# Multiplication and division on integers split into parts

Does anyone know where I might get instructions on how to do multiplication and division (and maybe even modulus) on integers that are stored in parts? im making a library that stores a `uint128_t` as `uint64_t UPPER, LOWER`.

-
This question contains several useful answers. –  Björn Pollex May 25 '11 at 21:18

Having your numbers splitted that way is an ideal prerequisite for Karatsuba multiplication. Consider:

``````x = x1 * 2^k + x2
y = y1 * 2^k + y2
``````

Using the school multiplication, you would need 4 multiplications:

``````x*y = (x1*y1) * 2^(2*k) + (x1*y2 + x2*y1) * 2^k + x2*y2
``````

Karatsuba needs a few more additions, but only 3 multiplications:

``````p1 = x1 * y1
p2 = x2 * y2
x*y = p1 * 2^(2*k) + ((x1+x2)*(y1+y2) - p1 - p2) * 2^k + p2
``````

Of course the problem is how to deal with overflows.

-
In my tests, Karatsuba multiplication was slower unless I had a lot more than two "digits". –  TBohne Mar 7 '12 at 17:13

Are you familiar with `GMP` library? Why don't you use it instead of implementing your own?

From the above link, you can download `tar.bz` file for Unix-based OS.

It has lots of information and installation file for MinGW, MSVC++, and CgyWin. Download that suits your need. You can also see these link:

After you're done with installation and configuration, you would like to know how to program using GMP, for that browse through these links:

-
i cant find "gmp.h" –  calccrypto May 25 '11 at 21:29
@calccrypto: Of course, you've to download and install it, before using it. –  Nawaz May 25 '11 at 21:30
install??? i thought it was just decompress, copy into some folder, and link the compiler to it –  calccrypto May 25 '11 at 21:31
@calccrypto: Yes. That whole process is installation, with configuration and all. –  Nawaz May 25 '11 at 21:33
there is no "gmp.h" file in the tar.gz –  calccrypto May 25 '11 at 21:34

I'm interested in the same subject, and I've found a similar question right here: How to implement big int in C++ I hope it will point you into the right direction!

-

Take a look at the various Big Integer libraries. Here's one that google found https://mattmccutchen.net/bigint/

-

http://en.wikipedia.org/wiki/Arbitrary-precision_arithmetic might be a good start. There are plenty of open source libraries already

-