Fix bug #3996: parse_string fails to parse string which contains semicolon
[maxima.git] / src / rat3d.lisp
blobe273e1d1636a8f454d851d633e6ed20a0e1d5f6f
1 ;;; -*- Mode: Lisp; Package: Maxima; Syntax: Common-Lisp; Base: 10 -*- ;;;;
2 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
3 ;;; The data in this file contains enhancments. ;;;;;
4 ;;; ;;;;;
5 ;;; Copyright (c) 1984,1987 by William Schelter,University of Texas ;;;;;
6 ;;; All rights reserved ;;;;;
7 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
8 ;;; (c) Copyright 1981 Massachusetts Institute of Technology ;;;
9 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
11 (in-package :maxima)
13 (macsyma-module rat3d)
15 ;; THIS IS THE NEW RATIONAL FUNCTION PACKAGE PART 4.
16 ;; IT INCLUDES THE POLYNOMIAL FACTORING ROUTINES.
18 (declare-top (special *min* *mx* *odr* nn* scanmapp *checkagain adn*))
20 (declare-top (special $factorflag $dontfactor $algebraic $ratfac))
22 ;;There really do seem to be two such variables...
23 (declare-top (special alpha *alpha gauss genvar minpoly*))
25 (defmvar *irreds nil)
26 (defmvar algfac* nil)
27 (defmvar low* nil)
29 (defmvar $intfaclim t)
30 (defmvar $berlefact t)
32 (defmvar $factor_max_degree 1000
33 "If set to an integer n, some potentially large (many factors) polynomials
34 of degree > n won't be factored, preventing huge memory allocations and
35 stack overflows. Set to zero to deactivate."
36 fixnum)
37 (putprop '$factor_max_degree 'posintegerset 'assign)
39 (defmvar $factor_max_degree_print_warning t
40 "Print a warning message when a polynomial is not factored because its
41 degree is larger than $factor_max_degree?"
42 boolean)
44 (defun listovars (q)
45 (cond ((pcoefp q) nil)
46 (t (let ((ans nil))
47 (declare (special ans))
48 (listovars0 q)))))
50 (defun listovars0 (q)
51 (declare (special ans))
52 (cond ((pcoefp q) ans)
53 ((member (car q) ans :test #'eq) (listovars1 (cdr q)))
54 (t (push (car q) ans)
55 (listovars1 (cdr q)))))
57 (defun listovars1 (ql)
58 (declare (special ans))
59 (cond ((null ql) ans)
60 (t (listovars0 (cadr ql)) (listovars1 (cddr ql)))))
62 (defun dontfactor (y)
63 (cond ((or (null $dontfactor) (equal $dontfactor '((mlist)))) nil)
64 ((memalike (pdis (make-poly y)) $dontfactor) t)))
66 (defun removealg (l)
67 (loop for var in l
68 unless (algv var) collect var))
70 (defun degvecdisrep (degl)
71 (do ((l degl (cdr l))
72 (gv genvar (cdr gv))
73 (ans 1))
74 ((null l) ans)
75 (and (> (car l) 0)
76 (setq ans (list (car gv) (car l) ans)))))
78 (defun ptermcont (p)
79 (let ((tcont (degvecdisrep (pmindegvec p)))
80 ($algebraic))
81 (list tcont (pquotient p tcont))))
83 (defun pmindegvec (p)
84 (minlist (let ((*odr* (putodr (reverse genvar)))
85 (nn* (1+ (length genvar)))
86 (*min* t))
87 (degvector nil 1 p))))
89 (defun pdegreevector (p)
90 (maxlist (let ((*odr* (putodr (reverse genvar)))
91 (nn* (1+ (length genvar)))
92 (*mx* t))
93 (degvector nil 1 p))))
95 (defun maxlist(l) (maxminl l t))
97 (defun minlist(l) (maxminl l nil))
99 (defun maxminl (l switch)
100 (do ((l1 (copy-list (car l)))
101 (ll (cdr l) (cdr ll)))
102 ((null ll) l1)
103 (do ((v1 l1 (cdr v1))
104 (v2 (car ll) (cdr v2)))
105 ((null v1))
106 (cond (switch
107 (cond ((> (car v2) (car v1))
108 (rplaca v1 (car v2)))))
109 (t (cond ((< (car v2) (car v1))
110 (rplaca v1 (car v2)))))))))
112 (defun quick-sqfr-check (p var)
113 (let ((gv (delete var (listovars p) :test #'equal))
114 (modulus (or modulus *alpha))
115 (l) (p0))
116 (if $algebraic (setq gv (removealg gv)))
117 (and gv
118 (not (pzerop (pcsubsty (setq l (rand (length gv) modulus))
119 gv (pmod (p-lc p)))))
120 (not (pcoefp (setq p0 (pcsubsty l gv (pmod p)))))
121 (pcoefp (pgcd p0 (pderivative p0 (car p0))))
122 (list l gv p0))))
124 (defun monom->facl (p)
125 (cond ((pcoefp p) (if (equal p 1) nil (list p 1)))
126 (t (list* (pget (car p)) (cadr p) (monom->facl (caddr p))))))
128 (defun psqfr (p)
129 (prog (r varl var mult factors)
130 (cond ((pcoefp p) (return (cfactor p)))
131 ((pminusp p) (return (cons -1 (cons 1 (psqfr (pminus p)))))))
132 (desetq (factors p) (ptermcont p))
133 (setq factors (monom->facl factors))
134 (cond ((pcoefp p) (go end)))
135 (setq varl (sort (listovars p) 'pointergp))
136 setvar
137 (setq var (car varl) varl (cdr varl) mult 0)
138 (cond ((pointergp var (car p)) (go nextvar))
139 ((dontfactor var)
140 (setq factors (cons p (cons 1 factors))
141 p 1)
142 (go end)))
143 (cond ((quick-sqfr-check p var) ;QUICK SQFR CHECK BY SUBST.
144 (setq r (oldcontent p))
145 (setq p (car r) factors (cons (cadr r)
146 (cons 1 factors)))
147 (go nextvar)))
148 (setq r (pderivative p var))
149 (cond ((pzerop r) (go nextvar)))
150 (cond ((and modulus (not (pcoefp r))) (pmonicize (cdr r))))
151 (setq p (pgcdcofacts p r))
152 (and algfac* (cadddr p) (setq adn* (ptimes adn* (cadddr p))))
153 (setq r (cadr p) ; PRODUCT OF P[I]
154 p (car p))
155 a (setq r (pgcdcofacts r p)
156 p (caddr r)
157 mult (1+ mult))
158 (and algfac* (cadddr r) (setq adn* (ptimes adn* (cadddr r))))
159 (cond ((not (pcoefp (cadr r)))
160 (setq factors
161 (cons (cadr r)
162 (cons mult factors)))))
163 (cond ((not (pcoefp (setq r (car r)))) (go a)))
164 nextvar
165 (cond ((pcoefp p) (go end))
166 (varl (go setvar))
167 (modulus (setq factors (append (fixmult (psqfr (pmodroot p))
168 modulus)
169 factors))
170 (setq p 1)))
171 end (setq p (cond ((equal 1 p) nil)
172 (t (cfactor p))))
173 (return (append p factors))))
175 (defun fixmult (l n)
176 (do ((l l (cddr l)))
177 ((null l))
178 (rplaca (cdr l) (* n (cadr l))))
181 (defun pmodroot (p)
182 (cond ((pcoefp p) p)
183 ((alg p) (pexpt p (expt modulus (1- (car (alg p))))))
184 (t (cons (car p) (pmodroot1 (cdr p))))))
186 (defun pmodroot1 (x)
187 (cond ((null x) x)
188 (t (cons (truncate (car x) modulus)
189 (cons (pmodroot (cadr x))
190 (pmodroot1 (cddr x)))))))
192 (defmvar $savefactors nil "If t factors of ratreped forms will be saved")
194 (defvar checkfactors () "List of saved factors")
196 (defun savefactors (l)
197 (when $savefactors
198 (savefactor1 (car l))
199 (savefactor1 (cdr l)))
202 (defun savefactor1 (p)
203 (unless (or (pcoefp p)
204 (ptzerop (p-red p))
205 (member p checkfactors :test #'equal))
206 (push p checkfactors)))
208 (defun heurtrial1 (poly facs)
209 (prog (h j)
210 (setq h (pdegreevector poly))
211 (cond ((or (member 1 h :test #'equal) (member 2 h :test #'equal)) (return (list poly))))
212 (cond ((null facs) (return (list poly))))
213 (setq h (pgcd poly (car facs)))
214 (return (cond ((pcoefp h) (heurtrial1 poly (cdr facs)))
215 ((pcoefp (setq j (pquotient poly h)))
216 (heurtrial1 poly (cdr facs)))
217 (t (heurtrial (list h j) (cdr facs)))))))
219 (defun heurtrial (x facs)
220 (cond ((null x) nil)
221 (t (nconc (heurtrial1 (car x) facs)
222 (heurtrial (cdr x) facs)))))
225 (defun pfactorquad (p)
226 (prog (a b c d $dontfactor l v)
227 (cond((or (onevarp p)(equal modulus 2))(return (list p))))
228 (setq l (pdegreevector p))
229 (cond ((not (member 2 l :test #'equal)) (return (list p))))
230 (setq l (nreverse l) v (reverse genvar)) ;FIND MOST MAIN VAR
231 loop (cond ((equal (car l) 2) (setq v (car v)))
232 (t (setq l (cdr l)) (setq v (cdr v)) (go loop)))
233 (desetq (a . c) (bothprodcoef (make-poly v 2 1) p))
234 (desetq (b . c) (bothprodcoef (make-poly v 1 1) c))
235 (setq d (pgcd (pgcd a b) c))
236 (cond ((pcoefp d) nil)
237 (t (setq *irreds (nconc *irreds (pfactor1 d)))
238 (return (pfactorquad (pquotient p d)))))
239 (setq d (pplus (pexpt b 2) (ptimes -4 (ptimes a c))))
240 (return
241 (cond ((setq c (pnthrootp d 2))
242 (setq d (ratreduce (pplus b c) (ptimes 2 a)))
243 (setq d (pabs (pplus (ptimes (make-poly v) (cdr d))
244 (car d))))
245 (setq *irreds (nconc *irreds (list d (pquotient p d))))
246 nil)
247 (modulus (list p)) ;NEED TO TAKE SQRT(INT. MOD P) LCF.
248 (t (setq *irreds (nconc *irreds (list p)))nil)))))
250 (defmfun $isqrt (x) ($inrt x 2))
252 (defmfun $inrt (x n)
253 (cond ((not (integerp (setq x (mratcheck x))))
254 (cond ((equal n 2) (list '($isqrt) x)) (t (list '($inrt) x n))))
255 ((zerop x) x)
256 ((not (integerp (setq n (mratcheck n)))) (list '($inrt) x n))
257 (t (car (iroot (abs x) n)))))
259 (defun iroot (a n) ; computes a^(1/n) see Fitch, SIGSAM Bull Nov 74
260 (cond ((< (integer-length a) n) (list 1 (1- a)))
261 (t ;assumes integer a>0 n>=2
262 (do ((x (expt 2 (1+ (truncate (integer-length a) n)))
263 (- x (truncate (+ n1 bk) n)))
264 (n1 (1- n)) (xn) (bk))
265 (nil)
266 (cond ((signp le (setq bk (- x (truncate a (setq xn (expt x n1))))))
267 (return (list x (- a (* x xn))))))))))
269 (defmfun $nthroot (p n)
270 (if (and (integerp n) (> n 0))
271 (let ((k (pnthrootp (cadr ($rat p)) n)))
272 (if k (pdis k) (merror (intl:gettext "nthroot: ~M is not a ~M power") p (format nil "~:r" n))))
273 (merror (intl::gettext "nthroot: ~M is not a positive integer") n)))
275 (defun pnthrootp (p n)
276 (ignore-rat-err (pnthroot p n)))
278 (defun pnthroot (poly n)
279 (cond ((equal n 1) poly)
280 ((pcoefp poly) (cnthroot poly n))
281 (t (let* ((var (p-var poly))
282 (ans (make-poly var (cquotient (p-le poly) n)
283 (pnthroot (p-lc poly) n)))
284 (ae (p-terms (pquotient (pctimes n (leadterm poly)) ans))))
285 (do ((p (psimp var (p-red poly))
286 (pdifference poly (pexpt ans n))))
287 ((pzerop p) ans)
288 (cond ((or (pcoefp p) (not (eq (p-var p) var))
289 (> (car ae) (p-le p)))
290 (rat-error "pnthroot error (should have been caught)")))
291 (setq ans (nconc ans (ptptquotient (cdr (leadterm p)) ae)))
292 )))))
294 (defun cnthroot(c n)
295 (cond ((minusp c)
296 (cond ((oddp n) (- (cnthroot (- c) n)))
297 (t (rat-error "cnthroot error (should have been caught"))))
298 ((zerop c) c)
299 ((zerop (cadr (setq c (iroot c n)))) (car c))
300 (t (rat-error "cnthroot error2 (should have been caught"))))
303 (defun pabs (x) (cond ((pminusp x) (pminus x)) (t x)))
305 (defun pfactorlin (p l)
306 (do ((degl l (cdr degl))
307 (v genvar (cdr v))
308 (a)(b))
309 ((null degl) nil)
310 (cond ((and (= (car degl) 1)
311 (not (algv (car v))))
312 (desetq (a . b) (bothprodcoef (make-poly (car v)) p))
313 (setq a (pgcd a b))
314 (return (cons (pquotientchk p a)
315 (cond ((equal a 1) nil)
316 (t (pfactor1 a)))))))))
319 (defun ffactor (l fn &aux (alpha alpha))
320 ;; (declare (special varlist)) ;i suppose...
321 (prog (q)
322 (cond ((and (null $factorflag) (mnump l)) (return l))
323 ((or (atom l) algfac* modulus) nil)
324 ((and (not gauss)(member 'irreducible (cdar l) :test #'eq))(return l))
325 ((and gauss (member 'irreducibleg (cdar l) :test #'eq)) (return l))
326 ((and (not gauss)(member 'factored (cdar l) :test #'eq))(return l))
327 ((and gauss (member 'gfactored (cdar l) :test #'eq)) (return l)))
328 (newvar l)
329 (if algfac* (setq varlist (cons alpha (remove alpha varlist :test #'equal))))
330 (setq q (ratrep* l))
331 (when algfac*
332 (setq alpha (cadr (ratrep* alpha)))
333 (setq minpoly* (subst (car (last genvar))
334 (car minpoly*)
335 minpoly*)))
336 (mapc #'(lambda (y z) (putprop y z (quote disrep)))
337 genvar
338 varlist)
339 (return (retfactor (cdr q) fn l))))
341 (defun factorout1 (l p)
342 (do ((gv genvar (cdr gv))
343 (dl l (cdr dl))
344 (ans))
345 ((null dl) (list ans p))
346 (cond ((zerop (car dl)))
347 (t (setq ans (cons (pget (car gv)) (cons (car dl) ans))
348 p (pquotient p (list (car gv) (car dl) 1)))))))
350 (defun factorout (p)
351 (cond ((and (pcoefp (ptterm (cdr p) 0))
352 (not (zerop (ptterm (cdr p) 0))))
353 (list nil p))
354 (t (factorout1 (pmindegvec p) p))))
356 (defun pfactor (p &aux ($algebraic algfac*))
357 (cond ((pcoefp p) (cfactor p))
358 ($ratfac (pfacprod p))
359 (t (setq p (factorout p))
360 (cond ((equal (cadr p) 1) (car p))
361 ((numberp (cadr p)) (append (cfactor (cadr p)) (car p)))
362 (t (let ((cont (cond (modulus (list (leadalgcoef (cadr p)) (monize (cadr p))))
363 (algfac* (algcontent (cadr p)))
364 (t (pcontent (cadr p))))))
365 (nconc
366 (cond ((equal (car cont) 1) nil)
367 (algfac*
368 (cond (modulus (list (car cont) 1))
369 ((equal (car cont) '(1 . 1)) nil)
370 ((equal (cdar cont) 1) (list (caar cont) 1))
371 (t (list (caar cont) 1 (cdar cont) -1))))
372 (t (cfactor (car cont))))
373 (pfactor11 (psqfr (cadr cont)))
374 (car p))))))))
376 (defun pfactor11 (p)
377 (cond ((null p) nil)
378 ((numberp (car p))
379 (cons (car p) (cons (cadr p) (pfactor11 (cddr p)))))
380 (t (let* ((adn* 1)
381 (f (pfactor1 (car p))))
382 (nconc (if (equal adn* 1) nil
383 (list adn* (- (cadr p))))
384 (do ((l f (cdr l))
385 (ans nil (cons (car l) (cons (cadr p) ans))))
386 ((null l) ans))
387 (pfactor11 (cddr p)))))))
389 (defun pfactor1 (p) ;ASSUMES P SQFR
390 (prog (factors *irreds *checkagain)
391 (cond ((dontfactor (car p)) (return (list p)))
392 ((and (not (zerop $factor_max_degree)) (> (apply 'max (pdegreevector p)) $factor_max_degree))
393 (when $factor_max_degree_print_warning
394 (mformat t "Refusing to factor polynomial ~M because its degree exceeds factor_max_degree (~M)~%" (pdis p) $factor_max_degree))
395 (return (list p)))
396 ((onevarp p)
397 (cond ((setq factors (factxn+-1 p))
398 (if (and (not modulus)
399 (or gauss (not algfac*)))
400 (setq *irreds factors
401 factors nil))
402 (go out))
403 ((and (not algfac*) (not modulus)
404 (not (equal (cadr p) 2)) (estcheck (cdr p)))
405 (return (list p))))))
406 (and (setq factors (pfactorlin p (pdegreevector p)))
407 (return factors))
408 (setq factors(if (or algfac* modulus) (list p) ;SQRT(NUM. CONT OF DISC)
409 (pfactorquad p)))
410 (cond ((null factors)(go out)))
411 (when checkfactors
412 (setq factors (heurtrial factors checkfactors))
413 (setq *checkagain (cdr factors)))
414 out (return (nconc *irreds (mapcan (function pfactorany) factors)))))
416 (defmvar $homog_hack nil) ; If T tries to eliminate homogeneous vars.
418 (declare-top (special *hvar *hmat))
420 (defun pfactorany (p)
421 (cond (*checkagain (let (checkfactors) (pfactor1 p)))
422 ((and $homog_hack (not algfac*) (not (onevarp p)))
423 (let ($homog_hack *hvar *hmat)
424 (mapcar #'hexpand (pfactor (hreduce p)))))
425 ($berlefact (factor1972 p))
426 (t (pkroneck p))))
429 (defun retfactor (x fn l &aux (a (ratfact x fn)))
430 (prog ()
431 b (cond ((null (cddr a))
432 (setq a (retfactor1 (car a) (cadr a)))
433 (return (cond ((and scanmapp (not (atom a)) (not (atom l))
434 (eq (caar a) (caar l)))
435 (tagirr l))
436 (t a))))
437 ((equal (car a) 1) (setq a (cddr a)) (go b))
438 (t (setq a (map2c #'retfactor1 a))
439 (return (cond ((member 0 a) 0)
440 (t (setq a (let (($expop 0) ($expon 0)
441 $negdistrib)
442 (muln (sortgreat a) t)))
443 (cond ((not (mtimesp a)) a)
444 (t (cons '(mtimes simp factored)
445 (cdr a)))))))))))
447 ;;; FOR LISTS OF ARBITRARY EXPRESSIONS
448 (defun retfactor1 (p e)
449 (power (tagirr (simplify (pdisrep p))) e))
451 (defun tagirr (x)
452 (cond ((or (atom x) (member 'irreducible (cdar x) :test #'eq)) x)
453 (t (cons (append (car x) '(irreducible)) (cdr x)))))
455 (defun revsign (x)
456 (cond ((null x) nil)
457 (t (cons (car x)
458 (cons (- (cadr x)) (revsign (cddr x)))))))
460 ;; THIS IS THE END OF THE NEW RATIONAL FUNCTION PACKAGE PART 4