2+z^2*y)*<<0>>
3062: [210] dp_prim(X);
3063: (1)*<<2>>+(-y-z)*<<1>>+(z*y)*<<0>>
3064: @end example
3065:
3066: @table @t
1.2 noro 3067: \JP @item �$B;2>H�(B
3068: \EG @item References
1.1 noro 3069: @fref{ptozp}.
3070: @end table
3071:
1.18 noro 3072: \JP @node dp_nf dp_nf_mod dp_true_nf dp_true_nf_mod dp_weyl_nf dp_weyl_nf_mod,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
3073: \EG @node dp_nf dp_nf_mod dp_true_nf dp_true_nf_mod dp_weyl_nf dp_weyl_nf_mod,,, Functions for Groebner basis computation
1.1 noro 3074: @subsection @code{dp_nf}, @code{dp_nf_mod}, @code{dp_true_nf}, @code{dp_true_nf_mod}
3075: @findex dp_nf
3076: @findex dp_true_nf
3077: @findex dp_nf_mod
3078: @findex dp_true_nf_mod
1.18 noro 3079: @findex dp_weyl_nf
3080: @findex dp_weyl_nf_mod
1.1 noro 3081:
3082: @table @t
3083: @item dp_nf(@var{indexlist},@var{dpoly},@var{dpolyarray},@var{fullreduce})
1.18 noro 3084: @item dp_weyl_nf(@var{indexlist},@var{dpoly},@var{dpolyarray},@var{fullreduce})
1.1 noro 3085: @item dp_nf_mod(@var{indexlist},@var{dpoly},@var{dpolyarray},@var{fullreduce},@var{mod})
1.18 noro 3086: @item dp_weyl_nf_mod(@var{indexlist},@var{dpoly},@var{dpolyarray},@var{fullreduce},@var{mod})
1.2 noro 3087: \JP :: �$BJ,;6I=8=B?9`<0$N@55,7A$r5a$a$k�(B. (�$B7k2L$ODj?tG\$5$l$F$$$k2DG=@-$"$j�(B)
1.1 noro 3088:
1.2 noro 3089: \BEG
3090: :: Computes the normal form of a distributed polynomial.
3091: (The result may be multiplied by a constant in the ground field.)
3092: \E
1.1 noro 3093: @item dp_true_nf(@var{indexlist},@var{dpoly},@var{dpolyarray},@var{fullreduce})
3094: @item dp_true_nf_mod(@var{indexlist},@var{dpoly},@var{dpolyarray},@var{fullreduce},@var{mod})
1.2 noro 3095: \JP :: �$BJ,;6I=8=B?9`<0$N@55,7A$r5a$a$k�(B. (�$B??$N7k2L$r�(B @code{[�$BJ,;R�(B, �$BJ,Jl�(B]} �$B$N7A$GJV$9�(B)
3096: \BEG
3097: :: Computes the normal form of a distributed polynomial. (The true result
3098: is returned in such a list as @code{[numerator, denominator]})
3099: \E
1.1 noro 3100: @end table
3101:
3102: @table @var
3103: @item return
1.2 noro 3104: \JP @code{dp_nf()} : �$BJ,;6I=8=B?9`<0�(B, @code{dp_true_nf()} : �$B%j%9%H�(B
3105: \EG @code{dp_nf()} : distributed polynomial, @code{dp_true_nf()} : list
1.1 noro 3106: @item indexlist
1.2 noro 3107: \JP �$B%j%9%H�(B
3108: \EG list
1.1 noro 3109: @item dpoly
1.2 noro 3110: \JP �$BJ,;6I=8=B?9`<0�(B
3111: \EG distributed polynomial
1.1 noro 3112: @item dpolyarray
1.2 noro 3113: \JP �$BG[Ns�(B
3114: \EG array of distributed polynomial
1.1 noro 3115: @item fullreduce
1.2 noro 3116: \JP �$B%U%i%0�(B
3117: \EG flag
1.1 noro 3118: @item mod
1.2 noro 3119: \JP �$BAG?t�(B
3120: \EG prime
1.1 noro 3121: @end table
3122:
3123: @itemize @bullet
1.2 noro 3124: \BJP
1.1 noro 3125: @item
3126: �$BJ,;6I=8=B?9`<0�(B @var{dpoly} �$B$N@55,7A$r5a$a$k�(B.
3127: @item
1.18 noro 3128: �$BL>A0$K�(B weyl �$B$r4^$`4X?t$O%o%$%kBe?t$K$*$1$k@55,7A7W;;$r9T$&�(B. �$B0J2<$N@bL@$O�(B weyl �$B$r4^$`$b$N$KBP$7$F$bF1MM$K@.N)$9$k�(B.
3129: @item
1.1 noro 3130: @code{dp_nf_mod()}, @code{dp_true_nf_mod()} �$B$NF~NO$O�(B, @code{dp_mod()} �$B$J$I�(B
3131: �$B$K$h$j�(B, �$BM-8BBN>e$NJ,;6I=8=B?9`<0$K$J$C$F$$$J$1$l$P$J$i$J$$�(B.
3132: @item
3133: �$B7k2L$KM-M}?t�(B, �$BM-M}<0$,4^$^$l$k$N$rHr$1$k$?$a�(B, @code{dp_nf()} �$B$O�(B
3134: �$B??$NCM$NDj?tG\$NCM$rJV$9�(B. �$BM-M}<078?t$N>l9g$N�(B @code{dp_nf_mod()} �$B$bF1MM�(B
3135: �$B$G$"$k$,�(B, �$B78?tBN$,M-8BBN$N>l9g�(B @code{dp_nf_mod()} �$B$O??$NCM$rJV$9�(B.
3136: @item
3137: @code{dp_true_nf()}, @code{dp_true_nf_mod()} �$B$O�(B,
3138: @code{[@var{nm},@var{dn}]} �$B$J$k7A$N%j%9%H$rJV$9�(B.
3139: �$B$?$@$7�(B, @var{nm} �$B$O78?t$KJ,?t�(B, �$BM-M}<0$r4^$^$J$$J,;6I=8=B?9`<0�(B, @var{dn} �$B$O�(B
3140: �$B?t$^$?$OB?9`<0$G�(B @var{nm}/@var{dn} �$B$,??$NCM$H$J$k�(B.
3141: @item
3142: @var{dpolyarray} �$B$OJ,;6I=8=B?9`<0$rMWAG$H$9$k%Y%/%H%k�(B,
3143: @var{indexlist} �$B$O@55,2=7W;;$KMQ$$$k�(B @var{dpolyarray} �$B$NMWAG$N%$%s%G%C%/%9�(B
3144: �$B$N%j%9%H�(B.
3145: @item
3146: @var{fullreduce} �$B$,�(B 0 �$B$G$J$$$H$-A4$F$N9`$KBP$7$F4JLs$r9T$&�(B. @var{fullreduce}
3147: �$B$,�(B 0 �$B$N$H$-F,9`$N$_$KBP$7$F4JLs$r9T$&�(B.
3148: @item
3149: @var{indexlist} �$B$G;XDj$5$l$?B?9`<0$O�(B, �$BA0$NJ}$N$b$N$,M%@hE*$K;H$o$l$k�(B.
3150: @item
3151: �$B0lHL$K$O�(B @var{indexlist} �$B$NM?$(J}$K$h$jH!?t$NCM$O0[$J$k2DG=@-$,$"$k$,�(B,
3152: �$B%0%l%V%J4pDl$KBP$7$F$O0l0UE*$KDj$^$k�(B.
3153: @item
3154: �$BJ,;6I=8=$G$J$$8GDj$5$l$?B?9`<0=89g$K$h$k@55,7A$rB??t5a$a$kI,MW$,$"$k>l9g�(B
3155: �$B$KJXMx$G$"$k�(B. �$BC10l$N1i;;$K4X$7$F$O�(B, @code{p_nf}, @code{p_true_nf} �$B$r�(B
3156: �$BMQ$$$k$H$h$$�(B.
1.2 noro 3157: \E
3158: \BEG
3159: @item
3160: Computes the normal form of a distributed polynomial.
3161: @item
1.18 noro 3162: Functions whose name contain @code{weyl} compute normal forms in Weyl algebra. The description below also applies to
3163: the functions for Weyl algebra.
3164: @item
1.2 noro 3165: @code{dp_nf_mod()} and @code{dp_true_nf_mod()} require
3166: distributed polynomials with coefficients in a finite field as arguments.
3167: @item
3168: The result of @code{dp_nf()} may be multiplied by a constant in the
3169: ground field in order to make the result integral. The same is true
3170: for @code{dp_nf_mod()}, but it returns the true normal form if
3171: the ground field is a finite field.
3172: @item
3173: @code{dp_true_nf()} and @code{dp_true_nf_mod()} return
3174: such a list as @code{[@var{nm},@var{dn}]}.
3175: Here @var{nm} is a distributed polynomial whose coefficients are integral
3176: in the ground field, @var{dn} is an integral element in the ground
3177: field and @var{nm}/@var{dn} is the true normal form.
3178: @item
3179: @var{dpolyarray} is a vector whose components are distributed polynomials
3180: and @var{indexlist} is a list of indices which is used for the normal form
3181: computation.
3182: @item
3183: When argument @var{fullreduce} has non-zero value,
3184: all terms are reduced. When it has value 0,
3185: only the head term is reduced.
3186: @item
3187: As for the polynomials specified by @var{indexlist}, one specified by
3188: an index placed at the preceding position has priority to be selected.
3189: @item
3190: In general, the result of the function may be different depending on
3191: @var{indexlist}. However, the result is unique for Groebner bases.
3192: @item
3193: These functions are useful when a fixed non-distributed polynomial set
3194: is used as a set of reducers to compute normal forms of many polynomials.
3195: For single computation @code{p_nf} and @code{p_true_nf} are sufficient.
3196: \E
1.1 noro 3197: @end itemize
3198:
3199: @example
3200: [0] load("gr")$
3201: [64] load("katsura")$
3202: [69] K=katsura(4)$
3203: [70] dp_ord(2)$
3204: [71] V=[u0,u1,u2,u3,u4]$
3205: [72] DP1=newvect(length(K),map(dp_ptod,K,V))$
3206: [73] G=gr(K,V,2)$
3207: [74] DP2=newvect(length(G),map(dp_ptod,G,V))$
3208: [75] T=dp_ptod((u0-u1+u2-u3+u4)^2,V)$
3209: [76] dp_dtop(dp_nf([0,1,2,3,4],T,DP1,1),V);
1.5 noro 3210: u4^2+(6*u3+2*u2+6*u1-2)*u4+9*u3^2+(6*u2+18*u1-6)*u3+u2^2
3211: +(6*u1-2)*u2+9*u1^2-6*u1+1
1.1 noro 3212: [77] dp_dtop(dp_nf([4,3,2,1,0],T,DP1,1),V);
3213: -5*u4^2+(-4*u3-4*u2-4*u1)*u4-u3^2-3*u3-u2^2+(2*u1-1)*u2-2*u1^2-3*u1+1
3214: [78] dp_dtop(dp_nf([0,1,2,3,4],T,DP2,1),V);
1.5 noro 3215: -11380879768451657780886122972730785203470970010204714556333530492210
3216: 456775930005716505560062087150928400876150217079820311439477560587583
3217: 488*u4^15+...
1.1 noro 3218: [79] dp_dtop(dp_nf([4,3,2,1,0],T,DP2,1),V);
1.5 noro 3219: -11380879768451657780886122972730785203470970010204714556333530492210
3220: 456775930005716505560062087150928400876150217079820311439477560587583
3221: 488*u4^15+...
1.1 noro 3222: [80] @@78==@@79;
3223: 1
3224: @end example
3225:
3226: @table @t
1.2 noro 3227: \JP @item �$B;2>H�(B
3228: \EG @item References
1.1 noro 3229: @fref{dp_dtop},
3230: @fref{dp_ord},
3231: @fref{dp_mod dp_rat},
3232: @fref{p_nf p_nf_mod p_true_nf p_true_nf_mod}.
3233: @end table
3234:
1.2 noro 3235: \JP @node dp_hm dp_ht dp_hc dp_rest,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
3236: \EG @node dp_hm dp_ht dp_hc dp_rest,,, Functions for Groebner basis computation
1.1 noro 3237: @subsection @code{dp_hm}, @code{dp_ht}, @code{dp_hc}, @code{dp_rest}
3238: @findex dp_hm
3239: @findex dp_ht
3240: @findex dp_hc
3241: @findex dp_rest
3242:
3243: @table @t
3244: @item dp_hm(@var{dpoly})
1.2 noro 3245: \JP :: �$BF,C19`<0$r<h$j=P$9�(B.
3246: \EG :: Gets the head monomial.
1.1 noro 3247: @item dp_ht(@var{dpoly})
1.2 noro 3248: \JP :: �$BF,9`$r<h$j=P$9�(B.
3249: \EG :: Gets the head term.
1.1 noro 3250: @item dp_hc(@var{dpoly})
1.2 noro 3251: \JP :: �$BF,78?t$r<h$j=P$9�(B.
3252: \EG :: Gets the head coefficient.
1.1 noro 3253: @item dp_rest(@var{dpoly})
1.2 noro 3254: \JP :: �$BF,C19`<0$r<h$j=|$$$?;D$j$rJV$9�(B.
3255: \EG :: Gets the remainder of the polynomial where the head monomial is removed.
1.1 noro 3256: @end table
3257:
3258: @table @var
1.2 noro 3259: \BJP
1.1 noro 3260: @item return
3261: @code{dp_hm()}, @code{dp_ht()}, @code{dp_rest()} : �$BJ,;6I=8=B?9`<0�(B,
3262: @code{dp_hc()} : �$B?t$^$?$OB?9`<0�(B
3263: @item dpoly
3264: �$BJ,;6I=8=B?9`<0�(B
1.2 noro 3265: \E
3266: \BEG
3267: @item return
3268: @code{dp_hm()}, @code{dp_ht()}, @code{dp_rest()} : distributed polynomial
3269: @code{dp_hc()} : number or polynomial
3270: @item dpoly
3271: distributed polynomial
3272: \E
1.1 noro 3273: @end table
3274:
3275: @itemize @bullet
1.2 noro 3276: \BJP
1.1 noro 3277: @item
3278: �$B$3$l$i$O�(B, �$BJ,;6I=8=B?9`<0$N3FItJ,$r<h$j=P$9$?$a$NH!?t$G$"$k�(B.
3279: @item
3280: �$BJ,;6I=8=B?9`<0�(B @var{p} �$B$KBP$7<!$,@.$jN)$D�(B.
1.2 noro 3281: \E
3282: \BEG
3283: @item
3284: These are used to get various parts of a distributed polynomial.
3285: @item
3286: The next equations hold for a distributed polynomial @var{p}.
3287: \E
1.1 noro 3288: @table @code
3289: @item @var{p} = dp_hm(@var{p}) + dp_rest(@var{p})
3290: @item dp_hm(@var{p}) = dp_hc(@var{p}) dp_ht(@var{p})
3291: @end table
3292: @end itemize
3293:
3294: @example
3295: [87] dp_ord(0)$
3296: [88] X=ptozp((a46^2+7/10*a46+7/48)*u3^4-50/27*a46^2-35/27*a46-49/216)$
3297: [89] T=dp_ptod(X,[u3,u4,a46])$
3298: [90] dp_hm(T);
3299: (2160)*<<4,0,2>>
3300: [91] dp_ht(T);
3301: (1)*<<4,0,2>>
3302: [92] dp_hc(T);
3303: 2160
3304: [93] dp_rest(T);
3305: (1512)*<<4,0,1>>+(315)*<<4,0,0>>+(-4000)*<<0,0,2>>+(-2800)*<<0,0,1>>
3306: +(-490)*<<0,0,0>>
3307: @end example
3308:
1.2 noro 3309: \JP @node dp_td dp_sugar,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
3310: \EG @node dp_td dp_sugar,,, Functions for Groebner basis computation
1.1 noro 3311: @subsection @code{dp_td}, @code{dp_sugar}
3312: @findex dp_td
3313: @findex dp_sugar
3314:
3315: @table @t
3316: @item dp_td(@var{dpoly})
1.2 noro 3317: \JP :: �$BF,9`$NA4<!?t$rJV$9�(B.
3318: \EG :: Gets the total degree of the head term.
1.1 noro 3319: @item dp_sugar(@var{dpoly})
1.2 noro 3320: \JP :: �$BB?9`<0$N�(B @code{sugar} �$B$rJV$9�(B.
3321: \EG :: Gets the @code{sugar} of a polynomial.
1.1 noro 3322: @end table
3323:
3324: @table @var
3325: @item return
1.2 noro 3326: \JP �$B<+A3?t�(B
3327: \EG non-negative integer
1.1 noro 3328: @item dpoly
1.2 noro 3329: \JP �$BJ,;6I=8=B?9`<0�(B
3330: \EG distributed polynomial
1.1 noro 3331: @item onoff
1.2 noro 3332: \JP �$B%U%i%0�(B
3333: \EG flag
1.1 noro 3334: @end table
3335:
3336: @itemize @bullet
1.2 noro 3337: \BJP
1.1 noro 3338: @item
3339: @code{dp_td()} �$B$O�(B, �$BF,9`$NA4<!?t�(B, �$B$9$J$o$A3FJQ?t$N;X?t$NOB$rJV$9�(B.
3340: @item
3341: �$BJ,;6I=8=B?9`<0$,@8@.$5$l$k$H�(B, @code{sugar} �$B$H8F$P$l$k$"$k@0?t$,IUM?�(B
3342: �$B$5$l$k�(B. �$B$3$NCM$O�(B �$B2>A[E*$K@F<!2=$7$F7W;;$7$?>l9g$K7k2L$,;}$DA4<!?t$NCM$H$J$k�(B.
3343: @item
3344: @code{sugar} �$B$O�(B, �$B%0%l%V%J4pDl7W;;$K$*$1$k@55,2=BP$NA*Br$N%9%H%i%F%8$r�(B
3345: �$B7hDj$9$k$?$a$N=EMW$J;X?K$H$J$k�(B.
1.2 noro 3346: \E
3347: \BEG
3348: @item
3349: Function @code{dp_td()} returns the total degree of the head term,
3350: i.e., the sum of all exponent of variables in that term.
3351: @item
3352: Upon creation of a distributed polynomial, an integer called @code{sugar}
3353: is associated. This value is
3354: the total degree of the virtually homogenized one of the original
3355: polynomial.
3356: @item
3357: The quantity @code{sugar} is an important guide to determine the
3358: selection strategy of critical pairs in Groebner basis computation.
3359: \E
1.1 noro 3360: @end itemize
3361:
3362: @example
3363: [74] dp_ord(0)$
3364: [75] X=<<1,2>>+<<0,1>>$
3365: [76] Y=<<1,2>>+<<1,0>>$
3366: [77] Z=X-Y;
3367: (-1)*<<1,0>>+(1)*<<0,1>>
3368: [78] dp_sugar(T);
3369: 3
3370: @end example
3371:
1.2 noro 3372: \JP @node dp_lcm,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
3373: \EG @node dp_lcm,,, Functions for Groebner basis computation
1.1 noro 3374: @subsection @code{dp_lcm}
3375: @findex dp_lcm
3376:
3377: @table @t
3378: @item dp_lcm(@var{dpoly1},@var{dpoly2})
1.2 noro 3379: \JP :: �$B:G>.8xG\9`$rJV$9�(B.
3380: \EG :: Returns the least common multiple of the head terms of the given two polynomials.
1.1 noro 3381: @end table
3382:
3383: @table @var
3384: @item return
1.2 noro 3385: \JP �$BJ,;6I=8=B?9`<0�(B
3386: \EG distributed polynomial
1.4 noro 3387: @item dpoly1 dpoly2
1.2 noro 3388: \JP �$BJ,;6I=8=B?9`<0�(B
3389: \EG distributed polynomial
1.1 noro 3390: @end table
3391:
3392: @itemize @bullet
1.2 noro 3393: \BJP
1.1 noro 3394: @item
3395: �$B$=$l$>$l$N0z?t$NF,9`$N:G>.8xG\9`$rJV$9�(B. �$B78?t$O�(B 1 �$B$G$"$k�(B.
1.2 noro 3396: \E
3397: \BEG
3398: @item
3399: Returns the least common multiple of the head terms of the given
3400: two polynomials, where coefficient is always set to 1.
3401: \E
1.1 noro 3402: @end itemize
3403:
3404: @example
3405: [100] dp_lcm(<<1,2,3,4,5>>,<<5,4,3,2,1>>);
3406: (1)*<<5,4,3,4,5>>
3407: @end example
3408:
3409: @table @t
1.2 noro 3410: \JP @item �$B;2>H�(B
3411: \EG @item References
1.1 noro 3412: @fref{p_nf p_nf_mod p_true_nf p_true_nf_mod}.
3413: @end table
3414:
1.2 noro 3415: \JP @node dp_redble,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
3416: \EG @node dp_redble,,, Functions for Groebner basis computation
1.1 noro 3417: @subsection @code{dp_redble}
3418: @findex dp_redble
3419:
3420: @table @t
3421: @item dp_redble(@var{dpoly1},@var{dpoly2})
1.2 noro 3422: \JP :: �$BF,9`$I$&$7$,@0=|2DG=$+$I$&$+D4$Y$k�(B.
3423: \EG :: Checks whether one head term is divisible by the other head term.
1.1 noro 3424: @end table
3425:
3426: @table @var
3427: @item return
1.2 noro 3428: \JP �$B@0?t�(B
3429: \EG integer
1.4 noro 3430: @item dpoly1 dpoly2
1.2 noro 3431: \JP �$BJ,;6I=8=B?9`<0�(B
3432: \EG distributed polynomial
1.1 noro 3433: @end table
3434:
3435: @itemize @bullet
1.2 noro 3436: \BJP
1.1 noro 3437: @item
3438: @var{dpoly1} �$B$NF,9`$,�(B @var{dpoly2} �$B$NF,9`$G3d$j@Z$l$l$P�(B 1, �$B3d$j@Z$l$J$1$l$P�(B
3439: 0 �$B$rJV$9�(B.
3440: @item
3441: �$BB?9`<0$N4JLs$r9T$&:]�(B, �$B$I$N9`$r4JLs$G$-$k$+$rC5$9$N$KMQ$$$k�(B.
1.2 noro 3442: \E
3443: \BEG
3444: @item
3445: Returns 1 if the head term of @var{dpoly2} divides the head term of
3446: @var{dpoly1}; otherwise 0.
3447: @item
3448: Used for finding candidate terms at reduction of polynomials.
3449: \E
1.1 noro 3450: @end itemize
3451:
3452: @example
3453: [148] C;
3454: (1)*<<1,1,1,0,0>>+(1)*<<0,1,1,1,0>>+(1)*<<1,1,0,0,1>>+(1)*<<1,0,0,1,1>>
3455: [149] T;
3456: (3)*<<2,1,0,0,0>>+(3)*<<1,2,0,0,0>>+(1)*<<0,3,0,0,0>>+(6)*<<1,1,1,0,0>>
3457: [150] for ( ; T; T = dp_rest(T)) print(dp_redble(T,C));
3458: 0
3459: 0
3460: 0
3461: 1
3462: @end example
3463:
3464: @table @t
1.2 noro 3465: \JP @item �$B;2>H�(B
3466: \EG @item References
1.1 noro 3467: @fref{dp_red dp_red_mod}.
3468: @end table
3469:
1.2 noro 3470: \JP @node dp_subd,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
3471: \EG @node dp_subd,,, Functions for Groebner basis computation
1.1 noro 3472: @subsection @code{dp_subd}
3473: @findex dp_subd
3474:
3475: @table @t
3476: @item dp_subd(@var{dpoly1},@var{dpoly2})
1.2 noro 3477: \JP :: �$BF,9`$N>&C19`<0$rJV$9�(B.
3478: \EG :: Returns the quotient monomial of the head terms.
1.1 noro 3479: @end table
3480:
3481: @table @var
3482: @item return
1.2 noro 3483: \JP �$BJ,;6I=8=B?9`<0�(B
3484: \EG distributed polynomial
1.4 noro 3485: @item dpoly1 dpoly2
1.2 noro 3486: \JP �$BJ,;6I=8=B?9`<0�(B
3487: \EG distributed polynomial
1.1 noro 3488: @end table
3489:
3490: @itemize @bullet
1.2 noro 3491: \BJP
1.1 noro 3492: @item
3493: @code{dp_ht(@var{dpoly1})/dp_ht(@var{dpoly2})} �$B$r5a$a$k�(B. �$B7k2L$N78?t$O�(B 1
3494: �$B$G$"$k�(B.
3495: @item
3496: �$B3d$j@Z$l$k$3$H$,$"$i$+$8$a$o$+$C$F$$$kI,MW$,$"$k�(B.
1.2 noro 3497: \E
3498: \BEG
3499: @item
3500: Gets @code{dp_ht(@var{dpoly1})/dp_ht(@var{dpoly2})}.
3501: The coefficient of the result is always set to 1.
3502: @item
3503: Divisibility assumed.
3504: \E
1.1 noro 3505: @end itemize
3506:
3507: @example
3508: [162] dp_subd(<<1,2,3,4,5>>,<<1,1,2,3,4>>);
3509: (1)*<<0,1,1,1,1>>
3510: @end example
3511:
3512: @table @t
1.2 noro 3513: \JP @item �$B;2>H�(B
3514: \EG @item References
1.1 noro 3515: @fref{dp_red dp_red_mod}.
3516: @end table
3517:
1.2 noro 3518: \JP @node dp_vtoe dp_etov,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
3519: \EG @node dp_vtoe dp_etov,,, Functions for Groebner basis computation
1.1 noro 3520: @subsection @code{dp_vtoe}, @code{dp_etov}
3521: @findex dp_vtoe
3522: @findex dp_etov
3523:
3524: @table @t
3525: @item dp_vtoe(@var{vect})
1.2 noro 3526: \JP :: �$B;X?t%Y%/%H%k$r9`$KJQ49�(B
3527: \EG :: Converts an exponent vector into a term.
1.1 noro 3528: @item dp_etov(@var{dpoly})
1.2 noro 3529: \JP :: �$BF,9`$r;X?t%Y%/%H%k$KJQ49�(B
3530: \EG :: Convert the head term of a distributed polynomial into an exponent vector.
1.1 noro 3531: @end table
3532:
3533: @table @var
3534: @item return
1.2 noro 3535: \JP @code{dp_vtoe} : �$BJ,;6I=8=B?9`<0�(B, @code{dp_etov} : �$B%Y%/%H%k�(B
3536: \EG @code{dp_vtoe} : distributed polynomial, @code{dp_etov} : vector
1.1 noro 3537: @item vect
1.2 noro 3538: \JP �$B%Y%/%H%k�(B
3539: \EG vector
1.1 noro 3540: @item dpoly
1.2 noro 3541: \JP �$BJ,;6I=8=B?9`<0�(B
3542: \EG distributed polynomial
1.1 noro 3543: @end table
3544:
3545: @itemize @bullet
1.2 noro 3546: \BJP
1.1 noro 3547: @item
3548: @code{dp_vtoe()} �$B$O�(B, �$B%Y%/%H%k�(B @var{vect} �$B$r;X?t%Y%/%H%k$H$9$k9`$r@8@.$9$k�(B.
3549: @item
3550: @code{dp_etov()} �$B$O�(B, �$BJ,;6I=8=B?9`<0�(B @code{dpoly} �$B$NF,9`$N;X?t%Y%/%H%k$r�(B
3551: �$B%Y%/%H%k$KJQ49$9$k�(B.
1.2 noro 3552: \E
3553: \BEG
3554: @item
3555: @code{dp_vtoe()} generates a term whose exponent vector is @var{vect}.
3556: @item
3557: @code{dp_etov()} generates a vector which is the exponent vector of the
3558: head term of @code{dpoly}.
3559: \E
1.1 noro 3560: @end itemize
3561:
3562: @example
3563: [211] X=<<1,2,3>>;
3564: (1)*<<1,2,3>>
3565: [212] V=dp_etov(X);
3566: [ 1 2 3 ]
3567: [213] V[2]++$
3568: [214] Y=dp_vtoe(V);
3569: (1)*<<1,2,4>>
3570: @end example
3571:
1.2 noro 3572: \JP @node dp_mbase,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
3573: \EG @node dp_mbase,,, Functions for Groebner basis computation
1.1 noro 3574: @subsection @code{dp_mbase}
3575: @findex dp_mbase
3576:
3577: @table @t
3578: @item dp_mbase(@var{dplist})
1.2 noro 3579: \JP :: monomial �$B4pDl$N7W;;�(B
3580: \EG :: Computes the monomial basis
1.1 noro 3581: @end table
3582:
3583: @table @var
3584: @item return
1.2 noro 3585: \JP �$BJ,;6I=8=B?9`<0$N%j%9%H�(B
3586: \EG list of distributed polynomial
1.1 noro 3587: @item dplist
1.2 noro 3588: \JP �$BJ,;6I=8=B?9`<0$N%j%9%H�(B
3589: \EG list of distributed polynomial
1.1 noro 3590: @end table
3591:
3592: @itemize @bullet
1.2 noro 3593: \BJP
1.1 noro 3594: @item
3595: �$B$"$k=g=x$G%0%l%V%J4pDl$H$J$C$F$$$kB?9`<0=89g$N�(B, �$B$=$N=g=x$K4X$9$kJ,;6I=8=�(B
3596: �$B$G$"$k�(B @var{dplist} �$B$K$D$$$F�(B,
3597: @var{dplist} �$B$,�(B K[X] �$BCf$G@8@.$9$k%$%G%"%k�(B I �$B$,�(B 0 �$B<!85$N;~�(B,
3598: K �$B>eM-8B<!85@~7A6u4V$G$"$k�(B K[X]/I �$B$N�(B monomial �$B$K$h$k4pDl$r5a$a$k�(B.
3599: @item
3600: �$BF@$i$l$?4pDl$N8D?t$,�(B, K[X]/I �$B$N�(B K-�$B@~7A6u4V$H$7$F$N<!85$KEy$7$$�(B.
1.2 noro 3601: \E
3602: \BEG
3603: @item
3604: Assuming that @var{dplist} is a list of distributed polynomials which
3605: is a Groebner basis with respect to the current ordering type and
3606: that the ideal @var{I} generated by @var{dplist} in K[X] is zero-dimensional,
3607: this function computes the monomial basis of a finite dimenstional K-vector
3608: space K[X]/I.
3609: @item
3610: The number of elements in the monomial basis is equal to the
3611: K-dimenstion of K[X]/I.
3612: \E
1.1 noro 3613: @end itemize
3614:
3615: @example
3616: [215] K=katsura(5)$
3617: [216] V=[u5,u4,u3,u2,u1,u0]$
3618: [217] G0=gr(K,V,0)$
3619: [218] H=map(dp_ptod,G0,V)$
3620: [219] map(dp_ptod,dp_mbase(H),V)$
3621: [u0^5,u4*u0^3,u3*u0^3,u2*u0^3,u1*u0^3,u0^4,u3^2*u0,u2*u3*u0,u1*u3*u0,
3622: u1*u2*u0,u1^2*u0,u4*u0^2,u3*u0^2,u2*u0^2,u1*u0^2,u0^3,u3^2,u2*u3,u1*u3,
3623: u1*u2,u1^2,u4*u0,u3*u0,u2*u0,u1*u0,u0^2,u4,u3,u2,u1,u0,1]
3624: @end example
3625:
3626: @table @t
1.2 noro 3627: \JP @item �$B;2>H�(B
3628: \EG @item References
1.1 noro 3629: @fref{gr hgr gr_mod}.
3630: @end table
3631:
1.2 noro 3632: \JP @node dp_mag,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
3633: \EG @node dp_mag,,, Functions for Groebner basis computation
1.1 noro 3634: @subsection @code{dp_mag}
3635: @findex dp_mag
3636:
3637: @table @t
3638: @item dp_mag(@var{p})
1.2 noro 3639: \JP :: �$B78?t$N%S%C%HD9$NOB$rJV$9�(B
3640: \EG :: Computes the sum of bit lengths of coefficients of a distributed polynomial.
1.1 noro 3641: @end table
3642:
3643: @table @var
3644: @item return
1.2 noro 3645: \JP �$B?t�(B
3646: \EG integer
1.1 noro 3647: @item p
1.2 noro 3648: \JP �$BJ,;6I=8=B?9`<0�(B
3649: \EG distributed polynomial
1.1 noro 3650: @end table
3651:
3652: @itemize @bullet
1.2 noro 3653: \BJP
1.1 noro 3654: @item
3655: �$BJ,;6I=8=B?9`<0$N78?t$K8=$l$kM-M}?t$K$D$-�(B, �$B$=$NJ,JlJ,;R�(B (�$B@0?t$N>l9g$OJ,;R�(B)
3656: �$B$N%S%C%HD9$NAmOB$rJV$9�(B.
3657: @item
3658: �$BBP>]$H$J$kB?9`<0$NBg$-$5$NL\0B$H$7$FM-8z$G$"$k�(B. �$BFC$K�(B, 0 �$B<!85%7%9%F%`$K$*$$$F$O�(B
3659: �$B78?tKDD%$,LdBj$H$J$j�(B, �$BESCf@8@.$5$l$kB?9`<0$,78?tKDD%$r5/$3$7$F$$$k$+$I$&$+�(B
3660: �$B$NH=Dj$KLrN)$D�(B.
3661: @item
3662: @code{dp_gr_flags()} �$B$G�(B, @code{ShowMag}, @code{Print} �$B$r�(B on �$B$K$9$k$3$H$K$h$j�(B
3663: �$BESCf@8@.$5$l$kB?9`<0$K$?$$$9$k�(B @code{dp_mag()} �$B$NCM$r8+$k$3$H$,$G$-$k�(B.
1.2 noro 3664: \E
3665: \BEG
3666: @item
3667: This function computes the sum of bit lengths of coefficients of a
3668: distributed polynomial @var{p}. If a coefficient is non integral,
3669: the sum of bit lengths of the numerator and the denominator is taken.
3670: @item
3671: This is a measure of the size of a polynomial. Especially for
3672: zero-dimensional system coefficient swells are often serious and
3673: the returned value is useful to detect such swells.
3674: @item
3675: If @code{ShowMag} and @code{Print} for @code{dp_gr_flags()} are on,
3676: values of @code{dp_mag()} for intermediate basis elements are shown.
3677: \E
1.1 noro 3678: @end itemize
3679:
3680: @example
3681: [221] X=dp_ptod((x+2*y)^10,[x,y])$
3682: [222] dp_mag(X);
3683: 115
3684: @end example
3685:
3686: @table @t
1.2 noro 3687: \JP @item �$B;2>H�(B
3688: \EG @item References
1.1 noro 3689: @fref{dp_gr_flags dp_gr_print}.
3690: @end table
3691:
1.2 noro 3692: \JP @node dp_red dp_red_mod,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
3693: \EG @node dp_red dp_red_mod,,, Functions for Groebner basis computation
1.1 noro 3694: @subsection @code{dp_red}, @code{dp_red_mod}
3695: @findex dp_red
3696: @findex dp_red_mod
3697:
3698: @table @t
3699: @item dp_red(@var{dpoly1},@var{dpoly2},@var{dpoly3})
3700: @item dp_red_mod(@var{dpoly1},@var{dpoly2},@var{dpoly3},@var{mod})
1.2 noro 3701: \JP :: �$B0l2s$N4JLsA`:n�(B
3702: \EG :: Single reduction operation
1.1 noro 3703: @end table
3704:
3705: @table @var
3706: @item return
1.2 noro 3707: \JP �$B%j%9%H�(B
3708: \EG list
1.4 noro 3709: @item dpoly1 dpoly2 dpoly3
1.2 noro 3710: \JP �$BJ,;6I=8=B?9`<0�(B
3711: \EG distributed polynomial
1.1 noro 3712: @item vlist
1.2 noro 3713: \JP �$B%j%9%H�(B
3714: \EG list
1.1 noro 3715: @item mod
1.2 noro 3716: \JP �$BAG?t�(B
3717: \EG prime
1.1 noro 3718: @end table
3719:
3720: @itemize @bullet
1.2 noro 3721: \BJP
1.1 noro 3722: @item
3723: @var{dpoly1} + @var{dpoly2} �$B$J$kJ,;6I=8=B?9`<0$r�(B @var{dpoly3} �$B$G�(B
3724: 1 �$B2s4JLs$9$k�(B.
3725: @item
3726: @code{dp_red_mod()} �$B$NF~NO$O�(B, �$BA4$FM-8BBN78?t$KJQ49$5$l$F$$$kI,MW$,$"$k�(B.
3727: @item
3728: �$B4JLs$5$l$k9`$O�(B @var{dpoly2} �$B$NF,9`$G$"$k�(B. �$B=>$C$F�(B, @var{dpoly2} �$B$N�(B
3729: �$BF,9`$,�(B @var{dpoly3} �$B$NF,9`$G3d$j@Z$l$k$3$H$,$"$i$+$8$a$o$+$C$F$$$J$1$l$P�(B
3730: �$B$J$i$J$$�(B.
3731: @item
3732: �$B0z?t$,@0?t78?t$N;~�(B, �$B4JLs$O�(B, �$BJ,?t$,8=$l$J$$$h$&�(B, �$B@0?t�(B @var{a}, @var{b},
1.4 noro 3733: �$B9`�(B @var{t} �$B$K$h$j�(B @var{a}(@var{dpoly1} + @var{dpoly2})-@var{bt} @var{dpoly3} �$B$H$7$F7W;;$5$l$k�(B.
1.1 noro 3734: @item
3735: �$B7k2L$O�(B, @code{[@var{a dpoly1},@var{a dpoly2 - bt dpoly3}]} �$B$J$k%j%9%H$G$"$k�(B.
1.2 noro 3736: \E
3737: \BEG
3738: @item
3739: Reduces a distributed polynomial, @var{dpoly1} + @var{dpoly2},
3740: by @var{dpoly3} for single time.
3741: @item
3742: An input for @code{dp_red_mod()} must be converted into a distributed
3743: polynomial with coefficients in a finite field.
3744: @item
3745: This implies that
3746: the divisibility of the head term of @var{dpoly2} by the head term of
3747: @var{dpoly3} is assumed.
3748: @item
3749: When integral coefficients, computation is so carefully performed that
3750: no rational operations appear in the reduction procedure.
3751: It is computed for integers @var{a} and @var{b}, and a term @var{t} as:
1.4 noro 3752: @var{a}(@var{dpoly1} + @var{dpoly2})-@var{bt} @var{dpoly3}.
1.2 noro 3753: @item
3754: The result is a list @code{[@var{a dpoly1},@var{a dpoly2 - bt dpoly3}]}.
3755: \E
1.1 noro 3756: @end itemize
3757:
3758: @example
3759: [157] D=(3)*<<2,1,0,0,0>>+(3)*<<1,2,0,0,0>>+(1)*<<0,3,0,0,0>>;
3760: (3)*<<2,1,0,0,0>>+(3)*<<1,2,0,0,0>>+(1)*<<0,3,0,0,0>>
3761: [158] R=(6)*<<1,1,1,0,0>>;
3762: (6)*<<1,1,1,0,0>>
3763: [159] C=12*<<1,1,1,0,0>>+(1)*<<0,1,1,1,0>>+(1)*<<1,1,0,0,1>>;
3764: (12)*<<1,1,1,0,0>>+(1)*<<0,1,1,1,0>>+(1)*<<1,1,0,0,1>>
3765: [160] dp_red(D,R,C);
1.5 noro 3766: [(6)*<<2,1,0,0,0>>+(6)*<<1,2,0,0,0>>+(2)*<<0,3,0,0,0>>,
3767: (-1)*<<0,1,1,1,0>>+(-1)*<<1,1,0,0,1>>]
1.1 noro 3768: @end example
3769:
3770: @table @t
1.2 noro 3771: \JP @item �$B;2>H�(B
3772: \EG @item References
1.1 noro 3773: @fref{dp_mod dp_rat}.
3774: @end table
3775:
1.2 noro 3776: \JP @node dp_sp dp_sp_mod,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
3777: \EG @node dp_sp dp_sp_mod,,, Functions for Groebner basis computation
1.1 noro 3778: @subsection @code{dp_sp}, @code{dp_sp_mod}
3779: @findex dp_sp
3780: @findex dp_sp_mod
3781:
3782: @table @t
3783: @item dp_sp(@var{dpoly1},@var{dpoly2})
3784: @item dp_sp_mod(@var{dpoly1},@var{dpoly2},@var{mod})
1.2 noro 3785: \JP :: S-�$BB?9`<0$N7W;;�(B
3786: \EG :: Computation of an S-polynomial
1.1 noro 3787: @end table
3788:
3789: @table @var
3790: @item return
1.2 noro 3791: \JP �$BJ,;6I=8=B?9`<0�(B
3792: \EG distributed polynomial
1.4 noro 3793: @item dpoly1 dpoly2
1.2 noro 3794: \JP �$BJ,;6I=8=B?9`<0�(B
3795: \EG distributed polynomial
1.1 noro 3796: @item mod
1.2 noro 3797: \JP �$BAG?t�(B
3798: \EG prime
1.1 noro 3799: @end table
3800:
3801: @itemize @bullet
1.2 noro 3802: \BJP
1.1 noro 3803: @item
3804: @var{dpoly1}, @var{dpoly2} �$B$N�(B S-�$BB?9`<0$r7W;;$9$k�(B.
3805: @item
3806: @code{dp_sp_mod()} �$B$NF~NO$O�(B, �$BA4$FM-8BBN78?t$KJQ49$5$l$F$$$kI,MW$,$"$k�(B.
3807: @item
3808: �$B7k2L$KM-M}?t�(B, �$BM-M}<0$,F~$k$N$rHr$1$k$?$a�(B, �$B7k2L$,Dj?tG\�(B, �$B$"$k$$$OB?9`<0�(B
3809: �$BG\$5$l$F$$$k2DG=@-$,$"$k�(B.
1.2 noro 3810: \E
3811: \BEG
3812: @item
3813: This function computes the S-polynomial of @var{dpoly1} and @var{dpoly2}.
3814: @item
3815: Inputs of @code{dp_sp_mod()} must be polynomials with coefficients in a
3816: finite field.
3817: @item
3818: The result may be multiplied by a constant in the ground field in order to
3819: make the result integral.
3820: \E
1.1 noro 3821: @end itemize
3822:
3823: @example
3824: [227] X=dp_ptod(x^2*y+x*y,[x,y]);
3825: (1)*<<2,1>>+(1)*<<1,1>>
3826: [228] Y=dp_ptod(x*y^2+x*y,[x,y]);
3827: (1)*<<1,2>>+(1)*<<1,1>>
3828: [229] dp_sp(X,Y);
3829: (-1)*<<2,1>>+(1)*<<1,2>>
3830: @end example
3831:
3832: @table @t
1.2 noro 3833: \JP @item �$B;2>H�(B
3834: \EG @item References
1.1 noro 3835: @fref{dp_mod dp_rat}.
3836: @end table
1.2 noro 3837: \JP @node p_nf p_nf_mod p_true_nf p_true_nf_mod,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
3838: \EG @node p_nf p_nf_mod p_true_nf p_true_nf_mod,,, Functions for Groebner basis computation
1.1 noro 3839: @subsection @code{p_nf}, @code{p_nf_mod}, @code{p_true_nf}, @code{p_true_nf_mod}
3840: @findex p_nf
3841: @findex p_nf_mod
3842: @findex p_true_nf
3843: @findex p_true_nf_mod
3844:
3845: @table @t
3846: @item p_nf(@var{poly},@var{plist},@var{vlist},@var{order})
3847: @itemx p_nf_mod(@var{poly},@var{plist},@var{vlist},@var{order},@var{mod})
1.2 noro 3848: \JP :: �$BI=8=B?9`<0$N@55,7A$r5a$a$k�(B. (�$B7k2L$ODj?tG\$5$l$F$$$k2DG=@-$"$j�(B)
3849: \BEG
3850: :: Computes the normal form of the given polynomial.
3851: (The result may be multiplied by a constant.)
3852: \E
1.1 noro 3853: @item p_true_nf(@var{poly},@var{plist},@var{vlist},@var{order})
3854: @itemx p_true_nf_mod(@var{poly},@var{plist},@var{vlist},@var{order},@var{mod})
1.2 noro 3855: \JP :: �$BI=8=B?9`<0$N@55,7A$r5a$a$k�(B. (�$B??$N7k2L$r�(B @code{[�$BJ,;R�(B, �$BJ,Jl�(B]} �$B$N7A$GJV$9�(B)
3856: \BEG
3857: :: Computes the normal form of the given polynomial. (The result is returned
3858: as a form of @code{[numerator, denominator]})
3859: \E
1.1 noro 3860: @end table
3861:
3862: @table @var
3863: @item return
1.2 noro 3864: \JP @code{p_nf} : �$BB?9`<0�(B, @code{p_true_nf} : �$B%j%9%H�(B
3865: \EG @code{p_nf} : polynomial, @code{p_true_nf} : list
1.1 noro 3866: @item poly
1.2 noro 3867: \JP �$BB?9`<0�(B
3868: \EG polynomial
1.4 noro 3869: @item plist vlist
1.2 noro 3870: \JP �$B%j%9%H�(B
3871: \EG list
1.1 noro 3872: @item order
1.2 noro 3873: \JP �$B?t�(B, �$B%j%9%H$^$?$O9TNs�(B
3874: \EG number, list or matrix
1.1 noro 3875: @item mod
1.2 noro 3876: \JP �$BAG?t�(B
3877: \EG prime
1.1 noro 3878: @end table
3879:
3880: @itemize @bullet
1.2 noro 3881: \BJP
1.1 noro 3882: @item
3883: @samp{gr} �$B$GDj5A$5$l$F$$$k�(B.
3884: @item
3885: �$BB?9`<0$N�(B, �$BB?9`<0%j%9%H$K$h$k@55,7A$r5a$a$k�(B.
3886: @item
3887: @code{dp_nf()}, @code{dp_true_nf()}, @code{dp_nf_mod()}, @code{dp_true_nf_mod}
3888: �$B$KBP$9$k%$%s%?%U%'!<%9$G$"$k�(B.
3889: @item
3890: @var{poly} �$B$*$h$S�(B @var{plist} �$B$O�(B, �$BJQ?t=g=x�(B @var{vlist} �$B$*$h$S�(B
3891: �$BJQ?t=g=x7?�(B @var{otype} �$B$K=>$C$FJ,;6I=8=B?9`<0$KJQ49$5$l�(B,
3892: @code{dp_nf()}, @code{dp_true_nf()}, @code{dp_nf_mod()},
3893: @code{dp_true_nf_mod()} �$B$KEO$5$l$k�(B.
3894: @item
3895: @code{dp_nf()}, @code{dp_true_nf()}, @code{dp_nf_mod()},
3896: @code{dp_true_nf_mod()} �$B$O�(B @var{fullreduce} �$B$,�(B 1 �$B$G8F$S=P$5$l$k�(B.
3897: @item
3898: �$B7k2L$OB?9`<0$KJQ49$5$l$F=PNO$5$l$k�(B.
3899: @item
3900: @code{p_true_nf()}, @code{p_true_nf_mod()} �$B$N=PNO$K4X$7$F$O�(B,
3901: @code{dp_true_nf()}, @code{dp_true_nf_mod()} �$B$N9`$r;2>H�(B.
1.2 noro 3902: \E
3903: \BEG
3904: @item
3905: Defined in the package @samp{gr}.
3906: @item
3907: Obtains the normal form of a polynomial by a polynomial list.
3908: @item
3909: These are interfaces to @code{dp_nf()}, @code{dp_true_nf()}, @code{dp_nf_mod()},
3910: @code{dp_true_nf_mod}
3911: @item
3912: The polynomial @var{poly} and the polynomials in @var{plist} is
3913: converted, according to the variable ordering @var{vlist} and
3914: type of term ordering @var{otype}, into their distributed polynomial
3915: counterparts and passed to @code{dp_nf()}.
3916: @item
3917: @code{dp_nf()}, @code{dp_true_nf()}, @code{dp_nf_mod()} and
3918: @code{dp_true_nf_mod()}
3919: is called with value 1 for @var{fullreduce}.
3920: @item
3921: The result is converted back into an ordinary polynomial.
3922: @item
3923: As for @code{p_true_nf()}, @code{p_true_nf_mod()}
3924: refer to @code{dp_true_nf()} and @code{dp_true_nf_mod()}.
3925: \E
1.1 noro 3926: @end itemize
3927:
3928: @example
3929: [79] K = katsura(5)$
3930: [80] V = [u5,u4,u3,u2,u1,u0]$
3931: [81] G = hgr(K,V,2)$
3932: [82] p_nf(K[1],G,V,2);
3933: 0
3934: [83] L = p_true_nf(K[1]+1,G,V,2);
3935: [-1503...,-1503...]
3936: [84] L[0]/L[1];
3937: 1
3938: @end example
3939:
3940: @table @t
1.2 noro 3941: \JP @item �$B;2>H�(B
3942: \EG @item References
1.1 noro 3943: @fref{dp_ptod},
3944: @fref{dp_dtop},
3945: @fref{dp_ord},
1.19 noro 3946: @fref{dp_nf dp_nf_mod dp_true_nf dp_true_nf_mod dp_weyl_nf dp_weyl_nf_mod}.
1.1 noro 3947: @end table
3948:
1.2 noro 3949: \JP @node p_terms,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
3950: \EG @node p_terms,,, Functions for Groebner basis computation
1.1 noro 3951: @subsection @code{p_terms}
3952: @findex p_terms
3953:
3954: @table @t
3955: @item p_terms(@var{poly},@var{vlist},@var{order})
1.2 noro 3956: \JP :: �$BB?9`<0$K$"$i$o$l$kC19`$r%j%9%H$K$9$k�(B.
3957: \EG :: Monomials appearing in the given polynomial is collected into a list.
1.1 noro 3958: @end table
3959:
3960: @table @var
3961: @item return
1.2 noro 3962: \JP �$B%j%9%H�(B
3963: \EG list
1.1 noro 3964: @item poly
1.2 noro 3965: \JP �$BB?9`<0�(B
3966: \EG polynomial
1.1 noro 3967: @item vlist
1.2 noro 3968: \JP �$B%j%9%H�(B
3969: \EG list
1.1 noro 3970: @item order
1.2 noro 3971: \JP �$B?t�(B, �$B%j%9%H$^$?$O9TNs�(B
3972: \EG number, list or matrix
1.1 noro 3973: @end table
3974:
3975: @itemize @bullet
1.2 noro 3976: \BJP
1.1 noro 3977: @item
3978: @samp{gr} �$B$GDj5A$5$l$F$$$k�(B.
3979: @item
3980: �$BB?9`<0$rC19`$KE83+$7$?;~$K8=$l$k9`$r%j%9%H$K$7$FJV$9�(B.
3981: @var{vlist} �$B$*$h$S�(B @var{order} �$B$K$h$jDj$^$k9`=g=x$K$h$j�(B, �$B=g=x$N9b$$$b$N�(B
3982: �$B$,%j%9%H$N@hF,$KMh$k$h$&$K%=!<%H$5$l$k�(B.
3983: @item
3984: �$B%0%l%V%J4pDl$O$7$P$7$P78?t$,5pBg$K$J$k$?$a�(B, �$B<B:]$K$I$N9`$,8=$l$F�(B
3985: �$B$$$k$N$+$r8+$k$?$a$J$I$KMQ$$$k�(B.
1.2 noro 3986: \E
3987: \BEG
3988: @item
3989: Defined in the package @samp{gr}.
3990: @item
3991: This returns a list which contains all non-zero monomials in the given
3992: polynomial. The monomials are ordered according to the current
3993: type of term ordering and @var{vlist}.
3994: @item
3995: Since polynomials in a Groebner base often have very large coefficients,
3996: examining a polynomial as it is may sometimes be difficult to perform.
3997: For such a case, this function enables to examine which term is really
3998: exists.
3999: \E
1.1 noro 4000: @end itemize
4001:
4002: @example
4003: [233] G=gr(katsura(5),[u5,u4,u3,u2,u1,u0],2)$
4004: [234] p_terms(G[0],[u5,u4,u3,u2,u1,u0],2);
1.5 noro 4005: [u5,u0^31,u0^30,u0^29,u0^28,u0^27,u0^26,u0^25,u0^24,u0^23,u0^22,
4006: u0^21,u0^20,u0^19,u0^18,u0^17,u0^16,u0^15,u0^14,u0^13,u0^12,u0^11,
4007: u0^10,u0^9,u0^8,u0^7,u0^6,u0^5,u0^4,u0^3,u0^2,u0,1]
1.1 noro 4008: @end example
4009:
1.2 noro 4010: \JP @node gb_comp,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
4011: \EG @node gb_comp,,, Functions for Groebner basis computation
1.1 noro 4012: @subsection @code{gb_comp}
4013: @findex gb_comp
4014:
4015: @table @t
4016: @item gb_comp(@var{plist1}, @var{plist2})
1.2 noro 4017: \JP :: �$BB?9`<0%j%9%H$,�(B, �$BId9f$r=|$$$F=89g$H$7$FEy$7$$$+$I$&$+D4$Y$k�(B.
4018: \EG :: Checks whether two polynomial lists are equal or not as a set
1.1 noro 4019: @end table
4020:
4021: @table @var
1.2 noro 4022: \JP @item return 0 �$B$^$?$O�(B 1
4023: \EG @item return 0 or 1
1.4 noro 4024: @item plist1 plist2
1.1 noro 4025: @end table
4026:
4027: @itemize @bullet
1.2 noro 4028: \BJP
1.1 noro 4029: @item
4030: @var{plist1}, @var{plist2} �$B$K$D$$$F�(B, �$BId9f$r=|$$$F=89g$H$7$FEy$7$$$+$I$&$+�(B
4031: �$BD4$Y$k�(B.
4032: @item
4033: �$B0[$J$kJ}K!$G5a$a$?%0%l%V%J4pDl$O�(B, �$B4pDl$N=g=x�(B, �$BId9f$,0[$J$k>l9g$,$"$j�(B,
4034: �$B$=$l$i$,Ey$7$$$+$I$&$+$rD4$Y$k$?$a$KMQ$$$k�(B.
1.2 noro 4035: \E
4036: \BEG
4037: @item
4038: This function checks whether @var{plist1} and @var{plist2} are equal or
4039: not as a set .
4040: @item
4041: For the same input and the same term ordering different
4042: functions for Groebner basis computations may produce different outputs
4043: as lists. This function compares such lists whether they are equal
4044: as a generating set of an ideal.
4045: \E
1.1 noro 4046: @end itemize
4047:
4048: @example
4049: [243] C=cyclic(6)$
4050: [244] V=[c0,c1,c2,c3,c4,c5]$
4051: [245] G0=gr(C,V,0)$
4052: [246] G=tolex(G0,V,0,V)$
4053: [247] GG=lex_tl(C,V,0,V,0)$
4054: [248] gb_comp(G,GG);
4055: 1
4056: @end example
4057:
1.2 noro 4058: \JP @node katsura hkatsura cyclic hcyclic,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
4059: \EG @node katsura hkatsura cyclic hcyclic,,, Functions for Groebner basis computation
1.1 noro 4060: @subsection @code{katsura}, @code{hkatsura}, @code{cyclic}, @code{hcyclic}
4061: @findex katsura
4062: @findex hkatsura
4063: @findex cyclic
4064: @findex hcyclic
4065:
4066: @table @t
4067: @item katsura(@var{n})
4068: @item hkatsura(@var{n})
4069: @item cyclic(@var{n})
4070: @item hcyclic(@var{n})
1.2 noro 4071: \JP :: �$BB?9`<0%j%9%H$N@8@.�(B
4072: \EG :: Generates a polynomial list of standard benchmark.
1.1 noro 4073: @end table
4074:
4075: @table @var
4076: @item return
1.2 noro 4077: \JP �$B%j%9%H�(B
4078: \EG list
1.1 noro 4079: @item n
1.2 noro 4080: \JP �$B@0?t�(B
4081: \EG integer
1.1 noro 4082: @end table
4083:
4084: @itemize @bullet
1.2 noro 4085: \BJP
1.1 noro 4086: @item
4087: @code{katsura()} �$B$O�(B @samp{katsura}, @code{cyclic()} �$B$O�(B @samp{cyclic}
4088: �$B$GDj5A$5$l$F$$$k�(B.
4089: @item
4090: �$B%0%l%V%J4pDl7W;;$G$7$P$7$P%F%9%H�(B, �$B%Y%s%A%^!<%/$KMQ$$$i$l$k�(B @code{katsura},
4091: @code{cyclic} �$B$*$h$S$=$N@F<!2=$r@8@.$9$k�(B.
4092: @item
4093: @code{cyclic} �$B$O�(B @code{Arnborg}, @code{Lazard}, @code{Davenport} �$B$J$I$N�(B
4094: �$BL>$G8F$P$l$k$3$H$b$"$k�(B.
1.2 noro 4095: \E
4096: \BEG
4097: @item
4098: Function @code{katsura()} is defined in @samp{katsura}, and
4099: function @code{cyclic()} in @samp{cyclic}.
4100: @item
4101: These functions generate a series of polynomial sets, respectively,
4102: which are often used for testing and bench marking:
4103: @code{katsura}, @code{cyclic} and their homogenized versions.
4104: @item
4105: Polynomial set @code{cyclic} is sometimes called by other name:
4106: @code{Arnborg}, @code{Lazard}, and @code{Davenport}.
4107: \E
1.1 noro 4108: @end itemize
4109:
4110: @example
4111: [74] load("katsura")$
4112: [79] load("cyclic")$
4113: [89] katsura(5);
4114: [u0+2*u4+2*u3+2*u2+2*u1+2*u5-1,2*u4*u0-u4+2*u1*u3+u2^2+2*u5*u1,
1.5 noro 4115: 2*u3*u0+2*u1*u4-u3+(2*u1+2*u5)*u2,2*u2*u0+2*u2*u4+(2*u1+2*u5)*u3
4116: -u2+u1^2,2*u1*u0+(2*u3+2*u5)*u4+2*u2*u3+2*u1*u2-u1,
1.1 noro 4117: u0^2-u0+2*u4^2+2*u3^2+2*u2^2+2*u1^2+2*u5^2]
4118: [90] hkatsura(5);
4119: [-t+u0+2*u4+2*u3+2*u2+2*u1+2*u5,
4120: -u4*t+2*u4*u0+2*u1*u3+u2^2+2*u5*u1,-u3*t+2*u3*u0+2*u1*u4+(2*u1+2*u5)*u2,
4121: -u2*t+2*u2*u0+2*u2*u4+(2*u1+2*u5)*u3+u1^2,
4122: -u1*t+2*u1*u0+(2*u3+2*u5)*u4+2*u2*u3+2*u1*u2,
4123: -u0*t+u0^2+2*u4^2+2*u3^2+2*u2^2+2*u1^2+2*u5^2]
4124: [91] cyclic(6);
4125: [c5*c4*c3*c2*c1*c0-1,
4126: ((((c4+c5)*c3+c5*c4)*c2+c5*c4*c3)*c1+c5*c4*c3*c2)*c0+c5*c4*c3*c2*c1,
4127: (((c3+c5)*c2+c5*c4)*c1+c5*c4*c3)*c0+c4*c3*c2*c1+c5*c4*c3*c2,
4128: ((c2+c5)*c1+c5*c4)*c0+c3*c2*c1+c4*c3*c2+c5*c4*c3,
4129: (c1+c5)*c0+c2*c1+c3*c2+c4*c3+c5*c4,c0+c1+c2+c3+c4+c5]
4130: [92] hcyclic(6);
4131: [-c^6+c5*c4*c3*c2*c1*c0,
4132: ((((c4+c5)*c3+c5*c4)*c2+c5*c4*c3)*c1+c5*c4*c3*c2)*c0+c5*c4*c3*c2*c1,
4133: (((c3+c5)*c2+c5*c4)*c1+c5*c4*c3)*c0+c4*c3*c2*c1+c5*c4*c3*c2,
4134: ((c2+c5)*c1+c5*c4)*c0+c3*c2*c1+c4*c3*c2+c5*c4*c3,
4135: (c1+c5)*c0+c2*c1+c3*c2+c4*c3+c5*c4,c0+c1+c2+c3+c4+c5]
4136: @end example
4137:
4138: @table @t
1.2 noro 4139: \JP @item �$B;2>H�(B
4140: \EG @item References
1.1 noro 4141: @fref{dp_dtop}.
4142: @end table
4143:
1.3 noro 4144: \JP @node primadec primedec,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
4145: \EG @node primadec primedec,,, Functions for Groebner basis computation
4146: @subsection @code{primadec}, @code{primedec}
4147: @findex primadec
4148: @findex primedec
4149:
4150: @table @t
4151: @item primadec(@var{plist},@var{vlist})
4152: @item primedec(@var{plist},@var{vlist})
4153: \JP :: �$B%$%G%"%k$NJ,2r�(B
4154: \EG :: Computes decompositions of ideals.
4155: @end table
4156:
4157: @table @var
4158: @item return
4159: @itemx plist
4160: \JP �$BB?9`<0%j%9%H�(B
4161: \EG list of polynomials
4162: @item vlist
4163: \JP �$BJQ?t%j%9%H�(B
4164: \EG list of variables
4165: @end table
4166:
4167: @itemize @bullet
4168: \BJP
4169: @item
4170: @code{primadec()}, @code{primedec} �$B$O�(B @samp{primdec} �$B$GDj5A$5$l$F$$$k�(B.
4171: @item
4172: @code{primadec()}, @code{primedec()} �$B$O$=$l$>$lM-M}?tBN>e$G$N%$%G%"%k$N�(B
4173: �$B=`AGJ,2r�(B, �$B:,4p$NAG%$%G%"%kJ,2r$r9T$&�(B.
4174: @item
4175: �$B0z?t$OB?9`<0%j%9%H$*$h$SJQ?t%j%9%H$G$"$k�(B. �$BB?9`<0$OM-M}?t78?t$N$_$,5v$5$l$k�(B.
4176: @item
4177: @code{primadec} �$B$O�(B @code{[�$B=`AG@.J,�(B, �$BIUB0AG%$%G%"%k�(B]} �$B$N%j%9%H$rJV$9�(B.
4178: @item
4179: @code{primadec} �$B$O�(B �$BAG0x;R$N%j%9%H$rJV$9�(B.
4180: @item
4181: �$B7k2L$K$*$$$F�(B, �$BB?9`<0%j%9%H$H$7$FI=<($5$l$F$$$k3F%$%G%"%k$OA4$F�(B
4182: �$B%0%l%V%J4pDl$G$"$k�(B. �$BBP1~$9$k9`=g=x$O�(B, �$B$=$l$>$l�(B
4183: �$BJQ?t�(B @code{PRIMAORD}, @code{PRIMEORD} �$B$K3JG<$5$l$F$$$k�(B.
4184: @item
4185: @code{primadec} �$B$O�(B @code{[Shimoyama,Yokoyama]} �$B$N=`AGJ,2r%"%k%4%j%:%`�(B
4186: �$B$r<BAu$7$F$$$k�(B.
4187: @item
4188: �$B$b$7AG0x;R$N$_$r5a$a$?$$$J$i�(B, @code{primedec} �$B$r;H$&J}$,$h$$�(B.
4189: �$B$3$l$O�(B, �$BF~NO%$%G%"%k$,:,4p%$%G%"%k$G$J$$>l9g$K�(B, @code{primadec}
4190: �$B$N7W;;$KM>J,$J%3%9%H$,I,MW$H$J$k>l9g$,$"$k$+$i$G$"$k�(B.
4191: \E
4192: \BEG
4193: @item
4194: Function @code{primadec()} and @code{primedec} are defined in @samp{primdec}.
4195: @item
4196: @code{primadec()}, @code{primedec()} are the function for primary
4197: ideal decomposition and prime decomposition of the radical over the
4198: rationals respectively.
4199: @item
4200: The arguments are a list of polynomials and a list of variables.
4201: These functions accept ideals with rational function coefficients only.
4202: @item
4203: @code{primadec} returns the list of pair lists consisting a primary component
4204: and its associated prime.
4205: @item
4206: @code{primedec} returns the list of prime components.
4207: @item
4208: Each component is a Groebner basis and the corresponding term order
4209: is indicated by the global variables @code{PRIMAORD}, @code{PRIMEORD}
4210: respectively.
4211: @item
4212: @code{primadec} implements the primary decompostion algorithm
4213: in @code{[Shimoyama,Yokoyama]}.
4214: @item
4215: If one only wants to know the prime components of an ideal, then
4216: use @code{primedec} because @code{primadec} may need additional costs
4217: if an input ideal is not radical.
4218: \E
4219: @end itemize
4220:
4221: @example
4222: [84] load("primdec")$
4223: [102] primedec([p*q*x-q^2*y^2+q^2*y,-p^2*x^2+p^2*x+p*q*y,
4224: (q^3*y^4-2*q^3*y^3+q^3*y^2)*x-q^3*y^4+q^3*y^3,
4225: -q^3*y^4+2*q^3*y^3+(-q^3+p*q^2)*y^2],[p,q,x,y]);
4226: [[y,x],[y,p],[x,q],[q,p],[x-1,q],[y-1,p],[(y-1)*x-y,q*y^2-2*q*y-p+q]]
4227: [103] primadec([x,z*y,w*y^2,w^2*y-z^3,y^3],[x,y,z,w]);
4228: [[[x,z*y,y^2,w^2*y-z^3],[z,y,x]],[[w,x,z*y,z^3,y^3],[w,z,y,x]]]
4229: @end example
4230:
4231: @table @t
4232: \JP @item �$B;2>H�(B
4233: \EG @item References
4234: @fref{fctr sqfr},
4235: \JP @fref{�$B9`=g=x$N@_Dj�(B}.
4236: \EG @fref{Setting term orderings}.
4237: @end table
1.5 noro 4238:
4239: \JP @node primedec_mod,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
4240: \EG @node primedec_mod,,, Functions for Groebner basis computation
4241: @subsection @code{primedec_mod}
4242: @findex primedec_mod
4243:
4244: @table @t
4245: @item primedec_mod(@var{plist},@var{vlist},@var{ord},@var{mod},@var{strategy})
4246: \JP :: �$B%$%G%"%k$NJ,2r�(B
4247: \EG :: Computes decompositions of ideals over small finite fields.
4248: @end table
4249:
4250: @table @var
4251: @item return
4252: @itemx plist
4253: \JP �$BB?9`<0%j%9%H�(B
4254: \EG list of polynomials
4255: @item vlist
4256: \JP �$BJQ?t%j%9%H�(B
4257: \EG list of variables
4258: @item ord
4259: \JP �$B?t�(B, �$B%j%9%H$^$?$O9TNs�(B
4260: \EG number, list or matrix
4261: @item mod
4262: \JP �$B@5@0?t�(B
4263: \EG positive integer
4264: @item strategy
4265: \JP �$B@0?t�(B
4266: \EG integer
4267: @end table
4268:
4269: @itemize @bullet
4270: \BJP
4271: @item
4272: @code{primedec_mod()} �$B$O�(B @samp{primdec_mod}
4273: �$B$GDj5A$5$l$F$$$k�(B. @code{[Yokoyama]} �$B$NAG%$%G%"%kJ,2r%"%k%4%j%:%`�(B
4274: �$B$r<BAu$7$F$$$k�(B.
4275: @item
4276: @code{primedec_mod()} �$B$OM-8BBN>e$G$N%$%G%"%k$N�(B
4277: �$B:,4p$NAG%$%G%"%kJ,2r$r9T$$�(B, �$BAG%$%G%"%k$N%j%9%H$rJV$9�(B.
4278: @item
4279: @code{primedec_mod()} �$B$O�(B, GF(@var{mod}) �$B>e$G$NJ,2r$rM?$($k�(B.
4280: �$B7k2L$N3F@.J,$N@8@.85$O�(B, �$B@0?t78?tB?9`<0$G$"$k�(B.
4281: @item
4282: �$B7k2L$K$*$$$F�(B, �$BB?9`<0%j%9%H$H$7$FI=<($5$l$F$$$k3F%$%G%"%k$OA4$F�(B
4283: [@var{vlist},@var{ord}] �$B$G;XDj$5$l$k9`=g=x$K4X$9$k%0%l%V%J4pDl$G$"$k�(B.
4284: @item
4285: @var{strategy} �$B$,�(B 0 �$B$G$J$$$H$-�(B, incremental �$B$K�(B component �$B$N6&DL�(B
4286: �$BItJ,$r7W;;$9$k$3$H$K$h$k�(B early termination �$B$r9T$&�(B. �$B0lHL$K�(B,
4287: �$B%$%G%"%k$N<!85$,9b$$>l9g$KM-8z$@$,�(B, 0 �$B<!85$N>l9g$J$I�(B, �$B<!85$,>.$5$$�(B
4288: �$B>l9g$K$O�(B overhead �$B$,Bg$-$$>l9g$,$"$k�(B.
1.7 noro 4289: @item
4290: �$B7W;;ESCf$GFbIt>pJs$r8+$?$$>l9g$K$O!"�(B
4291: �$BA0$b$C$F�(B @code{dp_gr_print(2)} �$B$r<B9T$7$F$*$1$P$h$$�(B.
1.5 noro 4292: \E
4293: \BEG
4294: @item
4295: Function @code{primedec_mod()}
4296: is defined in @samp{primdec_mod} and implements the prime decomposition
4297: algorithm in @code{[Yokoyama]}.
4298: @item
4299: @code{primedec_mod()}
4300: is the function for prime ideal decomposition
4301: of the radical of a polynomial ideal over small finite field,
4302: and they return a list of prime ideals, which are associated primes
4303: of the input ideal.
4304: @item
4305: @code{primedec_mod()} gives the decomposition over GF(@var{mod}).
4306: The generators of each resulting component consists of integral polynomials.
4307: @item
4308: Each resulting component is a Groebner basis with respect to
4309: a term order specified by [@var{vlist},@var{ord}].
4310: @item
4311: If @var{strategy} is non zero, then the early termination strategy
4312: is tried by computing the intersection of obtained components
4313: incrementally. In general, this strategy is useful when the krull
4314: dimension of the ideal is high, but it may add some overhead
4315: if the dimension is small.
1.7 noro 4316: @item
4317: If you want to see internal information during the computation,
4318: execute @code{dp_gr_print(2)} in advance.
1.5 noro 4319: \E
4320: @end itemize
4321:
4322: @example
4323: [0] load("primdec_mod")$
4324: [246] PP444=[x^8+x^2+t,y^8+y^2+t,z^8+z^2+t]$
4325: [247] primedec_mod(PP444,[x,y,z,t],0,2,1);
4326: [[y+z,x+z,z^8+z^2+t],[x+y,y^2+y+z^2+z+1,z^8+z^2+t],
4327: [y+z+1,x+z+1,z^8+z^2+t],[x+z,y^2+y+z^2+z+1,z^8+z^2+t],
4328: [y+z,x^2+x+z^2+z+1,z^8+z^2+t],[y+z+1,x^2+x+z^2+z+1,z^8+z^2+t],
4329: [x+z+1,y^2+y+z^2+z+1,z^8+z^2+t],[y+z+1,x+z,z^8+z^2+t],
4330: [x+y+1,y^2+y+z^2+z+1,z^8+z^2+t],[y+z,x+z+1,z^8+z^2+t]]
4331: [248]
4332: @end example
4333:
4334: @table @t
4335: \JP @item �$B;2>H�(B
4336: \EG @item References
4337: @fref{modfctr},
1.6 noro 4338: @fref{dp_gr_main dp_gr_mod_main dp_gr_f_main dp_weyl_gr_main dp_weyl_gr_mod_main dp_weyl_gr_f_main},
1.5 noro 4339: \JP @fref{�$B9`=g=x$N@_Dj�(B}.
1.7 noro 4340: \EG @fref{Setting term orderings},
4341: @fref{dp_gr_flags dp_gr_print}.
1.5 noro 4342: @end table
4343:
1.10 noro 4344: \JP @node bfunction bfct generic_bfct ann ann0,,, �$B%0%l%V%J4pDl$K4X$9$kH!?t�(B
4345: \EG @node bfunction bfct generic_bfct ann ann0,,, Functions for Groebner basis computation
4346: @subsection @code{bfunction}, @code{bfct}, @code{generic_bfct}, @code{ann}, @code{ann0}
1.6 noro 4347: @findex bfunction
1.9 noro 4348: @findex bfct
1.6 noro 4349: @findex generic_bfct
1.10 noro 4350: @findex ann
4351: @findex ann0
1.5 noro 4352:
1.6 noro 4353: @table @t
4354: @item bfunction(@var{f})
1.10 noro 4355: @itemx bfct(@var{f})
4356: @itemx generic_bfct(@var{plist},@var{vlist},@var{dvlist},@var{weight})
4357: \JP :: @var{b} �$B4X?t$N7W;;�(B
4358: \EG :: Computes the global @var{b} function of a polynomial or an ideal
4359: @item ann(@var{f})
4360: @itemx ann0(@var{f})
4361: \JP :: �$BB?9`<0$N%Y%-$N�(B annihilator �$B$N7W;;�(B
4362: \EG :: Computes the annihilator of a power of polynomial
1.6 noro 4363: @end table
1.10 noro 4364:
1.6 noro 4365: @table @var
4366: @item return
1.10 noro 4367: \JP �$BB?9`<0$^$?$O%j%9%H�(B
4368: \EG polynomial or list
4369: @item f
1.6 noro 4370: \JP �$BB?9`<0�(B
4371: \EG polynomial
4372: @item plist
4373: \JP �$BB?9`<0%j%9%H�(B
4374: \EG list of polynomials
4375: @item vlist dvlist
4376: \JP �$BJQ?t%j%9%H�(B
4377: \EG list of variables
4378: @end table
1.5 noro 4379:
1.6 noro 4380: @itemize @bullet
4381: \BJP
4382: @item @samp{bfct} �$B$GDj5A$5$l$F$$$k�(B.
1.10 noro 4383: @item @code{bfunction(@var{f})}, @code{bfct(@var{f})} �$B$OB?9`<0�(B @var{f} �$B$N�(B global @var{b} �$B4X?t�(B @code{b(s)} �$B$r�(B
1.6 noro 4384: �$B7W;;$9$k�(B. @code{b(s)} �$B$O�(B, Weyl �$BBe?t�(B @code{D} �$B>e$N0lJQ?tB?9`<04D�(B @code{D[s]}
4385: �$B$N85�(B @code{P(x,s)} �$B$,B8:_$7$F�(B, @code{P(x,s)f^(s+1)=b(s)f^s} �$B$rK~$?$9$h$&$J�(B
4386: �$BB?9`<0�(B @code{b(s)} �$B$NCf$G�(B, �$B<!?t$,:G$bDc$$$b$N$G$"$k�(B.
4387: @item @code{generic_bfct(@var{f},@var{vlist},@var{dvlist},@var{weight})}
4388: �$B$O�(B, @var{plist} �$B$G@8@.$5$l$k�(B @code{D} �$B$N:8%$%G%"%k�(B @code{I} �$B$N�(B,
1.10 noro 4389: �$B%&%'%$%H�(B @var{weight} �$B$K4X$9$k�(B global @var{b} �$B4X?t$r7W;;$9$k�(B.
1.6 noro 4390: @var{vlist} �$B$O�(B @code{x}-�$BJQ?t�(B, @var{vlist} �$B$OBP1~$9$k�(B @code{D}-�$BJQ?t�(B
4391: �$B$r=g$KJB$Y$k�(B.
1.9 noro 4392: @item @code{bfunction} �$B$H�(B @code{bfct} �$B$G$OMQ$$$F$$$k%"%k%4%j%:%`$,�(B
1.11 noro 4393: �$B0[$J$k�(B. �$B$I$A$i$,9bB.$+$OF~NO$K$h$k�(B.
1.10 noro 4394: @item @code{ann(@var{f})} �$B$O�(B, @code{@var{f}^s} �$B$N�(B annihilator ideal
4395: �$B$N@8@.7O$rJV$9�(B. @code{ann(@var{f})} �$B$O�(B, @code{[@var{a},@var{list}]}
4396: �$B$J$k%j%9%H$rJV$9�(B. �$B$3$3$G�(B, @var{a} �$B$O�(B @var{f} �$B$N�(B @var{b} �$B4X?t$N:G>.@0?t:,�(B,
4397: @var{list} �$B$O�(B @code{ann(@var{f})} �$B$N7k2L$N�(B @code{s}$ �$B$K�(B, @var{a} �$B$r�(B
4398: �$BBeF~$7$?$b$N$G$"$k�(B.
1.7 noro 4399: @item �$B>\:Y$K$D$$$F$O�(B, [Saito,Sturmfels,Takayama] �$B$r8+$h�(B.
1.6 noro 4400: \E
4401: \BEG
4402: @item These functions are defined in @samp{bfct}.
1.10 noro 4403: @item @code{bfunction(@var{f})} and @code{bfct(@var{f})} compute the global @var{b}-function @code{b(s)} of
1.6 noro 4404: a polynomial @var{f}.
4405: @code{b(s)} is a polynomial of the minimal degree
4406: such that there exists @code{P(x,s)} in D[s], which is a polynomial
4407: ring over Weyl algebra @code{D}, and @code{P(x,s)f^(s+1)=b(s)f^s} holds.
4408: @item @code{generic_bfct(@var{f},@var{vlist},@var{dvlist},@var{weight})}
1.10 noro 4409: computes the global @var{b}-function of a left ideal @code{I} in @code{D}
1.6 noro 4410: generated by @var{plist}, with respect to @var{weight}.
4411: @var{vlist} is the list of @code{x}-variables,
4412: @var{vlist} is the list of corresponding @code{D}-variables.
1.9 noro 4413: @item @code{bfunction(@var{f})} and @code{bfct(@var{f})} implement
4414: different algorithms and the efficiency depends on inputs.
1.10 noro 4415: @item @code{ann(@var{f})} returns the generator set of the annihilator
4416: ideal of @code{@var{f}^s}.
4417: @code{ann(@var{f})} returns a list @code{[@var{a},@var{list}]},
4418: where @var{a} is the minimal integral root of the global @var{b}-function
4419: of @var{f}, and @var{list} is a list of polynomials obtained by
4420: substituting @code{s} in @code{ann(@var{f})} with @var{a}.
1.7 noro 4421: @item See [Saito,Sturmfels,Takayama] for the details.
1.6 noro 4422: \E
4423: @end itemize
4424:
4425: @example
4426: [0] load("bfct")$
4427: [216] bfunction(x^3+y^3+z^3+x^2*y^2*z^2+x*y*z);
4428: -9*s^5-63*s^4-173*s^3-233*s^2-154*s-40
4429: [217] fctr(@@);
4430: [[-1,1],[s+2,1],[3*s+4,1],[3*s+5,1],[s+1,2]]
4431: [218] F = [4*x^3*dt+y*z*dt+dx,x*z*dt+4*y^3*dt+dy,
4432: x*y*dt+5*z^4*dt+dz,-x^4-z*y*x-y^4-z^5+t]$
4433: [219] generic_bfct(F,[t,z,y,x],[dt,dz,dy,dx],[1,0,0,0]);
4434: 20000*s^10-70000*s^9+101750*s^8-79375*s^7+35768*s^6-9277*s^5
4435: +1278*s^4-72*s^3
1.10 noro 4436: [220] P=x^3-y^2$
4437: [221] ann(P);
4438: [2*dy*x+3*dx*y^2,-3*dx*x-2*dy*y+6*s]
4439: [222] ann0(P);
4440: [-1,[2*dy*x+3*dx*y^2,-3*dx*x-2*dy*y-6]]
1.6 noro 4441: @end example
4442:
4443: @table @t
4444: \JP @item �$B;2>H�(B
4445: \EG @item References
4446: \JP @fref{Weyl �$BBe?t�(B}.
4447: \EG @fref{Weyl algebra}.
4448: @end table
1.5 noro 4449:
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