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I'm working on a cryptographic exercise, and I'm trying to calculate (2n-1)mod p where p is a prime number

What would be the best approach to do this? I'm working with C so 2n-1 becomes too large to hold when n is large

I came across the equation (a*b)modp=(a(bmodp))modp, but I'm not sure this applies in this case, as 2n-1 may be prime (or I'm not sure how to factorise this)

Help much appreciated.

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The numeric ranges of n and p are very relevant. –  Potatoswatter Nov 4 '13 at 8:18
P is a 10 digit prime (say 1000000007), and n is at most 9 digits. –  navinpai Nov 4 '13 at 8:26
Is it any 10 digit prime up to 999999999, or is there a specific upper limit? 2^32 ≈ 4*10^9 which is 10 digits, so the question is whether you can square any number less than p without overflowing the native 64-bit integer type. –  Potatoswatter Nov 4 '13 at 8:30
I can choose my prime, so say, I choose it as 1000000007 (the first 10 digit prime) –  navinpai Nov 4 '13 at 8:40

6 Answers 6

up vote 1 down vote accepted

You mention in the comments that n and p are 9 or 10 digits, or something. If you restrict them to 32 bit (unsigned long) values, you can find 2^n mod p with a simple (binary) modular exponentiation:

unsigned long long u = 1, w = 2;

while (n != 0)
    if ((n & 0x1) != 0)
        u = (u * w) % p; /* (mul-rdx) */

    if ((n >>= 1) != 0)
        w = (w * w) % p; /* (sqr-rdx) */

r = (unsigned long) u;

And, since (2^n - 1) mod p = r - 1 mod p :

r = (r == 0) ? (p - 1) : (r - 1);

If 2^n mod p = 0 - which doesn't actually occur if p > 2 is prime - but we might as well consider the general case - then (2^n - 1) mod p = -1 mod p.

Since the 'common residue' or 'remainder' (mod p) is in [0, p - 1], we add a some multiple of p so that it is in this range.

Otherwise, the result of 2^n mod p was in [1, p - 1], and subtracting 1 will be in this range already. It's probably better expressed as:

if (r == 0)
    r = p - 1; /* -1 mod p */
    r = r - 1;
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Thanks. This worked perfectly. But could you please shed some light on the final line? I'm not sure what that's doing –  navinpai Nov 5 '13 at 8:26
@navinpai - it's the ternary / conditional operator - I'll update the answer. –  Brett Hale Nov 5 '13 at 8:30

A couple tips to help you come up with a better way:

  1. Don't use (a*b)modp=(a(bmodp))modp to compute 2n-1 mod p, use it to compute 2n mod p and then subtract afterward.
  2. Fermat's little theorem can be useful here. That way, the exponent you actually have to deal with won't exceed p.
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i prefer your post on mine, nice answer –  zeeshan mughal Nov 4 '13 at 7:50
But how can i "subtract afterward"? Since mod may change in one of the steps. eg. (100mod100)=0 while (100-1)mod100=(99mod100)=99. How would subtracting afterward work? –  navinpai Nov 4 '13 at 7:54
Well, unless p = 2, 2^n mod p isn't going to be 0. –  Dennis Meng Nov 4 '13 at 7:55
(But in the general case, you can just test for it) –  Dennis Meng Nov 4 '13 at 7:55
@navinpai: -1 mod 100 = 99. –  Dietrich Epp Nov 4 '13 at 8:06

To take modulus you somehow must have 2^n-1 or you will move in a different direction of algorithms, interesting but seperate direction somehow, so i recommend you to use big int concept as it will be easy... make a structure and implement a big value in small values, e.g.

  struct bigint{
    int lowerbits;
    int upperbits;

decomposition of the statement also has solution like 2^n = (2^n-4 * 2^4 )-1%p decompose and seperatly handle them, that will be quite algorithmic then

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To compute 2^n - 1 mod p, you can use exponentiation by squaring after first removing any multiple of (p - 1) from n (since a^{p-1} = 1 mod p). In pseudo-code:

n = n % (p - 1)
result = 1
pow = 2
while n {
    if n % 2 {
        result = (result * pow) % p
    pow = (pow * pow) % p
    n /= 2
result = (result + p - 1) % p
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I don't understand the downvote for this answer. –  Brett Hale Nov 5 '13 at 9:54

First, focus on 2n mod p because you can always subtract one at the end.

Consider the powers of two. This is a sequence of numbers produced by repeatedly multiplying by two.

Consider the modulo operation. If the number is written in base p, you're just grabbing the last digit. Higher digits can be thrown away.

So at some point(s) in the sequence, you get a two-digit number (a 1 in the p's place), and your task is really just to get rid of the first digit (subtract p) when that happens.

Stopping here conceptually, the brute-force approach would be something like this:

uint64_t exp2modp( uint64_t n, uint64_t p ) {
    uint64_t ret = 1;
    uint64_t limit = p / 2;
    n %= p; // Apply Fermat's Little Theorem.

    while ( n -- ) {
        if ( ret >= limit ) {
            ret *= 2;
            ret -= p;
        } else {
            ret *= 2;
    return ret;

Unfortunately, this still takes forever for large n and p, and I can't think of any better number theory offhand.

If you have a multiplication facility which can compute (p-1)^2 without overflow, then you can use an analogous algorithm using repeated squaring with a modulo after each square operation, and then take the product of the series of square residuals, again with a modulo after each multiplication.

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step 1. x= shifting 1 n times and then subtract 1

step 2.result = logical and operation of x and p

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This causes overflow rather than working for large numbers. –  Potatoswatter Nov 4 '13 at 7:51
I think the question not contains on which type of data the operation will be done. So I just talked for a general solution. –  Debobroto Das Nov 4 '13 at 7:54
The problem is that this isn't general. Shifting and logical and are operations on bit-strings, not integers. General solutions are ones that make less assumptions. –  Potatoswatter Nov 4 '13 at 8:15
removed the int data type for x. –  Debobroto Das Nov 4 '13 at 10:35
It still doesn't work for n > 62 without an exotic platform. Also modulo isn't computed by logical AND unless p is also an integer 2^n-1. –  Potatoswatter Nov 4 '13 at 11:01

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