/* * 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. */ #include "BKE_context.h" #include "BKE_editmesh.h" #include "BKE_lib_id.h" #include "BKE_mesh.h" #include "BKE_mesh_wrapper.h" #include "BKE_modifier.h" #include "DNA_ID.h" #include "DNA_mesh_types.h" #include "DNA_meshdata_types.h" #include "DNA_space_types.h" #include "DNA_userdef_types.h" #include "DEG_depsgraph_query.h" #include "ED_spreadsheet.h" #include "NOD_geometry_nodes_eval_log.hh" #include "bmesh.h" #include "spreadsheet_data_source_geometry.hh" #include "spreadsheet_intern.hh" namespace geo_log = blender::nodes::geometry_nodes_eval_log; namespace blender::ed::spreadsheet { void GeometryDataSource::foreach_default_column_ids( FunctionRef fn) const { component_->attribute_foreach( [&](const bke::AttributeIDRef &attribute_id, const AttributeMetaData &meta_data) { if (meta_data.domain != domain_) { return true; } if (attribute_id.is_anonymous()) { return true; } SpreadsheetColumnID column_id; column_id.name = (char *)attribute_id.name().data(); fn(column_id); return true; }); } std::unique_ptr GeometryDataSource::get_column_values( const SpreadsheetColumnID &column_id) const { std::lock_guard lock{mutex_}; bke::ReadAttributeLookup attribute = component_->attribute_try_get_for_read(column_id.name); if (!attribute) { return {}; } const fn::GVArray *varray = scope_.add(std::move(attribute.varray)); if (attribute.domain != domain_) { return {}; } int domain_size = varray->size(); const CustomDataType type = bke::cpp_type_to_custom_data_type(varray->type()); switch (type) { case CD_PROP_FLOAT: return column_values_from_function(SPREADSHEET_VALUE_TYPE_FLOAT, column_id.name, domain_size, [varray](int index, CellValue &r_cell_value) { float value; varray->get(index, &value); r_cell_value.value_float = value; }); case CD_PROP_INT32: return column_values_from_function(SPREADSHEET_VALUE_TYPE_INT32, column_id.name, domain_size, [varray](int index, CellValue &r_cell_value) { int value; varray->get(index, &value); r_cell_value.value_int = value; }); case CD_PROP_BOOL: return column_values_from_function(SPREADSHEET_VALUE_TYPE_BOOL, column_id.name, domain_size, [varray](int index, CellValue &r_cell_value) { bool value; varray->get(index, &value); r_cell_value.value_bool = value; }); case CD_PROP_FLOAT2: { return column_values_from_function( SPREADSHEET_VALUE_TYPE_FLOAT2, column_id.name, domain_size, [varray](int index, CellValue &r_cell_value) { float2 value; varray->get(index, &value); r_cell_value.value_float2 = value; }, default_float2_column_width); } case CD_PROP_FLOAT3: { return column_values_from_function( SPREADSHEET_VALUE_TYPE_FLOAT3, column_id.name, domain_size, [varray](int index, CellValue &r_cell_value) { float3 value; varray->get(index, &value); r_cell_value.value_float3 = value; }, default_float3_column_width); } case CD_PROP_COLOR: { return column_values_from_function( SPREADSHEET_VALUE_TYPE_COLOR, column_id.name, domain_size, [varray](int index, CellValue &r_cell_value) { ColorGeometry4f value; varray->get(index, &value); r_cell_value.value_color = value; }, default_color_column_width); } default: break; } return {}; } int GeometryDataSource::tot_rows() const { return component_->attribute_domain_size(domain_); } using IsVertexSelectedFn = FunctionRef; static void get_selected_vertex_indices(const Mesh &mesh, const IsVertexSelectedFn is_vertex_selected_fn, MutableSpan selection) { for (const int i : IndexRange(mesh.totvert)) { if (!selection[i]) { continue; } if (!is_vertex_selected_fn(i)) { selection[i] = false; } } } static void get_selected_corner_indices(const Mesh &mesh, const IsVertexSelectedFn is_vertex_selected_fn, MutableSpan selection) { for (const int i : IndexRange(mesh.totloop)) { const MLoop &loop = mesh.mloop[i]; if (!selection[i]) { continue; } if (!is_vertex_selected_fn(loop.v)) { selection[i] = false; } } } static void get_selected_face_indices(const Mesh &mesh, const IsVertexSelectedFn is_vertex_selected_fn, MutableSpan selection) { for (const int poly_index : IndexRange(mesh.totpoly)) { if (!selection[poly_index]) { continue; } const MPoly &poly = mesh.mpoly[poly_index]; for (const int loop_index : IndexRange(poly.loopstart, poly.totloop)) { const MLoop &loop = mesh.mloop[loop_index]; if (!is_vertex_selected_fn(loop.v)) { selection[poly_index] = false; break; } } } } static void get_selected_edge_indices(const Mesh &mesh, const IsVertexSelectedFn is_vertex_selected_fn, MutableSpan selection) { for (const int i : IndexRange(mesh.totedge)) { if (!selection[i]) { continue; } const MEdge &edge = mesh.medge[i]; if (!is_vertex_selected_fn(edge.v1) || !is_vertex_selected_fn(edge.v2)) { selection[i] = false; } } } static void get_selected_indices_on_domain(const Mesh &mesh, const AttributeDomain domain, const IsVertexSelectedFn is_vertex_selected_fn, MutableSpan selection) { switch (domain) { case ATTR_DOMAIN_POINT: return get_selected_vertex_indices(mesh, is_vertex_selected_fn, selection); case ATTR_DOMAIN_FACE: return get_selected_face_indices(mesh, is_vertex_selected_fn, selection); case ATTR_DOMAIN_CORNER: return get_selected_corner_indices(mesh, is_vertex_selected_fn, selection); case ATTR_DOMAIN_EDGE: return get_selected_edge_indices(mesh, is_vertex_selected_fn, selection); default: return; } } /** * Only data sets corresponding to mesh objects in edit mode currently support selection filtering. */ bool GeometryDataSource::has_selection_filter() const { Object *object_orig = DEG_get_original_object(object_eval_); if (object_orig->type != OB_MESH) { return false; } if (object_orig->mode != OB_MODE_EDIT) { return false; } if (component_->type() != GEO_COMPONENT_TYPE_MESH) { return false; } return true; } void GeometryDataSource::apply_selection_filter(MutableSpan rows_included) const { std::lock_guard lock{mutex_}; BLI_assert(object_eval_->mode == OB_MODE_EDIT); BLI_assert(component_->type() == GEO_COMPONENT_TYPE_MESH); Object *object_orig = DEG_get_original_object(object_eval_); const MeshComponent *mesh_component = static_cast(component_); const Mesh *mesh_eval = mesh_component->get_for_read(); Mesh *mesh_orig = (Mesh *)object_orig->data; BMesh *bm = mesh_orig->edit_mesh->bm; BM_mesh_elem_table_ensure(bm, BM_VERT); int *orig_indices = (int *)CustomData_get_layer(&mesh_eval->vdata, CD_ORIGINDEX); if (orig_indices != nullptr) { /* Use CD_ORIGINDEX layer if it exists. */ auto is_vertex_selected = [&](int vertex_index) -> bool { const int i_orig = orig_indices[vertex_index]; if (i_orig < 0) { return false; } if (i_orig >= bm->totvert) { return false; } BMVert *vert = bm->vtable[i_orig]; return BM_elem_flag_test(vert, BM_ELEM_SELECT); }; get_selected_indices_on_domain(*mesh_eval, domain_, is_vertex_selected, rows_included); } else if (mesh_eval->totvert == bm->totvert) { /* Use a simple heuristic to match original vertices to evaluated ones. */ auto is_vertex_selected = [&](int vertex_index) -> bool { BMVert *vert = bm->vtable[vertex_index]; return BM_elem_flag_test(vert, BM_ELEM_SELECT); }; get_selected_indices_on_domain(*mesh_eval, domain_, is_vertex_selected, rows_included); } } void InstancesDataSource::foreach_default_column_ids( FunctionRef fn) const { if (component_->instances_amount() == 0) { return; } SpreadsheetColumnID column_id; column_id.name = (char *)"Name"; fn(column_id); for (const char *name : {"Position", "Rotation", "Scale", "ID"}) { column_id.name = (char *)name; fn(column_id); } } std::unique_ptr InstancesDataSource::get_column_values( const SpreadsheetColumnID &column_id) const { if (component_->instances_amount() == 0) { return {}; } const int size = this->tot_rows(); if (STREQ(column_id.name, "Name")) { Span reference_handles = component_->instance_reference_handles(); Span references = component_->references(); std::unique_ptr values = column_values_from_function( SPREADSHEET_VALUE_TYPE_INSTANCES, "Name", size, [reference_handles, references](int index, CellValue &r_cell_value) { const InstanceReference &reference = references[reference_handles[index]]; switch (reference.type()) { case InstanceReference::Type::Object: { Object &object = reference.object(); r_cell_value.value_object = ObjectCellValue{&object}; break; } case InstanceReference::Type::Collection: { Collection &collection = reference.collection(); r_cell_value.value_collection = CollectionCellValue{&collection}; break; } case InstanceReference::Type::GeometrySet: { const GeometrySet &geometry_set = reference.geometry_set(); r_cell_value.value_geometry_set = GeometrySetCellValue{&geometry_set}; break; } case InstanceReference::Type::None: { break; } } }); values->default_width = 8.0f; return values; } Span transforms = component_->instance_transforms(); if (STREQ(column_id.name, "Position")) { return column_values_from_function( SPREADSHEET_VALUE_TYPE_FLOAT3, column_id.name, size, [transforms](int index, CellValue &r_cell_value) { r_cell_value.value_float3 = transforms[index].translation(); }, default_float3_column_width); } if (STREQ(column_id.name, "Rotation")) { return column_values_from_function( SPREADSHEET_VALUE_TYPE_FLOAT3, column_id.name, size, [transforms](int index, CellValue &r_cell_value) { r_cell_value.value_float3 = transforms[index].to_euler(); }, default_float3_column_width); } if (STREQ(column_id.name, "Scale")) { return column_values_from_function( SPREADSHEET_VALUE_TYPE_FLOAT3, column_id.name, size, [transforms](int index, CellValue &r_cell_value) { r_cell_value.value_float3 = transforms[index].scale(); }, default_float3_column_width); } Span ids = component_->instance_ids(); if (STREQ(column_id.name, "ID")) { /* Make the column a bit wider by default, since the IDs tend to be large numbers. */ return column_values_from_function( SPREADSHEET_VALUE_TYPE_INT32, column_id.name, size, [ids](int index, CellValue &r_cell_value) { r_cell_value.value_int = ids[index]; }, 5.5f); } return {}; } int InstancesDataSource::tot_rows() const { return component_->instances_amount(); } GeometrySet spreadsheet_get_display_geometry_set(const SpaceSpreadsheet *sspreadsheet, Object *object_eval, const GeometryComponentType used_component_type) { GeometrySet geometry_set; if (sspreadsheet->object_eval_state == SPREADSHEET_OBJECT_EVAL_STATE_ORIGINAL) { Object *object_orig = DEG_get_original_object(object_eval); if (object_orig->type == OB_MESH) { MeshComponent &mesh_component = geometry_set.get_component_for_write(); if (object_orig->mode == OB_MODE_EDIT) { Mesh *mesh = (Mesh *)object_orig->data; BMEditMesh *em = mesh->edit_mesh; if (em != nullptr) { Mesh *new_mesh = (Mesh *)BKE_id_new_nomain(ID_ME, nullptr); /* This is a potentially heavy operation to do on every redraw. The best solution here is * to display the data directly from the bmesh without a conversion, which can be * implemented a bit later. */ BM_mesh_bm_to_me_for_eval(em->bm, new_mesh, nullptr); mesh_component.replace(new_mesh, GeometryOwnershipType::Owned); } } else { Mesh *mesh = (Mesh *)object_orig->data; mesh_component.replace(mesh, GeometryOwnershipType::ReadOnly); } } else if (object_orig->type == OB_POINTCLOUD) { PointCloud *pointcloud = (PointCloud *)object_orig->data; PointCloudComponent &pointcloud_component = geometry_set.get_component_for_write(); pointcloud_component.replace(pointcloud, GeometryOwnershipType::ReadOnly); } } else { if (used_component_type == GEO_COMPONENT_TYPE_MESH && object_eval->mode == OB_MODE_EDIT) { Mesh *mesh = BKE_modifier_get_evaluated_mesh_from_evaluated_object(object_eval, false); if (mesh == nullptr) { return geometry_set; } BKE_mesh_wrapper_ensure_mdata(mesh); MeshComponent &mesh_component = geometry_set.get_component_for_write(); mesh_component.replace(mesh, GeometryOwnershipType::ReadOnly); } else { if (BLI_listbase_count(&sspreadsheet->context_path) == 1) { /* Use final evaluated object. */ if (object_eval->runtime.geometry_set_eval != nullptr) { geometry_set = *object_eval->runtime.geometry_set_eval; } } else { const geo_log::NodeLog *node_log = geo_log::ModifierLog::find_node_by_spreadsheet_editor_context(*sspreadsheet); if (node_log != nullptr) { for (const geo_log::SocketLog &input_log : node_log->input_logs()) { if (const geo_log::GeometryValueLog *geo_value_log = dynamic_cast(input_log.value())) { const GeometrySet *full_geometry = geo_value_log->full_geometry(); if (full_geometry != nullptr) { geometry_set = *full_geometry; break; } } } } } } } return geometry_set; } static GeometryComponentType get_display_component_type(const bContext *C, Object *object_eval) { SpaceSpreadsheet *sspreadsheet = CTX_wm_space_spreadsheet(C); if (sspreadsheet->object_eval_state != SPREADSHEET_OBJECT_EVAL_STATE_ORIGINAL) { return (GeometryComponentType)sspreadsheet->geometry_component_type; } if (object_eval->type == OB_POINTCLOUD) { return GEO_COMPONENT_TYPE_POINT_CLOUD; } return GEO_COMPONENT_TYPE_MESH; } std::unique_ptr data_source_from_geometry(const bContext *C, Object *object_eval) { SpaceSpreadsheet *sspreadsheet = CTX_wm_space_spreadsheet(C); const AttributeDomain domain = (AttributeDomain)sspreadsheet->attribute_domain; const GeometryComponentType component_type = get_display_component_type(C, object_eval); GeometrySet geometry_set = spreadsheet_get_display_geometry_set( sspreadsheet, object_eval, component_type); if (!geometry_set.has(component_type)) { return {}; } if (component_type == GEO_COMPONENT_TYPE_INSTANCES) { return std::make_unique(geometry_set); } return std::make_unique(object_eval, geometry_set, component_type, domain); } } // namespace blender::ed::spreadsheet