godot/scene/3d/voxelizer.cpp
clayjohn 385ee5c70b Implement Physical Light Units as an optional setting.
This allows light sources to be specified in physical light units in addition to the regular energy multiplier. In order to avoid loss of precision at high values, brightness values are premultiplied by an exposure normalization value.

In support of Physical Light Units this PR also renames CameraEffects to CameraAttributes.
2022-08-31 12:14:46 -07:00

1008 lines
28 KiB
C++

/*************************************************************************/
/* voxelizer.cpp */
/*************************************************************************/
/* This file is part of: */
/* GODOT ENGINE */
/* https://godotengine.org */
/*************************************************************************/
/* Copyright (c) 2007-2022 Juan Linietsky, Ariel Manzur. */
/* Copyright (c) 2014-2022 Godot Engine contributors (cf. AUTHORS.md). */
/* */
/* Permission is hereby granted, free of charge, to any person obtaining */
/* a copy of this software and associated documentation files (the */
/* "Software"), to deal in the Software without restriction, including */
/* without limitation the rights to use, copy, modify, merge, publish, */
/* distribute, sublicense, and/or sell copies of the Software, and to */
/* permit persons to whom the Software is furnished to do so, subject to */
/* the following conditions: */
/* */
/* The above copyright notice and this permission notice shall be */
/* included in all copies or substantial portions of the Software. */
/* */
/* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, */
/* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF */
/* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.*/
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/* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */
/*************************************************************************/
#include "voxelizer.h"
#include "core/config/project_settings.h"
static _FORCE_INLINE_ void get_uv_and_normal(const Vector3 &p_pos, const Vector3 *p_vtx, const Vector2 *p_uv, const Vector3 *p_normal, Vector2 &r_uv, Vector3 &r_normal) {
if (p_pos.is_equal_approx(p_vtx[0])) {
r_uv = p_uv[0];
r_normal = p_normal[0];
return;
}
if (p_pos.is_equal_approx(p_vtx[1])) {
r_uv = p_uv[1];
r_normal = p_normal[1];
return;
}
if (p_pos.is_equal_approx(p_vtx[2])) {
r_uv = p_uv[2];
r_normal = p_normal[2];
return;
}
Vector3 v0 = p_vtx[1] - p_vtx[0];
Vector3 v1 = p_vtx[2] - p_vtx[0];
Vector3 v2 = p_pos - p_vtx[0];
real_t d00 = v0.dot(v0);
real_t d01 = v0.dot(v1);
real_t d11 = v1.dot(v1);
real_t d20 = v2.dot(v0);
real_t d21 = v2.dot(v1);
real_t denom = (d00 * d11 - d01 * d01);
if (denom == 0) {
r_uv = p_uv[0];
r_normal = p_normal[0];
return;
}
real_t v = (d11 * d20 - d01 * d21) / denom;
real_t w = (d00 * d21 - d01 * d20) / denom;
real_t u = 1.0f - v - w;
r_uv = p_uv[0] * u + p_uv[1] * v + p_uv[2] * w;
r_normal = (p_normal[0] * u + p_normal[1] * v + p_normal[2] * w).normalized();
}
void Voxelizer::_plot_face(int p_idx, int p_level, int p_x, int p_y, int p_z, const Vector3 *p_vtx, const Vector3 *p_normal, const Vector2 *p_uv, const MaterialCache &p_material, const AABB &p_aabb) {
if (p_level == cell_subdiv) {
//plot the face by guessing its albedo and emission value
//find best axis to map to, for scanning values
int closest_axis = 0;
real_t closest_dot = 0;
Plane plane = Plane(p_vtx[0], p_vtx[1], p_vtx[2]);
Vector3 normal = plane.normal;
for (int i = 0; i < 3; i++) {
Vector3 axis;
axis[i] = 1.0;
real_t dot = ABS(normal.dot(axis));
if (i == 0 || dot > closest_dot) {
closest_axis = i;
closest_dot = dot;
}
}
Vector3 axis;
axis[closest_axis] = 1.0;
Vector3 t1;
t1[(closest_axis + 1) % 3] = 1.0;
Vector3 t2;
t2[(closest_axis + 2) % 3] = 1.0;
t1 *= p_aabb.size[(closest_axis + 1) % 3] / real_t(color_scan_cell_width);
t2 *= p_aabb.size[(closest_axis + 2) % 3] / real_t(color_scan_cell_width);
Color albedo_accum;
Color emission_accum;
Vector3 normal_accum;
float alpha = 0.0;
//map to a grid average in the best axis for this face
for (int i = 0; i < color_scan_cell_width; i++) {
Vector3 ofs_i = real_t(i) * t1;
for (int j = 0; j < color_scan_cell_width; j++) {
Vector3 ofs_j = real_t(j) * t2;
Vector3 from = p_aabb.position + ofs_i + ofs_j;
Vector3 to = from + t1 + t2 + axis * p_aabb.size[closest_axis];
Vector3 half = (to - from) * 0.5;
//is in this cell?
if (!Geometry3D::triangle_box_overlap(from + half, half, p_vtx)) {
continue; //face does not span this cell
}
//go from -size to +size*2 to avoid skipping collisions
Vector3 ray_from = from + (t1 + t2) * 0.5 - axis * p_aabb.size[closest_axis];
Vector3 ray_to = ray_from + axis * p_aabb.size[closest_axis] * 2;
if (normal.dot(ray_from - ray_to) < 0) {
SWAP(ray_from, ray_to);
}
Vector3 intersection;
if (!plane.intersects_segment(ray_from, ray_to, &intersection)) {
if (ABS(plane.distance_to(ray_from)) < ABS(plane.distance_to(ray_to))) {
intersection = plane.project(ray_from);
} else {
intersection = plane.project(ray_to);
}
}
intersection = Face3(p_vtx[0], p_vtx[1], p_vtx[2]).get_closest_point_to(intersection);
Vector2 uv;
Vector3 lnormal;
get_uv_and_normal(intersection, p_vtx, p_uv, p_normal, uv, lnormal);
if (lnormal == Vector3()) { //just in case normal is not provided
lnormal = normal;
}
int uv_x = CLAMP(int(Math::fposmod(uv.x, (real_t)1.0) * bake_texture_size), 0, bake_texture_size - 1);
int uv_y = CLAMP(int(Math::fposmod(uv.y, (real_t)1.0) * bake_texture_size), 0, bake_texture_size - 1);
int ofs = uv_y * bake_texture_size + uv_x;
albedo_accum.r += p_material.albedo[ofs].r;
albedo_accum.g += p_material.albedo[ofs].g;
albedo_accum.b += p_material.albedo[ofs].b;
albedo_accum.a += p_material.albedo[ofs].a;
emission_accum.r += p_material.emission[ofs].r;
emission_accum.g += p_material.emission[ofs].g;
emission_accum.b += p_material.emission[ofs].b;
normal_accum += lnormal;
alpha += 1.0;
}
}
if (alpha == 0) {
//could not in any way get texture information.. so use closest point to center
Face3 f(p_vtx[0], p_vtx[1], p_vtx[2]);
Vector3 inters = f.get_closest_point_to(p_aabb.get_center());
Vector3 lnormal;
Vector2 uv;
get_uv_and_normal(inters, p_vtx, p_uv, p_normal, uv, normal);
if (lnormal == Vector3()) { //just in case normal is not provided
lnormal = normal;
}
int uv_x = CLAMP(Math::fposmod(uv.x, (real_t)1.0) * bake_texture_size, 0, bake_texture_size - 1);
int uv_y = CLAMP(Math::fposmod(uv.y, (real_t)1.0) * bake_texture_size, 0, bake_texture_size - 1);
int ofs = uv_y * bake_texture_size + uv_x;
alpha = 1.0 / (color_scan_cell_width * color_scan_cell_width);
albedo_accum.r = p_material.albedo[ofs].r * alpha;
albedo_accum.g = p_material.albedo[ofs].g * alpha;
albedo_accum.b = p_material.albedo[ofs].b * alpha;
albedo_accum.a = p_material.albedo[ofs].a * alpha;
emission_accum.r = p_material.emission[ofs].r * alpha;
emission_accum.g = p_material.emission[ofs].g * alpha;
emission_accum.b = p_material.emission[ofs].b * alpha;
normal_accum = lnormal * alpha;
} else {
float accdiv = 1.0 / (color_scan_cell_width * color_scan_cell_width);
alpha *= accdiv;
albedo_accum.r *= accdiv;
albedo_accum.g *= accdiv;
albedo_accum.b *= accdiv;
albedo_accum.a *= accdiv;
emission_accum.r *= accdiv;
emission_accum.g *= accdiv;
emission_accum.b *= accdiv;
normal_accum *= accdiv;
}
//put this temporarily here, corrected in a later step
bake_cells.write[p_idx].albedo[0] += albedo_accum.r;
bake_cells.write[p_idx].albedo[1] += albedo_accum.g;
bake_cells.write[p_idx].albedo[2] += albedo_accum.b;
bake_cells.write[p_idx].emission[0] += emission_accum.r;
bake_cells.write[p_idx].emission[1] += emission_accum.g;
bake_cells.write[p_idx].emission[2] += emission_accum.b;
bake_cells.write[p_idx].normal[0] += normal_accum.x;
bake_cells.write[p_idx].normal[1] += normal_accum.y;
bake_cells.write[p_idx].normal[2] += normal_accum.z;
bake_cells.write[p_idx].alpha += alpha;
} else {
//go down
int half = (1 << cell_subdiv) >> (p_level + 1);
for (int i = 0; i < 8; i++) {
AABB aabb = p_aabb;
aabb.size *= 0.5;
int nx = p_x;
int ny = p_y;
int nz = p_z;
if (i & 1) {
aabb.position.x += aabb.size.x;
nx += half;
}
if (i & 2) {
aabb.position.y += aabb.size.y;
ny += half;
}
if (i & 4) {
aabb.position.z += aabb.size.z;
nz += half;
}
//make sure to not plot beyond limits
if (nx < 0 || nx >= axis_cell_size[0] || ny < 0 || ny >= axis_cell_size[1] || nz < 0 || nz >= axis_cell_size[2]) {
continue;
}
{
AABB test_aabb = aabb;
//test_aabb.grow_by(test_aabb.get_longest_axis_size()*0.05); //grow a bit to avoid numerical error in real-time
Vector3 qsize = test_aabb.size * 0.5; //quarter size, for fast aabb test
if (!Geometry3D::triangle_box_overlap(test_aabb.position + qsize, qsize, p_vtx)) {
//if (!Face3(p_vtx[0],p_vtx[1],p_vtx[2]).intersects_aabb2(aabb)) {
//does not fit in child, go on
continue;
}
}
if (bake_cells[p_idx].children[i] == CHILD_EMPTY) {
//sub cell must be created
uint32_t child_idx = bake_cells.size();
bake_cells.write[p_idx].children[i] = child_idx;
bake_cells.resize(bake_cells.size() + 1);
bake_cells.write[child_idx].level = p_level + 1;
bake_cells.write[child_idx].x = nx / half;
bake_cells.write[child_idx].y = ny / half;
bake_cells.write[child_idx].z = nz / half;
}
_plot_face(bake_cells[p_idx].children[i], p_level + 1, nx, ny, nz, p_vtx, p_normal, p_uv, p_material, aabb);
}
}
}
Vector<Color> Voxelizer::_get_bake_texture(Ref<Image> p_image, const Color &p_color_mul, const Color &p_color_add) {
Vector<Color> ret;
if (p_image.is_null() || p_image->is_empty()) {
ret.resize(bake_texture_size * bake_texture_size);
for (int i = 0; i < bake_texture_size * bake_texture_size; i++) {
ret.write[i] = p_color_add;
}
return ret;
}
p_image = p_image->duplicate();
if (p_image->is_compressed()) {
p_image->decompress();
}
p_image->convert(Image::FORMAT_RGBA8);
p_image->resize(bake_texture_size, bake_texture_size, Image::INTERPOLATE_CUBIC);
const uint8_t *r = p_image->get_data().ptr();
ret.resize(bake_texture_size * bake_texture_size);
for (int i = 0; i < bake_texture_size * bake_texture_size; i++) {
Color c;
c.r = (r[i * 4 + 0] / 255.0) * p_color_mul.r + p_color_add.r;
c.g = (r[i * 4 + 1] / 255.0) * p_color_mul.g + p_color_add.g;
c.b = (r[i * 4 + 2] / 255.0) * p_color_mul.b + p_color_add.b;
c.a = r[i * 4 + 3] / 255.0;
ret.write[i] = c;
}
return ret;
}
Voxelizer::MaterialCache Voxelizer::_get_material_cache(Ref<Material> p_material) {
// This way of obtaining materials is inaccurate and also does not support some compressed formats very well.
Ref<BaseMaterial3D> mat = p_material;
Ref<Material> material = mat; //hack for now
if (material_cache.has(material)) {
return material_cache[material];
}
MaterialCache mc;
if (mat.is_valid()) {
Ref<Texture2D> albedo_tex = mat->get_texture(BaseMaterial3D::TEXTURE_ALBEDO);
Ref<Image> img_albedo;
if (albedo_tex.is_valid()) {
img_albedo = albedo_tex->get_image();
mc.albedo = _get_bake_texture(img_albedo, mat->get_albedo(), Color(0, 0, 0)); // albedo texture, color is multiplicative
} else {
mc.albedo = _get_bake_texture(img_albedo, Color(1, 1, 1), mat->get_albedo()); // no albedo texture, color is additive
}
Ref<Texture2D> emission_tex = mat->get_texture(BaseMaterial3D::TEXTURE_EMISSION);
Color emission_col = mat->get_emission();
float emission_energy = mat->get_emission_energy_multiplier() * exposure_normalization;
if (GLOBAL_GET("rendering/lights_and_shadows/use_physical_light_units")) {
emission_energy *= mat->get_emission_intensity();
}
Ref<Image> img_emission;
if (emission_tex.is_valid()) {
img_emission = emission_tex->get_image();
}
if (mat->get_emission_operator() == BaseMaterial3D::EMISSION_OP_ADD) {
mc.emission = _get_bake_texture(img_emission, Color(1, 1, 1) * emission_energy, emission_col * emission_energy);
} else {
mc.emission = _get_bake_texture(img_emission, emission_col * emission_energy, Color(0, 0, 0));
}
} else {
Ref<Image> empty;
mc.albedo = _get_bake_texture(empty, Color(0, 0, 0), Color(1, 1, 1));
mc.emission = _get_bake_texture(empty, Color(0, 0, 0), Color(0, 0, 0));
}
material_cache[p_material] = mc;
return mc;
}
void Voxelizer::plot_mesh(const Transform3D &p_xform, Ref<Mesh> &p_mesh, const Vector<Ref<Material>> &p_materials, const Ref<Material> &p_override_material) {
for (int i = 0; i < p_mesh->get_surface_count(); i++) {
if (p_mesh->surface_get_primitive_type(i) != Mesh::PRIMITIVE_TRIANGLES) {
continue; //only triangles
}
Ref<Material> src_material;
if (p_override_material.is_valid()) {
src_material = p_override_material;
} else if (i < p_materials.size() && p_materials[i].is_valid()) {
src_material = p_materials[i];
} else {
src_material = p_mesh->surface_get_material(i);
}
MaterialCache material = _get_material_cache(src_material);
Array a = p_mesh->surface_get_arrays(i);
Vector<Vector3> vertices = a[Mesh::ARRAY_VERTEX];
const Vector3 *vr = vertices.ptr();
Vector<Vector2> uv = a[Mesh::ARRAY_TEX_UV];
const Vector2 *uvr = nullptr;
Vector<Vector3> normals = a[Mesh::ARRAY_NORMAL];
const Vector3 *nr = nullptr;
Vector<int> index = a[Mesh::ARRAY_INDEX];
if (uv.size()) {
uvr = uv.ptr();
}
if (normals.size()) {
nr = normals.ptr();
}
if (index.size()) {
int facecount = index.size() / 3;
const int *ir = index.ptr();
for (int j = 0; j < facecount; j++) {
Vector3 vtxs[3];
Vector2 uvs[3];
Vector3 normal[3];
for (int k = 0; k < 3; k++) {
vtxs[k] = p_xform.xform(vr[ir[j * 3 + k]]);
}
if (uvr) {
for (int k = 0; k < 3; k++) {
uvs[k] = uvr[ir[j * 3 + k]];
}
}
if (nr) {
for (int k = 0; k < 3; k++) {
normal[k] = nr[ir[j * 3 + k]];
}
}
//test against original bounds
if (!Geometry3D::triangle_box_overlap(original_bounds.get_center(), original_bounds.size * 0.5, vtxs)) {
continue;
}
//plot
_plot_face(0, 0, 0, 0, 0, vtxs, normal, uvs, material, po2_bounds);
}
} else {
int facecount = vertices.size() / 3;
for (int j = 0; j < facecount; j++) {
Vector3 vtxs[3];
Vector2 uvs[3];
Vector3 normal[3];
for (int k = 0; k < 3; k++) {
vtxs[k] = p_xform.xform(vr[j * 3 + k]);
}
if (uvr) {
for (int k = 0; k < 3; k++) {
uvs[k] = uvr[j * 3 + k];
}
}
if (nr) {
for (int k = 0; k < 3; k++) {
normal[k] = nr[j * 3 + k];
}
}
//test against original bounds
if (!Geometry3D::triangle_box_overlap(original_bounds.get_center(), original_bounds.size * 0.5, vtxs)) {
continue;
}
//plot face
_plot_face(0, 0, 0, 0, 0, vtxs, normal, uvs, material, po2_bounds);
}
}
}
max_original_cells = bake_cells.size();
}
void Voxelizer::_sort() {
// cells need to be sorted by level and coordinates
// it is important that level has more priority (for compute), and that Z has the least,
// given it may aid older implementations plot using GPU
Vector<CellSort> sorted_cells;
uint32_t cell_count = bake_cells.size();
sorted_cells.resize(cell_count);
{
CellSort *sort_cellsp = sorted_cells.ptrw();
const Cell *bake_cellsp = bake_cells.ptr();
for (uint32_t i = 0; i < cell_count; i++) {
sort_cellsp[i].x = bake_cellsp[i].x;
sort_cellsp[i].y = bake_cellsp[i].y;
sort_cellsp[i].z = bake_cellsp[i].z;
sort_cellsp[i].level = bake_cellsp[i].level;
sort_cellsp[i].index = i;
}
}
sorted_cells.sort();
//verify just in case, index 0 must be level 0
ERR_FAIL_COND(sorted_cells[0].level != 0);
Vector<Cell> new_bake_cells;
new_bake_cells.resize(cell_count);
Vector<uint32_t> reverse_map;
{
reverse_map.resize(cell_count);
const CellSort *sort_cellsp = sorted_cells.ptr();
uint32_t *reverse_mapp = reverse_map.ptrw();
for (uint32_t i = 0; i < cell_count; i++) {
reverse_mapp[sort_cellsp[i].index] = i;
}
}
{
const CellSort *sort_cellsp = sorted_cells.ptr();
const Cell *bake_cellsp = bake_cells.ptr();
const uint32_t *reverse_mapp = reverse_map.ptr();
Cell *new_bake_cellsp = new_bake_cells.ptrw();
for (uint32_t i = 0; i < cell_count; i++) {
//copy to new cell
new_bake_cellsp[i] = bake_cellsp[sort_cellsp[i].index];
//remap children
for (uint32_t j = 0; j < 8; j++) {
if (new_bake_cellsp[i].children[j] != CHILD_EMPTY) {
new_bake_cellsp[i].children[j] = reverse_mapp[new_bake_cellsp[i].children[j]];
}
}
}
}
bake_cells = new_bake_cells;
sorted = true;
}
void Voxelizer::_fixup_plot(int p_idx, int p_level) {
if (p_level == cell_subdiv) {
leaf_voxel_count++;
float alpha = bake_cells[p_idx].alpha;
bake_cells.write[p_idx].albedo[0] /= alpha;
bake_cells.write[p_idx].albedo[1] /= alpha;
bake_cells.write[p_idx].albedo[2] /= alpha;
//transfer emission to light
bake_cells.write[p_idx].emission[0] /= alpha;
bake_cells.write[p_idx].emission[1] /= alpha;
bake_cells.write[p_idx].emission[2] /= alpha;
bake_cells.write[p_idx].normal[0] /= alpha;
bake_cells.write[p_idx].normal[1] /= alpha;
bake_cells.write[p_idx].normal[2] /= alpha;
Vector3 n(bake_cells[p_idx].normal[0], bake_cells[p_idx].normal[1], bake_cells[p_idx].normal[2]);
if (n.length() < 0.01) {
//too much fight over normal, zero it
bake_cells.write[p_idx].normal[0] = 0;
bake_cells.write[p_idx].normal[1] = 0;
bake_cells.write[p_idx].normal[2] = 0;
} else {
n.normalize();
bake_cells.write[p_idx].normal[0] = n.x;
bake_cells.write[p_idx].normal[1] = n.y;
bake_cells.write[p_idx].normal[2] = n.z;
}
bake_cells.write[p_idx].alpha = 1.0;
/*if (bake_light.size()) {
for(int i=0;i<6;i++) {
}
}*/
} else {
//go down
bake_cells.write[p_idx].emission[0] = 0;
bake_cells.write[p_idx].emission[1] = 0;
bake_cells.write[p_idx].emission[2] = 0;
bake_cells.write[p_idx].normal[0] = 0;
bake_cells.write[p_idx].normal[1] = 0;
bake_cells.write[p_idx].normal[2] = 0;
bake_cells.write[p_idx].albedo[0] = 0;
bake_cells.write[p_idx].albedo[1] = 0;
bake_cells.write[p_idx].albedo[2] = 0;
float alpha_average = 0;
for (int i = 0; i < 8; i++) {
uint32_t child = bake_cells[p_idx].children[i];
if (child == CHILD_EMPTY) {
continue;
}
_fixup_plot(child, p_level + 1);
alpha_average += bake_cells[child].alpha;
}
bake_cells.write[p_idx].alpha = alpha_average / 8.0;
}
}
void Voxelizer::begin_bake(int p_subdiv, const AABB &p_bounds, float p_exposure_normalization) {
sorted = false;
original_bounds = p_bounds;
cell_subdiv = p_subdiv;
exposure_normalization = p_exposure_normalization;
bake_cells.resize(1);
material_cache.clear();
//find out the actual real bounds, power of 2, which gets the highest subdivision
po2_bounds = p_bounds;
int longest_axis = po2_bounds.get_longest_axis_index();
axis_cell_size[longest_axis] = 1 << cell_subdiv;
leaf_voxel_count = 0;
for (int i = 0; i < 3; i++) {
if (i == longest_axis) {
continue;
}
axis_cell_size[i] = axis_cell_size[longest_axis];
real_t axis_size = po2_bounds.size[longest_axis];
//shrink until fit subdiv
while (axis_size / 2.0 >= po2_bounds.size[i]) {
axis_size /= 2.0;
axis_cell_size[i] >>= 1;
}
po2_bounds.size[i] = po2_bounds.size[longest_axis];
}
Transform3D to_bounds;
to_bounds.basis.scale(Vector3(po2_bounds.size[longest_axis], po2_bounds.size[longest_axis], po2_bounds.size[longest_axis]));
to_bounds.origin = po2_bounds.position;
Transform3D to_grid;
to_grid.basis.scale(Vector3(axis_cell_size[longest_axis], axis_cell_size[longest_axis], axis_cell_size[longest_axis]));
to_cell_space = to_grid * to_bounds.affine_inverse();
cell_size = po2_bounds.size[longest_axis] / axis_cell_size[longest_axis];
}
void Voxelizer::end_bake() {
if (!sorted) {
_sort();
}
_fixup_plot(0, 0);
}
//create the data for rendering server
int Voxelizer::get_voxel_gi_octree_depth() const {
return cell_subdiv;
}
Vector3i Voxelizer::get_voxel_gi_octree_size() const {
return Vector3i(axis_cell_size[0], axis_cell_size[1], axis_cell_size[2]);
}
int Voxelizer::get_voxel_gi_cell_count() const {
return bake_cells.size();
}
Vector<uint8_t> Voxelizer::get_voxel_gi_octree_cells() const {
Vector<uint8_t> data;
data.resize((8 * 4) * bake_cells.size()); //8 uint32t values
{
uint8_t *w = data.ptrw();
uint32_t *children_cells = (uint32_t *)w;
const Cell *cells = bake_cells.ptr();
uint32_t cell_count = bake_cells.size();
for (uint32_t i = 0; i < cell_count; i++) {
for (uint32_t j = 0; j < 8; j++) {
children_cells[i * 8 + j] = cells[i].children[j];
}
}
}
return data;
}
Vector<uint8_t> Voxelizer::get_voxel_gi_data_cells() const {
Vector<uint8_t> data;
data.resize((4 * 4) * bake_cells.size()); //8 uint32t values
{
uint8_t *w = data.ptrw();
uint32_t *dataptr = (uint32_t *)w;
const Cell *cells = bake_cells.ptr();
uint32_t cell_count = bake_cells.size();
for (uint32_t i = 0; i < cell_count; i++) {
{ //position
uint32_t x = cells[i].x;
uint32_t y = cells[i].y;
uint32_t z = cells[i].z;
uint32_t position = x;
position |= y << 11;
position |= z << 21;
dataptr[i * 4 + 0] = position;
}
{ //albedo + alpha
uint32_t rgba = uint32_t(CLAMP(cells[i].alpha * 255.0, 0, 255)) << 24; //a
rgba |= uint32_t(CLAMP(cells[i].albedo[2] * 255.0, 0, 255)) << 16; //b
rgba |= uint32_t(CLAMP(cells[i].albedo[1] * 255.0, 0, 255)) << 8; //g
rgba |= uint32_t(CLAMP(cells[i].albedo[0] * 255.0, 0, 255)); //r
dataptr[i * 4 + 1] = rgba;
}
{ //emission, as rgbe9995
Color emission = Color(cells[i].emission[0], cells[i].emission[1], cells[i].emission[2]);
dataptr[i * 4 + 2] = emission.to_rgbe9995();
}
{ //normal
Vector3 n(bake_cells[i].normal[0], bake_cells[i].normal[1], bake_cells[i].normal[2]);
n.normalize();
uint32_t normal = uint32_t(uint8_t(int8_t(CLAMP(n.x * 127.0, -128, 127))));
normal |= uint32_t(uint8_t(int8_t(CLAMP(n.y * 127.0, -128, 127)))) << 8;
normal |= uint32_t(uint8_t(int8_t(CLAMP(n.z * 127.0, -128, 127)))) << 16;
dataptr[i * 4 + 3] = normal;
}
}
}
return data;
}
Vector<int> Voxelizer::get_voxel_gi_level_cell_count() const {
uint32_t cell_count = bake_cells.size();
const Cell *cells = bake_cells.ptr();
Vector<int> level_count;
level_count.resize(cell_subdiv + 1); //remember, always x+1 levels for x subdivisions
{
int *w = level_count.ptrw();
for (int i = 0; i < cell_subdiv + 1; i++) {
w[i] = 0;
}
for (uint32_t i = 0; i < cell_count; i++) {
w[cells[i].level]++;
}
}
return level_count;
}
// euclidean distance computation based on:
// https://prideout.net/blog/distance_fields/
#define square(m_s) ((m_s) * (m_s))
#define INF 1e20
/* dt of 1d function using squared distance */
static void edt(float *f, int stride, int n) {
float *d = (float *)alloca(sizeof(float) * n + sizeof(int) * n + sizeof(float) * (n + 1));
int *v = reinterpret_cast<int *>(&(d[n]));
float *z = reinterpret_cast<float *>(&v[n]);
int k = 0;
v[0] = 0;
z[0] = -INF;
z[1] = +INF;
for (int q = 1; q <= n - 1; q++) {
float s = ((f[q * stride] + square(q)) - (f[v[k] * stride] + square(v[k]))) / (2 * q - 2 * v[k]);
while (s <= z[k]) {
k--;
s = ((f[q * stride] + square(q)) - (f[v[k] * stride] + square(v[k]))) / (2 * q - 2 * v[k]);
}
k++;
v[k] = q;
z[k] = s;
z[k + 1] = +INF;
}
k = 0;
for (int q = 0; q <= n - 1; q++) {
while (z[k + 1] < q) {
k++;
}
d[q] = square(q - v[k]) + f[v[k] * stride];
}
for (int i = 0; i < n; i++) {
f[i * stride] = d[i];
}
}
#undef square
Vector<uint8_t> Voxelizer::get_sdf_3d_image() const {
Vector3i octree_size = get_voxel_gi_octree_size();
uint32_t float_count = octree_size.x * octree_size.y * octree_size.z;
float *work_memory = memnew_arr(float, float_count);
for (uint32_t i = 0; i < float_count; i++) {
work_memory[i] = INF;
}
uint32_t y_mult = octree_size.x;
uint32_t z_mult = y_mult * octree_size.y;
//plot solid cells
{
const Cell *cells = bake_cells.ptr();
uint32_t cell_count = bake_cells.size();
for (uint32_t i = 0; i < cell_count; i++) {
if (cells[i].level < (cell_subdiv - 1)) {
continue; //do not care about this level
}
work_memory[cells[i].x + cells[i].y * y_mult + cells[i].z * z_mult] = 0;
}
}
//process in each direction
//xy->z
for (int i = 0; i < octree_size.x; i++) {
for (int j = 0; j < octree_size.y; j++) {
edt(&work_memory[i + j * y_mult], z_mult, octree_size.z);
}
}
//xz->y
for (int i = 0; i < octree_size.x; i++) {
for (int j = 0; j < octree_size.z; j++) {
edt(&work_memory[i + j * z_mult], y_mult, octree_size.y);
}
}
//yz->x
for (int i = 0; i < octree_size.y; i++) {
for (int j = 0; j < octree_size.z; j++) {
edt(&work_memory[i * y_mult + j * z_mult], 1, octree_size.x);
}
}
Vector<uint8_t> image3d;
image3d.resize(float_count);
{
uint8_t *w = image3d.ptrw();
for (uint32_t i = 0; i < float_count; i++) {
uint32_t d = uint32_t(Math::sqrt(work_memory[i]));
if (d == 0) {
w[i] = 0;
} else {
w[i] = MIN(d, 254u) + 1;
}
}
}
return image3d;
}
#undef INF
void Voxelizer::_debug_mesh(int p_idx, int p_level, const AABB &p_aabb, Ref<MultiMesh> &p_multimesh, int &idx) {
if (p_level == cell_subdiv - 1) {
Vector3 center = p_aabb.get_center();
Transform3D xform;
xform.origin = center;
xform.basis.scale(p_aabb.size * 0.5);
p_multimesh->set_instance_transform(idx, xform);
Color col;
col = Color(bake_cells[p_idx].albedo[0], bake_cells[p_idx].albedo[1], bake_cells[p_idx].albedo[2]);
//Color col = Color(bake_cells[p_idx].emission[0], bake_cells[p_idx].emission[1], bake_cells[p_idx].emission[2]);
p_multimesh->set_instance_color(idx, col);
idx++;
} else {
for (int i = 0; i < 8; i++) {
uint32_t child = bake_cells[p_idx].children[i];
if (child == CHILD_EMPTY || child >= (uint32_t)max_original_cells) {
continue;
}
AABB aabb = p_aabb;
aabb.size *= 0.5;
if (i & 1) {
aabb.position.x += aabb.size.x;
}
if (i & 2) {
aabb.position.y += aabb.size.y;
}
if (i & 4) {
aabb.position.z += aabb.size.z;
}
_debug_mesh(bake_cells[p_idx].children[i], p_level + 1, aabb, p_multimesh, idx);
}
}
}
Ref<MultiMesh> Voxelizer::create_debug_multimesh() {
Ref<MultiMesh> mm;
mm.instantiate();
mm->set_transform_format(MultiMesh::TRANSFORM_3D);
mm->set_use_colors(true);
mm->set_instance_count(leaf_voxel_count);
Ref<ArrayMesh> mesh;
mesh.instantiate();
{
Array arr;
arr.resize(Mesh::ARRAY_MAX);
Vector<Vector3> vertices;
Vector<Color> colors;
#define ADD_VTX(m_idx) \
vertices.push_back(face_points[m_idx]); \
colors.push_back(Color(1, 1, 1, 1));
for (int i = 0; i < 6; i++) {
Vector3 face_points[4];
for (int j = 0; j < 4; j++) {
real_t v[3];
v[0] = 1.0;
v[1] = 1 - 2 * ((j >> 1) & 1);
v[2] = v[1] * (1 - 2 * (j & 1));
for (int k = 0; k < 3; k++) {
if (i < 3) {
face_points[j][(i + k) % 3] = v[k];
} else {
face_points[3 - j][(i + k) % 3] = -v[k];
}
}
}
//tri 1
ADD_VTX(0);
ADD_VTX(1);
ADD_VTX(2);
//tri 2
ADD_VTX(2);
ADD_VTX(3);
ADD_VTX(0);
}
arr[Mesh::ARRAY_VERTEX] = vertices;
arr[Mesh::ARRAY_COLOR] = colors;
mesh->add_surface_from_arrays(Mesh::PRIMITIVE_TRIANGLES, arr);
}
{
Ref<StandardMaterial3D> fsm;
fsm.instantiate();
fsm->set_flag(StandardMaterial3D::FLAG_SRGB_VERTEX_COLOR, true);
fsm->set_flag(StandardMaterial3D::FLAG_ALBEDO_FROM_VERTEX_COLOR, true);
fsm->set_shading_mode(StandardMaterial3D::SHADING_MODE_UNSHADED);
fsm->set_albedo(Color(1, 1, 1, 1));
mesh->surface_set_material(0, fsm);
}
mm->set_mesh(mesh);
int idx = 0;
_debug_mesh(0, 0, po2_bounds, mm, idx);
return mm;
}
Transform3D Voxelizer::get_to_cell_space_xform() const {
return to_cell_space;
}
Voxelizer::Voxelizer() {
}