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PBR GLSL SHADER
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in vec2 v_texcoord; // texture coords | |
in vec3 v_normal; // normal | |
in vec3 v_binormal; // binormal (for TBN basis calc) | |
in vec3 v_pos; // pixel view space position | |
out vec4 color; | |
layout(std140) uniform Transforms | |
{ | |
mat4x4 world_matrix; // object's world position | |
mat4x4 view_matrix; // view (camera) transform | |
mat4x4 proj_matrix; // projection matrix | |
mat3x3 normal_matrix; // normal transformation matrix ( transpose(inverse(W * V)) ) | |
}; | |
layout(std140) uniform Material | |
{ | |
vec4 material; // x - metallic, y - roughness, w - "rim" lighting | |
vec4 albedo; // constant albedo color, used when textures are off | |
}; | |
uniform samplerCube envd; // prefiltered env cubemap | |
uniform sampler2D tex; // base texture (albedo) | |
uniform sampler2D norm; // normal map | |
uniform sampler2D spec; // "factors" texture (G channel used as roughness) | |
uniform sampler2D iblbrdf; // IBL BRDF normalization precalculated tex | |
#define PI 3.1415926 | |
// constant light position, only one light source for testing (treated as point light) | |
const vec4 light_pos = vec4(-2, 3, -2, 1); | |
// handy value clamping to 0 - 1 range | |
float saturate(in float value) | |
{ | |
return clamp(value, 0.0, 1.0); | |
} | |
// phong (lambertian) diffuse term | |
float phong_diffuse() | |
{ | |
return (1.0 / PI); | |
} | |
// compute fresnel specular factor for given base specular and product | |
// product could be NdV or VdH depending on used technique | |
vec3 fresnel_factor(in vec3 f0, in float product) | |
{ | |
return mix(f0, vec3(1.0), pow(1.01 - product, 5.0)); | |
} | |
// following functions are copies of UE4 | |
// for computing cook-torrance specular lighting terms | |
float D_blinn(in float roughness, in float NdH) | |
{ | |
float m = roughness * roughness; | |
float m2 = m * m; | |
float n = 2.0 / m2 - 2.0; | |
return (n + 2.0) / (2.0 * PI) * pow(NdH, n); | |
} | |
float D_beckmann(in float roughness, in float NdH) | |
{ | |
float m = roughness * roughness; | |
float m2 = m * m; | |
float NdH2 = NdH * NdH; | |
return exp((NdH2 - 1.0) / (m2 * NdH2)) / (PI * m2 * NdH2 * NdH2); | |
} | |
float D_GGX(in float roughness, in float NdH) | |
{ | |
float m = roughness * roughness; | |
float m2 = m * m; | |
float d = (NdH * m2 - NdH) * NdH + 1.0; | |
return m2 / (PI * d * d); | |
} | |
float G_schlick(in float roughness, in float NdV, in float NdL) | |
{ | |
float k = roughness * roughness * 0.5; | |
float V = NdV * (1.0 - k) + k; | |
float L = NdL * (1.0 - k) + k; | |
return 0.25 / (V * L); | |
} | |
// simple phong specular calculation with normalization | |
vec3 phong_specular(in vec3 V, in vec3 L, in vec3 N, in vec3 specular, in float roughness) | |
{ | |
vec3 R = reflect(-L, N); | |
float spec = max(0.0, dot(V, R)); | |
float k = 1.999 / (roughness * roughness); | |
return min(1.0, 3.0 * 0.0398 * k) * pow(spec, min(10000.0, k)) * specular; | |
} | |
// simple blinn specular calculation with normalization | |
vec3 blinn_specular(in float NdH, in vec3 specular, in float roughness) | |
{ | |
float k = 1.999 / (roughness * roughness); | |
return min(1.0, 3.0 * 0.0398 * k) * pow(NdH, min(10000.0, k)) * specular; | |
} | |
// cook-torrance specular calculation | |
vec3 cooktorrance_specular(in float NdL, in float NdV, in float NdH, in vec3 specular, in float roughness) | |
{ | |
#ifdef COOK_BLINN | |
float D = D_blinn(roughness, NdH); | |
#endif | |
#ifdef COOK_BECKMANN | |
float D = D_beckmann(roughness, NdH); | |
#endif | |
#ifdef COOK_GGX | |
float D = D_GGX(roughness, NdH); | |
#endif | |
float G = G_schlick(roughness, NdV, NdL); | |
float rim = mix(1.0 - roughness * material.w * 0.9, 1.0, NdV); | |
return (1.0 / rim) * specular * G * D; | |
} | |
void main() { | |
// point light direction to point in view space | |
vec3 local_light_pos = (view_matrix * (/*world_matrix */ light_pos)).xyz; | |
// light attenuation | |
float A = 20.0 / dot(local_light_pos - v_pos, local_light_pos - v_pos); | |
// L, V, H vectors | |
vec3 L = normalize(local_light_pos - v_pos); | |
vec3 V = normalize(-v_pos); | |
vec3 H = normalize(L + V); | |
vec3 nn = normalize(v_normal); | |
vec3 nb = normalize(v_binormal); | |
mat3x3 tbn = mat3x3(nb, cross(nn, nb), nn); | |
vec2 texcoord = v_texcoord; | |
// normal map | |
#if USE_NORMAL_MAP | |
// tbn basis | |
vec3 N = tbn * (texture2D(norm, texcoord).xyz * 2.0 - 1.0); | |
#else | |
vec3 N = nn; | |
#endif | |
// albedo/specular base | |
#if USE_ALBEDO_MAP | |
vec3 base = texture2D(tex, texcoord).xyz; | |
#else | |
vec3 base = albedo.xyz; | |
#endif | |
// roughness | |
#if USE_ROUGHNESS_MAP | |
float roughness = texture2D(spec, texcoord).y * material.y; | |
#else | |
float roughness = material.y; | |
#endif | |
// material params | |
float metallic = material.x; | |
// mix between metal and non-metal material, for non-metal | |
// constant base specular factor of 0.04 grey is used | |
vec3 specular = mix(vec3(0.04), base, metallic); | |
// diffuse IBL term | |
// I know that my IBL cubemap has diffuse pre-integrated value in 10th MIP level | |
// actually level selection should be tweakable or from separate diffuse cubemap | |
mat3x3 tnrm = transpose(normal_matrix); | |
vec3 envdiff = textureCubeLod(envd, tnrm * N, 10).xyz; | |
// specular IBL term | |
// 11 magic number is total MIP levels in cubemap, this is simplest way for picking | |
// MIP level from roughness value (but it's not correct, however it looks fine) | |
vec3 refl = tnrm * reflect(-V, N); | |
vec3 envspec = textureCubeLod( | |
envd, refl, max(roughness * 11.0, textureQueryLod(envd, refl).y) | |
).xyz; | |
// compute material reflectance | |
float NdL = max(0.0, dot(N, L)); | |
float NdV = max(0.001, dot(N, V)); | |
float NdH = max(0.001, dot(N, H)); | |
float HdV = max(0.001, dot(H, V)); | |
float LdV = max(0.001, dot(L, V)); | |
// fresnel term is common for any, except phong | |
// so it will be calcuated inside ifdefs | |
#ifdef PHONG | |
// specular reflectance with PHONG | |
vec3 specfresnel = fresnel_factor(specular, NdV); | |
vec3 specref = phong_specular(V, L, N, specfresnel, roughness); | |
#endif | |
#ifdef BLINN | |
// specular reflectance with BLINN | |
vec3 specfresnel = fresnel_factor(specular, HdV); | |
vec3 specref = blinn_specular(NdH, specfresnel, roughness); | |
#endif | |
#ifdef COOK | |
// specular reflectance with COOK-TORRANCE | |
vec3 specfresnel = fresnel_factor(specular, HdV); | |
vec3 specref = cooktorrance_specular(NdL, NdV, NdH, specfresnel, roughness); | |
#endif | |
specref *= vec3(NdL); | |
// diffuse is common for any model | |
vec3 diffref = (vec3(1.0) - specfresnel) * phong_diffuse() * NdL; | |
// compute lighting | |
vec3 reflected_light = vec3(0); | |
vec3 diffuse_light = vec3(0); // initial value == constant ambient light | |
// point light | |
vec3 light_color = vec3(1.0) * A; | |
reflected_light += specref * light_color; | |
diffuse_light += diffref * light_color; | |
// IBL lighting | |
vec2 brdf = texture2D(iblbrdf, vec2(roughness, 1.0 - NdV)).xy; | |
vec3 iblspec = min(vec3(0.99), fresnel_factor(specular, NdV) * brdf.x + brdf.y); | |
reflected_light += iblspec * envspec; | |
diffuse_light += envdiff * (1.0 / PI); | |
// final result | |
vec3 result = | |
diffuse_light * mix(base, vec3(0.0), metallic) + | |
reflected_light; | |
color = vec4(result, 1); | |
} |
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