Why won't my solution to SICP Exercise 1.3 work?

I just began working through SICP and I'm doing the first problem set, namely Exercise 1.3: "Define a procedure that takes three numbers as arguments and returns the sum of the squares of the two larger numbers."

``````(define (toptwosq x y z)
(cond ((and (> x y) (> z y))) (+ (* x x) (* z z))
((and (> y x) (> z x))) (+ (* y y) (* z z))
((and (> x z) (> y z))) (+ (* x x) (* y y))))
``````

When I run this, I get pretty odd results(none of which get me the sum of the squares of the largest two numbers). I've found other solutions that work and I understand why they work...but why doesn't mine?

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DrRacket is a great IDE/SCheme implementation and someone has made support for SICP: neilvandyke.org/racket-sicp. It will solve your parenthesis issue as it balances it in the IDE. –  Sylwester Jul 23 '13 at 1:26

You're closing the `cond` clauses too early.

((and (> x y) (> z y))) is your first `cond` clause, which will return #t if true and #f otherwise, and if true will make the value of the `cond` to be #t.

(+ (* x x) (* z z)) is your second `cond` clause, which will always return the value of the sum of the square of x and the square of z, making the `cond` statement return that value as any value other than #f is considered and true. Sometimes it's useful to exploit this one-part clause, but most of the time you want to use two part clauses.

``````(define (toptwosq x y z)
(cond ((and (> x y) (> z y)) (+ (* x x) (* z z)))
((and (> y x) (> z x)) (+ (* y y) (* z z)))
((and (> x z) (> y z)) (+ (* x x) (* y y)))))
``````

and you really should have an `else` clause

``````(else (+ (square x) (square y))
``````

As none of the cases you've put out so far will catch the case of x y and z being the same value.

Get an editor that does parenthesis matching and you life will become easier.

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the `cond` clause `(+ (* x x) (* z z))` will return the square of `z`, not the sum of squares. `+` acts as a test, and it's not evaluating to `#f`, ever. `(+ (* x x) (* z z))` is a "three parts clause" as you've put it, `(* z z)` is the last form in it. –  Will Ness Jul 23 '13 at 18:09

As @WorBlux pointed out, you have some parenthesis problems. Besides that, I have a couple of tips:

• It's a bit clearer if you use nested `if`s to separate conditions
• Your conditions are not correct, the equality cases are missing
• If the conditions are right, it won't be necessary to have a catch-all `else` case
• You should declare a helper procedure for performing the actual squared sum

This is what I mean:

``````(define (sumsq x y)
(+ (* x x) (* y y)))

(define (toptwosq a b c)
(if (>= a b)
(if (>= b c)
(sumsq a b)
(sumsq a c))
(if (>= a c)
(sumsq b a)
(sumsq b c))))
``````

The same code can be written as follows using `cond`, notice how to correctly express the conditions in such a way that all cases are covered:

``````(define (toptwosq a b c)
(cond ((and (>= a b) (>= b c)) (sumsq a b))
((and (>= a b) (<  b c)) (sumsq a c))
((and (<  a b) (>= a c)) (sumsq b a))
((and (<  a b) (<  a c)) (sumsq b c))))
``````

The last condition can be replaced with an `else`. It's not a "catch-all", we're certain that at this point no more cases remain to be considered:

``````(define (toptwosq a b c)
(cond ((and (>= a b) (>= b c)) (sumsq a b))
((and (>= a b) (<  b c)) (sumsq a c))
((and (<  a b) (>= a c)) (sumsq b a))
(else                    (sumsq b c))))
``````

And finally, if we're smart we can get rid of one case (the first and third cases are the same) and simplify the conditions even more:

``````(define (toptwosq a b c)
(cond ((or (>= a b c) (and (>= a c) (> b a)))
(sumsq a b))
((and (>= a b) (> c b))
(sumsq a c))
(else (sumsq b c))))
``````
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Why not make the second level if's a procedure you can use in both branches? –  Sylwester Jul 23 '13 at 1:28
It's possible, but it'll make the procedure harder to understand. I'll leave it as it is :) –  Óscar López Jul 23 '13 at 1:39
I like your nested ifs code much better: clear, self-evident, optimal: +1. --- The new `cond` codes have repeated tests, yikes. :) –  Will Ness Jul 23 '13 at 18:20
@WillNess I agree, the first solution is the simplest and clearest, with the least number of comparisons. –  Óscar López Jul 23 '13 at 18:25
So why add the worse ones? ... :) –  Will Ness Jul 23 '13 at 18:33

Just on a tangent, this is how the solution code could be derived, from a higher order description.

With equational syntax, (read `\$` as "of"; `f x` signifies application, parenthesis used for grouping only),

``````sum_sqrs_of_biggest_two (a,b,c) =                -- three arguments

= sumsqrs \$ take 2 \$ sort [a,b,c]          -- list of three values
= sumsqrs \$ take 2 \$ merge (sort [a,b]) [c]
= sumsqrs \$ take 2 \$
if a >= b
then merge [a,b] [c]
else merge [b,a] [c]
= sumsqrs \$
if a >= b
then if b >= c then [a,b] else [a,c]
else if a >= c then [b,a] else [b,c]
= if a >= b
then if b >= c then a^2+b^2 else a^2+c^2
else if a >= c then a^2+b^2 else b^2+c^2
``````

... and translate it back to the Scheme syntax.

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