# Reverse multiplication of 32-bit numbers

I have two large signed 32-bit numbers (java ints) being multiplied together such that they'll overflow. Actually, I have one of the numbers, and the result. Can I determine what the other operand was?

`knownResult = unknownOperand * knownOperand;`

Why? I have a string and a suffix being hashed with fnv1a. I know the resulting hash and the suffix, I want to see how easy it is to determine the hash of the original string.

This is the core of fnv1a:

``````hash ^= byte
hash *= PRIME
``````
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Hmm, well you know that `MAX_INT` > `unknownOperand` > (`MAX_INT` / `knownOperand`)... trying to think if that gets you any closer. In the `fnv1a` algorithm, what are `byte` and `PRIME`? Are they configurable or constants? Hash functions are generally made to be collision resistant, but the existence of collisions implies that you can't be sure you've arrived at a unique answer. – Patrick M Mar 21 '14 at 20:01
byte is the input to the hash function, PRIME is a parameter to fnv1a, in this case it is `0x01000193` – Michael Deardeuff Mar 21 '14 at 20:43

It depends. If the multiplier is even, at least one bit must inevitably be lost. So I hope that prime isn't 2.

If it's odd, then you can absolutely reverse it, just multiply by the modular multiplicative inverse of the multiplier to undo the multiplication.

There is an algorithm to calculate the modular multiplicative inverse modulo a power of two in Hacker's Delight.

For example, if the multiplier was `3`, then you'd multiply by `0xaaaaaaab` to undo (because `0xaaaaaaab * 3 = 1`). For `0x01000193`, the inverse is `0x359c449b`.

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You want to solve the equation `y = prime * x` for `x`, which you do by division in the finite ring modulo 232: `x = y / prime`.

Technically you do that by multiplying `y` with the multiplicative inverse of the prime modulo 232, which can be computed by the extended Euclidean algorithm.

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Uh, division? Or am I not understanding the question?

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`(a * b) / b` does not equal `a` due to overflow of `(a * b)`. Edited question to clarify this. – Michael Deardeuff Mar 21 '14 at 19:58