# Numpy matrix power/exponent with modulo?

Is it possible to use numpy's linalg.matrix_power with a modulo so the elements don't grow larger than a certain value?

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Can you define what you mean by modulus. –  Benjamin Dec 15 '11 at 3:01
modulus = remainder operation. Like 10 mod 3 = 1, 24 mod 5 = 4, etc. linalg.matrix_power is fast but I want to be able to apply modular operations to the elements before they grow too large. –  John Smith Dec 15 '11 at 3:08
Ah, modulo: en.wikipedia.org/wiki/Modulo_operation –  Benjamin Dec 15 '11 at 3:12
right but in conjunction with the matrix exponentiation before the elements blow up –  John Smith Dec 15 '11 at 3:26
"Modulus" usually refers to the absolute value of complex numbers (while "modulo" is indeed used for the remainder of integer division). –  EOL Dec 15 '11 at 14:06
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## 2 Answers

In order to prevent overflow, you can use the fact that you get the same result if you first take the modulo of each of your input numbers; in fact:

``````(M**k) mod p = ([M mod p]**k) mod p,
``````

for a matrix `M`. This comes from the following two fundamental identities, which are valid for integers `x` and `y`:

``````(x+y) mod p = ([x mod p]+[y mod p]) mod p  # All additions can be done on numbers *modulo p*
(x*y) mod p = ([x mod p]*[y mod p]) mod p  # All multiplications can be done on numbers *modulo p*
``````

The same identities hold for matrices as well, since matrix addition and multiplication can be expressed through scalar addition and multiplication. With this, you only exponentiate small numbers (n mod p is generally much smaller than n) and are much less likely to get overflows. In NumPy, you would therefore simply do

``````((arr % p)**k) % p
``````

in order to get `(arr**k) mod p`.

If this is still not enough (i.e., if there is a risk that `[n mod p]**k` causes overflow despite `n mod p` being small), you can break up the exponentiation into multiple exponentiations. The fundamental identities above yield

``````(n**[a+b]) mod p = ([{n mod p}**a mod p] * [{n mod p}**b mod p]) mod p
``````

and

``````(n**[a*b]) mod p = ([n mod p]**a mod p)**b mod p.
``````

Thus, you can break up power `k` as `a+b+…` or `a*b*…` or any combination thereof. The identities above allow you to perform only exponentiations of small numbers by small numbers, which greatly lowers the risk of integer overflows.

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What's wrong with the obvious approach?

E.g.

``````import numpy as np

x = np.arange(100).reshape(10,10)
y = np.linalg.matrix_power(x, 2) % 50
``````
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perhaps the OP is using large exponents and getting overflow issues. e.g. algorithms with exponentiation combined with modulo is often used on large ints in crypto stuff –  wim Dec 15 '11 at 4:07
Good point! I wasn't thinking it through. –  Joe Kington Dec 15 '11 at 4:11
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