(load "codegen.scm")
(load "typecheck.scm")
-(define (test actual expected)
- (when (not (equal? actual expected))
+(define (test-f pred actual expected)
+ (when (not (pred actual expected))
(error #f
(format "test failed:\nexpected: ~a\nactual: ~a"
expected actual))))
+(define (test . xs) (apply test-f (cons equal? xs)))
+(define (test-types . xs) (apply test-f (cons types-equal? xs)))
+
(define (read-file file)
(call-with-input-file file
(lambda (p)
result
(loop (read-char p) (string-append result (string next))))))))
-(define (test-prog prog output)
- (compile-to-binary prog "/tmp/test-prog")
+(define (test-prog prog exit-code)
+ (display prog)
+ (newline)
+ (compile-to-binary prog "/tmp/test-prog" host-os)
+ (test (system "/tmp/test-prog") exit-code))
+
+(define (test-prog-stdout prog output)
+ (display prog)
+ (newline)
+ (compile-to-binary prog "/tmp/test-prog" host-os)
(system "/tmp/test-prog > /tmp/test-output.txt")
(let ((str (read-file "/tmp/test-output.txt")))
- (test (substring str 0 (- (string-length str) 1))
- output)))
+ (test str output)))
-(test (typecheck '(lambda (x) (+ ((lambda (y) (x y 3)) 5) 2)))
+(test-types (typecheck '(lambda (x) (+ ((lambda (y) (x y 3)) 5) 2)))
'(abs (abs int (abs int int)) int))
-(test-prog '(+ 1 2) "3")
-(test-prog '((lambda (x) ((lambda (y) (+ x y)) 42)) 100) "142")
+ ; recursive types
+
+(test-types (substitute '((t1 (abs t1 t10))) 't1) '(abs t1 t10))
+
+(test-types (typecheck '(let ([bar (lambda (y) y)]
+ [foo (lambda (x) (foo (bar #t)))])
+ foo))
+ '(abs bool a))
+
+(test-types (typecheck '(let ([bar (lambda (y) y)]
+ [foo (lambda (x) (foo (bar #t)))])
+ bar))
+ '(abs a a))
+
+(test-types (typecheck '(let ([foo 3]
+ [bar (+ foo baz)]
+ [baz (- bar 1)])
+ bar))
+ 'int)
+
+(test-types (typecheck '(let ([foo 3]
+ [bar (baz foo)]
+ [baz (lambda (x) x)])
+ baz))
+ '(abs a a))
+
+(test-types (typecheck '(let ([foo 3]
+ [bar (baz foo)]
+ [baz (lambda (x) x)])
+ bar))
+ 'int)
+
+(test-prog '(+ 1 2) 3)
+(test-prog '(bool->int (= 2 0)) 0)
+(test-prog '((lambda (x) ((lambda (y) (+ x y)) 42)) 100) 142)
+
+(test-prog '(* 10 5) 50)
+
(test-prog '(let ((x (+ 1 32))
(y x))
- ((lambda (z) (+ 1 z)) (* y x)))
- "1090")
-(test-prog '(if ((lambda (x) (= x 2)) 1) 0 (- 32 1)) "31")
+ ((lambda (z) (+ 2 z)) (* y x)))
+ 67) ; exit code modulos at 256
+(test-prog '(if ((lambda (x) (= x 2)) 1) 0 (- 32 1)) 31)
+
+(test-prog-stdout '(if (= 3 2) 1 (let () (print "hello world!") 0)) "hello world!")
+
+(test-prog '((lambda (x y) (+ x y)) 1 2) 3)
+(test-prog '((lambda (x) (+ ((lambda (y) (+ y 1)) 3) x)) 2) 6)
+
+ ; passing closures about
+(test-prog '((lambda (z) ((lambda (x) (x 1)) (lambda (y) (+ z y)))) 2) 3)
+
+ ; passing builtins about
+(test-prog '((lambda (x) ((lambda (a b) (a b 3)) + x)) 3) 6)
+(test-prog '(bool->int ((lambda (x) (x #f)) !)) 1)
+(test-prog '((lambda (f) (f #t)) bool->int) 1)
+(test-prog-stdout '(let () ((lambda (f) (f "foo")) print) 0) "foo")
+(test-prog '((lambda (f) (f 3 3)) (lambda (x y) (bool->int (= x y)))) 1)
+(test-prog '(bool->int ((lambda (f) (! (f 2 3))) =)) 1)
+
+ ; recursion
+(test-prog '(let [(inc (lambda (f n x)
+ (if (= n 0)
+ x
+ (f f (- n 1) (+ x 1)))))]
+ (inc inc 3 2))
+ 5)
+
+(test-prog '(let ([go (lambda (n m x)
+ (if (= n 0)
+ x
+ (go (- n 1) m (* x m))))]
+ [pow (lambda (p y) (go p y 1))])
+
+ (pow 3 2))
+ 8)
+(test-prog '(let ([pow (lambda (p y)
+ (let ([go (lambda (n x)
+ (if (= n 0)
+ x
+ (go (- n 1) (* x y))))])
+ (go p 1)))])
+ (pow 4 2))
+ 16)