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用call/cc合成所有的控制流结构

用call/cc合成所有的控制流结构

作者: 小小阴谋家 | 来源:发表于2016-09-24 14:39 被阅读0次

    前言

    我们都知道call/cc是最强大的控制流语句,几乎所有控制流语句(极少特殊的不能)都能用call/cc合成。那么我就来进行一下总结,用call/cc合成所有的控制流结构。如果您觉得有实现不正确的,欢迎在文章底部进行评论,我将对这篇文章进行更新。
    除此之外,你还将学习到一些关于scheme宏编写的知识。

    除最后一段代码以外均在racket v6.6下测试通过。

    while语句

    包含while,continue和break。

    (require racket/stxparam)
    (define-syntax-parameter break (syntax-rules ()))
    (define-syntax-parameter continue (syntax-rules ()))
    (define-syntax while
      (syntax-rules ()
        [(_ test body ...)
            (call/cc (lambda (k1)
                       (let ([t (void)])
                        (begin (call/cc (lambda (k2) (set! t k2)))
                               (syntax-parameterize
                                   ([break (syntax-rules ()
                                             [(_) (k1 (void))])]
                                    [continue (syntax-rules ()
                                             [(_) (t (void))])])
                                 (when (not test) (break))
                                 body ... (continue))))))]))
    
    (let ([a 1])
      (while (< a 10)
             (set! a (+ a 1))
             (display a)))
    
    (let ([a 1])
      (while (< a 10)
             (set! a (+ a 1))
             (when (= a 5) (break))
             (display a)))
    
    (let ([a 1])
      (while (< a 10)
             (set! a (+ a 1))
             (when (= a 5) (continue))
             (display a)))
    
    (let ([a 1])
      (while (< a 10)
             (set! a (+ a 1))
             (let ([b 1])
               (while (< b a)
                    (display b)
                    (display " ")
                    (set! b (+ b 1))
                    (when (= b 5) (break))
                    )
             (display a)
             (display " "))))
    

    第一个测试输出:2345678910
    第二个测试输出:234
    第三个测试输出:234678910
    第四个测试输出:1 2 1 2 3 1 2 3 4 1 2 3 4 5 1 2 3 4 6 1 2 3 4 7 1 2 3 4 8 1 2 3 4 9 1 2 3 4 10

    goto语句

    (require racket/stxparam)
    (define-syntax-parameter goto (syntax-rules ()))
    (define-syntax prog
      (syntax-rules (label)
        [(_ "expanding" ((l1 code1 ...)(l codes ...) ...))
            ((call/cc (lambda (k)
                        (syntax-parameterize ([goto (syntax-rules ()
                                                      [(_ w) (k w)])]
                                                      )
                        (letrec ([l1 (lambda () (let () code1 ...))]
                                 [l (lambda () (let () (void) codes ...))] ...)
                          l1)))))]
        [(_ "expanding" (a ... (l codes ...)) (label lname) rest ...)
            (prog "expanding" (a ... (l codes ... (lname)) (lname)) rest ...)]
        [(_ "expanding" (i ... (l codes ...)) code1 rest ...)
            (prog "expanding" (i ... (l codes ... code1)) rest ...)]
        [(_ xxx ...)
            (prog "expanding" ((start-label)) xxx ...)]))
    
    (prog
          (goto k)
          (display "1")
          (label k)
          (display 2)
          )
    

    exception

    已经在上一篇文章Dynamic Scoping in Scheme提过,不再赘述。

    Generators

    很久之前写的东西,代码风格有些不一样。

    ;;;implement generators in scheme
    ;;;bugs fixed : Reset the Continuations
    (define *meta-cont* (lambda (v) (error "No Top Level generator")))
    (define-syntax (generator stx)
      (syntax-case stx ()
        [(generator expr ...)  #`(letrec (
                         [#,(datum->syntax #'generator `*cont*)
                          (lambda (v)
                            (reset expr ...)
                            )])
                         (lambda ()
                            (#,(datum->syntax #'generator `*cont*) (void))
                         ))]))
    
    (define-syntax yield
      (lambda (stx)
        (syntax-case stx ()
          [(yield  v) #`(call/cc (lambda (k)
                                (set! #,(datum->syntax #'yield `*cont*) (lambda (va) (reset (k va))))
                                   (*meta-cont* v)
                                   ))]
           )))
    
    
    (define-syntax reset
      (syntax-rules ()
        [(_ expr ...) (let ([preserved *meta-cont*])
                        (call/cc (lambda (k)
                                   (set! *meta-cont* (lambda (v) (set! *meta-cont* preserved) (k v)))
                                   (let ([result (begin expr ...)])
                                     (*meta-cont* result)
                                         ))))]))
    
    ;;example : yielding values
    (define y (generator (yield 1)
                         (yield 2)
                         (yield 3)))
    (y)
    (y)
    (y)
    
    ;;example : producer and consumer
    (define (looper thunk) (thunk) (looper thunk))
    (define product #f)
    (define p (generator (for-each (lambda (f)
                                     (set! product f)
                                     (display "I have put ")
                                     (display f)
                                     (newline)
                                     (yield (c))) `(apple pea grape banana))))
    
    (define c (generator (looper (lambda ()
                                   (display "I have eaten ")
                                   (display product)
                                   (newline)
                                   (set! product #f)
                                   (yield (p))))))
    
    (p)
    
    ;;example : generator makes infinite stream
    
    (define i (let ([v 0])
                  (generator (looper (lambda ()
                                (set! v (+ v 1))
                                (yield (stream-cons v (i))))))))
    (define s (i))
    
    (stream-ref s 0)
    (stream-ref s 1)
    (stream-ref s 2)
    (stream-ref s 0)
    (stream-ref s 100)
    
    
    ;;example : map generators
    
    (define map-generator
      (lambda (f g)
        (generator (looper (lambda ()
                             (yield (f (g))))))))
    
    (define a (map-generator (lambda (x) (+ 2 x))
               (generator (yield 1)
                         (yield 2)
                         (yield 3))))
    
    (a)
    (a)
    (a)
    

    tips:这样实现的generator可能会导致memory leaking。

    coroutines,fibers

    与generator原理类似,但略有不同,基本上每一本scheme语言的教材都有相关的代码,可以看the scheme programming language,4th edititon,就不给代码了。

    Partial Continuation

    shift/reset

    用callcc实现的shift/reset会有效率问题,和上面的generator一样,可能会导致内存泄漏,建议用racket自带的(racket/control)。

    (define *meta-cont* (lambda (v) (error "No Top Level reset")))
    (define-syntax reset
      (syntax-rules ()
        [(_ expr ...) (let ([preserved *meta-cont*])
                        (call/cc (lambda (k)
                                   (set! *meta-cont* (lambda (v) (set! *meta-cont* preserved) (k v)))
                                   (let ([result (begin expr ...)])
                                     (*meta-cont* result))
                                     )))]))
    
    (define-syntax shift
      (syntax-rules ()
        [(_ k expr ...) (call/cc
                         (lambda (k1)
                           (let* ([k (lambda (v) (reset (k1 v)))]
                                  [v (begin expr ...)]
                                  )
                             (*meta-cont* v))))]))
    
    (reset (+ 1 (shift k (k (k 1)))))
    (((reset (+ (shift a a) (shift b b))) 1) 3)
    

    shift0/reset0

    类似于shift/reset,把meta-cont换成了一个表。

    (define *meta-cont* (list (lambda (v) (error "No Top Level rest0"))))
    (define-syntax reset0
      (syntax-rules ()
        [(_ expr ...) (call/cc (lambda (k)
                                 (set! *meta-cont* (cons k
                                                    *meta-cont*
                                                    ))
                                 (let ([result (begin expr ...)]
                                       [c (car *meta-cont*)]
                                       [e (set! *meta-cont* (cdr *meta-cont*))]
                                       )
                                     (c result))
                                     ))]))
    
    (define-syntax shift0
      (syntax-rules ()
        [(_ k expr ...) (call/cc
                         (lambda (k1)
                           (let* ([k (lambda (v) (reset0 (k1 v)))]
                                  [c (car *meta-cont*)]
                                  [e (set! *meta-cont* (cdr *meta-cont*))]
                                  [v (begin expr ...)]
                                  )
                             (c v))))]))
    
    (reset0 (cons 1 (reset0 (shift0 k 2))))
    (reset0 (cons 1 (reset0 (shift0 k (shift0 t 2)))))
    (reset0 (+ 1 (shift0 k (k (k 1)))))
    (reset0 (cons 1 (reset0 (reset0 (shift0 k (shift0 t 1))))))
    *meta-cont*
    

    dynamic-wind,unwind-protect

    因为tspl上有实现的代码,我把它贴出来一下:(以下代码来自the scheme programming language,4th edititon

    (define dynamic-wind #f)
     (let ((winders '()))
       (define common-tail
         (lambda (x y)
           (let ((lx (length x)) (ly (length y)))
             (do ((x (if (> lx ly) (list-tail x (- lx ly)) x) (cdr x))
                  (y (if (> ly lx) (list-tail y (- ly lx)) y) (cdr y)))
                 ((eq? x y) x)))))
       (define do-wind
         (lambda (new)
           (let ((tail (common-tail new winders)))
             (let f ((l winders))
               (if (not (eq? l tail))
                   (begin
                     (set! winders (cdr l))
                     ((cdar l))
                     (f (cdr l)))))
             (let f ((l new))
               (if (not (eq? l tail))
                   (begin
                     (f (cdr l))
                     ((caar l))
                     (set! winders l)))))))
       (set! call/cc
         (let ((c call/cc))
           (lambda (f)
             (c (lambda (k)
                  (f (let ((save winders))
                       (lambda (x)
                         (if (not (eq? save winders)) (do-wind save))
                         (k x)))))))))
       (set! call-with-current-continuation call/cc)
       (set! dynamic-wind
         (lambda (in body out)
           (in)
           (set! winders (cons (cons in out) winders))
           (let ((ans (body)))
             (set! winders (cdr winders))
             (out)
             ans)))) 
    

    engines

    很遗憾,这个结构无法用call/cc合成。

    recommend readings
    1.the scheme programming language,chapter 5
    2.applications of continuations,Dan P Friedman
    3.schemewiki call-with-current-continuation & composable-continuations-tutorial
    4.
    lisp in small pieces,chapter 3

    5.wiki:delimited continuations
    6.okmij.org :Continuations and delimited control
    7.matt might :Continuations by example: Exceptions, time-traveling search, generators, threads, and coroutines

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