Exemplo n.º 1
0
        public static void updateVertex(SimplePriorityQueue <Spot> openSet, Spot s, Spot succ, Spot start, Spot goal)
        {
            double angle = theta(s.pos, s.parent.pos, succ.pos);

            if (s != start && s.lb <= angle && s.ub >= angle)
            {
                // Path - 2
                if (s.parent.g + s.parent.pos.DistanceTo(succ.pos) < succ.g && s.los)
                {
                    succ.g      = s.parent.g + (float)s.parent.pos.DistanceTo(succ.pos);
                    succ.parent = s.parent;
                    if (openSet.Contains(succ))
                    {
                        openSet.Remove(succ);
                    }
                    succ.f = succ.g + calcHeuristic(succ, goal);
                    openSet.Enqueue(succ, succ.f);
                }
            }
            else
            {
                // Path - 1
                if (s.g + s.pos.DistanceTo(succ.pos) < succ.g && s.los)
                {
                    succ.g      = s.g + (float)s.pos.DistanceTo(succ.pos);
                    succ.parent = s;
                    if (openSet.Contains(succ))
                    {
                        openSet.Remove(succ);
                    }
                    succ.f = succ.g + calcHeuristic(succ, goal);
                    openSet.Enqueue(succ, succ.f);
                }
            }
        }
Exemplo n.º 2
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        public override void Update()
        {
            base.Update();

            //Get next stage's entry limit
            int maxToMoveOn = pipeline.GetStage(StageID + 1).EntryLimit;

            int movedOn = 0;

            //Iterate over queue in order, until at most maxToMoveOn items have been moved on
            foreach (var item in queue)
            {
                if (movedOn >= maxToMoveOn)
                {
                    break;
                }

                if (pipeline.NextStageFreeForChunk(item, StageID))
                {
                    //Just before the chunk would move on, re-check that the preconditions still hold
                    if (CheckAndResolvePreconditionsBeforeExit(item))
                    {
                        MovingOnThisUpdate.Add(item);
                        movedOn++;
                    }
                }
                else
                {
                    //Otherwise, the chunk neither moves on nor terminates, it waits
                    continue;
                }
            }

            //Remove items from the queue when they move on
            foreach (var item in MovingOnThisUpdate)
            {
                queue.Remove(item);
            }

            //Remove items from the queue when they terminate
            foreach (var item in terminatingThisUpdateHelper)
            {
                queue.Remove(item);
            }

            ///Items in the going backwards list have already been removed from the queue,
            ///but we need to make sure they should really be going backwards, not just terminating
            GoingBackwardsThisUpdate.RemoveWhere((id) => TerminateHereCondition(id));

            //Clear the terminating helper list
            terminatingThisUpdateHelper.Clear();
        }
Exemplo n.º 3
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 public void ItemRemoved(TileItem item)
 {
     if (cfg.filter.Applies(item.def))
     {
         if (item.amtAvailable > 0)
         {
             queue.Remove(item);
         }
         else
         {
             unavailable.Remove(item);
         }
     }
 }
Exemplo n.º 4
0
        internal bool UnSubscribeBindModule(Module moudle)
        {
            using (new LockWait(ref _lock))
            {
                Type type = moudle.GetType();
                if (!_dic.ContainsKey(type))
                {
                    Log.E(string.Format("01,Have Not Bind Module | Type {0}  Name {1}", type, moudle.name));
                    return(false);
                }
                else
                {
                    var list = _dic[type];

                    if (!list.ContainsKey(moudle.name))
                    {
                        Log.E(string.Format("02,Have Not Bind Module | Type {0}  Name {1}", type, moudle.name));
                        return(false);
                    }
                    else
                    {
                        _dic[type].Remove(moudle.name);
                        if (_queue.Contains(moudle))
                        {
                            _queue.Remove(moudle);
                        }
                        return(true);
                    }
                }
            }
        }
Exemplo n.º 5
0
 public void DeRegisterEntity(ITimeNode node)
 {
     if (turnQueue.Contains(node))
     {
         turnQueue.Remove(node);
     }
 }
Exemplo n.º 6
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 public void Pause()
 {
     if (_queue.Contains(this))
     {
         _queue.Remove(this);
     }
 }
Exemplo n.º 7
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        public SimplePriorityQueue <Node> GetUnvisitedNeighbors(Node node, List <List <Node> > grid)
        {
            SimplePriorityQueue <Node> neighbors = new SimplePriorityQueue <Node>();
            int row    = node.Row;
            int column = node.Column;

            if (row > 0)
            {
                neighbors.Enqueue(grid[row - 1][column], 1000000);
            }
            if (row < grid.Count - 1)
            {
                neighbors.Enqueue(grid[row + 1][column], 1000000);
            }
            if (column > 0)
            {
                neighbors.Enqueue(grid[row][column - 1], 1000000);
            }
            if (column < grid[0].Count - 1)
            {
                neighbors.Enqueue(grid[row][column + 1], 1000000);
            }
            foreach (Node node1 in neighbors)
            {
                if (node1.IsVisited)
                {
                    neighbors.Remove(node1);
                }
            }
            return(neighbors);
        }
    public void refershNoveltyMapsBatch()
    {
        int i = 0;

        TileObject[,] tmpStrAlias;
        Vector2Int startMainMap = ParameterManager.Instance.StartCell;

        GeneratorUIManager.Instance.deleteMapOnUI(AliasDragAreas[2].GetChild(0));
        AliasDragAreas[2].GetComponent <MapListManager>().dictionaryMap.Clear();

        if (SimilarMapsQueue.Count <= 0)
        {
            GenerateAndTestAliasMaps();
        }

        while (i < BatchAliasNumber)
        {
            tmpStrAlias = SimilarMapsQueue.Last();
            float dst = SimilarMapsQueue.GetPriority(tmpStrAlias);
            SimilarMapsQueue.Remove(tmpStrAlias);

            Utility.renderAliasOnUI(AliasDragAreas[2].GetChild(0).GetComponent <RectTransform>(), ParameterManager.Instance.GridType, new StructuredAlias(tmpStrAlias, startMainMap, ParameterManager.Instance.EndCell, dst), AliasPrefab, true);

            i++;
        }
    }
Exemplo n.º 9
0
        /// <summary>
        /// Generar el árbol SPF de la topología en un proyecto, tomando el parámetro como punto de origen
        /// </summary>
        /// <param name="idRouterOrigen"></param>
        /// <param name="idProyecto"></param>
        /// <returns></returns>
        public static SimplePriorityQueue<NodoDijkstra> GenerarRutas(NodoDijkstra idRouterOrigen, int idProyecto)
        {
            idRouterOrigen.nMinDistancia = 0.0;
            SimplePriorityQueue<NodoDijkstra> routerQueue = new SimplePriorityQueue<NodoDijkstra>();
            routerQueue.Enqueue(idRouterOrigen, 1);

            while (routerQueue.Count > 0)
            {
                NodoDijkstra currentRouter = routerQueue.Dequeue();
                //Visita cada enlace adyacente al router u
                foreach (var enlace in currentRouter.listaEnlaces)
                {
                    NodoDijkstra vecino = new NodoDijkstra(enlace.idRouterB, idProyecto);
                    double nPesoBandwidth = enlace.nBandwidth;
                    double nDistanciaTotal = currentRouter.nMinDistancia + nPesoBandwidth;
                    if (nDistanciaTotal < vecino.nMinDistancia)
                    {
                        routerQueue.Remove(vecino);
                        vecino.nMinDistancia = nDistanciaTotal;
                        vecino.idRouterPrevio = currentRouter;
                        routerQueue.Enqueue(vecino, 1);
                    }
                }
            }
            return routerQueue;
        }
Exemplo n.º 10
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 protected void RemoveFromOpenQueue(SearchNode node)
 {
     if (node.Opened)
     {
         m_openQueue.Remove(node.Pos);
         node.Opened = false;
         node.SetSearchType(SearchType.None, true, true);
     }
 }
 // javadoc: 
 // "Returns true if and only if this queue contained the specified element"
 public bool remove(T t)
 {
     if(!simplePriorityQueue.Contains(t))
     {
         return false; 
     }
     simplePriorityQueue.Remove(t);   
     return true; 
 }
Exemplo n.º 12
0
        /* Function: deleteCircleEvent
         * ---------------------------
         * Deletes a potential circle event associated with a site event
         * from the event queue (it is no longer correct).
         */
        private void deleteCircleEvent(BeachArc arc)
        {
            CircleEvent ce = arc.circleEvent;

            arc.circleEvent = null;
            if (ce != null && sweepLine.Contains(ce))
            {
                sweepLine.Remove(ce);
                usedCircleEvents.Add(ce);
            }
        }
Exemplo n.º 13
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 public IEnumerable <IJob> Pop(Predicate <IJob> predicate)
 {
     lock (queue)
     {
         IEnumerable <IJob> matchedJobs = queue.Where(job => predicate(job));
         foreach (IJob job in matchedJobs)
         {
             queue.Remove(job);
         }
         return(matchedJobs);
     }
 }
Exemplo n.º 14
0
 /// <summary>
 /// remove "state" from open list and add it again with new priority
 /// </summary>
 /// <param name="state">the "state" that we change his priority</param>
 /// <param name="priority">the new priority of "state"</param>
 public void RemoveAndAddElementToOpenList(State <T> state, float priority)
 {
     foreach (State <T> var in openList)
     {
         if (var.Equals(state))
         {
             openList.Remove(var);
             openList.Enqueue(state, priority);
             return;
         }
     }
 }
    private bool RemoveFromQueue(AudioMixerSnapshot i_Snapshot)
    {
        AudioMixerSnapshotData snapshotData = GetDataFromQueue(i_Snapshot);

        if (snapshotData == null)
        {
            return(false);
        }

        m_Queue.Remove(snapshotData);
        return(true);
    }
Exemplo n.º 16
0
        /// <summary>
        /// The search command searches a searchable domain using the BFS algorithm
        /// </summary>
        /// <param name="domain">The search domain</param>
        /// <returns>The solution to the problem</returns>
        public Solution <T> search(ISearchable <T> domain)
        {
            openList = new SimplePriorityQueue <State <T> >();
            closed   = new HashSet <State <T> >();

            // We use a dictionary to hold the states in addition to the PriorityQueue to allow
            // random 'get' in O(1), a function not supported by Priority Queues (Space complexity is
            // now 2n as opposed to n).
            openListContains = new Dictionary <State <T>, double>();

            // We add the inital state to the list of states to check
            addNode(domain.getInitialState());

            while (openList.Count > 0)
            {
                State <T> nextNode = RemoveTopNode();
                // If we have reached the goal state, we generate the traceback and return it as a
                // solution
                if (nextNode.Equals(domain.getGoalState()))
                {
                    return(Backtrace(nextNode, numberOfEvaluations));
                }

                // getPossibleStates intializes our states, and assigns the predecessors as needed
                List <State <T> > followingNodes = domain.getPossibleStates(nextNode);
                foreach (State <T> node in followingNodes)
                {
                    // If the node isn't in the open list we add it - as long as its not in the closed
                    // list
                    if (!openListContains.ContainsKey(node))
                    {
                        if (!closed.Contains(node))
                        {
                            addNode(node);
                        }
                    }
                    // If the node is in the open list already, if we have found a cheaper path to it
                    // Then we update the predecessor node and its cost.
                    else
                    {
                        if (openListContains[node] > node.cost)
                        {
                            openList.Remove(node);
                            openListContains[node] = node.cost;
                            addNode(node);
                        }
                    }
                }
            }
            // If we reach here, there is no path to the destination
            return(null);
        }
Exemplo n.º 17
0
    public bool RemoveTargetTree(TreeScript tree)
    {
        if (!AreAvailableTreesInSanctuary())
        {
            return(false);
        }

        if (!TreesPriorityQueue.Contains(tree))
        {
            Debug.Log($"{tree.gameObject}Tree is not in the list of trees");
            return(false);
        }

        TreesPriorityQueue.Remove(tree);
        return(true);
    }
Exemplo n.º 18
0
 /// <summary>
 ///
 /// </summary>
 /// <param name="elapsed">time since update was last called, in microseconds</param>
 public void Update(double elapsed)
 {
     if (Playing)
     {
         Time += elapsed / Tempo * PPQ;
         while (tasks.Count > 0)
         {
             Scheduled nxt = tasks.First;
             if (tasks.GetPriority(nxt) > Time)
             {
                 break;
             }
             nxt();
             tasks.Remove(nxt);
         }
     }
 }
Exemplo n.º 19
0
 public void UCSearch(int v, int g, bool[] visited, ref int[] parent)
 {
     SimplePriorityQueue<int, int> open = new SimplePriorityQueue<int, int>(); // Orders elements in an ascending order by weight.
     int[] cost = new int[size]; // Stores the least cost for all nodes starting with the start node until the goal node.
     for (int i = 0; i < size; i++)
     {
         cost[i] = 0;
     }
     open.Enqueue(v, 0);
     while (open.Count > 0)
     {
         int x = open.Dequeue();
         visited[x] = true; // We mark the visited node here since UCS only expands the node with the least cost
         if (x == g)
         {
             return;
         }
         for (int i = 0; i < adj[x].Count; i++)
         {
             if (!open.Contains(adj[x][i]) && !visited[adj[x][i]]) // Adding nodes with their costs too the Queue
             {
                 parent[adj[x][i]] = x;
                 cost[adj[x][i]] = cost[x] + weight[x][i];
                 open.Enqueue(adj[x][i], cost[adj[x][i]]);
             }
             else if (open.Contains(adj[x][i])) // Updates the cost of a node in case a new path is found
             {
                 int temp = cost[adj[x][i]];
                 cost[adj[x][i]] = Math.Min(cost[adj[x][i]], (cost[x] + weight[x][i]));
                 if (cost[adj[x][i]] < temp) // If the new path has a smaller cost, then update the node and push it back to Queue
                 {
                     parent[adj[x][i]] = x; // Update the parent in case a less-cost path is found.
                     open.Remove(adj[x][i]);
                     open.Enqueue(adj[x][i], cost[adj[x][i]]);
                 }
             }
         }
     } // End of while
 } // End of UCSearch function
Exemplo n.º 20
0
    public int LabyrinthPath(Tile startTile, Tile startBoundaryTile, ref SimplePriorityQueue <Tile> potentialStarts)
    {
        Tile        next             = startTile;
        Tile        nextBoundaryTile = startBoundaryTile;
        Stack <int> quadrants        = new Stack <int>();

        quadrants.Push(Quadrant(next, startBoundaryTile));

        int count             = 0;
        int maxLabyrinthCount = 1000;

        do
        {
            LabyrinthStep(startTile, startBoundaryTile, ref next, ref nextBoundaryTile, ref quadrants);
            if (potentialStarts.Contains(next))
            {
                potentialStarts.Remove(next);
            }
        }while ((next != startTile || startBoundaryTile != nextBoundaryTile) && count++ < maxLabyrinthCount);

        // Winding number
        Debug.Log(String.Format("Winding number is {0}", quadrants.Count));
        return(quadrants.Count / 4);
    }
Exemplo n.º 21
0
        public void CancelAssetsAsync(int index)
        {
            if (!resultDic.TryGetValue(index, out var result))
            {
                return;
            }
            if (result.IsDone())
            {
                return;
            }
            if (requestDic.TryGetValue(result.ID, out var request))
            {
                if (waitingRequestQueue.Contains(request))
                {
                    waitingRequestQueue.Remove(request);
                }
                else if (runningRequestList.Contains(request))
                {
                    runningRequestList.Remove(request);
                    foreach (var assetPath in request.paths)
                    {
                        if (assetNodeDic.TryGetValue(assetPath, out var assetNode))
                        {
                            assetNode.ReleaseRef();
                        }
                        else
                        {
                            Debug.LogError("");
                        }
                    }
                    OnAsyncRequestCancel(request);
                }

                requestDic.Remove(request.id);
            }
        }
Exemplo n.º 22
0
    public List <Node> FindPath(Node start, Node goal)
    {
        start.fScore = start.DistanceTo(goal);

        SimplePriorityQueue <Node> open = new SimplePriorityQueue <Node>();

        open.Enqueue(start, start.fScore);

        List <Node> closed = new List <Node>();

        Dictionary <Node, float> gscores = new Dictionary <Node, float>();


        while (open.Count != 0)
        {
            Node current = open.Dequeue();


            if (current.Equals(goal))
            {
                return(ReconstructPath(current));
            }


            closed.Add(current);

            foreach (Node neighbor in Neighbors(current))
            {
                if (closed.Contains(neighbor))
                {
                    continue;
                }

                float tempGscore = current.gScore + world.Map.TileCost(neighbor);

                if (neighbor.DistanceTo(current) > 1)
                {
                    tempGscore += neighbor.sqrt2;
                }

                if (open.Contains(neighbor))
                {
                    if (gscores[neighbor] <= tempGscore)
                    {
                        continue;
                    }
                    else
                    {
                        open.Remove(neighbor);
                    }
                }

                neighbor.gScore   = tempGscore;
                neighbor.fScore   = tempGscore + neighbor.DistanceTo(goal, true);
                neighbor.CameFrom = current;

                gscores[neighbor] = neighbor.gScore;
                open.Enqueue(neighbor, neighbor.fScore);
            }
        }

        return(new List <Node>());
    }
Exemplo n.º 23
0
        public List <PathNode> GetPath(Vector3Int from, Vector3Int to)
        {
            // We will allow paths that start and end at map objects but NOT go through them.

            // If the from and to are the same, then the path is just the from
            if (from == to)
            {
                return new List <PathNode> {
                           from
                }
            }
            ;

            // Visited will store black nodes
            HashSet <PathNode>             visited = new HashSet <PathNode>();
            SimplePriorityQueue <PathNode> queue   = new SimplePriorityQueue <PathNode>();

            queue.Enqueue(from, 0);

            while (queue.Count > 0)
            {
                // Getting a node from the queue means that there is no better path to this
                // node. This means that it is done being visited, so we can turn it black and
                // add it to the visited set.
                PathNode current = queue.Dequeue();

                visited.Add(current);

                if (current.x == to.x && current.y == to.y)
                {
                    List <PathNode> path = new List <PathNode>();
                    while (current != null)
                    {
                        path.Insert(0, current);
                        current = current.prev;
                    }
                    return(path);
                }

                for (int x = current.x - 1; x <= current.x + 1; x++)
                {
                    for (int y = current.y - 1; y <= current.y + 1; y++)
                    {
                        if (x == current.x && y == current.y)
                        {
                            continue;                                   // Skip center
                        }
                        if (x != current.x && y != current.y)
                        {
                            continue;                                   // Skip diagonals
                        }
                        PathNode next = new PathNode {
                            x = x, y = y, prev = current, cost = current.cost + 1
                        };

                        if (level.IsMapObject(next) && !(next.x == to.x && next.y == to.y))
                        {
                            continue;                                                                 // Skip map objects unless it's the goal
                        }
                        if (level.IsOutOfBounds(next))
                        {
                            continue;                            // Skip out of bounds locations
                        }
                        // Gray node - in the middle of processing
                        if (queue.Contains(next))
                        {
                            if (queue.GetPriority(next) > next.cost)
                            {
                                queue.Remove(next);
                                queue.Enqueue(next, next.cost);
                            }
                        }
                        // White node - never seen before
                        else if (!visited.Contains(next))
                        {
                            queue.Enqueue(next, next.cost);
                        }
                    }
                }
            }

            return(null);
        }
    }
Exemplo n.º 24
0
 public void Unsubscribe(Object subscriber, Action <Object, TEventArgs> a)
 {
     subscribers.Remove(subscribers.First(x => x.Key.Equals(subscriber) && x.Value.Equals(a)));
 }
Exemplo n.º 25
0
        public static LinkedList <T> AStar <T>(T fromVertice, T toVertice) where T : IVertice
        {
            if (fromVertice == null || toVertice == null)
            {
                Debug.LogError("fromVertice: " + (fromVertice == null ? "null" : "ref") + " toVertice: " +
                               (toVertice == null ? "null" : "ref"));
                return(new LinkedList <T>());
            }

            var closedSet = new List <T>();
            var openSet   = new SimplePriorityQueue <T, float>(); // new List<T>();

            openSet.Enqueue(fromVertice, 0f);
            var cameFrom = new Dictionary <T, T>();

            var gScore = new Dictionary <T, float> {
                [fromVertice] = 0f
            };

            var fScore = new Dictionary <T, float> {
                [fromVertice] = HeuristicCostEstimate(fromVertice, toVertice)
            };

            while (openSet.Count > 0)
            {
                var currentVertice = openSet.First();
                if (currentVertice.Equals(toVertice))
                {
                    return(ReconstructPath(cameFrom, currentVertice));
                }

                openSet.Remove(currentVertice);
                closedSet.Add(currentVertice);

                foreach (T neighborVertice in currentVertice.Neighbors)
                {
                    if (closedSet.Contains(neighborVertice))
                    {
                        continue;
                    }

                    var tentativeGScore = gScore[currentVertice] + Vector3.Distance(currentVertice.Position, neighborVertice.Position);

                    if (openSet.Contains(neighborVertice) && tentativeGScore >= gScore[neighborVertice])
                    {
                        continue;
                    }

                    cameFrom[neighborVertice] = currentVertice;
                    gScore[neighborVertice]   = tentativeGScore;
                    fScore[neighborVertice]   = gScore[neighborVertice] +
                                                HeuristicCostEstimate(neighborVertice, toVertice);

                    if (openSet.Contains(neighborVertice))
                    {
                        openSet.Remove(neighborVertice);
                    }

                    openSet.Enqueue(neighborVertice, fScore[neighborVertice]);
                }
            }

            return(new LinkedList <T>());
        }
Exemplo n.º 26
0
        /// <summary>
        /// Generar y retornar el árbol SPF de la topología en un proyecto, tomando el parámetro como punto de origen
        /// </summary>
        /// <param name="idRouterOrigen"></param>
        /// <param name="idProyecto"></param>
        /// <param name="minBW"></param>
        /// <returns></returns>
        public static List<NodoDijkstra> GenerarRutas(NodoDijkstra idRouterOrigen, int idProyecto, double minBW, int nTipoMetrica = 2, int idAfinidad = 0)
        {
            idRouterOrigen.nMinDistancia = 0.0;
            SimplePriorityQueue<NodoDijkstra> routerQueue = new SimplePriorityQueue<NodoDijkstra>();
            routerQueue.Enqueue(idRouterOrigen, 1);

            //mantiene el registro de todos los nodos de la topologia por el que se pasa
            List<NodoDijkstra> routerList = new List<NodoDijkstra>();
            routerList.Add(idRouterOrigen);

            while (routerQueue.Count > 0)
            {
                NodoDijkstra currentRouter = routerQueue.Dequeue();
                //Visita cada enlace adyacente al router u
                foreach (var enlace in currentRouter.listaEnlacesDijkstra)
                {
                    int idRouterVecino = 0;
                    //Fix: Asegurandose de que se use el id del router adyacente en el enlace
                    if (enlace.idRouterB != currentRouter.idRouter)
                    {
                        idRouterVecino = enlace.idRouterB;
                        //enlace.target = enlace.targetB;
                    }
                    else
                    {
                        idRouterVecino = enlace.idRouterA;
                        //enlace.target = enlace.targetA;
                    }
                    //NodoDijkstra vecino = new NodoDijkstra(idRouterVecino, idProyecto);

                    NodoDijkstra vecino = enlace.target;

                    double nPesoBandwidth = 0;
                    switch(nTipoMetrica)        //ignore var name, aqui va lo del tipo de peso
                    {
                        case 1: //Pesos Administrativos
                            nPesoBandwidth = enlace.nPesoAdministrativo;
                            break;
                        case 2: //Minima Cantidad de Saltos
                            nPesoBandwidth = 1;
                            break;
                        case 3: // 1/BW Reservado
                            nPesoBandwidth = 1.00 / (enlace.nBandwidth - enlace.nBandwidthDisponible);
                            break;
                        case 4: // 1/BW Disponible
                            nPesoBandwidth = 1.00 / enlace.nBandwidthDisponible;
                            break;
                        default:
                            nPesoBandwidth = 1;
                            break;
                    }

                    double nDistanciaTotal = currentRouter.nMinDistancia + nPesoBandwidth;

                    //Aqui ocurre el filtro por afinidad
                    if (idAfinidad == 0)    //No afinidad definida
                    {
                        //En este if ocurre el filtro por BW disponible
                        if (nDistanciaTotal < vecino.nMinDistancia && minBW < enlace.nBandwidth) //Constraint check
                        {
                            if (routerQueue.Contains(vecino))
                                routerQueue.Remove(vecino);
                            vecino.nMinDistancia = nDistanciaTotal;
                            vecino.idRouterPrevio = currentRouter;
                            enlace.nBandwidthDisponible -= minBW; //reservar el BW en el enlace

                            routerQueue.Enqueue(vecino, 1);
                        }
                    }
                    else  //Afinidad definida
                    {
                        if (idAfinidad == enlace.idAfinidad)    //Afinidad check
                        {
                            //En este if ocurre el filtro por BW disponible
                            if (nDistanciaTotal < vecino.nMinDistancia && minBW < enlace.nBandwidth) //Constraint check
                            {
                                if (routerQueue.Contains(vecino))
                                    routerQueue.Remove(vecino);
                                vecino.nMinDistancia = nDistanciaTotal;
                                vecino.idRouterPrevio = currentRouter;
                                enlace.nBandwidthDisponible -= minBW; //reservar el BW en el enlace

                                routerQueue.Enqueue(vecino, 1);
                            }
                        }
                    }

                    //Agrega el router (bueno, los 2) al registro
                    int indexTarget = routerList.FindIndex(n => n.idRouter == vecino.idRouter);
                    if (indexTarget != -1)
                        routerList[indexTarget] = vecino;
                    else
                        routerList.Add(vecino);
                    int indexSource = routerList.FindIndex(n => n.idRouter == currentRouter.idRouter);
                    if (indexSource != -1)
                        routerList[indexSource] = currentRouter;
                    else
                        routerList.Add(currentRouter);

                }
            }
            return routerList;
        }
Exemplo n.º 27
0
 private void RemoveFromOpen(SearchNode node)
 {
     m_open.Remove(node);
     node.Opened = false;
     node.SetSearchType(SearchType.Expanded, true, true);
 }
Exemplo n.º 28
0
        public static Mesh Simplify(this Mesh originalMesh, int targetCount)
        {
            // gather distinct vertices
            Dictionary <Vector3, Vertex> vectorVertex = new Dictionary <Vector3, Vertex>(originalMesh.vertexCount);

            foreach (Triangle t in originalMesh.tris)
            {
                AddVertex(t.v1, vectorVertex);
                AddVertex(t.v2, vectorVertex);
                AddVertex(t.v3, vectorVertex);
            }

            // accumulate quadric matrices for each vertex based on its faces
            // assign initial quadric
            foreach (Triangle t in originalMesh.tris)
            {
                Matrix q  = t.Quadric();
                Vertex v1 = vectorVertex[t.v1];
                Vertex v2 = vectorVertex[t.v2];
                Vertex v3 = vectorVertex[t.v3];

                v1.Quadric = v1.Quadric.Add(q);
                v2.Quadric = v2.Quadric.Add(q);
                v3.Quadric = v3.Quadric.Add(q);
            }

            //vertex -> face map
            Dictionary <Vertex, List <Face> > vertexFaces = new Dictionary <Vertex, List <Face> >(originalMesh.vertexCount);

            foreach (Triangle t in originalMesh.tris)
            {
                Vertex v1 = vectorVertex[t.v1];
                Vertex v2 = vectorVertex[t.v2];
                Vertex v3 = vectorVertex[t.v3];

                Face f = new Face(v1, v2, v3);

                vertexFaces.AppendEx(v1, f);
                vertexFaces.AppendEx(v2, f);
                vertexFaces.AppendEx(v3, f);
            }

            System.Diagnostics.Stopwatch sw = System.Diagnostics.Stopwatch.StartNew();
            //gather distinct pairs
            Dictionary <Pair.Key, Pair> pairs = new Dictionary <Pair.Key, Pair>(originalMesh.trisCount);

            foreach (Triangle t in originalMesh.tris)
            {
                Vertex v1 = vectorVertex[t.v1];
                Vertex v2 = vectorVertex[t.v2];
                Vertex v3 = vectorVertex[t.v3];

                var one = sw.ElapsedMilliseconds;

                pairs.AddPair(v1, v2);
                pairs.AddPair(v2, v3);
                pairs.AddPair(v1, v3);
            }
            Console.WriteLine($"total: {sw.ElapsedMilliseconds}");

            Dictionary <Vertex, List <Pair> > vertexPairs = new Dictionary <Vertex, List <Pair> >(originalMesh.vertexCount);

            foreach (KeyValuePair <Pair.Key, Pair> p in pairs)
            {
                vertexPairs.AppendEx(p.Value.A, p.Value);
                vertexPairs.AppendEx(p.Value.B, p.Value);
            }

            var priorityQueue = new SimplePriorityQueue <Pair, float>(CompFloats);

            foreach (KeyValuePair <Pair.Key, Pair> item in pairs)
            {
                item.Value.Error();
                priorityQueue.Enqueue(item.Value, item.Value.CachedError);
            }

            //take best pair
            int currentFaceCount = originalMesh.tris.Length;
            int targetFaceCount  = targetCount;

            while (currentFaceCount > targetFaceCount && priorityQueue.Count > 0)
            {
                //best pair
                Pair p = priorityQueue.Dequeue();

                if (p.Removed)
                {
                    continue;
                }

                p.Removed = true;

                //get distinct faces
                var distinctFaces = new HashSet <Face>();
                if (vertexFaces.ContainsKey(p.A))
                {
                    foreach (var f in vertexFaces[p.A])
                    {
                        if (!f.Removed)
                        {
                            if (!distinctFaces.Contains(f))
                            {
                                distinctFaces.Add(f);
                            }
                        }
                    }
                }

                if (vertexFaces.ContainsKey(p.B))
                {
                    foreach (var f in vertexFaces[p.B])
                    {
                        if (!f.Removed)
                        {
                            if (!distinctFaces.Contains(f))
                            {
                                distinctFaces.Add(f);
                            }
                        }
                    }
                }

                //get related pairs
                var distintPairs = new HashSet <Pair>();
                if (vertexPairs.ContainsKey(p.A))
                {
                    foreach (var q in vertexPairs[p.A])
                    {
                        if (!q.Removed)
                        {
                            if (!distintPairs.Contains(q))
                            {
                                distintPairs.Add(q);
                            }
                        }
                    }
                }

                if (vertexPairs.ContainsKey(p.B))
                {
                    foreach (var q in vertexPairs[p.B])
                    {
                        if (!q.Removed)
                        {
                            if (!distintPairs.Contains(q))
                            {
                                distintPairs.Add(q);
                            }
                        }
                    }
                }

                //create new vertex
                Vertex v = new Vertex(p.Vector(), p.Quadric());

                //updateFaces
                var  newFaces = new List <Face>();
                bool valid    = true;
                foreach (var f in distinctFaces)
                {
                    var(v1, v2, v3) = (f.V1, f.V2, f.V3);

                    if (v1 == p.A || v1 == p.B)
                    {
                        v1 = v;
                    }

                    if (v2 == p.A || v2 == p.B)
                    {
                        v2 = v;
                    }

                    if (v3 == p.A || v3 == p.B)
                    {
                        v3 = v;
                    }

                    var face = new Face(v1, v2, v3);

                    if (face.Degenerate)
                    {
                        continue;
                    }

                    if (face.Normal().Dot(f.Normal()) < 1e-3)
                    {
                        valid = false;
                        break;
                    }

                    newFaces.Add(face);
                }

                if (!valid)
                {
                    continue;
                }

                if (vertexFaces.ContainsKey(p.A))
                {
                    vertexFaces.Remove(p.A);
                }

                if (vertexFaces.ContainsKey(p.B))
                {
                    vertexFaces.Remove(p.B);
                }

                foreach (var f in distinctFaces)
                {
                    f.Removed = true;
                    currentFaceCount--;
                }

                foreach (var f in newFaces)
                {
                    currentFaceCount++;
                    vertexFaces.AppendEx(f.V1, f);
                    vertexFaces.AppendEx(f.V2, f);
                    vertexFaces.AppendEx(f.V3, f);
                }

                if (vertexPairs.ContainsKey(p.A))
                {
                    vertexPairs.Remove(p.A);
                }

                if (vertexPairs.ContainsKey(p.B))
                {
                    vertexPairs.Remove(p.B);
                }

                var seen = new Dictionary <Vector3, bool>();

                foreach (var q in distintPairs)
                {
                    q.Removed = true;
                    priorityQueue.Remove(q);
                    var(a, b) = (q.A, q.B);

                    if (a == p.A || a == p.B)
                    {
                        a = v;
                    }
                    if (b == p.A || b == p.B)
                    {
                        b = v;
                    }
                    if (b == v)
                    {
                        (a, b) = (b, a);
                        // a = v
                    }
                    if (seen.ContainsKey(b.Vector3) && seen[b.Vector3])
                    {
                        //ignore duplicates
                        continue;
                    }
                    if (!seen.ContainsKey(b.Vector3))
                    {
                        seen.Add(b.Vector3, true);
                    }
                    else
                    {
                        seen[b.Vector3] = true;
                    }

                    var np = new Pair(a, b);
                    np.Error();
                    priorityQueue.Enqueue(np, np.CachedError);

                    vertexPairs.AppendEx(a, np);
                    vertexPairs.AppendEx(b, np);
                }
            }

            //gather distinct faces
            var finalDistinctFaces = new HashSet <Face>();

            foreach (var faces in vertexFaces)
            {
                foreach (var face in faces.Value)
                {
                    if (!face.Removed)
                    {
                        if (!finalDistinctFaces.Contains(face))
                        {
                            finalDistinctFaces.Add(face);
                        }
                    }
                }
            }

            //create final mesh
            Mesh newMesh = new Mesh
            {
                tris = finalDistinctFaces.Select(x => new Triangle(x.V1.Vector3, x.V2.Vector3, x.V3.Vector3)).ToArray()
            };

            return(newMesh);
        }
Exemplo n.º 29
0
        public Action[] Solve(HelirinState init, int min_life_score)
        {
            if (cost_maps == null || init == null)
            {
                return(null);
            }
            SimplePriorityQueue <HelirinState>   q         = new SimplePriorityQueue <HelirinState>();
            Dictionary <HelirinState, StateData> data      = new Dictionary <HelirinState, StateData>();
            Dictionary <HelirinState, int>       life_data = null;

            if (!Settings.allow_state_visit_with_less_life && Settings.invul_frames >= 0 && Settings.full_life >= 2)
            {
                life_data = new Dictionary <HelirinState, int>();
            }

            // Set range of possible inputs
            int min_input = 0;

            if (Settings.min_ab_speed == 1)
            {
                min_input = 1;
            }
            else if (Settings.min_ab_speed == 2)
            {
                min_input = 9;
            }
            else if (Settings.min_ab_speed == 3)
            {
                min_input = 17;
            }
            else if (Settings.min_ab_speed > 3)
            {
                min_input = 25;
            }

            // Init
            HelirinState norm_init  = NormaliseState(init);
            float        cost       = GetCost(init.xpos, init.ypos, init.life, init.invul, init.HasBonus());
            float        weight     = 0;
            float        total_cost = cost + weight;

            q.Enqueue(norm_init, total_cost);
            data.Add(norm_init, new StateData(init, weight, cost, null, null, false));
            if (life_data != null)
            {
                life_data.Add(ClearLifeDataOfState(norm_init), Flooding.GetRealInvul(init.life, init.invul));
            }

            // ProgressBar and preview settings
            float init_cost = cost;

            bool[,] preview = new bool[cost_maps[0][0].Get(true).Height, cost_maps[0][0].Get(true).Width];
            int since_last_update = 0;

            // A*
            HelirinState result = null;

            while (q.Count > 0 && result == null)
            {
                HelirinState norm_st = q.Dequeue();
                StateData    st_data = data[norm_st];
                st_data.already_treated = true;
                weight = st_data.weight + 1;

                // ProgressBar and preview settings
                preview[Physics.pos_to_px(st_data.exact_state.ypos) - f.PixelStart.y, Physics.pos_to_px(st_data.exact_state.xpos) - f.PixelStart.x] = true;
                since_last_update++;
                if (since_last_update >= Settings.nb_iterations_before_ui_update)
                {
                    since_last_update = 0;
                    parent.UpdateProgressBarAndHighlight(100 - st_data.cost * 100 / init_cost, preview);
                }

                for (int i = 24; i >= min_input; i--)
                {
                    Action       a        = (Action)i;
                    HelirinState nst      = p.Next(st_data.exact_state, a);
                    HelirinState norm_nst = NormaliseState(nst);

                    // Lose / Not enough life / Out of search space ?
                    int life_score = Flooding.GetRealInvul(nst.life, nst.invul);
                    if (nst.gs == GameState.Lose || (life_score < min_life_score && life_score >= 0) || IsOutOfSearchSpace(nst.xpos, nst.ypos))
                    {
                        continue;
                    }

                    // Already enqueued with more life ?
                    HelirinState cleared_nst = null;
                    if (life_data != null)
                    {
                        cleared_nst = ClearLifeDataOfState(norm_nst);
                        int old_life_score;
                        life_data.TryGetValue(cleared_nst, out old_life_score); // Default value for 'old_life_score' (type int) is 0.
                        if (old_life_score > life_score)
                        {
                            continue;
                        }
                    }

                    // Already visited ?
                    // If the state was already visited, we should not add it to the queue again! Otherwise it could overwrite the state entry and corrupt some paths.
                    StateData old;
                    data.TryGetValue(norm_nst, out old); // Default value for 'old' (type StateData) is null.
                    if (old != null && old.already_treated)
                    {
                        continue;
                    }

                    // Keep only if it is a non-infinite better cost
                    cost = GetCost(nst.xpos, nst.ypos, nst.life, nst.invul, nst.HasBonus());
                    if (cost >= float.PositiveInfinity)
                    {
                        continue;
                    }
                    total_cost = cost + weight;
                    if (old != null && total_cost >= old.cost + old.weight)
                    {
                        continue;
                    }

                    // Is the state terminal without having completed the objective?
                    if (cost > 0 && nst.IsTerminal())
                    {
                        continue;
                    }

                    // Everything's okay, we add the config to the data and queue

                    StateData nst_data = new StateData(nst, weight, cost, a, norm_st, false);
                    data[norm_nst] = nst_data;
                    if (life_data != null)
                    {
                        life_data[cleared_nst] = life_score;
                    }

                    // Target reached ? We look at the cost rather than the game state, because the target can be different than winning
                    if (cost <= 0)
                    {
                        result = norm_nst;
                        break;
                    }

                    // We don't use UpdatePriority because it does not change the InsertionIndex (first-in, first-out)
                    if (old != null)
                    {
                        q.Remove(norm_nst);
                    }
                    q.Enqueue(norm_nst, total_cost);

                    /*
                     * if (old == null)
                     *  q.Enqueue(norm_nst, total_cost);
                     * else
                     *  q.UpdatePriority(norm_nst, total_cost);
                     */
                }
            }

            // Retrieve full path
            if (result == null)
            {
                return(null);
            }
            List <Action> res = new List <Action>();

            while (result != null)
            {
                StateData sd = data[result];
                if (sd.action.HasValue)
                {
                    res.Add(sd.action.Value);
                }
                result = sd.previous_state;
            }
            res.Reverse();
            return(res.ToArray());
        }
Exemplo n.º 30
0
    private void Update()
    {
        int chunkX = Mathf.FloorToInt(player.position.x / chunkSize);
        int chunkZ = Mathf.FloorToInt(player.position.z / chunkSize);

        //Updating the chunks to be updated in the player's view
        //--> Adding the elements in a priority queue which will be updated with a coroutine
        if (chunkX != lastChunkPos.x || chunkZ != lastChunkPos.y)
        {
            //Removing the chunks out of player's view
            foreach (Chunk chunk in loadedChunks)
            {
                Vector2 chunkPos = chunk.GetPosFromMiddle();

                /*if (player.position.x / 16 != lastChunkPos.x || player.position.z / 16 != lastChunkPos.y)
                 * {
                 *  Debug.Log(Math.Abs(chunkPos.x - player.position.x / 16));
                 *  Debug.Log(Math.Abs(chunkPos.y - player.position.z / 16));
                 * }*/


                if (Math.Abs(chunkPos.x - player.position.x / chunkSize) > viewDistance + 2 || Math.Abs(chunkPos.y - player.position.z / chunkSize) > viewDistance + 2)
                {
                    chunkToDestroy.Enqueue(chunk, chunkToDestroy.Count);
                }
            }

            int minx = -viewDistance + (int)(player.position.x / chunkSize);
            int maxx = viewDistance + (int)(player.position.x / chunkSize);
            int minz = -viewDistance + (int)(player.position.z / chunkSize);
            int maxz = viewDistance + (int)(player.position.z / chunkSize);

            for (int i = minx; i < maxx; i++)
            {
                for (int j = minz; j < maxz; j++)
                {
                    Chunk toLoad = world.GenerateOrGetFromMiddle(i, j);
                    if (chunkToDestroy.Contains(toLoad))
                    {
                        chunkToDestroy.Remove(toLoad);
                        //Debug.Log("ToBeDestroyed removed chunk : " + toLoad.GetPosFromMiddle().x + " / " + toLoad.GetPosFromMiddle().y);
                    }

                    if (!loadedChunks.Contains(toLoad) && !loadedMeshes.ContainsKey(toLoad))
                    {
                        chunkPriority.Enqueue(toLoad, chunkPriority.Count);
                    }
                }
            }
            lastChunkPos.x = chunkX;
            lastChunkPos.y = chunkZ;


            //Debug.Log("To be destroyed : " + chunkToDestroy.Count);
            //Debug.Log("To be loaded : " + chunkPriority.Count);

            while (chunkToDestroy.Count > 0)
            {
                Chunk chunk = chunkToDestroy.Dequeue();
                loadedChunks.Remove(chunk);
                if (loadedMeshes.ContainsKey(chunk))
                {
                    GameObject mesh = loadedMeshes[chunk];
                    Destroy(mesh);
                }
                loadedMeshes.Remove(chunk);
                //Debug.Log("Removed chunk : " + chunk.GetPosFromMiddle().x + " / " + chunk.GetPosFromMiddle().y);
            }
            StartCoroutine(LoadAwaitingChunks());
        }
    }
    private static PathfindingResult RunPathfinder(Axial start, Axial end)
    {
        SimplePriorityQueue <Node> openNodes   = new SimplePriorityQueue <Node>();
        Dictionary <Axial, Node>   closedNodes = new Dictionary <Axial, Node>();

        Node startNode = new Node(start, 0, GetHeuristic(start, end));
        Node current   = null;

        openNodes.Enqueue(startNode, startNode.Cost);

        while (openNodes.Count > 0)
        {
            current = openNodes.Dequeue();
            closedNodes.Add(current.Position, current);

            if (current == end) // Reached end
            {
                break;
            }

            foreach (AxialDirection direction in AxialDirection.AllDirections)
            {
                Axial neighborPosition = current.Position + direction;

                if (!Utility.IsAxialPositionWalkable(neighborPosition))
                {
                    continue;
                }

                float newNeighborCost = current.Cost + GetMovementCost(current, direction);
                float heuristic       = GetHeuristic(neighborPosition, end);
                Node  neighbor        = new Node(neighborPosition, newNeighborCost, heuristic, current);

                // Update surrounding nodes if we have a better path, even if they've already been evaluated
                if (openNodes.Contains(neighbor))
                {
                    // The heuristic is deterministic, so this will get us the pure cost of the node
                    float currentCost = openNodes.GetPriority(neighbor) - heuristic;

                    if (newNeighborCost < currentCost)
                    {
                        openNodes.Remove(neighbor);
                    }
                }
                if (closedNodes.ContainsKey(neighborPosition))
                {
                    float currentCost = closedNodes[neighborPosition].Cost;
                    if (newNeighborCost < currentCost)
                    {
                        closedNodes.Remove(neighborPosition);
                    }
                }

                // Add them to the queue if applicable
                if (!openNodes.Contains(neighbor) && !closedNodes.ContainsKey(neighbor.Position))
                {
                    openNodes.Enqueue(neighbor, neighbor.FullValue);
                }
            }
        }

        return(CalculateResults(current));

        PathfindingResult CalculateResults(Node endNode)
        {
            if (endNode == null)
            {
                Debug.LogError($"Couldn't calculate path between {start} and {end}");
                return(null);
            }

            PathfindingResult result = new PathfindingResult()
            {
                OpenNodes   = openNodes,
                CloesdNodes = closedNodes,
            };

            result.FinishedPath = new LinkedList <Vector2>();
            result.FinishedPath.AddFirst(endNode);

            Node currentNode = endNode;

            while (currentNode.Parent != null)
            {
                currentNode = closedNodes[currentNode.Parent.Value];
                result.FinishedPath.AddFirst(currentNode);
            }

            // We're already in the first node, walking to it would just force us to walk to the center of the node, and we don't want that.
            result.FinishedPath.RemoveFirst();

            return(result);
        }
    }
Exemplo n.º 32
0
 private void Delete(SearchNode X)
 {
     m_openQueue.Remove(X);
     X.Closed = true;
 }