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Add Hamiltonian cycle.

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Oleksii Trekhleb 2018-05-17 07:40:13 +03:00
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README.md
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* [Topological Sorting](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/topological-sorting) - DFS method
* [Articulation Points](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/articulation-points) - Tarjan's algorithm (DFS based)
* [Bridges](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/bridges) - DFS based algorithm
* [Eulerian Path and Eulerian Circuit](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/eulerian-path) - Fleury's algorithm - Visit every edge once
* [Eulerian Path and Eulerian Circuit](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/eulerian-path) - Fleury's algorithm - Visit every edge exactly once
* [Hamiltonian Cycle](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/hamiltonian-cycle) - Visit every vertex exactly once
* [Strongly Connected Components](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/strongly-connected-components) - Kosaraju's algorithm
* **Uncategorized**
* [Tower of Hanoi](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/uncategorized/hanoi-tower)
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* [Maximum Subarray](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/sets/maximum-subarray)
* [Bellman-Ford Algorithm](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/bellman-ford) - finding shortest path to all graph vertices
* **Backtracking**
* [Hamiltonian Cycle](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/graph/hamiltonian-cycle) - Visit every vertex exactly once
* [N-Queens Problem](https://github.com/trekhleb/javascript-algorithms/tree/master/src/algorithms/uncategorized/n-queens)
* **Branch & Bound**

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src/algorithms/graph/hamiltonian-cycle/README.md Normal file
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# Hamiltonian Path
**Hamiltonian path** (or **traceable path**) is a path in an
undirected or directed graph that visits each vertex exactly once.
A **Hamiltonian cycle** (or **Hamiltonian circuit**) is a
Hamiltonian path that is a cycle. Determining whether such paths
and cycles exist in graphs is the **Hamiltonian path problem**.
![Hamiltonian cycle](https://upload.wikimedia.org/wikipedia/commons/6/6c/Hamiltonian_path_3d.svg)
One possible Hamiltonian cycle through every vertex of a
dodecahedron is shown in red like all platonic solids, the
dodecahedron is Hamiltonian.
## Naive Algorithm
Generate all possible configurations of vertices and print a
configuration that satisfies the given constraints. There
will be `n!` (n factorial) configurations.
```
while there are untried configurations
{
generate the next configuration
if ( there are edges between two consecutive vertices of this
configuration and there is an edge from the last vertex to
the first ).
{
print this configuration;
break;
}
}
```
## Backtracking Algorithm
Create an empty path array and add vertex `0` to it. Add other
vertices, starting from the vertex `1`. Before adding a vertex,
check for whether it is adjacent to the previously added vertex
and not already added. If we find such a vertex, we add the
vertex as part of the solution. If we do not find a vertex
then we return false.
## References
- [Hamiltonian path on Wikipedia](https://en.wikipedia.org/wiki/Hamiltonian_path)
- [Hamiltonian path on YouTube](https://www.youtube.com/watch?v=dQr4wZCiJJ4)
- [Hamiltonian cycle on GeeksForGeeks](https://www.geeksforgeeks.org/backtracking-set-7-hamiltonian-cycle/)

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src/algorithms/graph/hamiltonian-cycle/__test__/hamiltonianCycle.test.js Normal file
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import GraphVertex from '../../../../data-structures/graph/GraphVertex';
import GraphEdge from '../../../../data-structures/graph/GraphEdge';
import Graph from '../../../../data-structures/graph/Graph';
import hamiltonianCycle from '../hamiltonianCycle';
describe('hamiltonianCycle', () => {
it('should find hamiltonian paths in graph', () => {
const vertexA = new GraphVertex('A');
const vertexB = new GraphVertex('B');
const vertexC = new GraphVertex('C');
const vertexD = new GraphVertex('D');
const vertexE = new GraphVertex('E');
const edgeAB = new GraphEdge(vertexA, vertexB);
const edgeAE = new GraphEdge(vertexA, vertexE);
const edgeAC = new GraphEdge(vertexA, vertexC);
const edgeBE = new GraphEdge(vertexB, vertexE);
const edgeBC = new GraphEdge(vertexB, vertexC);
const edgeBD = new GraphEdge(vertexB, vertexD);
const edgeCD = new GraphEdge(vertexC, vertexD);
const edgeDE = new GraphEdge(vertexD, vertexE);
const graph = new Graph();
graph
.addEdge(edgeAB)
.addEdge(edgeAE)
.addEdge(edgeAC)
.addEdge(edgeBE)
.addEdge(edgeBC)
.addEdge(edgeBD)
.addEdge(edgeCD)
.addEdge(edgeDE);
const hamiltonianCycleSet = hamiltonianCycle(graph);
expect(hamiltonianCycleSet.length).toBe(8);
expect(hamiltonianCycleSet[0][0].getKey()).toBe(vertexA.getKey());
expect(hamiltonianCycleSet[0][1].getKey()).toBe(vertexB.getKey());
expect(hamiltonianCycleSet[0][2].getKey()).toBe(vertexE.getKey());
expect(hamiltonianCycleSet[0][3].getKey()).toBe(vertexD.getKey());
expect(hamiltonianCycleSet[0][4].getKey()).toBe(vertexC.getKey());
expect(hamiltonianCycleSet[1][0].getKey()).toBe(vertexA.getKey());
expect(hamiltonianCycleSet[1][1].getKey()).toBe(vertexB.getKey());
expect(hamiltonianCycleSet[1][2].getKey()).toBe(vertexC.getKey());
expect(hamiltonianCycleSet[1][3].getKey()).toBe(vertexD.getKey());
expect(hamiltonianCycleSet[1][4].getKey()).toBe(vertexE.getKey());
expect(hamiltonianCycleSet[2][0].getKey()).toBe(vertexA.getKey());
expect(hamiltonianCycleSet[2][1].getKey()).toBe(vertexE.getKey());
expect(hamiltonianCycleSet[2][2].getKey()).toBe(vertexB.getKey());
expect(hamiltonianCycleSet[2][3].getKey()).toBe(vertexD.getKey());
expect(hamiltonianCycleSet[2][4].getKey()).toBe(vertexC.getKey());
expect(hamiltonianCycleSet[3][0].getKey()).toBe(vertexA.getKey());
expect(hamiltonianCycleSet[3][1].getKey()).toBe(vertexE.getKey());
expect(hamiltonianCycleSet[3][2].getKey()).toBe(vertexD.getKey());
expect(hamiltonianCycleSet[3][3].getKey()).toBe(vertexB.getKey());
expect(hamiltonianCycleSet[3][4].getKey()).toBe(vertexC.getKey());
});
it('should return false for graph without Hamiltonian path', () => {
const vertexA = new GraphVertex('A');
const vertexB = new GraphVertex('B');
const vertexC = new GraphVertex('C');
const vertexD = new GraphVertex('D');
const vertexE = new GraphVertex('E');
const edgeAB = new GraphEdge(vertexA, vertexB);
const edgeAE = new GraphEdge(vertexA, vertexE);
const edgeBE = new GraphEdge(vertexB, vertexE);
const edgeBC = new GraphEdge(vertexB, vertexC);
const edgeBD = new GraphEdge(vertexB, vertexD);
const edgeCD = new GraphEdge(vertexC, vertexD);
const graph = new Graph();
graph
.addEdge(edgeAB)
.addEdge(edgeAE)
.addEdge(edgeBE)
.addEdge(edgeBC)
.addEdge(edgeBD)
.addEdge(edgeCD);
const hamiltonianCycleSet = hamiltonianCycle(graph);
expect(hamiltonianCycleSet.length).toBe(0);
});
});

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src/algorithms/graph/hamiltonian-cycle/hamiltonianCycle.js Normal file
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import GraphVertex from '../../../data-structures/graph/GraphVertex';
/**
* @param {number[][]} adjacencyMatrix
* @param {object} verticesIndices
* @param {GraphVertex[]} cycle
* @param {GraphVertex} vertexCandidate
* @return {boolean}
*/
function isSafe(adjacencyMatrix, verticesIndices, cycle, vertexCandidate) {
const endVertex = cycle[cycle.length - 1];
// Get end and candidate vertices indices in adjacency matrix.
const candidateVertexAdjacencyIndex = verticesIndices[vertexCandidate.getKey()];
const endVertexAdjacencyIndex = verticesIndices[endVertex.getKey()];
// Check if last vertex in the path and candidate vertex are adjacent.
if (!adjacencyMatrix[endVertexAdjacencyIndex][candidateVertexAdjacencyIndex]) {
return false;
}
// Check if vertexCandidate is being added to the path for the first time.
const candidateDuplicate = cycle.find(vertex => vertex.getKey() === vertexCandidate.getKey());
return !candidateDuplicate;
}
/**
* @param {number[][]} adjacencyMatrix
* @param {object} verticesIndices
* @param {GraphVertex[]} cycle
* @return {boolean}
*/
function isCycle(adjacencyMatrix, verticesIndices, cycle) {
// Check if first and last vertices in hamiltonian path are adjacent.
// Get start and end vertices from the path.
const startVertex = cycle[0];
const endVertex = cycle[cycle.length - 1];
// Get start/end vertices indices in adjacency matrix.
const startVertexAdjacencyIndex = verticesIndices[startVertex.getKey()];
const endVertexAdjacencyIndex = verticesIndices[endVertex.getKey()];
// Check if we can go from end vertex to the start one.
return !!adjacencyMatrix[endVertexAdjacencyIndex][startVertexAdjacencyIndex];
}
/**
* @param {number[][]} adjacencyMatrix
* @param {GraphVertex[]} vertices
* @param {object} verticesIndices
* @param {GraphVertex[][]} cycles
* @param {GraphVertex[]} cycle
*/
function hamiltonianCycleRecursive({
adjacencyMatrix,
vertices,
verticesIndices,
cycles,
cycle,
}) {
// Clone cycle in order to prevent it from modification by other DFS branches.
const currentCycle = [...cycle].map(vertex => new GraphVertex(vertex.value));
if (vertices.length === currentCycle.length) {
// Hamiltonian path is found.
// Now we need to check if it is cycle or not.
if (isCycle(adjacencyMatrix, verticesIndices, currentCycle)) {
// Another solution has been found. Save it.
cycles.push(currentCycle);
}
return;
}
for (let vertexIndex = 0; vertexIndex < vertices.length; vertexIndex += 1) {
// Get vertex candidate that we will try to put into next path step and see if it fits.
const vertexCandidate = vertices[vertexIndex];
// Check if it is safe to put vertex candidate to cycle.
if (isSafe(adjacencyMatrix, verticesIndices, currentCycle, vertexCandidate)) {
// Add candidate vertex to cycle path.
currentCycle.push(vertexCandidate);
// Try to find other vertices in cycle.
hamiltonianCycleRecursive({
adjacencyMatrix,
vertices,
verticesIndices,
cycles,
cycle: currentCycle,
});
// Remove candidate vertex from cycle path in order to try another one.
currentCycle.pop();
}
}
}
/**
* @param {Graph} graph
* @return {GraphVertex[][]}
*/
export default function hamiltonianCycle(graph) {
// Gather some information about the graph that we will need to during
// the problem solving.
const verticesIndices = graph.getVerticesIndices();
const adjacencyMatrix = graph.getAdjacencyMatrix();
const vertices = graph.getAllVertices();
// Define start vertex. We will always pick the first one
// this it doesn't matter which vertex to pick in a cycle.
// Every vertex is in a cycle so we can start from any of them.
const startVertex = vertices[0];
// Init cycles array that will hold all solutions.
const cycles = [];
// Init cycle array that will hold current cycle path.
const cycle = [startVertex];
// Try to find cycles recursively in Depth First Search order.
hamiltonianCycleRecursive({
adjacencyMatrix,
vertices,
verticesIndices,
cycles,
cycle,
});
// Return found cycles.
return cycles;
}