;;; -*- Mode: Lisp; Package: Maxima; Syntax: Common-Lisp; Base: 10 -*- ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;;; ;;; Copyright (C) 1999, 2002, 2009, 2015 Marek Rychlik ;;; ;;; This program is free software; you can redistribute it and/or modify ;;; it under the terms of the GNU General Public License as published by ;;; the Free Software Foundation; either version 2 of the License, or ;;; (at your option) any later version. ;;; ;;; This program is distributed in the hope that it will be useful, ;;; but WITHOUT ANY WARRANTY; without even the implied warranty of ;;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ;;; GNU General Public License for more details. ;;; ;;; You should have received a copy of the GNU General Public License ;;; along with this program; if not, write to the Free Software ;;; Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. ;;; ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; (defpackage "POLYNOMIAL" (:use :cl :ring :ring-and-order :monomial :order :term :termlist :infix) (:export "POLY" "POLY-TERMLIST" "POLY-SUGAR" "POLY-LT" "MAKE-POLY-FROM-TERMLIST" "MAKE-POLY-ZERO" "MAKE-VARIABLE" "POLY-UNIT" "POLY-LM" "POLY-SECOND-LM" "POLY-SECOND-LT" "POLY-LC" "POLY-SECOND-LC" "POLY-ZEROP" "POLY-LENGTH" "SCALAR-TIMES-POLY" "SCALAR-TIMES-POLY-1" "MONOM-TIMES-POLY" "TERM-TIMES-POLY" "POLY-ADD" "POLY-SUB" "POLY-UMINUS" "POLY-MUL" "POLY-EXPT" "POLY-APPEND" "POLY-NREVERSE" "POLY-CONTRACT" "POLY-EXTEND" "POLY-ADD-VARIABLES" "POLY-LIST-ADD-VARIABLES" "POLY-STANDARD-EXTENSION" "SATURATION-EXTENSION" "POLYSATURATION-EXTENSION" "SATURATION-EXTENSION-1" "COERCE-COEFF" "POLY-EVAL" "POLY-EVAL-SCALAR" "SPOLY" "POLY-PRIMITIVE-PART" "POLY-CONTENT" "READ-INFIX-FORM" "READ-POLY" "STRING->POLY" "POLY->ALIST" "STRING->ALIST" )) (in-package :polynomial) ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;; ;; Polynomials ;; ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; (defstruct (poly ;; ;; BOA constructor, by default constructs zero polynomial (:constructor make-poly-from-termlist (termlist &optional (sugar (termlist-sugar termlist)))) (:constructor make-poly-zero (&aux (termlist nil) (sugar -1))) ;; Constructor of polynomials representing a variable (:constructor make-variable (ring nvars pos &optional (power 1) &aux (termlist (list (make-term-variable ring nvars pos power))) (sugar power))) (:constructor poly-unit (ring dimension &aux (termlist (termlist-unit ring dimension)) (sugar 0)))) (termlist nil :type list) (sugar -1 :type fixnum)) ;; Leading term (defmacro poly-lt (p) `(car (poly-termlist ,p))) ;; Second term (defmacro poly-second-lt (p) `(cadar (poly-termlist ,p))) ;; Leading monomial (defun poly-lm (p) (term-monom (poly-lt p))) ;; Second monomial (defun poly-second-lm (p) (term-monom (poly-second-lt p))) ;; Leading coefficient (defun poly-lc (p) (term-coeff (poly-lt p))) ;; Second coefficient (defun poly-second-lc (p) (term-coeff (poly-second-lt p))) ;; Testing for a zero polynomial (defun poly-zerop (p) (null (poly-termlist p))) ;; The number of terms (defun poly-length (p) (length (poly-termlist p))) (defun scalar-times-poly (ring c p) (declare (type ring ring) (poly p)) (make-poly-from-termlist (scalar-times-termlist ring c (poly-termlist p)) (poly-sugar p))) ;; The scalar product omitting the head term (defun scalar-times-poly-1 (ring c p) (declare (type ring ring) (poly p)) (make-poly-from-termlist (scalar-times-termlist ring c (cdr (poly-termlist p))) (poly-sugar p))) (defun monom-times-poly (m p) (declare (poly p)) (make-poly-from-termlist (monom-times-termlist m (poly-termlist p)) (+ (poly-sugar p) (monom-sugar m)))) (defun term-times-poly (ring term p) (declare (type ring ring) (type term term) (type poly p)) (make-poly-from-termlist (term-times-termlist ring term (poly-termlist p)) (+ (poly-sugar p) (term-sugar term)))) (defun poly-add (ring-and-order p q) (declare (type ring-and-order ring-and-order) (type poly p q)) (make-poly-from-termlist (termlist-add ring-and-order (poly-termlist p) (poly-termlist q)) (max (poly-sugar p) (poly-sugar q)))) (defun poly-sub (ring-and-order p q) (declare (type ring-and-order ring-and-order) (type poly p q)) (make-poly-from-termlist (termlist-sub ring-and-order (poly-termlist p) (poly-termlist q)) (max (poly-sugar p) (poly-sugar q)))) (defun poly-uminus (ring p) (declare (type ring ring) (type poly p)) (make-poly-from-termlist (termlist-uminus ring (poly-termlist p)) (poly-sugar p))) (defun poly-mul (ring-and-order p q) (declare (type ring-and-order ring-and-order) (type poly p q)) (make-poly-from-termlist (termlist-mul ring-and-order (poly-termlist p) (poly-termlist q)) (+ (poly-sugar p) (poly-sugar q)))) (defun poly-expt (ring-and-order p n) (declare (type ring-and-order ring-and-order) (type poly p)) (make-poly-from-termlist (termlist-expt ring-and-order (poly-termlist p) n) (* n (poly-sugar p)))) (defun poly-append (&rest plist) (make-poly-from-termlist (apply #'append (mapcar #'poly-termlist plist)) (apply #'max (mapcar #'poly-sugar plist)))) (defun poly-nreverse (p) (declare (type poly p)) (setf (poly-termlist p) (nreverse (poly-termlist p))) p) (defun poly-contract (p &optional (k 1)) (declare (type poly p)) (make-poly-from-termlist (termlist-contract (poly-termlist p) k) (poly-sugar p))) (defun poly-extend (p &optional (m (make-monom :dimension 1))) (declare (type poly p)) (make-poly-from-termlist (termlist-extend (poly-termlist p) m) (+ (poly-sugar p) (monom-sugar m)))) (defun poly-add-variables (p k) (declare (type poly p)) (setf (poly-termlist p) (termlist-add-variables (poly-termlist p) k)) p) (defun poly-list-add-variables (plist k) (mapcar #'(lambda (p) (poly-add-variables p k)) plist)) (defun poly-standard-extension (plist &aux (k (length plist))) "Calculate [U1*P1,U2*P2,...,UK*PK], where PLIST=[P1,P2,...,PK]." (declare (list plist) (fixnum k)) (labels ((incf-power (g i) (dolist (x (poly-termlist g)) (incf (monom-elt (term-monom x) i))) (incf (poly-sugar g)))) (setf plist (poly-list-add-variables plist k)) (dotimes (i k plist) (incf-power (nth i plist) i)))) (defun saturation-extension (ring f plist &aux (k (length plist)) (d (monom-dimension (poly-lm (car plist))))) "Calculate [F, U1*P1-1,U2*P2-1,...,UK*PK-1], where PLIST=[P1,P2,...,PK]." (setf f (poly-list-add-variables f k) plist (mapcar #'(lambda (x) (setf (poly-termlist x) (nconc (poly-termlist x) (list (make-term (make-monom :dimension d) (funcall (ring-uminus ring) (funcall (ring-unit ring))))))) x) (poly-standard-extension plist))) (append f plist)) (defun polysaturation-extension (ring f plist &aux (k (length plist)) (d (+ k (monom-dimension (poly-lm (car plist)))))) "Calculate [F, U1*P1+U2*P2+...+UK*PK-1], where PLIST=[P1,P2,...,PK]." (setf f (poly-list-add-variables f k) plist (apply #'poly-append (poly-standard-extension plist)) (cdr (last (poly-termlist plist))) (list (make-term (make-monom :dimension d) (funcall (ring-uminus ring) (funcall (ring-unit ring)))))) (append f (list plist))) (defun saturation-extension-1 (ring f p) (polysaturation-extension ring f (list p))) ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;; ;; Evaluation of polynomial (prefix) expressions ;; ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; (defun coerce-coeff (ring expr vars) "Coerce an element of the coefficient ring to a constant polynomial." ;; Modular arithmetic handler by rat (make-poly-from-termlist (list (make-term (make-monom :dimension (length vars)) (funcall (ring-parse ring) expr))) 0)) (defun poly-eval (expr vars &optional (ring *ring-of-integers*) (order #'lex>) (list-marker '[) &aux (ring-and-order (make-ring-and-order :ring ring :order order))) (labels ((p-eval (arg) (poly-eval arg vars ring order)) (p-eval-scalar (arg) (poly-eval-scalar arg)) (p-eval-list (args) (mapcar #'p-eval args)) (p-add (x y) (poly-add ring-and-order x y))) (cond ((null expr) (error "Empty expression")) ((eql expr 0) (make-poly-zero)) ((member expr vars :test #'equalp) (let ((pos (position expr vars :test #'equalp))) (make-variable ring (length vars) pos))) ((atom expr) (coerce-coeff ring expr vars)) ((eq (car expr) list-marker) (cons list-marker (p-eval-list (cdr expr)))) (t (case (car expr) (+ (reduce #'p-add (p-eval-list (cdr expr)))) (- (case (length expr) (1 (make-poly-zero)) (2 (poly-uminus ring (p-eval (cadr expr)))) (3 (poly-sub ring-and-order (p-eval (cadr expr)) (p-eval (caddr expr)))) (otherwise (poly-sub ring-and-order (p-eval (cadr expr)) (reduce #'p-add (p-eval-list (cddr expr))))))) (* (if (endp (cddr expr)) ;unary (p-eval (cdr expr)) (reduce #'(lambda (p q) (poly-mul ring-and-order p q)) (p-eval-list (cdr expr))))) (/ ;; A polynomial can be divided by a scalar (cond ((endp (cddr expr)) ;; A special case (/ ?), the inverse (coerce-coeff ring (apply (ring-div ring) (cdr expr)) vars)) (t (let ((num (p-eval (cadr expr))) (denom-inverse (apply (ring-div ring) (cons (funcall (ring-unit ring)) (mapcar #'p-eval-scalar (cddr expr)))))) (scalar-times-poly ring denom-inverse num))))) (expt (cond ((member (cadr expr) vars :test #'equalp) ;;Special handling of (expt var pow) (let ((pos (position (cadr expr) vars :test #'equalp))) (make-variable ring (length vars) pos (caddr expr)))) ((not (and (integerp (caddr expr)) (plusp (caddr expr)))) ;; Negative power means division in coefficient ring ;; Non-integer power means non-polynomial coefficient (coerce-coeff ring expr vars)) (t (poly-expt ring-and-order (p-eval (cadr expr)) (caddr expr))))) (otherwise (coerce-coeff ring expr vars))))))) (defun poly-eval-scalar (expr &optional (ring *ring-of-integers*) &aux (order #'lex>)) "Evaluate a scalar expression EXPR in ring RING." (poly-lc (poly-eval expr nil ring order))) (defun spoly (ring f g) "It yields the S-polynomial of polynomials F and G." (declare (type poly f g)) (let* ((lcm (monom-lcm (poly-lm f) (poly-lm g))) (mf (monom-div lcm (poly-lm f))) (mg (monom-div lcm (poly-lm g)))) (declare (type monom mf mg)) (multiple-value-bind (c cf cg) (funcall (ring-ezgcd ring) (poly-lc f) (poly-lc g)) (declare (ignore c)) (poly-sub ring (scalar-times-poly ring cg (monom-times-poly mf f)) (scalar-times-poly ring cf (monom-times-poly mg g)))))) (defun poly-primitive-part (ring p) "Divide polynomial P with integer coefficients by gcd of its coefficients and return the result." (declare (type poly p)) (if (poly-zerop p) (values p 1) (let ((c (poly-content ring p))) (values (make-poly-from-termlist (mapcar #'(lambda (x) (make-term (term-monom x) (funcall (ring-div ring) (term-coeff x) c))) (poly-termlist p)) (poly-sugar p)) c)))) (defun poly-content (ring p) "Greatest common divisor of the coefficients of the polynomial P. Use the RING structure to compute the greatest common divisor." (declare (type poly p)) (reduce (ring-gcd ring) (mapcar #'term-coeff (rest (poly-termlist p))) :initial-value (poly-lc p))) (defun read-infix-form (&key (stream t)) "Parser of infix expressions with integer/rational coefficients The parser will recognize two kinds of polynomial expressions: - polynomials in fully expanded forms with coefficients written in front of symbolic expressions; constants can be optionally enclosed in (); for example, the infix form X^2-Y^2+(-4/3)*U^2*W^3-5 parses to (+ (- (EXPT X 2) (EXPT Y 2)) (* (- (/ 4 3)) (EXPT U 2) (EXPT W 3)) (- 5)) - lists of polynomials; for example [X-Y, X^2+3*Z] parses to (:[ (- X Y) (+ (EXPT X 2) (* 3 Z))) where the first symbol [ marks a list of polynomials. -other infix expressions, for example [(X-Y)*(X+Y)/Z,(X+1)^2] parses to: (:[ (/ (* (- X Y) (+ X Y)) Z) (EXPT (+ X 1) 2)) Currently this function is implemented using M. Kantrowitz's INFIX package." (read-from-string (concatenate 'string "#I(" (with-output-to-string (s) (loop (multiple-value-bind (line eof) (read-line stream t) (format s "~A" line) (when eof (return))))) ")"))) (defun read-poly (vars &key (stream t) (ring *ring-of-integers*) (order #'lex>)) "Reads an expression in prefix form from a stream STREAM. The expression read from the strem should represent a polynomial or a list of polynomials in variables VARS, over the ring RING. The polynomial or list of polynomials is returned, with terms in each polynomial ordered according to monomial order ORDER." (poly-eval (read-infix-form :stream stream) vars ring order)) (defun string->poly (str vars &key (stream t) (ring *ring-of-integers*) (order #'lex>)) "Converts a string STR to a polynomial in variables VARS." (with-input-from-string (s str) (read-poly vars :stream s :ring ring :order order))) (defun poly->alist (p) "Convert a polynomial P to an association list. Thus, the format of the returned value is ((MONOM[0] . COEFF[0]) (MONOM[1] . COEFF[1]) ...), where MONOM[I] is a list of exponents in the monomial and COEFF[I] is the corresponding coefficient in the ring." (declare (type poly p)) (mapcar #'term->cons (poly-termlist p))) (defun string->alist (str vars) "Convert a string STR representing a polynomial or polynomial list to an association list (... (MONOM . COEFF) ...)." (poly->alist (str->poly str vars)))