/* * 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. * * The Original Code is Copyright (C) 2009 Blender Foundation. * All rights reserved. */ /** \file * \ingroup RNA */ #include #include #include "RNA_define.h" #include "DNA_customdata_types.h" #include "BLI_sys_types.h" #include "BLI_utildefines.h" #include "rna_internal.h" /* own include */ #ifdef RNA_RUNTIME # include "DNA_mesh_types.h" # include "BKE_mesh.h" # include "BKE_mesh_mapping.h" # include "BKE_mesh_runtime.h" # include "BKE_mesh_tangent.h" # include "ED_mesh.h" static const char *rna_Mesh_unit_test_compare(struct Mesh *mesh, struct Mesh *mesh2, float threshold) { const char *ret = BKE_mesh_cmp(mesh, mesh2, threshold); if (!ret) { ret = "Same"; } return ret; } static void rna_Mesh_create_normals_split(Mesh *mesh) { if (!CustomData_has_layer(&mesh->ldata, CD_NORMAL)) { CustomData_add_layer(&mesh->ldata, CD_NORMAL, CD_CALLOC, NULL, mesh->totloop); CustomData_set_layer_flag(&mesh->ldata, CD_NORMAL, CD_FLAG_TEMPORARY); } } static void rna_Mesh_free_normals_split(Mesh *mesh) { CustomData_free_layers(&mesh->ldata, CD_NORMAL, mesh->totloop); } static void rna_Mesh_calc_tangents(Mesh *mesh, ReportList *reports, const char *uvmap) { float(*r_looptangents)[4]; if (CustomData_has_layer(&mesh->ldata, CD_MLOOPTANGENT)) { r_looptangents = CustomData_get_layer(&mesh->ldata, CD_MLOOPTANGENT); memset(r_looptangents, 0, sizeof(float[4]) * mesh->totloop); } else { r_looptangents = CustomData_add_layer( &mesh->ldata, CD_MLOOPTANGENT, CD_CALLOC, NULL, mesh->totloop); CustomData_set_layer_flag(&mesh->ldata, CD_MLOOPTANGENT, CD_FLAG_TEMPORARY); } /* Compute loop normals if needed. */ if (!CustomData_has_layer(&mesh->ldata, CD_NORMAL)) { BKE_mesh_calc_normals_split(mesh); } BKE_mesh_calc_loop_tangent_single(mesh, uvmap, r_looptangents, reports); } static void rna_Mesh_free_tangents(Mesh *mesh) { CustomData_free_layers(&mesh->ldata, CD_MLOOPTANGENT, mesh->totloop); } static void rna_Mesh_calc_looptri(Mesh *mesh) { BKE_mesh_runtime_looptri_ensure(mesh); } static void rna_Mesh_calc_smooth_groups( Mesh *mesh, bool use_bitflags, int *r_poly_group_len, int **r_poly_group, int *r_group_total) { *r_poly_group_len = mesh->totpoly; *r_poly_group = BKE_mesh_calc_smoothgroups(mesh->medge, mesh->totedge, mesh->mpoly, mesh->totpoly, mesh->mloop, mesh->totloop, r_group_total, use_bitflags); } static void rna_Mesh_normals_split_custom_do(Mesh *mesh, float (*custom_loopnors)[3], const bool use_vertices) { if (use_vertices) { BKE_mesh_set_custom_normals_from_vertices(mesh, custom_loopnors); } else { BKE_mesh_set_custom_normals(mesh, custom_loopnors); } } static void rna_Mesh_normals_split_custom_set(Mesh *mesh, ReportList *reports, int normals_len, float *normals) { float(*loopnors)[3] = (float(*)[3])normals; const int numloops = mesh->totloop; if (normals_len != numloops * 3) { BKE_reportf(reports, RPT_ERROR, "Number of custom normals is not number of loops (%f / %d)", (float)normals_len / 3.0f, numloops); return; } rna_Mesh_normals_split_custom_do(mesh, loopnors, false); DEG_id_tag_update(&mesh->id, 0); } static void rna_Mesh_normals_split_custom_set_from_vertices(Mesh *mesh, ReportList *reports, int normals_len, float *normals) { float(*vertnors)[3] = (float(*)[3])normals; const int numverts = mesh->totvert; if (normals_len != numverts * 3) { BKE_reportf(reports, RPT_ERROR, "Number of custom normals is not number of vertices (%f / %d)", (float)normals_len / 3.0f, numverts); return; } rna_Mesh_normals_split_custom_do(mesh, vertnors, true); DEG_id_tag_update(&mesh->id, 0); } static void rna_Mesh_transform(Mesh *mesh, float mat[16], bool shape_keys) { BKE_mesh_transform(mesh, (float(*)[4])mat, shape_keys); DEG_id_tag_update(&mesh->id, 0); } static void rna_Mesh_flip_normals(Mesh *mesh) { BKE_mesh_polygons_flip(mesh->mpoly, mesh->mloop, &mesh->ldata, mesh->totpoly); BKE_mesh_tessface_clear(mesh); BKE_mesh_calc_normals(mesh); BKE_mesh_runtime_clear_geometry(mesh); DEG_id_tag_update(&mesh->id, 0); } static void rna_Mesh_split_faces(Mesh *mesh, bool free_loop_normals) { BKE_mesh_split_faces(mesh, free_loop_normals != 0); } static void rna_Mesh_update_gpu_tag(Mesh *mesh) { BKE_mesh_batch_cache_dirty_tag(mesh, BKE_MESH_BATCH_DIRTY_ALL); } static void rna_Mesh_count_selected_items(Mesh *mesh, int r_count[3]) { BKE_mesh_count_selected_items(mesh, r_count); } static void rna_Mesh_clear_geometry(Mesh *mesh) { BKE_mesh_clear_geometry(mesh); DEG_id_tag_update(&mesh->id, ID_RECALC_GEOMETRY); WM_main_add_notifier(NC_GEOM | ND_DATA, mesh); } #else void RNA_api_mesh(StructRNA *srna) { FunctionRNA *func; PropertyRNA *parm; const int normals_array_dim[] = {1, 3}; func = RNA_def_function(srna, "transform", "rna_Mesh_transform"); RNA_def_function_ui_description(func, "Transform mesh vertices by a matrix " "(Warning: inverts normals if matrix is negative)"); parm = RNA_def_float_matrix(func, "matrix", 4, 4, NULL, 0.0f, 0.0f, "", "Matrix", 0.0f, 0.0f); RNA_def_parameter_flags(parm, 0, PARM_REQUIRED); RNA_def_boolean(func, "shape_keys", 0, "", "Transform Shape Keys"); func = RNA_def_function(srna, "flip_normals", "rna_Mesh_flip_normals"); RNA_def_function_ui_description(func, "Invert winding of all polygons " "(clears tessellation, does not handle custom normals)"); func = RNA_def_function(srna, "calc_normals", "BKE_mesh_calc_normals"); RNA_def_function_ui_description(func, "Calculate vertex normals"); func = RNA_def_function(srna, "create_normals_split", "rna_Mesh_create_normals_split"); RNA_def_function_ui_description(func, "Empty split vertex normals"); func = RNA_def_function(srna, "calc_normals_split", "BKE_mesh_calc_normals_split"); RNA_def_function_ui_description(func, "Calculate split vertex normals, which preserve sharp edges"); func = RNA_def_function(srna, "free_normals_split", "rna_Mesh_free_normals_split"); RNA_def_function_ui_description(func, "Free split vertex normals"); func = RNA_def_function(srna, "split_faces", "rna_Mesh_split_faces"); RNA_def_function_ui_description(func, "Split faces based on the edge angle"); RNA_def_boolean( func, "free_loop_normals", 1, "Free Loop Notmals", "Free loop normals custom data layer"); func = RNA_def_function(srna, "calc_tangents", "rna_Mesh_calc_tangents"); RNA_def_function_flag(func, FUNC_USE_REPORTS); RNA_def_function_ui_description( func, "Compute tangents and bitangent signs, to be used together with the split normals " "to get a complete tangent space for normal mapping " "(split normals are also computed if not yet present)"); parm = RNA_def_string(func, "uvmap", NULL, MAX_CUSTOMDATA_LAYER_NAME, "", "Name of the UV map to use for tangent space computation"); func = RNA_def_function(srna, "free_tangents", "rna_Mesh_free_tangents"); RNA_def_function_ui_description(func, "Free tangents"); func = RNA_def_function(srna, "calc_loop_triangles", "rna_Mesh_calc_looptri"); RNA_def_function_ui_description(func, "Calculate loop triangle tessellation (supports editmode too)"); func = RNA_def_function(srna, "calc_smooth_groups", "rna_Mesh_calc_smooth_groups"); RNA_def_function_ui_description(func, "Calculate smooth groups from sharp edges"); RNA_def_boolean( func, "use_bitflags", false, "", "Produce bitflags groups instead of simple numeric values"); /* return values */ parm = RNA_def_int_array(func, "poly_groups", 1, NULL, 0, 0, "", "Smooth Groups", 0, 0); RNA_def_parameter_flags(parm, PROP_DYNAMIC, PARM_OUTPUT); parm = RNA_def_int( func, "groups", 0, 0, INT_MAX, "groups", "Total number of groups", 0, INT_MAX); RNA_def_parameter_flags(parm, 0, PARM_OUTPUT); func = RNA_def_function(srna, "normals_split_custom_set", "rna_Mesh_normals_split_custom_set"); RNA_def_function_ui_description(func, "Define custom split normals of this mesh " "(use zero-vectors to keep auto ones)"); RNA_def_function_flag(func, FUNC_USE_REPORTS); /* TODO, see how array size of 0 works, this shouldn't be used */ parm = RNA_def_float_array(func, "normals", 1, NULL, -1.0f, 1.0f, "", "Normals", 0.0f, 0.0f); RNA_def_property_multi_array(parm, 2, normals_array_dim); RNA_def_parameter_flags(parm, PROP_DYNAMIC, PARM_REQUIRED); func = RNA_def_function(srna, "normals_split_custom_set_from_vertices", "rna_Mesh_normals_split_custom_set_from_vertices"); RNA_def_function_ui_description( func, "Define custom split normals of this mesh, from vertices' normals " "(use zero-vectors to keep auto ones)"); RNA_def_function_flag(func, FUNC_USE_REPORTS); /* TODO, see how array size of 0 works, this shouldn't be used */ parm = RNA_def_float_array(func, "normals", 1, NULL, -1.0f, 1.0f, "", "Normals", 0.0f, 0.0f); RNA_def_property_multi_array(parm, 2, normals_array_dim); RNA_def_parameter_flags(parm, PROP_DYNAMIC, PARM_REQUIRED); func = RNA_def_function(srna, "update", "ED_mesh_update"); RNA_def_boolean(func, "calc_edges", 0, "Calculate Edges", "Force recalculation of edges"); RNA_def_boolean(func, "calc_edges_loose", 0, "Calculate Loose Edges", "Calculate the loose state of each edge"); RNA_def_function_flag(func, FUNC_USE_CONTEXT); RNA_def_function(srna, "update_gpu_tag", "rna_Mesh_update_gpu_tag"); func = RNA_def_function(srna, "unit_test_compare", "rna_Mesh_unit_test_compare"); RNA_def_pointer(func, "mesh", "Mesh", "", "Mesh to compare to"); RNA_def_float_factor(func, "threshold", FLT_EPSILON * 60, 0.0f, FLT_MAX, "Threshold", "Comparison tolerance threshold", 0.0f, FLT_MAX); /* return value */ parm = RNA_def_string( func, "result", "nothing", 64, "Return value", "String description of result of comparison"); RNA_def_function_return(func, parm); func = RNA_def_function(srna, "clear_geometry", "rna_Mesh_clear_geometry"); RNA_def_function_ui_description( func, "Remove all geometry from the mesh. Note that this does not free shape keys or materials"); func = RNA_def_function(srna, "validate", "BKE_mesh_validate"); RNA_def_function_ui_description(func, "Validate geometry, return True when the mesh has had " "invalid geometry corrected/removed"); RNA_def_boolean(func, "verbose", false, "Verbose", "Output information about the errors found"); RNA_def_boolean(func, "clean_customdata", true, "Clean Custom Data", "Remove temp/cached custom-data layers, like e.g. normals..."); parm = RNA_def_boolean(func, "result", 0, "Result", ""); RNA_def_function_return(func, parm); func = RNA_def_function(srna, "validate_material_indices", "BKE_mesh_validate_material_indices"); RNA_def_function_ui_description( func, "Validate material indices of polygons, return True when the mesh has had " "invalid indices corrected (to default 0)"); parm = RNA_def_boolean(func, "result", 0, "Result", ""); RNA_def_function_return(func, parm); func = RNA_def_function(srna, "count_selected_items", "rna_Mesh_count_selected_items "); RNA_def_function_ui_description(func, "Return the number of selected items (vert, edge, face)"); parm = RNA_def_int_vector(func, "result", 3, NULL, 0, INT_MAX, "Result", NULL, 0, INT_MAX); RNA_def_function_output(func, parm); } #endif