A mother vertex in a Graph G = (V, E) is a vertex v such that a path from v can reach all other vertices in G by a path from v.
Example:
Input:
Output:
5
Approach:
We can solve this problem using Depth First Search approach. To further optimize our approach, we will use an efficient solution.
The below solution is also using Depth First Search to solve this problem, but it executes Depth First Search Cycle only once, and as soon as it finds the mother vertex, it stops the execution.
- While executing the Depth First Search, we have a Bitmask Array representing a bitmask for each vertex. This Bitmask Array is passed to all vertices during execution.
- Each vertex modifies their dedicated bitmask in such a way the all set bits representing the vertices can be visited from this vertex, including the current vertex.
- At each iteration, we check if all the vertices can be visited from this vertex by checking the current vertex bitmask value (If bits representing to all vertices are set). If all vertices can be visited from this vertex, then it breaks the execution and finds the mother vertex as the current vertex.
- If Vertex-2 has been visited from Vertex-1, and Vertex-2 has already been visited earlier, then the Vertex-1 updates it’s bitmask by doing OR operation with the Vertex-2 bitmask.
Time complexity: O(V+E)
How does the above idea work?
Let this approach support a graph having a maximum of 32 vertices. This method can be augmented to support more number of vertices as well, but here it is dealt with a maximum of 32 vertices.
-
A bitmask array of 32 bit-masks is created. The 0th index of array denotes the Bitmask for Vertex-0, while the 1st index of the array denotes the Bitmask for Vertex-1, and so on.
- All the vertices of the graph are visited using the Depth First Search algorithm, and the same bitmask array is passed to all vertices. The Bitmask values are set accordingly to represent all vertices that could be visited from this vertex.
- Bit Index is set corresponding to the neighbour vertices, including own bit index. Neighbour vertices will also repeat the same for their bitmask and return the same to Vertex-1.
- Vertex-1 will keep on performing the OR operation on the return value of all neighbours to its bitmask to represent all the vertices that could be visited from vertex-1.
- Do note that if the Vertex-2 is a neighbour of the Vertex-1, and it is already visited from another neighbour vertex, then it will not visit its neighbour’s vertex again and returns its bitmask to the first Node.
- Each iteration will check if bitmask corresponding to current vertex has all bits set to 1. If all bits are set to 1 for current vertex means, it means all vertices can be visited from the current vertex, and the current vertex is the mother vertex of the graph.
Below is the implementation of our above approach:
#include<bits/stdc++.h> using namespace std;
void PrintGraph(vector<vector< int >> adj)
{ int n=( int )adj.size();
for ( int i=0;i<n;i++)
{
for ( auto x:adj[i])
{
cout << "There is an edge from " << i << " to " << x << '\n' ;
}
}
} bool IsEdge(vector<vector< int >> adj, int src, int dest)
{ for ( auto x:adj[src])
{
if (x==dest)
return true ;
}
return false ;
} int MotherVertexUtil(
vector<vector< int >> adj, int index,
vector< int > mask, int * m_vertex)
{ int n=( int )adj.size();
// If mother vertex is already found
// then simply return with existing
// mask of the vertex index
if (*m_vertex != -1) {
return mask[index];
}
// if this vertex is already visited,
// return the bit-mask
// value of this vertex.
if (mask[index] != 0) {
return mask[index];
}
int tmpmask = 0;
// Set the bit corresponding
// to vertex index in tmpmask
tmpmask |= (1 << index);
for ( int i = 0; i < n; i++) {
if ((index != i)
&& IsEdge(adj, index, i)) {
// Set bits corresponding to all
// vertex which can be visited
// by this vertex by ORing
// the return value by util function
// Vertex is not visited
if (mask[i] == 0) {
int retmask
= MotherVertexUtil(
adj, i, mask, m_vertex);
tmpmask |= retmask;
}
// Vertex is already visited
else {
tmpmask |= mask[i];
}
// Check if current vertex is
// mother vertex or mother vertex
// is already found
if (tmpmask == ( pow (2, n) - 1)) {
// If all bits of a mask is set
// it means current vertex
// is mother vertex
if (*m_vertex == -1) {
*m_vertex = index;
}
return tmpmask;
}
}
}
// populate tmpmask as final
// bit mask of the vertex
mask[index] |= tmpmask;
return mask[index];
} int MotherVertex(vector<vector< int >> adj)
{ int n=adj.size();
vector< int > mask(n);
// Initially bit mask
// for all vertex will be 0
for ( int i=0;i<n;i++)
mask[i]=0;
// DFS traversal is used to check
// for the mother vertex
// All set bits (of bitmask of a vertex)
// represent the current vertex index
// and index of vertices which could be
// visited from the current vertex.
/* Example:
If a vertex index is 3
then and vertex 5, 7 and 10
can be visited from this vertex
then final bit mask of this vertex
would be
00000000000000000000010010101000
(bits 3, 5, 7 and 10 are set) */
// tmpmask is used to store
// the final bitmask of the vertex.
int tmpmask = 0;
// flag to check if
// mother vertex is found
int m_vertex = -1;
for ( int index = 0; index < n; index++) {
// set the bit corresponding
// to vertex index in tmpmask
tmpmask = (1 << index);
// mask for a vertex is 0
// means it has not yet
// visited so visit this vertex
if (mask[index] == 0) {
int retmask= MotherVertexUtil(adj, index,mask, &m_vertex);
// set bits corresponding to all
// vertices which can be visited
// from this vertex by ORing
// the return value by util function
tmpmask |= retmask;
}
// check if current vertex is
// mother vertex or mother vertex
// is already found
// If all bits of a mask is set
// it means current vertex
// is mother vertex
if (tmpmask == ( pow (2, n) - 1)) {
// current vertex is mother vertex
if (m_vertex == -1) {
m_vertex = index;
}
break ;
}
// populate tmpmask as final bit
// mask of the vertex
mask[index] |= tmpmask;
}
return m_vertex;
} int main()
{ int n;
n = 7;
vector<vector< int >> adj(n);
adj[0].push_back(2);
adj[0].push_back(1);
adj[1].push_back(3);
adj[4].push_back(1);
adj[5].push_back(2);
adj[5].push_back(6);
adj[6].push_back(0);
adj[6].push_back(4);
PrintGraph(adj);
int m_vertex = MotherVertex(adj);
if ( m_vertex == -1)
{
cout << "Mother vertex is not existing in this graph\n" ;
}
else
{
cout << "Mother vertex is: " << m_vertex << '\n' ;
}
return 0;
} |
// Java code for above implementation import java.util.*;
public class Main {
public static void main(String[] args)
{
int n = 7 ;
ArrayList<ArrayList<Integer> > adj
= new ArrayList<>();
for ( int i = 0 ; i < n; i++) {
adj.add( new ArrayList<>());
}
adj.get( 0 ).add( 2 );
adj.get( 0 ).add( 1 );
adj.get( 1 ).add( 3 );
adj.get( 4 ).add( 1 );
adj.get( 5 ).add( 2 );
adj.get( 5 ).add( 6 );
adj.get( 6 ).add( 0 );
adj.get( 6 ).add( 4 );
PrintGraph(adj);
int m_vertex = MotherVertex(adj);
if (m_vertex == - 1 ) {
System.out.println(
"Mother vertex is not existing in this graph" );
}
else {
System.out.println( "Mother vertex is: "
+ m_vertex);
}
}
public static void
PrintGraph(ArrayList<ArrayList<Integer> > adj)
{
int n = adj.size();
for ( int i = 0 ; i < n; i++) {
for ( int x : adj.get(i)) {
System.out.println( "There is an edge from "
+ i + " to " + x);
}
}
}
public static boolean
IsEdge(ArrayList<ArrayList<Integer> > adj, int src,
int dest)
{
for ( int x : adj.get(src)) {
if (x == dest)
return true ;
}
return false ;
}
public static int
MotherVertexUtil(ArrayList<ArrayList<Integer> > adj,
int index, int [] mask, int m_vertex)
{
int n = adj.size();
// If mother vertex is already found
// then simply return with existing
// mask of the vertex index
if (m_vertex != - 1 ) {
return mask[index];
}
// if this vertex is already visited,
// return the bit-mask
// value of this vertex.
if (mask[index] != 0 ) {
return mask[index];
}
int tmpmask = 0 ;
// Set the bit corresponding
// to vertex index in tmpmask
tmpmask |= ( 1 << index);
for ( int i = 0 ; i < n; i++) {
if ((index != i) && IsEdge(adj, index, i)) {
// Set bits corresponding to all
// vertex which can be visited
// by this vertex by ORing
// the return value by util function
// Vertex is not visited
if (mask[i] == 0 ) {
int retmask = MotherVertexUtil(
adj, i, mask, m_vertex);
tmpmask |= retmask;
}
// Vertex is already visited
else {
tmpmask |= mask[i];
}
// Check if current vertex is
// mother vertex or mother vertex
// is already found
if (tmpmask == (Math.pow( 2 , n) - 1 )) {
// If all bits of a mask is set
// it means current vertex
// is mother vertex
if (m_vertex == - 1 ) {
m_vertex = index;
}
return tmpmask;
}
}
}
// populate tmpmask as final
// bit mask of the vertex
mask[index] |= tmpmask;
return mask[index];
}
public static int
MotherVertex(ArrayList<ArrayList<Integer> > adj)
{
int n = adj.size();
int [] mask = new int [n];
// Initially bit mask
// for all vertex will be 0
for ( int i = 0 ; i < n; i++)
mask[i] = 0 ;
// DFS traversal is used to check
// for the mother vertex
// All set bits (of bitmask of a vertex)
// represent the current vertex index
// and index of vertices which could be
// visited from the current vertex.
/* Example:
If a vertex index is 3
then and vertex 5, 7 and 10
can be visited from this vertex
then final bit mask of this vertex
would be
00000000000000000000010010101000
(bits 3, 5, 7 and 10 are set) */
// tmpmask is used to store
// the final bitmask of the vertex.
int tmpmask = 0 ;
// flag to check if
// mother vertex is found
int m_vertex = - 1 ;
for ( int index = 0 ; index < n; index++) {
// set the bit corresponding
// to vertex index in tmpmask
tmpmask = ( 1 << index);
// mask for a vertex is 0
// means it has not yet
// visited so visit this vertex
if (mask[index] == 0 ) {
int retmask = MotherVertexUtil(
adj, index, mask, m_vertex);
// set bits corresponding to all
// vertices which can be visited
// from this vertex by ORing
// the return value by util function
tmpmask |= retmask;
}
// check if current vertex is
// mother vertex or mother vertex
// is already found
// If all bits of a mask is set
// it means current vertex
// is mother vertex
if (tmpmask == (Math.pow( 2 , n) - 1 )) {
// current vertex is mother vertex
if (m_vertex == - 1 ) {
m_vertex = index;
}
break ;
}
// populate tmpmask as final bit
// mask of the vertex
mask[index] |= tmpmask;
}
return m_vertex;
}
} // This code is contributed by Tapesh (tapeshdua420) |
def PrintGraph(adj):
n = len (adj)
for i in range (n):
for x in adj[i]:
print ( "There is an edge from {} to {}" . format (i, x))
def IsEdge(adj, src, dest):
for x in adj[src]:
if (x = = dest):
return True
return False
def MotherVertexUtil(adj, index, mask, m_vertex):
n = len (adj)
# If mother vertex is already found
# then simply return with existing
# mask of the vertex index
if (m_vertex[ 0 ] ! = - 1 ):
return mask[index]
# if this vertex is already visited,
# return the bit-mask
# value of this vertex.
if (mask[index] ! = 0 ):
return mask[index]
tmpmask = 0
# Set the bit corresponding
# to vertex index in tmpmask
tmpmask | = ( 1 << index)
for i in range (n):
if ((index ! = i) and IsEdge(adj, index, i)):
# Set bits corresponding to all
# vertex which can be visite
# by this vertex by ORing
# the return value by util function
# Vertex is not visited
if (mask[i] = = 0 ):
retmask = MotherVertexUtil(adj, i, mask, m_vertex)
tmpmask | = retmask
# Vertex is already visited
else :
tmpmask | = mask[i]
# Check if current vertex is
# mother vertex or mother vertex
# is already found
if (tmpmask = = ( pow ( 2 , n) - 1 )):
# If all bits of a mask is set
# it means current vertex
# is mother vertex
if (m_vertex[ 0 ] = = - 1 ):
m_vertex[ 0 ] = index
return tmpmask
# populate tmpmask as final
# bit mask of the vertex
mask[index] | = tmpmask
return mask[index]
def MotherVertex(adj):
n = len (adj)
mask = [ 0 ] * n
# Initially bit mask
# for all vertex will be 0
for i in range (n):
mask[i] = 0
# DFS traversal is used to check
# for the mother vertex
# All set bits (of bitmask of a vertex)
# represent the current vertex index
# and index of vertices which could be
# visited from the current vertex.
# Example:
# If a vertex index is 3
# then and vertex 5, 7 and 10
# can be visited from this vertex
# then final bit mask of this vertex
# would be
# 00000000000000000000010010101000
# (bits 3, 5, 7 and 10 are set)
# tmpmask is used to store
# the final bitmask of the vertex.
tmpmask = 0
# flag to check if
# mother vertex is found
m_vertex = [ - 1 , ]
for index in range (n):
# set the bit corresponding
# to vertex index in tmpmask
tmpmask = ( 1 << index)
# mask for a vertex is 0
# means it has not yet
# visited so visit this vertex
if (mask[index] = = 0 ):
retmask = MotherVertexUtil(adj, index, mask, m_vertex)
# set bits corresponding to all
# vertices which can be visited
# from this vertex by ORing
# the return value by util function
tmpmask | = retmask
# check if current vertex is
# mother vertex or mother vertex
# is already found
# If all bits of a mask is set
# it means current vertex
# is mother vertex
if (tmpmask = = ( pow ( 2 , n) - 1 )):
# current vertex is mother vertex
if (m_vertex[ 0 ] = = - 1 ):
m_vertex[ 0 ] = index
break
# populate tmpmask as final bit
# mask of the vertex
mask[index] | = tmpmask
return m_vertex[ 0 ]
if __name__ = = '__main__' :
n = 7
adj = [[] for _ in range (n)]
adj[ 0 ].append( 2 )
adj[ 0 ].append( 1 )
adj[ 1 ].append( 3 )
adj[ 4 ].append( 1 )
adj[ 5 ].append( 2 )
adj[ 5 ].append( 6 )
adj[ 6 ].append( 0 )
adj[ 6 ].append( 4 )
PrintGraph(adj)
m_vertex = MotherVertex(adj)
if (m_vertex = = - 1 ):
print ( "Mother vertex is not existing in this graph" )
else :
print ( "Mother vertex is:" , m_vertex)
|
// C# code for above implementation using System;
using System.Collections.Generic;
using System.Linq;
class Program {
public static void Main( string [] args)
{
int n = 7;
List<List< int > > adj = new List<List< int > >();
for ( int i = 0; i < n; i++) {
adj.Add( new List< int >());
}
adj[0].Add(2);
adj[0].Add(1);
adj[1].Add(3);
adj[4].Add(1);
adj[5].Add(2);
adj[5].Add(6);
adj[6].Add(0);
adj[6].Add(4);
PrintGraph(adj);
int m_vertex = MotherVertex(adj);
if (m_vertex == -1) {
Console.WriteLine(
"Mother vertex is not existing in this graph" );
}
else {
Console.WriteLine( "Mother vertex is: "
+ m_vertex);
}
}
public static void PrintGraph(List<List< int > > adj)
{
int n = adj.Count();
for ( int i = 0; i < n; i++) {
foreach ( var x in adj[i])
{
Console.WriteLine( "There is an edge from "
+ i + " to " + x);
}
}
}
public static bool IsEdge(List<List< int > > adj, int src,
int dest)
{
foreach ( var x in adj[src])
{
if (x == dest)
return true ;
}
return false ;
}
public static int MotherVertexUtil(List<List< int > > adj,
int index,
int [] mask,
int m_vertex)
{
int n = adj.Count();
// If mother vertex is already found
// then simply return with existing
// mask of the vertex index
if (m_vertex != -1)
return mask[index];
// if this vertex is already visited,
// return the bit-mask
// value of this vertex.
if (mask[index] != 0)
return mask[index];
int tmpmask = 0;
// Set the bit corresponding
// to vertex index in tmpmask
tmpmask |= (1 << index);
for ( int i = 0; i < n; i++) {
if ((index != i) && IsEdge(adj, index, i)) {
// Set bits corresponding to all
// vertex which can be visited
// by this vertex by ORing
// the return value by util function
// Vertex is not visited
if (mask[i] == 0) {
int retmask = MotherVertexUtil(
adj, i, mask, m_vertex);
tmpmask |= retmask;
}
// Vertex is already visited
else {
tmpmask |= mask[i];
}
// Check if current vertex is
// mother vertex or mother vertex
// is already found
if (tmpmask == Math.Pow((2), n) - 1) {
// If all bits of a mask is set
// it means current vertex
// is mother vertex
if (m_vertex == -1) {
m_vertex = index;
}
return tmpmask;
}
}
}
// populate tmpmask as final
// bit mask of the vertex
mask[index] |= tmpmask;
return mask[index];
}
public static int MotherVertex(List<List< int > > adj)
{
int n = adj.Count();
int [] mask = new int [n];
// Initially bit mask
// for all vertex will be 0
for ( int i = 0; i < n; i++) {
mask[i] = 0;
}
// DFS traversal is used to check
// for the mother vertex
// All set bits (of bitmask of a vertex)
// represent the current vertex index
// and index of vertices which could be
// visited from the current vertex.
/* Example:
If a vertex index is 3
then and vertex 5, 7 and 10
can be visited from this vertex
then final bit mask of this vertex
would be
00000000000000000000010010101000
(bits 3, 5, 7 and 10 are set) */
// tmpmask is used to store
// the final bitmask of the vertex.
int tmpmask = 0;
// flag to check if
// mother vertex is found
int m_vertex = -1;
for ( int index = 0; index < n; index++) {
// set the bit corresponding
// to vertex index in tmpmask
tmpmask = 1 << index;
// mask for a vertex is 0
// means it has not yet
// visited so visit this vertex
if (mask[index] == 0) {
int retmask = MotherVertexUtil(
adj, index, mask, m_vertex);
// set bits corresponding to all
// vertices which can be visited
// from this vertex by ORing
// the return value by util function
tmpmask |= retmask;
}
// check if current vertex is
// mother vertex or mother vertex
// is already found
// If all bits of a mask is set
// it means current vertex
// is mother vertex
if (tmpmask == Math.Pow((2), n) - 1)
{
// current vertex is mother vertex
if (m_vertex == -1) {
m_vertex = index;
}
break ;
}
// populate tmpmask as final bit
// mask of the vertex
mask[index] |= tmpmask;
}
return m_vertex;
}
} // This code is contributed by Tapesh (tapeshdua420) |
function PrintGraph(adj) {
let n = adj.length;
for (let i = 0; i < n; i++) {
for (let x of adj[i]) {
console.log(`There is an edge from ${i} to ${x}`);
}
}
} function IsEdge(adj, src, dest) {
for (let x of adj[src]) {
if (x === dest) {
return true ;
}
}
return false ;
} function MotherVertexUtil(adj, index, mask, m_vertex) {
let n = adj.length;
// If mother vertex is already found
// then simply return with existing
// mask of the vertex index
if (m_vertex[0] !== -1) {
return mask[index];
}
// if this vertex is already visited,
// return the bit-mask
// value of this vertex.
if (mask[index] !== 0) {
return mask[index];
}
let tmpmask = 0;
// Set the bit corresponding
// to vertex index in tmpmask
tmpmask |= (1 << index);
for (let i = 0; i < n; i++) {
// Set bits corresponding to all
// vertex which can be visited
// by this vertex by ORing
// the return value by util function
if (index !== i && IsEdge(adj, index, i)) {
// Vertex is not visited
if (mask[i] === 0) {
let retmask = MotherVertexUtil(adj, i, mask, m_vertex);
tmpmask |= retmask;
} // Vertex is already visited
else {
tmpmask |= mask[i];
}
// Check if current vertex is
// mother vertex or mother vertex
// is already found
if (tmpmask === (2 ** n - 1)) {
// If all bits of a mask is set
// it means current vertex
// is mother vertex
if (m_vertex[0] === -1) {
m_vertex[0] = index;
}
return tmpmask;
}
}
}
mask[index] |= tmpmask;
return mask[index];
} function MotherVertex(adj) {
let n = adj.length;
let mask = Array(n).fill(0);
// Initially bit mask
// for all vertex will be 0
for (let i = 0; i < n; i++) {
mask[i] = 0;
}
// DFS traversal is used to check
// for the mother vertex
// All set bits (of bitmask of a vertex)
// represent the current vertex index
// and index of vertices which could be
// visited from the current vertex.
/* Example:
If a vertex index is 3
then and vertex 5, 7 and 10
can be visited from this vertex
then final bit mask of this vertex
would be
00000000000000000000010010101000
(bits 3, 5, 7 and 10 are set) */
// tmpmask is used to store
// the final bitmask of the vertex.
let tmpmask = 0;
// flag to check if
// mother vertex is found
let m_vertex = [-1];
for (let index = 0; index < n; index++) {
// set the bit corresponding
// to vertex index in tmpmask
tmpmask = (1 << index);
// mask for a vertex is 0
// means it has not yet
// visited so visit this vertex
if (mask[index] === 0) {
let retmask = MotherVertexUtil(adj, index, mask, m_vertex);
// set bits corresponding to all
// vertices which can be visited
// from this vertex by ORing
// the return value by util function
tmpmask |= retmask;
}
// check if current vertex is
// mother vertex or mother vertex
// is already found
// If all bits of a mask is set
// it means current vertex
// is mother vertex
if (tmpmask === (2 ** n - 1)) {
// current vertex is mother vertex
if (m_vertex[0] === -1) {
m_vertex[0] = index;
}
break ;
}
// populate tmpmask as final bit
// mask of the vertex
mask[index] |= tmpmask;
}
return m_vertex[0];
} let n = 7; let adj = Array(n).fill().map(() => []); adj[0].push(2, 1); adj[1].push(3); adj[4].push(1); adj[5].push(2, 6); adj[6].push(0, 4); PrintGraph(adj); let m_vertex = MotherVertex(adj) if (m_vertex === -1)
console.log( "Mother vertex is not existing in this graph" );
else console.log( "Mother vertex is:" , m_vertex)
|
There is an edge from 0 to 2 There is an edge from 0 to 1 There is an edge from 1 to 3 There is an edge from 4 to 1 There is an edge from 5 to 2 There is an edge from 5 to 6 There is an edge from 6 to 0 There is an edge from 6 to 4 Mother vertex is: 5
Time Complexity: O(V ^ 2), where V is the total number of vertices in the graph.
Auxiliary Space: O(V)