transl: do not assume a catch's mode based on the last body form
[maxima.git] / src / comm2.lisp
blob94b96fb37f2a81beda5060446f263647e4a146eb
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 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
9 (in-package :maxima)
10 ;; ** (c) Copyright 1982 Massachusetts Institute of Technology **
12 (macsyma-module comm2)
14 ;;;; DIFF2
16 (defun diffint (e x)
17 (let (a)
18 (cond ((null (cdddr e))
19 (cond ((alike1 x (caddr e)) (cadr e))
20 ((and (not (atom (caddr e))) (atom x) (not (free (caddr e) x)))
21 (mul2 (cadr e) (sdiff (caddr e) x)))
22 ((or ($constantp (setq a (sdiff (cadr e) x)))
23 (and (atom (caddr e)) (free a (caddr e))))
24 (mul2 a (caddr e)))
25 (t (simplifya (list '(%integrate) a (caddr e)) t))))
26 ((alike1 x (caddr e)) (addn (diffint1 (cdr e) x x) t))
27 (t (addn (cons (if (equal (setq a (sdiff (cadr e) x)) 0)
29 (simplifya (list '(%integrate) a (caddr e)
30 (cadddr e) (car (cddddr e)))
31 t))
32 (diffint1 (cdr e) x (caddr e)))
33 t)))))
35 (defun diffint1 (e x y)
36 (let ((u (sdiff (cadddr e) x)) (v (sdiff (caddr e) x)))
37 (list (if (pzerop u) 0 (mul2 u (maxima-substitute (cadddr e) y (car e))))
38 (if (pzerop v) 0 (mul3 v (maxima-substitute (caddr e) y (car e)) -1)))))
40 (defun diffsumprod (e x)
41 (cond ((or (not ($mapatom x)) (not (free (cadddr e) x)) (not (free (car (cddddr e)) x)))
42 (diff%deriv (list e x 1)))
43 ((eq (caddr e) x) 0)
44 (t (let ((u (sdiff (cadr e) x)))
45 (setq u (simplifya (list '(%sum)
46 (if (eq (caar e) '%sum) u (div u (cadr e)))
47 (caddr e) (cadddr e) (car (cddddr e)))
48 t))
49 (if (eq (caar e) '%sum) u (mul2 e u))))))
51 (defun difflaplace (e x)
52 (cond ((or (not (atom x)) (eq (cadddr e) x)) (diff%deriv (list e x 1)))
53 ((eq (caddr e) x) 0)
54 (t ($laplace (sdiff (cadr e) x) (caddr e) (cadddr e)))))
56 (defun diff-%at (e x)
57 (cond ((freeof x e) 0)
58 ((not (freeofl x (hand-side (caddr e) 'r))) (diff%deriv (list e x 1)))
59 (t ($at (sdiff (cadr e) x) (caddr e)))))
61 (defun diffncexpt (e x)
62 (let ((base* (cadr e))
63 (pow (caddr e)))
64 (cond ((and (mnump pow) (or (not (fixnump pow)) (< pow 0))) ; POW cannot be 0
65 (diff%deriv (list e x 1)))
66 ((and (atom base*) (eq base* x) (free pow base*))
67 (mul2* pow (list '(mncexpt) base* (add2 pow -1))))
68 ((fixnump pow)
69 (let ((deriv (sdiff base* x))
70 (ans nil))
71 (do ((i 0 (1+ i))) ((= i pow))
72 (push (list '(mnctimes) (list '(mncexpt) base* i)
73 (list '(mnctimes) deriv
74 (list '(mncexpt) base* (- pow 1 i))))
75 ans))
76 (addn ans nil)))
77 ((and (not (depends pow x)) (or (atom pow) (and (atom base*) (free pow base*))))
78 (let ((deriv (sdiff base* x))
79 (index (gensumindex)))
80 (simplifya
81 (list '(%sum)
82 (list '(mnctimes) (list '(mncexpt) base* index)
83 (list '(mnctimes) deriv
84 (list '(mncexpt) base*
85 (list '(mplus) pow -1 (list '(mtimes) -1 index)))))
86 index 0 (list '(mplus) pow -1)) nil)))
87 (t (diff%deriv (list e x 1))))))
89 (defun stotaldiff (e)
90 (cond ((or (mnump e) (constant e)) 0)
91 ((or (atom e) (member 'array (cdar e) :test #'eq))
92 (let ((w (mget (if (atom e) e (caar e)) 'depends)))
93 (if w (cons '(mplus)
94 (mapcar #'(lambda (x)
95 (list '(mtimes) (chainrule e x) (list '(%del) x)))
96 w))
97 (list '(%del) e))))
98 ((specrepp e) (stotaldiff (specdisrep e)))
99 ((eq (caar e) 'mnctimes)
100 (let (($dotdistrib t))
101 (add2 (ncmuln (cons (stotaldiff (cadr e)) (cddr e)) t)
102 (ncmul2 (cadr e) (stotaldiff (ncmuln (cddr e) t))))))
103 ((eq (caar e) 'mncexpt)
104 (if (and (fixnump (caddr e)) (> (caddr e) 0))
105 (stotaldiff (list '(mnctimes) (cadr e)
106 (ncpower (cadr e) (1- (caddr e)))))
107 (list '(%derivative) e)))
108 (t (addn (cons 0 (mapcar #'(lambda (x)
109 (mul2 (sdiff e x) (list '(%del simp) x)))
110 (extractvars (margs e))))
111 t))))
113 (defun extractvars (e &aux vars)
114 (cond ((null e) nil)
115 ((atom (car e))
116 (cond ((not (maxima-constantp (car e)))
117 (cond ((setq vars (mget (car e) 'depends))
118 ;; The symbol has dependencies. Put the dependencies on
119 ;; the list of extracted vars.
120 (union* vars (extractvars (cdr e))))
122 ;; Put the symbol on the list of extracted vars.
123 (union* (ncons (car e)) (extractvars (cdr e))))))
124 (t (extractvars (cdr e)))))
125 ((member 'array (cdaar e) :test #'eq)
126 (union* (ncons (car e)) (extractvars (cdr e))))
127 (t (union* (extractvars (cdar e)) (extractvars (cdr e))))))
129 ;;;; AT
131 (defmfun $atvalue (exp eqs val)
132 (let (dl vl fun)
133 (cond ((notloreq eqs) (improper-arg-err eqs '$atvalue))
134 ((or (atom exp) (and (eq (caar exp) '%derivative) (atom (cadr exp))))
135 (improper-arg-err exp '$atvalue)))
136 (cond ((not (eq (caar exp) '%derivative))
137 (setq fun (caar exp)
138 vl (cdr exp)
139 dl (make-list (length vl) :initial-element 0)))
140 (t (setq fun (caaadr exp) vl (cdadr exp))
141 (dolist (v vl)
142 (setq dl (nconc dl (ncons (or (getf (cddr exp) v) 0)))))))
143 (if (or (mopp fun) (eq fun 'mqapply)) (improper-arg-err exp '$atvalue))
144 (atvarschk vl)
145 (do ((vl1 vl (cdr vl1)) (l atvars (cdr l))) ((null vl1))
146 (if (and (symbolp (car vl1)) (not (kindp (car vl1) '$constant)))
147 (setq val (maxima-substitute (car l) (car vl1) val))
148 (improper-arg-err (cons '(mlist) vl) '$atvalue)))
149 (setq eqs (if (eq (caar eqs) 'mequal) (list eqs) (cdr eqs)))
150 (setq eqs (do ((eqs eqs (cdr eqs)) (l)) ((null eqs) l)
151 (if (not (member (cadar eqs) vl :test #'eq))
152 (improper-arg-err (car eqs) '$atvalue))
153 (setq l (nconc l (ncons (cons (cadar eqs) (caddar eqs)))))))
154 (setq vl (do ((vl vl (cdr vl)) (l)) ((null vl) l)
155 (setq l (nconc l (ncons (cdr (or (assoc (car vl) eqs :test #'eq)
156 (cons nil munbound))))))))
157 (do ((atvalues (mget fun 'atvalues) (cdr atvalues)))
158 ((null atvalues)
159 (mputprop fun (cons (list dl vl val) (mget fun 'atvalues)) 'atvalues))
160 (when (and (equal (caar atvalues) dl) (equal (cadar atvalues) vl))
161 (rplaca (cddar atvalues) val) (return nil)))
162 (add2lnc fun $props)
163 val))
165 (defprop %at simp-%at operators)
167 (defun simp-%at (expr ignored simp-flag)
168 (declare (ignore ignored))
169 (twoargcheck expr)
170 (let* ((arg (simpcheck (cadr expr) simp-flag))
171 (e (resimplify (caddr expr)))
172 (eqn (if ($listp e)
173 (if (= ($length e) 1) ($first e) (cons '(mlist simp) (cdr ($sort e))))
174 e)))
175 (cond (($constantp arg) arg)
176 ((alike1 eqn '((mlist))) arg)
177 ((at-not-dependent eqn arg))
178 (t (eqtest (list '(%at) arg eqn) expr)))))
180 ;; Remove any variable from EQN if ARG is not dependent on it.
181 (defun at-not-dependent (eqn arg)
182 (if (eq (caar eqn) 'mequal)
183 (setq eqn (list '(mlist) eqn)))
184 (multiple-value-bind (e0 e1) (at-not-dependent-find-vars eqn arg)
185 (if e0
186 (if e1
187 (let*
188 ((e1 (mapcar #'(lambda (x) (list '(mequal) x ($assoc x eqn))) e1))
189 (eqn1 (if (= (length e1) 1) (first e1) (cons '(mlist) e1))))
190 (list '(%at) arg eqn1))
191 arg))))
193 ;; Test dependence via derivative to account for declared dependencies.
194 (defun at-not-dependent-find-vars (eqn arg)
195 (let ((e (mapcar #'second (rest eqn))))
196 (partition-by #'(lambda (x) (at-not-dependent-find-vars-1 x arg)) e)))
198 (defun at-not-dependent-find-vars-1 (x arg)
199 (if ($mapatom x)
200 (eql (mfuncall '$diff arg x) 0)
201 ;; We might be called with something like -1*x as the variable.
202 ;; (That might or might not be a bug in itself, but let it go for the moment.)
203 ;; Try to extract a variable and test for dependence on that.
204 ;; If there are 2 or more variables, return NIL (i.e., not at-not-dependent).
205 (let ((v ($listofvars x)))
206 (if (eql ($length v) 1)
207 (at-not-dependent-find-vars-1 ($first v) arg)))))
209 (defmfun $at (expr ateqs)
210 (if (notloreq ateqs) (improper-arg-err ateqs '$at))
211 (atscan (let ((*atp* t)) ($psubstitute ateqs expr)) ateqs))
213 (defun atscan (expr ateqs)
214 (cond ((or (atom expr)
215 (eq (caar expr) 'mrat)
216 (like ateqs '((mlist))))
217 expr)
218 ((eq (caar expr) '%derivative)
219 (or (and (not (atom (cadr expr)))
220 (let ((vl (cdadr expr)) dl)
221 (dolist (v vl)
222 (setq dl (nconc dl (ncons (or (getf (cddr expr) v) 0)))))
223 (atfind (caaadr expr)
224 (cdr ($psubstitute ateqs (cons '(mlist) vl)))
225 dl)))
226 (list '(%at) expr ateqs)))
227 ((member (caar expr) dummy-variable-operators :test #'eq)
228 (list '(%at) expr ateqs))
229 ((at1 expr))
230 (t (recur-apply #'(lambda (x) (atscan x ateqs)) expr))))
232 (defun at1 (expr)
233 (atfind (caar expr) (cdr expr) (make-list (length (cdr expr)) :initial-element 0)))
235 (defun atfind (fun vl dl)
236 (do ((atvalues (mget fun 'atvalues) (cdr atvalues)))
237 ((null atvalues))
238 (and (equal (caar atvalues) dl)
239 (do ((l (cadar atvalues) (cdr l)) (vl vl (cdr vl)))
240 ((null l) t)
241 (if (and (not (equal (car l) (car vl)))
242 (not (eq (car l) munbound)))
243 (return nil)))
244 (return (prog2
245 (atvarschk vl)
246 (substitutel vl atvars (caddar atvalues)))))))
248 (defmvar $logconcoeffp nil)
250 (defmfun ($logcontract :properties ((evfun t))) (e)
251 (lgcreciprocal (logcon e))) ; E is assumed to be simplified.
253 (defun logcon (e)
254 (cond ((atom e) e)
255 ((member (caar e) '(mplus mtimes) :test #'eq)
256 (if (not (lgcsimplep e)) (setq e (lgcsort e)))
257 (cond ((mplusp e) (lgcplus e))
258 ((mtimesp e) (lgctimes e))
259 (t (logcon e))))
260 (t (recur-apply #'logcon e))))
262 ;; The logcontract algorithm for a sum.
264 ;; The function accumulates the arguments of things like log(a)+log(b) into a
265 ;; list called LOG. It calls out to lgctimes to deal with things like
266 ;; a*log(b). When all the arguments have been processed, it simplifies all the
267 ;; logarithmic arguments using sratsimp.
268 (defun lgcplus (e)
269 (let ((log) (notlogs))
270 (dolist (arg (cdr e))
271 (cond
272 ((atom arg) (push arg notlogs))
273 ;; Only gather up log(x), not log[x]. It's not particularly obvious
274 ;; whether log(x)+log[y] should become log(x*y) or log[x*y], so we just
275 ;; ignore the fact that log[x] is a logarithm.
276 ((and (eq (caar arg) '%log)
277 (not (member 'array (car arg))))
278 (push (logcon (second arg)) log))
279 ((eq (caar arg) 'mtimes)
280 (let ((y (lgctimes arg)))
281 (if (or (atom y) (not (eq (caar y) '%log)))
282 (push y notlogs)
283 (push (cadr y) log))))
285 (push (logcon arg) notlogs))))
286 (cond
287 ((null log)
288 (subst0 (cons '(mplus) (nreverse notlogs)) e))
290 (let ((simplified-log (lgcsimp
291 (let (($ratfac t))
292 (sratsimp (muln log t))))))
293 (addn (cons simplified-log notlogs) t))))))
295 ;; The logcontract algorithm for a product
297 ;; The main transformation this does is of the form 3*log(x) => log(x^3). To
298 ;; make this work, we find the first %log term and insert any coefficients we
299 ;; find into that. Coefficients are identified by LOGCONCOEFFP, which checks the
300 ;; $LOGCONCOEFFP user variable.
301 (defun lgctimes (e)
302 ;; Apply logcontract to the arguments. It's possible that the subsequent
303 ;; simplification means that the result isn't a product any more. In that
304 ;; case, just return it.
305 (setq e (subst0 (cons '(mtimes) (mapcar 'logcon (cdr e))) e))
306 (if (not (mtimesp e))
308 (let ((log) (notlogs) (decints))
309 (dolist (arg (cdr e))
310 (cond ((and (null log) (not (atom arg))
311 (eq (caar arg) '%log) (not (equal (cadr arg) -1)))
312 (setq log (cadr arg)))
313 ((logconcoeffp arg) (push arg decints))
314 (t (setq notlogs (push arg notlogs)))))
315 (cond
316 ((or (null log) (null decints)) e)
317 (t (muln (cons (lgcsimp (power log (muln decints t)))
318 notlogs)
319 t))))))
321 (defun lgcsimp (e)
322 (cond ((atom e)
323 ;; e.g. log(1) -> 0, or log(%e) -> 1
324 (simplify (list '(%log) e)))
325 ((and (mexptp e) (eq (cadr e) '$%e))
326 ;; log(%e^expr) -> expr
327 (simplify (list '(%log) e)))
329 (list '(%log simp) e))))
331 ;; Tests that its argument is a sum of terms that are "simple".
333 ;; A "simple" term is either completely free of logarithms, is a logarithm
334 ;; itself, or is a number times a logarithm.
336 ;; This function assumes that its argument is not an atom.
337 (defun lgcsimplep (e)
338 (flet ((lgc-nonsimple-arg-p (arg)
339 (not (or (atom arg)
340 (eq (caar arg) '%log)
341 (not (isinop arg '%log))
342 ;; Product of a number with a logarithm e.g. 3*log(x)
343 (and (eq (caar arg) 'mtimes)
344 (null (cdddr arg))
345 (mnump (cadr arg))
346 (not (atom (caddr arg)))
347 (eq (caar (caddr arg)) '%log))))))
348 (and (eq (caar e) 'mplus)
349 (not (find-if #'lgc-nonsimple-arg-p (cdr e))))))
351 ;; Sort the argument so that coefficients come before logarithms and logarithms
352 ;; come before everything else.
353 (defun lgcsort (e)
354 (let ((logs) (notlogs) (decints) (varlist))
355 ;; Split the variables in E into logs, notlogs and coefficients. The list of
356 ;; variables is calculated by NEWVAR (and stored in the special variable
357 ;; VARLIST, which is why we have to bind it above).
358 (dolist (var (newvar e))
359 (cond
360 ((and (not (atom var)) (eq (caar var) '%log)) (push var logs))
361 ((logconcoeffp var) (push var decints))
362 (t (push var notlogs))))
363 (let* ((vl (nreconc decints (nconc (sort logs #'great)
364 (nreverse notlogs))))
365 (e1 (ratdisrep (ratrep e vl))))
366 (if (alike1 e e1) e e1))))
368 ;; lgcreciprocal performs the transformation log(1/x) => -log(x)
369 (defun lgcreciprocal (e)
370 (let (num denom)
371 (cond
372 ((atom e) e)
373 ((and (eq (caar e) '%log)
374 (setq num (member ($num (cadr e)) '(1 -1) :test #'equal))
375 (not (equal (setq denom ($denom (cadr e))) 1)))
376 (list '(mtimes simp) -1
377 (list '(%log simp) (if (= (car num) 1) denom (neg denom)))))
378 (t (recur-apply #'lgcreciprocal e)))))
380 (defun logconcoeffp (e)
381 (if $logconcoeffp
382 (is `(($logconcoeffp) ,e))
383 (maxima-integerp e)))
385 ;;;; RTCON
387 (defmfun ($rootscontract :properties ((evfun t))) (e) ; E is assumed to be simplified
388 (let ((radpe (and $radexpand (not (eq $radexpand '$all)) (eq $domain '$real)))
389 ($radexpand nil))
390 (rtcon e radpe)))
392 (defun rtcon (e radpe)
393 (cond ((atom e) e)
394 ((eq (caar e) 'mtimes)
395 (do ((x (cdr e) (cdr x)) (roots) (notroots) (y))
396 ((null x)
397 (cond ((null roots) (subst0 (cons '(mtimes) (nreverse notroots)) e))
398 (t (if $rootsconmode
399 (multiple-value-bind (min gcd lcm)
400 (rtc-getinfo roots)
401 (cond ((and (= min gcd) (not (= gcd 1))
402 (not (= min lcm))
403 (not (eq $rootsconmode '$all)))
404 (setq roots
405 (rt-separ
406 (list gcd
407 (rtcon
408 (rtc-fixitup
409 (rtc-divide-by-gcd roots gcd)
410 nil) radpe)
412 nil)))
413 ((eq $rootsconmode '$all)
414 (setq roots
415 (rt-separ (simp-roots lcm roots)
416 nil))))))
417 (rtc-fixitup roots notroots))))
418 (cond ((atom (car x))
419 (cond ((eq (car x) '$%i) (setq roots (rt-separ (list 2 -1) roots)))
420 (t (setq notroots (cons (car x) notroots)))))
421 ((and (eq (caaar x) 'mexpt) (ratnump (setq y (caddar x))))
422 (setq roots (rt-separ (list (caddr y)
423 (list '(mexpt)
424 (rtcon (cadar x) radpe) (cadr y)))
425 roots)))
427 ((and radpe (eq (caaar x) 'mabs))
428 (setq roots (rt-separ (list 2 `((mexpt) ,(rtcon (cadar x) radpe) 2) 1)
429 roots)))
430 (t (setq notroots (cons (rtcon (car x) radpe) notroots))))))
431 ((and radpe (eq (caar e) 'mabs))
432 (power (power (rtcon (cadr e) radpe) 2) '((rat simp) 1 2)))
433 (t (recur-apply #'(lambda (x) (rtcon x radpe)) e))))
435 ;; RT-SEPAR separates like roots into their appropriate "buckets",
436 ;; where a bucket looks like:
437 ;; ((<denom of power> (<term to be raised> <numer of power>)
438 ;; (<term> <numer>)) etc)
440 (defun rt-separ (a roots)
441 (let ((u (assoc (car a) roots :test #'equal)))
442 (cond (u (nconc u (cdr a))) (t (setq roots (cons a roots)))))
443 roots)
445 (defun simp-roots (lcm root-list)
446 (let (root1)
447 (do ((x root-list (cdr x)))
448 ((null x) (push lcm root1))
449 (push (list '(mexpt) (muln (cdar x) nil) (quotient lcm (caar x)))
450 root1))))
452 (defun rtc-getinfo (list)
453 (let ((m (caar list))
454 (g (caar list))
455 (l (caar list)))
456 (dolist (x (cdr list) (values m g l))
457 (setq m (min m (car x))
458 g (gcd g (car x))
459 l (lcm l (car x))))))
461 (defun rtc-fixitup (roots notroots)
462 (mapcar #'(lambda (x) (rplacd x (list (sratsimp (muln (cdr x) (not $rootsconmode))))))
463 roots)
464 (muln (nconc (mapcar #'(lambda (x) (power* (cadr x) `((rat) 1 ,(car x))))
465 roots)
466 notroots)
467 (not $rootsconmode)))
469 (defun rtc-divide-by-gcd (llist gcd)
470 (mapcar #'(lambda (x) (rplaca x (quotient (car x) gcd))) llist)
471 llist)
473 (defmfun $nterms (e)
474 (cond ((zerop1 e) 0)
475 ((atom e) 1)
476 ((eq (caar e) 'mtimes)
477 (if (equal -1 (cadr e)) (setq e (cdr e)))
478 (do ((l (cdr e) (cdr l)) (c 1 (* c ($nterms (car l)))))
479 ((null l) c)))
480 ((eq (caar e) 'mplus)
481 (do ((l (cdr e) (cdr l)) (c 0 (+ c ($nterms (car l)))))
482 ((null l) c)))
483 ((and (eq (caar e) 'mexpt) (integerp (caddr e)) (plusp (caddr e)))
484 (ftake '%binomial (+ (caddr e) ($nterms (cadr e)) -1) (caddr e)))
485 ((specrepp e) ($nterms (specdisrep e)))
486 (t 1)))
488 ;;;; ATAN2
490 ;; atan2 distributes over lists, matrices, and equations
491 (defprop %atan2 (mlist $matrix mequal) distribute_over)
493 (def-simplifier atan2 (y x)
494 (let (signy signx)
495 (cond ((and (zerop1 y) (zerop1 x))
496 (merror (intl:gettext "atan2: atan2(0,0) is undefined.")))
497 (;; float contagion
498 (and (or (numberp x) (ratnump x)) ; both numbers
499 (or (numberp y) (ratnump y)) ; ... but not bigfloats
500 (or $numer (floatp x) (floatp y))) ; at least one float
501 (atan ($float y) ($float x)))
502 (;; bfloat contagion
503 (and (mnump x)
504 (mnump y)
505 (or ($bfloatp x) ($bfloatp y))) ; at least one bfloat
506 (setq x ($bfloat x)
507 y ($bfloat y))
508 (*fpatan y (list x)))
509 ;; Simplifify infinities
510 ((or (eq x '$inf)
511 (alike1 x '((mtimes) -1 $minf)))
512 ;; Simplify atan2(y,inf) -> 0
514 ((or (eq x '$minf)
515 (alike1 x '((mtimes) -1 $inf)))
516 ;; Simplify atan2(y,minf) -> %pi for realpart(y)>=0 or -%pi
517 ;; for realpart(y)<0. When sign of y unknwon, return noun
518 ;; form. We are basically making atan2 on the branch cut
519 ;; be continuous with quadrant II.
520 (cond ((member (setq signy ($sign ($realpart y))) '($pos $pz $zero))
521 '$%pi)
522 ((eq signy '$neg) (mul -1 '$%pi))
523 (t (give-up))))
524 ((or (eq y '$inf)
525 (alike1 y '((mtimes) -1 $minf)))
526 ;; Simplify atan2(inf,x) -> %pi/2
527 (div '$%pi 2))
528 ((or (eq y '$minf)
529 (alike1 y '((mtimes -1 $inf))))
530 ;; Simplify atan2(minf,x) -> -%pi/2
531 (div '$%pi -2))
532 ((and (free x '$%i) (setq signx ($sign x))
533 (free y '$%i) (setq signy ($sign y))
534 (cond ((zerop1 y)
535 ;; Handle atan2(0, x) which is %pi or -%pi
536 ;; depending on the sign of x. We assume that
537 ;; x is never actually zero since atan2(0,0) is
538 ;; undefined.
539 (cond ((member signx '($neg $nz)) '$%pi)
540 ((member signx '($pos $pz)) 0)))
541 ((zerop1 x)
542 ;; Handle atan2(y, 0) which is %pi/2 or -%pi/2,
543 ;; depending on the sign of y.
544 (cond ((eq signy '$neg) (div '$%pi -2))
545 ((member signy '($pos $pz)) (div '$%pi 2))))
546 ((alike1 y x)
547 ;; Handle atan2(x,x) which is %pi/4 or -3*%pi/4
548 ;; depending on the sign of x.
549 (cond ((eq signx '$neg) (mul -3 (div '$%pi 4)))
550 ((member signx '($pos $pz)) (div '$%pi 4))))
551 ((alike1 y (mul -1 x))
552 ;; Handle atan2(-x,x) which is 3*%pi/4 or
553 ;; -%pi/4 depending on the sign of x.
554 (cond ((eq signx '$neg) (mul 3 (div '$%pi 4)))
555 ((member signx '($pos $pz)) (div '$%pi -4)))))))
556 ($logarc
557 (logarc '%atan2 (list ($logarc y) ($logarc x))))
558 ((and $trigsign (eq t (mminusp y)))
559 ;; atan2(-y,x) = -atan2(y,x) if trigsign is true.
560 (neg (take '(%atan2) (neg y) x)))
561 ;; atan2(y,x) = atan(y/x) + pi sign(y) (1-sign(x))/2
562 ((eq signx '$pos)
563 ;; atan2(y,x) = atan(y/x) when x is positive.
564 (take '(%atan) (div y x)))
565 ((and (eq signx '$neg)
566 (member (setq signy ($csign y)) '($pos $neg) :test #'eq))
567 (add (take '(%atan) (div y x))
568 (porm (eq signy '$pos) '$%pi)))
569 ((and (eq signx '$zero) (eq signy '$zero))
570 ;; Unfortunately, we'll rarely get here. For example,
571 ;; assume(equal(x,0)) atan2(x,x) simplifies via the alike1 case above
572 (merror (intl:gettext "atan2: atan2(0,0) is undefined.")))
573 (t (give-up)))))
575 ;;;; ARITHF
577 (defmfun $fibtophi (e &optional (lnorecurse nil))
578 (cond ((atom e) e)
579 ((eq (caar e) '$fib)
580 (setq e (cond (lnorecurse (cadr e)) (t ($fibtophi (cadr e) lnorecurse))))
581 (let ((phi (meval '$%phi)))
582 (div (add2 (power phi e) (neg (power (add2 1 (neg phi)) e)))
583 (add2 -1 (mul2 2 phi)))))
584 (t (recur-apply #'(lambda (x) ($fibtophi x lnorecurse)) e))))
586 (defmspec $numerval (l) (setq l (cdr l))
587 (do ((l l (cddr l)) (x (ncons '(mlist simp)))) ((null l) x)
588 (cond ((null (cdr l)) (merror (intl:gettext "numerval: expected an even number of arguments.")))
589 ((not (symbolp (car l)))
590 (merror (intl:gettext "numerval: expected a symbol; found ~M") (car l)))
591 ((boundp (car l))
592 (merror (intl:gettext "numerval: cannot declare a value because ~M is bound.") (car l))))
593 (mputprop (car l) (cadr l) '$numer)
594 (add2lnc (car l) $props)
595 (nconc x (ncons (car l)))))
597 (let (my-powers)
598 (declare (special my-powers))
600 (defmfun $derivdegree (e depvar var)
601 (let (my-powers) (declare (special my-powers)) (derivdeg1 e depvar var) (if (null my-powers) 0 (maximin my-powers '$max))))
603 (defun derivdeg1 (e depvar var)
604 (cond ((or (atom e) (specrepp e)))
605 ((eq (caar e) '%derivative)
606 (cond ((alike1 (cadr e) depvar)
607 (do ((l (cddr e) (cddr l))) ((null l))
608 (cond ((alike1 (car l) var)
609 (return (setq my-powers (cons (cadr l) my-powers)))))))))
610 (t (mapc #'(lambda (x) (derivdeg1 x depvar var)) (cdr e))))))
612 ;;;; BOX
614 ;; Set the the property reversealias
615 (defprop mbox $box reversealias)
616 (defprop mlabox $box reversealias)
618 (defmfun $dpart (&rest args)
619 (mpart args nil t nil '$dpart))
621 (defmfun $lpart (e &rest args)
622 (mpart args nil (list e) nil '$lpart))
624 (defmfun $box (e &optional (l nil l?))
625 (if l?
626 (list '(mlabox) e (box-label l))
627 (list '(mbox) e)))
629 (defun box (e label)
630 (if (eq label t)
631 (list '(mbox) e)
632 ($box e (car label))))
634 (defun box-label (x)
635 (if (atom x)
637 (coerce (mstring x) 'string)))
639 (defmfun $rembox (e &optional (l nil l?))
640 (let ((label (if l? (box-label l) '(nil))))
641 (rembox1 e label)))
643 (defun rembox1 (e label)
644 (cond ((atom e) e)
645 ((or (and (eq (caar e) 'mbox)
646 (or (equal label '(nil)) (member label '($unlabelled $unlabeled) :test #'eq)))
647 (and (eq (caar e) 'mlabox)
648 (or (equal label '(nil)) (equal label (caddr e)))))
649 (rembox1 (cadr e) label))
650 (t (recur-apply #'(lambda (x) (rembox1 x label)) e))))
652 ;;;; MAPF
654 (defmspec ($scanmap :properties ((evok t))) (l)
655 (let ((scanmapp t))
656 (resimplify (apply #'scanmap1 (mmapev l)))))
658 (defun scanmap1 (func e &optional (flag nil flag?))
659 (let ((arg2 (specrepcheck e)) newarg2)
660 (cond ((eq func '$rat)
661 (merror (intl:gettext "scanmap: cannot apply 'rat'.")))
662 (flag?
663 (unless (eq flag '$bottomup)
664 (merror (intl:gettext "scanmap: third argument must be 'bottomup', if present; found ~M") flag))
665 (if (mapatom arg2)
666 (funcer func (ncons arg2))
667 (subst0 (funcer func
668 (ncons (mcons-op-args (mop arg2)
669 (mapcar #'(lambda (u)
670 (scanmap1 func u '$bottomup))
671 (margs arg2)))))
672 arg2)))
673 ((mapatom arg2)
674 (funcer func (ncons arg2)))
676 (setq newarg2 (specrepcheck (funcer func (ncons arg2))))
677 (cond ((mapatom newarg2)
678 newarg2)
679 ((and (alike1 (cadr newarg2) arg2) (null (cddr newarg2)))
680 (subst0 (cons (ncons (caar newarg2))
681 (ncons (subst0
682 (mcons-op-args (mop arg2)
683 (mapcar #'(lambda (u) (scanmap1 func u))
684 (margs arg2)))
685 arg2)))
686 newarg2))
688 (subst0 (mcons-op-args (mop newarg2)
689 (mapcar #'(lambda (u) (scanmap1 func u))
690 (margs newarg2)))
691 newarg2)))))))
693 (defun subgen (form) ; This function does mapping of subscripts.
694 (do ((ds (if (eq (caar form) 'mqapply) (list (car form) (cadr form))
695 (ncons (car form)))
696 (outermap1 #'dsfunc1 (simplify (car sub)) ds))
697 (sub (reverse (or (and (eq 'mqapply (caar form)) (cddr form))
698 (cdr form)))
699 (cdr sub)))
700 ((null sub) ds)))
702 (defun dsfunc1 (dsn dso)
703 (cond ((or (atom dso) (atom (car dso))) dso)
704 ((member 'array (car dso) :test #'eq)
705 (cond ((eq 'mqapply (caar dso))
706 (nconc (list (car dso) (cadr dso) dsn) (cddr dso)))
707 (t (nconc (list (car dso) dsn) (cdr dso)))))
708 (t (mapcar #'(lambda (d) (dsfunc1 dsn d)) dso))))
710 ;;;; GENMAT
712 ;; GENMATRIX is improved in order to save time when creating a large matrix.
713 ;; see SF bug #4056
715 (defmfun $genmatrix (a i2 &optional (j2 i2) (i1 1) (j1 i1))
716 (let ((f))
717 (setq f (if (or (symbolp a) (hash-table-p a) (arrayp a))
718 #'(lambda (i j) (meval (list (list a 'array) i j)))
719 #'(lambda (i j) (mfuncall a i j))))
721 (if (notevery #'fixnump (list i2 j2 i1 j1))
722 (merror (intl:gettext "genmatrix: bounds must be integers; found ~M, ~M, ~M, ~M") i2 j2 i1 j1))
724 (if (or (> i1 i2) (> j1 j2))
725 (merror (intl:gettext "genmatrix: upper bounds must be greater than or equal to lower bounds; found ~M, ~M, ~M, ~M") i2 j2 i1 j1))
727 (cons '($matrix)
728 (loop for i from i1 to i2
729 collect (cons '(mlist)
730 (loop for j from j1 to j2
731 collect (funcall f i j)))))))
733 ; Execute deep copy for copymatrix and copylist.
734 ; Resolves SF bug report [ 1224960 ] sideeffect with copylist.
735 ; An optimization would be to call COPY-TREE only on mutable expressions.
737 (defmfun $copymatrix (x)
738 (unless ($matrixp x)
739 (merror (intl:gettext "copymatrix: argument must be a matrix; found ~M") x))
740 (copy-tree x))
742 (defmfun $copylist (x)
743 (unless ($listp x)
744 (merror (intl:gettext "copylist: argument must be a list; found ~M") x))
745 (copy-tree x))
747 (defmfun $copy (x)
748 (copy-tree x))
750 ;;;; ADDROW
752 (defmfun $addrow (m &rest rows)
753 (declare (dynamic-extent rows))
754 (cond ((not ($matrixp m))
755 (merror
756 (intl:gettext "addrow: first argument must be a matrix; found ~M")
758 ((null rows) m)
760 (let ((m (copy-tree m)))
761 (dolist (r rows m)
762 (setq m (addrow m r)))))))
764 (defmfun $addcol (m &rest cols)
765 (declare (dynamic-extent cols))
766 (cond ((not ($matrixp m)) (merror (intl:gettext "addcol: first argument must be a matrix; found ~M") m))
767 ((null cols) m)
768 ((null (cdr m))
769 (apply '$addcol (cons (ensure-matrix-column (first cols)) (rest cols))))
770 (t (let ((m ($transpose m)))
771 (dolist (c cols ($transpose m))
772 (setq m (addrow m ($transpose c))))))))
774 (defun ensure-matrix-column (a)
775 (if ($matrixp a) a
776 ;; otherwise must be a MLIST.
777 `(($matrix) ,@(mapcar #'(lambda (e) `((mlist) ,e)) (cdr a)))))
779 (defun addrow (m r)
780 (cond ((not (mxorlistp r)) (merror (intl:gettext "addrow or addcol: argument must be a matrix or list; found ~M") r))
781 ((and (cdr m)
782 (or (and (eq (caar r) 'mlist) (not (= (length (cadr m)) (length r))))
783 (and (eq (caar r) '$matrix)
784 (not (= (length (cadr m)) (length (cadr r))))
785 (prog2 (setq r ($transpose r))
786 (not (= (length (cadr m)) (length (cadr r))))))))
787 (merror (intl:gettext "addrow or addcol: incompatible structure."))))
788 (append m (if (eq (caar r) '$matrix) (cdr r) (ncons r))))
790 ;;;; ARRAYF
792 (defun my-nonatomic-expr-p (e)
793 (and (consp e) (consp (car e)) (symbolp (caar e))))
795 (defun my-lambda-expr-p (e)
796 (and (consp e) (consp (car e)) (eq 'lambda (caar e))))
798 (defmfun $arraymake (ary subs)
799 (cond
800 ;; We go through some gyrations here to allow as wide a range of inputs as possible.
801 ;; Previously $ARRAYMAKE didn't check the first argument at all;
802 ;; this is an attempt at a minimally-restrictive change.
803 ((not (or (symbolp ary) ($subvarp ary) (and (my-nonatomic-expr-p ary) (not (my-lambda-expr-p ary)))))
804 (merror (intl:gettext "arraymake: first argument must be a symbol, subscripted symbol, or nonatomic expression (but not a lambda expression); found: ~M") ary))
805 ((or (not ($listp subs)) (null (cdr subs)))
806 (merror (intl:gettext "arraymake: second argument must be a list of one or more elements; found ~M") subs))
807 ((symbolp ary)
808 (cons (cons (getopr ary) '(array)) (cdr subs)))
809 (t (cons '(mqapply array) (cons ary (cdr subs))))))
811 (defmspec $arrayinfo (ary)
812 (setq ary (cdr ary))
813 (arrayinfo-aux (car ary) (getvalue (car ary))))
815 (defun arrayinfo-aux (sym val)
816 (prog (arra ary)
817 (setq arra val)
818 (setq ary sym)
819 (if (and arra
820 (or (hash-table-p arra)
821 (arrayp arra)
822 (eq (marray-type arra) '$functional)))
823 (cond ((hash-table-p arra)
824 (let ((dim1 (gethash 'dim1 arra)))
825 (return (list* '(mlist) '$hash_table (if dim1 1 t)
826 (loop for u being the hash-keys in arra
827 unless (eq u 'dim1)
828 collect
829 (if dim1
831 (cons '(mlist simp) u)))))))
832 ((arrayp arra)
833 (return (let ((dims (array-dimensions arra)))
834 (list '(mlist) '$declared
835 ;; they don't want more info (array-type arra)
836 (length dims)
837 (cons '(mlist) (mapcar #'1- dims))))))
838 ((eq (marray-type arra) '$functional)
839 (return (arrayinfo-aux sym (mgenarray-content arra)))))
840 (let ((gen (safe-mgetl sym '(hashar array))) ary1)
841 (when (null gen)
842 (merror (intl:gettext "arrayinfo: ~M is not an array.") ary))
843 (setq ary1 (cadr gen))
844 (cond ((eq (car gen) 'hashar)
845 (setq ary1 (symbol-array ary1))
846 (return (append '((mlist simp) $hashed)
847 (cons (aref ary1 2)
848 (do ((i 3 (1+ i)) (l)
849 (n (cadr (arraydims ary1))))
850 ((= i n) (sort l #'(lambda (x y) (great y x))))
851 (do ((l1 (aref ary1 i) (cdr l1)))
852 ((null l1))
853 (push (cons '(mlist simp) (caar l1)) l)))))))
854 (t (setq ary1 (arraydims ary1))
855 (return (list '(mlist simp)
856 (cond ((safe-get ary 'array)
857 (cdr (assoc (car ary1)
858 '((t . $complete) (fixnum . $integer)
859 (flonum . $float)) :test #'eq)))
860 (t '$declared))
861 (length (cdr ary1))
862 (cons '(mlist simp) (mapcar #'1- (cdr ary1)))))))))))
864 ;;;; ALIAS
866 (defmspec $ordergreat (l)
867 (if greatorder (merror (intl:gettext "ordergreat: reordering is not allowed.")))
868 (makorder (setq greatorder (reverse (cdr l))) '_))
870 (defmspec $orderless (l)
871 (if lessorder (merror (intl:gettext "orderless: reordering is not allowed.")))
872 (makorder (setq lessorder (cdr l)) '|#|))
874 (defun makorder (l char)
875 (do ((l l (cdr l))
876 (n 101 (1+ n)))
877 ((null l) '$done)
878 (alias (car l)
879 (implode (nconc (ncons char) (mexploden n)
880 (exploden (stripdollar (car l))))))))
882 (defmfun $unorder ()
883 (let ((l (delete nil
884 (cons '(mlist simp)
885 (nconc (mapcar #'(lambda (x) (remalias (getalias x))) lessorder)
886 (mapcar #'(lambda (x) (remalias (getalias x))) greatorder)))
887 :test #'eq)))
888 (setq lessorder nil greatorder nil)
891 ;;;; CONCAT
893 (defmfun $concat (&rest l)
894 "Concatenates its arguments.
895 The arguments must evaluate to atoms. The return value is a symbol if
896 the first argument is a symbol and a string otherwise."
897 (when (null l)
898 (merror (intl:gettext "concat: there must be at least one argument.")))
899 (let ((result-is-a-string (or (numberp (car l)) (stringp (car l)))))
900 (setq l (mapcan #'(lambda (x) (unless (atom x) (merror (intl:gettext "concat: argument must be an atom; found ~M") x)) (string* x)) l))
901 (if result-is-a-string
902 (coerce l 'string)
903 (getalias (implode (cons '#\$ l))))))