/* Create uv map attributes. */
static void attr_create_uv_map(Scene *scene,
Mesh *mesh,
BL::Mesh b_mesh,
const vector<int>& nverts)
{
if(b_mesh.tessface_uv_textures.length() != 0) {
BL::Mesh::tessface_uv_textures_iterator l;
for(b_mesh.tessface_uv_textures.begin(l); l != b_mesh.tessface_uv_textures.end(); ++l) {
bool active_render = l->active_render();
AttributeStandard std = (active_render)? ATTR_STD_UV: ATTR_STD_NONE;
ustring name = ustring(l->name().c_str());
/* UV map */
if(mesh->need_attribute(scene, name) || mesh->need_attribute(scene, std)) {
Attribute *attr;
if(active_render)
attr = mesh->attributes.add(std, name);
else
attr = mesh->attributes.add(name, TypeDesc::TypePoint, ATTR_ELEMENT_CORNER);
BL::MeshTextureFaceLayer::data_iterator t;
float3 *fdata = attr->data_float3();
size_t i = 0;
for(l->data.begin(t); t != l->data.end(); ++t, ++i) {
fdata[0] = get_float3(t->uv1());
fdata[1] = get_float3(t->uv2());
fdata[2] = get_float3(t->uv3());
fdata += 3;
if(nverts[i] == 4) {
fdata[0] = get_float3(t->uv1());
fdata[1] = get_float3(t->uv3());
fdata[2] = get_float3(t->uv4());
fdata += 3;
}
}
}
/* UV tangent */
std = (active_render)? ATTR_STD_UV_TANGENT: ATTR_STD_NONE;
name = ustring((string(l->name().c_str()) + ".tangent").c_str());
if(mesh->need_attribute(scene, name) || (active_render && mesh->need_attribute(scene, std))) {
std = (active_render)? ATTR_STD_UV_TANGENT_SIGN: ATTR_STD_NONE;
name = ustring((string(l->name().c_str()) + ".tangent_sign").c_str());
bool need_sign = (mesh->need_attribute(scene, name) || mesh->need_attribute(scene, std));
mikk_compute_tangents(b_mesh, &(*l), mesh, nverts, need_sign, active_render);
}
}
}
else if(mesh->need_attribute(scene, ATTR_STD_UV_TANGENT)) {
bool need_sign = mesh->need_attribute(scene, ATTR_STD_UV_TANGENT_SIGN);
mikk_compute_tangents(b_mesh, NULL, mesh, nverts, need_sign, true);
}
}
void BlenderSync::sync_curves(Mesh *mesh,
BL::Mesh& b_mesh,
BL::Object& b_ob,
bool motion,
int motion_step)
{
if(!motion) {
/* Clear stored curve data */
mesh->curve_keys.clear();
mesh->curve_radius.clear();
mesh->curve_first_key.clear();
mesh->curve_shader.clear();
mesh->curve_attributes.clear();
}
/* obtain general settings */
const bool use_curves = scene->curve_system_manager->use_curves;
if(!(use_curves && b_ob.mode() != b_ob.mode_PARTICLE_EDIT)) {
if(!motion)
mesh->compute_bounds();
return;
}
const int primitive = scene->curve_system_manager->primitive;
const int triangle_method = scene->curve_system_manager->triangle_method;
const int resolution = scene->curve_system_manager->resolution;
const size_t vert_num = mesh->verts.size();
const size_t tri_num = mesh->num_triangles();
int used_res = 1;
/* extract particle hair data - should be combined with connecting to mesh later*/
ParticleCurveData CData;
if(!preview)
set_resolution(&b_ob, &b_scene, true);
ObtainCacheParticleData(mesh, &b_mesh, &b_ob, &CData, !preview);
/* add hair geometry to mesh */
if(primitive == CURVE_TRIANGLES) {
if(triangle_method == CURVE_CAMERA_TRIANGLES) {
/* obtain camera parameters */
float3 RotCam;
Camera *camera = scene->camera;
Transform &ctfm = camera->matrix;
if(camera->type == CAMERA_ORTHOGRAPHIC) {
RotCam = -make_float3(ctfm.x.z, ctfm.y.z, ctfm.z.z);
}
else {
Transform tfm = get_transform(b_ob.matrix_world());
Transform itfm = transform_quick_inverse(tfm);
RotCam = transform_point(&itfm, make_float3(ctfm.x.w,
ctfm.y.w,
ctfm.z.w));
}
bool is_ortho = camera->type == CAMERA_ORTHOGRAPHIC;
ExportCurveTrianglePlanes(mesh, &CData, RotCam, is_ortho);
}
else {
ExportCurveTriangleGeometry(mesh, &CData, resolution);
used_res = resolution;
}
}
else {
if(motion)
ExportCurveSegmentsMotion(mesh, &CData, motion_step);
else
ExportCurveSegments(scene, mesh, &CData);
}
/* generated coordinates from first key. we should ideally get this from
* blender to handle deforming objects */
if(!motion) {
if(mesh->need_attribute(scene, ATTR_STD_GENERATED)) {
float3 loc, size;
mesh_texture_space(b_mesh, loc, size);
if(primitive == CURVE_TRIANGLES) {
Attribute *attr_generated = mesh->attributes.add(ATTR_STD_GENERATED);
float3 *generated = attr_generated->data_float3();
for(size_t i = vert_num; i < mesh->verts.size(); i++)
generated[i] = mesh->verts[i]*size - loc;
}
else {
Attribute *attr_generated = mesh->curve_attributes.add(ATTR_STD_GENERATED);
float3 *generated = attr_generated->data_float3();
for(size_t i = 0; i < mesh->num_curves(); i++) {
float3 co = mesh->curve_keys[mesh->get_curve(i).first_key];
generated[i] = co*size - loc;
}
}
}
}
/* create vertex color attributes */
if(!motion) {
BL::Mesh::tessface_vertex_colors_iterator l;
int vcol_num = 0;
for(b_mesh.tessface_vertex_colors.begin(l); l != b_mesh.tessface_vertex_colors.end(); ++l, vcol_num++) {
if(!mesh->need_attribute(scene, ustring(l->name().c_str())))
continue;
ObtainCacheParticleVcol(mesh, &b_mesh, &b_ob, &CData, !preview, vcol_num);
if(primitive == CURVE_TRIANGLES) {
Attribute *attr_vcol = mesh->attributes.add(
ustring(l->name().c_str()), TypeDesc::TypeColor, ATTR_ELEMENT_CORNER_BYTE);
uchar4 *cdata = attr_vcol->data_uchar4();
ExportCurveTriangleVcol(&CData, tri_num * 3, used_res, cdata);
}
else {
Attribute *attr_vcol = mesh->curve_attributes.add(
ustring(l->name().c_str()), TypeDesc::TypeColor, ATTR_ELEMENT_CURVE);
float3 *fdata = attr_vcol->data_float3();
if(fdata) {
size_t i = 0;
for(size_t curve = 0; curve < CData.curve_vcol.size(); curve++)
if(!(CData.curve_keynum[curve] <= 1 || CData.curve_length[curve] == 0.0f))
fdata[i++] = color_srgb_to_scene_linear_v3(CData.curve_vcol[curve]);
}
}
}
}
/* create UV attributes */
if(!motion) {
BL::Mesh::tessface_uv_textures_iterator l;
int uv_num = 0;
for(b_mesh.tessface_uv_textures.begin(l); l != b_mesh.tessface_uv_textures.end(); ++l, uv_num++) {
bool active_render = l->active_render();
AttributeStandard std = (active_render)? ATTR_STD_UV: ATTR_STD_NONE;
ustring name = ustring(l->name().c_str());
/* UV map */
if(mesh->need_attribute(scene, name) || mesh->need_attribute(scene, std)) {
Attribute *attr_uv;
ObtainCacheParticleUV(mesh, &b_mesh, &b_ob, &CData, !preview, uv_num);
if(primitive == CURVE_TRIANGLES) {
if(active_render)
attr_uv = mesh->attributes.add(std, name);
else
attr_uv = mesh->attributes.add(name, TypeDesc::TypePoint, ATTR_ELEMENT_CORNER);
float3 *uv = attr_uv->data_float3();
ExportCurveTriangleUV(&CData, tri_num * 3, used_res, uv);
}
else {
if(active_render)
attr_uv = mesh->curve_attributes.add(std, name);
else
attr_uv = mesh->curve_attributes.add(name, TypeDesc::TypePoint, ATTR_ELEMENT_CURVE);
float3 *uv = attr_uv->data_float3();
if(uv) {
size_t i = 0;
for(size_t curve = 0; curve < CData.curve_uv.size(); curve++)
if(!(CData.curve_keynum[curve] <= 1 || CData.curve_length[curve] == 0.0f))
uv[i++] = CData.curve_uv[curve];
}
}
}
}
}
if(!preview)
set_resolution(&b_ob, &b_scene, false);
mesh->compute_bounds();
}
static void create_mesh(Scene *scene, Mesh *mesh, BL::Mesh b_mesh, const vector<uint>& used_shaders)
{
/* count vertices and faces */
int numverts = b_mesh.vertices.length();
int numfaces = b_mesh.tessfaces.length();
int numtris = 0;
bool use_loop_normals = b_mesh.use_auto_smooth();
BL::Mesh::vertices_iterator v;
BL::Mesh::tessfaces_iterator f;
for(b_mesh.tessfaces.begin(f); f != b_mesh.tessfaces.end(); ++f) {
int4 vi = get_int4(f->vertices_raw());
numtris += (vi[3] == 0)? 1: 2;
}
/* reserve memory */
mesh->reserve(numverts, numtris, 0, 0);
/* create vertex coordinates and normals */
int i = 0;
for(b_mesh.vertices.begin(v); v != b_mesh.vertices.end(); ++v, ++i)
mesh->verts[i] = get_float3(v->co());
Attribute *attr_N = mesh->attributes.add(ATTR_STD_VERTEX_NORMAL);
float3 *N = attr_N->data_float3();
for(b_mesh.vertices.begin(v); v != b_mesh.vertices.end(); ++v, ++N)
*N = get_float3(v->normal());
N = attr_N->data_float3();
/* create generated coordinates from undeformed coordinates */
if(mesh->need_attribute(scene, ATTR_STD_GENERATED)) {
Attribute *attr = mesh->attributes.add(ATTR_STD_GENERATED);
float3 loc, size;
mesh_texture_space(b_mesh, loc, size);
float3 *generated = attr->data_float3();
size_t i = 0;
for(b_mesh.vertices.begin(v); v != b_mesh.vertices.end(); ++v)
generated[i++] = get_float3(v->undeformed_co())*size - loc;
}
/* create faces */
vector<int> nverts(numfaces);
int fi = 0, ti = 0;
for(b_mesh.tessfaces.begin(f); f != b_mesh.tessfaces.end(); ++f, ++fi) {
int4 vi = get_int4(f->vertices_raw());
int n = (vi[3] == 0)? 3: 4;
int mi = clamp(f->material_index(), 0, used_shaders.size()-1);
int shader = used_shaders[mi];
bool smooth = f->use_smooth();
/* split vertices if normal is different
*
* note all vertex attributes must have been set here so we can split
* and copy attributes in split_vertex without remapping later */
if(use_loop_normals) {
BL::Array<float, 12> loop_normals = f->split_normals();
for(int i = 0; i < n; i++) {
float3 loop_N = make_float3(loop_normals[i * 3], loop_normals[i * 3 + 1], loop_normals[i * 3 + 2]);
if(N[vi[i]] != loop_N) {
int new_vi = mesh->split_vertex(vi[i]);
/* set new normal and vertex index */
N = attr_N->data_float3();
N[new_vi] = loop_N;
vi[i] = new_vi;
}
}
}
/* create triangles */
if(n == 4) {
if(is_zero(cross(mesh->verts[vi[1]] - mesh->verts[vi[0]], mesh->verts[vi[2]] - mesh->verts[vi[0]])) ||
is_zero(cross(mesh->verts[vi[2]] - mesh->verts[vi[0]], mesh->verts[vi[3]] - mesh->verts[vi[0]]))) {
mesh->set_triangle(ti++, vi[0], vi[1], vi[3], shader, smooth);
mesh->set_triangle(ti++, vi[2], vi[3], vi[1], shader, smooth);
}
else {
mesh->set_triangle(ti++, vi[0], vi[1], vi[2], shader, smooth);
mesh->set_triangle(ti++, vi[0], vi[2], vi[3], shader, smooth);
}
}
else
mesh->set_triangle(ti++, vi[0], vi[1], vi[2], shader, smooth);
nverts[fi] = n;
}
/* create vertex color attributes */
{
BL::Mesh::tessface_vertex_colors_iterator l;
for(b_mesh.tessface_vertex_colors.begin(l); l != b_mesh.tessface_vertex_colors.end(); ++l) {
if(!mesh->need_attribute(scene, ustring(l->name().c_str())))
continue;
Attribute *attr = mesh->attributes.add(
ustring(l->name().c_str()), TypeDesc::TypeColor, ATTR_ELEMENT_CORNER);
BL::MeshColorLayer::data_iterator c;
float3 *fdata = attr->data_float3();
size_t i = 0;
for(l->data.begin(c); c != l->data.end(); ++c, ++i) {
fdata[0] = color_srgb_to_scene_linear(get_float3(c->color1()));
fdata[1] = color_srgb_to_scene_linear(get_float3(c->color2()));
fdata[2] = color_srgb_to_scene_linear(get_float3(c->color3()));
if(nverts[i] == 4) {
fdata[3] = fdata[0];
fdata[4] = fdata[2];
fdata[5] = color_srgb_to_scene_linear(get_float3(c->color4()));
fdata += 6;
}
else
fdata += 3;
}
}
}
/* create uv map attributes */
{
BL::Mesh::tessface_uv_textures_iterator l;
for(b_mesh.tessface_uv_textures.begin(l); l != b_mesh.tessface_uv_textures.end(); ++l) {
bool active_render = l->active_render();
AttributeStandard std = (active_render)? ATTR_STD_UV: ATTR_STD_NONE;
ustring name = ustring(l->name().c_str());
/* UV map */
if(mesh->need_attribute(scene, name) || mesh->need_attribute(scene, std)) {
Attribute *attr;
if(active_render)
attr = mesh->attributes.add(std, name);
else
attr = mesh->attributes.add(name, TypeDesc::TypePoint, ATTR_ELEMENT_CORNER);
BL::MeshTextureFaceLayer::data_iterator t;
float3 *fdata = attr->data_float3();
size_t i = 0;
for(l->data.begin(t); t != l->data.end(); ++t, ++i) {
fdata[0] = get_float3(t->uv1());
fdata[1] = get_float3(t->uv2());
fdata[2] = get_float3(t->uv3());
fdata += 3;
if(nverts[i] == 4) {
fdata[0] = get_float3(t->uv1());
fdata[1] = get_float3(t->uv3());
fdata[2] = get_float3(t->uv4());
fdata += 3;
}
}
}
/* UV tangent */
std = (active_render)? ATTR_STD_UV_TANGENT: ATTR_STD_NONE;
name = ustring((string(l->name().c_str()) + ".tangent").c_str());
if(mesh->need_attribute(scene, name) || (active_render && mesh->need_attribute(scene, std))) {
std = (active_render)? ATTR_STD_UV_TANGENT_SIGN: ATTR_STD_NONE;
name = ustring((string(l->name().c_str()) + ".tangent_sign").c_str());
bool need_sign = (mesh->need_attribute(scene, name) || mesh->need_attribute(scene, std));
mikk_compute_tangents(b_mesh, *l, mesh, nverts, need_sign, active_render);
}
}
}
/* for volume objects, create a matrix to transform from object space to
* mesh texture space. this does not work with deformations but that can
* probably only be done well with a volume grid mapping of coordinates */
if(mesh->need_attribute(scene, ATTR_STD_GENERATED_TRANSFORM)) {
Attribute *attr = mesh->attributes.add(ATTR_STD_GENERATED_TRANSFORM);
Transform *tfm = attr->data_transform();
float3 loc, size;
mesh_texture_space(b_mesh, loc, size);
*tfm = transform_translate(-loc)*transform_scale(size);
}
}
/* Create uv map attributes. */
static void attr_create_uv_map(Scene *scene,
Mesh *mesh,
BL::Mesh& b_mesh,
const vector<int>& nverts,
const vector<int>& face_flags,
bool subdivision,
bool subdivide_uvs)
{
if(subdivision) {
BL::Mesh::uv_layers_iterator l;
int i = 0;
for(b_mesh.uv_layers.begin(l); l != b_mesh.uv_layers.end(); ++l, ++i) {
bool active_render = b_mesh.uv_textures[i].active_render();
AttributeStandard std = (active_render)? ATTR_STD_UV: ATTR_STD_NONE;
ustring name = ustring(l->name().c_str());
/* UV map */
if(mesh->need_attribute(scene, name) || mesh->need_attribute(scene, std)) {
Attribute *attr;
if(active_render)
attr = mesh->subd_attributes.add(std, name);
else
attr = mesh->subd_attributes.add(name, TypeDesc::TypePoint, ATTR_ELEMENT_CORNER);
if(subdivide_uvs) {
attr->flags |= ATTR_SUBDIVIDED;
}
BL::Mesh::polygons_iterator p;
float3 *fdata = attr->data_float3();
for(b_mesh.polygons.begin(p); p != b_mesh.polygons.end(); ++p) {
int n = p->loop_total();
for(int j = 0; j < n; j++) {
*(fdata++) = get_float3(l->data[p->loop_start() + j].uv());
}
}
}
}
}
else if(b_mesh.tessface_uv_textures.length() != 0) {
BL::Mesh::tessface_uv_textures_iterator l;
for(b_mesh.tessface_uv_textures.begin(l); l != b_mesh.tessface_uv_textures.end(); ++l) {
bool active_render = l->active_render();
AttributeStandard std = (active_render)? ATTR_STD_UV: ATTR_STD_NONE;
ustring name = ustring(l->name().c_str());
/* UV map */
if(mesh->need_attribute(scene, name) || mesh->need_attribute(scene, std)) {
Attribute *attr;
if(active_render)
attr = mesh->attributes.add(std, name);
else
attr = mesh->attributes.add(name, TypeDesc::TypePoint, ATTR_ELEMENT_CORNER);
BL::MeshTextureFaceLayer::data_iterator t;
float3 *fdata = attr->data_float3();
size_t i = 0;
for(l->data.begin(t); t != l->data.end(); ++t, ++i) {
int tri_a[3], tri_b[3];
face_split_tri_indices(nverts[i], face_flags[i], tri_a, tri_b);
float3 uvs[4];
uvs[0] = get_float3(t->uv1());
uvs[1] = get_float3(t->uv2());
uvs[2] = get_float3(t->uv3());
if(nverts[i] == 4) {
uvs[3] = get_float3(t->uv4());
}
fdata[0] = uvs[tri_a[0]];
fdata[1] = uvs[tri_a[1]];
fdata[2] = uvs[tri_a[2]];
fdata += 3;
if(nverts[i] == 4) {
fdata[0] = uvs[tri_b[0]];
fdata[1] = uvs[tri_b[1]];
fdata[2] = uvs[tri_b[2]];
fdata += 3;
}
}
}
/* UV tangent */
std = (active_render)? ATTR_STD_UV_TANGENT: ATTR_STD_NONE;
name = ustring((string(l->name().c_str()) + ".tangent").c_str());
if(mesh->need_attribute(scene, name) || (active_render && mesh->need_attribute(scene, std))) {
std = (active_render)? ATTR_STD_UV_TANGENT_SIGN: ATTR_STD_NONE;
name = ustring((string(l->name().c_str()) + ".tangent_sign").c_str());
bool need_sign = (mesh->need_attribute(scene, name) || mesh->need_attribute(scene, std));
mikk_compute_tangents(b_mesh,
&(*l),
mesh,
nverts,
face_flags,
need_sign,
active_render);
}
}
}
else if(mesh->need_attribute(scene, ATTR_STD_UV_TANGENT)) {
bool need_sign = mesh->need_attribute(scene, ATTR_STD_UV_TANGENT_SIGN);
mikk_compute_tangents(b_mesh,
NULL,
mesh,
nverts,
face_flags,
need_sign,
true);
}
}