2021-04-25 14:57:17 +02:00
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(load "shared/util.scm")
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(load "shared/sicp-evaluator.scm")
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2021-01-22 14:20:46 +01:00
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(display "\nex-4.11 - alternative-frame-implementation\n")
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; Test implementation from book.
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(define env-0 the-empty-environment)
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(define env-1 (extend-environment '(a b) '(1 2) env-0))
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(define env-2 (extend-environment '(c d) '(3 4) env-1))
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(assert (lookup-variable-value 'b env-2) 2)
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(set-variable-value! 'b 42 env-2)
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(assert (lookup-variable-value 'b env-2) 42)
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(define-variable! 'e 5 env-2)
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(assert (lookup-variable-value 'e env-2) 5)
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(define (make-frame variables values)
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(map cons variables values))
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(define (frame-variables frame) (map car frame))
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(define (frame-values frame) (map cdr frame))
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(define (add-binding-to-frame! var val frame)
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(if (null? (cdr frame))
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(set-cdr! frame (cons (cons var val) '()))
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(add-binding-to-frame! var val (cdr frame))))
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(define frame-var car)
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(define frame-val cdr)
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(define (lookup-variable-value var env)
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(define (env-loop env)
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(define (scan vars vals)
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(cond ((null? vars)
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(env-loop (enclosing-environment env)))
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((eq? var (car vars))
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(car vals))
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(else (scan (cdr vars) (cdr vals)))))
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(if (eq? env the-empty-environment)
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(error "Unbound variable" var)
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(let ((frame (first-frame env)))
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(scan (frame-variables frame)
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(frame-values frame)))))
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(env-loop env))
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(define (set-variable-value! var val env)
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(define (env-loop env)
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(define (scan frame)
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(cond ((null? frame)
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(env-loop (enclosing-environment env)))
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((eq? var (frame-var (car frame)))
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(set-cdr! (car frame) val))
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(else (scan (cdr frame)))))
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(if (eq? env the-empty-environment)
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(error "Unbound variable -- SET!" var)
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(let ((frame (first-frame env)))
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(scan frame))))
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(env-loop env))
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(define (define-variable! var val env)
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(let ((frame (first-frame env)))
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(define (scan frame)
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(cond ((null? frame)
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(add-binding-to-frame! var val (first-frame env)))
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((eq? var (frame-var (car frame)))
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(set-cdr! (car frame) val))
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(else (scan (cdr frame)))))
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(scan frame)))
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(define env-0 the-empty-environment)
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(define env-1 (extend-environment '(a b) '(1 2) env-0))
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(define env-2 (extend-environment '(c d) '(3 4) env-1))
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(assert (lookup-variable-value 'b env-2) 2)
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(set-variable-value! 'b 42 env-2)
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(assert (lookup-variable-value 'b env-2) 42)
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(define-variable! 'e 5 env-2)
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(assert (lookup-variable-value 'e env-2) 5)
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(display "\nex-4.12 - abstract-traversal\n")
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(define (find-pair-frame var frame)
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(assoc var frame))
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(define (find-pair-env var env)
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(define (env-loop env)
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(if (eq? env the-empty-environment)
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#f
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(let ((pair (assoc var (first-frame env))))
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(if (pair? pair)
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pair
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(env-loop (enclosing-environment env))))))
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(env-loop env))
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(define (lookup-variable-value var env)
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(let ((pair (find-pair-env var env)))
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(if (eq? pair #f)
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(error "Unbound variable" var)
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(frame-val pair))))
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(define (set-variable-value! var val env)
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(let ((pair (find-pair-env var env)))
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(if (pair? pair)
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(set-cdr! pair val)
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'())))
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(define (define-variable! var val env)
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(let ((frame (first-frame env)))
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(let ((pair (assoc var frame)))
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(if (pair? pair)
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(set-cdr! pair val)
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(add-binding-to-frame! var val frame)))))
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(define env-0 the-empty-environment)
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(define env-1 (extend-environment '(a b) '(1 2) env-0))
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(define env-2 (extend-environment '(c d) '(3 4) env-1))
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(assert (find-pair-env 'd env-2) (cons 'd 4))
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(assert (lookup-variable-value 'b env-2) 2)
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(set-variable-value! 'b 42 env-2)
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(assert (lookup-variable-value 'b env-2) 42)
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(define-variable! 'e 5 env-2)
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(assert (lookup-variable-value 'e env-2) 5)
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(display "\nex-4.13 - make-unbound!\n")
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; It seems like the reason for removing a binding is when one wants get access
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; to the same symbol in an outer environment. Therefore, we implement
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; make-unbound! so that it only deletes the symbol from the first frame in
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; which it is defined.
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(define (frame-without-var var frame)
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(cond
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((null? frame) '())
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((eq? var (frame-var (car frame))) (cdr frame))
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(else (cons (car frame) (frame-without-var var (cdr frame))))))
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(define (make-unbound-first! var env)
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(let ((len (length (first-frame env))))
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(set-car! env (frame-without-var var (first-frame env)))
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(if (= len (length (first-frame env)))
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#f
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#t)))
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(assert (make-unbound-first! 'd env-2) #t)
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(assert (make-unbound-first! 'e env-2) #t)
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(assert (make-unbound-first! 'b env-2) #f)
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(assert (make-unbound-first! 'c env-2) #t)
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(assert (first-frame env-2) '())
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(define (make-unbound! var env)
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(define (loop env)
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(if (eq? env the-empty-environment)
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#f
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(if (make-unbound-first! var env)
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#t
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(loop (enclosing-environment env)))))
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(loop env))
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(define env-0 the-empty-environment)
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(define env-1 (extend-environment '(a b) '(1 2) env-0))
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(define env-2 (extend-environment '(c d) '(3 4) env-1))
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(define env-3 (extend-environment '(a b) '(3 6) env-2))
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(assert (lookup-variable-value 'b env-3) 6)
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(assert (make-unbound! 'b env-3) #t)
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(assert (lookup-variable-value 'b env-3) 2)
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(assert (make-unbound! 'b env-3) #t)
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(assert (make-unbound! 'b env-3) #f)
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2021-01-22 17:05:51 +01:00
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(display "\nex-4.14 - map\n")
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2021-01-22 14:20:46 +01:00
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2021-01-22 17:05:51 +01:00
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; Louis's implementation of map will not work because the evaluator will
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; evaluate the lambda expression into a procedure list. The Scheme interpreter
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; does not know how to evaluate that list. Hence, the operation fails.
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2021-01-22 14:20:46 +01:00
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2021-01-22 17:05:51 +01:00
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(display "[answered]\n")
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(display "\nex-4.15 - halts?\n")
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(define (run-forever) (run-forever))
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(define (try p)
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(if (halts? p p)
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(run-forever)
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'halted))
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; Suppose (try try) runs forever then halts? evaluates to wrong and try returns
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; halt. That is a contradiction. Suppose (try try) halts. Then halts? evaluates
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; to true and try runs forever; again a contradiction. Therefore, a general
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; procedure halts? cannot exist.
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(display "[answered]\n")
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2021-01-23 20:02:35 +01:00
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(display "\nex-4.16 - scan-out-defines\n")
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2021-01-22 17:05:51 +01:00
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(define (lookup-variable-value var env)
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(let ((pair (find-pair-env var env)))
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(if (eq? pair #f)
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(error "Unbound variable" var)
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(let ((value (frame-val pair)))
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(if (eq? value '*unassigned*)
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(error "Unassigned variable" var)
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value)))))
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(define (scan-out-defines body)
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2021-01-23 20:02:35 +01:00
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(define (get-defines body)
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(cond
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((null? body) '())
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((definition? (car body)) (cons (car body) (get-defines (cdr body))))
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(else (get-defines (cdr body)))))
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(define (expression->new-expression exp)
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(if (definition? exp)
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(define->set exp)
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exp))
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(define (define->let-assignment def)
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(list (definition-variable def) '*unassigned*))
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(define (define->set def)
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(list 'set! (definition-variable def) (definition-value def)))
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(let* ((defines (get-defines body))
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(let-assignments (map define->let-assignment defines))
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(let-expression (list 'let let-assignments))
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(expressions (map expression->new-expression body)))
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(append let-expression expressions)))
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(define body
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'((define x 3)
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(if #t 1 2)
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(define b 2)
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(display "hello")))
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(define body-transformed
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'(let ((x *unassigned*)
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(b *unassigned*))
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(set! x 3)
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(if #t 1 2)
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(set! b 2)
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(display "hello")))
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(assert (scan-out-defines body) body-transformed)
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; I would install scan-out-defines into make-procedure. We might run into a
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; situation where we update the body of a procedure and call procedure-body
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; twice.
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(define (make-procedure parameters body env)
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(list 'procedure parameters (scan-out-defines body) env))
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2021-01-22 17:05:51 +01:00
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2021-01-24 17:12:40 +01:00
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(display "\nex-4.17 - extra-frame\n")
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2021-01-22 17:05:51 +01:00
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2021-01-23 20:02:35 +01:00
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; Why is there an extra frame in the transformed program? We have implemented
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; let via an additional transformation. Therefore, there is another
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; lambda-expression that results in an extra frame.
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; Explain why this difference in environment structure can never make a
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; difference in the behavior of a correct program? The transformation keeps the
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; order of the assignments. Hence, the behavior will not change.
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; Design a way to make the interpreter implement the ``simultaneous'' scope
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; rule for internal definitions without constructing the extra frame? We could
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; simply add a list of (define symbol *unassigned*) at the beginning of the
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; body and get the same behavior without an extra frame.
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(display "[answered]\n")
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(display "\nex-4.18 - alternative-scan-out\n")
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(define (solve f y0 dt)
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(define y (integral (delay dy) y0 dt))
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(define dy (stream-map f y))
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y)
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; Transformation from text:
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(lambda (f y0 dt)
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(let ((y '*unassigned*)
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(dy '*unassigned*))
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(set! y (integral (delay dy) y0 dt))
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(set! dy (stream-map f y))
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y))
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; Transformation from this exercise:
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(lambda (f y0 dt)
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(let ((y '*unassigned*)
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(dy '*unassigned*))
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(let ((a (integral (delay dy) y0 dt))
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(b (stream-map f y)))
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(set! y a)
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(set! dy b)
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y)))
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; The second transformation will not work because when b is evaluated y is not
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; yet assigned. The first transformation works because y was already set when
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; dy is set.
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(display "[answered]\n")
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2021-01-24 17:12:40 +01:00
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(display "\nex-4.19 - ambiguous-expression\n")
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2021-01-23 20:02:35 +01:00
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2021-01-24 17:12:40 +01:00
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; (let ((a 1))
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; (define (f x)
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; (define b (+ a x))
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; (define a 5)
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; (+ a b))
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; (f 10))
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2021-01-22 17:05:51 +01:00
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2021-01-24 17:12:40 +01:00
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; Ben: 16
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; Alyssa: error
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; Eva: 20
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; To implement Eva's suggested behavior one could reorder the defines so that
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; defines with self-evaluating expressions are interpreted first.
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(display "[answered]\n")
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(display "\nex-4.20 - letrec\n")
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(letrec ((fact
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(lambda (n)
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(if (= n 1)
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1
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(* n (fact (- n 1)))))))
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(assert (fact 10) 3628800))
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(define letrec-before
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'(letrec ((a 3) (b 2))
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(+ a b)))
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(define letrec-after
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'(let ((a *unassigned*) (b *unassigned*))
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(set! a 3)
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(set! b 2)
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(+ a b)))
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(define (letrec? exp) (tagged-list exp 'letrec))
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(define (letrec-bindings exp) (cadr exp))
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(define (letrec-body exp) (cddr exp))
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(define (letrec-binding-var binding) (car binding))
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(define (letrec-binding-exp binding) (cadr binding))
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(define (letrec-vars exp) (map let-binding-var (let-bindings exp)))
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(define (letrec-exps exp) (map let-binding-exp (let-bindings exp)))
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(define (letrec->combination exp)
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(define (binding->unassigned binding)
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(list (letrec-binding-var binding) '*unassigned*))
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(define (binding->set binding)
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(list 'set! (letrec-binding-var binding) (letrec-binding-exp binding)))
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(let* ((bindings (letrec-bindings exp))
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(bindings-unassigned (map binding->unassigned bindings))
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(let-unassigned (list 'let bindings-unassigned))
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(set-exps (map binding->set bindings))
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(body (letrec-body exp)))
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(append
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(append let-unassigned set-exps)
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body)))
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(assert (letrec->combination letrec-before) letrec-after)
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; b. With the let implementation the procedures odd? and even? cannot see and
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; therefore not call each other.
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(display "\nex-4.21 - recursive-without-define/letrec\n")
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; factorial
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(assert
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((lambda (n)
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|
((lambda (fact)
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|
(fact fact n))
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|
(lambda (ft k)
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|
(if (= k 1)
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1
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(* k (ft ft (- k 1)))))))
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|
10)
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|
3628800)
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|
|
; a. Fibonacci
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|
|
(define (fibo n)
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|
|
(cond
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|
((= n 0) 0)
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|
((< n 3) 1)
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|
(else (+ (fibo (- n 2)) (fibo (- n 1))))))
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|
|
(assert
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|
((lambda (n)
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|
((lambda (fib)
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|
|
(fib fib n))
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|
(lambda (f k)
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|
|
(cond
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|
|
((= k 0) 0)
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|
((< k 3) 1)
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|
(else (+ (f f (- k 2)) (f f (- k 1))))))))
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|
|
11)
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|
|
(fibo 11))
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|
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|
; b. odd?/even?
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|
|
(define (f x)
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|
|
((lambda (even? odd?)
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|
|
(even? even? odd? x))
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|
|
(lambda (ev? od? n)
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|
|
(if (= n 0) true (od? ev? od? (- n 1))))
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|
|
(lambda (ev? od? n)
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|
|
(if (= n 0) false (ev? ev? od? (- n 1))))))
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|
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|
|
(assert (f 31) false)
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|
|
(assert (f 42) true)
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|