Antialias direct light samples in LightmapperRD

Additionally use Vogel disk to enhance soft shadow quality.
This commit is contained in:
clayjohn 2024-08-18 01:10:48 -07:00
parent 96be44c0ec
commit 1521e49c23
2 changed files with 106 additions and 41 deletions

View File

@ -1584,9 +1584,6 @@ LightmapperRD::BakeError LightmapperRD::bake(BakeQuality p_quality, bool p_use_d
#endif #endif
/* SECONDARY (indirect) LIGHT PASS(ES) */ /* SECONDARY (indirect) LIGHT PASS(ES) */
if (p_step_function) {
p_step_function(0.6, RTR("Integrate indirect lighting"), p_bake_userdata, true);
}
if (p_bounces > 0) { if (p_bounces > 0) {
Vector<RD::Uniform> uniforms; Vector<RD::Uniform> uniforms;
@ -1650,6 +1647,10 @@ LightmapperRD::BakeError LightmapperRD::bake(BakeQuality p_quality, bool p_use_d
rd->submit(); rd->submit();
rd->sync(); rd->sync();
if (p_step_function) {
p_step_function(0.6, RTR("Integrate indirect lighting"), p_bake_userdata, true);
}
int count = 0; int count = 0;
for (int s = 0; s < atlas_slices; s++) { for (int s = 0; s < atlas_slices; s++) {
push_constant.atlas_slice = s; push_constant.atlas_slice = s;

View File

@ -359,7 +359,36 @@ float get_omni_attenuation(float distance, float inv_range, float decay) {
return nd * pow(max(distance, 0.0001), -decay); return nd * pow(max(distance, 0.0001), -decay);
} }
void trace_direct_light(vec3 p_position, vec3 p_normal, uint p_light_index, bool p_soft_shadowing, out vec3 r_light, out vec3 r_light_dir, inout uint r_noise) { const int AA_SAMPLES = 16;
const vec2 halton_map[AA_SAMPLES] = vec2[](
vec2(0.5, 0.33333333),
vec2(0.25, 0.66666667),
vec2(0.75, 0.11111111),
vec2(0.125, 0.44444444),
vec2(0.625, 0.77777778),
vec2(0.375, 0.22222222),
vec2(0.875, 0.55555556),
vec2(0.0625, 0.88888889),
vec2(0.5625, 0.03703704),
vec2(0.3125, 0.37037037),
vec2(0.8125, 0.7037037),
vec2(0.1875, 0.14814815),
vec2(0.6875, 0.48148148),
vec2(0.4375, 0.81481481),
vec2(0.9375, 0.25925926),
vec2(0.03125, 0.59259259));
vec2 get_vogel_disk(float p_i, float p_rotation, float p_sample_count_sqrt) {
const float golden_angle = 2.4;
float r = sqrt(p_i + 0.5) / p_sample_count_sqrt;
float theta = p_i * golden_angle + p_rotation;
return vec2(cos(theta), sin(theta)) * r;
}
void trace_direct_light(vec3 p_position, vec3 p_normal, uint p_light_index, bool p_soft_shadowing, out vec3 r_light, out vec3 r_light_dir, inout uint r_noise, float p_texel_size) {
r_light = vec3(0.0f); r_light = vec3(0.0f);
vec3 light_pos; vec3 light_pos;
@ -407,46 +436,70 @@ void trace_direct_light(vec3 p_position, vec3 p_normal, uint p_light_index, bool
} }
float penumbra = 0.0; float penumbra = 0.0;
if ((light_data.size > 0.0) && p_soft_shadowing) { if (p_soft_shadowing) {
const bool use_soft_shadows = (light_data.size > 0.0);
const uint ray_count = AA_SAMPLES;
const uint total_ray_count = use_soft_shadows ? params.ray_count : ray_count;
const uint shadowing_rays_check_penumbra_denom = 2;
const uint shadowing_ray_count = max(1, params.ray_count / ray_count);
const float shadowing_ray_count_sqrt = sqrt(float(total_ray_count));
// Setup tangent pass to calculate AA samples over the current texel.
vec3 aux = p_normal.y < 0.777 ? vec3(0.0, 1.0, 0.0) : vec3(1.0, 0.0, 0.0);
vec3 tangent = normalize(cross(p_normal, aux));
vec3 bitan = normalize(cross(p_normal, tangent));
// Setup light tangent pass to calculate samples over disk aligned towards the light
vec3 light_to_point = -r_light_dir; vec3 light_to_point = -r_light_dir;
vec3 aux = light_to_point.y < 0.777 ? vec3(0.0, 1.0, 0.0) : vec3(1.0, 0.0, 0.0); vec3 light_aux = light_to_point.y < 0.777 ? vec3(0.0, 1.0, 0.0) : vec3(1.0, 0.0, 0.0);
vec3 light_to_point_tan = normalize(cross(light_to_point, aux)); vec3 light_to_point_tan = normalize(cross(light_to_point, light_aux));
vec3 light_to_point_bitan = normalize(cross(light_to_point, light_to_point_tan)); vec3 light_to_point_bitan = normalize(cross(light_to_point, light_to_point_tan));
const uint shadowing_rays_check_penumbra_denom = 2;
uint shadowing_ray_count = p_soft_shadowing ? params.ray_count : 1;
uint hits = 0; uint hits = 0;
vec3 light_disk_to_point = light_to_point; for (uint i = 0; i < ray_count; i++) {
for (uint j = 0; j < shadowing_ray_count; j++) { // Create a random sample within the texel.
// Optimization: vec2 disk_sample = (halton_map[i] - vec2(0.5)) * p_texel_size * light_data.shadow_blur;
// Once already traced an important proportion of rays, if all are hits or misses, // Align the sample to world space.
// assume we're not in the penumbra so we can infer the rest would have the same result vec3 disk_aligned = (disk_sample.x * tangent + disk_sample.y * bitan);
if (p_soft_shadowing) { vec3 origin = p_position - disk_aligned;
if (j == shadowing_ray_count / shadowing_rays_check_penumbra_denom) { vec3 light_dir = normalize(light_pos - origin);
if (hits == j) {
// Assume totally lit if (use_soft_shadows) {
hits = shadowing_ray_count; uint soft_shadow_hits = 0;
break; for (uint j = 0; j < shadowing_ray_count; j++) {
} else if (hits == 0) { // Optimization:
// Assume totally dark // Once already traced an important proportion of rays, if all are hits or misses,
hits = 0; // assume we're not in the penumbra so we can infer the rest would have the same result.
break; if (j == shadowing_ray_count / shadowing_rays_check_penumbra_denom) {
if (soft_shadow_hits == j) {
// Assume totally lit
soft_shadow_hits = shadowing_ray_count;
break;
} else if (soft_shadow_hits == 0) {
// Assume totally dark
soft_shadow_hits = 0;
break;
}
}
float a = randomize(r_noise) * 2.0 * PI;
float vogel_index = float(total_ray_count - 1 - (i * shadowing_ray_count + j)); // Start from (total_ray_count - 1) so we check the outer points first.
vec2 light_disk_sample = (get_vogel_disk(vogel_index, a, shadowing_ray_count_sqrt)) * soft_shadowing_disk_size * light_data.shadow_blur;
vec3 light_disk_to_point = normalize(light_to_point + light_disk_sample.x * light_to_point_tan + light_disk_sample.y * light_to_point_bitan);
// Offset the ray origin for AA, offset the light position for soft shadows.
if (trace_ray_any_hit(origin - light_disk_to_point * (bake_params.bias + length(disk_sample)), p_position - light_disk_to_point * dist) == RAY_MISS) {
soft_shadow_hits++;
} }
} }
} hits += soft_shadow_hits;
} else {
float r = randomize(r_noise); // Offset the ray origin based on the disk. Also increase the bias for further samples to avoid bleeding.
float a = randomize(r_noise) * 2.0 * PI; if (trace_ray_any_hit(origin + light_dir * (bake_params.bias + length(disk_sample)), light_pos) == RAY_MISS) {
vec2 disk_sample = (r * vec2(cos(a), sin(a))) * soft_shadowing_disk_size * light_data.shadow_blur; hits++;
light_disk_to_point = normalize(light_to_point + disk_sample.x * light_to_point_tan + disk_sample.y * light_to_point_bitan); }
if (trace_ray_any_hit(p_position - light_disk_to_point * bake_params.bias, p_position - light_disk_to_point * dist) == RAY_MISS) {
hits++;
} }
} }
penumbra = float(hits) / float(total_ray_count);
penumbra = float(hits) / float(shadowing_ray_count);
} else { } else {
if (trace_ray_any_hit(p_position + r_light_dir * bake_params.bias, light_pos) == RAY_MISS) { if (trace_ray_any_hit(p_position + r_light_dir * bake_params.bias, light_pos) == RAY_MISS) {
penumbra = 1.0; penumbra = 1.0;
@ -470,7 +523,7 @@ vec3 trace_environment_color(vec3 ray_dir) {
return textureLod(sampler2D(environment, linear_sampler), st / vec2(PI * 2.0, PI), 0.0).rgb; return textureLod(sampler2D(environment, linear_sampler), st / vec2(PI * 2.0, PI), 0.0).rgb;
} }
vec3 trace_indirect_light(vec3 p_position, vec3 p_ray_dir, inout uint r_noise) { vec3 trace_indirect_light(vec3 p_position, vec3 p_ray_dir, inout uint r_noise, float p_texel_size) {
// The lower limit considers the case where the lightmapper might have bounces disabled but light probes are requested. // The lower limit considers the case where the lightmapper might have bounces disabled but light probes are requested.
vec3 position = p_position; vec3 position = p_position;
vec3 ray_dir = p_ray_dir; vec3 ray_dir = p_ray_dir;
@ -502,7 +555,7 @@ vec3 trace_indirect_light(vec3 p_position, vec3 p_ray_dir, inout uint r_noise) {
for (uint i = 0; i < bake_params.light_count; i++) { for (uint i = 0; i < bake_params.light_count; i++) {
vec3 light; vec3 light;
vec3 light_dir; vec3 light_dir;
trace_direct_light(position, normal, i, false, light, light_dir, r_noise); trace_direct_light(position, normal, i, false, light, light_dir, r_noise, p_texel_size);
direct_light += light * lights.data[i].indirect_energy; direct_light += light * lights.data[i].indirect_energy;
} }
@ -566,6 +619,14 @@ void main() {
return; //empty texel, no process return; //empty texel, no process
} }
vec3 position = texelFetch(sampler2DArray(source_position, linear_sampler), ivec3(atlas_pos, params.atlas_slice), 0).xyz; vec3 position = texelFetch(sampler2DArray(source_position, linear_sampler), ivec3(atlas_pos, params.atlas_slice), 0).xyz;
vec4 neighbor_position = texelFetch(sampler2DArray(source_position, linear_sampler), ivec3(atlas_pos + ivec2(1, 0), params.atlas_slice), 0).xyzw;
if (neighbor_position.w < 0.001) {
// Empty texel, try again.
neighbor_position.xyz = texelFetch(sampler2DArray(source_position, linear_sampler), ivec3(atlas_pos + ivec2(-1, 0), params.atlas_slice), 0).xyz;
}
float texel_size_world_space = distance(position, neighbor_position.xyz);
vec3 light_for_texture = vec3(0.0); vec3 light_for_texture = vec3(0.0);
vec3 light_for_bounces = vec3(0.0); vec3 light_for_bounces = vec3(0.0);
@ -582,7 +643,7 @@ void main() {
for (uint i = 0; i < bake_params.light_count; i++) { for (uint i = 0; i < bake_params.light_count; i++) {
vec3 light; vec3 light;
vec3 light_dir; vec3 light_dir;
trace_direct_light(position, normal, i, true, light, light_dir, noise); trace_direct_light(position, normal, i, true, light, light_dir, noise, texel_size_world_space);
if (lights.data[i].static_bake) { if (lights.data[i].static_bake) {
light_for_texture += light; light_for_texture += light;
@ -640,10 +701,13 @@ void main() {
} }
vec3 position = texelFetch(sampler2DArray(source_position, linear_sampler), ivec3(atlas_pos, params.atlas_slice), 0).xyz; vec3 position = texelFetch(sampler2DArray(source_position, linear_sampler), ivec3(atlas_pos, params.atlas_slice), 0).xyz;
int neighbor_offset = atlas_pos.x < bake_params.atlas_size.x - 1 ? 1 : -1;
vec3 neighbor_position = texelFetch(sampler2DArray(source_position, linear_sampler), ivec3(atlas_pos + ivec2(neighbor_offset, 0), params.atlas_slice), 0).xyz;
float texel_size_world_space = distance(position, neighbor_position);
uint noise = random_seed(ivec3(params.ray_from, atlas_pos)); uint noise = random_seed(ivec3(params.ray_from, atlas_pos));
for (uint i = params.ray_from; i < params.ray_to; i++) { for (uint i = params.ray_from; i < params.ray_to; i++) {
vec3 ray_dir = generate_ray_dir_from_normal(normal, noise); vec3 ray_dir = generate_ray_dir_from_normal(normal, noise);
vec3 light = trace_indirect_light(position, ray_dir, noise); vec3 light = trace_indirect_light(position, ray_dir, noise, texel_size_world_space);
#ifdef USE_SH_LIGHTMAPS #ifdef USE_SH_LIGHTMAPS
float c[4] = float[]( float c[4] = float[](
@ -737,7 +801,7 @@ void main() {
uint noise = random_seed(ivec3(params.ray_from, probe_index, 49502741 /* some prime */)); uint noise = random_seed(ivec3(params.ray_from, probe_index, 49502741 /* some prime */));
for (uint i = params.ray_from; i < params.ray_to; i++) { for (uint i = params.ray_from; i < params.ray_to; i++) {
vec3 ray_dir = generate_sphere_uniform_direction(noise); vec3 ray_dir = generate_sphere_uniform_direction(noise);
vec3 light = trace_indirect_light(position, ray_dir, noise); vec3 light = trace_indirect_light(position, ray_dir, noise, 0.0);
float c[9] = float[]( float c[9] = float[](
0.282095, //l0 0.282095, //l0