Common.MatDefs.Light.Deferred.frag Maven / Gradle / Ivy
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#define ATTENUATION
//#define HQ_ATTENUATION
varying vec2 texCoord;
uniform sampler2D m_DiffuseData;
uniform sampler2D m_SpecularData;
uniform sampler2D m_NormalData;
uniform sampler2D m_DepthData;
uniform vec3 m_FrustumCorner;
uniform vec2 m_FrustumNearFar;
uniform vec4 g_LightColor;
uniform vec4 g_LightPosition;
uniform vec3 g_CameraPosition;
uniform mat4 m_ViewProjectionMatrixInverse;
#ifdef COLORRAMP
uniform sampler2D m_ColorRamp;
#endif
float lightComputeDiffuse(in vec3 norm, in vec3 lightdir, in vec3 viewdir){
#ifdef MINNAERT
float NdotL = max(0.0, dot(norm, lightdir));
float NdotV = max(0.0, dot(norm, viewdir));
return NdotL * pow(max(NdotL * NdotV, 0.1), -1.0) * 0.5;
#else
return max(0.0, dot(norm, lightdir));
#endif
}
float lightComputeSpecular(in vec3 norm, in vec3 viewdir, in vec3 lightdir, in float shiny){
//#ifdef LOW_QUALITY
// Blinn-Phong
// Note: preferably, H should be computed in the vertex shader
vec3 H = (viewdir + lightdir) * vec3(0.5);
return pow(max(dot(H, norm), 0.0), shiny);
/*
#elif defined(WARDISO)
// Isotropic Ward
vec3 halfVec = normalize(viewdir + lightdir);
float NdotH = max(0.001, tangDot(norm, halfVec));
float NdotV = max(0.001, tangDot(norm, viewdir));
float NdotL = max(0.001, tangDot(norm, lightdir));
float a = tan(acos(NdotH));
float p = max(shiny/128.0, 0.001);
return NdotL * (1.0 / (4.0*3.14159265*p*p)) * (exp(-(a*a)/(p*p)) / (sqrt(NdotV * NdotL)));
#else
// Standard Phong
vec3 R = reflect(-lightdir, norm);
return pow(max(tangDot(R, viewdir), 0.0), shiny);
#endif
*/
}
vec2 computeLighting(in vec3 wvPos, in vec3 wvNorm, in vec3 wvViewDir, in vec4 wvLightDir, in float shiny){
float diffuseFactor = lightComputeDiffuse(wvNorm, wvLightDir.xyz, wvViewDir);
float specularFactor = lightComputeSpecular(wvNorm, wvViewDir, wvLightDir.xyz, shiny);
return vec2(diffuseFactor, specularFactor) * vec2(wvLightDir.w);
}
vec3 decodeNormal(in vec4 enc){
vec4 nn = enc * vec4(2.0,2.0,0.0,0.0) + vec4(-1.0,-1.0,1.0,-1.0);
float l = dot(nn.xyz, -nn.xyw);
nn.z = l;
nn.xy *= sqrt(l);
return nn.xyz * vec3(2.0) + vec3(0.0,0.0,-1.0);
}
vec3 getPosition(in vec2 newTexCoord){
//Reconstruction from depth
float depth = texture2D(m_DepthData, newTexCoord).r;
//if (depth == 1.0)
// return vec3(0.0, 0.0, 2.0);
//depth = (2.0 * m_FrustumNearFar.x)
/// (m_FrustumNearFar.y + m_FrustumNearFar.x - depth * (m_FrustumNearFar.y-m_FrustumNearFar.x));
//one frustum corner method
//float x = mix(-m_FrustumCorner.x, m_FrustumCorner.x, newTexCoord.x);
//float y = mix(-m_FrustumCorner.y, m_FrustumCorner.y, newTexCoord.y);
//return depth * vec3(x, y, m_FrustumCorner.z);
vec4 pos;
pos.xy = (newTexCoord * vec2(2.0)) - vec2(1.0);
pos.z = depth;
pos.w = 1.0;
pos = m_ViewProjectionMatrixInverse * pos;
//pos /= pos.w;
return pos.xyz;
}
// JME3 lights in world space
void lightComputeDir(in vec3 worldPos, in vec4 color, in vec4 position, out vec4 lightDir){
#ifdef DIR_LIGHT
lightDir.xyz = -position.xyz;
#else
lightDir.xyz = position.xyz - worldPos.xyz;
float dist = length(lightDir.xyz);
lightDir.w = clamp(1.0 - position.w * dist, 0.0, 1.0);
lightDir.xyz /= dist;
#endif
/*
float posLight = step(0.5, color.w);
vec3 tempVec = position.xyz * sign(posLight - 0.5) - (worldPos * posLight);
#ifdef ATTENUATION
float dist = length(tempVec);
lightDir.w = clamp(1.0 - position.w * dist * posLight, 0.0, 1.0);
lightDir.xyz = tempVec / vec3(dist);
#ifdef HQ_ATTENUATION
lightVec = tempVec;
#endif
#else
lightDir = vec4(normalize(tempVec), 1.0);
#endif
*/
}
void main(){
vec2 newTexCoord = texCoord;
vec4 diffuseColor = texture2D(m_DiffuseData, newTexCoord);
if (diffuseColor.a == 0.0)
discard;
vec4 specularColor = texture2D(m_SpecularData, newTexCoord);
vec3 worldPosition = getPosition(newTexCoord);
vec3 viewDir = normalize(g_CameraPosition - worldPosition);
vec4 normalInfo = vec4(texture2D(m_NormalData, newTexCoord).rg, 0.0, 0.0);
vec3 normal = decodeNormal(normalInfo);
vec4 lightDir;
lightComputeDir(worldPosition, g_LightColor, g_LightPosition, lightDir);
vec2 light = computeLighting(worldPosition, normal, viewDir, lightDir, specularColor.w*128.0);
#ifdef COLORRAMP
diffuseColor.rgb *= texture2D(m_ColorRamp, vec2(light.x, 0.0)).rgb;
specularColor.rgb *= texture2D(m_ColorRamp, vec2(light.y, 0.0)).rgb;
#endif
gl_FragColor = vec4(light.x * diffuseColor.xyz + light.y * specularColor.xyz, 1.0);
gl_FragColor.xyz *= g_LightColor.xyz;
}
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