The Luhn algorithm, also known as the modulus 10 or mod 10 algorithm, is a simple checksum formula used to validate a variety of identification numbers, such as credit card numbers, IMEI numbers, Canadian Social Insurance Numbers. The LUHN formula was created in the late 1960s by a group of mathematicians. Shortly thereafter, credit card companies adopted it. Because the algorithm is in the public domain, it can be used by anyone. Most credit cards and many government identification numbers use the algorithm as a simple method of distinguishing valid numbers from mistyped or otherwise incorrect numbers. It was designed to protect against accidental errors, not malicious attacks.

Steps involved in Luhn algorithm

Let’s understand the algorithm with an example:

Consider the example of an account number “79927398713“.

Step 1 – Starting from the rightmost digit double the value of every second digit,



Step 2 – If doubling of a number results in a two digits number i.e greater than 9(e.g., 6 × 2 = 12), then add the digits of the product (e.g., 12: 1 + 2 = 3, 15: 1 + 5 = 6), to get a single digit number.

Step 3 – Now take the sum of all the digits.

Step 4 – If the total modulo 10 is equal to 0 (if the total ends in zero) then the number is valid according to the Luhn formula; else it is not valid.





Since the sum is 70 which is a multiple of 10, therefore the account number is possibly valid.



The idea is simple, we traverse from end. For every second digit, we double it before adding. We add two digits of the number obtained after doubling.



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code #include <bits/stdc++.h> using namespace std; bool checkLuhn( const string& cardNo) { int nDigits = cardNo.length(); int nSum = 0, isSecond = false ; for ( int i = nDigits - 1; i >= 0; i--) { int d = cardNo[i] - '0' ; if (isSecond == true ) d = d * 2; nSum += d / 10; nSum += d % 10; isSecond = !isSecond; } return (nSum % 10 == 0); } int main() { string cardNo = "79927398713" ; if (checkLuhn(cardNo)) printf ( "This is a valid card" ); else printf ( "This is not a valid card" ); return 0; } chevron_right filter_none Java filter_none edit

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code import java.io.*; class GFG { static boolean checkLuhn(String cardNo) { int nDigits = cardNo.length(); int nSum = 0 ; boolean isSecond = false ; for ( int i = nDigits - 1 ; i >= 0 ; i--) { int d = cardNo.charAt(i) - '0' ; if (isSecond == true ) d = d * 2 ; nSum += d / 10 ; nSum += d % 10 ; isSecond = !isSecond; } return (nSum % 10 == 0 ); } static public void main (String[] args) { String cardNo = "79927398713" ; if (checkLuhn(cardNo)) System.out.println( "This is a valid card" ); else System.out.println( "This is not a valid card" ); } } chevron_right filter_none C# filter_none edit

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code using System; class GFG { static bool checkLuhn(String cardNo) { int nDigits = cardNo.Length; int nSum = 0; bool isSecond = false ; for ( int i = nDigits - 1; i >= 0; i--) { int d = cardNo[i] - '0' ; if (isSecond == true ) d = d * 2; nSum += d / 10; nSum += d % 10; isSecond = !isSecond; } return (nSum % 10 == 0); } static public void Main() { String cardNo = "79927398713" ; if (checkLuhn(cardNo)) Console.WriteLine( "This is a valid card" ); else Console.WriteLine( "This is not a valid card" ); } } chevron_right filter_none

This is not a valid card

Output:

The Luhn algorithm detects any single-digit error, as well as almost all transpositions of adjacent digits.



Source:

https://en.wikipedia.org/wiki/Luhn_algorithm

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