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# How to calculate modulus of large numbers?

How to calculate modulus of 5^55 modulus 221 without much use of calculator?

I guess there are some simple principles in number theory in cryptography to calculate such things.

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Here is an explanation: devx.com/tips/Tip/39012 – tur1ng Feb 1 '10 at 15:36
the devx link is not of much use, there are other simple methods in number theory for such things, AFAIK. – Priyank Bolia Feb 1 '10 at 15:42
@Priyank Bolia: Don't worry, it's unlikely this question will be closed. It's a good question. If it is closed, there will be plenty of people voting to reopen. – jason Feb 1 '10 at 16:19
Yeah, many of us are aware that sometimes computer science involves mathematics. – Jefromi Feb 1 '10 at 16:33
@JB King: MathOverflow is for mathematics at the graduate-level and higher; this question would be frowned upon there. – jason Feb 1 '10 at 17:00

Okay, so you want to calculate `a^b mod m`. First we'll take a naive approach and then see how we can refine it.

First, reduce `a mod m`. That means, find a number `a1` so that `0 <= a1 < m` and `a = a1 mod m`. Then repeatedly in a loop multiply by `a1` and reduce again `mod m`. Thus, in pseudocode:

``````a1 = a reduced mod m
p = 1
for(int i = 1; i <= b; i++) {
p *= a1
p = p reduced mod m
}
``````

By doing this, we avoid numbers larger than `m^2`. This is the key. The reason we avoid numbers larger than `m^2` is because at every step `0 <= p < m` and `0 <= a1 < m`.

As an example, let's compute `5^55 mod 221`. First, `5` is already reduced `mod 221`.

1. `1 * 5 = 5 mod 221`
2. `5 * 5 = 25 mod 221`
3. `25 * 5 = 125 mod 221`
4. `125 * 5 = 183 mod 221`
5. `183 * 5 = 31 mod 221`
6. `31 * 5 = 155 mod 221`
7. `155 * 5 = 112 mod 221`
8. `112 * 5 = 118 mod 221`
9. `118 * 5 = 148 mod 221`
10. `148 * 5 = 77 mod 221`
11. `77 * 5 = 164 mod 221`
12. `164 * 5 = 157 mod 221`
13. `157 * 5 = 122 mod 221`
14. `122 * 5 = 168 mod 221`
15. `168 * 5 = 177 mod 221`
16. `177 * 5 = 1 mod 221`
17. `1 * 5 = 5 mod 221`
18. `5 * 5 = 25 mod 221`
19. `25 * 5 = 125 mod 221`
20. `125 * 5 = 183 mod 221`
21. `183 * 5 = 31 mod 221`
22. `31 * 5 = 155 mod 221`
23. `155 * 5 = 112 mod 221`
24. `112 * 5 = 118 mod 221`
25. `118 * 5 = 148 mod 221`
26. `148 * 5 = 77 mod 221`
27. `77 * 5 = 164 mod 221`
28. `164 * 5 = 157 mod 221`
29. `157 * 5 = 122 mod 221`
30. `122 * 5 = 168 mod 221`
31. `168 * 5 = 177 mod 221`
32. `177 * 5 = 1 mod 221`
33. `1 * 5 = 5 mod 221`
34. `5 * 5 = 25 mod 221`
35. `25 * 5 = 125 mod 221`
36. `125 * 5 = 183 mod 221`
37. `183 * 5 = 31 mod 221`
38. `31 * 5 = 155 mod 221`
39. `155 * 5 = 112 mod 221`
40. `112 * 5 = 118 mod 221`
41. `118 * 5 = 148 mod 221`
42. `148 * 5 = 77 mod 221`
43. `77 * 5 = 164 mod 221`
44. `164 * 5 = 157 mod 221`
45. `157 * 5 = 122 mod 221`
46. `122 * 5 = 168 mod 221`
47. `168 * 5 = 177 mod 221`
48. `177 * 5 = 1 mod 221`
49. `1 * 5 = 5 mod 221`
50. `5 * 5 = 25 mod 221`
51. `25 * 5 = 125 mod 221`
52. `125 * 5 = 183 mod 221`
53. `183 * 5 = 31 mod 221`
54. `31 * 5 = 155 mod 221`
55. `155 * 5 = 112 mod 221`

Therefore, `5^55 = 112 mod 221`.

Now, we can improve this by using exponentiation by squaring; this is the famous trick wherein we reduce exponentiation to requiring only `log b` multiplications instead of `b`. Note that with the algorithm that I described above, the exponentiation by squaring improvement, you end up with the right-to-left binary method.

``````a1 = a reduced mod m
p = 1
while (b > 0) {
if (b is odd) {
p *= a1
p = p reduced mod m
}
b /= 2
a1 = (a1 * a1) reduced mod m
}
``````

Thus, since 55 = 110111 in binary

1. `1 * 5 = 5 mod 221` (`5` is `5^1 mod 221`)
2. `5 * 25 = 125 mod 221` (`25` is `5^2 mod 221`)
3. `125 * 183 = 112 mod 221` (`183` is `5^4 mod 221`)
4. `112 * 1 = 112 mod 221` (`1` is `5^16 mod 221`)
5. `112 * 1 = 112 mod 221` (`1` is `5^32 mod 221`)

Therefore the answer is `5^55 = 112 mod 221`. The reason this works is because

``````55 = 1 + 2 + 4 + 16 + 32
``````

so that

``````5^55 = 5^(1 + 2 + 4 + 16 + 32) mod 221
= 5^1 * 5^2 * 5^4 * 5^16 * 5^32 mod 221
= 5 * 25 * 183 * 1 * 1 mod 221
= 22875 mod 221
= 112 mod 221
``````

In the step where we calculate `5^1 mod 221`, `5^2 mod 221`, etc. we note that `5^(2^k)` = `5^(2^(k-1)) * 5^(2^(k-1))` because `2^k = 2^(k-1) + 2^(k-1)` so that we can first compute `5^1` and reduce `mod 221`, then square this and reduce `mod 221` to obtain `5^2 mod 221`, etc.

The above algorithm formalizes this idea.

-
Well, most programming languages have a built-in operator for this. For example, in C-derived languages, the `%` operator is the modulus operator. Thus, `int p = 625 % 221` would assign `183` to `p`. You can achieve the same functionality by dividing `625` by `221` as integer division and getting the answer `2`. Then you take `625 - 2 * 221` to get the remainder. In this case `625 - 2 * 221 = 183` which is the answer. – jason Feb 1 '10 at 15:48
Yes, as I described in the paragraph at the end you do exponentiation by squaring. – jason Feb 1 '10 at 15:52
You can actually do much better than exponentiation by squaring, especially in the large-exponent case. Notice that you found that `5^16 == 1 (mod 221)`. Therefore, `5^k == 5^(k%16) (mod 221)`. – Jefromi Feb 1 '10 at 16:01
@Jason: you have written: First, reduce a mod m. That means, find a number a1 so that 0 <= a1 < m and a = a1 mod m. It looks like the last equation contains a typo, shouldn't it be a1 = a mod m instead? – Tim Apr 10 '11 at 2:38
@Jason for the most part, if you just added ";" (and a few other characters) to your pseudocode, it would be C. – haneefmubarak Sep 2 '13 at 18:31

You can speed the process up (which might be helpful for very large exponents) using the binary expansion of the exponent. First calculate 5, 5^2, 5^4, 5^8 mod 221 - you do this by repeated squaring:

`````` 5^1 = 5(mod 221)
5^2 = 5^2 (mod 221) = 25(mod 221)
5^4 = (5^2)^2 = 25^2(mod 221) = 625 (mod 221) = 183(mod221)
5^8 = (5^4)^2 = 183^2(mod 221) = 33489 (mod 221) = 118(mod 221)
5^16 = (5^8)^2 = 118^2(mod 221) = 13924 (mod 221) = 1(mod 221)
5^32 = (5^16)^2 = 1^2(mod 221) = 1(mod 221)
``````

Now we can write

``````55 = 1 + 2 + 4 + 16 + 32

so 5^55 = 5^1 * 5^2 * 5^4 * 5^16 * 5^32
= 5   * 25  * 625 * 1    * 1 (mod 221)
= 125 * 625 (mod 221)
= 125 * 183 (mod 183) - because 625 = 183 (mod 221)
= 22875 ( mod 221)
= 112 (mod 221)
``````

You can see how for very large exponents this will be much faster (I believe it's log as opposed to linear in b, but not certain.)

-
this is even better explanation – Priyank Bolia Feb 1 '10 at 15:56
I suspect that it's actually much faster (in general) to avoid the exponentiation by squaring, and instead search directly for the least exponent \$k\$ such that \$5^k == 5 (mod 221)\$. This does of course depend on size of exponent versus modulus, but once you have that exponent, you just need a single calculation (exponent mod k) and lookup. Note it's also therefore definitely better if you need to repeat similar calculations. (You can't in general look for \$a^k == 1 (mod 221)\$ since this only happens if \$a\$ and 221 are relatively prime) – Jefromi Feb 1 '10 at 16:06
well, no, in general finding the least exponent with that property is much slower than sqaure-and-multiply. But if you know the factorization of the modulus then you can easily compute the carmichael lambda function which is a mutliple of your k. – James K Polk Feb 2 '10 at 0:31
``````/* The algorithm is from the book "Discrete Mathematics and Its
Applications 5th Edition" by Kenneth H. Rosen.
(base^exp)%mod
*/

int modular(int base, unsigned int exp, unsigned int mod)
{
int x = 1;
int power = base % mod;

for (int i = 0; i < sizeof(int) * 8; i++) {
int least_sig_bit = 0x00000001 & (exp >> i);
if (least_sig_bit)
x = (x * power) % mod;
power = (power * power) % mod;
}

return x;
}
``````
-

What you're looking for is modular exponentiation, specifically modular binary exponentiation. This wikipedia link has pseudocode.

-

Chinese Remainder Theorem comes to mind as an initial point as 221 = 13 * 17. So, break this down into 2 parts that get combined in the end, one for mod 13 and one for mod 17. Second, I believe there is some proof of a^(p-1) = 1 mod p for all non zero a which also helps reduce your problem as 5^55 becomes 5^3 for the mod 13 case as 13*4=52. If you look under the subject of "Finite Fields" you may find some good results on how to solve this.

EDIT: The reason I mention the factors is that this creates a way to factor zero into non-zero elements as if you tried something like 13^2 * 17^4 mod 221, the answer is zero since 13*17=221. A lot of large numbers aren't going to be prime, though there are ways to find large primes as they are used a lot in cryptography and other areas within Mathematics.

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well I don't know the factorials in the first place, and I am trying to prove that the number is a prime, using Miller Rabin Algorithm. So, I am at the opposite end. – Priyank Bolia Feb 1 '10 at 15:54
@Priyank Bolia: Riemann Hypothesis FTW! – jason Feb 1 '10 at 16:24
There aren't any factorials here, but there is a factorization which is different. The factorial of an integer n is defined as the product of all positive integers less than n,e.g. 2!=2, 3!=6, etc. and is often expressed using the ! symbol. Factorization is different and there isn't a common symbol used to express an integer being factored. – JB King Feb 1 '10 at 16:54

This is part of code I made for IBAN validation. Feel free to use.

``````    static void Main(string[] args)
{
int modulo = 97;
string input = Reverse("100020778788920323232343433");
int result = 0;
int lastRowValue = 1;

for (int i = 0; i < input.Length; i++)
{
// Calculating the modulus of a large number Wikipedia http://en.wikipedia.org/wiki/International_Bank_Account_Number
if (i > 0)
{
lastRowValue = ModuloByDigits(lastRowValue, modulo);
}
result += lastRowValue * int.Parse(input[i].ToString());
}
result = result % modulo;
Console.WriteLine(string.Format("Result: {0}", result));
}

public static int ModuloByDigits(int previousValue, int modulo)
{
// Calculating the modulus of a large number Wikipedia http://en.wikipedia.org/wiki/International_Bank_Account_Number
return ((previousValue * 10) % modulo);
}
public static string Reverse(string input)
{
char[] arr = input.ToCharArray();
Array.Reverse(arr);
return new string(arr);
}
``````
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``````5^55mod221=(5^10*5^10*5^10*5^10*5^10*5^5)mod221

=((5^10)mod221*(5^10*5^10*5^10*5^10*5^5))mod221

=(77*(5^10*5^10*5^10*5^10*5^5))mod221

=((77*5^10)mod221*(5^10*5^10*5^10*5^5))mod221

=(183*(5^10*5^10*5^10*5^5))mod221

=((183*5^10)mod221*(5^10*5^10*5^5))mod221

=(168*5^10*5^10*5^5))mod221

=((168*5^10)mod 221*(5^10*5^5))mod221

=(118*5^10*5^5))mod221

=((118*5^10)*(5^5))mod221

=(25*5^5)mod 221

=112
``````
-

Jason is saying that as opposed to first calculating 5^55 and then applying mod 21, you start with 5 mod 221, multiply the result by 5, and loop for a total of 54 times. I.e.

• 5 mod 221 = 5, 5 * 5 = 25
• 25 mod 221 = 25, 25 * 5 = 125
• 125 mod 221 = 125, 125 * 5 = 625
• 625 mod 221 = 183, 183 * 5 = 915
• ...

Eventually, you'll calculate 5^55 mod 221

-

Jason's answer in Java (note `i < exp`).

``````private static void testModulus() {
int bse = 5, exp = 55, mod = 221;

int a1 = bse % mod;
int p = 1;

System.out.println("1. " + (p % mod) + " * " + bse + " = " + (p % mod) * bse + " mod " + mod);

for (int i = 1; i < exp; i++) {
p *= a1;
System.out.println((i + 1) + ". " + (p % mod) + " * " + bse + " = " + ((p % mod) * bse) % mod + " mod " + mod);
p = (p % mod);
}

}
``````
-

Just provide another implementation of Jason's answer by C.

After discussing with my classmates, based on Jason's explanation, I like the recursive version more if you don't care about the performance very much:

For example:

``````#include<stdio.h>

int mypow( int base, int pow, int mod ){
if( pow == 0 ) return 1;
if( pow % 2 == 0 ){
int tmp = mypow( base, pow >> 1, mod );
return tmp * tmp % mod;
}
else{
return base * mypow( base, pow - 1, mod ) % mod;
}
}

int main(){
printf("%d", mypow(5,55,221));
return 0;
}
``````
-
does not work for input (0,0,1) – Anushree Acharjee Jul 9 '15 at 11:22