descriptive.mac: declare local variable to avoid possibility of name collision.
[maxima.git] / src / rat3b.lisp
blob26b0971e68add0b1952079058d4a2407ba713a56
1 ;;; -*- Mode: Lisp; Package: Maxima; Syntax: Common-Lisp; Base: 10 -*- ;;;;
2 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3 ;;; The data in this file contains enhancements. ;;;;;
4 ;;; ;;;;;
5 ;;; Copyright (c) 1984,1987 by William Schelter,University of Texas ;;;;;
6 ;;; All rights reserved ;;;;;
7 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
8 ;;; (c) Copyright 1980 Massachusetts Institute of Technology ;;;
9 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
11 (in-package :maxima)
13 (macsyma-module rat3b)
15 ;; THIS IS THE NEW RATIONAL FUNCTION PACKAGE PART 2.
16 ;; IT INCLUDES RATIONAL FUNCTIONS ONLY.
18 (defun ralgp (r) (or (palgp (car r)) (palgp (cdr r))))
20 (defun palgp (poly)
21 (cond ((pcoefp poly) nil)
22 ((alg poly) t)
23 (t (do ((p (cdr poly) (cddr p)))
24 ((null p))
25 (and (palgp (cadr p)) (return t))))))
28 (defun ratdx (e *x*)
29 (declare (special *x*))
30 (prog (varlist flag v* genvar *a a trunclist)
31 (declare (special v* *a flag trunclist))
32 (and (member 'trunc (car e) :test #'eq) (setq trunclist (cadddr (cdar e))))
33 (cond ((not (eq (caar e) (quote mrat))) (setq e (ratf e))))
34 (setq varlist (caddar e))
35 (setq genvar (car (cdddar e)))
36 ;; Next cond could be flushed if genvar would shrink with varlist
37 (cond ((> (length genvar) (length varlist))
38 ;; Presumably this produces a copy of GENVAR which has the
39 ;; same length as VARLIST. Why not rplacd?
40 (setq genvar (mapcar #'(lambda (a b) (declare (ignore a)) b)
41 varlist genvar))))
42 (setq *x* (fullratsimp *x*))
43 (newvar *x*)
44 (setq a (mapcan #'(lambda (z)
45 (prog (ff)
46 (newvar
47 (setq ff (fullratsimp (sdiff z *x*))))
48 (orderpointer varlist)
49 (return (list z ff)))) varlist))
50 (setq *a (cons nil a))
51 (mapc #'(lambda(z b)
52 (cond ((null (old-get *a z))(putprop b (rzero) 'diff))
53 ((and(putprop b(cdr (ratf (old-get *a z))) 'diff)
54 (alike1 z *x*))
55 (setq v* b))
56 (t (setq flag t)))) varlist genvar)
58 ;;; causing lisp error - [ 2010843 ] diff of Taylor poly
59 ;;(cond ((and (signp n (cdr (old-get trunclist v*)))
60 ;; (car (old-get trunclist v*))) (return 0)))
62 (and trunclist
63 (return (cons (list 'mrat 'simp varlist genvar trunclist 'trunc)
64 (cond (flag (psdp (cdr e)))
65 (t (psderivative (cdr e) v*))))))
66 (return (cons (list 'mrat 'simp varlist genvar)
67 (cond (flag (ratdx1 (cadr e) (cddr e)))
68 (t (ratderivative (cdr e) v*)))))))
70 (defun ratdx1 (u v)
71 (ratquotient (ratdif (rattimes (cons v 1) (ratdp u) t)
72 (rattimes (cons u 1) (ratdp v) t))
73 (cons (pexpt v 2) 1)))
75 (defun ratdp (p)
76 (cond ((pcoefp p) (rzero))
77 ((rzerop (get (car p) 'diff))
78 (ratdp1 (cons (list (car p) 'foo 1) 1) (cdr p)))
79 (t (ratdp2 (cons (list (car p) 'foo 1) 1)
80 (get (car p) 'diff)
81 (cdr p)))))
83 (defun ratdp1 (x v)
84 (cond ((null v) (rzero))
85 ((equal (car v) 0) (ratdp (cadr v)))
86 (t (ratplus (rattimes (subst (car v) 'foo x) (ratdp (cadr v)) t)
87 (ratdp1 x (cddr v))))))
89 (defun ratdp2 (x dx v)
90 (cond ((null v) (rzero))
91 ((equal (car v) 0) (ratdp (cadr v)))
92 ((equal (car v) 1)
93 (ratplus (ratdp2 x dx (cddr v))
94 (ratplus (rattimes dx (cons (cadr v) 1) t)
95 (rattimes (subst 1 'foo x)
96 (ratdp (cadr v)) t))))
97 (t (ratplus (ratdp2 x dx (cddr v))
98 (ratplus (rattimes dx
99 (rattimes (subst (1- (car v))
100 'foo
102 (cons (ptimes (car v)
103 (cadr v))
107 (rattimes (ratdp (cadr v))
108 (subst (car v) (quote foo) x)
109 t))))))
111 (defun ratderivative (rat var)
112 (let ((num (car rat))
113 (denom (cdr rat)))
114 (cond ((equal 1 denom) (cons (pderivative num var) 1))
115 (t (setq denom (pgcdcofacts denom (pderivative denom var)))
116 (setq num (ratreduce (pdifference (ptimes (cadr denom)
117 (pderivative num var))
118 (ptimes num (caddr denom)))
119 ;RATREDUCE ONLY NEEDS TO BE DONE WITH CONTENT OF GCD WRT VAR.
120 (car denom)))
121 (cond ((pzerop (car num)) num)
122 (t (rplacd num (ptimes (cdr num)
123 (pexpt (cadr denom) 2)))))))))
125 (defun ratdif (x y)
126 (ratplus x (ratminus y)))
128 (defun ratfact (x fn)
129 (cond ((and $keepfloat (or (pfloatp (car x)) (pfloatp (cdr x)))
130 (setq fn 'floatfact) nil))
131 ((not (equal (cdr x) 1))
132 (nconc (funcall fn (car x)) (fixmult (funcall fn (cdr x)) -1)))
133 (t (funcall fn (car x)))))
135 (defun floatfact (p)
136 (destructuring-let (((cont primp) (ptermcont p)))
137 (setq cont (monom->facl cont))
138 (cond ((equal primp 1) cont)
139 (t (append cont (list primp 1))))))
141 (defun ratinvert (y)
142 (ratalgdenom
143 (cond ((pzerop (car y)) (rat-error "`quotient' by `zero'"))
144 ((and modulus (pcoefp (car y)))
145 (cons (pctimes (crecip (car y)) (cdr y)) 1))
146 ((and $keepfloat (floatp (car y)))
147 (cons (pctimes (/ (car y)) (cdr y)) 1))
148 ((pminusp (car y)) (cons (pminus (cdr y)) (pminus (car y))))
149 (t (cons (cdr y) (car y))))))
151 (defun ratminus (x)
152 (cons (pminus (car x)) (cdr x)))
154 (defun ratalgdenom (x)
155 (cond ((not $ratalgdenom) x)
156 ((pcoefp (cdr x)) x)
157 ((and (alg (cdr x))
158 (ignore-rat-err
159 (rattimes (cons (car x) 1)
160 (rainv (cdr x)) t))))
161 (t x)))
163 (defun ratreduce (x y &aux b)
164 (cond ((pzerop y) (rat-error "`quotient' by `zero'"))
165 ((pzerop x) (rzero))
166 ((equal y 1) (cons x 1))
167 ((and $keepfloat (pcoefp y) (or $float (floatp y) (pfloatp x)))
168 (cons (pctimes (quotient 1.0 y) x) 1))
169 (t (setq b (pgcdcofacts x y))
170 (setq b (ratalgdenom (rplacd (cdr b) (caddr b))))
171 (cond ((and modulus (pcoefp (cdr b)))
172 (cons (pctimes (crecip (cdr b)) (car b)) 1))
173 ((pminusp (cdr b))
174 (cons (pminus (car b)) (pminus (cdr b))))
175 (t b)))))
177 (defun ptimes* (p q)
178 (cond ($ratwtlvl (wtptimes p q 0))
179 (t (ptimes p q))))
181 (defun rattimes (x y gcdsw)
182 (cond ($ratfac (facrtimes x y gcdsw))
183 ((and $algebraic gcdsw (ralgp x) (ralgp y))
184 (let ((w (rattimes x y nil)))
185 (ratreduce (car w) (cdr w))))
186 ((equal 1 (cdr x))
187 (cond ((equal 1 (cdr y)) (cons (ptimes* (car x) (car y)) 1))
188 (t (cond (gcdsw (rattimes (ratreduce (car x) (cdr y))
189 (cons (car y) 1) nil))
190 (t (cons (ptimes* (car x) (car y)) (cdr y)))))))
191 ((equal 1 (cdr y)) (rattimes y x gcdsw))
192 (t (cond (gcdsw (rattimes (ratreduce (car x) (cdr y))
193 (ratreduce (car y) (cdr x)) nil))
194 (t (cons (ptimes* (car x) (car y))
195 (ptimes* (cdr x) (cdr y))))))))
197 (defun ratexpt (x n)
198 (cond ((equal n 0) '(1 . 1))
199 ((equal n 1) x)
200 ((minusp n) (ratinvert (ratexpt x (- n))))
201 ($ratwtlvl (ratreduce (wtpexpt (car x) n) (wtpexpt (cdr x) n)))
202 ($algebraic (ratreduce (pexpt (car x) n) (pexpt (cdr x) n)))
203 (t (cons (pexpt (car x) n) (pexpt (cdr x) n)))))
205 (defun ratplus (x y &aux q n)
206 (cond ($ratfac (facrplus x y))
207 ($ratwtlvl
208 (ratreduce
209 (pplus (wtptimes (car x) (cdr y) 0)
210 (wtptimes (car y) (cdr x) 0))
211 (wtptimes (cdr x) (cdr y) 0)))
212 ((and $algebraic (ralgp x) (ralgp y))
213 (ratreduce
214 (pplus (ptimeschk (car x) (cdr y))
215 (ptimeschk (car y) (cdr x)))
216 (ptimeschk (cdr x) (cdr y))))
217 ((equal 1 (cdr x))
218 (cond ((equal 0 (car x)) y)
219 ((equal 1 (cdr y)) (cons (pplus (car x) (car y)) 1))
220 (t (cons (pplus (ptimes (car x) (cdr y)) (car y)) (cdr y)))))
221 ((equal 1 (cdr y))
222 (cond ((equal 0 (car y)) x)
223 (t (cons (pplus (ptimes (car y) (cdr x)) (car x)) (cdr x)))))
224 (t (setq q (pgcdcofacts (cdr x) (cdr y)))
225 (setq n (pplus (ptimes (car x)(caddr q))
226 (ptimes (car y)(cadr q))))
227 (if (cadddr q) ; denom factor from algebraic gcd
228 (setq n (ptimes n (cadddr q))))
229 (ratreduce n
230 (ptimes (car q)
231 (ptimes (cadr q) (caddr q)))))))
233 (defun ratquotient (x y)
234 (rattimes x (ratinvert y) t))
236 ;; THIS IS THE END OF THE NEW RATIONAL FUNCTION PACKAGE PART 2.
237 ;; IT INCLUDES RATIONAL FUNCTIONS ONLY.