veloren/assets/voxygen/shaders/clouds-frag.glsl
2022-07-10 16:40:49 +01:00

200 lines
7.5 KiB
GLSL

#version 420 core
#include <constants.glsl>
#define LIGHTING_TYPE (LIGHTING_TYPE_TRANSMISSION | LIGHTING_TYPE_REFLECTION)
#define LIGHTING_REFLECTION_KIND LIGHTING_REFLECTION_KIND_SPECULAR
#if (FLUID_MODE == FLUID_MODE_CHEAP)
#define LIGHTING_TRANSPORT_MODE LIGHTING_TRANSPORT_MODE_IMPORTANCE
#elif (FLUID_MODE == FLUID_MODE_SHINY)
#define LIGHTING_TRANSPORT_MODE LIGHTING_TRANSPORT_MODE_RADIANCE
#endif
#define LIGHTING_DISTRIBUTION_SCHEME LIGHTING_DISTRIBUTION_SCHEME_MICROFACET
#define LIGHTING_DISTRIBUTION LIGHTING_DISTRIBUTION_BECKMANN
// Must come before includes
#define IS_POSTPROCESS
#include <globals.glsl>
// Note: The sampler uniform is declared here because it differs for MSAA
#include <anti-aliasing.glsl>
#include <srgb.glsl>
#include <cloud.glsl>
#include <light.glsl>
// This *MUST* come after `cloud.glsl`: it contains a function that depends on `cloud.glsl` when clouds are enabled
#include <point_glow.glsl>
layout(set = 2, binding = 0)
uniform texture2D t_src_color;
layout(set = 2, binding = 1)
uniform sampler s_src_color;
layout(set = 2, binding = 2)
uniform texture2D t_src_depth;
layout(set = 2, binding = 3)
uniform sampler s_src_depth;
layout(location = 0) in vec2 uv;
layout (std140, set = 2, binding = 4)
uniform u_locals {
mat4 all_mat_inv;
};
layout(location = 0) out vec4 tgt_color;
vec3 wpos_at(vec2 uv) {
float buf_depth = texture(sampler2D(t_src_depth, s_src_depth), uv).x;
vec4 clip_space = vec4((uv * 2.0 - 1.0) * vec2(1, -1), buf_depth, 1.0);
vec4 view_space = all_mat_inv * clip_space;
view_space /= view_space.w;
if (buf_depth == 0.0) {
vec3 direction = normalize(view_space.xyz);
return direction.xyz * 524288.0625 + cam_pos.xyz;
} else {
return view_space.xyz;
}
}
void main() {
vec4 color = texture(sampler2D(t_src_color, s_src_color), uv);
#ifdef EXPERIMENTAL_BAREMINIMUM
tgt_color = vec4(color.rgb, 1);
return;
#endif
vec3 wpos = wpos_at(uv);
float dist = distance(wpos, cam_pos.xyz);
vec3 dir = (wpos - cam_pos.xyz) / dist;
// Apply clouds
float cloud_blend = 1.0;
if (color.a < 1.0) {
cloud_blend = 1.0 - color.a;
dist = DIST_CAP;
}
color.rgb = mix(color.rgb, get_cloud_color(color.rgb, dir, cam_pos.xyz, time_of_day.x, dist, 1.0), cloud_blend);
#if (CLOUD_MODE == CLOUD_MODE_NONE)
color.rgb = apply_point_glow(cam_pos.xyz + focus_off.xyz, dir, dist, color.rgb);
#elif (0 == 0)
if (medium.x == MEDIUM_AIR && rain_density > 0.001) {
vec3 cam_wpos = cam_pos.xyz + focus_off.xyz;
vec3 adjusted_dir = (vec4(dir, 0) * rain_dir_mat).xyz;
vec2 dir2d = adjusted_dir.xy;
vec3 rorigin = cam_pos.xyz + focus_off.xyz + 0.5;
vec3 rpos = vec3(0.0);
float t = 0.0;
const float PLANCK = 0.01;
while (true) {
float scale = min(pow(2, ceil(t / 2.0)), 32);
vec2 deltas = (step(vec2(0), dir2d) - fract(rpos.xy / scale + 100.0)) / dir2d;
float jump = max(min(deltas.x, deltas.y) * scale, PLANCK);
t += jump;
if (t >= 64.0) { break; }
rpos = rorigin + adjusted_dir * t;
vec2 diff = abs(round(rpos.xy) - rpos.xy);
vec3 wall_pos = vec3((diff.x > diff.y) ? rpos.xy : rpos.yx, rpos.z + integrated_rain_vel);
wall_pos.xz *= vec2(4, 0.3);
wall_pos.z += hash_two(uvec2(wall_pos.xy + vec2(0, 0.5)));
float depth_adjust = fract(hash_two(uvec2(wall_pos.xz) + 500u));
float wpos_dist = t - jump * depth_adjust;
vec3 wpos = cam_pos.xyz + dir * wpos_dist;
if (wpos_dist > dist) { break; }
if (length((fract(wall_pos.xz) - 0.5)) < 0.1 + pow(max(0.0, wpos_dist - (dist - 0.25)) / 0.25, 4.0) * 0.2) {
float density = rain_density * rain_occlusion_at(wpos);
if (fract(hash_two(uvec2(wall_pos.xz) + 1000u)) >= density) { continue; }
float alpha = 0.5 * clamp((wpos_dist - 1.0) * 0.5, 0.0, 1.0);
float light = dot(color.rgb, vec3(1)) + 0.05 + (get_sun_brightness() + get_moon_brightness()) * 0.2;
color.rgb = mix(color.rgb, vec3(0.3, 0.35, 0.5) * light, alpha);
}
}
}
#else
vec3 old_color = color.rgb;
// normalized direction from the camera position to the fragment in world, transformed by the relative rain direction
vec3 adjusted_dir = (vec4(dir, 0) * rain_dir_mat).xyz;
// stretch z values as they move away from 0
float z = (-1 / (abs(adjusted_dir.z) - 1) - 1) * sign(adjusted_dir.z);
// normalize xy to get a 2d direction
vec2 dir_2d = normalize(adjusted_dir.xy);
// sort of map cylinder around the camera to 2d grid
vec2 view_pos = vec2(atan2(dir_2d.x, dir_2d.y), z);
// compute camera position in the world
vec3 cam_wpos = cam_pos.xyz + focus_off.xyz;
// Rain density is now only based on the cameras current position.
// This could be affected by a setting where rain_density_at is instead
// called each iteration of the loop. With the current implementation
// of rain_dir this has issues with being in a place where it doesn't rain
// and seeing rain.
float rain_density = rain_density * 1.0;
if (medium.x == MEDIUM_AIR && rain_density > 0.0) {
float rain_dist = 50.0;
#if (CLOUD_MODE <= CLOUD_MODE_LOW)
const int iterations = 2;
#else
const int iterations = 4;
#endif
for (int i = 0; i < iterations; i ++) {
float old_rain_dist = rain_dist;
rain_dist *= 0.3 / 4.0 * iterations;
vec2 drop_density = vec2(30, 1);
vec2 rain_pos = (view_pos * rain_dist);
rain_pos.y += integrated_rain_vel;
vec2 cell = floor(rain_pos * drop_density) / drop_density;
float drop_depth = mix(
old_rain_dist,
rain_dist,
fract(hash(fract(vec4(cell, rain_dist, 0) * 0.1)))
);
float dist_to_rain = drop_depth / length(dir.xy);
vec3 rpos = dir * dist_to_rain;
if (dist < dist_to_rain || cam_wpos.z + rpos.z > CLOUD_AVG_ALT) {
continue;
}
if (dot(rpos * vec3(1, 1, 0.5), rpos) < 1.0) {
break;
}
float rain_density = 10.0 * rain_density * floor(rain_occlusion_at(cam_pos.xyz + rpos.xyz));
if (rain_density < 0.001 || fract(hash(fract(vec4(cell, rain_dist, 0) * 0.01))) > rain_density) {
continue;
}
vec2 near_drop = cell + (vec2(0.5) + (vec2(hash(vec4(cell, 0, 0)), 0.5) - 0.5) * vec2(2, 0)) / drop_density;
vec2 drop_size = vec2(0.0008, 0.03);
float avg_alpha = (drop_size.x * drop_size.y) * 10 / 1;
float alpha = sign(max(1 - length((rain_pos - near_drop) / drop_size * 0.1), 0));
float light = sqrt(dot(old_color, vec3(1))) + (get_sun_brightness() + get_moon_brightness()) * 0.01;
color.rgb = mix(color.rgb, vec3(0.3, 0.4, 0.5) * light, mix(avg_alpha, alpha, min(1000 / dist_to_rain, 1)) * 0.25);
}
}
#endif
tgt_color = vec4(color.rgb, 1);
}