/* * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software Foundation, * Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ /** \file * \ingroup balembic */ #include "abc_reader_mesh.h" #include "abc_axis_conversion.h" #include "abc_reader_transform.h" #include "abc_util.h" #include #include "MEM_guardedalloc.h" #include "DNA_material_types.h" #include "DNA_mesh_types.h" #include "DNA_meshdata_types.h" #include "DNA_object_types.h" #include "BLI_compiler_compat.h" #include "BLI_math_geom.h" #include "BKE_main.h" #include "BKE_material.h" #include "BKE_mesh.h" #include "BKE_modifier.h" #include "BKE_object.h" using Alembic::Abc::Int32ArraySamplePtr; using Alembic::Abc::P3fArraySamplePtr; using Alembic::AbcGeom::IFaceSet; using Alembic::AbcGeom::IFaceSetSchema; using Alembic::AbcGeom::IN3fGeomParam; using Alembic::AbcGeom::IObject; using Alembic::AbcGeom::IPolyMesh; using Alembic::AbcGeom::IPolyMeshSchema; using Alembic::AbcGeom::ISampleSelector; using Alembic::AbcGeom::ISubD; using Alembic::AbcGeom::ISubDSchema; using Alembic::AbcGeom::IV2fGeomParam; using Alembic::AbcGeom::kWrapExisting; using Alembic::AbcGeom::N3fArraySample; using Alembic::AbcGeom::N3fArraySamplePtr; using Alembic::AbcGeom::UInt32ArraySamplePtr; using Alembic::AbcGeom::V2fArraySamplePtr; namespace blender { namespace io { namespace alembic { /* NOTE: Alembic's polygon winding order is clockwise, to match with Renderman. */ /* Some helpers for mesh generation */ namespace utils { static void build_mat_map(const Main *bmain, std::map &mat_map) { Material *material = static_cast(bmain->materials.first); for (; material; material = static_cast(material->id.next)) { mat_map[material->id.name + 2] = material; } } static void assign_materials(Main *bmain, Object *ob, const std::map &mat_index_map) { bool can_assign = true; std::map::const_iterator it = mat_index_map.begin(); int matcount = 0; for (; it != mat_index_map.end(); ++it, matcount++) { if (!BKE_object_material_slot_add(bmain, ob)) { can_assign = false; break; } } /* TODO(kevin): use global map? */ std::map mat_map; build_mat_map(bmain, mat_map); std::map::iterator mat_iter; if (can_assign) { it = mat_index_map.begin(); for (; it != mat_index_map.end(); ++it) { std::string mat_name = it->first; mat_iter = mat_map.find(mat_name.c_str()); Material *assigned_mat; if (mat_iter == mat_map.end()) { assigned_mat = BKE_material_add(bmain, mat_name.c_str()); mat_map[mat_name] = assigned_mat; } else { assigned_mat = mat_iter->second; } BKE_object_material_assign(bmain, ob, assigned_mat, it->second, BKE_MAT_ASSIGN_OBDATA); } } } } /* namespace utils */ struct AbcMeshData { Int32ArraySamplePtr face_indices; Int32ArraySamplePtr face_counts; P3fArraySamplePtr positions; P3fArraySamplePtr ceil_positions; V2fArraySamplePtr uvs; UInt32ArraySamplePtr uvs_indices; }; static void read_mverts_interp(MVert *mverts, const P3fArraySamplePtr &positions, const P3fArraySamplePtr &ceil_positions, const float weight) { float tmp[3]; for (int i = 0; i < positions->size(); i++) { MVert &mvert = mverts[i]; const Imath::V3f &floor_pos = (*positions)[i]; const Imath::V3f &ceil_pos = (*ceil_positions)[i]; interp_v3_v3v3(tmp, floor_pos.getValue(), ceil_pos.getValue(), weight); copy_zup_from_yup(mvert.co, tmp); mvert.bweight = 0; } } static void read_mverts(CDStreamConfig &config, const AbcMeshData &mesh_data) { MVert *mverts = config.mvert; const P3fArraySamplePtr &positions = mesh_data.positions; if (config.weight != 0.0f && mesh_data.ceil_positions != NULL && mesh_data.ceil_positions->size() == positions->size()) { read_mverts_interp(mverts, positions, mesh_data.ceil_positions, config.weight); return; } read_mverts(mverts, positions, nullptr); } void read_mverts(MVert *mverts, const P3fArraySamplePtr positions, const N3fArraySamplePtr normals) { for (int i = 0; i < positions->size(); i++) { MVert &mvert = mverts[i]; Imath::V3f pos_in = (*positions)[i]; copy_zup_from_yup(mvert.co, pos_in.getValue()); mvert.bweight = 0; if (normals) { Imath::V3f nor_in = (*normals)[i]; short no[3]; normal_float_to_short_v3(no, nor_in.getValue()); copy_zup_from_yup(mvert.no, no); } } } static void read_mpolys(CDStreamConfig &config, const AbcMeshData &mesh_data) { MPoly *mpolys = config.mpoly; MLoop *mloops = config.mloop; MLoopUV *mloopuvs = config.mloopuv; const Int32ArraySamplePtr &face_indices = mesh_data.face_indices; const Int32ArraySamplePtr &face_counts = mesh_data.face_counts; const V2fArraySamplePtr &uvs = mesh_data.uvs; const size_t uvs_size = uvs == nullptr ? 0 : uvs->size(); const UInt32ArraySamplePtr &uvs_indices = mesh_data.uvs_indices; const bool do_uvs = (mloopuvs && uvs && uvs_indices) && (uvs_indices->size() == face_indices->size()); unsigned int loop_index = 0; unsigned int rev_loop_index = 0; unsigned int uv_index = 0; bool seen_invalid_geometry = false; for (int i = 0; i < face_counts->size(); i++) { const int face_size = (*face_counts)[i]; MPoly &poly = mpolys[i]; poly.loopstart = loop_index; poly.totloop = face_size; /* Polygons are always assumed to be smooth-shaded. If the Alembic mesh should be flat-shaded, * this is encoded in custom loop normals. See T71246. */ poly.flag |= ME_SMOOTH; /* NOTE: Alembic data is stored in the reverse order. */ rev_loop_index = loop_index + (face_size - 1); uint last_vertex_index = 0; for (int f = 0; f < face_size; f++, loop_index++, rev_loop_index--) { MLoop &loop = mloops[rev_loop_index]; loop.v = (*face_indices)[loop_index]; if (f > 0 && loop.v == last_vertex_index) { /* This face is invalid, as it has consecutive loops from the same vertex. This is caused * by invalid geometry in the Alembic file, such as in T76514. */ seen_invalid_geometry = true; } last_vertex_index = loop.v; if (do_uvs) { MLoopUV &loopuv = mloopuvs[rev_loop_index]; uv_index = (*uvs_indices)[loop_index]; /* Some Alembic files are broken (or at least export UVs in a way we don't expect). */ if (uv_index >= uvs_size) { continue; } loopuv.uv[0] = (*uvs)[uv_index][0]; loopuv.uv[1] = (*uvs)[uv_index][1]; } } } BKE_mesh_calc_edges(config.mesh, false, false); if (seen_invalid_geometry) { if (config.modifier_error_message) { *config.modifier_error_message = "Mesh hash invalid geometry; more details on the console"; } BKE_mesh_validate(config.mesh, true, true); } } static void process_no_normals(CDStreamConfig &config) { /* Absense of normals in the Alembic mesh is interpreted as 'smooth'. */ BKE_mesh_calc_normals(config.mesh); } static void process_loop_normals(CDStreamConfig &config, const N3fArraySamplePtr loop_normals_ptr) { size_t loop_count = loop_normals_ptr->size(); if (loop_count == 0) { process_no_normals(config); return; } float(*lnors)[3] = static_cast( MEM_malloc_arrayN(loop_count, sizeof(float[3]), "ABC::FaceNormals")); Mesh *mesh = config.mesh; MPoly *mpoly = mesh->mpoly; const N3fArraySample &loop_normals = *loop_normals_ptr; int abc_index = 0; for (int i = 0, e = mesh->totpoly; i < e; i++, mpoly++) { /* As usual, ABC orders the loops in reverse. */ for (int j = mpoly->totloop - 1; j >= 0; j--, abc_index++) { int blender_index = mpoly->loopstart + j; copy_zup_from_yup(lnors[blender_index], loop_normals[abc_index].getValue()); } } mesh->flag |= ME_AUTOSMOOTH; BKE_mesh_set_custom_normals(mesh, lnors); MEM_freeN(lnors); } static void process_vertex_normals(CDStreamConfig &config, const N3fArraySamplePtr vertex_normals_ptr) { size_t normals_count = vertex_normals_ptr->size(); if (normals_count == 0) { process_no_normals(config); return; } float(*vnors)[3] = static_cast( MEM_malloc_arrayN(normals_count, sizeof(float[3]), "ABC::VertexNormals")); const N3fArraySample &vertex_normals = *vertex_normals_ptr; for (int index = 0; index < normals_count; index++) { copy_zup_from_yup(vnors[index], vertex_normals[index].getValue()); } config.mesh->flag |= ME_AUTOSMOOTH; BKE_mesh_set_custom_normals_from_vertices(config.mesh, vnors); MEM_freeN(vnors); } static void process_normals(CDStreamConfig &config, const IN3fGeomParam &normals, const ISampleSelector &selector) { if (!normals.valid()) { process_no_normals(config); return; } IN3fGeomParam::Sample normsamp = normals.getExpandedValue(selector); Alembic::AbcGeom::GeometryScope scope = normals.getScope(); switch (scope) { case Alembic::AbcGeom::kFacevaryingScope: // 'Vertex Normals' in Houdini. process_loop_normals(config, normsamp.getVals()); break; case Alembic::AbcGeom::kVertexScope: case Alembic::AbcGeom::kVaryingScope: // 'Point Normals' in Houdini. process_vertex_normals(config, normsamp.getVals()); break; case Alembic::AbcGeom::kConstantScope: case Alembic::AbcGeom::kUniformScope: case Alembic::AbcGeom::kUnknownScope: process_no_normals(config); break; } } BLI_INLINE void read_uvs_params(CDStreamConfig &config, AbcMeshData &abc_data, const IV2fGeomParam &uv, const ISampleSelector &selector) { if (!uv.valid()) { return; } IV2fGeomParam::Sample uvsamp; uv.getIndexed(uvsamp, selector); abc_data.uvs = uvsamp.getVals(); abc_data.uvs_indices = uvsamp.getIndices(); if (abc_data.uvs_indices->size() == config.totloop) { std::string name = Alembic::Abc::GetSourceName(uv.getMetaData()); /* According to the convention, primary UVs should have had their name * set using Alembic::Abc::SetSourceName, but you can't expect everyone * to follow it! :) */ if (name.empty()) { name = uv.getName(); } void *cd_ptr = config.add_customdata_cb(config.mesh, name.c_str(), CD_MLOOPUV); config.mloopuv = static_cast(cd_ptr); } } static void *add_customdata_cb(Mesh *mesh, const char *name, int data_type) { CustomDataType cd_data_type = static_cast(data_type); void *cd_ptr; CustomData *loopdata; int numloops; /* unsupported custom data type -- don't do anything. */ if (!ELEM(cd_data_type, CD_MLOOPUV, CD_MLOOPCOL)) { return NULL; } loopdata = &mesh->ldata; cd_ptr = CustomData_get_layer_named(loopdata, cd_data_type, name); if (cd_ptr != NULL) { /* layer already exists, so just return it. */ return cd_ptr; } /* Create a new layer. */ numloops = mesh->totloop; cd_ptr = CustomData_add_layer_named(loopdata, cd_data_type, CD_DEFAULT, NULL, numloops, name); return cd_ptr; } static void get_weight_and_index(CDStreamConfig &config, Alembic::AbcCoreAbstract::TimeSamplingPtr time_sampling, size_t samples_number) { Alembic::AbcGeom::index_t i0, i1; config.weight = get_weight_and_index(config.time, time_sampling, samples_number, i0, i1); config.index = i0; config.ceil_index = i1; } static void read_mesh_sample(const std::string &iobject_full_name, ImportSettings *settings, const IPolyMeshSchema &schema, const ISampleSelector &selector, CDStreamConfig &config) { const IPolyMeshSchema::Sample sample = schema.getValue(selector); AbcMeshData abc_mesh_data; abc_mesh_data.face_counts = sample.getFaceCounts(); abc_mesh_data.face_indices = sample.getFaceIndices(); abc_mesh_data.positions = sample.getPositions(); get_weight_and_index(config, schema.getTimeSampling(), schema.getNumSamples()); if (config.weight != 0.0f) { Alembic::AbcGeom::IPolyMeshSchema::Sample ceil_sample; schema.get(ceil_sample, Alembic::Abc::ISampleSelector(config.ceil_index)); abc_mesh_data.ceil_positions = ceil_sample.getPositions(); } if ((settings->read_flag & MOD_MESHSEQ_READ_UV) != 0) { read_uvs_params(config, abc_mesh_data, schema.getUVsParam(), selector); } if ((settings->read_flag & MOD_MESHSEQ_READ_VERT) != 0) { read_mverts(config, abc_mesh_data); } if ((settings->read_flag & MOD_MESHSEQ_READ_POLY) != 0) { read_mpolys(config, abc_mesh_data); process_normals(config, schema.getNormalsParam(), selector); } if ((settings->read_flag & (MOD_MESHSEQ_READ_UV | MOD_MESHSEQ_READ_COLOR)) != 0) { read_custom_data(iobject_full_name, schema.getArbGeomParams(), config, selector); } } CDStreamConfig get_config(Mesh *mesh) { CDStreamConfig config; BLI_assert(mesh->mvert || mesh->totvert == 0); config.mesh = mesh; config.mvert = mesh->mvert; config.mloop = mesh->mloop; config.mpoly = mesh->mpoly; config.totloop = mesh->totloop; config.totpoly = mesh->totpoly; config.loopdata = &mesh->ldata; config.add_customdata_cb = add_customdata_cb; return config; } /* ************************************************************************** */ AbcMeshReader::AbcMeshReader(const IObject &object, ImportSettings &settings) : AbcObjectReader(object, settings) { m_settings->read_flag |= MOD_MESHSEQ_READ_ALL; IPolyMesh ipoly_mesh(m_iobject, kWrapExisting); m_schema = ipoly_mesh.getSchema(); get_min_max_time(m_iobject, m_schema, m_min_time, m_max_time); } bool AbcMeshReader::valid() const { return m_schema.valid(); } /* Specialisation of has_animations() as defined in abc_reader_object.h. */ template<> bool has_animations(Alembic::AbcGeom::IPolyMeshSchema &schema, ImportSettings *settings) { if (settings->is_sequence || !schema.isConstant()) { return true; } IV2fGeomParam uvsParam = schema.getUVsParam(); IN3fGeomParam normalsParam = schema.getNormalsParam(); return (uvsParam.valid() && !uvsParam.isConstant()) || (normalsParam.valid() && !normalsParam.isConstant()); } void AbcMeshReader::readObjectData(Main *bmain, const Alembic::Abc::ISampleSelector &sample_sel) { Mesh *mesh = BKE_mesh_add(bmain, m_data_name.c_str()); m_object = BKE_object_add_only_object(bmain, OB_MESH, m_object_name.c_str()); m_object->data = mesh; Mesh *read_mesh = this->read_mesh(mesh, sample_sel, MOD_MESHSEQ_READ_ALL, NULL); if (read_mesh != mesh) { /* XXX fixme after 2.80; mesh->flag isn't copied by BKE_mesh_nomain_to_mesh() */ /* read_mesh can be freed by BKE_mesh_nomain_to_mesh(), so get the flag before that happens. */ short autosmooth = (read_mesh->flag & ME_AUTOSMOOTH); BKE_mesh_nomain_to_mesh(read_mesh, mesh, m_object, &CD_MASK_MESH, true); mesh->flag |= autosmooth; } if (m_settings->validate_meshes) { BKE_mesh_validate(mesh, false, false); } readFaceSetsSample(bmain, mesh, sample_sel); if (has_animations(m_schema, m_settings)) { addCacheModifier(); } } bool AbcMeshReader::accepts_object_type( const Alembic::AbcCoreAbstract::ObjectHeader &alembic_header, const Object *const ob, const char **err_str) const { if (!Alembic::AbcGeom::IPolyMesh::matches(alembic_header)) { *err_str = "Object type mismatch, Alembic object path pointed to PolyMesh when importing, but not " "any more."; return false; } if (ob->type != OB_MESH) { *err_str = "Object type mismatch, Alembic object path points to PolyMesh."; return false; } return true; } bool AbcMeshReader::topology_changed(Mesh *existing_mesh, const ISampleSelector &sample_sel) { IPolyMeshSchema::Sample sample; try { sample = m_schema.getValue(sample_sel); } catch (Alembic::Util::Exception &ex) { printf("Alembic: error reading mesh sample for '%s/%s' at time %f: %s\n", m_iobject.getFullName().c_str(), m_schema.getName().c_str(), sample_sel.getRequestedTime(), ex.what()); // A similar error in read_mesh() would just return existing_mesh. return false; } const P3fArraySamplePtr &positions = sample.getPositions(); const Alembic::Abc::Int32ArraySamplePtr &face_indices = sample.getFaceIndices(); const Alembic::Abc::Int32ArraySamplePtr &face_counts = sample.getFaceCounts(); return positions->size() != existing_mesh->totvert || face_counts->size() != existing_mesh->totpoly || face_indices->size() != existing_mesh->totloop; } Mesh *AbcMeshReader::read_mesh(Mesh *existing_mesh, const ISampleSelector &sample_sel, int read_flag, const char **err_str) { IPolyMeshSchema::Sample sample; try { sample = m_schema.getValue(sample_sel); } catch (Alembic::Util::Exception &ex) { if (err_str != nullptr) { *err_str = "Error reading mesh sample; more detail on the console"; } printf("Alembic: error reading mesh sample for '%s/%s' at time %f: %s\n", m_iobject.getFullName().c_str(), m_schema.getName().c_str(), sample_sel.getRequestedTime(), ex.what()); return existing_mesh; } const P3fArraySamplePtr &positions = sample.getPositions(); const Alembic::Abc::Int32ArraySamplePtr &face_indices = sample.getFaceIndices(); const Alembic::Abc::Int32ArraySamplePtr &face_counts = sample.getFaceCounts(); /* Do some very minimal mesh validation. */ const int poly_count = face_counts->size(); const int loop_count = face_indices->size(); /* This is the same test as in poly_to_tri_count(). */ if (poly_count > 0 && loop_count < poly_count * 2) { if (err_str != nullptr) { *err_str = "Invalid mesh; more detail on the console"; } printf("Alembic: invalid mesh sample for '%s/%s' at time %f, less than 2 loops per face\n", m_iobject.getFullName().c_str(), m_schema.getName().c_str(), sample_sel.getRequestedTime()); return existing_mesh; } Mesh *new_mesh = NULL; /* Only read point data when streaming meshes, unless we need to create new ones. */ ImportSettings settings; settings.read_flag |= read_flag; if (topology_changed(existing_mesh, sample_sel)) { new_mesh = BKE_mesh_new_nomain_from_template( existing_mesh, positions->size(), 0, 0, face_indices->size(), face_counts->size()); settings.read_flag |= MOD_MESHSEQ_READ_ALL; } else { /* If the face count changed (e.g. by triangulation), only read points. * This prevents crash from T49813. * TODO(kevin): perhaps find a better way to do this? */ if (face_counts->size() != existing_mesh->totpoly || face_indices->size() != existing_mesh->totloop) { settings.read_flag = MOD_MESHSEQ_READ_VERT; if (err_str) { *err_str = "Topology has changed, perhaps by triangulating the" " mesh. Only vertices will be read!"; } } } CDStreamConfig config = get_config(new_mesh ? new_mesh : existing_mesh); config.time = sample_sel.getRequestedTime(); config.modifier_error_message = err_str; read_mesh_sample(m_iobject.getFullName(), &settings, m_schema, sample_sel, config); if (new_mesh) { /* Here we assume that the number of materials doesn't change, i.e. that * the material slots that were created when the object was loaded from * Alembic are still valid now. */ size_t num_polys = new_mesh->totpoly; if (num_polys > 0) { std::map mat_map; assign_facesets_to_mpoly(sample_sel, new_mesh->mpoly, num_polys, mat_map); } return new_mesh; } return existing_mesh; } void AbcMeshReader::assign_facesets_to_mpoly(const ISampleSelector &sample_sel, MPoly *mpoly, int totpoly, std::map &r_mat_map) { std::vector face_sets; m_schema.getFaceSetNames(face_sets); if (face_sets.empty()) { return; } int current_mat = 0; for (int i = 0; i < face_sets.size(); i++) { const std::string &grp_name = face_sets[i]; if (r_mat_map.find(grp_name) == r_mat_map.end()) { r_mat_map[grp_name] = 1 + current_mat++; } const int assigned_mat = r_mat_map[grp_name]; const IFaceSet faceset = m_schema.getFaceSet(grp_name); if (!faceset.valid()) { std::cerr << " Face set " << grp_name << " invalid for " << m_object_name << "\n"; continue; } const IFaceSetSchema face_schem = faceset.getSchema(); const IFaceSetSchema::Sample face_sample = face_schem.getValue(sample_sel); const Int32ArraySamplePtr group_faces = face_sample.getFaces(); const size_t num_group_faces = group_faces->size(); for (size_t l = 0; l < num_group_faces; l++) { size_t pos = (*group_faces)[l]; if (pos >= totpoly) { std::cerr << "Faceset overflow on " << faceset.getName() << '\n'; break; } MPoly &poly = mpoly[pos]; poly.mat_nr = assigned_mat - 1; } } } void AbcMeshReader::readFaceSetsSample(Main *bmain, Mesh *mesh, const ISampleSelector &sample_sel) { std::map mat_map; assign_facesets_to_mpoly(sample_sel, mesh->mpoly, mesh->totpoly, mat_map); utils::assign_materials(bmain, m_object, mat_map); } /* ************************************************************************** */ BLI_INLINE MEdge *find_edge(MEdge *edges, int totedge, int v1, int v2) { for (int i = 0, e = totedge; i < e; i++) { MEdge &edge = edges[i]; if (edge.v1 == v1 && edge.v2 == v2) { return &edge; } } return NULL; } static void read_subd_sample(const std::string &iobject_full_name, ImportSettings *settings, const ISubDSchema &schema, const ISampleSelector &selector, CDStreamConfig &config) { const ISubDSchema::Sample sample = schema.getValue(selector); AbcMeshData abc_mesh_data; abc_mesh_data.face_counts = sample.getFaceCounts(); abc_mesh_data.face_indices = sample.getFaceIndices(); abc_mesh_data.positions = sample.getPositions(); get_weight_and_index(config, schema.getTimeSampling(), schema.getNumSamples()); if (config.weight != 0.0f) { Alembic::AbcGeom::ISubDSchema::Sample ceil_sample; schema.get(ceil_sample, Alembic::Abc::ISampleSelector(config.ceil_index)); abc_mesh_data.ceil_positions = ceil_sample.getPositions(); } if ((settings->read_flag & MOD_MESHSEQ_READ_UV) != 0) { read_uvs_params(config, abc_mesh_data, schema.getUVsParam(), selector); } if ((settings->read_flag & MOD_MESHSEQ_READ_VERT) != 0) { read_mverts(config, abc_mesh_data); } if ((settings->read_flag & MOD_MESHSEQ_READ_POLY) != 0) { /* Alembic's 'SubD' scheme is used to store subdivision surfaces, i.e. the pre-subdivision * mesh. Currently we don't add a subdivision modifier when we load such data. This code is * assuming that the subdivided surface should be smooth. */ read_mpolys(config, abc_mesh_data); process_no_normals(config); } if ((settings->read_flag & (MOD_MESHSEQ_READ_UV | MOD_MESHSEQ_READ_COLOR)) != 0) { read_custom_data(iobject_full_name, schema.getArbGeomParams(), config, selector); } } /* ************************************************************************** */ AbcSubDReader::AbcSubDReader(const IObject &object, ImportSettings &settings) : AbcObjectReader(object, settings) { m_settings->read_flag |= MOD_MESHSEQ_READ_ALL; ISubD isubd_mesh(m_iobject, kWrapExisting); m_schema = isubd_mesh.getSchema(); get_min_max_time(m_iobject, m_schema, m_min_time, m_max_time); } bool AbcSubDReader::valid() const { return m_schema.valid(); } bool AbcSubDReader::accepts_object_type( const Alembic::AbcCoreAbstract::ObjectHeader &alembic_header, const Object *const ob, const char **err_str) const { if (!Alembic::AbcGeom::ISubD::matches(alembic_header)) { *err_str = "Object type mismatch, Alembic object path pointed to SubD when importing, but not any " "more."; return false; } if (ob->type != OB_MESH) { *err_str = "Object type mismatch, Alembic object path points to SubD."; return false; } return true; } void AbcSubDReader::readObjectData(Main *bmain, const Alembic::Abc::ISampleSelector &sample_sel) { Mesh *mesh = BKE_mesh_add(bmain, m_data_name.c_str()); m_object = BKE_object_add_only_object(bmain, OB_MESH, m_object_name.c_str()); m_object->data = mesh; Mesh *read_mesh = this->read_mesh(mesh, sample_sel, MOD_MESHSEQ_READ_ALL, NULL); if (read_mesh != mesh) { BKE_mesh_nomain_to_mesh(read_mesh, mesh, m_object, &CD_MASK_MESH, true); } ISubDSchema::Sample sample; try { sample = m_schema.getValue(sample_sel); } catch (Alembic::Util::Exception &ex) { printf("Alembic: error reading mesh sample for '%s/%s' at time %f: %s\n", m_iobject.getFullName().c_str(), m_schema.getName().c_str(), sample_sel.getRequestedTime(), ex.what()); return; } Int32ArraySamplePtr indices = sample.getCreaseIndices(); Alembic::Abc::FloatArraySamplePtr sharpnesses = sample.getCreaseSharpnesses(); if (indices && sharpnesses) { MEdge *edges = mesh->medge; int totedge = mesh->totedge; for (int i = 0, s = 0, e = indices->size(); i < e; i += 2, s++) { int v1 = (*indices)[i]; int v2 = (*indices)[i + 1]; if (v2 < v1) { /* It appears to be common to store edges with the smallest index first, in which case this * prevents us from doing the second search below. */ std::swap(v1, v2); } MEdge *edge = find_edge(edges, totedge, v1, v2); if (edge == NULL) { edge = find_edge(edges, totedge, v2, v1); } if (edge) { edge->crease = unit_float_to_uchar_clamp((*sharpnesses)[s]); } } mesh->cd_flag |= ME_CDFLAG_EDGE_CREASE; } if (m_settings->validate_meshes) { BKE_mesh_validate(mesh, false, false); } if (has_animations(m_schema, m_settings)) { addCacheModifier(); } } Mesh *AbcSubDReader::read_mesh(Mesh *existing_mesh, const ISampleSelector &sample_sel, int read_flag, const char **err_str) { ISubDSchema::Sample sample; try { sample = m_schema.getValue(sample_sel); } catch (Alembic::Util::Exception &ex) { if (err_str != nullptr) { *err_str = "Error reading mesh sample; more detail on the console"; } printf("Alembic: error reading mesh sample for '%s/%s' at time %f: %s\n", m_iobject.getFullName().c_str(), m_schema.getName().c_str(), sample_sel.getRequestedTime(), ex.what()); return existing_mesh; } const P3fArraySamplePtr &positions = sample.getPositions(); const Alembic::Abc::Int32ArraySamplePtr &face_indices = sample.getFaceIndices(); const Alembic::Abc::Int32ArraySamplePtr &face_counts = sample.getFaceCounts(); Mesh *new_mesh = NULL; ImportSettings settings; settings.read_flag |= read_flag; if (existing_mesh->totvert != positions->size()) { new_mesh = BKE_mesh_new_nomain_from_template( existing_mesh, positions->size(), 0, 0, face_indices->size(), face_counts->size()); settings.read_flag |= MOD_MESHSEQ_READ_ALL; } else { /* If the face count changed (e.g. by triangulation), only read points. * This prevents crash from T49813. * TODO(kevin): perhaps find a better way to do this? */ if (face_counts->size() != existing_mesh->totpoly || face_indices->size() != existing_mesh->totloop) { settings.read_flag = MOD_MESHSEQ_READ_VERT; if (err_str) { *err_str = "Topology has changed, perhaps by triangulating the" " mesh. Only vertices will be read!"; } } } /* Only read point data when streaming meshes, unless we need to create new ones. */ CDStreamConfig config = get_config(new_mesh ? new_mesh : existing_mesh); config.time = sample_sel.getRequestedTime(); read_subd_sample(m_iobject.getFullName(), &settings, m_schema, sample_sel, config); return config.mesh; } } // namespace alembic } // namespace io } // namespace blender