+(load "utils.scm")
+
(define (ast-type x)
(define (builtin? x)
(case x
('app (map f x))
('lambda `(lambda ,(lambda-args x) ,(f (lambda-body x))))
('if `(if ,@(map f (cdr x))))
- ('stack `(stack ,(cadr x) ,(map f (caddr x))))
+ ('stack `(stack ,(cadr x) ,(f (caddr x))))
(else x)))
(define (ast-collect f x)
['stack (either (p x) (inner (caddr x)))]
[else (p x)]))
-(define (let-bindings e)
- (define (pattern-match binding body)
- (if (eqv? (ast-type binding) 'var)
- (list (cons binding body))
- (let* ([constructor (car binding)]
- [destructor (lambda (i) (dtor-name constructor i))])
- (flat-map (lambda (y i)
- (pattern-match y `((,(destructor i) ,@body))))
- (cdr binding)
- (range 0 (length (cdr binding)))))))
- (flat-map (lambda (x) (pattern-match (car x) (cdr x))) (cadr e)))
+(define let-bindings cadr)
(define let-body cddr)
+ ; (let ([(foo a b) (foo 123 345)]) a)
+ ; |
+ ; v
+ ; (let ([a (foo~0 (foo 123 345)]
+ ; [b (foo~1 (foo 123 345)]) a)
+(define (expand-pattern-matches program)
+ (define (go x)
+ (define (pattern-match binding)
+ (let ([binding-name (car binding)]
+ [body (cadr binding)])
+ (if (eqv? (ast-type binding-name) 'var)
+ (list (list binding-name body))
+
+ (let* ([sum-name (car binding-name)]
+ [destructor (lambda (i) (dtor-name sum-name i))]
+ [products (cdr binding-name)]
+
+ [data-layouts (program-data-layouts program)]
+
+ [type (data-tor-type data-layouts sum-name)]
+
+ [sums (cdr (assoc type data-layouts))]
+ [sum (assoc sum-name sums)]
+
+ [expected-number (length (cdr sum))])
+
+ ; assert that we only do a let pattern match on an ADT with exactly one sum
+ (when (not (= 1 (length sums)))
+ (error #f (format "Cannot pattern match a ~a in a let since it has ~a possible constructors"
+ type
+ (length sums))))
+
+ ; assert that there is the correct number of bindings
+ (when (not (= (length products)
+ expected-number))
+ (error #f (format "Got ~a bindings: expected ~a for ~a"
+ (length products)
+ expected-number
+ binding)))
+
+ (flat-map (lambda (y i)
+ (pattern-match (list y `(,(destructor i) ,body))))
+ products
+ (range 0 (length products)))))))
+ (case (ast-type x)
+ ['let `(let ,(flat-map pattern-match (let-bindings x))
+ ,@(map go (let-body x)))]
+ [else (ast-traverse go x)]))
+ (program-map-exprs go program))
+
(define (lambda? x)
(and (list? x) (eq? (car x) 'lambda)))
-
(define (statement-type x)
(cond
[(and (list? x)
(filter (lambda (x) (eqv? (statement-type x) 'defines))
program))
+(define (program-map-exprs f program)
+ (map (lambda (x)
+ (case (statement-type x)
+ ['expr (f x)]
+ [else x]))
+ program))
+
(define (program-body program)
; hack to have multi-expression bodies
`(let ()
,@(filter (lambda (x) (eqv? (statement-type x) 'expr))
program)))
+(define (data-tor-type data-layouts tor)
+ (let* ([tors (flat-map data-tors data-layouts)]
+ [info (cadr (assoc tor tors))])
+ (car info)))
+
; a data tor is either a constructor or destructor for an ADT
; data-tors returns constructors and destructors for a data-layout
; (data A (foo Int Bool)
(strong-connect v)))
(car graph)))
result))
-
-
- ; utils
-
-(define (range s n)
- (if (= 0 n) '()
- (append (range s (- n 1))
- (list (+ s (- n 1))))))
-
-(define (flat-map f . xs) (fold-left append '() (apply map (cons f xs))))
-(define (repeat x n) (if (<= n 0) '()
- (cons x (repeat x (- n 1)))))
-
-
-(define-syntax push!
- (syntax-rules ()
- ((_ s x) (set! s (cons x s)))))
-
-(define-syntax pop!
- (syntax-rules ()
- ((_ s) (let ([x (car s)])
- (set! s (cdr s))
- x))))