# Logarithm in functional language with addition and multiplication only

While learning for an exam, I've just found the following task in an exercise:

Write a function that gives the integer logarithm to base 2 (rounded up) while only using multiplication and addition.

I tried, immediately, but couldn't come to any solution. I thought that would be an easy task but I could only find a solution when using integer division (e.g. in Haskell):

``````log2 :: Int -> Int
log2 1 = 0
log2 2 = 1
log2 x = 1 + log2 (x `div` 2)
``````

Is this task possible with multiplication only at all? Using multiplication on the left side (pattern) always results in compiler errors. And using it on the right side, how can I trace the solution back to lower numbers?

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You can do it with addition, multiplication, and `<=`. Also, your case for 2 is redundant, in that example. –  Carl Jan 10 '13 at 22:04
Division IS multiplication –  Wes Jan 10 '13 at 22:07
But I have to use `Int`s, no fractions. –  Marco W. Jan 10 '13 at 22:09

And using it on the right side, how can I trace the solution back to lower numbers?

Recursion. Since it's easier to compute the floor, we use the fact that

``````ceiling (log_2 n) == floor (log_2 (2*n-1))
``````

as can easily be seen. Then to find the logarithm to the base `b`, we compute the logarithm to base `b²` and adjust:

``````log2 :: Int -> Int
log2 1 = 0
log2 2 = 1
log2 n
| n < 1     = error "Argument of logarithm must be positive"
| otherwise = fst \$ doLog 2 1
where
m = 2*n-1
doLog base acc
| base*acc > m = (0, acc)
| otherwise = case doLog (base*base) acc of
(e, a) | base*a > m -> (2*e, a)
| otherwise  -> (2*e+1,a*base)
``````

A simpler algorithm that needs more steps would be to simply iterate, multiplying with 2 in each step, and count, until the argument value is reached or surpassed:

``````log2 :: Int -> Int
log2 n
| n < 1     = error "agument of logarithm must be positive"
| otherwise = go 0 1
where
go exponent prod
| prod < n  = go (exponent + 1) (2*prod)
| otherwise = exponent
``````
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`doLog :: (Num a) => a -> a -> (a, a)` or something like that. Shouldn't you project it in the `log2 n | otherwise` case? ;) –  Rhymoid Jan 10 '13 at 22:44
Ah, forgot the `fst`, thanks. Due to the top-level signature, it's `doLog :: Int -> Int -> (Int,Int)`, but of course it would also work polymorphically. –  Daniel Fischer Jan 10 '13 at 22:47
Of course. That would require you to pass `m` explicitly, though. –  Rhymoid Jan 10 '13 at 22:58
@Tinctorius And if `n :: t` for some `(Ord t, Num t)`, then `m :: t` and `base, acc :: t`. If `log2` is called at type `a -> r`, then `doLog` inherits type `a -> a -> (b, a)` from the guards, doesn't need any passing of `m`. –  Daniel Fischer Jan 10 '13 at 23:29
@MarcoW. It is already rather simple, I think. Of course you can have a simpler and slower algorithm. That's no problem, I will add one. –  Daniel Fischer Jan 10 '13 at 23:32

``````log2 n = length (takeWhile (<n) (iterate (*2) 1))
``````

?

I assume you can use functions from the Prelude (like `error`, `fst` and the comparison operators). If that's not allowed on the exam, you could theoretically use the definitions of `length`, `takeWhile` and `iterate` and end up with something relatively close (in spirit, probably not in the letter!) to Daniel's answer.

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Thank you for this super-short alternative! –  Marco W. Jan 16 '13 at 16:40