Bliss-Shader/shaders/programs/all_translucent.fsh

// #version 120
#extension GL_EXT_gpu_shader4 : enable

varying vec4 lmtexcoord;
varying vec4 color;
varying vec4 normalMat;
varying vec3 binormal;
uniform sampler2D normals;
varying vec3 tangent;
varying vec4 tangent_other;
varying vec3 viewVector;

#include "/lib/settings.glsl"
#include "/lib/res_params.glsl"


uniform sampler2D texture;
uniform sampler2D noisetex;
uniform sampler2DShadow shadow;
// uniform sampler2D gaux2;
uniform sampler2D gaux1;
uniform sampler2D depthtex1;
uniform sampler2D colortex5;

uniform float nightVision;

uniform vec3 sunVec;
uniform float frameTimeCounter;
uniform float lightSign;
uniform float near;
uniform float far;
uniform float moonIntensity;
uniform float sunIntensity;
uniform vec3 sunColor;
uniform vec3 nsunColor;
uniform vec3 upVec;
uniform float sunElevation;
uniform float fogAmount;
uniform vec2 texelSize;
uniform float rainStrength;
uniform float skyIntensityNight;
uniform float skyIntensity;
flat varying vec3 WsunVec;
uniform mat4 gbufferPreviousModelView;
uniform vec3 previousCameraPosition;
uniform int framemod8;
uniform sampler2D specular;
uniform int frameCounter;
uniform int isEyeInWater;


flat varying vec4 lightCol; //main light source color (rgb),used light source(1=sun,-1=moon)
flat varying vec3 avgAmbient;

#include "/lib/color_transforms.glsl"
#include "/lib/projections.glsl"
#include "/lib/sky_gradient.glsl"
#include "/lib/waterBump.glsl"

#include "/lib/diffuse_lighting.glsl"


		const vec2[8] offsets = vec2[8](vec2(1./8.,-3./8.),
									vec2(-1.,3.)/8.,
									vec2(5.0,1.)/8.,
									vec2(-3,-5.)/8.,
									vec2(-5.,5.)/8.,
									vec2(-7.,-1.)/8.,
									vec2(3,7.)/8.,
									vec2(7.,-7.)/8.);
float interleaved_gradientNoise(float temporal){
	vec2 coord = gl_FragCoord.xy;
	float noise = fract(52.9829189*fract(0.06711056*coord.x + 0.00583715*coord.y)+temporal);
	return noise;
}
vec3 srgbToLinear2(vec3 srgb){
    return mix(
        srgb / 12.92,
        pow(.947867 * srgb + .0521327, vec3(2.4) ),
        step( .04045, srgb )
    );
}
vec3 blackbody2(float Temp)
{
    float t = pow(Temp, -1.5);
    float lt = log(Temp);

    vec3 col = vec3(0.0);
         col.x = 220000.0 * t + 0.58039215686;
         col.y = 0.39231372549 * lt - 2.44549019608;
         col.y = Temp > 6500. ? 138039.215686 * t + 0.72156862745 : col.y;
         col.z = 0.76078431372 * lt - 5.68078431373;
         col = clamp(col,0.0,1.0);
         col = Temp < 1000. ? col * Temp * 0.001 : col;

    return srgbToLinear2(col);
}

float blueNoise(){
  return fract(texelFetch2D(noisetex, ivec2(gl_FragCoord.xy)%512, 0).a + 1.0/1.6180339887 * frameCounter);
}
float invLinZ (float lindepth){
	return -((2.0*near/lindepth)-far-near)/(far-near);
}
float ld(float dist) {
    return (2.0 * near) / (far + near - dist * (far - near));
}
vec3 nvec3(vec4 pos){
    return pos.xyz/pos.w;
}

vec4 nvec4(vec3 pos){
    return vec4(pos.xyz, 1.0);
}
vec3 rayTrace(vec3 dir,vec3 position,float dither, float fresnel, bool inwater){

    float quality = mix(15,SSR_STEPS,fresnel);
    vec3 clipPosition = toClipSpace3(position);
	float rayLength = ((position.z + dir.z * far*sqrt(3.)) > -near) ?
       (-near -position.z) / dir.z : far*sqrt(3.);
    vec3 direction = normalize(toClipSpace3(position+dir*rayLength)-clipPosition);  //convert to clip space
    direction.xy = normalize(direction.xy);

    //get at which length the ray intersects with the edge of the screen
    vec3 maxLengths = (step(0.,direction)-clipPosition) / direction;
    float mult = min(min(maxLengths.x,maxLengths.y),maxLengths.z);


    vec3 stepv = direction * mult / quality*vec3(RENDER_SCALE,1.0);


	vec3 spos = clipPosition*vec3(RENDER_SCALE,1.0) + stepv*dither;
	float minZ = clipPosition.z;
	float maxZ = spos.z+stepv.z*0.5;
	
	spos.xy += offsets[framemod8]*texelSize*0.5/RENDER_SCALE;

	float dist = 1.0 + clamp(position.z*position.z/50.0,0,2); // shrink sample size as distance increases
    for (int i = 0; i <= int(quality); i++) {
		// decode depth buffer
		float sp = texelFetch2D(depthtex1,ivec2(spos.xy/texelSize),0).x;


		if(sp <= max(maxZ,minZ) && sp >= min(maxZ,minZ) ) return vec3(spos.xy/RENDER_SCALE,sp);

		spos += stepv;
		
		//small bias
		float biasamount = 0.0002 / dist;

		minZ = maxZ-biasamount / ld(spos.z);
		
		maxZ += stepv.z;
    }

    return vec3(1.1);
}


float facos(float sx){
    float x = clamp(abs( sx ),0.,1.);
    float a = sqrt( 1. - x ) * ( -0.16882 * x + 1.56734 );
    return sx > 0. ? a : pi - a;
}




	float bayer2(vec2 a){
	a = floor(a);
    return fract(dot(a,vec2(0.5,a.y*0.75)));
}

float cdist(vec2 coord) {
	return max(abs(coord.s-0.5),abs(coord.t-0.5))*2.0;
}

	#define PW_DEPTH 1.0 //[0.5 1.0 1.5 2.0 2.5 3.0]
	#define PW_POINTS 1 //[2 4 6 8 16 32]
	#define bayer4(a)   (bayer2( .5*(a))*.25+bayer2(a))
#define bayer8(a)   (bayer4( .5*(a))*.25+bayer2(a))
#define bayer16(a)  (bayer8( .5*(a))*.25+bayer2(a))
#define bayer32(a)  (bayer16(.5*(a))*.25+bayer2(a))
#define bayer64(a)  (bayer32(.5*(a))*.25+bayer2(a))
#define bayer128(a) fract(bayer64(.5*(a))*.25+bayer2(a))
vec3 getParallaxDisplacement(vec3 posxz, float iswater,float bumpmult,vec3 viewVec) {
	float waveZ = mix(20.0,0.25,iswater);
	float waveM = mix(0.0,4.0,iswater);

	vec3 parallaxPos = posxz;
	vec2 vec = viewVector.xy * (1.0 / float(PW_POINTS)) * 22.0 * PW_DEPTH;
	float waterHeight = getWaterHeightmap(posxz.xz, waveM, waveZ, iswater) ;
	
	parallaxPos.xz += waterHeight * vec;

	return parallaxPos;

}
vec2 tapLocation(int sampleNumber,int nb, float nbRot,float jitter,float distort)
{
    float alpha = (sampleNumber+jitter)/nb;
    float angle = jitter*6.28 + alpha * nbRot * 6.28;

    float sin_v, cos_v;

	sin_v = sin(angle);
	cos_v = cos(angle);

    return vec2(cos_v, sin_v)*sqrt(alpha);
}
//Low discrepancy 2D sequence, integration error is as low as sobol but easier to compute : http://extremelearning.com.au/unreasonable-effectiveness-of-quasirandom-sequences/
vec2 R2_samples(int n){
	vec2 alpha = vec2(0.75487765, 0.56984026);
	return fract(alpha * n);
}
vec4 hash44(vec4 p4)
{
	p4 = fract(p4  * vec4(.1031, .1030, .0973, .1099));
    p4 += dot(p4, p4.wzxy+33.33);
    return fract((p4.xxyz+p4.yzzw)*p4.zywx);
}
vec3 TangentToWorld(vec3 N, vec3 H)
{
    vec3 UpVector = abs(N.z) < 0.999 ? vec3(0.0, 0.0, 1.0) : vec3(1.0, 0.0, 0.0);
    vec3 T = normalize(cross(UpVector, N));
    vec3 B = cross(N, T);

    return vec3((T * H.x) + (B * H.y) + (N * H.z));
}
float GGX (vec3 n, vec3 v, vec3 l, float r, float F0) {
  r*=r;r*=r;

  vec3 h = l + v;
  float hn = inversesqrt(dot(h, h));

  float dotLH = clamp(dot(h,l)*hn,0.,1.);
  float dotNH = clamp(dot(h,n)*hn,0.,1.);
  float dotNL = clamp(dot(n,l),0.,1.);
  float dotNHsq = dotNH*dotNH;

  float denom = dotNHsq * r - dotNHsq + 1.;
  float D = r / (3.141592653589793 * denom * denom);
  float F = F0 + (1. - F0) * exp2((-5.55473*dotLH-6.98316)*dotLH);
  float k2 = .25 * r;

  return dotNL * D * F / (dotLH*dotLH*(1.0-k2)+k2);
}

	vec3 applyBump(mat3 tbnMatrix, vec3 bump){	
		float bumpmult = 1.0;
		bump = bump * vec3(bumpmult, bumpmult, bumpmult) + vec3(0.0f, 0.0f, 1.0f - bumpmult);
		return normalize(bump*tbnMatrix);
	}

#define fsign(a)  (clamp((a)*1e35,0.,1.)*2.-1.)
float triangularize(float dither)
{
    float center = dither*2.0-1.0;
    dither = center*inversesqrt(abs(center));
    return clamp(dither-fsign(center),0.0,1.0);
}
vec3 fp10Dither(vec3 color,float dither){
	const vec3 mantissaBits = vec3(6.,6.,5.);
	vec3 exponent = floor(log2(color));
	return color + dither*exp2(-mantissaBits)*exp2(exponent);
}
float R2_dither(){
	vec2 alpha = vec2(0.75487765, 0.56984026);
	return fract(alpha.x * gl_FragCoord.x + alpha.y * gl_FragCoord.y + 1.0/1.6180339887 * frameCounter) ;
}
float interleaved_gradientNoise(){
	vec2 coord = gl_FragCoord.xy + (frameCounter%40000);
	// vec2 coord = gl_FragCoord.xy + frameTimeCounter;
	// vec2 coord = gl_FragCoord.xy;
	float noise = fract( 52.9829189 * fract( (coord.x * 0.06711056) + (coord.y * 0.00583715)) );
	return noise ;
}
//encoding by jodie
float encodeVec2(vec2 a){
    const vec2 constant1 = vec2( 1., 256.) / 65535.;
    vec2 temp = floor( a * 255. );
	return temp.x*constant1.x+temp.y*constant1.y;
}
float encodeVec2(float x,float y){
    return encodeVec2(vec2(x,y));
}
vec3 viewToWorld(vec3 viewPosition) {
    vec4 pos;
    pos.xyz = viewPosition;
    pos.w = 0.0;
    pos = gbufferModelViewInverse * pos;
    return pos.xyz;
}
vec3 worldToView(vec3 worldPos) {
    vec4 pos = vec4(worldPos, 0.0);
    pos = gbufferModelView * pos;
    return pos.xyz;
}
vec4 encode (vec3 n, vec2 lightmaps){
	n.xy = n.xy / dot(abs(n), vec3(1.0));
	n.xy = n.z <= 0.0 ? (1.0 - abs(n.yx)) * sign(n.xy) : n.xy;
    vec2 encn = clamp(n.xy * 0.5 + 0.5,-1.0,1.0);
	
    return vec4(encn,vec2(lightmaps.x,lightmaps.y));
}




float square(float x){
  return x*x;
}

float gSimple(float dp, float roughness){
  float k = roughness + 1;
  k *= k/8.0;
  return dp / (dp * (1.0-k) + k);
}
vec3 GGX2_2(vec3 n, vec3 v, vec3 l, float r, vec3 F0) {

  float alpha = square(r) + 1e-4;  // when roughness is zero it fucks up
  
  vec3 h = normalize(l + v) ;

  float dotNH = clamp(dot(h,n),0.,1.);
  float dotVH = clamp(dot(h,v),0.,1.);

  float D = alpha / (2.2 * square( (dotNH * alpha - 1.0) * square(dotNH)	+ 1.0) 	);
  
  vec3 F = F0 + (1. - F0) * pow(clamp(1.0 - dotVH,0.0,1.0),5.0);

  return F * D;
}
// float SunGGX(vec3 n, vec3 v, vec3 l, float Roughness, float F0){
	
// 	vec3 h = normalize(l + v) ;

// 	float dotNH = clamp(dot(h,n),0.,1.);
// 	float dotVH = clamp(dot(h,v),0.,1.);

// 	float alpha =max(square(Roughness),1e-4) ;

// 	float WallFresnel = F0 + (1. - F0) * pow(clamp(1.0 - dotVH,0.0,1.0),5.0);	
// 	float Sun =  square( dotNH - pow(alpha,1.5)  - 1.0);	

// 	float Final =  ((alpha / (10.0  * Sun + 1e-4)) * WallFresnel);	

// 	return Final ;
// }
float SunGGX(vec3 n, vec3 v, vec3 l, float roughness,float F0, float fresnel){


  float alpha = square(roughness) + 1e-4;  // when roughness is zero it fucks up

  vec3 h = normalize(l + v) * mix(1.000, 1.0025, 	pow(fresnel,2)	);
  
  float dotLH = clamp(dot(h,l),0.,1.);
  float dotNH = clamp(dot(h,n),0.,1.);
  float dotNL = clamp(dot(n,l),0.,1.);
  float dotNV = clamp(dot(n,v),0.,1.);
  float dotVH = clamp(dot(h,v),0.,1.);


  float D = alpha / (0.0541592653589793*square(square(dotNH) * (alpha - 1.0) + 1.0));
  float G = gSimple(dotNV, roughness) * gSimple(dotNL, roughness);
  float F = F0 + (1. - F0) * exp2((-5.55473*dotVH-6.98316)*dotVH);

  return dotNL * F * (G * D / (4 * dotNV * dotNL + 1e-7));
}


vec3 normVec (vec3 vec){
	return vec*inversesqrt(dot(vec,vec));
}
float getWaterHeightmap_dimension(vec2 posxz, float waveM, float waveZ, float iswater) { // water waves
	vec2 movement = vec2(frameTimeCounter*0.01);
	vec2 pos = posxz ;
	float caustic = 1.0;
	float weightSum = 0.0;

	float radiance = 2.39996;
	mat2 rotationMatrix  = mat2(vec2(cos(radiance),  -sin(radiance)),  vec2(sin(radiance),  cos(radiance)));

	for (int i = 0; i < 3; i++){
		pos = rotationMatrix * pos ;

		float Waves = texture2D(noisetex, pos / 64.0 + movement).b;

		
		caustic += exp2(pow(Waves,3.0) * -5.0);
		weightSum += exp2(-(3.0-caustic));
	}
	return ((3.0-caustic) * weightSum / (30.0 * 3.0));
}

vec3 getWaveHeightmap_dimension(vec2 posxz, float iswater){

		vec2 coord = posxz;

		float deltaPos =  0.25;

		float waveZ = mix(20.0,0.25,iswater);
		float waveM = mix(0.0,4.0,iswater);

		float h0 = getWaterHeightmap_dimension(coord, waveM, waveZ, iswater);
		float h1 = getWaterHeightmap_dimension(coord + vec2(deltaPos,0.0), waveM, waveZ, iswater);
		float h3 = getWaterHeightmap_dimension(coord + vec2(0.0,deltaPos), waveM, waveZ, iswater);


		float xDelta = ((h1-h0))/deltaPos*2.;
		float yDelta = ((h3-h0))/deltaPos*2.;

		vec3 wave = normalize(vec3(xDelta,yDelta,1.0-pow(abs(xDelta+yDelta),2.0)));

		return wave;
}

//////////////////////////////VOID MAIN//////////////////////////////
//////////////////////////////VOID MAIN//////////////////////////////
//////////////////////////////VOID MAIN//////////////////////////////
//////////////////////////////VOID MAIN//////////////////////////////
//////////////////////////////VOID MAIN//////////////////////////////
/* RENDERTARGETS:2,7,1,11,13,14 */
void main() {
	if (gl_FragCoord.x * texelSize.x < RENDER_SCALE.x  && gl_FragCoord.y * texelSize.y < RENDER_SCALE.y )	{

		gl_FragData[0] = texture2D(texture, lmtexcoord.xy,Texture_MipMap_Bias)*color;
		vec3 Albedo = toLinear(gl_FragData[0].rgb);

		float iswater = normalMat.w;

		#ifdef HAND
			iswater = 0.1;
		#endif
		#ifndef Vanilla_like_water
			if (iswater > 0.9) {
				Albedo = vec3(0.0);
				gl_FragData[0] = vec4(vec3(0.0),1.0/255.0);
			}
		#endif
		#ifdef Vanilla_like_water
			if (iswater > 0.5) {
				gl_FragData[0].a = luma(Albedo.rgb);
				Albedo = color.rgb;
			}
		#endif

		

		// gl_FragData[4] = vec4(Albedo, gl_FragData[0].a);


		vec2 tempOffset=offsets[framemod8];
		vec3 fragC = gl_FragCoord.xyz*vec3(texelSize,1.0);
		vec3 fragpos = toScreenSpace(gl_FragCoord.xyz*vec3(texelSize/RENDER_SCALE,1.0)-vec3(vec2(tempOffset)*texelSize*0.5,0.0));
		vec3 p3 = mat3(gbufferModelViewInverse) * fragpos + gbufferModelViewInverse[3].xyz;
		vec3 np3 = normVec(p3);


		vec3 normal = normalMat.xyz;
		vec3 WaterNormals;
		vec3 TranslucentNormals;

		mat3 tbnMatrix = mat3(tangent.x, binormal.x, normal.x,
							  tangent.y, binormal.y, normal.y,
							  tangent.z, binormal.z, normal.z);



		
		if (iswater > 0.4){
			float bumpmult = 1.;
			vec3 posxz = p3+cameraPosition;
			posxz.xz-=posxz.y;

			vec3 bump;

			posxz.xyz = getParallaxDisplacement(posxz,iswater,bumpmult,normalize(tbnMatrix*fragpos));

			bump = normalize(getWaveHeightmap_dimension(posxz.xz,iswater));
			WaterNormals = bump; // tangent space normals for refraction

			bump = bump * vec3(bumpmult, bumpmult, bumpmult) + vec3(0.0f, 0.0f, 1.0f - bumpmult);
			normal = normalize(bump * tbnMatrix);


		}else{
			vec3 normalTex = texture2D(normals, lmtexcoord.xy, Texture_MipMap_Bias).rgb;
			
			normalTex.xy = normalTex.xy*2.0-1.0;
			normalTex.z = clamp(sqrt(1.0 - dot(normalTex.xy, normalTex.xy)),0.0,1.0);

			TranslucentNormals = normalTex;

			normal = applyBump(tbnMatrix,normalTex);
		}

		TranslucentNormals += WaterNormals;

		vec4 data0 = vec4(1);
		vec4 data1 = clamp( encode(TranslucentNormals, lmtexcoord.zw),0.0,1.0);
		gl_FragData[3] = vec4(encodeVec2(data0.x,data1.x),	encodeVec2(data0.y,data1.y),	encodeVec2(data0.z,data1.z),	encodeVec2(data1.w,data0.w));
		gl_FragData[5] = vec4(encodeVec2(lmtexcoord.a,lmtexcoord.a),	encodeVec2(lmtexcoord.a,lmtexcoord.a),	encodeVec2(lmtexcoord.a,lmtexcoord.a),	encodeVec2(lmtexcoord.a,lmtexcoord.a));


		vec3 Indirect_lighting = DoAmbientLighting_Nether(gl_Fog.color.rgb, vec3(TORCH_R,TORCH_G,TORCH_B), lmtexcoord.z, viewToWorld(normal), np3,  p3 + cameraPosition);
		vec3 FinalColor = Indirect_lighting * Albedo;
	
		#ifdef Glass_Tint
			float alphashit = min(pow(gl_FragData[0].a,2.0),1.0);
			FinalColor *= alphashit;
		#endif
		
		vec2 SpecularTex = texture2D(specular, lmtexcoord.xy, Texture_MipMap_Bias).rg;
		SpecularTex = iswater > 0.0 && SpecularTex.r > 0.0 && SpecularTex.g < 0.9 ? SpecularTex : vec2(1.0,0.02);
		
		if (iswater > 0.0 || (SpecularTex.g > 0.0 || SpecularTex.r > 0.0)){
			vec3 Reflections_Final = vec3(0.0);
			float roughness = pow(1.0-SpecularTex.r,2.0);
			float f0 = SpecularTex.g;
			float F0 = f0;

			float visibilityFactor = clamp(exp2((pow(roughness,3.0) / f0) * -4),0,1);

			vec3 reflectedVector = reflect(normalize(fragpos), normal);
			float normalDotEye = dot(normal, normalize(fragpos));
			float fresnel = pow(clamp(1.0 + normalDotEye,0.0,1.0), 5.0);

			// snells window looking thing
			if(isEyeInWater == 1 && iswater > 0.99) fresnel = clamp(pow(1.66 + normalDotEye,25),0.02,1.0);

			fresnel = F0 + (1.0 - F0) * fresnel;

			vec4 Reflections = vec4(0.0);
			if(iswater > 0){
				#ifdef SCREENSPACE_REFLECTIONS
					vec3 rtPos = rayTrace(reflectedVector,fragpos.xyz, interleaved_gradientNoise(), fresnel, isEyeInWater == 1);
					if (rtPos.z < 1.){
						vec3 previousPosition = mat3(gbufferModelViewInverse) * toScreenSpace(rtPos) + gbufferModelViewInverse[3].xyz + cameraPosition-previousCameraPosition;
						previousPosition = mat3(gbufferPreviousModelView) * previousPosition + gbufferPreviousModelView[3].xyz;
						previousPosition.xy = projMAD(gbufferPreviousProjection, previousPosition).xy / -previousPosition.z * 0.5 + 0.5;
						if (previousPosition.x > 0.0 && previousPosition.y > 0.0 && previousPosition.x < 1.0 && previousPosition.x < 1.0) {
							Reflections.a = 1.0;
							Reflections.rgb = texture2D(colortex5,previousPosition.xy).rgb;
						}
					}
				#endif
			}


			Reflections_Final = mix(FinalColor, Reflections.rgb, Reflections.a * fresnel * visibilityFactor);


			float F2 = pow(clamp(1.0 + normalDotEye,0.0,1.0),pow(1.0-roughness,2.0) * 1.5 + 0.5);
			F2 = mix(f0, 1.0, F2); 

			Reflections_Final += mix( gl_Fog.color.rgb * 0.25, vec3(0.0), Reflections.a * visibilityFactor) ;

			gl_FragData[0].rgb = Reflections_Final;

			//correct alpha channel with fresnel
			float alpha0 = gl_FragData[0].a;
			gl_FragData[0].a = -gl_FragData[0].a*fresnel+gl_FragData[0].a+fresnel;

			if (gl_FragData[0].r > 65000.) gl_FragData[0].rgba = vec4(0.);


		} else {
			gl_FragData[0].rgb = FinalColor;
		}

		#ifndef HAND
			gl_FragData[1] = vec4(Albedo,iswater);
		#endif
	}
}