minetest_GLSLshaders/client/shaders/liquids_shader/opengl_fragment.glsl

uniform sampler2D baseTexture;
uniform sampler2D normalTexture;
uniform sampler2D reflectionTexture;

uniform float enable_bumpmapping;

uniform vec4 skyBgColor;
uniform float fogDistance;
uniform float timeOfDay;
uniform vec3 eyePosition;

varying vec3 vPosition;
varying vec2 uv;
varying vec3 viewVec;

varying vec4 fragPos; 
varying vec3 T, B, N; 
varying vec3 viewPos;
varying vec3 worldPos;
varying vec3 cameraPos;

uniform sampler2D reflectionSampler,refractionSampler,normalSampler;

//----------------
//tweakables

vec2 windDir = vec2(0.5, -0.8); //wind direction XY
float windSpeed = 0.05; //wind speed

float visibility = 18.0;

float scale = 0.2; //overall wave scale

vec2 bigWaves = vec2(0.3, 0.3); //strength of big waves
vec2 midWaves = vec2(0.3, 0.15); //strength of middle sized waves
vec2 smallWaves = vec2(0.15, 0.1); //strength of small waves

vec3 waterColor = vec3(0.2,0.4,0.5); //color of the water
float waterDensity = 0.0; //water density (0.0-1.0)
    
float choppy = 0.00; //wave choppyness
float aberration = 0.003; //chromatic aberration amount
float bump = 2.5; //overall water surface bumpyness
float reflBump = 0.20; //reflection distortion amount
float refrBump = 0.08; //refraction distortion amount

vec3 sunPos = vec3(0,0,0);
float sunSpec = 1000.0; //Sun specular hardness

float scatterAmount = 3.0; //amount of sunlight scattering of waves
vec3 scatterColor = vec3(0.0,1.0,0.95);// color of the sunlight scattering
//----------------

vec3 tangentSpace(vec3 v)
{
	vec3 vec;
	vec.xy=v.xy;
	vec.z=sqrt(1.0-dot(vec.xy,vec.xy));
	vec.xyz= normalize(vec.x*T+vec.y*B+vec.z*N);
	return vec;
}

float fresnel_dielectric(vec3 Incoming, vec3 Normal, float eta)
{
    /* compute fresnel reflectance without explicitly computing
       the refracted direction */
	float c = abs(dot(Incoming, Normal));
	float g = eta * eta - 1.0 + c * c;
	float result;

	if(g > 0.0) {
		g = sqrt(g);
		float A =(g - c)/(g + c);
		float B =(c *(g + c)- 1.0)/(c *(g - c)+ 1.0);
		result = 0.5 * A * A *(1.0 + B * B);
	}
	else
		result = 1.0;  /* TIR (no refracted component) */

	return result;
}



void main (void)
{

vec2 fragCoord = fragPos.xy;
	fragCoord = clamp(fragCoord,0.002,0.998);
	vec3 sunPos = vec3(0.0);
	sunPos.x=sin((timeOfDay-0.5)*3.14159);
	float timer = timeOfDay*1600;
	//cameraPos = eyePosition;

	//normal map
	vec2 nCoord = vec2(0.0); //normal coords
	uv = worldPos.xz;
	nCoord = uv * (scale * 0.05) + windDir * timer * (windSpeed*0.04);
	vec3 normal0 = 2.0 * texture2D(normalSampler, nCoord + vec2(-timer*0.015,-timer*0.005)).rgb - 1.0;
	nCoord = uv * (scale * 0.1) + windDir * timer * (windSpeed*0.08)-(normal0.xz)*choppy;
	vec3 normal1 = 2.0 * texture2D(normalSampler, nCoord + vec2(+timer*0.020,+timer*0.015)).rgb - 1.0;

	nCoord = uv * (scale * 0.25) + windDir * timer * (windSpeed*0.07)-(normal1.xz)*choppy;
	vec3 normal2 = 2.0 * texture2D(normalSampler, nCoord + vec2(-timer*0.04,-timer*0.03)).rgb - 1.0;
	nCoord = uv * (scale * 0.5) + windDir * timer * (windSpeed*0.09)-(normal2.xz)*choppy;
	vec3 normal3 = 2.0 * texture2D(normalSampler, nCoord + vec2(+timer*0.03,+timer*0.04)).rgb - 1.0;

	nCoord = uv * (scale* 1.0) + windDir * timer * (windSpeed*0.4)-(normal3.xz)*choppy;
	vec3 normal4 = 2.0 * texture2D(normalSampler, nCoord + vec2(-timer*0.02,+timer*0.1)).rgb - 1.0;  
	nCoord = uv * (scale * 2.0) + windDir * timer * (windSpeed*0.7)-(normal4.xz)*choppy;
	vec3 normal5 = 2.0 * texture2D(normalSampler, nCoord + vec2(+timer*0.1,-timer*0.06)).rgb - 1.0;

	vec3 normal = normalize(normal0 * bigWaves.x + normal1 * bigWaves.y +
                            normal2 * midWaves.x + normal3 * midWaves.y +
						    normal4 * smallWaves.x + normal5 * smallWaves.y);

    //normal.x = -normal.x; //in case you need to invert Red channel
    //normal.y = -normal.y; //in case you need to invert Green channel
   
    vec3 nVec = tangentSpace(normal*bump); //converting normals to tangent space    
    vec3 vVec = normalize(viewPos);
    vec3 lVec = normalize(sunPos);
    
    //normal for light scattering
	vec3 lNormal = normalize(normal0 * bigWaves.x*0.5 + normal1 * bigWaves.y*0.5 +
                            normal2 * midWaves.x*0.2 + normal3 * midWaves.y*0.2 +
						    normal4 * smallWaves.x*0.1 + normal5 * smallWaves.y*0.1);
    lNormal = tangentSpace(lNormal*bump);
    vec3 pNormal = tangentSpace(vec3(0.0));
    
	vec3 lR = reflect(lVec, lNormal);
    vec3 llR = reflect(lVec, pNormal);
    
    float sunFade = clamp((sunPos.x+50.0)/300.0,0.0,1.0);
    vec3 sunext = vec3(0.45, 0.55, 0.68);//sunlight extinction
    
	float s = clamp((dot(lR, vVec)*2.0-1.2), 0.0,1.0);
    float lightScatter = clamp((clamp(dot(-lVec,lNormal)*0.7+0.3,0.0,1.0)*s)*scatterAmount,0.0,1.0)*sunFade*clamp(1.0-exp(-(sunPos.x/500.0)),0.0,1.0);
    scatterColor = mix(vec3(scatterColor)*vec3(1.0,0.4,0.0), scatterColor, clamp(1.0-exp(-(sunPos.x/500.0)*sunext),0.0,1.0));
    
    //texture edge bleed removal
    float fade = 12.0;
    vec2 distortFade = vec2(0.0);
    distortFade.s = clamp(fragCoord.s*fade,0.0,1.0);
    distortFade.s -= clamp(1.0-(1.0-fragCoord.s)*fade,0.0,1.0);
    distortFade.t = clamp(fragCoord.t*fade,0.0,1.0);
    distortFade.t -= clamp(1.0-(1.0-fragCoord.t)*fade,0.0,1.0); 
    
    //vec3 reflection = texture2D(reflectionSampler, fragCoord+(nVec.st*reflBump*distortFade)).rgb;
	vec3 reflection = vec3(0.5, 0.5, 0.5);

    vec3 luminosity = vec3(0.30, 0.59, 0.11);
	float reflectivity = pow(dot(luminosity, reflection.rgb*2.0),3.0);
    
    vec3 R = reflect(vVec, nVec);

    float specular = pow(max(dot(R, lVec), 0.0),sunSpec)*reflectivity;
    vec3 specColor = mix(vec3(1.0,0.5,0.2), vec3(1.0,1.0,1.0), clamp(1.0-exp(-(sunPos.x*2.0)* sunext),0.0,1.0));

    vec2 rcoord = reflect(vVec,nVec).st;
    vec3 refraction = vec3(0.0,0.1,0.4);
    
    //refraction.r = texture2D(baseTexture, (fragCoord-(nVec.st*refrBump*distortFade))*1.0).r;
    //refraction.g = texture2D(baseTexture, (fragCoord-(nVec.st*refrBump*distortFade))*1.0-(rcoord*aberration)).g;
    //refraction.b = texture2D(baseTexture, (fragCoord-(nVec.st*refrBump*distortFade))*1.0-(rcoord*aberration*2.0)).b;
    
    //fresnel term
    float ior = 1.333;
    //ior = (cameraPos.y>0.0)?(1.333/1.0):(1.0/1.333); //air to water; water to air
    float eta = max(ior, 0.00001);
    float fresnel = fresnel_dielectric(-vVec,nVec,eta);
      
    float waterSunGradient = dot(normalize(cameraPos-worldPos), normalize(sunPos));
    waterSunGradient = clamp(pow(waterSunGradient*0.7+0.3,2.0),0.0,1.0);  
    vec3 waterSunColor = vec3(0.0,1.0,0.85)*waterSunGradient*0.5;
    
    float waterGradient = dot(normalize(cameraPos-worldPos), vec3(0.0,0.0,-1.0));
    waterGradient = clamp((waterGradient*0.5+0.5),0.2,1.0);
    vec3 watercolor = (vec3(0.0078, 0.5176, 0.700)+waterSunColor)*waterGradient*2.0;
    vec3 waterext = vec3(0.6, 0.9, 1.0);//water extinction
    
    watercolor = mix(watercolor*0.3*sunFade, watercolor, clamp(1.0-exp(-(sunPos.y/500.0)*sunext),0.0,1.0));
    
    float fog = length(cameraPos-worldPos)/visibility; 
    fog = (cameraPos.z<0.0)?fog:1.0;
    fog = clamp(fog,0.0,1.0);
    
    float darkness = visibility*2.0;
    darkness = clamp((cameraPos.z+darkness)/darkness,0.0,1.0);
    
    fresnel = clamp(fresnel,0.0,1.0);
        
    vec3 color = mix(mix(refraction,scatterColor,lightScatter),reflection,fresnel);
    //color = mix(clamp(refraction*1.5,0.0,1.0),reflection,fresnel);   
    //color = (cameraPos.z<0.0)?mix(color, watercolor*darkness, clamp(fog/ waterext,0.0,1.0)):color;
	
    color = color+ specColor*specular;
    float alpha = clamp((color.r+color.b+color.g)*1.2,0.1,0.7);
 
	vec4 col = vec4(color.r, color.g, color.b, alpha);
	col *= gl_Color;
	col = col * col; // SRGB -> Linear
	col *= 1.8;
	col.r = 1.0 - exp(1.0 - col.r) / exp(1.0);
	col.g = 1.0 - exp(1.0 - col.g) / exp(1.0);
	col.b = 1.0 - exp(1.0 - col.b) / exp(1.0);
	col = sqrt(col); // Linear -> SRGB
	if(fogDistance != 0.0){
		float d = max(0.0, min(vPosition.z / fogDistance * 1.5 - 0.6, 1.0));
		alpha = mix(alpha, 0.0, d);
	}

    gl_FragColor = vec4(col.r, col.g, col.b, alpha);   
}