virtualx-engine/editor/plugins/baked_light_baker.cpp

2732 lines
62 KiB
C++

/*************************************************************************/
/* baked_light_baker.cpp */
/*************************************************************************/
/* This file is part of: */
/* GODOT ENGINE */
/* http://www.godotengine.org */
/*************************************************************************/
/* Copyright (c) 2007-2017 Juan Linietsky, Ariel Manzur. */
/* Copyright (c) 2014-2017 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.*/
/* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY */
/* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, */
/* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE */
/* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */
/*************************************************************************/
#include "baked_light_baker.h"
#include "editor/editor_node.h"
#include "editor/editor_settings.h"
#include "io/marshalls.h"
#include <stdlib.h>
#include <cmath>
#if 0
void baked_light_baker_add_64f(double *dst,double value);
void baked_light_baker_add_64i(int64_t *dst,int64_t value);
//-separar en 2 testuras?
//*mejorar performance y threads
//*modos lineales
//*saturacion
_FORCE_INLINE_ static uint64_t get_uv_normal_bit(const Vector3& p_vector) {
int lat = Math::fast_ftoi(Math::floor(Math::acos(p_vector.dot(Vector3(0,1,0)))*6.0/Math_PI+0.5));
if (lat==0) {
return 60;
} else if (lat==6) {
return 61;
}
int lon = Math::fast_ftoi(Math::floor( (Math_PI+Math::atan2(p_vector.x,p_vector.z))*12.0/(Math_PI*2.0) + 0.5))%12;
return lon+(lat-1)*12;
}
_FORCE_INLINE_ static Vector3 get_bit_normal(int p_bit) {
if (p_bit==61) {
return Vector3(0,1,0);
} else if (p_bit==62){
return Vector3(0,-1,0);
}
float latang = ((p_bit / 12)+1)*Math_PI/6.0;
Vector2 latv(Math::sin(latang),Math::cos(latang));
float lonang = ((p_bit%12)*Math_PI*2.0/12.0)-Math_PI;
Vector2 lonv(Math::sin(lonang),Math::cos(lonang));
return Vector3(lonv.x*latv.x,latv.y,lonv.y*latv.x).normalized();
}
BakedLightBaker::MeshTexture* BakedLightBaker::_get_mat_tex(const Ref<Texture>& p_tex) {
if (!tex_map.has(p_tex)) {
Ref<ImageTexture> imgtex=p_tex;
if (imgtex.is_null())
return NULL;
Image image=imgtex->get_data();
if (image.empty())
return NULL;
if (image.get_format()!=Image::FORMAT_RGBA8) {
if (image.get_format()>Image::FORMAT_INDEXED_ALPHA) {
Error err = image.decompress();
if (err)
return NULL;
}
if (image.get_format()!=Image::FORMAT_RGBA8)
image.convert(Image::FORMAT_RGBA8);
}
if (imgtex->get_flags()&Texture::FLAG_CONVERT_TO_LINEAR) {
Image copy = image;
copy.srgb_to_linear();
image=copy;
}
PoolVector<uint8_t> dvt=image.get_data();
PoolVector<uint8_t>::Read r=dvt.read();
MeshTexture mt;
mt.tex_w=image.get_width();
mt.tex_h=image.get_height();
int len = image.get_width()*image.get_height()*4;
mt.tex.resize(len);
copymem(mt.tex.ptr(),r.ptr(),len);
textures.push_back(mt);
tex_map[p_tex]=&textures.back()->get();
}
return tex_map[p_tex];
}
void BakedLightBaker::_add_mesh(const Ref<Mesh>& p_mesh,const Ref<Material>& p_mat_override,const Transform& p_xform,int p_baked_texture) {
for(int i=0;i<p_mesh->get_surface_count();i++) {
if (p_mesh->surface_get_primitive_type(i)!=Mesh::PRIMITIVE_TRIANGLES)
continue;
Ref<Material> mat = p_mat_override.is_valid()?p_mat_override:p_mesh->surface_get_material(i);
MeshMaterial *matptr=NULL;
int baked_tex=p_baked_texture;
if (mat.is_valid()) {
if (!mat_map.has(mat)) {
MeshMaterial mm;
Ref<SpatialMaterial> fm = mat;
if (fm.is_valid()) {
//fixed route
mm.diffuse.color=fm->get_parameter(SpatialMaterial::PARAM_DIFFUSE);
if (linear_color)
mm.diffuse.color=mm.diffuse.color.to_linear();
mm.diffuse.tex=_get_mat_tex(fm->get_texture(SpatialMaterial::PARAM_DIFFUSE));
mm.specular.color=fm->get_parameter(SpatialMaterial::PARAM_SPECULAR);
if (linear_color)
mm.specular.color=mm.specular.color.to_linear();
mm.specular.tex=_get_mat_tex(fm->get_texture(SpatialMaterial::PARAM_SPECULAR));
} else {
mm.diffuse.color=Color(1,1,1,1);
mm.diffuse.tex=NULL;
mm.specular.color=Color(0,0,0,1);
mm.specular.tex=NULL;
}
materials.push_back(mm);
mat_map[mat]=&materials.back()->get();
}
matptr=mat_map[mat];
}
int facecount=0;
if (p_mesh->surface_get_format(i)&Mesh::ARRAY_FORMAT_INDEX) {
facecount=p_mesh->surface_get_array_index_len(i);
} else {
facecount=p_mesh->surface_get_array_len(i);
}
ERR_CONTINUE((facecount==0 || (facecount%3)!=0));
facecount/=3;
int tbase=triangles.size();
triangles.resize(facecount+tbase);
Array a = p_mesh->surface_get_arrays(i);
PoolVector<Vector3> vertices = a[Mesh::ARRAY_VERTEX];
PoolVector<Vector3>::Read vr=vertices.read();
PoolVector<Vector2> uv;
PoolVector<Vector2>::Read uvr;
PoolVector<Vector2> uv2;
PoolVector<Vector2>::Read uv2r;
PoolVector<Vector3> normal;
PoolVector<Vector3>::Read normalr;
bool read_uv=false;
bool read_normal=false;
if (p_mesh->surface_get_format(i)&Mesh::ARRAY_FORMAT_TEX_UV) {
uv=a[Mesh::ARRAY_TEX_UV];
uvr=uv.read();
read_uv=true;
if (mat.is_valid() && mat->get_flag(Material::FLAG_LIGHTMAP_ON_UV2) && p_mesh->surface_get_format(i)&Mesh::ARRAY_FORMAT_TEX_UV2) {
uv2=a[Mesh::ARRAY_TEX_UV2];
uv2r=uv2.read();
} else {
uv2r=uv.read();
if (baked_light->get_transfer_lightmaps_only_to_uv2()) {
baked_tex=-1;
}
}
}
if (p_mesh->surface_get_format(i)&Mesh::ARRAY_FORMAT_NORMAL) {
normal=a[Mesh::ARRAY_NORMAL];
normalr=normal.read();
read_normal=true;
}
Matrix3 normal_xform = p_xform.basis.inverse().transposed();
if (p_mesh->surface_get_format(i)&Mesh::ARRAY_FORMAT_INDEX) {
PoolVector<int> indices = a[Mesh::ARRAY_INDEX];
PoolVector<int>::Read ir = indices.read();
for(int i=0;i<facecount;i++) {
Triangle &t=triangles[tbase+i];
t.vertices[0]=p_xform.xform(vr[ ir[i*3+0] ]);
t.vertices[1]=p_xform.xform(vr[ ir[i*3+1] ]);
t.vertices[2]=p_xform.xform(vr[ ir[i*3+2] ]);
t.material=matptr;
t.baked_texture=baked_tex;
if (read_uv) {
t.uvs[0]=uvr[ ir[i*3+0] ];
t.uvs[1]=uvr[ ir[i*3+1] ];
t.uvs[2]=uvr[ ir[i*3+2] ];
t.bake_uvs[0]=uv2r[ ir[i*3+0] ];
t.bake_uvs[1]=uv2r[ ir[i*3+1] ];
t.bake_uvs[2]=uv2r[ ir[i*3+2] ];
}
if (read_normal) {
t.normals[0]=normal_xform.xform(normalr[ ir[i*3+0] ]).normalized();
t.normals[1]=normal_xform.xform(normalr[ ir[i*3+1] ]).normalized();
t.normals[2]=normal_xform.xform(normalr[ ir[i*3+2] ]).normalized();
}
}
} else {
for(int i=0;i<facecount;i++) {
Triangle &t=triangles[tbase+i];
t.vertices[0]=p_xform.xform(vr[ i*3+0 ]);
t.vertices[1]=p_xform.xform(vr[ i*3+1 ]);
t.vertices[2]=p_xform.xform(vr[ i*3+2 ]);
t.material=matptr;
t.baked_texture=baked_tex;
if (read_uv) {
t.uvs[0]=uvr[ i*3+0 ];
t.uvs[1]=uvr[ i*3+1 ];
t.uvs[2]=uvr[ i*3+2 ];
t.bake_uvs[0]=uv2r[ i*3+0 ];
t.bake_uvs[1]=uv2r[ i*3+1 ];
t.bake_uvs[2]=uv2r[ i*3+2 ];
}
if (read_normal) {
t.normals[0]=normal_xform.xform(normalr[ i*3+0 ]).normalized();
t.normals[1]=normal_xform.xform(normalr[ i*3+1 ]).normalized();
t.normals[2]=normal_xform.xform(normalr[ i*3+2 ]).normalized();
}
}
}
}
}
void BakedLightBaker::_parse_geometry(Node* p_node) {
if (p_node->cast_to<MeshInstance>()) {
MeshInstance *meshi=p_node->cast_to<MeshInstance>();
Ref<Mesh> mesh=meshi->get_mesh();
if (mesh.is_valid()) {
_add_mesh(mesh,meshi->get_material_override(),base_inv * meshi->get_global_transform(),meshi->get_baked_light_texture_id());
}
} else if (p_node->cast_to<Light>()) {
Light *dl=p_node->cast_to<Light>();
if (dl->get_bake_mode()!=Light::BAKE_MODE_DISABLED) {
LightData dirl;
dirl.type=VS::LightType(dl->get_light_type());
dirl.diffuse=dl->get_color(DirectionalLight::COLOR_DIFFUSE);
dirl.specular=dl->get_color(DirectionalLight::COLOR_SPECULAR);
if (linear_color)
dirl.diffuse=dirl.diffuse.to_linear();
if (linear_color)
dirl.specular=dirl.specular.to_linear();
dirl.energy=dl->get_parameter(DirectionalLight::PARAM_ENERGY);
dirl.pos=dl->get_global_transform().origin;
dirl.up=dl->get_global_transform().basis.get_axis(1).normalized();
dirl.left=dl->get_global_transform().basis.get_axis(0).normalized();
dirl.dir=-dl->get_global_transform().basis.get_axis(2).normalized();
dirl.spot_angle=dl->get_parameter(DirectionalLight::PARAM_SPOT_ANGLE);
dirl.spot_attenuation=dl->get_parameter(DirectionalLight::PARAM_SPOT_ATTENUATION);
dirl.attenuation=dl->get_parameter(DirectionalLight::PARAM_ATTENUATION);
dirl.darkening=dl->get_parameter(DirectionalLight::PARAM_SHADOW_DARKENING);
dirl.radius=dl->get_parameter(DirectionalLight::PARAM_RADIUS);
dirl.bake_direct=dl->get_bake_mode()==Light::BAKE_MODE_FULL;
dirl.rays_thrown=0;
dirl.bake_shadow=dl->get_bake_mode()==Light::BAKE_MODE_INDIRECT_AND_SHADOWS;
lights.push_back(dirl);
}
} else if (p_node->cast_to<Spatial>()){
Spatial *sp = p_node->cast_to<Spatial>();
Array arr = p_node->call("_get_baked_light_meshes");
for(int i=0;i<arr.size();i+=2) {
Transform xform=arr[i];
Ref<Mesh> mesh=arr[i+1];
_add_mesh(mesh,Ref<Material>(),base_inv * (sp->get_global_transform() * xform));
}
}
for(int i=0;i<p_node->get_child_count();i++) {
_parse_geometry(p_node->get_child(i));
}
}
void BakedLightBaker::_fix_lights() {
total_light_area=0;
for(int i=0;i<lights.size();i++) {
LightData &dl=lights[i];
switch(dl.type) {
case VS::LIGHT_DIRECTIONAL: {
float up_max=-1e10;
float dir_max=-1e10;
float left_max=-1e10;
float up_min=1e10;
float dir_min=1e10;
float left_min=1e10;
for(int j=0;j<triangles.size();j++) {
for(int k=0;k<3;k++) {
Vector3 v = triangles[j].vertices[k];
float up_d = dl.up.dot(v);
float dir_d = dl.dir.dot(v);
float left_d = dl.left.dot(v);
if (up_d>up_max)
up_max=up_d;
if (up_d<up_min)
up_min=up_d;
if (left_d>left_max)
left_max=left_d;
if (left_d<left_min)
left_min=left_d;
if (dir_d>dir_max)
dir_max=dir_d;
if (dir_d<dir_min)
dir_min=dir_d;
}
}
//make a center point, then the upvector and leftvector
dl.pos = dl.left*( left_max+left_min )*0.5 + dl.up*( up_max+up_min )*0.5 + dl.dir*(dir_min-(dir_max-dir_min));
dl.left*=(left_max-left_min)*0.5;
dl.up*=(up_max-up_min)*0.5;
dl.length = (dir_max - dir_min)*10; //arbitrary number to keep it in scale
dl.area=dl.left.length()*2*dl.up.length()*2;
dl.constant=1.0/dl.area;
} break;
case VS::LIGHT_OMNI:
case VS::LIGHT_SPOT: {
dl.attenuation_table.resize(ATTENUATION_CURVE_LEN);
for(int j=0;j<ATTENUATION_CURVE_LEN;j++) {
dl.attenuation_table[j]=1.0-Math::pow(j/float(ATTENUATION_CURVE_LEN),dl.attenuation);
float falloff=j*dl.radius/float(ATTENUATION_CURVE_LEN);
if (falloff==0)
falloff=0.000001;
float intensity=4*Math_PI*(falloff*falloff);
//dl.attenuation_table[j]*=falloff*falloff;
dl.attenuation_table[j]*=1.0/(3.0/intensity);
}
if (dl.type==VS::LIGHT_OMNI) {
dl.area=4.0*Math_PI*pow(dl.radius,2.0f);
dl.constant=1.0/3.5;
} else {
float r = Math::tan(Math::deg2rad(dl.spot_angle))*dl.radius;
float c = 1.0-(Math::deg2rad(dl.spot_angle)*0.5+0.5);
dl.constant=1.0/3.5;
dl.constant*=1.0/c;
dl.area=Math_PI*r*r*c;
}
} break;
}
total_light_area+=dl.area;
}
}
BakedLightBaker::BVH* BakedLightBaker::_parse_bvh(BVH** p_children, int p_size, int p_depth, int &max_depth) {
if (p_depth>max_depth) {
max_depth=p_depth;
}
if (p_size==1) {
return p_children[0];
} else if (p_size==0) {
return NULL;
}
AABB aabb;
aabb=p_children[0]->aabb;
for(int i=1;i<p_size;i++) {
aabb.merge_with(p_children[i]->aabb);
}
int li=aabb.get_longest_axis_index();
switch(li) {
case Vector3::AXIS_X: {
SortArray<BVH*,BVHCmpX> sort_x;
sort_x.nth_element(0,p_size,p_size/2,p_children);
//sort_x.sort(&p_bb[p_from],p_size);
} break;
case Vector3::AXIS_Y: {
SortArray<BVH*,BVHCmpY> sort_y;
sort_y.nth_element(0,p_size,p_size/2,p_children);
//sort_y.sort(&p_bb[p_from],p_size);
} break;
case Vector3::AXIS_Z: {
SortArray<BVH*,BVHCmpZ> sort_z;
sort_z.nth_element(0,p_size,p_size/2,p_children);
//sort_z.sort(&p_bb[p_from],p_size);
} break;
}
BVH* left = _parse_bvh(p_children,p_size/2,p_depth+1,max_depth);
BVH* right = _parse_bvh(&p_children[p_size/2],p_size-p_size/2,p_depth+1,max_depth);
BVH *_new = memnew(BVH);
_new->aabb=aabb;
_new->center=aabb.pos+aabb.size*0.5;
_new->children[0]=left;
_new->children[1]=right;
_new->leaf=NULL;
return _new;
}
void BakedLightBaker::_make_bvh() {
Vector<BVH*> bases;
bases.resize(triangles.size());
int max_depth=0;
for(int i=0;i<triangles.size();i++) {
bases[i]=memnew( BVH );
bases[i]->leaf=&triangles[i];
bases[i]->aabb.pos=triangles[i].vertices[0];
bases[i]->aabb.expand_to(triangles[i].vertices[1]);
bases[i]->aabb.expand_to(triangles[i].vertices[2]);
triangles[i].aabb=bases[i]->aabb;
bases[i]->center=bases[i]->aabb.pos+bases[i]->aabb.size*0.5;
}
bvh=_parse_bvh(bases.ptr(),bases.size(),1,max_depth);
ray_stack = memnew_arr(uint32_t,max_depth);
bvh_stack = memnew_arr(BVH*,max_depth);
bvh_depth = max_depth;
}
void BakedLightBaker::_octree_insert(int p_octant,Triangle* p_triangle, int p_depth) {
uint32_t *stack=octant_stack;
uint32_t *ptr_stack=octantptr_stack;
Octant *octants=octant_pool.ptr();
stack[0]=0;
ptr_stack[0]=0;
int stack_pos=0;
while(true) {
Octant *octant=&octants[ptr_stack[stack_pos]];
if (stack[stack_pos]<8) {
int i = stack[stack_pos];
stack[stack_pos]++;
//fit_aabb=fit_aabb.grow(bvh->aabb.size.x*0.0001);
int child_idx =octant->children[i];
bool encloses;
if (!child_idx) {
AABB aabb=octant->aabb;
aabb.size*=0.5;
if (i&1)
aabb.pos.x+=aabb.size.x;
if (i&2)
aabb.pos.y+=aabb.size.y;
if (i&4)
aabb.pos.z+=aabb.size.z;
aabb.grow_by(cell_size*octree_extra_margin);
if (!aabb.intersects(p_triangle->aabb))
continue;
encloses=aabb.grow(cell_size*-octree_extra_margin*2.0).encloses(p_triangle->aabb);
if (!encloses && !Face3(p_triangle->vertices[0],p_triangle->vertices[1],p_triangle->vertices[2]).intersects_aabb2(aabb))
continue;
} else {
Octant *child=&octants[child_idx];
AABB aabb=child->aabb;
aabb.grow_by(cell_size*octree_extra_margin);
if (!aabb.intersects(p_triangle->aabb))
continue;
encloses=aabb.grow(cell_size*-octree_extra_margin*2.0).encloses(p_triangle->aabb);
if (!encloses && !Face3(p_triangle->vertices[0],p_triangle->vertices[1],p_triangle->vertices[2]).intersects_aabb2(aabb))
continue;
}
if (encloses)
stack[stack_pos]=8; // quick and dirty opt
if (!child_idx) {
if (octant_pool_size==octant_pool.size()) {
octant_pool.resize(octant_pool_size+OCTANT_POOL_CHUNK);
octants=octant_pool.ptr();
octant=&octants[ptr_stack[stack_pos]];
}
child_idx=octant_pool_size++;
octant->children[i]=child_idx;
Octant *child=&octants[child_idx];
child->aabb=octant->aabb;
child->texture_x=0;
child->texture_y=0;
child->aabb.size*=0.5;
if (i&1)
child->aabb.pos.x+=child->aabb.size.x;
if (i&2)
child->aabb.pos.y+=child->aabb.size.y;
if (i&4)
child->aabb.pos.z+=child->aabb.size.z;
child->full_accum[0]=0;
child->full_accum[1]=0;
child->full_accum[2]=0;
child->sampler_ofs=0;
if (stack_pos==octree_depth-1) {
child->leaf=true;
child->offset[0]=child->aabb.pos.x+child->aabb.size.x*0.5;
child->offset[1]=child->aabb.pos.y+child->aabb.size.y*0.5;
child->offset[2]=child->aabb.pos.z+child->aabb.size.z*0.5;
child->next_leaf=leaf_list;
for(int ci=0;ci<8;ci++) {
child->normal_accum[ci][0]=0;
child->normal_accum[ci][1]=0;
child->normal_accum[ci][2]=0;
}
child->bake_neighbour=0;
child->first_neighbour=true;
leaf_list=child_idx;
cell_count++;
for(int ci=0;ci<8;ci++) {
child->light_accum[ci][0]=0;
child->light_accum[ci][1]=0;
child->light_accum[ci][2]=0;
}
child->parent=ptr_stack[stack_pos];
} else {
child->leaf=false;
for(int j=0;j<8;j++) {
child->children[j]=0;
}
}
}
if (!octants[child_idx].leaf) {
stack_pos++;
stack[stack_pos]=0;
ptr_stack[stack_pos]=child_idx;
} else {
Octant *child=&octants[child_idx];
Vector3 n = Plane(p_triangle->vertices[0],p_triangle->vertices[1],p_triangle->vertices[2]).normal;
for(int ci=0;ci<8;ci++) {
Vector3 pos = child->aabb.pos;
if (ci&1)
pos.x+=child->aabb.size.x;
if (ci&2)
pos.y+=child->aabb.size.y;
if (ci&4)
pos.z+=child->aabb.size.z;
pos.x=floor((pos.x+cell_size*0.5)/cell_size);
pos.y=floor((pos.y+cell_size*0.5)/cell_size);
pos.z=floor((pos.z+cell_size*0.5)/cell_size);
{
Map<Vector3,Vector3>::Element *E=endpoint_normal.find(pos);
if (!E) {
endpoint_normal[pos]=n;
} else {
E->get()+=n;
}
}
{
uint64_t bit = get_uv_normal_bit(n);
Map<Vector3,uint64_t>::Element *E=endpoint_normal_bits.find(pos);
if (!E) {
endpoint_normal_bits[pos]=(1<<bit);
} else {
E->get()|=(1<<bit);
}
}
}
}
} else {
stack_pos--;
if (stack_pos<0)
break;
}
}
}
void BakedLightBaker::_make_octree() {
AABB base = bvh->aabb;
float lal=base.get_longest_axis_size();
//must be square because we want square blocks
base.size.x=lal;
base.size.y=lal;
base.size.z=lal;
base.grow_by(lal*0.001); //for precision
octree_aabb=base;
cell_size=base.size.x;
for(int i=0;i<octree_depth;i++)
cell_size/=2.0;
octant_stack = memnew_arr(uint32_t,octree_depth*2 );
octantptr_stack = memnew_arr(uint32_t,octree_depth*2 );
octant_pool.resize(OCTANT_POOL_CHUNK);
octant_pool_size=1;
Octant *root=octant_pool.ptr();
root->leaf=false;
root->aabb=octree_aabb;
root->parent=-1;
for(int i=0;i<8;i++)
root->children[i]=0;
EditorProgress ep("bake_octree",vformat(TTR("Parsing %d Triangles:"), triangles.size()),triangles.size());
for(int i=0;i<triangles.size();i++) {
_octree_insert(0,&triangles[i],octree_depth-1);
if ((i%1000)==0) {
ep.step(TTR("Triangle #")+itos(i),i);
}
}
{
uint32_t oct_idx=leaf_list;
Octant *octants=octant_pool.ptr();
while(oct_idx) {
BakedLightBaker::Octant *oct = &octants[oct_idx];
for(int ci=0;ci<8;ci++) {
Vector3 pos = oct->aabb.pos;
if (ci&1)
pos.x+=oct->aabb.size.x;
if (ci&2)
pos.y+=oct->aabb.size.y;
if (ci&4)
pos.z+=oct->aabb.size.z;
pos.x=floor((pos.x+cell_size*0.5)/cell_size);
pos.y=floor((pos.y+cell_size*0.5)/cell_size);
pos.z=floor((pos.z+cell_size*0.5)/cell_size);
{
Map<Vector3,Vector3>::Element *E=endpoint_normal.find(pos);
if (!E) {
//?
print_line("lolwut?");
} else {
Vector3 n = E->get().normalized();
oct->normal_accum[ci][0]=n.x;
oct->normal_accum[ci][1]=n.y;
oct->normal_accum[ci][2]=n.z;
}
}
{
Map<Vector3,uint64_t>::Element *E=endpoint_normal_bits.find(pos);
if (!E) {
//?
print_line("lolwut?");
} else {
float max_aper=0;
for(uint64_t i=0;i<62;i++) {
if (!(E->get()&(1<<i)))
continue;
Vector3 ang_i = get_bit_normal(i);
for(uint64_t j=0;j<62;j++) {
if (i==j)
continue;
if (!(E->get()&(1<<j)))
continue;
Vector3 ang_j = get_bit_normal(j);
float ang = Math::acos(ang_i.dot(ang_j));
if (ang>max_aper)
max_aper=ang;
}
}
if (max_aper>0.75*Math_PI) {
//angle too wide prevent problems and forget
oct->normal_accum[ci][0]=0;
oct->normal_accum[ci][1]=0;
oct->normal_accum[ci][2]=0;
}
}
}
}
oct_idx=oct->next_leaf;
}
}
}
void BakedLightBaker::_plot_light(ThreadStack& thread_stack,const Vector3& p_plot_pos, const AABB& p_plot_aabb, const Color& p_light,const Color& p_tint_light,bool p_only_full, const Plane& p_plane) {
//stackless version
uint32_t *stack=thread_stack.octant_stack;
uint32_t *ptr_stack=thread_stack.octantptr_stack;
Octant *octants=octant_pool.ptr();
stack[0]=0;
ptr_stack[0]=0;
int stack_pos=0;
while(true) {
Octant &octant=octants[ptr_stack[stack_pos]];
if (stack[stack_pos]==0) {
Vector3 pos = octant.aabb.pos + octant.aabb.size*0.5;
float md = 1<<(octree_depth - stack_pos );
float r=cell_size*plot_size*md;
float div = 1.0/(md*md*md);
//div=1.0;
float d = p_plot_pos.distance_to(pos);
if ((p_plane.distance_to(pos)>-cell_size*1.75*md) && d<=r) {
float intensity = 1.0 - (d/r)*(d/r); //not gauss but..
baked_light_baker_add_64f(&octant.full_accum[0],p_tint_light.r*intensity*div);
baked_light_baker_add_64f(&octant.full_accum[1],p_tint_light.g*intensity*div);
baked_light_baker_add_64f(&octant.full_accum[2],p_tint_light.b*intensity*div);
}
}
if (octant.leaf) {
//if (p_plane.normal.dot(octant.aabb.get_support(p_plane.normal)) < p_plane.d-CMP_EPSILON) { //octants behind are no go
if (!p_only_full) {
float r=cell_size*plot_size;
for(int i=0;i<8;i++) {
Vector3 pos=octant.aabb.pos;
if (i&1)
pos.x+=octant.aabb.size.x;
if (i&2)
pos.y+=octant.aabb.size.y;
if (i&4)
pos.z+=octant.aabb.size.z;
float d = p_plot_pos.distance_to(pos);
if ((p_plane.distance_to(pos)>-cell_size*1.75) && d<=r) {
float intensity = 1.0 - (d/r)*(d/r); //not gauss but..
if (edge_damp>0) {
Vector3 normal = Vector3(octant.normal_accum[i][0],octant.normal_accum[i][1],octant.normal_accum[i][2]);
if (normal.x>0 || normal.y>0 || normal.z>0) {
float damp = Math::abs(p_plane.normal.dot(normal));
intensity*=pow(damp,edge_damp);
}
}
//intensity*=1.0-Math::abs(p_plane.distance_to(pos))/(plot_size*cell_size);
//intensity = Math::cos(d*Math_PI*0.5/r);
baked_light_baker_add_64f(&octant.light_accum[i][0],p_light.r*intensity);
baked_light_baker_add_64f(&octant.light_accum[i][1],p_light.g*intensity);
baked_light_baker_add_64f(&octant.light_accum[i][2],p_light.b*intensity);
}
}
}
stack_pos--;
} else if (stack[stack_pos]<8) {
int i = stack[stack_pos];
stack[stack_pos]++;
if (!octant.children[i]) {
continue;
}
Octant &child=octants[octant.children[i]];
if (!child.aabb.intersects(p_plot_aabb))
continue;
if (child.aabb.encloses(p_plot_aabb)) {
stack[stack_pos]=8; //don't test the rest
}
stack_pos++;
stack[stack_pos]=0;
ptr_stack[stack_pos]=octant.children[i];
} else {
stack_pos--;
if (stack_pos<0)
break;
}
}
}
float BakedLightBaker::_throw_ray(ThreadStack& thread_stack,bool p_bake_direct,const Vector3& p_begin, const Vector3& p_end,float p_rest,const Color& p_light,float *p_att_curve,float p_att_pos,int p_att_curve_len,int p_bounces,bool p_first_bounce,bool p_only_dist) {
uint32_t* stack = thread_stack.ray_stack;
BVH **bstack = thread_stack.bvh_stack;
enum {
TEST_AABB_BIT=0,
VISIT_LEFT_BIT=1,
VISIT_RIGHT_BIT=2,
VISIT_DONE_BIT=3,
};
Vector3 n = (p_end-p_begin);
float len=n.length();
if (len==0)
return 0;
n/=len;
real_t d=1e10;
bool inters=false;
Vector3 r_normal;
Vector3 r_point;
Vector3 end=p_end;
Triangle *triangle=NULL;
/*
for(int i=0;i<max_depth;i++)
stack[i]=0;
*/
int level=0;
//AABB ray_aabb;
//ray_aabb.pos=p_begin;
//ray_aabb.expand_to(p_end);
bstack[0]=bvh;
stack[0]=TEST_AABB_BIT;
while(true) {
uint32_t mode = stack[level];
const BVH &b = *bstack[level];
bool done=false;
switch(mode) {
case TEST_AABB_BIT: {
if (b.leaf) {
Face3 f3(b.leaf->vertices[0],b.leaf->vertices[1],b.leaf->vertices[2]);
Vector3 res;
if (f3.intersects_segment(p_begin,end,&res)) {
float nd = n.dot(res);
if (nd<d) {
d=nd;
r_point=res;
end=res;
len=(p_begin-end).length();
r_normal=f3.get_plane().get_normal();
triangle=b.leaf;
inters=true;
}
}
stack[level]=VISIT_DONE_BIT;
} else {
bool valid = b.aabb.smits_intersect_ray(p_begin,n,0,len);
//bool valid = b.aabb.intersects_segment(p_begin,p_end);
//bool valid = b.aabb.intersects(ray_aabb);
if (!valid) {
stack[level]=VISIT_DONE_BIT;
} else {
stack[level]=VISIT_LEFT_BIT;
}
}
} continue;
case VISIT_LEFT_BIT: {
stack[level]=VISIT_RIGHT_BIT;
bstack[level+1]=b.children[0];
stack[level+1]=TEST_AABB_BIT;
level++;
} continue;
case VISIT_RIGHT_BIT: {
stack[level]=VISIT_DONE_BIT;
bstack[level+1]=b.children[1];
stack[level+1]=TEST_AABB_BIT;
level++;
} continue;
case VISIT_DONE_BIT: {
if (level==0) {
done=true;
break;
} else
level--;
} continue;
}
if (done)
break;
}
if (inters) {
if (p_only_dist) {
return p_begin.distance_to(r_point);
}
//should check if there is normals first
Vector2 uv;
if (true) {
triangle->get_uv_and_normal(r_point,uv,r_normal);
} else {
}
if (n.dot(r_normal)>0)
return -1;
if (n.dot(r_normal)>0)
r_normal=-r_normal;
//ok...
Color diffuse_at_point(0.8,0.8,0.8);
Color specular_at_point(0.0,0.0,0.0);
float dist = p_begin.distance_to(r_point);
AABB aabb;
aabb.pos=r_point;
aabb.pos-=Vector3(1,1,1)*cell_size*plot_size;
aabb.size=Vector3(2,2,2)*cell_size*plot_size;
Color res_light=p_light;
float att=1.0;
float dp=(1.0-normal_damp)*n.dot(-r_normal)+normal_damp;
if (p_att_curve) {
p_att_pos+=dist;
int cpos = Math::fast_ftoi((p_att_pos/p_att_curve_len)*ATTENUATION_CURVE_LEN);
cpos=CLAMP(cpos,0,ATTENUATION_CURVE_LEN-1);
att=p_att_curve[cpos];
}
res_light.r*=dp;
res_light.g*=dp;
res_light.b*=dp;
//light is plotted before multiplication with diffuse, this way
//the multiplication can happen with more detail in the shader
if (triangle->material) {
//triangle->get_uv(r_point);
diffuse_at_point=triangle->material->diffuse.get_color(uv);
specular_at_point=triangle->material->specular.get_color(uv);
}
diffuse_at_point.r=res_light.r*diffuse_at_point.r;
diffuse_at_point.g=res_light.g*diffuse_at_point.g;
diffuse_at_point.b=res_light.b*diffuse_at_point.b;
if (p_bounces>0) {
p_rest-=dist;
if (p_rest<CMP_EPSILON)
return 0;
if (r_normal==-n)
return 0; //todo change a little
r_point+=r_normal*0.01;
specular_at_point.r=res_light.r*specular_at_point.r;
specular_at_point.g=res_light.g*specular_at_point.g;
specular_at_point.b=res_light.b*specular_at_point.b;
if (use_diffuse && (diffuse_at_point.r>CMP_EPSILON || diffuse_at_point.g>CMP_EPSILON || diffuse_at_point.b>CMP_EPSILON)) {
//diffuse bounce
Vector3 c1=r_normal.cross(n).normalized();
Vector3 c2=r_normal.cross(c1).normalized();
double r1 = double(rand())/RAND_MAX;
double r2 = double(rand())/RAND_MAX;
double r3 = double(rand())/RAND_MAX;
#if 0
Vector3 next = - ((c1*(r1-0.5)) + (c2*(r2-0.5)) + (r_normal*(r3-0.5))).normalized()*0.5 + r_normal*0.5;
if (next==Vector3())
next=r_normal;
Vector3 rn=next.normalized();
#else
Vector3 rn = ((c1*(r1-0.5)) + (c2*(r2-0.5)) + (r_normal*r3*0.5)).normalized();
#endif
_throw_ray(thread_stack,p_bake_direct,r_point,r_point+rn*p_rest,p_rest,diffuse_at_point,p_att_curve,p_att_pos,p_att_curve_len,p_bounces-1);
}
if (use_specular && (specular_at_point.r>CMP_EPSILON || specular_at_point.g>CMP_EPSILON || specular_at_point.b>CMP_EPSILON)) {
//specular bounce
//Vector3 c1=r_normal.cross(n).normalized();
//Vector3 c2=r_normal.cross(c1).normalized();
Vector3 rn = n - r_normal *r_normal.dot(n) * 2.0;
_throw_ray(thread_stack,p_bake_direct,r_point,r_point+rn*p_rest,p_rest,specular_at_point,p_att_curve,p_att_pos,p_att_curve_len,p_bounces-1);
}
}
//specular later
//_plot_light_point(r_point,octree,octree_aabb,p_light);
Color plot_light=res_light.linear_interpolate(diffuse_at_point,tint);
plot_light.r*=att;
plot_light.g*=att;
plot_light.b*=att;
Color tint_light=diffuse_at_point;
tint_light.r*=att;
tint_light.g*=att;
tint_light.b*=att;
bool skip=false;
if (!p_first_bounce || p_bake_direct) {
float r = plot_size * cell_size*2;
if (dist<r) {
//avoid accumulaiton of light on corners
//plot_light=plot_light.linear_interpolate(Color(0,0,0,0),1.0-sd/plot_size*plot_size);
skip=true;
} else {
Vector3 c1=r_normal.cross(n).normalized();
Vector3 c2=r_normal.cross(c1).normalized();
double r1 = double(rand())/RAND_MAX;
double r2 = double(rand())/RAND_MAX;
double r3 = double(rand())/RAND_MAX;
Vector3 rn = ((c1*(r1-0.5)) + (c2*(r2-0.5)) + (r_normal*r3*0.25)).normalized();
float d =_throw_ray(thread_stack,p_bake_direct,r_point,r_point+rn*p_rest,p_rest,diffuse_at_point,p_att_curve,p_att_pos,p_att_curve_len,p_bounces-1,false,true);
r = plot_size*cell_size*ao_radius;
if (d>0 && d<r) {
//avoid accumulaiton of light on corners
//plot_light=plot_light.linear_interpolate(Color(0,0,0,0),1.0-sd/plot_size*plot_size);
skip=true;
} else {
//plot_light=Color(0,0,0,0);
}
}
}
Plane plane(r_point,r_normal);
if (!skip)
_plot_light(thread_stack,r_point,aabb,plot_light,tint_light,!(!p_first_bounce || p_bake_direct),plane);
return dist;
}
return -1;
}
void BakedLightBaker::_make_octree_texture() {
BakedLightBaker::Octant *octants=octant_pool.ptr();
//find neighbours first, to have a better idea of what amount of space is needed
{
Vector<OctantHash> octant_hashing;
octant_hashing.resize(octant_pool_size);
Vector<uint32_t> hash_table;
int hash_table_size=Math::larger_prime(16384);
hash_table.resize(hash_table_size);
uint32_t*hashptr = hash_table.ptr();
OctantHash*octhashptr = octant_hashing.ptr();
for(int i=0;i<hash_table_size;i++)
hashptr[i]=0;
//step 1 add to hash table
uint32_t oct_idx=leaf_list;
while(oct_idx) {
BakedLightBaker::Octant *oct = &octants[oct_idx];
uint64_t base=0;
Vector3 pos = oct->aabb.pos - octree_aabb.pos; //make sure is always positive
base=int((pos.x+cell_size*0.5)/cell_size);
base<<=16;
base|=int((pos.y+cell_size*0.5)/cell_size);
base<<=16;
base|=int((pos.z+cell_size*0.5)/cell_size);
uint32_t hash = HashMapHasherDefault::hash(base);
uint32_t idx = hash % hash_table_size;
octhashptr[oct_idx].next=hashptr[idx];
octhashptr[oct_idx].hash=hash;
octhashptr[oct_idx].value=base;
hashptr[idx]=oct_idx;
oct_idx=oct->next_leaf;
}
//step 2 find neighbours
oct_idx=leaf_list;
int neighbours=0;
while(oct_idx) {
BakedLightBaker::Octant *oct = &octants[oct_idx];
Vector3 pos = oct->aabb.pos - octree_aabb.pos; //make sure is always positive
pos.x+=cell_size;
uint64_t base=0;
base=int((pos.x+cell_size*0.5)/cell_size);
base<<=16;
base|=int((pos.y+cell_size*0.5)/cell_size);
base<<=16;
base|=int((pos.z+cell_size*0.5)/cell_size);
uint32_t hash = HashMapHasherDefault::hash(base);
uint32_t idx = hash % hash_table_size;
uint32_t bucket = hashptr[idx];
while(bucket) {
if (octhashptr[bucket].value==base) {
oct->bake_neighbour=bucket;
octants[bucket].first_neighbour=false;
neighbours++;
break;
}
bucket = octhashptr[bucket].next;
}
oct_idx=oct->next_leaf;
}
print_line("octant with neighbour: "+itos(neighbours));
}
//ok let's try to just create a texture
int otex_w=256;
while (true) {
uint32_t oct_idx=leaf_list;
int row=0;
print_line("begin at row "+itos(row));
int longest_line_reused=0;
int col=0;
int processed=0;
//reset
while(oct_idx) {
BakedLightBaker::Octant *oct = &octants[oct_idx];
oct->texture_x=0;
oct->texture_y=0;
oct_idx=oct->next_leaf;
}
oct_idx=leaf_list;
//assign
while(oct_idx) {
BakedLightBaker::Octant *oct = &octants[oct_idx];
if (oct->first_neighbour && oct->texture_x==0 && oct->texture_y==0) {
//was not processed
uint32_t current_idx=oct_idx;
int reused=0;
while(current_idx) {
BakedLightBaker::Octant *o = &octants[current_idx];
if (col+1 >= otex_w) {
col=0;
row+=4;
}
o->texture_x=col;
o->texture_y=row;
processed++;
if (o->bake_neighbour) {
reused++;
}
col+=o->bake_neighbour ? 1 : 2; //reuse neighbour
current_idx=o->bake_neighbour;
}
if (reused>longest_line_reused) {
longest_line_reused=reused;
}
}
oct_idx=oct->next_leaf;
}
row+=4;
if (otex_w < row) {
otex_w*=2;
} else {
baked_light_texture_w=otex_w;
baked_light_texture_h=next_power_of_2(row);
print_line("w: "+itos(otex_w));
print_line("h: "+itos(row));
break;
}
}
{
otex_w=(1<<lattice_size)*(1<<lattice_size)*2; //make sure lattice fits horizontally
Vector3 lattice_cell_size=octree_aabb.size;
for(int i=0;i<lattice_size;i++) {
lattice_cell_size*=0.5;
}
while(true) {
//let's plot the leafs first, given the octree is not so obvious which size it will have
int row=4+4*(1<<lattice_size);
int col=0;
col=0;
row+=4;
print_line("end at row "+itos(row));
//put octree, no need for recursion, just loop backwards.
int regular_octants=0;
for(int i=octant_pool_size-1;i>=0;i--) {
BakedLightBaker::Octant *oct = &octants[i];
if (oct->leaf) //ignore leaf
continue;
if (oct->aabb.size.x>lattice_cell_size.x*1.1) { //bigger than latice, skip
oct->texture_x=0;
oct->texture_y=0;
} else if (oct->aabb.size.x>lattice_cell_size.x*0.8) {
//this is the initial lattice
Vector3 pos = oct->aabb.pos - octree_aabb.pos; //make sure is always positive
int x = int((pos.x+lattice_cell_size.x*0.5)/lattice_cell_size.x);
int y = int((pos.y+lattice_cell_size.y*0.5)/lattice_cell_size.y);
int z = int((pos.z+lattice_cell_size.z*0.5)/lattice_cell_size.z);
//bug net
ERR_FAIL_INDEX(x,(1<<lattice_size));
ERR_FAIL_INDEX(y,(1<<lattice_size));
ERR_FAIL_INDEX(z,(1<<lattice_size));
/*int ofs = z*(1<<lattice_size)*(1<<lattice_size)+y*(1<<lattice_size)+x;
ofs*=4;
oct->texture_x=ofs%otex_w;
oct->texture_y=(ofs/otex_w)*4+4;
*/
oct->texture_x=(x+(1<<lattice_size)*z)*2;
oct->texture_y=4+y*4;
//print_line("pos: "+itos(x)+","+itos(y)+","+itos(z)+" - ofs"+itos(oct->texture_x)+","+itos(oct->texture_y));
} else {
//an everyday regular octant
if (col+2 > otex_w) {
col=0;
row+=4;
}
oct->texture_x=col;
oct->texture_y=row;
col+=2;
regular_octants++;
}
}
print_line("octants end at row "+itos(row)+" totalling"+itos(regular_octants));
//ok evaluation.
if (otex_w<=2048 && row>2048) { //too big upwards, try bigger texture
otex_w*=2;
continue;
} else {
baked_octree_texture_w=otex_w;
baked_octree_texture_h=row+4;
break;
}
}
}
baked_octree_texture_h=next_power_of_2(baked_octree_texture_h);
print_line("RESULT! "+itos(baked_octree_texture_w)+","+itos(baked_octree_texture_h));
}
double BakedLightBaker::get_normalization(int p_light_idx) const {
double nrg=0;
const LightData &dl=lights[p_light_idx];
double cell_area = cell_size*cell_size;
//nrg+= /*dl.energy */ (dl.rays_thrown * cell_area / dl.area);
nrg=dl.rays_thrown * cell_area;
nrg*=(Math_PI*plot_size*plot_size)*0.5; // damping of radial linear gradient kernel
nrg*=dl.constant;
//nrg*=5;
return nrg;
}
double BakedLightBaker::get_modifier(int p_light_idx) const {
double nrg=0;
const LightData &dl=lights[p_light_idx];
double cell_area = cell_size*cell_size;
//nrg+= /*dl.energy */ (dl.rays_thrown * cell_area / dl.area);
nrg=cell_area;
nrg*=(Math_PI*plot_size*plot_size)*0.5; // damping of radial linear gradient kernel
nrg*=dl.constant;
//nrg*=5;
return nrg;
}
void BakedLightBaker::throw_rays(ThreadStack& thread_stack,int p_amount) {
for(int i=0;i<lights.size();i++) {
LightData &dl=lights[i];
int amount = p_amount * total_light_area / dl.area;
double mod = 1.0/double(get_modifier(i));
mod*=p_amount/float(amount);
switch(dl.type) {
case VS::LIGHT_DIRECTIONAL: {
for(int j=0;j<amount;j++) {
Vector3 from = dl.pos;
double r1 = double(rand())/RAND_MAX;
double r2 = double(rand())/RAND_MAX;
from+=dl.up*(r1*2.0-1.0);
from+=dl.left*(r2*2.0-1.0);
Vector3 to = from+dl.dir*dl.length;
Color col=dl.diffuse;
float m = mod*dl.energy;
col.r*=m;
col.g*=m;
col.b*=m;
dl.rays_thrown++;
baked_light_baker_add_64i(&total_rays,1);
_throw_ray(thread_stack,dl.bake_direct,from,to,dl.length,col,NULL,0,0,max_bounces,true);
}
} break;
case VS::LIGHT_OMNI: {
for(int j=0;j<amount;j++) {
Vector3 from = dl.pos;
double r1 = double(rand())/RAND_MAX;
double r2 = double(rand())/RAND_MAX;
double r3 = double(rand())/RAND_MAX;
#if 0
//crap is not uniform..
Vector3 dir = Vector3(r1*2.0-1.0,r2*2.0-1.0,r3*2.0-1.0).normalized();
#else
double phi = r1*Math_PI*2.0;
double costheta = r2*2.0-1.0;
double u = r3;
double theta = acos( costheta );
double r = 1.0 * pow( u,1/3.0 );
Vector3 dir(
r * sin( theta) * cos( phi ),
r * sin( theta) * sin( phi ),
r * cos( theta )
);
dir.normalize();
#endif
Vector3 to = dl.pos+dir*dl.radius;
Color col=dl.diffuse;
float m = mod*dl.energy;
col.r*=m;
col.g*=m;
col.b*=m;
dl.rays_thrown++;
baked_light_baker_add_64i(&total_rays,1);
_throw_ray(thread_stack,dl.bake_direct,from,to,dl.radius,col,dl.attenuation_table.ptr(),0,dl.radius,max_bounces,true);
//_throw_ray(i,from,to,dl.radius,col,NULL,0,dl.radius,max_bounces,true);
}
} break;
case VS::LIGHT_SPOT: {
for(int j=0;j<amount;j++) {
Vector3 from = dl.pos;
double r1 = double(rand())/RAND_MAX;
//double r2 = double(rand())/RAND_MAX;
double r3 = double(rand())/RAND_MAX;
float d=Math::tan(Math::deg2rad(dl.spot_angle));
float x = sin(r1*Math_PI*2.0)*d;
float y = cos(r1*Math_PI*2.0)*d;
Vector3 dir = r3*(dl.dir + dl.up*y + dl.left*x) + (1.0-r3)*dl.dir;
dir.normalize();
Vector3 to = dl.pos+dir*dl.radius;
Color col=dl.diffuse;
float m = mod*dl.energy;
col.r*=m;
col.g*=m;
col.b*=m;
dl.rays_thrown++;
baked_light_baker_add_64i(&total_rays,1);
_throw_ray(thread_stack,dl.bake_direct,from,to,dl.radius,col,dl.attenuation_table.ptr(),0,dl.radius,max_bounces,true);
//_throw_ray(i,from,to,dl.radius,col,NULL,0,dl.radius,max_bounces,true);
}
} break;
}
}
}
void BakedLightBaker::bake(const Ref<BakedLight> &p_light, Node* p_node) {
if (baking)
return;
cell_count=0;
base_inv=p_node->cast_to<Spatial>()->get_global_transform().affine_inverse();
EditorProgress ep("bake",TTR("Light Baker Setup:"),5);
baked_light=p_light;
lattice_size=baked_light->get_initial_lattice_subdiv();
octree_depth=baked_light->get_cell_subdivision();
plot_size=baked_light->get_plot_size();
max_bounces=baked_light->get_bounces();
use_diffuse=baked_light->get_bake_flag(BakedLight::BAKE_DIFFUSE);
use_specular=baked_light->get_bake_flag(BakedLight::BAKE_SPECULAR);
use_translucency=baked_light->get_bake_flag(BakedLight::BAKE_TRANSLUCENT);
edge_damp=baked_light->get_edge_damp();
normal_damp=baked_light->get_normal_damp();
octree_extra_margin=baked_light->get_cell_extra_margin();
tint=baked_light->get_tint();
ao_radius=baked_light->get_ao_radius();
ao_strength=baked_light->get_ao_strength();
linear_color=baked_light->get_bake_flag(BakedLight::BAKE_LINEAR_COLOR);
baked_textures.clear();
for(int i=0;i<baked_light->get_lightmaps_count();i++) {
BakeTexture bt;
bt.width=baked_light->get_lightmap_gen_size(i).x;
bt.height=baked_light->get_lightmap_gen_size(i).y;
baked_textures.push_back(bt);
}
ep.step(TTR("Parsing Geometry"),0);
_parse_geometry(p_node);
mat_map.clear();
tex_map.clear();
print_line("\ttotal triangles: "+itos(triangles.size()));
// no geometry
if (triangles.size() == 0) {
return;
}
ep.step(TTR("Fixing Lights"),1);
_fix_lights();
ep.step(TTR("Making BVH"),2);
_make_bvh();
ep.step(TTR("Creating Light Octree"),3);
_make_octree();
ep.step(TTR("Creating Octree Texture"),4);
_make_octree_texture();
baking=true;
_start_thread();
}
void BakedLightBaker::update_octree_sampler(PoolVector<int> &p_sampler) {
BakedLightBaker::Octant *octants=octant_pool.ptr();
double norm = 1.0/double(total_rays);
if (p_sampler.size()==0 || first_bake_to_map) {
Vector<int> tmp_smp;
tmp_smp.resize(32); //32 for header
for(int i=0;i<32;i++) {
tmp_smp[i]=0;
}
for(int i=octant_pool_size-1;i>=0;i--) {
if (i==0)
tmp_smp[1]=tmp_smp.size();
Octant &octant=octants[i];
octant.sampler_ofs = tmp_smp.size();
int idxcol[2]={0,0};
int r = CLAMP((octant.full_accum[0]*norm)*2048,0,32767);
int g = CLAMP((octant.full_accum[1]*norm)*2048,0,32767);
int b = CLAMP((octant.full_accum[2]*norm)*2048,0,32767);
idxcol[0]|=r;
idxcol[1]|=(g<<16)|b;
if (octant.leaf) {
tmp_smp.push_back(idxcol[0]);
tmp_smp.push_back(idxcol[1]);
} else {
for(int j=0;j<8;j++) {
if (octant.children[j]) {
idxcol[0]|=(1<<(j+16));
}
}
tmp_smp.push_back(idxcol[0]);
tmp_smp.push_back(idxcol[1]);
for(int j=0;j<8;j++) {
if (octant.children[j]) {
tmp_smp.push_back(octants[octant.children[j]].sampler_ofs);
if (octants[octant.children[j]].sampler_ofs==0) {
print_line("FUUUUUUUUCK");
}
}
}
}
}
p_sampler.resize(tmp_smp.size());
PoolVector<int>::Write w = p_sampler.write();
int ss = tmp_smp.size();
for(int i=0;i<ss;i++) {
w[i]=tmp_smp[i];
}
first_bake_to_map=false;
}
double gamma = baked_light->get_gamma_adjust();
double mult = baked_light->get_energy_multiplier();
float saturation = baked_light->get_saturation();
PoolVector<int>::Write w = p_sampler.write();
encode_uint32(octree_depth,(uint8_t*)&w[2]);
encode_uint32(linear_color,(uint8_t*)&w[3]);
encode_float(octree_aabb.pos.x,(uint8_t*)&w[4]);
encode_float(octree_aabb.pos.y,(uint8_t*)&w[5]);
encode_float(octree_aabb.pos.z,(uint8_t*)&w[6]);
encode_float(octree_aabb.size.x,(uint8_t*)&w[7]);
encode_float(octree_aabb.size.y,(uint8_t*)&w[8]);
encode_float(octree_aabb.size.z,(uint8_t*)&w[9]);
//norm*=multiplier;
for(int i=octant_pool_size-1;i>=0;i--) {
Octant &octant=octants[i];
int idxcol[2]={w[octant.sampler_ofs],w[octant.sampler_ofs+1]};
double rf=pow(octant.full_accum[0]*norm*mult,gamma);
double gf=pow(octant.full_accum[1]*norm*mult,gamma);
double bf=pow(octant.full_accum[2]*norm*mult,gamma);
double gray = (rf+gf+bf)/3.0;
rf = gray + (rf-gray)*saturation;
gf = gray + (gf-gray)*saturation;
bf = gray + (bf-gray)*saturation;
int r = CLAMP((rf)*2048,0,32767);
int g = CLAMP((gf)*2048,0,32767);
int b = CLAMP((bf)*2048,0,32767);
idxcol[0]=((idxcol[0]>>16)<<16)|r;
idxcol[1]=(g<<16)|b;
w[octant.sampler_ofs]=idxcol[0];
w[octant.sampler_ofs+1]=idxcol[1];
}
}
void BakedLightBaker::update_octree_images(PoolVector<uint8_t> &p_octree,PoolVector<uint8_t> &p_light) {
int len = baked_octree_texture_w*baked_octree_texture_h*4;
p_octree.resize(len);
int ilen = baked_light_texture_w*baked_light_texture_h*4;
p_light.resize(ilen);
PoolVector<uint8_t>::Write w = p_octree.write();
zeromem(w.ptr(),len);
PoolVector<uint8_t>::Write iw = p_light.write();
zeromem(iw.ptr(),ilen);
float gamma = baked_light->get_gamma_adjust();
float mult = baked_light->get_energy_multiplier();
for(int i=0;i<len;i+=4) {
w[i+0]=0xFF;
w[i+1]=0;
w[i+2]=0xFF;
w[i+3]=0xFF;
}
for(int i=0;i<ilen;i+=4) {
iw[i+0]=0xFF;
iw[i+1]=0;
iw[i+2]=0xFF;
iw[i+3]=0xFF;
}
float multiplier=1.0;
if (baked_light->get_format()==BakedLight::FORMAT_HDR8)
multiplier=8;
encode_uint32(baked_octree_texture_w,&w[0]);
encode_uint32(baked_octree_texture_h,&w[4]);
encode_uint32(0,&w[8]);
encode_float(1<<lattice_size,&w[12]);
encode_uint32(octree_depth-lattice_size,&w[16]);
encode_uint32(multiplier,&w[20]);
encode_uint16(baked_light_texture_w,&w[24]); //if present, use the baked light texture
encode_uint16(baked_light_texture_h,&w[26]);
encode_uint32(0,&w[28]); //baked light texture format
encode_float(octree_aabb.pos.x,&w[32]);
encode_float(octree_aabb.pos.y,&w[36]);
encode_float(octree_aabb.pos.z,&w[40]);
encode_float(octree_aabb.size.x,&w[44]);
encode_float(octree_aabb.size.y,&w[48]);
encode_float(octree_aabb.size.z,&w[52]);
BakedLightBaker::Octant *octants=octant_pool.ptr();
int octant_count=octant_pool_size;
uint8_t *ptr = w.ptr();
uint8_t *lptr = iw.ptr();
int child_offsets[8]={
0,
4,
baked_octree_texture_w*4,
baked_octree_texture_w*4+4,
baked_octree_texture_w*8+0,
baked_octree_texture_w*8+4,
baked_octree_texture_w*8+baked_octree_texture_w*4,
baked_octree_texture_w*8+baked_octree_texture_w*4+4,
};
int lchild_offsets[8]={
0,
4,
baked_light_texture_w*4,
baked_light_texture_w*4+4,
baked_light_texture_w*8+0,
baked_light_texture_w*8+4,
baked_light_texture_w*8+baked_light_texture_w*4,
baked_light_texture_w*8+baked_light_texture_w*4+4,
};
/*Vector<double> norm_arr;
norm_arr.resize(lights.size());
for(int i=0;i<lights.size();i++) {
norm_arr[i] = 1.0/get_normalization(i);
}
const double *normptr=norm_arr.ptr();
*/
double norm = 1.0/double(total_rays);
mult/=multiplier;
double saturation = baked_light->get_saturation();
for(int i=0;i<octant_count;i++) {
Octant &oct=octants[i];
if (oct.texture_x==0 && oct.texture_y==0)
continue;
if (oct.leaf) {
int ofs = (oct.texture_y * baked_light_texture_w + oct.texture_x)<<2;
ERR_CONTINUE(ofs<0 || ofs >ilen);
//write colors
for(int j=0;j<8;j++) {
/*
if (!oct.children[j])
continue;
*/
uint8_t *iptr=&lptr[ofs+lchild_offsets[j]];
float r=oct.light_accum[j][0]*norm;
float g=oct.light_accum[j][1]*norm;
float b=oct.light_accum[j][2]*norm;
r=pow(r*mult,gamma);
g=pow(g*mult,gamma);
b=pow(b*mult,gamma);
double gray = (r+g+b)/3.0;
r = gray + (r-gray)*saturation;
g = gray + (g-gray)*saturation;
b = gray + (b-gray)*saturation;
float ic[3]={
r,
g,
b,
};
iptr[0]=CLAMP(ic[0]*255.0,0,255);
iptr[1]=CLAMP(ic[1]*255.0,0,255);
iptr[2]=CLAMP(ic[2]*255.0,0,255);
iptr[3]=255;
}
} else {
int ofs = (oct.texture_y * baked_octree_texture_w + oct.texture_x)<<2;
ERR_CONTINUE(ofs<0 || ofs >len);
//write indices
for(int j=0;j<8;j++) {
if (!oct.children[j])
continue;
Octant&choct=octants[oct.children[j]];
uint8_t *iptr=&ptr[ofs+child_offsets[j]];
iptr[0]=choct.texture_x>>8;
iptr[1]=choct.texture_x&0xFF;
iptr[2]=choct.texture_y>>8;
iptr[3]=choct.texture_y&0xFF;
}
}
}
}
void BakedLightBaker::_free_bvh(BVH* p_bvh) {
if (!p_bvh->leaf) {
if (p_bvh->children[0])
_free_bvh(p_bvh->children[0]);
if (p_bvh->children[1])
_free_bvh(p_bvh->children[1]);
}
memdelete(p_bvh);
}
bool BakedLightBaker::is_baking() {
return baking;
}
void BakedLightBaker::set_pause(bool p_pause){
if (paused==p_pause)
return;
paused=p_pause;
if (paused) {
_stop_thread();
} else {
_start_thread();
}
}
bool BakedLightBaker::is_paused() {
return paused;
}
void BakedLightBaker::_bake_thread_func(void *arg) {
BakedLightBaker *ble = (BakedLightBaker*)arg;
ThreadStack thread_stack;
thread_stack.ray_stack = memnew_arr(uint32_t,ble->bvh_depth);
thread_stack.bvh_stack = memnew_arr(BVH*,ble->bvh_depth);
thread_stack.octant_stack = memnew_arr(uint32_t,ble->octree_depth*2 );
thread_stack.octantptr_stack = memnew_arr(uint32_t,ble->octree_depth*2 );
while(!ble->bake_thread_exit) {
ble->throw_rays(thread_stack,1000);
}
memdelete_arr(thread_stack.ray_stack );
memdelete_arr(thread_stack.bvh_stack );
memdelete_arr(thread_stack.octant_stack );
memdelete_arr(thread_stack.octantptr_stack );
}
void BakedLightBaker::_start_thread() {
if (threads.size()!=0)
return;
bake_thread_exit=false;
int thread_count = EDITOR_DEF("light_baker/custom_bake_threads",0);
if (thread_count<=0 || thread_count>64)
thread_count=OS::get_singleton()->get_processor_count();
//thread_count=1;
threads.resize(thread_count);
for(int i=0;i<threads.size();i++) {
threads[i]=Thread::create(_bake_thread_func,this);
}
}
void BakedLightBaker::_stop_thread() {
if (threads.size()==0)
return;
bake_thread_exit=true;
for(int i=0;i<threads.size();i++) {
Thread::wait_to_finish(threads[i]);
memdelete(threads[i]);
}
threads.clear();
}
void BakedLightBaker::_plot_pixel_to_lightmap(int x, int y, int width, int height, uint8_t *image, const Vector3& p_pos,const Vector3& p_normal,double *p_norm_ptr,float mult,float gamma) {
uint8_t *ptr = &image[(y*width+x)*4];
//int lc = lights.size();
double norm = 1.0/double(total_rays);
Color color;
Octant *octants=octant_pool.ptr();
int octant_idx=0;
while(true) {
Octant &octant=octants[octant_idx];
if (octant.leaf) {
Vector3 lpos = p_pos-octant.aabb.pos;
lpos/=octant.aabb.size;
Vector3 cols[8];
for(int i=0;i<8;i++) {
cols[i].x+=octant.light_accum[i][0]*norm;
cols[i].y+=octant.light_accum[i][1]*norm;
cols[i].z+=octant.light_accum[i][2]*norm;
}
/*Vector3 final = (cols[0] + (cols[1] - cols[0]) * lpos.y);
final = final + ((cols[2] + (cols[3] - cols[2]) * lpos.y) - final)*lpos.x;
Vector3 final2 = (cols[4+0] + (cols[4+1] - cols[4+0]) * lpos.y);
final2 = final2 + ((cols[4+2] + (cols[4+3] - cols[4+2]) * lpos.y) - final2)*lpos.x;*/
Vector3 finala = cols[0].linear_interpolate(cols[1],lpos.x);
Vector3 finalb = cols[2].linear_interpolate(cols[3],lpos.x);
Vector3 final = finala.linear_interpolate(finalb,lpos.y);
Vector3 final2a = cols[4+0].linear_interpolate(cols[4+1],lpos.x);
Vector3 final2b = cols[4+2].linear_interpolate(cols[4+3],lpos.x);
Vector3 final2 = final2a.linear_interpolate(final2b,lpos.y);
final = final.linear_interpolate(final2,lpos.z);
if (baked_light->get_format()==BakedLight::FORMAT_HDR8)
final*=8.0;
color.r=pow(final.x*mult,gamma);
color.g=pow(final.y*mult,gamma);
color.b=pow(final.z*mult,gamma);
color.a=1.0;
int lc = lights.size();
LightData *lv = lights.ptr();
for(int i=0;i<lc;i++) {
//shadow baking
if (!lv[i].bake_shadow)
continue;
Vector3 from = p_pos+p_normal*0.01;
Vector3 to;
float att=0;
switch(lv[i].type) {
case VS::LIGHT_DIRECTIONAL: {
to=from-lv[i].dir*lv[i].length;
} break;
case VS::LIGHT_OMNI: {
to=lv[i].pos;
float d = MIN(lv[i].radius,to.distance_to(from))/lv[i].radius;
att=d;//1.0-d;
} break;
default: continue;
}
uint32_t* stack = ray_stack;
BVH **bstack = bvh_stack;
enum {
TEST_RAY_BIT=0,
VISIT_LEFT_BIT=1,
VISIT_RIGHT_BIT=2,
VISIT_DONE_BIT=3,
};
bool intersected=false;
int level=0;
Vector3 n = (to-from);
float len=n.length();
if (len==0)
continue;
n/=len;
bstack[0]=bvh;
stack[0]=TEST_RAY_BIT;
while(!intersected) {
uint32_t mode = stack[level];
const BVH &b = *bstack[level];
bool done=false;
switch(mode) {
case TEST_RAY_BIT: {
if (b.leaf) {
Face3 f3(b.leaf->vertices[0],b.leaf->vertices[1],b.leaf->vertices[2]);
Vector3 res;
if (f3.intersects_segment(from,to)) {
intersected=true;
done=true;
}
stack[level]=VISIT_DONE_BIT;
} else {
bool valid = b.aabb.smits_intersect_ray(from,n,0,len);
//bool valid = b.aabb.intersects_segment(p_begin,p_end);
//bool valid = b.aabb.intersects(ray_aabb);
if (!valid) {
stack[level]=VISIT_DONE_BIT;
} else {
stack[level]=VISIT_LEFT_BIT;
}
}
} continue;
case VISIT_LEFT_BIT: {
stack[level]=VISIT_RIGHT_BIT;
bstack[level+1]=b.children[0];
stack[level+1]=TEST_RAY_BIT;
level++;
} continue;
case VISIT_RIGHT_BIT: {
stack[level]=VISIT_DONE_BIT;
bstack[level+1]=b.children[1];
stack[level+1]=TEST_RAY_BIT;
level++;
} continue;
case VISIT_DONE_BIT: {
if (level==0) {
done=true;
break;
} else
level--;
} continue;
}
if (done)
break;
}
if (intersected) {
color.a=Math::lerp(MAX(0.01,lv[i].darkening),1.0,att);
}
}
break;
} else {
Vector3 lpos = p_pos - octant.aabb.pos;
Vector3 half = octant.aabb.size * 0.5;
int ofs=0;
if (lpos.x >= half.x)
ofs|=1;
if (lpos.y >= half.y)
ofs|=2;
if (lpos.z >= half.z)
ofs|=4;
octant_idx = octant.children[ofs];
if (octant_idx==0)
return;
}
}
ptr[0]=CLAMP(color.r*255.0,0,255);
ptr[1]=CLAMP(color.g*255.0,0,255);
ptr[2]=CLAMP(color.b*255.0,0,255);
ptr[3]=CLAMP(color.a*255.0,0,255);
}
Error BakedLightBaker::transfer_to_lightmaps() {
if (!triangles.size() || baked_textures.size()==0)
return ERR_UNCONFIGURED;
EditorProgress ep("transfer_to_lightmaps",TTR("Transfer to Lightmaps:"),baked_textures.size()*2+triangles.size());
for(int i=0;i<baked_textures.size();i++) {
ERR_FAIL_COND_V( baked_textures[i].width<=0 || baked_textures[i].height<=0,ERR_UNCONFIGURED );
baked_textures[i].data.resize( baked_textures[i].width*baked_textures[i].height*4 );
zeromem(baked_textures[i].data.ptr(),baked_textures[i].data.size());
ep.step(TTR("Allocating Texture #")+itos(i+1),i);
}
Vector<double> norm_arr;
norm_arr.resize(lights.size());
for(int i=0;i<lights.size();i++) {
norm_arr[i] = 1.0/get_normalization(i);
}
float gamma = baked_light->get_gamma_adjust();
float mult = baked_light->get_energy_multiplier();
for(int i=0;i<triangles.size();i++) {
if (i%200==0) {
ep.step(TTR("Baking Triangle #")+itos(i),i+baked_textures.size());
}
Triangle &t=triangles[i];
if (t.baked_texture<0 || t.baked_texture>=baked_textures.size())
continue;
BakeTexture &bt=baked_textures[t.baked_texture];
Vector3 normal = Plane(t.vertices[0],t.vertices[1],t.vertices[2]).normal;
int x[3];
int y[3];
Vector3 vertices[3]={
t.vertices[0],
t.vertices[1],
t.vertices[2]
};
for(int j=0;j<3;j++) {
x[j]=t.bake_uvs[j].x*bt.width;
y[j]=t.bake_uvs[j].y*bt.height;
x[j]=CLAMP(x[j],0,bt.width-1);
y[j]=CLAMP(y[j],0,bt.height-1);
}
{
// sort the points vertically
if (y[1] > y[2]) {
SWAP(x[1], x[2]);
SWAP(y[1], y[2]);
SWAP(vertices[1],vertices[2]);
}
if (y[0] > y[1]) {
SWAP(x[0], x[1]);
SWAP(y[0], y[1]);
SWAP(vertices[0],vertices[1]);
}
if (y[1] > y[2]) {
SWAP(x[1], x[2]);
SWAP(y[1], y[2]);
SWAP(vertices[1],vertices[2]);
}
double dx_far = double(x[2] - x[0]) / (y[2] - y[0] + 1);
double dx_upper = double(x[1] - x[0]) / (y[1] - y[0] + 1);
double dx_low = double(x[2] - x[1]) / (y[2] - y[1] + 1);
double xf = x[0];
double xt = x[0] + dx_upper; // if y[0] == y[1], special case
for (int yi = y[0]; yi <= (y[2] > bt.height-1 ? bt.height-1 : y[2]); yi++)
{
if (yi >= 0) {
for (int xi = (xf > 0 ? int(xf) : 0); xi <= (xt < bt.width ? xt : bt.width-1) ; xi++) {
//pixels[int(x + y * width)] = color;
Vector2 v0 = Vector2(x[1]-x[0],y[1]-y[0]);
Vector2 v1 = Vector2(x[2]-x[0],y[2]-y[0]);
//vertices[2] - vertices[0];
Vector2 v2 = Vector2(xi-x[0],yi-y[0]);
float d00 = v0.dot( v0);
float d01 = v0.dot( v1);
float d11 = v1.dot( v1);
float d20 = v2.dot( v0);
float d21 = v2.dot( v1);
float denom = (d00 * d11 - d01 * d01);
Vector3 pos;
if (denom==0) {
pos=t.vertices[0];
} else {
float v = (d11 * d20 - d01 * d21) / denom;
float w = (d00 * d21 - d01 * d20) / denom;
float u = 1.0f - v - w;
pos = vertices[0]*u + vertices[1]*v + vertices[2]*w;
}
_plot_pixel_to_lightmap(xi,yi,bt.width,bt.height,bt.data.ptr(),pos,normal,norm_arr.ptr(),mult,gamma);
}
for (int xi = (xf < bt.width ? int(xf) : bt.width-1); xi >= (xt > 0 ? xt : 0); xi--) {
//pixels[int(x + y * width)] = color;
Vector2 v0 = Vector2(x[1]-x[0],y[1]-y[0]);
Vector2 v1 = Vector2(x[2]-x[0],y[2]-y[0]);
//vertices[2] - vertices[0];
Vector2 v2 = Vector2(xi-x[0],yi-y[0]);
float d00 = v0.dot( v0);
float d01 = v0.dot( v1);
float d11 = v1.dot( v1);
float d20 = v2.dot( v0);
float d21 = v2.dot( v1);
float denom = (d00 * d11 - d01 * d01);
Vector3 pos;
if (denom==0) {
pos=t.vertices[0];
} else {
float v = (d11 * d20 - d01 * d21) / denom;
float w = (d00 * d21 - d01 * d20) / denom;
float u = 1.0f - v - w;
pos = vertices[0]*u + vertices[1]*v + vertices[2]*w;
}
_plot_pixel_to_lightmap(xi,yi,bt.width,bt.height,bt.data.ptr(),pos,normal,norm_arr.ptr(),mult,gamma);
}
}
xf += dx_far;
if (yi < y[1])
xt += dx_upper;
else
xt += dx_low;
}
}
}
for(int i=0;i<baked_textures.size();i++) {
{
ep.step(TTR("Post-Processing Texture #")+itos(i),i+baked_textures.size()+triangles.size());
BakeTexture &bt=baked_textures[i];
Vector<uint8_t> copy_data=bt.data;
uint8_t *data=bt.data.ptr();
const int max_radius=8;
const int shadow_radius=2;
const int max_dist=0x7FFFFFFF;
for(int x=0;x<bt.width;x++) {
for(int y=0;y<bt.height;y++) {
uint8_t a = copy_data[(y*bt.width+x)*4+3];
if (a>0) {
//blur shadow
int from_x = MAX(0,x-shadow_radius);
int to_x = MIN(bt.width-1,x+shadow_radius);
int from_y = MAX(0,y-shadow_radius);
int to_y = MIN(bt.height-1,y+shadow_radius);
int sum=0;
int sumc=0;
for(int k=from_y;k<=to_y;k++) {
for(int l=from_x;l<=to_x;l++) {
const uint8_t * rp = &copy_data[(k*bt.width+l)<<2];
sum+=rp[3];
sumc++;
}
}
sum/=sumc;
data[(y*bt.width+x)*4+3]=sum;
} else {
int closest_dist=max_dist;
uint8_t closest_color[4];
int from_x = MAX(0,x-max_radius);
int to_x = MIN(bt.width-1,x+max_radius);
int from_y = MAX(0,y-max_radius);
int to_y = MIN(bt.height-1,y+max_radius);
for(int k=from_y;k<=to_y;k++) {
for(int l=from_x;l<=to_x;l++) {
int dy = y-k;
int dx = x-l;
int dist = dy*dy+dx*dx;
if (dist>=closest_dist)
continue;
const uint8_t * rp = &copy_data[(k*bt.width+l)<<2];
if (rp[3]==0)
continue;
closest_dist=dist;
closest_color[0]=rp[0];
closest_color[1]=rp[1];
closest_color[2]=rp[2];
closest_color[3]=rp[3];
}
}
if (closest_dist!=max_dist) {
data[(y*bt.width+x)*4+0]=closest_color[0];
data[(y*bt.width+x)*4+1]=closest_color[1];
data[(y*bt.width+x)*4+2]=closest_color[2];
data[(y*bt.width+x)*4+3]=closest_color[3];
}
}
}
}
}
PoolVector<uint8_t> dv;
dv.resize(baked_textures[i].data.size());
{
PoolVector<uint8_t>::Write w = dv.write();
copymem(w.ptr(),baked_textures[i].data.ptr(),baked_textures[i].data.size());
}
Image img(baked_textures[i].width,baked_textures[i].height,0,Image::FORMAT_RGBA8,dv);
Ref<ImageTexture> tex = memnew( ImageTexture );
tex->create_from_image(img);
baked_light->set_lightmap_texture(i,tex);
}
return OK;
}
void BakedLightBaker::clear() {
_stop_thread();
if (bvh)
_free_bvh(bvh);
if (ray_stack)
memdelete_arr(ray_stack);
if (octant_stack)
memdelete_arr(octant_stack);
if (octantptr_stack)
memdelete_arr(octantptr_stack);
if (bvh_stack)
memdelete_arr(bvh_stack);
/*
* ???
for(int i=0;i<octant_pool.size();i++) {
/*
if (octant_pool[i].leaf) {
memdelete_arr( octant_pool[i].light );
}
Vector<double> norm_arr;
norm_arr.resize(lights.size());
*/
for(int i=0;i<lights.size();i++) {
norm_arr[i] = 1.0/get_normalization(i);
}
const double *normptr=norm_arr.ptr();
}
*/
octant_pool.clear();
octant_pool_size=0;
bvh=NULL;
leaf_list=0;
cell_count=0;
ray_stack=NULL;
octant_stack=NULL;
octantptr_stack=NULL;
bvh_stack=NULL;
materials.clear();
materials.clear();
textures.clear();
lights.clear();
triangles.clear();
endpoint_normal.clear();
endpoint_normal_bits.clear();
baked_octree_texture_w=0;
baked_octree_texture_h=0;
paused=false;
baking=false;
bake_thread_exit=false;
first_bake_to_map=true;
baked_light=Ref<BakedLight>();
total_rays=0;
}
BakedLightBaker::BakedLightBaker() {
octree_depth=9;
lattice_size=4;
octant_pool.clear();
octant_pool_size=0;
bvh=NULL;
leaf_list=0;
cell_count=0;
ray_stack=NULL;
bvh_stack=NULL;
octant_stack=NULL;
octantptr_stack=NULL;
plot_size=2.5;
max_bounces=2;
materials.clear();
baked_octree_texture_w=0;
baked_octree_texture_h=0;
paused=false;
baking=false;
bake_thread_exit=false;
total_rays=0;
first_bake_to_map=true;
linear_color=false;
}
BakedLightBaker::~BakedLightBaker() {
clear();
}
#endif