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uniform sampler2DArrayShadow shadowCubeTexture;
uniform sampler2DArrayShadow shadowCascadeTexture;
#define LAMPS_LIB
layout(std140) uniform shadow_block
{
ShadowData shadows_data[MAX_SHADOW];
ShadowCubeData shadows_cube_data[MAX_SHADOW_CUBE];
ShadowCascadeData shadows_cascade_data[MAX_SHADOW_CASCADE];
};
layout(std140) uniform light_block
{
LightData lights_data[MAX_LIGHT];
};
/* type */
#define POINT 0.0
#define SUN 1.0
#define SPOT 2.0
#define AREA_RECT 4.0
/* Used to define the area light shape, doesn't directly correspond to a Blender light type. */
#define AREA_ELLIPSE 100.0
float cubeFaceIndexEEVEE(vec3 P)
{
vec3 aP = abs(P);
if (all(greaterThan(aP.xx, aP.yz))) {
return (P.x > 0.0) ? 0.0 : 1.0;
}
else if (all(greaterThan(aP.yy, aP.xz))) {
return (P.y > 0.0) ? 2.0 : 3.0;
}
else {
return (P.z > 0.0) ? 4.0 : 5.0;
}
}
vec2 cubeFaceCoordEEVEE(vec3 P, float face)
{
if (face < 2.0) {
return (P.zy / P.x) * vec2(-0.5, -sign(P.x) * 0.5) + 0.5;
}
else if (face < 4.0) {
return (P.xz / P.y) * vec2(sign(P.y) * 0.5, 0.5) + 0.5;
}
else {
return (P.xy / P.z) * vec2(0.5, -sign(P.z) * 0.5) + 0.5;
}
}
vec4 sample_cube(sampler2DArray tex, vec3 cubevec, float cube)
{
/* Manual Shadow Cube Layer indexing. */
/* TODO Shadow Cube Array. */
float face = cubeFaceIndexEEVEE(cubevec);
vec3 coord = vec3(cubeFaceCoordEEVEE(cubevec, face), cube * 6.0 + face);
return texture(tex, coord);
}
vec4 sample_cascade(sampler2DArray tex, vec2 co, float cascade_id)
{
return texture(tex, vec3(co, cascade_id));
}
float sample_cube_shadow(ShadowData sd, ShadowCubeData scd, float texid, vec3 W)
{
vec3 cubevec = W - scd.position.xyz;
float dist = max_v3(abs(cubevec));
dist = buffer_depth(true, dist, sd.sh_far, sd.sh_near);
/* Manual Shadow Cube Layer indexing. */
/* TODO Shadow Cube Array. */
float face = cubeFaceIndexEEVEE(cubevec);
vec2 coord = cubeFaceCoordEEVEE(cubevec, face);
return texture(shadowCubeTexture, vec4(coord, texid * 6.0 + face, dist));
}
float sample_cascade_shadow(ShadowData sd, mat4 shadowmat, mat4 shadowmat0, vec3 W, float texid)
{
vec4 coord = shadowmat * vec4(W, 1.0);
return texture(shadowCascadeTexture, vec4(coord.xy, texid, coord.z));
}
float shadow_cascade(ShadowData sd, int scd_id, float texid, vec3 W)
{
vec4 view_z = vec4(dot(W - cameraPos, cameraForward));
vec4 weights = smoothstep(shadows_cascade_data[scd_id].split_end_distances,
shadows_cascade_data[scd_id].split_start_distances.yzwx,
view_z);
weights.yzw -= weights.xyz;
vec4 vis = vec4(1.0);
/* Branching using (weights > 0.0) is reaally slooow on intel so avoid it for now. */
/* TODO OPTI: Only do 2 samples and blend. */
vis.x = sample_cascade_shadow(sd,
shadows_cascade_data[scd_id].shadowmat[0],
shadows_cascade_data[scd_id].shadowmat[0],
W,
texid + 0);
vis.y = sample_cascade_shadow(sd,
shadows_cascade_data[scd_id].shadowmat[1],
shadows_cascade_data[scd_id].shadowmat[0],
W,
texid + 1);
vis.z = sample_cascade_shadow(sd,
shadows_cascade_data[scd_id].shadowmat[2],
shadows_cascade_data[scd_id].shadowmat[0],
W,
texid + 2);
vis.w = sample_cascade_shadow(sd,
shadows_cascade_data[scd_id].shadowmat[3],
shadows_cascade_data[scd_id].shadowmat[0],
W,
texid + 3);
float weight_sum = dot(vec4(1.0), weights);
if (weight_sum > 0.9999) {
float vis_sum = dot(vec4(1.0), vis * weights);
return vis_sum / weight_sum;
}
else {
float vis_sum = dot(vec4(1.0), vis * step(0.001, weights));
return mix(1.0, vis_sum, weight_sum);
}
}
/* ----------------------------------------------------------- */
/* --------------------- Light Functions --------------------- */
/* ----------------------------------------------------------- */
/* From Frostbite PBR Course
* Distance based attenuation
* http://www.frostbite.com/wp-content/uploads/2014/11/course_notes_moving_frostbite_to_pbr.pdf */
float distance_attenuation(float dist_sqr, float inv_sqr_influence)
{
float factor = dist_sqr * inv_sqr_influence;
float fac = saturate(1.0 - factor * factor);
return fac * fac;
}
float spot_attenuation(LightData ld, vec3 l_vector)
{
float z = dot(ld.l_forward, l_vector.xyz);
vec3 lL = l_vector.xyz / z;
float x = dot(ld.l_right, lL) / ld.l_sizex;
float y = dot(ld.l_up, lL) / ld.l_sizey;
float ellipse = inversesqrt(1.0 + x * x + y * y);
float spotmask = smoothstep(0.0, 1.0, (ellipse - ld.l_spot_size) / ld.l_spot_blend);
return spotmask;
}
float light_attenuation(LightData ld, vec4 l_vector)
{
float vis = 1.0;
if (ld.l_type == SPOT) {
vis *= spot_attenuation(ld, l_vector.xyz);
}
if (ld.l_type >= SPOT) {
vis *= step(0.0, -dot(l_vector.xyz, ld.l_forward));
}
if (ld.l_type != SUN) {
vis *= distance_attenuation(l_vector.w * l_vector.w, ld.l_influence);
}
return vis;
}
float light_visibility(LightData ld,
vec3 W,
#ifndef VOLUMETRICS
vec3 viewPosition,
vec3 vN,
#endif
vec4 l_vector)
{
float vis = light_attenuation(ld, l_vector);
#if !defined(VOLUMETRICS) || defined(VOLUME_SHADOW)
/* shadowing */
if (ld.l_shadowid >= 0.0 && vis > 0.001) {
ShadowData data = shadows_data[int(ld.l_shadowid)];
if (ld.l_type == SUN) {
vis *= shadow_cascade(data, int(data.sh_data_start), data.sh_tex_start, W);
}
else {
vis *= sample_cube_shadow(
data, shadows_cube_data[int(data.sh_data_start)], data.sh_tex_start, W);
}
# ifndef VOLUMETRICS
/* Only compute if not already in shadow. */
if (data.sh_contact_dist > 0.0) {
vec4 L = (ld.l_type != SUN) ? l_vector : vec4(-ld.l_forward, 1.0);
float trace_distance = (ld.l_type != SUN) ? min(data.sh_contact_dist, l_vector.w) :
data.sh_contact_dist;
vec3 T, B;
make_orthonormal_basis(L.xyz / L.w, T, B);
vec4 rand = texelfetch_noise_tex(gl_FragCoord.xy);
rand.zw *= fast_sqrt(rand.y) * data.sh_contact_spread;
/* We use the full l_vector.xyz so that the spread is minimize
* if the shading point is further away from the light source */
vec3 ray_dir = L.xyz + T * rand.z + B * rand.w;
ray_dir = transform_direction(ViewMatrix, ray_dir);
ray_dir = normalize(ray_dir);
vec3 ray_ori = viewPosition;
/* Fix translucency shadowed by contact shadows. */
vN = (gl_FrontFacing) ? vN : -vN;
if (dot(vN, ray_dir) <= 0.0) {
return vis;
}
float bias = 0.5; /* Constant Bias */
bias += 1.0 - abs(dot(vN, ray_dir)); /* Angle dependent bias */
bias *= gl_FrontFacing ? data.sh_contact_offset : -data.sh_contact_offset;
vec3 nor_bias = vN * bias;
ray_ori += nor_bias;
ray_dir *= trace_distance;
ray_dir -= nor_bias;
vec3 hit_pos = raycast(
-1, ray_ori, ray_dir, data.sh_contact_thickness, rand.x, 0.1, 0.001, false);
if (hit_pos.z > 0.0) {
hit_pos = get_view_space_from_depth(hit_pos.xy, hit_pos.z);
float hit_dist = distance(viewPosition, hit_pos);
float dist_ratio = hit_dist / trace_distance;
return vis * saturate(dist_ratio * dist_ratio * dist_ratio);
}
}
# endif
}
#endif
return vis;
}
#ifdef USE_LTC
float light_diffuse(LightData ld, vec3 N, vec3 V, vec4 l_vector)
{
if (ld.l_type == AREA_RECT) {
vec3 corners[4];
corners[0] = normalize((l_vector.xyz + ld.l_right * -ld.l_sizex) + ld.l_up * ld.l_sizey);
corners[1] = normalize((l_vector.xyz + ld.l_right * -ld.l_sizex) + ld.l_up * -ld.l_sizey);
corners[2] = normalize((l_vector.xyz + ld.l_right * ld.l_sizex) + ld.l_up * -ld.l_sizey);
corners[3] = normalize((l_vector.xyz + ld.l_right * ld.l_sizex) + ld.l_up * ld.l_sizey);
return ltc_evaluate_quad(corners, N);
}
else if (ld.l_type == AREA_ELLIPSE) {
vec3 points[3];
points[0] = (l_vector.xyz + ld.l_right * -ld.l_sizex) + ld.l_up * -ld.l_sizey;
points[1] = (l_vector.xyz + ld.l_right * ld.l_sizex) + ld.l_up * -ld.l_sizey;
points[2] = (l_vector.xyz + ld.l_right * ld.l_sizex) + ld.l_up * ld.l_sizey;
return ltc_evaluate_disk(N, V, mat3(1.0), points);
}
else {
float radius = ld.l_radius;
radius /= (ld.l_type == SUN) ? 1.0 : l_vector.w;
vec3 L = (ld.l_type == SUN) ? -ld.l_forward : (l_vector.xyz / l_vector.w);
return ltc_evaluate_disk_simple(radius, dot(N, L));
}
}
float light_specular(LightData ld, vec4 ltc_mat, vec3 N, vec3 V, vec4 l_vector)
{
if (ld.l_type == AREA_RECT) {
vec3 corners[4];
corners[0] = (l_vector.xyz + ld.l_right * -ld.l_sizex) + ld.l_up * ld.l_sizey;
corners[1] = (l_vector.xyz + ld.l_right * -ld.l_sizex) + ld.l_up * -ld.l_sizey;
corners[2] = (l_vector.xyz + ld.l_right * ld.l_sizex) + ld.l_up * -ld.l_sizey;
corners[3] = (l_vector.xyz + ld.l_right * ld.l_sizex) + ld.l_up * ld.l_sizey;
ltc_transform_quad(N, V, ltc_matrix(ltc_mat), corners);
return ltc_evaluate_quad(corners, vec3(0.0, 0.0, 1.0));
}
else {
bool is_ellipse = (ld.l_type == AREA_ELLIPSE);
float radius_x = is_ellipse ? ld.l_sizex : ld.l_radius;
float radius_y = is_ellipse ? ld.l_sizey : ld.l_radius;
vec3 L = (ld.l_type == SUN) ? -ld.l_forward : l_vector.xyz;
vec3 Px = ld.l_right;
vec3 Py = ld.l_up;
if (ld.l_type == SPOT || ld.l_type == POINT) {
make_orthonormal_basis(l_vector.xyz / l_vector.w, Px, Py);
}
vec3 points[3];
points[0] = (L + Px * -radius_x) + Py * -radius_y;
points[1] = (L + Px * radius_x) + Py * -radius_y;
points[2] = (L + Px * radius_x) + Py * radius_y;
return ltc_evaluate_disk(N, V, ltc_matrix(ltc_mat), points);
}
}
#endif
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