README.md

Ojtli

Ojtli is a minimal and generic Java graph traversal and path finding algorithms library. It does not depend on another library which makes it very lightweight.

"Ojtli" is a nahuatl world that means "path".

Current version implements the following path search algorithms:

• Iterative deepening A* (IDA*): The algorithm described in the "Depth-First Iterative-Deepening: An Optimal Admissible Tree Search*" paper by Richard E. Korf for the Artifitial Ingelligence Journal. doi:10.1016/0004-3702(85)90084-0

Download and Install

To download and install Ojtli you currently have the following options.

Maven

Add dependency to io.github.miguelcarrasco:ojtli:

<dependency>
    <groupId>io.github.miguelcarrasco</groupId>
    <artifactId>ojtli</artifactId>
    <version>1.0.0</version>
</dependency>

Plain-old JAR

Download the following JAR and add it to your classpath:

• ojtli-1.0.0.jar

Usage

1. You need to create a class that implements the HeuristicSearch interface:

/**
 * Heurisitic Search interface used by several algorithms like
 * A* and IDA*.
 *
 * @param <T>
 */
public interface HeuristicSearch<T> {
    /**
     * Calculate the heuristic cost from "node" to "goal".
     *
     * @param node a node.
     * @param goal the goal node.
     * @return heuristic cost estimate.
     */
    float getHeuristicCostEstimate(T node, T goal);

    /**
     * Get the real cost of a node and a successor (neighbor).
     *
     * @param startNode a start node.
     * @param endNode   the end node.
     * @return real cost.
     */
    float getCost(T startNode, T endNode);

    /**
     * Get the neighbors (successors) elements of the specified node.
     *
     * @param node the node from witch neighbors will be generated.
     * @return A list that contains the neighbors of the specified node.
     */
    List<T> getNeighbors(T node);
}

Note that this interface use a generic parameter. The generic parameter allows you to use a class that represents a node in your graph.

For instance, suppose that you created a Node class in your code to represent a node on a graph, then a GraphSearch class can be created to implement the HeuristicSearch interface. GraphSearch must implement the interface methods which must do the following:

• getHeuristicCostEstimate(Node node, Node goal): this method must return a float that represents the estimated cost to get from the specified node (as the first param) to the goal node (as the second param) usually implemented using an admissible heuristic. An admissible heuristic is a computed estimate that must be less or equal than the real cost of going from the specified node to the goal node in the graph. It's important to ensure that the heuristic is an admissible one, if the heuristic is not admissible, that is, if the estimation value is greater than the real optimal cost, the path search algorithm does not guarantee that it will find an optimal path.
• getCost(Node startNode, Node endNode): this method must return a float that represent the real cost from the startNode and the endNode, where startNode and endNode are neighbors nodes in the graph.
• getNeighbors(Node node): this method must return a list of the neighbors nodes for the specified node.

2. Once you created an implementation of the HeuristicSearch interface for the specified node class, you can calculate the optimal path creating an instance of a PathSearch object implementing a specific algorithm. For the previous example if we want to use the IDA* algorithm to find an optimal path using our custom GraphSearch class that implements the HeuristicSearch interface, we can do it via:

// GraphSearch implements the HeuristicSearch interface
GraphSearch graphSearch = new GraphSearch();
        
// Create a PathSearch object specifing an implementation of the IDA* algorithm 
// for a GraphSearch object
PathSearch<Node> pathSearch = new IDAstarSearch<Node>(graphSearch);

// Find an optimal path from the specified node to the goal node as a ResultPath object
ResultPath<Node> resultPath = pathSearch.searchPath(node, goal);

// Get the optimal path from the node to the goal as a List
List<Node> optimalPath = resultPath.getPath();

// Gets the number of visited nodes in the corresponding path search.
int nodesVisited = resultPath.getNodesVisited()

In order to check if the goal has been reached, the path search algorithms use the equals method for the specified object that represent a node (Node instances in the previous example).