# Modular multiplicative inverse function in Python

Does some standard Python module contain a function to compute modular multiplicative inverse of a number, i.e. a number `y = invmod(x, p)` such that `x*y == 1 (mod p)`? Google doesn't seem to give any good hints on this.

Of course, one can come up with home-brewed 10-liner of extended Euclidean algorithm, but why reinvent the wheel.

For example, Java's `BigInteger` has `modInverse` method. Doesn't Python have something similar?

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My website kahnet.co.uk provides the theory and some code for a new method for calculating multiplicative inverses which, I believe, is the fastest currently available anywhere. The code is in assembler in the main with some pseudo code suitable for any language - hence not aimed at Python. If you rewrite it for Python let me know how you get on.

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Some explanation inline to your answer would improve its quality. –  Politank-Z Apr 21 at 15:06

I made an one-liner for CodeFights which is one of the shortest solution.

Code here:

``````MMI = lambda A, n,s=1,t=0,N=0: (n < 2 and t%N or MMI(n, A%n, t, s-A/n*t, N or n),-1)[n<1]
``````

It will return `-1` if `A` has no multiplicative inverse in `n`.

Usage:

``````MMI(23, 99) # returns 56
MMI(18, 24) # return -1
``````

The solution is similar to others. We all use Extended Euclidean Algorithm.

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Here is my code, it might be sloppy but it seems to work for me anyway.

``````# a is the number you want the inverse for
# b is the modulus

def mod_inverse(a, b):
r = -1
B = b
A = a
eq_set = []
full_set = []
mod_set = []

#euclid's algorithm
while r!=1 and r!=0:
r = b%a
q = b//a
eq_set = [r, b, a, q*-1]
b = a
a = r
full_set.append(eq_set)

for i in range(0, 4):
mod_set.append(full_set[-1][i])

mod_set.insert(2, 1)
counter = 0

#extended euclid's algorithm
for i in range(1, len(full_set)):
if counter%2 == 0:
mod_set[2] = full_set[-1*(i+1)][3]*mod_set[4]+mod_set[2]
mod_set[3] = full_set[-1*(i+1)][1]

elif counter%2 != 0:
mod_set[4] = full_set[-1*(i+1)][3]*mod_set[2]+mod_set[4]
mod_set[1] = full_set[-1*(i+1)][1]

counter += 1

if mod_set[3] == B:
return mod_set[2]%B
return mod_set[4]%B
``````
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You might also want to look at the gmpy module. It is an interface between Python and the GMP multiple-precision library. gmpy provides an invert function that does exactly what you need:

``````>>> import gmpy
>>> gmpy.invert(1234567, 1000000007)
mpz(989145189)
``````

As noted by @hyh , the `gmpy.invert()` returns 0 if the inverse does not exist. That matches the behavior of GMP's `mpz_invert()` function. `gmpy.divm(a, b, m)` provides a general solution to `a=bx (mod m)`.

``````>>> gmpy.divm(1, 1234567, 1000000007)
mpz(989145189)
>>> gmpy.divm(1, 0, 5)
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
ZeroDivisionError: not invertible
>>> gmpy.divm(1, 4, 8)
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
ZeroDivisionError: not invertible
>>> gmpy.divm(1, 4, 9)
mpz(7)
``````

`divm()` will return a solution when `gcd(b,m) == 1` and raises an exception when the multiplicative inverse does not exist.

Disclaimer: I'm the current maintainer of the gmpy library.

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This is cool until I found `gmpy.invert(0,5) = mpz(0)` instead of raising an error... –  hyh Apr 20 '13 at 7:06
@hyh Can you report this as an issue at gmpy's home page? It's always appreciated if issues are reported. –  casevh Apr 20 '13 at 7:17
code.google.com/p/gmpy/issues/detail?id=72 Hopefully this works. –  hyh Apr 20 '13 at 7:28
BTW, is there a modular multiplication in this `gmpy` package? (i.e. some function that has the same value but is faster than `(a * b)% p` ?) –  hyh Apr 21 '13 at 8:35
It has been proposed before and I am experimenting with different methods. The simplest approach of just calculating `(a * b) % p` in a function isn't faster than just evaluating `(a * b) % p` in Python. The overhead for a function call is greater than the cost of evaluating the expression. See code.google.com/p/gmpy/issues/detail?id=61 for more details. –  casevh Apr 21 '13 at 17:16

Maybe someone will find this useful (from wikibooks):

``````def egcd(a, b):
if a == 0:
return (b, 0, 1)
else:
g, y, x = egcd(b % a, a)
return (g, x - (b // a) * y, y)

def modinv(a, m):
g, x, y = egcd(a, m)
if g != 1:
raise Exception('modular inverse does not exist')
else:
return x % m
``````
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I was having problems with negative numbers using this algorithm. modinv(-3, 11) didn't work. I fixed it by replacing egcd with the implementation on page two of this pdf: anh.cs.luc.edu/331/notes/xgcd.pdf Hope that helps! –  Qaz Nov 3 '14 at 23:02
@Qaz You can also just reduce -3 modulo 11 to make it positive, in this case modinv(-3, 11) == modinv(-3 + 11, 11) == modinv(8, 11). That's probably what the algorithm in your PDF happens to do at some point. –  Thomas Nov 4 '14 at 13:59

To figure out the modular multiplicative inverse I recommend using the Extended Euclidean Algorithm like this:

``````def multiplicative_inverse(a, b):
origA = a
X = 0
prevX = 1
Y = 1
prevY = 0
while b != 0:
temp = b
quotient = a/b
b = a%b
a = temp
temp = X
a = prevX - quotient * X
prevX = temp
temp = Y
Y = prevY - quotient * Y
prevY = temp

return origA + prevY
``````
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If your modulus is prime (you call it p) then you may simply compute:

``` y = x**(p-2) mod p ```

Or in python proper:

``` y = pow(x,p-2,p) ```

Here is someone who has implemented some number theory capabilities in Python:

http://userpages.umbc.edu/~rcampbel/Computers/Python/numbthy.html

Here is an example done at the prompt:

```m = 1000000007
x = 1234567
y = pow(x,m-2,m)
y
989145189L
x*y
1221166008548163L
x*y % m
1L
```
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Naive exponentiation is not an option because of time (and memory) limit for any reasonably big value of p like say 1000000007. –  dorserg Jan 25 '11 at 21:11
modular exponentiation is done with at most N*2 multiplications where N is the number of bits in the exponent. using a modulus of 2**63-1 the inverse can be computed at the prompt and returns a result immediately. –  phkahler Jan 25 '11 at 21:13
Wow, awesome. I'm aware of quick exponentiation, I just wasn't aware that pow() function can take third argument which turns it into modular exponentiation. –  dorserg Jan 25 '11 at 21:17
That's why you're using Python right? Because it's awesome :-) –  phkahler Jan 25 '11 at 21:24