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# SICP Exercise 1.3 request for comments

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))))))
``````
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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

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.

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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))))
``````
-

`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))))
``````
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I think doing square is more expensive than a few extra tests. But that's just me :) – leppie Oct 2 '08 at 10:31
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
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

``````(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)))))
``````
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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

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))))
``````
-

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))))
``````
-
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
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

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))))))
``````
-

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)))))
``````
-
``````(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))))
``````
-
``````(define (f a b c)
(if (= a (min a b c))
(+ (* b b) (* c c))
(f b c a)))
``````
-
This one's gorgeous – Jordan Dimov Apr 13 '14 at 21:30

Here's yet another way to do it:

```#!/usr/bin/env mzscheme

(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
```
-

``````(define (procedure a b c)
(let ((y (sort (list a b c) >)) (square (lambda (x) (* x x))))
(+ (square (first y)) (square(second y)))))
``````
-
``````;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))))
``````
-
``````(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)))
``````
-

I think this is the smallest and most efficient way:

``````(define (square-sum-larger a b c)
(+
(square (max a b))
(square (max (min a b) c))))
``````
-