# What is the most efficient way to calculate the least common multiple of two integers?

What is the most efficient way to calculate the least common multiple of two integers?

I just came up with this, but it definitely leaves something to be desired.

``````int n=7, m=4, n1=n, m1=m;

while( m1 != n1 ){
if( m1 > n1 )
n1 += n;
else
m1 += m;
}

System.out.println( "lcm is " + m1 );
``````
• note that in case n and m are coprime, your loop iterates m + n - 2 times. which isn't good for large numbers compared to other solutions. Commented May 14, 2022 at 9:56
• Another problem with this algorithm is that it enters an infinite loop when one argument is zero and the other is not. It ought to return zero. Commented Apr 1 at 10:51

The least common multiple (lcm) of `a` and `b` is their product divided by their greatest common divisor (gcd) ( i.e. `lcm(a, b) = ab/gcd(a,b)`).

So, the question becomes, how to find the gcd? The Euclidean algorithm is generally how the gcd is computed. The direct implementation of the classic algorithm is efficient, but there are variations that take advantage of binary arithmetic to do a little better. See Knuth's "The Art of Computer Programming" Volume 2, "Seminumerical Algorithms" § 4.5.2.

• Yes, LCM using GCD is fast and easy to code. One small but important detail: in order to avoid overflows, calculate the final result like this: `lcm = a / gcd * b` instead of `lcm = a * b / gcd`.
– Bolo
Commented Jul 1, 2010 at 1:41
• @Bolo - if you are "worried" about overflow, you should be using `long` or in other circumstance even `BigInteger`. The LCM of two `int` values may be a `long`. Commented Jul 1, 2010 at 1:47
• @Stephen C With Bolo's approach the LCM can be computed without overflow if it can be represented. There is no need to use a bigger and slower number type just for the multiplication. Commented Jul 1, 2010 at 4:39
• @starblue - but conversely, there is nothing in the question that the LCM can be represented as an `int`. And we know for a fact that for certain values of `m` and `n` it cannot. My point is, that if you worry about overflow in the calculation you should also worry about overflow in the final result. Commented Jul 1, 2010 at 5:29
• @Stephen C It may happen that the two input integers are of order O(N) and their LCM is of order O(N). In the original approach the intermediate result is of order O(N^2), while in the modified one it's only O(N). Example: p = 2^31 - 1 = 2147483647, m = 2*p, n = 3*p. Their LCM = 6*p, these are not very large numbers (`long` can represent integers up to 2^63 - 1 = 9223372036854775807), but the original approach will overflow anyway (the intermediate value is 6*p*p). A simple reordering can greatly improve the algorithm's applicability, regardless of the type (`short`, `int`, or `long`).
– Bolo
Commented Jul 1, 2010 at 9:55

Remember The least common multiple is the least whole number that is a multiple of each of two or more numbers.

If you are trying to figure out the LCM of three integers, follow these steps:

``````  **Find the LCM of 19, 21, and 42.**
``````

Write the prime factorization for each number. 19 is a prime number. You do not need to factor 19.

``````21 = 3 × 7
42 = 2 × 3 × 7
19
``````

Repeat each prime factor the greatest number of times it appears in any of the prime factorizations above.

2 × 3 × 7 × 19 = 798

The least common multiple of 21, 42, and 19 is 798.

Best solution in C++ below without overflowing

``````#include <iostream>
#include <tuple>

long long gcd(long long a, long long b) {
while (b != 0)
std::tie(a, b) = std::make_tuple(b, a % b);
return a;
}

long long lcm(long long a, long long b) {
if (a > b)
return (a / gcd(a, b)) * b;
else
return (b / gcd(a, b)) * a;
}

int main() {
long long a, b;
std::cin >> a >> b;
std::cout << lcm(a, b) << std::endl;
return 0;
}
``````
• This may avoid overflow more often than a more naïve solution, but avoiding it entirely is not possible with fixed-width, homogeneous types. `lcm(std::numeric_limits<long long>::max(), std::numeric_limits<long long>::max() - 1)` will overflow and there is little you can do about it. Commented Apr 1 at 15:13

I think that the approach of "reduction by the greatest common divider" should be faster. Start by calculating the GCD (e.g. using Euclid's algorithm), then divide the product of the two numbers by the GCD.

I don't know whether it is optimized or not, but probably the easiest one:

``````public void lcm(int a, int b)
{
if (a > b)
{
min = b;
max = a;
}
else
{
min = a;
max = b;
}
for (i = 1; i < max; i++)
{
if ((min*i)%max == 0)
{
res = min*i;
break;
}
}
Console.Write("{0}", res);
}
``````

Extending @John D. Cook answer that is also marked answer for this question. ( https://stackoverflow.com/a/3154503/13272795), I am sharing algorithm to find LCM of n numbers, it maybe LCM of 2 numbers or any numbers. Source for this code is this

`````` int gcd(int a, int b)
{
if (b == 0)
return a;
return gcd(b, a % b);
}

// Returns LCM of array elements
ll findlcm(int arr[], int n)
{
// Initialize result
ll ans = arr[0];

// ans contains LCM of arr[0], ..arr[i]
// after i'th iteration,
for (int i = 1; i < n; i++)
ans = arr[i] * ans/gcd(arr[i], ans);
return ans;
}
``````
• This does not handle the case of LCM of no numbers, which is 1. Commented Apr 1 at 10:53

Take successive multiples of the larger of the two numbers until the result is a multiple of the smaller.

this might work..

``````   public int LCM(int x, int y)
{
int larger  = x>y? x: y,
smaller = x>y? y: x,
candidate = larger ;
while (candidate % smaller  != 0) candidate += larger ;
return candidate;
}
``````
• This will work okay for small values of x and y, it will have difficulty scaling. Commented Jul 1, 2010 at 3:12
• Dude, this helped in a challenge where Euclid algorithm caused stack-overflow. I guess to scale it up u just treat them as string and have functions for modulo and addition? Commented Apr 14, 2018 at 20:41

Here is a highly efficient approach to find the LCM of two numbers in python.

``````def gcd(a, b):
if min(a, b) == 0:
return max(a, b)
a_1 = max(a, b) % min(a, b)
return gcd(a_1, min(a, b))

def lcm(a, b):
return (a * b) // gcd(a, b)
``````

Using Euclidean algorithm to find gcd and then calculating the lcm dividing a by the product of gcd and b worked for me.

``````int euclidgcd(int a, int b){
if(b==0)
return a;
int a_rem = a % b;
return euclidgcd(b, a_rem);
}

long long lcm(int a, int b) {
int gcd=euclidgcd(a, b);
return (a/gcd*b);
}

int main() {
int a, b;
std::cin >> a >> b;
std::cout << lcm(a, b) << std::endl;
return 0;
}
``````

C++ template. Compile time

``````#include <iostream>

const int lhs = 8, rhs = 12;

template<int n, int mod_lhs=n % lhs, int mod_rhs=n % rhs> struct calc {
calc() { }
};

template<int n> struct calc<n, 0, 0> {
calc() { std::cout << n << std::endl; }
};

template<int n, int mod_rhs> struct calc<n, 0, mod_rhs> {
calc() { }
};

template<int n, int mod_lhs> struct calc <n, mod_lhs, 0> {
calc() { }
};

template<int n> struct lcm {
lcm() {
lcm<n-1>();
calc<n>();
}
};

template<> struct lcm<0> {
lcm() {}
};

int main() {
lcm<lhs * rhs>();
}
``````

Product of 2 numbers is equal to LCM * GCD or HCF. So best way to find LCM is to find GCD and divide the product with GCD. That is, LCM(a,b) = (a*b)/GCD(a,b).

• GDC? Did you mean GCD?
– Pang
Commented Jan 5, 2018 at 8:25
• Sounds like a repeat of the existing answers anyway.
– Pang
Commented Jan 5, 2018 at 8:28

First of all, you have to find the greatest common divisor

``````for(int i=1; i<=a && i<=b; i++) {

if (i % a == 0 && i % b == 0)
{
gcd = i;
}

}
``````

After that, using the GCD you can easily find the least common multiple like this

``````lcm = a / gcd * b;
``````
• Would it be faster to start iterating from the lower of the two numbers down to zero? This way, you can avoid having to iterate through the whole set. Something like `for (int i = a; i >= 0; i--)` and then if that if statement returns true, you can break out of the loop. Commented Apr 1, 2020 at 12:55
• This answer is O(min(a, b)) where the Euclidean algorithm in other answers is O(log(min(a, b)). So since the question asked for the most efficient method this answer is wrong. Commented Dec 8, 2023 at 10:30

## There is no way more efficient than using a built-in function!

As of Python 3.8 `lcm()` function has been added in math library. And can be called with folowing signature:

``````math.lcm(*integers)
``````

Returns the least common multiple of the specified integer arguments. If all arguments are nonzero, then the returned value is the smallest positive integer that is a multiple of all arguments. If any of the arguments is zero, then the returned value is 0. lcm() without arguments returns 1.

Since we know the mathematic property which states that "product of LCM and HCF of any two numbers is equal to the product of the two numbers".

lets say X and Y are two integers, then X * Y = HCF(X, Y) * LCM(X, Y)

Now we can find LCM by knowing the HCF, which we can find through Euclidean Algorithm.

``````  LCM(X, Y) = (X * Y) / HCF(X, Y)
``````

Hope this will be efficient.

``````import java.util.*;
public class Hello {
public static int HCF(int X, int Y){
if(X == 0)return Y;
return HCF(Y%X, X);
}
public static void main(String[] args) {
Scanner scanner = new Scanner(System.in);
int X = scanner.nextInt(), Y = scanner.nextInt();
System.out.print((X * Y) / HCF(X, Y));
}
}
``````

Yes, there are numerous way to calculate LCM such as using GCD (HCF). You can apply prime decomposition such as (optimized/naive) Sieve Eratosthenes or find factor of prime number to compute GCD, which is way more faster than calculate LCM directly. Then as all said above, LCM(X, Y) = (X * Y) / GCD(X, Y)

I googled the same question, and found this Stackoverflow page, however I come up with another simple solution using python

``````def find_lcm(numbers):
h = max(numbers)

lcm = h

def check(l, numbers):
remainders = [ l%n==0 for n in numbers]
return all(remainders)

while (check(lcm, numbers) == False):
lcm = lcm + h

return lcm

``````

for `numbers = [120,150,135,225]` it will return `5400`

``````numbers = [120,150,135,225]

print(find_lcm(numbers)) # will print 5400
``````

Euclidean GCD code snippet

``````int findGCD(int a, int b) {
if(a < 0 || b < 0)
return -1;

if (a == 0)
return b;
else if (b == 0)
return a;
else
return findGCD(b, a % b);
}
``````
• OP is looking for LCM Commented Dec 14, 2018 at 19:15