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448 lines
17 KiB
Org Mode
448 lines
17 KiB
Org Mode
#+TITLE: 2.4 - Multiple Representations for Abstract Data
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* Representations for Complex Numbers
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* Tagged Data
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#+begin_src scheme :tangle yes
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;; ===================================================================
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;; 2.4.2: Tagged Data
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;; ===================================================================
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(define (attach-tag type-tag contents)
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(cons type-tag contents))
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(define (type-tag datum)
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(if (pair? datum)
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(car datum)
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(error "Bad tagged datum -- TYPE-TAG" datum)))
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(define (contents datum)
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(if (pair? datum)
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(cdr datum)
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(error "Bad tagged datum -- CONTENTS" datum)))
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(define (rectangular? z)
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(eq? (type-tag z) 'rectangular))
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(define (polar? z)
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(eq? (type-tag z) 'polar))
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(define (real-part-rectangular z) (car z))
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(define (imag-part-rectangular z) (cdr z))
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(define (magnitude-rectangular z)
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(sqrt (+ (square (real-part-rectangular z))
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(square (imag-part-rectangular z)))))
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(define (angle-rectangular z)
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(atan (imag-part-rectangular z)
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(real-part-rectangular z)))
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(define (make-from-real-imag-rectangular x y)
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(attach-tag 'rectangular (cons x y)))
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(define (make-from-mag-ang-rectangular r a)
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(attach-tag 'rectangular
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(cons (* r (cos a)) (* r (sin a)))))
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(define (real-part-polar z)
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(* (magnitude-polar z) (cos (angle-polar z))))
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(define (imag-part-polar z)
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(* (magnitude-polar z) (sin (angle-polar z))))
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(define (magnitude-polar z) (car z))
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(define (angle-polar z) (cdr z))
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(define (make-from-real-imag-polar x y)
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(attach-tag 'polar
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(cons (sqrt (+ (square x) (square y)))
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(atan y x))))
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(define (make-from-mag-ang-polar r a)
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(attach-tag 'polar (cons r a)))
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(define (real-part z)
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(cond ((rectangular? z)
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(real-part-rectangular (contents z)))
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((polar? z)
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(real-part-polar (contents z)))
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(else (error "Unknown type -- REAL-PART" z))))
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(define (imag-part z)
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(cond ((rectangular? z)
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(imag-part-rectangular (contents z)))
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((polar? z)
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(imag-part-polar (contents z)))
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(else (error "Unknown type -- IMAG-PART" z))))
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(define (magnitude z)
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(cond ((rectangular? z)
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(magnitude-rectangular (contents z)))
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((polar? z)
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(magnitude-polar (contents z)))
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(else (error "Unknown type -- MAGNITUDE" z))))
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(define (angle z)
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(cond ((rectangular? z)
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(angle-rectangular (contents z)))
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((polar? z)
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(angle-polar (contents z)))
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(else (error "Unknown type -- ANGLE" z))))
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(define (add-complex z1 z2)
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(make-from-real-imag (+ (real-part z1) (real-part z2))
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(+ (imag-part z1) (imag-part z2))))
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(define (make-from-real-imag x y)
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(make-from-real-imag-rectangular x y))
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(define (make-from-mag-ang r a)
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(make-from-mag-ang-polar r a))
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#+end_src
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* Data-Directed Programming and Additivity
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#+begin_src scheme :tangle yes
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;; ===================================================================
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;; 2.4.3: Data-Directed Programming and Additivity
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;; ===================================================================
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(define (install-rectangular-package)
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;; internal procedures
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(define (real-part z) (car z))
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(define (imag-part z) (cdr z))
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(define (make-from-real-imag x y) (cons x y))
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(define (magnitude z)
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(sqrt (+ (square (real-part z))
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(square (imag-part z)))))
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(define (angle z)
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(atan (imag-part z) (real-part z)))
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(define (make-from-mag-ang r a)
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(cons (* r (cos a)) (* r (sin a))))
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;; interface to the rest of the system
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(define (tag x) (attach-tag 'rectangular x))
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(put 'real-part '(rectangular) real-part)
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(put 'imag-part '(rectangular) imag-part)
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(put 'magnitude '(rectangular) magnitude)
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(put 'angle '(rectangular) angle)
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(put 'make-from-real-imag 'rectangular
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(lambda (x y) (tag (make-from-real-imag x y))))
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(put 'make-from-mag-ang 'rectangular
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(lambda (r a) (tag (make-from-mag-ang r a))))
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'done)
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(define (install-polar-package)
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;; internal procedures
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(define (magnitude z) (car z))
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(define (angle z) (cdr z))
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(define (make-from-mag-ang r a) (cons r a))
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(define (real-part z)
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(* (magnitude z) (cos (angle z))))
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(define (imag-part z)
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(* (magnitude z) (sin (angle z))))
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(define (make-from-real-imag x y)
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(cons (sqrt (+ (square x) (square y)))
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(atan y x)))
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;; interface to the rest of the system
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(define (tag x) (attach-tag 'polar x))
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(put 'real-part '(polar) real-part)
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(put 'imag-part '(polar) imag-part)
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(put 'magnitude '(polar) magnitude)
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(put 'angle '(polar) angle)
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(put 'make-from-real-imag 'polar
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(lambda (x y) (tag (make-from-real-imag x y))))
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(put 'make-from-mag-ang 'polar
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(lambda (r a) (tag (make-from-mag-ang r a))))
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'done)
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(define (apply-generic op . args)
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(let ((type-tags (map type-tag args)))
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(let ((proc (get op type-tags)))
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(if proc
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(apply proc (map contents args))
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(error
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"No method for these types -- APPLY-GENERIC"
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(list op type-tags))))))
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(define (real-part z) (apply-generic 'real-part z))
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(define (imag-part z) (apply-generic 'imag-part z))
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(define (magnitude z) (apply-generic 'magnitude z))
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(define (angle z) (apply-generic 'angle z))
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(define (make-from-real-imag x y)
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((get 'make-from-real-imag 'rectangular) x y))
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(define (make-from-mag-ang r a)
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((get 'make-from-mag-ang 'polar) r a))
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#+end_src
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** Exercise 2.73
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Section *Note 2-3-2:: described a program that performs symbolic
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differentiation:
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#+begin_src scheme
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(define (deriv exp var)
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(cond ((number? exp) 0)
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((variable? exp) (if (same-variable? exp var) 1 0))
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((sum? exp)
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(make-sum (deriv (addend exp) var)
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(deriv (augend exp) var)))
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((product? exp)
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(make-sum
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(make-product (multiplier exp)
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(deriv (multiplicand exp) var))
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(make-product (deriv (multiplier exp) var)
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(multiplicand exp))))
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<MORE RULES CAN BE ADDED HERE>
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(else (error "unknown expression type -- DERIV" exp))))
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#+end_src
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We can regard this program as performing a dispatch on the type of
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the expression to be differentiated. In this situation the "type
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tag" of the datum is the algebraic operator symbol (such as `+')
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and the operation being performed is `deriv'. We can transform
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this program into data-directed style by rewriting the basic
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derivative procedure as
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#+begin_src scheme
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(define (deriv exp var)
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(cond ((number? exp) 0)
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((variable? exp) (if (same-variable? exp var) 1 0))
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(else ((get 'deriv (operator exp)) (operands exp)
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var))))
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(define (operator exp) (car exp))
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(define (operands exp) (cdr exp))
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#+end_src
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a. Explain what was done above. Why can't we assimilate the
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predicates `number?' and `same-variable?' into the
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data-directed dispatch?
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----------------------------------------------------------------------
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Rather than embed the logic for each operator we want to support
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in the ~deriv~ function, we'll dispatch them based on the
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operator in the expression.
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~number?~ and ~same-variable~ cannot be dispatched this way
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because they're scalar values, not compound expressions tagged
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with an operator to dispatch on.
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b. Write the procedures for derivatives of sums and products,
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and the auxiliary code required to install them in the table
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used by the program above.
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----------------------------------------------------------------------
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#+begin_src scheme
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(define (install-deriv-code)
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(define (deriv-sum exp var)
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(make-sum (deriv (addend exp) var)
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(deriv (augend exp) var)))
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(define (deriv-product expr var)
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(make-sum
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(make-product (multiplier exp)
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(deriv (multiplicand exp) var))
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(make-product (deriv (multiplier exp) var)
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(multiplicand exp))))
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(put 'deriv '+ deriv-sum)
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(put 'deriv '* deriv-product))
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#+end_src
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c. Choose any additional differentiation rule that you like,
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such as the one for exponents (*Note Exercise 2-56::), and
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install it in this data-directed system.
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d. In this simple algebraic manipulator the type of an
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expression is the algebraic operator that binds it together.
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Suppose, however, we indexed the procedures in the opposite
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way, so that the dispatch line in `deriv' looked like
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#+begin_src scheme
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((get (operator exp) 'deriv) (operands exp) var)
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#+end_src
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What corresponding changes to the derivative system are
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required?
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----------------------------------------------------------------------
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Nothing, only the implementations of the dispatch table storage
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/ lookup methods ( ~put~ / ~get~ ) would change.
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** Exercise 2.74:
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Insatiable Enterprises, Inc., is a highly decentralized
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conglomerate company consisting of a large number of independent
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divisions located all over the world. The company's computer
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facilities have just been interconnected by means of a clever
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network-interfacing scheme that makes the entire network appear to
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any user to be a single computer. Insatiable's president, in her
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first attempt to exploit the ability of the network to extract
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administrative information from division files, is dismayed to
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discover that, although all the division files have been
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implemented as data structures in Scheme, the particular data
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structure used varies from division to division. A meeting of
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division managers is hastily called to search for a strategy to
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integrate the files that will satisfy headquarters' needs while
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preserving the existing autonomy of the divisions.
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Show how such a strategy can be implemented with data-directed
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programming. As an example, suppose that each division's personnel
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records consist of a single file, which contains a set of records
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keyed on employees' names. The structure of the set varies from
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division to division. Furthermore, each employee's record is
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itself a set (structured differently from division to division)
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that contains information keyed under identifiers such as `address'
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and `salary'. In particular:
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a. Implement for headquarters a `get-record' procedure that
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retrieves a specified employee's record from a specified
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personnel file. The procedure should be applicable to any
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division's file. Explain how the individual divisions' files
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should be structured. In particular, what type information
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must be supplied?
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----------------------------------------------------------------------
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#+begin_src scheme
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(define division-identifier car)
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(define division-data cdr)
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(define tag-division cons)
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(define (get-record name tagged-file)
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(let ((division (division-identifier tagged-file))
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(file (division-data tagged-file)))
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(tag-division division (apply-generic 'get-record
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(division-identifier file)
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name
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(division-data file)))))
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#+end_src
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Division files must be tagged with a unique identifier for the
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division.
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b. Implement for headquarters a `get-salary' procedure that
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returns the salary information from a given employee's record
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from any division's personnel file. How should the record be
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structured in order to make this operation work?
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----------------------------------------------------------------------
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#+begin_src scheme
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(define (get-record-field tagged-record field)
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(let ((division (division-identifier tagged-record))
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(record (division-data tagged-record)))
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(apply-generic 'get-record-field
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division
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record
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field)))
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#+end_src
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c. Implement for headquarters a `find-employee-record'
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procedure. This should search all the divisions' files for
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the record of a given employee and return the record. Assume
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that this procedure takes as arguments an employee's name and
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a list of all the divisions' files.
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----------------------------------------------------------------------
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#+begin_src scheme
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(define (find-employee-record name division-files)
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(let* ((division-file (car division-files))
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(rest (cdr division-files))
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(found-file (get-record name division-file)))
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(if (nil? found-file)
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(find-employee-record name rest)
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found-file)))
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#+end_src
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d. When Insatiable takes over a new company, what changes must
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be made in order to incorporate the new personnel information
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into the central system?
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----------------------------------------------------------------------
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The new company's personnel information must be representable in
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scheme, and will have to be tagged with a new unique
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identifier. New implementations for ~get-record~ and
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~get-record-field~ will have to be implemented for the new data
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format.
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* Message Passing
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#+begin_src scheme
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;; ===================================================================
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;; 2.4.4: Message Passing
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;; ===================================================================
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(define (make-from-real-imag x y)
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(define (dispatch op)
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(cond ((eq? op 'real-part) x)
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((eq? op 'imag-part) y)
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((eq? op 'magnitude)
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(sqrt (+ (square x) (square y))))
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((eq? op 'angle) (atan y x))
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(else
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(error "Unknown op -- MAKE-FROM-REAL-IMAG" op))))
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dispatch)
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(define (apply-generic op arg) (arg op))
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#+end_src
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** Exercise 2.75
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Implement the constructor `make-from-mag-ang' in message-passing
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style. This procedure should be analogous to the
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`make-from-real-imag' procedure given above.
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----------------------------------------------------------------------
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#+begin_src scheme
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(define (make-from-mag-ang r a)
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(define (dispatch op)
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(cond ((eq? op 'real-part)
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(* r (cos a)))
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((eq? op 'imag-part)
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(* r (sin a)))
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((eq? op 'magnitude) r)
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((eq? op 'angle) a)
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(else
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(error "Unknown op -- MAKE-FROM-MAG-ANG" op))))
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dispatch)
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#+end_src
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** Exercise 2.76
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As a large system with generic operations evolves, new types of data
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objects or new operations may be needed. For each of the three
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strategies--generic operations with explicit dispatch, data-directed
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style, and message-passing-style--describe the changes that must be
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made to a system in order to add new types or new operations. Which
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organization would be most appropriate for a system in which new
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types must often be added? Which would be most appropriate for a
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system in which new operations must often be added?
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----------------------------------------------------------------------
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* Generic operations with explicit dispatch
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* A new constructor must be built to represent a new data format
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and uniquely tag it
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* Each generic accessor method must be updated to support a new
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tagged data format
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* New generics must be written to support all possible data formats
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(Not additive)
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* Data-directed style
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* To add a new format, operations must be registered with a
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global lookup table using a unique tag
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* To add a new operation, each type implementation must be
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updated to support the new operation, and a new generic
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function must be made to dispatch it
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* Message-passing style
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* To add a new type, a new constructor must be built that handles
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the supported operations
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* To add a new operation, all constructors must be updated to
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support it
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When new types must often be added, data-directed is more
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appropriate, as people creating new types don't have to worry about
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the operations contract changing frequently.
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When new operations must often be added, message-passing is more
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appropriate, as operations can be added independently from the type
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implementations (which can be caught up later).
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