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MLEM/Demos/PathfindingDemo.cs

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4.4 KiB
C#

using System;
using System.Collections.Generic;
using System.Linq;
using Microsoft.Xna.Framework;
using Microsoft.Xna.Framework.Graphics;
using MLEM.Extensions;
using MLEM.Input;
using MLEM.Pathfinding;
using MLEM.Startup;
using MonoGame.Extended;
namespace Demos {
public class PathfindingDemo : Demo {
private bool[,] world;
private AStar2 pathfinder;
private List<Point> path;
public PathfindingDemo(MlemGame game) : base(game) {
}
private void Init() {
// generate a simple random world for testing, where true is walkable area, and false is a wall
var random = new Random();
this.world = new bool[50, 50];
for (var x = 0; x < 50; x++) {
for (var y = 0; y < 50; y++) {
if (random.NextDouble() >= 0.25)
this.world[x, y] = true;
}
}
// Create a cost function, which determines how expensive (or difficult) it should be to move from a given position
// to the next, adjacent position. In our case, the only restriction should be walls and out-of-bounds positions, which
// both have a cost of float.MaxValue, meaning they are completely unwalkable.
// If your game contains harder-to-move-on areas like, say, a muddy pit, you can return a higher cost value for those
// locations. If you want to scale your cost function differently, you can specify a different default cost in your
// pathfinder's constructor
AStar<Point>.GetCost cost = (pos, nextPos) => {
if (nextPos.X < 0 || nextPos.Y < 0 || nextPos.X >= 50 || nextPos.Y >= 50)
return float.MaxValue;
return this.world[nextPos.X, nextPos.Y] ? 1 : float.MaxValue;
};
// Actually initialize the pathfinder with the cost function, as well as specify if moving diagonally between tiles should be
// allowed or not (in this case it's not)
this.pathfinder = new AStar2(cost, false);
// Now find a path from the top left to the bottom right corner and store it in a variable
// If no path can be found after the maximum amount of tries (10000 by default), the pathfinder will abort and return no path (null)
var foundPath = this.pathfinder.FindPath(Point.Zero, new Point(49, 49));
this.path = foundPath != null ? foundPath.ToList() : null;
// print out some info
Console.WriteLine("Pathfinding took " + this.pathfinder.LastTriesNeeded + " tries and "+this.pathfinder.LastTimeNeeded.TotalSeconds+" seconds");
if (this.path == null)
Console.WriteLine("Couldn't find a path, press the left mouse button to try again");
}
public override void LoadContent() {
base.LoadContent();
this.Init();
}
public override void Update(GameTime gameTime) {
base.Update(gameTime);
// when pressing the left mouse button, generate a new world and find a new path
if (this.InputHandler.IsMouseButtonPressed(MouseButton.Left)) {
this.Init();
}
}
public override void DoDraw(GameTime gameTime) {
this.GraphicsDevice.Clear(Color.White);
this.SpriteBatch.Begin(SpriteSortMode.Deferred, null, SamplerState.PointClamp, transformMatrix: Matrix.CreateScale(14));
// draw the world with simple shapes
for (var x = 0; x < 50; x++) {
for (var y = 0; y < 50; y++) {
if (!this.world[x, y]) {
this.SpriteBatch.FillRectangle(new Vector2(x, y), new Size2(1, 1), Color.Black);
}
}
}
// draw the path
// in a real game, you'd obviously make your characters walk along the path instead of drawing it
if (this.path != null) {
for (var i = 1; i < this.path.Count; i++) {
var first = this.path[i - 1];
var second = this.path[i];
this.SpriteBatch.DrawLine(new Vector2(first.X + 0.5F, first.Y + 0.5F), new Vector2(second.X + 0.5F, second.Y + 0.5F), Color.Blue, 0.25F);
}
}
this.SpriteBatch.End();
base.DoDraw(gameTime);
}
}
}