demotool/shaders/pbr.glsl

255 lines
7.2 KiB
GLSL

struct T_PBRMaterialOld
{
vec3 cAlbedo, cSpecular;
float roughness , anisotropy , subsurface , metallic;
};
struct T_PBRPrecomputedOld
{
float nDotC;
float ffndc; // Fresnel from n.c
vec3 tangent, bitangent;
float specAlpha , viewSpecular;
float aAspectX , aAspectY; // Anisotropy
};
float PBR_FresnelFromOld( in float dotProduct ) {
float d = clamp( 1.0 - dotProduct , 0 , 1 ) , d2 = d * d;
return d2 * d2 * d;
}
float PBR_GetSpecularOld( in float cosine , in float alpha )
{
float cs = cosine * cosine;
float as = alpha * alpha;
return clamp( 1. / ( cosine + sqrt( cs + as - cs * as ) ) , 0 , 1 );
}
// Precompute some of the material's properties. This is independant of the
// light source.
T_PBRPrecomputedOld PBR_PrecomputeOld(
in T_PBRMaterialOld material ,
in vec3 rayDir ,
in vec3 normal )
{
T_PBRPrecomputedOld rv;
rv.nDotC = dot( normal , rayDir );
rv.ffndc = PBR_FresnelFromOld( rv.nDotC );
rv.tangent = cross( vec3( 0. , 1. , 0. ) , normal );
if ( length( rv.tangent ) == 0.0 ) {
rv.tangent = cross( vec3( 1. , 0. , 0. ) , normal );
}
rv.tangent = normalize( rv.tangent );
rv.bitangent = normalize( cross( normal , rv.tangent ) );
rv.specAlpha = pow( material.roughness * .5 + .5 , 2. );
rv.viewSpecular = PBR_GetSpecularOld( rv.nDotC , rv.specAlpha );
const float sRoughness = material.roughness * material.roughness;
const float aspect = sqrt( 1.0 - material.anisotropy * .9 );
rv.aAspectX = max( .001, sRoughness / aspect );
rv.aAspectY = max( .001, sRoughness * aspect );
return rv;
}
// Actually compute a light source's contribution
vec3 PBR_ShadeOld(
in T_PBRMaterialOld material ,
in T_PBRPrecomputedOld precomputed ,
in vec3 rayDir ,
in vec3 normal ,
in vec3 lightDir )
{
const float nDotL = dot( normal , lightDir );
if ( nDotL <= 0. ) {
return vec3( 0. );
}
// FIXME: should be in common part
float lSpecular = dot( material.cSpecular , vec3( .3 , .6 , .1 ) );
vec3 cSpecular = lSpecular > 0 ? ( material.cSpecular / lSpecular ) : vec3( 1 );
const vec3 halfVec = normalize( lightDir + rayDir );
const float nDotH = dot( normal , halfVec );
const float lDotH = dot( lightDir , halfVec );
const float ffndl = PBR_FresnelFromOld( nDotL );
float grazingDiffuse = lDotH * lDotH * material.roughness;
float dSubsurface = mix( 1.0 , grazingDiffuse , ffndl )
* mix( 1.0 , grazingDiffuse , precomputed.ffndc );
dSubsurface = 1.25 * ( dSubsurface * ( 1.0 / ( nDotL + precomputed.nDotC ) - .5 ) + .5 );
grazingDiffuse = .5 + 2. * grazingDiffuse;
const float dFresnel = mix( 1.0 , grazingDiffuse , ffndl )
* mix( 1.0 , grazingDiffuse , precomputed.ffndc );
float specular = PBR_GetSpecularOld( nDotL , precomputed.specAlpha )
* precomputed.viewSpecular;
specular = mix( specular , 1.0 , PBR_FresnelFromOld( lDotH ) );
const vec3 d = vec3(
dot( halfVec , precomputed.tangent ) / precomputed.aAspectX ,
dot( halfVec , precomputed.bitangent ) / precomputed.aAspectY ,
nDotH );
const float ds = dot( d , d );
const float anisotropic = precomputed.aAspectX * precomputed.aAspectY
* ds * ds * 3.14159265;
return nDotL * ( material.cAlbedo
* mix( dFresnel , dSubsurface , material.subsurface )
* pow( 1.0 - material.metallic , 3 )
+ specular * cSpecular / anisotropic
);
}
// YAY let's do it again!
const float PI = 3.14159265;
float PBR_SchlickFresnel( in float u )
{
const float m = clamp( 1 - u , 0 , 1 ) ,
m2 = m * m;
return m2 * m2 * m;
}
float PBR_GTR1( in float nDotH , in float a )
{
if (a >= 1) {
return 1/PI;
}
float a2 = a * a ,
t = 1 + ( a2 - 1 ) * nDotH * nDotH;
return ( a2 - 1 ) / ( PI * log( a2 ) * t );
}
float PBR_GTR2( in float nDotH , in float a )
{
float a2 = a * a ,
t = 1 + ( a2 - 1 ) * nDotH * nDotH;
return a2 / ( PI * t * t );
}
float PBR_GTR2Aniso( in float nDotH ,
in float hDotX ,
in float hDotY ,
in float ax ,
in float ay )
{
float x = hDotX / ax , y = hDotY / ay ,
p = x * x + y * y + nDotH * nDotH;
return 1 / ( PI * ax * ay * p * p );
}
float PBR_SmithGGX( in float nDotV , in float alpha )
{
float a = alpha * alpha , b = nDotV * nDotV;
return 1 / ( nDotV + sqrt( a + b - a * b ) );
}
float PBR_SmithGGXAniso( in float nDotV ,
in float vDotX ,
in float vDotY ,
in float ax ,
in float ay )
{
float x = vDotX * ax , y = vDotY * ay;
return 1 / ( nDotV + sqrt( x * x + y * y + nDotV * nDotV ) );
}
vec3 NormalizeColor( in vec3 color )
{
float l = dot( color , vec3( .3 , .6 , .1 ) );
return l > 0 ? ( color / l ) : vec3( 1 );
}
struct T_PBRMaterial
{
vec3 cAlbedo;
float roughness;
float metallic;
float subsurface;
float anisotropy;
float specular; // Specular strengh for non-metals
float specularTint; // Albedo color% in specular tint (non-metals)
};
vec3 PBR_Shade( in T_PBRMaterial material ,
in vec3 camDir ,
in vec3 normal ,
in vec3 lightDir )
{
float nDotL = dot( normal , lightDir ) ,
nDotV = dot( normal , camDir );
if ( nDotL < 0 ) return vec3( 1 , 0 , 0 );
if ( nDotV < 0 ) return vec3( 0 , -nDotV , 0 );
// if ( nDotL < 0 || nDotV < 0 ) {
// return vec3( 0 );
// }
vec3 tangent = cross( vec3( 0 , 1 , 0 ) , normal );
if ( length( tangent ) == 0 ) {
tangent = cross( vec3( 1 , 0 , 0 ) , normal );
}
tangent = normalize( tangent );
vec3 bitangent = normalize( cross( normal , tangent ) );
vec3 halfVec = normalize( lightDir + camDir ) ,
tint = NormalizeColor( material.cAlbedo ) ,
cSpecular = mix( material.specular * .08 * mix(
vec3( 1 ) , tint , material.specularTint ) ,
material.cAlbedo , material.metallic );
//vec3 Csheen = mix(vec3(1), Ctint, sheenTint);
float nDotH = dot( normal , halfVec ) ,
lDotH = dot( lightDir , halfVec ) ,
// Diffuse fresnel - go from 1 at normal incidence to .5 at grazing
// and mix in diffuse retro-reflection based on roughness
FL = PBR_SchlickFresnel( nDotL ) ,
FV = PBR_SchlickFresnel( nDotV ) ,
Fd90 = 0.5 + 2 * lDotH * lDotH * material.roughness ,
Fd = mix( 1 , Fd90 , FL ) * mix( 1 , Fd90 , FV ) ,
// Based on Hanrahan-Krueger brdf approximation of isotropic bssrdf
// 1.25 scale is used to (roughly) preserve albedo
// Fss90 used to "flatten" retroreflection based on roughness
Fss90 = lDotH * lDotH * material.roughness ,
Fss = mix( 1 , Fss90 , FL ) * mix( 1 , Fss90 , FV ) ,
ss = 1.25 * ( Fss * ( 1 / ( nDotL + nDotV ) - .5 ) + .5 ) ,
// Specular
aspect = sqrt( 1 - material.anisotropy * .9 ) ,
rsqr = material.roughness * material.roughness ,
ax = max( .001, rsqr / aspect ) ,
ay = max( .001, rsqr * aspect ) ,
Ds = PBR_GTR2Aniso( nDotH , dot( halfVec , tangent ) ,
dot( halfVec , bitangent ) , ax , ay ) ,
FH = PBR_SchlickFresnel( lDotH ) ,
Gs = PBR_SmithGGXAniso( nDotL , dot( lightDir , tangent ) ,
dot( lightDir , bitangent ) , ax , ay )
* PBR_SmithGGXAniso( nDotV , dot( camDir , tangent ) ,
dot( camDir , bitangent ) , ax , ay );
// sheen
//vec3 Fsheen = FH * sheen * Csheen;
// clearcoat (ior = 1.5 -> F0 = 0.04)
/*
float Dr = PBR_GTR1( nDotH , mix( .1 , .001 , clearcoatGloss));
float Fr = mix(.04, 1.0, FH);
float Gr = smithG_GGX(NdotL, .25) * smithG_GGX(NdotV, .25);
*/
vec3 Fs = mix( cSpecular , vec3(1) , FH );
return nDotL * ( ( ( 1 / PI )
* mix( Fd , ss , material.subsurface )
* material.cAlbedo /* + Fsheen */)
* pow( 1 - material.metallic , 3 )
+ clamp( Gs , 0 , 1 ) * Fs * Ds );
//+ .25*clearcoat*Gr*Fr*Dr;
}