7a99ff254f
+ Adding Width/Height/Position/RealPosition to DrawableAxiosGameObject
215 lines
8.2 KiB
C#
215 lines
8.2 KiB
C#
using System;
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using Axios.Engine.Interfaces;
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using FarseerPhysics.SamplesFramework;
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using Microsoft.Xna.Framework;
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using Microsoft.Xna.Framework.Graphics;
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namespace Axios.Engine
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{
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public class DrawableAxiosGameObject : AxiosGameObject, IDrawableAxiosGameObject
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{
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protected int _draworder;
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protected Texture2D Texture;
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//public Vector2 Position = new Vector2(); //set this to a property and adjust if adjustunits is true
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public Vector2 _position = Vector2.Zero;
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public Vector2 Position
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{
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get
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{
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return ConvertUnits.ToDisplayUnits(_position);
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}
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set
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{
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_position = value;
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}
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}
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public Vector2 RealPosition
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{
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get { return _position; }
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private set { }
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}
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public Vector2 Origin = new Vector2();
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protected bool _adjustunits = true;
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protected bool _relativetocamera = true;
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protected float _rotation;
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public float Rotation
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{
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get { return _rotation; }
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set { _rotation = value; }
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}
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public bool AdjustUnits //if value changed - change position depending on adjusting the units
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{
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get { return _adjustunits; }
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set { _adjustunits = value; }
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}
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public bool RelativeToCamera
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{
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get { return _relativetocamera; }
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set { _relativetocamera = value; }
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}
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public int Width
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{
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get { return this.Texture.Width; }
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private set { }
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}
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public int Height
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{
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get { return this.Texture.Height; }
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private set { }
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}
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public override void LoadContent(AxiosGameScreen gameScreen)
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{
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base.LoadContent(gameScreen);
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}
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public virtual void Draw(AxiosGameScreen gameScreen, GameTime gameTime)
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{
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if (_relativetocamera)
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gameScreen.ScreenManager.SpriteBatch.Begin(0, null, null, null, null, null, gameScreen.Camera.View);
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else
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gameScreen.ScreenManager.SpriteBatch.Begin();
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if (_adjustunits)
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gameScreen.ScreenManager.SpriteBatch.Draw(Texture, ConvertUnits.ToDisplayUnits(_position), null, Color.White, _rotation, Origin, _scale, SpriteEffects.None, 0);
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else
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gameScreen.ScreenManager.SpriteBatch.Draw(Texture, _position, null, Color.White, _rotation, Origin, _scale, SpriteEffects.None, 0);
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gameScreen.ScreenManager.SpriteBatch.End();
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}
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public int DrawOrder
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{
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get
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{
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return this._draworder;
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}
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set
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{
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this._draworder = value;
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}
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}
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//Copied/adapted from http://create.msdn.com/en-US/education/catalog/tutorial/collision_2d_perpixel
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/// <summary>
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/// This method is a very simple collision detection based on textures.
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/// While Farseer (Box2D) is an excellent physics engine - it doesn't know, or care, about the textures.
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/// This method does a AABB test and if that is true - it tests the individual pixels in the textures.
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/// </summary>
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/// <param name="obj">Object to test against</param>
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/// <returns>true if the object is colliding, false if it isn't</returns>
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public bool CollidesWith(DrawableAxiosGameObject obj)
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{
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Rectangle thisobj = new Rectangle((int)this.Position.X, (int)this.Position.Y, this.Texture.Width, this.Texture.Height);
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Rectangle otherobj = new Rectangle((int)obj.Position.X, (int)obj.Position.Y, obj.Texture.Width, obj.Texture.Height);
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if (thisobj.Intersects(otherobj))
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{
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int top = Math.Max(thisobj.Top, otherobj.Top);
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int bottom = Math.Min(thisobj.Bottom, otherobj.Bottom);
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int left = Math.Max(thisobj.Left, otherobj.Left);
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int right = Math.Min(thisobj.Right, otherobj.Right);
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Color[] thisobjcolor = new Color[this.Texture.Width * this.Texture.Height];
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Color[] otherobjcolor = new Color[obj.Texture.Width * obj.Texture.Height];
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Texture.GetData(thisobjcolor);
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obj.Texture.GetData(otherobjcolor);
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// Check every point within the intersection bounds
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for (int y = top; y < bottom; y++)
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{
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for (int x = left; x < right; x++)
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{
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// Get the color of both pixels at this point
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Color colorA = thisobjcolor[(x - thisobj.Left) +
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(y - thisobj.Top) * thisobj.Width];
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Color colorB = otherobjcolor[(x - otherobj.Left) +
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(y - otherobj.Top) * otherobj.Width];
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// If both pixels are not completely transparent,
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if (colorA.A != 0 && colorB.A != 0)
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{
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// then an intersection has been found
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return true;
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}
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}
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}
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}
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return false;
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}
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//Copied/adapted from http://create.msdn.com/en-US/education/catalog/tutorial/collision_2d_perpixel
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/// <summary>
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/// This method is a very simple collision detection based on textures.
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/// While Farseer (Box2D) is an excellent physics engine - it doesn't know, or care, about the textures.
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/// This method does a AABB test and if that is true - it tests the individual pixels in the textures.
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/// </summary>
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/// <param name="obj">Object to test against</param>
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/// <returns>true if the object is colliding, false if it isn't</returns>
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public bool CollidesWith(Vector2 pos, Rectangle rect)
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{
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Rectangle thisobj = new Rectangle((int)this.Position.X, (int)this.Position.Y, this.Texture.Width, this.Texture.Height);
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Rectangle otherobj = new Rectangle((int)pos.X, (int)pos.Y, rect.Width, rect.Height);
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Texture2D obj = new Texture2D(Texture.GraphicsDevice, rect.Width, rect.Height);
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Color[] arr = new Color[rect.Width * rect.Height];
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for (int i = 0; i < rect.Width * rect.Height; ++i)
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arr[i] = Color.Black;
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obj.SetData(arr);
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if (thisobj.Intersects(otherobj))
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{
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int top = Math.Max(thisobj.Top, otherobj.Top);
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int bottom = Math.Min(thisobj.Bottom, otherobj.Bottom);
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int left = Math.Max(thisobj.Left, otherobj.Left);
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int right = Math.Min(thisobj.Right, otherobj.Right);
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Color[] thisobjcolor = new Color[this.Texture.Width * this.Texture.Height];
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Color[] otherobjcolor = new Color[obj.Width * obj.Height];
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Texture.GetData(thisobjcolor);
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obj.GetData(otherobjcolor);
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// Check every point within the intersection bounds
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for (int y = top; y < bottom; y++)
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{
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for (int x = left; x < right; x++)
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{
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// Get the color of both pixels at this point
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Color colorA = thisobjcolor[(x - thisobj.Left) +
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(y - thisobj.Top) * thisobj.Width];
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Color colorB = otherobjcolor[(x - otherobj.Left) +
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(y - otherobj.Top) * otherobj.Width];
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// If both pixels are not completely transparent,
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if (colorA.A != 0 && colorB.A != 0)
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{
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// then an intersection has been found
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return true;
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}
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}
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}
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}
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return false;
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}
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}
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}
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