Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm trying to learn scheme via SICP. Exercise 1.3 reads as follow: Define a procedure that takes three numbers as arguments and returns the sum of the squares of the two larger numbers. Please comment on how I can improve my solution.

(define (big x y)
    (if (> x y) x y))

(define (p a b c)
    (cond ((> a b) (+ (square a) (square (big b c))))
          (else (+ (square b) (square (big a c))))))
share|improve this question
1  
FWIW, I think your solution is better than any of the provided answers (if you rename big to max, as suggested). –  espertus Jun 19 '11 at 19:33
    
Nice solution on your own! –  lukas.pukenis Nov 4 '13 at 13:23

14 Answers 14

up vote 3 down vote accepted

Looks ok to me, is there anything specific you want to improve on?

You could do something like:

(define (max2 . l)
  (lambda ()
    (let ((a (apply max l)))
      (values a (apply max (remv a l))))))

(define (q a b c)
  (call-with-values (max2 a b c)
    (lambda (a b)
      (+ (* a a) (* b b)))))

(define (skip-min . l)
  (lambda ()
    (apply values (remv (apply min l) l))))

(define (p a b c)
  (call-with-values (skip-min a b c)
    (lambda (a b)
      (+ (* a a) (* b b)))))

And this (proc p) can be easily converted to handle any number of arguments.

share|improve this answer
    
I believe the OP was asking for comments on style, and in that department there are some things that could be talked about, such as what's in my post. :-) –  Chris Jester-Young Oct 2 '08 at 10:29
    
P.S. I see you on #scheme (though you seem to keep getting logged out)! Small world! –  Chris Jester-Young Oct 2 '08 at 11:11
    
Yeah, seems my ISP is heavily shaping traffic on some ports. Funny thing is, I can send data, it just takes ages to receive anything :( That said, I didnt know the world had more than 100 Scheme users! hehe –  leppie Oct 2 '08 at 11:31
    
Bummer about your ISP. Yes, it's nice to know there's a good handful of Schemers out here on the Internet.... :-) –  Chris Jester-Young Oct 2 '08 at 11:40
    
I'm a total newbie to scheme, so it's great to see your alternative solution (which is way over my head). –  ashitaka Oct 2 '08 at 12:32

Using only the concepts presented at that point of the book, I would do it:

(define (square x) (* x x))

(define (sum-of-squares x y) (+ (square x) (square y)))

(define (min x y) (if (< x y) x y))

(define (max x y) (if (> x y) x y))

(define (sum-squares-2-biggest x y z)
  (sum-of-squares (max x y) (max z (min x y))))
share|improve this answer

big is called max. Use standard library functionality when it's there.

My approach is different. Rather than lots of tests, I simply add the squares of all three, then subtract the square of the smallest one.

(define (exercise1.3 a b c)
  (let ((smallest (min a b c))
        (square (lambda (x) (* x x))))
    (+ (square a) (square b) (square c) (- (square smallest)))))

Whether you prefer this approach, or a bunch of if tests, is up to you, of course.


Alternative implementation using SRFI 95:

(define (exercise1.3 . args)
  (let ((sorted (sort! args >))
        (square (lambda (x) (* x x))))
    (+ (square (car sorted)) (square (cadr sorted)))))

As above, but as a one-liner (thanks synx @ freenode #scheme); also requires SRFI 1 and SRFI 26:

(define (exercise1.3 . args)
  (apply + (map! (cut expt <> 2) (take! (sort! args >) 2))))
share|improve this answer
    
I think doing square is more expensive than a few extra tests. But that's just me :) –  leppie Oct 2 '08 at 10:31
2  
I think code should optimise clarity first, performance second. However, I'm willing to accept that reasonable people can disagree on this. :-) –  Chris Jester-Young Oct 2 '08 at 10:33
    
I believe code should do only as intended :) –  leppie Oct 2 '08 at 10:40
    
This is a very interesting solution. There's more than one way to skin the cat. –  ashitaka Oct 2 '08 at 12:34
1  
min, let, lambda, sort!, map!, cut car, cadr, take!, and apply are not yet introduced at that point in the text. –  Shawn J. Goff Jan 9 '10 at 16:22

I did it with the following code, which uses the built-in min, max, and square procedures. They're simple enough to implement using only what's been introduced in the text up to that point.

(define (sum-of-highest-squares x y z)
   (+ (square (max x y))
      (square (max (min x y) z))))
share|improve this answer

What about something like this?

(define (p a b c)
  (if (> a b)
      (if (> b c)
          (+ (square a) (square b))
          (+ (square a) (square c)))
      (if (> a c)
          (+ (square a) (square b))
          (+ (square b) (square c)))))
share|improve this answer
    
Voted up cause I was struggling on this and my code was on similar lines. I'm only learning and don't know yet the bigger constructs in the other examples. With your code I corrected my faulty one. Since I'm not able to add html code in here, I'm putting in my code in a separate reply below. –  Christy John Dec 10 '09 at 14:10

You can also sort the list and add the squares of the first and second element of the sorted list:

(require (lib "list.ss")) ;; I use PLT Scheme

(define (exercise-1-3 a b c)
  (let* [(sorted-list (sort (list a b c) >))
         (x (first sorted-list))
         (y (second sorted-list))]
    (+ (* x x) (* y y))))
share|improve this answer
    
Sébastien, I haven't learnt yet how to work with lists; but again an interesting solution. I am using PLT-scheme. Will that require work on PLT-scheme ? –  ashitaka Oct 2 '08 at 12:37
1  
AFAIK, that only works on PLT Scheme. :-) –  Chris Jester-Young Oct 3 '08 at 10:49
    
Yes, I'm a DrScheme user –  Sébastien RoccaSerra Oct 4 '08 at 6:47

Using only the concepts introduced up to that point of the text, which I think is rather important, here is a different solution:

(define (smallest-of-three a b c)
        (if (< a b)
            (if (< a c) a c)
            (if (< b c) b c)))

(define (square a)
        (* a a))

(define (sum-of-squares-largest a b c) 
        (+ (square a)
           (square b)
           (square c)
           (- (square (smallest-of-three a b c)))))
share|improve this answer
(define (sum-sqr x y)
(+ (square x) (square y)))

(define (sum-squares-2-of-3 x y z)
    (cond ((and (<= x y) (<= x z)) (sum-sqr y z))
             ((and (<= y x) (<= y z)) (sum-sqr x z))
             ((and (<= z x) (<= z y)) (sum-sqr x y))))
share|improve this answer
(define (f a b c) 
  (if (= a (min a b c)) 
      (+ (* b b) (* c c)) 
      (f b c a)))
share|improve this answer
    
This one's gorgeous –  Jordan Dimov Apr 13 at 21:30

With Scott Hoffman's and some irc help I corrected my faulty code, here it is

(define (p a b c)
    (cond ((> a b)
    	(cond ((> b c)
    		(+ (square a) (square b)))
    		(else (+ (square a) (square c)))))
    	(else
    		(cond ((> a c)
    			(+ (square b) (square a)))
    			(else (+ (square b) (square c))))))
share|improve this answer

Here's yet another way to do it:

#!/usr/bin/env mzscheme
#lang scheme/load

(module ex-1.3 scheme/base
  (define (ex-1.3 a b c)
    (let* ((square (lambda (x) (* x x)))
           (p (lambda (a b c) (+ (square a) (square (if (> b c) b c))))))
      (if (> a b) (p a b c) (p b a c))))

  (require scheme/contract)
  (provide/contract [ex-1.3 (-> number? number? number? number?)]))

;; tests
(module ex-1.3/test scheme/base
  (require (planet "test.ss" ("schematics" "schemeunit.plt" 2))
           (planet "text-ui.ss" ("schematics" "schemeunit.plt" 2)))
  (require 'ex-1.3)

  (test/text-ui
   (test-suite
    "ex-1.3"
    (test-equal? "1 2 3" (ex-1.3 1 2 3) 13)
    (test-equal? "2 1 3" (ex-1.3 2 1 3) 13)
    (test-equal? "2 1. 3.5" (ex-1.3 2 1. 3.5) 16.25)
    (test-equal? "-2 -10. 3.5" (ex-1.3 -2 -10. 3.5) 16.25)
    (test-exn "2+1i 0 0" exn:fail:contract? (lambda () (ex-1.3 2+1i 0 0)))
    (test-equal? "all equal" (ex-1.3 3 3 3) 18))))

(require 'ex-1.3/test)

Example:

$ mzscheme ex-1.3.ss
6 success(es) 0 failure(s) 0 error(s) 6 test(s) run
0
share|improve this answer

I've had a go:

(define (procedure a b c)
    (let ((y (sort (list a b c) >)) (square (lambda (x) (* x x))))
        (+ (square (first y)) (square(second y)))))
share|improve this answer
;exercise 1.3
(define (sum-square-of-max a b c)
  (+ (if (> a b) (* a a) (* b b))
     (if (> b c) (* b b) (* c c))))
share|improve this answer
(define (sum a b) (+ a b))
(define (square a) (* a a))
(define (greater a b ) 
  ( if (< a b) b a))
(define (smaller a b ) 
  ( if (< a b) a b))
(define (sumOfSquare a b)
    (sum (square a) (square b)))
(define (sumOfSquareOfGreaterNumbers a b c)
  (sumOfSquare (greater a b) (greater (smaller a b) c)))
share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.