8

This program is for count number of partitions of a set with n elements into k subsets I am confusing here return k*countP(n-1, k) + countP(n-1, k-1); can some one explain what is happening here? why we are multiplying with k?

NOTE->I know this is not the best way to calculate number of partitions that would be DP

// A C++ program to count number of partitions 
// of a set with n elements into k subsets 
#include<iostream> 
using namespace std; 

// Returns count of different partitions of n 
// elements in k subsets 
int countP(int n, int k) 
{ 
    // Base cases 
    if (n == 0 || k == 0 || k > n) 
        return 0; 
    if (k == 1 || k == n) 
        return 1; 

    // S(n+1, k) = k*S(n, k) + S(n, k-1) 
    return k*countP(n-1, k) + countP(n-1, k-1); 
} 

// Driver program 
int main() 
{ 
    cout << countP(3, 2); 
    return 0; 
} 
4

What you mentioned is the Stirling numbers of the second kind which enumerates the number of ways to partition a set of n objects into k non-empty subsets and denoted by enter image description here or enter image description here.

Its recursive relation is:

enter image description here

for k > 0 with initial conditions:

enter image description here

.

Calculating it using dynamic programming is more faster than recursive approach:

int secondKindStirlingNumber(int n, int k) {

    int sf[n + 1][n + 1];
    for (int i = 0; i < k; i++) {
        sf[i][i] = 1;
    }
    for (int i = 1; i < n + 1; i++) {
        for (int j = 1; j < k + 1; j++) {
            sf[i][j] = j * sf[i - 1][j] + sf[i - 1][j - 1];
        }
    }
    return sf[n][k];
}
3

Each countP call implicitly considers a single element in the set, lets call it A.

The countP(n-1, k-1) term comes from the case where A is in a set by itself. In this case, we just have to count how many ways there are to partition all the other elements (N-1) into (K-1) subsets, since A takes up one subset by itself.

The k*countP(n-1, k) term, then, comes from the case where A is not in a set by itself. So we figure out the number of ways of partitioning all the other (N-1) values into K subsets, and multiply by K because there are K possible subsets we could add A to.

For example, consider the set [A,B,C,D], with K=2.

The first case, countP(n-1, k-1), describes the following situation:

{A, BCD}

The second case, k*countP(n-1, k), describes the following cases:

2*({BC,D}, {BD,C}, {B,CD}) 

Or:

{ABC,D}, {ABD,C}, {AB,CD}, {BC,AD}, {BD,AC}, {B,ACD}
2

Based on This a partition of a set is a grouping of the set's elements into non-empty subsets, in such a way that every element is included in one and only one of the subsets. So the total number of partitions of an n-element set is the Bell number which is calculated like below: Bell number formula Hence if you want to convert the formula to a recursive function it will be like: k*countP(n-1,k) + countP(n-1, k-1);

2

How do we get countP(n,k)? Assuming that we have devided previous n-1 element into a certain number of partions, and now we have the n-th element, and we try to make k partition.

we have two option for this:

either

  1. we have devided the previous n-1 elements into k partions(we have countP(n-1, k) ways of doing this), and we put this n-th element into one of these partions(we have k choices). So we have k*countP(n-1, k).

or:

  1. we divide previous n-1 elements into k-1 partition(we have countP(n-1, k-1); ways of doing this), and we make the n-th element a single partion to achieve a k partition(we only have 1 choice: putting it seperately). So we have countP(n-1, k-1);.

So we sum them up and get the result.

  • Great explanation, finally got it :-) – Siyon DP Dec 16 '18 at 9:12

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