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  • Last updated , by Bodigrim
  • License MIT
  • Categories Algorithms, Mathematics
  • Maintained by: Andrew Lelechenko andrew dot lelechenko at gmail dot com

  • Lottery factor: 1

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Installation

Tested Compilers

  1. 9.12.2
  2. 9.10.3
  3. 9.8.4
  4. 9.6.7
  5. 9.4.8
  6. 9.2.8
  7. 9.0.2
  8. 8.10.7
  9. 8.8.4
  10. 8.6.5
  11. 8.4.4
  12. 8.2.2
  13. 8.0.2

Readme

integer-roots Hackage Stackage LTS Stackage Nightly

Calculating integer roots and testing perfect powers of arbitrary precision.

Integer square root

The integer square root (integerSquareRoot) of a non-negative integer n is the greatest integer m such that $m\le\sqrt{n}$. Alternatively, in terms of the floor function, $m = \lfloor\sqrt{n}\rfloor$.

For example,

> integerSquareRoot 99
9
> integerSquareRoot 101
10

It is tempting to implement integerSquareRoot via sqrt :: Double -> Double:

integerSquareRoot :: Integer -> Integer
integerSquareRoot = truncate . sqrt . fromInteger

However, this implementation is faulty:

> integerSquareRoot (3037000502^2)
3037000501
> integerSquareRoot (2^1024) == 2^1024
True

The problem here is that Double can represent only a limited subset of integers without precision loss. Once we encounter larger integers, we lose precision and obtain all kinds of wrong results.

This library features a polymorphic, efficient and robust routine integerSquareRoot :: Integral a => a -> a, which computes integer square roots by Karatsuba square root algorithm without intermediate Doubles.

Integer cube roots

The integer cube root (integerCubeRoot) of an integer n equals to $\lfloor\sqrt[3]{n}\rfloor$.

Again, a naive approach is to implement integerCubeRoot via Double-typed computations:

integerCubeRoot :: Integer -> Integer
integerCubeRoot = truncate . (** (1/3)) . fromInteger

Here the precision loss is even worse than for integerSquareRoot:

> integerCubeRoot (4^3)
3
> integerCubeRoot (5^3)
4

That is why we provide a robust implementation of integerCubeRoot :: Integral a => a -> a, which computes roots by generalized Heron algorithm.

Higher powers

In spirit of integerSquareRoot and integerCubeRoot this library covers the general case as well, providing integerRoot :: (Integral a, Integral b) => b -> a -> a to compute integer k-th roots of arbitrary precision.

There is also highestPower routine, which tries hard to represent its input as a power with as large exponent as possible. This is a useful function in number theory, e. g., elliptic curve factorisation.

> map highestPower [2..10]
[(2,1),(3,1),(2,2),(5,1),(6,1),(7,1),(2,3),(3,2),(10,1)]