Bliss-Shader/shaders/dimensions/fogBehindTranslucent_pass.fsh

396 lines
12 KiB
GLSL

#include "/lib/settings.glsl"
// #if defined END_SHADER || defined NETHER_SHADER
#undef IS_LPV_ENABLED
// #endif
#ifndef OVERWORLD_SHADER
uniform float nightVision;
#endif
flat varying vec4 lightCol;
flat varying vec3 averageSkyCol;
flat varying vec3 averageSkyCol_Clouds;
flat varying float exposure;
// uniform int dhRenderDistance;
uniform sampler2D noisetex;
uniform sampler2D depthtex0;
uniform sampler2D depthtex1;
#ifdef DISTANT_HORIZONS
uniform sampler2D dhDepthTex;
uniform sampler2D dhDepthTex1;
#endif
uniform sampler2D colortex2;
uniform sampler2D colortex3;
// uniform sampler2D colortex4;
uniform sampler2D colortex6;
uniform sampler2D colortex7;
uniform sampler2D colortex11;
uniform sampler2D colortex14;
flat varying vec3 WsunVec;
uniform vec3 sunVec;
uniform float sunElevation;
// uniform float far;
uniform float dhFarPlane;
uniform float dhNearPlane;
uniform int frameCounter;
uniform float frameTimeCounter;
// varying vec2 texcoord;
uniform vec2 texelSize;
// flat varying vec2 TAA_Offset;
uniform int isEyeInWater;
uniform float rainStrength;
uniform ivec2 eyeBrightnessSmooth;
uniform float eyeAltitude;
uniform float caveDetection;
#define DHVLFOG
#define diagonal3(m) vec3((m)[0].x, (m)[1].y, m[2].z)
#define projMAD(m, v) (diagonal3(m) * (v) + (m)[3].xyz)
#include "/lib/color_transforms.glsl"
#include "/lib/color_dither.glsl"
#include "/lib/projections.glsl"
#include "/lib/res_params.glsl"
#include "/lib/sky_gradient.glsl"
#include "/lib/Shadow_Params.glsl"
#include "/lib/waterBump.glsl"
#include "/lib/DistantHorizons_projections.glsl"
float DH_ld(float dist) {
return (2.0 * dhNearPlane) / (dhFarPlane + dhNearPlane - dist * (dhFarPlane - dhNearPlane));
}
float DH_inv_ld (float lindepth){
return -((2.0*dhNearPlane/lindepth)-dhFarPlane-dhNearPlane)/(dhFarPlane-dhNearPlane);
}
float linearizeDepthFast(const in float depth, const in float near, const in float far) {
return (near * far) / (depth * (near - far) + far);
}
#ifdef OVERWORLD_SHADER
const bool shadowHardwareFiltering = true;
uniform sampler2DShadow shadow;
#ifdef TRANSLUCENT_COLORED_SHADOWS
uniform sampler2D shadowcolor0;
uniform sampler2DShadow shadowtex0;
uniform sampler2DShadow shadowtex1;
#endif
flat varying vec3 refractedSunVec;
#define TIMEOFDAYFOG
#include "/lib/lightning_stuff.glsl"
// #define CLOUDS_INTERSECT_TERRAIN
// #define CLOUDSHADOWSONLY
#include "/lib/volumetricClouds.glsl"
#include "/lib/overworld_fog.glsl"
#endif
#ifdef NETHER_SHADER
uniform sampler2D colortex4;
#include "/lib/nether_fog.glsl"
#endif
#ifdef END_SHADER
uniform sampler2D colortex4;
#include "/lib/end_fog.glsl"
#endif
#include "/lib/diffuse_lighting.glsl"
#define fsign(a) (clamp((a)*1e35,0.,1.)*2.-1.)
float interleaved_gradientNoise(){
return fract(52.9829189*fract(0.06711056*gl_FragCoord.x + 0.00583715*gl_FragCoord.y)+ 1.0/1.6180339887 * frameCounter);
}
float blueNoise(){
return fract(texelFetch2D(noisetex, ivec2(gl_FragCoord.xy)%512, 0).a+ 1.0/1.6180339887 * frameCounter );
}
float R2_dither(){
#ifdef TAA
vec2 coord = gl_FragCoord.xy + (frameCounter%40000) * 2.0;
#else
vec2 coord = gl_FragCoord.xy;
#endif
vec2 alpha = vec2(0.75487765, 0.56984026);
return fract(alpha.x * coord.x + alpha.y * coord.y ) ;
}
void waterVolumetrics_notoverworld(inout vec3 inColor, vec3 rayStart, vec3 rayEnd, float estEndDepth, float estSunDepth, float rayLength, float dither, vec3 waterCoefs, vec3 scatterCoef, vec3 ambient){
inColor *= exp(-rayLength * waterCoefs); //No need to take the integrated value
int spCount = rayMarchSampleCount;
vec3 start = toShadowSpaceProjected(rayStart);
vec3 end = toShadowSpaceProjected(rayEnd);
vec3 dV = (end-start);
//limit ray length at 32 blocks for performance and reducing integration error
//you can't see above this anyway
float maxZ = min(rayLength,12.0)/(1e-8+rayLength);
dV *= maxZ;
rayLength *= maxZ;
float dY = normalize(mat3(gbufferModelViewInverse) * rayEnd).y * rayLength;
estEndDepth *= maxZ;
estSunDepth *= maxZ;
vec3 wpos = mat3(gbufferModelViewInverse) * rayStart + gbufferModelViewInverse[3].xyz;
vec3 dVWorld = (wpos-gbufferModelViewInverse[3].xyz);
vec3 absorbance = vec3(1.0);
vec3 vL = vec3(0.0);
float expFactor = 11.0;
for (int i=0;i<spCount;i++) {
float d = (pow(expFactor, float(i+dither)/float(spCount))/expFactor - 1.0/expFactor)/(1-1.0/expFactor);
float dd = pow(expFactor, float(i+dither)/float(spCount)) * log(expFactor) / float(spCount)/(expFactor-1.0);
vec3 spPos = start.xyz + dV*d;
vec3 progressW = start.xyz+cameraPosition+dVWorld;
vec3 ambientMul = exp(-max(estEndDepth * d,0.0) * waterCoefs );
vec3 Indirectlight = ambientMul*ambient;
vec3 light = Indirectlight * scatterCoef;
vL += (light - light * exp(-waterCoefs * dd * rayLength)) / waterCoefs * absorbance;
absorbance *= exp(-dd * rayLength * waterCoefs);
}
inColor += vL;
}
vec4 blueNoise(vec2 coord){
return texelFetch2D(colortex6, ivec2(coord)%512 , 0) ;
}
vec2 R2_samples(int n){
vec2 alpha = vec2(0.75487765, 0.56984026);
return fract(alpha * n);
}
float fogPhase2(float lightPoint){
float linear = 1.0 - clamp(lightPoint*0.5+0.5,0.0,1.0);
float linear2 = 1.0 - clamp(lightPoint,0.0,1.0);
float exponential = exp2(pow(linear,0.3) * -15.0 ) * 1.5;
exponential += sqrt(exp2(sqrt(linear) * -12.5));
return exponential;
}
vec4 waterVolumetrics_test( vec3 rayStart, vec3 rayEnd, float estEndDepth, float estSunDepth, float rayLength, float dither, vec3 waterCoefs, vec3 scatterCoef, vec3 ambient, vec3 lightSource, float VdotL){
int spCount = rayMarchSampleCount;
vec3 start = toShadowSpaceProjected(rayStart);
vec3 end = toShadowSpaceProjected(rayEnd);
vec3 dV = (end-start);
//limit ray length at 32 blocks for performance and reducing integration error
//you can't see above this anyway
float maxZ = min(rayLength,12.0)/(1e-8+rayLength);
dV *= maxZ;
rayLength *= maxZ;
estEndDepth *= maxZ;
estSunDepth *= maxZ;
vec3 wpos = mat3(gbufferModelViewInverse) * rayStart + gbufferModelViewInverse[3].xyz;
vec3 dVWorld = (wpos - gbufferModelViewInverse[3].xyz);
vec3 newabsorbance = exp(-rayLength * waterCoefs); // No need to take the integrated value
#ifdef OVERWORLD_SHADER
float phase = fogPhase(VdotL) * 5.0;
#else
float phase = 1.0;
#endif
vec3 absorbance = vec3(1.0);
vec3 vL = vec3(0.0);
ambient = max(ambient * (normalize(wpos).y*0.3+0.7),0.0);
float expFactor = 11.0;
for (int i=0;i<spCount;i++) {
float d = (pow(expFactor, float(i+dither)/float(spCount))/expFactor - 1.0/expFactor)/(1-1.0/expFactor);
float dd = pow(expFactor, float(i+dither)/float(spCount)) * log(expFactor) / float(spCount)/(expFactor-1.0);
vec3 progressW = start.xyz+cameraPosition+dVWorld;
vec3 sh = vec3(1.0);
#ifdef OVERWORLD_SHADER
vec3 spPos = start.xyz + dV*d;
//project into biased shadowmap space
#ifdef DISTORT_SHADOWMAP
float distortFactor = calcDistort(spPos.xy);
#else
float distortFactor = 1.0;
#endif
vec3 pos = vec3(spPos.xy*distortFactor, spPos.z);
if (abs(pos.x) < 1.0-0.5/2048. && abs(pos.y) < 1.0-0.5/2048){
pos = pos*vec3(0.5,0.5,0.5/6.0)+0.5;
// sh = shadow2D( shadow, pos).x;
#ifdef TRANSLUCENT_COLORED_SHADOWS
sh = vec3(shadow2D(shadowtex0, pos).x);
if(shadow2D(shadowtex1, pos).x > pos.z && sh.x < 1.0){
vec4 translucentShadow = texture2D(shadowcolor0, pos.xy);
if(translucentShadow.a < 0.9) sh = normalize(translucentShadow.rgb+0.0001);
}
#else
sh = vec3(shadow2D(shadow, pos).x);
#endif
}
#ifdef VL_CLOUDS_SHADOWS
sh *= GetCloudShadow_VLFOG(progressW,WsunVec);
#endif
#endif
vec3 sunMul = exp(-estSunDepth * d * waterCoefs * 1.1);
vec3 ambientMul = exp(-estEndDepth * d * waterCoefs );
vec3 Directlight = ((lightSource * sh) * phase * sunMul) ;
vec3 Indirectlight = max(ambient * ambientMul, vec3(0.01,0.2,0.4) * ambientMul * MIN_LIGHT_AMOUNT * 0.03) ;
vec3 light = (Indirectlight + Directlight) * scatterCoef;
vL += (light - light * exp(-waterCoefs * dd * rayLength)) / waterCoefs * absorbance;
absorbance *= exp(-waterCoefs * dd * rayLength);
}
// inColor += vL;
return vec4( vL, dot(newabsorbance,vec3(0.335)));
}
vec2 decodeVec2(float a){
const vec2 constant1 = 65535. / vec2( 256., 65536.);
const float constant2 = 256. / 255.;
return fract( a * constant1 ) * constant2 ;
}
//////////////////////////////VOID MAIN//////////////////////////////
//////////////////////////////VOID MAIN//////////////////////////////
//////////////////////////////VOID MAIN//////////////////////////////
//////////////////////////////VOID MAIN//////////////////////////////
//////////////////////////////VOID MAIN//////////////////////////////
void main() {
/* RENDERTARGETS:13 */
gl_FragData[0] = vec4(0,0,0,1);
vec2 tc = floor(gl_FragCoord.xy)/VL_RENDER_RESOLUTION*texelSize+0.5*texelSize;
bool iswater = texture2D(colortex7,tc).a > 0.99;
//////////////////////////////////////////////////////////
///////////////// BEHIND OF TRANSLUCENTS /////////////////
//////////////////////////////////////////////////////////
if(texture2D(colortex2, tc).a > 0.0 || iswater){
float noise_1 = R2_dither();
float noise_2 = blueNoise();
float z0 = texture2D(depthtex0,tc).x;
#ifdef DISTANT_HORIZONS
float DH_z0 = texture2D(dhDepthTex,tc).x;
#else
float DH_z0 = 0.0;
#endif
float z = texture2D(depthtex1,tc).x;
#ifdef DISTANT_HORIZONS
float DH_z = texture2D(dhDepthTex1,tc).x;
#else
float DH_z = 0.0;
#endif
// vec3 lightningColor = (lightningEffect / 3) * (max(eyeBrightnessSmooth.y,0)/240.);
float dirtAmount = Dirt_Amount + 0.1;
// float dirtAmount = Dirt_Amount + 0.01;
vec3 waterEpsilon = vec3(Water_Absorb_R, Water_Absorb_G, Water_Absorb_B);
vec3 dirtEpsilon = vec3(Dirt_Absorb_R, Dirt_Absorb_G, Dirt_Absorb_B);
vec3 totEpsilon = dirtEpsilon*dirtAmount + waterEpsilon;
vec3 scatterCoef = dirtAmount * vec3(Dirt_Scatter_R, Dirt_Scatter_G, Dirt_Scatter_B) / 3.14;
#ifdef BIOME_TINT_WATER
// yoink the biome tint written in this buffer for water only.
if(iswater){
vec2 translucentdata = texture2D(colortex11,tc).gb;
vec3 wateralbedo = normalize(vec3(decodeVec2(translucentdata.x),decodeVec2(translucentdata.y).x)+0.00001) * 0.5 + 0.5;
scatterCoef = dirtAmount * wateralbedo / 3.14;
}
#endif
vec3 directLightColor = lightCol.rgb/80.0;
vec3 indirectLightColor = averageSkyCol/30.0;
vec3 indirectLightColor_dynamic = averageSkyCol_Clouds/30.0;
vec3 viewPos1 = toScreenSpace_DH(tc/RENDER_SCALE, z, DH_z);
vec3 viewPos0 = toScreenSpace_DH(tc/RENDER_SCALE, z0, DH_z0);
vec3 playerPos = normalize(mat3(gbufferModelViewInverse) * viewPos1);
#ifdef OVERWORLD_SHADER
// vec2 lightmap = decodeVec2(texture2D(colortex14, tc).a);
vec2 lightmap = vec2(0.0,texture2D(colortex14, tc).a);
#ifdef DISTANT_HORIZONS
if(z >= 1.0) lightmap.y = 0.99;
#endif
#else
vec2 lightmap = decodeVec2(texture2D(colortex14, tc).a);
lightmap.y = 1.0;
#endif
float Vdiff = distance(viewPos1, viewPos0) * 2.0;
float VdotU = playerPos.y;
float estimatedDepth = Vdiff * abs(VdotU) ; //assuming water plane
float estimatedSunDepth = estimatedDepth / abs(WsunVec.y); //assuming water plane
indirectLightColor_dynamic *= ambient_brightness * pow(1.0-pow(1.0-lightmap.y,0.5),3.0) ;
// float TorchBrightness_autoAdjust = mix(1.0, 30.0, clamp(exp(-10.0*exposure),0.0,1.0)) ;
// indirectLightColor_dynamic += vec3(TORCH_R,TORCH_G,TORCH_B) * TorchBrightness_autoAdjust * pow(1.0-sqrt(1.0-clamp(lightmap.x,0.0,1.0)),2.0) * 2.0;
vec3 cloudDepth = vec3(0.0);
vec4 VolumetricFog2 = vec4(0,0,0,1);
vec4 VolumetricClouds = vec4(0,0,0,1);
#ifdef OVERWORLD_SHADER
if(!iswater){
#if defined CLOUDS_INTERSECT_TERRAIN
VolumetricClouds = renderClouds(viewPos1, vec2(noise_1,noise_2), directLightColor, indirectLightColor, cloudDepth);
#endif
VolumetricFog2 = GetVolumetricFog(viewPos1, vec2(noise_1, noise_2), directLightColor, indirectLightColor,indirectLightColor_dynamic,cloudDepth);
#if defined CLOUDS_INTERSECT_TERRAIN
VolumetricFog2 = vec4(VolumetricClouds.rgb * VolumetricFog2.a + VolumetricFog2.rgb, VolumetricFog2.a*VolumetricClouds.a);
#endif
}
#endif
vec4 underwaterVlFog = vec4(0,0,0,1);
if(iswater) underwaterVlFog = waterVolumetrics_test(viewPos0, viewPos1, estimatedDepth, estimatedSunDepth, Vdiff, noise_1, totEpsilon, scatterCoef, indirectLightColor_dynamic, directLightColor, dot(normalize(viewPos1), normalize(sunVec*lightCol.a)) );
vec4 fogFinal = vec4(underwaterVlFog.rgb * VolumetricFog2.a + VolumetricFog2.rgb, VolumetricFog2.a * underwaterVlFog.a);
gl_FragData[0] = clamp(fogFinal, 0.0, 65000.0);
}
}