Union By Rank and Path Compression in Union-Find Algorithm
In the previous post, we introduced union find algorithm and used it to detect cycles in a graph. We used the following union() and find() operations for subsets.
C++
// Naive implementation of find int find( int parent[], int i) { if (parent[i] == -1) return i; return find(parent, parent[i]); } // Naive implementation of union() void Union( int parent[], int x, int y) { int xset = find(parent, x); int yset = find(parent, y); parent[xset] = yset; } |
Java
// Naive implementation of find static int find( int parent[], int i) { if (parent[i] == - 1 ) return i; return find(parent, parent[i]); } // Naive implementation of union() static void Union( int parent[], int x, int y) { int xset = find(parent, x); int yset = find(parent, y); parent[xset] = yset; } // This code is contributed by divyesh072019 |
Python3
# Naive implementation of find def find(parent, i): if (parent[i] = = - 1 ): return i return find(parent, parent[i]) # Naive implementation of union() def Union(parent, x, y): xset = find(parent, x) yset = find(parent, y) parent[xset] = yset # This code is contributed by rutvik_56 |
C#
// Naive implementation of find static int find( int []parent, int i) { if (parent[i] == -1) return i; return find(parent, parent[i]); } // Naive implementation of union() static void Union( int []parent, int x, int y) { int xset = find(parent, x); int yset = find(parent, y); parent[xset] = yset; } // This code is contributed by pratham76 |
Javascript
<script> // Naive implementation of find function find(parent, i) { if (parent[i] == -1) return i; return find(parent, parent[i]); } // Naive implementation of union() function Union(parent, x, y) { let xset = find(parent, x); let yset = find(parent, y); parent[xset] = yset; } <script> |
The above union() and find() are naive and the worst case time complexity is linear. The trees created to represent subsets can be skewed and can become like a linked list. Following is an example worst case scenario.
Let there be 4 elements 0, 1, 2, 3 Initially, all elements are single element subsets. 0 1 2 3 Do Union(0, 1) 1 2 3 / 0 Do Union(1, 2) 2 3 / 1 / 0 Do Union(2, 3) 3 / 2 / 1 / 0
The above operations can be optimized to O(Log n) in the worst case. The idea is to always attach a smaller depth tree under the root of the deeper tree. This technique is called union by rank. The term rank is preferred instead of height because if the path compression technique (we have discussed it below) is used, then the rank is not always equal to height. Also, the size (in place of height) of trees can also be used as rank. Using size as rank also yields worst-case time complexity as O(Logn).
Let us see the above example with union by rank Initially, all elements are single element subsets. 0 1 2 3 Do Union(0, 1) 1 2 3 / 0 Do Union(1, 2) 1 3 / \ 0 2 Do Union(2, 3) 1 / | \ 0 2 3
The second optimization to naive method is Path Compression. The idea is to flatten the tree when find() is called. When find() is called for an element x, root of the tree is returned. The find() operation traverses up from x to find root. The idea of path compression is to make the found root as parent of x so that we don’t have to traverse all intermediate nodes again. If x is root of a subtree, then path (to root) from all nodes under x also compresses.
Let the subset {0, 1, .. 9} be represented as below and find() is called for element 3. 9 / | \ 4 5 6 / / \ 0 7 8 / 3 / \ 1 2 When find() is called for 3, we traverse up and find 9 as representative of this subset. With path compression, we also make 3 and 0 as the child of 9 so that when find() is called next time for 0, 1, 2 or 3, the path to root is reduced. --------9------- / / / \ \ 0 4 5 6 3 / \ / \ 7 8 1 2
The two techniques -path compression with the union by rank/size, the time complexity will reach nearly constant time. It turns out, that the final amortized time complexity is O(α(n)), where α(n) is the inverse Ackermann function, which grows very steadily (it does not even exceed for n<10600 approximately).
Following is union by rank and path compression-based implementation to find a cycle in a graph.
C++
// A C++ program to detect cycle in a graph using union by // rank and path compression #include <bits/stdc++.h> using namespace std; // a structure to represent an edge in the graph struct Edge { int src, dest; }; // a structure to represent a graph struct Graph { // V-> Number of vertices, E-> Number of edges int V, E; // graph is represented as an array of edges struct Edge* edge; }; struct subset { int parent; int rank; }; // Creates a graph with V vertices and E edges struct Graph* createGraph( int V, int E) { struct Graph* graph = ( struct Graph*) malloc ( sizeof ( struct Graph)); graph->V = V; graph->E = E; graph->edge = ( struct Edge*) malloc (graph->E * sizeof ( struct Edge)); return graph; } // A utility function to find set of an element i // (uses path compression technique) int find( struct subset subsets[], int i) { // find root and make root as parent of i (path // compression) if (subsets[i].parent != i) subsets[i].parent = find(subsets, subsets[i].parent); return subsets[i].parent; } // A function that does union of two sets of x and y // (uses union by rank) void Union( struct subset subsets[], int xroot, int yroot) { // Attach smaller rank tree under root of high rank tree // (Union by Rank) if (subsets[xroot].rank < subsets[yroot].rank) subsets[xroot].parent = yroot; else if (subsets[xroot].rank > subsets[yroot].rank) subsets[yroot].parent = xroot; // If ranks are same, then make one as root and // increment its rank by one else { subsets[yroot].parent = xroot; subsets[xroot].rank++; } } // The main function to check whether a given graph contains // cycle or not int isCycle( struct Graph* graph) { int V = graph->V; int E = graph->E; // Allocate memory for creating V sets struct subset* subsets = ( struct subset*) malloc (V * sizeof ( struct subset)); for ( int v = 0; v < V; ++v) { subsets[v].parent = v; subsets[v].rank = 0; } // Iterate through all edges of graph, find sets of both // vertices of every edge, if sets are same, then there // is cycle in graph. for ( int e = 0; e < E; ++e) { int x = find(subsets, graph->edge[e].src); int y = find(subsets, graph->edge[e].dest); if (x == y) return 1; Union(subsets, x, y); } return 0; } // Driver code int main() { /* Let us create the following graph 0 | \ | \ 1-----2 */ int V = 3, E = 3; struct Graph* graph = createGraph(V, E); // add edge 0-1 graph->edge[0].src = 0; graph->edge[0].dest = 1; // add edge 1-2 graph->edge[1].src = 1; graph->edge[1].dest = 2; // add edge 0-2 graph->edge[2].src = 0; graph->edge[2].dest = 2; if (isCycle(graph)) cout << "Graph contains cycle" ; else cout << "Graph doesn't contain cycle" ; return 0; } // This code is contributed by Aditya Kumar (adityakumar129) |
C
// A C program to detect cycle in a graph using union by // rank and path compression #include <stdio.h> #include <stdlib.h> // a structure to represent an edge in the graph typedef struct Edge { int src, dest; }Edge; // a structure to represent a graph typedef struct Graph { // V-> Number of vertices, E-> Number of edges int V, E; // graph is represented as an array of edges struct Edge* edge; }Graph; typedef struct subset { int parent; int rank; }subset; // Creates a graph with V vertices and E edges Graph* createGraph( int V, int E) { Graph* graph = (Graph*) malloc ( sizeof (Graph)); graph->V = V; graph->E = E; graph->edge = (Edge*) malloc (graph->E * sizeof (Edge)); return graph; } // A utility function to find set of an element i // (uses path compression technique) int find(subset subsets[], int i) { // find root and make root as parent of i (path // compression) if (subsets[i].parent != i) subsets[i].parent = find(subsets, subsets[i].parent); return subsets[i].parent; } // A function that does union of two sets of x and y // (uses union by rank) void Union(subset subsets[], int xroot, int yroot) { // Attach smaller rank tree under root of high rank tree // (Union by Rank) if (subsets[xroot].rank < subsets[yroot].rank) subsets[xroot].parent = yroot; else if (subsets[xroot].rank > subsets[yroot].rank) subsets[yroot].parent = xroot; // If ranks are same, then make one as root and // increment its rank by one else { subsets[yroot].parent = xroot; subsets[xroot].rank++; } } // The main function to check whether a given graph contains // cycle or not int isCycle(Graph* graph) { int V = graph->V; int E = graph->E; // Allocate memory for creating V sets subset* subsets = (subset*) malloc (V * sizeof (subset)); for ( int v = 0; v < V; ++v) { subsets[v].parent = v; subsets[v].rank = 0; } // Iterate through all edges of graph, find sets of both // vertices of every edge, if sets are same, then there // is cycle in graph. for ( int e = 0; e < E; ++e) { int x = find(subsets, graph->edge[e].src); int y = find(subsets, graph->edge[e].dest); if (x == y) return 1; Union(subsets, x, y); } return 0; } // Driver code int main() { /* Let us create the following graph 0 | \ | \ 1-----2 */ int V = 3, E = 3; Graph* graph = createGraph(V, E); // add edge 0-1 graph->edge[0].src = 0; graph->edge[0].dest = 1; // add edge 1-2 graph->edge[1].src = 1; graph->edge[1].dest = 2; // add edge 0-2 graph->edge[2].src = 0; graph->edge[2].dest = 2; if (isCycle(graph)) printf ( "Graph contains cycle" ); else printf ( "Graph doesn't contain cycle" ); return 0; } // This code is contributed by Aditya Kumar (adityakumar129) |
Java
// A union by rank and path compression // based program to detect cycle in a graph class Graph { int V, E; Edge[] edge; Graph( int nV, int nE) { V = nV; E = nE; edge = new Edge[E]; for ( int i = 0 ; i < E; i++) { edge[i] = new Edge(); } } // class to represent edge class Edge { int src, dest; } // class to represent Subset class subset { int parent; int rank; } // A utility function to find // set of an element i (uses // path compression technique) int find(subset[] subsets, int i) { if (subsets[i].parent != i) subsets[i].parent = find(subsets, subsets[i].parent); return subsets[i].parent; } // A function that does union // of two sets of x and y // (uses union by rank) void Union(subset[] subsets, int x, int y) { int xroot = find(subsets, x); int yroot = find(subsets, y); if (subsets[xroot].rank < subsets[yroot].rank) subsets[xroot].parent = yroot; else if (subsets[yroot].rank < subsets[xroot].rank) subsets[yroot].parent = xroot; else { subsets[xroot].parent = yroot; subsets[yroot].rank++; } } // The main function to check whether // a given graph contains cycle or not int isCycle(Graph graph) { int V = graph.V; int E = graph.E; subset[] subsets = new subset[V]; for ( int v = 0 ; v < V; v++) { subsets[v] = new subset(); subsets[v].parent = v; subsets[v].rank = 0 ; } for ( int e = 0 ; e < E; e++) { int x = find(subsets, graph.edge[e].src); int y = find(subsets, graph.edge[e].dest); if (x == y) return 1 ; Union(subsets, x, y); } return 0 ; } // Driver Code public static void main(String[] args) { /* Let us create the following graph 0 | \ | \ 1-----2 */ int V = 3 , E = 3 ; Graph graph = new Graph(V, E); // add edge 0-1 graph.edge[ 0 ].src = 0 ; graph.edge[ 0 ].dest = 1 ; // add edge 1-2 graph.edge[ 1 ].src = 1 ; graph.edge[ 1 ].dest = 2 ; // add edge 0-2 graph.edge[ 2 ].src = 0 ; graph.edge[ 2 ].dest = 2 ; if (graph.isCycle(graph) == 1 ) System.out.println( "Graph contains cycle" ); else System.out.println( "Graph doesn't contain cycle" ); } } // This code is contributed // by ashwani khemani |
Python3
# A union by rank and path compression based # program to detect cycle in a graph from collections import defaultdict # a structure to represent a graph class Graph: def __init__( self , num_of_v): self .num_of_v = num_of_v self .edges = defaultdict( list ) # graph is represented as an # array of edges def add_edge( self , u, v): self .edges[u].append(v) class Subset: def __init__( self , parent, rank): self .parent = parent self .rank = rank # A utility function to find set of an element # node(uses path compression technique) def find(subsets, node): if subsets[node].parent ! = node: subsets[node].parent = find(subsets, subsets[node].parent) return subsets[node].parent # A function that does union of two sets # of u and v(uses union by rank) def union(subsets, u, v): # Attach smaller rank tree under root # of high rank tree(Union by Rank) if subsets[u].rank > subsets[v].rank: subsets[v].parent = u elif subsets[v].rank > subsets[u].rank: subsets[u].parent = v # If ranks are same, then make one as # root and increment its rank by one else : subsets[v].parent = u subsets[u].rank + = 1 # The main function to check whether a given # graph contains cycle or not def isCycle(graph): # Allocate memory for creating sets subsets = [] for u in range (graph.num_of_v): subsets.append(Subset(u, 0 )) # Iterate through all edges of graph, # find sets of both vertices of every # edge, if sets are same, then there # is cycle in graph. for u in graph.edges: u_rep = find(subsets, u) for v in graph.edges[u]: v_rep = find(subsets, v) if u_rep = = v_rep: return True else : union(subsets, u_rep, v_rep) # Driver Code g = Graph( 3 ) # add edge 0-1 g.add_edge( 0 , 1 ) # add edge 1-2 g.add_edge( 1 , 2 ) # add edge 0-2 g.add_edge( 0 , 2 ) if isCycle(g): print ( 'Graph contains cycle' ) else : print ( 'Graph does not contain cycle' ) # This code is contributed by # Sampath Kumar Surine |
C#
// A union by rank and path compression // based program to detect cycle in a graph using System; class Graph { public int V, E; public Edge[] edge; public Graph( int nV, int nE) { V = nV; E = nE; edge = new Edge[E]; for ( int i = 0; i < E; i++) { edge[i] = new Edge(); } } // class to represent edge public class Edge { public int src, dest; } // class to represent Subset class subset { public int parent; public int rank; } // A utility function to find // set of an element i (uses // path compression technique) int find(subset[] subsets, int i) { if (subsets[i].parent != i) subsets[i].parent = find(subsets, subsets[i].parent); return subsets[i].parent; } // A function that does union // of two sets of x and y // (uses union by rank) void Union(subset[] subsets, int x, int y) { int xroot = find(subsets, x); int yroot = find(subsets, y); if (subsets[xroot].rank < subsets[yroot].rank) subsets[xroot].parent = yroot; else if (subsets[yroot].rank < subsets[xroot].rank) subsets[yroot].parent = xroot; else { subsets[xroot].parent = yroot; subsets[yroot].rank++; } } // The main function to check whether // a given graph contains cycle or not int isCycle(Graph graph) { int V = graph.V; int E = graph.E; subset[] subsets = new subset[V]; for ( int v = 0; v < V; v++) { subsets[v] = new subset(); subsets[v].parent = v; subsets[v].rank = 0; } for ( int e = 0; e < E; e++) { int x = find(subsets, graph.edge[e].src); int y = find(subsets, graph.edge[e].dest); if (x == y) return 1; Union(subsets, x, y); } return 0; } // Driver Code static public void Main(String[] args) { /* Let us create the following graph 0 | \ | \ 1-----2 */ int V = 3, E = 3; Graph graph = new Graph(V, E); // add edge 0-1 graph.edge[0].src = 0; graph.edge[0].dest = 1; // add edge 1-2 graph.edge[1].src = 1; graph.edge[1].dest = 2; // add edge 0-2 graph.edge[2].src = 0; graph.edge[2].dest = 2; if (graph.isCycle(graph) == 1) Console.WriteLine( "Graph contains cycle" ); else Console.WriteLine( "Graph doesn't contain cycle" ); } } // This code is contributed // by Arnab Kundu |
Javascript
<script> // A union by rank and path compression // based program to detect cycle in a graph let V, E; let edge; function Graph(nV,nE) { V = nV; E = nE; edge = new Array(E); for (let i = 0; i < E; i++) { edge[i] = new Edge(); } } // class to represent edge class Edge { constructor() { this .src=0; this .dest=0; } } // class to represent Subset class subset { constructor() { this .parent=0; this .rank=0; } } // A utility function to find // set of an element i (uses // path compression technique) function find(subsets,i) { if (subsets[i].parent != i) subsets[i].parent = find(subsets, subsets[i].parent); return subsets[i].parent; } // A function that does union // of two sets of x and y // (uses union by rank) function Union(subsets,x,y) { let xroot = find(subsets, x); let yroot = find(subsets, y); if (subsets[xroot].rank < subsets[yroot].rank) subsets[xroot].parent = yroot; else if (subsets[yroot].rank < subsets[xroot].rank) subsets[yroot].parent = xroot; else { subsets[xroot].parent = yroot; subsets[yroot].rank++; } } // The main function to check whether // a given graph contains cycle or not function isCycle() { let subsets = new Array(V); for (let v = 0; v < V; v++) { subsets[v] = new subset(); subsets[v].parent = v; subsets[v].rank = 0; } for (let e = 0; e < E; e++) { let x = find(subsets, edge[e].src); let y = find(subsets, edge[e].dest); if (x == y) return 1; Union(subsets, x, y); } return 0; } // Driver Code /* Let us create the following graph 0 | \ | \ 1-----2 */ V = 3, E = 3; Graph(V, E); // add edge 0-1 edge[0].src = 0; edge[0].dest = 1; // add edge 1-2 edge[1].src = 1; edge[1].dest = 2; // add edge 0-2 edge[2].src = 0; edge[2].dest = 2; if (isCycle() == 1) document.write( "Graph contains cycle" ); else document.write( "Graph doesn't contain cycle" ); // This code is contributed by avanitrachhadiya2155 </script> |
Graph contains cycle
Time complexity: O(ElogV) where E is the number of edges in the graph and V is the number of vertices.
Space complexity: O(V), where V is the number of vertices. This is because we are using an array of subsets to store the representative elements of each vertex, and the size of this array is proportional to the number of vertices.
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