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guile-bootstrap / guile /test-suite /tests /srfi-1.test
mike dupont
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 ;;;; srfi-1.test --- Test suite for Guile's SRFI-1 functions. -*- scheme -*-
;;;;
;;;; Copyright 2003-2006, 2008-2011, 2014, 2020 Free Software Foundation, Inc.
;;;;
;;;; This library is free software; you can redistribute it and/or
;;;; modify it under the terms of the GNU Lesser General Public
;;;; License as published by the Free Software Foundation; either
;;;; version 3 of the License, or (at your option) any later version.
;;;;
;;;; This library is distributed in the hope that it will be useful,
;;;; but WITHOUT ANY WARRANTY; without even the implied warranty of
;;;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
;;;; Lesser General Public License for more details.
;;;;
;;;; You should have received a copy of the GNU Lesser General Public
;;;; License along with this library; if not, write to the Free Software
;;;; Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
(define-module (test-srfi-1)
#:use-module (test-suite lib)
#:use-module (ice-9 copy-tree)
#:use-module (srfi srfi-1))
(define (ref-delete x lst . proc)
"Reference implemenation of srfi-1 `delete'."
(set! proc (if (null? proc) equal? (car proc)))
(do ((ret '())
(lst lst (cdr lst)))
((null? lst)
(reverse! ret))
(if (not (proc x (car lst)))
(set! ret (cons (car lst) ret)))))
(define (ref-delete-duplicates lst . proc)
"Reference implemenation of srfi-1 `delete-duplicates'."
(set! proc (if (null? proc) equal? (car proc)))
(if (null? lst)
'()
(do ((keep '()))
((null? lst)
(reverse! keep))
(let ((elem (car lst)))
(set! keep (cons elem keep))
(set! lst (ref-delete elem lst proc))))))
;;
;; alist-copy
;;
(with-test-prefix "alist-copy"
;; return a list which is the pairs making up alist A, the spine and cells
(define (alist-pairs a)
(let more ((a a)
(result a))
(if (pair? a)
(more (cdr a) (cons a result))
result)))
;; return a list of the elements common to lists X and Y, compared with eq?
(define (common-elements x y)
(if (null? x)
'()
(if (memq (car x) y)
(cons (car x) (common-elements (cdr x) y))
(common-elements (cdr x) y))))
;; validate an alist-copy of OLD to NEW
;; lists must be equal, and must comprise new pairs
(define (valid-alist-copy? old new)
(and (equal? old new)
(null? (common-elements old new))))
(pass-if-exception "too few args" exception:wrong-num-args
(alist-copy))
(pass-if-exception "too many args" exception:wrong-num-args
(alist-copy '() '()))
(let ((old '()))
(pass-if old (valid-alist-copy? old (alist-copy old))))
(let ((old '((1 . 2))))
(pass-if old (valid-alist-copy? old (alist-copy old))))
(let ((old '((1 . 2) (3 . 4))))
(pass-if old (valid-alist-copy? old (alist-copy old))))
(let ((old '((1 . 2) (3 . 4) (5 . 6))))
(pass-if old (valid-alist-copy? old (alist-copy old)))))
;;
;; alist-delete
;;
(with-test-prefix "alist-delete"
(pass-if "equality call arg order"
(let ((good #f))
(alist-delete 'k '((ak . 123))
(lambda (k ak)
(if (and (eq? k 'k) (eq? ak 'ak))
(set! good #t))))
good))
(pass-if "delete keys greater than 5"
(equal? '((4 . x) (5 . y))
(alist-delete 5 '((4 . x) (5 . y) (6 . z)) <)))
(pass-if "empty"
(equal? '() (alist-delete 'x '())))
(pass-if "(y)"
(equal? '() (alist-delete 'y '((y . 1)))))
(pass-if "(n)"
(equal? '((n . 1)) (alist-delete 'y '((n . 1)))))
(pass-if "(y y)"
(equal? '() (alist-delete 'y '((y . 1) (y . 2)))))
(pass-if "(n y)"
(equal? '((n . 1)) (alist-delete 'y '((n . 1) (y . 2)))))
(pass-if "(y n)"
(equal? '((n . 2)) (alist-delete 'y '((y . 1) (n . 2)))))
(pass-if "(n n)"
(equal? '((n . 1) (n . 2)) (alist-delete 'y '((n . 1) (n . 2)))))
(pass-if "(y y y)"
(equal? '() (alist-delete 'y '((y . 1) (y . 2) (y . 3)))))
(pass-if "(n y y)"
(equal? '((n . 1)) (alist-delete 'y '((n . 1) (y . 2) (y . 3)))))
(pass-if "(y n y)"
(equal? '((n . 2)) (alist-delete 'y '((y . 1) (n . 2) (y . 3)))))
(pass-if "(n n y)"
(equal? '((n . 1) (n . 2)) (alist-delete 'y '((n . 1) (n . 2) (y . 3)))))
(pass-if "(y y n)"
(equal? '( (n . 3)) (alist-delete 'y '((y . 1) (y . 2) (n . 3)))))
(pass-if "(n y n)"
(equal? '((n . 1) (n . 3)) (alist-delete 'y '((n . 1) (y . 2) (n . 3)))))
(pass-if "(y n n)"
(equal? '((n . 2) (n . 3)) (alist-delete 'y '((y . 1) (n . 2) (n . 3)))))
(pass-if "(n n n)"
(equal? '((n . 1) (n . 2) (n . 3)) (alist-delete 'y '((n . 1) (n . 2) (n . 3))))))
;;
;; append-map
;;
(with-test-prefix "append-map"
(with-test-prefix "one list"
(pass-if "()"
(equal? '() (append-map noop '(()))))
(pass-if "(1)"
(equal? '(1) (append-map noop '((1)))))
(pass-if "(1 2)"
(equal? '(1 2) (append-map noop '((1 2)))))
(pass-if "() ()"
(equal? '() (append-map noop '(() ()))))
(pass-if "() (1)"
(equal? '(1) (append-map noop '(() (1)))))
(pass-if "() (1 2)"
(equal? '(1 2) (append-map noop '(() (1 2)))))
(pass-if "(1) (2)"
(equal? '(1 2) (append-map noop '((1) (2)))))
(pass-if "(1 2) ()"
(equal? '(1 2) (append-map noop '(() (1 2))))))
(with-test-prefix "two lists"
(pass-if "() / 9"
(equal? '() (append-map noop '(()) '(9))))
(pass-if "(1) / 9"
(equal? '(1) (append-map noop '((1)) '(9))))
(pass-if "() () / 9 9"
(equal? '() (append-map noop '(() ()) '(9 9))))
(pass-if "(1) (2) / 9"
(equal? '(1) (append-map noop '((1) (2)) '(9))))
(pass-if "(1) (2) / 9 9"
(equal? '(1 2) (append-map noop '((1) (2)) '(9 9))))))
;;
;; append-reverse
;;
(with-test-prefix "append-reverse"
;; return a list which is the cars and cdrs of LST
(define (list-contents lst)
(if (null? lst)
'()
(cons* (car lst) (cdr lst) (list-contents (cdr lst)))))
(define (valid-append-reverse revhead tail want)
(let ((revhead-contents (list-contents revhead))
(got (append-reverse revhead tail)))
(and (equal? got want)
;; revhead unchanged
(equal? revhead-contents (list-contents revhead)))))
(pass-if-exception "too few args (0)" exception:wrong-num-args
(append-reverse))
(pass-if-exception "too few args (1)" exception:wrong-num-args
(append-reverse '(x)))
(pass-if-exception "too many args (3)" exception:wrong-num-args
(append-reverse '() '() #f))
(pass-if (valid-append-reverse '() '() '()))
(pass-if (valid-append-reverse '() '(1 2 3) '(1 2 3)))
(pass-if (valid-append-reverse '(1) '() '(1)))
(pass-if (valid-append-reverse '(1) '(2) '(1 2)))
(pass-if (valid-append-reverse '(1) '(2 3) '(1 2 3)))
(pass-if (valid-append-reverse '(1 2) '() '(2 1)))
(pass-if (valid-append-reverse '(1 2) '(3) '(2 1 3)))
(pass-if (valid-append-reverse '(1 2) '(3 4) '(2 1 3 4)))
(pass-if (valid-append-reverse '(1 2 3) '() '(3 2 1)))
(pass-if (valid-append-reverse '(1 2 3) '(4) '(3 2 1 4)))
(pass-if (valid-append-reverse '(1 2 3) '(4 5) '(3 2 1 4 5))))
;;
;; append-reverse!
;;
(with-test-prefix "append-reverse!"
(pass-if-exception "too few args (0)" exception:wrong-num-args
(append-reverse!))
(pass-if-exception "too few args (1)" exception:wrong-num-args
(append-reverse! '(x)))
(pass-if-exception "too many args (3)" exception:wrong-num-args
(append-reverse! '() '() #f))
(pass-if (equal? '() (append-reverse! '() '())))
(pass-if (equal? '(1 2 3) (append-reverse! '() '(1 2 3))))
(pass-if (equal? '(1) (append-reverse! '(1) '())))
(pass-if (equal? '(1 2) (append-reverse! '(1) '(2))))
(pass-if (equal? '(1 2 3) (append-reverse! '(1) '(2 3))))
(pass-if (equal? '(2 1) (append-reverse! '(1 2) '())))
(pass-if (equal? '(2 1 3) (append-reverse! '(1 2) '(3))))
(pass-if (equal? '(2 1 3 4) (append-reverse! '(1 2) '(3 4))))
(pass-if (equal? '(3 2 1) (append-reverse! '(1 2 3) '())))
(pass-if (equal? '(3 2 1 4) (append-reverse! '(1 2 3) '(4))))
(pass-if (equal? '(3 2 1 4 5) (append-reverse! '(1 2 3) '(4 5)))))
;;
;; assoc
;;
(with-test-prefix "assoc"
(pass-if "not found"
(let ((alist '((a . 1)
(b . 2)
(c . 3))))
(eqv? #f (assoc 'z alist))))
(pass-if "found"
(let ((alist '((a . 1)
(b . 2)
(c . 3))))
(eqv? (second alist) (assoc 'b alist))))
;; this was wrong in guile 1.8.0 (a gremlin newly introduced in the 1.8
;; series, 1.6.x and earlier was ok)
(pass-if "= arg order"
(let ((alist '((b . 1)))
(good #f))
(assoc 'a alist (lambda (x y)
(set! good (and (eq? x 'a)
(eq? y 'b)))))
good))
;; likewise this one bad in guile 1.8.0
(pass-if "srfi-1 example <"
(let ((alist '((1 . a)
(5 . b)
(6 . c))))
(eq? (third alist) (assoc 5 alist <)))))
;;
;; break
;;
(with-test-prefix "break"
(define (test-break lst want-v1 want-v2)
(call-with-values
(lambda ()
(break negative? lst))
(lambda (got-v1 got-v2)
(and (equal? got-v1 want-v1)
(equal? got-v2 want-v2)))))
(pass-if "empty"
(test-break '() '() '()))
(pass-if "y"
(test-break '(1) '(1) '()))
(pass-if "n"
(test-break '(-1) '() '(-1)))
(pass-if "yy"
(test-break '(1 2) '(1 2) '()))
(pass-if "ny"
(test-break '(-1 1) '() '(-1 1)))
(pass-if "yn"
(test-break '(1 -1) '(1) '(-1)))
(pass-if "nn"
(test-break '(-1 -2) '() '(-1 -2)))
(pass-if "yyy"
(test-break '(1 2 3) '(1 2 3) '()))
(pass-if "nyy"
(test-break '(-1 1 2) '() '(-1 1 2)))
(pass-if "yny"
(test-break '(1 -1 2) '(1) '(-1 2)))
(pass-if "nny"
(test-break '(-1 -2 1) '() '(-1 -2 1)))
(pass-if "yyn"
(test-break '(1 2 -1) '(1 2) '(-1)))
(pass-if "nyn"
(test-break '(-1 1 -2) '() '(-1 1 -2)))
(pass-if "ynn"
(test-break '(1 -1 -2) '(1) '(-1 -2)))
(pass-if "nnn"
(test-break '(-1 -2 -3) '() '(-1 -2 -3))))
;;
;; break!
;;
(with-test-prefix "break!"
(define (test-break! lst want-v1 want-v2)
(call-with-values
(lambda ()
(break! negative? lst))
(lambda (got-v1 got-v2)
(and (equal? got-v1 want-v1)
(equal? got-v2 want-v2)))))
(pass-if "empty"
(test-break! '() '() '()))
(pass-if "y"
(test-break! (list 1) '(1) '()))
(pass-if "n"
(test-break! (list -1) '() '(-1)))
(pass-if "yy"
(test-break! (list 1 2) '(1 2) '()))
(pass-if "ny"
(test-break! (list -1 1) '() '(-1 1)))
(pass-if "yn"
(test-break! (list 1 -1) '(1) '(-1)))
(pass-if "nn"
(test-break! (list -1 -2) '() '(-1 -2)))
(pass-if "yyy"
(test-break! (list 1 2 3) '(1 2 3) '()))
(pass-if "nyy"
(test-break! (list -1 1 2) '() '(-1 1 2)))
(pass-if "yny"
(test-break! (list 1 -1 2) '(1) '(-1 2)))
(pass-if "nny"
(test-break! (list -1 -2 1) '() '(-1 -2 1)))
(pass-if "yyn"
(test-break! (list 1 2 -1) '(1 2) '(-1)))
(pass-if "nyn"
(test-break! (list -1 1 -2) '() '(-1 1 -2)))
(pass-if "ynn"
(test-break! (list 1 -1 -2) '(1) '(-1 -2)))
(pass-if "nnn"
(test-break! (list -1 -2 -3) '() '(-1 -2 -3))))
;;
;; car+cdr
;;
(with-test-prefix "car+cdr"
(pass-if "(1 . 2)"
(call-with-values
(lambda ()
(car+cdr '(1 . 2)))
(lambda (x y)
(and (eqv? x 1)
(eqv? y 2))))))
;;
;; concatenate and concatenate!
;;
(let ()
(define (common-tests concatenate-proc unmodified?)
(define (try lstlst want)
(let ((lstlst-copy (copy-tree lstlst))
(got (concatenate-proc lstlst)))
(if unmodified?
(if (not (equal? lstlst lstlst-copy))
(error "input lists modified")))
(equal? got want)))
(pass-if-exception "too few args" exception:wrong-num-args
(concatenate-proc))
(pass-if-exception "too many args" exception:wrong-num-args
(concatenate-proc '() '()))
(pass-if-exception "number" exception:wrong-type-arg
(concatenate-proc 123))
(pass-if-exception "vector" exception:wrong-type-arg
(concatenate-proc #(1 2 3)))
(pass-if "no lists"
(try '() '()))
(pass-if (try '((1)) '(1)))
(pass-if (try '((1 2)) '(1 2)))
(pass-if (try '(() (1)) '(1)))
(pass-if (try '(() () (1)) '(1)))
(pass-if (try '((1) (2)) '(1 2)))
(pass-if (try '(() (1 2)) '(1 2)))
(pass-if (try '((1) 2) '(1 . 2)))
(pass-if (try '((1) (2) 3) '(1 2 . 3)))
(pass-if (try '((1) (2) (3 . 4)) '(1 2 3 . 4)))
)
(with-test-prefix "concatenate"
(common-tests concatenate #t))
(with-test-prefix "concatenate!"
(common-tests concatenate! #f)))
;;
;; count
;;
(with-test-prefix "count"
(pass-if-exception "no args" exception:wrong-num-args
(count))
(pass-if-exception "one arg" exception:wrong-num-args
(count noop))
(with-test-prefix "one list"
(define (or1 x)
x)
(pass-if "empty list" (= 0 (count or1 '())))
(pass-if-exception "pred arg count 0" exception:wrong-num-args
(count (lambda () x) '(1 2 3)))
(pass-if-exception "pred arg count 2" exception:wrong-num-args
(count (lambda (x y) x) '(1 2 3)))
(pass-if-exception "improper 1" exception:wrong-type-arg
(count or1 1))
(pass-if-exception "improper 2" exception:wrong-type-arg
(count or1 '(1 . 2)))
(pass-if-exception "improper 3" exception:wrong-type-arg
(count or1 '(1 2 . 3)))
(pass-if (= 0 (count or1 '(#f))))
(pass-if (= 1 (count or1 '(#t))))
(pass-if (= 0 (count or1 '(#f #f))))
(pass-if (= 1 (count or1 '(#f #t))))
(pass-if (= 1 (count or1 '(#t #f))))
(pass-if (= 2 (count or1 '(#t #t))))
(pass-if (= 0 (count or1 '(#f #f #f))))
(pass-if (= 1 (count or1 '(#f #f #t))))
(pass-if (= 1 (count or1 '(#t #f #f))))
(pass-if (= 2 (count or1 '(#t #f #t))))
(pass-if (= 3 (count or1 '(#t #t #t)))))
(with-test-prefix "two lists"
(define (or2 x y)
(or x y))
(pass-if "arg order"
(= 1 (count (lambda (x y)
(and (= 1 x)
(= 2 y)))
'(1) '(2))))
(pass-if "empty lists" (= 0 (count or2 '() '())))
(pass-if-exception "pred arg count 0" exception:wrong-num-args
(count (lambda () #t) '(1 2 3) '(1 2 3)))
(pass-if-exception "pred arg count 1" exception:wrong-num-args
(count (lambda (x) x) '(1 2 3) '(1 2 3)))
(pass-if-exception "pred arg count 3" exception:wrong-num-args
(count (lambda (x y z) x) '(1 2 3) '(1 2 3)))
(pass-if-exception "improper first 1" exception:wrong-type-arg
(count or2 1 '(1 2 3)))
(pass-if-exception "improper first 2" exception:wrong-type-arg
(count or2 '(1 . 2) '(1 2 3)))
(pass-if-exception "improper first 3" exception:wrong-type-arg
(count or2 '(1 2 . 3) '(1 2 3)))
(pass-if-exception "improper second 1" exception:wrong-type-arg
(count or2 '(1 2 3) 1))
(pass-if-exception "improper second 2" exception:wrong-type-arg
(count or2 '(1 2 3) '(1 . 2)))
(pass-if-exception "improper second 3" exception:wrong-type-arg
(count or2 '(1 2 3) '(1 2 . 3)))
(pass-if (= 0 (count or2 '(#f) '(#f))))
(pass-if (= 1 (count or2 '(#t) '(#f))))
(pass-if (= 1 (count or2 '(#f) '(#t))))
(pass-if (= 0 (count or2 '(#f #f) '(#f #f))))
(pass-if (= 1 (count or2 '(#t #f) '(#t #f))))
(pass-if (= 2 (count or2 '(#t #t) '(#f #f))))
(pass-if (= 2 (count or2 '(#t #f) '(#f #t))))
(with-test-prefix "stop shortest"
(pass-if (= 2 (count or2 '(#t #f #t) '(#f #t))))
(pass-if (= 2 (count or2 '(#t #f #t #t) '(#f #t))))
(pass-if (= 2 (count or2 '(#t #f) '(#f #t #t))))
(pass-if (= 2 (count or2 '(#t #f) '(#f #t #t #t))))))
(with-test-prefix "three lists"
(define (or3 x y z)
(or x y z))
(pass-if "arg order"
(= 1 (count (lambda (x y z)
(and (= 1 x)
(= 2 y)
(= 3 z)))
'(1) '(2) '(3))))
(pass-if "empty lists" (= 0 (count or3 '() '() '())))
;; currently bad pred argument gives wrong-num-args when 3 or more
;; lists, as opposed to wrong-type-arg for 1 or 2 lists
(pass-if-exception "pred arg count 0" exception:wrong-num-args
(count (lambda () #t) '(1 2 3) '(1 2 3) '(1 2 3)))
(pass-if-exception "pred arg count 2" exception:wrong-num-args
(count (lambda (x y) x) '(1 2 3) '(1 2 3)'(1 2 3) ))
(pass-if-exception "pred arg count 4" exception:wrong-num-args
(count (lambda (w x y z) x) '(1 2 3) '(1 2 3) '(1 2 3)))
(pass-if-exception "improper first 1" exception:wrong-type-arg
(count or3 1 '(1 2 3) '(1 2 3)))
(pass-if-exception "improper first 2" exception:wrong-type-arg
(count or3 '(1 . 2) '(1 2 3) '(1 2 3)))
(pass-if-exception "improper first 3" exception:wrong-type-arg
(count or3 '(1 2 . 3) '(1 2 3) '(1 2 3)))
(pass-if-exception "improper second 1" exception:wrong-type-arg
(count or3 '(1 2 3) 1 '(1 2 3)))
(pass-if-exception "improper second 2" exception:wrong-type-arg
(count or3 '(1 2 3) '(1 . 2) '(1 2 3)))
(pass-if-exception "improper second 3" exception:wrong-type-arg
(count or3 '(1 2 3) '(1 2 . 3) '(1 2 3)))
(pass-if-exception "improper third 1" exception:wrong-type-arg
(count or3 '(1 2 3) '(1 2 3) 1))
(pass-if-exception "improper third 2" exception:wrong-type-arg
(count or3 '(1 2 3) '(1 2 3) '(1 . 2)))
(pass-if-exception "improper third 3" exception:wrong-type-arg
(count or3 '(1 2 3) '(1 2 3) '(1 2 . 3)))
(pass-if (= 0 (count or3 '(#f) '(#f) '(#f))))
(pass-if (= 1 (count or3 '(#t) '(#f) '(#f))))
(pass-if (= 1 (count or3 '(#f) '(#t) '(#f))))
(pass-if (= 1 (count or3 '(#f) '(#f) '(#t))))
(pass-if (= 0 (count or3 '(#f #f) '(#f #f) '(#f #f))))
(pass-if (= 1 (count or3 '(#t #f) '(#f #f) '(#f #f))))
(pass-if (= 1 (count or3 '(#f #t) '(#f #f) '(#f #f))))
(pass-if (= 1 (count or3 '(#f #f) '(#t #f) '(#f #f))))
(pass-if (= 1 (count or3 '(#f #f) '(#f #t) '(#f #f))))
(pass-if (= 1 (count or3 '(#f #f) '(#f #f) '(#t #f))))
(pass-if (= 1 (count or3 '(#f #f) '(#f #f) '(#f #t))))
(pass-if (= 2 (count or3 '(#t #t) '(#f #f) '(#f #f))))
(pass-if (= 2 (count or3 '(#f #f) '(#t #t) '(#f #f))))
(pass-if (= 2 (count or3 '(#f #f) '(#f #f) '(#t #t))))
(pass-if (= 2 (count or3 '(#f #f) '(#t #f) '(#f #t))))
(with-test-prefix "stop shortest"
(pass-if (= 0 (count or3 '() '(#t #t #t) '(#t #t))))
(pass-if (= 0 (count or3 '(#t #t #t) '() '(#t #t))))
(pass-if (= 0 (count or3 '(#t #t #t) '(#t #t) '())))
(pass-if (= 1 (count or3 '(#t) '(#t #t #t) '(#t #t))))
(pass-if (= 1 (count or3 '(#t #t #t) '(#t) '(#t #t))))
(pass-if (= 1 (count or3 '(#t #t #t) '(#t #t) '(#t)))))
(pass-if "apply list unchanged"
(let ((lst (list (list 1 2) (list 3 4) (list 5 6))))
(and (equal? 2 (apply count or3 lst))
;; lst unmodified
(equal? '((1 2) (3 4) (5 6)) lst))))))
;;
;; delete and delete!
;;
(let ()
;; Call (PROC lst) for all lists of length up to 6, with all combinations
;; of elements to be retained or deleted. Elements to retain are numbers,
;; 0 upwards. Elements to be deleted are #f.
(define (test-lists proc)
(do ((n 0 (1+ n)))
((>= n 6))
(do ((limit (ash 1 n))
(i 0 (1+ i)))
((>= i limit))
(let ((lst '()))
(do ((bit 0 (1+ bit)))
((>= bit n))
(set! lst (cons (if (logbit? bit i) bit #f) lst)))
(proc lst)))))
(define (common-tests delete-proc)
(pass-if-exception "too few args" exception:wrong-num-args
(delete-proc 0))
(pass-if-exception "too many args" exception:wrong-num-args
(delete-proc 0 '() equal? 99))
(pass-if "empty"
(eq? '() (delete-proc 0 '() equal?)))
(pass-if "equal?"
(equal? '((1) (3))
(delete-proc '(2) '((1) (2) (3)) equal?)))
(pass-if "eq?"
(equal? '((1) (2) (3))
(delete-proc '(2) '((1) (2) (3)) eq?)))
(pass-if "called arg order"
(equal? '(1 2 3)
(delete-proc 3 '(1 2 3 4 5) <))))
(with-test-prefix "delete"
(common-tests delete)
(test-lists
(lambda (lst)
(let ((lst-copy (list-copy lst)))
(with-test-prefix lst-copy
(pass-if "result"
(equal? (delete #f lst equal?)
(ref-delete #f lst equal?)))
(pass-if "non-destructive"
(equal? lst-copy lst)))))))
(with-test-prefix "delete!"
(common-tests delete!)
(test-lists
(lambda (lst)
(pass-if lst
(equal? (delete! #f lst)
(ref-delete #f lst)))))))
;;
;; delete-duplicates and delete-duplicates!
;;
(let ()
;; Call (PROC lst) for all lists of length 1 <= n <= 4, with all
;; combinations of numbers 1 to n in the elements
(define (test-lists proc)
(do ((n 1 (1+ n)))
((> n 4))
(do ((limit (integer-expt n n))
(i 0 (1+ i)))
((>= i limit))
(let ((lst '()))
(do ((j 0 (1+ j))
(rem i (quotient rem n)))
((>= j n))
(set! lst (cons (remainder rem n) lst)))
(proc lst)))))
(define (common-tests delete-duplicates-proc)
(pass-if-exception "too few args" exception:wrong-num-args
(delete-duplicates-proc))
(pass-if-exception "too many args" exception:wrong-num-args
(delete-duplicates-proc '() equal? 99))
(pass-if "empty"
(eq? '() (delete-duplicates-proc '())))
(pass-if "equal? (the default)"
(equal? '((2))
(delete-duplicates-proc '((2) (2) (2)))))
(pass-if "eq?"
(equal? '((2) (2) (2))
(delete-duplicates-proc '((2) (2) (2)) eq?)))
(pass-if "called arg order"
(let ((ok #t))
(delete-duplicates-proc '(1 2 3 4 5)
(lambda (x y)
(if (> x y)
(set! ok #f))
#f))
ok)))
(with-test-prefix "delete-duplicates"
(common-tests delete-duplicates)
(test-lists
(lambda (lst)
(let ((lst-copy (list-copy lst)))
(with-test-prefix lst-copy
(pass-if "result"
(equal? (delete-duplicates lst)
(ref-delete-duplicates lst)))
(pass-if "non-destructive"
(equal? lst-copy lst)))))))
(with-test-prefix "delete-duplicates!"
(common-tests delete-duplicates!)
(test-lists
(lambda (lst)
(pass-if lst
(equal? (delete-duplicates! lst)
(ref-delete-duplicates lst)))))))
;;
;; drop
;;
(with-test-prefix "drop"
(pass-if "'() 0"
(null? (drop '() 0)))
(pass-if "'(a) 0"
(let ((lst '(a)))
(eq? lst
(drop lst 0))))
(pass-if "'(a b) 0"
(let ((lst '(a b)))
(eq? lst
(drop lst 0))))
(pass-if "'(a) 1"
(let ((lst '(a)))
(eq? (cdr lst)
(drop lst 1))))
(pass-if "'(a b) 1"
(let ((lst '(a b)))
(eq? (cdr lst)
(drop lst 1))))
(pass-if "'(a b) 2"
(let ((lst '(a b)))
(eq? (cddr lst)
(drop lst 2))))
(pass-if "'(a b c) 1"
(let ((lst '(a b c)))
(eq? (cddr lst)
(drop lst 2))))
(pass-if "circular '(a) 0"
(let ((lst (circular-list 'a)))
(eq? lst
(drop lst 0))))
(pass-if "circular '(a) 1"
(let ((lst (circular-list 'a)))
(eq? lst
(drop lst 1))))
(pass-if "circular '(a) 2"
(let ((lst (circular-list 'a)))
(eq? lst
(drop lst 1))))
(pass-if "circular '(a b) 1"
(let ((lst (circular-list 'a)))
(eq? (cdr lst)
(drop lst 0))))
(pass-if "circular '(a b) 2"
(let ((lst (circular-list 'a)))
(eq? lst
(drop lst 1))))
(pass-if "circular '(a b) 5"
(let ((lst (circular-list 'a)))
(eq? (cdr lst)
(drop lst 5))))
(pass-if "'(a . b) 1"
(eq? 'b
(drop '(a . b) 1)))
(pass-if "'(a b . c) 1"
(equal? 'c
(drop '(a b . c) 2))))
;;
;; drop-right
;;
(with-test-prefix "drop-right"
(pass-if-exception "() -1" exception:out-of-range
(drop-right '() -1))
(pass-if (equal? '() (drop-right '() 0)))
(pass-if-exception "() 1" exception:wrong-type-arg
(drop-right '() 1))
(pass-if-exception "(1) -1" exception:out-of-range
(drop-right '(1) -1))
(pass-if (equal? '(1) (drop-right '(1) 0)))
(pass-if (equal? '() (drop-right '(1) 1)))
(pass-if-exception "(1) 2" exception:wrong-type-arg
(drop-right '(1) 2))
(pass-if-exception "(4 5) -1" exception:out-of-range
(drop-right '(4 5) -1))
(pass-if (equal? '(4 5) (drop-right '(4 5) 0)))
(pass-if (equal? '(4) (drop-right '(4 5) 1)))
(pass-if (equal? '() (drop-right '(4 5) 2)))
(pass-if-exception "(4 5) 3" exception:wrong-type-arg
(drop-right '(4 5) 3))
(pass-if-exception "(4 5 6) -1" exception:out-of-range
(drop-right '(4 5 6) -1))
(pass-if (equal? '(4 5 6) (drop-right '(4 5 6) 0)))
(pass-if (equal? '(4 5) (drop-right '(4 5 6) 1)))
(pass-if (equal? '(4) (drop-right '(4 5 6) 2)))
(pass-if (equal? '() (drop-right '(4 5 6) 3)))
(pass-if-exception "(4 5 6) 4" exception:wrong-type-arg
(drop-right '(4 5 6) 4))
(pass-if "(a b . c) 0"
(equal? (drop-right '(a b . c) 0) '(a b)))
(pass-if "(a b . c) 1"
(equal? (drop-right '(a b . c) 1) '(a))))
;;
;; drop-right!
;;
(with-test-prefix "drop-right!"
(pass-if-exception "() -1" exception:out-of-range
(drop-right! '() -1))
(pass-if (equal? '() (drop-right! '() 0)))
(pass-if-exception "() 1" exception:wrong-type-arg
(drop-right! '() 1))
(pass-if-exception "(1) -1" exception:out-of-range
(drop-right! (list 1) -1))
(pass-if (equal? '(1) (drop-right! (list 1) 0)))
(pass-if (equal? '() (drop-right! (list 1) 1)))
(pass-if-exception "(1) 2" exception:wrong-type-arg
(drop-right! (list 1) 2))
(pass-if-exception "(4 5) -1" exception:out-of-range
(drop-right! (list 4 5) -1))
(pass-if (equal? '(4 5) (drop-right! (list 4 5) 0)))
(pass-if (equal? '(4) (drop-right! (list 4 5) 1)))
(pass-if (equal? '() (drop-right! (list 4 5) 2)))
(pass-if-exception "(4 5) 3" exception:wrong-type-arg
(drop-right! (list 4 5) 3))
(pass-if-exception "(4 5 6) -1" exception:out-of-range
(drop-right! (list 4 5 6) -1))
(pass-if (equal? '(4 5 6) (drop-right! (list 4 5 6) 0)))
(pass-if (equal? '(4 5) (drop-right! (list 4 5 6) 1)))
(pass-if (equal? '(4) (drop-right! (list 4 5 6) 2)))
(pass-if (equal? '() (drop-right! (list 4 5 6) 3)))
(pass-if-exception "(4 5 6) 4" exception:wrong-type-arg
(drop-right! (list 4 5 6) 4)))
;;
;; drop-while
;;
(with-test-prefix "drop-while"
(pass-if (equal? '() (drop-while odd? '())))
(pass-if (equal? '() (drop-while odd? '(1))))
(pass-if (equal? '() (drop-while odd? '(1 3))))
(pass-if (equal? '() (drop-while odd? '(1 3 5))))
(pass-if (equal? '(2) (drop-while odd? '(2))))
(pass-if (equal? '(2) (drop-while odd? '(1 2))))
(pass-if (equal? '(4) (drop-while odd? '(1 3 4))))
(pass-if (equal? '(2 1) (drop-while odd? '(2 1))))
(pass-if (equal? '(4 3) (drop-while odd? '(1 4 3))))
(pass-if (equal? '(4 1 3) (drop-while odd? '(4 1 3)))))
;;
;; eighth
;;
(with-test-prefix "eighth"
(pass-if-exception "() -1" exception:wrong-type-arg
(eighth '(a b c d e f g)))
(pass-if (eq? 'h (eighth '(a b c d e f g h))))
(pass-if (eq? 'h (eighth '(a b c d e f g h i)))))
;;
;; fifth
;;
(with-test-prefix "fifth"
(pass-if-exception "() -1" exception:wrong-type-arg
(fifth '(a b c d)))
(pass-if (eq? 'e (fifth '(a b c d e))))
(pass-if (eq? 'e (fifth '(a b c d e f)))))
;;
;; filter-map
;;
(with-test-prefix "filter-map"
(with-test-prefix "one list"
(pass-if-exception "'x" exception:wrong-type-arg
(filter-map noop 'x))
(pass-if-exception "'(1 . x)" exception:wrong-type-arg
(filter-map noop '(1 . x)))
(pass-if "(1)"
(equal? '(1) (filter-map noop '(1))))
(pass-if "(#f)"
(equal? '() (filter-map noop '(#f))))
(pass-if "(1 2)"
(equal? '(1 2) (filter-map noop '(1 2))))
(pass-if "(#f 2)"
(equal? '(2) (filter-map noop '(#f 2))))
(pass-if "(#f #f)"
(equal? '() (filter-map noop '(#f #f))))
(pass-if "(1 2 3)"
(equal? '(1 2 3) (filter-map noop '(1 2 3))))
(pass-if "(#f 2 3)"
(equal? '(2 3) (filter-map noop '(#f 2 3))))
(pass-if "(1 #f 3)"
(equal? '(1 3) (filter-map noop '(1 #f 3))))
(pass-if "(1 2 #f)"
(equal? '(1 2) (filter-map noop '(1 2 #f)))))
(with-test-prefix "two lists"
(pass-if-exception "'x '(1 2 3)" exception:wrong-type-arg
(filter-map noop 'x '(1 2 3)))
(pass-if-exception "'(1 2 3) 'x" exception:wrong-type-arg
(filter-map noop '(1 2 3) 'x))
(pass-if-exception "'(1 . x) '(1 2 3)" exception:wrong-type-arg
(filter-map noop '(1 . x) '(1 2 3)))
(pass-if-exception "'(1 2 3) '(1 . x)" exception:wrong-type-arg
(filter-map noop '(1 2 3) '(1 . x)))
(pass-if "(1 2 3) (4 5 6)"
(equal? '(5 7 9) (filter-map + '(1 2 3) '(4 5 6))))
(pass-if "(#f 2 3) (4 5)"
(equal? '(2) (filter-map noop '(#f 2 3) '(4 5))))
(pass-if "(4 #f) (1 2 3)"
(equal? '(4) (filter-map noop '(4 #f) '(1 2 3))))
(pass-if "() (1 2 3)"
(equal? '() (filter-map noop '() '(1 2 3))))
(pass-if "(1 2 3) ()"
(equal? '() (filter-map noop '(1 2 3) '()))))
(with-test-prefix "three lists"
(pass-if-exception "'x '(1 2 3) '(1 2 3)" exception:wrong-type-arg
(filter-map noop 'x '(1 2 3) '(1 2 3)))
(pass-if-exception "'(1 2 3) 'x '(1 2 3)" exception:wrong-type-arg
(filter-map noop '(1 2 3) 'x '(1 2 3)))
(pass-if-exception "'(1 2 3) '(1 2 3) 'x" exception:wrong-type-arg
(filter-map noop '(1 2 3) '(1 2 3) 'x))
(pass-if-exception "'(1 . x) '(1 2 3) '(1 2 3)" exception:wrong-type-arg
(filter-map noop '(1 . x) '(1 2 3) '(1 2 3)))
(pass-if-exception "'(1 2 3) '(1 . x) '(1 2 3)" exception:wrong-type-arg
(filter-map noop '(1 2 3) '(1 . x) '(1 2 3)))
(pass-if-exception "'(1 2 3) '(1 2 3) '(1 . x)" exception:wrong-type-arg
(filter-map noop '(1 2 3) '(1 2 3) '(1 . x)))
(pass-if "(1 2 3) (4 5 6) (7 8 9)"
(equal? '(12 15 18) (filter-map + '(1 2 3) '(4 5 6) '(7 8 9))))
(pass-if "(#f 2 3) (4 5) (7 8 9)"
(equal? '(2) (filter-map noop '(#f 2 3) '(4 5) '(7 8 9))))
(pass-if "(#f 2 3) (7 8 9) (4 5)"
(equal? '(2) (filter-map noop '(#f 2 3) '(7 8 9) '(4 5))))
(pass-if "(4 #f) (1 2 3) (7 8 9)"
(equal? '(4) (filter-map noop '(4 #f) '(1 2 3) '(7 8 9))))
(pass-if "apply list unchanged"
(let ((lst (list (list 1 #f 2) (list 3 4 5) (list 6 7 8))))
(and (equal? '(1 2) (apply filter-map noop lst))
;; lst unmodified
(equal? lst '((1 #f 2) (3 4 5) (6 7 8))))))))
;;
;; find
;;
(with-test-prefix "find"
(pass-if (eqv? #f (find odd? '())))
(pass-if (eqv? #f (find odd? '(0))))
(pass-if (eqv? #f (find odd? '(0 2))))
(pass-if (eqv? 1 (find odd? '(1))))
(pass-if (eqv? 1 (find odd? '(0 1))))
(pass-if (eqv? 1 (find odd? '(0 1 2))))
(pass-if (eqv? 1 (find odd? '(2 0 1))))
(pass-if (eqv? 1 (find (lambda (x) (= 1 x)) '(2 0 1)))))
;;
;; find-tail
;;
(with-test-prefix "find-tail"
(pass-if (let ((lst '()))
(eq? #f (find-tail odd? lst))))
(pass-if (let ((lst '(0)))
(eq? #f (find-tail odd? lst))))
(pass-if (let ((lst '(0 2)))
(eq? #f (find-tail odd? lst))))
(pass-if (let ((lst '(1)))
(eq? lst (find-tail odd? lst))))
(pass-if (let ((lst '(1 2)))
(eq? lst (find-tail odd? lst))))
(pass-if (let ((lst '(2 1)))
(eq? (cdr lst) (find-tail odd? lst))))
(pass-if (let ((lst '(2 1 0)))
(eq? (cdr lst) (find-tail odd? lst))))
(pass-if (let ((lst '(2 0 1)))
(eq? (cddr lst) (find-tail odd? lst))))
(pass-if (let ((lst '(2 0 1)))
(eq? (cddr lst) (find-tail (lambda (x) (= 1 x)) lst)))))
;;
;; fold
;;
(with-test-prefix "fold"
(pass-if-exception "no args" exception:wrong-num-args
(fold))
(pass-if-exception "one arg" exception:wrong-num-args
(fold 123))
(pass-if-exception "two args" exception:wrong-num-args
(fold 123 noop))
(with-test-prefix "one list"
(pass-if "arg order"
(eq? #t (fold (lambda (x prev)
(and (= 1 x)
(= 2 prev)))
2 '(1))))
(pass-if "empty list" (= 123 (fold + 123 '())))
(pass-if-exception "proc arg count 0" exception:wrong-num-args
(fold (lambda () x) 123 '(1 2 3)))
(pass-if-exception "proc arg count 1" exception:wrong-num-args
(fold (lambda (x) x) 123 '(1 2 3)))
(pass-if-exception "proc arg count 3" exception:wrong-num-args
(fold (lambda (x y z) x) 123 '(1 2 3)))
(pass-if-exception "improper 1" exception:wrong-type-arg
(fold + 123 1))
(pass-if-exception "improper 2" exception:wrong-type-arg
(fold + 123 '(1 . 2)))
(pass-if-exception "improper 3" exception:wrong-type-arg
(fold + 123 '(1 2 . 3)))
(pass-if (= 3 (fold + 1 '(2))))
(pass-if (= 6 (fold + 1 '(2 3))))
(pass-if (= 10 (fold + 1 '(2 3 4)))))
(with-test-prefix "two lists"
(pass-if "arg order"
(eq? #t (fold (lambda (x y prev)
(and (= 1 x)
(= 2 y)
(= 3 prev)))
3 '(1) '(2))))
(pass-if "empty lists" (= 1 (fold + 1 '() '())))
;; currently bad proc argument gives wrong-num-args when 2 or more
;; lists, as opposed to wrong-type-arg for 1 list
(pass-if-exception "proc arg count 2" exception:wrong-num-args
(fold (lambda (x prev) x) 1 '(1 2 3) '(1 2 3)))
(pass-if-exception "proc arg count 4" exception:wrong-num-args
(fold (lambda (x y z prev) x) 1 '(1 2 3) '(1 2 3)))
(pass-if-exception "improper first 1" exception:wrong-type-arg
(fold + 1 1 '(1 2 3)))
(pass-if-exception "improper first 2" exception:wrong-type-arg
(fold + 1 '(1 . 2) '(1 2 3)))
(pass-if-exception "improper first 3" exception:wrong-type-arg
(fold + 1 '(1 2 . 3) '(1 2 3)))
(pass-if-exception "improper second 1" exception:wrong-type-arg
(fold + 1 '(1 2 3) 1))
(pass-if-exception "improper second 2" exception:wrong-type-arg
(fold + 1 '(1 2 3) '(1 . 2)))
(pass-if-exception "improper second 3" exception:wrong-type-arg
(fold + 1 '(1 2 3) '(1 2 . 3)))
(pass-if (= 6 (fold + 1 '(2) '(3))))
(pass-if (= 15 (fold + 1 '(2 3) '(4 5))))
(pass-if (= 28 (fold + 1 '(2 3 4) '(5 6 7))))
(with-test-prefix "stop shortest"
(pass-if (= 13 (fold + 1 '(1 2 3) '(4 5))))
(pass-if (= 13 (fold + 1 '(4 5) '(1 2 3))))
(pass-if (= 11 (fold + 1 '(3 4) '(1 2 9 9))))
(pass-if (= 11 (fold + 1 '(1 2 9 9) '(3 4)))))
(pass-if "apply list unchanged"
(let ((lst (list (list 1 2) (list 3 4))))
(and (equal? 11 (apply fold + 1 lst))
;; lst unmodified
(equal? '((1 2) (3 4)) lst)))))
(with-test-prefix "three lists"
(pass-if "arg order"
(eq? #t (fold (lambda (x y z prev)
(and (= 1 x)
(= 2 y)
(= 3 z)
(= 4 prev)))
4 '(1) '(2) '(3))))
(pass-if "empty lists" (= 1 (fold + 1 '() '() '())))
(pass-if-exception "proc arg count 3" exception:wrong-num-args
(fold (lambda (x y prev) x) 1 '(1 2 3) '(1 2 3)'(1 2 3) ))
(pass-if-exception "proc arg count 5" exception:wrong-num-args
(fold (lambda (w x y z prev) x) 1 '(1 2 3) '(1 2 3) '(1 2 3)))
(pass-if-exception "improper first 1" exception:wrong-type-arg
(fold + 1 1 '(1 2 3) '(1 2 3)))
(pass-if-exception "improper first 2" exception:wrong-type-arg
(fold + 1 '(1 . 2) '(1 2 3) '(1 2 3)))
(pass-if-exception "improper first 3" exception:wrong-type-arg
(fold + 1 '(1 2 . 3) '(1 2 3) '(1 2 3)))
(pass-if-exception "improper second 1" exception:wrong-type-arg
(fold + 1 '(1 2 3) 1 '(1 2 3)))
(pass-if-exception "improper second 2" exception:wrong-type-arg
(fold + 1 '(1 2 3) '(1 . 2) '(1 2 3)))
(pass-if-exception "improper second 3" exception:wrong-type-arg
(fold + 1 '(1 2 3) '(1 2 . 3) '(1 2 3)))
(pass-if-exception "improper third 1" exception:wrong-type-arg
(fold + 1 '(1 2 3) '(1 2 3) 1))
(pass-if-exception "improper third 2" exception:wrong-type-arg
(fold + 1 '(1 2 3) '(1 2 3) '(1 . 2)))
(pass-if-exception "improper third 3" exception:wrong-type-arg
(fold + 1 '(1 2 3) '(1 2 3) '(1 2 . 3)))
(pass-if (= 10 (fold + 1 '(2) '(3) '(4))))
(pass-if (= 28 (fold + 1 '(2 5) '(3 6) '(4 7))))
(pass-if (= 55 (fold + 1 '(2 5 8) '(3 6 9) '(4 7 10))))
(with-test-prefix "stop shortest"
(pass-if (= 28 (fold + 1 '(2 5 9) '(3 6) '(4 7))))
(pass-if (= 28 (fold + 1 '(2 5) '(3 6 9) '(4 7))))
(pass-if (= 28 (fold + 1 '(2 5) '(3 6) '(4 7 9)))))
(pass-if "apply list unchanged"
(let ((lst (list (list 1 2) (list 3 4) (list 5 6))))
(and (equal? 22 (apply fold + 1 lst))
;; lst unmodified
(equal? '((1 2) (3 4) (5 6)) lst))))))
;;
;; fold-right
;;
(with-test-prefix "fold-right"
(pass-if "one list"
(equal? (iota 10)
(fold-right cons '() (iota 10))))
(pass-if "two lists"
(equal? (zip (iota 10) (map integer->char (iota 10)))
(fold-right (lambda (x y z)
(cons (list x y) z))
'()
(iota 10)
(map integer->char (iota 10)))))
(pass-if "tail-recursive"
(= 1e6 (fold-right (lambda (x y) (+ 1 y))
0
(iota 1e6)))))
;;
;; unfold
;;
(with-test-prefix "unfold"
(pass-if "basic"
(equal? (iota 10)
(unfold (lambda (x) (>= x 10))
identity
1+
0)))
(pass-if "tail-gen"
(equal? (append (iota 10) '(tail 10))
(unfold (lambda (x) (>= x 10))
identity
1+
0
(lambda (seed) (list 'tail seed)))))
(pass-if "tail-recursive"
;; Bug #30071.
(pair? (unfold (lambda (x) (>= x 1e6))
identity
1+
0))))
;;
;; length+
;;
(with-test-prefix "length+"
(pass-if-exception "too few args" exception:wrong-num-args
(length+))
(pass-if-exception "too many args" exception:wrong-num-args
(length+ 123 456))
(pass-if-exception "not a pair" exception:wrong-type-arg
(length+ 'x))
(pass-if-exception "improper list" exception:wrong-type-arg
(length+ '(x y . z)))
(pass-if (= 0 (length+ '())))
(pass-if (= 1 (length+ '(x))))
(pass-if (= 2 (length+ '(x y))))
(pass-if (= 3 (length+ '(x y z))))
(pass-if (not (length+ (circular-list 1))))
(pass-if (not (length+ (circular-list 1 2))))
(pass-if (not (length+ (circular-list 1 2 3)))))
;;
;; last
;;
(with-test-prefix "last"
(pass-if-exception "empty" exception:wrong-type-arg
(last '()))
(pass-if "one elem"
(eqv? 1 (last '(1))))
(pass-if "two elems"
(eqv? 2 (last '(1 2))))
(pass-if "three elems"
(eqv? 3 (last '(1 2 3))))
(pass-if "four elems"
(eqv? 4 (last '(1 2 3 4)))))
;;
;; list=
;;
(with-test-prefix "list="
(pass-if "no lists"
(eq? #t (list= eqv?)))
(with-test-prefix "one list"
(pass-if "empty"
(eq? #t (list= eqv? '())))
(pass-if "one elem"
(eq? #t (list= eqv? '(1))))
(pass-if "two elems"
(eq? #t (list= eqv? '(2)))))
(with-test-prefix "two lists"
(pass-if "empty / empty"
(eq? #t (list= eqv? '() '())))
(pass-if "one / empty"
(eq? #f (list= eqv? '(1) '())))
(pass-if "empty / one"
(eq? #f (list= eqv? '() '(1))))
(pass-if "one / one same"
(eq? #t (list= eqv? '(1) '(1))))
(pass-if "one / one diff"
(eq? #f (list= eqv? '(1) '(2))))
(pass-if "called arg order"
(let ((good #t))
(list= (lambda (x y)
(set! good (and good (= (1+ x) y)))
#t)
'(1 3) '(2 4))
good)))
(with-test-prefix "three lists"
(pass-if "empty / empty / empty"
(eq? #t (list= eqv? '() '() '())))
(pass-if "one / empty / empty"
(eq? #f (list= eqv? '(1) '() '())))
(pass-if "one / one / empty"
(eq? #f (list= eqv? '(1) '(1) '())))
(pass-if "one / diff / empty"
(eq? #f (list= eqv? '(1) '(2) '())))
(pass-if "one / one / one"
(eq? #t (list= eqv? '(1) '(1) '(1))))
(pass-if "two / two / diff"
(eq? #f (list= eqv? '(1 2) '(1 2) '(1 99))))
(pass-if "two / two / two"
(eq? #t (list= eqv? '(1 2) '(1 2) '(1 2))))
(pass-if "called arg order"
(let ((good #t))
(list= (lambda (x y)
(set! good (and good (= (1+ x) y)))
#t)
'(1 4) '(2 5) '(3 6))
good))))
;;
;; list-copy
;;
(with-test-prefix "list-copy"
(pass-if (equal? '() (list-copy '())))
(pass-if (equal? '(1 2) (list-copy '(1 2))))
(pass-if (equal? '(1 2 3) (list-copy '(1 2 3))))
(pass-if (equal? '(1 2 3 4) (list-copy '(1 2 3 4))))
(pass-if (equal? '(1 2 3 4 5) (list-copy '(1 2 3 4 5))))
;; improper lists can be copied
(pass-if (equal? 1 (list-copy 1)))
(pass-if (equal? '(1 . 2) (list-copy '(1 . 2))))
(pass-if (equal? '(1 2 . 3) (list-copy '(1 2 . 3))))
(pass-if (equal? '(1 2 3 . 4) (list-copy '(1 2 3 . 4))))
(pass-if (equal? '(1 2 3 4 . 5) (list-copy '(1 2 3 4 . 5)))))
;;
;; list-index
;;
(with-test-prefix "list-index"
(pass-if-exception "no args" exception:wrong-num-args
(list-index))
(pass-if-exception "one arg" exception:wrong-num-args
(list-index noop))
(with-test-prefix "one list"
(pass-if "empty list" (eq? #f (list-index symbol? '())))
(pass-if-exception "pred arg count 0" exception:wrong-num-args
(list-index (lambda () x) '(1 2 3)))
(pass-if-exception "pred arg count 2" exception:wrong-num-args
(list-index (lambda (x y) x) '(1 2 3)))
(pass-if-exception "improper 1" exception:wrong-type-arg
(list-index symbol? 1))
(pass-if-exception "improper 2" exception:wrong-type-arg
(list-index symbol? '(1 . 2)))
(pass-if-exception "improper 3" exception:wrong-type-arg
(list-index symbol? '(1 2 . 3)))
(pass-if (eqv? #f (list-index symbol? '(1))))
(pass-if (eqv? 0 (list-index symbol? '(x))))
(pass-if (eqv? #f (list-index symbol? '(1 2))))
(pass-if (eqv? 0 (list-index symbol? '(x 1))))
(pass-if (eqv? 1 (list-index symbol? '(1 x))))
(pass-if (eqv? #f (list-index symbol? '(1 2 3))))
(pass-if (eqv? 0 (list-index symbol? '(x 1 2))))
(pass-if (eqv? 1 (list-index symbol? '(1 x 2))))
(pass-if (eqv? 2 (list-index symbol? '(1 2 x)))))
(with-test-prefix "two lists"
(define (sym1 x y)
(symbol? x))
(define (sym2 x y)
(symbol? y))
(pass-if "arg order"
(eqv? 0 (list-index (lambda (x y)
(and (= 1 x)
(= 2 y)))
'(1) '(2))))
(pass-if "empty lists" (eqv? #f (list-index sym2 '() '())))
(pass-if-exception "pred arg count 0" exception:wrong-num-args
(list-index (lambda () #t) '(1 2 3) '(1 2 3)))
(pass-if-exception "pred arg count 1" exception:wrong-num-args
(list-index (lambda (x) x) '(1 2 3) '(1 2 3)))
(pass-if-exception "pred arg count 3" exception:wrong-num-args
(list-index (lambda (x y z) x) '(1 2 3) '(1 2 3)))
(pass-if-exception "improper first 1" exception:wrong-type-arg
(list-index sym2 1 '(1 2 3)))
(pass-if-exception "improper first 2" exception:wrong-type-arg
(list-index sym2 '(1 . 2) '(1 2 3)))
(pass-if-exception "improper first 3" exception:wrong-type-arg
(list-index sym2 '(1 2 . 3) '(1 2 3)))
(pass-if-exception "improper second 1" exception:wrong-type-arg
(list-index sym2 '(1 2 3) 1))
(pass-if-exception "improper second 2" exception:wrong-type-arg
(list-index sym2 '(1 2 3) '(1 . 2)))
(pass-if-exception "improper second 3" exception:wrong-type-arg
(list-index sym2 '(1 2 3) '(1 2 . 3)))
(pass-if (eqv? #f (list-index sym2 '(1) '(2))))
(pass-if (eqv? 0 (list-index sym2 '(1) '(x))))
(pass-if (eqv? #f (list-index sym2 '(1 2) '(3 4))))
(pass-if (eqv? 0 (list-index sym2 '(1 2) '(x 3))))
(pass-if (eqv? 1 (list-index sym2 '(1 2) '(3 x))))
(pass-if (eqv? #f (list-index sym2 '(1 2 3) '(3 4 5))))
(pass-if (eqv? 0 (list-index sym2 '(1 2 3) '(x 3 4))))
(pass-if (eqv? 1 (list-index sym2 '(1 2 3) '(3 x 4))))
(pass-if (eqv? 2 (list-index sym2 '(1 2 3) '(3 4 x))))
(with-test-prefix "stop shortest"
(pass-if (eqv? #f (list-index sym1 '(1 2 x) '(4 5))))
(pass-if (eqv? #f (list-index sym2 '(4 5) '(1 2 x))))
(pass-if (eqv? #f (list-index sym1 '(3 4) '(1 2 x y))))
(pass-if (eqv? #f (list-index sym2 '(1 2 x y) '(3 4))))))
(with-test-prefix "three lists"
(define (sym1 x y z)
(symbol? x))
(define (sym2 x y z)
(symbol? y))
(define (sym3 x y z)
(symbol? z))
(pass-if "arg order"
(eqv? 0 (list-index (lambda (x y z)
(and (= 1 x)
(= 2 y)
(= 3 z)))
'(1) '(2) '(3))))
(pass-if "empty lists" (eqv? #f (list-index sym3 '() '() '())))
;; currently bad pred argument gives wrong-num-args when 3 or more
;; lists, as opposed to wrong-type-arg for 1 or 2 lists
(pass-if-exception "pred arg count 0" exception:wrong-num-args
(list-index (lambda () #t) '(1 2 3) '(1 2 3) '(1 2 3)))
(pass-if-exception "pred arg count 2" exception:wrong-num-args
(list-index (lambda (x y) x) '(1 2 3) '(1 2 3)'(1 2 3) ))
(pass-if-exception "pred arg count 4" exception:wrong-num-args
(list-index (lambda (w x y z) x) '(1 2 3) '(1 2 3) '(1 2 3)))
(pass-if-exception "improper first 1" exception:wrong-type-arg
(list-index sym3 1 '(1 2 3) '(1 2 3)))
(pass-if-exception "improper first 2" exception:wrong-type-arg
(list-index sym3 '(1 . 2) '(1 2 3) '(1 2 3)))
(pass-if-exception "improper first 3" exception:wrong-type-arg
(list-index sym3 '(1 2 . 3) '(1 2 3) '(1 2 3)))
(pass-if-exception "improper second 1" exception:wrong-type-arg
(list-index sym3 '(1 2 3) 1 '(1 2 3)))
(pass-if-exception "improper second 2" exception:wrong-type-arg
(list-index sym3 '(1 2 3) '(1 . 2) '(1 2 3)))
(pass-if-exception "improper second 3" exception:wrong-type-arg
(list-index sym3 '(1 2 3) '(1 2 . 3) '(1 2 3)))
(pass-if-exception "improper third 1" exception:wrong-type-arg
(list-index sym3 '(1 2 3) '(1 2 3) 1))
(pass-if-exception "improper third 2" exception:wrong-type-arg
(list-index sym3 '(1 2 3) '(1 2 3) '(1 . 2)))
(pass-if-exception "improper third 3" exception:wrong-type-arg
(list-index sym3 '(1 2 3) '(1 2 3) '(1 2 . 3)))
(pass-if (eqv? #f (list-index sym3 '(#f) '(#f) '(#f))))
(pass-if (eqv? 0 (list-index sym3 '(#f) '(#f) '(x))))
(pass-if (eqv? #f (list-index sym3 '(#f #f) '(#f #f) '(#f #f))))
(pass-if (eqv? 0 (list-index sym3 '(#f #f) '(#f #f) '(x #f))))
(pass-if (eqv? 1 (list-index sym3 '(#f #f) '(#f #f) '(#f x))))
(pass-if (eqv? #f (list-index sym3 '(#f #f #f) '(#f #f #f) '(#f #f #f))))
(pass-if (eqv? 0 (list-index sym3 '(#f #f #f) '(#f #f #f) '(x #f #f))))
(pass-if (eqv? 1 (list-index sym3 '(#f #f #f) '(#f #f #f) '(#f x #f))))
(pass-if (eqv? 2 (list-index sym3 '(#f #f #f) '(#f #f #f) '(#f #f x))))
(with-test-prefix "stop shortest"
(pass-if (eqv? #f (list-index sym2 '() '(x x x) '(x x))))
(pass-if (eqv? #f (list-index sym1 '(x x x) '() '(x x))))
(pass-if (eqv? #f (list-index sym2 '(x x x) '(x x) '())))
(pass-if (eqv? #f (list-index sym2 '(#t) '(#t x x) '(#t x))))
(pass-if (eqv? #f (list-index sym1 '(#t x x) '(#t) '(#t x))))
(pass-if (eqv? #f (list-index sym1 '(#t x x) '(#t x) '(#t)))))
(pass-if "apply list unchanged"
(let ((lst (list (list 1 2) (list 3 4) (list 5 6))))
(and (equal? #f (apply list-index sym3 lst))
;; lst unmodified
(equal? '((1 2) (3 4) (5 6)) lst))))))
;;
;; list-tabulate
;;
(with-test-prefix "list-tabulate"
(pass-if-exception "-1" exception:wrong-type-arg
(list-tabulate -1 identity))
(pass-if "0"
(equal? '() (list-tabulate 0 identity)))
(pass-if "1"
(equal? '(0) (list-tabulate 1 identity)))
(pass-if "2"
(equal? '(0 1) (list-tabulate 2 identity)))
(pass-if "3"
(equal? '(0 1 2) (list-tabulate 3 identity)))
(pass-if "4"
(equal? '(0 1 2 3) (list-tabulate 4 identity)))
(pass-if "string ref proc"
(equal? '(#\a #\b #\c #\d) (list-tabulate 4
(lambda (i)
(string-ref "abcd" i))))))
;;
;; lset=
;;
(with-test-prefix "lset="
;; in guile 1.6.7 and earlier, lset= incorrectly demanded at least one
;; list arg
(pass-if "no args"
(eq? #t (lset= eq?)))
(with-test-prefix "one arg"
(pass-if "()"
(eq? #t (lset= eqv? '())))
(pass-if "(1)"
(eq? #t (lset= eqv? '(1))))
(pass-if "(1 2)"
(eq? #t (lset= eqv? '(1 2)))))
(with-test-prefix "two args"
(pass-if "() ()"
(eq? #t (lset= eqv? '() '())))
(pass-if "(1) (1)"
(eq? #t (lset= eqv? '(1) '(1))))
(pass-if "(1) (2)"
(eq? #f (lset= eqv? '(1) '(2))))
(pass-if "(1) (1 2)"
(eq? #f (lset= eqv? '(1) '(1 2))))
(pass-if "(1 2) (2 1)"
(eq? #t (lset= eqv? '(1 2) '(2 1))))
(pass-if "called arg order"
(let ((good #t))
(lset= (lambda (x y)
(if (not (= x (1- y)))
(set! good #f))
#t)
'(1 1) '(2 2))
good)))
(with-test-prefix "three args"
(pass-if "() () ()"
(eq? #t (lset= eqv? '() '() '())))
(pass-if "(1) (1) (1)"
(eq? #t (lset= eqv? '(1) '(1) '(1))))
(pass-if "(1) (1) (2)"
(eq? #f (lset= eqv? '(1) '(1) '(2))))
(pass-if "(1) (1) (1 2)"
(eq? #f (lset= eqv? '(1) '(1) '(1 2))))
(pass-if "(1 2 3) (3 2 1) (1 3 2)"
(eq? #t (lset= eqv? '(1 2 3) '(3 2 1) '(1 3 2))))
(pass-if "called arg order"
(let ((good #t))
(lset= (lambda (x y)
(if (not (= x (1- y)))
(set! good #f))
#t)
'(1 1) '(2 2) '(3 3))
good))))
;;
;; lset-adjoin
;;
(with-test-prefix "lset-adjoin"
;; in guile 1.6.7 and earlier, lset-adjoin didn't actually use the given
;; `=' procedure, all comparisons were just with `equal?
;;
(with-test-prefix "case-insensitive ="
(pass-if "(\"x\") \"X\""
(equal? '("x") (lset-adjoin string-ci=? '("x") "X"))))
(pass-if "called arg order"
(let ((good #f))
(lset-adjoin (lambda (x y)
(set! good (and (= x 1) (= y 2)))
(= x y))
'(1) 2)
good))
(pass-if (equal? '() (lset-adjoin = '())))
(pass-if (equal? '(1) (lset-adjoin = '() 1)))
(pass-if (equal? '(1) (lset-adjoin = '() 1 1)))
(pass-if (equal? '(2 1) (lset-adjoin = '() 1 2)))
(pass-if (equal? '(3 1 2) (lset-adjoin = '(1 2) 1 2 3 2 1)))
(pass-if "apply list unchanged"
(let ((lst (list 1 2)))
(and (equal? '(2 1 3) (apply lset-adjoin = '(3) lst))
;; lst unmodified
(equal? '(1 2) lst))))
(pass-if "(1 1) 1 1"
(equal? '(1 1) (lset-adjoin = '(1 1) 1 1)))
;; duplicates among args are cast out
(pass-if "(2) 1 1"
(equal? '(1 2) (lset-adjoin = '(2) 1 1))))
;;
;; lset-difference
;;
(with-test-prefix "lset-difference"
(pass-if "called arg order"
(let ((good #f))
(lset-difference (lambda (x y)
(set! good (and (= x 1) (= y 2)))
(= x y))
'(1) '(2))
good)))
;;
;; lset-difference!
;;
(with-test-prefix "lset-difference!"
(pass-if-exception "proc - num" exception:wrong-type-arg
(lset-difference! 123 '(4)))
(pass-if-exception "proc - list" exception:wrong-type-arg
(lset-difference! (list 1 2 3) '(4)))
(pass-if "called arg order"
(let ((good #f))
(lset-difference! (lambda (x y)
(set! good (and (= x 1) (= y 2)))
(= x y))
(list 1) (list 2))
good))
(pass-if (equal? '() (lset-difference! = '())))
(pass-if (equal? '(1) (lset-difference! = (list 1))))
(pass-if (equal? '(1 2) (lset-difference! = (list 1 2))))
(pass-if (equal? '() (lset-difference! = (list ) '(3))))
(pass-if (equal? '() (lset-difference! = (list 3) '(3))))
(pass-if (equal? '(1) (lset-difference! = (list 1 3) '(3))))
(pass-if (equal? '(1) (lset-difference! = (list 3 1) '(3))))
(pass-if (equal? '(1) (lset-difference! = (list 1 3 3) '(3))))
(pass-if (equal? '(1) (lset-difference! = (list 3 1 3) '(3))))
(pass-if (equal? '(1) (lset-difference! = (list 3 3 1) '(3))))
(pass-if (equal? '(1) (lset-difference! = (list 1 2 3) '(2 3))))
(pass-if (equal? '(1) (lset-difference! = (list 1 2 3) '(3 2))))
(pass-if (equal? '(1) (lset-difference! = (list 1 2 3) '(3) '(2))))
(pass-if (equal? '(1) (lset-difference! = (list 1 2 3) '(2) '(3))))
(pass-if (equal? '(1) (lset-difference! = (list 1 2 3) '(2) '(2 3))))
(pass-if (equal? '(1) (lset-difference! = (list 1 2 3) '(2) '(3 2))))
(pass-if (equal? '(1 2) (lset-difference! = (list 1 2 3) '(3) '(3))))
(pass-if (equal? '(1 2) (lset-difference! = (list 1 3 2) '(3) '(3))))
(pass-if (equal? '(1 2) (lset-difference! = (list 3 1 2) '(3) '(3))))
(pass-if (equal? '(1 2 3) (lset-difference! = (list 1 2 3 4) '(4))))
(pass-if (equal? '(1 2 3) (lset-difference! = (list 1 2 4 3) '(4))))
(pass-if (equal? '(1 2 3) (lset-difference! = (list 1 4 2 3) '(4))))
(pass-if (equal? '(1 2 3) (lset-difference! = (list 4 1 2 3) '(4))))
(pass-if (equal? '(1 2) (lset-difference! = (list 1 2 3 4) '(4) '(3))))
(pass-if (equal? '(1 2) (lset-difference! = (list 1 3 2 4) '(4) '(3))))
(pass-if (equal? '(1 2) (lset-difference! = (list 3 1 2 4) '(4) '(3))))
(pass-if (equal? '(1 2) (lset-difference! = (list 1 3 4 2) '(4) '(3))))
(pass-if (equal? '(1 2) (lset-difference! = (list 3 1 4 2) '(4) '(3))))
(pass-if (equal? '(1 2) (lset-difference! = (list 3 4 1 2) '(4) '(3)))))
;;
;; lset-diff+intersection
;;
(with-test-prefix "lset-diff+intersection"
(pass-if "called arg order"
(let ((good #f))
(lset-diff+intersection (lambda (x y)
(set! good (and (= x 1) (= y 2)))
(= x y))
'(1) '(2))
good)))
;;
;; lset-diff+intersection!
;;
(with-test-prefix "lset-diff+intersection"
(pass-if "called arg order"
(let ((good #f))
(lset-diff+intersection (lambda (x y)
(set! good (and (= x 1) (= y 2)))
(= x y))
(list 1) (list 2))
good)))
;;
;; lset-intersection
;;
(with-test-prefix "lset-intersection"
(pass-if "called arg order"
(let ((good #f))
(lset-intersection (lambda (x y)
(set! good (and (= x 1) (= y 2)))
(= x y))
'(1) '(2))
good)))
;;
;; lset-intersection!
;;
(with-test-prefix "lset-intersection"
(pass-if "called arg order"
(let ((good #f))
(lset-intersection (lambda (x y)
(set! good (and (= x 1) (= y 2)))
(= x y))
(list 1) (list 2))
good)))
;;
;; lset-union
;;
(with-test-prefix "lset-union"
(pass-if "no args"
(eq? '() (lset-union eq?)))
(pass-if "one arg"
(equal? '(1 2 3) (lset-union eq? '(1 2 3))))
(pass-if "'() '()"
(equal? '() (lset-union eq? '() '())))
(pass-if "'() '(1 2 3)"
(equal? '(1 2 3) (lset-union eq? '() '(1 2 3))))
(pass-if "'(1 2 3) '()"
(equal? '(1 2 3) (lset-union eq? '(1 2 3) '())))
(pass-if "'(1 2 3) '(4 3 5)"
(equal? '(5 4 1 2 3) (lset-union eq? '(1 2 3) '(4 3 5))))
(pass-if "'(1 2 3) '(4) '(3 5))"
(equal? '(5 4 1 2 3) (lset-union eq? '(1 2 3) '(4) '(3 5))))
;; in guile 1.6.7 and earlier, `=' was called with the arguments the wrong
;; way around
(pass-if "called arg order"
(let ((good #f))
(lset-union (lambda (x y)
(set! good (and (= x 1) (= y 2)))
(= x y))
'(1) '(2))
good)))
;;
;; member
;;
(with-test-prefix "member"
(pass-if-exception "no args" exception:wrong-num-args
(member))
(pass-if-exception "one arg" exception:wrong-num-args
(member 1))
(pass-if "1 (1 2 3)"
(let ((lst '(1 2 3)))
(eq? lst (member 1 lst))))
(pass-if "2 (1 2 3)"
(let ((lst '(1 2 3)))
(eq? (cdr lst) (member 2 lst))))
(pass-if "3 (1 2 3)"
(let ((lst '(1 2 3)))
(eq? (cddr lst) (member 3 lst))))
(pass-if "4 (1 2 3)"
(let ((lst '(1 2 3)))
(eq? #f (member 4 lst))))
(pass-if "called arg order"
(let ((good #f))
(member 1 '(2) (lambda (x y)
(set! good (and (eqv? 1 x)
(eqv? 2 y)))))
good)))
;;
;; ninth
;;
(with-test-prefix "ninth"
(pass-if-exception "() -1" exception:wrong-type-arg
(ninth '(a b c d e f g h)))
(pass-if (eq? 'i (ninth '(a b c d e f g h i))))
(pass-if (eq? 'i (ninth '(a b c d e f g h i j)))))
;;
;; not-pair?
;;
(with-test-prefix "not-pair?"
(pass-if "inum"
(eq? #t (not-pair? 123)))
(pass-if "pair"
(eq? #f (not-pair? '(x . y))))
(pass-if "symbol"
(eq? #t (not-pair? 'x))))
;;
;; take
;;
(with-test-prefix "take"
(pass-if "'() 0"
(null? (take '() 0)))
(pass-if "'(a) 0"
(null? (take '(a) 0)))
(pass-if "'(a b) 0"
(null? (take '() 0)))
(pass-if "'(a b c) 0"
(null? (take '() 0)))
(pass-if "'(a) 1"
(let* ((lst '(a))
(got (take lst 1)))
(and (equal? '(a) got)
(not (eq? lst got)))))
(pass-if "'(a b) 1"
(equal? '(a)
(take '(a b) 1)))
(pass-if "'(a b c) 1"
(equal? '(a)
(take '(a b c) 1)))
(pass-if "'(a b) 2"
(let* ((lst '(a b))
(got (take lst 2)))
(and (equal? '(a b) got)
(not (eq? lst got)))))
(pass-if "'(a b c) 2"
(equal? '(a b)
(take '(a b c) 2)))
(pass-if "circular '(a) 0"
(equal? '()
(take (circular-list 'a) 0)))
(pass-if "circular '(a) 1"
(equal? '(a)
(take (circular-list 'a) 1)))
(pass-if "circular '(a) 2"
(equal? '(a a)
(take (circular-list 'a) 2)))
(pass-if "circular '(a b) 5"
(equal? '(a b a b a)
(take (circular-list 'a 'b) 5)))
(pass-if "'(a . b) 1"
(equal? '(a)
(take '(a . b) 1)))
(pass-if "'(a b . c) 1"
(equal? '(a)
(take '(a b . c) 1)))
(pass-if "'(a b . c) 2"
(equal? '(a b)
(take '(a b . c) 2))))
;;
;; take-while
;;
(with-test-prefix "take-while"
(pass-if (equal? '() (take-while odd? '())))
(pass-if (equal? '(1) (take-while odd? '(1))))
(pass-if (equal? '(1 3) (take-while odd? '(1 3))))
(pass-if (equal? '(1 3 5) (take-while odd? '(1 3 5))))
(pass-if (equal? '() (take-while odd? '(2))))
(pass-if (equal? '(1) (take-while odd? '(1 2))))
(pass-if (equal? '(1 3) (take-while odd? '(1 3 4))))
(pass-if (equal? '() (take-while odd? '(2 1))))
(pass-if (equal? '(1) (take-while odd? '(1 4 3))))
(pass-if (equal? '() (take-while odd? '(4 1 3)))))
;;
;; take-while!
;;
(with-test-prefix "take-while!"
(pass-if (equal? '() (take-while! odd? '())))
(pass-if (equal? '(1) (take-while! odd? (list 1))))
(pass-if (equal? '(1 3) (take-while! odd? (list 1 3))))
(pass-if (equal? '(1 3 5) (take-while! odd? (list 1 3 5))))
(pass-if (equal? '() (take-while! odd? (list 2))))
(pass-if (equal? '(1) (take-while! odd? (list 1 2))))
(pass-if (equal? '(1 3) (take-while! odd? (list 1 3 4))))
(pass-if (equal? '() (take-while! odd? (list 2 1))))
(pass-if (equal? '(1) (take-while! odd? (list 1 4 3))))
(pass-if (equal? '() (take-while! odd? (list 4 1 3)))))
;;
;; partition
;;
(define (test-partition pred list kept-good dropped-good)
(call-with-values (lambda ()
(partition pred list))
(lambda (kept dropped)
(and (equal? kept kept-good)
(equal? dropped dropped-good)))))
(with-test-prefix "partition"
(pass-if "with dropped tail"
(test-partition even? '(1 2 3 4 5 6 7)
'(2 4 6) '(1 3 5 7)))
(pass-if "with kept tail"
(test-partition even? '(1 2 3 4 5 6)
'(2 4 6) '(1 3 5)))
(pass-if "with everything dropped"
(test-partition even? '(1 3 5 7)
'() '(1 3 5 7)))
(pass-if "with everything kept"
(test-partition even? '(2 4 6)
'(2 4 6) '()))
(pass-if "with empty list"
(test-partition even? '()
'() '()))
(pass-if "with reasonably long list"
;; the old implementation from SRFI-1 reference implementation
;; would signal a stack-overflow for a list of only 500 elements!
(call-with-values (lambda ()
(partition even?
(make-list 10000 1)))
(lambda (even odd)
(and (= (length odd) 10000)
(= (length even) 0)))))
(pass-if-exception "with improper list"
exception:wrong-type-arg
(partition symbol? '(a b . c))))
;;
;; partition!
;;
(define (test-partition! pred list kept-good dropped-good)
(call-with-values (lambda ()
(partition! pred list))
(lambda (kept dropped)
(and (equal? kept kept-good)
(equal? dropped dropped-good)))))
(with-test-prefix "partition!"
(pass-if "with dropped tail"
(test-partition! even? (list 1 2 3 4 5 6 7)
'(2 4 6) '(1 3 5 7)))
(pass-if "with kept tail"
(test-partition! even? (list 1 2 3 4 5 6)
'(2 4 6) '(1 3 5)))
(pass-if "with everything dropped"
(test-partition! even? (list 1 3 5 7)
'() '(1 3 5 7)))
(pass-if "with everything kept"
(test-partition! even? (list 2 4 6)
'(2 4 6) '()))
(pass-if "with empty list"
(test-partition! even? '()
'() '()))
(pass-if "with reasonably long list"
;; the old implementation from SRFI-1 reference implementation
;; would signal a stack-overflow for a list of only 500 elements!
(call-with-values (lambda ()
(partition! even?
(make-list 10000 1)))
(lambda (even odd)
(and (= (length odd) 10000)
(= (length even) 0)))))
(pass-if-exception "with improper list"
exception:wrong-type-arg
(partition! symbol? (cons* 'a 'b 'c))))
;;
;; reduce
;;
(with-test-prefix "reduce"
(pass-if "empty"
(let* ((calls '())
(ret (reduce (lambda (x prev)
(set! calls (cons (list x prev) calls))
x)
1 '())))
(and (equal? calls '())
(equal? ret 1))))
(pass-if "one elem"
(let* ((calls '())
(ret (reduce (lambda (x prev)
(set! calls (cons (list x prev) calls))
x)
1 '(2))))
(and (equal? calls '())
(equal? ret 2))))
(pass-if "two elems"
(let* ((calls '())
(ret (reduce (lambda (x prev)
(set! calls (cons (list x prev) calls))
x)
1 '(2 3))))
(and (equal? calls '((3 2)))
(equal? ret 3))))
(pass-if "three elems"
(let* ((calls '())
(ret (reduce (lambda (x prev)
(set! calls (cons (list x prev) calls))
x)
1 '(2 3 4))))
(and (equal? calls '((4 3)
(3 2)))
(equal? ret 4))))
(pass-if "four elems"
(let* ((calls '())
(ret (reduce (lambda (x prev)
(set! calls (cons (list x prev) calls))
x)
1 '(2 3 4 5))))
(and (equal? calls '((5 4)
(4 3)
(3 2)))
(equal? ret 5)))))
;;
;; reduce-right
;;
(with-test-prefix "reduce-right"
(pass-if "empty"
(let* ((calls '())
(ret (reduce-right (lambda (x prev)
(set! calls (cons (list x prev) calls))
x)
1 '())))
(and (equal? calls '())
(equal? ret 1))))
(pass-if "one elem"
(let* ((calls '())
(ret (reduce-right (lambda (x prev)
(set! calls (cons (list x prev) calls))
x)
1 '(2))))
(and (equal? calls '())
(equal? ret 2))))
(pass-if "two elems"
(let* ((calls '())
(ret (reduce-right (lambda (x prev)
(set! calls (cons (list x prev) calls))
x)
1 '(2 3))))
(and (equal? calls '((2 3)))
(equal? ret 2))))
(pass-if "three elems"
(let* ((calls '())
(ret (reduce-right (lambda (x prev)
(set! calls (cons (list x prev) calls))
x)
1 '(2 3 4))))
(and (equal? calls '((2 3)
(3 4)))
(equal? ret 2))))
(pass-if "four elems"
(let* ((calls '())
(ret (reduce-right (lambda (x prev)
(set! calls (cons (list x prev) calls))
x)
1 '(2 3 4 5))))
(and (equal? calls '((2 3)
(3 4)
(4 5)))
(equal? ret 2)))))
;;
;; remove
;;
(with-test-prefix "remove"
(pass-if (equal? '() (remove odd? '())))
(pass-if (equal? '() (remove odd? '(1))))
(pass-if (equal? '(2) (remove odd? '(2))))
(pass-if (equal? '() (remove odd? '(1 3))))
(pass-if (equal? '(2) (remove odd? '(2 3))))
(pass-if (equal? '(2) (remove odd? '(1 2))))
(pass-if (equal? '(2 4) (remove odd? '(2 4))))
(pass-if (equal? '() (remove odd? '(1 3 5))))
(pass-if (equal? '(2) (remove odd? '(2 3 5))))
(pass-if (equal? '(2) (remove odd? '(1 2 5))))
(pass-if (equal? '(2 4) (remove odd? '(2 4 5))))
(pass-if (equal? '(6) (remove odd? '(1 3 6))))
(pass-if (equal? '(2 6) (remove odd? '(2 3 6))))
(pass-if (equal? '(2 6) (remove odd? '(1 2 6))))
(pass-if (equal? '(2 4 6) (remove odd? '(2 4 6)))))
;;
;; remove!
;;
(with-test-prefix "remove!"
(pass-if (equal? '() (remove! odd? '())))
(pass-if (equal? '() (remove! odd? (list 1))))
(pass-if (equal? '(2) (remove! odd? (list 2))))
(pass-if (equal? '() (remove! odd? (list 1 3))))
(pass-if (equal? '(2) (remove! odd? (list 2 3))))
(pass-if (equal? '(2) (remove! odd? (list 1 2))))
(pass-if (equal? '(2 4) (remove! odd? (list 2 4))))
(pass-if (equal? '() (remove! odd? (list 1 3 5))))
(pass-if (equal? '(2) (remove! odd? (list 2 3 5))))
(pass-if (equal? '(2) (remove! odd? (list 1 2 5))))
(pass-if (equal? '(2 4) (remove! odd? (list 2 4 5))))
(pass-if (equal? '(6) (remove! odd? (list 1 3 6))))
(pass-if (equal? '(2 6) (remove! odd? (list 2 3 6))))
(pass-if (equal? '(2 6) (remove! odd? (list 1 2 6))))
(pass-if (equal? '(2 4 6) (remove! odd? (list 2 4 6)))))
;;
;; seventh
;;
(with-test-prefix "seventh"
(pass-if-exception "() -1" exception:wrong-type-arg
(seventh '(a b c d e f)))
(pass-if (eq? 'g (seventh '(a b c d e f g))))
(pass-if (eq? 'g (seventh '(a b c d e f g h)))))
;;
;; sixth
;;
(with-test-prefix "sixth"
(pass-if-exception "() -1" exception:wrong-type-arg
(sixth '(a b c d e)))
(pass-if (eq? 'f (sixth '(a b c d e f))))
(pass-if (eq? 'f (sixth '(a b c d e f g)))))
;;
;; split-at
;;
(with-test-prefix "split-at"
(define (equal-values? lst thunk)
(call-with-values thunk
(lambda got
(equal? lst got))))
(pass-if-exception "() -1" exception:out-of-range
(split-at '() -1))
(pass-if (equal-values? '(() ())
(lambda () (split-at '() 0))))
(pass-if-exception "() 1" exception:wrong-type-arg
(split-at '() 1))
(pass-if-exception "(1) -1" exception:out-of-range
(split-at '(1) -1))
(pass-if (equal-values? '(() (1)) (lambda () (split-at '(1) 0))))
(pass-if (equal-values? '((1) ()) (lambda () (split-at '(1) 1))))
(pass-if-exception "(1) 2" exception:wrong-type-arg
(split-at '(1) 2))
(pass-if-exception "(4 5) -1" exception:out-of-range
(split-at '(4 5) -1))
(pass-if (equal-values? '(() (4 5)) (lambda () (split-at '(4 5) 0))))
(pass-if (equal-values? '((4) (5)) (lambda () (split-at '(4 5) 1))))
(pass-if (equal-values? '((4 5) ()) (lambda () (split-at '(4 5) 2))))
(pass-if-exception "(4 5) 3" exception:wrong-type-arg
(split-at '(4 5) 3))
(pass-if-exception "(4 5 6) -1" exception:out-of-range
(split-at '(4 5 6) -1))
(pass-if (equal-values? '(() (4 5 6)) (lambda () (split-at '(4 5 6) 0))))
(pass-if (equal-values? '((4) (5 6)) (lambda () (split-at '(4 5 6) 1))))
(pass-if (equal-values? '((4 5) (6)) (lambda () (split-at '(4 5 6) 2))))
(pass-if (equal-values? '((4 5 6) ()) (lambda () (split-at '(4 5 6) 3))))
(pass-if-exception "(4 5 6) 4" exception:wrong-type-arg
(split-at '(4 5 6) 4)))
;;
;; split-at!
;;
(with-test-prefix "split-at!"
(define (equal-values? lst thunk)
(call-with-values thunk
(lambda got
(equal? lst got))))
(pass-if-exception "() -1" exception:out-of-range
(split-at! '() -1))
(pass-if (equal-values? '(() ())
(lambda () (split-at! '() 0))))
(pass-if-exception "() 1" exception:wrong-type-arg
(split-at! '() 1))
(pass-if-exception "(1) -1" exception:out-of-range
(split-at! (list 1) -1))
(pass-if (equal-values? '(() (1)) (lambda () (split-at! (list 1) 0))))
(pass-if (equal-values? '((1) ()) (lambda () (split-at! (list 1) 1))))
(pass-if-exception "(1) 2" exception:wrong-type-arg
(split-at! (list 1) 2))
(pass-if-exception "(4 5) -1" exception:out-of-range
(split-at! (list 4 5) -1))
(pass-if (equal-values? '(() (4 5)) (lambda () (split-at! (list 4 5) 0))))
(pass-if (equal-values? '((4) (5)) (lambda () (split-at! (list 4 5) 1))))
(pass-if (equal-values? '((4 5) ()) (lambda () (split-at! (list 4 5) 2))))
(pass-if-exception "(4 5) 3" exception:wrong-type-arg
(split-at! (list 4 5) 3))
(pass-if-exception "(4 5 6) -1" exception:out-of-range
(split-at! (list 4 5 6) -1))
(pass-if (equal-values? '(() (4 5 6)) (lambda () (split-at! (list 4 5 6) 0))))
(pass-if (equal-values? '((4) (5 6)) (lambda () (split-at! (list 4 5 6) 1))))
(pass-if (equal-values? '((4 5) (6)) (lambda () (split-at! (list 4 5 6) 2))))
(pass-if (equal-values? '((4 5 6) ()) (lambda () (split-at! (list 4 5 6) 3))))
(pass-if-exception "(4 5 6) 4" exception:wrong-type-arg
(split-at! (list 4 5 6) 4)))
;;
;; span
;;
(with-test-prefix "span"
(define (test-span lst want-v1 want-v2)
(call-with-values
(lambda ()
(span positive? lst))
(lambda (got-v1 got-v2)
(and (equal? got-v1 want-v1)
(equal? got-v2 want-v2)))))
(pass-if "empty"
(test-span '() '() '()))
(pass-if "y"
(test-span '(1) '(1) '()))
(pass-if "n"
(test-span '(-1) '() '(-1)))
(pass-if "yy"
(test-span '(1 2) '(1 2) '()))
(pass-if "ny"
(test-span '(-1 1) '() '(-1 1)))
(pass-if "yn"
(test-span '(1 -1) '(1) '(-1)))
(pass-if "nn"
(test-span '(-1 -2) '() '(-1 -2)))
(pass-if "yyy"
(test-span '(1 2 3) '(1 2 3) '()))
(pass-if "nyy"
(test-span '(-1 1 2) '() '(-1 1 2)))
(pass-if "yny"
(test-span '(1 -1 2) '(1) '(-1 2)))
(pass-if "nny"
(test-span '(-1 -2 1) '() '(-1 -2 1)))
(pass-if "yyn"
(test-span '(1 2 -1) '(1 2) '(-1)))
(pass-if "nyn"
(test-span '(-1 1 -2) '() '(-1 1 -2)))
(pass-if "ynn"
(test-span '(1 -1 -2) '(1) '(-1 -2)))
(pass-if "nnn"
(test-span '(-1 -2 -3) '() '(-1 -2 -3))))
;;
;; span!
;;
(with-test-prefix "span!"
(define (test-span! lst want-v1 want-v2)
(call-with-values
(lambda ()
(span! positive? lst))
(lambda (got-v1 got-v2)
(and (equal? got-v1 want-v1)
(equal? got-v2 want-v2)))))
(pass-if "empty"
(test-span! '() '() '()))
(pass-if "y"
(test-span! (list 1) '(1) '()))
(pass-if "n"
(test-span! (list -1) '() '(-1)))
(pass-if "yy"
(test-span! (list 1 2) '(1 2) '()))
(pass-if "ny"
(test-span! (list -1 1) '() '(-1 1)))
(pass-if "yn"
(test-span! (list 1 -1) '(1) '(-1)))
(pass-if "nn"
(test-span! (list -1 -2) '() '(-1 -2)))
(pass-if "yyy"
(test-span! (list 1 2 3) '(1 2 3) '()))
(pass-if "nyy"
(test-span! (list -1 1 2) '() '(-1 1 2)))
(pass-if "yny"
(test-span! (list 1 -1 2) '(1) '(-1 2)))
(pass-if "nny"
(test-span! (list -1 -2 1) '() '(-1 -2 1)))
(pass-if "yyn"
(test-span! (list 1 2 -1) '(1 2) '(-1)))
(pass-if "nyn"
(test-span! (list -1 1 -2) '() '(-1 1 -2)))
(pass-if "ynn"
(test-span! (list 1 -1 -2) '(1) '(-1 -2)))
(pass-if "nnn"
(test-span! (list -1 -2 -3) '() '(-1 -2 -3))))
;;
;; take!
;;
(with-test-prefix "take!"
(pass-if-exception "() -1" exception:out-of-range
(take! '() -1))
(pass-if (equal? '() (take! '() 0)))
(pass-if-exception "() 1" exception:wrong-type-arg
(take! '() 1))
(pass-if-exception "(1) -1" exception:out-of-range
(take! '(1) -1))
(pass-if (equal? '() (take! '(1) 0)))
(pass-if (equal? '(1) (take! '(1) 1)))
(pass-if-exception "(1) 2" exception:wrong-type-arg
(take! '(1) 2))
(pass-if-exception "(4 5) -1" exception:out-of-range
(take! '(4 5) -1))
(pass-if (equal? '() (take! '(4 5) 0)))
(pass-if (equal? '(4) (take! '(4 5) 1)))
(pass-if (equal? '(4 5) (take! '(4 5) 2)))
(pass-if-exception "(4 5) 3" exception:wrong-type-arg
(take! '(4 5) 3))
(pass-if-exception "(4 5 6) -1" exception:out-of-range
(take! '(4 5 6) -1))
(pass-if (equal? '() (take! '(4 5 6) 0)))
(pass-if (equal? '(4) (take! '(4 5 6) 1)))
(pass-if (equal? '(4 5) (take! '(4 5 6) 2)))
(pass-if (equal? '(4 5 6) (take! '(4 5 6) 3)))
(pass-if-exception "(4 5 6) 4" exception:wrong-type-arg
(take! '(4 5 6) 4)))
;;
;; take-right
;;
(with-test-prefix "take-right"
(pass-if-exception "() -1" exception:out-of-range
(take-right '() -1))
(pass-if (equal? '() (take-right '() 0)))
(pass-if-exception "() 1" exception:wrong-type-arg
(take-right '() 1))
(pass-if-exception "(1) -1" exception:out-of-range
(take-right '(1) -1))
(pass-if (equal? '() (take-right '(1) 0)))
(pass-if (equal? '(1) (take-right '(1) 1)))
(pass-if-exception "(1) 2" exception:wrong-type-arg
(take-right '(1) 2))
(pass-if-exception "(4 5) -1" exception:out-of-range
(take-right '(4 5) -1))
(pass-if (equal? '() (take-right '(4 5) 0)))
(pass-if (equal? '(5) (take-right '(4 5) 1)))
(pass-if (equal? '(4 5) (take-right '(4 5) 2)))
(pass-if-exception "(4 5) 3" exception:wrong-type-arg
(take-right '(4 5) 3))
(pass-if-exception "(4 5 6) -1" exception:out-of-range
(take-right '(4 5 6) -1))
(pass-if (equal? '() (take-right '(4 5 6) 0)))
(pass-if (equal? '(6) (take-right '(4 5 6) 1)))
(pass-if (equal? '(5 6) (take-right '(4 5 6) 2)))
(pass-if (equal? '(4 5 6) (take-right '(4 5 6) 3)))
(pass-if-exception "(4 5 6) 4" exception:wrong-type-arg
(take-right '(4 5 6) 4))
(pass-if "(a b . c) 0"
(equal? (take-right '(a b . c) 0) 'c))
(pass-if "(a b . c) 1"
(equal? (take-right '(a b . c) 1) '(b . c))))
;;
;; tenth
;;
(with-test-prefix "tenth"
(pass-if-exception "() -1" exception:wrong-type-arg
(tenth '(a b c d e f g h i)))
(pass-if (eq? 'j (tenth '(a b c d e f g h i j))))
(pass-if (eq? 'j (tenth '(a b c d e f g h i j k)))))
;;
;; xcons
;;
(with-test-prefix "xcons"
(pass-if (equal? '(y . x) (xcons 'x 'y))))