;; Copyright (c) 2014 Yuichi Nishiwaki, and other picrin contributers. ;; Copyright (c) 2009-2012 Alex Shinn ;; All rights reserved. ;; Redistribution and use in source and binary forms, with or without ;; modification, are permitted provided that the following conditions ;; are met: ;; 1. Redistributions of source code must retain the above copyright ;; notice, this list of conditions and the following disclaimer. ;; 2. Redistributions in binary form must reproduce the above copyright ;; notice, this list of conditions and the following disclaimer in the ;; documentation and/or other materials provided with the distribution. ;; 3. The name of the author may not be used to endorse or promote products ;; derived from this software without specific prior written permission. ;; THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR ;; IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES ;; OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. ;; IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, ;; INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT ;; NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, ;; DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY ;; THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT ;; (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF ;; THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. (import (scheme base) ; (scheme char) (scheme lazy) (scheme inexact) ; (scheme complex) (scheme time) (scheme file) (scheme read) (scheme write) ; (scheme eval) (scheme process-context) ; (scheme case-lambda) ) ;; R7RS test suite. Covers all procedures and syntax in the small ;; language except `delete-file'. Currently assumes full-unicode ;; support, the full numeric tower and all standard libraries ;; provided. (define (test-begin . o) #f) (define (test-end . o) #f) (define counter 1) (define-syntax test (syntax-rules () ((test expected expr) (let ((res expr)) (display "case ") (write counter) (cond ((equal? res expected) (display " PASS: ") (write 'expr) (display " equals ") (write expected) (display "") (newline) ) ((not (equal? res expected)) (display " FAIL: ") (write 'expr) (newline) (display " expected ") (write expected) (display " but got ") (write res) (display "") (newline))) (set! counter (+ counter 1)))))) (newline) (test-begin "R7RS") (test-begin "4.1 Primitive expression types") (let () (define x 28) (test 28 x)) (test 'a (quote a)) (test #(a b c) (quote #(a b c))) (test '(+ 1 2) (quote (+ 1 2))) (test 'a 'a) (test #(a b c) '#(a b c)) (test '() '()) (test '(+ 1 2) '(+ 1 2)) (test '(quote a) '(quote a)) (test '(quote a) ''a) (test "abc" '"abc") (test "abc" "abc") (test 145932 '145932) (test 145932 145932) (test #t '#t) (test #t #t) (test 7 (+ 3 4)) (test 12 ((if #f + *) 3 4)) (test 8 ((lambda (x) (+ x x)) 4)) (define reverse-subtract (lambda (x y) (- y x))) (test 3 (reverse-subtract 7 10)) (define add4 (let ((x 4)) (lambda (y) (+ x y)))) (test 10 (add4 6)) (test '(3 4 5 6) ((lambda x x) 3 4 5 6)) (test '(5 6) ((lambda (x y . z) z) 3 4 5 6)) (test 'yes (if (> 3 2) 'yes 'no)) (test 'no (if (> 2 3) 'yes 'no)) (test 1 (if (> 3 2) (- 3 2) (+ 3 2))) (let () (define x 2) (test 3 (+ x 1))) (test-end) (test-begin "4.2 Derived expression types") (test 'greater (cond ((> 3 2) 'greater) ((< 3 2) 'less))) (test 'equal (cond ((> 3 3) 'greater) ((< 3 3) 'less) (else 'equal))) (test 2 (cond ((assv 'b '((a 1) (b 2))) => cadr) (else #f))) (test 'composite (case (* 2 3) ((2 3 5 7) 'prime) ((1 4 6 8 9) 'composite))) (test 'c (case (car '(c d)) ((a e i o u) 'vowel) ((w y) 'semivowel) (else => (lambda (x) x)))) (test '((other . z) (semivowel . y) (other . x) (semivowel . w) (vowel . u)) (map (lambda (x) (case x ((a e i o u) => (lambda (w) (cons 'vowel w))) ((w y) (cons 'semivowel x)) (else => (lambda (w) (cons 'other w))))) '(z y x w u))) (test #t (and (= 2 2) (> 2 1))) (test #f (and (= 2 2) (< 2 1))) (test '(f g) (and 1 2 'c '(f g))) (test #t (and)) (test #t (or (= 2 2) (> 2 1))) (test #t (or (= 2 2) (< 2 1))) (test #f (or #f #f #f)) (test '(b c) (or (memq 'b '(a b c)) (/ 3 0))) (test 6 (let ((x 2) (y 3)) (* x y))) (test 35 (let ((x 2) (y 3)) (let ((x 7) (z (+ x y))) (* z x)))) (test 70 (let ((x 2) (y 3)) (let* ((x 7) (z (+ x y))) (* z x)))) (test #t (letrec ((even? (lambda (n) (if (zero? n) #t (odd? (- n 1))))) (odd? (lambda (n) (if (zero? n) #f (even? (- n 1)))))) (even? 88))) (test 5 (letrec* ((p (lambda (x) (+ 1 (q (- x 1))))) (q (lambda (y) (if (zero? y) 0 (+ 1 (p (- y 1)))))) (x (p 5)) (y x)) y)) ;; By Jussi Piitulainen ;; and John Cowan : ;; http://lists.scheme-reports.org/pipermail/scheme-reports/2013-December/003876.html (define (means ton) (letrec* ((mean (lambda (f g) (f (/ (sum g ton) n)))) (sum (lambda (g ton) (if (null? ton) (+) (if (number? ton) (g ton) (+ (sum g (car ton)) (sum g (cdr ton))))))) (n (sum (lambda (x) 1) ton))) (values (mean values values) (mean exp log) (mean / /)))) (let*-values (((a b c) (means '(8 5 99 1 22)))) (test 27 a) (test 9.728 b) (test (/ 1800 497) c)) (let*-values (((root rem) (exact-integer-sqrt 32))) (test 35 (* root rem))) (test '(1073741824 0) (let*-values (((root rem) (exact-integer-sqrt (expt 2 60)))) (list root rem))) (test '(1518500249 3000631951) (let*-values (((root rem) (exact-integer-sqrt (expt 2 61)))) (list root rem))) (test '(815238614083298888 443242361398135744) (let*-values (((root rem) (exact-integer-sqrt (expt 2 119)))) (list root rem))) (test '(1152921504606846976 0) (let*-values (((root rem) (exact-integer-sqrt (expt 2 120)))) (list root rem))) (test '(1630477228166597776 1772969445592542976) (let*-values (((root rem) (exact-integer-sqrt (expt 2 121)))) (list root rem))) (test '(31622776601683793319 62545769258890964239) (let*-values (((root rem) (exact-integer-sqrt (expt 10 39)))) (list root rem))) (let*-values (((root rem) (exact-integer-sqrt (expt 2 140)))) (test 0 rem) (test (expt 2 140) (square root))) (test '(x y x y) (let ((a 'a) (b 'b) (x 'x) (y 'y)) (let*-values (((a b) (values x y)) ((x y) (values a b))) (list a b x y)))) (let () (define x 0) (set! x 5) (test 6 (+ x 1))) (test #(0 1 2 3 4) (do ((vec (make-vector 5)) (i 0 (+ i 1))) ((= i 5) vec) (vector-set! vec i i))) (test 25 (let ((x '(1 3 5 7 9))) (do ((x x (cdr x)) (sum 0 (+ sum (car x)))) ((null? x) sum)))) (test '((6 1 3) (-5 -2)) (let loop ((numbers '(3 -2 1 6 -5)) (nonneg '()) (neg '())) (cond ((null? numbers) (list nonneg neg)) ((>= (car numbers) 0) (loop (cdr numbers) (cons (car numbers) nonneg) neg)) ((< (car numbers) 0) (loop (cdr numbers) nonneg (cons (car numbers) neg)))))) (test 3 (force (delay (+ 1 2)))) (test '(3 3) (let ((p (delay (+ 1 2)))) (list (force p) (force p)))) (define integers (letrec ((next (lambda (n) (delay (cons n (next (+ n 1))))))) (next 0))) (define head (lambda (stream) (car (force stream)))) (define tail (lambda (stream) (cdr (force stream)))) (test 2 (head (tail (tail integers)))) (define (stream-filter p? s) (delay-force (if (null? (force s)) (delay '()) (let ((h (car (force s))) (t (cdr (force s)))) (if (p? h) (delay (cons h (stream-filter p? t))) (stream-filter p? t)))))) (test 5 (head (tail (tail (stream-filter odd? integers))))) (let () (define x 5) (define count 0) (define p (delay (begin (set! count (+ count 1)) (if (> count x) count (force p))))) (test 6 (force p)) (test 6 (begin (set! x 10) (force p)))) (test #t (promise? (delay (+ 2 2)))) (test #t (promise? (make-promise (+ 2 2)))) (test #t (let ((x (delay (+ 2 2)))) (force x) (promise? x))) (test #t (let ((x (make-promise (+ 2 2)))) (force x) (promise? x))) ;; (define radix ;; (make-parameter ;; 10 ;; (lambda (x) ;; (if (and (integer? x) (<= 2 x 16)) ;; x ;; (error "invalid radix"))))) ;; (define (f n) (number->string n (radix))) ;; (test "12" (f 12)) ;; (test "1100" (parameterize ((radix 2)) ;; (f 12))) ;; (test "12" (f 12)) (test '(list 3 4) `(list ,(+ 1 2) 4)) (let ((name 'a)) (test '(list a (quote a)) `(list ,name ',name))) (test '(a 3 4 5 6 b) `(a ,(+ 1 2) ,@(map abs '(4 -5 6)) b)) (test #(10 5 4 16 9 8) `#(10 5 ,(square 2) ,@(map square '(4 3)) 8)) (test '(a `(b ,(+ 1 2) ,(foo 4 d) e) f) `(a `(b ,(+ 1 2) ,(foo ,(+ 1 3) d) e) f) ) (let ((name1 'x) (name2 'y)) (test '(a `(b ,x ,'y d) e) `(a `(b ,,name1 ,',name2 d) e))) (test '(list 3 4) (quasiquote (list (unquote (+ 1 2)) 4)) ) (test `(list ,(+ 1 2) 4) (quasiquote (list (unquote (+ 1 2)) 4))) ;; (define plus ;; (case-lambda ;; (() 0) ;; ((x) x) ;; ((x y) (+ x y)) ;; ((x y z) (+ (+ x y) z)) ;; (args (apply + args)))) ;; (test 0 (plus)) ;; (test 1 (plus 1)) ;; (test 3 (plus 1 2)) ;; (test 6 (plus 1 2 3)) ;; (test 10 (plus 1 2 3 4)) ;; (define mult ;; (case-lambda ;; (() 1) ;; ((x) x) ;; ((x y) (* x y)) ;; ((x y . z) (apply mult (* x y) z)))) ;; (test 1 (mult)) ;; (test 1 (mult 1)) ;; (test 2 (mult 1 2)) ;; (test 6 (mult 1 2 3)) ;; (test 24 (mult 1 2 3 4)) (test-end) (test-begin "4.3 Macros") ;; (test 'now (let-syntax ;; ((when (syntax-rules () ;; ((when test stmt1 stmt2 ...) ;; (if test ;; (begin stmt1 ;; stmt2 ...)))))) ;; (let ((if #t)) ;; (when if (set! if 'now)) ;; if))) ;; (test 'outer (let ((x 'outer)) ;; (let-syntax ((m (syntax-rules () ((m) x)))) ;; (let ((x 'inner)) ;; (m))))) ;; (test 7 (letrec-syntax ;; ((my-or (syntax-rules () ;; ((my-or) #f) ;; ((my-or e) e) ;; ((my-or e1 e2 ...) ;; (let ((temp e1)) ;; (if temp ;; temp ;; (my-or e2 ...))))))) ;; (let ((x #f) ;; (y 7) ;; (temp 8) ;; (let odd?) ;; (if even?)) ;; (my-or x ;; (let temp) ;; (if y) ;; y)))) (define-syntax be-like-begin (syntax-rules () ((be-like-begin name) (define-syntax name (syntax-rules () ((name expr (... ...)) (begin expr (... ...)))))))) (be-like-begin sequence) (test 4 (sequence 1 2 3 4)) (define-syntax jabberwocky (syntax-rules () ((_ hatter) (begin (define march-hare 42) (define-syntax hatter (syntax-rules () ((_) march-hare))))))) (jabberwocky mad-hatter) (test 42 (mad-hatter)) (test 'ok (let ((=> #f)) (cond (#t => 'ok)))) (test-end) (test-begin "5 Program structure") (define add3 (lambda (x) (+ x 3))) (test 6 (add3 3)) (define first car) (test 1 (first '(1 2))) ;; (test 45 (let ((x 5)) ;; (define foo (lambda (y) (bar x y))) ;; (define bar (lambda (a b) (+ (* a b) a))) ;; (foo (+ x 3)))) (test 'ok (let () (define-values () (values)) 'ok)) (test 1 (let () (define-values (x) (values 1)) x)) ;; (test 3 ;; (let () ;; (define-values x (values 1 2)) ;; (apply + x))) (test 3 (let () (define-values (x y) (values 1 2)) (+ x y))) (test 6 (let () (define-values (x y z) (values 1 2 3)) (+ x y z))) ;; (test 10 ;; (let () ;; (define-values (x y . z) (values 1 2 3 4)) ;; (+ x y (car z) (cadr z)))) (test '(2 1) (let ((x 1) (y 2)) (define-syntax swap! (syntax-rules () ((swap! a b) (let ((tmp a)) (set! a b) (set! b tmp))))) (swap! x y) (list x y))) ;; Records (define-record-type (kons x y) pare? (x kar set-kar!) (y kdr)) (test #t (pare? (kons 1 2))) (test #f (pare? (cons 1 2))) (test 1 (kar (kons 1 2))) (test 2 (kdr (kons 1 2))) (test 3 (let ((k (kons 1 2))) (set-kar! k 3) (kar k))) (test-end) ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;; 6 Standard Procedures (test-begin "6.1 Equivalence Predicates") (test #t (eqv? 'a 'a)) (test #f (eqv? 'a 'b)) (test #t (eqv? 2 2)) (test #t (eqv? '() '())) (test #t (eqv? 100000000 100000000)) (test #f (eqv? (cons 1 2) (cons 1 2))) (test #f (eqv? (lambda () 1) (lambda () 2))) (test #f (eqv? #f 'nil)) (define gen-counter (lambda () (let ((n 0)) (lambda () (set! n (+ n 1)) n)))) (test #t (let ((g (gen-counter))) (eqv? g g))) (test #f (eqv? (gen-counter) (gen-counter))) (define gen-loser (lambda () (let ((n 0)) (lambda () (set! n (+ n 1)) 27)))) (test #t (let ((g (gen-loser))) (eqv? g g))) (test #f (letrec ((f (lambda () (if (eqv? f g) 'f 'both))) (g (lambda () (if (eqv? f g) 'g 'both)))) (eqv? f g))) (test #t (let ((x '(a))) (eqv? x x))) (test #t (eq? 'a 'a)) (test #f (eq? (list 'a) (list 'a))) (test #t (eq? '() '())) (test #t (let ((x '(a))) (eq? x x))) (test #t (let ((x '#())) (eq? x x))) (test #t (let ((p (lambda (x) x))) (eq? p p))) (test #t (equal? 'a 'a)) (test #t (equal? '(a) '(a))) (test #t (equal? '(a (b) c) '(a (b) c))) (test #t (equal? "abc" "abc")) (test #t (equal? 2 2)) (test #t (equal? (make-vector 5 'a) (make-vector 5 'a))) (test-end) (test-begin "6.2 Numbers") ;; (test #t (complex? 3+4i)) (test #t (complex? 3)) (test #t (real? 3)) ;; (test #t (real? -2.5+0i)) ;; (test #f (real? -2.5+0.0i)) ;; (test #t (real? #e1e10)) (test #t (real? +inf.0)) (test #f (rational? -inf.0)) ;; (test #t (rational? 6/10)) ;; (test #t (rational? 6/3)) ;; (test #t (integer? 3+0i)) (test #t (integer? 3.0)) ;; (test #t (integer? 8/4)) (test #f (exact? 3.0)) ;; (test #t (exact? #e3.0)) ;; (test #t (inexact? 3.)) (test #t (exact-integer? 32)) (test #f (exact-integer? 32.0)) ;; (test #f (exact-integer? 32/5)) (test #t (finite? 3)) (test #f (finite? +inf.0)) ;; (test #f (finite? 3.0+inf.0i)) (test #f (infinite? 3)) (test #t (infinite? +inf.0)) (test #f (infinite? +nan.0)) ;; (test #t (infinite? 3.0+inf.0i)) (test #t (nan? +nan.0)) (test #f (nan? 32)) ;; (test #t (nan? +nan.0+5.0i)) ;; (test #f (nan? 1+2i)) ;; (test #t (= 1 1.0 1.0+0.0i)) ;; (test #f (= 1.0 1.0+1.0i)) ;; (test #t (< 1 2 3)) ;; (test #f (< 1 1 2)) ;; (test #t (> 3.0 2.0 1.0)) ;; (test #f (> -3.0 2.0 1.0)) ;; (test #t (<= 1 1 2)) ;; (test #f (<= 1 2 1)) ;; (test #t (>= 2 1 1)) ;; (test #f (>= 1 2 1)) ;; From R7RS 6.2.6 Numerical operations: ;; ;; These predicates are required to be transitive. ;; ;; _Note:_ The traditional implementations of these predicates in ;; Lisp-like languages, which involve converting all arguments to inexact ;; numbers if any argument is inexact, are not transitive. ;; Example from Alan Bawden (let ((a (- (expt 2 1000) 1)) (b (inexact (expt 2 1000))) ; assuming > single-float-epsilon (c (+ (expt 2 1000) 1))) (test #t (if (and (= a b) (= b c)) (= a c) #t))) ;; From CLtL 12.3. Comparisons on Numbers: ;; ;; Let _a_ be the result of (/ 10.0 single-float-epsilon), and let ;; _j_ be the result of (floor a). ..., all of (<= a j), (< j (+ j ;; 1)), and (<= (+ j 1) a) would be true; transitivity would then ;; imply that (< a a) ought to be true ... ;; Transliteration from Jussi Piitulainen (define single-float-epsilon (do ((eps 1.0 (* eps 2.0))) ((= eps (+ eps 1.0)) eps))) (let* ((a (/ 10.0 single-float-epsilon)) (j (exact a))) (test #t (if (and (<= a j) (< j (+ j 1))) (not (<= (+ j 1) a)) #t))) (test #t (zero? 0)) (test #t (zero? 0.0)) ;; (test #t (zero? 0.0+0.0i)) (test #f (zero? 1)) (test #f (zero? -1)) (test #f (positive? 0)) (test #f (positive? 0.0)) (test #t (positive? 1)) (test #t (positive? 1.0)) (test #f (positive? -1)) (test #f (positive? -1.0)) (test #t (positive? +inf.0)) (test #f (positive? -inf.0)) (test #f (negative? 0)) (test #f (negative? 0.0)) (test #f (negative? 1)) (test #f (negative? 1.0)) (test #t (negative? -1)) (test #t (negative? -1.0)) (test #f (negative? +inf.0)) (test #t (negative? -inf.0)) (test #f (odd? 0)) (test #t (odd? 1)) (test #t (odd? -1)) (test #f (odd? 102)) (test #t (even? 0)) (test #f (even? 1)) (test #t (even? -2)) (test #t (even? 102)) (test 3 (max 3)) (test 4 (max 3 4)) (test 4.0 (max 3.9 4)) (test 5.0 (max 5 3.9 4)) (test +inf.0 (max 100 +inf.0)) (test 3 (min 3)) (test 3 (min 3 4)) (test 3.0 (min 3 3.1)) (test -inf.0 (min -inf.0 -100)) (test 7 (+ 3 4)) (test 3 (+ 3)) (test 0 (+)) (test 4 (* 4)) (test 1 (*)) (test -1 (- 3 4)) (test -6 (- 3 4 5)) (test -3 (- 3)) ;; (test 3/20 (/ 3 4 5)) ;; (test 1/3 (/ 3)) (test 7 (abs -7)) (test 7 (abs 7)) ;; (test-values (values 2 1) (floor/ 5 2)) ;; (test-values (values -3 1) (floor/ -5 2)) ;; (test-values (values -3 -1) (floor/ 5 -2)) ;; (test-values (values 2 -1) (floor/ -5 -2)) ;; (test-values (values 2 1) (truncate/ 5 2)) ;; (test-values (values -2 -1) (truncate/ -5 2)) ;; (test-values (values -2 1) (truncate/ 5 -2)) ;; (test-values (values 2 -1) (truncate/ -5 -2)) ;; (test-values (values 2.0 -1.0) (truncate/ -5.0 -2)) (test 1 (modulo 13 4)) (test 1 (remainder 13 4)) (test 3 (modulo -13 4)) (test -1 (remainder -13 4)) (test -3 (modulo 13 -4)) (test 1 (remainder 13 -4)) (test -1 (modulo -13 -4)) (test -1 (remainder -13 -4)) (test -1.0 (remainder -13 -4.0)) (test 4 (gcd 32 -36)) (test 0 (gcd)) (test 288 (lcm 32 -36)) (test 288.0 (lcm 32.0 -36)) (test 1 (lcm)) ;; (test 3 (numerator (/ 6 4))) ;; (test 2 (denominator (/ 6 4))) ;; (test 2.0 (denominator (inexact (/ 6 4)))) ;; (test 11.0 (numerator 5.5)) ;; (test 2.0 (denominator 5.5)) ;; (test 5.0 (numerator 5.0)) ;; (test 1.0 (denominator 5.0)) (test -5.0 (floor -4.3)) (test -4.0 (ceiling -4.3)) (test -4.0 (truncate -4.3)) (test -4.0 (round -4.3)) (test 3.0 (floor 3.5)) (test 4.0 (ceiling 3.5)) (test 3.0 (truncate 3.5)) (test 4.0 (round 3.5)) ;; (test 4 (round 7/2)) (test 7 (round 7)) ;; (test 1/3 (rationalize (exact .3) 1/10)) ;; (test #i1/3 (rationalize .3 1/10)) (test 1.0 (inexact (exp 0))) ;; may return exact number (test 20.0855369231877 (exp 3)) (test 0.0 (inexact (log 1))) ;; may return exact number (test 1.0 (log (exp 1))) (test 42.0 (log (exp 42))) (test 2.0 (log 100 10)) (test 12.0 (log 4096 2)) (test 0.0 (inexact (sin 0))) ;; may return exact number (test 1.0 (sin 1.5707963267949)) (test 1.0 (inexact (cos 0))) ;; may return exact number (test -1.0 (cos 3.14159265358979)) (test 0.0 (inexact (tan 0))) ;; may return exact number (test 1.5574077246549 (tan 1)) (test 0.0 (asin 0)) (test 1.5707963267949 (asin 1)) (test 0.0 (acos 1)) (test 3.14159265358979 (acos -1)) (test 0.0 (atan 0.0 1.0)) (test -0.0 (atan -0.0 1.0)) (test 0.785398163397448 (atan 1.0 1.0)) (test 1.5707963267949 (atan 1.0 0.0)) (test 2.35619449019234 (atan 1.0 -1.0)) (test 3.14159265358979 (atan 0.0 -1.0)) (test -3.14159265358979 (atan -0.0 -1.0)) ; (test -2.35619449019234 (atan -1.0 -1.0)) (test -1.5707963267949 (atan -1.0 0.0)) (test -0.785398163397448 (atan -1.0 1.0)) ;; (test undefined (atan 0.0 0.0)) (test 1764 (square 42)) (test 4 (square 2)) (test 3.0 (inexact (sqrt 9))) (test 1.4142135623731 (sqrt 2)) ;; (test 0.0+1.0i (inexact (sqrt -1))) (test '(2 0) (call-with-values (lambda () (exact-integer-sqrt 4)) list)) (test '(2 1) (call-with-values (lambda () (exact-integer-sqrt 5)) list)) (test 27 (expt 3 3)) (test 1 (expt 0 0)) (test 0 (expt 0 1)) (test 1.0 (expt 0.0 0)) (test 0.0 (expt 0 1.0)) ;; (test 1+2i (make-rectangular 1 2)) ;; (test 0.54030230586814+0.841470984807897i (make-polar 1 1)) ;; (test 1 (real-part 1+2i)) ;; (test 2 (imag-part 1+2i)) ;; (test 2.23606797749979 (magnitude 1+2i)) ;; (test 1.10714871779409 (angle 1+2i)) (test 1.0 (inexact 1)) (test #t (inexact? (inexact 1))) (test 1 (exact 1.0)) (test #t (exact? (exact 1.0))) (test 100 (string->number "100")) (test 256 (string->number "100" 16)) (test 100.0 (string->number "1e2")) (test-end) (test-begin "6.3 Booleans") (test #t #t) (test #f #f) (test #f '#f) (test #f (not #t)) (test #f (not 3)) (test #f (not (list 3))) (test #t (not #f)) (test #f (not '())) (test #f (not (list))) (test #f (not 'nil)) (test #t (boolean? #f)) (test #f (boolean? 0)) (test #f (boolean? '())) (test #t (boolean=? #t #t)) (test #t (boolean=? #f #f)) (test #f (boolean=? #t #f)) (test #t (boolean=? #f #f #f)) (test #f (boolean=? #t #t #f)) (test-end) (test-begin "6.4 Lists") (let* ((x (list 'a 'b 'c)) (y x)) (test '(a b c) (values y)) (test #t (list? y)) (set-cdr! x 4) (test '(a . 4) (values x)) (test #t (eqv? x y)) (test #f (list? y)) (set-cdr! x x) (test #f (list? x))) (test #t (pair? '(a . b))) (test #t (pair? '(a b c))) (test #f (pair? '())) (test #f (pair? '#(a b))) (test '(a) (cons 'a '())) (test '((a) b c d) (cons '(a) '(b c d))) (test '("a" b c) (cons "a" '(b c))) (test '(a . 3) (cons 'a 3)) (test '((a b) . c) (cons '(a b) 'c)) (test 'a (car '(a b c))) (test '(a) (car '((a) b c d))) (test 1 (car '(1 . 2))) (test '(b c d) (cdr '((a) b c d))) (test 2 (cdr '(1 . 2))) (define (g) '(constant-list)) (test #t (list? '(a b c))) (test #t (list? '())) (test #f (list? '(a . b))) (test #f (let ((x (list 'a))) (set-cdr! x x) (list? x))) (test '(3 3) (make-list 2 3)) (test '(a 7 c) (list 'a (+ 3 4) 'c)) (test '() (list)) (test 3 (length '(a b c))) (test 3 (length '(a (b) (c d e)))) (test 0 (length '())) (test '(x y) (append '(x) '(y))) (test '(a b c d) (append '(a) '(b c d))) (test '(a (b) (c)) (append '(a (b)) '((c)))) (test '(a b c . d) (append '(a b) '(c . d))) (test 'a (append '() 'a)) (test '(c b a) (reverse '(a b c))) (test '((e (f)) d (b c) a) (reverse '(a (b c) d (e (f))))) (test '(d e) (list-tail '(a b c d e) 3)) (test 'c (list-ref '(a b c d) 2)) (test 'c (list-ref '(a b c d) (exact (round 1.8)))) (test '(0 ("Sue" "Sue") "Anna") (let ((lst (list 0 '(2 2 2 2) "Anna"))) (list-set! lst 1 '("Sue" "Sue")) lst)) (test '(a b c) (memq 'a '(a b c))) (test '(b c) (memq 'b '(a b c))) (test #f (memq 'a '(b c d))) (test #f (memq (list 'a) '(b (a) c))) (test '((a) c) (member (list 'a) '(b (a) c))) ;; (test '("b" "c") (member "B" '("a" "b" "c") string-ci=?)) (test '(101 102) (memv 101 '(100 101 102))) (let () (define e '((a 1) (b 2) (c 3))) (test '(a 1) (assq 'a e)) (test '(b 2) (assq 'b e)) (test #f (assq 'd e))) (test #f (assq (list 'a) '(((a)) ((b)) ((c))))) (test '((a)) (assoc (list 'a) '(((a)) ((b)) ((c))))) (test '(2 4) (assoc 2.0 '((1 1) (2 4) (3 9)) =)) (test '(5 7) (assv 5 '((2 3) (5 7) (11 13)))) (test '(1 2 3) (list-copy '(1 2 3))) (test "foo" (list-copy "foo")) (test '() (list-copy '())) (test '(3 . 4) (list-copy '(3 . 4))) (test '(6 7 8 . 9) (list-copy '(6 7 8 . 9))) (let* ((l1 '((a b) (c d) e)) (l2 (list-copy l1))) (test l2 '((a b) (c d) e)) (test #t (eq? (car l1) (car l2))) (test #t (eq? (cadr l1) (cadr l2))) (test #f (eq? (cdr l1) (cdr l2))) (test #f (eq? (cddr l1) (cddr l2)))) (test-end) (test-begin "6.5 Symbols") (test #t (symbol? 'foo)) (test #t (symbol? (car '(a b)))) (test #f (symbol? "bar")) (test #t (symbol? 'nil)) (test #f (symbol? '())) (test #f (symbol? #f)) (test #t (symbol=? 'a 'a)) (test #f (symbol=? 'a 'A)) (test #t (symbol=? 'a 'a 'a)) (test #f (symbol=? 'a 'a 'A)) (test "flying-fish" (symbol->string 'flying-fish)) (test "Martin" (symbol->string 'Martin)) (test "Malvina" (symbol->string (string->symbol "Malvina"))) (test 'mISSISSIppi (string->symbol "mISSISSIppi")) (test #t (eq? 'bitBlt (string->symbol "bitBlt"))) (test #t (eq? 'LollyPop (string->symbol (symbol->string 'LollyPop)))) (test #t (string=? "K. Harper, M.D." (symbol->string (string->symbol "K. Harper, M.D.")))) (test-end) (test-begin "6.6 Characters") (test #t (char? #\a)) (test #f (char? "a")) (test #f (char? 'a)) (test #f (char? 0)) (test #t (char=? #\a #\a #\a)) (test #f (char=? #\a #\A)) (test #t (char? #\a #\b)) (test #f (char>? #\a #\a)) (test #t (char>? #\c #\b #\a)) (test #t (char<=? #\a #\b #\b)) (test #t (char<=? #\a #\a)) (test #f (char<=? #\b #\a)) (test #f (char>=? #\a #\b)) (test #t (char>=? #\a #\a)) (test #t (char>=? #\b #\b #\a)) ;; (test #t (char-ci=? #\a #\a)) ;; (test #t (char-ci=? #\a #\A #\a)) ;; (test #f (char-ci=? #\a #\b)) ;; (test #t (char-ci? #\A #\b)) ;; (test #f (char-ci>? #\a #\A)) ;; (test #t (char-ci>? #\c #\B #\a)) ;; (test #t (char-ci<=? #\a #\B #\b)) ;; (test #t (char-ci<=? #\A #\a)) ;; (test #f (char-ci<=? #\b #\A)) ;; (test #f (char-ci>=? #\A #\b)) ;; (test #t (char-ci>=? #\a #\A)) ;; (test #t (char-ci>=? #\b #\B #\a)) ;; (test #t (char-alphabetic? #\a)) ;; (test #f (char-alphabetic? #\space)) ;; (test #t (char-numeric? #\0)) ;; (test #f (char-numeric? #\.)) ;; (test #f (char-numeric? #\a)) ;; (test #t (char-whitespace? #\space)) ;; (test #t (char-whitespace? #\tab)) ;; (test #t (char-whitespace? #\newline)) ;; (test #f (char-whitespace? #\_)) ;; (test #f (char-whitespace? #\a)) ;; (test #t (char-upper-case? #\A)) ;; (test #f (char-upper-case? #\a)) ;; (test #f (char-upper-case? #\3)) ;; (test #t (char-lower-case? #\a)) ;; (test #f (char-lower-case? #\A)) ;; (test #f (char-lower-case? #\3)) ;; (test #t (char-alphabetic? #\Λ)) ;; (test #f (char-alphabetic? #\x0E50)) ;; (test #t (char-upper-case? #\Λ)) ;; (test #f (char-upper-case? #\λ)) ;; (test #f (char-lower-case? #\Λ)) ;; (test #t (char-lower-case? #\λ)) ;; (test #f (char-numeric? #\Λ)) ;; (test #t (char-numeric? #\x0E50)) ;; (test #t (char-whitespace? #\x1680)) ;; (test 0 (digit-value #\0)) ;; (test 3 (digit-value #\3)) ;; (test 9 (digit-value #\9)) ;; (test 4 (digit-value #\x0664)) ;; (test 0 (digit-value #\x0AE6)) ;; (test #f (digit-value #\.)) ;; (test #f (digit-value #\-)) (test 97 (char->integer #\a)) (test #\a (integer->char 97)) ;; (test #\A (char-upcase #\a)) ;; (test #\A (char-upcase #\A)) ;; (test #\a (char-downcase #\a)) ;; (test #\a (char-downcase #\A)) ;; (test #\a (char-foldcase #\a)) ;; (test #\a (char-foldcase #\A)) ;; (test #\Λ (char-upcase #\λ)) ;; (test #\Λ (char-upcase #\Λ)) ;; (test #\λ (char-downcase #\λ)) ;; (test #\λ (char-downcase #\Λ)) ;; (test #\λ (char-foldcase #\λ)) ;; (test #\λ (char-foldcase #\Λ)) (test-end) (test-begin "6.7 Strings") (test #t (string? "")) (test #t (string? " ")) (test #f (string? 'a)) (test #f (string? #\a)) (test 3 (string-length (make-string 3))) (test "---" (make-string 3 #\-)) (test "" (string)) (test "---" (string #\- #\- #\-)) (test "kitten" (string #\k #\i #\t #\t #\e #\n)) (test 0 (string-length "")) (test 1 (string-length "a")) (test 3 (string-length "abc")) (test #\a (string-ref "abc" 0)) (test #\b (string-ref "abc" 1)) (test #\c (string-ref "abc" 2)) (test "a-c" (let ((str (string #\a #\b #\c))) (string-set! str 1 #\-) str)) ;; (test (string #\a #\x1F700 #\c) ;; (let ((s (string #\a #\b #\c))) ;; (string-set! s 1 #\x1F700) ;; s)) #;(test #t (string=? "" "")) (test #t (string=? "abc" "abc" "abc")) (test #f (string=? "" "abc")) (test #f (string=? "abc" "aBc")) (test #f (string? "" "")) (test #f (string>? "abc" "abc")) (test #f (string>? "abc" "abcd")) (test #t (string>? "acd" "abcd" "abc")) (test #f (string>? "abc" "bbc")) (test #t (string<=? "" "")) (test #t (string<=? "abc" "abc")) (test #t (string<=? "abc" "abcd" "abcd")) (test #f (string<=? "abcd" "abc")) (test #t (string<=? "abc" "bbc")) (test #t (string>=? "" "")) (test #t (string>=? "abc" "abc")) (test #f (string>=? "abc" "abcd")) (test #t (string>=? "abcd" "abcd" "abc")) (test #f (string>=? "abc" "bbc")) ;; (test #t (string-ci=? "" "")) ;; (test #t (string-ci=? "abc" "abc")) ;; (test #f (string-ci=? "" "abc")) ;; (test #t (string-ci=? "abc" "aBc")) ;; (test #f (string-ci=? "abc" "aBcD")) ;; (test #f (string-ci? "abc" "aBc")) ;; (test #f (string-ci>? "abc" "aBcD")) ;; (test #t (string-ci>? "ABCd" "aBc")) ;; (test #t (string-ci<=? "abc" "aBc")) ;; (test #t (string-ci<=? "abc" "aBcD")) ;; (test #f (string-ci<=? "ABCd" "aBc")) ;; (test #t (string-ci>=? "abc" "aBc")) ;; (test #f (string-ci>=? "abc" "aBcD")) ;; (test #t (string-ci>=? "ABCd" "aBc")) ;; (test #t (string-ci=? "ΑΒΓ" "αβγ" "αβγ")) ;; (test #f (string-ci? "ΑΒΓ" "αβγ")) ;; (test #t (string-ci<=? "ΑΒΓ" "αβγ")) ;; (test #t (string-ci>=? "ΑΒΓ" "αβγ")) ;; ;; latin ;; (test "ABC" (string-upcase "abc")) ;; (test "ABC" (string-upcase "ABC")) ;; (test "abc" (string-downcase "abc")) ;; (test "abc" (string-downcase "ABC")) ;; (test "abc" (string-foldcase "abc")) ;; (test "abc" (string-foldcase "ABC")) ;; ;; cyrillic ;; (test "ΑΒΓ" (string-upcase "αβγ")) ;; (test "ΑΒΓ" (string-upcase "ΑΒΓ")) ;; (test "αβγ" (string-downcase "αβγ")) ;; (test "αβγ" (string-downcase "ΑΒΓ")) ;; (test "αβγ" (string-foldcase "αβγ")) ;; (test "αβγ" (string-foldcase "ΑΒΓ")) ;; ;; special cases ;; (test "SSA" (string-upcase "ßa")) ;; (test "ßa" (string-downcase "ßa")) ;; (test "ssa" (string-downcase "SSA")) ;; (test "İ" (string-upcase "İ")) ;; (test "i\x0307;" (string-downcase "İ")) ;; (test "i\x0307;" (string-foldcase "İ")) ;; (test "J̌" (string-upcase "ǰ")) ;; ;; context-sensitive (final sigma) ;; (test "ΓΛΏΣΣΑ" (string-upcase "γλώσσα")) ;; (test "γλώσσα" (string-downcase "ΓΛΏΣΣΑ")) ;; (test "γλώσσα" (string-foldcase "ΓΛΏΣΣΑ")) ;; (test "ΜΈΛΟΣ" (string-upcase "μέλος")) ;; (test #t (and (member (string-downcase "ΜΈΛΟΣ") '("μέλος" "μέλοσ")) #t)) ;; (test "μέλοσ" (string-foldcase "ΜΈΛΟΣ")) ;; (test #t (and (member (string-downcase "ΜΈΛΟΣ ΕΝΌΣ") ;; '("μέλος ενός" "μέλοσ ενόσ")) ;; #t)) (test "" (substring "" 0 0)) (test "" (substring "a" 0 0)) (test "" (substring "abc" 1 1)) (test "ab" (substring "abc" 0 2)) (test "bc" (substring "abc" 1 3)) (test "" (string-append "")) (test "" (string-append "" "")) (test "abc" (string-append "" "abc")) (test "abc" (string-append "abc" "")) (test "abcde" (string-append "abc" "de")) (test "abcdef" (string-append "abc" "de" "f")) (test '() (string->list "")) (test '(#\a) (string->list "a")) (test '(#\a #\b #\c) (string->list "abc")) (test '(#\a #\b #\c) (string->list "abc" 0)) (test '(#\b #\c) (string->list "abc" 1)) (test '(#\b #\c) (string->list "abc" 1 3)) (test "" (list->string '())) (test "abc" (list->string '(#\a #\b #\c))) (test "" (string-copy "")) (test "" (string-copy "" 0)) (test "" (string-copy "" 0 0)) (test "abc" (string-copy "abc")) (test "abc" (string-copy "abc" 0)) (test "bc" (string-copy "abc" 1)) (test "b" (string-copy "abc" 1 2)) (test "bc" (string-copy "abc" 1 3)) ;; (test "-----" ;; (let ((str (make-string 5 #\x))) (string-fill! str #\-) str)) ;; (test "xx---" ;; (let ((str (make-string 5 #\x))) (string-fill! str #\- 2) str)) ;; (test "xx-xx" ;; (let ((str (make-string 5 #\x))) (string-fill! str #\- 2 3) str)) ;; (test "a12de" ;; (let ((str (string-copy "abcde"))) (string-copy! str 1 "12345" 0 2) str)) ;; (test "-----" ;; (let ((str (make-string 5 #\x))) (string-copy! str 0 "-----") str)) ;; (test "---xx" ;; (let ((str (make-string 5 #\x))) (string-copy! str 0 "-----" 2) str)) ;; (test "xx---" ;; (let ((str (make-string 5 #\x))) (string-copy! str 2 "-----" 0 3) str)) ;; (test "xx-xx" ;; (let ((str (make-string 5 #\x))) (string-copy! str 2 "-----" 2 3) str)) ;; same source and dest ;; (test "aabde" ;; (let ((str (string-copy "abcde"))) (string-copy! str 1 str 0 2) str)) ;; (test "abcab" ;; (let ((str (string-copy "abcde"))) (string-copy! str 3 str 0 2) str)) (test-end) (test-begin "6.8 Vectors") (test #t (vector? #())) (test #t (vector? #(1 2 3))) (test #t (vector? '#(1 2 3))) (test 0 (vector-length (make-vector 0))) (test 1000 (vector-length (make-vector 1000))) (test #(0 (2 2 2 2) "Anna") '#(0 (2 2 2 2) "Anna")) (test #(a b c) (vector 'a 'b 'c)) (test 8 (vector-ref '#(1 1 2 3 5 8 13 21) 5)) (test 13 (vector-ref '#(1 1 2 3 5 8 13 21) (let ((i (round (* 2 (acos -1))))) (if (inexact? i) (exact i) i)))) (test #(0 ("Sue" "Sue") "Anna") (let ((vec (vector 0 '(2 2 2 2) "Anna"))) (vector-set! vec 1 '("Sue" "Sue")) vec)) (test '(dah dah didah) (vector->list '#(dah dah didah))) (test '(dah didah) (vector->list '#(dah dah didah) 1)) (test '(dah) (vector->list '#(dah dah didah) 1 2)) (test #(dididit dah) (list->vector '(dididit dah))) (test #() (string->vector "")) (test #(#\A #\B #\C) (string->vector "ABC")) (test #(#\B #\C) (string->vector "ABC" 1)) (test #(#\B) (string->vector "ABC" 1 2)) (test "" (vector->string #())) (test "123" (vector->string #(#\1 #\2 #\3))) (test "23" (vector->string #(#\1 #\2 #\3) 1)) (test "2" (vector->string #(#\1 #\2 #\3) 1 2)) (test #() (vector-copy #())) (test #(a b c) (vector-copy #(a b c))) (test #(b c) (vector-copy #(a b c) 1)) (test #(b) (vector-copy #(a b c) 1 2)) (test #() (vector-append #())) (test #() (vector-append #() #())) (test #(a b c) (vector-append #() #(a b c))) (test #(a b c) (vector-append #(a b c) #())) (test #(a b c d e) (vector-append #(a b c) #(d e))) (test #(a b c d e f) (vector-append #(a b c) #(d e) #(f))) (test #(1 2 smash smash 5) (let ((vec (vector 1 2 3 4 5))) (vector-fill! vec 'smash 2 4) vec)) (test #(x x x x x) (let ((vec (vector 1 2 3 4 5))) (vector-fill! vec 'x) vec)) (test #(1 2 x x x) (let ((vec (vector 1 2 3 4 5))) (vector-fill! vec 'x 2) vec)) (test #(1 2 x 4 5) (let ((vec (vector 1 2 3 4 5))) (vector-fill! vec 'x 2 3) vec)) (test #(1 a b 4 5) (let ((vec (vector 1 2 3 4 5))) (vector-copy! vec 1 #(a b c d e) 0 2) vec)) (test #(a b c d e) (let ((vec (vector 1 2 3 4 5))) (vector-copy! vec 0 #(a b c d e)) vec)) (test #(c d e 4 5) (let ((vec (vector 1 2 3 4 5))) (vector-copy! vec 0 #(a b c d e) 2) vec)) (test #(1 2 a b c) (let ((vec (vector 1 2 3 4 5))) (vector-copy! vec 2 #(a b c d e) 0 3) vec)) (test #(1 2 c 4 5) (let ((vec (vector 1 2 3 4 5))) (vector-copy! vec 2 #(a b c d e) 2 3) vec)) ;; same source and dest (test #(1 1 2 4 5) (let ((vec (vector 1 2 3 4 5))) (vector-copy! vec 1 vec 0 2) vec)) (test #(1 2 3 1 2) (let ((vec (vector 1 2 3 4 5))) (vector-copy! vec 3 vec 0 2) vec)) (test-end) (test-begin "6.9 Bytevectors") (test #t (bytevector? #u8())) (test #t (bytevector? #u8(0 1 2))) (test #f (bytevector? #())) (test #f (bytevector? #(0 1 2))) (test #f (bytevector? '())) (test #t (bytevector? (make-bytevector 0))) (test 0 (bytevector-length (make-bytevector 0))) (test 1024 (bytevector-length (make-bytevector 1024))) (test 1024 (bytevector-length (make-bytevector 1024 255))) (test 3 (bytevector-length (bytevector 0 1 2))) (test 0 (bytevector-u8-ref (bytevector 0 1 2) 0)) (test 1 (bytevector-u8-ref (bytevector 0 1 2) 1)) (test 2 (bytevector-u8-ref (bytevector 0 1 2) 2)) (test #u8(0 255 2) (let ((bv (bytevector 0 1 2))) (bytevector-u8-set! bv 1 255) bv)) (test #u8() (bytevector-copy #u8())) (test #u8(0 1 2) (bytevector-copy #u8(0 1 2))) (test #u8(1 2) (bytevector-copy #u8(0 1 2) 1)) (test #u8(1) (bytevector-copy #u8(0 1 2) 1 2)) (test #u8(1 6 7 4 5) (let ((bv (bytevector 1 2 3 4 5))) (bytevector-copy! bv 1 #u8(6 7 8 9 10) 0 2) bv)) (test #u8(6 7 8 9 10) (let ((bv (bytevector 1 2 3 4 5))) (bytevector-copy! bv 0 #u8(6 7 8 9 10)) bv)) (test #u8(8 9 10 4 5) (let ((bv (bytevector 1 2 3 4 5))) (bytevector-copy! bv 0 #u8(6 7 8 9 10) 2) bv)) (test #u8(1 2 6 7 8) (let ((bv (bytevector 1 2 3 4 5))) (bytevector-copy! bv 2 #u8(6 7 8 9 10) 0 3) bv)) (test #u8(1 2 8 4 5) (let ((bv (bytevector 1 2 3 4 5))) (bytevector-copy! bv 2 #u8(6 7 8 9 10) 2 3) bv)) ;; same source and dest (test #u8(1 1 2 4 5) (let ((bv (bytevector 1 2 3 4 5))) (bytevector-copy! bv 1 bv 0 2) bv)) (test #u8(1 2 3 1 2) (let ((bv (bytevector 1 2 3 4 5))) (bytevector-copy! bv 3 bv 0 2) bv)) (test #u8() (bytevector-append #u8())) (test #u8() (bytevector-append #u8() #u8())) (test #u8(0 1 2) (bytevector-append #u8() #u8(0 1 2))) (test #u8(0 1 2) (bytevector-append #u8(0 1 2) #u8())) (test #u8(0 1 2 3 4) (bytevector-append #u8(0 1 2) #u8(3 4))) (test #u8(0 1 2 3 4 5) (bytevector-append #u8(0 1 2) #u8(3 4) #u8(5))) ;; (test "ABC" (utf8->string #u8(#x41 #x42 #x43))) ;; (test "ABC" (utf8->string #u8(0 #x41 #x42 #x43) 1)) ;; (test "ABC" (utf8->string #u8(0 #x41 #x42 #x43 0) 1 4)) ;; (test "λ" (utf8->string #u8(0 #xCE #xBB 0) 1 3)) ;; (test #u8(#x41 #x42 #x43) (string->utf8 "ABC")) ;; (test #u8(#x42 #x43) (string->utf8 "ABC" 1)) ;; (test #u8(#x42) (string->utf8 "ABC" 1 2)) ;; (test #u8(#xCE #xBB) (string->utf8 "λ")) (test-end) (test-begin "6.10 Control Features") (test #t (procedure? car)) (test #f (procedure? 'car)) (test #t (procedure? (lambda (x) (* x x)))) (test #f (procedure? '(lambda (x) (* x x)))) (test #t (call-with-current-continuation procedure?)) (test 7 (apply + (list 3 4))) (define compose (lambda (f g) (lambda args (f (apply g args))))) (test '(30 0) (call-with-values (lambda () ((compose exact-integer-sqrt *) 12 75)) list)) (test '(b e h) (map cadr '((a b) (d e) (g h)))) (test '(1 4 27 256 3125) (map (lambda (n) (expt n n)) '(1 2 3 4 5))) (test '(5 7 9) (map + '(1 2 3) '(4 5 6 7))) (test #t (let ((res (let ((count 0)) (map (lambda (ignored) (set! count (+ count 1)) count) '(a b))))) (or (equal? res '(1 2)) (equal? res '(2 1))))) (test '(10 200 3000 40 500 6000) (let ((ls1 (list 10 100 1000)) (ls2 (list 1 2 3 4 5 6))) (set-cdr! (cddr ls1) ls1) (map * ls1 ls2))) ;; (test "abdegh" (string-map char-foldcase "AbdEgH")) (test "IBM" (string-map (lambda (c) (integer->char (+ 1 (char->integer c)))) "HAL")) ;; (test "StUdLyCaPs" ;; (string-map ;; (lambda (c k) (if (eqv? k #\u) (char-upcase c) (char-downcase c))) ;; "studlycaps xxx" ;; "ululululul")) (test #(b e h) (vector-map cadr '#((a b) (d e) (g h)))) (test #(1 4 27 256 3125) (vector-map (lambda (n) (expt n n)) '#(1 2 3 4 5))) (test #(5 7 9) (vector-map + '#(1 2 3) '#(4 5 6 7))) (test #t (let ((res (let ((count 0)) (vector-map (lambda (ignored) (set! count (+ count 1)) count) '#(a b))))) (or (equal? res #(1 2)) (equal? res #(2 1))))) (test #(0 1 4 9 16) (let ((v (make-vector 5))) (for-each (lambda (i) (vector-set! v i (* i i))) '(0 1 2 3 4)) v)) (test 9750 (let ((ls1 (list 10 100 1000)) (ls2 (list 1 2 3 4 5 6)) (count 0)) (set-cdr! (cddr ls1) ls1) (for-each (lambda (x y) (set! count (+ count (* x y)))) ls2 ls1) count)) (test '(101 100 99 98 97) (let ((v '())) (string-for-each (lambda (c) (set! v (cons (char->integer c) v))) "abcde") v)) (test '(0 1 4 9 16) (let ((v (make-list 5))) (vector-for-each (lambda (i) (list-set! v i (* i i))) '#(0 1 2 3 4)) v)) (test -3 (call-with-current-continuation (lambda (exit) (for-each (lambda (x) (if (negative? x) (exit x))) '(54 0 37 -3 245 19)) #t))) (define list-length (lambda (obj) (call-with-current-continuation (lambda (return) (letrec ((r (lambda (obj) (cond ((null? obj) 0) ((pair? obj) (+ (r (cdr obj)) 1)) (else (return #f)))))) (r obj)))))) (test 4 (list-length '(1 2 3 4))) (test #f (list-length '(a b . c))) (test 5 (call-with-values (lambda () (values 4 5)) (lambda (a b) b))) (test -1 (call-with-values * -)) #; (test '(connect talk1 disconnect connect talk2 disconnect) (let ((path '()) (c #f)) (let ((add (lambda (s) (set! path (cons s path))))) (dynamic-wind (lambda () (add 'connect)) (lambda () (add (call-with-current-continuation (lambda (c0) (set! c c0) 'talk1)))) (lambda () (add 'disconnect))) (if (< (length path) 4) (c 'talk2) (reverse path))))) (test-end) (test-begin "6.11 Exceptions") ;; (test 65 ;; (with-exception-handler ;; (lambda (con) 42) ;; (lambda () ;; (+ (raise-continuable "should be a number") ;; 23)))) ;; (test #t ;; (error-object? (guard (exn (else exn)) (error "BOOM!" 1 2 3)))) ;; (test "BOOM!" ;; (error-object-message (guard (exn (else exn)) (error "BOOM!" 1 2 3)))) ;; (test '(1 2 3) ;; (error-object-irritants (guard (exn (else exn)) (error "BOOM!" 1 2 3)))) ;; (test #f ;; (file-error? (guard (exn (else exn)) (error "BOOM!")))) ;; (test #t ;; (file-error? (guard (exn (else exn)) (open-input-file " no such file ")))) ;; (test #f ;; (read-error? (guard (exn (else exn)) (error "BOOM!")))) ;; (test #t ;; (read-error? (guard (exn (else exn)) (read (open-input-string ")"))))) (define something-went-wrong #f) (define (test-exception-handler-1 v) (call-with-current-continuation (lambda (k) (with-exception-handler (lambda (x) (set! something-went-wrong (list "condition: " x)) (k 'exception)) (lambda () (+ 1 (if (> v 0) (+ v 100) (raise 'an-error)))))))) (test 106 (test-exception-handler-1 5)) (test #f something-went-wrong) (test 'exception (test-exception-handler-1 -1)) (test '("condition: " an-error) something-went-wrong) (set! something-went-wrong #f) ;; (define (test-exception-handler-2 v) ;; (guard (ex (else 'caught-another-exception)) ;; (with-exception-handler ;; (lambda (x) ;; (set! something-went-wrong #t) ;; (list "exception:" x)) ;; (lambda () ;; (+ 1 (if (> v 0) (+ v 100) (raise 'an-error))))))) ;; (test 106 (test-exception-handler-2 5)) ;; (test #f something-went-wrong) ;; (test 'caught-another-exception (test-exception-handler-2 -1)) ;; (test #t something-went-wrong) ;; Based on an example from R6RS-lib section 7.1 Exceptions. ;; R7RS section 6.11 Exceptions has a simplified version. ;; (let* ((out (open-output-string)) ;; (value (with-exception-handler ;; (lambda (con) ;; (cond ;; ((not (list? con)) ;; (raise con)) ;; ((list? con) ;; (display (car con) out)) ;; (else ;; (display "a warning has been issued" out))) ;; 42) ;; (lambda () ;; (+ (raise-continuable ;; (list "should be a number")) ;; 23))))) ;; (test "should be a number" (get-output-string out)) ;; (test 65 value)) ;; From SRFI-34 "Examples" section - #3 ;; (define (test-exception-handler-3 v out) ;; (guard (condition ;; (else ;; (display "condition: " out) ;; (write condition out) ;; (display #\! out) ;; 'exception)) ;; (+ 1 (if (= v 0) (raise 'an-error) (/ 10 v))))) ;; (let* ((out (open-output-string)) ;; (value (test-exception-handler-3 0 out))) ;; (test 'exception value) ;; (test "condition: an-error!" (get-output-string out))) ;; (define (test-exception-handler-4 v out) ;; (call-with-current-continuation ;; (lambda (k) ;; (with-exception-handler ;; (lambda (x) ;; (display "reraised " out) ;; (write x out) (display #\! out) ;; (k 'zero)) ;; (lambda () ;; (guard (condition ;; ((positive? condition) ;; 'positive) ;; ((negative? condition) ;; 'negative)) ;; (raise v))))))) ;; From SRFI-34 "Examples" section - #5 ;; (let* ((out (open-output-string)) ;; (value (test-exception-handler-4 1 out))) ;; (test "" (get-output-string out)) ;; (test 'positive value)) ;; ;; From SRFI-34 "Examples" section - #6 ;; (let* ((out (open-output-string)) ;; (value (test-exception-handler-4 -1 out))) ;; (test "" (get-output-string out)) ;; (test 'negative value)) ;; ;; From SRFI-34 "Examples" section - #7 ;; (let* ((out (open-output-string)) ;; (value (test-exception-handler-4 0 out))) ;; (test "reraised 0!" (get-output-string out)) ;; (test 'zero value)) ;; From SRFI-34 "Examples" section - #8 ;; (test 42 ;; (guard (condition ;; ((assq 'a condition) => cdr) ;; ((assq 'b condition))) ;; (raise (list (cons 'a 42))))) ;; ;; From SRFI-34 "Examples" section - #9 ;; (test '(b . 23) ;; (guard (condition ;; ((assq 'a condition) => cdr) ;; ((assq 'b condition))) ;; (raise (list (cons 'b 23))))) ;; (test 'caught-d ;; (guard (condition ;; ((assq 'c condition) 'caught-c) ;; ((assq 'd condition) 'caught-d)) ;; (list ;; (sqrt 8) ;; (guard (condition ;; ((assq 'a condition) => cdr) ;; ((assq 'b condition))) ;; (raise (list (cons 'd 24))))))) (test-end) (test-begin "6.12 Environments and evaluation") ;; (test 21 (eval '(* 7 3) (scheme-report-environment 5))) ;; (test 20 ;; (let ((f (eval '(lambda (f x) (f x x)) (null-environment 5)))) ;; (f + 10))) ;; (test 1024 (eval '(expt 2 10) (environment '(scheme base)))) ;; ;; (sin 0) may return exact number ;; (test 0.0 (inexact (eval '(sin 0) (environment '(scheme inexact))))) ;; ;; ditto ;; (test 1024.0 (eval '(+ (expt 2 10) (inexact (sin 0))) ;; (environment '(scheme base) '(scheme inexact)))) (test-end) (test-begin "6.13 Input and output") (test #t (port? (current-input-port))) (test #t (input-port? (current-input-port))) (test #t (output-port? (current-output-port))) (test #t (output-port? (current-error-port))) (test #t (input-port? (open-input-string "abc"))) (test #t (output-port? (open-output-string))) (test #t (textual-port? (open-input-string "abc"))) (test #t (textual-port? (open-output-string))) (test #t (binary-port? (open-input-bytevector #u8(0 1 2)))) (test #t (binary-port? (open-output-bytevector))) (test #t (input-port-open? (open-input-string "abc"))) (test #t (output-port-open? (open-output-string))) (test #f (let ((in (open-input-string "abc"))) (close-input-port in) (input-port-open? in))) (test #f (let ((out (open-output-string))) (close-output-port out) (output-port-open? out))) (test #f (let ((out (open-output-string))) (close-port out) (output-port-open? out))) (test #t (eof-object? (eof-object))) (test #t (eof-object? (read (open-input-string "")))) (test #t (char-ready? (open-input-string "42"))) (test 42 (read (open-input-string " 42 "))) (test #t (eof-object? (read-char (open-input-string "")))) (test #\a (read-char (open-input-string "abc"))) (test #t (eof-object? (read-line (open-input-string "")))) (test "abc" (read-line (open-input-string "abc"))) (test "abc" (read-line (open-input-string "abc\ndef\n"))) (test #t (eof-object? (read-string 3 (open-input-string "")))) (test "abc" (read-string 3 (open-input-string "abcd"))) (test "abc" (read-string 3 (open-input-string "abc\ndef\n"))) ;; (let ((in (open-input-string (string #\x10F700 #\x10F701 #\x10F702)))) ;; (let* ((c1 (read-char in)) ;; (c2 (read-char in)) ;; (c3 (read-char in))) ;; (test #\x10F700 c1) ;; (test #\x10F701 c2) ;; (test #\x10F702 c3))) ;; (test (string #\x10F700) ;; (let ((out (open-output-string))) ;; (write-char #\x10F700 out) ;; (get-output-string out))) (test "abc" (let ((out (open-output-string))) (write 'abc out) (get-output-string out))) (test "abc def" (let ((out (open-output-string))) (display "abc def" out) (get-output-string out))) (test "abc" (let ((out (open-output-string))) (display #\a out) (display "b" out) (display #\c out) (get-output-string out))) (test #t (let* ((out (open-output-string)) (r (begin (newline out) (get-output-string out)))) (or (equal? r "\n") (equal? r "\r\n")))) (test "abc def" (let ((out (open-output-string))) (write-string "abc def" out) (get-output-string out))) (test "def" (let ((out (open-output-string))) (write-string "abc def" out 4) (get-output-string out))) (test "c d" (let ((out (open-output-string))) (write-string "abc def" out 2 5) (get-output-string out))) (test "" (let ((out (open-output-string))) (flush-output-port out) (get-output-string out))) (test #t (eof-object? (read-u8 (open-input-bytevector #u8())))) (test 1 (read-u8 (open-input-bytevector #u8(1 2 3)))) (test #t (eof-object? (read-bytevector 3 (open-input-bytevector #u8())))) (test #t (u8-ready? (open-input-bytevector #u8(1)))) (test #u8(1) (read-bytevector 3 (open-input-bytevector #u8(1)))) (test #u8(1 2) (read-bytevector 3 (open-input-bytevector #u8(1 2)))) (test #u8(1 2 3) (read-bytevector 3 (open-input-bytevector #u8(1 2 3)))) (test #u8(1 2 3) (read-bytevector 3 (open-input-bytevector #u8(1 2 3 4)))) (test #t (let ((bv (bytevector 1 2 3 4 5))) (eof-object? (read-bytevector! bv (open-input-bytevector #u8()))))) (test #u8(6 7 8 9 10) (let ((bv (bytevector 1 2 3 4 5))) (read-bytevector! bv (open-input-bytevector #u8(6 7 8 9 10)) 0 5) bv)) (test #u8(6 7 8 4 5) (let ((bv (bytevector 1 2 3 4 5))) (read-bytevector! bv (open-input-bytevector #u8(6 7 8 9 10)) 0 3) bv)) (test #u8(1 2 3 6 5) (let ((bv (bytevector 1 2 3 4 5))) (read-bytevector! bv (open-input-bytevector #u8(6 7 8 9 10)) 3 4) bv)) (test #u8(1 2 3) (let ((out (open-output-bytevector))) (write-u8 1 out) (write-u8 2 out) (write-u8 3 out) (get-output-bytevector out))) (test #u8(1 2 3 4 5) (let ((out (open-output-bytevector))) (write-bytevector #u8(1 2 3 4 5) out) (get-output-bytevector out))) (test #u8(3 4 5) (let ((out (open-output-bytevector))) (write-bytevector #u8(1 2 3 4 5) out 2) (get-output-bytevector out))) (test #u8(3 4) (let ((out (open-output-bytevector))) (write-bytevector #u8(1 2 3 4 5) out 2 4) (get-output-bytevector out))) (test #u8() (let ((out (open-output-bytevector))) (flush-output-port out) (get-output-bytevector out))) (test #t (and (member (let ((out (open-output-string)) (x (list 1))) (set-cdr! x x) (write x out) (get-output-string out)) ;; labels not guaranteed to be 0 indexed, spacing may differ '("#0=(1 . #0#)" "#1=(1 . #1#)")) #t)) (test "((1 2 3) (1 2 3))" (let ((out (open-output-string)) (x (list 1 2 3))) (write (list x x) out) (get-output-string out))) (test "((1 2 3) (1 2 3))" (let ((out (open-output-string)) (x (list 1 2 3))) (write-simple (list x x) out) (get-output-string out))) (test #t (and (member (let ((out (open-output-string)) (x (list 1 2 3))) (write-shared (list x x) out) (get-output-string out)) '("(#0=(1 2 3) #0#)" "(#1=(1 2 3) #1#)")) #t)) (test-begin "Read syntax") ;; check reading boolean followed by eof (test #t (read (open-input-string "#t"))) (test #t (read (open-input-string "#true"))) (test #f (read (open-input-string "#f"))) (test #f (read (open-input-string "#false"))) (define (read2 port) (let* ((o1 (read port)) (o2 (read port))) (cons o1 o2))) ;; check reading boolean followed by delimiter (test '(#t . (5)) (read2 (open-input-string "#t(5)"))) (test '(#t . 6) (read2 (open-input-string "#true 6 "))) (test '(#f . 7) (read2 (open-input-string "#f 7"))) (test '(#f . "8") (read2 (open-input-string "#false\"8\""))) (test '() (read (open-input-string "()"))) (test '(1 2) (read (open-input-string "(1 2)"))) (test '(1 . 2) (read (open-input-string "(1 . 2)"))) (test '(1 2) (read (open-input-string "(1 . (2))"))) (test '(1 2 3 4 5) (read (open-input-string "(1 . (2 3 4 . (5)))"))) (test '1 (cadr (read (open-input-string "#0=(1 . #0#)")))) (test '(1 2 3) (cadr (read (open-input-string "(#0=(1 2 3) #0#)")))) (test '(quote (1 2)) (read (open-input-string "'(1 2)"))) (test '(quote (1 (unquote 2))) (read (open-input-string "'(1 ,2)"))) (test '(quote (1 (unquote-splicing 2))) (read (open-input-string "'(1 ,@2)"))) (test '(quasiquote (1 (unquote 2))) (read (open-input-string "`(1 ,2)"))) (test #() (read (open-input-string "#()"))) (test #(a b) (read (open-input-string "#(a b)"))) (test #u8() (read (open-input-string "#u8()"))) (test #u8(0 1) (read (open-input-string "#u8(0 1)"))) (test 'abc (read (open-input-string "abc"))) (test 'abc (read (open-input-string "abc def"))) (test 'ABC (read (open-input-string "ABC"))) (test 'Hello (read (open-input-string "|H\\x65;llo|"))) (test 'abc (read (open-input-string "#!fold-case ABC"))) (test 'ABC (read (open-input-string "#!fold-case #!no-fold-case ABC"))) (test 'def (read (open-input-string "#; abc def"))) (test 'def (read (open-input-string "; abc \ndef"))) (test 'def (read (open-input-string "#| abc |# def"))) (test 'ghi (read (open-input-string "#| abc #| def |# |# ghi"))) (test 'ghi (read (open-input-string "#; ; abc\n def ghi"))) (test '(abs -16) (read (open-input-string "(#;sqrt abs -16)"))) (test '(a d) (read (open-input-string "(a #; #;b c d)"))) (test '(a e) (read (open-input-string "(a #;(b #;c d) e)"))) (test '(a . c) (read (open-input-string "(a . #;b c)"))) (test '(a . b) (read (open-input-string "(a . b #;c)"))) ;; (define (test-read-error str) ;; (test-assert ;; (guard (exn (else #t)) ;; (read (open-input-string str)) ;; #f))) ;; (test-read-error "(#;a . b)") ;; (test-read-error "(a . #;b)") ;; (test-read-error "(a #;. b)") ;; (test-read-error "(#;x #;y . z)") ;; (test-read-error "(#; #;x #;y . z)") ;; (test-read-error "(#; #;x . z)") ;; (test #\a (read (open-input-string "#\\a"))) ;; (test #\space (read (open-input-string "#\\space"))) ;; (test 0 (char->integer (read (open-input-string "#\\null")))) ;; (test 7 (char->integer (read (open-input-string "#\\alarm")))) ;; (test 8 (char->integer (read (open-input-string "#\\backspace")))) ;; (test 9 (char->integer (read (open-input-string "#\\tab")))) ;; (test 10 (char->integer (read (open-input-string "#\\newline")))) ;; (test 13 (char->integer (read (open-input-string "#\\return")))) ;; (test #x7F (char->integer (read (open-input-string "#\\delete")))) ;; (test #x1B (char->integer (read (open-input-string "#\\escape")))) ;; (test #x03BB (char->integer (read (open-input-string "#\\λ")))) ;; (test #x03BB (char->integer (read (open-input-string "#\\x03BB")))) ;; (test "abc" (read (open-input-string "\"abc\""))) ;; (test "abc" (read (open-input-string "\"abc\" \"def\""))) ;; (test "ABC" (read (open-input-string "\"ABC\""))) ;; (test "Hello" (read (open-input-string "\"H\\x65;llo\""))) ;; (test 7 (char->integer (string-ref (read (open-input-string "\"\\a\"")) 0))) ;; (test 8 (char->integer (string-ref (read (open-input-string "\"\\b\"")) 0))) ;; (test 9 (char->integer (string-ref (read (open-input-string "\"\\t\"")) 0))) ;; (test 10 (char->integer (string-ref (read (open-input-string "\"\\n\"")) 0))) ;; (test 13 (char->integer (string-ref (read (open-input-string "\"\\r\"")) 0))) ;; (test #x22 (char->integer (string-ref (read (open-input-string "\"\\\"\"")) 0))) ;; (test #x7C (char->integer (string-ref (read (open-input-string "\"\\|\"")) 0))) ;; (test "line 1\nline 2\n" (read (open-input-string "\"line 1\nline 2\n\""))) ;; (test "line 1continued\n" (read (open-input-string "\"line 1\\\ncontinued\n\""))) ;; (test "line 1continued\n" (read (open-input-string "\"line 1\\ \ncontinued\n\""))) ;; (test "line 1continued\n" (read (open-input-string "\"line 1\\\n continued\n\""))) ;; (test "line 1continued\n" (read (open-input-string "\"line 1\\ \t \n \t continued\n\""))) ;; (test "line 1\n\nline 3\n" (read (open-input-string "\"line 1\\ \t \n \t \n\nline 3\n\""))) ;; (test #x03BB (char->integer (string-ref (read (open-input-string "\"\\x03BB;\"")) 0))) (test-end) (test-begin "Numeric syntax") ;; Numeric syntax adapted from Peter Bex's tests. ;; ;; These are updated to R7RS, using string ports instead of ;; string->number, and "error" tests removed because implementations ;; are free to provide their own numeric extensions. Currently all ;; tests are run by default - need to cond-expand and test for ;; infinities and -0.0. ;; (define-syntax test-numeric-syntax ;; (syntax-rules () ;; ((test-numeric-syntax str expect strs ...) ;; (let* ((z (read (open-input-string str))) ;; (out (open-output-string)) ;; (z-str (begin (write z out) (get-output-string out)))) ;; (test expect (values z)) ;; (test #t (and (member z-str '(str strs ...)) #t)))))) ;; Each test is of the form: ;; ;; (test-numeric-syntax input-str expected-value expected-write-values ...) ;; ;; where the input should be eqv? to the expected-value, and the ;; written output the same as any of the expected-write-values. The ;; form ;; ;; (test-numeric-syntax input-str expected-value) ;; ;; is a shorthand for ;; ;; (test-numeric-syntax input-str expected-value (input-str)) ;; Simple ;; (test-numeric-syntax "1" 1) ;; (test-numeric-syntax "+1" 1 "1") ;; (test-numeric-syntax "-1" -1) ;; (test-numeric-syntax "#i1" 1.0 "1.0" "1.") ;; (test-numeric-syntax "#I1" 1.0 "1.0" "1.") ;; (test-numeric-syntax "#i-1" -1.0 "-1.0" "-1.") ;; ;; Decimal ;; (test-numeric-syntax "1.0" 1.0 "1.0" "1.") ;; (test-numeric-syntax "1." 1.0 "1.0" "1.") ;; (test-numeric-syntax ".1" 0.1 "0.1" "100.0e-3") ;; (test-numeric-syntax "-.1" -0.1 "-0.1" "-100.0e-3") ;; ;; Some Schemes don't allow negative zero. This is okay with the standard ;; (test-numeric-syntax "-.0" -0.0 "-0." "-0.0" "0.0" "0." ".0") ;; (test-numeric-syntax "-0." -0.0 "-.0" "-0.0" "0.0" "0." ".0") ;; (test-numeric-syntax "#i1.0" 1.0 "1.0" "1.") ;; (test-numeric-syntax "#e1.0" 1 "1") ;; (test-numeric-syntax "#e-.0" 0 "0") ;; (test-numeric-syntax "#e-0." 0 "0") ;; ;; Decimal notation with suffix ;; (test-numeric-syntax "1e2" 100.0 "100.0" "100.") ;; (test-numeric-syntax "1E2" 100.0 "100.0" "100.") ;; (test-numeric-syntax "1s2" 100.0 "100.0" "100.") ;; (test-numeric-syntax "1S2" 100.0 "100.0" "100.") ;; (test-numeric-syntax "1f2" 100.0 "100.0" "100.") ;; (test-numeric-syntax "1F2" 100.0 "100.0" "100.") ;; (test-numeric-syntax "1d2" 100.0 "100.0" "100.") ;; (test-numeric-syntax "1D2" 100.0 "100.0" "100.") ;; (test-numeric-syntax "1l2" 100.0 "100.0" "100.") ;; (test-numeric-syntax "1L2" 100.0 "100.0" "100.") ;; ;; NaN, Inf ;; (test-numeric-syntax "+nan.0" +nan.0 "+nan.0" "+NaN.0") ;; (test-numeric-syntax "+NAN.0" +nan.0 "+nan.0" "+NaN.0") ;; (test-numeric-syntax "+inf.0" +inf.0 "+inf.0" "+Inf.0") ;; (test-numeric-syntax "+InF.0" +inf.0 "+inf.0" "+Inf.0") ;; (test-numeric-syntax "-inf.0" -inf.0 "-inf.0" "-Inf.0") ;; (test-numeric-syntax "-iNF.0" -inf.0 "-inf.0" "-Inf.0") ;; (test-numeric-syntax "#i+nan.0" +nan.0 "+nan.0" "+NaN.0") ;; (test-numeric-syntax "#i+inf.0" +inf.0 "+inf.0" "+Inf.0") ;; (test-numeric-syntax "#i-inf.0" -inf.0 "-inf.0" "-Inf.0") ;; ;; Exact ratios ;; (test-numeric-syntax "1/2" (/ 1 2)) ;; (test-numeric-syntax "#e1/2" (/ 1 2) "1/2") ;; (test-numeric-syntax "10/2" 5 "5") ;; (test-numeric-syntax "-1/2" (- (/ 1 2))) ;; (test-numeric-syntax "0/10" 0 "0") ;; (test-numeric-syntax "#e0/10" 0 "0") ;; (test-numeric-syntax "#i3/2" (/ 3.0 2.0) "1.5") ;; ;; Exact complex ;; (test-numeric-syntax "1+2i" (make-rectangular 1 2)) ;; (test-numeric-syntax "1+2I" (make-rectangular 1 2) "1+2i") ;; (test-numeric-syntax "1-2i" (make-rectangular 1 -2)) ;; (test-numeric-syntax "-1+2i" (make-rectangular -1 2)) ;; (test-numeric-syntax "-1-2i" (make-rectangular -1 -2)) ;; (test-numeric-syntax "+i" (make-rectangular 0 1) "+i" "+1i" "0+i" "0+1i") ;; (test-numeric-syntax "0+i" (make-rectangular 0 1) "+i" "+1i" "0+i" "0+1i") ;; (test-numeric-syntax "0+1i" (make-rectangular 0 1) "+i" "+1i" "0+i" "0+1i") ;; (test-numeric-syntax "-i" (make-rectangular 0 -1) "-i" "-1i" "0-i" "0-1i") ;; (test-numeric-syntax "0-i" (make-rectangular 0 -1) "-i" "-1i" "0-i" "0-1i") ;; (test-numeric-syntax "0-1i" (make-rectangular 0 -1) "-i" "-1i" "0-i" "0-1i") ;; (test-numeric-syntax "+2i" (make-rectangular 0 2) "2i" "+2i" "0+2i") ;; (test-numeric-syntax "-2i" (make-rectangular 0 -2) "-2i" "0-2i") ;; ;; Decimal-notation complex numbers (rectangular notation) ;; (test-numeric-syntax "1.0+2i" (make-rectangular 1.0 2) "1.0+2.0i" "1.0+2i" "1.+2i" "1.+2.i") ;; (test-numeric-syntax "1+2.0i" (make-rectangular 1 2.0) "1.0+2.0i" "1+2.0i" "1.+2.i" "1+2.i") ;; (test-numeric-syntax "1e2+1.0i" (make-rectangular 100.0 1.0) "100.0+1.0i" "100.+1.i") ;; (test-numeric-syntax "1s2+1.0i" (make-rectangular 100.0 1.0) "100.0+1.0i" "100.+1.i") ;; (test-numeric-syntax "1.0+1e2i" (make-rectangular 1.0 100.0) "1.0+100.0i" "1.+100.i") ;; (test-numeric-syntax "1.0+1s2i" (make-rectangular 1.0 100.0) "1.0+100.0i" "1.+100.i") ;; ;; Fractional complex numbers (rectangular notation) ;; (test-numeric-syntax "1/2+3/4i" (make-rectangular (/ 1 2) (/ 3 4))) ;; ;; Mixed fractional/decimal notation complex numbers (rectangular notation) ;; (test-numeric-syntax "0.5+3/4i" (make-rectangular 0.5 (/ 3 4)) ;; "0.5+0.75i" ".5+.75i" "0.5+3/4i" ".5+3/4i" "500.0e-3+750.0e-3i") ;; ;; Complex NaN, Inf (rectangular notation) ;; ;;(test-numeric-syntax "+nan.0+nan.0i" (make-rectangular the-nan the-nan) "+NaN.0+NaN.0i") ;; (test-numeric-syntax "+inf.0+inf.0i" (make-rectangular +inf.0 +inf.0) "+Inf.0+Inf.0i") ;; (test-numeric-syntax "-inf.0+inf.0i" (make-rectangular -inf.0 +inf.0) "-Inf.0+Inf.0i") ;; (test-numeric-syntax "-inf.0-inf.0i" (make-rectangular -inf.0 -inf.0) "-Inf.0-Inf.0i") ;; (test-numeric-syntax "+inf.0-inf.0i" (make-rectangular +inf.0 -inf.0) "+Inf.0-Inf.0i") ;; ;; Complex numbers (polar notation) ;; ;; Need to account for imprecision in write output. ;; ;;(test-numeric-syntax "1@2" -0.416146836547142+0.909297426825682i "-0.416146836547142+0.909297426825682i") ;; ;; Base prefixes ;; (test-numeric-syntax "#x11" 17 "17") ;; (test-numeric-syntax "#X11" 17 "17") ;; (test-numeric-syntax "#d11" 11 "11") ;; (test-numeric-syntax "#D11" 11 "11") ;; (test-numeric-syntax "#o11" 9 "9") ;; (test-numeric-syntax "#O11" 9 "9") ;; (test-numeric-syntax "#b11" 3 "3") ;; (test-numeric-syntax "#B11" 3 "3") ;; (test-numeric-syntax "#o7" 7 "7") ;; (test-numeric-syntax "#xa" 10 "10") ;; (test-numeric-syntax "#xA" 10 "10") ;; (test-numeric-syntax "#xf" 15 "15") ;; (test-numeric-syntax "#x-10" -16 "-16") ;; (test-numeric-syntax "#d-10" -10 "-10") ;; (test-numeric-syntax "#o-10" -8 "-8") ;; (test-numeric-syntax "#b-10" -2 "-2") ;; ;; Combination of prefixes ;; (test-numeric-syntax "#e#x10" 16 "16") ;; (test-numeric-syntax "#i#x10" 16.0 "16.0" "16.") ;; ;; (Attempted) decimal notation with base prefixes ;; (test-numeric-syntax "#d1." 1.0 "1.0" "1.") ;; (test-numeric-syntax "#d.1" 0.1 "0.1" ".1" "100.0e-3") ;; (test-numeric-syntax "#x1e2" 482 "482") ;; (test-numeric-syntax "#d1e2" 100.0 "100.0" "100.") ;; ;; Fractions with prefixes ;; (test-numeric-syntax "#x10/2" 8 "8") ;; (test-numeric-syntax "#x11/2" (/ 17 2) "17/2") ;; (test-numeric-syntax "#d11/2" (/ 11 2) "11/2") ;; (test-numeric-syntax "#o11/2" (/ 9 2) "9/2") ;; (test-numeric-syntax "#b11/10" (/ 3 2) "3/2") ;; ;; Complex numbers with prefixes ;; ;;(test-numeric-syntax "#x10+11i" (make-rectangular 16 17) "16+17i") ;; (test-numeric-syntax "#d1.0+1.0i" (make-rectangular 1.0 1.0) "1.0+1.0i" "1.+1.i") ;; (test-numeric-syntax "#d10+11i" (make-rectangular 10 11) "10+11i") ;; ;;(test-numeric-syntax "#o10+11i" (make-rectangular 8 9) "8+9i") ;; ;;(test-numeric-syntax "#b10+11i" (make-rectangular 2 3) "2+3i") ;; ;;(test-numeric-syntax "#e1.0+1.0i" (make-rectangular 1 1) "1+1i" "1+i") ;; ;;(test-numeric-syntax "#i1.0+1.0i" (make-rectangular 1.0 1.0) "1.0+1.0i" "1.+1.i") (test-end) (test-end) (test-begin "6.14 System interface") ;; 6.14 System interface ;; (test "/usr/local/bin:/usr/bin:/bin" (get-environment-variable "PATH")) (test #t (string? (get-environment-variable "PATH"))) ;; (test '(("USER" . "root") ("HOME" . "/")) (get-environment-variables)) (let ((env (get-environment-variables))) (define (env-pair? x) (and (pair? x) (string? (car x)) (string? (cdr x)))) (define (all? pred ls) (or (null? ls) (and (pred (car ls)) (all? pred (cdr ls))))) (test #t (list? env)) (test #t (all? env-pair? env))) (test #t (list? (command-line))) (test #t (real? (current-second))) (test #t (inexact? (current-second))) (test #t (exact? (current-jiffy))) (test #t (exact? (jiffies-per-second))) (test #t (list? (features))) (test #t (and (memq 'r7rs (features)) #t)) (test #t (file-exists? ".")) (test #f (file-exists? " no such file ")) ;; (test #t (file-error? ;; (guard (exn (else exn)) ;; (delete-file " no such file ")))) (test-end) (test-end)