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2109 lines
73 KiB
EmacsLisp
2109 lines
73 KiB
EmacsLisp
;;; calc-rewr.el --- rewriting functions for Calc -*- lexical-binding:t -*-
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;; Copyright (C) 1990-1993, 2001-2024 Free Software Foundation, Inc.
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;; Author: David Gillespie <daveg@synaptics.com>
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;; This file is part of GNU Emacs.
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;; GNU Emacs is free software: you can redistribute it and/or modify
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;; it under the terms of the GNU General Public License as published by
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;; the Free Software Foundation, either version 3 of the License, or
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;; (at your option) any later version.
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;; GNU Emacs is distributed in the hope that it will be useful,
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;; but WITHOUT ANY WARRANTY; without even the implied warranty of
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;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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;; GNU General Public License for more details.
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;; You should have received a copy of the GNU General Public License
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;; along with GNU Emacs. If not, see <https://www.gnu.org/licenses/>.
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;;; Commentary:
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;;; Code:
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;; This file is autoloaded from calc-ext.el.
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(require 'calc-ext)
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(require 'calc-macs)
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(defvar math-rewrite-default-iters 100)
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;; The variable calc-rewr-sel is local to calc-rewrite-selection and
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;; calc-rewrite, but is used by calc-locate-selection-marker.
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(defvar calc-rewr-sel)
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(defun calc-rewrite-selection (rules-str &optional many prefix)
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(interactive "sRewrite rule(s): \np")
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(calc-slow-wrapper
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(calc-preserve-point)
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(let* ((num (max 1 (calc-locate-cursor-element (point))))
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(reselect t)
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(pop-rules nil)
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rules
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(entry (calc-top num 'entry))
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(expr (car entry))
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(calc-rewr-sel (calc-auto-selection entry))
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(math-rewrite-selections t)
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(math-rewrite-default-iters 1))
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(if (or (null rules-str) (equal rules-str "") (equal rules-str "$"))
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(if (= num 1)
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(error "Can't use same stack entry for formula and rules")
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(setq rules (calc-top-n 1 t)
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pop-rules t))
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(setq rules (if (stringp rules-str)
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(math-read-exprs rules-str) rules-str))
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(if (eq (car-safe rules) 'error)
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(error "Bad format in expression: %s" (nth 1 rules)))
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(if (= (length rules) 1)
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(setq rules (car rules))
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(setq rules (cons 'vec rules)))
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(or (memq (car-safe rules) '(vec var calcFunc-assign
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calcFunc-condition))
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(let ((rhs (math-read-expr
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(read-string (concat "Rewrite from: " rules-str
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" to: ")))))
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(if (eq (car-safe rhs) 'error)
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(error "Bad format in expression: %s" (nth 1 rhs)))
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(setq rules (list 'calcFunc-assign rules rhs))))
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(or (eq (car-safe rules) 'var)
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(calc-record rules "rule")))
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(if (eq many 0)
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(setq many '(var inf var-inf))
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(if many (setq many (prefix-numeric-value many))))
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(if calc-rewr-sel
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(setq expr (calc-replace-sub-formula (car entry)
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calc-rewr-sel
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(list 'calcFunc-select calc-rewr-sel)))
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(setq expr (car entry)
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reselect nil
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math-rewrite-selections nil))
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(setq expr (calc-encase-atoms
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(calc-normalize
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(math-rewrite
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(calc-normalize expr)
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rules many)))
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calc-rewr-sel nil
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expr (calc-locate-select-marker expr))
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(or (consp calc-rewr-sel) (setq calc-rewr-sel nil))
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(if pop-rules (calc-pop-stack 1))
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(calc-pop-push-record-list 1 (or prefix "rwrt") (list expr)
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(- num (if pop-rules 1 0))
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(list (and reselect calc-rewr-sel))))
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(calc-handle-whys)))
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(defun calc-locate-select-marker (expr)
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(if (Math-primp expr)
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expr
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(if (and (eq (car expr) 'calcFunc-select)
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(= (length expr) 2))
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(progn
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(setq calc-rewr-sel (if calc-rewr-sel t (nth 1 expr)))
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(nth 1 expr))
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(cons (car expr)
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(mapcar 'calc-locate-select-marker (cdr expr))))))
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(defun calc-rewrite (rules-str many)
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(interactive "sRewrite rule(s): \nP")
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(calc-slow-wrapper
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(let (n rules expr)
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(if (or (null rules-str) (equal rules-str "") (equal rules-str "$"))
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(setq expr (calc-top-n 2)
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rules (calc-top-n 1 t)
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n 2)
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(setq rules (if (stringp rules-str)
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(math-read-exprs rules-str) rules-str))
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(if (eq (car-safe rules) 'error)
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(error "Bad format in expression: %s" (nth 1 rules)))
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(if (= (length rules) 1)
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(setq rules (car rules))
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(setq rules (cons 'vec rules)))
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(or (memq (car-safe rules) '(vec var calcFunc-assign
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calcFunc-condition))
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(let ((rhs (math-read-expr
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(read-string (concat "Rewrite from: " rules-str
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" to: ")))))
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(if (eq (car-safe rhs) 'error)
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(error "Bad format in expression: %s" (nth 1 rhs)))
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(setq rules (list 'calcFunc-assign rules rhs))))
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(or (eq (car-safe rules) 'var)
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(calc-record rules "rule"))
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(setq expr (calc-top-n 1)
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n 1))
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(if (eq many 0)
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(setq many '(var inf var-inf))
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(if many (setq many (prefix-numeric-value many))))
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(setq expr (calc-normalize (math-rewrite expr rules many)))
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(let (calc-rewr-sel)
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(setq expr (calc-locate-select-marker expr)))
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(calc-pop-push-record-list n "rwrt" (list expr)))
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(calc-handle-whys)))
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(defun calc-match (pat &optional _interactive)
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(interactive "sPattern: \np")
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(calc-slow-wrapper
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(let (n expr)
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(if (or (null pat) (equal pat "") (equal pat "$"))
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(setq expr (calc-top-n 2)
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pat (calc-top-n 1)
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n 2)
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(setq pat (if (stringp pat) (math-read-expr pat) pat))
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(if (eq (car-safe pat) 'error)
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(error "Bad format in expression: %s" (nth 1 pat)))
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(if (not (eq (car-safe pat) 'var))
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(calc-record pat "pat"))
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(setq expr (calc-top-n 1)
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n 1))
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(or (math-vectorp expr) (error "Argument must be a vector"))
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(calc-enter-result n "mtcn"
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(math-match-patterns pat expr
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(not (not (calc-is-inverse))))))))
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(defvar math-mt-many)
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;; The variable math-rewrite-whole-expr is local to math-rewrite,
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;; but is used by math-rewrite-phase
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(defvar math-rewrite-whole-expr)
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(defun math-rewrite (rewrite-whole-expr rules &optional mt-many)
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(let* ((math-rewrite-whole-expr rewrite-whole-expr)
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(math-mt-many mt-many)
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(crules (math-compile-rewrites rules))
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(heads (math-rewrite-heads math-rewrite-whole-expr))
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(trace-buffer (get-buffer "*Trace*"))
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(calc-display-just 'center)
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(calc-display-origin 39)
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(calc-line-breaking 78)
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(calc-line-numbering nil)
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(calc-show-selections t)
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(calc-why nil)
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(math-mt-func (lambda (x)
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(let ((result (math-apply-rewrites x (cdr crules)
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heads crules)))
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(if result
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(progn
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(if trace-buffer
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(let ((fmt (math-format-stack-value
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(list result nil nil))))
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(with-current-buffer trace-buffer
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(insert "\nrewrite to\n" fmt "\n"))))
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(setq heads (math-rewrite-heads result heads t))))
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result))))
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(if trace-buffer
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(let ((fmt (math-format-stack-value (list math-rewrite-whole-expr nil nil))))
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(with-current-buffer trace-buffer
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(setq truncate-lines t)
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(goto-char (point-max))
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(insert "\n\nBegin rewriting\n" fmt "\n"))))
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(or math-mt-many (setq math-mt-many (or (nth 1 (car crules))
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math-rewrite-default-iters)))
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(if (equal math-mt-many '(var inf var-inf)) (setq math-mt-many 1000000))
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(if (equal math-mt-many '(neg (var inf var-inf))) (setq math-mt-many -1000000))
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(math-rewrite-phase (nth 3 (car crules)))
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(if trace-buffer
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(let ((fmt (math-format-stack-value (list math-rewrite-whole-expr nil nil))))
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(with-current-buffer trace-buffer
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(insert "\nDone rewriting"
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(if (= math-mt-many 0) " (reached iteration limit)" "")
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":\n" fmt "\n"))))
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math-rewrite-whole-expr))
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(defvar math-rewrite-phase 1)
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(defun math-rewrite-phase (sched)
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(while (and sched (/= math-mt-many 0))
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(if (listp (car sched))
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(while (let ((save-expr math-rewrite-whole-expr))
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(math-rewrite-phase (car sched))
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(not (equal math-rewrite-whole-expr save-expr))))
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(if (symbolp (car sched))
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(progn
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(setq math-rewrite-whole-expr
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(math-normalize (list (car sched) math-rewrite-whole-expr)))
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(if trace-buffer
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(let ((fmt (math-format-stack-value
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(list math-rewrite-whole-expr nil nil))))
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(with-current-buffer trace-buffer
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(insert "\ncall "
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(substring (symbol-name (car sched)) 9)
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":\n" fmt "\n")))))
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(let ((math-rewrite-phase (car sched)))
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(if trace-buffer
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(with-current-buffer trace-buffer
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(insert (format "\n(Phase %d)\n" math-rewrite-phase))))
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(while (let ((save-expr math-rewrite-whole-expr))
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(setq math-rewrite-whole-expr (math-normalize
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(math-map-tree-rec math-rewrite-whole-expr)))
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(not (equal math-rewrite-whole-expr save-expr)))))))
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(setq sched (cdr sched))))
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(defun calcFunc-rewrite (expr rules &optional many)
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(or (null many) (integerp many)
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(equal many '(var inf var-inf)) (equal many '(neg (var inf var-inf)))
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(math-reject-arg many 'fixnump))
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(condition-case err
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(math-rewrite expr rules (or many 1))
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(error (math-reject-arg rules (nth 1 err)))))
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(defun calcFunc-match (pat vec)
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(or (math-vectorp vec) (math-reject-arg vec 'vectorp))
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(condition-case err
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(math-match-patterns pat vec nil)
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(error (math-reject-arg pat (nth 1 err)))))
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(defun calcFunc-matchnot (pat vec)
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(or (math-vectorp vec) (math-reject-arg vec 'vectorp))
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(condition-case err
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(math-match-patterns pat vec t)
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(error (math-reject-arg pat (nth 1 err)))))
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(defun math-match-patterns (pat vec &optional not-flag)
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(let ((newvec nil)
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(crules (math-compile-patterns pat)))
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(while (setq vec (cdr vec))
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(if (eq (not (math-apply-rewrites (car vec) crules))
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not-flag)
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(setq newvec (cons (car vec) newvec))))
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(cons 'vec (nreverse newvec))))
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(defun calcFunc-matches (expr pat)
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(condition-case err
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(if (math-apply-rewrites expr (math-compile-patterns pat))
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1
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0)
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(error (math-reject-arg pat (nth 1 err)))))
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(defun calcFunc-vmatches (expr pat)
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(condition-case err
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(or (math-apply-rewrites expr (math-compile-patterns pat))
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0)
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(error (math-reject-arg pat (nth 1 err)))))
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;; A compiled rule set is an a-list of entries whose cars are functors,
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;; and whose cdrs are lists of rules. If there are rules with no
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;; well-defined head functor, they are included on all lists and also
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;; on an extra list whose car is nil.
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;;
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;; The first entry in the a-list is of the form (schedule A B C ...).
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;;
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;; Rule list entries take the form (regs prog head phases), where:
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;;
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;; regs is a vector of match registers.
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;;
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;; prog is a match program (see below).
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;;
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;; head is a rare function name appearing in the rule body (but not the
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;; head of the whole rule), or nil if none.
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;;
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;; phases is a list of phase numbers for which the rule is enabled.
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;;
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;; A match program is a list of match instructions.
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;;
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;; In the following, "part" is a register number that contains the
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;; subexpression to be operated on.
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;;
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;; Register 0 is the whole expression being matched. The others are
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;; meta-variables in the pattern, temporaries used for matching and
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;; backtracking, and constant expressions.
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;;
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;; (same part reg)
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;; The selected part must be math-equal to the contents of "reg".
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;;
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;; (same-neg part reg)
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;; The selected part must be math-equal to the negative of "reg".
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;;
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;; (copy part reg)
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;; The selected part is copied into "reg". (Rarely used.)
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;;
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;; (copy-neg part reg)
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;; The negative of the selected part is copied into "reg".
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;;
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;; (integer part)
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;; The selected part must be an integer.
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;;
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;; (real part)
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;; The selected part must be a real.
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;;
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;; (constant part)
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;; The selected part must be a constant.
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;;
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;; (negative part)
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;; The selected part must "look" negative.
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;;
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;; (rel part op reg)
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;; The selected part must satisfy "part op reg", where "op"
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;; is one of the 6 relational ops, and "reg" is a register.
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;;
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;; (mod part modulo value)
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;; The selected part must satisfy "part % modulo = value", where
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;; "modulo" and "value" are constants.
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;;
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;; (func part head reg1 reg2 ... regn)
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;; The selected part must be an n-ary call to function "head".
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;; The arguments are stored in "reg1" through "regn".
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;;
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;; (func-def part head defs reg1 reg2 ... regn)
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;; The selected part must be an n-ary call to function "head".
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;; "Defs" is a list of value/register number pairs for default args.
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;; If a match, assign default values to registers and then skip
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;; immediately over any following "func-def" instructions and
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;; the following "func" instruction. If wrong number of arguments,
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;; proceed to the following "func-def" or "func" instruction.
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;;
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;; (func-opt part head defs reg1)
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;; Like func-def with "n=1", except that if the selected part is
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;; not a call to "head", then the part itself successfully matches
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;; "reg1" (and the defaults are assigned).
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;;
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;; (try part heads mark reg1 [def])
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;; The selected part must be a function of the correct type which is
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;; associative and/or commutative. "Heads" is a list of acceptable
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;; types. An initial assignment of arguments to "reg1" is tried.
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;; If the program later fails, it backtracks to this instruction
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;; and tries other assignments of arguments to "reg1".
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;; If "def" exists and normal matching fails, backtrack and assign
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;; "part" to "reg1", and "def" to "reg2" in the following "try2".
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;; The "mark" is a vector of size 5; only "mark[3-4]" are initialized.
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;; "mark[0]" points to the argument list; "mark[1]" points to the
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;; current argument; "mark[2]" is 0 if there are two arguments,
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;; 1 if reg1 is matching single arguments, 2 if reg2 is matching
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;; single arguments (a+b+c+d is never split as (a+b)+(c+d)), or
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;; 3 if reg2 is matching "def"; "mark[3]" is 0 if the function must
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;; have two arguments, 1 if phase-2 can be skipped, 2 if full
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;; backtracking is necessary; "mark[4]" is t if the arguments have
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;; been switched from the order given in the original pattern.
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;;
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;; (try2 try reg2)
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;; Every "try" will be followed by a "try2" whose "try" field is
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;; a pointer to the corresponding "try". The arguments which were
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;; not stored in "reg1" by that "try" are now stored in "reg2".
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;;
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;; (alt instr nil mark)
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;; Basic backtracking. Execute the instruction sequence "instr".
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;; If this fails, back up and execute following the "alt" instruction.
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;; The "mark" must be the vector "[nil nil 4]". The "instr" sequence
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;; should execute "end-alt" at the end.
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;;
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;; (end-alt ptr)
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;; Register success of the first alternative of a previous "alt".
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;; "Ptr" is a pointer to the next instruction following that "alt".
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;;
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;; (apply part reg1 reg2)
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;; The selected part must be a function call. The functor
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;; (as a variable name) is stored in "reg1"; the arguments
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;; (as a vector) are stored in "reg2".
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;;
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;; (cons part reg1 reg2)
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;; The selected part must be a nonempty vector. The first element
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;; of the vector is stored in "reg1"; the rest of the vector
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;; (as another vector) is stored in "reg2".
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;;
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;; (rcons part reg1 reg2)
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;; The selected part must be a nonempty vector. The last element
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;; of the vector is stored in "reg2"; the rest of the vector
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;; (as another vector) is stored in "reg1".
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;;
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;; (select part reg)
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;; If the selected part is a unary call to function "select", its
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;; argument is stored in "reg"; otherwise (provided this is an `a r'
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;; and not a `g r' command) the selected part is stored in "reg".
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;;
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;; (cond expr)
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;; The "expr", with registers substituted, must simplify to
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;; a non-zero value.
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;;
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;; (let reg expr)
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;; Evaluate "expr" and store the result in "reg". Always succeeds.
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;;
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;; (done rhs remember)
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;; Rewrite the expression to "rhs", with register substituted.
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;; Normalize; if the result is different from the original
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;; expression, the match has succeeded. This is the last
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;; instruction of every program. If "remember" is non-nil,
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;; record the result of the match as a new literal rule.
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;; Pseudo-functions related to rewrites:
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;;
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;; In patterns: quote, plain, condition, opt, apply, cons, select
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;;
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;; In righthand sides: quote, plain, eval, evalsimp, evalextsimp,
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;; apply, cons, select
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;;
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;; In conditions: let + same as for righthand sides
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;; Some optimizations that would be nice to have:
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;;
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;; * Merge registers with disjoint lifetimes.
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;; * Merge constant registers with equivalent values.
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;;
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;; * If an argument of a commutative op math-depends neither on the
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;; rest of the pattern nor on any of the conditions, then no backtracking
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;; should be done for that argument. (This won't apply to very many
|
|
;; cases.)
|
|
;;
|
|
;; * If top functor is "select", and its argument is a unique function,
|
|
;; add the rule to the lists for both "select" and that function.
|
|
;; (Currently rules like this go on the "nil" list.)
|
|
;; Same for "func-opt" functions. (Though not urgent for these.)
|
|
;;
|
|
;; * Shouldn't evaluate a "let" condition until the end, or until it
|
|
;; would enable another condition to be evaluated.
|
|
;;
|
|
|
|
;; Some additional features to add / things to think about:
|
|
;;;
|
|
;;; * Figure out what happens to "a +/- b" and "a +/- opt(b)".
|
|
;;;
|
|
;;; * Same for interval forms.
|
|
;;;
|
|
;;; * Have a name(v,pat) pattern which matches pat, and gives the
|
|
;;; whole match the name v. Beware of circular structures!
|
|
;;;
|
|
|
|
(defvar math-rewrite-whole nil)
|
|
|
|
(defun math-compile-patterns (pats)
|
|
(if (and (eq (car-safe pats) 'var)
|
|
(calc-var-value (nth 2 pats)))
|
|
(let ((prop (get (nth 2 pats) 'math-pattern-cache)))
|
|
(or prop
|
|
(put (nth 2 pats) 'math-pattern-cache (setq prop (list nil))))
|
|
(or (eq (car prop) (symbol-value (nth 2 pats)))
|
|
(progn
|
|
(setcdr prop (math-compile-patterns
|
|
(symbol-value (nth 2 pats))))
|
|
(setcar prop (symbol-value (nth 2 pats)))))
|
|
(cdr prop))
|
|
(let ((math-rewrite-whole t))
|
|
(cdr (math-compile-rewrites (cons
|
|
'vec
|
|
(mapcar (lambda (x)
|
|
(list 'vec x t))
|
|
(if (eq (car-safe pats) 'vec)
|
|
(cdr pats)
|
|
(list pats)))))))))
|
|
|
|
(defvar math-make-import-list nil)
|
|
|
|
;; The variable math-import-list is local to part of math-compile-rewrites,
|
|
;; but is also used in a different part, and so the local version could
|
|
;; be affected by the non-local version when math-compile-rewrites calls itself.
|
|
(defvar math-import-list nil)
|
|
|
|
;; The variables math-regs, math-num-regs, math-prog-last, math-bound-vars,
|
|
;; math-conds, math-copy-neg, math-rhs, math-pattern, math-remembering and
|
|
;; math-aliased-vars are local to math-compile-rewrites,
|
|
;; but are used by many functions math-rwcomp-*, which are called by
|
|
;; math-compile-rewrites.
|
|
(defvar math-regs)
|
|
(defvar math-num-regs)
|
|
(defvar math-prog-last)
|
|
(defvar math-bound-vars)
|
|
(defvar math-conds)
|
|
(defvar math-copy-neg)
|
|
(defvar math-rhs)
|
|
(defvar math-pattern)
|
|
(defvar math-remembering)
|
|
(defvar math-aliased-vars)
|
|
|
|
(defun math-compile-rewrites (rules &optional name)
|
|
(if (eq (car-safe rules) 'var)
|
|
(let ((prop (get (nth 2 rules) 'math-rewrite-cache))
|
|
(math-import-list nil)
|
|
(math-make-import-list t)
|
|
p)
|
|
(or (calc-var-value (nth 2 rules))
|
|
(error "Rules variable %s has no stored value" (nth 1 rules)))
|
|
(or prop
|
|
(put (nth 2 rules) 'math-rewrite-cache
|
|
(setq prop (list (list (cons (nth 2 rules) nil))))))
|
|
(setq p (car prop))
|
|
(while (and p (eq (symbol-value (car (car p))) (cdr (car p))))
|
|
(setq p (cdr p)))
|
|
(or (null p)
|
|
(progn
|
|
(message "Compiling rule set %s..." (nth 1 rules))
|
|
(setcdr prop (math-compile-rewrites
|
|
(symbol-value (nth 2 rules))
|
|
(nth 2 rules)))
|
|
(message "Compiling rule set %s...done" (nth 1 rules))
|
|
(setcar prop (cons (cons (nth 2 rules)
|
|
(symbol-value (nth 2 rules)))
|
|
math-import-list))))
|
|
(cdr prop))
|
|
(if (or (not (eq (car-safe rules) 'vec))
|
|
(and (memq (length rules) '(3 4))
|
|
(let ((p rules))
|
|
(while (and (setq p (cdr p))
|
|
(memq (car-safe (car p))
|
|
'(vec
|
|
calcFunc-assign
|
|
calcFunc-condition
|
|
calcFunc-import
|
|
calcFunc-phase
|
|
calcFunc-schedule
|
|
calcFunc-iterations))))
|
|
p)))
|
|
(setq rules (list rules))
|
|
(setq rules (cdr rules)))
|
|
(if (assq 'calcFunc-import rules)
|
|
(let ((pp (setq rules (copy-sequence rules)))
|
|
p part)
|
|
(while (setq p (car (cdr pp)))
|
|
(if (eq (car-safe p) 'calcFunc-import)
|
|
(progn
|
|
(setcdr pp (cdr (cdr pp)))
|
|
(or (and (eq (car-safe (nth 1 p)) 'var)
|
|
(setq part (calc-var-value (nth 2 (nth 1 p))))
|
|
(memq (car-safe part) '(vec
|
|
calcFunc-assign
|
|
calcFunc-condition)))
|
|
(error "Argument of import() must be a rules variable"))
|
|
(if math-make-import-list
|
|
(setq math-import-list
|
|
(cons (cons (nth 2 (nth 1 p))
|
|
(symbol-value (nth 2 (nth 1 p))))
|
|
math-import-list)))
|
|
(while (setq p (cdr (cdr p)))
|
|
(or (cdr p)
|
|
(error "import() must have odd number of arguments"))
|
|
(setq part (math-rwcomp-substitute part
|
|
(car p) (nth 1 p))))
|
|
(if (eq (car-safe part) 'vec)
|
|
(setq part (cdr part))
|
|
(setq part (list part)))
|
|
(setcdr pp (append part (cdr pp))))
|
|
(setq pp (cdr pp))))))
|
|
(let ((rule-set nil)
|
|
(all-heads nil)
|
|
(nil-rules nil)
|
|
;; (rule-count 0)
|
|
(math-schedule nil)
|
|
(math-iterations nil)
|
|
(math-phases nil)
|
|
(math-all-phases nil)
|
|
(math-remembering nil)
|
|
math-pattern math-rhs math-conds)
|
|
(while rules
|
|
(cond
|
|
((and (eq (car-safe (car rules)) 'calcFunc-iterations)
|
|
(= (length (car rules)) 2))
|
|
(or (integerp (nth 1 (car rules)))
|
|
(equal (nth 1 (car rules)) '(var inf var-inf))
|
|
(equal (nth 1 (car rules)) '(neg (var inf var-inf)))
|
|
(error "Invalid argument for iterations(n)"))
|
|
(or math-iterations
|
|
(setq math-iterations (nth 1 (car rules)))))
|
|
((eq (car-safe (car rules)) 'calcFunc-schedule)
|
|
(or math-schedule
|
|
(setq math-schedule (math-parse-schedule (cdr (car rules))))))
|
|
((eq (car-safe (car rules)) 'calcFunc-phase)
|
|
(setq math-phases (cdr (car rules)))
|
|
(if (equal math-phases '((var all var-all)))
|
|
(setq math-phases nil))
|
|
(let ((p math-phases))
|
|
(while p
|
|
(or (integerp (car p))
|
|
(error "Phase numbers must be small integers"))
|
|
(or (memq (car p) math-all-phases)
|
|
(setq math-all-phases (cons (car p) math-all-phases)))
|
|
(setq p (cdr p)))))
|
|
((or (and (eq (car-safe (car rules)) 'vec)
|
|
(cdr (cdr (car rules)))
|
|
(not (nthcdr 4 (car rules)))
|
|
(setq math-conds (nth 3 (car rules))
|
|
math-rhs (nth 2 (car rules))
|
|
math-pattern (nth 1 (car rules))))
|
|
(progn
|
|
(setq math-conds nil
|
|
math-pattern (car rules))
|
|
(while (and (eq (car-safe math-pattern) 'calcFunc-condition)
|
|
(= (length math-pattern) 3))
|
|
(let ((cond (nth 2 math-pattern)))
|
|
(setq math-conds (if math-conds
|
|
(list 'calcFunc-land math-conds cond)
|
|
cond)
|
|
math-pattern (nth 1 math-pattern))))
|
|
(and (eq (car-safe math-pattern) 'calcFunc-assign)
|
|
(= (length math-pattern) 3)
|
|
(setq math-rhs (nth 2 math-pattern)
|
|
math-pattern (nth 1 math-pattern)))))
|
|
(let* ((math-prog (list nil))
|
|
(math-prog-last math-prog)
|
|
(math-num-regs 1)
|
|
(math-regs (list (list nil 0 nil nil)))
|
|
(math-bound-vars nil)
|
|
(math-aliased-vars nil)
|
|
(math-copy-neg nil))
|
|
(setq math-conds (and math-conds (math-flatten-lands math-conds)))
|
|
(math-rwcomp-pattern math-pattern 0)
|
|
(while math-conds
|
|
(let ((expr (car math-conds)))
|
|
(setq math-conds (cdr math-conds))
|
|
(math-rwcomp-cond-instr expr)))
|
|
(math-rwcomp-instr 'done
|
|
(if (eq math-rhs t)
|
|
(cons 'vec
|
|
(delq
|
|
nil
|
|
(nreverse
|
|
(mapcar
|
|
(lambda (v)
|
|
(and (car v)
|
|
(list
|
|
'calcFunc-assign
|
|
(math-build-var-name
|
|
(car v))
|
|
(math-rwcomp-register-expr
|
|
(nth 1 v)))))
|
|
math-regs))))
|
|
(math-rwcomp-match-vars math-rhs))
|
|
math-remembering)
|
|
(setq math-prog (cdr math-prog))
|
|
(let* ((heads (math-rewrite-heads math-pattern))
|
|
(rule (list (vconcat
|
|
(nreverse
|
|
(mapcar (lambda (x) (nth 3 x))
|
|
math-regs)))
|
|
math-prog
|
|
heads
|
|
math-phases))
|
|
(head (and (not (Math-primp math-pattern))
|
|
(not (and (eq (car (car math-prog)) 'try)
|
|
(nth 5 (car math-prog))))
|
|
(not (memq (car (car math-prog)) '(func-opt
|
|
apply
|
|
select
|
|
alt)))
|
|
(if (memq (car (car math-prog)) '(func
|
|
func-def))
|
|
(nth 2 (car math-prog))
|
|
(if (eq (car math-pattern) 'calcFunc-quote)
|
|
(car-safe (nth 1 math-pattern))
|
|
(car math-pattern))))))
|
|
(let (found)
|
|
(while heads
|
|
(if (setq found (assq (car heads) all-heads))
|
|
(setcdr found (1+ (cdr found)))
|
|
(setq all-heads (cons (cons (car heads) 1) all-heads)))
|
|
(setq heads (cdr heads))))
|
|
(if (eq head '-) (setq head '+))
|
|
(if (memq head '(calcFunc-cons calcFunc-rcons)) (setq head 'vec))
|
|
(if head
|
|
(progn
|
|
(nconc (or (assq head rule-set)
|
|
(car (setq rule-set (cons (cons head
|
|
(copy-sequence
|
|
nil-rules))
|
|
rule-set))))
|
|
(list rule))
|
|
(if (eq head '*)
|
|
(nconc (or (assq '/ rule-set)
|
|
(car (setq rule-set (cons (cons
|
|
'/
|
|
(copy-sequence
|
|
nil-rules))
|
|
rule-set))))
|
|
(list rule))))
|
|
(setq nil-rules (nconc nil-rules (list rule)))
|
|
(let ((ptr rule-set))
|
|
(while ptr
|
|
(nconc (car ptr) (list rule))
|
|
(setq ptr (cdr ptr))))))))
|
|
(t
|
|
(error "Rewrite rule set must be a vector of A := B rules")))
|
|
(setq rules (cdr rules)))
|
|
(if nil-rules
|
|
(setq rule-set (cons (cons nil nil-rules) rule-set)))
|
|
(setq all-heads (mapcar #'car
|
|
(sort all-heads (lambda (x y)
|
|
(< (cdr x) (cdr y))))))
|
|
(let ((set rule-set)
|
|
rule heads ptr)
|
|
(while set
|
|
(setq rule (cdr (car set)))
|
|
(while rule
|
|
(if (consp (setq heads (nth 2 (car rule))))
|
|
(progn
|
|
(setq heads (delq (car (car set)) heads)
|
|
ptr all-heads)
|
|
(while (and ptr (not (memq (car ptr) heads)))
|
|
(setq ptr (cdr ptr)))
|
|
(setcar (nthcdr 2 (car rule)) (car ptr))))
|
|
(setq rule (cdr rule)))
|
|
(setq set (cdr set))))
|
|
(let ((plus (assq '+ rule-set)))
|
|
(if plus
|
|
(setq rule-set (cons (cons '- (cdr plus)) rule-set))))
|
|
(cons (list 'schedule math-iterations name
|
|
(or math-schedule
|
|
(sort math-all-phases '<)
|
|
(list 1)))
|
|
rule-set))))
|
|
|
|
(defun math-flatten-lands (expr)
|
|
(if (eq (car-safe expr) 'calcFunc-land)
|
|
(append (math-flatten-lands (nth 1 expr))
|
|
(math-flatten-lands (nth 2 expr)))
|
|
(list expr)))
|
|
|
|
;; The variables math-rewrite-heads-heads (i.e.; heads for math-rewrite-heads)
|
|
;; math-rewrite-heads-blanks and math-rewrite-heads-skips are local to
|
|
;; math-rewrite-heads, but used by math-rewrite-heads-rec, which is called by
|
|
;; math-rewrite-heads.
|
|
(defvar math-rewrite-heads-heads)
|
|
(defvar math-rewrite-heads-skips)
|
|
(defvar math-rewrite-heads-blanks)
|
|
|
|
(defun math-rewrite-heads (expr &optional more all)
|
|
(let ((math-rewrite-heads-heads more)
|
|
(math-rewrite-heads-skips (and (not all)
|
|
'(calcFunc-apply calcFunc-condition calcFunc-opt
|
|
calcFunc-por calcFunc-pnot)))
|
|
(math-rewrite-heads-blanks (and (not all)
|
|
'(calcFunc-quote calcFunc-plain calcFunc-select
|
|
calcFunc-cons calcFunc-rcons
|
|
calcFunc-pand))))
|
|
(or (Math-primp expr)
|
|
(math-rewrite-heads-rec expr))
|
|
math-rewrite-heads-heads))
|
|
|
|
(defun math-rewrite-heads-rec (expr)
|
|
(or (memq (car expr) math-rewrite-heads-skips)
|
|
(progn
|
|
(or (memq (car expr) math-rewrite-heads-heads)
|
|
(memq (car expr) math-rewrite-heads-blanks)
|
|
(memq 'algebraic (get (car expr) 'math-rewrite-props))
|
|
(setq math-rewrite-heads-heads (cons (car expr) math-rewrite-heads-heads)))
|
|
(while (setq expr (cdr expr))
|
|
(or (Math-primp (car expr))
|
|
(math-rewrite-heads-rec (car expr)))))))
|
|
|
|
(defun math-parse-schedule (sched)
|
|
(mapcar (lambda (s)
|
|
(if (integerp s)
|
|
s
|
|
(if (math-vectorp s)
|
|
(math-parse-schedule (cdr s))
|
|
(if (eq (car-safe s) 'var)
|
|
(math-var-to-calcFunc s)
|
|
(error "Improper component in rewrite schedule")))))
|
|
sched))
|
|
|
|
(defun math-rwcomp-match-vars (expr)
|
|
(if (Math-primp expr)
|
|
(if (eq (car-safe expr) 'var)
|
|
(let ((entry (assq (nth 2 expr) math-regs)))
|
|
(if entry
|
|
(math-rwcomp-register-expr (nth 1 entry))
|
|
expr))
|
|
expr)
|
|
(if (and (eq (car expr) 'calcFunc-quote)
|
|
(= (length expr) 2))
|
|
(math-rwcomp-match-vars (nth 1 expr))
|
|
(if (and (eq (car expr) 'calcFunc-plain)
|
|
(= (length expr) 2)
|
|
(not (Math-primp (nth 1 expr))))
|
|
(list (car expr)
|
|
(cons (car (nth 1 expr))
|
|
(mapcar 'math-rwcomp-match-vars (cdr (nth 1 expr)))))
|
|
(cons (car expr)
|
|
(mapcar 'math-rwcomp-match-vars (cdr expr)))))))
|
|
|
|
(defun math-rwcomp-register-expr (num)
|
|
(let ((entry (nth (1- (- math-num-regs num)) math-regs)))
|
|
(if (nth 2 entry)
|
|
(list 'neg (list 'calcFunc-register (nth 1 entry)))
|
|
(list 'calcFunc-register (nth 1 entry)))))
|
|
|
|
;; The variables math-rwcomp-subst-old, math-rwcomp-subst-new,
|
|
;; math-rwcomp-subst-old-func and math-rwcomp-subst-new-func
|
|
;; are local to math-rwcomp-substitute, but are used by
|
|
;; math-rwcomp-subst-rec, which is called by math-rwcomp-substitute.
|
|
(defvar math-rwcomp-subst-new)
|
|
(defvar math-rwcomp-subst-old)
|
|
(defvar math-rwcomp-subst-new-func)
|
|
(defvar math-rwcomp-subst-old-func)
|
|
|
|
(defun math-rwcomp-substitute (expr rwcomp-subst-old rwcomp-subst-new)
|
|
(let ((math-rwcomp-subst-old rwcomp-subst-old)
|
|
(math-rwcomp-subst-new rwcomp-subst-new))
|
|
(if (and (eq (car-safe rwcomp-subst-old) 'var)
|
|
(memq (car-safe rwcomp-subst-new) '(var calcFunc-lambda)))
|
|
(let ((math-rwcomp-subst-old-func (math-var-to-calcFunc rwcomp-subst-old))
|
|
(math-rwcomp-subst-new-func (math-var-to-calcFunc rwcomp-subst-new)))
|
|
(math-rwcomp-subst-rec expr))
|
|
(let ((math-rwcomp-subst-old-func nil))
|
|
(math-rwcomp-subst-rec expr)))))
|
|
|
|
(defun math-rwcomp-subst-rec (expr)
|
|
(cond ((equal expr math-rwcomp-subst-old) math-rwcomp-subst-new)
|
|
((Math-primp expr) expr)
|
|
(t (if (eq (car expr) math-rwcomp-subst-old-func)
|
|
(math-build-call math-rwcomp-subst-new-func
|
|
(mapcar 'math-rwcomp-subst-rec
|
|
(cdr expr)))
|
|
(cons (car expr)
|
|
(mapcar 'math-rwcomp-subst-rec (cdr expr)))))))
|
|
|
|
(defvar math-rwcomp-tracing nil)
|
|
|
|
(defun math-rwcomp-trace (instr)
|
|
(when math-rwcomp-tracing
|
|
(terpri) (princ instr))
|
|
instr)
|
|
|
|
(defun math-rwcomp-instr (&rest instr)
|
|
(setcdr math-prog-last
|
|
(setq math-prog-last (list (math-rwcomp-trace instr)))))
|
|
|
|
(defun math-rwcomp-multi-instr (tail &rest instr)
|
|
(setcdr math-prog-last
|
|
(setq math-prog-last (list (math-rwcomp-trace (append instr tail))))))
|
|
|
|
(defun math-rwcomp-bind-var (reg var)
|
|
(setcar (math-rwcomp-reg-entry reg) (nth 2 var))
|
|
(setq math-bound-vars (cons (nth 2 var) math-bound-vars))
|
|
(math-rwcomp-do-conditions))
|
|
|
|
(defun math-rwcomp-unbind-vars (mark)
|
|
(while (not (eq math-bound-vars mark))
|
|
(setcar (assq (car math-bound-vars) math-regs) nil)
|
|
(setq math-bound-vars (cdr math-bound-vars))))
|
|
|
|
(defun math-rwcomp-do-conditions ()
|
|
(let ((cond math-conds))
|
|
(while cond
|
|
(if (math-rwcomp-all-regs-done (car cond))
|
|
(let ((expr (car cond)))
|
|
(setq math-conds (delq (car cond) math-conds))
|
|
(setcar cond 1)
|
|
(math-rwcomp-cond-instr expr)))
|
|
(setq cond (cdr cond)))))
|
|
|
|
(defun math-rwcomp-cond-instr (expr)
|
|
(let (op arg)
|
|
(cond ((and (eq (car-safe expr) 'calcFunc-matches)
|
|
(= (length expr) 3)
|
|
(eq (car-safe (setq arg (math-rwcomp-match-vars (nth 1 expr))))
|
|
'calcFunc-register))
|
|
(math-rwcomp-pattern (nth 2 expr) (nth 1 arg)))
|
|
((math-numberp (setq expr (math-rwcomp-match-vars expr)))
|
|
(if (Math-zerop expr)
|
|
(math-rwcomp-instr 'backtrack)))
|
|
((and (eq (car expr) 'calcFunc-let)
|
|
(= (length expr) 3))
|
|
(let ((reg (math-rwcomp-reg)))
|
|
(math-rwcomp-instr 'let reg (nth 2 expr))
|
|
(math-rwcomp-pattern (nth 1 expr) reg)))
|
|
((and (eq (car expr) 'calcFunc-let)
|
|
(= (length expr) 2)
|
|
(eq (car-safe (nth 1 expr)) 'calcFunc-assign)
|
|
(= (length (nth 1 expr)) 3))
|
|
(let ((reg (math-rwcomp-reg)))
|
|
(math-rwcomp-instr 'let reg (nth 2 (nth 1 expr)))
|
|
(math-rwcomp-pattern (nth 1 (nth 1 expr)) reg)))
|
|
((and (setq op (cdr (assq (car-safe expr)
|
|
'( (calcFunc-integer . integer)
|
|
(calcFunc-real . real)
|
|
(calcFunc-constant . constant)
|
|
(calcFunc-negative . negative) ))))
|
|
(= (length expr) 2)
|
|
(or (and (eq (car-safe (nth 1 expr)) 'neg)
|
|
(memq op '(integer real constant))
|
|
(setq arg (nth 1 (nth 1 expr))))
|
|
(setq arg (nth 1 expr)))
|
|
(eq (car-safe (setq arg (nth 1 expr))) 'calcFunc-register))
|
|
(math-rwcomp-instr op (nth 1 arg)))
|
|
((and (assq (car-safe expr) calc-tweak-eqn-table)
|
|
(= (length expr) 3)
|
|
(eq (car-safe (nth 1 expr)) 'calcFunc-register))
|
|
(if (math-constp (nth 2 expr))
|
|
(let ((reg (math-rwcomp-reg)))
|
|
(setcar (nthcdr 3 (car math-regs)) (nth 2 expr))
|
|
(math-rwcomp-instr 'rel (nth 1 (nth 1 expr))
|
|
(car expr) reg))
|
|
(if (eq (car (nth 2 expr)) 'calcFunc-register)
|
|
(math-rwcomp-instr 'rel (nth 1 (nth 1 expr))
|
|
(car expr) (nth 1 (nth 2 expr)))
|
|
(math-rwcomp-instr 'cond expr))))
|
|
((and (eq (car-safe expr) 'calcFunc-eq)
|
|
(= (length expr) 3)
|
|
(eq (car-safe (nth 1 expr)) '%)
|
|
(eq (car-safe (nth 1 (nth 1 expr))) 'calcFunc-register)
|
|
(math-constp (nth 2 (nth 1 expr)))
|
|
(math-constp (nth 2 expr)))
|
|
(math-rwcomp-instr 'mod (nth 1 (nth 1 (nth 1 expr)))
|
|
(nth 2 (nth 1 expr)) (nth 2 expr)))
|
|
((equal expr '(var remember var-remember))
|
|
(setq math-remembering 1))
|
|
((and (eq (car-safe expr) 'calcFunc-remember)
|
|
(= (length expr) 2))
|
|
(setq math-remembering (if math-remembering
|
|
(list 'calcFunc-lor
|
|
math-remembering (nth 1 expr))
|
|
(nth 1 expr))))
|
|
(t (math-rwcomp-instr 'cond expr)))))
|
|
|
|
(defun math-rwcomp-same-instr (reg1 reg2 neg)
|
|
(math-rwcomp-instr (if (eq (eq (nth 2 (math-rwcomp-reg-entry reg1))
|
|
(nth 2 (math-rwcomp-reg-entry reg2)))
|
|
neg)
|
|
'same-neg
|
|
'same)
|
|
reg1 reg2))
|
|
|
|
(defun math-rwcomp-copy-instr (reg1 reg2 neg)
|
|
(if (eq (eq (nth 2 (math-rwcomp-reg-entry reg1))
|
|
(nth 2 (math-rwcomp-reg-entry reg2)))
|
|
neg)
|
|
(math-rwcomp-instr 'copy-neg reg1 reg2)
|
|
(or (eq reg1 reg2)
|
|
(math-rwcomp-instr 'copy reg1 reg2))))
|
|
|
|
(defun math-rwcomp-reg ()
|
|
(prog1
|
|
math-num-regs
|
|
(setq math-regs (cons (list nil math-num-regs nil 0) math-regs)
|
|
math-num-regs (1+ math-num-regs))))
|
|
|
|
(defun math-rwcomp-reg-entry (num)
|
|
(nth (1- (- math-num-regs num)) math-regs))
|
|
|
|
|
|
(defun math-rwcomp-pattern (expr part &optional not-direct)
|
|
(cond ((or (math-rwcomp-no-vars expr)
|
|
(and (eq (car expr) 'calcFunc-quote)
|
|
(= (length expr) 2)
|
|
(setq expr (nth 1 expr))))
|
|
(if (eq (car-safe expr) 'calcFunc-register)
|
|
(math-rwcomp-same-instr part (nth 1 expr) nil)
|
|
(let ((reg (math-rwcomp-reg)))
|
|
(setcar (nthcdr 3 (car math-regs)) expr)
|
|
(math-rwcomp-same-instr part reg nil))))
|
|
((eq (car expr) 'var)
|
|
(let ((entry (assq (nth 2 expr) math-regs)))
|
|
(if entry
|
|
(math-rwcomp-same-instr part (nth 1 entry) nil)
|
|
(if not-direct
|
|
(let ((reg (math-rwcomp-reg)))
|
|
(math-rwcomp-pattern expr reg)
|
|
(math-rwcomp-copy-instr part reg nil))
|
|
(if (setq entry (assq (nth 2 expr) math-aliased-vars))
|
|
(progn
|
|
(setcar (math-rwcomp-reg-entry (nth 1 entry))
|
|
(nth 2 expr))
|
|
(setcar entry nil)
|
|
(math-rwcomp-copy-instr part (nth 1 entry) nil))
|
|
(math-rwcomp-bind-var part expr))))))
|
|
((and (eq (car expr) 'calcFunc-select)
|
|
(= (length expr) 2))
|
|
(let ((reg (math-rwcomp-reg)))
|
|
(math-rwcomp-instr 'select part reg)
|
|
(math-rwcomp-pattern (nth 1 expr) reg)))
|
|
((and (eq (car expr) 'calcFunc-opt)
|
|
(memq (length expr) '(2 3)))
|
|
(error "opt( ) occurs in context where it is not allowed"))
|
|
((eq (car expr) 'neg)
|
|
(if (eq (car (nth 1 expr)) 'var)
|
|
(let ((entry (assq (nth 2 (nth 1 expr)) math-regs)))
|
|
(if entry
|
|
(math-rwcomp-same-instr part (nth 1 entry) t)
|
|
(if math-copy-neg
|
|
(let ((reg (math-rwcomp-best-reg (nth 1 expr))))
|
|
(math-rwcomp-copy-instr part reg t)
|
|
(math-rwcomp-pattern (nth 1 expr) reg))
|
|
(setcar (cdr (cdr (math-rwcomp-reg-entry part))) t)
|
|
(math-rwcomp-pattern (nth 1 expr) part))))
|
|
(if (math-rwcomp-is-algebraic (nth 1 expr))
|
|
(math-rwcomp-cond-instr (list 'calcFunc-eq
|
|
(math-rwcomp-register-expr part)
|
|
expr))
|
|
(let ((reg (math-rwcomp-reg)))
|
|
(math-rwcomp-instr 'func part 'neg reg)
|
|
(math-rwcomp-pattern (nth 1 expr) reg)))))
|
|
((and (eq (car expr) 'calcFunc-apply)
|
|
(= (length expr) 3))
|
|
(let ((reg1 (math-rwcomp-reg))
|
|
(reg2 (math-rwcomp-reg)))
|
|
(math-rwcomp-instr 'apply part reg1 reg2)
|
|
(math-rwcomp-pattern (nth 1 expr) reg1)
|
|
(math-rwcomp-pattern (nth 2 expr) reg2)))
|
|
((and (eq (car expr) 'calcFunc-cons)
|
|
(= (length expr) 3))
|
|
(let ((reg1 (math-rwcomp-reg))
|
|
(reg2 (math-rwcomp-reg)))
|
|
(math-rwcomp-instr 'cons part reg1 reg2)
|
|
(math-rwcomp-pattern (nth 1 expr) reg1)
|
|
(math-rwcomp-pattern (nth 2 expr) reg2)))
|
|
((and (eq (car expr) 'calcFunc-rcons)
|
|
(= (length expr) 3))
|
|
(let ((reg1 (math-rwcomp-reg))
|
|
(reg2 (math-rwcomp-reg)))
|
|
(math-rwcomp-instr 'rcons part reg1 reg2)
|
|
(math-rwcomp-pattern (nth 1 expr) reg1)
|
|
(math-rwcomp-pattern (nth 2 expr) reg2)))
|
|
((and (eq (car expr) 'calcFunc-condition)
|
|
(>= (length expr) 3))
|
|
(math-rwcomp-pattern (nth 1 expr) part)
|
|
(setq expr (cdr expr))
|
|
(while (setq expr (cdr expr))
|
|
(let ((cond (math-flatten-lands (car expr))))
|
|
(while cond
|
|
(if (math-rwcomp-all-regs-done (car cond))
|
|
(math-rwcomp-cond-instr (car cond))
|
|
(setq math-conds (cons (car cond) math-conds)))
|
|
(setq cond (cdr cond))))))
|
|
((and (eq (car expr) 'calcFunc-pand)
|
|
(= (length expr) 3))
|
|
(math-rwcomp-pattern (nth 1 expr) part)
|
|
(math-rwcomp-pattern (nth 2 expr) part))
|
|
((and (eq (car expr) 'calcFunc-por)
|
|
(= (length expr) 3))
|
|
(math-rwcomp-instr 'alt nil nil [nil nil 4])
|
|
(let ((math-conds nil)
|
|
(head math-prog-last)
|
|
(mark math-bound-vars)
|
|
(math-copy-neg t))
|
|
(math-rwcomp-pattern (nth 1 expr) part t)
|
|
(let ((amark math-aliased-vars)
|
|
(math-aliased-vars math-aliased-vars)
|
|
(tail math-prog-last)
|
|
(p math-bound-vars)
|
|
entry)
|
|
(while (not (eq p mark))
|
|
(setq entry (assq (car p) math-regs)
|
|
math-aliased-vars (cons (list (car p) (nth 1 entry) nil)
|
|
math-aliased-vars)
|
|
p (cdr p))
|
|
(setcar (math-rwcomp-reg-entry (nth 1 entry)) nil))
|
|
(setcar (cdr (car head)) (cdr head))
|
|
(setcdr head nil)
|
|
(setq math-prog-last head)
|
|
(math-rwcomp-pattern (nth 2 expr) part)
|
|
(math-rwcomp-instr 'same 0 0)
|
|
(setcdr tail math-prog-last)
|
|
(setq p math-aliased-vars)
|
|
(while (not (eq p amark))
|
|
(if (car (car p))
|
|
(setcar (math-rwcomp-reg-entry (nth 1 (car p)))
|
|
(car (car p))))
|
|
(setq p (cdr p)))))
|
|
(math-rwcomp-do-conditions))
|
|
((and (eq (car expr) 'calcFunc-pnot)
|
|
(= (length expr) 2))
|
|
(math-rwcomp-instr 'alt nil nil [nil nil 4])
|
|
(let ((head math-prog-last)
|
|
(mark math-bound-vars))
|
|
(math-rwcomp-pattern (nth 1 expr) part)
|
|
(math-rwcomp-unbind-vars mark)
|
|
(math-rwcomp-instr 'end-alt head)
|
|
(math-rwcomp-instr 'backtrack)
|
|
(setcar (cdr (car head)) (cdr head))
|
|
(setcdr head nil)
|
|
(setq math-prog-last head)))
|
|
(t (let ((props (get (car expr) 'math-rewrite-props)))
|
|
(if (and (eq (car expr) 'calcFunc-plain)
|
|
(= (length expr) 2)
|
|
(not (math-primp (nth 1 expr))))
|
|
(setq expr (nth 1 expr))) ; but "props" is still nil
|
|
(if (and (memq 'algebraic props)
|
|
(math-rwcomp-is-algebraic expr))
|
|
(math-rwcomp-cond-instr (list 'calcFunc-eq
|
|
(math-rwcomp-register-expr part)
|
|
expr))
|
|
(if (and (memq 'commut props)
|
|
(= (length expr) 3))
|
|
(let ((arg1 (nth 1 expr))
|
|
(arg2 (nth 2 expr))
|
|
try1 def code head (flip nil))
|
|
(if (eq (car expr) '-)
|
|
(setq arg2 (math-rwcomp-neg arg2)))
|
|
(setq arg1 (cons arg1 (math-rwcomp-best-reg arg1))
|
|
arg2 (cons arg2 (math-rwcomp-best-reg arg2)))
|
|
(or (math-rwcomp-order arg1 arg2)
|
|
(setq def arg1 arg1 arg2 arg2 def flip t))
|
|
(if (math-rwcomp-optional-arg (car expr) arg1)
|
|
(error "Too many opt( ) arguments in this context"))
|
|
(setq def (math-rwcomp-optional-arg (car expr) arg2)
|
|
head (if (memq (car expr) '(+ -))
|
|
'(+ -)
|
|
(if (eq (car expr) '*)
|
|
'(* /)
|
|
(list (car expr))))
|
|
code (if (math-rwcomp-is-constrained
|
|
(car arg1) head)
|
|
(if (math-rwcomp-is-constrained
|
|
(car arg2) head)
|
|
0 1)
|
|
2))
|
|
(math-rwcomp-multi-instr (and def (list def))
|
|
'try part head
|
|
(vector nil nil nil code flip)
|
|
(cdr arg1))
|
|
(setq try1 (car math-prog-last))
|
|
(math-rwcomp-pattern (car arg1) (cdr arg1))
|
|
(math-rwcomp-instr 'try2 try1 (cdr arg2))
|
|
(if (and (= part 0) (not def) (not math-rewrite-whole)
|
|
(not (eq math-rhs t))
|
|
(setq def (get (car expr)
|
|
'math-rewrite-default)))
|
|
(let ((reg1 (math-rwcomp-reg))
|
|
(reg2 (math-rwcomp-reg)))
|
|
(if (= (aref (nth 3 try1) 3) 0)
|
|
(aset (nth 3 try1) 3 1))
|
|
(math-rwcomp-instr 'try (cdr arg2)
|
|
(if (equal head '(* /))
|
|
'(*) head)
|
|
(vector nil nil nil
|
|
(if (= code 0)
|
|
1 2)
|
|
nil)
|
|
reg1 def)
|
|
(setq try1 (car math-prog-last))
|
|
(math-rwcomp-pattern (car arg2) reg1)
|
|
(math-rwcomp-instr 'try2 try1 reg2)
|
|
(setq math-rhs (list (if (eq (car expr) '-)
|
|
'+ (car expr))
|
|
math-rhs
|
|
(list 'calcFunc-register
|
|
reg2))))
|
|
(math-rwcomp-pattern (car arg2) (cdr arg2))))
|
|
(let* ((args (mapcar (lambda (x)
|
|
(cons x (math-rwcomp-best-reg x)))
|
|
(cdr expr)))
|
|
(args2 (copy-sequence args))
|
|
(argp (reverse args2))
|
|
(defs nil)
|
|
(num 1))
|
|
(while argp
|
|
(let ((def (math-rwcomp-optional-arg (car expr)
|
|
(car argp))))
|
|
(if def
|
|
(progn
|
|
(setq args2 (delq (car argp) args2)
|
|
defs (cons (cons def (cdr (car argp)))
|
|
defs))
|
|
(math-rwcomp-multi-instr
|
|
(mapcar 'cdr args2)
|
|
(if (or (and (memq 'unary1 props)
|
|
(= (length args2) 1)
|
|
(eq (car args2) (car args)))
|
|
(and (memq 'unary2 props)
|
|
(= (length args) 2)
|
|
(eq (car args2) (nth 1 args))))
|
|
'func-opt
|
|
'func-def)
|
|
part (car expr)
|
|
defs))))
|
|
(setq argp (cdr argp)))
|
|
(math-rwcomp-multi-instr (mapcar 'cdr args)
|
|
'func part (car expr))
|
|
(setq args (sort args 'math-rwcomp-order))
|
|
(while args
|
|
(math-rwcomp-pattern (car (car args)) (cdr (car args)))
|
|
(setq num (1+ num)
|
|
args (cdr args))))))))))
|
|
|
|
(defun math-rwcomp-best-reg (x)
|
|
(or (and (eq (car-safe x) 'var)
|
|
(let ((entry (assq (nth 2 x) math-aliased-vars)))
|
|
(and entry
|
|
(not (nth 2 entry))
|
|
(not (nth 2 (math-rwcomp-reg-entry (nth 1 entry))))
|
|
(progn
|
|
(setcar (cdr (cdr entry)) t)
|
|
(nth 1 entry)))))
|
|
(math-rwcomp-reg)))
|
|
|
|
(defun math-rwcomp-all-regs-done (expr)
|
|
(if (Math-primp expr)
|
|
(or (not (eq (car-safe expr) 'var))
|
|
(assq (nth 2 expr) math-regs)
|
|
(eq (nth 2 expr) 'var-remember)
|
|
(math-const-var expr))
|
|
(if (and (eq (car expr) 'calcFunc-let)
|
|
(= (length expr) 3))
|
|
(math-rwcomp-all-regs-done (nth 2 expr))
|
|
(if (and (eq (car expr) 'calcFunc-let)
|
|
(= (length expr) 2)
|
|
(eq (car-safe (nth 1 expr)) 'calcFunc-assign)
|
|
(= (length (nth 1 expr)) 3))
|
|
(math-rwcomp-all-regs-done (nth 2 (nth 1 expr)))
|
|
(while (and (setq expr (cdr expr))
|
|
(math-rwcomp-all-regs-done (car expr))))
|
|
(null expr)))))
|
|
|
|
(defun math-rwcomp-no-vars (expr)
|
|
(if (Math-primp expr)
|
|
(or (not (eq (car-safe expr) 'var))
|
|
(math-const-var expr))
|
|
(and (not (memq (car expr) '(calcFunc-condition
|
|
calcFunc-select calcFunc-quote
|
|
calcFunc-plain calcFunc-opt
|
|
calcFunc-por calcFunc-pand
|
|
calcFunc-pnot calcFunc-apply
|
|
calcFunc-cons calcFunc-rcons)))
|
|
(progn
|
|
(while (and (setq expr (cdr expr))
|
|
(math-rwcomp-no-vars (car expr))))
|
|
(null expr)))))
|
|
|
|
(defun math-rwcomp-is-algebraic (expr)
|
|
(if (Math-primp expr)
|
|
(or (not (eq (car-safe expr) 'var))
|
|
(math-const-var expr)
|
|
(assq (nth 2 expr) math-regs))
|
|
(and (memq 'algebraic (get (car expr) 'math-rewrite-props))
|
|
(progn
|
|
(while (and (setq expr (cdr expr))
|
|
(math-rwcomp-is-algebraic (car expr))))
|
|
(null expr)))))
|
|
|
|
(defun math-rwcomp-is-constrained (expr not-these)
|
|
(if (Math-primp expr)
|
|
(not (eq (car-safe expr) 'var))
|
|
(if (eq (car expr) 'calcFunc-plain)
|
|
(math-rwcomp-is-constrained (nth 1 expr) not-these)
|
|
(not (or (memq (car expr) '(neg calcFunc-select))
|
|
(memq (car expr) not-these)
|
|
(and (memq 'commut (get (car expr) 'math-rewrite-props))
|
|
(or (eq (car-safe (nth 1 expr)) 'calcFunc-opt)
|
|
(eq (car-safe (nth 2 expr)) 'calcFunc-opt))))))))
|
|
|
|
(defun math-rwcomp-optional-arg (head argp)
|
|
(let ((arg (car argp)))
|
|
(if (eq (car-safe arg) 'calcFunc-opt)
|
|
(and (memq (length arg) '(2 3))
|
|
(progn
|
|
(or (eq (car-safe (nth 1 arg)) 'var)
|
|
(error "First argument of opt( ) must be a variable"))
|
|
(setcar argp (nth 1 arg))
|
|
(if (= (length arg) 2)
|
|
(or (get head 'math-rewrite-default)
|
|
(error "opt( ) must include a default in this context"))
|
|
(nth 2 arg))))
|
|
(and (eq (car-safe arg) 'neg)
|
|
(let* ((part (list (nth 1 arg)))
|
|
(partp (math-rwcomp-optional-arg head part)))
|
|
(and partp
|
|
(setcar argp (math-rwcomp-neg (car part)))
|
|
(math-neg partp)))))))
|
|
|
|
(defun math-rwcomp-neg (expr)
|
|
(if (memq (car-safe expr) '(* /))
|
|
(if (eq (car-safe (nth 1 expr)) 'var)
|
|
(list (car expr) (list 'neg (nth 1 expr)) (nth 2 expr))
|
|
(if (eq (car-safe (nth 2 expr)) 'var)
|
|
(list (car expr) (nth 1 expr) (list 'neg (nth 2 expr)))
|
|
(math-neg expr)))
|
|
(math-neg expr)))
|
|
|
|
(defun math-rwcomp-assoc-args (expr)
|
|
(if (and (eq (car-safe (nth 1 expr)) (car expr))
|
|
(= (length (nth 1 expr)) 3))
|
|
(math-rwcomp-assoc-args (nth 1 expr)))
|
|
(if (and (eq (car-safe (nth 2 expr)) (car expr))
|
|
(= (length (nth 2 expr)) 3))
|
|
(math-rwcomp-assoc-args (nth 2 expr))))
|
|
|
|
(defun math-rwcomp-addsub-args (expr)
|
|
(if (memq (car-safe (nth 1 expr)) '(+ -))
|
|
(math-rwcomp-addsub-args (nth 1 expr)))
|
|
(if (eq (car expr) '-)
|
|
()
|
|
(if (eq (car-safe (nth 2 expr)) '+)
|
|
(math-rwcomp-addsub-args (nth 2 expr)))))
|
|
|
|
(defun math-rwcomp-order (a b)
|
|
(< (math-rwcomp-priority (car a))
|
|
(math-rwcomp-priority (car b))))
|
|
|
|
;; Order of priority: 0 Constants and other exact matches (first)
|
|
;; 10 Functions (except below)
|
|
;; 20 Meta-variables which occur more than once
|
|
;; 30 Algebraic functions
|
|
;; 40 Commutative/associative functions
|
|
;; 50 Meta-variables which occur only once
|
|
;; +100 for every "!!!" (pnot) in the pattern
|
|
;; 10000 Optional arguments (last)
|
|
|
|
(defun math-rwcomp-priority (expr)
|
|
(+ (math-rwcomp-count-pnots expr)
|
|
(cond ((eq (car-safe expr) 'calcFunc-opt)
|
|
10000)
|
|
((math-rwcomp-no-vars expr)
|
|
0)
|
|
((eq (car expr) 'calcFunc-quote)
|
|
0)
|
|
((eq (car expr) 'var)
|
|
(if (assq (nth 2 expr) math-regs)
|
|
0
|
|
(if (= (math-rwcomp-count-refs expr) 1)
|
|
50
|
|
20)))
|
|
(t (let ((props (get (car expr) 'math-rewrite-props)))
|
|
(if (or (memq 'commut props)
|
|
(memq 'assoc props))
|
|
40
|
|
(if (memq 'algebraic props)
|
|
30
|
|
10)))))))
|
|
|
|
(defun math-rwcomp-count-refs (var)
|
|
(let ((count (or (math-expr-contains-count math-pattern var) 0))
|
|
(p math-conds))
|
|
(while p
|
|
(if (eq (car-safe (car p)) 'calcFunc-let)
|
|
(if (= (length (car p)) 3)
|
|
(setq count (+ count
|
|
(or (math-expr-contains-count (nth 2 (car p)) var)
|
|
0)))
|
|
(if (and (= (length (car p)) 2)
|
|
(eq (car-safe (nth 1 (car p))) 'calcFunc-assign)
|
|
(= (length (nth 1 (car p))) 3))
|
|
(setq count (+ count
|
|
(or (math-expr-contains-count
|
|
(nth 2 (nth 1 (car p))) var) 0))))))
|
|
(setq p (cdr p)))
|
|
count))
|
|
|
|
(defun math-rwcomp-count-pnots (expr)
|
|
(if (Math-primp expr)
|
|
0
|
|
(if (eq (car expr) 'calcFunc-pnot)
|
|
100
|
|
(let ((count 0))
|
|
(while (setq expr (cdr expr))
|
|
(setq count (+ count (math-rwcomp-count-pnots (car expr)))))
|
|
count))))
|
|
|
|
;; In the current implementation, all associative functions must
|
|
;; also be commutative.
|
|
|
|
(put '+ 'math-rewrite-props '(algebraic assoc commut))
|
|
(put '- 'math-rewrite-props '(algebraic assoc commut)) ; see below
|
|
(put '* 'math-rewrite-props '(algebraic assoc commut)) ; see below
|
|
(put '/ 'math-rewrite-props '(algebraic unary1))
|
|
(put '^ 'math-rewrite-props '(algebraic unary1))
|
|
(put '% 'math-rewrite-props '(algebraic))
|
|
(put 'neg 'math-rewrite-props '(algebraic))
|
|
(put 'calcFunc-idiv 'math-rewrite-props '(algebraic))
|
|
(put 'calcFunc-abs 'math-rewrite-props '(algebraic))
|
|
(put 'calcFunc-sign 'math-rewrite-props '(algebraic))
|
|
(put 'calcFunc-round 'math-rewrite-props '(algebraic))
|
|
(put 'calcFunc-rounde 'math-rewrite-props '(algebraic))
|
|
(put 'calcFunc-roundu 'math-rewrite-props '(algebraic))
|
|
(put 'calcFunc-trunc 'math-rewrite-props '(algebraic))
|
|
(put 'calcFunc-floor 'math-rewrite-props '(algebraic))
|
|
(put 'calcFunc-ceil 'math-rewrite-props '(algebraic))
|
|
(put 'calcFunc-re 'math-rewrite-props '(algebraic))
|
|
(put 'calcFunc-im 'math-rewrite-props '(algebraic))
|
|
(put 'calcFunc-conj 'math-rewrite-props '(algebraic))
|
|
(put 'calcFunc-arg 'math-rewrite-props '(algebraic))
|
|
(put 'calcFunc-and 'math-rewrite-props '(assoc commut))
|
|
(put 'calcFunc-or 'math-rewrite-props '(assoc commut))
|
|
(put 'calcFunc-xor 'math-rewrite-props '(assoc commut))
|
|
(put 'calcFunc-eq 'math-rewrite-props '(commut))
|
|
(put 'calcFunc-neq 'math-rewrite-props '(commut))
|
|
(put 'calcFunc-land 'math-rewrite-props '(assoc commut))
|
|
(put 'calcFunc-lor 'math-rewrite-props '(assoc commut))
|
|
(put 'calcFunc-beta 'math-rewrite-props '(commut))
|
|
(put 'calcFunc-gcd 'math-rewrite-props '(assoc commut))
|
|
(put 'calcFunc-lcm 'math-rewrite-props '(assoc commut))
|
|
(put 'calcFunc-max 'math-rewrite-props '(algebraic assoc commut))
|
|
(put 'calcFunc-min 'math-rewrite-props '(algebraic assoc commut))
|
|
(put 'calcFunc-vunion 'math-rewrite-props '(assoc commut))
|
|
(put 'calcFunc-vint 'math-rewrite-props '(assoc commut))
|
|
(put 'calcFunc-vxor 'math-rewrite-props '(assoc commut))
|
|
|
|
;; Note: "*" is not commutative for matrix args, but we pretend it is.
|
|
;; Also, "-" is not commutative but the code tweaks things so that it is.
|
|
|
|
(put '+ 'math-rewrite-default 0)
|
|
(put '- 'math-rewrite-default 0)
|
|
(put '* 'math-rewrite-default 1)
|
|
(put '/ 'math-rewrite-default 1)
|
|
(put '^ 'math-rewrite-default 1)
|
|
(put 'calcFunc-land 'math-rewrite-default 1)
|
|
(put 'calcFunc-lor 'math-rewrite-default 0)
|
|
(put 'calcFunc-vunion 'math-rewrite-default '(vec))
|
|
(put 'calcFunc-vint 'math-rewrite-default '(vec))
|
|
(put 'calcFunc-vdiff 'math-rewrite-default '(vec))
|
|
(put 'calcFunc-vxor 'math-rewrite-default '(vec))
|
|
|
|
(defmacro math-rwfail (&optional back)
|
|
`(setq pc (and ,(if back
|
|
'(setq btrack (cdr btrack))
|
|
'btrack)
|
|
'((backtrack)))))
|
|
|
|
;; This monstrosity is necessary because the use of static vectors of
|
|
;; registers makes rewrite rules non-reentrant. Yucko!
|
|
(defmacro math-rweval (form)
|
|
`(let ((orig (car rules)))
|
|
(setcar rules '(nil nil nil no-phase))
|
|
(unwind-protect
|
|
,form
|
|
(setcar rules orig))))
|
|
|
|
;; The variable math-apply-rw-regs is local to math-apply-rewrites,
|
|
;; but is used by math-rwapply-replace-regs and math-rwapply-reg-looks-negp
|
|
;; which are called by math-apply-rewrites.
|
|
(defvar math-apply-rw-regs)
|
|
|
|
;; The variable math-apply-rw-ruleset is local to math-apply-rewrites,
|
|
;; but is used by math-rwapply-remember.
|
|
(defvar math-apply-rw-ruleset)
|
|
|
|
(defun math-apply-rewrites (expr rules &optional heads apply-rw-ruleset)
|
|
(and
|
|
(setq rules (cdr (or (assq (car-safe expr) rules)
|
|
(assq nil rules))))
|
|
(let ((math-apply-rw-ruleset apply-rw-ruleset)
|
|
(result nil)
|
|
op math-apply-rw-regs inst part pc mark btrack
|
|
(tracing math-rwcomp-tracing)
|
|
(phase math-rewrite-phase))
|
|
(while rules
|
|
(or
|
|
(and (setq part (nth 2 (car rules)))
|
|
heads
|
|
(not (memq part heads)))
|
|
(and (setq part (nth 3 (car rules)))
|
|
(not (memq phase part)))
|
|
(progn
|
|
(setq math-apply-rw-regs (car (car rules))
|
|
pc (nth 1 (car rules))
|
|
btrack nil)
|
|
(aset math-apply-rw-regs 0 expr)
|
|
(while pc
|
|
|
|
(and tracing
|
|
(progn (terpri) (princ (car pc))
|
|
(if (and (natnump (nth 1 (car pc)))
|
|
(< (nth 1 (car pc)) (length math-apply-rw-regs)))
|
|
(princ
|
|
(format "\n part = %s"
|
|
(aref math-apply-rw-regs (nth 1 (car pc))))))))
|
|
|
|
(cond ((eq (setq op (car (setq inst (car pc)))) 'func)
|
|
(if (and (consp
|
|
(setq part (aref math-apply-rw-regs (car (cdr inst)))))
|
|
(eq (car part)
|
|
(car (setq inst (cdr (cdr inst)))))
|
|
(progn
|
|
(while (and (setq inst (cdr inst)
|
|
part (cdr part))
|
|
inst)
|
|
(aset math-apply-rw-regs (car inst) (car part)))
|
|
(not (or inst part))))
|
|
(setq pc (cdr pc))
|
|
(math-rwfail)))
|
|
|
|
((eq op 'same)
|
|
(if (or (equal (setq part (aref math-apply-rw-regs (nth 1 inst)))
|
|
(setq mark (aref math-apply-rw-regs (nth 2 inst))))
|
|
(Math-equal part mark))
|
|
(setq pc (cdr pc))
|
|
(math-rwfail)))
|
|
|
|
((and (eq op 'try)
|
|
calc-matrix-mode
|
|
(not (eq calc-matrix-mode 'scalar))
|
|
(eq (car (nth 2 inst)) '*)
|
|
(consp (setq part (aref math-apply-rw-regs (car (cdr inst)))))
|
|
(eq (car part) '*)
|
|
(not (math-known-scalarp part)))
|
|
(setq mark (nth 3 inst)
|
|
pc (cdr pc))
|
|
(if (aref mark 4)
|
|
(progn
|
|
(aset math-apply-rw-regs (nth 4 inst) (nth 2 part))
|
|
(aset mark 1 (cdr (cdr part))))
|
|
(aset math-apply-rw-regs (nth 4 inst) (nth 1 part))
|
|
(aset mark 1 (cdr part)))
|
|
(aset mark 0 (cdr part))
|
|
(aset mark 2 0))
|
|
|
|
((eq op 'try)
|
|
(if (and (consp (setq part
|
|
(aref math-apply-rw-regs (car (cdr inst)))))
|
|
(memq (car part) (nth 2 inst))
|
|
(= (length part) 3)
|
|
(or (not (eq (car part) '/))
|
|
(Math-objectp (nth 2 part))))
|
|
(progn
|
|
(setq op nil
|
|
mark (car (cdr (setq inst (cdr (cdr inst))))))
|
|
(and
|
|
(memq 'assoc (get (car part) 'math-rewrite-props))
|
|
(not (= (aref mark 3) 0))
|
|
(while (if (and (consp (nth 1 part))
|
|
(memq (car (nth 1 part)) (car inst)))
|
|
(setq op (cons (if (eq (car part) '-)
|
|
(math-rwapply-neg
|
|
(nth 2 part))
|
|
(nth 2 part))
|
|
op)
|
|
part (nth 1 part))
|
|
(if (and (consp (nth 2 part))
|
|
(memq (car (nth 2 part))
|
|
(car inst))
|
|
(not (eq (car (nth 2 part)) '-)))
|
|
(setq op (cons (nth 1 part) op)
|
|
part (nth 2 part))))))
|
|
(setq op (cons (nth 1 part)
|
|
(cons (if (eq (car part) '-)
|
|
(math-rwapply-neg
|
|
(nth 2 part))
|
|
(if (eq (car part) '/)
|
|
(math-rwapply-inv
|
|
(nth 2 part))
|
|
(nth 2 part)))
|
|
op))
|
|
btrack (cons pc btrack)
|
|
pc (cdr pc))
|
|
(aset math-apply-rw-regs (nth 2 inst) (car op))
|
|
(aset mark 0 op)
|
|
(aset mark 1 op)
|
|
(aset mark 2 (if (cdr (cdr op)) 1 0)))
|
|
(if (nth 5 inst)
|
|
(if (and (consp part)
|
|
(eq (car part) 'neg)
|
|
(eq (car (nth 2 inst)) '*)
|
|
(eq (nth 5 inst) 1))
|
|
(progn
|
|
(setq mark (nth 3 inst)
|
|
pc (cdr pc))
|
|
(aset math-apply-rw-regs (nth 4 inst) (nth 1 part))
|
|
(aset mark 1 -1)
|
|
(aset mark 2 4))
|
|
(setq mark (nth 3 inst)
|
|
pc (cdr pc))
|
|
(aset math-apply-rw-regs (nth 4 inst) part)
|
|
(aset mark 2 3))
|
|
(math-rwfail))))
|
|
|
|
((eq op 'try2)
|
|
(setq part (nth 1 inst) ; try instr
|
|
mark (nth 3 part)
|
|
op (aref mark 2)
|
|
pc (cdr pc))
|
|
(aset math-apply-rw-regs (nth 2 inst)
|
|
(cond
|
|
((eq op 0)
|
|
(if (eq (aref mark 0) (aref mark 1))
|
|
(nth 1 (aref mark 0))
|
|
(car (aref mark 0))))
|
|
((eq op 1)
|
|
(setq mark (delq (car (aref mark 1))
|
|
(copy-sequence (aref mark 0)))
|
|
op (car (nth 2 part)))
|
|
(if (eq op '*)
|
|
(progn
|
|
(setq mark (nreverse mark)
|
|
part (list '* (nth 1 mark) (car mark))
|
|
mark (cdr mark))
|
|
(while (setq mark (cdr mark))
|
|
(setq part (list '* (car mark) part))))
|
|
(setq part (car mark)
|
|
mark (cdr mark)
|
|
part (if (and (eq op '+)
|
|
(consp (car mark))
|
|
(eq (car (car mark)) 'neg))
|
|
(list '- part
|
|
(nth 1 (car mark)))
|
|
(list op part (car mark))))
|
|
(while (setq mark (cdr mark))
|
|
(setq part (if (and (eq op '+)
|
|
(consp (car mark))
|
|
(eq (car (car mark)) 'neg))
|
|
(list '- part
|
|
(nth 1 (car mark)))
|
|
(list op part (car mark))))))
|
|
part)
|
|
((eq op 2)
|
|
(car (aref mark 1)))
|
|
((eq op 3) (nth 5 part))
|
|
(t (aref mark 1)))))
|
|
|
|
((eq op 'select)
|
|
(setq pc (cdr pc))
|
|
(if (and (consp (setq part (aref math-apply-rw-regs (nth 1 inst))))
|
|
(eq (car part) 'calcFunc-select))
|
|
(aset math-apply-rw-regs (nth 2 inst) (nth 1 part))
|
|
(if math-rewrite-selections
|
|
(math-rwfail)
|
|
(aset math-apply-rw-regs (nth 2 inst) part))))
|
|
|
|
((eq op 'same-neg)
|
|
(if (or (equal (setq part (aref math-apply-rw-regs (nth 1 inst)))
|
|
(setq mark (math-neg
|
|
(aref math-apply-rw-regs (nth 2 inst)))))
|
|
(Math-equal part mark))
|
|
(setq pc (cdr pc))
|
|
(math-rwfail)))
|
|
|
|
((eq op 'backtrack)
|
|
(setq inst (car (car btrack)) ; "try" or "alt" instr
|
|
pc (cdr (car btrack))
|
|
mark (or (nth 3 inst) [nil nil 4])
|
|
op (aref mark 2))
|
|
(cond ((eq op 0)
|
|
(if (setq op (cdr (aref mark 1)))
|
|
(aset math-apply-rw-regs (nth 4 inst)
|
|
(car (aset mark 1 op)))
|
|
(if (nth 5 inst)
|
|
(progn
|
|
(aset mark 2 3)
|
|
(aset math-apply-rw-regs (nth 4 inst)
|
|
(aref math-apply-rw-regs (nth 1 inst))))
|
|
(math-rwfail t))))
|
|
((eq op 1)
|
|
(if (setq op (cdr (aref mark 1)))
|
|
(aset math-apply-rw-regs (nth 4 inst)
|
|
(car (aset mark 1 op)))
|
|
(if (= (aref mark 3) 1)
|
|
(if (nth 5 inst)
|
|
(progn
|
|
(aset mark 2 3)
|
|
(aset math-apply-rw-regs (nth 4 inst)
|
|
(aref math-apply-rw-regs (nth 1 inst))))
|
|
(math-rwfail t))
|
|
(aset mark 2 2)
|
|
(aset mark 1 (cons nil (aref mark 0)))
|
|
(math-rwfail))))
|
|
((eq op 2)
|
|
(if (setq op (cdr (aref mark 1)))
|
|
(progn
|
|
(setq mark (delq (car (aset mark 1 op))
|
|
(copy-sequence
|
|
(aref mark 0)))
|
|
op (car (nth 2 inst)))
|
|
(if (eq op '*)
|
|
(progn
|
|
(setq mark (nreverse mark)
|
|
part (list '* (nth 1 mark)
|
|
(car mark))
|
|
mark (cdr mark))
|
|
(while (setq mark (cdr mark))
|
|
(setq part (list '* (car mark)
|
|
part))))
|
|
(setq part (car mark)
|
|
mark (cdr mark)
|
|
part (if (and (eq op '+)
|
|
(consp (car mark))
|
|
(eq (car (car mark))
|
|
'neg))
|
|
(list '- part
|
|
(nth 1 (car mark)))
|
|
(list op part (car mark))))
|
|
(while (setq mark (cdr mark))
|
|
(setq part (if (and (eq op '+)
|
|
(consp (car mark))
|
|
(eq (car (car mark))
|
|
'neg))
|
|
(list '- part
|
|
(nth 1 (car mark)))
|
|
(list op part (car mark))))))
|
|
(aset math-apply-rw-regs (nth 4 inst) part))
|
|
(if (nth 5 inst)
|
|
(progn
|
|
(aset mark 2 3)
|
|
(aset math-apply-rw-regs (nth 4 inst)
|
|
(aref math-apply-rw-regs (nth 1 inst))))
|
|
(math-rwfail t))))
|
|
((eq op 4)
|
|
(setq btrack (cdr btrack)))
|
|
(t (math-rwfail t))))
|
|
|
|
((eq op 'integer)
|
|
(if (Math-integerp (setq part
|
|
(aref math-apply-rw-regs (nth 1 inst))))
|
|
(setq pc (cdr pc))
|
|
(if (Math-primp part)
|
|
(math-rwfail)
|
|
(setq part (math-rweval (math-simplify part)))
|
|
(if (Math-integerp part)
|
|
(setq pc (cdr pc))
|
|
(math-rwfail)))))
|
|
|
|
((eq op 'real)
|
|
(if (Math-realp (setq part (aref math-apply-rw-regs (nth 1 inst))))
|
|
(setq pc (cdr pc))
|
|
(if (Math-primp part)
|
|
(math-rwfail)
|
|
(setq part (math-rweval (math-simplify part)))
|
|
(if (Math-realp part)
|
|
(setq pc (cdr pc))
|
|
(math-rwfail)))))
|
|
|
|
((eq op 'constant)
|
|
(if (math-constp (setq part (aref math-apply-rw-regs (nth 1 inst))))
|
|
(setq pc (cdr pc))
|
|
(if (Math-primp part)
|
|
(math-rwfail)
|
|
(setq part (math-rweval (math-simplify part)))
|
|
(if (math-constp part)
|
|
(setq pc (cdr pc))
|
|
(math-rwfail)))))
|
|
|
|
((eq op 'negative)
|
|
(if (math-looks-negp (setq part
|
|
(aref math-apply-rw-regs (nth 1 inst))))
|
|
(setq pc (cdr pc))
|
|
(if (Math-primp part)
|
|
(math-rwfail)
|
|
(setq part (math-rweval (math-simplify part)))
|
|
(if (math-looks-negp part)
|
|
(setq pc (cdr pc))
|
|
(math-rwfail)))))
|
|
|
|
((eq op 'rel)
|
|
(setq part (math-compare (aref math-apply-rw-regs (nth 1 inst))
|
|
(aref math-apply-rw-regs (nth 3 inst)))
|
|
op (nth 2 inst))
|
|
(if (= part 2)
|
|
(setq part (math-rweval
|
|
(math-simplify
|
|
(calcFunc-sign
|
|
(math-sub
|
|
(aref math-apply-rw-regs (nth 1 inst))
|
|
(aref math-apply-rw-regs (nth 3 inst))))))))
|
|
(if (cond ((eq op 'calcFunc-eq)
|
|
(eq part 0))
|
|
((eq op 'calcFunc-neq)
|
|
(memq part '(-1 1)))
|
|
((eq op 'calcFunc-lt)
|
|
(eq part -1))
|
|
((eq op 'calcFunc-leq)
|
|
(memq part '(-1 0)))
|
|
((eq op 'calcFunc-gt)
|
|
(eq part 1))
|
|
((eq op 'calcFunc-geq)
|
|
(memq part '(0 1))))
|
|
(setq pc (cdr pc))
|
|
(math-rwfail)))
|
|
|
|
((eq op 'func-def)
|
|
(if (and
|
|
(consp (setq part (aref math-apply-rw-regs (car (cdr inst)))))
|
|
(eq (car part)
|
|
(car (setq inst (cdr (cdr inst))))))
|
|
(progn
|
|
(setq inst (cdr inst)
|
|
mark (car inst))
|
|
(while (and (setq inst (cdr inst)
|
|
part (cdr part))
|
|
inst)
|
|
(aset math-apply-rw-regs (car inst) (car part)))
|
|
(if (or inst part)
|
|
(setq pc (cdr pc))
|
|
(while (eq (car (car (setq pc (cdr pc))))
|
|
'func-def))
|
|
(setq pc (cdr pc)) ; skip over "func"
|
|
(while mark
|
|
(aset math-apply-rw-regs (cdr (car mark)) (car (car mark)))
|
|
(setq mark (cdr mark)))))
|
|
(math-rwfail)))
|
|
|
|
((eq op 'func-opt)
|
|
(if (or (not
|
|
(and
|
|
(consp
|
|
(setq part (aref math-apply-rw-regs (car (cdr inst)))))
|
|
(eq (car part) (nth 2 inst))))
|
|
(and (= (length part) 2)
|
|
(setq part (nth 1 part))))
|
|
(progn
|
|
(setq mark (nth 3 inst))
|
|
(aset math-apply-rw-regs (nth 4 inst) part)
|
|
(while (eq (car (car (setq pc (cdr pc)))) 'func-def))
|
|
(setq pc (cdr pc)) ; skip over "func"
|
|
(while mark
|
|
(aset math-apply-rw-regs (cdr (car mark)) (car (car mark)))
|
|
(setq mark (cdr mark))))
|
|
(setq pc (cdr pc))))
|
|
|
|
((eq op 'mod)
|
|
(if (if (Math-zerop
|
|
(setq part (aref math-apply-rw-regs (nth 1 inst))))
|
|
(Math-zerop (nth 3 inst))
|
|
(and (not (Math-zerop (nth 2 inst)))
|
|
(progn
|
|
(setq part (math-mod part (nth 2 inst)))
|
|
(or (Math-numberp part)
|
|
(setq part (math-rweval
|
|
(math-simplify part))))
|
|
(Math-equal part (nth 3 inst)))))
|
|
(setq pc (cdr pc))
|
|
(math-rwfail)))
|
|
|
|
((eq op 'apply)
|
|
(if (and (consp
|
|
(setq part (aref math-apply-rw-regs (car (cdr inst)))))
|
|
(not (Math-objvecp part))
|
|
(not (eq (car part) 'var)))
|
|
(progn
|
|
(aset math-apply-rw-regs (nth 2 inst)
|
|
(math-calcFunc-to-var (car part)))
|
|
(aset math-apply-rw-regs (nth 3 inst)
|
|
(cons 'vec (cdr part)))
|
|
(setq pc (cdr pc)))
|
|
(math-rwfail)))
|
|
|
|
((eq op 'cons)
|
|
(if (and (consp
|
|
(setq part (aref math-apply-rw-regs (car (cdr inst)))))
|
|
(eq (car part) 'vec)
|
|
(cdr part))
|
|
(progn
|
|
(aset math-apply-rw-regs (nth 2 inst) (nth 1 part))
|
|
(aset math-apply-rw-regs (nth 3 inst)
|
|
(cons 'vec (cdr (cdr part))))
|
|
(setq pc (cdr pc)))
|
|
(math-rwfail)))
|
|
|
|
((eq op 'rcons)
|
|
(if (and (consp
|
|
(setq part (aref math-apply-rw-regs (car (cdr inst)))))
|
|
(eq (car part) 'vec)
|
|
(cdr part))
|
|
(progn
|
|
(aset math-apply-rw-regs (nth 2 inst) (calcFunc-rhead part))
|
|
(aset math-apply-rw-regs (nth 3 inst) (calcFunc-rtail part))
|
|
(setq pc (cdr pc)))
|
|
(math-rwfail)))
|
|
|
|
((eq op 'cond)
|
|
(if (math-is-true
|
|
(math-rweval
|
|
(math-simplify
|
|
(math-rwapply-replace-regs (nth 1 inst)))))
|
|
(setq pc (cdr pc))
|
|
(math-rwfail)))
|
|
|
|
((eq op 'let)
|
|
(aset math-apply-rw-regs (nth 1 inst)
|
|
(math-rweval
|
|
(math-normalize
|
|
(math-rwapply-replace-regs (nth 2 inst)))))
|
|
(setq pc (cdr pc)))
|
|
|
|
((eq op 'copy)
|
|
(aset math-apply-rw-regs (nth 2 inst)
|
|
(aref math-apply-rw-regs (nth 1 inst)))
|
|
(setq pc (cdr pc)))
|
|
|
|
((eq op 'copy-neg)
|
|
(aset math-apply-rw-regs (nth 2 inst)
|
|
(math-rwapply-neg (aref math-apply-rw-regs (nth 1 inst))))
|
|
(setq pc (cdr pc)))
|
|
|
|
((eq op 'alt)
|
|
(setq btrack (cons pc btrack)
|
|
pc (nth 1 inst)))
|
|
|
|
((eq op 'end-alt)
|
|
(while (and btrack (not (eq (car btrack) (nth 1 inst))))
|
|
(setq btrack (cdr btrack)))
|
|
(setq btrack (cdr btrack)
|
|
pc (cdr pc)))
|
|
|
|
((eq op 'done)
|
|
(setq result (math-rwapply-replace-regs (nth 1 inst)))
|
|
(if (or (and (eq (car-safe result) '+)
|
|
(eq (nth 2 result) 0))
|
|
(and (eq (car-safe result) '*)
|
|
(eq (nth 2 result) 1)))
|
|
(setq result (nth 1 result)))
|
|
(setq part (and (nth 2 inst)
|
|
(math-is-true
|
|
(math-rweval
|
|
(math-simplify
|
|
(math-rwapply-replace-regs
|
|
(nth 2 inst)))))))
|
|
(if (or (equal result expr)
|
|
(equal (setq result (math-normalize result)) expr))
|
|
(setq result nil)
|
|
(if part (math-rwapply-remember expr result))
|
|
(setq rules nil))
|
|
(setq pc nil))
|
|
|
|
(t (error "%s is not a valid rewrite opcode" op))))))
|
|
(setq rules (cdr rules)))
|
|
result)))
|
|
|
|
(defun math-rwapply-neg (expr)
|
|
(if (and (consp expr)
|
|
(memq (car expr) '(* /)))
|
|
(if (Math-objectp (nth 2 expr))
|
|
(list (car expr) (nth 1 expr) (math-neg (nth 2 expr)))
|
|
(list (car expr)
|
|
(if (Math-objectp (nth 1 expr))
|
|
(math-neg (nth 1 expr))
|
|
(list '* -1 (nth 1 expr)))
|
|
(nth 2 expr)))
|
|
(math-neg expr)))
|
|
|
|
(defun math-rwapply-inv (expr)
|
|
(if (and (Math-integerp expr)
|
|
calc-prefer-frac)
|
|
(math-make-frac 1 expr)
|
|
(list '/ 1 expr)))
|
|
|
|
(defun math-rwapply-replace-regs (expr)
|
|
(cond ((Math-primp expr)
|
|
expr)
|
|
((eq (car expr) 'calcFunc-register)
|
|
(setq expr (aref math-apply-rw-regs (nth 1 expr)))
|
|
(if (eq (car-safe expr) '*)
|
|
(if (eq (nth 1 expr) -1)
|
|
(math-neg (nth 2 expr))
|
|
(if (eq (nth 1 expr) 1)
|
|
(nth 2 expr)
|
|
expr))
|
|
expr))
|
|
((and (eq (car expr) 'calcFunc-eval)
|
|
(= (length expr) 2))
|
|
(calc-with-default-simplification
|
|
(math-normalize (math-rwapply-replace-regs (nth 1 expr)))))
|
|
((and (eq (car expr) 'calcFunc-evalsimp)
|
|
(= (length expr) 2))
|
|
(math-simplify (math-rwapply-replace-regs (nth 1 expr))))
|
|
((and (eq (car expr) 'calcFunc-evalextsimp)
|
|
(= (length expr) 2))
|
|
(math-simplify-extended (math-rwapply-replace-regs (nth 1 expr))))
|
|
((and (eq (car expr) 'calcFunc-apply)
|
|
(= (length expr) 3))
|
|
(let ((func (math-rwapply-replace-regs (nth 1 expr)))
|
|
(args (math-rwapply-replace-regs (nth 2 expr)))
|
|
call)
|
|
(if (and (math-vectorp args)
|
|
(not (eq (car-safe (setq call (math-build-call
|
|
(math-var-to-calcFunc func)
|
|
(cdr args))))
|
|
'calcFunc-call)))
|
|
call
|
|
(list 'calcFunc-apply func args))))
|
|
((and (eq (car expr) 'calcFunc-cons)
|
|
(= (length expr) 3))
|
|
(let ((head (math-rwapply-replace-regs (nth 1 expr)))
|
|
(tail (math-rwapply-replace-regs (nth 2 expr))))
|
|
(if (math-vectorp tail)
|
|
(cons 'vec (cons head (cdr tail)))
|
|
(list 'calcFunc-cons head tail))))
|
|
((and (eq (car expr) 'calcFunc-rcons)
|
|
(= (length expr) 3))
|
|
(let ((head (math-rwapply-replace-regs (nth 1 expr)))
|
|
(tail (math-rwapply-replace-regs (nth 2 expr))))
|
|
(if (math-vectorp head)
|
|
(append head (list tail))
|
|
(list 'calcFunc-rcons head tail))))
|
|
((and (eq (car expr) 'neg)
|
|
(math-rwapply-reg-looks-negp (nth 1 expr)))
|
|
(math-rwapply-reg-neg (nth 1 expr)))
|
|
((and (eq (car expr) 'neg)
|
|
(eq (car-safe (nth 1 expr)) 'calcFunc-register)
|
|
(math-scalarp (aref math-apply-rw-regs (nth 1 (nth 1 expr)))))
|
|
(math-neg (math-rwapply-replace-regs (nth 1 expr))))
|
|
((and (eq (car expr) '+)
|
|
(math-rwapply-reg-looks-negp (nth 1 expr)))
|
|
(list '- (math-rwapply-replace-regs (nth 2 expr))
|
|
(math-rwapply-reg-neg (nth 1 expr))))
|
|
((and (eq (car expr) '+)
|
|
(math-rwapply-reg-looks-negp (nth 2 expr)))
|
|
(list '- (math-rwapply-replace-regs (nth 1 expr))
|
|
(math-rwapply-reg-neg (nth 2 expr))))
|
|
((and (eq (car expr) '-)
|
|
(math-rwapply-reg-looks-negp (nth 2 expr)))
|
|
(list '+ (math-rwapply-replace-regs (nth 1 expr))
|
|
(math-rwapply-reg-neg (nth 2 expr))))
|
|
((eq (car expr) '*)
|
|
(cond ((eq (nth 1 expr) -1)
|
|
(if (math-rwapply-reg-looks-negp (nth 2 expr))
|
|
(math-rwapply-reg-neg (nth 2 expr))
|
|
(math-neg (math-rwapply-replace-regs (nth 2 expr)))))
|
|
((eq (nth 1 expr) 1)
|
|
(math-rwapply-replace-regs (nth 2 expr)))
|
|
((eq (nth 2 expr) -1)
|
|
(if (math-rwapply-reg-looks-negp (nth 1 expr))
|
|
(math-rwapply-reg-neg (nth 1 expr))
|
|
(math-neg (math-rwapply-replace-regs (nth 1 expr)))))
|
|
((eq (nth 2 expr) 1)
|
|
(math-rwapply-replace-regs (nth 1 expr)))
|
|
(t
|
|
(let ((arg1 (math-rwapply-replace-regs (nth 1 expr)))
|
|
(arg2 (math-rwapply-replace-regs (nth 2 expr))))
|
|
(cond ((and (eq (car-safe arg1) '/)
|
|
(eq (nth 1 arg1) 1))
|
|
(list '/ arg2 (nth 2 arg1)))
|
|
((and (eq (car-safe arg2) '/)
|
|
(eq (nth 1 arg2) 1))
|
|
(list '/ arg1 (nth 2 arg2)))
|
|
(t (list '* arg1 arg2)))))))
|
|
((eq (car expr) '/)
|
|
(let ((arg1 (math-rwapply-replace-regs (nth 1 expr)))
|
|
(arg2 (math-rwapply-replace-regs (nth 2 expr))))
|
|
(if (eq (car-safe arg2) '/)
|
|
(list '/ (list '* arg1 (nth 2 arg2)) (nth 1 arg2))
|
|
(list '/ arg1 arg2))))
|
|
((and (eq (car expr) 'calcFunc-plain)
|
|
(= (length expr) 2))
|
|
(if (Math-primp (nth 1 expr))
|
|
(nth 1 expr)
|
|
(if (eq (car (nth 1 expr)) 'calcFunc-register)
|
|
(aref math-apply-rw-regs (nth 1 (nth 1 expr)))
|
|
(cons (car (nth 1 expr)) (mapcar 'math-rwapply-replace-regs
|
|
(cdr (nth 1 expr)))))))
|
|
(t (cons (car expr) (mapcar 'math-rwapply-replace-regs (cdr expr))))))
|
|
|
|
(defun math-rwapply-reg-looks-negp (expr)
|
|
(if (eq (car-safe expr) 'calcFunc-register)
|
|
(math-looks-negp (aref math-apply-rw-regs (nth 1 expr)))
|
|
(if (memq (car-safe expr) '(* /))
|
|
(or (math-rwapply-reg-looks-negp (nth 1 expr))
|
|
(math-rwapply-reg-looks-negp (nth 2 expr))))))
|
|
|
|
(defun math-rwapply-reg-neg (expr) ; expr must satisfy rwapply-reg-looks-negp
|
|
(if (eq (car expr) 'calcFunc-register)
|
|
(math-neg (math-rwapply-replace-regs expr))
|
|
(if (math-rwapply-reg-looks-negp (nth 1 expr))
|
|
(math-rwapply-replace-regs (list (car expr)
|
|
(math-rwapply-reg-neg (nth 1 expr))
|
|
(nth 2 expr)))
|
|
(math-rwapply-replace-regs (list (car expr)
|
|
(nth 1 expr)
|
|
(math-rwapply-reg-neg (nth 2 expr)))))))
|
|
|
|
(defun math-rwapply-remember (old new)
|
|
(let ((varval (symbol-value (nth 2 (car math-apply-rw-ruleset))))
|
|
(rules (assq (car-safe old) math-apply-rw-ruleset)))
|
|
(if (and (eq (car-safe varval) 'vec)
|
|
(not (memq (car-safe old) '(nil schedule + -)))
|
|
rules)
|
|
(progn
|
|
(setcdr varval (cons (list 'calcFunc-assign
|
|
(if (math-rwcomp-no-vars old)
|
|
old
|
|
(list 'calcFunc-quote old))
|
|
new)
|
|
(cdr varval)))
|
|
(setcdr rules (cons (list (vector nil old)
|
|
(list (list 'same 0 1)
|
|
(list 'done new nil))
|
|
nil nil)
|
|
(cdr rules)))))))
|
|
|
|
(provide 'calc-rewr)
|
|
|
|
;;; calc-rewr.el ends here
|