56

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 );

10 Answers 10

113

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.

  • 70
    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 Jul 1 '10 at 1:41
  • 5
    @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. – Stephen C Jul 1 '10 at 1:47
  • 11
    @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. – starblue Jul 1 '10 at 4:39
  • 2
    @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. – Stephen C Jul 1 '10 at 5:29
  • 5
    @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 Jul 1 '10 at 9:55
5

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.

3

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.

1

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);
}
1

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

for(int = 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;
1

Best solution in C++ below without overflowing

#include <iostream>
using namespace std; 
long long gcd(long long int a, long long int b){        
    if(b==0)
        return a;
    return gcd(b,a%b);
}

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 int a ,b ;
    cin>>a>>b;
    cout<<lcm(a,b)<<endl;        
    return 0;
}
0

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. – andand Jul 1 '10 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? – Shivam Chawla Apr 14 '18 at 20:41
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>();
}
0

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 – Munim Munna Dec 14 '18 at 19:15
-1

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 Jan 5 '18 at 8:25
  • 1
    Sounds like a repeat of the existing answers anyway. – Pang Jan 5 '18 at 8:28

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