mes/tests/scm.test
Jan Nieuwenhuizen a937d18c38
build: Simplify, drop make.scm experiment.
* build.sh: Rewrite.
* build-aux/build-cc.sh: New file.
* build-aux/build-mes.sh: New file.
* build-aux/build-mlibc.sh: New file.
* build-aux/cc.sh: New file.
* build-aux/cc-mes.sh: New file.
* build-aux/cc-mlibc.sh: New file.
* install.sh: Update.
* make.scm: Remove.
* guile/guix/make.scm: Remove.
* guile/guix/records.scm: Remove.
* guile/guix/shell-utilsg.scm: Remove.
2018-04-29 18:38:57 +02:00

159 lines
5.6 KiB
Scheme
Executable file

#! /bin/sh
# -*-scheme-*-
MES=${MES-$(dirname $0)/../src/mes}
$MES -s $0
exit $?
!#
;;; -*-scheme-*-
;;; Mes --- Maxwell Equations of Software
;;; Copyright © 2016,2017,2018 Jan (janneke) Nieuwenhuizen <janneke@gnu.org>
;;;
;;; This file is part of Mes.
;;;
;;; Mes is free software; you can redistribute it and/or modify it
;;; under the terms of the GNU General Public License as published by
;;; the Free Software Foundation; either version 3 of the License, or (at
;;; your option) any later version.
;;;
;;; Mes is distributed in the hope that it will be useful, but
;;; WITHOUT ANY WARRANTY; without even the implied warranty of
;;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
;;; GNU General Public License for more details.
;;;
;;; You should have received a copy of the GNU General Public License
;;; along with Mes. If not, see <http://www.gnu.org/licenses/>.
(mes-use-module (mes scm))
(mes-use-module (srfi srfi-0))
(mes-use-module (mes test))
(pass-if "first dummy" #t)
(pass-if-not "second dummy" #f)
(pass-if "when" (seq? (when #t 'true) 'true))
(pass-if "when 2" (seq? (when #f 'true) *unspecified*))
(pass-if "map" (sequal? (map identity '(1 2 3 4)) '(1 2 3 4)))
(pass-if "map 2 " (sequal? (map (lambda (i a) (cons i a)) '(1 2 3 4) '(a b c d))
'((1 . a) (2 . b) (3 . c) (4 . d))))
(pass-if "for-each" (sequal? (let ((acc '())) (for-each (lambda (x) (set! acc (cons x acc))) '(1 2 3 4)) acc) '(4 3 2 1)))
(define xxxa 0)
(pass-if "set! " (seq? (begin (set! xxxa 1) xxxa) 1))
(pass-if "set! 2" (seq? (let ((a 0)) (set! a 1) a) 1))
(pass-if "list-ref" (seq? (list-ref '(0 1 2) 1) 1))
(pass-if "do" (sequal? (let ((acc '())) (do ((i 0 (+ i 1))) ((>= i 3)) (set! acc (cons i acc))) acc) '(2 1 0)))
(pass-if ">=" (>= 3 2 1))
(pass-if-equal "string-length"
0
(string-length ""))
(pass-if-equal "string-length 2"
3
(string-length (string-append "a" "b" "c")))
(pass-if-equal "string->list"
'()
(string->list ""))
(pass-if-equal "string->list 2"
'(#\a #\b #\c #\newline)
(string->list "abc\n"))
(pass-if "string-append" (sequal? (string-append "a" "b" "c") "abc"))
(pass-if "substring" (sequal? (substring "hello world" 6) "world"))
(pass-if "substring 2" (sequal? (substring "hello world" 4 7) "o w"))
(pass-if "string-ref" (seq? (string-ref "hello world" 4) #\o))
(pass-if "eq?" (not (eq? (string-append "a" "b" "c") "abc")))
(pass-if "char" (seq? (char->integer #\A) 65))
(pass-if "char 2" (seq? (char->integer #\101) (char->integer #\A)))
(pass-if "char 3" (seq? (integer->char 10) #\newline))
(pass-if "char 4" (seq? (integer->char 32) #\space))
(pass-if "string " (sequal? (string #\a #\space #\s #\t #\r #\i #\n #\g) "a string"))
(pass-if "length" (seq? (length '()) 0))
(pass-if "length 2" (seq? (length '(a b c)) 3))
(pass-if "make-list" (seq? (make-list 0) '()))
(pass-if "make-list 1" (sequal? (make-list 1 0) '(0)))
(pass-if "memq" (sequal? (memq 'a '(a b c)) '(a b c)))
(pass-if "memq" (sequal? (memq 'b '(a b c)) '(b c)))
(pass-if "memq" (seq? (memq 'd '(a b c)) #f))
(pass-if "member" (sequal? (member '(a) '((a) b c)) '((a) b c)))
(pass-if "assq-ref" (seq? (assq-ref '((b . 1) (c . 2)) 'c) 2))
(pass-if "assq-ref 2" (seq? (assq-ref '((b . 1) (c . 2)) 'a) #f))
(pass-if "assq-set!" (sequal? (assq-set! '((b . 1)) 'a 0) '((a . 0) (b . 1))))
(pass-if "assq-set! 2" (sequal? (assq-set! '((a . 0)) 'a 1) '((a . 1))))
(pass-if "assoc" (sequal? (assoc '(a . 0) '((a . 0) (b . 1) ((a . 0) aa))) '((a . 0) aa)))
(pass-if-equal "assoc-set!" '((a . 0) (b . 2)) (assoc-set! '((a . 0) (b . 1)) 'b 2))
(pass-if-equal "assoc-set! new" '((b . 2) (a . 0)) (assoc-set! '((a . 0)) 'b 2))
(pass-if "builtin? car" (builtin? car))
(pass-if "builtin? cdr" (builtin? cdr))
(pass-if "builtin? cons" (builtin? cons))
(pass-if "builtin? eq?" (builtin? eq?))
(pass-if "builtin? if" (builtin? eq?))
(when (not guile?)
(pass-if "builtin? eval" (not (builtin? not))))
(pass-if "procedure?" (procedure? builtin?))
(pass-if "procedure?" (procedure? procedure?))
(pass-if "gensym"
(symbol? (gensym)))
(pass-if "gensym 1"
(not (eq? (gensym) (gensym))))
(pass-if "gensym 2"
(not (eq? (gensym) (gensym))))
(pass-if "last-pair " (sequal? (last-pair '(1 2 3 4)) '(4)))
(pass-if "last-pair 2" (seq? (last-pair '()) '()))
;; (pass-if "circular-list? "
;; (seq?
;; (let ((x (list 1 2 3 4)))
;; (set-cdr! (last-pair x) (cddr x))
;; (circular-list? x))
;; #t))
(pass-if-equal "iota"
'(0 1 2) (iota 3))
(pass-if-equal "iota 0"
'() (iota 0))
(pass-if-equal "iota -1"
'() (iota -1))
(pass-if-equal "reverse" '(3 2 1)
(reverse '(1 2 3)))
(pass-if-equal "reverse fresh" '(1 2 3)
(let ((list '(1 2 3)))
(reverse list)
list))
(pass-if-equal "reverse!" '(1)
(let ((list '(1 2 3)))
(reverse! list)
list))
(pass-if-equal "reverse! ()" '()
(reverse! '()))
(pass-if "cond-expand" (sequal? (cond-expand (foobar #f) (mes (display ": pass: *YAY*") 'mes) (guile (display ": pass: *GUILE*") 'mes)) 'mes))
(pass-if "apply identity" (seq? (apply identity '(0)) 0))
(pass-if "apply identity 2" (sequal? (apply identity '((0 1))) '(0 1)))
(pass-if "apply append" (sequal? (apply append '((1 2) (3 4))) '(1 2 3 4)))
(pass-if "char-alphabetic?" (seq? (char-alphabetic? #\a) #t))
(pass-if "char-alphabetic? 2" (seq? (char-alphabetic? #\[) #f))
(pass-if-equal "compose" 1 ((compose car cdr car) '((0 1 2))))
(if (not guile?)
(pass-if "make-vector" (sequal? (make-vector 3) #(*unspecified* *unspecified* *unspecified*))))
(pass-if "make-vector 2" (sequal? (make-vector 3 1) #(1 1 1)))
(result 'report)