Python/graphs/edmonds_karp_multiple_source_and_sink.py

class FlowNetwork:
    def __init__(self, graph, sources, sinks):
        self.sourceIndex = None
        self.sinkIndex = None
        self.graph = graph

        self._normalizeGraph(sources, sinks)
        self.verticesCount = len(graph)
        self.maximumFlowAlgorithm = None

    # make only one source and one sink
    def _normalizeGraph(self, sources, sinks):
        if sources is int:
            sources = [sources]
        if sinks is int:
            sinks = [sinks]

        if len(sources) == 0 or len(sinks) == 0:
            return

        self.sourceIndex = sources[0]
        self.sinkIndex = sinks[0]

        # make fake vertex if there are more
        # than one source or sink
        if len(sources) > 1 or len(sinks) > 1:
            maxInputFlow = 0
            for i in sources:
                maxInputFlow += sum(self.graph[i])


            size = len(self.graph) + 1
            for room in self.graph:
                room.insert(0, 0)
            self.graph.insert(0, [0] * size)
            for i in sources:
                self.graph[0][i + 1] = maxInputFlow
            self.sourceIndex  = 0

            size = len(self.graph) + 1
            for room in self.graph:
                room.append(0)
            self.graph.append([0] * size)
            for i in sinks:
                self.graph[i + 1][size - 1] = maxInputFlow
            self.sinkIndex = size - 1


    def findMaximumFlow(self):
        if self.maximumFlowAlgorithm is None:
            raise Exception("You need to set maximum flow algorithm before.")
        if self.sourceIndex is None or self.sinkIndex is None:
            return 0

        self.maximumFlowAlgorithm.execute()
        return self.maximumFlowAlgorithm.getMaximumFlow()

    def setMaximumFlowAlgorithm(self, Algorithm):
        self.maximumFlowAlgorithm = Algorithm(self)


class FlowNetworkAlgorithmExecutor(object):
    def __init__(self, flowNetwork):
        self.flowNetwork = flowNetwork
        self.verticesCount = flowNetwork.verticesCount
        self.sourceIndex = flowNetwork.sourceIndex
        self.sinkIndex = flowNetwork.sinkIndex
        # it's just a reference, so you shouldn't change
        # it in your algorithms, use deep copy before doing that
        self.graph = flowNetwork.graph
        self.executed = False

    def execute(self):
        if not self.executed:
            self._algorithm()
            self.executed = True

    # You should override it
    def _algorithm(self):
        pass


class MaximumFlowAlgorithmExecutor(FlowNetworkAlgorithmExecutor):
    def __init__(self, flowNetwork):
        super(MaximumFlowAlgorithmExecutor, self).__init__(flowNetwork)
        # use this to save your result
        self.maximumFlow = -1

    def getMaximumFlow(self):
        if not self.executed:
            raise Exception("You should execute algorithm before using its result!")

        return self.maximumFlow

class PushRelabelExecutor(MaximumFlowAlgorithmExecutor):
    def __init__(self, flowNetwork):
        super(PushRelabelExecutor, self).__init__(flowNetwork)

        self.preflow = [[0] * self.verticesCount for i in range(self.verticesCount)]

        self.heights = [0] * self.verticesCount
        self.excesses = [0] * self.verticesCount

    def _algorithm(self):
        self.heights[self.sourceIndex] = self.verticesCount

        # push some substance to graph
        for nextVertexIndex, bandwidth in enumerate(self.graph[self.sourceIndex]):
            self.preflow[self.sourceIndex][nextVertexIndex] += bandwidth
            self.preflow[nextVertexIndex][self.sourceIndex] -= bandwidth
            self.excesses[nextVertexIndex] += bandwidth

        # Relabel-to-front selection rule
        verticesList = [i for i in range(self.verticesCount)
                        if i != self.sourceIndex and i != self.sinkIndex]

        # move through list
        i = 0
        while i < len(verticesList):
            vertexIndex = verticesList[i]
            previousHeight = self.heights[vertexIndex]
            self.processVertex(vertexIndex)
            if self.heights[vertexIndex] > previousHeight:
                # if it was relabeled, swap elements
                # and start from 0 index
                verticesList.insert(0, verticesList.pop(i))
                i = 0
            else:
                i += 1

        self.maximumFlow = sum(self.preflow[self.sourceIndex])

    def processVertex(self, vertexIndex):
        while self.excesses[vertexIndex] > 0:
            for neighbourIndex in range(self.verticesCount):
                # if it's neighbour and current vertex is higher
                if self.graph[vertexIndex][neighbourIndex] - self.preflow[vertexIndex][neighbourIndex] > 0\
                        and self.heights[vertexIndex] > self.heights[neighbourIndex]:
                    self.push(vertexIndex, neighbourIndex)

            self.relabel(vertexIndex)

    def push(self, fromIndex, toIndex):
        preflowDelta = min(self.excesses[fromIndex],
                           self.graph[fromIndex][toIndex] - self.preflow[fromIndex][toIndex])
        self.preflow[fromIndex][toIndex] += preflowDelta
        self.preflow[toIndex][fromIndex] -= preflowDelta
        self.excesses[fromIndex] -= preflowDelta
        self.excesses[toIndex] += preflowDelta

    def relabel(self, vertexIndex):
        minHeight = None
        for toIndex in range(self.verticesCount):
            if self.graph[vertexIndex][toIndex] - self.preflow[vertexIndex][toIndex] > 0:
                if minHeight is None or self.heights[toIndex] < minHeight:
                    minHeight = self.heights[toIndex]

        if minHeight is not None:
            self.heights[vertexIndex] = minHeight + 1

if __name__ == '__main__':
    entrances = [0]
    exits = [3]
    # graph = [
    #     [0, 0, 4, 6, 0, 0],
    #     [0, 0, 5, 2, 0, 0],
    #     [0, 0, 0, 0, 4, 4],
    #     [0, 0, 0, 0, 6, 6],
    #     [0, 0, 0, 0, 0, 0],
    #     [0, 0, 0, 0, 0, 0],
    # ]
    graph = [[0, 7, 0, 0], [0, 0, 6, 0], [0, 0, 0, 8], [9, 0, 0, 0]]

    # prepare our network
    flowNetwork = FlowNetwork(graph, entrances, exits)
    # set algorithm
    flowNetwork.setMaximumFlowAlgorithm(PushRelabelExecutor)
    # and calculate
    maximumFlow = flowNetwork.findMaximumFlow()

    print("maximum flow is {}".format(maximumFlow))
Created a generalized algo to edmonds karp (#724) Edmonds Karp algorithm is traditionally with only one source and one sink. What do you do if you have multiple sources and sinks? This algorithm is a generalized algorithm that regardless of however many sinks and sources you have, will allow you to use this algorithm. It does this by using the traditional algorithm but adding an artificial source and sink that allows with "infinite" weight. 2019-04-25 11:48:14 +00:00			`class FlowNetwork:`
			`def __init__(self, graph, sources, sinks):`
			`self.sourceIndex = None`
			`self.sinkIndex = None`
			`self.graph = graph`

			`self._normalizeGraph(sources, sinks)`
			`self.verticesCount = len(graph)`
			`self.maximumFlowAlgorithm = None`

			`# make only one source and one sink`
			`def _normalizeGraph(self, sources, sinks):`
			`if sources is int:`
			`sources = [sources]`
			`if sinks is int:`
			`sinks = [sinks]`

			`if len(sources) == 0 or len(sinks) == 0:`
			`return`

			`self.sourceIndex = sources[0]`
			`self.sinkIndex = sinks[0]`

			`# make fake vertex if there are more`
			`# than one source or sink`
			`if len(sources) > 1 or len(sinks) > 1:`
			`maxInputFlow = 0`
			`for i in sources:`
			`maxInputFlow += sum(self.graph[i])`


			`size = len(self.graph) + 1`
			`for room in self.graph:`
			`room.insert(0, 0)`
			`self.graph.insert(0, [0] * size)`
			`for i in sources:`
			`self.graph[0][i + 1] = maxInputFlow`
			`self.sourceIndex = 0`

			`size = len(self.graph) + 1`
			`for room in self.graph:`
			`room.append(0)`
			`self.graph.append([0] * size)`
			`for i in sinks:`
			`self.graph[i + 1][size - 1] = maxInputFlow`
			`self.sinkIndex = size - 1`


			`def findMaximumFlow(self):`
			`if self.maximumFlowAlgorithm is None:`
			`raise Exception("You need to set maximum flow algorithm before.")`
			`if self.sourceIndex is None or self.sinkIndex is None:`
			`return 0`

			`self.maximumFlowAlgorithm.execute()`
			`return self.maximumFlowAlgorithm.getMaximumFlow()`

			`def setMaximumFlowAlgorithm(self, Algorithm):`
			`self.maximumFlowAlgorithm = Algorithm(self)`


			`class FlowNetworkAlgorithmExecutor(object):`
			`def __init__(self, flowNetwork):`
			`self.flowNetwork = flowNetwork`
			`self.verticesCount = flowNetwork.verticesCount`
			`self.sourceIndex = flowNetwork.sourceIndex`
			`self.sinkIndex = flowNetwork.sinkIndex`
			`# it's just a reference, so you shouldn't change`
			`# it in your algorithms, use deep copy before doing that`
			`self.graph = flowNetwork.graph`
			`self.executed = False`

			`def execute(self):`
			`if not self.executed:`
			`self._algorithm()`
			`self.executed = True`

			`# You should override it`
			`def _algorithm(self):`
			`pass`



			`class MaximumFlowAlgorithmExecutor(FlowNetworkAlgorithmExecutor):`
			`def __init__(self, flowNetwork):`
			`super(MaximumFlowAlgorithmExecutor, self).__init__(flowNetwork)`
			`# use this to save your result`
			`self.maximumFlow = -1`

			`def getMaximumFlow(self):`
			`if not self.executed:`
			`raise Exception("You should execute algorithm before using its result!")`

			`return self.maximumFlow`

			`class PushRelabelExecutor(MaximumFlowAlgorithmExecutor):`
			`def __init__(self, flowNetwork):`
			`super(PushRelabelExecutor, self).__init__(flowNetwork)`

			`self.preflow = [[0] * self.verticesCount for i in range(self.verticesCount)]`

			`self.heights = [0] * self.verticesCount`
			`self.excesses = [0] * self.verticesCount`

			`def _algorithm(self):`
			`self.heights[self.sourceIndex] = self.verticesCount`

			`# push some substance to graph`
			`for nextVertexIndex, bandwidth in enumerate(self.graph[self.sourceIndex]):`
			`self.preflow[self.sourceIndex][nextVertexIndex] += bandwidth`
			`self.preflow[nextVertexIndex][self.sourceIndex] -= bandwidth`
			`self.excesses[nextVertexIndex] += bandwidth`

			`# Relabel-to-front selection rule`
			`verticesList = [i for i in range(self.verticesCount)`
			`if i != self.sourceIndex and i != self.sinkIndex]`

			`# move through list`
			`i = 0`
			`while i < len(verticesList):`
			`vertexIndex = verticesList[i]`
			`previousHeight = self.heights[vertexIndex]`
			`self.processVertex(vertexIndex)`
			`if self.heights[vertexIndex] > previousHeight:`
			`# if it was relabeled, swap elements`
			`# and start from 0 index`
			`verticesList.insert(0, verticesList.pop(i))`
			`i = 0`
			`else:`
			`i += 1`

			`self.maximumFlow = sum(self.preflow[self.sourceIndex])`

			`def processVertex(self, vertexIndex):`
			`while self.excesses[vertexIndex] > 0:`
			`for neighbourIndex in range(self.verticesCount):`
			`# if it's neighbour and current vertex is higher`
			`if self.graph[vertexIndex][neighbourIndex] - self.preflow[vertexIndex][neighbourIndex] > 0\`
			`and self.heights[vertexIndex] > self.heights[neighbourIndex]:`
			`self.push(vertexIndex, neighbourIndex)`

			`self.relabel(vertexIndex)`

			`def push(self, fromIndex, toIndex):`
			`preflowDelta = min(self.excesses[fromIndex],`
			`self.graph[fromIndex][toIndex] - self.preflow[fromIndex][toIndex])`
			`self.preflow[fromIndex][toIndex] += preflowDelta`
			`self.preflow[toIndex][fromIndex] -= preflowDelta`
			`self.excesses[fromIndex] -= preflowDelta`
			`self.excesses[toIndex] += preflowDelta`

			`def relabel(self, vertexIndex):`
			`minHeight = None`
			`for toIndex in range(self.verticesCount):`
			`if self.graph[vertexIndex][toIndex] - self.preflow[vertexIndex][toIndex] > 0:`
			`if minHeight is None or self.heights[toIndex] < minHeight:`
			`minHeight = self.heights[toIndex]`

			`if minHeight is not None:`
			`self.heights[vertexIndex] = minHeight + 1`

			`if __name__ == '__main__':`
			`entrances = [0]`
			`exits = [3]`
			`# graph = [`
			`# [0, 0, 4, 6, 0, 0],`
			`# [0, 0, 5, 2, 0, 0],`
			`# [0, 0, 0, 0, 4, 4],`
			`# [0, 0, 0, 0, 6, 6],`
			`# [0, 0, 0, 0, 0, 0],`
			`# [0, 0, 0, 0, 0, 0],`
			`# ]`
			`graph = [[0, 7, 0, 0], [0, 0, 6, 0], [0, 0, 0, 8], [9, 0, 0, 0]]`

			`# prepare our network`
			`flowNetwork = FlowNetwork(graph, entrances, exits)`
			`# set algorithm`
			`flowNetwork.setMaximumFlowAlgorithm(PushRelabelExecutor)`
			`# and calculate`
			`maximumFlow = flowNetwork.findMaximumFlow()`

			`print("maximum flow is {}".format(maximumFlow))`