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386 lines
13 KiB
Org Mode
386 lines
13 KiB
Org Mode
#+BEGIN_HTML
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---
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title: 2.1 - Introduction to Data Abstraction
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layout: org
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---
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#+END_HTML
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* Example: Arithmetic Operations for Rational Numbers
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#+begin_src scheme :tangle yes
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;; ===================================================================
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;; 2.1.1: Example: Arithmetic Operators for Rational Numbers
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;; ===================================================================
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(define (add-rat x y)
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(make-rat (+ (* (numer x) (denom y))
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(* (numer y) (denom x)))
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(* (denom x) (denom y))))
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(define (sub-rat x y)
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(make-rat (- (* (numer x) (denom y))
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(* (numer y) (denom x)))
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(* (denom x) (denom y))))
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(define (mul-rat x y)
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(make-rat (* (numer x) (numer y))
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(* (denom x) (denom y))))
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(define (div-rat x y)
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(make-rat (* (numer x) (denom y))
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(* (denom x) (numer y))))
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(define (equal-rat? x y)
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(= (* (numer x) (denom y))
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(* (numer y) (denom x))))
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(define (make-rat n d) (cons n d))
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(define (numer x) (car x))
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(define (denom x) (cdr x))
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(define (print-rat x)
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(newline)
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(display (numer x))
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(display "/")
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(display (denom x)))
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(define (gcd a b)
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(if (= b 0)
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a
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(gcd b (remainder a b))))
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(define (make-rat n d)
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(let ((g (gcd n d)))
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(cons (/ n g) (/ d g))))
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#+end_src
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** Exercise 2.1:
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Define a better version of `make-rat' that handles
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both positive and negative arguments. `Make-rat' should normalize
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the sign so that if the rational number is positive, both the
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numerator and denominator are positive, and if the rational number
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is negative, only the numerator is negative.
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----------------------------------------------------------------------
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#+begin_src scheme :tangle yes
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;; -------------------------------------------------------------------
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;; Exercise 2.1
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;; -------------------------------------------------------------------
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(define (make-rat n d)
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(cond ((and (negative? n) (negative? d)) (make-rat (abs n) (abs d)))
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((negative? d) (make-rat (- n) (- d)))
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(else (let ((g (gcd n d)))
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(cons (/ n g) (/ d g))))))
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#+end_src
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* Abstraction Barriers
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** Exercise 2.2
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Consider the problem of representing line segments in a plane.
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Each segment is represented as a pair of points: a starting point
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and an ending point. Define a constructor `make-segment' and
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selectors `start-segment' and `end-segment' that define the
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representation of segments in terms of points. Furthermore, a
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point can be represented as a pair of numbers: the x coordinate and
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the y coordinate. Accordingly, specify a constructor `make-point'
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and selectors `x-point' and `y-point' that define this
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representation. Finally, using your selectors and constructors,
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define a procedure `midpoint-segment' that takes a line segment as
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argument and returns its midpoint (the point whose coordinates are
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the average of the coordinates of the endpoints). To try your
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procedures, you'll need a way to print points:
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#+begin_src scheme :tangle yes
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;; -------------------------------------------------------------------
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;; Excercise 2.2
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;; -------------------------------------------------------------------
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(define (print-point p)
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(newline)
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(display "(")
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(display (x-point p))
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(display ",")
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(display (y-point p))
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(display ")"))
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#+end_src
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----------------------------------------------------------------------
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#+begin_src scheme :tangle yes
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(define make-point cons)
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(define x-point car)
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(define y-point cdr)
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(define make-segment cons)
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(define start-segment car)
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(define end-segment cdr)
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(define (midpoint-segment segment)
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(let ((p1 (start-segment segment))
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(p2 (end-segment segment)))
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(let ((average (lambda (x y) (/ (+ x y) 2))))
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(make-point
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(average (x-point p1) (x-point p2))
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(average (y-point p1) (y-point p2))))))
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#+end_src
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** Exercise 2.3:
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Implement a representation for rectangles in a plane. (Hint: You
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may want to make use of *Note Exercise 2-2::.) In terms of your
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constructors and selectors, create procedures that compute the
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perimeter and the area of a given rectangle. Now implement a
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different representation for rectangles. Can you design your
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system with suitable abstraction barriers, so that the same
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perimeter and area procedures will work using either
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representation?
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----------------------------------------------------------------------
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#+begin_src scheme :tangle yes
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;; -------------------------------------------------------------------
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;; Exercise 2.3
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;; -------------------------------------------------------------------
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(define (perimeter-rectangle r)
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(+ (* 2 (width-rectangle r))
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(* 2 (height-rectangle r))))
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(define (area-rectangle r)
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(* (width-rectangle r)
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(height-rectangle r)))
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;; ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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;; Hard mode - Expose the 4 points of the rectangle
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;; Width and Height have their own abstraction layer
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;;~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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(define (width-rectangle r)
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(abs (- (x2-rectangle r)
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(x1-rectangle r))))
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(define (height-rectangle r)
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(abs (- (y2-rectangle r)
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(y1-rectangle r))))
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(define (x1-rectangle r) (x-point (top-left-point-rectangle r)))
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(define (x2-rectangle r) (x-point (bottom-right-point-rectangle r)))
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(define (y1-rectangle r) (y-point (top-left-point-rectangle r)))
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(define (y2-rectangle r) (y-point (bottom-right-point-rectangle r)))
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;; -------------------------------------------------------------------
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;; Rectangle implementation using two points on a plane
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(define make-rectangle cons)
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(define top-left-point-rectangle car)
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(define bottom-right-point-rectangle cdr)
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(define (top-right-point-rectangle r)
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(make-point (x-point (top-left-point-rectangle r))
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(y-point (bottom-right-point-rectangle r))))
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(define (bottom-left-point-rectangle r)
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(make-point (x-point (top-left-point-rectangle r))
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(y-point (bottom-right-point-rectangle r))))
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;; -------------------------------------------------------------------
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;; Rectangle implementation using an origin point, width and height
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(define (make-rectangle origin width height)
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(cons origin (cons width height)))
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(define (top-left-point-rectangle r) (car r))
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(define (top-right-point-rectangle r)
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(let ((x (x-point (car r)))
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(y (y-point (car r)))
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(width (car (cdr r))))
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(make-point (+ x width) y)))
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(define (bottom-left-point-rectangle r)
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(let ((x (x-point (car r)))
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(y (y-point (car r)))
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(height (cdr (cdr r))))
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(make-point x (+ y height))))
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(define (bottom-right-point-rectangle r)
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(let ((x (x-point (car r)))
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(y (y-point (car r)))
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(width (car (cdr r)))
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(height (cdr (cdr r))))
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(make-point (+ x width) (+ y height))))
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;; ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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;; Simpler solution - Expose only width + height
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;; ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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;; -------------------------------------------------------------------
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;; Rectangle implementation using two points on a plane
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(define make-rectangle cons)
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(define (width-rectangle r)
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(let ((p1 (car r))
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(p2 (cdr r)))
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(abs (- (x-point p1)
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(x-point p2)))))
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(define (height-rectangle r)
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(let ((p1 (car r))
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(p2 (cdr r)))
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(abs (- (y-point p1)
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(y-point p2)))))
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;; -------------------------------------------------------------------
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;; Rectangle implementation using an origin point, width and height
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(define (make-rectangle origin width height)
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(cons origin (cons width height)))
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(define (width-rectangle r) (car (cdr r)))
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(define (height-rectangle r) (cdr (cdr r)))
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#+end_src
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* What is Meant by Data
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** Exercise 2.4
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Here is an alternative procedural representation of pairs. For
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this representation, verify that `(car (cons x y))' yields `x' for
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any objects `x' and `y'.
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#+begin_src scheme :tangle yes
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;; -------------------------------------------------------------------
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;; Exercise 2.4
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;; -------------------------------------------------------------------
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(define (cons x y)
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(lambda (m) (m x y)))
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(define (car z)
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(z (lambda (p q) p)))
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#+end_src
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What is the corresponding definition of `cdr'? (Hint: To verify
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that this works, make use of the substitution model of section
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*Note 1-1-5::.)
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----------------------------------------------------------------------
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#+begin_src scheme :tangle yes
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(define (cdr z)
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(z (lambda (p q) q)))
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#+end_src
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** Exercise 2.5
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Show that we can represent pairs of nonnegative integers using only
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numbers and arithmetic operations if we represent the pair a and b
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as the integer that is the product 2^a 3^b. Give the corresponding
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definitions of the procedures `cons', `car', and `cdr'.
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----------------------------------------------------------------------
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#+begin_src scheme :tangle yes
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;; -------------------------------------------------------------------
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;; Exercise 2.5
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;; -------------------------------------------------------------------
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(define (cons a b)
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(* (expt 2 a) (expt 3 b)))
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(define (factor-count n x count)
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(if (= 0 (remainder x n))
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(factor-count n (/ x n) (+ 1 count))
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count))
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(define (car p)
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(factor-count 2 p 0))
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(define (cdr p)
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(factor-count 3 p 0))
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#+end_src
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** Exercise 2.6
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In case representing pairs as procedures wasn't mind-boggling
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enough, consider that, in a language that can manipulate
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procedures, we can get by without numbers (at least insofar as
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nonnegative integers are concerned) by implementing 0 and the
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operation of adding 1 as
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#+begin_src scheme
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(define zero (lambda (f) (lambda (x) x)))
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(define (add-1 n)
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(lambda (f) (lambda (x) (f ((n f) x)))))
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#+end_src
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This representation is known as "Church numerals", after its
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inventor, Alonzo Church, the logician who invented the [lambda]
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calculus.
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Define `one' and `two' directly (not in terms of `zero' and
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`add-1'). (Hint: Use substitution to evaluate `(add-1 zero)').
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Give a direct definition of the addition procedure `+' (not in
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terms of repeated application of `add-1').
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----------------------------------------------------------------------
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#+begin_src scheme :tangle yes
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(define one (lambda (f) (lambda (x) (f x))))
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(define two (lambda (f) (lambda (x) (f (f x)))))
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(define (add a b)
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(lambda (f)
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(lambda (x)
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((a f) ((b f) x)))))
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#+end_src
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* Extended Exercise: Interval Arithmetic
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#+begin_src scheme :tangle yes
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;; ===================================================================
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;; 2.1.4: Extended Exercise: Interval Arithmetic
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;; ===================================================================
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(define (add-interval x y)
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(make-interval (+ (lower-bound x) (lower-bound y))
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(+ (upper-bound x) (upper-bound y))))
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(define (mul-interval x y)
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(let ((p1 (* (lower-bound x) (lower-bound y)))
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(p2 (* (lower-bound x) (upper-bound y)))
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(p3 (* (upper-bound x) (lower-bound y)))
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(p4 (* (upper-bound x) (upper-bound y))))
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(make-interval (min p1 p2 p3 p4)
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(max p1 p2 p3 p4))))
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(define (div-interval x y)
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(mul-interval x
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(make-interval (/ 1.0 (upper-bound y))
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(/ 1.0 (lower-bound y)))))
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#+end_src
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** Exercise 2.7
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Alyssa's program is incomplete because she has not specified the
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implementation of the interval abstraction. Here is a definition
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of the interval constructor:
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#+begin_src scheme :tangle yes
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;; -------------------------------------------------------------------
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;; Exercise 2.7
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;; -------------------------------------------------------------------
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(define (make-interval a b) (cons a b))
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#+end_src
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Define selectors `upper-bound' and `lower-bound' to complete the
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implementation.
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----------------------------------------------------------------------
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#+begin_src scheme :tangle yes
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(define (upper-bound p)
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(max (car p) (cdr p)))
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(define (lower-bound p)
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(min (car p) (cdr p)))
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#+end_src
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** Exercise 2.8:
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Using reasoning analogous to Alyssa's, describe how the difference
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of two intervals may be computed. Define a corresponding
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subtraction procedure, called `sub-interval'.
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----------------------------------------------------------------------
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#+begin_src scheme :tangle yes
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;; -------------------------------------------------------------------
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;; Exercise 2.8
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;; -------------------------------------------------------------------
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#+end_src
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