package com.jme3.scene.plugins.blender.textures;
import java.awt.Graphics2D;
import java.awt.RenderingHints;
import java.awt.image.BufferedImage;
import java.nio.ByteBuffer;
import java.util.ArrayList;
import java.util.LinkedHashMap;
import java.util.List;
import java.util.logging.Level;
import java.util.logging.Logger;
import jme3tools.converters.ImageToAwt;
import com.jme3.math.ColorRGBA;
import com.jme3.math.Vector2f;
import com.jme3.scene.Geometry;
import com.jme3.scene.Mesh;
import com.jme3.scene.plugins.blender.BlenderContext;
import com.jme3.scene.plugins.blender.BlenderContext.LoadedFeatureDataType;
import com.jme3.scene.plugins.blender.file.Structure;
import com.jme3.scene.plugins.blender.materials.MaterialContext;
import com.jme3.scene.plugins.blender.textures.TriangulatedTexture.TriangleTextureElement;
import com.jme3.scene.plugins.blender.textures.UVCoordinatesGenerator.UVCoordinatesType;
import com.jme3.scene.plugins.blender.textures.UVProjectionGenerator.UVProjectionType;
import com.jme3.scene.plugins.blender.textures.blending.TextureBlender;
import com.jme3.scene.plugins.blender.textures.blending.TextureBlenderFactory;
import com.jme3.scene.plugins.blender.textures.io.PixelIOFactory;
import com.jme3.scene.plugins.blender.textures.io.PixelInputOutput;
import com.jme3.texture.Image;
import com.jme3.texture.Texture;
import com.jme3.texture.Texture.MagFilter;
import com.jme3.texture.Texture.MinFilter;
import com.jme3.texture.Texture.WrapMode;
import com.jme3.texture.Texture2D;
import com.jme3.texture.TextureCubeMap;
import com.jme3.util.BufferUtils;
/**
* This class represents a texture that is defined for the material. It can be
* made of several textures (both 2D and 3D) that are merged together and
* returned as a single texture.
*
* @author Marcin Roguski (Kaelthas)
*/
public class CombinedTexture {
private static final Logger LOGGER = Logger.getLogger(CombinedTexture.class.getName());
/** The mapping type of the texture. Defined bu MaterialContext.MTEX_COL, MTEX_NOR etc. */
private final int mappingType;
/**
* If set to true then if a texture without alpha is added then all textures below are discarded because
* the new one will cover them anyway. If set to false then all textures are stored.
*/
private boolean discardCoveredTextures;
/** The data for each of the textures. */
private List<TextureData> textureDatas = new ArrayList<TextureData>();
/** The result texture. */
private Texture resultTexture;
/** The UV values for the result texture. */
private List<Vector2f> resultUVS;
/**
* Constructor. Stores the texture mapping type (ie. color map, normal map).
*
* @param mappingType
* texture mapping type
* @param discardCoveredTextures
* if set to true then if a texture without alpha is added then all textures below are discarded because
* the new one will cover them anyway, if set to false then all textures are stored
*/
public CombinedTexture(int mappingType, boolean discardCoveredTextures) {
this.mappingType = mappingType;
this.discardCoveredTextures = discardCoveredTextures;
}
/**
* This method adds a texture data to the resulting texture.
*
* @param texture
* the source texture
* @param textureBlender
* the texture blender (to mix the texture with its material
* color)
* @param uvCoordinatesType
* the type of UV coordinates
* @param projectionType
* the type of UV coordinates projection (for flat textures)
* @param textureStructure
* the texture sructure
* @param uvCoordinatesName
* the name of the used user's UV coordinates for this texture
* @param blenderContext
* the blender context
*/
public void add(Texture texture, TextureBlender textureBlender, int uvCoordinatesType, int projectionType, Structure textureStructure, String uvCoordinatesName, BlenderContext blenderContext) {
if (!(texture instanceof GeneratedTexture) && !(texture instanceof Texture2D)) {
throw new IllegalArgumentException("Unsupported texture type: " + (texture == null ? "null" : texture.getClass()));
}
if (!(texture instanceof GeneratedTexture) || blenderContext.getBlenderKey().isLoadGeneratedTextures()) {
if (UVCoordinatesGenerator.isTextureCoordinateTypeSupported(UVCoordinatesType.valueOf(uvCoordinatesType))) {
TextureData textureData = new TextureData();
textureData.texture = texture;
textureData.textureBlender = textureBlender;
textureData.uvCoordinatesType = UVCoordinatesType.valueOf(uvCoordinatesType);
textureData.projectionType = UVProjectionType.valueOf(projectionType);
textureData.textureStructure = textureStructure;
textureData.uvCoordinatesName = uvCoordinatesName;
if (discardCoveredTextures && textureDatas.size() > 0 && this.isWithoutAlpha(textureData, blenderContext)) {
textureDatas.clear();// clear previous textures, they will be covered anyway
}
textureDatas.add(textureData);
} else {
LOGGER.warning("The texture coordinates type is not supported: " + UVCoordinatesType.valueOf(uvCoordinatesType) + ". The texture '" + textureStructure.getName() + "'.");
}
}
}
/**
* This method flattens the texture and creates a single result of Texture2D
* type.
*
* @param geometry
* the geometry the texture is created for
* @param geometriesOMA
* the old memory address of the geometries list that the given
* geometry belongs to (needed for bounding box creation)
* @param userDefinedUVCoordinates
* the UV's defined by user (null or zero length table if none
* were defined)
* @param blenderContext
* the blender context
*/
@SuppressWarnings("unchecked")
public void flatten(Geometry geometry, Long geometriesOMA, LinkedHashMap<String, List<Vector2f>> userDefinedUVCoordinates, BlenderContext blenderContext) {
Mesh mesh = geometry.getMesh();
Texture previousTexture = null;
UVCoordinatesType masterUVCoordinatesType = null;
String masterUserUVSetName = null;
for (TextureData textureData : textureDatas) {
// decompress compressed textures (all will be merged into one texture anyway)
if (textureDatas.size() > 1 && textureData.texture.getImage().getFormat().isCompressed()) {
textureData.texture.setImage(ImageUtils.decompress(textureData.texture.getImage()));
textureData.textureBlender = TextureBlenderFactory.alterTextureType(textureData.texture.getImage().getFormat(), textureData.textureBlender);
}
if (previousTexture == null) {// the first texture will lead the others to its shape
if (textureData.texture instanceof GeneratedTexture) {
resultTexture = ((GeneratedTexture) textureData.texture).triangulate(mesh, geometriesOMA, textureData.uvCoordinatesType, blenderContext);
} else if (textureData.texture instanceof Texture2D) {
resultTexture = textureData.texture;
if (textureData.uvCoordinatesType == UVCoordinatesType.TEXCO_UV && userDefinedUVCoordinates != null && userDefinedUVCoordinates.size() > 0) {
if (textureData.uvCoordinatesName == null) {
resultUVS = userDefinedUVCoordinates.values().iterator().next();// get the first UV available
} else {
resultUVS = userDefinedUVCoordinates.get(textureData.uvCoordinatesName);
}
masterUserUVSetName = textureData.uvCoordinatesName;
} else {
List<Geometry> geometries = (List<Geometry>) blenderContext.getLoadedFeature(geometriesOMA, LoadedFeatureDataType.LOADED_FEATURE);
resultUVS = UVCoordinatesGenerator.generateUVCoordinatesFor2DTexture(mesh, textureData.uvCoordinatesType, textureData.projectionType, geometries);
}
}
this.blend(resultTexture, textureData.textureBlender, blenderContext);
previousTexture = resultTexture;
masterUVCoordinatesType = textureData.uvCoordinatesType;
} else {
if (textureData.texture instanceof GeneratedTexture) {
if (!(resultTexture instanceof TriangulatedTexture)) {
resultTexture = new TriangulatedTexture((Texture2D) resultTexture, resultUVS, blenderContext);
resultUVS = null;
previousTexture = resultTexture;
}
TriangulatedTexture triangulatedTexture = ((GeneratedTexture) textureData.texture).triangulate(mesh, geometriesOMA, textureData.uvCoordinatesType, blenderContext);
triangulatedTexture.castToUVS((TriangulatedTexture) resultTexture, blenderContext);
triangulatedTexture.blend(textureData.textureBlender, (TriangulatedTexture) resultTexture, blenderContext);
resultTexture = previousTexture = triangulatedTexture;
} else if (textureData.texture instanceof Texture2D) {
if (this.isUVTypesMatch(masterUVCoordinatesType, masterUserUVSetName, textureData.uvCoordinatesType, textureData.uvCoordinatesName) && resultTexture instanceof Texture2D) {
this.scale((Texture2D) textureData.texture, resultTexture.getImage().getWidth(), resultTexture.getImage().getHeight());
ImageUtils.merge(resultTexture.getImage(), textureData.texture.getImage());
previousTexture = resultTexture;
} else {
if (!(resultTexture instanceof TriangulatedTexture)) {
resultTexture = new TriangulatedTexture((Texture2D) resultTexture, resultUVS, blenderContext);
resultUVS = null;
}
// first triangulate the current texture
List<Vector2f> textureUVS = null;
if (textureData.uvCoordinatesType == UVCoordinatesType.TEXCO_UV && userDefinedUVCoordinates != null && userDefinedUVCoordinates.size() > 0) {
if (textureData.uvCoordinatesName == null) {
textureUVS = userDefinedUVCoordinates.values().iterator().next();// get the first UV available
} else {
textureUVS = userDefinedUVCoordinates.get(textureData.uvCoordinatesName);
}
} else {
List<Geometry> geometries = (List<Geometry>) blenderContext.getLoadedFeature(geometriesOMA, LoadedFeatureDataType.LOADED_FEATURE);
textureUVS = UVCoordinatesGenerator.generateUVCoordinatesFor2DTexture(mesh, textureData.uvCoordinatesType, textureData.projectionType, geometries);
}
TriangulatedTexture triangulatedTexture = new TriangulatedTexture((Texture2D) textureData.texture, textureUVS, blenderContext);
// then move the texture to different UV's
triangulatedTexture.castToUVS((TriangulatedTexture) resultTexture, blenderContext);
// merge triangulated textures
for (int i = 0; i < ((TriangulatedTexture) resultTexture).getFaceTextureCount(); ++i) {
ImageUtils.merge(((TriangulatedTexture) resultTexture).getFaceTextureElement(i).image, triangulatedTexture.getFaceTextureElement(i).image);
}
}
}
}
}
if (resultTexture instanceof TriangulatedTexture) {
if (mappingType == MaterialContext.MTEX_NOR) {
for (int i = 0; i < ((TriangulatedTexture) resultTexture).getFaceTextureCount(); ++i) {
TriangleTextureElement triangleTextureElement = ((TriangulatedTexture) resultTexture).getFaceTextureElement(i);
triangleTextureElement.image = ImageUtils.convertToNormalMapTexture(triangleTextureElement.image, 1);// TODO: get proper strength factor
}
}
resultUVS = ((TriangulatedTexture) resultTexture).getResultUVS();
resultTexture = ((TriangulatedTexture) resultTexture).getResultTexture();
}
// setting additional data
resultTexture.setWrap(WrapMode.Repeat);
// the filters are required if generated textures are used because
// otherwise ugly lines appear between the mesh faces
resultTexture.setMagFilter(MagFilter.Nearest);
resultTexture.setMinFilter(MinFilter.NearestNoMipMaps);
}
/**
* Generates a texture that will be used by the sky spatial.
* The result texture has 6 layers. Every image in each layer has equal size and its shape is a square.
* The size of each image is the maximum size (width or height) of the textures given.
* The default sky generated texture size is used (this value is set in the BlenderKey) if no picture textures
* are present or their sizes is lower than the generated texture size.
* The textures of lower sizes are properly scaled.
* All the textures are mixed into one and put as layers in the result texture.
*
* @param horizontalColor
* the horizon color
* @param zenithColor
* the zenith color
* @param blenderContext
* the blender context
* @return texture for the sky
*/
public TextureCubeMap generateSkyTexture(ColorRGBA horizontalColor, ColorRGBA zenithColor, BlenderContext blenderContext) {
LOGGER.log(Level.FINE, "Preparing sky texture from {0} applied textures.", textureDatas.size());
LOGGER.fine("Computing the texture size.");
int size = -1;
for (TextureData textureData : textureDatas) {
if (textureData.texture instanceof Texture2D) {
size = Math.max(textureData.texture.getImage().getWidth(), size);
size = Math.max(textureData.texture.getImage().getHeight(), size);
}
}
if (size < 0) {
size = blenderContext.getBlenderKey().getSkyGeneratedTextureSize();
}
LOGGER.log(Level.FINE, "The sky texture size will be: {0}x{0}.", size);
TextureCubeMap result = null;
for (TextureData textureData : textureDatas) {
TextureCubeMap texture = null;
if (textureData.texture instanceof GeneratedTexture) {
texture = ((GeneratedTexture) textureData.texture).generateSkyTexture(size, horizontalColor, zenithColor, blenderContext);
} else {
// first create a grayscale version of the image
Image image = textureData.texture.getImage();
if (image.getWidth() != image.getHeight() || image.getWidth() != size) {
image = ImageUtils.resizeTo(image, size, size);
}
Image grayscaleImage = ImageUtils.convertToGrayscaleTexture(image);
// add the sky colors to the image
PixelInputOutput sourcePixelIO = PixelIOFactory.getPixelIO(grayscaleImage.getFormat());
PixelInputOutput targetPixelIO = PixelIOFactory.getPixelIO(image.getFormat());
TexturePixel texturePixel = new TexturePixel();
for (int x = 0; x < image.getWidth(); ++x) {
for (int y = 0; y < image.getHeight(); ++y) {
sourcePixelIO.read(grayscaleImage, 0, texturePixel, x, y);
texturePixel.intensity = texturePixel.red;// no matter which factor we use here, in grayscale they are all equal
ImageUtils.color(texturePixel, horizontalColor, zenithColor);
targetPixelIO.write(image, 0, texturePixel, x, y);
}
}
// create the cubemap texture from the coloured image
ByteBuffer sourceData = image.getData(0);
ArrayList<ByteBuffer> data = new ArrayList<ByteBuffer>(6);
for (int i = 0; i < 6; ++i) {
data.add(BufferUtils.clone(sourceData));
}
texture = new TextureCubeMap(new Image(image.getFormat(), image.getWidth(), image.getHeight(), 6, data));
}
if (result == null) {
result = texture;
} else {
ImageUtils.mix(result.getImage(), texture.getImage());
}
}
return result;
}
/**
* The method checks if the texture UV coordinates match.
* It the types are equal and different then UVCoordinatesType.TEXCO_UV then we consider them a match.
* If they are both UVCoordinatesType.TEXCO_UV then they match only when their UV sets names are equal.
* In other cases they are considered NOT a match.
* @param type1
* the UV coord type
* @param uvSetName1
* the user's UV coords set name (considered only for UVCoordinatesType.TEXCO_UV)
* @param type2
* the UV coord type
* @param uvSetName2
* the user's UV coords set name (considered only for UVCoordinatesType.TEXCO_UV)
* @return <b>true</b> if the types match and <b>false</b> otherwise
*/
private boolean isUVTypesMatch(UVCoordinatesType type1, String uvSetName1, UVCoordinatesType type2, String uvSetName2) {
if (type1 == type2) {
if (type1 == UVCoordinatesType.TEXCO_UV) {
if (uvSetName1 != null && uvSetName2 != null && uvSetName1.equals(uvSetName2)) {
return true;
}
} else {
return true;
}
}
return false;
}
/**
* This method blends the texture.
*
* @param texture
* the texture to be blended
* @param textureBlender
* blending definition for the texture
* @param blenderContext
* the blender context
*/
private void blend(Texture texture, TextureBlender textureBlender, BlenderContext blenderContext) {
if (texture instanceof TriangulatedTexture) {
((TriangulatedTexture) texture).blend(textureBlender, null, blenderContext);
} else if (texture instanceof Texture2D) {
Image blendedImage = textureBlender.blend(texture.getImage(), null, blenderContext);
texture.setImage(blendedImage);
} else {
throw new IllegalArgumentException("Invalid type for texture to blend!");
}
}
/**
* @return the result texture
*/
public Texture getResultTexture() {
return resultTexture;
}
/**
* @return the result UV coordinates
*/
public List<Vector2f> getResultUVS() {
return resultUVS;
}
/**
* @return the amount of added textures
*/
public int getTexturesCount() {
return textureDatas.size();
}
/**
* @return the texture's mapping type
*/
public int getMappingType() {
return mappingType;
}
/**
* @return <b>true</b> if the texture has at least one generated texture component and <b>false</b> otherwise
*/
public boolean hasGeneratedTextures() {
if (textureDatas != null) {
for (TextureData textureData : textureDatas) {
if (textureData.texture instanceof GeneratedTexture) {
return true;
}
}
}
return false;
}
/**
* This method determines if the given texture has no alpha channel.
*
* @param texture
* the texture to check for alpha channel
* @return <b>true</b> if the texture has no alpha channel and <b>false</b>
* otherwise
*/
private boolean isWithoutAlpha(TextureData textureData, BlenderContext blenderContext) {
ColorBand colorBand = new ColorBand(textureData.textureStructure, blenderContext);
if (!colorBand.hasTransparencies()) {
int type = ((Number) textureData.textureStructure.getFieldValue("type")).intValue();
if (type == TextureHelper.TEX_MAGIC) {
return true;
}
if (type == TextureHelper.TEX_VORONOI) {
int voronoiColorType = ((Number) textureData.textureStructure.getFieldValue("vn_coltype")).intValue();
return voronoiColorType != 0;// voronoiColorType == 0:
// intensity, voronoiColorType
// != 0: col1, col2 or col3
}
if (type == TextureHelper.TEX_CLOUDS) {
int sType = ((Number) textureData.textureStructure.getFieldValue("stype")).intValue();
return sType == 1;// sType==0: without colors, sType==1: with
// colors
}
// checking the flat textures for alpha values presence
if (type == TextureHelper.TEX_IMAGE) {
Image image = textureData.texture.getImage();
switch (image.getFormat()) {
case BGR8:
case DXT1:
case Luminance16:
case Luminance16F:
case Luminance32F:
case Luminance8:
case RGB10:
case RGB111110F:
case RGB16:
case RGB16F:
case RGB32F:
case RGB565:
case RGB8:
return true;// these types have no alpha by definition
case ABGR8:
case DXT3:
case DXT5:
case Luminance16Alpha16:
case Luminance16FAlpha16F:
case Luminance8Alpha8:
case RGBA16:
case RGBA16F:
case RGBA32F:
case RGBA8:// with these types it is better to make sure if the texture is or is not transparent
PixelInputOutput pixelInputOutput = PixelIOFactory.getPixelIO(image.getFormat());
TexturePixel pixel = new TexturePixel();
int depth = image.getDepth() == 0 ? 1 : image.getDepth();
for (int layerIndex = 0; layerIndex < depth; ++layerIndex) {
for (int x = 0; x < image.getWidth(); ++x) {
for (int y = 0; y < image.getHeight(); ++y) {
pixelInputOutput.read(image, layerIndex, pixel, x, y);
if (pixel.alpha < 1.0f) {
return false;
}
}
}
}
return true;
}
}
}
return false;
}
/**
* This method scales the given texture to the given size.
*
* @param texture
* the texture to be scaled
* @param width
* new width of the texture
* @param height
* new height of the texture
*/
private void scale(Texture2D texture, int width, int height) {
// first determine if scaling is required
boolean scaleRequired = texture.getImage().getWidth() != width || texture.getImage().getHeight() != height;
if (scaleRequired) {
Image image = texture.getImage();
BufferedImage sourceImage = ImageToAwt.convert(image, false, true, 0);
int sourceWidth = sourceImage.getWidth();
int sourceHeight = sourceImage.getHeight();
BufferedImage targetImage = new BufferedImage(width, height, sourceImage.getType());
Graphics2D g = targetImage.createGraphics();
g.setRenderingHint(RenderingHints.KEY_INTERPOLATION, RenderingHints.VALUE_INTERPOLATION_BILINEAR);
g.drawImage(sourceImage, 0, 0, width, height, 0, 0, sourceWidth, sourceHeight, null);
g.dispose();
Image output = new ImageLoader().load(targetImage, false);
image.setWidth(width);
image.setHeight(height);
image.setData(output.getData(0));
image.setFormat(output.getFormat());
}
}
/**
* A simple class to aggregate the texture data (improves code quality).
*
* @author Marcin Roguski (Kaelthas)
*/
private static class TextureData {
/** The texture. */
public Texture texture;
/** The texture blender (to mix the texture with its material color). */
public TextureBlender textureBlender;
/** The type of UV coordinates. */
public UVCoordinatesType uvCoordinatesType;
/** The type of UV coordinates projection (for flat textures). */
public UVProjectionType projectionType;
/** The texture sructure. */
public Structure textureStructure;
/** The name of the user's UV coordinates that are used for this texture. */
public String uvCoordinatesName;
}
}