# Euclidean algorithm (GCD) with multiple numbers?

So I'm writing a program in Python to get the GCD of any amount of numbers.

``````def GCD(numbers):

if numbers[-1] == 0:
return numbers[0]

# i'm stuck here, this is wrong
for i in range(len(numbers)-1):
print GCD([numbers[i+1], numbers[i] % numbers[i+1]])

print GCD(30, 40, 36)
``````

The function takes a list of numbers. This should print 2. However, I don't understand how to use the the algorithm recursively so it can handle multiple numbers. Can someone explain?

updated, still not working:

``````def GCD(numbers):

if numbers[-1] == 0:
return numbers[0]

gcd = 0

for i in range(len(numbers)):
gcd = GCD([numbers[i+1], numbers[i] % numbers[i+1]])
gcdtemp = GCD([gcd, numbers[i+2]])
gcd = gcdtemp

return gcd
``````

Ok, solved it

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

if b == 0:
return a
else:
return GCD(b, a % b)
``````

and then use reduce, like

``````reduce(GCD, (30, 40, 36))
``````
• your first problem that I notice is that you will need to sort the list so that the smallest element is the last May 18 '13 at 19:22
• Not sure if duplicate or just related: Computing greatest common denominator in python May 18 '13 at 19:26
• just fyi if you can do it with iterative instead of recurse it would probably be faster and able to handle larger values ... recursion of undefined depth can be a little sketchy in python May 18 '13 at 20:10

Since GCD is associative, `GCD(a,b,c,d)` is the same as `GCD(GCD(GCD(a,b),c),d)`. In this case, Python's `reduce` function would be a good candidate for reducing the cases for which `len(numbers) > 2` to a simple 2-number comparison. The code would look something like this:

``````if len(numbers) > 2:
return reduce(lambda x,y: GCD([x,y]), numbers)
``````

Reduce applies the given function to each element in the list, so that something like

``````gcd = reduce(lambda x,y:GCD([x,y]),[a,b,c,d])
``````

is the same as doing

``````gcd = GCD(a,b)
gcd = GCD(gcd,c)
gcd = GCD(gcd,d)
``````

Now the only thing left is to code for when `len(numbers) <= 2`. Passing only two arguments to `GCD` in `reduce` ensures that your function recurses at most once (since `len(numbers) > 2` only in the original call), which has the additional benefit of never overflowing the stack.

You can use `reduce`:

``````>>> from fractions import gcd
>>> reduce(gcd,(30,40,60))
10
``````

which is equivalent to;

``````>>> lis = (30,40,60,70)
>>> res = gcd(*lis[:2])  #get the gcd of first two numbers
>>> for x in lis[2:]:    #now iterate over the list starting from the 3rd element
...    res = gcd(res,x)

>>> res
10
``````

help on `reduce`:

``````>>> reduce?
Type:       builtin_function_or_method
reduce(function, sequence[, initial]) -> value

Apply a function of two arguments cumulatively to the items of a sequence,
from left to right, so as to reduce the sequence to a single value.
For example, reduce(lambda x, y: x+y, [1, 2, 3, 4, 5]) calculates
((((1+2)+3)+4)+5).  If initial is present, it is placed before the items
of the sequence in the calculation, and serves as a default when the
sequence is empty.
``````
• While technically correct and absolutely the version I would prefer, I don't think it will help him understand why it works, as the solution is 'hidden' in the definition of reduce. May 18 '13 at 19:29
• i'm not going to use an already made gcd function though, i want to learn May 18 '13 at 19:31

A solution to finding out the LCM of more than two numbers in PYTHON is as follow:

``````#finding LCM (Least Common Multiple) of a series of numbers

def GCD(a, b):
#Gives greatest common divisor using Euclid's Algorithm.
while b:
a, b = b, a % b
return a

def LCM(a, b):
#gives lowest common multiple of two numbers
return a * b // GCD(a, b)

def LCMM(*args):
#gives LCM of a list of numbers passed as argument
return reduce(LCM, args)
``````

Here I've added +1 in the last argument of range() function because the function itself starts from zero (0) to n-1. Click the hyperlink to know more about range() function :

``````print ("LCM of numbers (1 to 5) : " + str(LCMM(*range(1, 5+1))))
print ("LCM of numbers (1 to 10) : " + str(LCMM(*range(1, 10+1))))
print (reduce(LCMM,(1,2,3,4,5)))
``````

The GCD operator is commutative and associative. This means that

``````gcd(a,b,c) = gcd(gcd(a,b),c) = gcd(a,gcd(b,c))
``````

So once you know how to do it for 2 numbers, you can do it for any number

To do it for two numbers, you simply need to implement Euclid's formula, which is simply:

``````// Ensure a >= b >= 1, flip a and b if necessary
while b > 0
t = a % b
a = b
b = t
end
return a
``````

Define that function as, say `euclid(a,b)`. Then, you can define `gcd(nums)` as:

``````if (len(nums) == 1)
return nums[1]
else
return euclid(nums[1], gcd(nums[:2]))
``````

This uses the associative property of gcd() to compute the answer

• Then why don't you use that knowledge? Generate gcd for one pair, and work your way through your list with the above properties of gcd. May 18 '13 at 19:25
• Take the gcd of the first number with the second, save the result to a variable. get the next number of the list, get the gcd of the previously saved result together with the new value. repeat until end of list. the value of your variable is the gcd of all numbers together. May 18 '13 at 19:26
• @Femaref updated my post with your solution that I don't know how to implement May 18 '13 at 19:33

Python 3.9 introduced multiple arguments version of `math.gcd`, so you can use:

``````import math
math.gcd(30, 40, 36)
``````

3.5 <= Python <= 3.8.x:

``````import functools
import math
functools.reduce(math.gcd, (30, 40, 36))
``````

3 <= Python < 3.5:

``````import fractions
import functools
functools.reduce(fractions.gcd, (30, 40, 36))
``````

Try calling the `GCD()` as follows,

``````i = 0
temp = numbers[i]
for i in range(len(numbers)-1):
temp = GCD(numbers[i+1], temp)
``````

My way of solving it in Python. Hope it helps.

``````def find_gcd(arr):
if len(arr) <= 1:
return arr
else:
for i in range(len(arr)-1):
a = arr[i]
b = arr[i+1]
while b:
a, b = b, a%b
arr[i+1] = a
return a
def main(array):
print(find_gcd(array))

main(array=[8, 18, 22, 24]) # 2
main(array=[8, 24]) # 8
main(array=[5]) # [5]
main(array=[]) # []
``````

Some dynamics how I understand it:

ex.[8, 18] -> [18, 8] -> [8, 2] -> [2, 0]

18 = 8x + 2 = (2y)x + 2 = 2z where z = xy + 1

ex.[18, 22] -> [22, 18] -> [18, 4] -> [4, 2] -> [2, 0]

22 = 18w + 4 = (4x+2)w + 4 = ((2y)x + 2)w + 2 = 2z

As of python 3.9 beta 4, it has got built-in support for finding gcd over a list of numbers.

``````Python 3.9.0b4 (v3.9.0b4:69dec9c8d2, Jul  2 2020, 18:41:53)
[Clang 6.0 (clang-600.0.57)] on darwin
>>> import math
>>> A = [30, 40, 36]
>>> print(math.gcd(*A))
2
``````

One of the issues is that many of the calculations only work with numbers greater than 1. I modified the solution found here so that it accepts numbers smaller than 1. Basically, we can re scale the array using the minimum value and then use that to calculate the GCD of numbers smaller than 1.

``````# GCD of more than two (or array) numbers - alows folating point numbers
# Function implements the Euclidian algorithm to find H.C.F. of two number
def find_gcd(x, y):
while(y):
x, y = y, x % y
return x

# Driver Code
l_org = [60e-6, 20e-6, 30e-6]
min_val = min(l_org)
l = [item/min_val for item in l_org]

num1 = l[0]
num2 = l[1]
gcd = find_gcd(num1, num2)

for i in range(2, len(l)):
gcd = find_gcd(gcd, l[i])

gcd = gcd * min_val
print(gcd)

``````

HERE IS A SIMPLE METHOD TO FIND GCD OF 2 NUMBERS

``````a = int(input("Enter the value of first number:"))
b = int(input("Enter the value of second number:"))
c,d = a,b
while a!=0:
b,a=a,b%a
print("GCD of ",c,"and",d,"is",b)
``````