Use Alchemy SSAO

This commit is contained in:
Vincent Lejeune 2014-05-11 18:00:30 +02:00
parent 518a5fd8ef
commit e5410e23a2

View File

@ -1,3 +1,5 @@
// From paper http://graphics.cs.williams.edu/papers/AlchemyHPG11/
uniform sampler2D ntex; uniform sampler2D ntex;
uniform sampler2D dtex; uniform sampler2D dtex;
uniform sampler2D noise_texture; uniform sampler2D noise_texture;
@ -22,57 +24,60 @@ layout (std140) uniform MatrixesData
in vec2 uv; in vec2 uv;
out float AO; out float AO;
const float strengh = 5.; const float sigma = 1.;
const float radius = 1.f; const float beta = 0.0001;
const float epsilon = .00001;
const float radius = .1;
const float k = 1.;
#define SAMPLES 16 #define SAMPLES 16
const float invSamples = strengh / SAMPLES; const float invSamples = 1. / SAMPLES;
vec3 rand(vec2 co)
{
float noiseX = clamp(fract(sin(dot(co ,vec2(12.9898,78.233))) * 43758.5453),0.0,1.0)*2.0-1.0;
float noiseY = clamp(fract(sin(dot(co ,vec2(12.9898,78.233)*2.0)) * 43758.5453),0.0,1.0)*2.0-1.0;
return vec3(noiseX, noiseY, length(texture(noise_texture, co * pow(3.14159265359, 2.)).xyz));
}
vec3 DecodeNormal(vec2 n); vec3 DecodeNormal(vec2 n);
vec4 getPosFromUVDepth(vec3 uvDepth, mat4 InverseProjectionMatrix); vec4 getPosFromUVDepth(vec3 uvDepth, mat4 InverseProjectionMatrix);
vec3 rand(vec2 co)
{
float noiseX = clamp(fract(sin(dot(co ,vec2(12.9898,78.233))) * 43758.5453),0.0,1.0)*2.0-1.0;
float noiseY = clamp(fract(sin(dot(co ,vec2(12.9898,78.233)*2.0)) * 43758.5453),0.0,1.0)*2.0-1.0;
return vec3(noiseX, noiseY, length(texture(noise_texture, co * pow(3.14159265359, 2.)).xyz));
}
void main(void) void main(void)
{ {
vec4 cur = texture(ntex, uv); vec4 cur = texture(ntex, uv);
float curdepth = texture(dtex, uv).x; float curdepth = texture(dtex, uv).x;
vec4 FragPos = getPosFromUVDepth(vec3(uv, curdepth), InverseProjectionMatrix); vec4 FragPos = getPosFromUVDepth(vec3(uv, curdepth), InverseProjectionMatrix);
if (FragPos.z < 0.) discard;
// get the normal of current fragment // get the normal of current fragment
vec3 norm = normalize(DecodeNormal(2. * texture(ntex, uv).xy - 1.)); vec3 norm = normalize(DecodeNormal(2. * texture(ntex, uv).xy - 1.));
// Workaround for nvidia and skyboxes // Workaround for nvidia and skyboxes
float len = dot(vec3(1.0), abs(cur.xyz)); float len = dot(vec3(1.0), abs(cur.xyz));
if (len < 0.2 || curdepth > 0.9955) discard; if (len < 0.2 || curdepth > 0.9955) discard;
// Make a tangent as random as possible
vec3 randvect = rand(uv);
vec3 tangent = normalize(cross(norm, randvect));
vec3 bitangent = cross(norm, tangent);
float bl = 0.0; float randAngle = rand(uv).x;
vec2 Xaxis = vec2(cos(randAngle), sin(randAngle));
Xaxis = normalize(Xaxis);
vec2 Yaxis = vec2(sin(randAngle), -cos(randAngle));
Yaxis = normalize(Yaxis);
for(int i = 0; i < SAMPLES; ++i) { float bl = 0.0;
vec3 sampleDir = samplePoints[i].x * tangent + samplePoints[i].y * bitangent + samplePoints[i].z * norm;
sampleDir *= samplePoints[i].w;
vec4 samplePos = FragPos + radius * vec4(sampleDir, 0.0);
vec4 sampleProj = ProjectionMatrix * samplePos;
sampleProj /= sampleProj.w;
bool isInsideTexture = (sampleProj.x > -1.) && (sampleProj.x < 1.) && (sampleProj.y > -1.) && (sampleProj.y < 1.); for(int i = 0; i < SAMPLES; ++i) {
// get the depth of the occluder fragment vec2 occluder_uv = samplePoints[i].x * Xaxis + samplePoints[i].y * Yaxis;
float occluderFragmentDepth = texture(dtex, (sampleProj.xy * 0.5) + 0.5).x; occluder_uv *= samplePoints[i].w * radius;
// Position of the occluder fragment in worldSpace occluder_uv += uv;
vec4 occluderPos = getPosFromUVDepth(vec3((sampleProj.xy * 0.5) + 0.5, occluderFragmentDepth), InverseProjectionMatrix);
bool isOccluded = isInsideTexture && (sampleProj.z > (2. * occluderFragmentDepth - 1.0)) && (distance(FragPos, occluderPos) < radius); if (occluder_uv.x < 0. || occluder_uv.x > 1. || occluder_uv.y < 0. || occluder_uv.y > 1.) continue;
bl += isOccluded ? samplePoints[i].z * smoothstep(5 * radius, 0, distance(samplePos, FragPos)) : 0.;
}
AO = max(1.0 - bl * invSamples, 0.); float occluderFragmentDepth = texture(dtex, occluder_uv).x;
vec4 OccluderPos = getPosFromUVDepth(vec3(occluder_uv, occluderFragmentDepth), InverseProjectionMatrix);
vec3 vi = (OccluderPos - FragPos).xyz;
bl += max(0, dot(vi, norm) - FragPos.z * beta) / (dot(vi, vi) + epsilon);
}
AO = max(pow(1.0 - 2. * sigma * bl * invSamples, k), 0.);
} }