Applied-Energistics-2-tilera-Edition/src/main/java/appeng/client/render/cablebus/CubeBuilder.java

/*
 * This file is part of Applied Energistics 2.
 * Copyright (c) 2013 - 2014, AlgorithmX2, All rights reserved.
 *
 * Applied Energistics 2 is free software: you can redistribute it and/or modify
 * it under the terms of the GNU Lesser General Public License as published by
 * the Free Software Foundation, either version 3 of the License, or
 * (at your option) any later version.
 *
 * Applied Energistics 2 is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU Lesser General Public License for more details.
 *
 * You should have received a copy of the GNU Lesser General Public License
 * along with Applied Energistics 2.  If not, see <http://www.gnu.org/licenses/lgpl>.
 */

package appeng.client.render.cablebus;


import java.util.ArrayList;
import java.util.EnumMap;
import java.util.EnumSet;
import java.util.List;
import javax.vecmath.Vector4f;

import com.google.common.base.Preconditions;

import net.minecraft.client.renderer.block.model.BakedQuad;
import net.minecraft.client.renderer.texture.TextureAtlasSprite;
import net.minecraft.client.renderer.vertex.DefaultVertexFormats;
import net.minecraft.client.renderer.vertex.VertexFormat;
import net.minecraft.client.renderer.vertex.VertexFormatElement;
import net.minecraft.util.EnumFacing;
import net.minecraftforge.client.model.pipeline.UnpackedBakedQuad;


/**
 * Builds the quads for a cube.
 */
public class CubeBuilder
{

	private VertexFormat format;

	private final List<BakedQuad> output;

	private final EnumMap<EnumFacing, TextureAtlasSprite> textures = new EnumMap<>( EnumFacing.class );

	private EnumSet<EnumFacing> drawFaces = EnumSet.allOf( EnumFacing.class );

	private final EnumMap<EnumFacing, Vector4f> customUv = new EnumMap<>( EnumFacing.class );

	private byte[] uvRotations = new byte[EnumFacing.values().length];

	private int color = 0xFFFFFFFF;

	private boolean renderFullBright;

	public CubeBuilder( VertexFormat format, List<BakedQuad> output )
	{
		this.output = output;
		this.format = format;
	}

	public CubeBuilder( VertexFormat format )
	{
		this( format, new ArrayList<>( 6 ) );
	}

	public void addCube( float x1, float y1, float z1, float x2, float y2, float z2 )
	{
		x1 /= 16.0f;
		y1 /= 16.0f;
		z1 /= 16.0f;
		x2 /= 16.0f;
		y2 /= 16.0f;
		z2 /= 16.0f;

		// If brightness is forced to specific values, extend the vertex format to contain the multi-texturing lightmap
		// offset
		VertexFormat savedFormat = null;
		if( renderFullBright )
		{
			savedFormat = format;
			format = new VertexFormat( savedFormat );
			if( !format.getElements().contains( DefaultVertexFormats.TEX_2S ) )
			{
				format.addElement( DefaultVertexFormats.TEX_2S );
			}
		}

		for( EnumFacing face : drawFaces )
		{
			putFace( face, x1, y1, z1, x2, y2, z2 );
		}

		// Restore old format
		if( savedFormat != null )
		{
			format = savedFormat;
		}
	}

	public void addQuad( EnumFacing face, float x1, float y1, float z1, float x2, float y2, float z2 )
	{
		// If brightness is forced to specific values, extend the vertex format to contain the multi-texturing lightmap
		// offset
		VertexFormat savedFormat = null;
		if( renderFullBright )
		{
			savedFormat = format;
			format = new VertexFormat( savedFormat );
			if( !format.getElements().contains( DefaultVertexFormats.TEX_2S ) )
			{
				format.addElement( DefaultVertexFormats.TEX_2S );
			}
		}

		putFace( face, x1, y1, z1, x2, y2, z2 );

		// Restore old format
		if( savedFormat != null )
		{
			format = savedFormat;
		}
	}

	private static final class UvVector
	{
		float u1;
		float u2;
		float v1;
		float v2;
	}

	private void putFace( EnumFacing face, float x1, float y1, float z1, float x2, float y2, float z2 )
	{

		TextureAtlasSprite texture = textures.get( face );

		UnpackedBakedQuad.Builder builder = new UnpackedBakedQuad.Builder( format );
		builder.setTexture( texture );
		builder.setQuadOrientation( face );

		UvVector uv = new UvVector();

		// The user might have set specific UV coordinates for this face
		Vector4f customUv = this.customUv.get( face );
		if( customUv != null )
		{
			uv.u1 = texture.getInterpolatedU( customUv.x );
			uv.v1 = texture.getInterpolatedV( customUv.y );
			uv.u2 = texture.getInterpolatedU( customUv.z );
			uv.v2 = texture.getInterpolatedV( customUv.w );
		}
		else
		{
			uv = getDefaultUv( face, texture, x1, y1, z1, x2, y2, z2 );
		}

		switch( face )
		{
			case DOWN:
				putVertexTR( builder, face, x2, y1, z1, uv );
				putVertexBR( builder, face, x2, y1, z2, uv );
				putVertexBL( builder, face, x1, y1, z2, uv );
				putVertexTL( builder, face, x1, y1, z1, uv );
				break;
			case UP:
				putVertexTL( builder, face, x1, y2, z1, uv );
				putVertexBL( builder, face, x1, y2, z2, uv );
				putVertexBR( builder, face, x2, y2, z2, uv );
				putVertexTR( builder, face, x2, y2, z1, uv );
				break;
			case NORTH:
				putVertexBR( builder, face, x2, y2, z1, uv );
				putVertexTR( builder, face, x2, y1, z1, uv );
				putVertexTL( builder, face, x1, y1, z1, uv );
				putVertexBL( builder, face, x1, y2, z1, uv );
				break;
			case SOUTH:
				putVertexBL( builder, face, x1, y2, z2, uv );
				putVertexTL( builder, face, x1, y1, z2, uv );
				putVertexTR( builder, face, x2, y1, z2, uv );
				putVertexBR( builder, face, x2, y2, z2, uv );
				break;
			case WEST:
				putVertexTL( builder, face, x1, y1, z1, uv );
				putVertexTR( builder, face, x1, y1, z2, uv );
				putVertexBR( builder, face, x1, y2, z2, uv );
				putVertexBL( builder, face, x1, y2, z1, uv );
				break;
			case EAST:
				putVertexBR( builder, face, x2, y2, z1, uv );
				putVertexBL( builder, face, x2, y2, z2, uv );
				putVertexTL( builder, face, x2, y1, z2, uv );
				putVertexTR( builder, face, x2, y1, z1, uv );
				break;
		}

		int[] vertexData = builder.build().getVertexData();
		output.add( new BakedQuad( vertexData, -1, face, texture, true, format ) );
	}

	private UvVector getDefaultUv( EnumFacing face, TextureAtlasSprite texture, float x1, float y1, float z1, float x2, float y2, float z2 )
	{

		UvVector uv = new UvVector();

		switch( face )
		{
			case DOWN:
				uv.u1 = texture.getInterpolatedU( x1 * 16 );
				uv.v1 = texture.getInterpolatedV( z1 * 16 );
				uv.u2 = texture.getInterpolatedU( x2 * 16 );
				uv.v2 = texture.getInterpolatedV( z2 * 16 );
				break;
			case UP:
				uv.u1 = texture.getInterpolatedU( x1 * 16 );
				uv.v1 = texture.getInterpolatedV( z1 * 16 );
				uv.u2 = texture.getInterpolatedU( x2 * 16 );
				uv.v2 = texture.getInterpolatedV( z2 * 16 );
				break;
			case NORTH:
				uv.u1 = texture.getInterpolatedU( x1 * 16 );
				uv.v1 = texture.getInterpolatedV( 16 - y1 * 16 );
				uv.u2 = texture.getInterpolatedU( x2 * 16 );
				uv.v2 = texture.getInterpolatedV( 16 - y2 * 16 );
				break;
			case SOUTH:
				uv.u1 = texture.getInterpolatedU( x1 * 16 );
				uv.v1 = texture.getInterpolatedV( 16 - y1 * 16 );
				uv.u2 = texture.getInterpolatedU( x2 * 16 );
				uv.v2 = texture.getInterpolatedV( 16 - y2 * 16 );
				break;
			case WEST:
				uv.u1 = texture.getInterpolatedU( z1 * 16 );
				uv.v1 = texture.getInterpolatedV( 16 - y1 * 16 );
				uv.u2 = texture.getInterpolatedU( z2 * 16 );
				uv.v2 = texture.getInterpolatedV( 16 - y2 * 16 );
				break;
			case EAST:
				uv.u1 = texture.getInterpolatedU( z2 * 16 );
				uv.v1 = texture.getInterpolatedV( 16 - y1 * 16 );
				uv.u2 = texture.getInterpolatedU( z1 * 16 );
				uv.v2 = texture.getInterpolatedV( 16 - y2 * 16 );
				break;
		}

		return uv;
	}

	// uv.u1, uv.v1
	private void putVertexTL( UnpackedBakedQuad.Builder builder, EnumFacing face, float x, float y, float z, UvVector uv )
	{
		float u, v;

		switch( uvRotations[face.ordinal()] )
		{
			default:
			case 0:
				u = uv.u1;
				v = uv.v1;
				break;
			case 1: // 90° clockwise
				u = uv.u1;
				v = uv.v2;
				break;
			case 2: // 180° clockwise
				u = uv.u2;
				v = uv.v2;
				break;
			case 3: // 270° clockwise
				u = uv.u2;
				v = uv.v1;
				break;
		}

		putVertex( builder, face, x, y, z, u, v );
	}

	// uv.u2, uv.v1
	private void putVertexTR( UnpackedBakedQuad.Builder builder, EnumFacing face, float x, float y, float z, UvVector uv )
	{
		float u;
		float v;

		switch( uvRotations[face.ordinal()] )
		{
			default:
			case 0:
				u = uv.u2;
				v = uv.v1;
				break;
			case 1: // 90° clockwise
				u = uv.u1;
				v = uv.v1;
				break;
			case 2: // 180° clockwise
				u = uv.u1;
				v = uv.v2;
				break;
			case 3: // 270° clockwise
				u = uv.u2;
				v = uv.v2;
				break;
		}
		putVertex( builder, face, x, y, z, u, v );
	}

	// uv.u2, uv.v2
	private void putVertexBR( UnpackedBakedQuad.Builder builder, EnumFacing face, float x, float y, float z, UvVector uv )
	{

		float u;
		float v;

		switch( uvRotations[face.ordinal()] )
		{
			default:
			case 0:
				u = uv.u2;
				v = uv.v2;
				break;
			case 1: // 90° clockwise
				u = uv.u2;
				v = uv.v1;
				break;
			case 2: // 180° clockwise
				u = uv.u1;
				v = uv.v1;
				break;
			case 3: // 270° clockwise
				u = uv.u1;
				v = uv.v2;
				break;
		}

		putVertex( builder, face, x, y, z, u, v );
	}

	// uv.u1, uv.v2
	private void putVertexBL( UnpackedBakedQuad.Builder builder, EnumFacing face, float x, float y, float z, UvVector uv )
	{

		float u;
		float v;

		switch( uvRotations[face.ordinal()] )
		{
			default:
			case 0:
				u = uv.u1;
				v = uv.v2;
				break;
			case 1: // 90° clockwise
				u = uv.u2;
				v = uv.v2;
				break;
			case 2: // 180° clockwise
				u = uv.u2;
				v = uv.v1;
				break;
			case 3: // 270° clockwise
				u = uv.u1;
				v = uv.v1;
				break;
		}

		putVertex( builder, face, x, y, z, u, v );
	}

	private void putVertex( UnpackedBakedQuad.Builder builder, EnumFacing face, float x, float y, float z, float u, float v )
	{
		VertexFormat format = builder.getVertexFormat();

		for( int i = 0; i < format.getElementCount(); i++ )
		{
			VertexFormatElement e = format.getElement( i );
			switch( e.getUsage() )
			{
				case POSITION:
					builder.put( i, x, y, z );
					break;
				case NORMAL:
					builder.put( i, face.getFrontOffsetX(), face.getFrontOffsetY(), face.getFrontOffsetZ() );
					break;
				case COLOR:
					// Color format is RGBA
					float r = ( color >> 16 & 0xFF ) / 255f;
					float g = ( color >> 8 & 0xFF ) / 255f;
					float b = ( color & 0xFF ) / 255f;
					float a = ( color >> 24 & 0xFF ) / 255f;
					builder.put( i, r, g, b, a );
					break;
				case UV:
					if( e.getIndex() == 0 )
					{
						builder.put( i, u, v );
					}
					else
					{
						// Force Brightness to 15, this is for full bright mode
						// this vertex element will only be present in that case
						final float lightMapU = (float) ( 15 * 0x20 ) / 0xFFFF;
						final float lightMapV = (float) ( 15 * 0x20 ) / 0xFFFF;
						builder.put( i, lightMapU, lightMapV );
					}
					break;
				default:
					builder.put( i );
					break;
			}
		}
	}

	public void setTexture( TextureAtlasSprite texture )
	{
		for( EnumFacing face : EnumFacing.values() )
		{
			textures.put( face, texture );
		}
	}

	public void setTextures( TextureAtlasSprite up, TextureAtlasSprite down, TextureAtlasSprite north, TextureAtlasSprite south, TextureAtlasSprite east, TextureAtlasSprite west )
	{
		textures.put( EnumFacing.UP, up );
		textures.put( EnumFacing.DOWN, down );
		textures.put( EnumFacing.NORTH, north );
		textures.put( EnumFacing.SOUTH, south );
		textures.put( EnumFacing.EAST, east );
		textures.put( EnumFacing.WEST, west );
	}

	public void setTexture( EnumFacing facing, TextureAtlasSprite sprite )
	{
		textures.put( facing, sprite );
	}

	public void setDrawFaces( EnumSet<EnumFacing> drawFaces )
	{
		this.drawFaces = drawFaces;
	}

	public void setColor( int color )
	{
		this.color = color;
	}

	/**
	 * Sets the vertex color for future vertices to the given RGB value, and forces the alpha component to 255.
	 */
	public void setColorRGB( int color )
	{
		setColor( color | 0xFF000000 );
	}

	public void setColorRGB( float r, float g, float b )
	{
		setColorRGB( (int) ( r * 255 ) << 16 | (int) ( g * 255 ) << 8 | (int) ( b * 255 ) );
	}

	public void setRenderFullBright( boolean renderFullBright )
	{
		this.renderFullBright = renderFullBright;
	}

	public void setCustomUv( EnumFacing facing, float u1, float v1, float u2, float v2 )
	{
		customUv.put( facing, new Vector4f( u1, v1, u2, v2 ) );
	}

	public void setUvRotation( EnumFacing facing, int rotation )
	{
		if( rotation == 2 )
		{
			rotation = 3;
		}
		else if( rotation == 3 )
		{
			rotation = 2;
		}
		Preconditions.checkArgument( rotation >= 0 && rotation <= 3, "rotation" );
		uvRotations[facing.ordinal()] = (byte) rotation;
	}

	public List<BakedQuad> getOutput()
	{
		return output;
	}
}