/// var BABYLON; (function (BABYLON) { var maxSimultaneousLights = 4; var PBRMaterialDefines = (function (_super) { __extends(PBRMaterialDefines, _super); function PBRMaterialDefines() { _super.call(this); this.ALBEDO = false; this.AMBIENT = false; this.OPACITY = false; this.OPACITYRGB = false; this.REFLECTION = false; this.EMISSIVE = false; this.REFLECTIVITY = false; this.BUMP = false; this.SPECULAROVERALPHA = false; this.CLIPPLANE = false; this.ALPHATEST = false; this.ALPHAFROMALBEDO = false; this.POINTSIZE = false; this.FOG = false; this.LIGHT0 = false; this.LIGHT1 = false; this.LIGHT2 = false; this.LIGHT3 = false; this.SPOTLIGHT0 = false; this.SPOTLIGHT1 = false; this.SPOTLIGHT2 = false; this.SPOTLIGHT3 = false; this.HEMILIGHT0 = false; this.HEMILIGHT1 = false; this.HEMILIGHT2 = false; this.HEMILIGHT3 = false; this.POINTLIGHT0 = false; this.POINTLIGHT1 = false; this.POINTLIGHT2 = false; this.POINTLIGHT3 = false; this.DIRLIGHT0 = false; this.DIRLIGHT1 = false; this.DIRLIGHT2 = false; this.DIRLIGHT3 = false; this.SPECULARTERM = false; this.SHADOW0 = false; this.SHADOW1 = false; this.SHADOW2 = false; this.SHADOW3 = false; this.SHADOWS = false; this.SHADOWVSM0 = false; this.SHADOWVSM1 = false; this.SHADOWVSM2 = false; this.SHADOWVSM3 = false; this.SHADOWPCF0 = false; this.SHADOWPCF1 = false; this.SHADOWPCF2 = false; this.SHADOWPCF3 = false; this.OPACITYFRESNEL = false; this.EMISSIVEFRESNEL = false; this.FRESNEL = false; this.NORMAL = false; this.UV1 = false; this.UV2 = false; this.VERTEXCOLOR = false; this.VERTEXALPHA = false; this.NUM_BONE_INFLUENCERS = 0; this.BonesPerMesh = 0; this.INSTANCES = false; this.MICROSURFACEFROMREFLECTIVITYMAP = false; this.MICROSURFACEAUTOMATIC = false; this.EMISSIVEASILLUMINATION = false; this.LINKEMISSIVEWITHALBEDO = false; this.LIGHTMAP = false; this.USELIGHTMAPASSHADOWMAP = false; this.REFLECTIONMAP_3D = false; this.REFLECTIONMAP_SPHERICAL = false; this.REFLECTIONMAP_PLANAR = false; this.REFLECTIONMAP_CUBIC = false; this.REFLECTIONMAP_PROJECTION = false; this.REFLECTIONMAP_SKYBOX = false; this.REFLECTIONMAP_EXPLICIT = false; this.REFLECTIONMAP_EQUIRECTANGULAR = false; this.INVERTCUBICMAP = false; this.LOGARITHMICDEPTH = false; this.CAMERATONEMAP = false; this.CAMERACONTRAST = false; this.OVERLOADEDVALUES = false; this.OVERLOADEDSHADOWVALUES = false; this.USESPHERICALFROMREFLECTIONMAP = false; this.REFRACTION = false; this.REFRACTIONMAP_3D = false; this.LINKREFRACTIONTOTRANSPARENCY = false; this.REFRACTIONMAPINLINEARSPACE = false; this.LODBASEDMICROSFURACE = false; this._keys = Object.keys(this); } return PBRMaterialDefines; })(BABYLON.MaterialDefines); var PBRMaterial = (function (_super) { __extends(PBRMaterial, _super); function PBRMaterial(name, scene) { var _this = this; _super.call(this, name, scene); this.directIntensity = 1.0; this.emissiveIntensity = 1.0; this.environmentIntensity = 1.0; this.specularIntensity = 1.0; this._lightingInfos = new BABYLON.Vector4(this.directIntensity, this.emissiveIntensity, this.environmentIntensity, this.specularIntensity); this.overloadedShadowIntensity = 1.0; this.overloadedShadeIntensity = 1.0; this._overloadedShadowInfos = new BABYLON.Vector4(this.overloadedShadowIntensity, this.overloadedShadeIntensity, 0.0, 0.0); this.cameraExposure = 1.0; this.cameraContrast = 1.0; this._cameraInfos = new BABYLON.Vector4(1.0, 1.0, 0.0, 0.0); this._microsurfaceTextureLods = new BABYLON.Vector2(0.0, 0.0); this.overloadedAmbientIntensity = 0.0; this.overloadedAlbedoIntensity = 0.0; this.overloadedReflectivityIntensity = 0.0; this.overloadedEmissiveIntensity = 0.0; this._overloadedIntensity = new BABYLON.Vector4(this.overloadedAmbientIntensity, this.overloadedAlbedoIntensity, this.overloadedReflectivityIntensity, this.overloadedEmissiveIntensity); this.overloadedAmbient = BABYLON.Color3.White(); this.overloadedAlbedo = BABYLON.Color3.White(); this.overloadedReflectivity = BABYLON.Color3.White(); this.overloadedEmissive = BABYLON.Color3.White(); this.overloadedReflection = BABYLON.Color3.White(); this.overloadedMicroSurface = 0.0; this.overloadedMicroSurfaceIntensity = 0.0; this.overloadedReflectionIntensity = 0.0; this._overloadedMicroSurface = new BABYLON.Vector3(this.overloadedMicroSurface, this.overloadedMicroSurfaceIntensity, this.overloadedReflectionIntensity); this.disableBumpMap = false; this.ambientColor = new BABYLON.Color3(0, 0, 0); this.albedoColor = new BABYLON.Color3(1, 1, 1); this.reflectivityColor = new BABYLON.Color3(1, 1, 1); this.reflectionColor = new BABYLON.Color3(0.5, 0.5, 0.5); this.microSurface = 0.5; this.emissiveColor = new BABYLON.Color3(0, 0, 0); this.useAlphaFromAlbedoTexture = false; this.useEmissiveAsIllumination = false; this.linkEmissiveWithAlbedo = false; this.useSpecularOverAlpha = true; this.disableLighting = false; this.indexOfRefraction = 0.66; this.invertRefractionY = false; this.linkRefractionWithTransparency = false; this.useLightmapAsShadowmap = false; this.useMicroSurfaceFromReflectivityMapAlpha = false; this.useAutoMicroSurfaceFromReflectivityMap = false; this.useScalarInLinearSpace = false; this._renderTargets = new BABYLON.SmartArray(16); this._worldViewProjectionMatrix = BABYLON.Matrix.Zero(); this._globalAmbientColor = new BABYLON.Color3(0, 0, 0); this._tempColor = new BABYLON.Color3(); this._defines = new PBRMaterialDefines(); this._cachedDefines = new PBRMaterialDefines(); this._myScene = null; this._myShadowGenerator = null; this._cachedDefines.BonesPerMesh = -1; this.getRenderTargetTextures = function () { _this._renderTargets.reset(); if (_this.reflectionTexture && _this.reflectionTexture.isRenderTarget) { _this._renderTargets.push(_this.reflectionTexture); } if (_this.refractionTexture && _this.refractionTexture.isRenderTarget) { _this._renderTargets.push(_this.refractionTexture); } return _this._renderTargets; }; } Object.defineProperty(PBRMaterial.prototype, "useLogarithmicDepth", { get: function () { return this._useLogarithmicDepth; }, set: function (value) { this._useLogarithmicDepth = value && this.getScene().getEngine().getCaps().fragmentDepthSupported; }, enumerable: true, configurable: true }); PBRMaterial.prototype.needAlphaBlending = function () { if (this.linkRefractionWithTransparency) { return false; } return (this.alpha < 1.0) || (this.opacityTexture != null) || this._shouldUseAlphaFromAlbedoTexture() || this.opacityFresnelParameters && this.opacityFresnelParameters.isEnabled; }; PBRMaterial.prototype.needAlphaTesting = function () { if (this.linkRefractionWithTransparency) { return false; } return this.albedoTexture != null && this.albedoTexture.hasAlpha; }; PBRMaterial.prototype._shouldUseAlphaFromAlbedoTexture = function () { return this.albedoTexture != null && this.albedoTexture.hasAlpha && this.useAlphaFromAlbedoTexture; }; PBRMaterial.prototype.getAlphaTestTexture = function () { return this.albedoTexture; }; PBRMaterial.prototype._checkCache = function (scene, mesh, useInstances) { if (!mesh) { return true; } if (this._defines.INSTANCES !== useInstances) { return false; } if (mesh._materialDefines && mesh._materialDefines.isEqual(this._defines)) { return true; } return false; }; PBRMaterial.prototype.convertColorToLinearSpaceToRef = function (color, ref) { PBRMaterial.convertColorToLinearSpaceToRef(color, ref, this.useScalarInLinearSpace); }; PBRMaterial.convertColorToLinearSpaceToRef = function (color, ref, useScalarInLinear) { if (!useScalarInLinear) { color.toLinearSpaceToRef(ref); } else { ref.r = color.r; ref.g = color.g; ref.b = color.b; } }; PBRMaterial.BindLights = function (scene, mesh, effect, defines, useScalarInLinearSpace) { var lightIndex = 0; var depthValuesAlreadySet = false; for (var index = 0; index < scene.lights.length; index++) { var light = scene.lights[index]; if (!light.isEnabled()) { continue; } if (!light.canAffectMesh(mesh)) { continue; } this._lightRadiuses[lightIndex] = light.radius; BABYLON.MaterialHelper.BindLightProperties(light, effect, lightIndex); // GAMMA CORRECTION. this.convertColorToLinearSpaceToRef(light.diffuse, PBRMaterial._scaledAlbedo, useScalarInLinearSpace); PBRMaterial._scaledAlbedo.scaleToRef(light.intensity, PBRMaterial._scaledAlbedo); effect.setColor4("vLightDiffuse" + lightIndex, PBRMaterial._scaledAlbedo, light.range); if (defines["SPECULARTERM"]) { this.convertColorToLinearSpaceToRef(light.specular, PBRMaterial._scaledReflectivity, useScalarInLinearSpace); PBRMaterial._scaledReflectivity.scaleToRef(light.intensity, PBRMaterial._scaledReflectivity); effect.setColor3("vLightSpecular" + lightIndex, PBRMaterial._scaledReflectivity); } // Shadows if (scene.shadowsEnabled) { depthValuesAlreadySet = BABYLON.MaterialHelper.BindLightShadow(light, scene, mesh, lightIndex, effect, depthValuesAlreadySet); } lightIndex++; if (lightIndex === maxSimultaneousLights) break; } effect.setFloat4("vLightRadiuses", this._lightRadiuses[0], this._lightRadiuses[1], this._lightRadiuses[2], this._lightRadiuses[3]); }; PBRMaterial.prototype.isReady = function (mesh, useInstances) { if (this.checkReadyOnlyOnce) { if (this._wasPreviouslyReady) { return true; } } var scene = this.getScene(); if (!this.checkReadyOnEveryCall) { if (this._renderId === scene.getRenderId()) { if (this._checkCache(scene, mesh, useInstances)) { return true; } } } var engine = scene.getEngine(); var needNormals = false; var needUVs = false; this._defines.reset(); if (scene.texturesEnabled) { // Textures if (scene.texturesEnabled) { if (scene.getEngine().getCaps().textureLOD) { this._defines.LODBASEDMICROSFURACE = true; } if (this.albedoTexture && BABYLON.StandardMaterial.DiffuseTextureEnabled) { if (!this.albedoTexture.isReady()) { return false; } else { needUVs = true; this._defines.ALBEDO = true; } } if (this.ambientTexture && BABYLON.StandardMaterial.AmbientTextureEnabled) { if (!this.ambientTexture.isReady()) { return false; } else { needUVs = true; this._defines.AMBIENT = true; } } if (this.opacityTexture && BABYLON.StandardMaterial.OpacityTextureEnabled) { if (!this.opacityTexture.isReady()) { return false; } else { needUVs = true; this._defines.OPACITY = true; if (this.opacityTexture.getAlphaFromRGB) { this._defines.OPACITYRGB = true; } } } if (this.reflectionTexture && BABYLON.StandardMaterial.ReflectionTextureEnabled) { if (!this.reflectionTexture.isReady()) { return false; } else { needNormals = true; this._defines.REFLECTION = true; if (this.reflectionTexture.coordinatesMode === BABYLON.Texture.INVCUBIC_MODE) { this._defines.INVERTCUBICMAP = true; } this._defines.REFLECTIONMAP_3D = this.reflectionTexture.isCube; switch (this.reflectionTexture.coordinatesMode) { case BABYLON.Texture.CUBIC_MODE: case BABYLON.Texture.INVCUBIC_MODE: this._defines.REFLECTIONMAP_CUBIC = true; break; case BABYLON.Texture.EXPLICIT_MODE: this._defines.REFLECTIONMAP_EXPLICIT = true; break; case BABYLON.Texture.PLANAR_MODE: this._defines.REFLECTIONMAP_PLANAR = true; break; case BABYLON.Texture.PROJECTION_MODE: this._defines.REFLECTIONMAP_PROJECTION = true; break; case BABYLON.Texture.SKYBOX_MODE: this._defines.REFLECTIONMAP_SKYBOX = true; break; case BABYLON.Texture.SPHERICAL_MODE: this._defines.REFLECTIONMAP_SPHERICAL = true; break; case BABYLON.Texture.EQUIRECTANGULAR_MODE: this._defines.REFLECTIONMAP_EQUIRECTANGULAR = true; break; } if (this.reflectionTexture instanceof BABYLON.HDRCubeTexture && this.reflectionTexture) { this._defines.USESPHERICALFROMREFLECTIONMAP = true; needNormals = true; } } } if (this.lightmapTexture && BABYLON.StandardMaterial.LightmapTextureEnabled) { if (!this.lightmapTexture.isReady()) { return false; } else { needUVs = true; this._defines.LIGHTMAP = true; this._defines.USELIGHTMAPASSHADOWMAP = this.useLightmapAsShadowmap; } } if (this.emissiveTexture && BABYLON.StandardMaterial.EmissiveTextureEnabled) { if (!this.emissiveTexture.isReady()) { return false; } else { needUVs = true; this._defines.EMISSIVE = true; } } if (this.reflectivityTexture && BABYLON.StandardMaterial.SpecularTextureEnabled) { if (!this.reflectivityTexture.isReady()) { return false; } else { needUVs = true; this._defines.REFLECTIVITY = true; this._defines.MICROSURFACEFROMREFLECTIVITYMAP = this.useMicroSurfaceFromReflectivityMapAlpha; this._defines.MICROSURFACEAUTOMATIC = this.useAutoMicroSurfaceFromReflectivityMap; } } } if (scene.getEngine().getCaps().standardDerivatives && this.bumpTexture && BABYLON.StandardMaterial.BumpTextureEnabled && !this.disableBumpMap) { if (!this.bumpTexture.isReady()) { return false; } else { needUVs = true; this._defines.BUMP = true; } } if (this.refractionTexture && BABYLON.StandardMaterial.RefractionTextureEnabled) { if (!this.refractionTexture.isReady()) { return false; } else { needUVs = true; this._defines.REFRACTION = true; this._defines.REFRACTIONMAP_3D = this.refractionTexture.isCube; if (this.linkRefractionWithTransparency) { this._defines.LINKREFRACTIONTOTRANSPARENCY = true; } if (this.refractionTexture instanceof BABYLON.HDRCubeTexture) { this._defines.REFRACTIONMAPINLINEARSPACE = true; } } } } // Effect if (scene.clipPlane) { this._defines.CLIPPLANE = true; } if (engine.getAlphaTesting()) { this._defines.ALPHATEST = true; } if (this._shouldUseAlphaFromAlbedoTexture()) { this._defines.ALPHAFROMALBEDO = true; } if (this.useEmissiveAsIllumination) { this._defines.EMISSIVEASILLUMINATION = true; } if (this.linkEmissiveWithAlbedo) { this._defines.LINKEMISSIVEWITHALBEDO = true; } if (this.useLogarithmicDepth) { this._defines.LOGARITHMICDEPTH = true; } if (this.cameraContrast != 1) { this._defines.CAMERACONTRAST = true; } if (this.cameraExposure != 1) { this._defines.CAMERATONEMAP = true; } if (this.overloadedShadeIntensity != 1 || this.overloadedShadowIntensity != 1) { this._defines.OVERLOADEDSHADOWVALUES = true; } if (this.overloadedMicroSurfaceIntensity > 0 || this.overloadedEmissiveIntensity > 0 || this.overloadedReflectivityIntensity > 0 || this.overloadedAlbedoIntensity > 0 || this.overloadedAmbientIntensity > 0 || this.overloadedReflectionIntensity > 0) { this._defines.OVERLOADEDVALUES = true; } // Point size if (this.pointsCloud || scene.forcePointsCloud) { this._defines.POINTSIZE = true; } // Fog if (scene.fogEnabled && mesh && mesh.applyFog && scene.fogMode !== BABYLON.Scene.FOGMODE_NONE && this.fogEnabled) { this._defines.FOG = true; } if (scene.lightsEnabled && !this.disableLighting) { needNormals = BABYLON.MaterialHelper.PrepareDefinesForLights(scene, mesh, this._defines) || needNormals; } if (BABYLON.StandardMaterial.FresnelEnabled) { // Fresnel if (this.opacityFresnelParameters && this.opacityFresnelParameters.isEnabled || this.emissiveFresnelParameters && this.emissiveFresnelParameters.isEnabled) { if (this.opacityFresnelParameters && this.opacityFresnelParameters.isEnabled) { this._defines.OPACITYFRESNEL = true; } if (this.emissiveFresnelParameters && this.emissiveFresnelParameters.isEnabled) { this._defines.EMISSIVEFRESNEL = true; } needNormals = true; this._defines.FRESNEL = true; } } if (this._defines.SPECULARTERM && this.useSpecularOverAlpha) { this._defines.SPECULAROVERALPHA = true; } // Attribs if (mesh) { if (needNormals && mesh.isVerticesDataPresent(BABYLON.VertexBuffer.NormalKind)) { this._defines.NORMAL = true; } if (needUVs) { if (mesh.isVerticesDataPresent(BABYLON.VertexBuffer.UVKind)) { this._defines.UV1 = true; } if (mesh.isVerticesDataPresent(BABYLON.VertexBuffer.UV2Kind)) { this._defines.UV2 = true; } } if (mesh.useVertexColors && mesh.isVerticesDataPresent(BABYLON.VertexBuffer.ColorKind)) { this._defines.VERTEXCOLOR = true; if (mesh.hasVertexAlpha) { this._defines.VERTEXALPHA = true; } } if (mesh.useBones && mesh.computeBonesUsingShaders) { this._defines.NUM_BONE_INFLUENCERS = mesh.numBoneInfluencers; this._defines.BonesPerMesh = (mesh.skeleton.bones.length + 1); } // Instances if (useInstances) { this._defines.INSTANCES = true; } } // Get correct effect if (!this._defines.isEqual(this._cachedDefines)) { this._defines.cloneTo(this._cachedDefines); scene.resetCachedMaterial(); // Fallbacks var fallbacks = new BABYLON.EffectFallbacks(); if (this._defines.REFLECTION) { fallbacks.addFallback(0, "REFLECTION"); } if (this._defines.REFLECTIVITY) { fallbacks.addFallback(0, "REFLECTIVITY"); } if (this._defines.BUMP) { fallbacks.addFallback(0, "BUMP"); } if (this._defines.SPECULAROVERALPHA) { fallbacks.addFallback(0, "SPECULAROVERALPHA"); } if (this._defines.FOG) { fallbacks.addFallback(1, "FOG"); } if (this._defines.POINTSIZE) { fallbacks.addFallback(0, "POINTSIZE"); } if (this._defines.LOGARITHMICDEPTH) { fallbacks.addFallback(0, "LOGARITHMICDEPTH"); } BABYLON.MaterialHelper.HandleFallbacksForShadows(this._defines, fallbacks); if (this._defines.SPECULARTERM) { fallbacks.addFallback(0, "SPECULARTERM"); } if (this._defines.OPACITYFRESNEL) { fallbacks.addFallback(1, "OPACITYFRESNEL"); } if (this._defines.EMISSIVEFRESNEL) { fallbacks.addFallback(2, "EMISSIVEFRESNEL"); } if (this._defines.FRESNEL) { fallbacks.addFallback(3, "FRESNEL"); } if (this._defines.NUM_BONE_INFLUENCERS > 0) { fallbacks.addCPUSkinningFallback(0, mesh); } //Attributes var attribs = [BABYLON.VertexBuffer.PositionKind]; if (this._defines.NORMAL) { attribs.push(BABYLON.VertexBuffer.NormalKind); } if (this._defines.UV1) { attribs.push(BABYLON.VertexBuffer.UVKind); } if (this._defines.UV2) { attribs.push(BABYLON.VertexBuffer.UV2Kind); } if (this._defines.VERTEXCOLOR) { attribs.push(BABYLON.VertexBuffer.ColorKind); } BABYLON.MaterialHelper.PrepareAttributesForBones(attribs, mesh, this._defines, fallbacks); BABYLON.MaterialHelper.PrepareAttributesForInstances(attribs, this._defines); // Legacy browser patch var shaderName = "pbr"; if (!scene.getEngine().getCaps().standardDerivatives) { shaderName = "legacypbr"; } var join = this._defines.toString(); this._effect = scene.getEngine().createEffect(shaderName, attribs, ["world", "view", "viewProjection", "vEyePosition", "vLightsType", "vAmbientColor", "vAlbedoColor", "vReflectivityColor", "vEmissiveColor", "vReflectionColor", "vLightData0", "vLightDiffuse0", "vLightSpecular0", "vLightDirection0", "vLightGround0", "lightMatrix0", "vLightData1", "vLightDiffuse1", "vLightSpecular1", "vLightDirection1", "vLightGround1", "lightMatrix1", "vLightData2", "vLightDiffuse2", "vLightSpecular2", "vLightDirection2", "vLightGround2", "lightMatrix2", "vLightData3", "vLightDiffuse3", "vLightSpecular3", "vLightDirection3", "vLightGround3", "lightMatrix3", "vFogInfos", "vFogColor", "pointSize", "vAlbedoInfos", "vAmbientInfos", "vOpacityInfos", "vReflectionInfos", "vEmissiveInfos", "vReflectivityInfos", "vBumpInfos", "vLightmapInfos", "vRefractionInfos", "mBones", "vClipPlane", "albedoMatrix", "ambientMatrix", "opacityMatrix", "reflectionMatrix", "emissiveMatrix", "reflectivityMatrix", "bumpMatrix", "lightmapMatrix", "refractionMatrix", "shadowsInfo0", "shadowsInfo1", "shadowsInfo2", "shadowsInfo3", "depthValues", "opacityParts", "emissiveLeftColor", "emissiveRightColor", "vLightingIntensity", "vOverloadedShadowIntensity", "vOverloadedIntensity", "vCameraInfos", "vOverloadedAlbedo", "vOverloadedReflection", "vOverloadedReflectivity", "vOverloadedEmissive", "vOverloadedMicroSurface", "logarithmicDepthConstant", "vSphericalX", "vSphericalY", "vSphericalZ", "vSphericalXX", "vSphericalYY", "vSphericalZZ", "vSphericalXY", "vSphericalYZ", "vSphericalZX", "vMicrosurfaceTextureLods", "vLightRadiuses" ], ["albedoSampler", "ambientSampler", "opacitySampler", "reflectionCubeSampler", "reflection2DSampler", "emissiveSampler", "reflectivitySampler", "bumpSampler", "lightmapSampler", "refractionCubeSampler", "refraction2DSampler", "shadowSampler0", "shadowSampler1", "shadowSampler2", "shadowSampler3" ], join, fallbacks, this.onCompiled, this.onError); } if (!this._effect.isReady()) { return false; } this._renderId = scene.getRenderId(); this._wasPreviouslyReady = true; if (mesh) { if (!mesh._materialDefines) { mesh._materialDefines = new PBRMaterialDefines(); } this._defines.cloneTo(mesh._materialDefines); } return true; }; PBRMaterial.prototype.unbind = function () { if (this.reflectionTexture && this.reflectionTexture.isRenderTarget) { this._effect.setTexture("reflection2DSampler", null); } if (this.refractionTexture && this.refractionTexture.isRenderTarget) { this._effect.setTexture("refraction2DSampler", null); } _super.prototype.unbind.call(this); }; PBRMaterial.prototype.bindOnlyWorldMatrix = function (world) { this._effect.setMatrix("world", world); }; PBRMaterial.prototype.bind = function (world, mesh) { this._myScene = this.getScene(); // Matrices this.bindOnlyWorldMatrix(world); // Bones BABYLON.MaterialHelper.BindBonesParameters(mesh, this._effect); if (this._myScene.getCachedMaterial() !== this) { this._effect.setMatrix("viewProjection", this._myScene.getTransformMatrix()); if (BABYLON.StandardMaterial.FresnelEnabled) { if (this.opacityFresnelParameters && this.opacityFresnelParameters.isEnabled) { this._effect.setColor4("opacityParts", new BABYLON.Color3(this.opacityFresnelParameters.leftColor.toLuminance(), this.opacityFresnelParameters.rightColor.toLuminance(), this.opacityFresnelParameters.bias), this.opacityFresnelParameters.power); } if (this.emissiveFresnelParameters && this.emissiveFresnelParameters.isEnabled) { this._effect.setColor4("emissiveLeftColor", this.emissiveFresnelParameters.leftColor, this.emissiveFresnelParameters.power); this._effect.setColor4("emissiveRightColor", this.emissiveFresnelParameters.rightColor, this.emissiveFresnelParameters.bias); } } // Textures if (this._myScene.texturesEnabled) { if (this.albedoTexture && BABYLON.StandardMaterial.DiffuseTextureEnabled) { this._effect.setTexture("albedoSampler", this.albedoTexture); this._effect.setFloat2("vAlbedoInfos", this.albedoTexture.coordinatesIndex, this.albedoTexture.level); this._effect.setMatrix("albedoMatrix", this.albedoTexture.getTextureMatrix()); } if (this.ambientTexture && BABYLON.StandardMaterial.AmbientTextureEnabled) { this._effect.setTexture("ambientSampler", this.ambientTexture); this._effect.setFloat2("vAmbientInfos", this.ambientTexture.coordinatesIndex, this.ambientTexture.level); this._effect.setMatrix("ambientMatrix", this.ambientTexture.getTextureMatrix()); } if (this.opacityTexture && BABYLON.StandardMaterial.OpacityTextureEnabled) { this._effect.setTexture("opacitySampler", this.opacityTexture); this._effect.setFloat2("vOpacityInfos", this.opacityTexture.coordinatesIndex, this.opacityTexture.level); this._effect.setMatrix("opacityMatrix", this.opacityTexture.getTextureMatrix()); } if (this.reflectionTexture && BABYLON.StandardMaterial.ReflectionTextureEnabled) { this._microsurfaceTextureLods.x = Math.log(this.reflectionTexture.getSize().width) * Math.LOG2E; if (this.reflectionTexture.isCube) { this._effect.setTexture("reflectionCubeSampler", this.reflectionTexture); } else { this._effect.setTexture("reflection2DSampler", this.reflectionTexture); } this._effect.setMatrix("reflectionMatrix", this.reflectionTexture.getReflectionTextureMatrix()); this._effect.setFloat2("vReflectionInfos", this.reflectionTexture.level, 0); if (this._defines.USESPHERICALFROMREFLECTIONMAP) { this._effect.setFloat3("vSphericalX", this.reflectionTexture.sphericalPolynomial.x.x, this.reflectionTexture.sphericalPolynomial.x.y, this.reflectionTexture.sphericalPolynomial.x.z); this._effect.setFloat3("vSphericalY", this.reflectionTexture.sphericalPolynomial.y.x, this.reflectionTexture.sphericalPolynomial.y.y, this.reflectionTexture.sphericalPolynomial.y.z); this._effect.setFloat3("vSphericalZ", this.reflectionTexture.sphericalPolynomial.z.x, this.reflectionTexture.sphericalPolynomial.z.y, this.reflectionTexture.sphericalPolynomial.z.z); this._effect.setFloat3("vSphericalXX", this.reflectionTexture.sphericalPolynomial.xx.x, this.reflectionTexture.sphericalPolynomial.xx.y, this.reflectionTexture.sphericalPolynomial.xx.z); this._effect.setFloat3("vSphericalYY", this.reflectionTexture.sphericalPolynomial.yy.x, this.reflectionTexture.sphericalPolynomial.yy.y, this.reflectionTexture.sphericalPolynomial.yy.z); this._effect.setFloat3("vSphericalZZ", this.reflectionTexture.sphericalPolynomial.zz.x, this.reflectionTexture.sphericalPolynomial.zz.y, this.reflectionTexture.sphericalPolynomial.zz.z); this._effect.setFloat3("vSphericalXY", this.reflectionTexture.sphericalPolynomial.xy.x, this.reflectionTexture.sphericalPolynomial.xy.y, this.reflectionTexture.sphericalPolynomial.xy.z); this._effect.setFloat3("vSphericalYZ", this.reflectionTexture.sphericalPolynomial.yz.x, this.reflectionTexture.sphericalPolynomial.yz.y, this.reflectionTexture.sphericalPolynomial.yz.z); this._effect.setFloat3("vSphericalZX", this.reflectionTexture.sphericalPolynomial.zx.x, this.reflectionTexture.sphericalPolynomial.zx.y, this.reflectionTexture.sphericalPolynomial.zx.z); } } if (this.emissiveTexture && BABYLON.StandardMaterial.EmissiveTextureEnabled) { this._effect.setTexture("emissiveSampler", this.emissiveTexture); this._effect.setFloat2("vEmissiveInfos", this.emissiveTexture.coordinatesIndex, this.emissiveTexture.level); this._effect.setMatrix("emissiveMatrix", this.emissiveTexture.getTextureMatrix()); } if (this.lightmapTexture && BABYLON.StandardMaterial.LightmapTextureEnabled) { this._effect.setTexture("lightmapSampler", this.lightmapTexture); this._effect.setFloat2("vLightmapInfos", this.lightmapTexture.coordinatesIndex, this.lightmapTexture.level); this._effect.setMatrix("lightmapMatrix", this.lightmapTexture.getTextureMatrix()); } if (this.reflectivityTexture && BABYLON.StandardMaterial.SpecularTextureEnabled) { this._effect.setTexture("reflectivitySampler", this.reflectivityTexture); this._effect.setFloat2("vReflectivityInfos", this.reflectivityTexture.coordinatesIndex, this.reflectivityTexture.level); this._effect.setMatrix("reflectivityMatrix", this.reflectivityTexture.getTextureMatrix()); } if (this.bumpTexture && this._myScene.getEngine().getCaps().standardDerivatives && BABYLON.StandardMaterial.BumpTextureEnabled && !this.disableBumpMap) { this._effect.setTexture("bumpSampler", this.bumpTexture); this._effect.setFloat2("vBumpInfos", this.bumpTexture.coordinatesIndex, 1.0 / this.bumpTexture.level); this._effect.setMatrix("bumpMatrix", this.bumpTexture.getTextureMatrix()); } if (this.refractionTexture && BABYLON.StandardMaterial.RefractionTextureEnabled) { this._microsurfaceTextureLods.y = Math.log(this.refractionTexture.getSize().width) * Math.LOG2E; var depth = 1.0; if (this.refractionTexture.isCube) { this._effect.setTexture("refractionCubeSampler", this.refractionTexture); } else { this._effect.setTexture("refraction2DSampler", this.refractionTexture); this._effect.setMatrix("refractionMatrix", this.refractionTexture.getReflectionTextureMatrix()); if (this.refractionTexture.depth) { depth = this.refractionTexture.depth; } } this._effect.setFloat4("vRefractionInfos", this.refractionTexture.level, this.indexOfRefraction, depth, this.invertRefractionY ? -1 : 1); } if ((this.reflectionTexture || this.refractionTexture) && this._myScene.getEngine().getCaps().textureLOD) { this._effect.setFloat2("vMicrosurfaceTextureLods", this._microsurfaceTextureLods.x, this._microsurfaceTextureLods.y); } } // Clip plane BABYLON.MaterialHelper.BindClipPlane(this._effect, this._myScene); // Point size if (this.pointsCloud) { this._effect.setFloat("pointSize", this.pointSize); } // Colors this._myScene.ambientColor.multiplyToRef(this.ambientColor, this._globalAmbientColor); // GAMMA CORRECTION. this.convertColorToLinearSpaceToRef(this.reflectivityColor, PBRMaterial._scaledReflectivity); this._effect.setVector3("vEyePosition", this._myScene._mirroredCameraPosition ? this._myScene._mirroredCameraPosition : this._myScene.activeCamera.position); this._effect.setColor3("vAmbientColor", this._globalAmbientColor); this._effect.setColor4("vReflectivityColor", PBRMaterial._scaledReflectivity, this.microSurface); // GAMMA CORRECTION. this.convertColorToLinearSpaceToRef(this.emissiveColor, PBRMaterial._scaledEmissive); this._effect.setColor3("vEmissiveColor", PBRMaterial._scaledEmissive); // GAMMA CORRECTION. this.convertColorToLinearSpaceToRef(this.reflectionColor, PBRMaterial._scaledReflection); this._effect.setColor3("vReflectionColor", PBRMaterial._scaledReflection); } if (this._myScene.getCachedMaterial() !== this || !this.isFrozen) { // GAMMA CORRECTION. this.convertColorToLinearSpaceToRef(this.albedoColor, PBRMaterial._scaledAlbedo); this._effect.setColor4("vAlbedoColor", PBRMaterial._scaledAlbedo, this.alpha * mesh.visibility); // Lights if (this._myScene.lightsEnabled && !this.disableLighting) { PBRMaterial.BindLights(this._myScene, mesh, this._effect, this._defines, this.useScalarInLinearSpace); } // View if (this._myScene.fogEnabled && mesh.applyFog && this._myScene.fogMode !== BABYLON.Scene.FOGMODE_NONE || this.reflectionTexture) { this._effect.setMatrix("view", this._myScene.getViewMatrix()); } // Fog BABYLON.MaterialHelper.BindFogParameters(this._myScene, mesh, this._effect); this._lightingInfos.x = this.directIntensity; this._lightingInfos.y = this.emissiveIntensity; this._lightingInfos.z = this.environmentIntensity; this._lightingInfos.w = this.specularIntensity; this._effect.setVector4("vLightingIntensity", this._lightingInfos); this._overloadedShadowInfos.x = this.overloadedShadowIntensity; this._overloadedShadowInfos.y = this.overloadedShadeIntensity; this._effect.setVector4("vOverloadedShadowIntensity", this._overloadedShadowInfos); this._cameraInfos.x = this.cameraExposure; this._cameraInfos.y = this.cameraContrast; this._effect.setVector4("vCameraInfos", this._cameraInfos); this._overloadedIntensity.x = this.overloadedAmbientIntensity; this._overloadedIntensity.y = this.overloadedAlbedoIntensity; this._overloadedIntensity.z = this.overloadedReflectivityIntensity; this._overloadedIntensity.w = this.overloadedEmissiveIntensity; this._effect.setVector4("vOverloadedIntensity", this._overloadedIntensity); this.convertColorToLinearSpaceToRef(this.overloadedAmbient, this._tempColor); this._effect.setColor3("vOverloadedAmbient", this._tempColor); this.convertColorToLinearSpaceToRef(this.overloadedAlbedo, this._tempColor); this._effect.setColor3("vOverloadedAlbedo", this._tempColor); this.convertColorToLinearSpaceToRef(this.overloadedReflectivity, this._tempColor); this._effect.setColor3("vOverloadedReflectivity", this._tempColor); this.convertColorToLinearSpaceToRef(this.overloadedEmissive, this._tempColor); this._effect.setColor3("vOverloadedEmissive", this._tempColor); this.convertColorToLinearSpaceToRef(this.overloadedReflection, this._tempColor); this._effect.setColor3("vOverloadedReflection", this._tempColor); this._overloadedMicroSurface.x = this.overloadedMicroSurface; this._overloadedMicroSurface.y = this.overloadedMicroSurfaceIntensity; this._overloadedMicroSurface.z = this.overloadedReflectionIntensity; this._effect.setVector3("vOverloadedMicroSurface", this._overloadedMicroSurface); // Log. depth BABYLON.MaterialHelper.BindLogDepth(this._defines, this._effect, this._myScene); } _super.prototype.bind.call(this, world, mesh); this._myScene = null; }; PBRMaterial.prototype.getAnimatables = function () { var results = []; if (this.albedoTexture && this.albedoTexture.animations && this.albedoTexture.animations.length > 0) { results.push(this.albedoTexture); } if (this.ambientTexture && this.ambientTexture.animations && this.ambientTexture.animations.length > 0) { results.push(this.ambientTexture); } if (this.opacityTexture && this.opacityTexture.animations && this.opacityTexture.animations.length > 0) { results.push(this.opacityTexture); } if (this.reflectionTexture && this.reflectionTexture.animations && this.reflectionTexture.animations.length > 0) { results.push(this.reflectionTexture); } if (this.emissiveTexture && this.emissiveTexture.animations && this.emissiveTexture.animations.length > 0) { results.push(this.emissiveTexture); } if (this.reflectivityTexture && this.reflectivityTexture.animations && this.reflectivityTexture.animations.length > 0) { results.push(this.reflectivityTexture); } if (this.bumpTexture && this.bumpTexture.animations && this.bumpTexture.animations.length > 0) { results.push(this.bumpTexture); } if (this.lightmapTexture && this.lightmapTexture.animations && this.lightmapTexture.animations.length > 0) { results.push(this.lightmapTexture); } if (this.refractionTexture && this.refractionTexture.animations && this.refractionTexture.animations.length > 0) { results.push(this.refractionTexture); } return results; }; PBRMaterial.prototype.dispose = function (forceDisposeEffect) { if (this.albedoTexture) { this.albedoTexture.dispose(); } if (this.ambientTexture) { this.ambientTexture.dispose(); } if (this.opacityTexture) { this.opacityTexture.dispose(); } if (this.reflectionTexture) { this.reflectionTexture.dispose(); } if (this.emissiveTexture) { this.emissiveTexture.dispose(); } if (this.reflectivityTexture) { this.reflectivityTexture.dispose(); } if (this.bumpTexture) { this.bumpTexture.dispose(); } if (this.lightmapTexture) { this.lightmapTexture.dispose(); } if (this.refractionTexture) { this.refractionTexture.dispose(); } _super.prototype.dispose.call(this, forceDisposeEffect); }; PBRMaterial.prototype.clone = function (name) { var newPBRMaterial = new PBRMaterial(name, this.getScene()); // Base material this.copyTo(newPBRMaterial); newPBRMaterial.directIntensity = this.directIntensity; newPBRMaterial.emissiveIntensity = this.emissiveIntensity; newPBRMaterial.environmentIntensity = this.environmentIntensity; newPBRMaterial.specularIntensity = this.specularIntensity; newPBRMaterial.cameraExposure = this.cameraExposure; newPBRMaterial.cameraContrast = this.cameraContrast; newPBRMaterial.overloadedShadowIntensity = this.overloadedShadowIntensity; newPBRMaterial.overloadedShadeIntensity = this.overloadedShadeIntensity; newPBRMaterial.overloadedAmbientIntensity = this.overloadedAmbientIntensity; newPBRMaterial.overloadedAlbedoIntensity = this.overloadedAlbedoIntensity; newPBRMaterial.overloadedReflectivityIntensity = this.overloadedReflectivityIntensity; newPBRMaterial.overloadedEmissiveIntensity = this.overloadedEmissiveIntensity; newPBRMaterial.overloadedAmbient = this.overloadedAmbient; newPBRMaterial.overloadedAlbedo = this.overloadedAlbedo; newPBRMaterial.overloadedReflectivity = this.overloadedReflectivity; newPBRMaterial.overloadedEmissive = this.overloadedEmissive; newPBRMaterial.overloadedReflection = this.overloadedReflection; newPBRMaterial.overloadedMicroSurface = this.overloadedMicroSurface; newPBRMaterial.overloadedMicroSurfaceIntensity = this.overloadedMicroSurfaceIntensity; newPBRMaterial.overloadedReflectionIntensity = this.overloadedReflectionIntensity; newPBRMaterial.disableBumpMap = this.disableBumpMap; // Standard material if (this.albedoTexture && this.albedoTexture.clone) { newPBRMaterial.albedoTexture = this.albedoTexture.clone(); } if (this.ambientTexture && this.ambientTexture.clone) { newPBRMaterial.ambientTexture = this.ambientTexture.clone(); } if (this.opacityTexture && this.opacityTexture.clone) { newPBRMaterial.opacityTexture = this.opacityTexture.clone(); } if (this.reflectionTexture && this.reflectionTexture.clone) { newPBRMaterial.reflectionTexture = this.reflectionTexture.clone(); } if (this.emissiveTexture && this.emissiveTexture.clone) { newPBRMaterial.emissiveTexture = this.emissiveTexture.clone(); } if (this.reflectivityTexture && this.reflectivityTexture.clone) { newPBRMaterial.reflectivityTexture = this.reflectivityTexture.clone(); } if (this.bumpTexture && this.bumpTexture.clone) { newPBRMaterial.bumpTexture = this.bumpTexture.clone(); } if (this.lightmapTexture && this.lightmapTexture.clone) { newPBRMaterial.lightmapTexture = this.lightmapTexture.clone(); newPBRMaterial.useLightmapAsShadowmap = this.useLightmapAsShadowmap; } if (this.refractionTexture && this.refractionTexture.clone) { newPBRMaterial.refractionTexture = this.refractionTexture.clone(); newPBRMaterial.linkRefractionWithTransparency = this.linkRefractionWithTransparency; } newPBRMaterial.ambientColor = this.ambientColor.clone(); newPBRMaterial.albedoColor = this.albedoColor.clone(); newPBRMaterial.reflectivityColor = this.reflectivityColor.clone(); newPBRMaterial.reflectionColor = this.reflectionColor.clone(); newPBRMaterial.microSurface = this.microSurface; newPBRMaterial.emissiveColor = this.emissiveColor.clone(); newPBRMaterial.useAlphaFromAlbedoTexture = this.useAlphaFromAlbedoTexture; newPBRMaterial.useEmissiveAsIllumination = this.useEmissiveAsIllumination; newPBRMaterial.useMicroSurfaceFromReflectivityMapAlpha = this.useMicroSurfaceFromReflectivityMapAlpha; newPBRMaterial.useAutoMicroSurfaceFromReflectivityMap = this.useAutoMicroSurfaceFromReflectivityMap; newPBRMaterial.useScalarInLinearSpace = this.useScalarInLinearSpace; newPBRMaterial.useSpecularOverAlpha = this.useSpecularOverAlpha; newPBRMaterial.indexOfRefraction = this.indexOfRefraction; newPBRMaterial.invertRefractionY = this.invertRefractionY; newPBRMaterial.emissiveFresnelParameters = this.emissiveFresnelParameters.clone(); newPBRMaterial.opacityFresnelParameters = this.opacityFresnelParameters.clone(); return newPBRMaterial; }; PBRMaterial.prototype.serialize = function () { var serializationObject = _super.prototype.serialize.call(this); serializationObject.customType = "BABYLON.PBRMaterial"; serializationObject.directIntensity = this.directIntensity; serializationObject.emissiveIntensity = this.emissiveIntensity; serializationObject.environmentIntensity = this.environmentIntensity; serializationObject.specularIntensity = this.specularIntensity; serializationObject.cameraExposure = this.cameraExposure; serializationObject.cameraContrast = this.cameraContrast; serializationObject.overloadedShadowIntensity = this.overloadedShadowIntensity; serializationObject.overloadedShadeIntensity = this.overloadedShadeIntensity; serializationObject.overloadedAmbientIntensity = this.overloadedAmbientIntensity; serializationObject.overloadedAlbedoIntensity = this.overloadedAlbedoIntensity; serializationObject.overloadedReflectivityIntensity = this.overloadedReflectivityIntensity; serializationObject.overloadedEmissiveIntensity = this.overloadedEmissiveIntensity; serializationObject.overloadedAmbient = this.overloadedAmbient.asArray(); serializationObject.overloadedAlbedo = this.overloadedAlbedo.asArray(); serializationObject.overloadedReflectivity = this.overloadedReflectivity.asArray(); serializationObject.overloadedEmissive = this.overloadedEmissive.asArray(); serializationObject.overloadedReflection = this.overloadedReflection.asArray(); serializationObject.overloadedMicroSurface = this.overloadedMicroSurface; serializationObject.overloadedMicroSurfaceIntensity = this.overloadedMicroSurfaceIntensity; serializationObject.overloadedReflectionIntensity = this.overloadedReflectionIntensity; serializationObject.disableBumpMap = this.disableBumpMap; // Standard material if (this.albedoTexture) { serializationObject.albedoTexture = this.albedoTexture.serialize(); } if (this.ambientTexture) { serializationObject.ambientTexture = this.ambientTexture.serialize(); } if (this.opacityTexture) { serializationObject.opacityTexture = this.opacityTexture.serialize(); } if (this.reflectionTexture) { serializationObject.reflectionTexture = this.reflectionTexture.serialize(); } if (this.emissiveTexture) { serializationObject.emissiveTexture = this.emissiveTexture.serialize(); } if (this.reflectivityTexture) { serializationObject.reflectivityTexture = this.reflectivityTexture.serialize(); } if (this.bumpTexture) { serializationObject.bumpTexture = this.bumpTexture.serialize(); } if (this.lightmapTexture) { serializationObject.lightmapTexture = this.lightmapTexture.serialize(); serializationObject.useLightmapAsShadowmap = this.useLightmapAsShadowmap; } if (this.refractionTexture) { serializationObject.refractionTexture = this.refractionTexture; serializationObject.linkRefractionWithTransparency = this.linkRefractionWithTransparency; } serializationObject.ambientColor = this.ambientColor.asArray(); serializationObject.albedoColor = this.albedoColor.asArray(); serializationObject.reflectivityColor = this.reflectivityColor.asArray(); serializationObject.reflectionColor = this.reflectionColor.asArray(); serializationObject.microSurface = this.microSurface; serializationObject.emissiveColor = this.emissiveColor.asArray(); serializationObject.useAlphaFromAlbedoTexture = this.useAlphaFromAlbedoTexture; serializationObject.useEmissiveAsIllumination = this.useEmissiveAsIllumination; serializationObject.useMicroSurfaceFromReflectivityMapAlpha = this.useMicroSurfaceFromReflectivityMapAlpha; serializationObject.useAutoMicroSurfaceFromReflectivityMap = this.useAutoMicroSurfaceFromReflectivityMap; serializationObject.useScalarInLinear = this.useScalarInLinearSpace; serializationObject.useSpecularOverAlpha = this.useSpecularOverAlpha; serializationObject.indexOfRefraction = this.indexOfRefraction; serializationObject.invertRefractionY = this.invertRefractionY; serializationObject.emissiveFresnelParameters = this.emissiveFresnelParameters.serialize(); serializationObject.opacityFresnelParameters = this.opacityFresnelParameters.serialize(); return serializationObject; }; PBRMaterial.Parse = function (source, scene, rootUrl) { var material = new PBRMaterial(source.name, scene); material.alpha = source.alpha; material.id = source.id; if (source.disableDepthWrite) { material.disableDepthWrite = source.disableDepthWrite; } if (source.checkReadyOnlyOnce) { material.checkReadyOnlyOnce = source.checkReadyOnlyOnce; } BABYLON.Tags.AddTagsTo(material, source.tags); material.backFaceCulling = source.backFaceCulling; material.wireframe = source.wireframe; material.directIntensity = source.directIntensity; material.emissiveIntensity = source.emissiveIntensity; material.environmentIntensity = source.environmentIntensity; material.specularIntensity = source.specularIntensity; material.cameraExposure = source.cameraExposure; material.cameraContrast = source.cameraContrast; material.overloadedShadowIntensity = source.overloadedShadowIntensity; material.overloadedShadeIntensity = source.overloadedShadeIntensity; material.overloadedAmbientIntensity = source.overloadedAmbientIntensity; material.overloadedAlbedoIntensity = source.overloadedAlbedoIntensity; material.overloadedReflectivityIntensity = source.overloadedReflectivityIntensity; material.overloadedEmissiveIntensity = source.overloadedEmissiveIntensity; material.overloadedAmbient = BABYLON.Color3.FromArray(source.overloadedAmbient); material.overloadedAlbedo = BABYLON.Color3.FromArray(source.overloadedAlbedo); material.overloadedReflectivity = BABYLON.Color3.FromArray(source.overloadedReflectivity); material.overloadedEmissive = BABYLON.Color3.FromArray(source.overloadedEmissive); material.overloadedReflection = BABYLON.Color3.FromArray(source.overloadedReflection); material.overloadedMicroSurface = source.overloadedMicroSurface; material.overloadedMicroSurfaceIntensity = source.overloadedMicroSurfaceIntensity; material.overloadedReflectionIntensity = source.overloadedReflectionIntensity; material.disableBumpMap = source.disableBumpMap; // Standard material if (source.albedoTexture) { material.albedoTexture = BABYLON.Texture.Parse(source.albedoTexture, scene, rootUrl); } if (source.ambientTexture) { material.ambientTexture = BABYLON.Texture.Parse(source.ambientTexture, scene, rootUrl); } if (source.opacityTexture) { material.opacityTexture = BABYLON.Texture.Parse(source.opacityTexture, scene, rootUrl); } if (source.reflectionTexture) { material.reflectionTexture = BABYLON.Texture.Parse(source.reflectionTexture, scene, rootUrl); } if (source.emissiveTexture) { material.emissiveTexture = BABYLON.Texture.Parse(source.emissiveTexture, scene, rootUrl); } if (source.reflectivityTexture) { material.reflectivityTexture = BABYLON.Texture.Parse(source.reflectivityTexture, scene, rootUrl); } if (source.bumpTexture) { material.bumpTexture = BABYLON.Texture.Parse(source.bumpTexture, scene, rootUrl); } if (source.lightmapTexture) { material.lightmapTexture = BABYLON.Texture.Parse(source.lightmapTexture, scene, rootUrl); material.useLightmapAsShadowmap = source.useLightmapAsShadowmap; } if (source.refractionTexture) { material.refractionTexture = BABYLON.Texture.Parse(source.refractionTexture, scene, rootUrl); material.linkRefractionWithTransparency = source.linkRefractionWithTransparency; } material.ambientColor = BABYLON.Color3.FromArray(source.ambient); material.albedoColor = BABYLON.Color3.FromArray(source.albedo); material.reflectivityColor = BABYLON.Color3.FromArray(source.reflectivity); material.reflectionColor = BABYLON.Color3.FromArray(source.reflectionColor); material.microSurface = source.microSurface; material.emissiveColor = BABYLON.Color3.FromArray(source.emissive); material.useAlphaFromAlbedoTexture = source.useAlphaFromAlbedoTexture; material.useEmissiveAsIllumination = source.useEmissiveAsIllumination; material.useMicroSurfaceFromReflectivityMapAlpha = source.useMicroSurfaceFromReflectivityMapAlpha; material.useAutoMicroSurfaceFromReflectivityMap = source.useAutoMicroSurfaceFromReflectivityMap; material.useScalarInLinearSpace = source.useScalarInLinear; material.useSpecularOverAlpha = source.useSpecularOverAlpha; material.indexOfRefraction = source.indexOfRefraction; material.invertRefractionY = source.invertRefractionY; material.emissiveFresnelParameters = BABYLON.FresnelParameters.Parse(source.emissiveFresnelParameters); material.opacityFresnelParameters = BABYLON.FresnelParameters.Parse(source.opacityFresnelParameters); return material; }; PBRMaterial._scaledAlbedo = new BABYLON.Color3(); PBRMaterial._scaledReflectivity = new BABYLON.Color3(); PBRMaterial._scaledEmissive = new BABYLON.Color3(); PBRMaterial._scaledReflection = new BABYLON.Color3(); PBRMaterial._lightRadiuses = [1, 1, 1, 1]; return PBRMaterial; })(BABYLON.Material); BABYLON.PBRMaterial = PBRMaterial; })(BABYLON || (BABYLON = {})); BABYLON.Effect.ShadersStore['pbrVertexShader'] = "precision highp float;\n\n// Attributes\nattribute vec3 position;\n#ifdef NORMAL\nattribute vec3 normal;\n#endif\n#ifdef UV1\nattribute vec2 uv;\n#endif\n#ifdef UV2\nattribute vec2 uv2;\n#endif\n#ifdef VERTEXCOLOR\nattribute vec4 color;\n#endif\n\n#include\n\n// Uniforms\n#include\n\nuniform mat4 view;\nuniform mat4 viewProjection;\n\n#ifdef ALBEDO\nvarying vec2 vAlbedoUV;\nuniform mat4 albedoMatrix;\nuniform vec2 vAlbedoInfos;\n#endif\n\n#ifdef AMBIENT\nvarying vec2 vAmbientUV;\nuniform mat4 ambientMatrix;\nuniform vec2 vAmbientInfos;\n#endif\n\n#ifdef OPACITY\nvarying vec2 vOpacityUV;\nuniform mat4 opacityMatrix;\nuniform vec2 vOpacityInfos;\n#endif\n\n#ifdef EMISSIVE\nvarying vec2 vEmissiveUV;\nuniform vec2 vEmissiveInfos;\nuniform mat4 emissiveMatrix;\n#endif\n\n#ifdef LIGHTMAP\nvarying vec2 vLightmapUV;\nuniform vec2 vLightmapInfos;\nuniform mat4 lightmapMatrix;\n#endif\n\n#if defined(REFLECTIVITY)\nvarying vec2 vReflectivityUV;\nuniform vec2 vReflectivityInfos;\nuniform mat4 reflectivityMatrix;\n#endif\n\n#ifdef BUMP\nvarying vec2 vBumpUV;\nuniform vec2 vBumpInfos;\nuniform mat4 bumpMatrix;\n#endif\n\n#ifdef POINTSIZE\nuniform float pointSize;\n#endif\n\n// Output\nvarying vec3 vPositionW;\n#ifdef NORMAL\nvarying vec3 vNormalW;\n#endif\n\n#ifdef VERTEXCOLOR\nvarying vec4 vColor;\n#endif\n\n\n#include\n#include\n#include\n\n#ifdef REFLECTIONMAP_SKYBOX\nvarying vec3 vPositionUVW;\n#endif\n\n#ifdef REFLECTIONMAP_EQUIRECTANGULAR_FIXED\nvarying vec3 vDirectionW;\n#endif\n\n#include\n\nvoid main(void) {\n#ifdef REFLECTIONMAP_SKYBOX\n vPositionUVW = position;\n#endif \n\n#include\n#include\n\n gl_Position = viewProjection * finalWorld * vec4(position, 1.0);\n\n vec4 worldPos = finalWorld * vec4(position, 1.0);\n vPositionW = vec3(worldPos);\n\n#ifdef NORMAL\n vNormalW = normalize(vec3(finalWorld * vec4(normal, 0.0)));\n#endif\n\n#ifdef REFLECTIONMAP_EQUIRECTANGULAR_FIXED\n vDirectionW = normalize(vec3(finalWorld * vec4(position, 0.0)));\n#endif\n\n // Texture coordinates\n#ifndef UV1\n vec2 uv = vec2(0., 0.);\n#endif\n#ifndef UV2\n vec2 uv2 = vec2(0., 0.);\n#endif\n\n#ifdef ALBEDO\n if (vAlbedoInfos.x == 0.)\n {\n vAlbedoUV = vec2(albedoMatrix * vec4(uv, 1.0, 0.0));\n }\n else\n {\n vAlbedoUV = vec2(albedoMatrix * vec4(uv2, 1.0, 0.0));\n }\n#endif\n\n#ifdef AMBIENT\n if (vAmbientInfos.x == 0.)\n {\n vAmbientUV = vec2(ambientMatrix * vec4(uv, 1.0, 0.0));\n }\n else\n {\n vAmbientUV = vec2(ambientMatrix * vec4(uv2, 1.0, 0.0));\n }\n#endif\n\n#ifdef OPACITY\n if (vOpacityInfos.x == 0.)\n {\n vOpacityUV = vec2(opacityMatrix * vec4(uv, 1.0, 0.0));\n }\n else\n {\n vOpacityUV = vec2(opacityMatrix * vec4(uv2, 1.0, 0.0));\n }\n#endif\n\n#ifdef EMISSIVE\n if (vEmissiveInfos.x == 0.)\n {\n vEmissiveUV = vec2(emissiveMatrix * vec4(uv, 1.0, 0.0));\n }\n else\n {\n vEmissiveUV = vec2(emissiveMatrix * vec4(uv2, 1.0, 0.0));\n }\n#endif\n\n#ifdef LIGHTMAP\n if (vLightmapInfos.x == 0.)\n {\n vLightmapUV = vec2(lightmapMatrix * vec4(uv, 1.0, 0.0));\n }\n else\n {\n vLightmapUV = vec2(lightmapMatrix * vec4(uv2, 1.0, 0.0));\n }\n#endif\n\n#if defined(REFLECTIVITY)\n if (vReflectivityInfos.x == 0.)\n {\n vReflectivityUV = vec2(reflectivityMatrix * vec4(uv, 1.0, 0.0));\n }\n else\n {\n vReflectivityUV = vec2(reflectivityMatrix * vec4(uv2, 1.0, 0.0));\n }\n#endif\n\n#ifdef BUMP\n if (vBumpInfos.x == 0.)\n {\n vBumpUV = vec2(bumpMatrix * vec4(uv, 1.0, 0.0));\n }\n else\n {\n vBumpUV = vec2(bumpMatrix * vec4(uv2, 1.0, 0.0));\n }\n#endif\n\n // Clip plane\n#include\n\n // Fog\n#include\n\n // Shadows\n#include\n\n // Vertex color\n#ifdef VERTEXCOLOR\n vColor = color;\n#endif\n\n // Point size\n#ifdef POINTSIZE\n gl_PointSize = pointSize;\n#endif\n\n // Log. depth\n#include\n}"; BABYLON.Effect.ShadersStore['pbrPixelShader'] = "#ifdef BUMP\n#extension GL_OES_standard_derivatives : enable\n#endif\n\n#ifdef LODBASEDMICROSFURACE\n#extension GL_EXT_shader_texture_lod : enable\n#endif\n\n#ifdef LOGARITHMICDEPTH\n#extension GL_EXT_frag_depth : enable\n#endif\n\nprecision highp float;\n\n// Constants\n#define RECIPROCAL_PI2 0.15915494\n#define FRESNEL_MAXIMUM_ON_ROUGH 0.25\n\nuniform vec3 vEyePosition;\nuniform vec3 vAmbientColor;\nuniform vec3 vReflectionColor;\nuniform vec4 vAlbedoColor;\nuniform vec4 vLightRadiuses;\n\n// CUSTOM CONTROLS\nuniform vec4 vLightingIntensity;\nuniform vec4 vCameraInfos;\n\n#ifdef OVERLOADEDVALUES\n uniform vec4 vOverloadedIntensity;\n uniform vec3 vOverloadedAmbient;\n uniform vec3 vOverloadedAlbedo;\n uniform vec3 vOverloadedReflectivity;\n uniform vec3 vOverloadedEmissive;\n uniform vec3 vOverloadedReflection;\n uniform vec3 vOverloadedMicroSurface;\n#endif\n\n#ifdef OVERLOADEDSHADOWVALUES\n uniform vec4 vOverloadedShadowIntensity;\n#endif\n\n#ifdef USESPHERICALFROMREFLECTIONMAP\n uniform vec3 vSphericalX;\n uniform vec3 vSphericalY;\n uniform vec3 vSphericalZ;\n uniform vec3 vSphericalXX;\n uniform vec3 vSphericalYY;\n uniform vec3 vSphericalZZ;\n uniform vec3 vSphericalXY;\n uniform vec3 vSphericalYZ;\n uniform vec3 vSphericalZX;\n\n vec3 EnvironmentIrradiance(vec3 normal)\n {\n // Note: 'normal' is assumed to be normalised (or near normalised)\n // This isn't as critical as it is with other calculations (e.g. specular highlight), but the result will be incorrect nonetheless.\n\n // TODO: switch to optimal implementation\n vec3 result =\n vSphericalX * normal.x +\n vSphericalY * normal.y +\n vSphericalZ * normal.z +\n vSphericalXX * normal.x * normal.x +\n vSphericalYY * normal.y * normal.y +\n vSphericalZZ * normal.z * normal.z +\n vSphericalYZ * normal.y * normal.z +\n vSphericalZX * normal.z * normal.x +\n vSphericalXY * normal.x * normal.y;\n\n return result.rgb;\n }\n#endif\n\n#ifdef LODBASEDMICROSFURACE\n uniform vec2 vMicrosurfaceTextureLods;\n#endif\n\n// PBR CUSTOM CONSTANTS\nconst float kPi = 3.1415926535897932384626433832795;\nconst float kRougnhessToAlphaScale = 0.1;\nconst float kRougnhessToAlphaOffset = 0.29248125;\n\n#ifdef PoissonSamplingEnvironment\n const int poissonSphereSamplersCount = 32;\n vec3 poissonSphereSamplers[poissonSphereSamplersCount];\n\n void initSamplers()\n {\n poissonSphereSamplers[0] = vec3( -0.552198926093, 0.801049753814, -0.0322487480415 );\n poissonSphereSamplers[1] = vec3( 0.344874796559, -0.650989584719, 0.283038477033 ); \n poissonSphereSamplers[2] = vec3( -0.0710183703467, 0.163770497767, -0.95022416734 ); \n poissonSphereSamplers[3] = vec3( 0.422221832073, 0.576613638193, 0.519157625948 ); \n poissonSphereSamplers[4] = vec3( -0.561872200916, -0.665581249881, -0.131630473211 ); \n poissonSphereSamplers[5] = vec3( -0.409905973809, 0.0250731510778, 0.674676954809 ); \n poissonSphereSamplers[6] = vec3( 0.206829570551, -0.190199352704, 0.919073906156 ); \n poissonSphereSamplers[7] = vec3( -0.857514664463, 0.0274425010091, -0.475068738967 ); \n poissonSphereSamplers[8] = vec3( -0.816275009951, -0.0432916479141, 0.40394579291 ); \n poissonSphereSamplers[9] = vec3( 0.397976181928, -0.633227519667, -0.617794410447 ); \n poissonSphereSamplers[10] = vec3( -0.181484199014, 0.0155418272003, -0.34675720703 ); \n poissonSphereSamplers[11] = vec3( 0.591734926919, 0.489930882201, -0.51675303188 ); \n poissonSphereSamplers[12] = vec3( -0.264514973057, 0.834248662136, 0.464624235985 ); \n poissonSphereSamplers[13] = vec3( -0.125845223505, 0.812029586099, -0.46213797731 ); \n poissonSphereSamplers[14] = vec3( 0.0345715424639, 0.349983742938, 0.855109899027 ); \n poissonSphereSamplers[15] = vec3( 0.694340492749, -0.281052190209, -0.379600605543 ); \n poissonSphereSamplers[16] = vec3( -0.241055518078, -0.580199280578, 0.435381168431 );\n poissonSphereSamplers[17] = vec3( 0.126313722289, 0.715113642744, 0.124385788055 ); \n poissonSphereSamplers[18] = vec3( 0.752862552387, 0.277075021888, 0.275059597549 );\n poissonSphereSamplers[19] = vec3( -0.400896300918, -0.309374534321, -0.74285782627 ); \n poissonSphereSamplers[20] = vec3( 0.121843331941, -0.00381197918195, 0.322441835258 ); \n poissonSphereSamplers[21] = vec3( 0.741656771351, -0.472083016745, 0.14589173819 ); \n poissonSphereSamplers[22] = vec3( -0.120347565985, -0.397252703556, -0.00153836114051 ); \n poissonSphereSamplers[23] = vec3( -0.846258835203, -0.433763808754, 0.168732209784 ); \n poissonSphereSamplers[24] = vec3( 0.257765618362, -0.546470581239, -0.242234375624 ); \n poissonSphereSamplers[25] = vec3( -0.640343473361, 0.51920903395, 0.549310644325 ); \n poissonSphereSamplers[26] = vec3( -0.894309984621, 0.297394061018, 0.0884583225292 ); \n poissonSphereSamplers[27] = vec3( -0.126241933628, -0.535151016335, -0.440093659672 ); \n poissonSphereSamplers[28] = vec3( -0.158176440297, -0.393125021578, 0.890727226039 ); \n poissonSphereSamplers[29] = vec3( 0.896024272938, 0.203068725821, -0.11198597748 ); \n poissonSphereSamplers[30] = vec3( 0.568671758933, -0.314144243629, 0.509070768816 ); \n poissonSphereSamplers[31] = vec3( 0.289665332178, 0.104356977462, -0.348379247171 );\n }\n\n vec3 environmentSampler(samplerCube cubeMapSampler, vec3 centralDirection, float microsurfaceAverageSlope)\n {\n vec3 result = vec3(0., 0., 0.);\n for(int i = 0; i < poissonSphereSamplersCount; i++)\n {\n vec3 offset = poissonSphereSamplers[i];\n vec3 direction = centralDirection + microsurfaceAverageSlope * offset;\n result += textureCube(cubeMapSampler, direction, 0.).rgb;\n }\n\n result /= 32.0;\n return result;\n }\n\n#endif\n\n// PBR HELPER METHODS\nfloat Square(float value)\n{\n return value * value;\n}\n\nfloat getLuminance(vec3 color)\n{\n return clamp(dot(color, vec3(0.2126, 0.7152, 0.0722)), 0., 1.);\n}\n\nfloat convertRoughnessToAverageSlope(float roughness)\n{\n // Calculate AlphaG as square of roughness; add epsilon to avoid numerical issues\n const float kMinimumVariance = 0.0005;\n float alphaG = Square(roughness) + kMinimumVariance;\n return alphaG;\n}\n\n// Based on Beckamm roughness to Blinn exponent + http://casual-effects.blogspot.ca/2011/08/plausible-environment-lighting-in-two.html \nfloat getMipMapIndexFromAverageSlope(float maxMipLevel, float alpha)\n{\n // do not take in account lower mips hence -1... and wait from proper preprocess.\n // formula comes from approximation of the mathematical solution.\n //float mip = maxMipLevel + kRougnhessToAlphaOffset + 0.5 * log2(alpha);\n \n // In the mean time \n // Always [0..1] goes from max mip to min mip in a log2 way. \n // Change 5 to nummip below.\n // http://www.wolframalpha.com/input/?i=x+in+0..1+plot+(+5+%2B+0.3+%2B+0.1+*+5+*+log2(+(1+-+x)+*+(1+-+x)+%2B+0.0005))\n float mip = kRougnhessToAlphaOffset + maxMipLevel + (maxMipLevel * kRougnhessToAlphaScale * log2(alpha));\n \n return clamp(mip, 0., maxMipLevel);\n}\n\n// From Microfacet Models for Refraction through Rough Surfaces, Walter et al. 2007\nfloat smithVisibilityG1_TrowbridgeReitzGGX(float dot, float alphaG)\n{\n float tanSquared = (1.0 - dot * dot) / (dot * dot);\n return 2.0 / (1.0 + sqrt(1.0 + alphaG * alphaG * tanSquared));\n}\n\nfloat smithVisibilityG_TrowbridgeReitzGGX_Walter(float NdotL, float NdotV, float alphaG)\n{\n return smithVisibilityG1_TrowbridgeReitzGGX(NdotL, alphaG) * smithVisibilityG1_TrowbridgeReitzGGX(NdotV, alphaG);\n}\n\n// Trowbridge-Reitz (GGX)\n// Generalised Trowbridge-Reitz with gamma power=2.0\nfloat normalDistributionFunction_TrowbridgeReitzGGX(float NdotH, float alphaG)\n{\n // Note: alphaG is average slope (gradient) of the normals in slope-space.\n // It is also the (trigonometric) tangent of the median distribution value, i.e. 50% of normals have\n // a tangent (gradient) closer to the macrosurface than this slope.\n float a2 = Square(alphaG);\n float d = NdotH * NdotH * (a2 - 1.0) + 1.0;\n return a2 / (kPi * d * d);\n}\n\nvec3 fresnelSchlickGGX(float VdotH, vec3 reflectance0, vec3 reflectance90)\n{\n return reflectance0 + (reflectance90 - reflectance0) * pow(clamp(1.0 - VdotH, 0., 1.), 5.0);\n}\n\nvec3 FresnelSchlickEnvironmentGGX(float VdotN, vec3 reflectance0, vec3 reflectance90, float smoothness)\n{\n // Schlick fresnel approximation, extended with basic smoothness term so that rough surfaces do not approach reflectance90 at grazing angle\n float weight = mix(FRESNEL_MAXIMUM_ON_ROUGH, 1.0, smoothness);\n return reflectance0 + weight * (reflectance90 - reflectance0) * pow(clamp(1.0 - VdotN, 0., 1.), 5.0);\n}\n\n// Cook Torance Specular computation.\nvec3 computeSpecularTerm(float NdotH, float NdotL, float NdotV, float VdotH, float roughness, vec3 specularColor)\n{\n float alphaG = convertRoughnessToAverageSlope(roughness);\n float distribution = normalDistributionFunction_TrowbridgeReitzGGX(NdotH, alphaG);\n float visibility = smithVisibilityG_TrowbridgeReitzGGX_Walter(NdotL, NdotV, alphaG);\n visibility /= (4.0 * NdotL * NdotV); // Cook Torance Denominator integated in viibility to avoid issues when visibility function changes.\n\n vec3 fresnel = fresnelSchlickGGX(VdotH, specularColor, vec3(1., 1., 1.));\n\n float specTerm = max(0., visibility * distribution) * NdotL;\n return fresnel * specTerm * kPi; // TODO: audit pi constants\n}\n\nfloat computeDiffuseTerm(float NdotL, float NdotV, float VdotH, float roughness)\n{\n // Diffuse fresnel falloff as per Disney principled BRDF, and in the spirit of\n // of general coupled diffuse/specular models e.g. Ashikhmin Shirley.\n float diffuseFresnelNV = pow(clamp(1.0 - NdotL, 0.000001, 1.), 5.0);\n float diffuseFresnelNL = pow(clamp(1.0 - NdotV, 0.000001, 1.), 5.0);\n float diffuseFresnel90 = 0.5 + 2.0 * VdotH * VdotH * roughness;\n float diffuseFresnelTerm =\n (1.0 + (diffuseFresnel90 - 1.0) * diffuseFresnelNL) *\n (1.0 + (diffuseFresnel90 - 1.0) * diffuseFresnelNV);\n\n\n return diffuseFresnelTerm * NdotL;\n // PI Test\n // diffuseFresnelTerm /= kPi;\n}\n\nfloat adjustRoughnessFromLightProperties(float roughness, float lightRadius, float lightDistance)\n{\n // At small angle this approximation works. \n float lightRoughness = lightRadius / lightDistance;\n // Distribution can sum.\n float totalRoughness = clamp(lightRoughness + roughness, 0., 1.);\n return totalRoughness;\n}\n\nfloat computeDefaultMicroSurface(float microSurface, vec3 reflectivityColor)\n{\n float kReflectivityNoAlphaWorkflow_SmoothnessMax = 0.95;\n\n float reflectivityLuminance = getLuminance(reflectivityColor);\n float reflectivityLuma = sqrt(reflectivityLuminance);\n microSurface = reflectivityLuma * kReflectivityNoAlphaWorkflow_SmoothnessMax;\n\n return microSurface;\n}\n\nvec3 toLinearSpace(vec3 color)\n{\n return vec3(pow(color.r, 2.2), pow(color.g, 2.2), pow(color.b, 2.2));\n}\n\nvec3 toGammaSpace(vec3 color)\n{\n return vec3(pow(color.r, 1.0 / 2.2), pow(color.g, 1.0 / 2.2), pow(color.b, 1.0 / 2.2));\n}\n\n#ifdef CAMERATONEMAP\n vec3 toneMaps(vec3 color)\n {\n color = max(color, 0.0);\n\n // TONE MAPPING / EXPOSURE\n color.rgb = color.rgb * vCameraInfos.x;\n\n float tuning = 1.5; // TODO: sync up so e.g. 18% greys are matched to exposure appropriately\n // PI Test\n // tuning *= kPi;\n vec3 tonemapped = 1.0 - exp2(-color.rgb * tuning); // simple local photographic tonemapper\n color.rgb = mix(color.rgb, tonemapped, 1.0);\n return color;\n }\n#endif\n\n#ifdef CAMERACONTRAST\n vec4 contrasts(vec4 color)\n {\n color = clamp(color, 0.0, 1.0);\n\n vec3 resultHighContrast = color.rgb * color.rgb * (3.0 - 2.0 * color.rgb);\n float contrast = vCameraInfos.y;\n if (contrast < 1.0)\n {\n // Decrease contrast: interpolate towards zero-contrast image (flat grey)\n color.rgb = mix(vec3(0.5, 0.5, 0.5), color.rgb, contrast);\n }\n else\n {\n // Increase contrast: apply simple shoulder-toe high contrast curve\n color.rgb = mix(color.rgb, resultHighContrast, contrast - 1.0);\n }\n\n return color;\n }\n#endif\n// END PBR HELPER METHODS\n\n uniform vec4 vReflectivityColor;\n uniform vec3 vEmissiveColor;\n\n// Input\nvarying vec3 vPositionW;\n\n#ifdef NORMAL\nvarying vec3 vNormalW;\n#endif\n\n#ifdef VERTEXCOLOR\nvarying vec4 vColor;\n#endif\n\n// Lights\n#include\n#include\n#include\n#include\n\n// Samplers\n#ifdef ALBEDO\nvarying vec2 vAlbedoUV;\nuniform sampler2D albedoSampler;\nuniform vec2 vAlbedoInfos;\n#endif\n\n#ifdef AMBIENT\nvarying vec2 vAmbientUV;\nuniform sampler2D ambientSampler;\nuniform vec2 vAmbientInfos;\n#endif\n\n#ifdef OPACITY\t\nvarying vec2 vOpacityUV;\nuniform sampler2D opacitySampler;\nuniform vec2 vOpacityInfos;\n#endif\n\n#ifdef EMISSIVE\nvarying vec2 vEmissiveUV;\nuniform vec2 vEmissiveInfos;\nuniform sampler2D emissiveSampler;\n#endif\n\n#ifdef LIGHTMAP\nvarying vec2 vLightmapUV;\nuniform vec2 vLightmapInfos;\nuniform sampler2D lightmapSampler;\n#endif\n\n#if defined(REFLECTIVITY)\nvarying vec2 vReflectivityUV;\nuniform vec2 vReflectivityInfos;\nuniform sampler2D reflectivitySampler;\n#endif\n\n// Fresnel\n#include\n\n#ifdef OPACITYFRESNEL\nuniform vec4 opacityParts;\n#endif\n\n#ifdef EMISSIVEFRESNEL\nuniform vec4 emissiveLeftColor;\nuniform vec4 emissiveRightColor;\n#endif\n\n// Refraction Reflection\n#if defined(REFLECTIONMAP_SPHERICAL) || defined(REFLECTIONMAP_PROJECTION) || defined(REFRACTION)\n uniform mat4 view;\n#endif\n\n// Refraction\n#ifdef REFRACTION\n uniform vec4 vRefractionInfos;\n\n #ifdef REFRACTIONMAP_3D\n uniform samplerCube refractionCubeSampler;\n #else\n uniform sampler2D refraction2DSampler;\n uniform mat4 refractionMatrix;\n #endif\n#endif\n\n// Reflection\n#ifdef REFLECTION\nuniform vec2 vReflectionInfos;\n\n#ifdef REFLECTIONMAP_3D\nuniform samplerCube reflectionCubeSampler;\n#else\nuniform sampler2D reflection2DSampler;\n#endif\n\n#ifdef REFLECTIONMAP_SKYBOX\nvarying vec3 vPositionUVW;\n#else\n #ifdef REFLECTIONMAP_EQUIRECTANGULAR_FIXED\n varying vec3 vDirectionW;\n #endif\n\n #if defined(REFLECTIONMAP_PLANAR) || defined(REFLECTIONMAP_CUBIC) || defined(REFLECTIONMAP_PROJECTION)\n uniform mat4 reflectionMatrix;\n #endif\n#endif\n\n#include\n\n#endif\n\n// Shadows\n#ifdef SHADOWS\n\nfloat unpack(vec4 color)\n{\n const vec4 bit_shift = vec4(1.0 / (255.0 * 255.0 * 255.0), 1.0 / (255.0 * 255.0), 1.0 / 255.0, 1.0);\n return dot(color, bit_shift);\n}\n\n#if defined(POINTLIGHT0) || defined(POINTLIGHT1) || defined(POINTLIGHT2) || defined(POINTLIGHT3)\nuniform vec2 depthValues;\n\nfloat computeShadowCube(vec3 lightPosition, samplerCube shadowSampler, float darkness, float bias)\n{\n\tvec3 directionToLight = vPositionW - lightPosition;\n\tfloat depth = length(directionToLight);\n\tdepth = clamp(depth, 0., 1.0);\n\n\tdirectionToLight = normalize(directionToLight);\n\tdirectionToLight.y = - directionToLight.y;\n\n\tfloat shadow = unpack(textureCube(shadowSampler, directionToLight)) + bias;\n\n if (depth > shadow)\n {\n#ifdef OVERLOADEDSHADOWVALUES\n return mix(1.0, darkness, vOverloadedShadowIntensity.x);\n#else\n return darkness;\n#endif\n }\n return 1.0;\n}\n\nfloat computeShadowWithPCFCube(vec3 lightPosition, samplerCube shadowSampler, float mapSize, float bias, float darkness)\n{\n vec3 directionToLight = vPositionW - lightPosition;\n float depth = length(directionToLight);\n\n depth = (depth - depthValues.x) / (depthValues.y - depthValues.x);\n depth = clamp(depth, 0., 1.0);\n\n directionToLight = normalize(directionToLight);\n directionToLight.y = -directionToLight.y;\n\n float visibility = 1.;\n\n vec3 poissonDisk[4];\n poissonDisk[0] = vec3(-1.0, 1.0, -1.0);\n poissonDisk[1] = vec3(1.0, -1.0, -1.0);\n poissonDisk[2] = vec3(-1.0, -1.0, -1.0);\n poissonDisk[3] = vec3(1.0, -1.0, 1.0);\n\n // Poisson Sampling\n float biasedDepth = depth - bias;\n\n if (unpack(textureCube(shadowSampler, directionToLight + poissonDisk[0] * mapSize)) < biasedDepth) visibility -= 0.25;\n if (unpack(textureCube(shadowSampler, directionToLight + poissonDisk[1] * mapSize)) < biasedDepth) visibility -= 0.25;\n if (unpack(textureCube(shadowSampler, directionToLight + poissonDisk[2] * mapSize)) < biasedDepth) visibility -= 0.25;\n if (unpack(textureCube(shadowSampler, directionToLight + poissonDisk[3] * mapSize)) < biasedDepth) visibility -= 0.25;\n\n#ifdef OVERLOADEDSHADOWVALUES\n return min(1.0, mix(1.0, visibility + darkness, vOverloadedShadowIntensity.x));\n#else\n return min(1.0, visibility + darkness);\n#endif\n}\n#endif\n\n#if defined(SPOTLIGHT0) || defined(SPOTLIGHT1) || defined(SPOTLIGHT2) || defined(SPOTLIGHT3) || defined(DIRLIGHT0) || defined(DIRLIGHT1) || defined(DIRLIGHT2) || defined(DIRLIGHT3)\nfloat computeShadow(vec4 vPositionFromLight, sampler2D shadowSampler, float darkness, float bias)\n{\n vec3 depth = vPositionFromLight.xyz / vPositionFromLight.w;\n depth = 0.5 * depth + vec3(0.5);\n vec2 uv = depth.xy;\n\n if (uv.x < 0. || uv.x > 1.0 || uv.y < 0. || uv.y > 1.0)\n {\n return 1.0;\n }\n\n float shadow = unpack(texture2D(shadowSampler, uv)) + bias;\n\n if (depth.z > shadow)\n {\n#ifdef OVERLOADEDSHADOWVALUES\n return mix(1.0, darkness, vOverloadedShadowIntensity.x);\n#else\n return darkness;\n#endif\n }\n return 1.;\n}\n\nfloat computeShadowWithPCF(vec4 vPositionFromLight, sampler2D shadowSampler, float mapSize, float bias, float darkness)\n{\n vec3 depth = vPositionFromLight.xyz / vPositionFromLight.w;\n depth = 0.5 * depth + vec3(0.5);\n vec2 uv = depth.xy;\n\n if (uv.x < 0. || uv.x > 1.0 || uv.y < 0. || uv.y > 1.0)\n {\n return 1.0;\n }\n\n float visibility = 1.;\n\n vec2 poissonDisk[4];\n poissonDisk[0] = vec2(-0.94201624, -0.39906216);\n poissonDisk[1] = vec2(0.94558609, -0.76890725);\n poissonDisk[2] = vec2(-0.094184101, -0.92938870);\n poissonDisk[3] = vec2(0.34495938, 0.29387760);\n\n // Poisson Sampling\n float biasedDepth = depth.z - bias;\n\n if (unpack(texture2D(shadowSampler, uv + poissonDisk[0] * mapSize)) < biasedDepth) visibility -= 0.25;\n if (unpack(texture2D(shadowSampler, uv + poissonDisk[1] * mapSize)) < biasedDepth) visibility -= 0.25;\n if (unpack(texture2D(shadowSampler, uv + poissonDisk[2] * mapSize)) < biasedDepth) visibility -= 0.25;\n if (unpack(texture2D(shadowSampler, uv + poissonDisk[3] * mapSize)) < biasedDepth) visibility -= 0.25;\n\n#ifdef OVERLOADEDSHADOWVALUES\n return min(1.0, mix(1.0, visibility + darkness, vOverloadedShadowIntensity.x));\n#else\n return min(1.0, visibility + darkness);\n#endif\n}\n\n// Thanks to http://devmaster.net/\nfloat unpackHalf(vec2 color)\n{\n return color.x + (color.y / 255.0);\n}\n\nfloat linstep(float low, float high, float v) {\n return clamp((v - low) / (high - low), 0.0, 1.0);\n}\n\nfloat ChebychevInequality(vec2 moments, float compare, float bias)\n{\n float p = smoothstep(compare - bias, compare, moments.x);\n float variance = max(moments.y - moments.x * moments.x, 0.02);\n float d = compare - moments.x;\n float p_max = linstep(0.2, 1.0, variance / (variance + d * d));\n\n return clamp(max(p, p_max), 0.0, 1.0);\n}\n\nfloat computeShadowWithVSM(vec4 vPositionFromLight, sampler2D shadowSampler, float bias, float darkness)\n{\n vec3 depth = vPositionFromLight.xyz / vPositionFromLight.w;\n depth = 0.5 * depth + vec3(0.5);\n vec2 uv = depth.xy;\n\n if (uv.x < 0. || uv.x > 1.0 || uv.y < 0. || uv.y > 1.0 || depth.z >= 1.0)\n {\n return 1.0;\n }\n\n vec4 texel = texture2D(shadowSampler, uv);\n\n vec2 moments = vec2(unpackHalf(texel.xy), unpackHalf(texel.zw));\n#ifdef OVERLOADEDSHADOWVALUES\n return min(1.0, mix(1.0, 1.0 - ChebychevInequality(moments, depth.z, bias) + darkness, vOverloadedShadowIntensity.x));\n#else\n return min(1.0, 1.0 - ChebychevInequality(moments, depth.z, bias) + darkness);\n#endif\n}\n#endif\n\n#endif\n\n#include\n#include\n#include\n\n// Fog\n#include\n\n// Light Computing\nstruct lightingInfo\n{\n vec3 diffuse;\n#ifdef SPECULARTERM\n vec3 specular;\n#endif\n};\n\nlightingInfo computeLighting(vec3 viewDirectionW, vec3 vNormal, vec4 lightData, vec3 diffuseColor, vec3 specularColor, float range, float roughness, float NdotV, float lightRadius) {\n lightingInfo result;\n\n vec3 lightDirection;\n float attenuation = 1.0;\n float lightDistance;\n \n // Point\n if (lightData.w == 0.)\n {\n vec3 lightOffset = lightData.xyz - vPositionW;\n \n // Inverse squared falloff.\n float lightDistanceSquared = dot(lightOffset, lightOffset);\n float lightDistanceFalloff = 1.0 / ((lightDistanceSquared + 0.0001) * range);\n attenuation = lightDistanceFalloff;\n \n lightDistance = sqrt(lightDistanceSquared);\n lightDirection = normalize(lightOffset);\n }\n // Directional\n else\n {\n lightDistance = length(-lightData.xyz);\n lightDirection = normalize(-lightData.xyz);\n }\n \n // Roughness\n roughness = adjustRoughnessFromLightProperties(roughness, lightRadius, lightDistance);\n \n // diffuse\n vec3 H = normalize(viewDirectionW + lightDirection);\n float NdotL = max(0.00000000001, dot(vNormal, lightDirection));\n float VdotH = clamp(0.00000000001, 1.0, dot(viewDirectionW, H));\n\n float diffuseTerm = computeDiffuseTerm(NdotL, NdotV, VdotH, roughness);\n result.diffuse = diffuseTerm * diffuseColor * attenuation;\n\n#ifdef SPECULARTERM\n // Specular\n float NdotH = max(0.00000000001, dot(vNormal, H));\n\n vec3 specTerm = computeSpecularTerm(NdotH, NdotL, NdotV, VdotH, roughness, specularColor);\n result.specular = specTerm * attenuation;\n#endif\n\n return result;\n}\n\nlightingInfo computeSpotLighting(vec3 viewDirectionW, vec3 vNormal, vec4 lightData, vec4 lightDirection, vec3 diffuseColor, vec3 specularColor, float range, float roughness, float NdotV, float lightRadius) {\n lightingInfo result;\n\n vec3 lightOffset = lightData.xyz - vPositionW;\n vec3 lightVectorW = normalize(lightOffset);\n\n // diffuse\n float cosAngle = max(0.000000000000001, dot(-lightDirection.xyz, lightVectorW));\n \n if (cosAngle >= lightDirection.w)\n {\n cosAngle = max(0., pow(cosAngle, lightData.w));\n \n // Inverse squared falloff.\n float lightDistanceSquared = dot(lightOffset, lightOffset);\n float lightDistanceFalloff = 1.0 / ((lightDistanceSquared + 0.0001) * range);\n float attenuation = lightDistanceFalloff;\n \n // Directional falloff.\n attenuation *= cosAngle;\n \n // Roughness.\n float lightDistance = sqrt(lightDistanceSquared);\n roughness = adjustRoughnessFromLightProperties(roughness, lightRadius, lightDistance);\n \n // Diffuse\n vec3 H = normalize(viewDirectionW - lightDirection.xyz);\n float NdotL = max(0.00000000001, dot(vNormal, -lightDirection.xyz));\n float VdotH = clamp(dot(viewDirectionW, H), 0.00000000001, 1.0);\n\n float diffuseTerm = computeDiffuseTerm(NdotL, NdotV, VdotH, roughness);\n result.diffuse = diffuseTerm * diffuseColor * attenuation;\n\n#ifdef SPECULARTERM\n // Specular\n float NdotH = max(0.00000000001, dot(vNormal, H));\n\n vec3 specTerm = computeSpecularTerm(NdotH, NdotL, NdotV, VdotH, roughness, specularColor);\n result.specular = specTerm * attenuation;\n#endif\n\n return result;\n }\n\n result.diffuse = vec3(0.);\n#ifdef SPECULARTERM\n result.specular = vec3(0.);\n#endif\n\n return result;\n}\n\nlightingInfo computeHemisphericLighting(vec3 viewDirectionW, vec3 vNormal, vec4 lightData, vec3 diffuseColor, vec3 specularColor, vec3 groundColor, float roughness, float NdotV, float lightRadius) {\n lightingInfo result;\n\n // Roughness\n // Do not touch roughness on hemispheric.\n\n // Diffuse\n float ndl = dot(vNormal, lightData.xyz) * 0.5 + 0.5;\n result.diffuse = mix(groundColor, diffuseColor, ndl);\n\n#ifdef SPECULARTERM\n // Specular\n vec3 lightVectorW = normalize(lightData.xyz);\n vec3 H = normalize(viewDirectionW + lightVectorW);\n float NdotH = max(0.00000000001, dot(vNormal, H));\n float NdotL = max(0.00000000001, ndl);\n float VdotH = clamp(0.00000000001, 1.0, dot(viewDirectionW, H));\n\n vec3 specTerm = computeSpecularTerm(NdotH, NdotL, NdotV, VdotH, roughness, specularColor);\n result.specular = specTerm;\n#endif\n\n return result;\n}\n\nvoid main(void) {\n#include\n\n #ifdef PoissonSamplingEnvironment\n initSamplers();\n #endif\n\n vec3 viewDirectionW = normalize(vEyePosition - vPositionW);\n\n // Albedo\n vec4 surfaceAlbedo = vec4(1., 1., 1., 1.);\n vec3 surfaceAlbedoContribution = vAlbedoColor.rgb;\n \n // Alpha\n float alpha = vAlbedoColor.a;\n\n #ifdef ALBEDO\n surfaceAlbedo = texture2D(albedoSampler, vAlbedoUV);\n surfaceAlbedo = vec4(toLinearSpace(surfaceAlbedo.rgb), surfaceAlbedo.a);\n\n #ifndef LINKREFRACTIONTOTRANSPARENCY\n #ifdef ALPHATEST\n if (surfaceAlbedo.a < 0.4)\n discard;\n #endif\n #endif\n\n #ifdef ALPHAFROMALBEDO\n alpha *= surfaceAlbedo.a;\n #endif\n\n surfaceAlbedo.rgb *= vAlbedoInfos.y;\n #else\n // No Albedo texture.\n surfaceAlbedo.rgb = surfaceAlbedoContribution;\n surfaceAlbedoContribution = vec3(1., 1., 1.);\n #endif\n\n #ifdef VERTEXCOLOR\n surfaceAlbedo.rgb *= vColor.rgb;\n #endif\n\n #ifdef OVERLOADEDVALUES\n surfaceAlbedo.rgb = mix(surfaceAlbedo.rgb, vOverloadedAlbedo, vOverloadedIntensity.y);\n #endif\n\n // Bump\n #ifdef NORMAL\n vec3 normalW = normalize(vNormalW);\n #else\n vec3 normalW = vec3(1.0, 1.0, 1.0);\n #endif\n\n\n #ifdef BUMP\n normalW = perturbNormal(viewDirectionW);\n #endif\n\n // Ambient color\n vec3 ambientColor = vec3(1., 1., 1.);\n\n #ifdef AMBIENT\n ambientColor = texture2D(ambientSampler, vAmbientUV).rgb * vAmbientInfos.y;\n \n #ifdef OVERLOADEDVALUES\n ambientColor.rgb = mix(ambientColor.rgb, vOverloadedAmbient, vOverloadedIntensity.x);\n #endif\n #endif\n\n // Specular map\n float microSurface = vReflectivityColor.a;\n vec3 surfaceReflectivityColor = vReflectivityColor.rgb;\n \n #ifdef OVERLOADEDVALUES\n surfaceReflectivityColor.rgb = mix(surfaceReflectivityColor.rgb, vOverloadedReflectivity, vOverloadedIntensity.z);\n #endif\n\n #ifdef REFLECTIVITY\n vec4 surfaceReflectivityColorMap = texture2D(reflectivitySampler, vReflectivityUV);\n surfaceReflectivityColor = surfaceReflectivityColorMap.rgb;\n surfaceReflectivityColor = toLinearSpace(surfaceReflectivityColor);\n\n #ifdef OVERLOADEDVALUES\n surfaceReflectivityColor = mix(surfaceReflectivityColor, vOverloadedReflectivity, vOverloadedIntensity.z);\n #endif\n\n #ifdef MICROSURFACEFROMREFLECTIVITYMAP\n microSurface = surfaceReflectivityColorMap.a;\n #else\n #ifdef MICROSURFACEAUTOMATIC\n microSurface = computeDefaultMicroSurface(microSurface, surfaceReflectivityColor);\n #endif\n #endif\n #endif\n\n #ifdef OVERLOADEDVALUES\n microSurface = mix(microSurface, vOverloadedMicroSurface.x, vOverloadedMicroSurface.y);\n #endif\n\n // Compute N dot V.\n float NdotV = max(0.00000000001, dot(normalW, viewDirectionW));\n\n // Adapt microSurface.\n microSurface = clamp(microSurface, 0., 1.) * 0.98;\n\n // Compute roughness.\n float roughness = clamp(1. - microSurface, 0.000001, 1.0);\n \n // Lighting\n vec3 lightDiffuseContribution = vec3(0., 0., 0.);\n \n#ifdef OVERLOADEDSHADOWVALUES\n vec3 shadowedOnlyLightDiffuseContribution = vec3(1., 1., 1.);\n#endif\n\n#ifdef SPECULARTERM\n vec3 lightSpecularContribution= vec3(0., 0., 0.);\n#endif\n float notShadowLevel = 1.; // 1 - shadowLevel\n\n#ifdef LIGHT0\n#ifndef SPECULARTERM\n vec3 vLightSpecular0 = vec3(0.0);\n#endif\n#ifdef SPOTLIGHT0\n lightingInfo info = computeSpotLighting(viewDirectionW, normalW, vLightData0, vLightDirection0, vLightDiffuse0.rgb, vLightSpecular0, vLightDiffuse0.a, roughness, NdotV, vLightRadiuses[0]);\n#endif\n#ifdef HEMILIGHT0\n lightingInfo info = computeHemisphericLighting(viewDirectionW, normalW, vLightData0, vLightDiffuse0.rgb, vLightSpecular0, vLightGround0, roughness, NdotV, vLightRadiuses[0]);\n#endif\n#if defined(POINTLIGHT0) || defined(DIRLIGHT0)\n lightingInfo info = computeLighting(viewDirectionW, normalW, vLightData0, vLightDiffuse0.rgb, vLightSpecular0, vLightDiffuse0.a, roughness, NdotV, vLightRadiuses[0]);\n#endif\n#ifdef SHADOW0\n#ifdef SHADOWVSM0\n notShadowLevel = computeShadowWithVSM(vPositionFromLight0, shadowSampler0, shadowsInfo0.z, shadowsInfo0.x);\n#else\n#ifdef SHADOWPCF0\n#if defined(POINTLIGHT0)\n notShadowLevel = computeShadowWithPCFCube(vLightData0.xyz, shadowSampler0, shadowsInfo0.y, shadowsInfo0.z, shadowsInfo0.x);\n#else\n notShadowLevel = computeShadowWithPCF(vPositionFromLight0, shadowSampler0, shadowsInfo0.y, shadowsInfo0.z, shadowsInfo0.x);\n#endif\n#else\n#if defined(POINTLIGHT0)\n notShadowLevel = computeShadowCube(vLightData0.xyz, shadowSampler0, shadowsInfo0.x, shadowsInfo0.z);\n#else\n notShadowLevel = computeShadow(vPositionFromLight0, shadowSampler0, shadowsInfo0.x, shadowsInfo0.z);\n#endif\n#endif\n#endif\n#else\n notShadowLevel = 1.;\n#endif\n lightDiffuseContribution += info.diffuse * notShadowLevel;\n#ifdef OVERLOADEDSHADOWVALUES\n shadowedOnlyLightDiffuseContribution *= notShadowLevel;\n#endif\n\n#ifdef SPECULARTERM\n lightSpecularContribution += info.specular * notShadowLevel;\n#endif\n#endif\n\n#ifdef LIGHT1\n#ifndef SPECULARTERM\n vec3 vLightSpecular1 = vec3(0.0);\n#endif\n#ifdef SPOTLIGHT1\n info = computeSpotLighting(viewDirectionW, normalW, vLightData1, vLightDirection1, vLightDiffuse1.rgb, vLightSpecular1, vLightDiffuse1.a, roughness, NdotV, vLightRadiuses[1]);\n#endif\n#ifdef HEMILIGHT1\n info = computeHemisphericLighting(viewDirectionW, normalW, vLightData1, vLightDiffuse1.rgb, vLightSpecular1, vLightGround1, roughness, NdotV, vLightRadiuses[1]);\n#endif\n#if defined(POINTLIGHT1) || defined(DIRLIGHT1)\n info = computeLighting(viewDirectionW, normalW, vLightData1, vLightDiffuse1.rgb, vLightSpecular1, vLightDiffuse1.a, roughness, NdotV, vLightRadiuses[1]);\n#endif\n#ifdef SHADOW1\n#ifdef SHADOWVSM1\n notShadowLevel = computeShadowWithVSM(vPositionFromLight1, shadowSampler1, shadowsInfo1.z, shadowsInfo1.x);\n#else\n#ifdef SHADOWPCF1\n#if defined(POINTLIGHT1)\n notShadowLevel = computeShadowWithPCFCube(vLightData1.xyz, shadowSampler1, shadowsInfo1.y, shadowsInfo1.z, shadowsInfo1.x);\n#else\n notShadowLevel = computeShadowWithPCF(vPositionFromLight1, shadowSampler1, shadowsInfo1.y, shadowsInfo1.z, shadowsInfo1.x);\n#endif\n#else\n#if defined(POINTLIGHT1)\n notShadowLevel = computeShadowCube(vLightData1.xyz, shadowSampler1, shadowsInfo1.x, shadowsInfo1.z);\n#else\n notShadowLevel = computeShadow(vPositionFromLight1, shadowSampler1, shadowsInfo1.x, shadowsInfo1.z);\n#endif\n#endif\n#endif\n#else\n notShadowLevel = 1.;\n#endif\n\n lightDiffuseContribution += info.diffuse * notShadowLevel;\n#ifdef OVERLOADEDSHADOWVALUES\n shadowedOnlyLightDiffuseContribution *= notShadowLevel;\n#endif\n\n#ifdef SPECULARTERM\n lightSpecularContribution += info.specular * notShadowLevel;\n#endif\n#endif\n\n#ifdef LIGHT2\n#ifndef SPECULARTERM\n vec3 vLightSpecular2 = vec3(0.0);\n#endif\n#ifdef SPOTLIGHT2\n info = computeSpotLighting(viewDirectionW, normalW, vLightData2, vLightDirection2, vLightDiffuse2.rgb, vLightSpecular2, vLightDiffuse2.a, roughness, NdotV, vLightRadiuses[2]);\n#endif\n#ifdef HEMILIGHT2\n info = computeHemisphericLighting(viewDirectionW, normalW, vLightData2, vLightDiffuse2.rgb, vLightSpecular2, vLightGround2, roughness, NdotV, vLightRadiuses[2]);\n#endif\n#if defined(POINTLIGHT2) || defined(DIRLIGHT2)\n info = computeLighting(viewDirectionW, normalW, vLightData2, vLightDiffuse2.rgb, vLightSpecular2, vLightDiffuse2.a, roughness, NdotV, vLightRadiuses[2]);\n#endif\n#ifdef SHADOW2\n#ifdef SHADOWVSM2\n notShadowLevel = computeShadowWithVSM(vPositionFromLight2, shadowSampler2, shadowsInfo2.z, shadowsInfo2.x);\n#else\n#ifdef SHADOWPCF2\n#if defined(POINTLIGHT2)\n notShadowLevel = computeShadowWithPCFCube(vLightData2.xyz, shadowSampler2, shadowsInfo2.y, shadowsInfo2.z, shadowsInfo2.x);\n#else\n notShadowLevel = computeShadowWithPCF(vPositionFromLight2, shadowSampler2, shadowsInfo2.y, shadowsInfo2.z, shadowsInfo2.x);\n#endif\n#else\n#if defined(POINTLIGHT2)\n notShadowLevel = computeShadowCube(vLightData2.xyz, shadowSampler2, shadowsInfo2.x, shadowsInfo2.z);\n#else\n notShadowLevel = computeShadow(vPositionFromLight2, shadowSampler2, shadowsInfo2.x, shadowsInfo2.z);\n#endif\n#endif\t\n#endif\t\n#else\n notShadowLevel = 1.;\n#endif\n\n lightDiffuseContribution += info.diffuse * notShadowLevel;\n#ifdef OVERLOADEDSHADOWVALUES\n shadowedOnlyLightDiffuseContribution *= notShadowLevel;\n#endif\n\n#ifdef SPECULARTERM\n lightSpecularContribution += info.specular * notShadowLevel;\n#endif\n#endif\n\n#ifdef LIGHT3\n#ifndef SPECULARTERM\n vec3 vLightSpecular3 = vec3(0.0);\n#endif\n#ifdef SPOTLIGHT3\n info = computeSpotLighting(viewDirectionW, normalW, vLightData3, vLightDirection3, vLightDiffuse3.rgb, vLightSpecular3, vLightDiffuse3.a, roughness, NdotV, vLightRadiuses[3]);\n#endif\n#ifdef HEMILIGHT3\n info = computeHemisphericLighting(viewDirectionW, normalW, vLightData3, vLightDiffuse3.rgb, vLightSpecular3, vLightGround3, roughness, NdotV, vLightRadiuses[3]);\n#endif\n#if defined(POINTLIGHT3) || defined(DIRLIGHT3)\n info = computeLighting(viewDirectionW, normalW, vLightData3, vLightDiffuse3.rgb, vLightSpecular3, vLightDiffuse3.a, roughness, NdotV, vLightRadiuses[3]);\n#endif\n#ifdef SHADOW3\n#ifdef SHADOWVSM3\n notShadowLevel = computeShadowWithVSM(vPositionFromLight3, shadowSampler3, shadowsInfo3.z, shadowsInfo3.x);\n#else\n#ifdef SHADOWPCF3\n#if defined(POINTLIGHT3)\n notShadowLevel = computeShadowWithPCFCube(vLightData3.xyz, shadowSampler3, shadowsInfo3.y, shadowsInfo3.z, shadowsInfo3.x);\n#else\n notShadowLevel = computeShadowWithPCF(vPositionFromLight3, shadowSampler3, shadowsInfo3.y, shadowsInfo3.z, shadowsInfo3.x);\n#endif\n#else\n#if defined(POINTLIGHT3)\n notShadowLevel = computeShadowCube(vLightData3.xyz, shadowSampler3, shadowsInfo3.x, shadowsInfo3.z);\n#else\n notShadowLevel = computeShadow(vPositionFromLight3, shadowSampler3, shadowsInfo3.x, shadowsInfo3.z);\n#endif\n#endif\t\n#endif\t\n#else\n notShadowLevel = 1.;\n#endif\n\n lightDiffuseContribution += info.diffuse * notShadowLevel;\n#ifdef OVERLOADEDSHADOWVALUES\n shadowedOnlyLightDiffuseContribution *= notShadowLevel;\n#endif\n\n#ifdef SPECULARTERM\n lightSpecularContribution += info.specular * notShadowLevel;\n#endif\n#endif\n\n#ifdef SPECULARTERM\n lightSpecularContribution *= vLightingIntensity.w;\n#endif\n\n#ifdef OPACITY\n vec4 opacityMap = texture2D(opacitySampler, vOpacityUV);\n\n #ifdef OPACITYRGB\n opacityMap.rgb = opacityMap.rgb * vec3(0.3, 0.59, 0.11);\n alpha *= (opacityMap.x + opacityMap.y + opacityMap.z)* vOpacityInfos.y;\n #else\n alpha *= opacityMap.a * vOpacityInfos.y;\n #endif\n\n#endif\n\n#ifdef VERTEXALPHA\n alpha *= vColor.a;\n#endif\n\n#ifdef OPACITYFRESNEL\n float opacityFresnelTerm = computeFresnelTerm(viewDirectionW, normalW, opacityParts.z, opacityParts.w);\n\n alpha += opacityParts.x * (1.0 - opacityFresnelTerm) + opacityFresnelTerm * opacityParts.y;\n#endif\n\n// Refraction\nvec3 surfaceRefractionColor = vec3(0., 0., 0.);\n\n// Go mat -> blurry reflexion according to microSurface\n#ifndef LODBASEDMICROSFURACE\n float bias = 20. * (1.0 - microSurface);\n#else\n float alphaG = convertRoughnessToAverageSlope(roughness);\n#endif\n \n#ifdef REFRACTION\n\tvec3 refractionVector = normalize(refract(-viewDirectionW, normalW, vRefractionInfos.y));\n \n #ifdef LODBASEDMICROSFURACE\n float lodRefraction = getMipMapIndexFromAverageSlope(vMicrosurfaceTextureLods.y, alphaG);\n #endif\n \n #ifdef REFRACTIONMAP_3D\n refractionVector.y = refractionVector.y * vRefractionInfos.w;\n\n if (dot(refractionVector, viewDirectionW) < 1.0)\n {\n #ifdef LODBASEDMICROSFURACE\n surfaceRefractionColor = textureCubeLodEXT(refractionCubeSampler, refractionVector, lodRefraction).rgb * vRefractionInfos.x;\n #else\n surfaceRefractionColor = textureCube(refractionCubeSampler, refractionVector, bias).rgb * vRefractionInfos.x;\n #endif\n }\n \n #ifndef REFRACTIONMAPINLINEARSPACE\n surfaceRefractionColor = toLinearSpace(surfaceRefractionColor.rgb); \n #endif\n #else\n vec3 vRefractionUVW = vec3(refractionMatrix * (view * vec4(vPositionW + refractionVector * vRefractionInfos.z, 1.0)));\n\n vec2 refractionCoords = vRefractionUVW.xy / vRefractionUVW.z;\n\n refractionCoords.y = 1.0 - refractionCoords.y;\n\n #ifdef LODBASEDMICROSFURACE\n surfaceRefractionColor = texture2DLodEXT(refraction2DSampler, refractionCoords, lodRefraction).rgb * vRefractionInfos.x;\n #else\n surfaceRefractionColor = texture2D(refraction2DSampler, refractionCoords).rgb * vRefractionInfos.x;\n #endif \n \n surfaceRefractionColor = toLinearSpace(surfaceRefractionColor.rgb); \n #endif\n#endif\n\n// Reflection\nvec3 environmentRadiance = vReflectionColor.rgb;\nvec3 environmentIrradiance = vReflectionColor.rgb;\n\n#ifdef REFLECTION\n vec3 vReflectionUVW = computeReflectionCoords(vec4(vPositionW, 1.0), normalW);\n\n #ifdef LODBASEDMICROSFURACE\n float lodReflection = getMipMapIndexFromAverageSlope(vMicrosurfaceTextureLods.x, alphaG);\n #endif\n \n #ifdef REFLECTIONMAP_3D\n \n #ifdef LODBASEDMICROSFURACE\n environmentRadiance = textureCubeLodEXT(reflectionCubeSampler, vReflectionUVW, lodReflection).rgb * vReflectionInfos.x;\n #else\n environmentRadiance = textureCube(reflectionCubeSampler, vReflectionUVW, bias).rgb * vReflectionInfos.x;\n #endif\n \n #ifdef PoissonSamplingEnvironment\n environmentRadiance = environmentSampler(reflectionCubeSampler, vReflectionUVW, alphaG) * vReflectionInfos.x;\n #endif\n\n #ifdef USESPHERICALFROMREFLECTIONMAP\n #ifndef REFLECTIONMAP_SKYBOX\n vec3 normalEnvironmentSpace = (reflectionMatrix * vec4(normalW, 1)).xyz;\n environmentIrradiance = EnvironmentIrradiance(normalEnvironmentSpace);\n #endif\n #else\n environmentRadiance = toLinearSpace(environmentRadiance.rgb);\n \n environmentIrradiance = textureCube(reflectionCubeSampler, normalW, 20.).rgb * vReflectionInfos.x;\n environmentIrradiance = toLinearSpace(environmentIrradiance.rgb);\n environmentIrradiance *= 0.2; // Hack in case of no hdr cube map use for environment.\n #endif\n #else\n vec2 coords = vReflectionUVW.xy;\n\n #ifdef REFLECTIONMAP_PROJECTION\n coords /= vReflectionUVW.z;\n #endif\n\n coords.y = 1.0 - coords.y;\n #ifdef LODBASEDMICROSFURACE\n environmentRadiance = texture2DLodExt(reflection2DSampler, coords, lodReflection).rgb * vReflectionInfos.x;\n #else\n environmentRadiance = texture2D(reflection2DSampler, coords).rgb * vReflectionInfos.x;\n #endif\n \n environmentRadiance = toLinearSpace(environmentRadiance.rgb);\n\n environmentIrradiance = texture2D(reflection2DSampler, coords, 20.).rgb * vReflectionInfos.x;\n environmentIrradiance = toLinearSpace(environmentIrradiance.rgb);\n #endif\n#endif\n\n#ifdef OVERLOADEDVALUES\n environmentIrradiance = mix(environmentIrradiance, vOverloadedReflection, vOverloadedMicroSurface.z);\n environmentRadiance = mix(environmentRadiance, vOverloadedReflection, vOverloadedMicroSurface.z);\n#endif\n\nenvironmentRadiance *= vLightingIntensity.z;\nenvironmentIrradiance *= vLightingIntensity.z;\n\n// Compute reflection specular fresnel\nvec3 specularEnvironmentR0 = surfaceReflectivityColor.rgb;\nvec3 specularEnvironmentR90 = vec3(1.0, 1.0, 1.0);\nvec3 specularEnvironmentReflectance = FresnelSchlickEnvironmentGGX(clamp(NdotV, 0., 1.), specularEnvironmentR0, specularEnvironmentR90, sqrt(microSurface));\n\n// Compute refractance\nvec3 refractance = vec3(0.0 , 0.0, 0.0);\n#ifdef REFRACTION\n vec3 transmission = vec3(1.0 , 1.0, 1.0);\n #ifdef LINKREFRACTIONTOTRANSPARENCY\n // Transmission based on alpha.\n transmission *= (1.0 - alpha);\n \n // Tint the material with albedo.\n // TODO. PBR Tinting.\n vec3 mixedAlbedo = surfaceAlbedoContribution.rgb * surfaceAlbedo.rgb;\n float maxChannel = max(max(mixedAlbedo.r, mixedAlbedo.g), mixedAlbedo.b);\n vec3 tint = clamp(maxChannel * mixedAlbedo, 0.0, 1.0);\n \n // Decrease Albedo Contribution\n surfaceAlbedoContribution *= alpha;\n \n // Decrease irradiance Contribution\n environmentIrradiance *= alpha;\n \n // Tint reflectance\n surfaceRefractionColor *= tint;\n \n // Put alpha back to 1;\n alpha = 1.0;\n #endif\n \n // Add Multiple internal bounces.\n vec3 bounceSpecularEnvironmentReflectance = (2.0 * specularEnvironmentReflectance) / (1.0 + specularEnvironmentReflectance);\n specularEnvironmentReflectance = mix(bounceSpecularEnvironmentReflectance, specularEnvironmentReflectance, alpha);\n \n // In theory T = 1 - R.\n transmission *= 1.0 - specularEnvironmentReflectance;\n \n // Should baked in diffuse.\n refractance = surfaceRefractionColor * transmission;\n#endif\n\n// Apply Energy Conservation taking in account the environment level only if the environment is present.\nfloat reflectance = max(max(surfaceReflectivityColor.r, surfaceReflectivityColor.g), surfaceReflectivityColor.b);\nsurfaceAlbedo.rgb = (1. - reflectance) * surfaceAlbedo.rgb;\n\nrefractance *= vLightingIntensity.z;\nenvironmentRadiance *= specularEnvironmentReflectance;\n\n// Emissive\nvec3 surfaceEmissiveColor = vEmissiveColor;\n#ifdef EMISSIVE\n vec3 emissiveColorTex = texture2D(emissiveSampler, vEmissiveUV).rgb;\n surfaceEmissiveColor = toLinearSpace(emissiveColorTex.rgb) * surfaceEmissiveColor * vEmissiveInfos.y;\n#endif\n\n#ifdef OVERLOADEDVALUES\n surfaceEmissiveColor = mix(surfaceEmissiveColor, vOverloadedEmissive, vOverloadedIntensity.w);\n#endif\n\n#ifdef EMISSIVEFRESNEL\n float emissiveFresnelTerm = computeFresnelTerm(viewDirectionW, normalW, emissiveRightColor.a, emissiveLeftColor.a);\n\n surfaceEmissiveColor *= emissiveLeftColor.rgb * (1.0 - emissiveFresnelTerm) + emissiveFresnelTerm * emissiveRightColor.rgb;\n#endif\n\n// Composition\n#ifdef EMISSIVEASILLUMINATION\n vec3 finalDiffuse = max(lightDiffuseContribution * surfaceAlbedoContribution + vAmbientColor, 0.0) * surfaceAlbedo.rgb;\n \n #ifdef OVERLOADEDSHADOWVALUES\n shadowedOnlyLightDiffuseContribution = max(shadowedOnlyLightDiffuseContribution * surfaceAlbedoContribution + vAmbientColor, 0.0) * surfaceAlbedo.rgb;\n #endif\n#else\n #ifdef LINKEMISSIVEWITHALBEDO\n vec3 finalDiffuse = max((lightDiffuseContribution + surfaceEmissiveColor) * surfaceAlbedoContribution + vAmbientColor, 0.0) * surfaceAlbedo.rgb;\n\n #ifdef OVERLOADEDSHADOWVALUES\n shadowedOnlyLightDiffuseContribution = max((shadowedOnlyLightDiffuseContribution + surfaceEmissiveColor) * surfaceAlbedoContribution + vAmbientColor, 0.0) * surfaceAlbedo.rgb;\n #endif\n #else\n vec3 finalDiffuse = max(lightDiffuseContribution * surfaceAlbedoContribution + surfaceEmissiveColor + vAmbientColor, 0.0) * surfaceAlbedo.rgb;\n\n #ifdef OVERLOADEDSHADOWVALUES\n shadowedOnlyLightDiffuseContribution = max(shadowedOnlyLightDiffuseContribution * surfaceAlbedoContribution + surfaceEmissiveColor + vAmbientColor, 0.0) * surfaceAlbedo.rgb;\n #endif\n #endif\n#endif\n\n#ifdef OVERLOADEDSHADOWVALUES\n finalDiffuse = mix(finalDiffuse, shadowedOnlyLightDiffuseContribution, (1.0 - vOverloadedShadowIntensity.y));\n#endif\n\n#ifdef SPECULARTERM\n vec3 finalSpecular = lightSpecularContribution * surfaceReflectivityColor;\n#else\n vec3 finalSpecular = vec3(0.0);\n#endif\n\n#ifdef OVERLOADEDSHADOWVALUES\n finalSpecular = mix(finalSpecular, vec3(0.0), (1.0 - vOverloadedShadowIntensity.y));\n#endif\n\n#ifdef SPECULAROVERALPHA\n alpha = clamp(alpha + dot(finalSpecular, vec3(0.3, 0.59, 0.11)), 0., 1.);\n#endif\n\n// Composition\n// Reflection already includes the environment intensity.\n#ifdef EMISSIVEASILLUMINATION\n vec4 finalColor = vec4(finalDiffuse * ambientColor * vLightingIntensity.x + surfaceAlbedo.rgb * environmentIrradiance + finalSpecular * vLightingIntensity.x + environmentRadiance + surfaceEmissiveColor * vLightingIntensity.y + refractance, alpha);\n#else\n vec4 finalColor = vec4(finalDiffuse * ambientColor * vLightingIntensity.x + surfaceAlbedo.rgb * environmentIrradiance + finalSpecular * vLightingIntensity.x + environmentRadiance + refractance, alpha);\n#endif\n\n#ifdef LIGHTMAP\n vec3 lightmapColor = texture2D(lightmapSampler, vLightmapUV).rgb * vLightmapInfos.y;\n\n #ifdef USELIGHTMAPASSHADOWMAP\n finalColor.rgb *= lightmapColor;\n #else\n finalColor.rgb += lightmapColor;\n #endif\n#endif\n\n finalColor = max(finalColor, 0.0);\n\n#ifdef CAMERATONEMAP\n finalColor.rgb = toneMaps(finalColor.rgb);\n#endif\n\n finalColor.rgb = toGammaSpace(finalColor.rgb);\n\n#ifdef CAMERACONTRAST\n finalColor = contrasts(finalColor);\n#endif\n\n // Normal Display.\n // gl_FragColor = vec4(normalW * 0.5 + 0.5, 1.0);\n\n // Ambient reflection color.\n // gl_FragColor = vec4(ambientReflectionColor, 1.0);\n\n // Reflection color.\n // gl_FragColor = vec4(reflectionColor, 1.0);\n\n // Base color.\n // gl_FragColor = vec4(surfaceAlbedo.rgb, 1.0);\n\n // Specular color.\n // gl_FragColor = vec4(surfaceReflectivityColor.rgb, 1.0);\n\n // MicroSurface color.\n // gl_FragColor = vec4(microSurface, microSurface, microSurface, 1.0);\n\n // Specular Map\n // gl_FragColor = vec4(reflectivityMapColor.rgb, 1.0);\n \n // Refractance\n // gl_FragColor = vec4(refractance.rgb, 1.0);\n\n //// Emissive Color\n //vec2 test = vEmissiveUV * 0.5 + 0.5;\n //gl_FragColor = vec4(test.x, test.y, 1.0, 1.0);\n\n#include\n#include(color, finalColor)\n\n gl_FragColor = finalColor;\n}"; BABYLON.Effect.ShadersStore['legacypbrVertexShader'] = "precision mediump float;\n\n// Attributes\nattribute vec3 position;\nattribute vec3 normal;\n#ifdef UV1\nattribute vec2 uv;\n#endif\n#ifdef UV2\nattribute vec2 uv2;\n#endif\n#ifdef VERTEXCOLOR\nattribute vec4 color;\n#endif\n\n#include\n\n// Uniforms\nuniform mat4 world;\nuniform mat4 view;\nuniform mat4 viewProjection;\n\n#ifdef ALBEDO\nvarying vec2 vAlbedoUV;\nuniform mat4 albedoMatrix;\nuniform vec2 vAlbedoInfos;\n#endif\n\n#ifdef AMBIENT\nvarying vec2 vAmbientUV;\nuniform mat4 ambientMatrix;\nuniform vec2 vAmbientInfos;\n#endif\n\n#ifdef OPACITY\nvarying vec2 vOpacityUV;\nuniform mat4 opacityMatrix;\nuniform vec2 vOpacityInfos;\n#endif\n\n#ifdef EMISSIVE\nvarying vec2 vEmissiveUV;\nuniform vec2 vEmissiveInfos;\nuniform mat4 emissiveMatrix;\n#endif\n\n#if defined(REFLECTIVITY)\nvarying vec2 vReflectivityUV;\nuniform vec2 vReflectivityInfos;\nuniform mat4 reflectivityMatrix;\n#endif\n\n// Output\nvarying vec3 vPositionW;\nvarying vec3 vNormalW;\n\n#ifdef VERTEXCOLOR\nvarying vec4 vColor;\n#endif\n\n#include\n\nvoid main(void) {\n mat4 finalWorld = world;\n\n#include\n\n finalWorld = finalWorld * influence;\n#endif\n\n\tgl_Position = viewProjection * finalWorld * vec4(position, 1.0);\n\n\tvec4 worldPos = finalWorld * vec4(position, 1.0);\n\tvPositionW = vec3(worldPos);\n\tvNormalW = normalize(vec3(finalWorld * vec4(normal, 0.0)));\n\n\t// Texture coordinates\n#ifndef UV1\n\tvec2 uv = vec2(0., 0.);\n#endif\n#ifndef UV2\n\tvec2 uv2 = vec2(0., 0.);\n#endif\n\n#ifdef ALBEDO\n\tif (vAlbedoInfos.x == 0.)\n\t{\n\t\tvAlbedoUV = vec2(albedoMatrix * vec4(uv, 1.0, 0.0));\n\t}\n\telse\n\t{\n\t\tvAlbedoUV = vec2(albedoMatrix * vec4(uv2, 1.0, 0.0));\n\t}\n#endif\n\n#ifdef AMBIENT\n\tif (vAmbientInfos.x == 0.)\n\t{\n\t\tvAmbientUV = vec2(ambientMatrix * vec4(uv, 1.0, 0.0));\n\t}\n\telse\n\t{\n\t\tvAmbientUV = vec2(ambientMatrix * vec4(uv2, 1.0, 0.0));\n\t}\n#endif\n\n#ifdef OPACITY\n\tif (vOpacityInfos.x == 0.)\n\t{\n\t\tvOpacityUV = vec2(opacityMatrix * vec4(uv, 1.0, 0.0));\n\t}\n\telse\n\t{\n\t\tvOpacityUV = vec2(opacityMatrix * vec4(uv2, 1.0, 0.0));\n\t}\n#endif\n\n#ifdef EMISSIVE\n\tif (vEmissiveInfos.x == 0.)\n\t{\n\t\tvEmissiveUV = vec2(emissiveMatrix * vec4(uv, 1.0, 0.0));\n\t}\n\telse\n\t{\n\t\tvEmissiveUV = vec2(emissiveMatrix * vec4(uv2, 1.0, 0.0));\n\t}\n#endif\n\n#if defined(REFLECTIVITY)\n\tif (vReflectivityInfos.x == 0.)\n\t{\n\t\tvReflectivityUV = vec2(reflectivityMatrix * vec4(uv, 1.0, 0.0));\n\t}\n\telse\n\t{\n\t\tvReflectivityUV = vec2(reflectivityMatrix * vec4(uv2, 1.0, 0.0));\n\t}\n#endif\n\n#include\n\n\t// Vertex color\n#ifdef VERTEXCOLOR\n\tvColor = color;\n#endif\n}"; BABYLON.Effect.ShadersStore['legacypbrPixelShader'] = "precision mediump float;\n\n// Constants\n#define RECIPROCAL_PI2 0.15915494\n#define FRESNEL_MAXIMUM_ON_ROUGH 0.25\n\nuniform vec3 vEyePosition;\nuniform vec3 vAmbientColor;\nuniform vec4 vAlbedoColor;\nuniform vec3 vReflectionColor;\n\n// CUSTOM CONTROLS\nuniform vec4 vLightingIntensity;\nuniform vec4 vCameraInfos;\n\n#ifdef OVERLOADEDVALUES\nuniform vec4 vOverloadedIntensity;\nuniform vec3 vOverloadedAmbient;\nuniform vec3 vOverloadedAlbedo;\nuniform vec3 vOverloadedReflectivity;\nuniform vec3 vOverloadedEmissive;\nuniform vec3 vOverloadedReflection;\nuniform vec3 vOverloadedMicroSurface;\n#endif\n\n#ifdef OVERLOADEDSHADOWVALUES\nuniform vec4 vOverloadedShadowIntensity;\n#endif\n\n// PBR CUSTOM CONSTANTS\nconst float kPi = 3.1415926535897932384626433832795;\n\n// PBR HELPER METHODS\nfloat Square(float value)\n{\n return value * value;\n}\n\nfloat getLuminance(vec3 color)\n{\n return clamp(dot(color, vec3(0.2126, 0.7152, 0.0722)), 0., 1.);\n}\n\nfloat convertRoughnessToAverageSlope(float roughness)\n{\n // Calculate AlphaG as square of roughness; add epsilon to avoid numerical issues\n const float kMinimumVariance = 0.0005;\n float alphaG = Square(roughness) + kMinimumVariance;\n return alphaG;\n}\n\n// From Microfacet Models for Refraction through Rough Surfaces, Walter et al. 2007\nfloat smithVisibilityG1_TrowbridgeReitzGGX(float dot, float alphaG)\n{\n float tanSquared = (1.0 - dot * dot) / (dot * dot);\n return 2.0 / (1.0 + sqrt(1.0 + alphaG * alphaG * tanSquared));\n}\n\nfloat smithVisibilityG_TrowbridgeReitzGGX_Walter(float NdotL, float NdotV, float alphaG)\n{\n return smithVisibilityG1_TrowbridgeReitzGGX(NdotL, alphaG) * smithVisibilityG1_TrowbridgeReitzGGX(NdotV, alphaG);\n}\n\n// Trowbridge-Reitz (GGX)\n// Generalised Trowbridge-Reitz with gamma power=2.0\nfloat normalDistributionFunction_TrowbridgeReitzGGX(float NdotH, float alphaG)\n{\n // Note: alphaG is average slope (gradient) of the normals in slope-space.\n // It is also the (trigonometric) tangent of the median distribution value, i.e. 50% of normals have\n // a tangent (gradient) closer to the macrosurface than this slope.\n float a2 = Square(alphaG);\n float d = NdotH * NdotH * (a2 - 1.0) + 1.0;\n return a2 / (kPi * d * d);\n}\n\nvec3 fresnelSchlickGGX(float VdotH, vec3 reflectance0, vec3 reflectance90)\n{\n return reflectance0 + (reflectance90 - reflectance0) * pow(clamp(1.0 - VdotH, 0., 1.), 5.0);\n}\n\nvec3 FresnelSchlickEnvironmentGGX(float VdotN, vec3 reflectance0, vec3 reflectance90, float smoothness)\n{\n // Schlick fresnel approximation, extended with basic smoothness term so that rough surfaces do not approach reflectance90 at grazing angle\n float weight = mix(FRESNEL_MAXIMUM_ON_ROUGH, 1.0, smoothness);\n return reflectance0 + weight * (reflectance90 - reflectance0) * pow(clamp(1.0 - VdotN, 0., 1.), 5.0);\n}\n\n// Cook Torance Specular computation.\nvec3 computeSpecularTerm(float NdotH, float NdotL, float NdotV, float VdotH, float roughness, vec3 specularColor)\n{\n float alphaG = convertRoughnessToAverageSlope(roughness);\n float distribution = normalDistributionFunction_TrowbridgeReitzGGX(NdotH, alphaG);\n float visibility = smithVisibilityG_TrowbridgeReitzGGX_Walter(NdotL, NdotV, alphaG);\n visibility /= (4.0 * NdotL * NdotV); // Cook Torance Denominator integated in viibility to avoid issues when visibility function changes.\n\n vec3 fresnel = fresnelSchlickGGX(VdotH, specularColor, vec3(1., 1., 1.));\n\n float specTerm = max(0., visibility * distribution) * NdotL;\n return fresnel * specTerm;\n}\n\nfloat computeDiffuseTerm(float NdotL, float NdotV, float VdotH, float roughness)\n{\n // Diffuse fresnel falloff as per Disney principled BRDF, and in the spirit of\n // of general coupled diffuse/specular models e.g. Ashikhmin Shirley.\n float diffuseFresnelNV = pow(clamp(1.0 - NdotL, 0.000001, 1.), 5.0);\n float diffuseFresnelNL = pow(clamp(1.0 - NdotV, 0.000001, 1.), 5.0);\n float diffuseFresnel90 = 0.5 + 2.0 * VdotH * VdotH * roughness;\n float diffuseFresnelTerm =\n (1.0 + (diffuseFresnel90 - 1.0) * diffuseFresnelNL) *\n (1.0 + (diffuseFresnel90 - 1.0) * diffuseFresnelNV);\n\n return diffuseFresnelTerm * NdotL;\n}\n\nfloat computeDefaultMicroSurface(float microSurface, vec3 reflectivityColor)\n{\n if (microSurface == 0.)\n {\n float kReflectivityNoAlphaWorkflow_SmoothnessMax = 0.95;\n\n float reflectivityLuminance = getLuminance(reflectivityColor);\n float reflectivityLuma = sqrt(reflectivityLuminance);\n microSurface = reflectivityLuma * kReflectivityNoAlphaWorkflow_SmoothnessMax;\n }\n return microSurface;\n}\n\nvec3 toLinearSpace(vec3 color)\n{\n return vec3(pow(color.r, 2.2), pow(color.g, 2.2), pow(color.b, 2.2));\n}\n\nvec3 toGammaSpace(vec3 color)\n{\n return vec3(pow(color.r, 1.0 / 2.2), pow(color.g, 1.0 / 2.2), pow(color.b, 1.0 / 2.2));\n}\n\n#ifdef CAMERATONEMAP\n vec3 toneMaps(vec3 color)\n {\n color = max(color, 0.0);\n\n // TONE MAPPING / EXPOSURE\n color.rgb = color.rgb * vCameraInfos.x;\n\n float tuning = 1.5; // TODO: sync up so e.g. 18% greys are matched to exposure appropriately\n vec3 tonemapped = 1.0 - exp2(-color.rgb * tuning); // simple local photographic tonemapper\n color.rgb = mix(color.rgb, tonemapped, 1.0);\n return color;\n }\n#endif\n\n#ifdef CAMERACONTRAST\n vec4 contrasts(vec4 color)\n {\n color = clamp(color, 0.0, 1.0);\n\n vec3 resultHighContrast = color.rgb * color.rgb * (3.0 - 2.0 * color.rgb);\n float contrast = vCameraInfos.y;\n if (contrast < 1.0)\n {\n // Decrease contrast: interpolate towards zero-contrast image (flat grey)\n color.rgb = mix(vec3(0.5, 0.5, 0.5), color.rgb, contrast);\n }\n else\n {\n // Increase contrast: apply simple shoulder-toe high contrast curve\n color.rgb = mix(color.rgb, resultHighContrast, contrast - 1.0);\n }\n\n return color;\n }\n#endif\n// END PBR HELPER METHODS\n\nuniform vec4 vReflectivityColor;\nuniform vec3 vEmissiveColor;\n\n// Input\nvarying vec3 vPositionW;\n\n#ifdef NORMAL\nvarying vec3 vNormalW;\n#endif\n\n#ifdef VERTEXCOLOR\nvarying vec4 vColor;\n#endif\n\n// Lights\n#include\n#include\n#include\n#include\n\n// Samplers\n#ifdef ALBEDO\nvarying vec2 vAlbedoUV;\nuniform sampler2D albedoSampler;\nuniform vec2 vAlbedoInfos;\n#endif\n\n#ifdef AMBIENT\nvarying vec2 vAmbientUV;\nuniform sampler2D ambientSampler;\nuniform vec2 vAmbientInfos;\n#endif\n\n#ifdef OPACITY\t\nvarying vec2 vOpacityUV;\nuniform sampler2D opacitySampler;\nuniform vec2 vOpacityInfos;\n#endif\n\n#ifdef EMISSIVE\nvarying vec2 vEmissiveUV;\nuniform vec2 vEmissiveInfos;\nuniform sampler2D emissiveSampler;\n#endif\n\n#ifdef LIGHTMAP\nvarying vec2 vLightmapUV;\nuniform vec2 vLightmapInfos;\nuniform sampler2D lightmapSampler;\n#endif\n\n#if defined(REFLECTIVITY)\nvarying vec2 vReflectivityUV;\nuniform vec2 vReflectivityInfos;\nuniform sampler2D reflectivitySampler;\n#endif\n\n#include\n\n// Light Computing\nstruct lightingInfo\n{\n vec3 diffuse;\n#ifdef SPECULARTERM\n vec3 specular;\n#endif\n};\n\nlightingInfo computeLighting(vec3 viewDirectionW, vec3 vNormal, vec4 lightData, vec3 diffuseColor, vec3 specularColor, float range, float roughness, float NdotV) {\n lightingInfo result;\n\n vec3 lightVectorW;\n float attenuation = 1.0;\n if (lightData.w == 0.)\n {\n vec3 direction = lightData.xyz - vPositionW;\n\n attenuation = max(0., 1.0 - length(direction) / range);\n lightVectorW = normalize(direction);\n }\n else\n {\n lightVectorW = normalize(-lightData.xyz);\n }\n\n // diffuse\n vec3 H = normalize(viewDirectionW + lightVectorW);\n float NdotL = max(0.00000000001, dot(vNormal, lightVectorW));\n float VdotH = clamp(0.00000000001, 1.0, dot(viewDirectionW, H));\n\n float diffuseTerm = computeDiffuseTerm(NdotL, NdotV, VdotH, roughness);\n result.diffuse = diffuseTerm * diffuseColor * attenuation;\n\n#ifdef SPECULARTERM\n // Specular\n float NdotH = max(0.00000000001, dot(vNormal, H));\n\n vec3 specTerm = computeSpecularTerm(NdotH, NdotL, NdotV, VdotH, roughness, specularColor);\n result.specular = specTerm * specularColor * attenuation;\n#endif\n\n return result;\n}\n\nlightingInfo computeSpotLighting(vec3 viewDirectionW, vec3 vNormal, vec4 lightData, vec4 lightDirection, vec3 diffuseColor, vec3 specularColor, float range, float roughness, float NdotV) {\n lightingInfo result;\n\n vec3 direction = lightData.xyz - vPositionW;\n vec3 lightVectorW = normalize(direction);\n float attenuation = max(0., 1.0 - length(direction) / range);\n\n // diffuse\n float cosAngle = max(0.0000001, dot(-lightDirection.xyz, lightVectorW));\n float spotAtten = 0.0;\n\n if (cosAngle >= lightDirection.w)\n {\n cosAngle = max(0., pow(cosAngle, lightData.w));\n spotAtten = clamp((cosAngle - lightDirection.w) / (1. - cosAngle), 0.0, 1.0);\n\n // Diffuse\n vec3 H = normalize(viewDirectionW - lightDirection.xyz);\n float NdotL = max(0.00000000001, dot(vNormal, -lightDirection.xyz));\n float VdotH = clamp(dot(viewDirectionW, H), 0.00000000001, 1.0);\n\n float diffuseTerm = computeDiffuseTerm(NdotL, NdotV, VdotH, roughness);\n result.diffuse = diffuseTerm * diffuseColor * attenuation * spotAtten;\n\n#ifdef SPECULARTERM\n // Specular\n float NdotH = max(0.00000000001, dot(vNormal, H));\n\n vec3 specTerm = computeSpecularTerm(NdotH, NdotL, NdotV, VdotH, roughness, specularColor);\n result.specular = specTerm * specularColor * attenuation * spotAtten;\n#endif\n\n return result;\n }\n\n result.diffuse = vec3(0.);\n#ifdef SPECULARTERM\n result.specular = vec3(0.);\n#endif\n\n return result;\n}\n\nlightingInfo computeHemisphericLighting(vec3 viewDirectionW, vec3 vNormal, vec4 lightData, vec3 diffuseColor, vec3 specularColor, vec3 groundColor, float roughness, float NdotV) {\n lightingInfo result;\n\n vec3 lightVectorW = normalize(lightData.xyz);\n\n // Diffuse\n float ndl = dot(vNormal, lightData.xyz) * 0.5 + 0.5;\n result.diffuse = mix(groundColor, diffuseColor, ndl);\n\n#ifdef SPECULARTERM\n // Specular\n vec3 H = normalize(viewDirectionW + lightVectorW);\n float NdotH = max(0.00000000001, dot(vNormal, H));\n float NdotL = max(0.00000000001, ndl);\n float VdotH = clamp(0.00000000001, 1.0, dot(viewDirectionW, H));\n\n vec3 specTerm = computeSpecularTerm(NdotH, NdotL, NdotV, VdotH, roughness, specularColor);\n result.specular = specTerm * specularColor;\n#endif\n\n return result;\n}\n\nvoid main(void) {\n#include\n\n vec3 viewDirectionW = normalize(vEyePosition - vPositionW);\n\n // Base color\n vec4 baseColor = vec4(1., 1., 1., 1.);\n vec3 diffuseColor = vAlbedoColor.rgb;\n \n // Alpha\n float alpha = vAlbedoColor.a;\n\n#ifdef ALBEDO\n baseColor = texture2D(diffuseSampler, vAlbedoUV);\n baseColor = vec4(toLinearSpace(baseColor.rgb), baseColor.a);\n\n#ifdef ALPHATEST\n if (baseColor.a < 0.4)\n discard;\n#endif\n\n#ifdef ALPHAFROMALBEDO\n alpha *= baseColor.a;\n#endif\n\n baseColor.rgb *= vAlbedoInfos.y;\n#endif\n\n#ifdef VERTEXCOLOR\n baseColor.rgb *= vColor.rgb;\n#endif\n\n#ifdef OVERLOADEDVALUES\n baseColor.rgb = mix(baseColor.rgb, vOverloadedAlbedo, vOverloadedIntensity.y);\n albedoColor.rgb = mix(albedoColor.rgb, vOverloadedAlbedo, vOverloadedIntensity.y);\n#endif\n\n // Bump\n#ifdef NORMAL\n vec3 normalW = normalize(vNormalW);\n#else\n vec3 normalW = vec3(1.0, 1.0, 1.0);\n#endif\n\n // Ambient color\n vec3 baseAmbientColor = vec3(1., 1., 1.);\n\n#ifdef AMBIENT\n baseAmbientColor = texture2D(ambientSampler, vAmbientUV).rgb * vAmbientInfos.y;\n #ifdef OVERLOADEDVALUES\n baseAmbientColor.rgb = mix(baseAmbientColor.rgb, vOverloadedAmbient, vOverloadedIntensity.x);\n #endif\n#endif\n\n // Reflectivity map\n float microSurface = vReflectivityColor.a;\n vec3 reflectivityColor = vReflectivityColor.rgb;\n\n #ifdef OVERLOADEDVALUES\n reflectivityColor.rgb = mix(reflectivityColor.rgb, vOverloadedReflectivity, vOverloadedIntensity.z);\n #endif\n\n #ifdef REFLECTIVITY\n vec4 reflectivityMapColor = texture2D(reflectivitySampler, vReflectivityUV);\n reflectivityColor = toLinearSpace(reflectivityMapColor.rgb);\n\n #ifdef OVERLOADEDVALUES\n reflectivityColor.rgb = mix(reflectivityColor.rgb, vOverloadedReflectivity, vOverloadedIntensity.z);\n #endif\n\n #ifdef MICROSURFACEFROMREFLECTIVITYMAP\n microSurface = reflectivityMapColor.a;\n #else\n microSurface = computeDefaultMicroSurface(microSurface, reflectivityColor);\n #endif\n #endif\n\n #ifdef OVERLOADEDVALUES\n microSurface = mix(microSurface, vOverloadedMicroSurface.x, vOverloadedMicroSurface.y);\n #endif\n\n // Apply Energy Conservation taking in account the environment level only if the environment is present.\n float reflectance = max(max(reflectivityColor.r, reflectivityColor.g), reflectivityColor.b);\n baseColor.rgb = (1. - reflectance) * baseColor.rgb;\n\n // Compute Specular Fresnel + Reflectance.\n float NdotV = max(0.00000000001, dot(normalW, viewDirectionW));\n\n // Adapt microSurface.\n microSurface = clamp(microSurface, 0., 1.) * 0.98;\n\n // Call rough to not conflict with previous one.\n float rough = clamp(1. - microSurface, 0.000001, 1.0);\n\n // Lighting\n vec3 diffuseBase = vec3(0., 0., 0.);\n\n#ifdef OVERLOADEDSHADOWVALUES\n vec3 shadowedOnlyDiffuseBase = vec3(1., 1., 1.);\n#endif\n\n#ifdef SPECULARTERM\n vec3 specularBase = vec3(0., 0., 0.);\n#endif\n float shadow = 1.;\n\n#ifdef LIGHT0\n#ifndef SPECULARTERM\n vec3 vLightSpecular0 = vec3(0.0);\n#endif\n#ifdef SPOTLIGHT0\n lightingInfo info = computeSpotLighting(viewDirectionW, normalW, vLightData0, vLightDirection0, vLightDiffuse0.rgb, vLightSpecular0, vLightDiffuse0.a, rough, NdotV);\n#endif\n#ifdef HEMILIGHT0\n lightingInfo info = computeHemisphericLighting(viewDirectionW, normalW, vLightData0, vLightDiffuse0.rgb, vLightSpecular0, vLightGround0, rough, NdotV);\n#endif\n#if defined(POINTLIGHT0) || defined(DIRLIGHT0)\n lightingInfo info = computeLighting(viewDirectionW, normalW, vLightData0, vLightDiffuse0.rgb, vLightSpecular0, vLightDiffuse0.a, rough, NdotV);\n#endif\n\n shadow = 1.;\n diffuseBase += info.diffuse * shadow;\n#ifdef OVERLOADEDSHADOWVALUES\n shadowedOnlyDiffuseBase *= shadow;\n#endif\n\n#ifdef SPECULARTERM\n specularBase += info.specular * shadow;\n#endif\n#endif\n\n#ifdef LIGHT1\n#ifndef SPECULARTERM\n vec3 vLightSpecular1 = vec3(0.0);\n#endif\n#ifdef SPOTLIGHT1\n info = computeSpotLighting(viewDirectionW, normalW, vLightData1, vLightDirection1, vLightDiffuse1.rgb, vLightSpecular1, vLightDiffuse1.a, rough, NdotV);\n#endif\n#ifdef HEMILIGHT1\n info = computeHemisphericLighting(viewDirectionW, normalW, vLightData1, vLightDiffuse1.rgb, vLightSpecular1, vLightGround1, rough, NdotV);\n#endif\n#if defined(POINTLIGHT1) || defined(DIRLIGHT1)\n info = computeLighting(viewDirectionW, normalW, vLightData1, vLightDiffuse1.rgb, vLightSpecular1, vLightDiffuse1.a, rough, NdotV);\n#endif\n\n shadow = 1.;\n diffuseBase += info.diffuse * shadow;\n#ifdef OVERLOADEDSHADOWVALUES\n shadowedOnlyDiffuseBase *= shadow;\n#endif\n\n#ifdef SPECULARTERM\n specularBase += info.specular * shadow;\n#endif\n#endif\n\n#ifdef LIGHT2\n#ifndef SPECULARTERM\n vec3 vLightSpecular2 = vec3(0.0);\n#endif\n#ifdef SPOTLIGHT2\n info = computeSpotLighting(viewDirectionW, normalW, vLightData2, vLightDirection2, vLightDiffuse2.rgb, vLightSpecular2, vLightDiffuse2.a, rough, NdotV);\n#endif\n#ifdef HEMILIGHT2\n info = computeHemisphericLighting(viewDirectionW, normalW, vLightData2, vLightDiffuse2.rgb, vLightSpecular2, vLightGround2, rough, NdotV);\n#endif\n#if defined(POINTLIGHT2) || defined(DIRLIGHT2)\n info = computeLighting(viewDirectionW, normalW, vLightData2, vLightDiffuse2.rgb, vLightSpecular2, vLightDiffuse2.a, rough, NdotV);\n#endif\n\n shadow = 1.;\n diffuseBase += info.diffuse * shadow;\n#ifdef OVERLOADEDSHADOWVALUES\n shadowedOnlyDiffuseBase *= shadow;\n#endif\n\n#ifdef SPECULARTERM\n specularBase += info.specular * shadow;\n#endif\n#endif\n\n#ifdef LIGHT3\n#ifndef SPECULARTERM\n vec3 vLightSpecular3 = vec3(0.0);\n#endif\n#ifdef SPOTLIGHT3\n info = computeSpotLighting(viewDirectionW, normalW, vLightData3, vLightDirection3, vLightDiffuse3.rgb, vLightSpecular3, vLightDiffuse3.a, rough, NdotV);\n#endif\n#ifdef HEMILIGHT3\n info = computeHemisphericLighting(viewDirectionW, normalW, vLightData3, vLightDiffuse3.rgb, vLightSpecular3, vLightGround3, rough, NdotV);\n#endif\n#if defined(POINTLIGHT3) || defined(DIRLIGHT3)\n info = computeLighting(viewDirectionW, normalW, vLightData3, vLightDiffuse3.rgb, vLightSpecular3, vLightDiffuse3.a, rough, NdotV);\n#endif\n\n shadow = 1.;\n diffuseBase += info.diffuse * shadow;\n#ifdef OVERLOADEDSHADOWVALUES\n shadowedOnlyDiffuseBase *= shadow;\n#endif\n\n#ifdef SPECULARTERM\n specularBase += info.specular * shadow;\n#endif\n#endif\n\n// Reflection\nvec3 reflectionColor = vReflectionColor.rgb;\nvec3 ambientReflectionColor = vReflectionColor.rgb;\n\nreflectionColor *= vLightingIntensity.z;\nambientReflectionColor *= vLightingIntensity.z;\n\n// Compute reflection reflectivity fresnel\nvec3 reflectivityEnvironmentR0 = reflectivityColor.rgb;\nvec3 reflectivityEnvironmentR90 = vec3(1.0, 1.0, 1.0);\nvec3 reflectivityEnvironmentReflectanceViewer = FresnelSchlickEnvironmentGGX(clamp(NdotV, 0., 1.), reflectivityEnvironmentR0, reflectivityEnvironmentR90, sqrt(microSurface));\nreflectionColor *= reflectivityEnvironmentReflectanceViewer;\n\n#ifdef OVERLOADEDVALUES\n ambientReflectionColor = mix(ambientReflectionColor, vOverloadedReflection, vOverloadedMicroSurface.z);\n reflectionColor = mix(reflectionColor, vOverloadedReflection, vOverloadedMicroSurface.z);\n#endif\n\n#ifdef OPACITY\n vec4 opacityMap = texture2D(opacitySampler, vOpacityUV);\n\n#ifdef OPACITYRGB\n opacityMap.rgb = opacityMap.rgb * vec3(0.3, 0.59, 0.11);\n alpha *= (opacityMap.x + opacityMap.y + opacityMap.z)* vOpacityInfos.y;\n#else\n alpha *= opacityMap.a * vOpacityInfos.y;\n#endif\n\n#endif\n\n#ifdef VERTEXALPHA\n alpha *= vColor.a;\n#endif\n\n // Emissive\n vec3 emissiveColor = vEmissiveColor;\n#ifdef EMISSIVE\n vec3 emissiveColorTex = texture2D(emissiveSampler, vEmissiveUV).rgb;\n emissiveColor = toLinearSpace(emissiveColorTex.rgb) * emissiveColor * vEmissiveInfos.y;\n#endif\n\n#ifdef OVERLOADEDVALUES\n emissiveColor = mix(emissiveColor, vOverloadedEmissive, vOverloadedIntensity.w);\n#endif\n\n // Composition\n#ifdef EMISSIVEASILLUMINATION\n vec3 finalDiffuse = max(diffuseBase * albedoColor + vAmbientColor, 0.0) * baseColor.rgb;\n\n #ifdef OVERLOADEDSHADOWVALUES\n shadowedOnlyDiffuseBase = max(shadowedOnlyDiffuseBase * albedoColor + vAmbientColor, 0.0) * baseColor.rgb;\n #endif\n#else\n #ifdef LINKEMISSIVEWITHALBEDO\n vec3 finalDiffuse = max((diffuseBase + emissiveColor) * albedoColor + vAmbientColor, 0.0) * baseColor.rgb;\n #ifdef OVERLOADEDSHADOWVALUES\n shadowedOnlyDiffuseBase = max((shadowedOnlyDiffuseBase + emissiveColor) * albedoColor + vAmbientColor, 0.0) * baseColor.rgb;\n #endif\n #else\n vec3 finalDiffuse = max(diffuseBase * albedoColor + emissiveColor + vAmbientColor, 0.0) * baseColor.rgb;\n #ifdef OVERLOADEDSHADOWVALUES\n shadowedOnlyDiffuseBase = max(shadowedOnlyDiffuseBase * albedoColor + emissiveColor + vAmbientColor, 0.0) * baseColor.rgb;\n #endif\n #endif\n#endif\n\n#ifdef OVERLOADEDSHADOWVALUES\n finalDiffuse = mix(finalDiffuse, shadowedOnlyDiffuseBase, (1.0 - vOverloadedShadowIntensity.y));\n#endif\n\n// diffuse lighting from environment 0.2 replaces Harmonic...\n// Ambient Reflection already includes the environment intensity.\nfinalDiffuse += baseColor.rgb * ambientReflectionColor * 0.2;\n\n#ifdef SPECULARTERM\n vec3 finalSpecular = specularBase * reflectivityColor * vLightingIntensity.w;\n#else\n vec3 finalSpecular = vec3(0.0);\n#endif\n\n#ifdef SPECULAROVERALPHA\n alpha = clamp(alpha + dot(finalSpecular, vec3(0.3, 0.59, 0.11)), 0., 1.);\n#endif\n\n// Composition\n// Reflection already includes the environment intensity.\n#ifdef EMISSIVEASILLUMINATION\n vec4 color = vec4(finalDiffuse * baseAmbientColor * vLightingIntensity.x + finalSpecular * vLightingIntensity.x + reflectionColor + emissiveColor * vLightingIntensity.y, alpha);\n#else\n vec4 color = vec4(finalDiffuse * baseAmbientColor * vLightingIntensity.x + finalSpecular * vLightingIntensity.x + reflectionColor, alpha);\n#endif\n\n color = max(color, 0.0);\n\n#ifdef CAMERATONEMAP\n color.rgb = toneMaps(color.rgb);\n#endif\n\n color.rgb = toGammaSpace(color.rgb);\n\n#ifdef CAMERACONTRAST\n color = contrasts(color);\n#endif\n\n gl_FragColor = color;\n}";