;;; calc-tests.el --- tests for calc -*- lexical-binding: t; -*- ;; Copyright (C) 2014-2020 Free Software Foundation, Inc. ;; Author: Leo Liu ;; Keywords: maint ;; This file is part of GNU Emacs. ;; GNU Emacs is free software: you can redistribute it and/or modify ;; it under the terms of the GNU General Public License as published by ;; the Free Software Foundation, either version 3 of the License, or ;; (at your option) any later version. ;; GNU Emacs is distributed in the hope that it will be useful, ;; but WITHOUT ANY WARRANTY; without even the implied warranty of ;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ;; GNU General Public License for more details. ;; You should have received a copy of the GNU General Public License ;; along with GNU Emacs. If not, see . ;;; Commentary: ;;; Code: (require 'cl-lib) (require 'ert) (require 'calc) (require 'calc-ext) (require 'calc-units) (require 'calc-forms) ;; XXX The order in which calc libraries (in particular calc-units) ;; are loaded influences whether a calc integer in an expression ;; involving units is represented as a lisp integer or a calc float, ;; see bug#19582. Until this will be fixed the following function can ;; be used to compare such calc expressions. (defun calc-tests-equal (a b) "Like `equal' but allow for different representations of numbers. For example: (calc-tests-equal 10 '(float 1 1)) => t. A and B should be calc expressions." (cond ((math-numberp a) (and (math-numberp b) (math-equal a b))) ((atom a) (equal a b)) ((consp b) ;; Can't be dotted or circular. (and (= (length a) (length b)) (equal (car a) (car b)) (cl-every #'calc-tests-equal (cdr a) (cdr b)))))) (defun calc-tests-simple (fun string &rest args) "Push STRING on the calc stack, then call FUN and return the new top. The result is a calc (i.e., lisp) expression, not its string representation. Also pop the entire stack afterwards. An existing calc stack is reused, otherwise a new one is created." (calc-eval string 'push) (prog1 (ignore-errors (apply fun args) (calc-top-n 1)) (calc-pop 0))) (ert-deftest calc-remove-units () (should (calc-tests-equal (calc-tests-simple #'calc-remove-units "-1 m") -1))) (ert-deftest calc-extract-units () (should (calc-tests-equal (calc-tests-simple #'calc-extract-units "-1 m") '(var m var-m))) (should (calc-tests-equal (calc-tests-simple #'calc-extract-units "-1 m*cm") '(* (float 1 -2) (^ (var m var-m) 2))))) (ert-deftest calc-convert-units () ;; Used to ask for `(The expression is unitless when simplified) Old Units: '. (should (calc-tests-equal (calc-tests-simple #'calc-convert-units "-1 m" nil "cm") '(* -100 (var cm var-cm)))) ;; Gave wrong result. (should (calc-tests-equal (calc-tests-simple #'calc-convert-units "-1 m" (math-read-expr "1m") "cm") '(* -100 (var cm var-cm))))) (ert-deftest calc-imaginary-i () "Test `math-imaginary-i' for non-special-const values." (let ((var-i (calcFunc-polar (calcFunc-sqrt -1)))) (should (math-imaginary-i))) (let ((var-i (calcFunc-sqrt -1))) (should (math-imaginary-i)))) (ert-deftest calc-bug-23889 () "Test for https://debbugs.gnu.org/23889 and 25652." (skip-unless t) ;; (>= math-bignum-digit-length 9)) (dolist (mode '(deg rad)) (let ((calc-angle-mode mode)) ;; If user inputs angle units, then should ignore `calc-angle-mode'. (should (string= "5253" (substring (number-to-string (nth 1 (math-simplify-units '(calcFunc-cos (* 45 (var rad var-rad)))))) 0 4))) (should (string= "7071" (substring (number-to-string (nth 1 (math-simplify-units '(calcFunc-cos (* 45 (var deg var-deg)))))) 0 4))) (should (string= "8939" (substring (number-to-string (nth 1 (math-simplify-units '(+ (calcFunc-sin (* 90 (var rad var-rad))) (calcFunc-cos (* 90 (var deg var-deg))))))) 0 4))) (should (string= "5519" (substring (number-to-string (nth 1 (math-simplify-units '(+ (calcFunc-sin (* 90 (var deg var-deg))) (calcFunc-cos (* 90 (var rad var-rad))))))) 0 4))) ;; If user doesn't input units, then must use `calc-angle-mode'. (should (string= (if (eq calc-angle-mode 'deg) "9998" "5403") (substring (number-to-string (nth 1 (calcFunc-cos 1))) 0 4)))))) (ert-deftest calc-trig () "Trigonometric simplification; bug#33052." (let ((calc-angle-mode 'rad)) (let ((calc-symbolic-mode t)) (should (equal (math-simplify '(calcFunc-sin (/ (var pi var-pi) 4))) '(/ (calcFunc-sqrt 2) 2))) (should (equal (math-simplify '(calcFunc-cos (/ (var pi var-pi) 4))) '(/ (calcFunc-sqrt 2) 2))) (should (equal (math-simplify '(calcFunc-sec (/ (var pi var-pi) 4))) '(calcFunc-sqrt 2))) (should (equal (math-simplify '(calcFunc-csc (/ (var pi var-pi) 4))) '(calcFunc-sqrt 2))) (should (equal (math-simplify '(calcFunc-tan (/ (var pi var-pi) 3))) '(calcFunc-sqrt 3))) (should (equal (math-simplify '(calcFunc-cot (/ (var pi var-pi) 3))) '(/ (calcFunc-sqrt 3) 3)))) (let ((calc-symbolic-mode nil)) (should (equal (math-simplify '(calcFunc-sin (/ (var pi var-pi) 4))) '(calcFunc-sin (/ (var pi var-pi) 4)))) (should (equal (math-simplify '(calcFunc-cos (/ (var pi var-pi) 4))) '(calcFunc-cos (/ (var pi var-pi) 4)))) (should (equal (math-simplify '(calcFunc-sec (/ (var pi var-pi) 4))) '(calcFunc-sec (/ (var pi var-pi) 4)))) (should (equal (math-simplify '(calcFunc-csc (/ (var pi var-pi) 4))) '(calcFunc-csc (/ (var pi var-pi) 4)))) (should (equal (math-simplify '(calcFunc-tan (/ (var pi var-pi) 3))) '(calcFunc-tan (/ (var pi var-pi) 3)))) (should (equal (math-simplify '(calcFunc-cot (/ (var pi var-pi) 3))) '(calcFunc-cot (/ (var pi var-pi) 3))))))) (ert-deftest calc-format-radix () "Test integer formatting (bug#36689)." (let ((calc-group-digits nil)) (let ((calc-number-radix 10)) (should (equal (math-format-number 12345678901) "12345678901"))) (let ((calc-number-radix 2)) (should (equal (math-format-number 12345) "2#11000000111001"))) (let ((calc-number-radix 8)) (should (equal (math-format-number 12345678901) "8#133767016065"))) (let ((calc-number-radix 16)) (should (equal (math-format-number 12345678901) "16#2DFDC1C35"))) (let ((calc-number-radix 36)) (should (equal (math-format-number 12345678901) "36#5O6AQT1")))) (let ((calc-group-digits t)) (let ((calc-number-radix 10)) (should (equal (math-format-number 12345678901) "12,345,678,901"))) (let ((calc-number-radix 2)) (should (equal (math-format-number 12345) "2#11,0000,0011,1001"))) (let ((calc-number-radix 8)) (should (equal (math-format-number 12345678901) "8#133,767,016,065"))) (let ((calc-number-radix 16)) (should (equal (math-format-number 12345678901) "16#2,DFDC,1C35"))) (let ((calc-number-radix 36)) (should (equal (math-format-number 12345678901) "36#5,O6A,QT1"))))) (ert-deftest calc-calendar () "Test calendar conversions (bug#36822)." (should (equal (calcFunc-julian (math-parse-date "2019-07-27")) 2458692)) (should (equal (math-parse-date "2019-07-27") '(date 737267))) (should (equal (calcFunc-julian '(date 0)) 1721425)) (should (equal (math-date-to-gregorian-dt 1) '(1 1 1))) (should (equal (math-date-to-gregorian-dt 0) '(-1 12 31))) (should (equal (math-date-to-gregorian-dt -1721425) '(-4714 11 24))) (should (equal (math-absolute-from-gregorian-dt 2019 7 27) 737267)) (should (equal (math-absolute-from-gregorian-dt 1 1 1) 1)) (should (equal (math-absolute-from-gregorian-dt -1 12 31) 0)) (should (equal (math-absolute-from-gregorian-dt -99 12 31) -35795)) (should (equal (math-absolute-from-gregorian-dt -4714 11 24) -1721425)) (should (equal (calcFunc-julian '(date -1721425)) 0)) (should (equal (math-date-to-julian-dt 1) '(1 1 3))) (should (equal (math-date-to-julian-dt -1721425) '(-4713 1 1))) (should (equal (math-absolute-from-julian-dt 2019 1 1) 737073)) (should (equal (math-absolute-from-julian-dt 1 1 3) 1)) (should (equal (math-absolute-from-julian-dt -101 1 1) -36892)) (should (equal (math-absolute-from-julian-dt -101 3 1) -36832)) (should (equal (math-absolute-from-julian-dt -4713 1 1) -1721425))) (ert-deftest calc-solve-linear-system () "Test linear system solving (bug#35374)." ;; x + y = 3 ;; 2x - 3y = -4 ;; with the unique solution x=1, y=2 (should (equal (calcFunc-solve '(vec (calcFunc-eq (+ (var x var-x) (var y var-y)) 3) (calcFunc-eq (- (* 2 (var x var-x)) (* 3 (var y var-y))) -4)) '(vec (var x var-x) (var y var-y))) '(vec (calcFunc-eq (var x var-x) 1) (calcFunc-eq (var y var-y) 2)))) ;; x + y = 1 ;; x + y = 2 ;; has no solution (should (equal (calcFunc-solve '(vec (calcFunc-eq (+ (var x var-x) (var y var-y)) 1) (calcFunc-eq (+ (var x var-x) (var y var-y)) 2)) '(vec (var x var-x) (var y var-y))) '(calcFunc-solve (vec (calcFunc-eq (+ (var x var-x) (var y var-y)) 1) (calcFunc-eq (+ (var x var-x) (var y var-y)) 2)) (vec (var x var-x) (var y var-y))))) ;; x - y = 1 ;; x + y = 1 ;; with the unique solution x=1, y=0 (should (equal (calcFunc-solve '(vec (calcFunc-eq (- (var x var-x) (var y var-y)) 1) (calcFunc-eq (+ (var x var-x) (var y var-y)) 1)) '(vec (var x var-x) (var y var-y))) '(vec (calcFunc-eq (var x var-x) 1) (calcFunc-eq (var y var-y) 0)))) ;; 2x - 3y + z = 5 ;; x + y - 2z = 0 ;; -x + 2y + 3z = -3 ;; with the unique solution x=1, y=-1, z=0 (should (equal (calcFunc-solve '(vec (calcFunc-eq (+ (- (* 2 (var x var-x)) (* 3 (var y var-y))) (var z var-z)) 5) (calcFunc-eq (- (+ (var x var-x) (var y var-y)) (* 2 (var z var-z))) 0) (calcFunc-eq (+ (- (* 2 (var y var-y)) (var x var-x)) (* 3 (var z var-z))) -3)) '(vec (var x var-x) (var y var-y) (var z var-z))) ;; The `float' forms in the result are just artifacts of Calc's ;; current solver; it should be fixed to produce exact (integral) ;; results in this case. '(vec (calcFunc-eq (var x var-x) (float 1 0)) (calcFunc-eq (var y var-y) (float -1 0)) (calcFunc-eq (var z var-z) 0)))) ;; x = y + 1 ;; x = y ;; has no solution (should (equal (calcFunc-solve '(vec (calcFunc-eq (var x var-x) (+ (var y var-y) 1)) (calcFunc-eq (var x var-x) (var y var-y))) '(vec (var x var-x) (var y var-y))) '(calcFunc-solve (vec (calcFunc-eq (var x var-x) (+ (var y var-y) 1)) (calcFunc-eq (var x var-x) (var y var-y))) (vec (var x var-x) (var y var-y))))) ;; x + y + z = 6 ;; x + y = 3 ;; x - y = 1 ;; with the unique solution x=2, y=1, z=3 (should (equal (calcFunc-solve '(vec (calcFunc-eq (+ (+ (var x var-x) (var y var-y)) (var z var-z)) 6) (calcFunc-eq (+ (var x var-x) (var y var-y)) 3) (calcFunc-eq (- (var x var-x) (var y var-y)) 1)) '(vec (var x var-x) (var y var-y) (var z var-z))) '(vec (calcFunc-eq (var x var-x) 2) (calcFunc-eq (var y var-y) 1) (calcFunc-eq (var z var-z) 3)))) ;; x = 3 ;; x + 4y^2 = 3 (ok, so this one isn't linear) ;; with the unique (double) solution x=3, y=0 (should (equal (calcFunc-solve '(vec (calcFunc-eq (var x var-x) 3) (calcFunc-eq (+ (var x var-x) (* 4 (^ (var y var-y) 2))) 3)) '(vec (var x var-x) (var y var-y))) '(vec (calcFunc-eq (var x var-x) 3) (calcFunc-eq (var y var-y) 0))))) (ert-deftest calc-poly-div () "Test polynomial division, and that the remainder is recorded in the trail." (with-current-buffer (calc-trail-buffer) (let ((inhibit-read-only t)) (erase-buffer) (calc-eval "2x**3+1" 'push) (calc-eval "x**2+2x" 'push) (calc-poly-div nil) (let ((tos (calc-top-n 1)) (trail (buffer-string))) (calc-pop 0) (should (equal tos '(- (* 2 (var x var-x)) 4))) (should (equal trail "pdiv 2 * x - 4\nprem 8 * x + 1\n")))))) (ert-deftest calc-Math-integerp () (should (Math-integerp -7)) (should (Math-integerp (ash 1 65))) (should-not (Math-integerp '(float 1 0))) (should-not (Math-integerp nil)) (should (Math-num-integerp -7)) (should (Math-num-integerp (ash 1 65))) (should (Math-num-integerp '(float 1 0))) (should-not (Math-num-integerp nil))) (ert-deftest calc-matrix-determinant () (should (equal (calcFunc-det '(vec (vec 3))) 3)) (should (equal (calcFunc-det '(vec (vec 2 3) (vec 6 7))) -4)) (should (equal (calcFunc-det '(vec (vec 1 2 3) (vec 4 5 7) (vec 9 6 2))) 15)) (should (equal (calcFunc-det '(vec (vec 0 5 7 3) (vec 0 0 2 0) (vec 1 2 3 4) (vec 0 0 0 3))) 30)) (should (equal (calcFunc-det '(vec (vec (var a var-a)))) '(var a var-a))) (should (equal (calcFunc-det '(vec (vec 2 (var a var-a)) (vec 7 (var a var-a)))) '(* -5 (var a var-a)))) (should (equal (calcFunc-det '(vec (vec 1 0 0 0) (vec 0 1 0 0) (vec 0 0 0 1) (vec 0 0 (var a var-a) 0))) '(neg (var a var-a))))) (ert-deftest calc-gcd () (should (equal (calcFunc-gcd 3 4) 1)) (should (equal (calcFunc-gcd 12 15) 3)) (should (equal (calcFunc-gcd -12 15) 3)) (should (equal (calcFunc-gcd 12 -15) 3)) (should (equal (calcFunc-gcd -12 -15) 3)) (should (equal (calcFunc-gcd 0 5) 5)) (should (equal (calcFunc-gcd 5 0) 5)) (should (equal (calcFunc-gcd 0 -5) 5)) (should (equal (calcFunc-gcd -5 0) 5)) (should (equal (calcFunc-gcd 0 0) 0)) (should (equal (calcFunc-gcd 0 '(var x var-x)) '(calcFunc-abs (var x var-x)))) (should (equal (calcFunc-gcd '(var x var-x) 0) '(calcFunc-abs (var x var-x))))) (ert-deftest calc-sum-gcd () ;; sum(gcd(0,n),n,-1,-1) (should (equal (math-simplify '(calcFunc-sum (calcFunc-gcd 0 (var n var-n)) (var n var-n) -1 -1)) 1)) ;; sum(sum(gcd(n,k),k,-1,1),n,-1,1) (should (equal (math-simplify '(calcFunc-sum (calcFunc-sum (calcFunc-gcd (var n var-n) (var k var-k)) (var k var-k) -1 1) (var n var-n) -1 1)) 8))) (defun calc-tests--fac (n) (apply #'* (number-sequence 1 n))) (defun calc-tests--choose (n k) "N choose K, reference implementation." (cond ((and (integerp n) (integerp k)) (if (<= 0 n) (if (<= 0 k n) (/ (calc-tests--fac n) (* (calc-tests--fac k) (calc-tests--fac (- n k)))) 0) ; 0≤n %S, expected %S" n k got expected))) (put 'calc-tests--check-choose 'ert-explainer 'calc-tests--explain-choose) (defun calc-tests--calc-to-number (x) "Convert a Calc object to a Lisp number." (pcase x ((pred numberp) x) (`(frac ,p ,q) (/ (float p) q)) (`(float ,m ,e) (* m (expt 10 e))) (_ (error "calc object not converted: %S" x)))) (ert-deftest calc-choose () "Test computation of binomial coefficients (bug#16999)." ;; Integral arguments (dolist (n (number-sequence -6 6)) (dolist (k (number-sequence -6 6)) (should (calc-tests--check-choose n k)))) ;; Fractional n, natural k (should (equal (calc-tests--calc-to-number (calcFunc-choose '(frac 15 2) 3)) (calc-tests--choose 7.5 3))) (should (equal (calc-tests--calc-to-number (calcFunc-choose '(frac 1 2) 2)) (calc-tests--choose 0.5 2))) (should (equal (calc-tests--calc-to-number (calcFunc-choose '(frac -15 2) 3)) (calc-tests--choose -7.5 3)))) (ert-deftest calc-business-days () (cl-flet ((m (s) (math-parse-date s)) (b+ (a b) (calcFunc-badd a b)) (b- (a b) (calcFunc-bsub a b))) ;; Sanity check. (should (equal (m "2020-09-07") '(date 737675))) ;; Test with standard business days (Mon-Fri): (should (equal (b+ (m "2020-09-07") 1) (m "2020-09-08"))) ; Mon->Tue (should (equal (b+ (m "2020-09-08") 1) (m "2020-09-09"))) ; Tue->Wed (should (equal (b+ (m "2020-09-09") 1) (m "2020-09-10"))) ; Wed->Thu (should (equal (b+ (m "2020-09-10") 1) (m "2020-09-11"))) ; Thu->Fri (should (equal (b+ (m "2020-09-11") 1) (m "2020-09-14"))) ; Fri->Mon (should (equal (b+ (m "2020-09-07") 4) (m "2020-09-11"))) ; Mon->Fri (should (equal (b+ (m "2020-09-07") 6) (m "2020-09-15"))) ; Mon->Tue (should (equal (b+ (m "2020-09-12") 1) (m "2020-09-14"))) ; Sat->Mon (should (equal (b+ (m "2020-09-13") 1) (m "2020-09-14"))) ; Sun->Mon (should (equal (b- (m "2020-09-11") 1) (m "2020-09-10"))) ; Fri->Thu (should (equal (b- (m "2020-09-10") 1) (m "2020-09-09"))) ; Thu->Wed (should (equal (b- (m "2020-09-09") 1) (m "2020-09-08"))) ; Wed->Tue (should (equal (b- (m "2020-09-08") 1) (m "2020-09-07"))) ; Tue->Mon (should (equal (b- (m "2020-09-07") 1) (m "2020-09-04"))) ; Mon->Fri (should (equal (b- (m "2020-09-11") 4) (m "2020-09-07"))) ; Fri->Mon (should (equal (b- (m "2020-09-15") 6) (m "2020-09-07"))) ; Tue->Mon (should (equal (b- (m "2020-09-12") 1) (m "2020-09-11"))) ; Sat->Fri (should (equal (b- (m "2020-09-13") 1) (m "2020-09-11"))) ; Sun->Fri ;; Stepping fractional days (should (equal (b+ (m "2020-09-08 21:00") '(frac 1 2)) (m "2020-09-09 09:00"))) (should (equal (b+ (m "2020-09-11 21:00") '(frac 1 2)) (m "2020-09-14 09:00"))) (should (equal (b- (m "2020-09-08 21:00") '(frac 1 2)) (m "2020-09-08 09:00"))) (should (equal (b- (m "2020-09-14 06:00") '(frac 1 2)) (m "2020-09-11 18:00"))) ;; Test with a couple of extra days off: (let ((var-Holidays (list 'vec '(var sat var-sat) '(var sun var-sun) (m "2020-09-09") (m "2020-09-11")))) (should (equal (b+ (m "2020-09-07") 1) (m "2020-09-08"))) ; Mon->Tue (should (equal (b+ (m "2020-09-08") 1) (m "2020-09-10"))) ; Tue->Thu (should (equal (b+ (m "2020-09-10") 1) (m "2020-09-14"))) ; Thu->Mon (should (equal (b+ (m "2020-09-14") 1) (m "2020-09-15"))) ; Mon->Tue (should (equal (b+ (m "2020-09-15") 1) (m "2020-09-16"))) ; Tue->Wed (should (equal (b- (m "2020-09-16") 1) (m "2020-09-15"))) ; Wed->Tue (should (equal (b- (m "2020-09-15") 1) (m "2020-09-14"))) ; Tue->Mon (should (equal (b- (m "2020-09-14") 1) (m "2020-09-10"))) ; Mon->Thu (should (equal (b- (m "2020-09-10") 1) (m "2020-09-08"))) ; Thu->Tue (should (equal (b- (m "2020-09-08") 1) (m "2020-09-07"))) ; Tue->Mon ) ;; Test with odd non-business weekdays (Tue, Wed, Sat): (let ((var-Holidays '(vec (var tue var-tue) (var wed var-wed) (var sat var-sat)))) (should (equal (b+ (m "2020-09-07") 1) (m "2020-09-10"))) ; Mon->Thu (should (equal (b+ (m "2020-09-10") 1) (m "2020-09-11"))) ; Thu->Fri (should (equal (b+ (m "2020-09-11") 1) (m "2020-09-13"))) ; Fri->Sun (should (equal (b+ (m "2020-09-13") 1) (m "2020-09-14"))) ; Sun->Mon (should (equal (b- (m "2020-09-14") 1) (m "2020-09-13"))) ; Mon->Sun (should (equal (b- (m "2020-09-13") 1) (m "2020-09-11"))) ; Sun->Fri (should (equal (b- (m "2020-09-11") 1) (m "2020-09-10"))) ; Fri->Thu (should (equal (b- (m "2020-09-10") 1) (m "2020-09-07"))) ; Thu->Mon ) )) (ert-deftest calc-unix-date () (let* ((d-1970-01-01 (math-parse-date "1970-01-01")) (d-2020-09-07 (math-parse-date "2020-09-07")) (d-1991-01-09-0600 (math-parse-date "1991-01-09 06:00"))) ;; calcFunc-unixtime (command "t U") converts a date value to Unix time, ;; and a number to a date. (should (equal d-1970-01-01 '(date 719163))) (should (equal (calcFunc-unixtime d-1970-01-01 0) 0)) (should (equal (calc-tests--calc-to-number (cadr (calcFunc-unixtime 0 0))) (cadr d-1970-01-01))) (should (equal (calcFunc-unixtime d-2020-09-07 0) (* (- (cadr d-2020-09-07) (cadr d-1970-01-01)) 86400))) (should (equal (calcFunc-unixtime d-1991-01-09-0600 0) 663400800)) (should (equal (calc-tests--calc-to-number (cadr (calcFunc-unixtime 663400800 0))) 726841.25)) (let ((calc-date-format '(U))) ;; Test parsing Unix time. (should (equal (calc-tests--calc-to-number (cadr (math-parse-date "0"))) 719163)) (should (equal (calc-tests--calc-to-number (cadr (math-parse-date "469324800"))) (+ 719163 (/ 469324800 86400)))) (should (equal (calc-tests--calc-to-number (cadr (math-parse-date "663400800"))) 726841.25)) ;; Test formatting Unix time. (should (equal (math-format-date d-1970-01-01) "0")) (should (equal (math-format-date d-2020-09-07) (number-to-string (* (- (cadr d-2020-09-07) (cadr d-1970-01-01)) 86400)))) (should (equal (math-format-date d-1991-01-09-0600) "663400800"))))) ;; Reference implementations of binary shift functions: (defun calc-tests--clip (x w) "Clip X to W bits, signed if W is negative, otherwise unsigned." (if (>= w 0) (logand x (- (ash 1 w) 1)) (let ((y (calc-tests--clip x (- w))) (msb (ash 1 (- (- w) 1)))) (- y (ash (logand y msb) 1))))) (defun calc-tests--lsh (x n w) "Logical shift left X by N steps, word size W." (if (< n 0) (calc-tests--rsh x (- n) w) (calc-tests--clip (ash x n) w))) (defun calc-tests--rsh (x n w) "Logical shift right X by N steps, word size W." (if (< n 0) (calc-tests--lsh x (- n) w) ;; First zero-extend, then shift. (calc-tests--clip (ash (calc-tests--clip x (abs w)) (- n)) w))) (defun calc-tests--ash (x n w) "Arithmetic shift left X by N steps, word size W." (if (< n 0) (calc-tests--rash x (- n) w) (calc-tests--clip (ash x n) w))) (defun calc-tests--rash (x n w) "Arithmetic shift right X by N steps, word size W." (if (< n 0) (calc-tests--ash x (- n) w) ;; First sign-extend, then shift. (calc-tests--clip (ash (calc-tests--clip x (- (abs w))) (- n)) w))) (defun calc-tests--rot (x n w) "Rotate X left by N steps, word size W." (let* ((aw (abs w)) (y (calc-tests--clip x aw)) (steps (mod n aw))) (calc-tests--clip (logior (ash y steps) (ash y (- steps aw))) w))) (ert-deftest calc-shift-binary () (dolist (w '(16 32 -16 -32)) (dolist (x '(0 1 #x1234 #x8000 #xabcd #xffff #x12345678 #xabcdef12 #x80000000 #xffffffff #x1234567890ab #x1234967890ab -1 -14 #x-8000 #x-ffff #x-8001 #x-10000 #x-80000000 #x-ffffffff #x-80000001 #x-100000000)) (dolist (n '(0 1 4 16 32 -1 -4 -16 -32)) (should (equal (calcFunc-lsh x n w) (calc-tests--lsh x n w))) (should (equal (calcFunc-rsh x n w) (calc-tests--rsh x n w))) (should (equal (calcFunc-ash x n w) (calc-tests--ash x n w))) (should (equal (calcFunc-rash x n w) (calc-tests--rash x n w))) (should (equal (calcFunc-rot x n w) (calc-tests--rot x n w))))))) (provide 'calc-tests) ;;; calc-tests.el ends here ;; Local Variables: ;; bug-reference-url-format: "https://debbugs.gnu.org/%s" ;; End: