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fgdata/Shaders/HDR/atmos_aerial_perspective.frag
Fernando García Liñán 82d415cbd4 HDR: Add remaining aerosol types
Now the properties of the atmospheric medium can be changed through the
property tree.
2023-04-16 07:19:22 +02:00

87 lines
2.9 KiB
GLSL

/*
* Render the aerial perspective LUT, similar to
* "A Scalable and Production Ready Sky and Atmosphere Rendering Technique"
* by Sébastien Hillaire (2020).
*
* Unlike the paper, we are using a tiled 2D texture instead of a true 3D
* texture. For some reason the overhead of rendering to a texture many times
* (the depth of the 3D texture) seems to be too high, probably because OSG is
* not sharing state between those passes.
*/
#version 330 core
layout(location = 0) out vec4 fragColor;
in vec2 texcoord;
uniform sampler2D transmittance_lut;
uniform mat4 fg_ViewMatrixInverse;
uniform vec3 fg_CameraPositionCart;
uniform vec3 fg_SunDirectionWorld;
const float AP_SLICE_COUNT = 32.0;
const float AP_MAX_DEPTH = 128000.0;
const int AERIAL_PERSPECTIVE_STEPS = 10;
const float RADIUS_OFFSET = 10.0;
// pos_from_depth.glsl
vec3 get_view_space_from_depth(vec2 uv, float depth);
// atmos.glsl
float get_earth_radius();
float get_ray_end(vec3 ray_origin, vec3 ray_dir, float t_max);
vec4 compute_inscattering(in vec3 ray_origin,
in vec3 ray_dir,
in float t_max,
in vec3 sun_dir,
in int steps,
in sampler2D transmittance_lut,
out vec4 transmittance);
// atmos_spectral.glsl
vec4 get_sun_spectral_irradiance();
vec3 linear_srgb_from_spectral_samples(vec4 L);
void main()
{
// Account for the depth slice we are currently in. Depth goes from 0 to
// DEPTH_RANGE in a squared distribution. The first slice is not 0 since
// that would waste a slice.
float x = texcoord.x * AP_SLICE_COUNT;
float slice = ceil(x);
float w = slice / AP_SLICE_COUNT; // [0,1]
float depth = w*w * AP_MAX_DEPTH;
vec2 coord = vec2(fract(x), texcoord.y);
vec3 frag_pos = get_view_space_from_depth(coord, 1.0);
vec3 ray_dir = vec4(fg_ViewMatrixInverse * vec4(normalize(frag_pos), 0.0)).xyz;
vec3 ray_origin = fg_CameraPositionCart;
vec3 ray_end = ray_origin + ray_dir * depth;
float t_max = depth;
if (length(ray_end) <= (get_earth_radius() + RADIUS_OFFSET)) {
ray_end = normalize(ray_end) * (get_earth_radius() + RADIUS_OFFSET + 1.0);
ray_dir = ray_end - ray_origin;
t_max = length(ray_dir);
ray_dir /= t_max;
}
vec4 transmittance;
vec4 L = compute_inscattering(ray_origin,
ray_dir,
t_max,
fg_SunDirectionWorld,
AERIAL_PERSPECTIVE_STEPS,
transmittance_lut,
transmittance);
// In-scattering
fragColor.rgb = linear_srgb_from_spectral_samples(
L * get_sun_spectral_irradiance());
// Transmittance
fragColor.a = dot(transmittance, vec4(0.25));
}