RuntimeData/shader/Atomsphere.frag

#version 450 core

#define PI 3.141592
#define iSteps 16
#define jSteps 8

layout(location = 0) in vec4 FragmentVertex;

layout(location = 0) out vec4 FragColor;

layout(binding = 1) uniform AtomSphere
{
    vec3 position;
    float intensity;
    float scattering_direction;
}sun;

vec2 rsi(vec3 r0, vec3 rd, float sr) {
    // ray-sphere intersection that assumes
    // the sphere is centered at the origin.
    // No intersection when result.x > result.y
    float a = dot(rd, rd);
    float b = 2.0 * dot(rd, r0);
    float c = dot(r0, r0) - (sr * sr);
    float d = (b*b) - 4.0*a*c;
    if (d < 0.0) return vec2(1e5,-1e5);
    return vec2(
        (-b - sqrt(d))/(2.0*a),
        (-b + sqrt(d))/(2.0*a)
    );
}

vec3 atmosphere(vec3 r, vec3 r0, vec3 pSun, float iSun, float rPlanet, float rAtmos, vec3 kRlh, float kMie, float shRlh, float shMie, float g) 
{
    // Normalize the sun and view directions.
    pSun = normalize(pSun);
    r = normalize(r);

    // Calculate the step size of the primary ray.
    vec2 p = rsi(r0, r, rAtmos);
    if (p.x > p.y) return vec3(0,0,0);
    p.y = min(p.y, rsi(r0, r, rPlanet).x);
    float iStepSize = (p.y - p.x) / float(iSteps);

    // Initialize the primary ray time.
    float iTime = 0.0;

    // Initialize accumulators for Rayleigh and Mie scattering.
    vec3 totalRlh = vec3(0,0,0);
    vec3 totalMie = vec3(0,0,0);

    // Initialize optical depth accumulators for the primary ray.
    float iOdRlh = 0.0;
    float iOdMie = 0.0;

    // Calculate the Rayleigh and Mie phases.
    float mu = dot(r, pSun);
    float mumu = mu * mu;
    float gg = g * g;
    float pRlh = 3.0 / (16.0 * PI) * (1.0 + mumu);
    float pMie = 3.0 / (8.0 * PI) * ((1.0 - gg) * (mumu + 1.0)) / (pow(1.0 + gg - 2.0 * mu * g, 1.5) * (2.0 + gg));

    // Sample the primary ray.
    for (int i = 0; i < iSteps; i++) {

        // Calculate the primary ray sample position.
        vec3 iPos = r0 + r * (iTime + iStepSize * 0.5);

        // Calculate the height of the sample.
        float iHeight = length(iPos) - rPlanet;

        // Calculate the optical depth of the Rayleigh and Mie scattering for this step.
        float odStepRlh = exp(-iHeight / shRlh) * iStepSize;
        float odStepMie = exp(-iHeight / shMie) * iStepSize;

        // Accumulate optical depth.
        iOdRlh += odStepRlh;
        iOdMie += odStepMie;

        // Calculate the step size of the secondary ray.
        float jStepSize = rsi(iPos, pSun, rAtmos).y / float(jSteps);

        // Initialize the secondary ray time.
        float jTime = 0.0;

        // Initialize optical depth accumulators for the secondary ray.
        float jOdRlh = 0.0;
        float jOdMie = 0.0;

        // Sample the secondary ray.
        for (int j = 0; j < jSteps; j++) {

            // Calculate the secondary ray sample position.
            vec3 jPos = iPos + pSun * (jTime + jStepSize * 0.5);

            // Calculate the height of the sample.
            float jHeight = length(jPos) - rPlanet;

            // Accumulate the optical depth.
            jOdRlh += exp(-jHeight / shRlh) * jStepSize;
            jOdMie += exp(-jHeight / shMie) * jStepSize;

            // Increment the secondary ray time.
            jTime += jStepSize;
        }

        // Calculate attenuation.
        vec3 attn = exp(-(kMie * (iOdMie + jOdMie) + kRlh * (iOdRlh + jOdRlh)));

        // Accumulate scattering.
        totalRlh += odStepRlh * attn;
        totalMie += odStepMie * attn;

        // Increment the primary ray time.
        iTime += iStepSize;
    }

    // Calculate and return the final color.
    return iSun * (pRlh * kRlh * totalRlh + pMie * kMie * totalMie);
}

void main()
{
    vec3 nrd=vec3(FragmentVertex.x,-FragmentVertex.y,FragmentVertex.z);       //vulkan coord to opengl(shader from opengl sample)

    vec3 color=atmosphere(
        nrd,                            // normalized ray direction
        vec3(0,6372e3,0),               // ray origin
        sun.position,                   // position of the sun
        sun.intensity,                  // intensity of the sun
        6371e3,                         // radius of the planet in meters
        6471e3,                         // radius of the atmosphere in meters
        vec3(5.5e-6, 13.0e-6, 22.4e-6), // Rayleigh scattering coefficient
        21e-6,                          // Mie scattering coefficient
        8e3,                            // Rayleigh scale height
        1.2e3,                          // Mie scale height
        sun.scattering_direction        // Mie preferred scattering direction
    );

    FragColor=vec4(1.0-exp(-color),1);
}
first commit 2020-04-07 19:00:37 +08:00			`#version 450 core`

			`#define PI 3.141592`
			`#define iSteps 16`
			`#define jSteps 8`

			`layout(location = 0) in vec4 FragmentVertex;`

			`layout(location = 0) out vec4 FragColor;`

			`layout(binding = 1) uniform AtomSphere`
			`{`
			`vec3 position;`
			`float intensity;`
			`float scattering_direction;`
			`}sun;`

			`vec2 rsi(vec3 r0, vec3 rd, float sr) {`
			`// ray-sphere intersection that assumes`
			`// the sphere is centered at the origin.`
			`// No intersection when result.x > result.y`
			`float a = dot(rd, rd);`
			`float b = 2.0 * dot(rd, r0);`
			`float c = dot(r0, r0) - (sr * sr);`
			`float d = (bb) - 4.0a*c;`
			`if (d < 0.0) return vec2(1e5,-1e5);`
			`return vec2(`
			`(-b - sqrt(d))/(2.0*a),`
			`(-b + sqrt(d))/(2.0*a)`
			`);`
			`}`

			`vec3 atmosphere(vec3 r, vec3 r0, vec3 pSun, float iSun, float rPlanet, float rAtmos, vec3 kRlh, float kMie, float shRlh, float shMie, float g)`
			`{`
			`// Normalize the sun and view directions.`
			`pSun = normalize(pSun);`
			`r = normalize(r);`

			`// Calculate the step size of the primary ray.`
			`vec2 p = rsi(r0, r, rAtmos);`
			`if (p.x > p.y) return vec3(0,0,0);`
			`p.y = min(p.y, rsi(r0, r, rPlanet).x);`
			`float iStepSize = (p.y - p.x) / float(iSteps);`

			`// Initialize the primary ray time.`
			`float iTime = 0.0;`

			`// Initialize accumulators for Rayleigh and Mie scattering.`
			`vec3 totalRlh = vec3(0,0,0);`
			`vec3 totalMie = vec3(0,0,0);`

			`// Initialize optical depth accumulators for the primary ray.`
			`float iOdRlh = 0.0;`
			`float iOdMie = 0.0;`

			`// Calculate the Rayleigh and Mie phases.`
			`float mu = dot(r, pSun);`
			`float mumu = mu * mu;`
			`float gg = g * g;`
			`float pRlh = 3.0 / (16.0 * PI) * (1.0 + mumu);`
			`float pMie = 3.0 / (8.0 * PI) * ((1.0 - gg) * (mumu + 1.0)) / (pow(1.0 + gg - 2.0 * mu * g, 1.5) * (2.0 + gg));`

			`// Sample the primary ray.`
			`for (int i = 0; i < iSteps; i++) {`

			`// Calculate the primary ray sample position.`
			`vec3 iPos = r0 + r * (iTime + iStepSize * 0.5);`

			`// Calculate the height of the sample.`
			`float iHeight = length(iPos) - rPlanet;`

			`// Calculate the optical depth of the Rayleigh and Mie scattering for this step.`
			`float odStepRlh = exp(-iHeight / shRlh) * iStepSize;`
			`float odStepMie = exp(-iHeight / shMie) * iStepSize;`

			`// Accumulate optical depth.`
			`iOdRlh += odStepRlh;`
			`iOdMie += odStepMie;`

			`// Calculate the step size of the secondary ray.`
			`float jStepSize = rsi(iPos, pSun, rAtmos).y / float(jSteps);`

			`// Initialize the secondary ray time.`
			`float jTime = 0.0;`

			`// Initialize optical depth accumulators for the secondary ray.`
			`float jOdRlh = 0.0;`
			`float jOdMie = 0.0;`

			`// Sample the secondary ray.`
			`for (int j = 0; j < jSteps; j++) {`

			`// Calculate the secondary ray sample position.`
			`vec3 jPos = iPos + pSun * (jTime + jStepSize * 0.5);`

			`// Calculate the height of the sample.`
			`float jHeight = length(jPos) - rPlanet;`

			`// Accumulate the optical depth.`
			`jOdRlh += exp(-jHeight / shRlh) * jStepSize;`
			`jOdMie += exp(-jHeight / shMie) * jStepSize;`

			`// Increment the secondary ray time.`
			`jTime += jStepSize;`
			`}`

			`// Calculate attenuation.`
			`vec3 attn = exp(-(kMie * (iOdMie + jOdMie) + kRlh * (iOdRlh + jOdRlh)));`

			`// Accumulate scattering.`
			`totalRlh += odStepRlh * attn;`
			`totalMie += odStepMie * attn;`

			`// Increment the primary ray time.`
			`iTime += iStepSize;`
			`}`

			`// Calculate and return the final color.`
			`return iSun * (pRlh * kRlh * totalRlh + pMie * kMie * totalMie);`
			`}`

			`void main()`
			`{`
			`vec3 nrd=vec3(FragmentVertex.x,-FragmentVertex.y,FragmentVertex.z); //vulkan coord to opengl(shader from opengl sample)`

			`vec3 color=atmosphere(`
			`nrd, // normalized ray direction`
			`vec3(0,6372e3,0), // ray origin`
			`sun.position, // position of the sun`
			`sun.intensity, // intensity of the sun`
			`6371e3, // radius of the planet in meters`
			`6471e3, // radius of the atmosphere in meters`
			`vec3(5.5e-6, 13.0e-6, 22.4e-6), // Rayleigh scattering coefficient`
			`21e-6, // Mie scattering coefficient`
			`8e3, // Rayleigh scale height`
			`1.2e3, // Mie scale height`
			`sun.scattering_direction // Mie preferred scattering direction`
			`);`

			`FragColor=vec4(1.0-exp(-color),1);`
			`}`