# How does a 32bit computer work with large bit numbers? Ex. 512bit integers [closed]

I have been reading an article on cryptography, and I thought to myself "How does a 32bit computer actually perform operations on a 512bit value, or even a 64 bit value?"

Would anyone be able to point me in the right direction? Maybe I am at a loss of how to properly express what I want to know, but Google searches haven't been very helpful in figuring this out.

Thanks!

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## closed as not a real question by Mitch Wheat, casperOne♦Oct 4 '12 at 11:50

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by operating on 32 bits at a time.... –  Mitch Wheat Oct 3 '12 at 23:58
The algorithms are actually familiar to you from your grade school arithmetic, except back then you didn't realize they were algorithms. Instead of of base 10 "digits" you use base 2**32 words. Knuth's "Seminumerical Algorithms" contains many variants and analysis. –  JamesKPolk Oct 4 '12 at 0:03

This is an expansion of GregS's comment.

Suppose I know all the one hundred `single-digit * single-digit` multiplications (from `0 * 0 = 0` up to `9 * 9 = 81`), and someone asks me to calculate `561 * 845`. I could say, "sorry I can't multiply numbers that large"; or, I could remember my childhood education and do this:

``````       561
845 *
----------
2805
2244
4488   +
==========
474045
``````

which requires only that I can do, in any given step, a multiplication within my known range, or an addition (with carry).

Now, suppose that instead of decimal digits, each of the symbols above was instead a 32 bit word; and instead of me, we had a processor that can multiply 32 bit words to a 64 bit result, and add (With carry) 32 bit words. Voila, we have a system for doing arbitrarily large binary multiplications.

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32-bits at a time. There are flags to indicate carry, overflow etc to allow multi-word arithmetic by means of repeated operations.

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A 32 bit processor can split larger numbers out onto more than one register although it is slower than performing operations on a single 32 bit register. For addition/subtraction it simply performs arithmetic starting from the least significant register and then carries the status bits over to the next significant register. It can get a bit more complex with multiplication/division but the main downside is performance.