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Application of Ford-Fulkerson algorithm to find the maximum matching between 2 sides of a bipartite graph

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Bipartite Matching Algorithm

Extension of a Ford Fulkerson max flow problem using depth first search

Problem Statement

Given an undirected bipartite graph, find the maximum matching between left & right halves. Each node in the Left half L mapped to at most 1 node in R. Similarly, each node in the Right Half R is mapped to at most 1 node in L
Goal: maximize the number of matchings

Algorithm

Convert to a Max Flow / Min Cut problem by making a directed graph:

  1. Make all edges from L to R directed with capacity 1
    A flow of 1 corresponds to yes there's a matching and 0 mean no matching
    Since there's only 2 values, it could even be implemented as a boolean
  2. Add a Source S & create directed edges from S to every vertex in the left half with capacity 1
  3. Add a Sink T & create directed edges from every vertex in the right half to T with capacity 1
  4. Use Ford-Fulkerson algorithm to find the max flow

Usage (setting things up in main())

  • Graph is represented as an edge list
  • vertexCount must be an accurate number of nodes in the graph
  • getStringVertexIdFromArrayIndex allows conversion between the array indexes used by the actual algorithm & the human-readable names of the vertices. These are sequential with "S" and "T" being added at the end
  • S & T are added to the end of the list of vertices with S getting array index vertexCount and T getting array index vertexCount+1
  • int[] leftHalfVertices contains the array indexes of the vertices in the left part of the bipartite graph
  • Similarly, int[] rightHalfVertices contains the vertices in the right half
  • These must be consecutive integers with the 1st number in rightHalfVertices being 1 greater than the last number in leftHalfVertices
  • Use addEdge() method on BipartiteMatching class to add new edges
    The initial bipartie graph is undirected so undirected edges should only be added once. They are converted to directed edges when finding the max flow
  • Run connectSourceToLeftHalf() to modify the graph & add the source, then connectSinkToRightHalf() to connect the sink
  • Run fordFulkersonMaxFlow(source, sink) to find the maximum matching

Starting Graphs

      

Relabeled Graphs

The code uses array indexes instead of nice human-readable Vertex names. Red numbers represent array indexes        

Directed Graphs With Source & Sink Added

All edge capacities are 1 but omitted here for clarity of the picture
       

Maximum Matching Solutions

These are not unique, but these are what the program finds