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After debugging for a few hours, the algorithm seems to be working. Right now to check if it works i'm checking the end node position to the currentNode position when the while loop quits. So far the values look correct. The problem is, the farther I get from the NPC, who is current stationary, the worse the performance gets. It gets to a point where the game is unplayable less than 10 fps. My current PathGraph is 2500 nodes, which I believe is pretty small, right? Any ideas on how to improve performance?

struct Node
{
    bool walkable;      //Whether this node is blocked or open
    vect2 position;     //The tile's position on the map in pixels
    int xIndex, yIndex; //The index values of the tile in the array
    Node*[4] connections; //An array of pointers to nodes this current node connects to
    Node* parent;
    int gScore;
    int hScore;
    int fScore;
}

class AStar
{
    private:
    SList!Node openList;    //List of nodes who have been visited, with F scores but not processed
    SList!Node closedList;  //List of nodes who have had their connections processed

    //Node*[4] connections;     //The connections of the current node;

    Node currentNode;           //The current node being processed

    Node[] Path;        //The path found;

    const int connectionCost = 10;

    Node start, end;

//////////////////////////////////////////////////////////

    void AddToList(ref SList!Node list, ref Node node )
    {
        list.insert( node );
    }

    void RemoveFrom(ref SList!Node list, ref Node node )
    {
        foreach( elem; list )
        {
            if( node.xIndex == elem.xIndex && node.yIndex == elem.yIndex )
            {
                auto a = find( list[] , elem );
                list.linearRemove( take(a, 1 ) );
            }
        }
    }


    bool IsInList( SList!Node list, ref Node node )
    {
        foreach( elem; list )
        {
            if( node.xIndex == elem.xIndex && node.yIndex == elem.yIndex )
                return true;
        }

        return false;
    }

    void ClearList( SList!Node list )
    {
        list.clear;
    }

    void SetParentNode( ref Node parent, ref Node child )
    {
        child.parent = &parent;
    }

    void SetStartAndEndNode( vect2 vStart, vect2 vEnd, Node[] PathGraph )
    {
        int startXIndex, startYIndex;
        int endXIndex, endYIndex;

        startXIndex = cast(int)( vStart.x / 32 );
        startYIndex = cast(int)( vStart.y / 32 );

        endXIndex = cast(int)( vEnd.x / 32 );
        endYIndex = cast(int)( vEnd.y / 32 );

        foreach( node; PathGraph )
        {
            if( node.xIndex == startXIndex && node.yIndex == startYIndex )
            {
                start = node;
            }
            if( node.xIndex == endXIndex && node.yIndex == endYIndex )
            {
                end = node;
            }
        }
    }

    void SetStartScores( ref Node start )
    {
        start.gScore = 0;

        start.hScore = CalculateHScore( start, end );

        start.fScore = CalculateFScore( start );

    }

    Node GetLowestFScore()
    {
        Node lowest;

        lowest.fScore = 10000;

        foreach( elem; openList )
        {
            if( elem.fScore < lowest.fScore )
                lowest = elem;
        }

        return lowest;
    }

    //This function current sets the program into an infinite loop
    //I still need to debug to figure out why the parent nodes aren't correct
    void GeneratePath()
    {
        while( currentNode.position != start.position )
        {
            Path ~= currentNode;
            currentNode = *currentNode.parent;
        }
    }

    void ReversePath()
    {
        Node[] temp;
        for(int i = Path.length - 1; i >= 0; i-- )
        {
            temp ~= Path[i];
        }
        Path = temp.dup;
    }

    public:
    //@FIXME It seems to find the path, but now performance is terrible
    void FindPath( vect2 vStart, vect2 vEnd, Node[] PathGraph )
    {
        openList.clear;
        closedList.clear;

        SetStartAndEndNode( vStart, vEnd, PathGraph );
        SetStartScores( start );
        AddToList( openList, start );

        while( currentNode.position != end.position )
        {
            currentNode = GetLowestFScore();

            if( currentNode.position == end.position )
                break;
            else
            {
                RemoveFrom( openList, currentNode );
                AddToList( closedList, currentNode );

                for( int i = 0; i < currentNode.connections.length; i++ )
                {
                    if( currentNode.connections[i] is null )
                        continue;
                    else
                    {
                        if( IsInList( closedList, *currentNode.connections[i] ) 
                           && currentNode.gScore < currentNode.connections[i].gScore )
                        {
                            currentNode.connections[i].gScore = currentNode.gScore + connectionCost;
                                 currentNode.connections[i].hScore = abs( currentNode.connections[i].xIndex - end.xIndex ) 
                            + abs(     currentNode.connections[i].yIndex - end.yIndex );
                            currentNode.connections[i].fScore =     currentNode.connections[i].gScore +   currentNode.connections[i].hScore;
                            currentNode.connections[i].parent = &currentNode;
                        }
                        else if( IsInList( openList, *currentNode.connections[i] ) 
                                && currentNode.gScore < currentNode.connections[i].gScore )
                        {
                            currentNode.connections[i].gScore = currentNode.gScore + connectionCost;
                            currentNode.connections[i].hScore = abs( currentNode.connections[i].xIndex - end.xIndex ) 
                            + abs(     currentNode.connections[i].yIndex - end.yIndex );
                            currentNode.connections[i].fScore = currentNode.connections[i].gScore + currentNode.connections[i].hScore;
                            currentNode.connections[i].parent = &currentNode;
                        }
                        else
                        {

                            currentNode.connections[i].gScore = currentNode.gScore + connectionCost;
                            currentNode.connections[i].hScore = abs( currentNode.connections[i].xIndex - end.xIndex ) 
                            + abs( currentNode.connections[i].yIndex - end.yIndex );
                             currentNode.connections[i].fScore = currentNode.connections[i].gScore +     currentNode.connections[i].hScore;
                            currentNode.connections[i].parent = &currentNode;
                            AddToList( openList, *currentNode.connections[i] );
                        }
                    }   
                }
            }
        }

        writeln( "Current Node Position: ", currentNode.position );
        writeln( "End Node Position: ", end.position );

        if( currentNode.position == end.position )
        {
            writeln( "Current Node Parent: ", currentNode.parent );
           //GeneratePath();
           //ReversePath();
        }
    }

    Node[] GetPath()
    {
        return Path;
    }
}
share|improve this question
    
why do you use Node for the lists instead of Node*? –  Trass3r Apr 3 '12 at 20:11

3 Answers 3

up vote 6 down vote accepted

You're using singly-linked lists for both the "open list" and the "closed list", leading to unnecessary linear-time operations.

The former should be a priority queue (heap), while the latter is best implemented as a hash table.

share|improve this answer
    
Ok, I've pretty much figured out how to setup a min-heap, however, i'm not sure how to setup a hash table. I think my only option is an associative array, and from which I read, that's what a hash table is setup with. In this case what would be the hash/key value? –  RedShft Apr 2 '12 at 23:47
    
@RedShft: since you're going to use the associative array as a set, there are only keys, no values. Use the elements you're now storing in your list as keys and use a dummy value, e.g. true. –  larsmans Apr 3 '12 at 9:00

using a unsorted linked list as your data structure for starters

A* relies on a log(n) insert pop and update node for it to work properly

check up on a min heap

share|improve this answer

In implementing Eric Lippert's A-* algorithm, I found no discernible time difference between implementing closed with a HashSet<> (with hash algorithm return x<<16 ^ y) or a bool[Width,Height].

I was able to improve performance by ~40% replacing Eric's PrioirtyQueue<> (implemented using SortedDIctionary<>) with a hand-rolled MinHeap<>. This was for a war-game map of ~420x750 hexes, measuring a few long diagonal paths acrsoss the map.

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