# SICP exercise 1.16, where is my bug, because it looks right to me

I've just started working through this book for fun; I wish it were homework, but I could never afford to attend MIT, and there are tons of people smarter than me anyway. :p

fast-exp is supposed to find b^n, i.e. 4^2 = 16, 3^3 = 27

``````(define (fast-exp b n)
(define (fast-exp-iter n-prime a)
(cond ((= n-prime 1) a)
((= (remainder n-prime 2) 1) (fast-exp-iter (- n-prime 1) (* a b)))
(else (fast-exp-iter (/ n-prime 2) (* a b b)))))
(fast-exp-iter n 1))

fast-exp 4 2; Expected 16, Actual 2
``````
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Style notes...I'm guessing you're used to C syntax. You'll want to bunch up the closing brackets, it'll look nicer that way. You can also use square brackets in Scheme, so your cond could look like (cond [(= n-prime 1) a] ...) –  omouse Oct 31 '09 at 17:16
I have taken the liberty to fix the indentation and parentheses. –  Svante Oct 31 '09 at 18:35
@omouse cool thanks for the tip! –  Dave Nov 1 '09 at 3:54
I know that this solution is not correct. This was 3 years ago, and would require some relearning to see if I can correct it. –  Dave Aug 10 '12 at 19:39

You forgot to call fast-exp. Instead, you evaluated three separate atoms. To actually evaluate the fast-exp of 4 to the 2, you'd have to write

``````(fast-exp 4 2)
``````
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hah! Many thanks –  Dave Oct 29 '09 at 13:36

Your solution is calculating wrong answers. (See http://ideone.com/quT6A) In fact, how you in principle can write a tail-recursive fast exponentiation passing only two numbers as arguments? I don't think it's even possible, because in the middle of computation you don't know what multiplier to use if you encounter odd exponent. But I can give an example of working solution that is exactly what is expected by SICP authors (iterative process using "invariant quantity" (a * b^n), where a is initially 1)

``````(define (pow x y)
(define (powi acc x y)
(cond
((= y 0) acc)
((odd? y) (powi (* acc x) x (- y 1)))
(else (powi acc (* x x) (/ y 2)))))
(powi 1 x y))
``````
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