# 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?

• In Python 3.8 (due to be released later this year), you'll be able to use the built-in pow function for this: y = pow(x, -1, p). See bugs.python.org/issue36027. It only took 8.5 years from the question being asked to a solution appearing in the standard library! – Mark Dickinson Jun 6 '19 at 19:32
• I see @MarkDickinson modestly neglected to mention that ey is the author of this very useful enhancement, so I will. Thanks for this work, Mark, it looks great! – Don Hatch Jul 24 '19 at 10:19

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

• 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
• If you happen to be using sympy, then x, _, g = sympy.numbers.igcdex(a, m) does the trick. – Lynn Sep 16 '16 at 18:15

If your modulus is prime (you call it p) then you may simply compute:

y = x**(p-2) mod p  # Pseudocode


Or in Python proper:

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


Here is someone who has implemented some number theory capabilities in Python: http://www.math.umbc.edu/~campbell/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

• 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
• By the way this works because from Fermat little theorem pow(x,m-1,m) must be 1. Hence (pow(x,m-2,m) * x) % m == 1. So pow(x,m-2,m) is the inverse of x (mod m). – Piotr Dabkowski Jul 4 '19 at 22:15

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.

gmpy2 now properly raises an exception when the inverse does not exists:

>>> import gmpy2

>>> gmpy2.invert(0,5)
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
ZeroDivisionError: invert() no inverse exists

• This is cool until I found gmpy.invert(0,5) = mpz(0) instead of raising an error... – h__ 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
• 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 ?) – h__ 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
• The great thing is that this also works for non-prime modulii. – synecdoche May 24 '13 at 2:19

Here is a one-liner for CodeFights; it is one of the shortest solutions:

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 uses the Extended Euclidean Algorithm.

Sympy, a python module for symbolic mathematics, has a built-in modular inverse function if you don't want to implement your own (or if you're using Sympy already):

from sympy import mod_inverse

mod_inverse(11, 35) # returns 16
mod_inverse(15, 35) # raises ValueError: 'inverse of 15 (mod 35) does not exist'


This doesn't seem to be documented on the Sympy website, but here's the docstring: Sympy mod_inverse docstring on Github

As of 3.8 pythons pow() function can take a modulus and a negative integer. See here. Their case for how to use it is

>>> pow(38, -1, 97)
23
>>> 23 * 38 % 97 == 1
True


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 = full_set[-1*(i+1)]*mod_set+mod_set
mod_set = full_set[-1*(i+1)]

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

counter += 1

if mod_set == B:
return mod_set%B
return mod_set%B


The code above will not run in python3 and is less efficient compared to the GCD variants. However, this code is very transparent. It triggered me to create a more compact version:

def imod(a, n):
c = 1
while (c % a > 0):
c += n
return c // a

• This is OK to explain it to kids, and when n == 7. But otherwise it's about equivalent of this "algorithm": for i in range(2, n): if i * a % n == 1: return i – Tomasz Gandor Dec 23 '19 at 2:51

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

• There appears to be a bug in this code: a = prevX - quotient * X should be X = prevX - quotient * X, and it should return prevX. FWIW, this implementation is similar to that in Qaz's link in the comment to Märt Bakhoff's answer. – PM 2Ring Nov 8 '15 at 10:55

I try different solutions from this thread and in the end I use this one:

def egcd(a, b):
lastremainder, remainder = abs(a), abs(b)
x, lastx, y, lasty = 0, 1, 1, 0
while remainder:
lastremainder, (quotient, remainder) = remainder, divmod(lastremainder, remainder)
x, lastx = lastx - quotient*x, x
y, lasty = lasty - quotient*y, y
return lastremainder, lastx * (-1 if a < 0 else 1), lasty * (-1 if b < 0 else 1)

def modinv(a, m):
g, x, y = self.egcd(a, m)
if g != 1:
raise ValueError('modinv for {} does not exist'.format(a))
return x % m


Modular_inverse in Python

• this code is invalid. return in egcd is indended in a wrong way – ph4r05 Feb 22 '19 at 10:50
• @DonHatch, copy-paste fixed, thx – Al Po Dec 11 '19 at 7:47

Well, I don't have a function in python but I have a function in C which you can easily convert to python, in the below c function extended euclidian algorithm is used to calculate inverse mod.

int imod(int a,int n){
int c,i=1;
while(1){
c = n * i + 1;
if(c%a==0){
c = c/a;
break;
}
i++;
}
return c;}


Python Function

def imod(a,n):
i=1
while True:
c = n * i + 1;
if(c%a==0):
c = c/a
break;
i = i+1

return c


Reference to the above C function is taken from the following link C program to find Modular Multiplicative Inverse of two Relatively Prime Numbers

Here is a concise 1-liner that does it, without using any external libraries.

# Given 0<a<b, returns the unique c such that 0<c<b and a*c == gcd(a,b) (mod b).
# In particular, if a,b are relatively prime, returns the inverse of a modulo b.
def invmod(a,b): return 0 if a==0 else 1 if b%a==0 else b - invmod(b%a,a)*b//a


Note that this is really just egcd, streamlined to return only the single coefficient of interest.

from the cpython implementation source code:

def invmod(a, n):
b, c = 1, 0
while n:
q, r = divmod(a, n)
a, b, c, n = n, c, b - q*c, r
# at this point a is the gcd of the original inputs
if a == 1:
return b
raise ValueError("Not invertible")


according to the comment above this code, it can return small negative values, so you could potentially check if negative and add n when negative before returning b.

Many of the links above are broken as for 1/23/2017. I found this implementation: https://courses.csail.mit.edu/6.857/2016/files/ffield.py