730 lines
24 KiB
GLSL
730 lines
24 KiB
GLSL
#version 400
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uniform mat4 model, view;
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uniform sampler2D u_texture2d;
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uniform vec3 u_coefficients_sh[9];
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uniform bool u_textured = true;
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uniform bool u_lit = false;
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uniform bool u_matcaps = false;
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uniform vec4 u_diffuse = vec4(1.0,1.0,1.0,1.0);
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// lightmapping
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uniform sampler2D u_lightmap;
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uniform bool u_texlit;
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uniform bool u_texmod = true;
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uniform float u_litboost = 1.0;
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in vec3 v_position;
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in vec3 v_position_ws;
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#ifdef RIM
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uniform mat4 M; // RIM
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uniform vec3 u_rimcolor = vec3(0.2,0.2,0.2);
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uniform vec3 u_rimrange = vec3(0.11,0.98,0.5);
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uniform vec3 u_rimpivot = vec3(0,0,0);
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uniform bool u_rimambient = true;
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#endif
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in vec3 v_normal, v_normal_ws;
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in vec2 v_texcoord, v_texcoord2;
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in vec4 v_color;
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in vec3 v_tangent;
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in vec3 v_binormal;
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in vec3 v_to_camera;
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out vec4 fragcolor;
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{{include-shadowmap}}
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in vec4 vpeye;
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in vec4 vneye;
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in vec4 sc;
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vec4 shadowing() {
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return shadowmap(vpeye, vneye, v_texcoord, sc);
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}
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uniform vec3 u_cam_pos;
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uniform vec3 u_cam_dir;
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uniform int u_num_lights;
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struct light_t {
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int type;
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vec3 diffuse;
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vec3 specular;
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vec3 ambient;
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vec3 pos;
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vec3 dir;
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float power;
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float innerCone;
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float outerCone;
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// falloff
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float constant;
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float linear;
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float quadratic;
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};
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#define MAX_LIGHTS 16
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const int LIGHT_DIRECTIONAL = 0;
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const int LIGHT_POINT = 1;
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const int LIGHT_SPOT = 2;
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uniform light_t u_lights[MAX_LIGHTS];
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#ifdef SHADING_PHONG
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vec3 shading_phong(light_t l) {
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vec3 lightDir;
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float attenuation = 1.0;
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if (l.type == LIGHT_DIRECTIONAL) {
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lightDir = normalize(-l.dir);
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} else if (l.type == LIGHT_POINT || l.type == LIGHT_SPOT) {
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vec3 toLight = l.pos - v_position_ws;
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lightDir = normalize(toLight);
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float distance = length(toLight);
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attenuation = 1.0 / (l.constant + l.linear * distance + l.quadratic * (distance * distance));
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if (l.type == LIGHT_SPOT) {
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float angle = dot(l.dir, -lightDir);
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if (angle > l.outerCone) {
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float intensity = (angle-l.outerCone)/(l.innerCone-l.outerCone);
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attenuation *= clamp(intensity, 0.0, 1.0);
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} else {
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attenuation = 0.0;
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}
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}
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}
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// fast-rejection for faraway vertices
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if (attenuation <= 0.01) {
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return vec3(0,0,0);
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}
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vec3 n = normalize(v_normal_ws);
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float diffuse = max(dot(n, lightDir), 0.0);
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vec3 halfVec = normalize(lightDir + u_cam_dir);
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float specular = pow(max(dot(n, halfVec), 0.0), l.power);
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return (attenuation*l.ambient + diffuse*attenuation*l.diffuse + specular*attenuation*l.specular);
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}
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#endif
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#ifdef SHADING_PBR
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uniform vec2 resolution = vec2(640.0,480.0); // debug options below use this (USE_MAP_DEBUGGING, USE_AMBIENT_DEBUGGING)
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#define USE_BRUTEFORCE_IRRADIANCE false // Samples irradiance from tex_skysphere when enabled.
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#define USE_WRAPAROUND_SPECULAR true // Makes silhouettes more reflective to avoid black pixels.
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#define USE_SPECULAR_AO_ATTENUATION true // Dampens IBL specular ambient with AO if enabled.
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#define USE_NORMAL_VARIATION_TO_ROUGHNESS true // Increases roughness if normal map has variation and was minified.
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#define USE_MAP_DEBUGGING false // Shows all ColorMaps as horizontal bars
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#define USE_AMBIENT_DEBUGGING false // Splits the screen in two and shows image-based specular (left), full shading (middle), diffuse shading (right).
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#define BOOST_LIGHTING 2.00f // Multiplies analytic light's color with this constant because otherwise they look really pathetic.
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#define BOOST_SPECULAR 1.50f
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#define BOOST_NOISE 2.50f
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struct ColorMap
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{
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bool has_tex;
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vec4 color;
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};
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uniform ColorMap map_albedo; uniform sampler2D map_albedo_tex;
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uniform ColorMap map_diffuse; uniform sampler2D map_diffuse_tex;
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uniform ColorMap map_specular; uniform sampler2D map_specular_tex; // not used
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uniform ColorMap map_normals; uniform sampler2D map_normals_tex;
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uniform ColorMap map_roughness; uniform sampler2D map_roughness_tex;
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uniform ColorMap map_metallic; uniform sampler2D map_metallic_tex;
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uniform ColorMap map_ao; uniform sampler2D map_ao_tex;
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uniform ColorMap map_ambient; uniform sampler2D map_ambient_tex;
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uniform ColorMap map_emissive; uniform sampler2D map_emissive_tex;
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#define sample_colormap(ColorMap_, uv_) \
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(ColorMap_.has_tex ? texture( ColorMap_##_tex, uv_ ) : ColorMap_.color)
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uniform float skysphere_rotation=-90;
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uniform float skysphere_mip_count;
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uniform float exposure=1;
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uniform uint frame_count;
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uniform float specular_shininess;
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uniform sampler2D tex_skysphere;
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uniform sampler2D tex_skyenv;
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uniform sampler2D tex_brdf_lut;
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uniform bool has_tex_skysphere;
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uniform bool has_tex_skyenv;
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const float PI = 3.1415926536;
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// MurMurHash 3 finalizer. Implementation is in public domain.
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uint hash( uint h )
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{
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h ^= h >> 16;
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h *= 0x85ebca6bU;
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h ^= h >> 13;
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h *= 0xc2b2ae35U;
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h ^= h >> 16;
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return h;
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}
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// Random function using the idea of StackOverflow user "Spatial" https://stackoverflow.com/a/17479300
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// Creates random 23 bits and puts them into the fraction bits of an 32-bit float.
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float random( uvec3 h )
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{
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uint m = hash(h.x ^ hash( h.y ) ^ hash( h.z ));
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return uintBitsToFloat( ( m & 0x007FFFFFu ) | 0x3f800000u ) - 1.;
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}
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float random( vec3 v )
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{
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return random(floatBitsToUint( v ));
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}
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vec3 fresnel_schlick( vec3 H, vec3 V, vec3 F0 )
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{
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float cosTheta = clamp( dot( H, V ), 0., 1. );
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return F0 + ( vec3( 1.0 ) - F0 ) * pow( 1. - cosTheta, 5.0 );
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}
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// A Fresnel term that dampens rough specular reflections.
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// https://seblagarde.wordpress.com/2011/08/17/hello-world/
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vec3 fresnel_schlick_roughness( vec3 H, vec3 V, vec3 F0, float roughness )
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{
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float cosTheta = clamp( dot( H, V ), 0., 1. );
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return F0 + ( max( vec3( 1.0 - roughness ), F0 ) - F0 ) * pow( 1. - cosTheta, 5.0 );
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}
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float distribution_ggx( vec3 N, vec3 H, float roughness )
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{
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float a = roughness * roughness;
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float a2 = a * a;
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float NdotH = max( 0., dot( N, H ) );
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float factor = NdotH * NdotH * ( a2 - 1. ) + 1.;
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return a2 / ( PI * factor * factor );
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}
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float geometry_schlick_ggx( vec3 N, vec3 V, float k )
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{
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float NdotV = max( 0., dot( N, V ) );
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return NdotV / (NdotV * ( 1. - k ) + k );
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}
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float geometry_smith( vec3 N, vec3 V, vec3 L, float roughness )
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{
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#if 1 // original
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float r = roughness + 1.;
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float k = (r * r) / 8.;
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#elif 0 // vries
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float a = roughness;
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float k = (a * a) / 2.0;
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#elif 0 // vries improved?
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float a = roughness * roughness;
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float k = a / 2.0;
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#endif
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return geometry_schlick_ggx( N, V, k ) * geometry_schlick_ggx( N, L, k );
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}
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vec2 sphere_to_polar( vec3 normal )
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{
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normal = normalize( normal );
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return vec2( ( atan( normal.z, normal.x ) + skysphere_rotation ) / PI / 2.0 + 0.5, acos( normal.y ) / PI );
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}
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// Our vertically GL_CLAMPed textures seem to blend towards black when sampling the half-pixel edge.
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// Not sure if it has a border, or this if is a driver bug, but can repro on multiple nvidia cards.
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// Knowing the texture height we can limit sampling to the centers of the top and bottom pixel rows.
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vec2 sphere_to_polar_clamp_y( vec3 normal, float texture_height )
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{
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normal = normalize( normal );
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return vec2( ( atan( normal.z, normal.x ) + skysphere_rotation ) / PI / 2.0 + 0.5, clamp(acos( normal.y ) / PI, 0.5 / texture_height, 1.0 - 0.5 / texture_height) );
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}
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vec3 sample_sky( vec3 normal )
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{
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vec2 polar = sphere_to_polar( normal );
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return texture( tex_skysphere, polar ).rgb * exposure;
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}
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// Takes samples around the hemisphere, converts them to radiances via weighting and
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// returns a normalized sum.
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vec3 sample_irradiance_slow( vec3 normal, vec3 vertex_tangent )
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{
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float delta = 0.10;
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vec3 up = abs( normal.y ) < 0.999 ? vec3( 0., 1., 0. ) : vec3( 0., 0., 1. );
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vec3 tangent_x = normalize( cross( up, normal ) );
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vec3 tangent_y = cross( normal, tangent_x );
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int numIrradianceSamples = 0;
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vec3 irradiance = vec3(0.);
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for ( float phi = 0.; phi < 2. * PI ; phi += delta )
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{
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for ( float theta = 0.; theta < 0.5 * PI; theta += delta )
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{
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vec3 tangent_space = vec3(
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sin( theta ) * cos( phi ),
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sin( theta ) * sin( phi ),
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cos( theta ) );
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vec3 world_space = tangent_space.x * tangent_x + tangent_space.y + tangent_y + tangent_space.z * normal;
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vec3 color = sample_sky( world_space );
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irradiance += color * cos( theta ) * sin( theta );
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numIrradianceSamples++;
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}
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}
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irradiance = PI * irradiance / float( numIrradianceSamples );
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return irradiance;
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}
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vec3 sample_irradiance_fast( vec3 normal, vec3 vertex_tangent )
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{
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// Sample the irradiance map if it exists, otherwise fall back to blurred reflection map.
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if ( has_tex_skyenv )
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{
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vec2 polar = sphere_to_polar_clamp_y( normal, 180.0 );
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return textureLod( tex_skyenv, polar, 0.0 ).rgb * exposure;
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}
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else
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{
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vec2 polar = sphere_to_polar( normal );
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return textureLod( tex_skysphere, polar, 0.80 * skysphere_mip_count ).rgb * exposure;
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}
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}
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vec3 specular_ibl( vec3 V, vec3 N, float roughness, vec3 fresnel )
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{
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// What we'd like to do here is take a LOT of skybox samples around the reflection
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// vector R according to the BRDF lobe.
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//
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// Unfortunately it's not possible in real time so we use the following UE4 style approximations:
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// 1. Integrate incoming light and BRDF separately ("split sum approximation")
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// 2. Assume V = R = N so that we can just blur the skybox and sample that.
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// 3. Bake the BRDF integral into a lookup texture so that it can be computed in constant time.
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//
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// Here we also simplify approximation #2 by using bilinear mipmaps with a magic formula instead
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// of properly convolving it with a GGX lobe.
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//
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// For details, see Brian Karis, "Real Shading in Unreal Engine 4", 2013.
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vec3 R = 2. * dot( V, N ) * N - V;
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vec2 polar = sphere_to_polar( R );
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// Map roughness from range [0, 1] into a mip LOD [0, skysphere_mip_count].
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// The magic numbers were chosen empirically.
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float mip = 0.9 * skysphere_mip_count * pow(roughness, 0.25 * BOOST_SPECULAR);
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vec3 prefiltered = textureLod( tex_skysphere, polar, mip ).rgb * exposure;
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float NdotV = dot( N, V );
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// dot( N, V ) seems to produce negative values so we can try to stretch it a bit behind the silhouette
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// to avoid black pixels.
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if (USE_WRAPAROUND_SPECULAR)
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{
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NdotV = NdotV * 0.9 + 0.1;
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}
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NdotV = min(0.99, max(0.01, NdotV));
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// A precomputed lookup table contains a scale and a bias term for specular intensity (called "fresnel" here).
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// See equation (8) in Karis' course notes mentioned above.
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vec2 envBRDF = texture( tex_brdf_lut, vec2(NdotV, 1.0-roughness) ).xy; // (NdotV,1-roughtness) for green top-left (NdotV,roughness) for green bottom-left
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vec3 specular = prefiltered * (fresnel * envBRDF.x + vec3(envBRDF.y));
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return specular;
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}
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#endif
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vec3 lighting() {
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vec3 lit = vec3(0,0,0);
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#ifndef SHADING_NONE
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for (int i=0; i<u_num_lights; i++) {
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#ifdef SHADING_PHONG
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lit += shading_phong(u_lights[i]);
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#endif
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#ifdef SHADING_PBR
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#endif
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}
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#endif
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return lit;
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}
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vec3 sh_lighting(vec3 n) {
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vec3 SHLightResult[9];
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SHLightResult[0] = 0.282095f * u_coefficients_sh[0];
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SHLightResult[1] = -0.488603f * u_coefficients_sh[1] * n.y;
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SHLightResult[2] = 0.488603f * u_coefficients_sh[2] * n.z;
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SHLightResult[3] = -0.488603f * u_coefficients_sh[3] * n.x;
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SHLightResult[4] = 1.092548f * u_coefficients_sh[4] * n.x * n.y;
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SHLightResult[5] = -1.092548f * u_coefficients_sh[5] * n.y * n.z;
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SHLightResult[6] = 0.315392f * u_coefficients_sh[6] * (3.0f * n.z * n.z - 1.0f);
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SHLightResult[7] = -1.092548f * u_coefficients_sh[7] * n.x * n.z;
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SHLightResult[8] = 0.546274f * u_coefficients_sh[8] * (n.x * n.x - n.y * n.y);
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vec3 result = vec3(0.0);
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for (int i = 0; i < 9; ++i)
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result += SHLightResult[i];
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return result;
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}
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#ifdef LIGHTMAP_BAKING
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void main() {
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vec3 n = normalize(v_normal_ws);
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vec4 diffuse;
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if(u_textured) {
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diffuse = texture(u_texture2d, v_texcoord);
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} else {
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diffuse = u_diffuse; // * v_color;
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}
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if (u_texlit) {
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vec4 litsample = texture(u_lightmap, v_texcoord);
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diffuse *= litsample;
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}
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fragcolor = vec4(diffuse.rgb*u_litboost, 1.0);
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}
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#endif
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#ifdef SHADING_PHONG
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void main() {
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vec3 n = normalize(v_normal_ws);
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vec4 lit = vec4(1.0, 1.0, 1.0, 1.0);
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// SH lighting
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if (!u_texlit) {
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vec3 result = sh_lighting(n);
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if( (result.x*result.x+result.y*result.y+result.z*result.z) > 0.0 ) lit = vec4(result, 1.0);
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}
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// analytical lights
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lit += vec4(lighting(), 0.0);
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// base
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vec4 diffuse;
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if(u_matcaps) {
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vec2 muv = vec2(view * vec4(v_normal_ws, 0))*0.5+vec2(0.5,0.5); // normal (model space) to view space
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diffuse = texture(u_texture2d, vec2(muv.x, 1.0-muv.y));
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} else if(u_textured) {
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diffuse = texture(u_texture2d, v_texcoord);
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} else {
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diffuse = u_diffuse; // * v_color;
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}
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if (u_texlit) {
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vec4 litsample = texture(u_lightmap, v_texcoord);
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if (u_texmod) {
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diffuse *= litsample;
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} else {
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diffuse += litsample;
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}
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diffuse.rgb += sh_lighting(n);
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}
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// lighting mix
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fragcolor = diffuse * lit * shadowing();
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// rimlight
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#ifdef RIM
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{
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vec3 n = normalize(mat3(M) * v_normal); // convert normal to view space
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vec3 p = (M * vec4(v_position,1.0)).xyz; // convert position to view space
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vec3 v = vec3(0,-1,0);
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if (!u_rimambient) {
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v = normalize(u_rimpivot-p);
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}
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float rim = 1.0 - max(dot(v,n), 0.0);
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vec3 col = u_rimcolor*(pow(smoothstep(1.0-u_rimrange.x,u_rimrange.y,rim), u_rimrange.z));
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fragcolor += vec4(col, 1.0);}
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#endif
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fragcolor.rgb = pow( fragcolor.rgb, vec3(1. / 2.2) );
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}
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#endif
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#ifdef SHADING_PBR
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void main(void)
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{
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vec3 baseColor = vec3( 0.5, 0.5, 0.5 );
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float roughness = 1.0;
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float metallic = 0.0;
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float ao = 1.0;
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float alpha = 1.0;
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vec4 baseColor_alpha;
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if ( map_albedo.has_tex )
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baseColor_alpha = sample_colormap( map_albedo, v_texcoord );
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else
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baseColor_alpha = sample_colormap( map_diffuse, v_texcoord );
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baseColor = baseColor_alpha.xyz;
|
|
alpha = baseColor_alpha.w;
|
|
|
|
if( map_metallic.has_tex && map_roughness.has_tex ) {
|
|
metallic = sample_colormap( map_metallic, v_texcoord ).x;
|
|
roughness = sample_colormap( map_roughness, v_texcoord ).x;
|
|
}
|
|
else if( map_roughness.has_tex ) {
|
|
//< @r-lyeh, metalness B, roughness G, (@todo: self-shadowing occlusion R; for now, any of R/B are metallic)
|
|
metallic = sample_colormap( map_roughness, v_texcoord ).b + sample_colormap( map_roughness, v_texcoord ).r;
|
|
roughness = sample_colormap( map_roughness, v_texcoord ).g;
|
|
}
|
|
|
|
if ( map_ao.has_tex )
|
|
ao = sample_colormap( map_ao, v_texcoord ).x;
|
|
else if ( map_ambient.has_tex )
|
|
ao = sample_colormap( map_ambient, v_texcoord ).x;
|
|
|
|
vec3 emissive = sample_colormap( map_emissive, v_texcoord ).rgb;
|
|
|
|
vec3 normalmap = texture( map_normals_tex, v_texcoord ).xyz * vec3(2.0) - vec3(1.0);
|
|
float normalmap_mip = textureQueryLod( map_normals_tex, v_texcoord ).x;
|
|
float normalmap_length = length(normalmap);
|
|
normalmap /= normalmap_length;
|
|
|
|
vec3 normal = v_normal_ws;
|
|
|
|
if ( map_normals.has_tex )
|
|
{
|
|
// Mikkelsen's tangent space normal map decoding. See http://mikktspace.com/ for rationale.
|
|
vec3 bi = cross( v_normal_ws, v_tangent );
|
|
vec3 nmap = normalmap.xyz;
|
|
normal = nmap.x * v_tangent + nmap.y * bi + nmap.z * v_normal_ws;
|
|
}
|
|
|
|
normal = normalize( normal );
|
|
|
|
if( USE_MAP_DEBUGGING && !USE_AMBIENT_DEBUGGING )
|
|
{
|
|
vec3 c = vec3(1., 0., 0.);
|
|
float x = gl_FragCoord.x / resolution.x;
|
|
float y = gl_FragCoord.y / resolution.y;
|
|
if ( y < (7.0/7.0) ) c = vec3(.5) + .5*v_normal_ws;
|
|
if ( y < (6.0/7.0) ) c = vec3(.5) + .5*normalmap;
|
|
if ( y < (5.0/7.0) ) c = vec3(ao);
|
|
if ( y < (4.0/7.0) ) c = vec3(emissive);
|
|
if ( y < (3.0/7.0) ) c = vec3(metallic);
|
|
if ( y < (2.0/7.0) ) c = vec3(roughness);
|
|
if ( y < (1.0/7.0) ) c = baseColor;
|
|
fragcolor = vec4(c, 1.);
|
|
return;
|
|
}
|
|
|
|
if (USE_NORMAL_VARIATION_TO_ROUGHNESS)
|
|
{
|
|
// Try to reduce specular aliasing by increasing roughness when minified normal maps have high variation.
|
|
float variation = 1. - pow( normalmap_length, 8. );
|
|
float minification = clamp( normalmap_mip - 2., 0., 1. );
|
|
roughness = mix( roughness, 1.0, variation * minification );
|
|
}
|
|
|
|
fragcolor = baseColor_alpha;
|
|
|
|
|
|
vec3 N = normal;
|
|
vec3 V = normalize( v_to_camera );
|
|
|
|
vec3 Lo = vec3(0.);
|
|
vec3 F0 = vec3(0.04);
|
|
F0 = mix( F0, baseColor, metallic );
|
|
|
|
bool use_ibl = has_tex_skysphere;
|
|
// use_ibl = false;
|
|
|
|
// Add contributions from analytic lights.
|
|
|
|
{
|
|
for ( int i = 0; i < u_num_lights; i++ )
|
|
{
|
|
light_t l = u_lights[i];
|
|
vec3 lightDir;
|
|
float attenuation = 1.0;
|
|
|
|
if (l.type == LIGHT_DIRECTIONAL) {
|
|
lightDir = normalize(-l.dir);
|
|
} else if (l.type == LIGHT_POINT || l.type == LIGHT_SPOT) {
|
|
vec3 toLight = l.pos - v_position_ws;
|
|
lightDir = normalize(toLight);
|
|
float distance = length(toLight);
|
|
attenuation = 1.0 / (l.constant + l.linear * distance + l.quadratic * (distance * distance));
|
|
|
|
if (l.type == LIGHT_SPOT) {
|
|
float angle = dot(l.dir, -lightDir);
|
|
if (angle > l.outerCone) {
|
|
float intensity = (angle-l.outerCone)/(l.innerCone-l.outerCone);
|
|
attenuation *= clamp(intensity, 0.0, 1.0);
|
|
} else {
|
|
attenuation = 0.0;
|
|
}
|
|
}
|
|
}
|
|
|
|
// fast-rejection for faraway vertices
|
|
if (attenuation <= 0.01) {
|
|
continue;
|
|
}
|
|
|
|
vec3 radiance = l.diffuse * BOOST_LIGHTING;
|
|
|
|
vec3 L = normalize( lightDir );
|
|
vec3 H = normalize( V + L );
|
|
|
|
vec3 F = fresnel_schlick( H, V, F0 );
|
|
vec3 kS = F;
|
|
vec3 kD = vec3(1.0) - kS;
|
|
kD *= 1.0 - metallic;
|
|
|
|
// Premultiplied alpha applied to the diffuse component only
|
|
kD *= alpha;
|
|
|
|
float D = distribution_ggx( N, H, roughness );
|
|
float G = geometry_smith( N, V, L, roughness );
|
|
|
|
vec3 num = D * F * G;
|
|
float denom = 4. * max( 0., dot( N, V ) ) * max( 0., dot( N, L ) );
|
|
|
|
vec3 specular = kS * (num / max( 0.001, denom ));
|
|
|
|
float NdotL = max( 0., dot( N, L ) );
|
|
|
|
Lo += ( kD * ( baseColor / PI ) + specular ) * radiance * NdotL * attenuation;
|
|
}
|
|
}
|
|
|
|
vec3 ambient = sample_colormap( map_ambient, v_texcoord ).xyz;
|
|
vec3 diffuse_ambient;
|
|
vec3 specular_ambient;
|
|
|
|
if ( use_ibl )
|
|
{
|
|
// Image based lighting.
|
|
// Based on https://learnopengl.com/PBR/IBL/Diffuse-irradiance
|
|
|
|
vec3 irradiance = vec3(0.);
|
|
|
|
if ( USE_BRUTEFORCE_IRRADIANCE )
|
|
{
|
|
irradiance = sample_irradiance_slow( normal, v_tangent );
|
|
}
|
|
else
|
|
{
|
|
irradiance = sample_irradiance_fast( normal, v_tangent );
|
|
}
|
|
|
|
// Compute the Fresnel term for a perfect mirror reflection with L = R.
|
|
// In this case the halfway vector H = N.
|
|
//
|
|
// We use a modified Fresnel function that dampens specular reflections of very
|
|
// rough surfaces to avoid too bright pixels at grazing angles.
|
|
vec3 F = fresnel_schlick_roughness( N, V, F0, roughness );
|
|
vec3 kS = F;
|
|
|
|
// Subtract the amount of reflected light (specular) to get the energy left for
|
|
// absorbed (diffuse) light.
|
|
vec3 kD = vec3(1.) - kS;
|
|
|
|
// Metallic surfaces have only a specular reflection.
|
|
kD *= 1.0 - metallic;
|
|
|
|
// Premultiplied alpha applied to the diffuse component only
|
|
kD *= alpha;
|
|
|
|
// Modulate the incoming lighting with the diffuse color: some wavelengths get absorbed.
|
|
diffuse_ambient = irradiance * baseColor;
|
|
|
|
// Ambient light also has a specular part.
|
|
specular_ambient = specular_ibl( V, normal, roughness, F );
|
|
|
|
// Ambient occlusion tells us the fraction of sky light that reaches this point.
|
|
if (USE_SPECULAR_AO_ATTENUATION)
|
|
{
|
|
ambient = ao * (kD * diffuse_ambient + specular_ambient);
|
|
}
|
|
else
|
|
{
|
|
// We don't attenuate specular_ambient ambient here with AO which might cause flickering in dark cavities.
|
|
ambient = ao * (kD * diffuse_ambient) + specular_ambient;
|
|
}
|
|
}
|
|
|
|
vec3 color = (ambient + Lo) + emissive;
|
|
|
|
if ( USE_AMBIENT_DEBUGGING )
|
|
{
|
|
float y = gl_FragCoord.y / resolution.y;
|
|
if( USE_MAP_DEBUGGING && y > 0.5 )
|
|
{
|
|
if ( (y-0.5) < (7.0/7.0/2.0) ) color = vec3(.5) + .5*v_normal_ws;
|
|
if ( (y-0.5) < (6.0/7.0/2.0) ) color = vec3(.5) + .5*normalmap;
|
|
if ( (y-0.5) < (5.0/7.0/2.0) ) color = vec3(ao);
|
|
if ( (y-0.5) < (4.0/7.0/2.0) ) color = vec3(emissive);
|
|
if ( (y-0.5) < (3.0/7.0/2.0) ) color = vec3(metallic);
|
|
if ( (y-0.5) < (2.0/7.0/2.0) ) color = vec3(roughness);
|
|
if ( (y-0.5) < (1.0/7.0/2.0) ) color = baseColor;
|
|
} else {
|
|
float x = gl_FragCoord.x / resolution.x;
|
|
if ( x < 0.33 )
|
|
color = specular_ambient;
|
|
else if( x > 0.66 )
|
|
color = diffuse_ambient;
|
|
}
|
|
}
|
|
|
|
// dither with noise.
|
|
// float dither = random( uvec3( floatBitsToUint( gl_FragCoord.xy ), frame_count ) );
|
|
// color += BOOST_NOISE * vec3( (-1.0/256.) + (2./256.) * dither );
|
|
|
|
#if 0 // original
|
|
// basic tonemap and gamma correction
|
|
color = color / ( vec3(1.) + color );
|
|
color = pow( color, vec3(1. / 2.2) );
|
|
#elif 0
|
|
// filmic tonemapper
|
|
vec3 linearColor = color;
|
|
vec3 x = max(vec3(0.0), linearColor - 0.004);
|
|
color = (x * (6.2 * x + 0.5)) / (x * (6.2 * x + 1.7) + 0.06);
|
|
// gamma correction
|
|
// color = pow( color, vec3(1. / 2.2) );
|
|
#elif 0
|
|
// aces film (CC0, src: https://knarkowicz.wordpress.com/2016/01/06/aces-filmic-tone-mapping-curve/)
|
|
vec3 x = color;
|
|
float a = 2.51f;
|
|
float b = 0.03f;
|
|
float c = 2.43f;
|
|
float d = 0.59f;
|
|
float e = 0.14f;
|
|
color = clamp((x*(a*x+b))/(x*(c*x+d)+e), 0.0, 1.0);
|
|
// gamma correction
|
|
color = pow( color, vec3(1. / 2.2) );
|
|
#endif
|
|
color = pow( color, vec3(1. / 2.2) );
|
|
|
|
// Technically this alpha may be too transparent, if there is a lot of reflected light we wouldn't
|
|
// see the background, maybe we can approximate it well enough by adding a fresnel term
|
|
fragcolor = vec4( color * shadowing().xyz, alpha );
|
|
|
|
// rimlight
|
|
#ifdef RIM
|
|
{
|
|
vec3 n = normalize(mat3(M) * v_normal_ws); // convert normal to view space
|
|
vec3 p = (M * vec4(v_position,1.0)).xyz; // convert position to view space
|
|
vec3 v = vec3(0,-1,0);
|
|
if (!u_rimambient) {
|
|
v = normalize(u_rimpivot-p);
|
|
}
|
|
float rim = 1.0 - max(dot(v,n), 0.0);
|
|
vec3 col = u_rimcolor*(pow(smoothstep(1.0-u_rimrange.x,u_rimrange.y,rim), u_rimrange.z));
|
|
fragcolor += vec4(col, 1.0);}
|
|
#endif
|
|
}
|
|
|
|
#endif
|