Rename *ll* and *ul* to ll and ul in make-defint-assumptions
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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 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
8 ;;; (c) Copyright 1980 Massachusetts Institute of Technology ;;;
9 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
11 (in-package :maxima)
13 (macsyma-module ratmac macro)
15 ;; Polynomials
16 ;; ===========
18 ;; A polynomial in a single variable is stored as a sparse list of coefficients,
19 ;; whose first element is the polynomial's variable. The rest of the elements
20 ;; form a plist with keys the powers (in descending order) and values the
21 ;; coefficients.
23 ;; For example, 42*x^2 + 1 might be stored as ($x 2 42 0 1). If, say,
24 ;; x*sin(x)+x^2 is respresented as a polynomial in x, we might expect it to come
25 ;; out as something like
27 ;; ($x 2 1 1 ((%sin) $x)),
29 ;; but to make it easier to work with polynomials we don't allow arbitrary
30 ;; conses as coefficients. What actually happens is that the expression is
31 ;; thought of as a polynomial in two variables x and "sin(x)". More on that
32 ;; below.
34 ;; Multivariate polynomials are stored in basically the same way as single
35 ;; variable polynomials, using the observation that a polynomial in X and Y with
36 ;; coefficients in K is the same as a polynomial in X with coefficients in K[Y].
38 ;; Specifically, the coefficient terms can be polynomials themselves (in other
39 ;; variables). So x^2 + x*y could be rperesented as (($x 2 1 1 ($y 1 1))) or
40 ;; alternatively as (($y 1 ($x 1 1) 0 ($x 2 1))), depending on whether x or y
41 ;; was taken as the primary variable. If you add together two polynomials in
42 ;; different variables (say x+1 and y+2) in the rational function code, then it
43 ;; decides on the main variable using POINTERGP. This only works if the
44 ;; variables have already been given a numbering by the rest of the rational
45 ;; function code.
47 ;; In the x*sin(x) + x^2 example above, the expression can be represented as
48 ;; something like ($x 2 1 1 (sinx 1 1)). When passed around as expressions
49 ;; outside of the core rational function code, polynomials come with some header
50 ;; information that explains what the variables are. In this case, it would be
51 ;; responsible for remembering that "sinx" means sin(x).
53 ;; As a slightly special case, a polynomial can also be an atom, in which case
54 ;; it is treated as a degree zero polynomial in no particular variable. Test for
55 ;; this using the pcoefp macro defined below.
57 ;; There are accessor macros for the parts of a polynomial defined below: p-var,
58 ;; p-terms, p-lc, p-le and p-red (which extract the primary variable, the list
59 ;; of powers and coefficients, the leading coefficient, the leading exponent and
60 ;; the list of powers and coefficients except the leading coefficient,
61 ;; respectively).
63 ;; Rational expressions
64 ;; ====================
66 ;; A rational expression is just a quotient of two polynomials p/q and, as such,
67 ;; is stored as a cons pair (p . q), where p and q are in the format described
68 ;; above. Since bare coefficients are allowed as polynomials, we can represent
69 ;; zero as (0 . 1), which literally means 0/1.
71 ;; These format are also documented in the "Introduction to Polynomials" page of
72 ;; the manual.
74 ;; PCOEFP
76 ;; Returns true if E (which is hopefully a polynomial expression) should be
77 ;; thought of as a bare coefficient.
78 (defmacro pcoefp (e) `(atom ,e))
80 ;; PZEROP
82 ;; Return true iff the polynomial X is syntactically the zero polynomial. This
83 ;; only happens when the polynomial is a bare coefficient and that coefficient
84 ;; is zero.
85 (declaim (inline pzerop))
86 (defun pzerop (x)
87 (cond
88 ((fixnump x) (zerop x))
89 ((consp x) nil)
90 ((floatp x) (zerop x))))
92 ;; PZERO
94 ;; A simple macro that evaluates to the zero polynomial.
95 (defmacro pzero () 0)
97 ;; PTZEROP
99 ;; TERMS should be a list of terms of a polynomial. Returns T if that list is
100 ;; empty, so the polynomial has no terms.
101 (defmacro ptzerop (terms) `(null ,terms))
103 ;; PTZERO
105 ;; A simple macro that evaluates to an empty list of polynomial terms,
106 ;; representing the zero polynomial.
107 (defmacro ptzero () '())
109 ;; CMINUS
111 ;; Return the negation of a coefficient, which had better be numeric.
112 (defmacro cminus (c) `(- ,c))
114 ;; CMINUSP
116 ;; Return T if the coefficient C is negative. Only works if C is a real number.
117 (defmacro cminusp (c) `(minusp ,c))
120 ;; VALGET
122 ;; Retrieve a stored value from the given symbol, stored by VALPUT. This is used
123 ;; in the rational function code, which uses it to store information on gensyms
124 ;; that represent variables.
126 ;; Historical note from 2000 (presumably wfs):
128 ;; The PDP-10 implementation used to use the PRINTNAME of the gensym as a
129 ;; place to store a VALUE. Somebody changed this to value-cell instead, even
130 ;; though using the value-cell costs more. Anyway, in NIL I want it to use the
131 ;; property list, as thats a lot cheaper than creating a value cell. Actually,
132 ;; better to use the PACKAGE slot, a kludge is a kludge right?
133 (defmacro valget (item)
134 `(symbol-value ,item))
136 ;; VALPUT
138 ;; Store a value on the given symbol, which can be later retrieved by
139 ;; valget. This is used by the rational function code.
140 (defmacro valput (item val)
141 `(setf (symbol-value ,item) ,val))
143 ;; POINTERGP
145 ;; Test whether one symbol should occur before another in a canonical ordering.
147 ;; A historical note from Richard Fateman, on the maxima list, 2006/03/17:
149 ;; "The name pointergp comes from the original hack when we wanted a bunch of
150 ;; atoms that could be ordered fast, we just generated, say, 10 gensyms. Then
151 ;; we sorted them by the addresses of the symbols in memory. Then we
152 ;; associated them with x,y,z,.... This meant that pointergp was one or two
153 ;; instructions on a PDP-10, in assembler."
155 ;; "That version of pointergp turned out to be more trouble than it was worth
156 ;; because we sometimes had to interpolate between two gensym "addresses" and
157 ;; to do that we had to kind of renumber too much of the universe. Or maybe
158 ;; we just weren't clever enough to do it without introducing bugs."
160 ;; Richard Fateman also says pointergp needs to be fast because it's called a
161 ;; lot. So if you get an error from pointergp, it's probably because someone
162 ;; forgot to initialize things correctly.
163 (declaim (inline pointergp))
164 (defun pointergp (a b)
165 (> (symbol-value a) (symbol-value b)))
167 ;; ALGV
169 ;; V should be a symbol. If V has an "algebraic value" (stored in the TELLRAT
170 ;; property) then return it, provided that the $ALGEBRAIC flag is
171 ;; true. Otherwise, return NIL.
172 (defmacro algv (v)
173 `(and $algebraic (get ,v 'tellrat)))
175 ;; RZERO
177 ;; Expands to the zero rational expression (literally 0/1)
178 (defmacro rzero () ''(0 . 1))
180 ;; RZEROP
182 ;; Test whether a rational expression is zero. A quotient p/q is zero iff p is
183 ;; zero.
184 (defmacro rzerop (a) `(pzerop (car ,a)))
186 ;; PRIMPART
188 ;; Calculate the primitive part of a polynomial. This is the polynomial divided
189 ;; through by the greatest common divisor of its coefficients.
190 (defmacro primpart (p) `(second (oldcontent ,p)))
192 ;; MAKE-POLY
194 ;; A convenience macro for constructing polynomials. VAR is the main variable
195 ;; and should be a symbol. With no other arguments, it constructs the polynomial
196 ;; representing the linear polynomial "VAR".
198 ;; A single optional argument is taken to be a coefficient list and, if the list
199 ;; is known at compile time, some tidying up is done with PSIMP.
201 ;; With two optional arguments, they are taken to be an exponent/coefficient
202 ;; pair. So (make-poly 'x 3 2) represents 2*x^3.
204 ;; With all three optional arguments, the first two are interpreted as above,
205 ;; but this coefficient is prepended to an existing list of terms passed in the
206 ;; third argument.
208 ;; Note: Polynomials are normally assumed to have terms listed in descending
209 ;; order of exponent. MAKE-POLY does not ensure this, so
210 ;; (make-poly 'x 1 2 '(2 1)) results in '(x 1 2 2 1), for example.
211 (defmacro make-poly (var &optional (terms-or-e nil options?) (c nil e-c?) (terms nil terms?))
212 (cond ((null options?) `(cons ,var '(1 1)))
213 ((null e-c?) `(psimp ,var ,terms-or-e))
214 ((null terms?) `(list ,var ,terms-or-e ,c))
215 (t `(psimp ,var (list* ,terms-or-e ,c ,terms)))))
217 ;; P-VAR
219 ;; Extract the main variable from the polynomial P. Note: this does not work for
220 ;; a bare coefficient.
221 (defmacro p-var (p) `(car ,p))
223 ;; P-TERMS
225 ;; Extract the list of terms from the polynomial P. Note: this does not work for
226 ;; a bare coefficient.
227 (defmacro p-terms (p) `(cdr ,p))
229 ;; P-LC
231 ;; Extract the leading coefficient of the polynomial P. Note: this does not work for
232 ;; a bare coefficient.
233 (defmacro p-lc (p) `(caddr ,p))
235 ;; P-LE
237 ;; Extract the leading exponent or degree of the polynomial P. Note: this does
238 ;; not work for a bare coefficient.
239 (defmacro p-le (p) `(cadr ,p))
241 ;; P-RED
243 ;; Extract the terms of the polynomial P, save the leading term.
244 (defmacro p-red (p) `(cdddr ,p))
246 ;; PT-LC
248 ;; Extract the leading coefficient from TERMS, a list of polynomial terms.
249 (defmacro pt-lc (terms) `(cadr ,terms))
251 ;; PT-LE
253 ;; Extract the leading exponent (or degree) from TERMS, a list of polynomial
254 ;; terms.
255 (defmacro pt-le (terms) `(car ,terms))
257 ;; PT-RED
259 ;; Return all but the leading term of TERMS, a list of polynomial terms.
260 (defmacro pt-red (terms) `(cddr ,terms))
262 ;; R+
264 ;; Sum one or more rational expressions with RATPL
265 (defmacro r+ (r . l)
266 (cond ((null l) r)
267 (t `(ratpl ,r (r+ ,@l)))))
269 ;; R*
271 ;; Take the product of one or more rational expressions with RATTI.
272 (defmacro r* (r . l)
273 (cond ((null l) r)
274 (t `(ratti ,r (r* ,@l) t))))
276 ;; R-
278 ;; Subtract the sum of the second and following rational expressions from the
279 ;; first, using RATDIF.
280 (defmacro r- (r . l)
281 (cond ((null l) `(ratminus (ratfix ,r)))
282 (t `(ratdif (ratfix ,r) (r+ ,@l)))))