private ColorRGBA getAmbientColor(LightList lightList) { ambientLightColor.set(0, 0, 0, 1); for (int j = 0; j < lightList.size(); j++) { Light l = lightList.get(j); if (l instanceof AmbientLight) { ambientLightColor.addLocal(l.getColor()); } } ambientLightColor.a = 1.0f; return ambientLightColor; }
public void setLighting(LightList list) { // XXX: This is abuse of setLighting() to // apply fixed function bindings // and do other book keeping. if (list == null || list.size() == 0) { glDisable(GL_LIGHTING); applyFixedFuncBindings(false); setModelView(worldMatrix, viewMatrix); return; } // Number of lights set previously int numLightsSetPrev = lightList.size(); // If more than maxLights are defined, they will be ignored. // The GL1 renderer is not permitted to crash due to a // GL1 limitation. It must render anything that the GL2 renderer // can render (even incorrectly). lightList.clear(); materialAmbientColor.set(0, 0, 0, 0); for (int i = 0; i < list.size(); i++) { Light l = list.get(i); if (l.getType() == Light.Type.Ambient) { // Gather materialAmbientColor.addLocal(l.getColor()); } else { // Add to list lightList.add(l); // Once maximum lights reached, exit loop. if (lightList.size() >= maxLights) { break; } } } applyFixedFuncBindings(true); glEnable(GL_LIGHTING); fb16.clear(); fb16.put(materialAmbientColor.r) .put(materialAmbientColor.g) .put(materialAmbientColor.b) .put(1) .flip(); glLightModel(GL_LIGHT_MODEL_AMBIENT, fb16); if (context.matrixMode != GL_MODELVIEW) { glMatrixMode(GL_MODELVIEW); context.matrixMode = GL_MODELVIEW; } // Lights are already in world space, so just convert // them to view space. glLoadMatrix(storeMatrix(viewMatrix, fb16)); for (int i = 0; i < lightList.size(); i++) { int glLightIndex = GL_LIGHT0 + i; Light light = lightList.get(i); Light.Type lightType = light.getType(); ColorRGBA col = light.getColor(); Vector3f pos; // Enable the light glEnable(glLightIndex); // OGL spec states default value for light ambient is black switch (lightType) { case Directional: DirectionalLight dLight = (DirectionalLight) light; fb16.clear(); fb16.put(col.r).put(col.g).put(col.b).put(col.a).flip(); glLight(glLightIndex, GL_DIFFUSE, fb16); glLight(glLightIndex, GL_SPECULAR, fb16); pos = tempVec.set(dLight.getDirection()).negateLocal().normalizeLocal(); fb16.clear(); fb16.put(pos.x).put(pos.y).put(pos.z).put(0.0f).flip(); glLight(glLightIndex, GL_POSITION, fb16); glLightf(glLightIndex, GL_SPOT_CUTOFF, 180); break; case Point: PointLight pLight = (PointLight) light; fb16.clear(); fb16.put(col.r).put(col.g).put(col.b).put(col.a).flip(); glLight(glLightIndex, GL_DIFFUSE, fb16); glLight(glLightIndex, GL_SPECULAR, fb16); pos = pLight.getPosition(); fb16.clear(); fb16.put(pos.x).put(pos.y).put(pos.z).put(1.0f).flip(); glLight(glLightIndex, GL_POSITION, fb16); glLightf(glLightIndex, GL_SPOT_CUTOFF, 180); if (pLight.getRadius() > 0) { // Note: this doesn't follow the same attenuation model // as the one used in the lighting shader. glLightf(glLightIndex, GL_CONSTANT_ATTENUATION, 1); glLightf(glLightIndex, GL_LINEAR_ATTENUATION, pLight.getInvRadius() * 2); glLightf( glLightIndex, GL_QUADRATIC_ATTENUATION, pLight.getInvRadius() * pLight.getInvRadius()); } else { glLightf(glLightIndex, GL_CONSTANT_ATTENUATION, 1); glLightf(glLightIndex, GL_LINEAR_ATTENUATION, 0); glLightf(glLightIndex, GL_QUADRATIC_ATTENUATION, 0); } break; case Spot: SpotLight sLight = (SpotLight) light; fb16.clear(); fb16.put(col.r).put(col.g).put(col.b).put(col.a).flip(); glLight(glLightIndex, GL_DIFFUSE, fb16); glLight(glLightIndex, GL_SPECULAR, fb16); pos = sLight.getPosition(); fb16.clear(); fb16.put(pos.x).put(pos.y).put(pos.z).put(1.0f).flip(); glLight(glLightIndex, GL_POSITION, fb16); Vector3f dir = sLight.getDirection(); fb16.clear(); fb16.put(dir.x).put(dir.y).put(dir.z).put(1.0f).flip(); glLight(glLightIndex, GL_SPOT_DIRECTION, fb16); float outerAngleRad = sLight.getSpotOuterAngle(); float innerAngleRad = sLight.getSpotInnerAngle(); float spotCut = outerAngleRad * FastMath.RAD_TO_DEG; float spotExpo = 0.0f; if (outerAngleRad > 0) { spotExpo = (1.0f - (innerAngleRad / outerAngleRad)) * 128.0f; } glLightf(glLightIndex, GL_SPOT_CUTOFF, spotCut); glLightf(glLightIndex, GL_SPOT_EXPONENT, spotExpo); if (sLight.getSpotRange() > 0) { glLightf(glLightIndex, GL_LINEAR_ATTENUATION, sLight.getInvSpotRange()); } else { glLightf(glLightIndex, GL_LINEAR_ATTENUATION, 0); } break; default: throw new UnsupportedOperationException("Unrecognized light type: " + lightType); } } // Disable lights after the index for (int i = lightList.size(); i < numLightsSetPrev; i++) { glDisable(GL_LIGHT0 + i); } // This will set view matrix as well. setModelView(worldMatrix, viewMatrix); }
/** * The method loads library of a given ID from linked blender file. * * @param id the ID of the linked feature (it contains its name and blender path) * @return loaded feature or null if none was found * @throws BlenderFileException and exception is throw when problems with reading a blend file * occur */ @SuppressWarnings("unchecked") protected Object loadLibrary(Structure id) throws BlenderFileException { Pointer pLib = (Pointer) id.getFieldValue("lib"); if (pLib.isNotNull()) { String fullName = id.getFieldValue("name").toString(); // we need full name with the prefix String nameOfFeatureToLoad = id.getName(); Structure library = pLib.fetchData().get(0); String path = library.getFieldValue("filepath").toString(); if (!blenderContext.getLinkedFeatures().keySet().contains(path)) { File file = new File(path); List<String> pathsToCheck = new ArrayList<String>(); String currentPath = file.getName(); do { pathsToCheck.add(currentPath); file = file.getParentFile(); if (file != null) { currentPath = file.getName() + '/' + currentPath; } } while (file != null); Spatial loadedAsset = null; BlenderKey blenderKey = null; for (String p : pathsToCheck) { blenderKey = new BlenderKey(p); blenderKey.setLoadUnlinkedAssets(true); try { loadedAsset = blenderContext.getAssetManager().loadAsset(blenderKey); break; // break if no exception was thrown } catch (AssetNotFoundException e) { LOGGER.log(Level.FINEST, "Cannot locate linked resource at path: {0}.", p); } } if (loadedAsset != null) { Map<String, Map<String, Object>> linkedData = loadedAsset.getUserData("linkedData"); for (Entry<String, Map<String, Object>> entry : linkedData.entrySet()) { String linkedDataFilePath = "this".equals(entry.getKey()) ? path : entry.getKey(); List<Node> scenes = (List<Node>) entry.getValue().get("scenes"); for (Node scene : scenes) { blenderContext.addLinkedFeature(linkedDataFilePath, "SC" + scene.getName(), scene); } List<Node> objects = (List<Node>) entry.getValue().get("objects"); for (Node object : objects) { blenderContext.addLinkedFeature(linkedDataFilePath, "OB" + object.getName(), object); } List<TemporalMesh> meshes = (List<TemporalMesh>) entry.getValue().get("meshes"); for (TemporalMesh mesh : meshes) { blenderContext.addLinkedFeature(linkedDataFilePath, "ME" + mesh.getName(), mesh); } List<MaterialContext> materials = (List<MaterialContext>) entry.getValue().get("materials"); for (MaterialContext materialContext : materials) { blenderContext.addLinkedFeature( linkedDataFilePath, "MA" + materialContext.getName(), materialContext); } List<Texture> textures = (List<Texture>) entry.getValue().get("textures"); for (Texture texture : textures) { blenderContext.addLinkedFeature( linkedDataFilePath, "TE" + texture.getName(), texture); } List<Texture> images = (List<Texture>) entry.getValue().get("images"); for (Texture image : images) { blenderContext.addLinkedFeature(linkedDataFilePath, "IM" + image.getName(), image); } List<Animation> animations = (List<Animation>) entry.getValue().get("animations"); for (Animation animation : animations) { blenderContext.addLinkedFeature( linkedDataFilePath, "AC" + animation.getName(), animation); } List<Camera> cameras = (List<Camera>) entry.getValue().get("cameras"); for (Camera camera : cameras) { blenderContext.addLinkedFeature(linkedDataFilePath, "CA" + camera.getName(), camera); } List<Light> lights = (List<Light>) entry.getValue().get("lights"); for (Light light : lights) { blenderContext.addLinkedFeature(linkedDataFilePath, "LA" + light.getName(), light); } Spatial sky = (Spatial) entry.getValue().get("sky"); if (sky != null) { blenderContext.addLinkedFeature(linkedDataFilePath, sky.getName(), sky); } List<Filter> filters = (List<Filter>) entry.getValue().get("filters"); for (Filter filter : filters) { blenderContext.addLinkedFeature(linkedDataFilePath, filter.getName(), filter); } } } else { LOGGER.log(Level.WARNING, "No features loaded from path: {0}.", path); } } Object result = blenderContext.getLinkedFeature(path, fullName); if (result == null) { LOGGER.log( Level.WARNING, "Could NOT find asset named {0} in the library of path: {1}.", new Object[] {nameOfFeatureToLoad, path}); } else { blenderContext.addLoadedFeatures(id.getOldMemoryAddress(), LoadedDataType.STRUCTURE, id); blenderContext.addLoadedFeatures(id.getOldMemoryAddress(), LoadedDataType.FEATURE, result); } return result; } else { LOGGER.warning("Library link points to nothing!"); } return null; }
protected void renderMultipassLighting(Shader shader, Geometry g, RenderManager rm) { Renderer r = rm.getRenderer(); LightList lightList = g.getWorldLightList(); Uniform lightDir = shader.getUniform("g_LightDirection"); Uniform lightColor = shader.getUniform("g_LightColor"); Uniform lightPos = shader.getUniform("g_LightPosition"); Uniform ambientColor = shader.getUniform("g_AmbientLightColor"); boolean isFirstLight = true; boolean isSecondLight = false; for (int i = 0; i < lightList.size(); i++) { Light l = lightList.get(i); if (l instanceof AmbientLight) { continue; } if (isFirstLight) { // set ambient color for first light only ambientColor.setValue(VarType.Vector4, getAmbientColor(lightList)); isFirstLight = false; isSecondLight = true; } else if (isSecondLight) { ambientColor.setValue(VarType.Vector4, ColorRGBA.Black); // apply additive blending for 2nd and future lights r.applyRenderState(additiveLight); isSecondLight = false; } TempVars vars = TempVars.get(); Quaternion tmpLightDirection = vars.quat1; Quaternion tmpLightPosition = vars.quat2; ColorRGBA tmpLightColor = vars.color; Vector4f tmpVec = vars.vect4f; ColorRGBA color = l.getColor(); tmpLightColor.set(color); tmpLightColor.a = l.getType().getId(); lightColor.setValue(VarType.Vector4, tmpLightColor); switch (l.getType()) { case Directional: DirectionalLight dl = (DirectionalLight) l; Vector3f dir = dl.getDirection(); tmpLightPosition.set(dir.getX(), dir.getY(), dir.getZ(), -1); lightPos.setValue(VarType.Vector4, tmpLightPosition); tmpLightDirection.set(0, 0, 0, 0); lightDir.setValue(VarType.Vector4, tmpLightDirection); break; case Point: PointLight pl = (PointLight) l; Vector3f pos = pl.getPosition(); float invRadius = pl.getInvRadius(); tmpLightPosition.set(pos.getX(), pos.getY(), pos.getZ(), invRadius); lightPos.setValue(VarType.Vector4, tmpLightPosition); tmpLightDirection.set(0, 0, 0, 0); lightDir.setValue(VarType.Vector4, tmpLightDirection); break; case Spot: SpotLight sl = (SpotLight) l; Vector3f pos2 = sl.getPosition(); Vector3f dir2 = sl.getDirection(); float invRange = sl.getInvSpotRange(); float spotAngleCos = sl.getPackedAngleCos(); tmpLightPosition.set(pos2.getX(), pos2.getY(), pos2.getZ(), invRange); lightPos.setValue(VarType.Vector4, tmpLightPosition); // We transform the spot directoin in view space here to save 5 varying later in the // lighting shader // one vec4 less and a vec4 that becomes a vec3 // the downside is that spotAngleCos decoding happen now in the frag shader. tmpVec.set(dir2.getX(), dir2.getY(), dir2.getZ(), 0); rm.getCurrentCamera().getViewMatrix().mult(tmpVec, tmpVec); tmpLightDirection.set(tmpVec.getX(), tmpVec.getY(), tmpVec.getZ(), spotAngleCos); lightDir.setValue(VarType.Vector4, tmpLightDirection); break; default: throw new UnsupportedOperationException("Unknown type of light: " + l.getType()); } vars.release(); r.setShader(shader); r.renderMesh(g.getMesh(), g.getLodLevel(), 1); } if (isFirstLight && lightList.size() > 0) { // There are only ambient lights in the scene. Render // a dummy "normal light" so we can see the ambient ambientColor.setValue(VarType.Vector4, getAmbientColor(lightList)); lightColor.setValue(VarType.Vector4, ColorRGBA.BlackNoAlpha); lightPos.setValue(VarType.Vector4, nullDirLight); r.setShader(shader); r.renderMesh(g.getMesh(), g.getLodLevel(), 1); } }
/** * Uploads the lights in the light list as two uniform arrays.<br> * <br> * * * * <p><code>uniform vec4 g_LightColor[numLights];</code><br> * // g_LightColor.rgb is the diffuse/specular color of the light.<br> * // g_Lightcolor.a is the type of light, 0 = Directional, 1 = Point, <br> * // 2 = Spot. <br> * <br> * <code>uniform vec4 g_LightPosition[numLights];</code><br> * // g_LightPosition.xyz is the position of the light (for point lights)<br> * // or the direction of the light (for directional lights).<br> * // g_LightPosition.w is the inverse radius (1/r) of the light (for attenuation) <br> */ protected void updateLightListUniforms(Shader shader, Geometry g, int numLights) { if (numLights == 0) { // this shader does not do lighting, ignore. return; } LightList lightList = g.getWorldLightList(); Uniform lightColor = shader.getUniform("g_LightColor"); Uniform lightPos = shader.getUniform("g_LightPosition"); Uniform lightDir = shader.getUniform("g_LightDirection"); lightColor.setVector4Length(numLights); lightPos.setVector4Length(numLights); lightDir.setVector4Length(numLights); Uniform ambientColor = shader.getUniform("g_AmbientLightColor"); ambientColor.setValue(VarType.Vector4, getAmbientColor(lightList)); int lightIndex = 0; for (int i = 0; i < numLights; i++) { if (lightList.size() <= i) { lightColor.setVector4InArray(0f, 0f, 0f, 0f, lightIndex); lightPos.setVector4InArray(0f, 0f, 0f, 0f, lightIndex); } else { Light l = lightList.get(i); ColorRGBA color = l.getColor(); lightColor.setVector4InArray( color.getRed(), color.getGreen(), color.getBlue(), l.getType().getId(), i); switch (l.getType()) { case Directional: DirectionalLight dl = (DirectionalLight) l; Vector3f dir = dl.getDirection(); lightPos.setVector4InArray(dir.getX(), dir.getY(), dir.getZ(), -1, lightIndex); break; case Point: PointLight pl = (PointLight) l; Vector3f pos = pl.getPosition(); float invRadius = pl.getInvRadius(); lightPos.setVector4InArray(pos.getX(), pos.getY(), pos.getZ(), invRadius, lightIndex); break; case Spot: SpotLight sl = (SpotLight) l; Vector3f pos2 = sl.getPosition(); Vector3f dir2 = sl.getDirection(); float invRange = sl.getInvSpotRange(); float spotAngleCos = sl.getPackedAngleCos(); lightPos.setVector4InArray(pos2.getX(), pos2.getY(), pos2.getZ(), invRange, lightIndex); lightDir.setVector4InArray( dir2.getX(), dir2.getY(), dir2.getZ(), spotAngleCos, lightIndex); break; case Ambient: // skip this light. Does not increase lightIndex continue; default: throw new UnsupportedOperationException("Unknown type of light: " + l.getType()); } } lightIndex++; } while (lightIndex < numLights) { lightColor.setVector4InArray(0f, 0f, 0f, 0f, lightIndex); lightPos.setVector4InArray(0f, 0f, 0f, 0f, lightIndex); lightIndex++; } }
/** @param l */ public LightModel(Light l) { light = l; if (!(l instanceof AmbientLight)) { symbolMaterial = new Material( CurrentData.getEditorWindow().getB3DApp().getAssetManager(), "Common/MatDefs/Misc/Unshaded.j3md"); symbolMaterial.setColor("Color", l.getColor()); representativeMaterial = new Material( CurrentData.getEditorWindow().getB3DApp().getAssetManager(), "Common/MatDefs/Light/Lighting.j3md"); if (l instanceof DirectionalLight) { /*Light*/ DirectionalLight dLight = (DirectionalLight) l; /*Representativ*/ representativeMaterial.setTexture( "DiffuseMap", CurrentData.getEditorWindow() .getB3DApp() .getAssetManager() .loadTexture("Textures/showDirectionalLightTexture.PNG")); representative = new Geometry("LightModel", new Box(1, 1, 1)); representative.setMaterial(representativeMaterial); /*Symbol*/ Vector3f end = CurrentData.getEditorWindow() .getB3DApp() .getCamera() .getLocation() .add(CurrentData.getEditorWindow().getB3DApp().getCamera().getDirection().mult(20)) .add(dLight.getDirection().mult(100)); Line symbolMesh = new Line(representative.getWorldTranslation(), end); symbolMesh.setPointSize(5); symbol = new Geometry("LightSymbol", symbolMesh); symbol.setMaterial(symbolMaterial); } else if (l instanceof PointLight) { PointLight pLight = (PointLight) l; representativeMaterial.setTexture( "DiffuseMap", CurrentData.getEditorWindow() .getB3DApp() .getAssetManager() .loadTexture("Textures/showPointLightTexture.PNG")); representative = new Geometry("LightModel", new Box(1, 1, 1)); representative.setMaterial(representativeMaterial); representative.setLocalTranslation(pLight.getPosition()); symbol = new Geometry("LightSymbol", new Sphere(15, 15, pLight.getRadius())); symbol.setMaterial(symbolMaterial); symbolMaterial.getAdditionalRenderState().setWireframe(true); } else if (l instanceof SpotLight) { /*Light*/ SpotLight sLight = (SpotLight) l; /*Representativ*/ representativeMaterial.setTexture( "DiffuseMap", CurrentData.getEditorWindow() .getB3DApp() .getAssetManager() .loadTexture("Textures/showSpotLightTexture.PNG")); representative = new Geometry("LightModel", new Box(1, 1, 1)); representative.setLocalTranslation(sLight.getPosition()); representative.setMaterial(representativeMaterial); /*Symbol*/ Vector3f end = sLight.getPosition().add(sLight.getDirection().mult(sLight.getSpotRange())); Line symbolMesh = new Line(representative.getWorldTranslation(), end); symbolMesh.setPointSize(5); symbol = new Geometry("LightSymbol", symbolMesh); symbol.setMaterial(symbolMaterial); } node.attachChild(representative); if (symbol != null) { node.attachChild(symbol); } } }