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.
r*r
andn
, what value would you try for r? And how would you let Haskell know about it?