import type { Texture } from '@luma.gl/core'; import type { Vector2, Vector3, Vector4, NumberArray2, NumberArray3, NumberArray4 } from '@math.gl/core'; import { ShaderModule } from "../../../lib/shader-module/shader-module.js"; /** Non-uniform block bindings for pbr module */ export type PBRMaterialBindings = { pbr_baseColorSampler?: Texture | null; pbr_normalSampler?: Texture | null; pbr_emissiveSampler?: Texture | null; pbr_metallicRoughnessSampler?: Texture | null; pbr_occlusionSampler?: Texture | null; pbr_diffuseEnvSampler?: Texture | null; pbr_specularEnvSampler?: Texture | null; pbr_BrdfLUT?: Texture | null; }; export type PBRMaterialUniforms = { unlit?: boolean; baseColorMapEnabled?: boolean; baseColorFactor?: Readonly; normalMapEnabled?: boolean; normalScale?: number; emissiveMapEnabled?: boolean; emissiveFactor?: Readonly; metallicRoughnessValues?: Readonly; metallicRoughnessMapEnabled?: boolean; occlusionMapEnabled?: boolean; occlusionStrength?: number; alphaCutoffEnabled?: boolean; alphaCutoff?: number; IBLenabled?: boolean; scaleIBLAmbient?: Readonly; scaleDiffBaseMR?: Readonly; scaleFGDSpec?: Readonly; }; export type PBRMaterialProps = PBRMaterialBindings & PBRMaterialUniforms; /** * An implementation of PBR (Physically-Based Rendering). * Physically Based Shading of a microfacet surface defined by a glTF material. */ export declare const pbrMaterial: { readonly props: PBRMaterialProps; readonly uniforms: PBRMaterialUniforms; readonly name: "pbrMaterial"; readonly dependencies: [{ readonly props: import("../lights/lighting").LightingProps; readonly uniforms: import("../lights/lighting").LightingUniforms; readonly name: "lighting"; readonly defines: { readonly MAX_LIGHTS: 3; }; readonly uniformTypes: { readonly enabled: "i32"; readonly lightType: "i32"; readonly directionalLightCount: "i32"; readonly pointLightCount: "i32"; readonly ambientLightColor: "vec3"; readonly lightColor0: "vec3"; readonly lightPosition0: "vec3"; readonly lightDirection0: "vec3"; readonly lightAttenuation0: "vec3"; readonly lightColor1: "vec3"; readonly lightPosition1: "vec3"; readonly lightDirection1: "vec3"; readonly lightAttenuation1: "vec3"; readonly lightColor2: "vec3"; readonly lightPosition2: "vec3"; readonly lightDirection2: "vec3"; readonly lightAttenuation2: "vec3"; }; readonly defaultUniforms: { readonly enabled: 1; readonly lightType: import("../lights/lighting").LIGHT_TYPE.POINT; readonly directionalLightCount: 0; readonly pointLightCount: 0; readonly ambientLightColor: readonly [0.1, 0.1, 0.1]; readonly lightColor0: readonly [1, 1, 1]; readonly lightPosition0: readonly [1, 1, 2]; readonly lightDirection0: readonly [1, 1, 1]; readonly lightAttenuation0: readonly [1, 0, 0]; readonly lightColor1: readonly [1, 1, 1]; readonly lightPosition1: readonly [1, 1, 2]; readonly lightDirection1: readonly [1, 1, 1]; readonly lightAttenuation1: readonly [1, 0, 0]; readonly lightColor2: readonly [1, 1, 1]; readonly lightPosition2: readonly [1, 1, 2]; readonly lightDirection2: readonly [1, 1, 1]; readonly lightAttenuation2: readonly [1, 0, 0]; }; readonly source: "// #if (defined(SHADER_TYPE_FRAGMENT) && defined(LIGHTING_FRAGMENT)) || (defined(SHADER_TYPE_VERTEX) && defined(LIGHTING_VERTEX))\nstruct AmbientLight {\n color: vec3,\n};\n\nstruct PointLight {\n color: vec3,\n position: vec3,\n attenuation: vec3, // 2nd order x:Constant-y:Linear-z:Exponential\n};\n\nstruct DirectionalLight {\n color: vec3,\n direction: vec3,\n};\n\nstruct lightingUniforms {\n enabled: i32,\n pointLightCount: i32,\n directionalLightCount: i32,\n\n ambientColor: vec3,\n\n // TODO - support multiple lights by uncommenting arrays below\n lightType: i32,\n lightColor: vec3,\n lightDirection: vec3,\n lightPosition: vec3,\n lightAttenuation: vec3,\n\n // AmbientLight ambientLight;\n // PointLight pointLight[MAX_LIGHTS];\n // DirectionalLight directionalLight[MAX_LIGHTS];\n};\n\n// Binding 0:1 is reserved for lighting (Note: could go into separate bind group as it is stable across draw calls)\n@binding(1) @group(0) var lighting : lightingUniforms;\n\nfn lighting_getPointLight(index: i32) -> PointLight {\n return PointLight(lighting.lightColor, lighting.lightPosition, lighting.lightAttenuation);\n}\n\nfn lighting_getDirectionalLight(index: i32) -> DirectionalLight {\n return DirectionalLight(lighting.lightColor, lighting.lightDirection);\n} \n\nfn getPointLightAttenuation(pointLight: PointLight, distance: f32) -> f32 {\n return pointLight.attenuation.x\n + pointLight.attenuation.y * distance\n + pointLight.attenuation.z * distance * distance;\n}\n"; readonly vs: "precision highp int;\n\n// #if (defined(SHADER_TYPE_FRAGMENT) && defined(LIGHTING_FRAGMENT)) || (defined(SHADER_TYPE_VERTEX) && defined(LIGHTING_VERTEX))\nstruct AmbientLight {\n vec3 color;\n};\n\nstruct PointLight {\n vec3 color;\n vec3 position;\n vec3 attenuation; // 2nd order x:Constant-y:Linear-z:Exponential\n};\n\nstruct DirectionalLight {\n vec3 color;\n vec3 direction;\n};\n\nuniform lightingUniforms {\n int enabled;\n int lightType;\n\n int directionalLightCount;\n int pointLightCount;\n\n vec3 ambientColor;\n\n vec3 lightColor0;\n vec3 lightPosition0;\n vec3 lightDirection0;\n vec3 lightAttenuation0;\n\n vec3 lightColor1;\n vec3 lightPosition1;\n vec3 lightDirection1;\n vec3 lightAttenuation1;\n\n vec3 lightColor2;\n vec3 lightPosition2;\n vec3 lightDirection2;\n vec3 lightAttenuation2;\n} lighting;\n\nPointLight lighting_getPointLight(int index) {\n switch (index) {\n case 0:\n return PointLight(lighting.lightColor0, lighting.lightPosition0, lighting.lightAttenuation0);\n case 1:\n return PointLight(lighting.lightColor1, lighting.lightPosition1, lighting.lightAttenuation1);\n case 2:\n default: \n return PointLight(lighting.lightColor2, lighting.lightPosition2, lighting.lightAttenuation2);\n }\n}\n\nDirectionalLight lighting_getDirectionalLight(int index) {\n switch (index) {\n case 0:\n return DirectionalLight(lighting.lightColor0, lighting.lightDirection0);\n case 1:\n return DirectionalLight(lighting.lightColor1, lighting.lightDirection1);\n case 2:\n default: \n return DirectionalLight(lighting.lightColor2, lighting.lightDirection2);\n }\n} \n\nfloat getPointLightAttenuation(PointLight pointLight, float distance) {\n return pointLight.attenuation.x\n + pointLight.attenuation.y * distance\n + pointLight.attenuation.z * distance * distance;\n}\n\n// #endif\n"; readonly fs: "precision highp int;\n\n// #if (defined(SHADER_TYPE_FRAGMENT) && defined(LIGHTING_FRAGMENT)) || (defined(SHADER_TYPE_VERTEX) && defined(LIGHTING_VERTEX))\nstruct AmbientLight {\n vec3 color;\n};\n\nstruct PointLight {\n vec3 color;\n vec3 position;\n vec3 attenuation; // 2nd order x:Constant-y:Linear-z:Exponential\n};\n\nstruct DirectionalLight {\n vec3 color;\n vec3 direction;\n};\n\nuniform lightingUniforms {\n int enabled;\n int lightType;\n\n int directionalLightCount;\n int pointLightCount;\n\n vec3 ambientColor;\n\n vec3 lightColor0;\n vec3 lightPosition0;\n vec3 lightDirection0;\n vec3 lightAttenuation0;\n\n vec3 lightColor1;\n vec3 lightPosition1;\n vec3 lightDirection1;\n vec3 lightAttenuation1;\n\n vec3 lightColor2;\n vec3 lightPosition2;\n vec3 lightDirection2;\n vec3 lightAttenuation2;\n} lighting;\n\nPointLight lighting_getPointLight(int index) {\n switch (index) {\n case 0:\n return PointLight(lighting.lightColor0, lighting.lightPosition0, lighting.lightAttenuation0);\n case 1:\n return PointLight(lighting.lightColor1, lighting.lightPosition1, lighting.lightAttenuation1);\n case 2:\n default: \n return PointLight(lighting.lightColor2, lighting.lightPosition2, lighting.lightAttenuation2);\n }\n}\n\nDirectionalLight lighting_getDirectionalLight(int index) {\n switch (index) {\n case 0:\n return DirectionalLight(lighting.lightColor0, lighting.lightDirection0);\n case 1:\n return DirectionalLight(lighting.lightColor1, lighting.lightDirection1);\n case 2:\n default: \n return DirectionalLight(lighting.lightColor2, lighting.lightDirection2);\n }\n} \n\nfloat getPointLightAttenuation(PointLight pointLight, float distance) {\n return pointLight.attenuation.x\n + pointLight.attenuation.y * distance\n + pointLight.attenuation.z * distance * distance;\n}\n\n// #endif\n"; readonly getUniforms: (props?: import("../lights/lighting").LightingProps, prevUniforms?: Partial) => import("../lights/lighting").LightingUniforms; }, ShaderModule]; readonly vs: "out vec3 pbr_vPosition;\nout vec2 pbr_vUV;\n\n#ifdef HAS_NORMALS\n# ifdef HAS_TANGENTS\nout mat3 pbr_vTBN;\n# else\nout vec3 pbr_vNormal;\n# endif\n#endif\n\nvoid pbr_setPositionNormalTangentUV(vec4 position, vec4 normal, vec4 tangent, vec2 uv)\n{\n vec4 pos = pbrProjection.modelMatrix * position;\n pbr_vPosition = vec3(pos.xyz) / pos.w;\n\n#ifdef HAS_NORMALS\n#ifdef HAS_TANGENTS\n vec3 normalW = normalize(vec3(pbrProjection.normalMatrix * vec4(normal.xyz, 0.0)));\n vec3 tangentW = normalize(vec3(pbrProjection.modelMatrix * vec4(tangent.xyz, 0.0)));\n vec3 bitangentW = cross(normalW, tangentW) * tangent.w;\n pbr_vTBN = mat3(tangentW, bitangentW, normalW);\n#else // HAS_TANGENTS != 1\n pbr_vNormal = normalize(vec3(pbrProjection.modelMatrix * vec4(normal.xyz, 0.0)));\n#endif\n#endif\n\n#ifdef HAS_UV\n pbr_vUV = uv;\n#else\n pbr_vUV = vec2(0.,0.);\n#endif\n}\n"; readonly fs: "precision highp float;\n\nuniform pbrMaterialUniforms {\n // Material is unlit\n bool unlit;\n\n // Base color map\n bool baseColorMapEnabled;\n vec4 baseColorFactor;\n\n bool normalMapEnabled; \n float normalScale; // #ifdef HAS_NORMALMAP\n\n bool emissiveMapEnabled;\n vec3 emissiveFactor; // #ifdef HAS_EMISSIVEMAP\n\n vec2 metallicRoughnessValues;\n bool metallicRoughnessMapEnabled;\n\n bool occlusionMapEnabled;\n float occlusionStrength; // #ifdef HAS_OCCLUSIONMAP\n \n bool alphaCutoffEnabled;\n float alphaCutoff; // #ifdef ALPHA_CUTOFF\n \n // IBL\n bool IBLenabled;\n vec2 scaleIBLAmbient; // #ifdef USE_IBL\n \n // debugging flags used for shader output of intermediate PBR variables\n // #ifdef PBR_DEBUG\n vec4 scaleDiffBaseMR;\n vec4 scaleFGDSpec;\n // #endif\n} pbrMaterial;\n\n// Samplers\n#ifdef HAS_BASECOLORMAP\nuniform sampler2D pbr_baseColorSampler;\n#endif\n#ifdef HAS_NORMALMAP\nuniform sampler2D pbr_normalSampler;\n#endif\n#ifdef HAS_EMISSIVEMAP\nuniform sampler2D pbr_emissiveSampler;\n#endif\n#ifdef HAS_METALROUGHNESSMAP\nuniform sampler2D pbr_metallicRoughnessSampler;\n#endif\n#ifdef HAS_OCCLUSIONMAP\nuniform sampler2D pbr_occlusionSampler;\n#endif\n#ifdef USE_IBL\nuniform samplerCube pbr_diffuseEnvSampler;\nuniform samplerCube pbr_specularEnvSampler;\nuniform sampler2D pbr_brdfLUT;\n#endif\n\n// Inputs from vertex shader\n\nin vec3 pbr_vPosition;\nin vec2 pbr_vUV;\n\n#ifdef HAS_NORMALS\n#ifdef HAS_TANGENTS\nin mat3 pbr_vTBN;\n#else\nin vec3 pbr_vNormal;\n#endif\n#endif\n\n// Encapsulate the various inputs used by the various functions in the shading equation\n// We store values in this struct to simplify the integration of alternative implementations\n// of the shading terms, outlined in the Readme.MD Appendix.\nstruct PBRInfo {\n float NdotL; // cos angle between normal and light direction\n float NdotV; // cos angle between normal and view direction\n float NdotH; // cos angle between normal and half vector\n float LdotH; // cos angle between light direction and half vector\n float VdotH; // cos angle between view direction and half vector\n float perceptualRoughness; // roughness value, as authored by the model creator (input to shader)\n float metalness; // metallic value at the surface\n vec3 reflectance0; // full reflectance color (normal incidence angle)\n vec3 reflectance90; // reflectance color at grazing angle\n float alphaRoughness; // roughness mapped to a more linear change in the roughness (proposed by [2])\n vec3 diffuseColor; // color contribution from diffuse lighting\n vec3 specularColor; // color contribution from specular lighting\n vec3 n; // normal at surface point\n vec3 v; // vector from surface point to camera\n};\n\nconst float M_PI = 3.141592653589793;\nconst float c_MinRoughness = 0.04;\n\nvec4 SRGBtoLINEAR(vec4 srgbIn)\n{\n#ifdef MANUAL_SRGB\n#ifdef SRGB_FAST_APPROXIMATION\n vec3 linOut = pow(srgbIn.xyz,vec3(2.2));\n#else // SRGB_FAST_APPROXIMATION\n vec3 bLess = step(vec3(0.04045),srgbIn.xyz);\n vec3 linOut = mix( srgbIn.xyz/vec3(12.92), pow((srgbIn.xyz+vec3(0.055))/vec3(1.055),vec3(2.4)), bLess );\n#endif //SRGB_FAST_APPROXIMATION\n return vec4(linOut,srgbIn.w);;\n#else //MANUAL_SRGB\n return srgbIn;\n#endif //MANUAL_SRGB\n}\n\n// Find the normal for this fragment, pulling either from a predefined normal map\n// or from the interpolated mesh normal and tangent attributes.\nvec3 getNormal()\n{\n // Retrieve the tangent space matrix\n#ifndef HAS_TANGENTS\n vec3 pos_dx = dFdx(pbr_vPosition);\n vec3 pos_dy = dFdy(pbr_vPosition);\n vec3 tex_dx = dFdx(vec3(pbr_vUV, 0.0));\n vec3 tex_dy = dFdy(vec3(pbr_vUV, 0.0));\n vec3 t = (tex_dy.t * pos_dx - tex_dx.t * pos_dy) / (tex_dx.s * tex_dy.t - tex_dy.s * tex_dx.t);\n\n#ifdef HAS_NORMALS\n vec3 ng = normalize(pbr_vNormal);\n#else\n vec3 ng = cross(pos_dx, pos_dy);\n#endif\n\n t = normalize(t - ng * dot(ng, t));\n vec3 b = normalize(cross(ng, t));\n mat3 tbn = mat3(t, b, ng);\n#else // HAS_TANGENTS\n mat3 tbn = pbr_vTBN;\n#endif\n\n#ifdef HAS_NORMALMAP\n vec3 n = texture(pbr_normalSampler, pbr_vUV).rgb;\n n = normalize(tbn * ((2.0 * n - 1.0) * vec3(pbrMaterial.normalScale, pbrMaterial.normalScale, 1.0)));\n#else\n // The tbn matrix is linearly interpolated, so we need to re-normalize\n vec3 n = normalize(tbn[2].xyz);\n#endif\n\n return n;\n}\n\n// Calculation of the lighting contribution from an optional Image Based Light source.\n// Precomputed Environment Maps are required uniform inputs and are computed as outlined in [1].\n// See our README.md on Environment Maps [3] for additional discussion.\n#ifdef USE_IBL\nvec3 getIBLContribution(PBRInfo pbrInfo, vec3 n, vec3 reflection)\n{\n float mipCount = 9.0; // resolution of 512x512\n float lod = (pbrInfo.perceptualRoughness * mipCount);\n // retrieve a scale and bias to F0. See [1], Figure 3\n vec3 brdf = SRGBtoLINEAR(texture(pbr_brdfLUT,\n vec2(pbrInfo.NdotV, 1.0 - pbrInfo.perceptualRoughness))).rgb;\n vec3 diffuseLight = SRGBtoLINEAR(texture(pbr_diffuseEnvSampler, n)).rgb;\n\n#ifdef USE_TEX_LOD\n vec3 specularLight = SRGBtoLINEAR(texture(pbr_specularEnvSampler, reflection, lod)).rgb;\n#else\n vec3 specularLight = SRGBtoLINEAR(texture(pbr_specularEnvSampler, reflection)).rgb;\n#endif\n\n vec3 diffuse = diffuseLight * pbrInfo.diffuseColor;\n vec3 specular = specularLight * (pbrInfo.specularColor * brdf.x + brdf.y);\n\n // For presentation, this allows us to disable IBL terms\n diffuse *= pbrMaterial.scaleIBLAmbient.x;\n specular *= pbrMaterial.scaleIBLAmbient.y;\n\n return diffuse + specular;\n}\n#endif\n\n// Basic Lambertian diffuse\n// Implementation from Lambert's Photometria https://archive.org/details/lambertsphotome00lambgoog\n// See also [1], Equation 1\nvec3 diffuse(PBRInfo pbrInfo)\n{\n return pbrInfo.diffuseColor / M_PI;\n}\n\n// The following equation models the Fresnel reflectance term of the spec equation (aka F())\n// Implementation of fresnel from [4], Equation 15\nvec3 specularReflection(PBRInfo pbrInfo)\n{\n return pbrInfo.reflectance0 +\n (pbrInfo.reflectance90 - pbrInfo.reflectance0) *\n pow(clamp(1.0 - pbrInfo.VdotH, 0.0, 1.0), 5.0);\n}\n\n// This calculates the specular geometric attenuation (aka G()),\n// where rougher material will reflect less light back to the viewer.\n// This implementation is based on [1] Equation 4, and we adopt their modifications to\n// alphaRoughness as input as originally proposed in [2].\nfloat geometricOcclusion(PBRInfo pbrInfo)\n{\n float NdotL = pbrInfo.NdotL;\n float NdotV = pbrInfo.NdotV;\n float r = pbrInfo.alphaRoughness;\n\n float attenuationL = 2.0 * NdotL / (NdotL + sqrt(r * r + (1.0 - r * r) * (NdotL * NdotL)));\n float attenuationV = 2.0 * NdotV / (NdotV + sqrt(r * r + (1.0 - r * r) * (NdotV * NdotV)));\n return attenuationL * attenuationV;\n}\n\n// The following equation(s) model the distribution of microfacet normals across\n// the area being drawn (aka D())\n// Implementation from \"Average Irregularity Representation of a Roughened Surface\n// for Ray Reflection\" by T. S. Trowbridge, and K. P. Reitz\n// Follows the distribution function recommended in the SIGGRAPH 2013 course notes\n// from EPIC Games [1], Equation 3.\nfloat microfacetDistribution(PBRInfo pbrInfo)\n{\n float roughnessSq = pbrInfo.alphaRoughness * pbrInfo.alphaRoughness;\n float f = (pbrInfo.NdotH * roughnessSq - pbrInfo.NdotH) * pbrInfo.NdotH + 1.0;\n return roughnessSq / (M_PI * f * f);\n}\n\nvoid PBRInfo_setAmbientLight(inout PBRInfo pbrInfo) {\n pbrInfo.NdotL = 1.0;\n pbrInfo.NdotH = 0.0;\n pbrInfo.LdotH = 0.0;\n pbrInfo.VdotH = 1.0;\n}\n\nvoid PBRInfo_setDirectionalLight(inout PBRInfo pbrInfo, vec3 lightDirection) {\n vec3 n = pbrInfo.n;\n vec3 v = pbrInfo.v;\n vec3 l = normalize(lightDirection); // Vector from surface point to light\n vec3 h = normalize(l+v); // Half vector between both l and v\n\n pbrInfo.NdotL = clamp(dot(n, l), 0.001, 1.0);\n pbrInfo.NdotH = clamp(dot(n, h), 0.0, 1.0);\n pbrInfo.LdotH = clamp(dot(l, h), 0.0, 1.0);\n pbrInfo.VdotH = clamp(dot(v, h), 0.0, 1.0);\n}\n\nvoid PBRInfo_setPointLight(inout PBRInfo pbrInfo, PointLight pointLight) {\n vec3 light_direction = normalize(pointLight.position - pbr_vPosition);\n PBRInfo_setDirectionalLight(pbrInfo, light_direction);\n}\n\nvec3 calculateFinalColor(PBRInfo pbrInfo, vec3 lightColor) {\n // Calculate the shading terms for the microfacet specular shading model\n vec3 F = specularReflection(pbrInfo);\n float G = geometricOcclusion(pbrInfo);\n float D = microfacetDistribution(pbrInfo);\n\n // Calculation of analytical lighting contribution\n vec3 diffuseContrib = (1.0 - F) * diffuse(pbrInfo);\n vec3 specContrib = F * G * D / (4.0 * pbrInfo.NdotL * pbrInfo.NdotV);\n // Obtain final intensity as reflectance (BRDF) scaled by the energy of the light (cosine law)\n return pbrInfo.NdotL * lightColor * (diffuseContrib + specContrib);\n}\n\nvec4 pbr_filterColor(vec4 colorUnused)\n{\n // The albedo may be defined from a base texture or a flat color\n#ifdef HAS_BASECOLORMAP\n vec4 baseColor = SRGBtoLINEAR(texture(pbr_baseColorSampler, pbr_vUV)) * pbrMaterial.baseColorFactor;\n#else\n vec4 baseColor = pbrMaterial.baseColorFactor;\n#endif\n\n#ifdef ALPHA_CUTOFF\n if (baseColor.a < pbrMaterial.alphaCutoff) {\n discard;\n }\n#endif\n\n vec3 color = vec3(0, 0, 0);\n\n if(pbrMaterial.unlit){\n color.rgb = baseColor.rgb;\n }\n else{\n // Metallic and Roughness material properties are packed together\n // In glTF, these factors can be specified by fixed scalar values\n // or from a metallic-roughness map\n float perceptualRoughness = pbrMaterial.metallicRoughnessValues.y;\n float metallic = pbrMaterial.metallicRoughnessValues.x;\n#ifdef HAS_METALROUGHNESSMAP\n // Roughness is stored in the 'g' channel, metallic is stored in the 'b' channel.\n // This layout intentionally reserves the 'r' channel for (optional) occlusion map data\n vec4 mrSample = texture(pbr_metallicRoughnessSampler, pbr_vUV);\n perceptualRoughness = mrSample.g * perceptualRoughness;\n metallic = mrSample.b * metallic;\n#endif\n perceptualRoughness = clamp(perceptualRoughness, c_MinRoughness, 1.0);\n metallic = clamp(metallic, 0.0, 1.0);\n // Roughness is authored as perceptual roughness; as is convention,\n // convert to material roughness by squaring the perceptual roughness [2].\n float alphaRoughness = perceptualRoughness * perceptualRoughness;\n\n vec3 f0 = vec3(0.04);\n vec3 diffuseColor = baseColor.rgb * (vec3(1.0) - f0);\n diffuseColor *= 1.0 - metallic;\n vec3 specularColor = mix(f0, baseColor.rgb, metallic);\n\n // Compute reflectance.\n float reflectance = max(max(specularColor.r, specularColor.g), specularColor.b);\n\n // For typical incident reflectance range (between 4% to 100%) set the grazing\n // reflectance to 100% for typical fresnel effect.\n // For very low reflectance range on highly diffuse objects (below 4%),\n // incrementally reduce grazing reflecance to 0%.\n float reflectance90 = clamp(reflectance * 25.0, 0.0, 1.0);\n vec3 specularEnvironmentR0 = specularColor.rgb;\n vec3 specularEnvironmentR90 = vec3(1.0, 1.0, 1.0) * reflectance90;\n\n vec3 n = getNormal(); // normal at surface point\n vec3 v = normalize(pbrProjection.camera - pbr_vPosition); // Vector from surface point to camera\n\n float NdotV = clamp(abs(dot(n, v)), 0.001, 1.0);\n vec3 reflection = -normalize(reflect(v, n));\n\n PBRInfo pbrInfo = PBRInfo(\n 0.0, // NdotL\n NdotV,\n 0.0, // NdotH\n 0.0, // LdotH\n 0.0, // VdotH\n perceptualRoughness,\n metallic,\n specularEnvironmentR0,\n specularEnvironmentR90,\n alphaRoughness,\n diffuseColor,\n specularColor,\n n,\n v\n );\n\n\n#ifdef USE_LIGHTS\n // Apply ambient light\n PBRInfo_setAmbientLight(pbrInfo);\n color += calculateFinalColor(pbrInfo, lighting.ambientColor);\n\n // Apply directional light\n for(int i = 0; i < lighting.directionalLightCount; i++) {\n if (i < lighting.directionalLightCount) {\n PBRInfo_setDirectionalLight(pbrInfo, lighting_getDirectionalLight(i).direction);\n color += calculateFinalColor(pbrInfo, lighting_getDirectionalLight(i).color);\n }\n }\n\n // Apply point light\n for(int i = 0; i < lighting.pointLightCount; i++) {\n if (i < lighting.pointLightCount) {\n PBRInfo_setPointLight(pbrInfo, lighting_getPointLight(i));\n float attenuation = getPointLightAttenuation(lighting_getPointLight(i), distance(lighting_getPointLight(i).position, pbr_vPosition));\n color += calculateFinalColor(pbrInfo, lighting_getPointLight(i).color / attenuation);\n }\n }\n#endif\n\n // Calculate lighting contribution from image based lighting source (IBL)\n#ifdef USE_IBL\n if (pbrMaterial.IBLenabled) {\n color += getIBLContribution(pbrInfo, n, reflection);\n }\n#endif\n\n // Apply optional PBR terms for additional (optional) shading\n#ifdef HAS_OCCLUSIONMAP\n if (pbrMaterial.occlusionMapEnabled) {\n float ao = texture(pbr_occlusionSampler, pbr_vUV).r;\n color = mix(color, color * ao, pbrMaterial.occlusionStrength);\n }\n#endif\n\n#ifdef HAS_EMISSIVEMAP\n if (pbrMaterial.emissiveMapEnabled) {\n vec3 emissive = SRGBtoLINEAR(texture(pbr_emissiveSampler, pbr_vUV)).rgb * pbrMaterial.emissiveFactor;\n color += emissive;\n }\n#endif\n\n // This section uses mix to override final color for reference app visualization\n // of various parameters in the lighting equation.\n#ifdef PBR_DEBUG\n // TODO: Figure out how to debug multiple lights\n\n // color = mix(color, F, pbr_scaleFGDSpec.x);\n // color = mix(color, vec3(G), pbr_scaleFGDSpec.y);\n // color = mix(color, vec3(D), pbr_scaleFGDSpec.z);\n // color = mix(color, specContrib, pbr_scaleFGDSpec.w);\n\n // color = mix(color, diffuseContrib, pbr_scaleDiffBaseMR.x);\n color = mix(color, baseColor.rgb, pbrMaterial.scaleDiffBaseMR.y);\n color = mix(color, vec3(metallic), pbrMaterial.scaleDiffBaseMR.z);\n color = mix(color, vec3(perceptualRoughness), pbrMaterial.scaleDiffBaseMR.w);\n#endif\n\n }\n\n return vec4(pow(color,vec3(1.0/2.2)), baseColor.a);\n}\n"; readonly defines: { readonly LIGHTING_FRAGMENT: 1; }; readonly getUniforms: (props: Partial) => Partial; readonly uniformTypes: { readonly unlit: "i32"; readonly baseColorMapEnabled: "i32"; readonly baseColorFactor: "vec4"; readonly normalMapEnabled: "i32"; readonly normalScale: "f32"; readonly emissiveMapEnabled: "i32"; readonly emissiveFactor: "vec3"; readonly metallicRoughnessValues: "vec2"; readonly metallicRoughnessMapEnabled: "i32"; readonly occlusionMapEnabled: "i32"; readonly occlusionStrength: "f32"; readonly alphaCutoffEnabled: "i32"; readonly alphaCutoff: "f32"; readonly IBLenabled: "i32"; readonly scaleIBLAmbient: "vec2"; readonly scaleDiffBaseMR: "vec4"; readonly scaleFGDSpec: "vec4"; }; }; //# sourceMappingURL=pbr-material.d.ts.map