slang-shaders/crt/shaders/metacrt/bufD.slang
2017-06-12 16:17:53 -05:00

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#version 450
// Meta CRT - @P_Malin
// https://www.shadertoy.com/view/4dlyWX#
// In which I add and remove aliasing
layout(push_constant) uniform Push
{
vec4 SourceSize;
vec4 OriginalSize;
vec4 OutputSize;
uint FrameCount;
} params;
layout(std140, set = 0, binding = 0) uniform UBO
{
mat4 MVP;
} global;
#pragma stage vertex
layout(location = 0) in vec4 Position;
layout(location = 1) in vec2 TexCoord;
layout(location = 0) out vec2 vTexCoord;
void main()
{
gl_Position = global.MVP * Position;
vTexCoord = TexCoord;
}
#pragma stage fragment
layout(location = 0) in vec2 vTexCoord;
layout(location = 0) out vec4 FragColor;
layout(set = 0, binding = 2) uniform sampler2D Source;
layout(set = 0, binding = 3) uniform sampler2D Original;
#define iResolution params.SourceSize
#define iChannel0 Source
#define iChannel1 Source
#define vFragCoord vec2(vTexCoord.xy * params.OutputSize.xy)
#define iGlobalTime float(params.FrameCount)
// Temporal Anti-aliasing Pass
#define ENABLE_TAA
///////////////////////////
// Hash Functions
///////////////////////////
// From: Hash without Sine by Dave Hoskins
// https://www.shadertoy.com/view/4djSRW
// *** Use this for integer stepped ranges, ie Value-Noise/Perlin noise functions.
//#define HASHSCALE1 .1031
//#define HASHSCALE3 vec3(.1031, .1030, .0973)
//#define HASHSCALE4 vec4(1031, .1030, .0973, .1099)
// For smaller input rangers like audio tick or 0-1 UVs use these...
#define HASHSCALE1 443.8975
#define HASHSCALE3 vec3(443.897, 441.423, 437.195)
#define HASHSCALE4 vec3(443.897, 441.423, 437.195, 444.129)
//----------------------------------------------------------------------------------------
// 2 out, 1 in...
vec2 hash21(float p)
{
vec3 p3 = fract(vec3(p) * HASHSCALE3);
p3 += dot(p3, p3.yzx + 19.19);
return fract((p3.xx+p3.yz)*p3.zy);
}
/// 2 out, 3 in...
vec2 hash23(vec3 p3)
{
p3 = fract(p3 * HASHSCALE3);
p3 += dot(p3, p3.yzx+19.19);
return fract((p3.xx+p3.yz)*p3.zy);
}
// 1 out, 3 in...
float hash13(vec3 p3)
{
p3 = fract(p3 * HASHSCALE1);
p3 += dot(p3, p3.yzx + 19.19);
return fract((p3.x + p3.y) * p3.z);
}
///////////////////////////
// Data Storage
///////////////////////////
vec4 LoadVec4( sampler2D tex, in ivec2 vAddr )
{
return texelFetch( tex, vAddr, 0 );
}
vec3 LoadVec3( sampler2D tex, in ivec2 vAddr )
{
return LoadVec4( tex, vAddr ).xyz;
}
bool AtAddress( ivec2 p, ivec2 c ) { return all( equal( p, c ) ); }
void StoreVec4( in ivec2 vAddr, in vec4 vValue, inout vec4 fragColor, in ivec2 fragCoord )
{
fragColor = AtAddress( fragCoord, vAddr ) ? vValue : fragColor;
}
void StoreVec3( in ivec2 vAddr, in vec3 vValue, inout vec4 fragColor, in ivec2 fragCoord )
{
StoreVec4( vAddr, vec4( vValue, 0.0 ), fragColor, fragCoord);
}
///////////////////////////
// Camera
///////////////////////////
struct CameraState
{
vec3 vPos;
vec3 vTarget;
float fFov;
vec2 vJitter;
float fPlaneInFocus;
};
void Cam_LoadState( out CameraState cam, sampler2D tex, ivec2 addr )
{
vec4 vPos = LoadVec4( tex, addr + ivec2(0,0) );
cam.vPos = vPos.xyz;
vec4 targetFov = LoadVec4( tex, addr + ivec2(1,0) );
cam.vTarget = targetFov.xyz;
cam.fFov = targetFov.w;
vec4 jitterDof = LoadVec4( tex, addr + ivec2(2,0) );
cam.vJitter = jitterDof.xy;
cam.fPlaneInFocus = jitterDof.z;
}
void Cam_StoreState( ivec2 addr, const in CameraState cam, inout vec4 fragColor, in ivec2 fragCoord )
{
StoreVec4( addr + ivec2(0,0), vec4( cam.vPos, 0 ), fragColor, fragCoord );
StoreVec4( addr + ivec2(1,0), vec4( cam.vTarget, cam.fFov ), fragColor, fragCoord );
StoreVec4( addr + ivec2(2,0), vec4( cam.vJitter, cam.fPlaneInFocus, 0 ), fragColor, fragCoord );
}
mat3 Cam_GetWorldToCameraRotMatrix( const CameraState cameraState )
{
vec3 vForward = normalize( cameraState.vTarget - cameraState.vPos );
vec3 vRight = normalize( cross(vec3(0, 1, 0), vForward) );
vec3 vUp = normalize( cross(vForward, vRight) );
return mat3( vRight, vUp, vForward );
}
vec2 Cam_GetViewCoordFromUV( const in vec2 vUV )
{
vec2 vWindow = vUV * 2.0 - 1.0;
vWindow.x *= iResolution.x / iResolution.y;
return vWindow;
}
void Cam_GetCameraRay( const vec2 vUV, const CameraState cam, out vec3 vRayOrigin, out vec3 vRayDir )
{
vec2 vView = Cam_GetViewCoordFromUV( vUV );
vRayOrigin = cam.vPos;
float fPerspDist = 1.0 / tan( radians( cam.fFov ) );
vRayDir = normalize( Cam_GetWorldToCameraRotMatrix( cam ) * vec3( vView, fPerspDist ) );
}
vec2 Cam_GetUVFromWindowCoord( const in vec2 vWindow )
{
vec2 vScaledWindow = vWindow;
vScaledWindow.x *= iResolution.y / iResolution.x;
return (vScaledWindow * 0.5 + 0.5);
}
vec2 Cam_WorldToWindowCoord(const in vec3 vWorldPos, const in CameraState cameraState )
{
vec3 vOffset = vWorldPos - cameraState.vPos;
vec3 vCameraLocal;
vCameraLocal = vOffset * Cam_GetWorldToCameraRotMatrix( cameraState );
vec2 vWindowPos = vCameraLocal.xy / (vCameraLocal.z * tan( radians( cameraState.fFov ) ));
return vWindowPos;
}
float EncodeDepthAndObject( float depth, int objectId )
{
//depth = max( 0.0, depth );
//objectId = max( 0, objectId + 1 );
//return exp2(-depth) + float(objectId);
return depth;
}
float DecodeDepthAndObjectId( float value, out int objectId )
{
objectId = 0;
return max(0.0, value);
//objectId = int( floor( value ) ) - 1;
//return abs( -log2(fract(value)) );
}
///////////////////////////////
#define iChannelCurr iChannel0
#define iChannelHistory iChannel1
vec3 Tonemap( vec3 x )
{
float a = 0.010;
float b = 0.132;
float c = 0.010;
float d = 0.163;
float e = 0.101;
return ( x * ( a * x + b ) ) / ( x * ( c * x + d ) + e );
}
vec3 TAA_ColorSpace( vec3 color )
{
return Tonemap(color);
}
void main()
{
CameraState camCurr;
Cam_LoadState( camCurr, iChannelCurr, ivec2(0) );
CameraState camPrev;
Cam_LoadState( camPrev, iChannelHistory, ivec2(0) );
vec2 vUV = vFragCoord.xy / iResolution.xy;
vec2 vUnJitterUV = vUV - camCurr.vJitter / iResolution.xy;
FragColor = textureLod(iChannelCurr, vUnJitterUV, 0.0);
#ifdef ENABLE_TAA
vec3 vRayOrigin, vRayDir;
Cam_GetCameraRay( vUV, camCurr, vRayOrigin, vRayDir );
float fDepth;
int iObjectId;
vec4 vCurrTexel = texelFetch( iChannelCurr, ivec2(vFragCoord.xy), 0);
fDepth = DecodeDepthAndObjectId( vCurrTexel.w, iObjectId );
vec3 vWorldPos = vRayOrigin + vRayDir * fDepth;
vec2 vPrevUV = Cam_GetUVFromWindowCoord( Cam_WorldToWindowCoord(vWorldPos, camPrev) );// + camPrev.vJitter / iResolution.xy;
if ( all( greaterThanEqual( vPrevUV, vec2(0) )) && all( lessThan( vPrevUV, vec2(1) )) )
{
vec3 vMin = vec3( 10000);
vec3 vMax = vec3(-10000);
ivec2 vCurrXY = ivec2(floor(vFragCoord.xy));
int iNeighborhoodSize = 1;
for ( int iy=-iNeighborhoodSize; iy<=iNeighborhoodSize; iy++)
{
for ( int ix=-iNeighborhoodSize; ix<=iNeighborhoodSize; ix++)
{
ivec2 iOffset = ivec2(ix, iy);
vec3 vTest = TAA_ColorSpace( texelFetch( iChannelCurr, vCurrXY + iOffset, 0 ).rgb );
vMin = min( vMin, vTest );
vMax = max( vMax, vTest );
}
}
float epsilon = 0.001;
vMin -= epsilon;
vMax += epsilon;
float fBlend = 0.0f;
//ivec2 vPrevXY = ivec2(floor(vPrevUV.xy * iResolution.xy));
vec4 vHistory = textureLod( iChannelHistory, vPrevUV, 0.0 );
vec3 vPrevTest = TAA_ColorSpace( vHistory.rgb );
if( all( greaterThanEqual(vPrevTest, vMin ) ) && all( lessThanEqual( vPrevTest, vMax ) ) )
{
fBlend = 0.9;
//FragColor.r *= 0.0;
}
FragColor.rgb = mix( FragColor.rgb, vHistory.rgb, fBlend);
}
else
{
//FragColor.gb *= 0.0;
}
#endif
FragColor.rgb += (hash13( vec3( vFragCoord, iGlobalTime ) ) * 2.0 - 1.0) * 0.03;
Cam_StoreState( ivec2(0), camCurr, FragColor, ivec2(vFragCoord.xy) );
Cam_StoreState( ivec2(3,0), camPrev, FragColor, ivec2(vFragCoord.xy) );
}