# How to implement this signature?

I have this fingerprint for string s, f(s) = (S[1]r^m-1) xor (S[2]r^m-2) xor....(xor S[n]r^0)) mod (2^32) let s contains only a's and b's (0,1 respectively).

If it were addition instead of xor then it would be easy. We can solve it using the rule: (a + b)mod m = ((a mod m) + (b mod m)) mod m, but here it's not the case. So, any idea keep in mind that I cannot compute e.g. r^m-1 since I may face integer overflow.

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It looks like this question might be better suited for math.stackexchange.com –  RacerNerd Apr 29 '13 at 18:53
define integer overflow. Do you actually mean Integer.MAX_VALUE? –  Woot4Moo Apr 29 '13 at 18:56
yes, if r^m-1 is too large then it will truncated. –  ajab Apr 29 '13 at 18:57
What are r and m? Can you point us to the document that defines this signature algorithm? –  Edward Falk Apr 29 '13 at 19:07
Are you sure that modulo isn't associative over xor the way it is for addition? –  Edward Falk Apr 29 '13 at 19:09

If the concern is overflow, I recommend using `BigInteger` this will not overflow assuming you have enough memory:

Semantics of arithmetic operations exactly mimic those of Java's integer arithmetic operators, as defined in The Java Language Specification. For example, division by zero throws an ArithmeticException, and division of a negative by a positive yields a negative (or zero) remainder. All of the details in the Spec concerning overflow are ignored, as BigIntegers are made as large as necessary to accommodate the results of an operation.

BigInteger is not really a type. It's a class. It's a wrapper class designed to give you the same functionality as an int, but allows you to use numbers as big as you need without the worry of overflow.

Types do overflow because they are simply a couple of bytes (exact amount depends on the type) of memory, and once that small amount of memory overflows, so do the numbers.

No class "overflows" unless it is specifically designed to do so (or if you run out of resources). A class is defined with enough memory for everything it contains, which would mostly be references to other classes or other data structures.

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I have already tried that, but if you noticed that my modulo is 2^32 and BigIntger.pow(int). 2^32 wont fit in int variable. –  ajab Apr 29 '13 at 19:03
@ajab BigInteger is NOT the same as an int. I have used BigInteger to calculate numbers far greater than `2^32` –  Woot4Moo Apr 29 '13 at 19:05
yes, it could work but still I am not looking for such answer. what i need is a way to manipulate the structure of the signature to deal with it using long or even int variables. the problem is the modulo is not associative over xor! –  ajab Apr 29 '13 at 19:24
I'm pretty well convinced that overflow is not an issue here, and the entire thing can be done in 32-bit integer math. –  Edward Falk May 1 '13 at 2:10

Overflow is not a problem, because:

• XOR is a bitwuse operation (the presence/absence of higher bits does affect the result)
• the final action of `mod 2^32` masks off higher bits

Just use a `long` to hold your result (64 bits, so bit 31 does not cause sign issues).

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i will have overflow before doing any xoring for example: let r = 6548745, m-1 = 17 then 6548745 ^ 17 wont fit even long variable! –  ajab Apr 29 '13 at 19:15
If you compute it on a 32-bit machine, the overflow will be harmless, and you'll be effectively computing the modulo 2^32 operation for free –  Edward Falk May 1 '13 at 2:04

The Java `BigInteger` class does not support raising to exponents of type `BigInteger`. What you can do is implement an algorithm to compute the power yourself, using Exponentiation by Squaring. These usually come in the form of a recursive algorithm that will compute your power, without actually raising the number to more than an exponent of `2` (hence squaring).

The Java `BigInteger` class does, however, deal with the problem of overflow.

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Wait ... if m is simply the length of S, it's all a lot simpler:

``````int re = 1;
int sig = 0;
for (int i=m-1; i>=0; --m) {
if (s[i] != 0)
sig ^= re;
re = (re*r) & 0xffffffff;
}
``````

This seems almost too simple to me; are you sure you have the expression correct?

``````/**
* Return x^e, mod 2^32
*/
unsigned int
iExp(unsigned int x, unsigned int e)
{
unsigned int rval = 1;
while (e > 0) {
if ((e & 1) != 0)
rval *= x;
x *= x;
e >>= 1;
}
return rval & 0xffffffff;
}
``````

If S is an array of 0 or 1 values, then it's really a "use"/"don't use" flag for the rest of the subexpression:

``````// I've taken the liberty of indexing S starting at 0 instead of 1
// compute f(s) = (S[0]r^m-1) xor (S[1]r^m-2) xor....(xor S[m-1]r^0)) mod (2^32)

int rval = 0;
for (x : S) {
--m;
if (x != 0)
rval ^= iExpr(r, m);
}
``````

I haven't tested this (I don't have any test vectors), but this should do it.

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