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2.82.rkt
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#lang sicp
(define global-array '())
(define (make-entry k v) (list k v))
(define (key entry) (car entry))
(define (value entry) (cadr entry))
(define (put op type item)
(define (put-helper k array)
(cond ((null? array) (list(make-entry k item)))
((equal? (key (car array)) k) array)
(else (cons (car array) (put-helper k (cdr array))))))
(set! global-array (put-helper (list op type) global-array)))
(define (get op type)
(define (get-helper k array)
(cond ((null? array) #f)
((equal? (key (car array)) k) (value (car array)))
(else (get-helper k (cdr array)))))
(get-helper (list op type) global-array))
(define (attach-tag type-tag contents)
(if (number? contents)
contents
(cons type-tag contents)))
(define (type-tag datum)
(cond ((number? datum) 'scheme-number)
((pair? datum) (car datum))
(else (error "Bad tagged datum -- TYPE-TAG" datum))))
(define (contents datum)
(cond ((number? datum) datum)
((pair? datum) (cdr datum))
(else (error "Bad tagged datum -- CONTENTS" datum))))
(define (rectangular? z)
(eq? (type-tag z) 'rectangular))
(define (polar? z)
(eq? (type-tag z) 'polar))
(define (square x)
(* x x))
(define (install-rectangular-package)
;; internal procedures
(define (real-part z) (car z))
(define (imag-part z) (cdr z))
(define (make-from-real-imag x y) (cons x y))
(define (magnitude z)
(sqrt (+ (square (real-part z))
(square (imag-part z)))))
(define (angle z)
(atan (imag-part z) (real-part z)))
(define (make-from-mag-ang r a)
(cons (* r (cos a)) (* r (sin a))))
;; interface to the rest of the system
(define (tag x) (attach-tag 'rectangular x))
(put 'real-part '(rectangular) real-part)
(put 'imag-part '(rectangular) imag-part)
(put 'magnitude '(rectangular) magnitude)
(put 'angle '(rectangular) angle)
(put 'make-from-real-imag 'rectangular
(lambda (x y) (tag (make-from-real-imag x y))))
(put 'make-from-mag-ang 'rectangular
(lambda (r a) (tag (make-from-mag-ang r a))))
'done)
(define (install-polar-package)
;; internal procedures
(define (magnitude z) (car z))
(define (angle z) (cdr z))
(define (make-from-mag-ang r a) (cons r a))
(define (real-part z)
(* (magnitude z) (cos (angle z))))
(define (imag-part z)
(* (magnitude z) (sin (angle z))))
(define (make-from-real-imag x y)
(cons (sqrt (+ (square x) (square y)))
(atan y x)))
;; interface to the rest of the system
(define (tag x) (attach-tag 'polar x))
(put 'real-part '(polar) real-part)
(put 'imag-part '(polar) imag-part)
(put 'magnitude '(polar) magnitude)
(put 'angle '(polar) angle)
(put 'make-from-real-imag 'polar
(lambda (x y) (tag (make-from-real-imag x y))))
(put 'make-from-mag-ang 'polar
(lambda (r a) (tag (make-from-mag-ang r a))))
'done)
(define (apply-generic-old op . args)
(let ((type-tags (map type-tag args)))
(let ((proc (get op type-tags)))
(if proc
(apply proc (map contents args))
(if (> (length args) 1)
(let ((type1 (car type-tags))
(type2 (cadr type-tags))
(a1 (car args))
(a2 (cadr args)))
(let ((t1->t2 (get-coercion type1 type2))
(t2->t1 (get-coercion type2 type1)))
(cond ((equal? type1 type2) (error "No method for these types" (list op type-tags)))
(t1->t2
(apply-generic op (t1->t2 a1) a2))
(t2->t1
(apply-generic op a1 (t2->t1 a2)))
(else
(error "No method for these types" (list op type-tags))))))
(error "No method for these types"
(list op type-tags)))))))
(define (every seq)
(cond ((null? seq) #t)
((eq? (car seq) #f) #f)
(else (every (cdr seq)))))
(define (coerce-list-to-type seq type)
(map (lambda (x)
(let* ((xtype (type-tag x))
(proc (get-coercion xtype type)))
(if (eq? type xtype)
x
(proc x)))) seq))
(define (can-coerce-list-to-type seq type)
(every (map (lambda (x)
(let* ((xtype (type-tag x))
(proc (get-coercion xtype type)))
(or (eq? type xtype) proc))) seq)))
(define (apply-generic op . args)
(let ((type-tags (map type-tag args)))
(define (iter items)
(if (null? items)
(error "No method for these types" (list op type-tags)))
(if (can-coerce-list-to-type args (type-tag (car items)))
; args is a list, we need to use apply because of the spread operator
(apply apply-generic (cons op (coerce-list-to-type args (type-tag (car items)))))
(iter (cdr items))))
(let ((proc (get op type-tags)))
(if proc
(apply proc (map contents args))
(if (> (length args) 1)
(iter args)
(error "No method for these types" (list op type-tags)))))))
(define (real-part z) (apply-generic 'real-part z))
(define (imag-part z) (apply-generic 'imag-part z))
(define (magnitude z) (apply-generic 'magnitude z))
(define (angle z) (apply-generic 'angle z))
(define (make-from-real-imag x y)
((get 'make-from-real-imag 'rectangular) x y))
(define (make-from-mag-ang r a)
((get 'make-from-mag-ang 'polar) r a))
(define (add x y) (apply-generic 'add x y))
(define (sub x y) (apply-generic 'sub x y))
(define (mul x y) (apply-generic 'mul x y))
(define (div x y) (apply-generic 'div x y))
(define (equ? x y) (apply-generic 'equ? x y))
(define (=zero? x) (apply-generic '=zero? x))
(define (install-scheme-number-package)
(define (tag x)
(attach-tag 'scheme-number x))
(put 'add '(scheme-number scheme-number)
(lambda (x y) (tag (+ x y))))
(put 'sub '(scheme-number scheme-number)
(lambda (x y) (tag (- x y))))
(put 'mul '(scheme-number scheme-number)
(lambda (x y) (tag (* x y))))
(put 'div '(scheme-number scheme-number)
(lambda (x y) (tag (/ x y))))
(put 'make 'scheme-number
(lambda (x) (tag x)))
(put 'equ? '(scheme-number scheme-number)
=)
(put '=zero? '(scheme-number)
(lambda (x) (= x 0)))
(put 'exp '(scheme-number scheme-number)
(lambda (x y) (tag (expt x y))))
'done)
(define (make-scheme-number n)
((get 'make 'scheme-number) n))
(define (install-rational-package)
;; internal procedures
(define (numer x) (car x))
(define (denom x) (cdr x))
(define (make-rat n d)
(let ((g (gcd n d)))
(cons (/ n g) (/ d g))))
(define (add-rat x y)
(make-rat (+ (* (numer x) (denom y))
(* (numer y) (denom x)))
(* (denom x) (denom y))))
(define (sub-rat x y)
(make-rat (- (* (numer x) (denom y))
(* (numer y) (denom x)))
(* (denom x) (denom y))))
(define (mul-rat x y)
(make-rat (* (numer x) (numer y))
(* (denom x) (denom y))))
(define (div-rat x y)
(make-rat (* (numer x) (denom y))
(* (denom x) (numer y))))
(define (equ?-rat x y)
(equal? (make-rat x) (make-rat y)))
;; interface to rest of the system
(define (tag x) (attach-tag 'rational x))
(put 'add '(rational rational)
(lambda (x y) (tag (add-rat x y))))
(put 'sub '(rational rational)
(lambda (x y) (tag (sub-rat x y))))
(put 'mul '(rational rational)
(lambda (x y) (tag (mul-rat x y))))
(put 'div '(rational rational)
(lambda (x y) (tag (div-rat x y))))
(put 'equ? '(rational rational)
(lambda (x y) (equal? x y)))
(put '=zero? '(rational)
(lambda (rat) (= (numer rat) 0)))
(put 'make 'rational
(lambda (n d) (tag (make-rat n d))))
'done)
(define (make-rational n d)
((get 'make 'rational) n d))
(define (install-complex-package)
;; imported procedures from rectangular and polar packages
(define (make-from-real-imag x y)
((get 'make-from-real-imag 'rectangular) x y))
(define (make-from-mag-ang r a)
((get 'make-from-mag-ang 'polar) r a))
;; internal procedures
(define (add-complex z1 z2)
(make-from-real-imag (+ (real-part z1) (real-part z2))
(+ (imag-part z1) (imag-part z2))))
(define (sub-complex z1 z2)
(make-from-real-imag (- (real-part z1) (real-part z2))
(- (imag-part z1) (imag-part z2))))
(define (mul-complex z1 z2)
(make-from-mag-ang (* (magnitude z1) (magnitude z2))
(+ (angle z1) (angle z2))))
(define (div-complex z1 z2)
(make-from-mag-ang (/ (magnitude z1) (magnitude z2))
(- (angle z1) (angle z2))))
(define (equ?-complex x y)
(equal? x y))
;; interface to rest of the system
(define (tag z) (attach-tag 'complex z))
(put 'add '(complex complex)
(lambda (z1 z2) (tag (add-complex z1 z2))))
(put 'sub '(complex complex)
(lambda (z1 z2) (tag (sub-complex z1 z2))))
(put 'mul '(complex complex)
(lambda (z1 z2) (tag (mul-complex z1 z2))))
(put 'div '(complex complex)
(lambda (z1 z2) (tag (div-complex z1 z2))))
(put 'equ? '(complex complex)
(lambda (z1 z2) (equ?-complex z1 z2)))
(put '=zero? '(complex)
(lambda (z) (= 0 (real-part z) (imag-part z))))
(put 'make-from-real-imag 'complex
(lambda (x y) (tag (make-from-real-imag x y))))
(put 'make-from-mag-ang 'complex
(lambda (r a) (tag (make-from-mag-ang r a))))
; added:
(put 'real-part '(complex) real-part)
(put 'imag-part '(complex) imag-part)
(put 'magnitude '(complex) magnitude)
(put 'angle '(complex) angle)
'done)
(define (make-complex-from-real-imag x y)
((get 'make-from-real-imag 'complex) x y))
(define (make-complex-from-mag-ang r a)
((get 'make-from-mag-ang 'complex) r a))
(install-scheme-number-package)
(install-rational-package)
(install-complex-package)
(install-rectangular-package)
(install-polar-package)
(define (scheme-number->complex n)
(make-complex-from-real-imag (contents n) 0))
(define global-coercion-array '())
(define (put-coercion type1 type2 item)
(define (put-helper k array)
(cond ((null? array) (list(make-entry k item)))
((equal? (key (car array)) k) array)
(else (cons (car array) (put-helper k (cdr array))))))
(set! global-coercion-array (put-helper (list type1 type2) global-coercion-array)))
(define (get-coercion type1 type2)
(define (get-helper k array)
(cond ((null? array) #f)
((equal? (key (car array)) k) (value (car array)))
(else (get-helper k (cdr array)))))
(get-helper (list type1 type2) global-coercion-array))
(define (scheme-number->rational scheme-number)
(make-rational scheme-number 1))
(put-coercion 'scheme-number 'rational scheme-number->rational)
(apply-generic 'add (make-rational 2 1) (make-rational 3 4))
(apply-generic 'add (make-scheme-number 2) (make-rational 3 4))