(load-relative "loadtest.ss") (Section 'basic) ;; ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; (test '() 'null null) (test '() 'null ()) (let ([f (lambda () #&7)]) (test #t eq? (f) (f))) ;; test that all symbol characters are supported. '(+ - ... !.. $.+ %.- &.! *.: /:. :+. <-. =. >. ?. ~. _. ^.) (define disjoint-type-functions (list boolean? char? null? number? pair? procedure? string? symbol? vector?)) (define type-examples (list #t #f #\a '() 9739 '(test) record-error "test" "" 'test '#() '#(a b c) )) (define i 1) (for-each (lambda (x) (display (make-string i #\ )) (set! i (+ 3 i)) (write x) (newline)) disjoint-type-functions) (define type-matrix (map (lambda (x) (let ((t (map (lambda (f) (f x)) disjoint-type-functions))) (write t) (write x) (newline) t)) type-examples)) (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) (arity-test not 1 1) (test #t boolean? #f) (test #t boolean? #t) (test #f boolean? 0) (test #f boolean? '()) (arity-test boolean? 1 1) (test #t eqv? 'a 'a) (test #f eqv? 'a 'b) (test #t eqv? 2 2) (test #f eqv? 2 2.0) (test #t eqv? '() '()) (test #t eqv? '10000 '10000) (test #t eqv? 10000000000000000000 10000000000000000000) (test #f eqv? 10000000000000000000 10000000000000000001) (test #f eqv? 10000000000000000000 20000000000000000000) (test #f eqv? (cons 1 2) (cons 1 2)) (test #f eqv? (lambda () 1) (lambda () 2)) (test #f eqv? #f 'nil) (let ((p (lambda (x) x))) (test #t eqv? p p)) (define gen-counter (lambda () (let ((n 0)) (lambda () (set! n (+ n 1)) n)))) (let ((g (gen-counter))) (test #t eqv? g g)) (test #f eqv? (gen-counter) (gen-counter)) (letrec ((f (lambda () (if (eqv? f g) 'f 'both))) (g (lambda () (if (eqv? f g) 'g 'both)))) (test #f eqv? f g)) (test #t eq? 'a 'a) (test #f eq? (list 'a) (list 'a)) (test #t eq? '() '()) (test #t eq? car car) (let ((x '(a))) (test #t eq? x x)) (let ((x '#())) (test #t eq? x x)) (let ((x (lambda (x) x))) (test #t eq? x x)) (test #t equal? 'a 'a) (test #t equal? '("a") '("a")) (test #t equal? '(a) '(a)) (test #t equal? '(a (b) c) '(a (b) c)) (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 #t equal? (box "a") (box "a")) (test #f equal? "" (string #\null)) (test #f equal? 'a "a") (test #f equal? 'a 'b) (test #f equal? '(a) '(b)) (test #f equal? '(a (b) d) '(a (b) c)) (test #f equal? '(a (b) c) '(d (b) c)) (test #f equal? '(a (b) c) '(a (d) c)) (test #f equal? "abc" "abcd") (test #f equal? "abcd" "abc") (test #f equal? 2 3) (test #f equal? 2.0 2) (test #f equal? (make-vector 5 'b) (make-vector 5 'a)) (test #f equal? (box "a") (box "b")) (arity-test eq? 2 2) (arity-test eqv? 2 2) (arity-test equal? 2 2) (test '(a b c d e) 'dot '(a . (b . (c . (d . (e . ())))))) (define x (list 'a 'b 'c)) (define y x) (and list? (test #t list? y)) (set-cdr! x 4) (test '(a . 4) 'set-cdr! x) (test #t eqv? x y) (test '(a b c . d) 'dot '(a . (b . (c . d)))) (test #f list? y) (let ((x (list 'a))) (set-cdr! x x) (test #f list? x)) (arity-test list? 1 1) (test #t pair? '(a . b)) (test #t pair? '(a . 1)) (test #t pair? '(a b c)) (test #f pair? '()) (test #f pair? '#(a b)) (arity-test pair? 1 1) (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) (arity-test cons 2 2) (test 'a car '(a b c)) (test '(a) car '((a) b c d)) (test 1 car '(1 . 2)) (arity-test car 1 1) (err/rt-test (car 1)) (test '(b c d) cdr '((a) b c d)) (test 2 cdr '(1 . 2)) (arity-test cdr 1 1) (err/rt-test (cdr 1)) (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 '()) (arity-test length 1 1) (err/rt-test (length 1)) (err/rt-test (length '(1 . 2))) (err/rt-test (length "a")) ; (err/rt-test (length (quote #0=(1 . #0#)))) (err/rt-test (let ([p (cons 1 1)]) (set-cdr! p p) (length p))) (define x (cons 4 0)) (set-cdr! x x) (err/rt-test (length x)) (define l '(1 2 3)) (set-cdr! l 5) (test '(1 . 5) 'set-cdr! l) (set-car! l 0) (test '(0 . 5) 'set-car! l) (arity-test set-car! 2 2) (arity-test set-cdr! 2 2) (err/rt-test (set-car! 4 4)) (err/rt-test (set-cdr! 4 4)) (define (box-tests box unbox box? set-box! set-box!-name unbox-name) (define b (box 5)) (test 5 unbox b) (when set-box! (set-box! b 6) (test 6 unbox b)) (test #t box? b) (test #f box? 5) (arity-test box 1 1) (arity-test unbox 1 1) (arity-test box? 1 1) (when set-box! (arity-test set-box! 2 2)) (err/rt-test (unbox 8)) (when set-box! (err/rt-test (set-box! 8 8)))) (box-tests box unbox box? set-box! 'set-box! 'unbox) (box-tests make-weak-box weak-box-value weak-box? #f #f 'weak-box-value) (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 '() append) (test '(a b c . d) append '(a b) '(c . d)) (test 'a append '() 'a) (test 1 append 1) (test '(1 . 2) append '(1) 2) (test '(1 . 2) append '(1) 2) (err/rt-test (append '(1 2 . 3) 1)) (err/rt-test (append '(1 2 3) 1 '(4 5 6))) (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 '() append!) (test '(a b c . d) append! '(a b) '(c . d)) (test 'a append! '() 'a) (test 1 append! 1) (err/rt-test (append! '(1 2 . 3) 1)) (err/rt-test (append! '(1 2 3) 1 '(4 5 6))) (err/rt-test (append! (cons-immutable 1 null) '(4 5 6))) (define l '(1 2)) (define l2 '(3 4 . 7)) (define l3 (append l l2)) (test '(1 2 3 4 . 7) 'append l3) (set-car! l2 5) (test '(1 2 5 4 . 7) 'append l3) (set-car! l3 0) (test '(0 2 5 4 . 7) 'append l3) (test '(1 2) 'append l) (let* ([l '(1 2)] [l2 '(3 4 . 7)] [l3 (append! l l2)]) (test '(1 2 3 4 . 7) 'append! l3) (set-car! l2 5) (test '(1 2 5 4 . 7) 'append! l3) (set-car! l3 0) (test '(0 2 5 4 . 7) 'append! l3) (test '(0 2 5 4 . 7) 'append! l)) (test '(c b a) reverse '(a b c)) (test '((e (f)) d (b c) a) reverse '(a (b c) d (e (f)))) (arity-test reverse 1 1) (err/rt-test (reverse 1)) (err/rt-test (reverse '(1 . 1))) (define l '(a b c)) (test '(c b a) reverse! l) (test '(a) 'reverse! l) (test '((e (f)) d (b c) a) reverse! '(a (b c) d (e (f)))) (arity-test reverse! 1 1) (err/rt-test (reverse! 1)) (err/rt-test (reverse! '(1 . 1))) (test 'c list-ref '(a b c d) 2) (test 'c list-ref '(a b c . d) 2) (arity-test list-ref 2 2) (err/rt-test (list-ref 1 1) exn:application:mismatch?) (err/rt-test (list-ref '(a b . c) 2) exn:application:mismatch?) (err/rt-test (list-ref '(1 2 3) 2.0)) (err/rt-test (list-ref '(1) '(1))) (err/rt-test (list-ref '(1) 1) exn:application:mismatch?) (err/rt-test (list-ref '() 0) exn:application:mismatch?) (err/rt-test (list-ref '() 0) exn:application:mismatch?) (err/rt-test (list-ref '(1) -1)) (err/rt-test (list-ref '(1) 2000000000000) exn:application:mismatch?) (test '(c d) list-tail '(a b c d) 2) (test '(a b c d) list-tail '(a b c d) 0) (test '(b c . d) list-tail '(a b c . d) 1) (test 1 list-tail 1 0) (arity-test list-tail 2 2) (err/rt-test (list-tail 1 1) exn:application:mismatch?) (err/rt-test (list-tail '(1 2 3) 2.0)) (err/rt-test (list-tail '(1) '(1))) (err/rt-test (list-tail '(1) -1)) (err/rt-test (list-tail '(1) 2) exn:application:mismatch?) (err/rt-test (list-tail '(1 2 . 3) 3) exn:application:mismatch?) (define (test-mem memq memq-name) (test '(a b c) memq 'a '(a b c)) (test '(b c) memq 'b '(a b c)) (test '(b . c) memq 'b '(a b . c)) (test '#f memq 'a '(b c d)) (arity-test memq 2 2) (err/rt-test (memq 'a 1) exn:application:mismatch?) (err/rt-test (memq 'a '(1 . 2)) exn:application:mismatch?)) (test-mem memq 'memq) (test-mem memv 'memv) (test-mem member 'member) (test #f memq "apple" '("apple")) (test #f memv "apple" '("apple")) (test '("apple") member "apple" '("apple")) ; (test #f memq 1/2 '(1/2)) ; rationals are immutable and we may want to optimize (test '(1/2) memv 1/2 '(1/2)) (test '(1/2) member 1/2 '(1/2)) (test '((1 2)) member '(1 2) '(1 2 (1 2))) (define (test-ass assq assq-name) (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 '(a 1) assq 'a '((x 0) (a 1) b 2)) (test '(a 1) assq 'a '((x 0) (a 1) . 0)) (arity-test assq 2 2) (err/rt-test (assq 1 1) exn:application:mismatch?) (err/rt-test (assq 1 '(1 2)) exn:application:mismatch?) (err/rt-test (assq 1 '((0) . 2)) exn:application:mismatch?)) (test-ass assq 'assq) (test-ass assv 'assv) (test-ass assoc 'assoc) (test #f assq '(a) '(((a)) ((b)) ((c)))) (test #f assv '(a) '(((a)) ((b)) ((c)))) (test '((b) 1) assoc '(b) '(((a)) ((b) 1) ((c)))) ; (test #f assq '1/2 '(((a)) (1/2) ((c)))) ; rationals are immutable and we may want to optimize (test '(1/2) assv '1/2 '(((a)) (1/2) ((c)))) (test '(1/2) assoc '1/2 '(((a)) (1/2) ((c)))) (test #f immutable? (cons 1 null)) (test #f immutable? (list 1)) (test #f immutable? (list 1 2)) (test #f immutable? (list* 1 null)) (test #f immutable? (list* 1 2 null)) (test #f immutable? 1) (test #f immutable? #(1 2 3)) (test #f immutable? #()) (test #f immutable? (string-copy "hi")) (test #t immutable? (cons-immutable 1 null)) (test #t immutable? (list-immutable 1)) (test #t immutable? (list-immutable 1 2)) (test #t immutable? (list*-immutable 1 null)) (test #t immutable? (list*-immutable 1 2 null)) (test #t immutable? "hi") (test #t immutable? (string->immutable-string "hi")) (test #t immutable? (string->immutable-string (string-copy "hi"))) (test #t immutable? (make-immutable-hash-table null)) (test #t immutable? (make-immutable-hash-table '((a . b)))) (test #t immutable? (make-immutable-hash-table '((a . b)) 'equal)) (test #f immutable? (make-hash-table)) (test #f immutable? (make-hash-table 'equal)) (test #f immutable? (make-hash-table 'weak)) (test #f immutable? (make-hash-table 'weak 'equal)) (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) ;;; But first, what case are symbols in? Determine the standard case: #ci(parameterize ([read-case-sensitive #f]) (define char-standard-case char-upcase) (if (string=? (symbol->string 'A) "a") (set! char-standard-case char-downcase)) (test #t 'standard-case (string=? (symbol->string 'a) (symbol->string 'A))) (test #t 'standard-case (or (string=? (symbol->string 'a) "A") (string=? (symbol->string 'A) "a"))) (let () (define (str-copy s) (let ((v (make-string (string-length s)))) (do ((i (- (string-length v) 1) (- i 1))) ((< i 0) v) (string-set! v i (string-ref s i))))) (define (string-standard-case s) (set! s (str-copy s)) (do ((i 0 (+ 1 i)) (sl (string-length s))) ((>= i sl) s) (string-set! s i (char-standard-case (string-ref s i))))) (test (string-standard-case "flying-fish") symbol->string 'flying-fish) (test (string-standard-case "martin") symbol->string 'Martin) (test "Malvina" symbol->string (string->symbol "Malvina")) (test #t 'standard-case (eq? 'a 'A)))) (define x (string #\a #\b)) (define y (string->symbol x)) (string-set! x 0 #\c) (test "cb" 'string-set! x) (test "ab" symbol->string y) (test y string->symbol "ab") #ci(test #t eq? 'mISSISSIppi 'mississippi) #ci(test #f 'string->symbol (eq? 'bitBlt (string->symbol "bitBlt"))) #cs(test #t 'string->symbol (eq? 'bitBlt (string->symbol "bitBlt"))) (test 'JollyWog string->symbol (symbol->string 'JollyWog)) #ci(test 'JollyWog string->symbol (symbol->string 'JollyWog)) (arity-test symbol? 1 1) (define (char-tests) (test #t eqv? '#\ #\Space) (test #t eqv? #\space '#\Space) (test #t char? #\a) (test #t char? #\() (test #t char? #\ ) (test #t char? '#\newline) (arity-test char? 1 1) (test #f char=? #\A #\B) (test #f char=? #\A #\A #\B) (test #f char=? #\A #\B #\A) (test #f char=? #\a #\b) (test #f char=? #\9 #\0) (test #t char=? #\A #\A) (test #t char=? #\A #\A #\A) (test #t char=? #\370 #\370) (test #f char=? #\371 #\370) (test #f char=? #\370 #\371) (arity-test char=? 2 -1) (err/rt-test (char=? #\a 1)) (err/rt-test (char=? #\a #\b 1)) (err/rt-test (char=? 1 #\a)) (test #t char? #\A #\B) (test #t char>? #\B #\A) (test #f char>? #\A #\B #\C) (test #f char>? #\B #\A #\C) (test #t char>? #\C #\B #\A) (test #f char>? #\a #\b) (test #t char>? #\9 #\0) (test #f char>? #\A #\A) (test #f char>? #\370 #\370) (test #t char>? #\371 #\370) (test #f char>? #\370 #\371) (arity-test char>? 2 -1) (err/rt-test (char>? #\a 1)) (err/rt-test (char>? #\a #\a 1)) (err/rt-test (char>? 1 #\a)) (test #t char<=? #\A #\B) (test #t char<=? #\A #\B #\C) (test #t char<=? #\A #\A #\C) (test #f char<=? #\A #\B #\A) (test #f char<=? #\B #\A #\C) (test #t char<=? #\a #\b) (test #f char<=? #\9 #\0) (test #t char<=? #\A #\A) (test #t char<=? #\370 #\370) (test #f char<=? #\371 #\370) (test #t char<=? #\370 #\371) (arity-test char<=? 2 -1) (err/rt-test (char<=? #\a 1)) (err/rt-test (char<=? #\b #\a 1)) (err/rt-test (char<=? 1 #\a)) (test #f char>=? #\A #\B) (test #f char>=? #\a #\b) (test #t char>=? #\9 #\0) (test #t char>=? #\A #\A) (test #t char>=? #\370 #\370) (test #t char>=? #\371 #\370) (test #f char>=? #\370 #\371) (arity-test char>=? 2 -1) (err/rt-test (char>=? #\a 1)) (err/rt-test (char>=? #\a #\b 1)) (err/rt-test (char>=? 1 #\a)) (test #f char-ci=? #\A #\B) (test #f char-ci=? #\A #\A #\B) (test #f char-ci=? #\a #\B) (test #f char-ci=? #\A #\b) (test #f char-ci=? #\a #\b) (test #f char-ci=? #\9 #\0) (test #t char-ci=? #\A #\A) (test #t char-ci=? #\A #\a) (test #t char-ci=? #\A #\a #\A) (test #t char-ci=? #\370 #\370) (test #f char-ci=? #\371 #\370) (test #f char-ci=? #\370 #\371) (arity-test char-ci=? 2 -1) (err/rt-test (char-ci=? #\a 1)) (err/rt-test (char-ci=? #\a #\b 1)) (err/rt-test (char-ci=? 1 #\a)) (test #t char-ci? #\A #\B) (test #f char-ci>? #\B #\A #\C) (test #t char-ci>? #\C #\B #\A) (test #f char-ci>? #\a #\B) (test #f char-ci>? #\A #\b) (test #f char-ci>? #\a #\b) (test #t char-ci>? #\C #\b #\A) (test #t char-ci>? #\9 #\0) (test #f char-ci>? #\A #\A) (test #f char-ci>? #\A #\a) (test #f char-ci>? #\370 #\370) (test #t char-ci>? #\371 #\370) (test #f char-ci>? #\370 #\371) (arity-test char-ci>? 2 -1) (err/rt-test (char-ci>? #\a 1)) (err/rt-test (char-ci>? #\a #\b 1)) (err/rt-test (char-ci>? 1 #\a)) (test #t char-ci<=? #\A #\B) (test #t char-ci<=? #\a #\B) (test #t char-ci<=? #\a #\B #\C) (test #f char-ci<=? #\a #\b #\A) (test #t char-ci<=? #\A #\b) (test #t char-ci<=? #\a #\b) (test #f char-ci<=? #\9 #\0) (test #t char-ci<=? #\A #\A) (test #t char-ci<=? #\A #\a) (test #t char-ci<=? #\370 #\370) (test #f char-ci<=? #\371 #\370) (test #t char-ci<=? #\370 #\371) (arity-test char-ci<=? 2 -1) (err/rt-test (char-ci<=? #\a 1)) (err/rt-test (char-ci<=? #\b #\a 1)) (err/rt-test (char-ci<=? 1 #\a)) (test #f char-ci>=? #\A #\B) (test #f char-ci>=? #\B #\A #\C) (test #t char-ci>=? #\B #\B #\A) (test #f char-ci>=? #\a #\B) (test #f char-ci>=? #\A #\b) (test #f char-ci>=? #\a #\b) (test #t char-ci>=? #\9 #\0) (test #t char-ci>=? #\A #\A) (test #t char-ci>=? #\A #\a) (test #t char-ci>=? #\370 #\370) (test #t char-ci>=? #\371 #\370) (test #f char-ci>=? #\370 #\371) (arity-test char-ci>=? 2 -1) (err/rt-test (char-ci>=? #\a 1)) (err/rt-test (char-ci>=? #\a #\b 1)) (err/rt-test (char-ci>=? 1 #\a))) (char-tests) (define (ascii-range start end) (let ([s (or (and (number? start) start) (char->integer start))] [e (or (and (number? end) end) (char->integer end))]) (let loop ([n e][l (list (integer->char e))]) (if (= n s) l (let ([n (sub1 n)]) (loop n (cons (integer->char n) l))))))) (define uppers (ascii-range #\A #\Z)) (define lowers (ascii-range #\a #\z)) (define alphas (append uppers lowers)) (define digits (ascii-range #\0 #\9)) (define whites (list #\newline #\return #\space #\page #\tab #\vtab)) (define (test-all is-a? name members) (let loop ([n 0]) (unless (= n 128) (let ([c (integer->char n)]) (test (and (memq c members) #t) `(,is-a? (integer->char ,n)) (is-a? c)) (loop (add1 n))))) (arity-test is-a? 1 1) (err/rt-test (is-a? 1))) (test-all char-alphabetic? 'char-alphabetic? alphas) (test-all char-numeric? 'char-numeric? digits) (test-all char-whitespace? 'char-whitespace? whites) (test-all char-upper-case? 'char-upper-case? uppers) (test-all char-lower-case? 'char-lower-case? lowers) (let loop ([n 0]) (unless (= n 512) (test n 'integer->char (char->integer (integer->char n))) (loop (add1 n)))) (test 0 char->integer #\nul) (test 10 char->integer #\newline) (test 13 char->integer #\return) (test 9 char->integer #\tab) (test 8 char->integer #\backspace) (test 12 char->integer #\page) (test 32 char->integer #\space) (test 127 char->integer #\rubout) (test #\null 'null #\nul) (test #\newline 'linefeed #\linefeed) (test #\. integer->char (char->integer #\.)) (test #\A integer->char (char->integer #\A)) (test #\a integer->char (char->integer #\a)) (test #\371 integer->char (char->integer #\371)) (test #\U12345 integer->char (char->integer #\U12345)) (arity-test integer->char 1 1) (arity-test char->integer 1 1) (err/rt-test (integer->char 5.0)) (err/rt-test (integer->char 'a)) (err/rt-test (integer->char -1)) (err/rt-test (integer->char (expt 2 32))) (err/rt-test (integer->char 10000000000000000)) (err/rt-test (char->integer 5)) (define (test-up/down case case-name members memassoc) (let loop ([n 0]) (unless (= n 128) (let ([c (integer->char n)]) (if (memq c members) (test (cdr (assq c memassoc)) case c) (test c case c))) (loop (add1 n)))) (arity-test case 1 1) (err/rt-test (case 2))) (test-up/down char-upcase 'char-upcase lowers (map cons lowers uppers)) (test-up/down char-downcase 'char-downcase uppers (map cons uppers lowers)) (test #t string? "The word \"recursion\\\" has many meanings.") (test #t string? "") (arity-test string? 1 1) (test 3 'make-string (string-length (make-string 3))) (test "" make-string 0) (arity-test make-string 1 2) (err/rt-test (make-string "hello")) (err/rt-test (make-string 5 "hello")) (err/rt-test (make-string 5.0 #\b)) (err/rt-test (make-string 5.2 #\a)) (err/rt-test (make-string -5 #\f)) (define 64-bit-machine? (eq? (expt 2 40) (eq-hash-code (expt 2 40)))) (unless 64-bit-machine? (err/rt-test (make-string 500000000000000 #\f) exn:fail:out-of-memory?)) ;; bignum on 32-bit machines (err/rt-test (make-string 50000000000000000000 #\f) exn:fail:out-of-memory?) ;; bignum on 64-bit machines (define f (make-string 3 #\*)) (test "?**" 'string-set! (begin (string-set! f 0 #\?) f)) (arity-test string-set! 3 3) (err/rt-test (string-set! "hello" 0 #\a)) ; immutable string constant (define hello-string (string-copy "hello")) (err/rt-test (string-set! hello-string 'a #\a)) (err/rt-test (string-set! 'hello 4 #\a)) (err/rt-test (string-set! hello-string 4 'a)) (err/rt-test (string-set! hello-string 4.0 'a)) (err/rt-test (string-set! hello-string 5 #\a) exn:application:mismatch?) (err/rt-test (string-set! hello-string -1 #\a)) (err/rt-test (string-set! hello-string (expt 2 100) #\a) exn:application:mismatch?) (test "abc" string #\a #\b #\c) (test "" string) (err/rt-test (string #\a 1)) (err/rt-test (string 1 #\a)) (err/rt-test (string 1)) (test 3 string-length "abc") (test 0 string-length "") (arity-test string-length 1 1) (err/rt-test (string-length 'apple)) (test #\a string-ref "abc" 0) (test #\c string-ref "abc" 2) (arity-test string-ref 2 2) (err/rt-test (string-ref 'apple 4)) (err/rt-test (string-ref "apple" 4.0)) (err/rt-test (string-ref "apple" '(4))) (err/rt-test (string-ref "apple" 5) exn:application:mismatch?) (err/rt-test (string-ref "" 0) exn:application:mismatch?) (err/rt-test (string-ref "" (expt 2 100)) exn:application:mismatch?) (err/rt-test (string-ref "apple" -1)) (test "" substring "ab" 0 0) (test "" substring "ab" 1 1) (test "" substring "ab" 2 2) (test "a" substring "ab" 0 1) (test "b" substring "ab" 1 2) (test "ab" substring "ab" 0 2) (test "ab" substring "ab" 0) (test "b" substring "ab" 1) (test "" substring "ab" 2) (test (string #\a #\nul #\b) substring (string #\- #\a #\nul #\b #\*) 1 4) (arity-test substring 2 3) (err/rt-test (substring 'hello 2 3)) (err/rt-test (substring "hello" "2" 3)) (err/rt-test (substring "hello" 2.0 3)) (err/rt-test (substring "hello" 2 3.0)) (err/rt-test (substring "hello" 2 "3")) (err/rt-test (substring "hello" 2 7) exn:application:mismatch?) (err/rt-test (substring "hello" -2 3)) (err/rt-test (substring "hello" 4 3) exn:application:mismatch?) (err/rt-test (substring "hello" (expt 2 100) 3) exn:application:mismatch?) (err/rt-test (substring "hello" (expt 2 100) 5) exn:application:mismatch?) (err/rt-test (substring "hello" 3 (expt 2 100)) exn:application:mismatch?) (test "foobar" string-append "foo" "bar") (test "foo" string-append "foo") (test "foo" string-append "foo" "") (test "foogoo" string-append "foo" "" "goo") (test "foo" string-append "" "foo") (test "" string-append) (test (string #\a #\nul #\b #\c #\nul #\d) string-append (string #\a #\nul #\b) (string #\c #\nul #\d)) (err/rt-test (string-append 1)) (err/rt-test (string-append "hello" 1)) (err/rt-test (string-append "hello" 1 "done")) (test "" make-string 0) (define s (string-copy "hello")) (define s2 (string-copy s)) (test "hello" 'string-copy s2) (string-set! s 2 #\x) (test "hello" 'string-copy s2) (test (string #\a #\nul #\b) string-copy (string #\a #\nul #\b)) (string-fill! s #\x) (test "xxxxx" 'string-fill! s) (arity-test string-copy 1 1) (arity-test string-fill! 2 2) (err/rt-test (string-copy 'blah)) (err/rt-test (string-fill! 'sym #\1)) (err/rt-test (string-fill! "static" #\1)) (err/rt-test (string-fill! (string-copy "oops") 5)) (let ([s (make-string 10 #\x)]) (test (void) string-copy! s 0 "hello") (test "helloxxxxx" values s) (test (void) string-copy! s 3 "hello") (test "helhelloxx" values s) (err/rt-test (string-copy! s 6 "hello") exn:application:mismatch?) (test (void) string-copy! s 5 "hello" 3) (test "helhelooxx" values s) (test (void) string-copy! s 5 "hello" 3) (test "helhelooxx" values s) (test (void) string-copy! s 0 "hello" 3 4) (test "lelhelooxx" values s) (test (void) string-copy! s 1 "hello" 3 5) (test "llohelooxx" values s) (err/rt-test (string-copy! s 1 "hello" 3 6) exn:application:mismatch?)) (arity-test string-copy! 3 5) (let ([s (string-copy x)]) (err/rt-test (string-copy! "x" 0 "x")) (err/rt-test (string-copy! s "x" "x")) (err/rt-test (string-copy! 0 0 "x")) (err/rt-test (string-copy! s 0 "x" -1)) (err/rt-test (string-copy! s 0 "x" 1 0) exn:application:mismatch?) (err/rt-test (string-copy! s 2 "x" 0 1) exn:application:mismatch?)) (test "Hello, and how are you?" string->immutable-string "Hello, and how are you?") (arity-test string->immutable-string 1 1) (err/rt-test (string->immutable-string 'hello)) (define ax (string #\a #\nul #\370 #\x)) (define abigx (string #\a #\nul #\370 #\X)) (define ax2 (string #\a #\nul #\370 #\x)) (define ay (string #\a #\nul #\371 #\x)) (define (string-tests) (test #t string=? "" "") (test #f string? "" "") (test #t string<=? "" "") (test #t string>=? "" "") (test #t string-ci=? "" "") (test #f string-ci? "" "") (test #t string-ci<=? "" "") (test #t string-ci>=? "" "") (test #f string=? "A" "B") (test #f string=? "a" "b") (test #f string=? "9" "0") (test #t string=? "A" "A") (test #f string=? "A" "AB") (test #t string=? ax ax2) (test #f string=? ax abigx) (test #f string=? ax ay) (test #f string=? ay ax) (test #t string? "A" "B") (test #f string>? "a" "b") (test #t string>? "9" "0") (test #f string>? "A" "A") (test #f string>? "A" "AB") (test #t string>? "AB" "A") (test #f string>? ax ax2) (test #f string>? ax ay) (test #t string>? ay ax) (test #t string<=? "A" "B") (test #t string<=? "a" "b") (test #f string<=? "9" "0") (test #t string<=? "A" "A") (test #t string<=? "A" "AB") (test #f string<=? "AB" "A") (test #t string<=? ax ax2) (test #t string<=? ax ay) (test #f string<=? ay ax) (test #f string>=? "A" "B") (test #f string>=? "a" "b") (test #t string>=? "9" "0") (test #t string>=? "A" "A") (test #f string>=? "A" "AB") (test #t string>=? "AB" "A") (test #t string>=? ax ax2) (test #f string>=? ax ay) (test #t string>=? ay ax) (test #f string-ci=? "A" "B") (test #f string-ci=? "a" "B") (test #f string-ci=? "A" "b") (test #f string-ci=? "a" "b") (test #f string-ci=? "9" "0") (test #t string-ci=? "A" "A") (test #t string-ci=? "A" "a") (test #f string-ci=? "A" "AB") (test #t string-ci=? ax ax2) (test #t string-ci=? ax abigx) (test #f string-ci=? ax ay) (test #f string-ci=? ay ax) (test #f string-ci=? abigx ay) (test #f string-ci=? ay abigx) (test #t string-ci? "A" "B") (test #f string-ci>? "a" "B") (test #f string-ci>? "A" "b") (test #f string-ci>? "a" "b") (test #t string-ci>? "9" "0") (test #f string-ci>? "A" "A") (test #f string-ci>? "A" "a") (test #f string-ci>? "A" "AB") (test #t string-ci>? "AB" "A") (test #f string-ci>? ax ax2) (test #f string-ci>? ax abigx) (test #f string-ci>? ax ay) (test #t string-ci>? ay ax) (test #f string-ci>? abigx ay) (test #t string-ci>? ay abigx) (test #t string-ci<=? "A" "B") (test #t string-ci<=? "a" "B") (test #t string-ci<=? "A" "b") (test #t string-ci<=? "a" "b") (test #f string-ci<=? "9" "0") (test #t string-ci<=? "A" "A") (test #t string-ci<=? "A" "a") (test #t string-ci<=? "A" "AB") (test #f string-ci<=? "AB" "A") (test #t string-ci<=? ax ax2) (test #t string-ci<=? ax abigx) (test #t string-ci<=? ax ay) (test #f string-ci<=? ay ax) (test #t string-ci<=? abigx ay) (test #f string-ci<=? ay abigx) (test #f string-ci>=? "A" "B") (test #f string-ci>=? "a" "B") (test #f string-ci>=? "A" "b") (test #f string-ci>=? "a" "b") (test #t string-ci>=? "9" "0") (test #t string-ci>=? "A" "A") (test #t string-ci>=? "A" "a") (test #f string-ci>=? "A" "AB") (test #t string-ci>=? "AB" "A") (test #t string-ci>=? ax ax2) (test #t string-ci>=? ax abigx) (test #f string-ci>=? ax ay) (test #t string-ci>=? ay ax) (test #f string-ci>=? abigx ay) (test #t string-ci>=? ay abigx)) (string-tests) (map (lambda (pred) (arity-test pred 2 -1) (err/rt-test (pred "a" 1)) (err/rt-test (pred "a" "b" 5)) (err/rt-test (pred 1 "a"))) (list string=? string>? string=? string<=? string-ci=? string-ci>? string-ci=? string-ci<=? string-locale=? string-locale>? string-locale? string-locale-ciinteger #\*))) (test #"?**" 'bytes-set! (begin (bytes-set! f 0 (char->integer #\?)) f)) (arity-test bytes-set! 3 3) (err/rt-test (bytes-set! #"hello" 0 #\a)) ; immutable bytes constant (define hello-bytes (bytes-copy #"hello")) (err/rt-test (bytes-set! hello-bytes 'a 97)) (err/rt-test (bytes-set! 'hello 4 97)) (err/rt-test (bytes-set! hello-bytes 4 'a)) (err/rt-test (bytes-set! hello-bytes 4.0 'a)) (err/rt-test (bytes-set! hello-bytes 5 97) exn:application:mismatch?) (err/rt-test (bytes-set! hello-bytes -1 97)) (err/rt-test (bytes-set! hello-bytes (expt 2 100) 97) exn:application:mismatch?) (test #"abc" bytes 97 98 99) (test #"" bytes) (err/rt-test (bytes #\a 1)) (err/rt-test (bytes 1 #\a)) (err/rt-test (bytes #\1)) (test 3 bytes-length #"abc") (test 0 bytes-length #"") (arity-test bytes-length 1 1) (err/rt-test (bytes-length 'apple)) (test 97 bytes-ref #"abc" 0) (test 99 bytes-ref #"abc" 2) (arity-test bytes-ref 2 2) (err/rt-test (bytes-ref 'apple 4)) (err/rt-test (bytes-ref #"apple" 4.0)) (err/rt-test (bytes-ref #"apple" '(4))) (err/rt-test (bytes-ref #"apple" 5) exn:application:mismatch?) (err/rt-test (bytes-ref #"" 0) exn:application:mismatch?) (err/rt-test (bytes-ref #"" (expt 2 100)) exn:application:mismatch?) (err/rt-test (bytes-ref #"apple" -1)) (test #"" subbytes #"ab" 0 0) (test #"" subbytes #"ab" 1 1) (test #"" subbytes #"ab" 2 2) (test #"a" subbytes #"ab" 0 1) (test #"b" subbytes #"ab" 1 2) (test #"ab" subbytes #"ab" 0 2) (test #"ab" subbytes #"ab" 0) (test #"b" subbytes #"ab" 1) (test #"" subbytes #"ab" 2) (test (bytes 97 0 98) subbytes (bytes 32 97 0 98 45) 1 4) (arity-test subbytes 2 3) (err/rt-test (subbytes 'hello 2 3)) (err/rt-test (subbytes #"hello" #"2" 3)) (err/rt-test (subbytes #"hello" 2.0 3)) (err/rt-test (subbytes #"hello" 2 3.0)) (err/rt-test (subbytes #"hello" 2 #"3")) (err/rt-test (subbytes #"hello" 2 7) exn:application:mismatch?) (err/rt-test (subbytes #"hello" -2 3)) (err/rt-test (subbytes #"hello" 4 3) exn:application:mismatch?) (err/rt-test (subbytes #"hello" (expt 2 100) 3) exn:application:mismatch?) (err/rt-test (subbytes #"hello" (expt 2 100) 5) exn:application:mismatch?) (err/rt-test (subbytes #"hello" 3 (expt 2 100)) exn:application:mismatch?) (test #"foobar" bytes-append #"foo" #"bar") (test #"foo" bytes-append #"foo") (test #"foo" bytes-append #"foo" #"") (test #"foogoo" bytes-append #"foo" #"" #"goo") (test #"foo" bytes-append #"" #"foo") (test #"" bytes-append) (test (bytes 97 0 98 99 0 100) bytes-append (bytes 97 0 98) (bytes 99 0 100)) (err/rt-test (bytes-append 1)) (err/rt-test (bytes-append #"hello" 1)) (err/rt-test (bytes-append #"hello" 1 #"done")) (test #"" make-bytes 0) (define s (bytes-copy #"hello")) (define s2 (bytes-copy s)) (test #"hello" 'bytes-copy s2) (bytes-set! s 2 (char->integer #\x)) (test #"hello" 'bytes-copy s2) (test (bytes 97 0 98) bytes-copy (bytes 97 0 98)) (bytes-fill! s (char->integer #\x)) (test #"xxxxx" 'bytes-fill! s) (arity-test bytes-copy 1 1) (arity-test bytes-fill! 2 2) (err/rt-test (bytes-copy 'blah)) (err/rt-test (bytes-fill! 'sym 1)) (err/rt-test (bytes-fill! #"static" 1)) (err/rt-test (bytes-fill! (bytes-copy #"oops") #\5)) (define r (regexp "(-[0-9]*)+")) (test '("-12--345" "-345") regexp-match r "a-12--345b") (test '((1 . 9) (5 . 9)) regexp-match-positions r "a-12--345b") (test '("--345" "-345") regexp-match r "a-12--345b" 2) (test '("--34" "-34") regexp-match r "a-12--345b" 2 8) (test '((4 . 9) (5 . 9)) regexp-match-positions r "a-12--345b" 2) (test '((4 . 8) (5 . 8)) regexp-match-positions r "a-12--345b" 2 8) (test '("a-b") regexp-match "a[-c]b" "a-b") (test '("a-b") regexp-match "a[c-]b" "a-b") (test #f regexp-match "x+" "12345") (test "su casa" regexp-replace "mi" "mi casa" "su") (define r2 (regexp "([Mm])i ([a-zA-Z]*)")) (define insert "\\1y \\2") (test "My Casa" regexp-replace r2 "Mi Casa" insert) (test "my cerveza Mi Mi Mi" regexp-replace r2 "mi cerveza Mi Mi Mi" insert) (test "my cerveza My Mi Mi" regexp-replace* r2 "mi cerveza Mi Mi Mi" insert) (test "bbb" regexp-replace* "a" "aaa" "b") ;; Test weird port offsets: (define (test-weird-offset regexp-match regexp-match-positions) (test #f regexp-match "e" (open-input-string "")) (test #f regexp-match "e" (open-input-string "") (expt 2 100)) (test #f regexp-match "e" (open-input-string "") (expt 2 100) (expt 2 101)) (test '((3 . 4)) regexp-match-positions "e" (open-input-string "eaae") 2 (expt 2 101))) (test-weird-offset regexp-match regexp-match-positions) (test-weird-offset regexp-match-peek regexp-match-peek-positions) ;; Check greedy and non-greedy operators: (define (do-the-tests prefix suffix start end) (define input (format "~a~a~a" prefix " " suffix)) (define (check-greedy-stuff mk-input regexp-match regexp-match-positions) (define (testre s-answer p-answer pattern) (let ([p-answer (if (and p-answer start) (list (cons (+ start (caar p-answer)) (+ start (cdar p-answer)))) p-answer)]) (cond [end (test s-answer regexp-match pattern (mk-input) start (+ end (string-length input))) (test p-answer regexp-match-positions pattern (mk-input) start (+ end (string-length input)))] [start (test s-answer regexp-match pattern (mk-input) start) (test p-answer regexp-match-positions pattern (mk-input) start)] [else (test s-answer regexp-match pattern (mk-input)) (test p-answer regexp-match-positions pattern (mk-input))]))) (define strs (if (string? (mk-input)) list (lambda l (map string->bytes/utf-8 l)))) (testre (strs " ") '((0 . 22)) "<.*>") (testre (strs "") '((0 . 10)) "<.*?>") (testre (strs " ") '((0 . 22)) "<.*?>$") (testre (strs "") '((0 . 0)) "b*") (testre (strs "string (reverse! s))] [plain (regexp-replace* "[()]" s "")]) (test (cons plain (map list->string (map reverse! (vector->list v)))) regexp-match s plain))] [(or (= n mx) (< (random 10) 3)) (if (and (positive? m) (< (random 10) 7)) (begin (let loop ([p 0][m (sub1 m)]) (if (vector-ref open p) (if (zero? m) (vector-set! open p #f) (loop (add1 p) (sub1 m))) (loop (add1 p) m))) (loop n (sub1 m) (cons #\) s))) (let ([c (integer->char (+ (char->integer #\a) (random 26)))]) (let loop ([p 0]) (unless (= p n) (when (vector-ref open p) (vector-set! v p (cons c (vector-ref v p)))) (loop (add1 p)))) (loop n m (cons c s))))] [else (loop (add1 n) (add1 m) (cons #\( s))])))) '(1 10 100 500)) (define (test-bad-re-args who) (err/rt-test (who 'e "hello")) (err/rt-test (who "e" 'hello)) (err/rt-test (who "e" "hello" -1 5)) (err/rt-test (who "e" "hello" (- (expt 2 100)) 5)) (err/rt-test (who "e" (open-input-string "") (- (expt 2 100)) 5)) (err/rt-test (who "e" "hello" 1 (- (expt 2 100)))) (err/rt-test (who "e" (open-input-string "") 1 (- (expt 2 100)))) (err/rt-test (who "e" "hello" 1 +inf.0)) (err/rt-test (who "e" "" 0 1) exn:application:mismatch?) (err/rt-test (who "e" "hello" 3 2) exn:application:mismatch?) (err/rt-test (who "e" "hello" 3 12) exn:application:mismatch?) (err/rt-test (who "e" "hello" (expt 2 100) 5) exn:application:mismatch?) (err/rt-test (who "e" (open-input-string "") (expt 2 100) 5) exn:application:mismatch?) (err/rt-test (who "e" (open-input-string "") (expt 2 100) (sub1 (expt 2 100))) exn:application:mismatch?)) (test-bad-re-args regexp-match) (test-bad-re-args regexp-match-positions) ;; Test non-capturing parens (test '("1aaa2" "a") regexp-match #rx"1(a)*2" "01aaa23") (test '("1aaa2") regexp-match #rx"1(?:a)*2" "01aaa23") (test '("1akakak2" "ak") regexp-match #rx"1(ak)*2" "01akakak23") (test '("1akakak2") regexp-match #rx"1(?:ak)*2" "01akakak23") (test '("1akakkakkkk2" "akkkk") regexp-match #rx"1(ak*)*2" "01akakkakkkk23") (test '("1akakkakkkk2") regexp-match #rx"1(?:ak*)*2" "01akakkakkkk23") (test '("01akakkakkkk23" "1akakkakkkk2" "1" "a" "k" "2") regexp-match #rx"(?:0)(((?:1))(?:(a)(?:(k))*)*((?:2)))(?:3)" "_01akakkakkkk23_") (test '((1 . 10) (7 . 9)) regexp-match-positions #rx"1(ak*)*2" "01akakkak23") (test '((1 . 10)) regexp-match-positions #rx"1(?:ak*)*2" "01akakkak23") ;; Regexps that shouldn't work: (err/rt-test (regexp "[a--b]") exn:fail?) (err/rt-test (regexp "[a-b-c]") exn:fail?) ;; A good test of unicode-friendly ".": (test '("load-extension: couldn't open \\\" (%s)\"") regexp-match (regexp "^(?:[^\\\"]|\\\\.)*\"") "load-extension: couldn't open \\\" (%s)\"") ;; Test bounded byte consumption on failure: (let ([is (open-input-string "barfoo")]) (test '(#f #\f) list (regexp-match "^foo" is 0 3) (read-char is))) (let ([is (open-input-string "barfoo")]) (test '(#f #\f) list (regexp-match "foo" is 0 3) (read-char is))) (arity-test regexp 1 1) (arity-test regexp? 1 1) (arity-test regexp-match 2 5) (arity-test regexp-match-positions 2 5) (arity-test regexp-match-peek 2 5) (arity-test regexp-match-peek-positions 2 5) (arity-test regexp-replace 3 3) (arity-test regexp-replace* 3 3) (test #t vector? '#(0 (2 2 2 2) "Anna")) (test #t vector? '#()) (arity-test vector? 1 1) (test '#(a b c) vector 'a 'b 'c) (test '#() vector) (test 3 vector-length '#(0 (2 2 2 2) "Anna")) (test 0 vector-length '#()) (arity-test vector-length 1 1) (err/rt-test (vector-length "apple")) (test 8 vector-ref '#(1 1 2 3 5 8 13 21) 5) (arity-test vector-ref 2 2) (err/rt-test (vector-ref "apple" 3)) (err/rt-test (vector-ref #(4 5 6) 3) exn:application:mismatch?) (err/rt-test (vector-ref #() 0) exn:application:mismatch?) (err/rt-test (vector-ref #() (expt 2 100)) exn:application:mismatch?) (err/rt-test (vector-ref #(4 5 6) -1)) (err/rt-test (vector-ref #(4 5 6) 2.0)) (err/rt-test (vector-ref #(4 5 6) "2")) (test '#(0 ("Sue" "Sue") "Anna") 'vector-set (let ((vec (vector 0 '(2 2 2 2) "Anna"))) (vector-set! vec 1 '("Sue" "Sue")) vec)) (test '#(hi hi) make-vector 2 'hi) (test '#() make-vector 0) (test '#() make-vector 0 'a) (test 2048 vector-length (make-vector 2048 'a)) (arity-test make-vector 1 2) (err/rt-test (make-vector "a" 'a)) (err/rt-test (make-vector 1.0 'a)) (err/rt-test (make-vector 10.2 'a)) (err/rt-test (make-vector -1 'a)) (err/rt-test (make-vector 1000000000000000000000 'a) exn:fail:out-of-memory?) (arity-test vector-set! 3 3) (err/rt-test (vector-set! #() 0 'x) exn:application:mismatch?) (err/rt-test (vector-set! #(1 2 3) -1 'x)) (err/rt-test (vector-set! #(1 2 3) 3 'x) exn:application:mismatch?) (err/rt-test (vector-set! #(1 2 3) (expt 2 100) 'x) exn:application:mismatch?) (err/rt-test (vector-set! '(1 2 3) 2 'x)) (err/rt-test (vector-set! #(1 2 3) "2" 'x)) (define v (quote #(1 2 3))) (vector-fill! v 0) (test (quote #(0 0 0)) 'vector-fill! v) (arity-test vector-fill! 2 2) (err/rt-test (vector-fill! '(1 2 3) 0)) (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 #t call-with-escape-continuation procedure?) (test #t procedure? (case-lambda ((x) x) ((x y) (+ x y)))) (arity-test procedure? 1 1) (test 7 apply + (list 3 4)) (test 7 apply (lambda (a b) (+ a b)) (list 3 4)) (test 17 apply + 10 (list 3 4)) (test '() apply list '()) (define compose (lambda (f g) (lambda args (f (apply g args))))) (test 30 (compose sqrt *) 12 75) (err/rt-test (apply) exn:application:arity?) (err/rt-test (apply (lambda x x)) exn:application:arity?) (err/rt-test (apply (lambda x x) 1)) (err/rt-test (apply (lambda x x) 1 2)) (err/rt-test (apply (lambda x x) 1 '(2 . 3))) (test '(b e h) map cadr '((a b) (d e) (g h))) (test '(5 7 9) map + '(1 2 3) '(4 5 6)) (test '#(0 1 4 9 16) 'for-each (let ((v (make-vector 5))) (for-each (lambda (i) (vector-set! v i (* i i))) '(0 1 2 3 4)) v)) (err/rt-test (let ([l (list 1 2 3)]) (for-each (lambda (x) (set-cdr! (cdr l) 1)) l)) exn:application:mismatch?) (define (map-tests map) (let ([size? exn:application:mismatch?] [non-list? type?]) (err/rt-test (map (lambda (x y) (+ x y)) '(1 2) '1)) (err/rt-test (map (lambda (x y) (+ x y)) '2 '(1 2))) (err/rt-test (map (lambda (x y) (+ x y)) '(1 2) '(1 2 3)) size?) (err/rt-test (map (lambda (x y) (+ x y)) '(1 2 3) '(1 2)) size?) (err/rt-test (map (lambda (x) (+ x)) '(1 2 . 3)) non-list?) (err/rt-test (map (lambda (x y) (+ x y)) '(1 2 . 3) '(1 2)) non-list?) (err/rt-test (map (lambda (x y) (+ x y)) '(1 2 . 3) '(1 2 3)) non-list?) (err/rt-test (map (lambda (x y) (+ x y)) '(1 2) '(1 2 . 3)) non-list?) (err/rt-test (map (lambda (x y) (+ x y)) '(1 2 3) '(1 2 . 3)) non-list?) (err/rt-test (map) exn:application:arity?) (err/rt-test (map (lambda (x y) (+ x y))) exn:application:arity?) (err/rt-test (map (lambda () 10) null) exn:application:mismatch?) (err/rt-test (map (case-lambda [() 9] [(x y) 10]) '(1 2 3)) exn:application:mismatch?) (err/rt-test (map (lambda (x) 10) '(1 2) '(3 4)) exn:application:mismatch?))) (map-tests map) (map-tests for-each) (map-tests andmap) (map-tests ormap) (test-values (list (void)) (lambda () (for-each (lambda (x) (values 1 2)) '(1 2)))) (err/rt-test (map (lambda (x) (values 1 2)) '(1 2)) arity?) (test #t andmap add1 null) (test #f ormap add1 null) (test #f andmap positive? '(1 -2 3)) (test #t ormap positive? '(1 -2 3)) (test #f andmap negative? '(1 -2 3)) (test #t ormap negative? '(1 -2 3)) (test 4 andmap add1 '(1 2 3)) (test 2 ormap add1 '(1 2 3)) (err/rt-test (ormap (lambda (x) (values 1 2)) '(1 2)) arity?) (err/rt-test (andmap (lambda (x) (values 1 2)) '(1 2)) arity?) (test-values '(1 2) (lambda () (ormap (lambda (x) (values 1 2)) '(1)))) (test-values '(1 2) (lambda () (andmap (lambda (x) (values 1 2)) '(1)))) (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 '() map cadr '()) ;; ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;; exceptions (test 10 'exns (with-handlers ([integer? (lambda (x) 10)]) (raise 12))) (test '(apple) 'exns (with-handlers ([void (lambda (x) (list x))]) (with-handlers ([integer? (lambda (x) 10)]) (raise 'apple)))) (test '((10)) 'exns (with-handlers ([void (lambda (x) (list x))]) (with-handlers ([integer? (lambda (x) (raise (list x)))]) (raise 10)))) (test '((10)) 'exns (let/ec esc (parameterize ([uncaught-exception-handler (lambda (x) (esc (list x)))]) (with-handlers ([integer? (lambda (x) (raise (list x)))]) (raise 10))))) (test '#((10)) 'exns (let/ec esc (with-handlers ([void (lambda (x) (vector x))]) (parameterize ([uncaught-exception-handler (lambda (x) (esc (list x)))]) (with-handlers ([integer? (lambda (x) (raise (list x)))]) (raise 10)))))) (test '(except) 'escape (let/ec k (call-with-exception-handler (lambda (exn) (k (list exn))) (lambda () (raise 'except))))) (test '#&except 'escape (let/ec k (call-with-exception-handler (lambda (exn) (k (list exn))) (lambda () (call-with-exception-handler (lambda (exn) (k (box exn))) (lambda () (raise 'except))))))) (test '#(except) 'escape (with-handlers ([void (lambda (x) x)]) (values (call-with-exception-handler (lambda (exn) (vector exn)) (lambda () (raise 'except)))))) (test '(except) 'escape (with-handlers ([void (lambda (x) x)]) (values (call-with-exception-handler (lambda (exn) (vector exn)) (lambda () (call-with-exception-handler (lambda (exn) (list exn)) (lambda () (raise 'except)))))))) (test '#((except)) 'escape (with-handlers ([void (lambda (x) x)]) (values (call-with-exception-handler (lambda (exn) (vector exn)) (lambda () (values (call-with-exception-handler (lambda (exn) (list exn)) (lambda () (raise 'except))))))))) ;; ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;;; This tests full conformance of call-with-current-continuation. It ;;; is a separate test because some schemes do not support call/cc ;;; other than escape procedures. I am indebted to ;;; raja@copper.ucs.indiana.edu (Raja Sooriamurthi) for fixing this ;;; code. The function leaf-eq? compares the leaves of 2 arbitrary ;;; trees constructed of conses. (define (next-leaf-generator obj eot) (letrec ((return #f) (cont (lambda (x) (recurx obj) (set! cont (lambda (x) (return eot))) (cont #f))) (recurx (lambda (obj) (if (pair? obj) (for-each recurx obj) (call-with-current-continuation (lambda (c) (set! cont c) (return obj))))))) (lambda () (call-with-current-continuation (lambda (ret) (set! return ret) (cont #f)))))) (define (leaf-eq? x y) (let* ((eot (list 'eot)) (xf (next-leaf-generator x eot)) (yf (next-leaf-generator y eot))) (letrec ((loop (lambda (x y) (cond ((not (eq? x y)) #f) ((eq? eot x) #t) (else (loop (xf) (yf))))))) (loop (xf) (yf))))) (define (test-cont) (newline) (display ";testing continuations; ") (test #t leaf-eq? '(a (b (c))) '((a) b c)) (test #f leaf-eq? '(a (b (c))) '((a) b c d)) '(report-errs)) (define (test-cc-values test-call/cc) (test '(a b c) call-with-values (lambda () (test-call/cc (lambda (k) (dynamic-wind void (lambda () (k 'a 'b 'c)) (lambda () (values 1 2)))))) list) (test 1 dynamic-wind (lambda () (test-call/cc void)) (lambda () 1) (lambda () (test-call/cc void))) ; Try devious jumping with pre- and post-thunks: (test 2 test-call/cc (lambda (exit) (dynamic-wind (lambda () (exit 2)) void void))) (test 3 test-call/cc (lambda (exit) (dynamic-wind void void (lambda () (exit 3))))) (let ([rv (lambda (get-v) (let ([x 0]) (test-call/cc (lambda (exit) (dynamic-wind void (lambda () (exit)) (lambda () (set! x (get-v)))))) x))] [r56 (lambda () (let ([x 0] [y 1] [c1 #f]) (dynamic-wind (lambda () (set! x (add1 x))) (lambda () (let/cc k (set! c1 k)) (if (>= x 5) (set! c1 #f))) (lambda () (set! y (add1 y)))) (when c1 (c1)) (list x y)))] [rx.y (lambda (get-x get-y) (let ([c1 #f] [x 0] [y 0]) (let ([v (dynamic-wind (lambda () (set! y x)) (lambda () (let/cc k (set! c1 k))) (lambda () (set! x (get-x)) (when c1 ((begin0 c1 (set! c1 #f)) (get-y)))))]) (cons y v))))] [rv2 (lambda (get-v) (let ([c1 #f] [give-up #f]) (test-call/cc (lambda (exit) (dynamic-wind (lambda () (when give-up (give-up (get-v)))) (lambda () (let/cc k (set! c1 k))) (lambda () (set! give-up exit) (c1)))))))] [r10-11-12 (lambda () (let ([c2 #f] [x 10] [y 11]) (let ([v (dynamic-wind (lambda () (set! y (add1 y))) (lambda () (begin0 x (set! x (add1 x)))) (lambda () (let/cc k (set! c2 k))))]) (when c2 ((begin0 c2 (set! c2 #f)))) (list v x y))))] [r13.14 (lambda () (let ([c0 #f] [x 11] [y 12]) (dynamic-wind (lambda () (let/cc k (set! c0 k))) (lambda () (set! x (add1 x))) (lambda () (set! y (add1 y)) (when c0 ((begin0 c0 (set! c0 #f)))))) (cons x y)))] [ra-b-a-b (lambda (get-a get-b) (let ([l null]) (let ((k-in (test-call/cc (lambda (k1) (dynamic-wind (lambda () (set! l (append l (list (get-a))))) (lambda () (call/cc (lambda (k2) (k1 k2)))) (lambda () (set! l (append l (list (get-b)))))))))) (k-in (lambda (v) l)))))]) (test 4 rv (lambda () 4)) (test '(5 6) r56) (test '(7 . 8) rx.y (lambda () 7) (lambda () 8)) (test 9 rv2 (lambda () 9)) (test '(10 11 12) r10-11-12) (test '(13 . 14) r13.14) ; !!! fixed in 50: (test '(enter exit enter exit) ra-b-a-b (lambda () 'enter) (lambda () 'exit)) (test '((13 . 14) (10 11 12) (13 . 14) (10 11 12)) ra-b-a-b r13.14 r10-11-12) (test '((10 11 12) (13 . 14) (10 11 12) (13 . 14)) ra-b-a-b r10-11-12 r13.14) (test 10 call/cc (lambda (k) (k 10))) (test '((enter exit enter exit) (exit enter exit enter) (enter exit enter exit) (exit enter exit enter)) ra-b-a-b (lambda () (ra-b-a-b (lambda () 'enter) (lambda () 'exit))) (lambda () (ra-b-a-b (lambda () 'exit) (lambda () 'enter)))) (test '(enter exit enter exit) rv (lambda () (ra-b-a-b (lambda () 'enter) (lambda () 'exit)))) (test '(enter exit enter exit) rv2 (lambda () (ra-b-a-b (lambda () 'enter) (lambda () 'exit)))) (test '(10 11 12) rv r10-11-12) (test '(10 11 12) rv2 r10-11-12) (test '(13 . 14) rv r13.14) (test '(13 . 14) rv2 r13.14) (test 12 'dw/ec (test-call/cc (lambda (k0) (test-call/cc (lambda (k1) (test-call/cc (lambda (k2) (dynamic-wind void (lambda () (k1 6)) (lambda () (k2 12)))))))))) ;; !!! fixed in 53 (for call/ec) (test 13 'dw/ec (test-call/cc (lambda (k0) (test-call/cc (lambda (k1) (test-call/cc (lambda (k2) (dynamic-wind void (lambda () (k1 6)) (lambda () (k2 12))))) (k0 13)))))) )) (test-cc-values call/cc) (test-cc-values call/ec) (test 'ok 'ec-cc-exn-combo (with-handlers ([void (lambda (x) 'ok)]) (define f (let ([k #f]) (lambda (n) (case n [(0) (let/ec r (r (set! k (let/cc k k))))] [(1) (k)])))) (f 0) (f 1))) (test '(1 2 3 4 1 2 3 4) 'dyn-wind-pre/post-order (let ([x null] [go-back #f]) (dynamic-wind (lambda () (set! x (cons 4 x))) (lambda () (dynamic-wind (lambda () (set! x (cons 3 x))) (lambda () (set! go-back (let/cc k k))) (lambda () (set! x (cons 2 x))))) (lambda () (set! x (cons 1 x)))) (if (procedure? go-back) (go-back 1) x))) (test '(5 . 5) 'suspended-cont-escape (let ([retry #f]) (let ([v (let/ec exit (dynamic-wind void (lambda () (exit 5)) (lambda () (let/ec inner-escape (set! retry (let/cc k k)) (inner-escape 12) 10))))]) (if (procedure? retry) (retry 10) (cons v v))))) (test '(here) 'escape-interrupt-full-jump-up (let ([b #f] [v null]) (define (f g) (dynamic-wind void g (lambda () (set! v (cons 'here v)) (b 10)))) (let/ec big (set! b big) (let/cc ok (f (lambda () (ok #f))))) v)) ;; Check interaction of map and call/cc (let () (define (try n m) (let ([retries (make-vector n)] [copy #f] [special -1] [in (let loop ([i n]) (if (= i 0) null (cons (- n i) (loop (sub1 i)))))]) (let ([v (apply map (lambda (a . rest) (+ (let/cc k (vector-set! retries a k) 1) a)) (let loop ([m m]) (if (zero? m) null (cons in (loop (sub1 m))))))]) (test (map (lambda (i) (if (= i special) (+ i 2) (add1 i))) in) `(map/cc ,n ,m) v)) (if copy (when (pair? copy) (set! special (add1 special)) ((begin0 (car copy) (set! copy (cdr copy))) 2)) (begin (set! copy (vector->list retries)) ((vector-ref retries (random n)) 1))))) (try 3 1) (try 10 1) (try 3 2) (try 10 2) (try 5 3) (try 3 5) (try 10 5)) ;; Make sure let doesn't allocate a mutatble cell too early: (test 2 'let+call/cc (let ([count 0]) (let ([first-time? #t] [k (call/cc values)]) (if first-time? (begin (set! first-time? #f) (set! count (+ count 1)) (k values)))) count)) (arity-test call/cc 1 2) (arity-test call/ec 1 1) (err/rt-test (call/cc 4)) (err/rt-test (call/cc (lambda () 0))) (err/rt-test (call/ec 4)) (err/rt-test (call/ec (lambda () 0))) (test #t primitive? car) (test #f primitive? leaf-eq?) (arity-test primitive? 1 1) (test 1 procedure-arity procedure-arity) (test 2 procedure-arity cons) (test (make-arity-at-least 2) procedure-arity >) (test (list 0 1) procedure-arity current-output-port) (test (list 1 3 (make-arity-at-least 5)) procedure-arity (case-lambda [(x) 0] [(x y z) 1] [(x y z w u . rest) 2])) (test (make-arity-at-least 0) procedure-arity (lambda x 1)) (test (list 0 (make-arity-at-least 0)) procedure-arity (case-lambda [() 10] [x 1])) (test (make-arity-at-least 0) procedure-arity (lambda x x)) (arity-test procedure-arity 1 1) (test #t procedure-arity-includes? cons 2) (test #f procedure-arity-includes? cons 0) (test #f procedure-arity-includes? cons 3) (test #t procedure-arity-includes? list 3) (test #t procedure-arity-includes? list 3000) (test #t procedure-arity-includes? (lambda () 0) 0) (test #f procedure-arity-includes? (lambda () 0) 1) (test #f procedure-arity-includes? cons 10000000000000000000000000000) (test #t procedure-arity-includes? list 10000000000000000000000000000) (test #t procedure-arity-includes? (lambda x x) 10000000000000000000000000000) (err/rt-test (procedure-arity-includes? cons -1)) (err/rt-test (procedure-arity-includes? cons 1.0)) (err/rt-test (procedure-arity-includes? 'cons 1)) (arity-test procedure-arity-includes? 2 2) (newline) (display ";testing scheme 4 functions; ") (test '(#\P #\space #\l) string->list "P l") (test '() string->list "") (test "1\\\"" list->string '(#\1 #\\ #\")) (test "" list->string '()) (arity-test list->string 1 1) (arity-test string->list 1 1) (err/rt-test (string->list 'hello)) (err/rt-test (list->string 'hello)) (err/rt-test (list->string '(#\h . #\e))) (err/rt-test (list->string '(#\h 1 #\e))) (test '(dah dah didah) vector->list '#(dah dah didah)) (test '() vector->list '#()) (test '#(dididit dah) list->vector '(dididit dah)) (test '#() list->vector '()) (arity-test list->vector 1 1) (arity-test vector->list 1 1) (err/rt-test (vector->list 'hello)) (err/rt-test (list->vector 'hello)) (err/rt-test (list->vector '(#\h . #\e))) (test-cont) ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;; hash tables (arity-test make-hash-table 0 2) (err/rt-test (make-hash-table 'a)) (err/rt-test (make-hash-table 'weak 'weak) exn:application:mismatch?) (err/rt-test (make-hash-table 'equal 'equal) exn:application:mismatch?) (let () (define-struct ax (b c)) ; opaque (define-struct a (b c) (make-inspector)) (define save (let ([x null]) (case-lambda [() x] [(a) (set! x (cons a x)) a]))) (define an-ax (make-ax 1 2)) (let ([check-hash-tables (lambda (maybe-weak reorder?) (let ([h1 (apply make-hash-table maybe-weak)] [l (list 1 2 3)]) (test #t eq? (eq-hash-code l) (eq-hash-code l)) (test #t eq? (equal-hash-code l) (equal-hash-code l)) (test #t eq? (equal-hash-code l) (equal-hash-code (list 1 2 3))) (hash-table-put! h1 l 'ok) (test 'ok hash-table-get h1 l) (test 'nope hash-table-get h1 (list 1 2 3) (lambda () 'nope)) (test '(((1 2 3) . ok)) hash-table-map h1 (lambda (k v) (cons k v))) (hash-table-remove! h1 l) (test 'nope hash-table-get h1 l (lambda () 'nope))) (let ([h1 (apply make-hash-table 'equal maybe-weak)] [l (list 1 2 3)] [v (vector 5 6 7)] [a (make-a 1 (make-a 2 3))] [b (box (list 1 2 3))]) (test 0 hash-table-count h1) ;; Fill in table. Use `puts1' and `puts2' so we can ;; vary the order of additions. (let ([puts1 (lambda () (hash-table-put! h1 (save l) 'list) (hash-table-put! h1 (save "Hello World!") 'string) (hash-table-put! h1 (save 123456789123456789123456789) 'bignum) (hash-table-put! h1 (save 3.45) 'flonum) (hash-table-put! h1 (save 3/45) 'rational) (hash-table-put! h1 (save 3+45i) 'complex))] [puts2 (lambda () (hash-table-put! h1 (save (list 5 7)) 'another-list) (hash-table-put! h1 (save 3+0.0i) 'izi-complex) (hash-table-put! h1 (save v) 'vector) (hash-table-put! h1 (save a) 'struct) (hash-table-put! h1 (save an-ax) 'structx) (hash-table-put! h1 (save b) 'box))]) (if reorder? (begin (puts2) (test 6 hash-table-count h1) (puts1)) (begin (puts1) (test 6 hash-table-count h1) (puts2)))) (when reorder? ;; Add 1000 things and take them back out in an effort to ;; trigger GCs that somehow affect hashing: (let loop ([i 0.0]) (unless (= i 1000.0) (hash-table-put! h1 i #t) (loop (add1 i)) (hash-table-remove! h1 i)))) (test 12 hash-table-count h1) (test 'list hash-table-get h1 l) (test 'list hash-table-get h1 (list 1 2 3)) (test 'another-list hash-table-get h1 (list 5 7)) (test 'string hash-table-get h1 "Hello World!") (test 'bignum hash-table-get h1 123456789123456789123456789) (test 'flonum hash-table-get h1 3.45) (test 'rational hash-table-get h1 3/45) (test 'complex hash-table-get h1 3+45i) (test 'izi-complex hash-table-get h1 3+0.0i) (test 'vector hash-table-get h1 v) (test 'vector hash-table-get h1 #(5 6 7)) (test 'struct hash-table-get h1 a) (test 'struct hash-table-get h1 (make-a 1 (make-a 2 3))) (test 'structx hash-table-get h1 an-ax) (test #f hash-table-get h1 (make-ax 1 2) (lambda () #f)) (test 'box hash-table-get h1 b) (test 'box hash-table-get h1 #&(1 2 3)) (test #t andmap (lambda (i) (and (member i (hash-table-map h1 (lambda (k v) (cons k v)))) #t)) `(((1 2 3) . list) ((5 7) . another-list) ("Hello World!" . string) (123456789123456789123456789 . bignum) (3.45 . flonum) (3/45 . rational) (3+45i . complex) (3+0.0i . izi-complex) (#(5 6 7) . vector) (,(make-a 1 (make-a 2 3)) . struct) (,an-ax . structx) (#&(1 2 3) . box))) (hash-table-remove! h1 (list 1 2 3)) (test 11 hash-table-count h1) (test 'not-there hash-table-get h1 l (lambda () 'not-there)) (let ([c 0]) (hash-table-for-each h1 (lambda (k v) (set! c (add1 c)))) (test 11 'count c)) ;; return the hash table: h1))]) (let ([check-tables-equal (lambda (mode t1 t2) (test #t equal? t1 t2) (test (equal-hash-code t1) equal-hash-code t2) (let ([meta-ht (make-hash-table 'equal)]) (hash-table-put! meta-ht t1 mode) (test mode hash-table-get meta-ht t2 (lambda () #f))) (test (hash-table-count t1) hash-table-count t2))]) (check-tables-equal 'the-norm-table (check-hash-tables null #f) (check-hash-tables null #t)) (check-tables-equal 'the-weak-table (check-hash-tables (list 'weak) #f) (check-hash-tables (list 'weak) #t))) (save))) ; prevents gcing of the ht-registered values (test #f hash-table? 5) (test #t hash-table? (make-hash-table)) (test #f hash-table? 5 'equal) (test #f hash-table? (make-hash-table) 'equal) (test #t hash-table? (make-hash-table 'equal) 'equal) (test #f hash-table? (make-hash-table 'weak) 'equal) (test #t hash-table? (make-hash-table 'weak 'equal) 'equal) (test #f hash-table? 5 'weak) (test #f hash-table? (make-hash-table) 'weak) (test #f hash-table? (make-hash-table 'equal) 'weak) (test #t hash-table? (make-hash-table 'weak) 'weak) (test #t hash-table? (make-hash-table 'weak 'equal) 'weak) (test #f hash-table? 5 'weak 'equal) (test #f hash-table? (make-hash-table) 'weak 'equal) (test #f hash-table? (make-hash-table 'equal) 'weak 'equal) (test #f hash-table? (make-hash-table 'weak) 'weak 'equal) (test #t hash-table? (make-hash-table 'weak 'equal) 'weak 'equal) ;; Double check that table are equal after deletions (let ([test-del-eq (lambda (flags) (let ([ht1 (apply make-hash-table flags)] [ht2 (apply make-hash-table flags)]) (test #t equal? ht1 ht2) (hash-table-put! ht1 'apple 1) (hash-table-put! ht2 'apple 1) (test #t equal? ht1 ht2) (hash-table-put! ht2 'banana 2) (test #f equal? ht1 ht2) (hash-table-remove! ht2 'banana) (test #t equal? ht1 ht2)))]) (test-del-eq null) (test-del-eq '(equal)) (test-del-eq '(weak))) (err/rt-test (hash-table-count 0)) (err/rt-test (hash-table-put! 1 2 3)) (err/rt-test (hash-table-get 1 2)) (err/rt-test (hash-table-remove! 1 2)) (err/rt-test (hash-table-get (make-hash-table) 2) exn:application:mismatch?) (err/rt-test (hash-table? 5 5)) (err/rt-test (hash-table? 5 'equal 5)) (err/rt-test (hash-table? (make-hash-table) 'equal 'equal) exn:application:mismatch?) (err/rt-test (hash-table? (make-hash-table) 'weak 'weak) exn:application:mismatch?) (define im-t (make-immutable-hash-table null)) (test #t hash-table? im-t) (test #f hash-table? im-t 'equal) (test null hash-table-map im-t cons) (err/rt-test (hash-table-put! im-t 1 2)) (test #f hash-table-get im-t 5 (lambda () #f)) (define im-t (make-immutable-hash-table '((1 . 2)))) (test '((1 . 2)) hash-table-map im-t cons) (test 2 hash-table-get im-t 1) (define im-t (make-immutable-hash-table '(("hello" . 2)))) (test 'none hash-table-get im-t "hello" (lambda () 'none)) (define im-t (make-immutable-hash-table '(("hello" . 2)) 'equal)) (test 2 hash-table-get im-t "hello" (lambda () 'none)) (test #t hash-table? im-t 'equal) (err/rt-test (hash-table-put! im-t 1 2)) (err/rt-test (hash-table-remove! im-t 1)) (err/rt-test (make-immutable-hash-table '(1))) (err/rt-test (make-immutable-hash-table '((1 . 2) . 2))) (err/rt-test (make-immutable-hash-table '((1 . 2) 3))) (define cyclic-alist '#0=((1 . 2) . #0#)) (err/rt-test (make-immutable-hash-table cyclic-alist)) (err/rt-test (make-immutable-hash-table '((1 . 2)) 'weak)) (test 2 hash-table-get (hash-table-copy #hasheq((1 . 2))) 1) (test (void) hash-table-put! (hash-table-copy #hasheq((1 . 2))) 3 4) (arity-test make-hash-table 0 2) (arity-test make-immutable-hash-table 1 2) (arity-test hash-table-count 1 1) (arity-test hash-table-get 2 3) (arity-test hash-table-put! 3 3) (arity-test hash-table-remove! 2 2) (arity-test hash-table-map 2 2) (arity-test hash-table-for-each 2 2) (arity-test hash-table? 1 3) ;; ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;; Misc (test #t string? (version)) (test #t string? (banner)) (test #t symbol? (system-type)) (test (system-type) system-type 'os) (test #t string? (system-type 'machine)) (test #t symbol? (system-type 'link)) (test #t relative-path? (system-library-subpath)) (test #t 'cmdline (let ([v (current-command-line-arguments)]) (and (vector? v) (andmap string? (vector->list v))))) (err/rt-test (current-command-line-arguments '("a"))) (err/rt-test (current-command-line-arguments #("a" 1))) (arity-test version 0 0) (arity-test banner 0 0) (arity-test system-type 0 1) (arity-test system-library-subpath 0 1) (arity-test current-command-line-arguments 0 1) ;; ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;; procedure-closure-contents-eq? (for-each (lambda (jit?) (parameterize ([eval-jit-enabled jit?]) (let ([f #f]) (set! f (eval '(lambda (x) (lambda () x)))) ((f 'c)) ; forced JIT compilation (test #t procedure-closure-contents-eq? (f 'a) (f 'a)) (test #f procedure-closure-contents-eq? (f 'a) (f 'b)) (set! f (eval '(case-lambda [(x) (lambda () 12)] [(x y) (lambda () (list x y))]))) ((f 'c)) ; forces JIT compilation ((f 'c 'd)) ; forces JIT compilation (test #t procedure-closure-contents-eq? (f 'a) (f 'a)) (test #t procedure-closure-contents-eq? (f 'a 'b) (f 'a 'b)) (test #f procedure-closure-contents-eq? (f 'a 'b) (f 'c 'b))))) '(#t #f)) (test #t procedure-closure-contents-eq? add1 add1) ;; ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; (report-errs) "last item in file"