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Hi I want to multiply 2 big integer in a most timely optimized way. I am currently using karatsuba algorithm. Can anyone suggest more optimized way or algo to do it.

Thanks

public static BigInteger karatsuba(BigInteger x, BigInteger y) {

        // cutoff to brute force
        int N = Math.max(x.bitLength(), y.bitLength());
        System.out.println(N);
        if (N <= 2000) return x.multiply(y);                // optimize this parameter

        // number of bits divided by 2, rounded up
        N = (N / 2) + (N % 2);

        // x = a + 2^N b,   y = c + 2^N d
        BigInteger b = x.shiftRight(N);
        BigInteger a = x.subtract(b.shiftLeft(N));
        BigInteger d = y.shiftRight(N);
        BigInteger c = y.subtract(d.shiftLeft(N));

        // compute sub-expressions
        BigInteger ac    = karatsuba(a, c);
        BigInteger bd    = karatsuba(b, d);
        BigInteger abcd  = karatsuba(a.add(b), c.add(d));

        return ac.add(abcd.subtract(ac).subtract(bd).shiftLeft(N)).add(bd.shiftLeft(2*N));
    }
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  • 3
    what's wrong with BigInteger.Multiply() ? Commented Feb 23, 2013 at 8:38
  • 1
    It's complexity is of order O(n^2). Karatsuba is approximately O(n^1.5). I want a more optimized one.
    – KingJames
    Commented Feb 23, 2013 at 8:39
  • If you want speed then why not Toom-Cook ? Commented Feb 23, 2013 at 8:48
  • 2
    If the size isn't going to be bigger than 500 digits, then you won't need to go any higher than Karatsuba. Toom-Cook >=3 and FFT are only useful when you get into tens of thousands of digits.
    – Mysticial
    Commented Feb 23, 2013 at 8:54
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    There's probably a way to solve the problem without solving this problem (fast bigint multiplication) then.
    – user555045
    Commented Feb 23, 2013 at 12:00

2 Answers 2

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The version of BigInteger in jdk8 switches between the naive algorithm, The Toom-Cook algorithm, and Karatsuba depending on the size of the input to get excellent performance.

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Complexity and actual speed are very different things in practice, because of the constant factors involved in the O notation. There is always a point where complexity prevails, but it may very well be out of the range (of input size) you are working with. The implementation details (level of optimization) of an algorithm also directly affect those constant factors.

My suggestion is to try a few different algorithms, preferably from a library that the authors already spent some effort optimizing, and actually measure and compare their speeds on your inputs.

Regarding SPOJ, don't forget the possibility that the main problem lies elsewhere (i.e. not in the multiplication speed of large integers).

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  • Interestingly enough, the constant is dependent also upon the machine word size. If you were dealing with raw bits, Karatsuba becomes advantageous much sooner, than if you can assume say 32 or 64-bit multiplications are O(1) and therefore the bit size will be higher. Its also the details of memory allocation, copying and usage that are relevant as if you are not careful, the optimized algorithms tend to make the constant larger than is necessary. Commented Aug 12, 2021 at 8:57

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