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source: branches/f4grobner/division.lisp@ 2010

Last change on this file since 2010 was 1965, checked in by Marek Rychlik, 9 years ago

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[1199]1;;; -*- Mode: Lisp -*-
[148]2;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3;;;
4;;; Copyright (C) 1999, 2002, 2009, 2015 Marek Rychlik <rychlik@u.arizona.edu>
5;;;
6;;; This program is free software; you can redistribute it and/or modify
7;;; it under the terms of the GNU General Public License as published by
8;;; the Free Software Foundation; either version 2 of the License, or
9;;; (at your option) any later version.
10;;;
11;;; This program is distributed in the hope that it will be useful,
12;;; but WITHOUT ANY WARRANTY; without even the implied warranty of
13;;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
14;;; GNU General Public License for more details.
15;;;
16;;; You should have received a copy of the GNU General Public License
17;;; along with this program; if not, write to the Free Software
18;;; Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
19;;;
20;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
21
[459]22(defpackage "DIVISION"
[1616]23 (:use :cl :utils :ring :monom :polynomial :grobner-debug :term :ring-and-order)
[470]24 (:export "$POLY_TOP_REDUCTION_ONLY"
25 "POLY-PSEUDO-DIVIDE"
[459]26 "POLY-EXACT-DIVIDE"
[491]27 "NORMAL-FORM-STEP"
[459]28 "NORMAL-FORM"
29 "POLY-NORMALIZE"
[472]30 "POLY-NORMALIZE-LIST"
[473]31 "BUCHBERGER-CRITERION"
[1299]32 "GROBNER-TEST"
[459]33 ))
[148]34
[460]35(in-package :division)
36
[469]37(defvar $poly_top_reduction_only nil
38 "If not FALSE, use top reduction only whenever possible.
39Top reduction means that division algorithm stops after the first reduction.")
40
[59]41;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
42;;
43;; An implementation of the division algorithm
44;;
45;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
46
[1176]47(defun grobner-op (ring-and-order c1 c2 m f g
48 &aux
49 (ring (ro-ring ring-and-order)))
[59]50 "Returns C2*F-C1*M*G, where F and G are polynomials M is a monomial.
51Assume that the leading terms will cancel."
[1965]52 (declare (type ring-and-order ring-and-order)
53 (type monom m)
54 (type poly f g))
[59]55 #+grobner-check(funcall (ring-zerop ring)
56 (funcall (ring-sub ring)
57 (funcall (ring-mul ring) c2 (poly-lc f))
58 (funcall (ring-mul ring) c1 (poly-lc g))))
59 #+grobner-check(monom-equal-p (poly-lm f) (monom-mul m (poly-lm g)))
[1205]60 ;; Note that below we can drop the leading terms of f ang g for the
[1206]61 ;; purpose of polynomial arithmetic.
62 ;;
[1212]63 ;; TODO: Make sure that the sugar calculation is correct if leading
64 ;; terms are dropped.
[1176]65 (poly-sub ring-and-order
[1263]66 (scalar-times-poly-1 ring c2 f)
67 (scalar-times-poly-1 ring c1 (monom-times-poly m g))))
[59]68
[1242]69(defun check-loop-invariant (ring-and-order c f a fl r p
[1237]70 &aux
71 (ring (ro-ring ring-and-order))
[1264]72 (p-zero (make-poly-zero))
73 (a (mapcar #'poly-reverse a))
74 (r (poly-reverse r)))
[1238]75 "Check loop invariant of division algorithms, when we divide a
76polynomial F by the list of polynomials FL. The invariant is the
[1242]77identity C*F=SUM AI*FI+R+P, where F0 is the initial value of F, A is
[1238]78the list of partial quotients, R is the intermediate value of the
[1242]79remainder, and P is the intermediate value which eventually becomes
[1269]800. A thing to remember is that the terms of polynomials in A and
81the polynomial R have their terms in reversed order. Hence, before
82the arithmetic is performed, we need to fix the order of terms"
[1413]83 #|
84 (format t "~&----------------------------------------------------------------~%")
85 (format t "#### Loop invariant check ####:~%C=~A~%F=~A~%A=~A~%FL=~A~%R=~A~%P=~A~%"
[1275]86 c f a fl r p)
[1413]87 |#
[1242]88 (flet ((p-add (x y) (poly-add ring-and-order x y))
89 (p-sub (x y) (poly-sub ring-and-order x y))
90 (p-mul (x y) (poly-mul ring-and-order x y)))
[1257]91 (let* ((prod (inner-product a fl p-add p-mul p-zero))
92 (succeeded-p
93 (poly-zerop
94 (p-sub
95 (scalar-times-poly ring c f)
96 (reduce #'p-add (list prod r p))))))
[1270]97 (unless succeeded-p
[1280]98 (error "#### Polynomial division Loop invariant failed ####:~%C=~A~%F=~A~%A=~A~%FL=~A~%R=~A~%P=~A~%"
[1271]99 c f a fl r p))
[1257]100 succeeded-p)))
[1237]101
102
[1179]103(defun poly-pseudo-divide (ring-and-order f fl
104 &aux
105 (ring (ro-ring ring-and-order)))
[59]106 "Pseudo-divide a polynomial F by the list of polynomials FL. Return
107multiple values. The first value is a list of quotients A. The second
108value is the remainder R. The third argument is a scalar coefficient
109C, such that C*F can be divided by FL within the ring of coefficients,
110which is not necessarily a field. Finally, the fourth value is an
111integer count of the number of reductions performed. The resulting
[1220]112objects satisfy the equation: C*F= sum A[i]*FL[i] + R. The sugar of
[1221]113the quotients is initialized to default."
[59]114 (declare (type poly f) (list fl))
[1241]115 ;; Loop invariant: c*f=sum ai*fi+r+p, where p must eventually become 0
[59]116 (do ((r (make-poly-zero))
117 (c (funcall (ring-unit ring)))
118 (a (make-list (length fl) :initial-element (make-poly-zero)))
119 (division-count 0)
120 (p f))
121 ((poly-zerop p)
[1278]122 #+grobner-check(check-loop-invariant ring-and-order c f a fl r p)
[59]123 (debug-cgb "~&~3T~d reduction~:p" division-count)
124 (when (poly-zerop r) (debug-cgb " ---> 0"))
[1211]125 ;; We obtained the terms in reverse order, so must fix that
[1210]126 (setf a (mapcar #'poly-nreverse a)
127 r (poly-nreverse r))
[1219]128 ;; Initialize the sugar of the quotients
129 (mapc #'poly-reset-sugar a)
[1210]130 (values a r c division-count))
[59]131 (declare (fixnum division-count))
[1252]132 ;; Check the loop invariant here
[1277]133 #+grobner-check(check-loop-invariant ring-and-order c f a fl r p)
[1207]134 (do ((fl fl (rest fl)) ;scan list of divisors
[59]135 (b a (rest b)))
136 ((cond
[1207]137 ((endp fl) ;no division occurred
138 (push (poly-lt p) (poly-termlist r)) ;move lt(p) to remainder
139 (setf (poly-sugar r) (max (poly-sugar r) (term-sugar (poly-lt p))))
140 (pop (poly-termlist p)) ;remove lt(p) from p
141 t)
142 ((monom-divides-p (poly-lm (car fl)) (poly-lm p)) ;division occurred
143 (incf division-count)
144 (multiple-value-bind (gcd c1 c2)
145 (funcall (ring-ezgcd ring) (poly-lc (car fl)) (poly-lc p))
146 (declare (ignore gcd))
147 (let ((m (monom-div (poly-lm p) (poly-lm (car fl)))))
148 ;; Multiply the equation c*f=sum ai*fi+r+p by c1.
149 (mapl #'(lambda (x)
150 (setf (car x) (scalar-times-poly ring c1 (car x))))
151 a)
152 (setf r (scalar-times-poly ring c1 r)
153 c (funcall (ring-mul ring) c c1)
154 p (grobner-op ring-and-order c2 c1 m p (car fl)))
[1851]155 (push (make-term :monom m :coeff c2) (poly-termlist (car b))))
[1248]156 t))))
157 )))
[59]158
[1284]159(defun poly-exact-divide (ring-and-order f g)
[59]160 "Divide a polynomial F by another polynomial G. Assume that exact division
161with no remainder is possible. Returns the quotient."
[1284]162 (declare (type poly f g) (type ring-and-order ring-and-order))
[59]163 (multiple-value-bind (quot rem coeff division-count)
[1284]164 (poly-pseudo-divide ring-and-order f (list g))
[59]165 (declare (ignore division-count coeff)
166 (list quot)
167 (type poly rem)
168 (type fixnum division-count))
169 (unless (poly-zerop rem) (error "Exact division failed."))
170 (car quot)))
171
172;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
173;;
174;; An implementation of the normal form
175;;
176;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
177
[1180]178(defun normal-form-step (ring-and-order fl p r c division-count
179 &aux
180 (ring (ro-ring ring-and-order))
181 (g (find (poly-lm p) fl
182 :test #'monom-divisible-by-p
183 :key #'poly-lm)))
[59]184 (cond
185 (g ;division possible
186 (incf division-count)
187 (multiple-value-bind (gcd cg cp)
188 (funcall (ring-ezgcd ring) (poly-lc g) (poly-lc p))
189 (declare (ignore gcd))
190 (let ((m (monom-div (poly-lm p) (poly-lm g))))
191 ;; Multiply the equation c*f=sum ai*fi+r+p by cg.
192 (setf r (scalar-times-poly ring cg r)
193 c (funcall (ring-mul ring) c cg)
194 ;; p := cg*p-cp*m*g
[1181]195 p (grobner-op ring-and-order cp cg m p g))))
[59]196 (debug-cgb "/"))
197 (t ;no division possible
198 (push (poly-lt p) (poly-termlist r)) ;move lt(p) to remainder
199 (setf (poly-sugar r) (max (poly-sugar r) (term-sugar (poly-lt p))))
200 (pop (poly-termlist p)) ;remove lt(p) from p
201 (debug-cgb "+")))
202 (values p r c division-count))
203
[1432]204;;
[1433]205;; Merge NORMAL-FORM someday with POLY-PSEUDO-DIVIDE.
[1432]206;;
[1433]207;; TODO: It is hard to test normal form as there is no loop invariant,
208;; like for POLY-PSEUDO-DIVIDE. Is there a testing strategy? One
209;; method would be to test NORMAL-FORM using POLY-PSEUDO-DIVIDE.
210;;
[1182]211(defun normal-form (ring-and-order f fl
212 &optional
213 (top-reduction-only $poly_top_reduction_only)
214 (ring (ro-ring ring-and-order)))
[1568]215 #+grobner-check(when (null fl) (warn "normal-form: empty divisor list."))
[59]216 (do ((r (make-poly-zero))
217 (c (funcall (ring-unit ring)))
[1254]218 (division-count 0))
[59]219 ((or (poly-zerop f)
220 ;;(endp fl)
221 (and top-reduction-only (not (poly-zerop r))))
222 (progn
[1239]223 (debug-cgb "~&~3T~D reduction~:P" division-count)
[59]224 (when (poly-zerop r)
225 (debug-cgb " ---> 0")))
226 (setf (poly-termlist f) (nreconc (poly-termlist r) (poly-termlist f)))
227 (values f c division-count))
228 (declare (fixnum division-count)
229 (type poly r))
230 (multiple-value-setq (f r c division-count)
[1182]231 (normal-form-step ring-and-order fl f r c division-count))))
[59]232
[1187]233(defun buchberger-criterion (ring-and-order g)
[59]234 "Returns T if G is a Grobner basis, by using the Buchberger
235criterion: for every two polynomials h1 and h2 in G the S-polynomial
236S(h1,h2) reduces to 0 modulo G."
[1222]237 (every #'poly-zerop
238 (makelist (normal-form ring-and-order (spoly ring-and-order (elt g i) (elt g j)) g nil)
239 (i 0 (- (length g) 2))
240 (j (1+ i) (1- (length g))))))
[59]241
[64]242
243(defun poly-normalize (ring p &aux (c (poly-lc p)))
244 "Divide a polynomial by its leading coefficient. It assumes
245that the division is possible, which may not always be the
246case in rings which are not fields. The exact division operator
[1197]247is assumed to be provided by the RING structure."
[64]248 (mapc #'(lambda (term)
249 (setf (term-coeff term) (funcall (ring-div ring) (term-coeff term) c)))
250 (poly-termlist p))
251 p)
252
253(defun poly-normalize-list (ring plist)
254 "Divide every polynomial in a list PLIST by its leading coefficient. "
255 (mapcar #'(lambda (x) (poly-normalize ring x)) plist))
[1297]256
257;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
258;;
259;; The function GROBNER-CHECK is provided primarily for debugging purposes. To
260;; enable verification of grobner bases with BUCHBERGER-CRITERION, do
261;; (pushnew :grobner-check *features*) and compile/load this file.
262;; With this feature, the calculations will slow down CONSIDERABLY.
263;;
264;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
265
[1298]266(defun grobner-test (ring-and-order g f)
[1297]267 "Test whether G is a Grobner basis and F is contained in G. Return T
268upon success and NIL otherwise."
269 (debug-cgb "~&GROBNER CHECK: ")
270 (let (($poly_grobner_debug nil)
[1298]271 (stat1 (buchberger-criterion ring-and-order g))
[1297]272 (stat2
273 (every #'poly-zerop
[1298]274 (makelist (normal-form ring-and-order (copy-tree (elt f i)) g nil)
[1297]275 (i 0 (1- (length f)))))))
[1404]276 (unless stat1 (error "~&Buchberger criterion failed, not a grobner basis: ~A" g))
[1297]277 (unless stat2
[1406]278 (error "~&Original polynomials not in ideal spanned by Grobner basis: ~A" f)))
[1297]279 (debug-cgb "~&GROBNER CHECK END")
280 t)
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