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I need to calculate a*a mod n but a is fairly large, resulting in overflow when I square it. Doing ((a%n)*(a%n))%n doesn't work either. This is in C++ and I'm using int 64's.

edit: example a value = 821037907258, which overflows if you square it

I am using DevCPP and I've already tried getting big-integer libraries working to no avail.

edit 2: No, there's no pattern to these numbers.

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2  
Example values please. –  juergen d Apr 9 '12 at 16:05
    
Are you able to use a big-integer library? –  Oliver Charlesworth Apr 9 '12 at 16:06
2  
What is N? Has it a pattern? –  juergen d Apr 9 '12 at 16:09
1  
If you are use g++, you could use __uint128_t and __int128_t extensions. –  dasblinkenlight Apr 9 '12 at 16:13
1  
@juergend Double is 64-bits, which is what, 13 bits for the mantissa? That leaves 2 bits for signs (one for integer part, one for mantissa) and you get like, 51 bits of integer precision. That won't help the overflow much, in fact, it will overflow sooner - assuming the OP wants accuracy –  std''OrgnlDave Apr 9 '12 at 16:13

5 Answers 5

If you can't use a big-integer library, and you don't have a native uint128_t (or similar), you'll need to do this manually.

One option is to express a as the sum of two 32-bit quantities, i.e. a = 232b + c, where b contains the 32 msbs, and c contains the 32 lsbs. Squaring is then a set of four cross-multiplications; each result is guaranteed to fit into a 64-bit type. You then do the modulo operation as you recombine the individual terms (carefully taking into account the shifts needed to realign everything).

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2  
To the downvoter, reread the answer. –  leppie Apr 9 '12 at 16:10
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@WhatsInAName Basically, Oli is telling you to implement long multiplication and long division the same way you would do it grade-school. –  Mysticial Apr 9 '12 at 16:21
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@WhatsInAName: I don't think Mysticial is trying to be snarky... –  Oliver Charlesworth Apr 9 '12 at 16:25
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@WhatsInAName I'm not trying to be snarky - I apologize if you took it that way. In grade-school arithmetic, you "shift" the digits. In computers, you "shift" the bits. It's all the same except in a different base. –  Mysticial Apr 9 '12 at 16:27
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Is there any guarantee that mod(2^64, n)*b*b (or each subterm as we calculate the end result) won't overflow? Or should we recursively apply the multiplication function described above? –  vhallac Apr 9 '12 at 16:37

I know you no longer need this, and there is an alternative solution, but I want to add an alternative method to implement it. It provides two different techniques: the double and add algorithm, and the method to handle mod(a + b, n) with overflow detection.

Double and add algorithm is usually used in fields where multiplication is not possible or too costly to calculate directly (such as elliptic curves), but we could adopt it to handle it in our situation to handle overflows instead.

The following code is probably slower than the accepted solution (even when you optimize it), but if speed is not critical, you may prefer it for clarity.

unsigned addmod(unsigned x, unsigned y, unsigned n)
{
    // Precondition: x<n, y<n
    // If it will overflow, use alternative calculation
    if (x + y <= x) x = x - (n - y);
    else x = (x + y) % n;
    return x;
}

unsigned sqrmod(unsigned a, unsigned n)
{
    unsigned b;
    unsigned sum = 0;

    // Make sure original number is less than n
    a = a % n;

    // Use double and add algorithm to calculate a*a mod n
    for (b = a; b != 0; b >>= 1) {
        if (b & 1) {
            sum = addmod(sum, a, n);
        }
        a = addmod(a, a, n);
    }
    return sum;
}
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x = x - (n - y) - are you sure that does anything useful? –  Oliver Charlesworth Apr 9 '12 at 19:05
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@OliCharlesworth It calculates (x+y)%n without overflowing. The non-overflow is simple to prove. both x and y are less than n (and hence maximum word size), and we are only subtracting numbers, so they only go downwards, which means they can never overflow. To prove x - (n - y) is correct is a little trickier. First, since it overflows, x+y is clearly greater than n. Also, since both x and y are less than n, x+y is less than 2*n, so the modulus is equal to (x+y)-n. If you write x+y as x-(-y) and rearrange terms, you get the formula I used. –  vhallac Apr 9 '12 at 20:17
    
@OliCharlesworth I think you can use the alternative formula (x+y)+2^W-n instead of x-(n-y), but I didn't try it. This would have the advantage of letting us calculate x+y only once in addmul. –  vhallac Apr 9 '12 at 20:23
    
addmod() needs a comment saying a precondition is that x < n and y < n. –  Craig McQueen Oct 29 '13 at 5:52
    
@CraigMcQueen Yes. It is not obvious. I am editing the answer to add it. –  vhallac Oct 30 '13 at 17:51

Here is a double-and-add implementation of a multiplication a * b % m, without overflows, whatever the size of a, b and m.

uint64_t mulmod(uint64_t a, uint64_t b, uint64_t m) {
    uint64_t res = 0;
    uint64_t temp_b;

    /* Only needed if b may be >= m */
    if (b >= m) {
        if (m > UINT64_MAX / 2u)
            b -= m;
        else
            b %= m;
    }

    while (a != 0) {
        if (a & 1) {
            if (b >= m - res) /* Equiv to if (res + b >= m), without overflow */
                res -= m;
            res += b;
        }
        a >>= 1;

        /* Double b, modulo m */
        temp_b = b;
        if (b >= m - b)       /* Equiv to if (2 * b >= m), without overflow */
            temp_b -= m;
        b += temp_b;
    }
    return res;
}

This is my modification of another answer to another similar question.

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You can implement the multiplication yourself, adding n each run, and mod'ing the result right away.

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2  
You realize he's talking about numbers over 4 billion, right? That's what it takes to overflow a 64-bit int... –  std''OrgnlDave Apr 9 '12 at 16:07
    
It would take way too long for me to iterate through the a-value to do this –  WhatsInAName Apr 9 '12 at 16:08
    
@OrgnlDave: that would be enough to overflow a 32-bit int. For a 64-bit int, you need something about 4 billion times that size. (Or do you mean the two inputs are over 4 billion, so multiplying them overflows a 64-bit int?) –  Jerry Coffin Apr 9 '12 at 16:09

I really think that ((a%n)*(a%n))%n should work for positive integers. Why do you think it doesn't work? Do you have a counter-example? If n could be negative, then the % operator is undefined.

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1  
a is smaller than n. a^2 is larger than n. However, a^2 overflows. –  WhatsInAName Apr 9 '12 at 16:27
    
@WhatsInAName: If (n-1) squared can overflow, you should have said that in the question, because the question doesn't say that. Your question merely says that a squared overflows. This answer depends on n squared not overflowing. –  Mooing Duck Apr 9 '12 at 16:37
    
I didn't know it mattered because I'm not squaring n. But yes, n-1 squared would overflow, too. –  WhatsInAName Apr 9 '12 at 16:40
    
If n is very large, then a%n can be very large. –  Oliver Charlesworth Apr 9 '12 at 16:43
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@MooingDuck: I don't think that's necessary. The fact that the OP is asking the question at all implies that n-1 squared can overflow. This answer is based on an unwarranted assumption. –  Oliver Charlesworth Apr 9 '12 at 16:49

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