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.NET 4.0 provides the System.Numerics.BigInteger type for arbitrarily-large integers. I need to compute the square root (or a reasonable approximation -- e.g., integer square root) of a BigInteger. So that I don't have to reimplement the wheel, does anyone have a nice extension method for this?

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Sorry, but my brain hurts from just starting to think about the math behind this :-P. And the nubers are to big to cast to a long? –  Alxandr Aug 7 '10 at 23:17
    
Yes, I'd need around 256 bits, possibly 512 - so no cheating with ulongs –  Anonym Aug 8 '10 at 1:01

4 Answers 4

The simplest feasible way to compute a square root to an arbitrary precision is probably Newton's method.

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The joy of newtons method... –  Marlon Dec 5 '10 at 0:41

Google(java biginteger sqrt) gives many hits which help. For instance http://www.merriampark.com/bigsqrt.htm

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Porting this should be easy enough...but i don't think there's a BigDecimal Implementation for .NET (as of now). +1 anyway :) –  st0le Sep 14 '10 at 14:19

I am not sure if Newton's Method is the best way to compute bignum square roots, because it involves divisions which are slow for bignums. You can use a CORDIC method, which uses only addition and shifts (shown here for unsigned ints)

static uint isqrt(uint x)
{
    int b=15; // this is the next bit we try 
    uint r=0; // r will contain the result
    uint r2=0; // here we maintain r squared
    while(b>=0) 
    {
        uint sr2=r2;
        uint sr=r;
                    // compute (r+(1<<b))**2, we have r**2 already.
        r2+=(uint)((r<<(1+b))+(1<<(b+b)));      
        r+=(uint)(1<<b);
        if (r2>x) 
        {
            r=sr;
            r2=sr2;
        }
        b--;
    }
    return r;
}

There's a similar method which uses only addition and shifts, called 'Dijkstras Square Root', explained for example here:

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This computes the integer square root of an integer. If you need decimals, you can pre-scale the operand. –  Nordic Mainframe Aug 8 '10 at 0:31
    
you can compute to arbitrary precision by continuing the loop for negative values of b and converting left shifts of -n to right shifts of n. –  Chris Dodd Aug 8 '10 at 19:28
    
Easily adapted to 64-bit long, which is what I needed. Thanks! –  yoyo Sep 4 '13 at 20:49

Check if BigInteger is not a perfect square has code to compute the integer square root of a Java BigInteger. Here it is translated into C#, as an extension method.

    public static BigInteger Sqrt(this BigInteger n)
    {
        if (n == 0) return 0;
        if (n > 0)
        {
            int bitLength = Convert.ToInt32(Math.Ceiling(BigInteger.Log(n, 2)));
            BigInteger root = BigInteger.One << (bitLength / 2);

            while (!isSqrt(n, root))
            {
                root += n / root;
                root /= 2;
            }

            return root;
        }

        throw new ArithmeticException("NaN");
    }

    private static Boolean isSqrt(BigInteger n, BigInteger root)
    {
        BigInteger lowerBound = root*root;
        BigInteger upperBound = (root + 1)*(root + 1);

        return (n >= lowerBound && n < upperBound);
    }

Informal testing indicates that this is about 75X slower than Math.Sqrt, for small integers. The VS profiler points to the multiplications in isSqrt as the hotspots.

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1  
BigInteger does not optimize the division operator. Bitshift right one instead of dividing by two will improve performance (at least in my case). –  GeirGrusom Oct 28 '11 at 6:59
    
The UpperBound definition can also be rewritten as the polynomial expansion BigInteger upperBound = lowerBound + root + root + 1 or inlined in the return as return n >= lowerBound && n <= lowerBound + root + root –  Jesan Fafon Aug 13 at 22:57

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