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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

up vote 6 down vote accepted

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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