descriptive.mac: declare local variable to avoid possibility of name collision.
[maxima.git] / src / optim.lisp
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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)
11 ;; ** (c) Copyright 1982 Massachusetts Institute of Technology **
13 (macsyma-module optim)
15 (defvar *subexp* (make-array 64 :initial-element nil))
17 (defmvar $optimprefix '$%
18 nil
19 :setting-predicate #'symbolp)
21 (defmvar $optimwarn t "warns if `optimize' encounters a special form.")
23 ;; $OPTIMIZE takes a Macsyma expression and returns a BLOCK form which is
24 ;; equivalent, but which uses local variables to store the results of computing
25 ;; common subexpressions. These subexpressions are found by hashing them.
27 (defmfun $optimize (x0)
28 (let (($optimwarn $optimwarn)
29 *setqs*
30 vars
31 (*optimcount* 0)
32 (*xvars* (cdr ($listofvars x0))))
33 (declare (special *optimcount* *xvars* *setqs* vars))
34 (fill *subexp* nil)
35 (prog ((x (collapse (opformat (collapse x0)))))
36 (when (atom x) (return x))
37 (comexp x)
38 (setq x (optim x))
39 (return (prog1 (cond ((null vars) x0)
40 (t (if (or (not (eq (caar x) 'mprog))
41 (and ($listp (cadr x)) (cdadr x)))
42 (setq x (nreverse (cons x *setqs*)))
43 (setq x (nreconc *setqs* (cddr x))))
44 `((mprog simp) ((mlist) ,@(nreverse vars)) ,@x)))
45 (fill *subexp* nil))))))
47 (defun opformat (x)
48 (cond ((atom x) x)
49 ((specrepp x) (opformat (specdisrep x)))
50 ((and $optimwarn
51 (mspecfunp (caar x))
52 (prog2 (mtell (intl:gettext "optimize: encountered a special form; result may be wrong."))
53 (setq $optimwarn nil))))
54 ((eq (caar x) 'mexpt) (opmexpt x))
55 (t (let ((newargs (mapcar #'opformat (cdr x))))
56 (if (alike newargs (cdr x)) x (cons (car x) newargs))))))
58 (defun opmexpt (x)
59 (let ((*base (opformat (cadr x))) (exp (opformat (caddr x))) xnew negexp)
60 (setq negexp
61 (cond ((and (realp exp) (minusp exp)) (- exp))
62 ((and (ratnump exp) (minusp (cadr exp)))
63 (list (car exp) (- (cadr exp)) (caddr exp)))
64 ((and (mtimesp exp) (realp (cadr exp)) (minusp (cadr exp)))
65 (if (equal (cadr exp) -1)
66 (if (null (cdddr exp)) (caddr exp)
67 (cons (car exp) (cddr exp)))
68 (list* (car exp) (- (cadr exp)) (cddr exp))))
69 ((and (mtimesp exp) (ratnump (cadr exp)) (minusp (cadadr exp)))
70 (list* (car exp)
71 (list (caadr exp) (- (cadadr exp)) (caddr (cadr exp)))
72 (cddr exp)))))
73 (setq xnew
74 (cond (negexp
75 `((mquotient)
77 ,(cond ((equal negexp 1) *base)
78 (t (setq xnew (list (car x) *base negexp))
79 (if (and (ratnump negexp) (equal (caddr negexp) 2))
80 (opmexpt xnew)
81 xnew)))))
82 ((and (ratnump exp) (equal (caddr exp) 2))
83 (setq exp (cadr exp))
84 (if (equal exp 1) `((%sqrt) ,*base)
85 `((mexpt) ((%sqrt) ,*base) ,exp)))
86 (t (list (car x) *base exp))))
87 (if (alike1 x xnew) x xnew)))
89 (defmfun $collapse (x)
90 (fill *subexp* nil)
91 (prog1 (collapse x) (fill *subexp* nil)))
93 (defun collapse (x)
94 (cond ((atom x) x)
95 ((specrepp x) (collapse (specdisrep x)))
96 (t (let ((n (opt-hash (caar x))))
97 (do ((l (cdr x) (cdr l)))
98 ((null l))
99 (if (not (eq (collapse (car l)) (car l)))
100 (rplaca l (collapse (car l))))
101 (setq n (rem (+ (opt-hash (car l)) n) 12553.)))
102 (setq n (logand 63 n))
103 (do ((l (aref *subexp* n) (cdr l)))
104 ((null l) (setf (aref *subexp* n) (cons (list x) (aref *subexp* n))) x)
105 (if (alike1 x (caar l)) (return (caar l))))))))
107 (defun comexp (x)
108 (if (not (or (atom x) (eq (caar x) 'rat)))
109 (let ((n (opt-hash (caar x))))
110 (dolist (u (cdr x)) (setq n (rem (+ (opt-hash u) n) 12553.)))
111 (setq x (assol x (aref *subexp* (logand 63. n))))
112 (cond ((null (cdr x)) (rplacd x 'seen) (mapc #'comexp (cdar x)))
113 (t (rplacd x 'comexp))))))
115 (defun optim (x)
116 (declare (special *setqs*))
117 (cond ((atom x) x)
118 ((and (member 'array (cdar x) :test #'eq)
119 (not (eq (caar x) 'mqapply))
120 (not (mget (caar x) 'arrayfun-mode)))
122 ((eq (caar x) 'rat) x)
123 (t (let ((n (opt-hash (caar x))) (nx (list (car x))))
124 (dolist (u (cdr x))
125 (setq n (rem (+ (opt-hash u) n) 12553.)
126 nx (cons (optim u) nx)))
127 (setq x (assol x (aref *subexp* (logand 63. n))) nx (nreverse nx))
128 (cond ((eq (cdr x) 'seen) nx)
129 ((eq (cdr x) 'comexp)
130 (rplacd x (getoptimvar))
131 (push `((msetq) ,(cdr x) ,nx) *setqs*)
132 (cdr x))
133 (t (cdr x)))))))
135 (defun opt-hash (exp) ; EXP is in general representation.
136 (rem (if (atom exp)
137 (sxhash exp)
138 (do ((n (opt-hash (caar exp)))
139 (args (cdr exp) (cdr args)))
140 ((null args) n)
141 (setq n (rem (+ (opt-hash (car args)) n) 12553.))))
142 12553.)) ; a prime number < 2^14 ; = PRIME(1500)
145 (defun getoptimvar ()
146 (declare (special *optimcount* *xvars* vars))
147 (loop with var
149 (incf *optimcount*)
150 (setq var (make-symbol (format nil "~A~D" $optimprefix *optimcount*)))
151 while (member var *xvars* :test #'eq)
152 finally
153 (push var vars)
154 (return var)))