# Code for Greatest Common Divisor in Python [closed]

The greatest common divisor (GCD) of a and b is the largest number that divides both of them with no remainder.

One way to find the GCD of two numbers is Euclid’s algorithm, which is based on the observation that if `r` is the remainder when `a` is divided by `b`, then `gcd(a, b) = gcd(b, r)`. As a base case, we can use `gcd(a, 0) = a`.

Write a function called gcd that takes parameters `a` and `b` and returns their greatest common divisor.

``````>>> from fractions import gcd
>>> gcd(20,8)
4
``````

Source code from the `inspect` module in Python 2.7:

``````>>> print inspect.getsource(gcd)
def gcd(a, b):
"""Calculate the Greatest Common Divisor of a and b.

Unless b==0, the result will have the same sign as b (so that when
b is divided by it, the result comes out positive).
"""
while b:
a, b = b, a%b
return a
``````

As of Python 3.5, `gcd` is in the `math` module; the one in `fractions` is deprecated. Moreover, `inspect.getsource` no longer returns explanatory source code for either method.

• It doesn't return "the _largest_ number that divides both of them with no remainder" e.g., `fractions.gcd(1, -1)` is `-1` but `1 > -1` i.e., `1` divides both `1` and `-1` with no remainder and it is larger than `-1`, see bugs.python.org/issue22477
– jfs
Sep 24 '14 at 12:39
• @J.F.Sebastian I don't see this as an issue... just look at the comment in the source code: "Unless b==0, the result will have the same sign as b", hence `gcd(1, -1) == -1` seems totally legit to me. Jan 11 '15 at 2:30
• @MarcoBonelli: yes. It behaves as documented but it is not the textbook definition that most people are familiar with. Read the discussion that I've linked above. Personally, I like `fractions.gcd()` as is (it works on Euclidean ring elements).
– jfs
Jan 11 '15 at 6:57
• @J.F.Sebastian FWIW, as of Python 3.5, `math.gcd(1, -1)` returns `1`. Nov 1 '16 at 22:50
• @A-B-B math.gcd() and fractions.gcd() are different as said in the answer and the comments.
– jfs
Nov 1 '16 at 22:56

The algorithms with m-n can runs awfully long.

This one performs much better:

``````def gcd(x, y):
while y != 0:
(x, y) = (y, x % y)
return x
``````
• This is the one in the standard library as well. Apr 7 '14 at 15:21
• How does that algorithm even work? its like magic. Nov 9 '14 at 2:37
• @netom: no, the assignment can not be written like that; the tuple assignment uses `x` before it is assigned. You assigned `y` to `x` first, so now `y` is going to be set to `0` (as `y % y` is always 0). Mar 19 '15 at 16:54
• @MartijnPieters yes, you're right, I should've used a temporary variable. like this: x_ = y; y = x % y; x = x_ Nov 15 '16 at 12:50
• @netom: which is not needed at all when using a tuple assignment as done in this answer. Nov 15 '16 at 12:51

This version of code utilizes Euclid's Algorithm for finding GCD.

``````def gcd_recursive(a, b):
if b == 0:
return a
else:
return gcd_recursive(b, a % b)
``````
• You used iter in the name but its actually a recursive version. Jan 1 '16 at 17:53
• recursion is poorly efficient compared to loop versions, + you need to call it with b>a May 10 '17 at 11:42
• `def gcd(a, b): if b == 0: return a return gcd(b, a % b)` Sep 4 '17 at 22:17
``````gcd = lambda m,n: m if not n else gcd(n,m%n)
``````

using recursion,

``````def gcd(a,b):
return a if not b else gcd(b, a%b)
``````

using while,

``````def gcd(a,b):
while b:
a,b = b, a%b
return a
``````

using lambda,

``````gcd = lambda a,b : a if not b else gcd(b, a%b)

>>> gcd(10,20)
>>> 10
``````
• @rem I think the "if not b" part does serve as the ending condition. Apr 5 at 0:50
``````def gcd(m,n):
return gcd(abs(m-n), min(m, n)) if (m-n) else n
``````
• Never use 'is' when you mean to compare for equality. The small integers cache is a CPython implementation detail. Jul 10 '13 at 10:23
• this is very slow May 15 at 19:38

Very concise solution using recursion:

``````def gcd(a, b):
if b == 0:
return a
return gcd(b, a%b)
``````
``````a=int(raw_input('1st no \n'))
b=int(raw_input('2nd no \n'))

def gcd(m,n):
z=abs(m-n)
if (m-n)==0:
return n
else:
return gcd(z,min(m,n))

print gcd(a,b)
``````

A different approach based on euclid's algorithm.

``````def gcdRecur(a, b):
'''
a, b: positive integers

returns: a positive integer, the greatest common divisor of a & b.
'''
# Base case is when b = 0
if b == 0:
return a

# Recursive case
return gcdRecur(b, a % b)
``````

I think another way is to use recursion. Here is my code:

``````def gcd(a, b):
if a > b:
c = a - b
gcd(b, c)
elif a < b:
c = b - a
gcd(a, c)
else:
return a
``````
• You are not returning after the recursive calls... try running `gcd(10,5)`... Jul 27 '19 at 23:04

in python with recursion:

``````def gcd(a, b):
if a%b == 0:
return b
return gcd(b, a%b)
``````
``````def gcd(a,b):
if b > a:
return gcd(b,a)
r = a%b
if r == 0:
return b
return gcd(r,b)
``````

# For `a>b`:

``````def gcd(a, b):

if(a<b):
a,b=b,a

while(b!=0):
r,b=b,a%r
a=r
return a
``````

# For either `a>b` or `a<b`:

``````def gcd(a, b):

t = min(a, b)

# Keep looping until t divides both a & b evenly
while a % t != 0 or b % t != 0:
t -= 1

return t
``````
• swap vars in python is children play: `b, a = a, b`. try to read more about the language Feb 8 '16 at 0:10
• I like what you say, but I don't like the way you say it Nov 14 '16 at 23:40

I had to do something like this for a homework assignment using while loops. Not the most efficient way, but if you don't want to use a function this works:

``````num1 = 20
num1_list = []
num2 = 40
num2_list = []
x = 1
y = 1
while x <= num1:
if num1 % x == 0:
num1_list.append(x)
x += 1
while y <= num2:
if num2 % y == 0:
num2_list.append(y)
y += 1
xy = list(set(num1_list).intersection(num2_list))
print(xy[-1])
``````
``````def _grateest_common_devisor_euclid(p, q):
if q==0 :
return p
else:
reminder = p%q
return _grateest_common_devisor_euclid(q, reminder)

print(_grateest_common_devisor_euclid(8,3))
``````

# This code calculates the gcd of more than two numbers depending on the choice given by # the user, here user gives the number

``````numbers = [];
count = input ("HOW MANY NUMBERS YOU WANT TO CALCULATE GCD?\n")
for i in range(0, count):
number = input("ENTER THE NUMBER : \n")
numbers.append(number)
numbers_sorted = sorted(numbers)
print  'NUMBERS SORTED IN INCREASING ORDER\n',numbers_sorted
gcd = numbers_sorted

for i in range(1, count):
divisor = gcd
dividend = numbers_sorted[i]
remainder = dividend % divisor
if remainder == 0 :
gcd = divisor
else :
while not remainder == 0 :
dividend_one = divisor
divisor_one = remainder
remainder = dividend_one % divisor_one
gcd = divisor_one

print 'GCD OF ' ,count,'NUMBERS IS \n', gcd
``````
• Welcome to Stack Overflow! Would you consider adding some narrative to explain why this code works, and what makes it an answer to the question? This would be very helpful to the person asking the question, and anyone else who comes along. Jun 11 '13 at 11:41

The value swapping didn't work well for me. So I just set up a mirror-like situation for numbers that are entered in either a < b OR a > b:

``````def gcd(a, b):
if a > b:
r = a % b
if r == 0:
return b
else:
return gcd(b, r)
if a < b:
r = b % a
if r == 0:
return a
else:
return gcd(a, r)

print gcd(18, 2)
``````
• This is not even valid Python syntax. Indentation is important. Jul 10 '13 at 10:23
• What about when a = b? you should have an initial IF condition to catch this. Jan 12 '15 at 13:25
``````#This program will find the hcf of a given list of numbers.

A = [65, 20, 100, 85, 125]     #creates and initializes the list of numbers

def greatest_common_divisor(_A):
iterator = 1
factor = 1
a_length = len(_A)
smallest = 99999

#get the smallest number
for number in _A: #iterate through array
if number < smallest: #if current not the smallest number
smallest = number #set to highest

while iterator <= smallest: #iterate from 1 ... smallest number
for index in range(0, a_length): #loop through array
if _A[index] % iterator != 0: #if the element is not equally divisible by 0
break #stop and go to next element
if index == (a_length - 1): #if we reach the last element of array
factor = iterator #it means that all of them are divisibe by 0
iterator += 1 #let's increment to check if array divisible by next iterator
#print the factor
print factor

print "The highest common factor of: ",
for element in A:
print element,
print " is: ",
``````

greatest_common_devisor(A)

``````def gcdIter(a, b):
gcd= min (a,b)
for i in range(0,min(a,b)):
if (a%gcd==0 and b%gcd==0):
return gcd
break
gcd-=1
``````
• This is the easiest way...Do not make it hard! May 25 '18 at 12:48
• Thanks for providing code which might help solve the problem, but generally, answers are much more helpful if they include an explanation of what the code is intended to do, and why that solves the problem. May 25 '18 at 13:04
• This code is incomplete (no final return statement) and improperly formatted (no indentaion). I'm not even sure what that `break` statement is trying to achieve. May 25 '18 at 15:37

Here's the solution implementing the concept of `Iteration`:

``````def gcdIter(a, b):
'''
a, b: positive integers

returns: a positive integer, the greatest common divisor of a & b.
'''
if a > b:
result = b
result = a

if result == 1:
return 1

while result > 0:
if a % result == 0 and b % result == 0:
return result
result -= 1
``````