5

The integer square root of a positive integer n is the largest integer whose square is less than or equal to n. (E.g. the integer square root of 7 is 2, and that of 9 is 3).

Here is my attempt:

intSquareRoot :: Int -> Int
intSquareRoot n
    | n*n > n   = intSquareRoot (n - 1) 
    | n*n <= n  = n

I'm guessing its not working because n decreases along with the recursion as required, but due to this being Haskell you can't use variables to keep the original n.

2
  • It's not quite clear to me how you intend this to work. Assuming you had a separate variable r (for root) and started comparing r*r and n, what value would you try for r? And how would you let Haskell know about it?
    – JB.
    Nov 13, 2013 at 22:00
  • I don't really know if I'm even going in the right direction to solve this to be honest! I'm relatively new at Haskell and this was my first attempt at solving this problem, any alternative way of solving it would be greatly appreciated!
    – benharris
    Nov 13, 2013 at 22:04

5 Answers 5

8

... but due to this being Haskell you cant use variables to keep the original n.

I don't know what makes you say that. Here's how you could implement it:

intSquareRoot :: Int -> Int
intSquareRoot n = aux n
  where
    aux x
      | x*x > n = aux (x - 1)
      | otherwise = x

This is good enough to play around, but it's not a very efficient implementation. A better one can be found on Haskell's wiki:

(^!) :: Num a => a -> Int -> a
(^!) x n = x^n

squareRoot :: Integer -> Integer
squareRoot 0 = 0
squareRoot 1 = 1
squareRoot n =
   let twopows = iterate (^!2) 2
       (lowerRoot, lowerN) =
          last $ takeWhile ((n>=) . snd) $ zip (1:twopows) twopows
       newtonStep x = div (x + div n x) 2
       iters = iterate newtonStep (squareRoot (div n lowerN) * lowerRoot)
       isRoot r  =  r^!2 <= n && n < (r+1)^!2
  in  head $ dropWhile (not . isRoot) iters
2
  • How does it compare to intSqrt = floor . sqrt . fromInteger?
    – kqr
    Nov 14, 2013 at 7:41
  • 2
    @kqr The link I posted to Haskell's wiki explains why that approach is problematic: 1) rounding problems will lead to incorrect results; 2) Integers have arbitrary precision, while floats do not - this means that converting it to a float might fail with an overflow error, Infinity or an imprecise value. Nov 14, 2013 at 10:01
6

You might not have editable variables, but you can pass arguments recursively....

intSquareRoot :: Int -> Int
intSquareRoot n = try n where
  try i   | i*i > n   = try (i - 1) 
          | i*i <= n  = i

giving

ghci> intSquareRoot 16
4
ghci> intSquareRoot 17
4
1
  • That's great thanks! I've had such a mind blank with this, completely forgot I could use 'where'!
    – benharris
    Nov 13, 2013 at 22:10
3

Your initial attempt, as well as the good correction of user2989737, tries every number from n down to the solution. It is very slow for large numbers, complexity is O(n). It will be better to start from 0 up to the solution, which improves complexity to O(sqrt n):

intSquareRoot :: Int -> Int
intSquareRoot n = try 0 where
  try i   | i*i <= n    = try (i + 1) 
          | True        = i - 1

But here is a much more efficient code using Babylonian method (Newton's method applied to square roots):

squareRoot :: Integral t => t -> t
squareRoot n 
   | n > 0    = babylon n
   | n == 0   = 0
   | n < 0    = error "Negative input"
   where
   babylon a   | a > b  = babylon b
               | True   = a
      where b  = quot (a + quot n a) 2

It is not as fast as Pedro Rodrigues solution (GNU's multiprecision library algorithm), but it is much simpler and easier to understand. It also needs to use an internal recursion in order to keep the original n.

To make it complete, I generalized it to any Integral type, checked for negative input, and checked for n == 0 to avoid division by 0.

1

The proposed solution doesn't work because overlaps the n parameter in each recursion call.

The following solution uses binary search and finds the integer square root in O(log(n)):

intSquareRoot :: Int -> Int
intSquareRoot n = bbin 0 (n+1)
    where bbin a b | a + 1 == b = a
                   | otherwise = if m*m > n
                                 then bbin a m
                                 else bbin m b
                               where m = (a + b) `div` 2

dividing the range [a,b) by two on each recursion call ([a,m) or [m,b)) depending where the square root is located.

0

I tried to find the integer square root and its remainder with the following:

squareRoot :: Integer -> Integer
squareRoot n
  | n < 0     = error "negative input"
  | otherwise = square n 10
    where
      square n m
        | n > m*m   = square n (m*m)
        | otherwise = root (m*m) (2*m) 1
          where
            root a b c
              | a+b+c > n = root (a-b+c) (b-2*c) c
              | otherwise = b `div` 2 + c

squareRootRemainder :: Integer -> Integer
squareRootRemainder n = n-(squareRoot n)^2

From top to bottom: I check whether or not the number is negative and its magnitude one hundred at a time so that I can use the binomial coefficients 100, 20 and 1 to decompose the number. If their sum is greater than the latter, then I subtract the first coefficient with the second and add the third, otherwise I show the result by halving the second coefficient and adding the third.


The idea works according to this:

81-18+1 = 64, the square of 8, 18 double the product of 9 and 1, so 9+1 is the root of 100.
64-16+1 = 49, the square of 7, 16 double the product of 8 and 1, so 8+1 is the root of 81.
49-14+1 = 36, the square of 6, 14 double the product of 7 and 1, so 7+1 is the root of 64.
...

And it carries on. I don't know whether it's the most efficient or not. I thought that it was a good exercise in trying to make it reasonable and capable of being generalized since the cube root uses coefficients 1000, 300, 30 and 1, with the number having to be checked for its magnitude one thousand at a time.

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