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737 lines
26 KiB
Common Lisp
737 lines
26 KiB
Common Lisp
;;; The contents of this file are subject to the Mozilla Public
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;;; License Version 1.1 (the "License"); you may not use this file
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;;; except in compliance with the License. You may obtain a copy of
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;;; the License at http://www.mozilla.org/MPL/
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;;;
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;;; Software distributed under the License is distributed on an "AS
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;;; IS" basis, WITHOUT WARRANTY OF ANY KIND, either express or
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;;; implied. See the License for the specific language governing
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;;; rights and limitations under the License.
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;;;
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;;; The Original Code is the Language Design and Prototyping Environment.
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;;;
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;;; The Initial Developer of the Original Code is Netscape Communications
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;;; Corporation. Portions created by Netscape Communications Corporation are
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;;; Copyright (C) 1999 Netscape Communications Corporation. All
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;;; Rights Reserved.
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;;;
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;;; Contributor(s): Waldemar Horwat <waldemar@acm.org>
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;;;
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;;; Handy lisp utilities
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;;;
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;;; Waldemar Horwat (waldemar@acm.org)
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;;;
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;;; ------------------------------------------------------------------------------------------------------
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;;; MCL FIXES
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(setq *print-right-margin* 150)
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;;; Fix name-char and char-name.
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#+mcl
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(locally
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(declare (optimize (speed 3) (safety 0) (debug 1)))
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(eval-when (:compile-toplevel :load-toplevel :execute)
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(setq *warn-if-redefine* nil)
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(setq *warn-if-redefine-kernel* nil))
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(defun char-name (c)
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(dolist (e ccl::*name-char-alist*)
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(declare (list e))
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(when (eq c (cdr e))
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(return-from char-name (car e))))
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(let ((code (char-code c)))
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(declare (fixnum code))
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(cond ((< code #x100)
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(unless (and (>= code 32) (<= code 216) (/= code 127))
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(format nil "x~2,'0X" code)))
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(t (format nil "u~4,'0X" code)))))
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(defun name-char (name)
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(if (characterp name)
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name
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(let* ((name (string name))
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(namelen (length name)))
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(declare (fixnum namelen))
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(or (cdr (assoc name ccl::*name-char-alist* :test #'string-equal))
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(if (= namelen 1)
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(char name 0)
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(when (>= namelen 2)
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(flet
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((number-char (name base lg-base)
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(let ((n 0))
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(dotimes (i (length name) (code-char n))
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(let ((code (digit-char-p (char name i) base)))
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(if code
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(setq n (logior code (ash n lg-base)))
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(return)))))))
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(case (char name 0)
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(#\^
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(when (= namelen 2)
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(code-char (the fixnum (logxor (the fixnum (char-code (char-upcase (char name 1)))) #x40)))))
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((#\x #\X #\u #\U)
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(number-char (subseq name 1) 16 4))
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((#\0 #\1 #\2 #\3 #\4 #\5 #\6 #\7)
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(number-char name 8 3))))))))))
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(eval-when (:compile-toplevel :load-toplevel :execute)
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(setq *warn-if-redefine* t)
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(setq *warn-if-redefine-kernel* t)))
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;;; ------------------------------------------------------------------------------------------------------
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;;; READER SYNTAX
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; Define #?num to produce a character with code given by the hexadecimal number num.
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; (This is a portable extension; the #\u syntax installed above does the same thing
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; but is not portable.)
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(set-dispatch-macro-character
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#\# #\?
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#'(lambda (stream subchar arg)
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(declare (ignore subchar arg))
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(let ((*read-base* 16))
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(code-char (read stream t nil t)))))
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;;; ------------------------------------------------------------------------------------------------------
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;;; MACROS
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; (list*-bind (var1 var2 ... varn) expr body):
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; evaluates expr to obtain a value v;
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; binds var1, var2, ..., varn such that (list* var1 var2 ... varn) is equal to v;
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; evaluates body with these bindings;
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; returns the result values from the body.
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(defmacro list*-bind ((var1 &rest vars) expr &body body)
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(labels
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((gen-let*-bindings (var1 vars expr)
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(if vars
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(let ((expr-var (gensym "REST")))
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(list*
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(list expr-var expr)
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(list var1 (list 'car expr-var))
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(gen-let*-bindings (car vars) (cdr vars) (list 'cdr expr-var))))
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(list
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(list var1 expr)))))
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(list* 'let* (gen-let*-bindings var1 vars expr) body)))
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(set-pprint-dispatch '(cons (member list*-bind))
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(pprint-dispatch '(multiple-value-bind () ())))
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; (multiple-value-map-bind (var1 var2 ... varn) f (src1 src2 ... srcm) body)
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; evaluates src1, src2, ..., srcm to obtain lists l1, l2, ..., lm;
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; calls f on corresponding elements of lists l1, ..., lm; each such call should return n values v1 v2 ... vn;
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; binds var1, var2, ..., varn such var1 is the list of all v1's, var2 is the list of all v2's, etc.;
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; evaluates body with these bindings;
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; returns the result values from the body.
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(defmacro multiple-value-map-bind ((&rest vars) f (&rest srcs) &body body)
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(let ((n (length vars))
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(m (length srcs))
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(fun (gensym "F"))
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(ss nil)
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(vs nil)
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(accumulators nil))
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(dotimes (i n)
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(push (gensym "V") vs)
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(push (gensym "ACC") accumulators))
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(dotimes (i m)
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(push (gensym "S") ss))
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`(let ((,fun ,f)
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,@(mapcar #'(lambda (acc) (list acc nil)) accumulators))
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(mapc #'(lambda ,ss
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(multiple-value-bind ,vs (funcall ,fun ,@ss)
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,@(mapcar #'(lambda (accumulator v) (list 'push v accumulator))
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accumulators vs)))
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,@srcs)
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(let ,(mapcar #'(lambda (var accumulator) (list var (list 'nreverse accumulator)))
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vars accumulators)
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,@body))))
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;;; ------------------------------------------------------------------------------------------------------
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;;; VALUE ASSERTS
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(eval-when (:compile-toplevel :load-toplevel :execute)
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(defconstant *value-asserts* t))
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; Assert that (test value) returns non-nil. Return value.
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(defmacro assert-value (value test &rest format-and-parameters)
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(if *value-asserts*
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(let ((v (gensym "VALUE")))
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`(let ((,v ,value))
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(unless (,test ,v)
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,(if format-and-parameters
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`(error ,@format-and-parameters)
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`(error "~S doesn't satisfy ~S" ',value ',test)))
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,v))
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value))
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; Assert that value is non-nil. Return value.
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(defmacro assert-non-null (value &rest format-and-parameters)
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`(assert-value ,value identity .
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,(or format-and-parameters
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`("~S is null" ',value))))
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; Assert that value is non-nil. Return nil.
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; Do not evaluate value in nondebug versions.
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(defmacro assert-true (value &rest format-and-parameters)
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(if *value-asserts*
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`(unless ,value
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,(if format-and-parameters
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`(error ,@format-and-parameters)
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`(error "~S is false" ',value)))
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nil))
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; Assert that expr returns n values. Return those values.
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(defmacro assert-n-values (n expr)
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(if *value-asserts*
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(let ((v (gensym "VALUES")))
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`(let ((,v (multiple-value-list ,expr)))
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(unless (= (length ,v) ,n)
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(error "~S returns ~D values instead of ~D" ',expr (length ,v) ',n))
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(values-list ,v)))
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expr))
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; Assert that expr returns one value. Return that value.
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(defmacro assert-one-value (expr)
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`(assert-n-values 1 ,expr))
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; Assert that expr returns two values. Return those values.
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(defmacro assert-two-values (expr)
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`(assert-n-values 2 ,expr))
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; Assert that expr returns three values. Return those values.
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(defmacro assert-three-values (expr)
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`(assert-n-values 3 ,expr))
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;;; ------------------------------------------------------------------------------------------------------
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;;; STRUCTURED TYPES
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(defconstant *type-asserts* t)
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(defun tuple? (value structured-types)
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(if (endp structured-types)
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(null value)
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(and (consp value)
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(structured-type? (car value) (first structured-types))
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(tuple? (cdr value) (rest structured-types)))))
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(defun list-of? (value structured-type)
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(or
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(null value)
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(and (consp value)
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(structured-type? (car value) structured-type)
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(list-of? (cdr value) structured-type))))
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; Return true if value has the given structured-type.
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; A structured-type can be a Common Lisp type or one of the forms below:
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;
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; (cons t1 t2) is the type of pairs whose car has structured-type t1 and
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; cdr has structured-type t2.
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;
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; (tuple t1 t2 ... tn) is the type of n-element lists whose first element
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; has structured-type t1, second element has structured-type t2, ...,
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; and last element has structured-type tn.
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;
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; (list t) is the type of lists all of whose elements have structured-type t.
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;
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(defun structured-type? (value structured-type)
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(cond
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((consp structured-type)
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(case (first structured-type)
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(cons (and (consp value)
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(structured-type? (car value) (second structured-type))
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(structured-type? (cdr value) (third structured-type))))
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(tuple (tuple? value (rest structured-type)))
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(list (list-of? value (second structured-type)))
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(t (typep value structured-type))))
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((null structured-type) nil)
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(t (typep value structured-type))))
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; Ensure that value has type given by typespec
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; (which should not be quoted). Return the value.
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(defmacro assert-type (value structured-type)
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(if *type-asserts*
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(let ((v (gensym "VALUE")))
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`(let ((,v ,value))
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(unless (structured-type? ,v ',structured-type)
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(error "~S should have type ~S" ,v ',structured-type))
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,v))
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value))
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(deftype bool () '(member nil t))
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;;; ------------------------------------------------------------------------------------------------------
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;;; GENERAL UTILITIES
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; f must be either a function, a symbol, or a list of the form (setf <symbol>).
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; If f is a function or has a function binding, return that function; otherwise return nil.
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(defun callable (f)
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(cond
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((functionp f) f)
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((fboundp f) (fdefinition f))
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(t nil)))
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; Return the first character of symbol's name or nil if s's name has zero length.
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(defun first-symbol-char (symbol)
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(let ((name (symbol-name symbol)))
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(when (> (length name) 0)
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(char name 0))))
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(defconstant *get2-nonce* (if (boundp '*get2-nonce*) (symbol-value '*get2-nonce*) (gensym)))
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; Perform a get except that return two values:
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; The value returned from the get or nil if the property is not present
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; t if the property is present or nil if not.
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(defun get2 (symbol property)
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(let ((value (get symbol property *get2-nonce*)))
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(if (eq value *get2-nonce*)
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(values nil nil)
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(values value t))))
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; Return a list of all the keys in the hash table.
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(defun hash-table-keys (hash-table)
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(let ((keys nil))
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(maphash #'(lambda (key value)
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(declare (ignore value))
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(push key keys))
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hash-table)
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keys))
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; Return a list of all the keys in the hash table sorted by their string representations.
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(defun sorted-hash-table-keys (hash-table)
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(with-standard-io-syntax
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(let ((*print-readably* nil)
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(*print-escape* nil))
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(sort (hash-table-keys hash-table) #'string<
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:key #'(lambda (item)
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(if (symbolp item)
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(or (get item :sort-key)
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(symbol-name item))
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(write-to-string item)))))))
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; Return an association list of all the entries in the hash table.
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(defun hash-table-entries (hash-table)
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(let ((entries nil))
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(maphash #'(lambda (key value)
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(push (cons key value) entries))
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hash-table)
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entries))
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; Return true if the two hash tables are equal, using the given equality test for testing their elements.
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(defun hash-table-= (hash-table1 hash-table2 &key (test #'eql))
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(and (= (hash-table-count hash-table1) (hash-table-count hash-table2))
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(progn
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(maphash
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#'(lambda (key1 value1)
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(multiple-value-bind (value2 present2) (gethash key1 hash-table2)
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(unless (and present2 (funcall test value1 value2))
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(return-from hash-table-= nil))))
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hash-table1)
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t)))
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; Given an association list ((key1 . data1) (key2 . data2) ... (keyn datan)),
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; produce another association list whose keys are sets of the keys of the original list,
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; where the data elements of each such set are equal according to the given test function.
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; The keys within each set are listed in the same order as in the original list.
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; Set X comes before set Y if X contains a key earlier in the original list than any
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; key in Y.
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(defun collect-equivalences (alist &key (test #'eql))
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(if (endp alist)
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nil
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(let* ((element (car alist))
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(key (car element))
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(data (cdr element))
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(rest (cdr alist)))
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(if (rassoc data rest :test test)
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(let ((filtered-rest nil)
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(additional-keys nil))
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(dolist (elt rest)
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(if (funcall test data (cdr elt))
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(push (car elt) additional-keys)
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(push elt filtered-rest)))
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(acons (cons key (nreverse additional-keys)) data
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(collect-equivalences (nreverse filtered-rest) :test test)))
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(acons (list key) data (collect-equivalences rest :test test))))))
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;;; ------------------------------------------------------------------------------------------------------
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;;; BITMAPS
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; Treating integer m as a bitmap, call f on the number of each bit set in m.
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(defun bitmap-each-bit (f m)
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(assert-true (>= m 0))
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(dotimes (i (integer-length m))
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(when (logbitp i m)
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(funcall f i))))
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; Treating integer m as a bitmap, return a sorted list of disjoint, nonadjacent ranges
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; of bits set in m. Each range is a pair (x . y) and indicates that bits numbered x through
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; y, inclusive, are set in m. If m is negative, the last range will be a pair (x . :infinity).
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(defun bitmap-to-ranges (m)
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(labels
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((bitmap-to-ranges-sub (m ranges)
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(if (zerop m)
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ranges
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(let* ((hi (integer-length m))
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(m (- m (ash 1 hi)))
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(lo (integer-length m))
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(m (+ m (ash 1 lo))))
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(bitmap-to-ranges-sub m (acons lo (1- hi) ranges))))))
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(if (minusp m)
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(let* ((lo (integer-length m))
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(m (+ m (ash 1 lo))))
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(bitmap-to-ranges-sub m (list (cons lo :infinity))))
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(bitmap-to-ranges-sub m nil))))
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; Same as bitmap-to-ranges but abbreviate pairs (x . x) by x.
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(defun bitmap-to-abbreviated-ranges (m)
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(mapcar #'(lambda (range)
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(if (eql (car range) (cdr range))
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(car range)
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range))
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(bitmap-to-ranges m)))
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;;; ------------------------------------------------------------------------------------------------------
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;;; PACKAGES
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; Call f on each external symbol defined in the package.
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(defun each-package-external-symbol (package f)
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(with-package-iterator (iter package :external)
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(loop
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(multiple-value-bind (present symbol) (iter)
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(unless present
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(return))
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(funcall f symbol)))))
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; Return a list of all external symbols defined in the package.
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(defun package-external-symbols (package)
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(with-package-iterator (iter package :external)
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(let ((list nil))
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(loop
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(multiple-value-bind (present symbol) (iter)
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(unless present
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(return))
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(push symbol list)))
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list)))
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; Return a sorted list of all external symbols defined in the package.
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(defun sorted-package-external-symbols (package)
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(sort (package-external-symbols package) #'string<))
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; Call f on each internal symbol defined in the package.
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(defun each-package-internal-symbol (package f)
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(with-package-iterator (iter package :internal)
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(loop
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(multiple-value-bind (present symbol) (iter)
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(unless present
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(return))
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(funcall f symbol)))))
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; Return a list of all internal symbols defined in the package.
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(defun package-internal-symbols (package)
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(with-package-iterator (iter package :internal)
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(let ((list nil))
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(loop
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(multiple-value-bind (present symbol) (iter)
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(unless present
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(return))
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(push symbol list)))
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list)))
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; Return a sorted list of all internal symbols defined in the package.
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(defun sorted-package-internal-symbols (package)
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(sort (package-internal-symbols package) #'string<))
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;;; ------------------------------------------------------------------------------------------------------
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;;; INTSETS
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;;; An intset is a finite set of integers, represented as an ordered list of ranges.
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;;; Each range is a cons (low . high), both low and high being inclusive. Ranges must
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;;; be nonoverlapping, and adjacent ranges must be consolidated.
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(defconstant *empty-intset* nil)
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; Return true if the intset is valid.
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(defun valid-intset? (intset)
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(and (structured-type? intset '(list (cons integer integer)))
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(or (null intset)
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(let ((prev (- (caar intset) 2)))
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(dolist (range intset t)
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(let ((low (car range))
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(high (cdr range)))
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(unless (and (< prev (1- low)) (<= low high))
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(return nil))
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(setq prev high)))))))
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; Return an intset that is the union of the given intset and the intset
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; containg the given values.
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(defun intset-add-value (intset &rest values)
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(labels
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((add-value (intset value)
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(if (endp intset)
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(list (cons value value))
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(let* ((first-range (first intset))
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(rest (rest intset))
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(first-low (car first-range))
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(first-high (cdr first-range)))
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(cond
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((> value first-high)
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(cond
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((/= value (1+ first-high)) (cons first-range (add-value rest value)))
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((or (endp rest) (/= (caar rest) (1+ value))) (acons first-low value rest))
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(t (acons first-low (cdar rest) (rest rest)))))
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((< value first-low)
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(if (/= value (1- first-low))
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(acons value value intset)
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(acons value first-high rest)))
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(t intset))))))
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(dolist (value values)
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(assert-true (integerp value))
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(add-value intset value))))
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|
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; Return an intset that is the union of the given intset and the intset
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; containg all integers between low and high, inclusive. low <= high+1 is required.
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(defun intset-add-range (intset low high)
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(labels
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((add-range (intset low high)
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(if (endp intset)
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(list (cons low high))
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(let* ((first-range (first intset))
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(rest (rest intset))
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(first-low (car first-range))
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(first-high (cdr first-range)))
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(cond
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((> low (1+ first-high))
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(cons first-range (add-range rest low high)))
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((< high (1- first-low))
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|
(acons low high intset))
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((<= high first-high)
|
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(if (>= low first-low)
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|
intset
|
|
(acons low first-high rest)))
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(t (add-range rest (min low first-low) high)))))))
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|
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(assert-true (and (integerp low) (integerp high) (<= low (1+ high))))
|
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(if (= low (1+ high))
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intset
|
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(add-range intset low high))))
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|
|
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; Return an intset constructed from a list of ranges. Each range has two expressions,
|
|
; low and high. high can be null to indicate a one-element range.
|
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(defun intset-from-ranges (&rest ranges)
|
|
(if (endp ranges)
|
|
*empty-intset*
|
|
(progn
|
|
(assert-true (cdr ranges))
|
|
(intset-add-range (apply #'intset-from-ranges (cddr ranges))
|
|
(first ranges)
|
|
(or (second ranges) (first ranges))))))
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|
|
|
|
|
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; Return true if value is a member of the intset.
|
|
(defun intset-member? (intset value)
|
|
(if (endp intset)
|
|
nil
|
|
(let ((first-range (first intset)))
|
|
(if (> value (cdr first-range))
|
|
(intset-member? (rest intset) value)
|
|
(>= value (car first-range))))))
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|
|
|
|
|
; Return the union of the two intsets.
|
|
(defun intset-union (intset1 intset2)
|
|
(cond
|
|
((endp intset1) intset2)
|
|
((endp intset2) intset1)
|
|
(t (let* ((first-range1 (first intset1))
|
|
(rest1 (rest intset1))
|
|
(first-low1 (car first-range1))
|
|
(first-high1 (cdr first-range1))
|
|
(first-range2 (first intset2))
|
|
(rest2 (rest intset2))
|
|
(first-low2 (car first-range2))
|
|
(first-high2 (cdr first-range2)))
|
|
(cond
|
|
((< first-high1 (1- first-low2))
|
|
(cons first-range1 (intset-union rest1 intset2)))
|
|
((< first-high2 (1- first-low1))
|
|
(cons first-range2 (intset-union intset1 rest2)))
|
|
(t (intset-union (intset-add-range intset1 first-low2 first-high2) rest2)))))))
|
|
|
|
|
|
; Return the intersection of the two intsets.
|
|
(defun intset-intersection (intset1 intset2)
|
|
(if (or (endp intset1) (endp intset2))
|
|
nil
|
|
(let* ((first-range1 (first intset1))
|
|
(rest1 (rest intset1))
|
|
(first-low1 (car first-range1))
|
|
(first-high1 (cdr first-range1))
|
|
(first-range2 (first intset2))
|
|
(rest2 (rest intset2))
|
|
(first-low2 (car first-range2))
|
|
(first-high2 (cdr first-range2))
|
|
(low (max first-low1 first-low2)))
|
|
(cond
|
|
((< first-high1 first-high2)
|
|
(if (<= low first-high1)
|
|
(acons low first-high1 (intset-intersection rest1 intset2))
|
|
(intset-intersection rest1 intset2)))
|
|
((> first-high1 first-high2)
|
|
(if (<= low first-high2)
|
|
(acons low first-high2 (intset-intersection intset1 rest2))
|
|
(intset-intersection intset1 rest2)))
|
|
(t (acons low first-high1 (intset-intersection rest1 rest2)))))))
|
|
|
|
|
|
; Return the the intset containing the elements of intset1 that are not in intset2.
|
|
(defun intset-difference (intset1 intset2)
|
|
(cond
|
|
((endp intset1) nil)
|
|
((endp intset2) intset1)
|
|
(t (let* ((first-range1 (first intset1))
|
|
(rest1 (rest intset1))
|
|
(first-low1 (car first-range1))
|
|
(first-high1 (cdr first-range1))
|
|
(first-range2 (first intset2))
|
|
(rest2 (rest intset2))
|
|
(first-low2 (car first-range2))
|
|
(first-high2 (cdr first-range2)))
|
|
(cond
|
|
((< first-high1 first-low2)
|
|
(cons first-range1 (intset-difference rest1 intset2)))
|
|
((> first-low1 first-high2)
|
|
(intset-difference intset1 rest2))
|
|
((< first-low1 first-low2)
|
|
(acons first-low1 (1- first-low2) (intset-difference (acons first-low2 first-high1 rest1) intset2)))
|
|
((> first-high1 first-high2)
|
|
(intset-difference (acons (1+ first-high2) first-high1 rest1) rest2))
|
|
(t (intset-difference rest1 intset2)))))))
|
|
|
|
|
|
; Return true if the two intsets are equal.
|
|
(declaim (inline intset=))
|
|
(defun intset= (intset1 intset2)
|
|
(equal intset1 intset2))
|
|
|
|
|
|
; Return the number of elements in the intset.
|
|
(defun intset-length (intset)
|
|
(if (endp intset)
|
|
0
|
|
(+ 1 (- (cdar intset) (caar intset))
|
|
(intset-length (rest intset)))))
|
|
|
|
|
|
; Return the lowest element of the intset or nil if the intset is empty.
|
|
(declaim (inline intset-min))
|
|
(defun intset-min (intset)
|
|
(caar intset))
|
|
|
|
|
|
; Return the highest element of the intset or nil if the intset is empty.
|
|
(defun intset-max (intset)
|
|
(cdar (last intset)))
|
|
|
|
|
|
;;; ------------------------------------------------------------------------------------------------------
|
|
;;; PARTIAL ORDERS
|
|
|
|
(defstruct partial-order
|
|
(next-number 0 :type integer)) ;Bit number to use for next element
|
|
|
|
|
|
(defstruct (partial-order-element (:constructor make-partial-order-element (partial-order number predecessor-bitmap))
|
|
(:copier nil)
|
|
(:predicate partial-order-element?))
|
|
(partial-order nil :type partial-order) ;Partial order to which this element belongs
|
|
(number nil :type integer) ;Bit number of this element
|
|
(predecessor-bitmap nil :type integer)) ;Bitmap of elements less than or equal to this one in the partial order
|
|
|
|
|
|
; Construct a new unique element in the partial order that is greater than the
|
|
; given predecessors. Return that element.
|
|
(defun partial-order-add-element (partial-order &rest predecessors)
|
|
(let* ((number (partial-order-next-number partial-order))
|
|
(predecessor-bitmap (ash 1 number)))
|
|
(dolist (predecessor predecessors)
|
|
(assert-true (eq (partial-order-element-partial-order predecessor) partial-order))
|
|
(setq predecessor-bitmap (logior predecessor-bitmap (partial-order-element-predecessor-bitmap predecessor))))
|
|
(incf (partial-order-next-number partial-order))
|
|
(make-partial-order-element partial-order number predecessor-bitmap)))
|
|
|
|
|
|
(defmacro def-partial-order-element (partial-order name &rest predecessors)
|
|
`(defparameter ,name (partial-order-add-element ,partial-order ,@predecessors)))
|
|
|
|
|
|
; Return true if element1 is greater than or equal to element2 in this partial order.
|
|
(defun partial-order->= (element1 element2)
|
|
(assert-true (eq (partial-order-element-partial-order element1) (partial-order-element-partial-order element2)))
|
|
(logbitp (partial-order-element-number element2) (partial-order-element-predecessor-bitmap element1)))
|
|
|
|
|
|
; Return true if element1 is less than element2 in this partial order.
|
|
(declaim (inline partial-order-<))
|
|
(defun partial-order-< (element1 element2)
|
|
(not (partial-order->= element1 element2)))
|
|
|
|
|
|
;;; ------------------------------------------------------------------------------------------------------
|
|
;;; DEPTH-FIRST SEARCH
|
|
|
|
; Return a depth-first-ordered list of the nodes in a directed graph.
|
|
; The graph may contain cycles, so a general depth-first search is used.
|
|
; start is the start node.
|
|
; successors is a function that takes a node and returns a list of that
|
|
; node's successors.
|
|
; test is a function that takes two nodes and returns true if they are
|
|
; the same node. test should be either #'eq, #'eql, or #'equal
|
|
; because it is used as a test function in a hash table.
|
|
(defun depth-first-search (test successors start)
|
|
(let ((visited-nodes (make-hash-table :test test))
|
|
(dfs-list nil))
|
|
(labels
|
|
((visit (node)
|
|
(setf (gethash node visited-nodes) t)
|
|
(dolist (successor (funcall successors node))
|
|
(unless (gethash successor visited-nodes)
|
|
(visit successor)))
|
|
(push node dfs-list)))
|
|
(visit start)
|
|
dfs-list)))
|