/* * ***** BEGIN GPL LICENSE BLOCK ***** * * 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) 2004 Blender Foundation. * All rights reserved. * * The Original Code is: all of this file. * * Contributor(s): none yet. * * ***** END GPL LICENSE BLOCK ***** */ /** \file blender/editors/mesh/editmesh_select.c * \ingroup edmesh */ #include "MEM_guardedalloc.h" #include "BLI_bitmap.h" #include "BLI_listbase.h" #include "BLI_linklist.h" #include "BLI_linklist_stack.h" #include "BLI_math.h" #include "BLI_math_bits.h" #include "BLI_rand.h" #include "BLI_array.h" #include "BKE_context.h" #include "BKE_report.h" #include "BKE_paint.h" #include "BKE_editmesh.h" #include "IMB_imbuf_types.h" #include "IMB_imbuf.h" #include "WM_api.h" #include "WM_types.h" #include "RNA_access.h" #include "RNA_define.h" #include "RNA_enum_types.h" #include "ED_mesh.h" #include "ED_screen.h" #include "ED_view3d.h" #include "DNA_mesh_types.h" #include "DNA_meshdata_types.h" #include "DNA_object_types.h" #include "UI_resources.h" #include "bmesh_tools.h" #include "mesh_intern.h" /* own include */ /* use bmesh operator flags for a few operators */ #define BMO_ELE_TAG 1 /* ****************************** MIRROR **************** */ void EDBM_select_mirrored(BMEditMesh *em, bool extend, int *r_totmirr, int *r_totfail) { Mesh *me = (Mesh *)em->ob->data; BMesh *bm = em->bm; BMIter iter; int totmirr = 0; int totfail = 0; bool use_topology = (me && (me->editflag & ME_EDIT_MIRROR_TOPO)); *r_totmirr = *r_totfail = 0; /* select -> tag */ if (bm->selectmode & SCE_SELECT_VERTEX) { BMVert *v; BM_ITER_MESH (v, &iter, bm, BM_VERTS_OF_MESH) { BM_elem_flag_set(v, BM_ELEM_TAG, BM_elem_flag_test(v, BM_ELEM_SELECT)); } } else if (em->selectmode & SCE_SELECT_EDGE) { BMEdge *e; BM_ITER_MESH (e, &iter, bm, BM_EDGES_OF_MESH) { BM_elem_flag_set(e, BM_ELEM_TAG, BM_elem_flag_test(e, BM_ELEM_SELECT)); } } else { BMFace *f; BM_ITER_MESH (f, &iter, bm, BM_FACES_OF_MESH) { BM_elem_flag_set(f, BM_ELEM_TAG, BM_elem_flag_test(f, BM_ELEM_SELECT)); } } EDBM_verts_mirror_cache_begin(em, 0, true, true, use_topology); if (!extend) EDBM_flag_disable_all(em, BM_ELEM_SELECT); if (bm->selectmode & SCE_SELECT_VERTEX) { BMVert *v; BM_ITER_MESH (v, &iter, bm, BM_VERTS_OF_MESH) { if (!BM_elem_flag_test(v, BM_ELEM_HIDDEN) && BM_elem_flag_test(v, BM_ELEM_TAG)) { BMVert *v_mirr = EDBM_verts_mirror_get(em, v); if (v_mirr && !BM_elem_flag_test(v_mirr, BM_ELEM_HIDDEN)) { BM_vert_select_set(bm, v_mirr, true); totmirr++; } else { totfail++; } } } } else if (em->selectmode & SCE_SELECT_EDGE) { BMEdge *e; BM_ITER_MESH (e, &iter, bm, BM_EDGES_OF_MESH) { if (!BM_elem_flag_test(e, BM_ELEM_HIDDEN) && BM_elem_flag_test(e, BM_ELEM_TAG)) { BMEdge *e_mirr = EDBM_verts_mirror_get_edge(em, e); if (e_mirr && !BM_elem_flag_test(e_mirr, BM_ELEM_HIDDEN)) { BM_edge_select_set(bm, e_mirr, true); totmirr++; } else { totfail++; } } } } else { BMFace *f; BM_ITER_MESH (f, &iter, bm, BM_FACES_OF_MESH) { if (!BM_elem_flag_test(f, BM_ELEM_HIDDEN) && BM_elem_flag_test(f, BM_ELEM_TAG)) { BMFace *f_mirr = EDBM_verts_mirror_get_face(em, f); if (f_mirr && !BM_elem_flag_test(f_mirr, BM_ELEM_HIDDEN)) { BM_face_select_set(bm, f_mirr, true); totmirr++; } else { totfail++; } } } } EDBM_verts_mirror_cache_end(em); *r_totmirr = totmirr; *r_totfail = totfail; } void EDBM_automerge(Scene *scene, Object *obedit, bool update, const char hflag) { bool ok; BMEditMesh *em = BKE_editmesh_from_object(obedit); ok = BMO_op_callf(em->bm, BMO_FLAG_DEFAULTS, "automerge verts=%hv dist=%f", hflag, scene->toolsettings->doublimit); if (LIKELY(ok) && update) { EDBM_update_generic(em, true, true); } } /* ****************************** SELECTION ROUTINES **************** */ unsigned int bm_solidoffs = 0, bm_wireoffs = 0, bm_vertoffs = 0; /* set in drawobject.c ... for colorindices */ /* facilities for border select and circle select */ static BLI_bitmap *selbuf = NULL; static BLI_bitmap *edbm_backbuf_alloc(const int size) { return BLI_BITMAP_NEW(size, "selbuf"); } /* reads rect, and builds selection array for quick lookup */ /* returns if all is OK */ bool EDBM_backbuf_border_init(ViewContext *vc, short xmin, short ymin, short xmax, short ymax) { struct ImBuf *buf; unsigned int *dr; int a; if (vc->obedit == NULL || !V3D_IS_ZBUF(vc->v3d)) { return false; } buf = ED_view3d_backbuf_read(vc, xmin, ymin, xmax, ymax); if (buf == NULL) return false; if (bm_vertoffs == 0) return false; dr = buf->rect; /* build selection lookup */ selbuf = edbm_backbuf_alloc(bm_vertoffs + 1); a = (xmax - xmin + 1) * (ymax - ymin + 1); while (a--) { if (*dr > 0 && *dr <= bm_vertoffs) { BLI_BITMAP_ENABLE(selbuf, *dr); } dr++; } IMB_freeImBuf(buf); return true; } bool EDBM_backbuf_check(unsigned int index) { /* odd logic, if selbuf is NULL we assume no zbuf-selection is enabled * and just ignore the depth buffer, this is error prone since its possible * code doesn't set the depth buffer by accident, but leave for now. - Campbell */ if (selbuf == NULL) return true; if (index > 0 && index <= bm_vertoffs) return BLI_BITMAP_TEST_BOOL(selbuf, index); return false; } void EDBM_backbuf_free(void) { if (selbuf) MEM_freeN(selbuf); selbuf = NULL; } struct LassoMaskData { unsigned int *px; int width; }; static void edbm_mask_lasso_px_cb(int x, int y, void *user_data) { struct LassoMaskData *data = user_data; data->px[(y * data->width) + x] = true; } /* mcords is a polygon mask * - grab backbuffer, * - draw with black in backbuffer, * - grab again and compare * returns 'OK' */ bool EDBM_backbuf_border_mask_init(ViewContext *vc, const int mcords[][2], short tot, short xmin, short ymin, short xmax, short ymax) { unsigned int *dr, *dr_mask, *dr_mask_arr; struct ImBuf *buf; int a; struct LassoMaskData lasso_mask_data; /* method in use for face selecting too */ if (vc->obedit == NULL) { if (!BKE_paint_select_elem_test(vc->obact)) { return false; } } else if (!V3D_IS_ZBUF(vc->v3d)) { return false; } buf = ED_view3d_backbuf_read(vc, xmin, ymin, xmax, ymax); if (buf == NULL) return false; if (bm_vertoffs == 0) return false; dr = buf->rect; dr_mask = dr_mask_arr = MEM_callocN(sizeof(*dr_mask) * buf->x * buf->y, __func__); lasso_mask_data.px = dr_mask; lasso_mask_data.width = (xmax - xmin) + 1; fill_poly_v2i_n( xmin, ymin, xmax + 1, ymax + 1, mcords, tot, edbm_mask_lasso_px_cb, &lasso_mask_data); /* build selection lookup */ selbuf = edbm_backbuf_alloc(bm_vertoffs + 1); a = (xmax - xmin + 1) * (ymax - ymin + 1); while (a--) { if (*dr > 0 && *dr <= bm_vertoffs && *dr_mask == true) { BLI_BITMAP_ENABLE(selbuf, *dr); } dr++; dr_mask++; } IMB_freeImBuf(buf); MEM_freeN(dr_mask_arr); return true; } /* circle shaped sample area */ bool EDBM_backbuf_circle_init(ViewContext *vc, short xs, short ys, short rads) { struct ImBuf *buf; unsigned int *dr; short xmin, ymin, xmax, ymax, xc, yc; int radsq; /* method in use for face selecting too */ if (vc->obedit == NULL) { if (!BKE_paint_select_elem_test(vc->obact)) { return false; } } else if (!V3D_IS_ZBUF(vc->v3d)) { return false; } xmin = xs - rads; xmax = xs + rads; ymin = ys - rads; ymax = ys + rads; buf = ED_view3d_backbuf_read(vc, xmin, ymin, xmax, ymax); if (bm_vertoffs == 0) return false; if (buf == NULL) return false; dr = buf->rect; /* build selection lookup */ selbuf = edbm_backbuf_alloc(bm_vertoffs + 1); radsq = rads * rads; for (yc = -rads; yc <= rads; yc++) { for (xc = -rads; xc <= rads; xc++, dr++) { if (xc * xc + yc * yc < radsq) { if (*dr > 0 && *dr <= bm_vertoffs) { BLI_BITMAP_ENABLE(selbuf, *dr); } } } } IMB_freeImBuf(buf); return true; } /* -------------------------------------------------------------------- */ /** \name Find Nearest Vert/Edge/Face * * \note Screen-space manhatten distances are used here, * since its faster and good enough for the purpose of selection. * * \note \a dist_bias is used so we can bias against selected items. * when choosing between elements of a single type, but return the real distance * to avoid the bias interfering with distance comparisons when mixing types. * \{ */ #define FIND_NEAR_SELECT_BIAS 5 #define FIND_NEAR_CYCLE_THRESHOLD_MIN 3 struct NearestVertUserData_Hit { float dist; float dist_bias; int index; BMVert *vert; }; struct NearestVertUserData { float mval_fl[2]; bool use_select_bias; bool use_cycle; int cycle_index_prev; struct NearestVertUserData_Hit hit; struct NearestVertUserData_Hit hit_cycle; }; static void findnearestvert__doClosest(void *userData, BMVert *eve, const float screen_co[2], int index) { struct NearestVertUserData *data = userData; float dist_test, dist_test_bias; dist_test = dist_test_bias = len_manhattan_v2v2(data->mval_fl, screen_co); if (data->use_select_bias && BM_elem_flag_test(eve, BM_ELEM_SELECT)) { dist_test_bias += FIND_NEAR_SELECT_BIAS; } if (dist_test_bias < data->hit.dist_bias) { data->hit.dist_bias = dist_test_bias; data->hit.dist = dist_test; data->hit.index = index; data->hit.vert = eve; } if (data->use_cycle) { if ((data->hit_cycle.vert == NULL) && (index > data->cycle_index_prev) && (dist_test_bias < FIND_NEAR_CYCLE_THRESHOLD_MIN)) { data->hit_cycle.dist_bias = dist_test_bias; data->hit_cycle.dist = dist_test; data->hit_cycle.index = index; data->hit_cycle.vert = eve; } } } /** * Nearest vertex under the cursor. * * \param r_dist (in/out), minimal distance to the nearest and at the end, actual distance * \param use_select_bias * - When true, selected vertice are given a 5 pixel bias to make them further than unselect verts. * - When false, unselected vertice are given the bias. * \param use_cycle Cycle over elements within #FIND_NEAR_CYCLE_THRESHOLD_MIN in order of index. */ BMVert *EDBM_vert_find_nearest_ex( ViewContext *vc, float *r_dist, const bool use_select_bias, bool use_cycle) { BMesh *bm = vc->em->bm; if (V3D_IS_ZBUF(vc->v3d)) { const int dist_px = ED_view3d_backbuf_sample_size_clamp(vc->ar, *r_dist); float dist_test; unsigned int index; BMVert *eve; index = ED_view3d_backbuf_sample_rect( vc, vc->mval, dist_px, bm_wireoffs, 0xFFFFFF, &dist_test); eve = index ? BM_vert_at_index_find_or_table(bm, index - 1) : NULL; if (eve) { if (dist_test < *r_dist) { *r_dist = dist_test; return eve; } } return NULL; } else { struct NearestVertUserData data = {{0}}; const struct NearestVertUserData_Hit *hit; const eV3DProjTest clip_flag = V3D_PROJ_TEST_CLIP_DEFAULT; static int prev_select_index = 0; static const BMVert *prev_select_elem = NULL; if ((use_cycle == false) || (prev_select_elem && (prev_select_elem != BM_vert_at_index_find_or_table(bm, prev_select_index)))) { prev_select_index = 0; prev_select_elem = NULL; } data.mval_fl[0] = vc->mval[0]; data.mval_fl[1] = vc->mval[1]; data.use_select_bias = use_select_bias; data.use_cycle = use_cycle; data.hit.dist = data.hit_cycle.dist = \ data.hit.dist_bias = data.hit_cycle.dist_bias = *r_dist; data.cycle_index_prev = prev_select_index; ED_view3d_init_mats_rv3d(vc->obedit, vc->rv3d); mesh_foreachScreenVert(vc, findnearestvert__doClosest, &data, clip_flag); hit = (data.use_cycle && data.hit_cycle.vert) ? &data.hit_cycle : &data.hit; *r_dist = hit->dist; prev_select_elem = hit->vert; prev_select_index = hit->index; return hit->vert; } } BMVert *EDBM_vert_find_nearest(ViewContext *vc, float *r_dist) { return EDBM_vert_find_nearest_ex(vc, r_dist, false, false); } /* find the distance to the edge we already have */ struct NearestEdgeUserData_ZBuf { float mval_fl[2]; float dist; const BMEdge *edge_test; }; static void find_nearest_edge_center__doZBuf( void *userData, BMEdge *eed, const float screen_co_a[2], const float screen_co_b[2], int UNUSED(index)) { struct NearestEdgeUserData_ZBuf *data = userData; if (eed == data->edge_test) { float dist_test; float screen_co_mid[2]; mid_v2_v2v2(screen_co_mid, screen_co_a, screen_co_b); dist_test = len_manhattan_v2v2(data->mval_fl, screen_co_mid); if (dist_test < data->dist) { data->dist = dist_test; } } } struct NearestEdgeUserData_Hit { float dist; float dist_bias; int index; BMEdge *edge; /* edges only, un-biased manhatten distance to which ever edge we pick * (not used for choosing) */ float dist_center; }; struct NearestEdgeUserData { ViewContext vc; float mval_fl[2]; bool use_select_bias; bool use_cycle; int cycle_index_prev; struct NearestEdgeUserData_Hit hit; struct NearestEdgeUserData_Hit hit_cycle; }; /* note; uses v3d, so needs active 3d window */ static void find_nearest_edge__doClosest( void *userData, BMEdge *eed, const float screen_co_a[2], const float screen_co_b[2], int index) { struct NearestEdgeUserData *data = userData; float dist_test, dist_test_bias; float fac = line_point_factor_v2(data->mval_fl, screen_co_a, screen_co_b); float screen_co[2]; if (fac <= 0.0f) { fac = 0.0f; copy_v2_v2(screen_co, screen_co_a); } else if (fac >= 1.0f) { fac = 1.0f; copy_v2_v2(screen_co, screen_co_b); } else { interp_v2_v2v2(screen_co, screen_co_a, screen_co_b, fac); } dist_test = dist_test_bias = len_manhattan_v2v2(data->mval_fl, screen_co); if (data->use_select_bias && BM_elem_flag_test(eed, BM_ELEM_SELECT)) { dist_test += FIND_NEAR_SELECT_BIAS; } if (data->vc.rv3d->rflag & RV3D_CLIPPING) { float vec[3]; interp_v3_v3v3(vec, eed->v1->co, eed->v2->co, fac); if (ED_view3d_clipping_test(data->vc.rv3d, vec, true)) { return; } } if (dist_test_bias < data->hit.dist_bias) { float screen_co_mid[2]; data->hit.dist_bias = dist_test_bias; data->hit.dist = dist_test; data->hit.index = index; data->hit.edge = eed; mid_v2_v2v2(screen_co_mid, screen_co_a, screen_co_b); data->hit.dist_center = len_manhattan_v2v2(data->mval_fl, screen_co_mid); } if (data->use_cycle) { if ((data->hit_cycle.edge == NULL) && (index > data->cycle_index_prev) && (dist_test_bias < FIND_NEAR_CYCLE_THRESHOLD_MIN)) { float screen_co_mid[2]; data->hit_cycle.dist_bias = dist_test_bias; data->hit_cycle.dist = dist_test; data->hit_cycle.index = index; data->hit_cycle.edge = eed; mid_v2_v2v2(screen_co_mid, screen_co_a, screen_co_b); data->hit_cycle.dist_center = len_manhattan_v2v2(data->mval_fl, screen_co_mid); } } } BMEdge *EDBM_edge_find_nearest_ex( ViewContext *vc, float *r_dist, float *r_dist_center, const bool use_select_bias, const bool use_cycle, BMEdge **r_eed_zbuf) { BMesh *bm = vc->em->bm; if (V3D_IS_ZBUF(vc->v3d)) { const int dist_px = ED_view3d_backbuf_sample_size_clamp(vc->ar, *r_dist); float dist_test = 0.0f; unsigned int index; BMEdge *eed; ED_view3d_backbuf_validate(vc); index = ED_view3d_backbuf_sample_rect(vc, vc->mval, dist_px, bm_solidoffs, bm_wireoffs, &dist_test); eed = index ? BM_edge_at_index_find_or_table(bm, index - 1) : NULL; if (r_eed_zbuf) { *r_eed_zbuf = eed; } /* exception for faces (verts don't need this) */ if (r_dist_center && eed) { struct NearestEdgeUserData_ZBuf data; data.mval_fl[0] = vc->mval[0]; data.mval_fl[1] = vc->mval[1]; data.dist = FLT_MAX; data.edge_test = eed; ED_view3d_init_mats_rv3d(vc->obedit, vc->rv3d); mesh_foreachScreenEdge(vc, find_nearest_edge_center__doZBuf, &data, V3D_PROJ_TEST_CLIP_DEFAULT); *r_dist_center = data.dist; } /* end exception */ if (eed) { if (dist_test < *r_dist) { *r_dist = dist_test; return eed; } } return NULL; } else { struct NearestEdgeUserData data = {{0}}; const struct NearestEdgeUserData_Hit *hit; /* interpolate along the edge before doing a clipping plane test */ const eV3DProjTest clip_flag = V3D_PROJ_TEST_CLIP_DEFAULT & ~V3D_PROJ_TEST_CLIP_BB; static int prev_select_index = 0; static const BMEdge *prev_select_elem = NULL; if ((use_cycle == false) || (prev_select_elem && (prev_select_elem != BM_edge_at_index_find_or_table(bm, prev_select_index)))) { prev_select_index = 0; prev_select_elem = NULL; } data.vc = *vc; data.mval_fl[0] = vc->mval[0]; data.mval_fl[1] = vc->mval[1]; data.use_select_bias = use_select_bias; data.use_cycle = use_cycle; data.hit.dist = data.hit_cycle.dist = \ data.hit.dist_bias = data.hit_cycle.dist_bias = *r_dist; data.cycle_index_prev = prev_select_index; ED_view3d_init_mats_rv3d(vc->obedit, vc->rv3d); mesh_foreachScreenEdge(vc, find_nearest_edge__doClosest, &data, clip_flag); hit = (data.use_cycle && data.hit_cycle.edge) ? &data.hit_cycle : &data.hit; *r_dist = hit->dist; if (r_dist_center) { *r_dist_center = hit->dist_center; } prev_select_elem = hit->edge; prev_select_index = hit->index; return hit->edge; } } BMEdge *EDBM_edge_find_nearest( ViewContext *vc, float *r_dist) { return EDBM_edge_find_nearest_ex(vc, r_dist, false, false, false, NULL); } /* find the distance to the face we already have */ struct NearestFaceUserData_ZBuf { float mval_fl[2]; float dist; const BMFace *face_test; }; static void find_nearest_face_center__doZBuf(void *userData, BMFace *efa, const float screen_co[2], int UNUSED(index)) { struct NearestFaceUserData_ZBuf *data = userData; if (efa == data->face_test) { const float dist_test = len_manhattan_v2v2(data->mval_fl, screen_co); if (dist_test < data->dist) { data->dist = dist_test; } } } struct NearestFaceUserData_Hit { float dist; float dist_bias; int index; BMFace *face; }; struct NearestFaceUserData { float mval_fl[2]; bool use_select_bias; bool use_cycle; int cycle_index_prev; struct NearestFaceUserData_Hit hit; struct NearestFaceUserData_Hit hit_cycle; }; static void findnearestface__doClosest(void *userData, BMFace *efa, const float screen_co[2], int index) { struct NearestFaceUserData *data = userData; float dist_test, dist_test_bias; dist_test = dist_test_bias = len_manhattan_v2v2(data->mval_fl, screen_co); if (data->use_select_bias && BM_elem_flag_test(efa, BM_ELEM_SELECT)) { dist_test_bias += FIND_NEAR_SELECT_BIAS; } if (dist_test_bias < data->hit.dist_bias) { data->hit.dist_bias = dist_test_bias; data->hit.dist = dist_test; data->hit.index = index; data->hit.face = efa; } if (data->use_cycle) { if ((data->hit_cycle.face == NULL) && (index > data->cycle_index_prev) && (dist_test_bias < FIND_NEAR_CYCLE_THRESHOLD_MIN)) { data->hit_cycle.dist_bias = dist_test_bias; data->hit_cycle.dist = dist_test; data->hit_cycle.index = index; data->hit_cycle.face = efa; } } } BMFace *EDBM_face_find_nearest_ex( ViewContext *vc, float *r_dist, float *r_dist_center, const bool use_select_bias, const bool use_cycle, BMFace **r_efa_zbuf) { BMesh *bm = vc->em->bm; if (V3D_IS_ZBUF(vc->v3d)) { float dist_test = 0.0f; unsigned int index; BMFace *efa; ED_view3d_backbuf_validate(vc); index = ED_view3d_backbuf_sample(vc, vc->mval[0], vc->mval[1]); efa = index ? BM_face_at_index_find_or_table(bm, index - 1) : NULL; if (r_efa_zbuf) { *r_efa_zbuf = efa; } /* exception for faces (verts don't need this) */ if (r_dist_center && efa) { struct NearestFaceUserData_ZBuf data; data.mval_fl[0] = vc->mval[0]; data.mval_fl[1] = vc->mval[1]; data.dist = FLT_MAX; data.face_test = efa; ED_view3d_init_mats_rv3d(vc->obedit, vc->rv3d); mesh_foreachScreenFace(vc, find_nearest_face_center__doZBuf, &data, V3D_PROJ_TEST_CLIP_DEFAULT); *r_dist_center = data.dist; } /* end exception */ if (efa) { if (dist_test < *r_dist) { *r_dist = dist_test; return efa; } } return NULL; } else { struct NearestFaceUserData data = {{0}}; const struct NearestFaceUserData_Hit *hit; const eV3DProjTest clip_flag = V3D_PROJ_TEST_CLIP_DEFAULT; static int prev_select_index = 0; static const BMFace *prev_select_elem = NULL; if ((use_cycle == false) || (prev_select_elem && (prev_select_elem != BM_face_at_index_find_or_table(bm, prev_select_index)))) { prev_select_index = 0; prev_select_elem = NULL; } data.mval_fl[0] = vc->mval[0]; data.mval_fl[1] = vc->mval[1]; data.use_select_bias = use_select_bias; data.use_cycle = use_cycle; data.hit.dist = data.hit_cycle.dist = \ data.hit.dist_bias = data.hit_cycle.dist_bias = *r_dist; data.cycle_index_prev = prev_select_index; ED_view3d_init_mats_rv3d(vc->obedit, vc->rv3d); mesh_foreachScreenFace(vc, findnearestface__doClosest, &data, clip_flag); hit = (data.use_cycle && data.hit_cycle.face) ? &data.hit_cycle : &data.hit; *r_dist = hit->dist; if (r_dist_center) { *r_dist_center = hit->dist; } prev_select_elem = hit->face; prev_select_index = hit->index; return hit->face; } } BMFace *EDBM_face_find_nearest(ViewContext *vc, float *r_dist) { return EDBM_face_find_nearest_ex(vc, r_dist, NULL, false, false, NULL); } #undef FIND_NEAR_SELECT_BIAS #undef FIND_NEAR_CYCLE_THRESHOLD_MIN /* best distance based on screen coords. * use em->selectmode to define how to use * selected vertices and edges get disadvantage * return 1 if found one */ static int unified_findnearest(ViewContext *vc, BMVert **r_eve, BMEdge **r_eed, BMFace **r_efa) { BMEditMesh *em = vc->em; static short mval_prev[2] = {-1, -1}; /* only cycle while the mouse remains still */ const bool use_cycle = ((mval_prev[0] == vc->mval[0]) && (mval_prev[1] == vc->mval[1])); const float dist_init = ED_view3d_select_dist_px(); /* since edges select lines, we give dots advantage of ~20 pix */ const float dist_margin = (dist_init / 2); float dist = dist_init; BMFace *efa_zbuf = NULL; BMEdge *eed_zbuf = NULL; BMVert *eve = NULL; BMEdge *eed = NULL; BMFace *efa = NULL; /* no afterqueue (yet), so we check it now, otherwise the em_xxxofs indices are bad */ ED_view3d_backbuf_validate(vc); if ((dist > 0.0f) && em->selectmode & SCE_SELECT_FACE) { float dist_center = 0.0f; float *dist_center_p = (em->selectmode & (SCE_SELECT_EDGE | SCE_SELECT_VERTEX)) ? &dist_center : NULL; efa = EDBM_face_find_nearest_ex(vc, &dist, dist_center_p, true, use_cycle, &efa_zbuf); if (efa && dist_center_p) { dist = min_ff(dist_margin, dist_center); } } if ((dist > 0.0f) && (em->selectmode & SCE_SELECT_EDGE)) { float dist_center = 0.0f; float *dist_center_p = (em->selectmode & SCE_SELECT_VERTEX) ? &dist_center : NULL; eed = EDBM_edge_find_nearest_ex(vc, &dist, dist_center_p, true, use_cycle, &eed_zbuf); if (eed && dist_center_p) { dist = min_ff(dist_margin, dist_center); } } if ((dist > 0.0f) && em->selectmode & SCE_SELECT_VERTEX) { eve = EDBM_vert_find_nearest_ex(vc, &dist, true, use_cycle); } /* return only one of 3 pointers, for frontbuffer redraws */ if (eve) { efa = NULL; eed = NULL; } else if (eed) { efa = NULL; } /* there may be a face under the cursor, who's center if too far away * use this if all else fails, it makes sense to select this */ if ((eve || eed || efa) == 0) { if (eed_zbuf) { eed = eed_zbuf; } else if (efa_zbuf) { efa = efa_zbuf; } } mval_prev[0] = vc->mval[0]; mval_prev[1] = vc->mval[1]; *r_eve = eve; *r_eed = eed; *r_efa = efa; return (eve || eed || efa); } /** \} */ /* **************** SIMILAR "group" SELECTS. FACE, EDGE AND VERTEX ************** */ static EnumPropertyItem prop_similar_compare_types[] = { {SIM_CMP_EQ, "EQUAL", 0, "Equal", ""}, {SIM_CMP_GT, "GREATER", 0, "Greater", ""}, {SIM_CMP_LT, "LESS", 0, "Less", ""}, {0, NULL, 0, NULL, NULL} }; static EnumPropertyItem prop_similar_types[] = { {SIMVERT_NORMAL, "NORMAL", 0, "Normal", ""}, {SIMVERT_FACE, "FACE", 0, "Amount of Adjacent Faces", ""}, {SIMVERT_VGROUP, "VGROUP", 0, "Vertex Groups", ""}, {SIMVERT_EDGE, "EDGE", 0, "Amount of connecting edges", ""}, {SIMEDGE_LENGTH, "LENGTH", 0, "Length", ""}, {SIMEDGE_DIR, "DIR", 0, "Direction", ""}, {SIMEDGE_FACE, "FACE", 0, "Amount of Faces Around an Edge", ""}, {SIMEDGE_FACE_ANGLE, "FACE_ANGLE", 0, "Face Angles", ""}, {SIMEDGE_CREASE, "CREASE", 0, "Crease", ""}, {SIMEDGE_BEVEL, "BEVEL", 0, "Bevel", ""}, {SIMEDGE_SEAM, "SEAM", 0, "Seam", ""}, {SIMEDGE_SHARP, "SHARP", 0, "Sharpness", ""}, #ifdef WITH_FREESTYLE {SIMEDGE_FREESTYLE, "FREESTYLE_EDGE", 0, "Freestyle Edge Marks", ""}, #endif {SIMFACE_MATERIAL, "MATERIAL", 0, "Material", ""}, {SIMFACE_IMAGE, "IMAGE", 0, "Image", ""}, {SIMFACE_AREA, "AREA", 0, "Area", ""}, {SIMFACE_SIDES, "SIDES", 0, "Polygon Sides", ""}, {SIMFACE_PERIMETER, "PERIMETER", 0, "Perimeter", ""}, {SIMFACE_NORMAL, "NORMAL", 0, "Normal", ""}, {SIMFACE_COPLANAR, "COPLANAR", 0, "Co-planar", ""}, {SIMFACE_SMOOTH, "SMOOTH", 0, "Flat/Smooth", ""}, #ifdef WITH_FREESTYLE {SIMFACE_FREESTYLE, "FREESTYLE_FACE", 0, "Freestyle Face Marks", ""}, #endif {0, NULL, 0, NULL, NULL} }; /* selects new faces/edges/verts based on the existing selection */ static int similar_face_select_exec(bContext *C, wmOperator *op) { Object *ob = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(ob); BMOperator bmop; /* get the type from RNA */ const int type = RNA_enum_get(op->ptr, "type"); const float thresh = RNA_float_get(op->ptr, "threshold"); const int compare = RNA_enum_get(op->ptr, "compare"); /* initialize the bmop using EDBM api, which does various ui error reporting and other stuff */ EDBM_op_init(em, &bmop, op, "similar_faces faces=%hf type=%i thresh=%f compare=%i", BM_ELEM_SELECT, type, thresh, compare); /* execute the operator */ BMO_op_exec(em->bm, &bmop); /* clear the existing selection */ EDBM_flag_disable_all(em, BM_ELEM_SELECT); /* select the output */ BMO_slot_buffer_hflag_enable(em->bm, bmop.slots_out, "faces.out", BM_FACE, BM_ELEM_SELECT, true); /* finish the operator */ if (!EDBM_op_finish(em, &bmop, op, true)) { return OPERATOR_CANCELLED; } EDBM_update_generic(em, false, false); return OPERATOR_FINISHED; } /* ***************************************************** */ /* EDGE GROUP */ /* wrap the above function but do selection flushing edge to face */ static int similar_edge_select_exec(bContext *C, wmOperator *op) { Object *ob = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(ob); BMOperator bmop; /* get the type from RNA */ const int type = RNA_enum_get(op->ptr, "type"); const float thresh = RNA_float_get(op->ptr, "threshold"); const int compare = RNA_enum_get(op->ptr, "compare"); /* initialize the bmop using EDBM api, which does various ui error reporting and other stuff */ EDBM_op_init(em, &bmop, op, "similar_edges edges=%he type=%i thresh=%f compare=%i", BM_ELEM_SELECT, type, thresh, compare); /* execute the operator */ BMO_op_exec(em->bm, &bmop); /* clear the existing selection */ EDBM_flag_disable_all(em, BM_ELEM_SELECT); /* select the output */ BMO_slot_buffer_hflag_enable(em->bm, bmop.slots_out, "edges.out", BM_EDGE, BM_ELEM_SELECT, true); EDBM_selectmode_flush(em); /* finish the operator */ if (!EDBM_op_finish(em, &bmop, op, true)) { return OPERATOR_CANCELLED; } EDBM_update_generic(em, false, false); return OPERATOR_FINISHED; } /* ********************************* */ /* * VERT GROUP * mode 1: same normal * mode 2: same number of face users * mode 3: same vertex groups */ static int similar_vert_select_exec(bContext *C, wmOperator *op) { Object *ob = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(ob); BMOperator bmop; /* get the type from RNA */ const int type = RNA_enum_get(op->ptr, "type"); const float thresh = RNA_float_get(op->ptr, "threshold"); const int compare = RNA_enum_get(op->ptr, "compare"); /* initialize the bmop using EDBM api, which does various ui error reporting and other stuff */ EDBM_op_init(em, &bmop, op, "similar_verts verts=%hv type=%i thresh=%f compare=%i", BM_ELEM_SELECT, type, thresh, compare); /* execute the operator */ BMO_op_exec(em->bm, &bmop); /* clear the existing selection */ EDBM_flag_disable_all(em, BM_ELEM_SELECT); /* select the output */ BMO_slot_buffer_hflag_enable(em->bm, bmop.slots_out, "verts.out", BM_VERT, BM_ELEM_SELECT, true); /* finish the operator */ if (!EDBM_op_finish(em, &bmop, op, true)) { return OPERATOR_CANCELLED; } EDBM_selectmode_flush(em); EDBM_update_generic(em, false, false); return OPERATOR_FINISHED; } static int edbm_select_similar_exec(bContext *C, wmOperator *op) { ToolSettings *ts = CTX_data_tool_settings(C); PropertyRNA *prop = RNA_struct_find_property(op->ptr, "threshold"); const int type = RNA_enum_get(op->ptr, "type"); if (!RNA_property_is_set(op->ptr, prop)) { RNA_property_float_set(op->ptr, prop, ts->select_thresh); } else { ts->select_thresh = RNA_property_float_get(op->ptr, prop); } if (type < 100) return similar_vert_select_exec(C, op); else if (type < 200) return similar_edge_select_exec(C, op); else return similar_face_select_exec(C, op); } static EnumPropertyItem *select_similar_type_itemf(bContext *C, PointerRNA *UNUSED(ptr), PropertyRNA *UNUSED(prop), bool *r_free) { Object *obedit; if (!C) /* needed for docs and i18n tools */ return prop_similar_types; obedit = CTX_data_edit_object(C); if (obedit && obedit->type == OB_MESH) { EnumPropertyItem *item = NULL; int a, totitem = 0; BMEditMesh *em = BKE_editmesh_from_object(obedit); if (em->selectmode & SCE_SELECT_VERTEX) { for (a = SIMVERT_NORMAL; a < SIMEDGE_LENGTH; a++) { RNA_enum_items_add_value(&item, &totitem, prop_similar_types, a); } } else if (em->selectmode & SCE_SELECT_EDGE) { for (a = SIMEDGE_LENGTH; a < SIMFACE_MATERIAL; a++) { RNA_enum_items_add_value(&item, &totitem, prop_similar_types, a); } } else if (em->selectmode & SCE_SELECT_FACE) { #ifdef WITH_FREESTYLE const int a_end = SIMFACE_FREESTYLE; #else const int a_end = SIMFACE_SMOOTH; #endif for (a = SIMFACE_MATERIAL; a <= a_end; a++) { RNA_enum_items_add_value(&item, &totitem, prop_similar_types, a); } } RNA_enum_item_end(&item, &totitem); *r_free = true; return item; } return NULL; } void MESH_OT_select_similar(wmOperatorType *ot) { PropertyRNA *prop; /* identifiers */ ot->name = "Select Similar"; ot->idname = "MESH_OT_select_similar"; ot->description = "Select similar vertices, edges or faces by property types"; /* api callbacks */ ot->invoke = WM_menu_invoke; ot->exec = edbm_select_similar_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; /* properties */ prop = ot->prop = RNA_def_enum(ot->srna, "type", prop_similar_types, SIMVERT_NORMAL, "Type", ""); RNA_def_enum_funcs(prop, select_similar_type_itemf); RNA_def_enum(ot->srna, "compare", prop_similar_compare_types, SIM_CMP_EQ, "Compare", ""); RNA_def_float(ot->srna, "threshold", 0.0f, 0.0f, 1.0f, "Threshold", "", 0.0f, 1.0f); } /* -------------------------------------------------------------------- */ /* Select Similar Regions */ static int edbm_select_similar_region_exec(bContext *C, wmOperator *op) { Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); BMesh *bm = em->bm; bool changed = false; /* group vars */ int *groups_array; int (*group_index)[2]; int group_tot; int i; if (bm->totfacesel < 2) { BKE_report(op->reports, RPT_ERROR, "No face regions selected"); return OPERATOR_CANCELLED; } groups_array = MEM_mallocN(sizeof(*groups_array) * bm->totfacesel, __func__); group_tot = BM_mesh_calc_face_groups(bm, groups_array, &group_index, NULL, NULL, BM_ELEM_SELECT, BM_VERT); BM_mesh_elem_table_ensure(bm, BM_FACE); for (i = 0; i < group_tot; i++) { ListBase faces_regions; int tot; const int fg_sta = group_index[i][0]; const int fg_len = group_index[i][1]; int j; BMFace **fg = MEM_mallocN(sizeof(*fg) * fg_len, __func__); for (j = 0; j < fg_len; j++) { fg[j] = BM_face_at_index(bm, groups_array[fg_sta + j]); } tot = BM_mesh_region_match(bm, fg, fg_len, &faces_regions); MEM_freeN(fg); if (tot) { LinkData *link; while ((link = BLI_pophead(&faces_regions))) { BMFace *f, **faces = link->data; unsigned int i = 0; while ((f = faces[i++])) { BM_face_select_set(bm, f, true); } MEM_freeN(faces); MEM_freeN(link); changed = true; } } } MEM_freeN(groups_array); MEM_freeN(group_index); if (changed) { WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit); } else { BKE_report(op->reports, RPT_WARNING, "No matching face regions found"); } return OPERATOR_FINISHED; } void MESH_OT_select_similar_region(wmOperatorType *ot) { /* identifiers */ ot->name = "Select Similar Regions"; ot->idname = "MESH_OT_select_similar_region"; ot->description = "Select similar face regions to the current selection"; /* api callbacks */ ot->exec = edbm_select_similar_region_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; } /* **************** Mode Select *************** */ static int edbm_select_mode_exec(bContext *C, wmOperator *op) { const int type = RNA_enum_get(op->ptr, "type"); const int action = RNA_enum_get(op->ptr, "action"); const bool use_extend = RNA_boolean_get(op->ptr, "use_extend"); const bool use_expand = RNA_boolean_get(op->ptr, "use_expand"); if (EDBM_selectmode_toggle(C, type, action, use_extend, use_expand)) { return OPERATOR_FINISHED; } else { return OPERATOR_CANCELLED; } } static int edbm_select_mode_invoke(bContext *C, wmOperator *op, const wmEvent *event) { /* detecting these options based on shift/ctrl here is weak, but it's done * to make this work when clicking buttons or menus */ if (!RNA_struct_property_is_set(op->ptr, "use_extend")) RNA_boolean_set(op->ptr, "use_extend", event->shift); if (!RNA_struct_property_is_set(op->ptr, "use_expand")) RNA_boolean_set(op->ptr, "use_expand", event->ctrl); return edbm_select_mode_exec(C, op); } void MESH_OT_select_mode(wmOperatorType *ot) { PropertyRNA *prop; static EnumPropertyItem elem_items[] = { {SCE_SELECT_VERTEX, "VERT", ICON_VERTEXSEL, "Vertices", ""}, {SCE_SELECT_EDGE, "EDGE", ICON_EDGESEL, "Edges", ""}, {SCE_SELECT_FACE, "FACE", ICON_FACESEL, "Faces", ""}, {0, NULL, 0, NULL, NULL}, }; static EnumPropertyItem actions_items[] = { {0, "DISABLE", 0, "Disable", "Disable selected markers"}, {1, "ENABLE", 0, "Enable", "Enable selected markers"}, {2, "TOGGLE", 0, "Toggle", "Toggle disabled flag for selected markers"}, {0, NULL, 0, NULL, NULL} }; /* identifiers */ ot->name = "Select Mode"; ot->idname = "MESH_OT_select_mode"; ot->description = "Change selection mode"; /* api callbacks */ ot->invoke = edbm_select_mode_invoke; ot->exec = edbm_select_mode_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; /* properties */ prop = RNA_def_boolean(ot->srna, "use_extend", false, "Extend", ""); RNA_def_property_flag(prop, PROP_SKIP_SAVE); prop = RNA_def_boolean(ot->srna, "use_expand", false, "Expand", ""); RNA_def_property_flag(prop, PROP_SKIP_SAVE); ot->prop = prop = RNA_def_enum(ot->srna, "type", elem_items, 0, "Type", ""); RNA_def_property_flag(prop, PROP_SKIP_SAVE); RNA_def_enum(ot->srna, "action", actions_items, 2, "Action", "Selection action to execute"); } /* ***************************************************** */ /* **************** LOOP SELECTS *************** */ static void walker_select_count(BMEditMesh *em, int walkercode, void *start, const bool select, const bool select_mix, int *r_totsel, int *r_totunsel) { BMesh *bm = em->bm; BMElem *ele; BMWalker walker; int tot[2] = {0, 0}; BMW_init(&walker, bm, walkercode, BMW_MASK_NOP, BMW_MASK_NOP, BMW_MASK_NOP, BMW_FLAG_TEST_HIDDEN, BMW_NIL_LAY); for (ele = BMW_begin(&walker, start); ele; ele = BMW_step(&walker)) { tot[(BM_elem_flag_test_bool(ele, BM_ELEM_SELECT) != select)] += 1; if (!select_mix && tot[0] && tot[1]) { tot[0] = tot[1] = -1; break; } } *r_totsel = tot[0]; *r_totunsel = tot[1]; BMW_end(&walker); } static void walker_select(BMEditMesh *em, int walkercode, void *start, const bool select) { BMesh *bm = em->bm; BMElem *ele; BMWalker walker; BMW_init(&walker, bm, walkercode, BMW_MASK_NOP, BMW_MASK_NOP, BMW_MASK_NOP, BMW_FLAG_TEST_HIDDEN, BMW_NIL_LAY); for (ele = BMW_begin(&walker, start); ele; ele = BMW_step(&walker)) { if (!select) { BM_select_history_remove(bm, ele); } BM_elem_select_set(bm, ele, select); } BMW_end(&walker); } static int edbm_loop_multiselect_exec(bContext *C, wmOperator *op) { Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); BMEdge *eed; BMEdge **edarray; int edindex; const bool is_ring = RNA_boolean_get(op->ptr, "ring"); BMIter iter; int totedgesel = 0; BM_ITER_MESH (eed, &iter, em->bm, BM_EDGES_OF_MESH) { if (BM_elem_flag_test(eed, BM_ELEM_SELECT)) { totedgesel++; } } edarray = MEM_mallocN(sizeof(BMEdge *) * totedgesel, "edge array"); edindex = 0; BM_ITER_MESH (eed, &iter, em->bm, BM_EDGES_OF_MESH) { if (BM_elem_flag_test(eed, BM_ELEM_SELECT)) { edarray[edindex] = eed; edindex++; } } if (is_ring) { for (edindex = 0; edindex < totedgesel; edindex += 1) { eed = edarray[edindex]; walker_select(em, BMW_EDGERING, eed, true); } EDBM_selectmode_flush(em); } else { for (edindex = 0; edindex < totedgesel; edindex += 1) { eed = edarray[edindex]; walker_select(em, BMW_EDGELOOP, eed, true); } EDBM_selectmode_flush(em); } MEM_freeN(edarray); // if (EM_texFaceCheck()) WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit); return OPERATOR_FINISHED; } void MESH_OT_loop_multi_select(wmOperatorType *ot) { /* identifiers */ ot->name = "Multi Select Loops"; ot->idname = "MESH_OT_loop_multi_select"; ot->description = "Select a loop of connected edges by connection type"; /* api callbacks */ ot->exec = edbm_loop_multiselect_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; /* properties */ RNA_def_boolean(ot->srna, "ring", 0, "Ring", ""); } /* ***************** MAIN MOUSE SELECTION ************** */ /* ***************** loop select (non modal) ************** */ static void mouse_mesh_loop_face(BMEditMesh *em, BMEdge *eed, bool select, bool select_clear) { if (select_clear) { EDBM_flag_disable_all(em, BM_ELEM_SELECT); } walker_select(em, BMW_FACELOOP, eed, select); } static void mouse_mesh_loop_edge_ring(BMEditMesh *em, BMEdge *eed, bool select, bool select_clear) { if (select_clear) { EDBM_flag_disable_all(em, BM_ELEM_SELECT); } walker_select(em, BMW_EDGERING, eed, select); } static void mouse_mesh_loop_edge(BMEditMesh *em, BMEdge *eed, bool select, bool select_clear, bool select_cycle) { bool edge_boundary = false; /* cycle between BMW_EDGELOOP / BMW_EDGEBOUNDARY */ if (select_cycle && BM_edge_is_boundary(eed)) { int tot[2]; /* if the loops selected toggle the boundaries */ walker_select_count(em, BMW_EDGELOOP, eed, select, false, &tot[0], &tot[1]); if (tot[select] == 0) { edge_boundary = true; /* if the boundaries selected, toggle back to the loop */ walker_select_count(em, BMW_EDGEBOUNDARY, eed, select, false, &tot[0], &tot[1]); if (tot[select] == 0) { edge_boundary = false; } } } if (select_clear) { EDBM_flag_disable_all(em, BM_ELEM_SELECT); } if (edge_boundary) { walker_select(em, BMW_EDGEBOUNDARY, eed, select); } else { walker_select(em, BMW_EDGELOOP, eed, select); } } static bool mouse_mesh_loop(bContext *C, const int mval[2], bool extend, bool deselect, bool toggle, bool ring) { ViewContext vc; BMEditMesh *em; BMEdge *eed; bool select = true; bool select_clear = false; bool select_cycle = true; float dist = ED_view3d_select_dist_px() * 0.6666f; float mvalf[2]; em_setup_viewcontext(C, &vc); mvalf[0] = (float)(vc.mval[0] = mval[0]); mvalf[1] = (float)(vc.mval[1] = mval[1]); em = vc.em; /* no afterqueue (yet), so we check it now, otherwise the bm_xxxofs indices are bad */ ED_view3d_backbuf_validate(&vc); eed = EDBM_edge_find_nearest(&vc, &dist); if (eed == NULL) { return false; } if (extend == false && deselect == false && toggle == false) { select_clear = true; } if (extend) { select = true; } else if (deselect) { select = false; } else if (select_clear || (BM_elem_flag_test(eed, BM_ELEM_SELECT) == 0)) { select = true; } else if (toggle) { select = false; select_cycle = false; } if (em->selectmode & SCE_SELECT_FACE) { mouse_mesh_loop_face(em, eed, select, select_clear); } else { if (ring) { mouse_mesh_loop_edge_ring(em, eed, select, select_clear); } else { mouse_mesh_loop_edge(em, eed, select, select_clear, select_cycle); } } EDBM_selectmode_flush(em); /* sets as active, useful for other tools */ if (select) { if (em->selectmode & SCE_SELECT_VERTEX) { /* Find nearest vert from mouse * (initialize to large values incase only one vertex can be projected) */ float v1_co[2], v2_co[2]; float length_1 = FLT_MAX; float length_2 = FLT_MAX; /* We can't be sure this has already been set... */ ED_view3d_init_mats_rv3d(vc.obedit, vc.rv3d); if (ED_view3d_project_float_object(vc.ar, eed->v1->co, v1_co, V3D_PROJ_TEST_CLIP_NEAR) == V3D_PROJ_RET_OK) { length_1 = len_squared_v2v2(mvalf, v1_co); } if (ED_view3d_project_float_object(vc.ar, eed->v2->co, v2_co, V3D_PROJ_TEST_CLIP_NEAR) == V3D_PROJ_RET_OK) { length_2 = len_squared_v2v2(mvalf, v2_co); } #if 0 printf("mouse to v1: %f\nmouse to v2: %f\n", len_squared_v2v2(mvalf, v1_co), len_squared_v2v2(mvalf, v2_co)); #endif BM_select_history_store(em->bm, (length_1 < length_2) ? eed->v1 : eed->v2); } else if (em->selectmode & SCE_SELECT_EDGE) { BM_select_history_store(em->bm, eed); } else if (em->selectmode & SCE_SELECT_FACE) { /* Select the face of eed which is the nearest of mouse. */ BMFace *f, *efa = NULL; BMIter iterf; float best_dist = FLT_MAX; /* We can't be sure this has already been set... */ ED_view3d_init_mats_rv3d(vc.obedit, vc.rv3d); BM_ITER_ELEM (f, &iterf, eed, BM_FACES_OF_EDGE) { if (BM_elem_flag_test(f, BM_ELEM_SELECT)) { float cent[3]; float co[2], tdist; BM_face_calc_center_mean(f, cent); if (ED_view3d_project_float_object(vc.ar, cent, co, V3D_PROJ_TEST_CLIP_NEAR) == V3D_PROJ_RET_OK) { tdist = len_squared_v2v2(mvalf, co); if (tdist < best_dist) { /* printf("Best face: %p (%f)\n", f, tdist);*/ best_dist = tdist; efa = f; } } } } if (efa) { BM_mesh_active_face_set(em->bm, efa); BM_select_history_store(em->bm, efa); } } } WM_event_add_notifier(C, NC_GEOM | ND_SELECT, vc.obedit); return true; } static int edbm_select_loop_invoke(bContext *C, wmOperator *op, const wmEvent *event) { view3d_operator_needs_opengl(C); if (mouse_mesh_loop(C, event->mval, RNA_boolean_get(op->ptr, "extend"), RNA_boolean_get(op->ptr, "deselect"), RNA_boolean_get(op->ptr, "toggle"), RNA_boolean_get(op->ptr, "ring"))) { return OPERATOR_FINISHED; } else { return OPERATOR_CANCELLED; } } void MESH_OT_loop_select(wmOperatorType *ot) { /* identifiers */ ot->name = "Loop Select"; ot->idname = "MESH_OT_loop_select"; ot->description = "Select a loop of connected edges"; /* api callbacks */ ot->invoke = edbm_select_loop_invoke; ot->poll = ED_operator_editmesh_region_view3d; /* flags */ ot->flag = OPTYPE_UNDO; /* properties */ RNA_def_boolean(ot->srna, "extend", 0, "Extend Select", "Extend the selection"); RNA_def_boolean(ot->srna, "deselect", 0, "Deselect", "Remove from the selection"); RNA_def_boolean(ot->srna, "toggle", 0, "Toggle Select", "Toggle the selection"); RNA_def_boolean(ot->srna, "ring", 0, "Select Ring", "Select ring"); } void MESH_OT_edgering_select(wmOperatorType *ot) { /* description */ ot->name = "Edge Ring Select"; ot->idname = "MESH_OT_edgering_select"; ot->description = "Select an edge ring"; /* callbacks */ ot->invoke = edbm_select_loop_invoke; ot->poll = ED_operator_editmesh_region_view3d; /* flags */ ot->flag = OPTYPE_UNDO; RNA_def_boolean(ot->srna, "extend", 0, "Extend", "Extend the selection"); RNA_def_boolean(ot->srna, "deselect", 0, "Deselect", "Remove from the selection"); RNA_def_boolean(ot->srna, "toggle", 0, "Toggle Select", "Toggle the selection"); RNA_def_boolean(ot->srna, "ring", 1, "Select Ring", "Select ring"); } /* ******************** (de)select all operator **************** */ static int edbm_select_all_exec(bContext *C, wmOperator *op) { Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); const int action = RNA_enum_get(op->ptr, "action"); switch (action) { case SEL_TOGGLE: EDBM_select_toggle_all(em); break; case SEL_SELECT: EDBM_flag_enable_all(em, BM_ELEM_SELECT); break; case SEL_DESELECT: EDBM_flag_disable_all(em, BM_ELEM_SELECT); break; case SEL_INVERT: EDBM_select_swap(em); EDBM_selectmode_flush(em); break; } WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit); return OPERATOR_FINISHED; } void MESH_OT_select_all(wmOperatorType *ot) { /* identifiers */ ot->name = "(De)select All"; ot->idname = "MESH_OT_select_all"; ot->description = "(De)select all vertices, edges or faces"; /* api callbacks */ ot->exec = edbm_select_all_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; WM_operator_properties_select_all(ot); } static int edbm_faces_select_interior_exec(bContext *C, wmOperator *UNUSED(op)) { Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); if (EDBM_select_interior_faces(em)) { WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit); return OPERATOR_FINISHED; } else { return OPERATOR_CANCELLED; } } void MESH_OT_select_interior_faces(wmOperatorType *ot) { /* identifiers */ ot->name = "Select Interior Faces"; ot->idname = "MESH_OT_select_interior_faces"; ot->description = "Select faces where all edges have more than 2 face users"; /* api callbacks */ ot->exec = edbm_faces_select_interior_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; } /* ************************************************** */ /* here actual select happens */ /* gets called via generic mouse select operator */ bool EDBM_select_pick(bContext *C, const int mval[2], bool extend, bool deselect, bool toggle) { ViewContext vc; BMVert *eve = NULL; BMEdge *eed = NULL; BMFace *efa = NULL; /* setup view context for argument to callbacks */ em_setup_viewcontext(C, &vc); vc.mval[0] = mval[0]; vc.mval[1] = mval[1]; if (unified_findnearest(&vc, &eve, &eed, &efa)) { /* Deselect everything */ if (extend == false && deselect == false && toggle == false) EDBM_flag_disable_all(vc.em, BM_ELEM_SELECT); if (efa) { if (extend) { /* set the last selected face */ BM_mesh_active_face_set(vc.em->bm, efa); /* Work-around: deselect first, so we can guarantee it will */ /* be active even if it was already selected */ BM_select_history_remove(vc.em->bm, efa); BM_face_select_set(vc.em->bm, efa, false); BM_select_history_store(vc.em->bm, efa); BM_face_select_set(vc.em->bm, efa, true); } else if (deselect) { BM_select_history_remove(vc.em->bm, efa); BM_face_select_set(vc.em->bm, efa, false); } else { /* set the last selected face */ BM_mesh_active_face_set(vc.em->bm, efa); if (!BM_elem_flag_test(efa, BM_ELEM_SELECT)) { BM_select_history_store(vc.em->bm, efa); BM_face_select_set(vc.em->bm, efa, true); } else if (toggle) { BM_select_history_remove(vc.em->bm, efa); BM_face_select_set(vc.em->bm, efa, false); } } } else if (eed) { if (extend) { /* Work-around: deselect first, so we can guarantee it will */ /* be active even if it was already selected */ BM_select_history_remove(vc.em->bm, eed); BM_edge_select_set(vc.em->bm, eed, false); BM_select_history_store(vc.em->bm, eed); BM_edge_select_set(vc.em->bm, eed, true); } else if (deselect) { BM_select_history_remove(vc.em->bm, eed); BM_edge_select_set(vc.em->bm, eed, false); } else { if (!BM_elem_flag_test(eed, BM_ELEM_SELECT)) { BM_select_history_store(vc.em->bm, eed); BM_edge_select_set(vc.em->bm, eed, true); } else if (toggle) { BM_select_history_remove(vc.em->bm, eed); BM_edge_select_set(vc.em->bm, eed, false); } } } else if (eve) { if (extend) { /* Work-around: deselect first, so we can guarantee it will */ /* be active even if it was already selected */ BM_select_history_remove(vc.em->bm, eve); BM_vert_select_set(vc.em->bm, eve, false); BM_select_history_store(vc.em->bm, eve); BM_vert_select_set(vc.em->bm, eve, true); } else if (deselect) { BM_select_history_remove(vc.em->bm, eve); BM_vert_select_set(vc.em->bm, eve, false); } else { if (!BM_elem_flag_test(eve, BM_ELEM_SELECT)) { BM_select_history_store(vc.em->bm, eve); BM_vert_select_set(vc.em->bm, eve, true); } else if (toggle) { BM_select_history_remove(vc.em->bm, eve); BM_vert_select_set(vc.em->bm, eve, false); } } } EDBM_selectmode_flush(vc.em); /* change active material on object */ if (efa && efa->mat_nr != vc.obedit->actcol - 1) { vc.obedit->actcol = efa->mat_nr + 1; vc.em->mat_nr = efa->mat_nr; WM_event_add_notifier(C, NC_MATERIAL | ND_SHADING_LINKS, NULL); } WM_event_add_notifier(C, NC_GEOM | ND_SELECT, vc.obedit); return true; } return false; } static void edbm_strip_selections(BMEditMesh *em) { BMEditSelection *ese, *nextese; if (!(em->selectmode & SCE_SELECT_VERTEX)) { ese = em->bm->selected.first; while (ese) { nextese = ese->next; if (ese->htype == BM_VERT) BLI_freelinkN(&(em->bm->selected), ese); ese = nextese; } } if (!(em->selectmode & SCE_SELECT_EDGE)) { ese = em->bm->selected.first; while (ese) { nextese = ese->next; if (ese->htype == BM_EDGE) BLI_freelinkN(&(em->bm->selected), ese); ese = nextese; } } if (!(em->selectmode & SCE_SELECT_FACE)) { ese = em->bm->selected.first; while (ese) { nextese = ese->next; if (ese->htype == BM_FACE) BLI_freelinkN(&(em->bm->selected), ese); ese = nextese; } } } /* when switching select mode, makes sure selection is consistent for editing */ /* also for paranoia checks to make sure edge or face mode works */ void EDBM_selectmode_set(BMEditMesh *em) { BMVert *eve; BMEdge *eed; BMFace *efa; BMIter iter; em->bm->selectmode = em->selectmode; edbm_strip_selections(em); /* strip BMEditSelections from em->selected that are not relevant to new mode */ if (em->bm->totvertsel == 0 && em->bm->totedgesel == 0 && em->bm->totfacesel == 0) { return; } if (em->selectmode & SCE_SELECT_VERTEX) { if (em->bm->totvertsel) { EDBM_select_flush(em); } } else if (em->selectmode & SCE_SELECT_EDGE) { /* deselect vertices, and select again based on edge select */ BM_ITER_MESH (eve, &iter, em->bm, BM_VERTS_OF_MESH) { BM_vert_select_set(em->bm, eve, false); } if (em->bm->totedgesel) { BM_ITER_MESH (eed, &iter, em->bm, BM_EDGES_OF_MESH) { if (BM_elem_flag_test(eed, BM_ELEM_SELECT)) { BM_edge_select_set(em->bm, eed, true); } } /* selects faces based on edge status */ EDBM_selectmode_flush(em); } } else if (em->selectmode & SCE_SELECT_FACE) { /* deselect eges, and select again based on face select */ BM_ITER_MESH (eed, &iter, em->bm, BM_EDGES_OF_MESH) { BM_edge_select_set(em->bm, eed, false); } if (em->bm->totfacesel) { BM_ITER_MESH (efa, &iter, em->bm, BM_FACES_OF_MESH) { if (BM_elem_flag_test(efa, BM_ELEM_SELECT)) { BM_face_select_set(em->bm, efa, true); } } } } } /** * Expand & Contract the Selection * (used when chaning modes and Ctrl key held) * * Flush the selection up: * - vert -> edge * - vert -> face * - edge -> face * * Flush the selection down: * - face -> edge * - face -> vert * - edge -> vert */ void EDBM_selectmode_convert(BMEditMesh *em, const short selectmode_old, const short selectmode_new) { BMesh *bm = em->bm; BMVert *eve; BMEdge *eed; BMFace *efa; BMIter iter; /* first tag-to-select, then select --- this avoids a feedback loop */ /* have to find out what the selectionmode was previously */ if (selectmode_old == SCE_SELECT_VERTEX) { if (bm->totvertsel == 0) { /* pass */ } else if (selectmode_new == SCE_SELECT_EDGE) { /* flush up (vert -> edge) */ /* select all edges associated with every selected vert */ BM_ITER_MESH (eed, &iter, bm, BM_EDGES_OF_MESH) { BM_elem_flag_set(eed, BM_ELEM_TAG, BM_edge_is_any_vert_flag_test(eed, BM_ELEM_SELECT)); } BM_ITER_MESH (eed, &iter, bm, BM_EDGES_OF_MESH) { if (BM_elem_flag_test(eed, BM_ELEM_TAG)) { BM_edge_select_set(bm, eed, true); } } } else if (selectmode_new == SCE_SELECT_FACE) { /* flush up (vert -> face) */ /* select all faces associated with every selected vert */ BM_ITER_MESH (efa, &iter, bm, BM_FACES_OF_MESH) { BM_elem_flag_set(efa, BM_ELEM_TAG, BM_face_is_any_vert_flag_test(efa, BM_ELEM_SELECT)); } BM_ITER_MESH (efa, &iter, bm, BM_FACES_OF_MESH) { if (BM_elem_flag_test(efa, BM_ELEM_TAG)) { BM_face_select_set(bm, efa, true); } } } } else if (selectmode_old == SCE_SELECT_EDGE) { if (bm->totedgesel == 0) { /* pass */ } else if (selectmode_new == SCE_SELECT_FACE) { /* flush up (edge -> face) */ /* select all faces associated with every selected edge */ BM_ITER_MESH (efa, &iter, bm, BM_FACES_OF_MESH) { BM_elem_flag_set(efa, BM_ELEM_TAG, BM_face_is_any_edge_flag_test(efa, BM_ELEM_SELECT)); } BM_ITER_MESH (efa, &iter, bm, BM_FACES_OF_MESH) { if (BM_elem_flag_test(efa, BM_ELEM_TAG)) { BM_face_select_set(bm, efa, true); } } } else if (selectmode_new == SCE_SELECT_VERTEX) { /* flush down (edge -> vert) */ BM_ITER_MESH (eve, &iter, bm, BM_VERTS_OF_MESH) { if (!BM_vert_is_all_edge_flag_test(eve, BM_ELEM_SELECT, true)) { BM_vert_select_set(bm, eve, false); } } /* deselect edges without both verts selected */ BM_mesh_deselect_flush(bm); } } else if (selectmode_old == SCE_SELECT_FACE) { if (bm->totfacesel == 0) { /* pass */ } else if (selectmode_new == SCE_SELECT_EDGE) { /* flush down (face -> edge) */ BM_ITER_MESH (eed, &iter, bm, BM_EDGES_OF_MESH) { if (!BM_edge_is_all_face_flag_test(eed, BM_ELEM_SELECT, true)) { BM_edge_select_set(bm, eed, false); } } } else if (selectmode_new == SCE_SELECT_VERTEX) { /* flush down (face -> vert) */ BM_ITER_MESH (eve, &iter, bm, BM_VERTS_OF_MESH) { if (!BM_vert_is_all_face_flag_test(eve, BM_ELEM_SELECT, true)) { BM_vert_select_set(bm, eve, false); } } /* deselect faces without verts selected */ BM_mesh_deselect_flush(bm); } } } /* user facing function, does notification */ bool EDBM_selectmode_toggle(bContext *C, const short selectmode_new, const int action, const bool use_extend, const bool use_expand) { ToolSettings *ts = CTX_data_tool_settings(C); Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = NULL; bool ret = false; if (obedit && obedit->type == OB_MESH) { em = BKE_editmesh_from_object(obedit); } if (em == NULL) { return ret; } switch (action) { case -1: /* already set */ break; case 0: /* disable */ /* check we have something to do */ if ((em->selectmode & selectmode_new) == 0) { return false; } em->selectmode &= ~selectmode_new; break; case 1: /* enable */ /* check we have something to do */ if ((em->selectmode & selectmode_new) != 0) { return false; } em->selectmode |= selectmode_new; break; case 2: /* toggle */ /* can't disable this flag if its the only one set */ if (em->selectmode == selectmode_new) { return false; } em->selectmode ^= selectmode_new; break; default: BLI_assert(0); break; } if (use_extend == 0 || em->selectmode == 0) { if (use_expand) { const short selmode_max = highest_order_bit_s(ts->selectmode); EDBM_selectmode_convert(em, selmode_max, selectmode_new); } } switch (selectmode_new) { case SCE_SELECT_VERTEX: if (use_extend == 0 || em->selectmode == 0) { em->selectmode = SCE_SELECT_VERTEX; } ts->selectmode = em->selectmode; EDBM_selectmode_set(em); ret = true; break; case SCE_SELECT_EDGE: if (use_extend == 0 || em->selectmode == 0) { em->selectmode = SCE_SELECT_EDGE; } ts->selectmode = em->selectmode; EDBM_selectmode_set(em); ret = true; break; case SCE_SELECT_FACE: if (use_extend == 0 || em->selectmode == 0) { em->selectmode = SCE_SELECT_FACE; } ts->selectmode = em->selectmode; EDBM_selectmode_set(em); ret = true; break; default: BLI_assert(0); break; } if (ret == true) { WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit->data); WM_main_add_notifier(NC_SCENE | ND_TOOLSETTINGS, NULL); } return ret; } /** * Use to disable a selectmode if its enabled, Using another mode as a fallback * if the disabled mode is the only mode set. * * \return true if the mode is changed. */ bool EDBM_selectmode_disable(Scene *scene, BMEditMesh *em, const short selectmode_disable, const short selectmode_fallback) { /* note essential, but switch out of vertex mode since the * selected regions wont be nicely isolated after flushing */ if (em->selectmode & selectmode_disable) { if (em->selectmode == selectmode_disable) { em->selectmode = selectmode_fallback; } else { em->selectmode &= ~selectmode_disable; } scene->toolsettings->selectmode = em->selectmode; EDBM_selectmode_set(em); WM_main_add_notifier(NC_SCENE | ND_TOOLSETTINGS, scene); return true; } else { return false; } } void EDBM_deselect_by_material(BMEditMesh *em, const short index, const bool select) { BMIter iter; BMFace *efa; BM_ITER_MESH (efa, &iter, em->bm, BM_FACES_OF_MESH) { if (BM_elem_flag_test(efa, BM_ELEM_HIDDEN)) continue; if (efa->mat_nr == index) { BM_face_select_set(em->bm, efa, select); } } } void EDBM_select_toggle_all(BMEditMesh *em) /* exported for UV */ { if (em->bm->totvertsel || em->bm->totedgesel || em->bm->totfacesel) EDBM_flag_disable_all(em, BM_ELEM_SELECT); else EDBM_flag_enable_all(em, BM_ELEM_SELECT); } void EDBM_select_swap(BMEditMesh *em) /* exported for UV */ { BMIter iter; BMVert *eve; BMEdge *eed; BMFace *efa; if (em->bm->selectmode & SCE_SELECT_VERTEX) { BM_ITER_MESH (eve, &iter, em->bm, BM_VERTS_OF_MESH) { if (BM_elem_flag_test(eve, BM_ELEM_HIDDEN)) continue; BM_vert_select_set(em->bm, eve, !BM_elem_flag_test(eve, BM_ELEM_SELECT)); } } else if (em->selectmode & SCE_SELECT_EDGE) { BM_ITER_MESH (eed, &iter, em->bm, BM_EDGES_OF_MESH) { if (BM_elem_flag_test(eed, BM_ELEM_HIDDEN)) continue; BM_edge_select_set(em->bm, eed, !BM_elem_flag_test(eed, BM_ELEM_SELECT)); } } else { BM_ITER_MESH (efa, &iter, em->bm, BM_FACES_OF_MESH) { if (BM_elem_flag_test(efa, BM_ELEM_HIDDEN)) continue; BM_face_select_set(em->bm, efa, !BM_elem_flag_test(efa, BM_ELEM_SELECT)); } } // if (EM_texFaceCheck()) } bool EDBM_select_interior_faces(BMEditMesh *em) { BMesh *bm = em->bm; BMIter iter; BMIter eiter; BMFace *efa; BMEdge *eed; bool ok; bool changed = false; BM_ITER_MESH (efa, &iter, em->bm, BM_FACES_OF_MESH) { if (BM_elem_flag_test(efa, BM_ELEM_HIDDEN)) continue; ok = true; BM_ITER_ELEM (eed, &eiter, efa, BM_EDGES_OF_FACE) { if (!BM_edge_face_count_is_over(eed, 2)) { ok = false; break; } } if (ok) { BM_face_select_set(bm, efa, true); changed = true; } } return changed; } /************************ Select Linked Operator *************************/ struct DelimitData { int cd_loop_type; int cd_loop_offset; }; static bool select_linked_delimit_test( BMEdge *e, int delimit, const struct DelimitData *delimit_data) { BLI_assert(delimit); if (delimit & BMO_DELIM_SEAM) { if (BM_elem_flag_test(e, BM_ELEM_SEAM)) { return true; } } if (delimit & BMO_DELIM_SHARP) { if (BM_elem_flag_test(e, BM_ELEM_SMOOTH) == 0) { return true; } } if (delimit & BMO_DELIM_NORMAL) { if (!BM_edge_is_contiguous(e)) { return true; } } if (delimit & BMO_DELIM_MATERIAL) { if (e->l && e->l->radial_next != e->l) { const short mat_nr = e->l->f->mat_nr; BMLoop *l_iter = e->l->radial_next; do { if (l_iter->f->mat_nr != mat_nr) { return true; } } while ((l_iter = l_iter->radial_next) != e->l); } } if (delimit & BMO_DELIM_UV) { if (BM_edge_is_contiguous_loop_cd(e, delimit_data->cd_loop_type, delimit_data->cd_loop_offset) == 0) { return true; } } return false; } static void select_linked_delimit_begin(BMesh *bm, short selectmode, int delimit) { struct DelimitData delimit_data = {0}; BMIter iter; BMEdge *e; if (delimit & BMO_DELIM_UV) { delimit_data.cd_loop_type = CD_MLOOPUV; delimit_data.cd_loop_offset = CustomData_get_offset(&bm->ldata, delimit_data.cd_loop_type); if (delimit_data.cd_loop_offset == -1) { delimit &= ~BMO_DELIM_UV; } } /* grr, shouldn't need to alloc BMO flags here */ BM_mesh_elem_toolflags_ensure(bm); if (selectmode == SCE_SELECT_FACE) { BM_ITER_MESH (e, &iter, bm, BM_EDGES_OF_MESH) { const bool is_walk_ok = ( (select_linked_delimit_test(e, delimit, &delimit_data) == false)); BMO_elem_flag_set(bm, e, BMO_ELE_TAG, is_walk_ok); } } else { /* don't delimit selected edges in vert/edge mode */ BM_ITER_MESH (e, &iter, bm, BM_EDGES_OF_MESH) { const bool is_walk_ok = ( BM_elem_flag_test(e, BM_ELEM_SELECT) || (select_linked_delimit_test(e, delimit, &delimit_data) == false)); BMO_elem_flag_set(bm, e, BMO_ELE_TAG, is_walk_ok); } } } static void select_linked_delimit_end(BMEditMesh *em) { BMesh *bm = em->bm; BM_mesh_elem_toolflags_clear(bm); } static int edbm_select_linked_exec(bContext *C, wmOperator *op) { Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); BMesh *bm = em->bm; BMIter iter; BMWalker walker; const int delimit = RNA_enum_get(op->ptr, "delimit"); if (delimit) { select_linked_delimit_begin(em->bm, em->selectmode, delimit); } if (em->selectmode & SCE_SELECT_VERTEX) { BMVert *v; BM_ITER_MESH (v, &iter, em->bm, BM_VERTS_OF_MESH) { BM_elem_flag_set(v, BM_ELEM_TAG, BM_elem_flag_test(v, BM_ELEM_SELECT)); } BMW_init(&walker, em->bm, delimit ? BMW_LOOP_SHELL_WIRE : BMW_VERT_SHELL, BMW_MASK_NOP, delimit ? BMO_ELE_TAG : BMW_MASK_NOP, BMW_MASK_NOP, BMW_FLAG_TEST_HIDDEN, BMW_NIL_LAY); if (delimit) { BM_ITER_MESH (v, &iter, em->bm, BM_VERTS_OF_MESH) { if (BM_elem_flag_test(v, BM_ELEM_TAG)) { BMElem *ele_walk; BMW_ITER (ele_walk, &walker, v) { if (ele_walk->head.htype == BM_LOOP) { BMVert *v_step = ((BMLoop *)ele_walk)->v; BM_vert_select_set(em->bm, v_step, true); BM_elem_flag_disable(v_step, BM_ELEM_TAG); } else { BMEdge *e_step = (BMEdge *)ele_walk; BLI_assert(ele_walk->head.htype == BM_EDGE); BM_edge_select_set(em->bm, e_step, true); BM_elem_flag_disable(e_step->v1, BM_ELEM_TAG); BM_elem_flag_disable(e_step->v2, BM_ELEM_TAG); } } } } } else { BM_ITER_MESH (v, &iter, em->bm, BM_VERTS_OF_MESH) { if (BM_elem_flag_test(v, BM_ELEM_TAG)) { BMEdge *e_walk; BMW_ITER (e_walk, &walker, v) { BM_edge_select_set(em->bm, e_walk, true); BM_elem_flag_disable(e_walk, BM_ELEM_TAG); } } } } BMW_end(&walker); EDBM_selectmode_flush(em); } else if (em->selectmode & SCE_SELECT_EDGE) { BMEdge *e; BM_ITER_MESH (e, &iter, em->bm, BM_EDGES_OF_MESH) { BM_elem_flag_set(e, BM_ELEM_TAG, BM_elem_flag_test(e, BM_ELEM_SELECT)); } BMW_init(&walker, em->bm, delimit ? BMW_LOOP_SHELL_WIRE : BMW_VERT_SHELL, BMW_MASK_NOP, delimit ? BMO_ELE_TAG : BMW_MASK_NOP, BMW_MASK_NOP, BMW_FLAG_TEST_HIDDEN, BMW_NIL_LAY); if (delimit) { BM_ITER_MESH (e, &iter, em->bm, BM_EDGES_OF_MESH) { if (BM_elem_flag_test(e, BM_ELEM_TAG)) { BMElem *ele_walk; BMW_ITER (ele_walk, &walker, e) { if (ele_walk->head.htype == BM_LOOP) { BMLoop *l_step = (BMLoop *)ele_walk; BM_edge_select_set(em->bm, l_step->e, true); BM_edge_select_set(em->bm, l_step->prev->e, true); BM_elem_flag_disable(l_step->e, BM_ELEM_TAG); } else { BMEdge *e_step = (BMEdge *)ele_walk; BLI_assert(ele_walk->head.htype == BM_EDGE); BM_edge_select_set(em->bm, e_step, true); BM_elem_flag_disable(e_step, BM_ELEM_TAG); } } } } } else { BM_ITER_MESH (e, &iter, em->bm, BM_EDGES_OF_MESH) { if (BM_elem_flag_test(e, BM_ELEM_TAG)) { BMEdge *e_walk; BMW_ITER (e_walk, &walker, e) { BM_edge_select_set(em->bm, e_walk, true); BM_elem_flag_disable(e_walk, BM_ELEM_TAG); } } } } BMW_end(&walker); EDBM_selectmode_flush(em); } else { BMFace *f; BM_ITER_MESH (f, &iter, em->bm, BM_FACES_OF_MESH) { BM_elem_flag_set(f, BM_ELEM_TAG, BM_elem_flag_test(f, BM_ELEM_SELECT)); } BMW_init(&walker, bm, BMW_ISLAND, BMW_MASK_NOP, delimit ? BMO_ELE_TAG : BMW_MASK_NOP, BMW_MASK_NOP, BMW_FLAG_TEST_HIDDEN, BMW_NIL_LAY); BM_ITER_MESH (f, &iter, em->bm, BM_FACES_OF_MESH) { if (BM_elem_flag_test(f, BM_ELEM_TAG)) { BMFace *f_walk; BMW_ITER (f_walk, &walker, f) { BM_face_select_set(bm, f_walk, true); BM_elem_flag_disable(f_walk, BM_ELEM_TAG); } } } BMW_end(&walker); } if (delimit) { select_linked_delimit_end(em); } WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit); return OPERATOR_FINISHED; } void MESH_OT_select_linked(wmOperatorType *ot) { /* identifiers */ ot->name = "Select Linked All"; ot->idname = "MESH_OT_select_linked"; ot->description = "Select all vertices linked to the active mesh"; /* api callbacks */ ot->exec = edbm_select_linked_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; RNA_def_enum_flag(ot->srna, "delimit", mesh_delimit_mode_items, BMO_DELIM_SEAM, "Delimit", "Delimit selected region"); } static int edbm_select_linked_pick_exec(bContext *C, wmOperator *op); static void edbm_select_linked_pick_ex( BMEditMesh *em, BMVert *eve, BMEdge *eed, BMFace *efa, bool sel, int delimit) { BMesh *bm = em->bm; BMWalker walker; if (delimit) { select_linked_delimit_begin(bm, em->selectmode, delimit); } /* Note: logic closely matches 'edbm_select_linked_exec', keep in sync */ if ((em->selectmode & SCE_SELECT_VERTEX) && eve) { BMW_init(&walker, bm, delimit ? BMW_LOOP_SHELL_WIRE : BMW_VERT_SHELL, BMW_MASK_NOP, delimit ? BMO_ELE_TAG : BMW_MASK_NOP, BMW_MASK_NOP, BMW_FLAG_TEST_HIDDEN, BMW_NIL_LAY); if (delimit) { BMElem *ele_walk; BMW_ITER (ele_walk, &walker, eve) { if (ele_walk->head.htype == BM_LOOP) { BMVert *v_step = ((BMLoop *)ele_walk)->v; BM_vert_select_set(bm, v_step, sel); } else { BMEdge *e_step = (BMEdge *)ele_walk; BLI_assert(ele_walk->head.htype == BM_EDGE); BM_edge_select_set(bm, e_step, sel); } } } else { BMEdge *e_walk; BMW_ITER (e_walk, &walker, eve) { BM_edge_select_set(bm, e_walk, sel); } } BMW_end(&walker); EDBM_selectmode_flush(em); } else if ((em->selectmode & SCE_SELECT_EDGE) && eed) { BMW_init(&walker, bm, delimit ? BMW_LOOP_SHELL_WIRE : BMW_VERT_SHELL, BMW_MASK_NOP, delimit ? BMO_ELE_TAG : BMW_MASK_NOP, BMW_MASK_NOP, BMW_FLAG_TEST_HIDDEN, BMW_NIL_LAY); if (delimit) { BMElem *ele_walk; BMW_ITER (ele_walk, &walker, eed) { if (ele_walk->head.htype == BM_LOOP) { BMEdge *e_step = ((BMLoop *)ele_walk)->e; BM_edge_select_set(bm, e_step, sel); } else { BMEdge *e_step = (BMEdge *)ele_walk; BLI_assert(ele_walk->head.htype == BM_EDGE); BM_edge_select_set(bm, e_step, sel); } } } else { BMEdge *e_walk; BMW_ITER (e_walk, &walker, eed) { BM_edge_select_set(bm, e_walk, sel); } } BMW_end(&walker); EDBM_selectmode_flush(em); } else if ((em->selectmode & SCE_SELECT_FACE) && efa) { BMW_init(&walker, bm, BMW_ISLAND, BMW_MASK_NOP, delimit ? BMO_ELE_TAG : BMW_MASK_NOP, BMW_MASK_NOP, BMW_FLAG_TEST_HIDDEN, BMW_NIL_LAY); { BMFace *f_walk; BMW_ITER (f_walk, &walker, efa) { BM_face_select_set(bm, f_walk, sel); BM_elem_flag_disable(f_walk, BM_ELEM_TAG); } } BMW_end(&walker); } if (delimit) { select_linked_delimit_end(em); } } static int edbm_select_linked_pick_invoke(bContext *C, wmOperator *op, const wmEvent *event) { Object *obedit = CTX_data_edit_object(C); ViewContext vc; BMEditMesh *em; BMesh *bm; BMVert *eve; BMEdge *eed; BMFace *efa; const bool sel = !RNA_boolean_get(op->ptr, "deselect"); const int delimit = RNA_enum_get(op->ptr, "delimit"); int index; if (RNA_struct_property_is_set(op->ptr, "index")) { return edbm_select_linked_pick_exec(C, op); } /* unified_finednearest needs ogl */ view3d_operator_needs_opengl(C); /* setup view context for argument to callbacks */ em_setup_viewcontext(C, &vc); em = vc.em; bm = em->bm; if (bm->totedge == 0) { return OPERATOR_CANCELLED; } vc.mval[0] = event->mval[0]; vc.mval[1] = event->mval[1]; /* return warning! */ if (unified_findnearest(&vc, &eve, &eed, &efa) == 0) { WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit); return OPERATOR_CANCELLED; } edbm_select_linked_pick_ex(em, eve, eed, efa, sel, delimit); /* to support redo */ if ((em->selectmode & SCE_SELECT_VERTEX) && eve) { BM_mesh_elem_index_ensure(bm, BM_VERT); index = BM_elem_index_get(eve); } else if ((em->selectmode & SCE_SELECT_EDGE) && eed) { BM_mesh_elem_index_ensure(bm, BM_EDGE); index = BM_elem_index_get(eed) + bm->totvert; } else if ((em->selectmode & SCE_SELECT_FACE) && efa) { BM_mesh_elem_index_ensure(bm, BM_FACE); index = BM_elem_index_get(efa) + bm->totvert + bm->totedge; } else { index = -1; } RNA_int_set(op->ptr, "index", index); WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit); return OPERATOR_FINISHED; } static int edbm_select_linked_pick_exec(bContext *C, wmOperator *op) { Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); BMesh *bm = em->bm; int index; BMVert *eve = NULL; BMEdge *eed = NULL; BMFace *efa = NULL; const bool sel = !RNA_boolean_get(op->ptr, "deselect"); const int delimit = RNA_enum_get(op->ptr, "delimit"); index = RNA_int_get(op->ptr, "index"); if (index < 0 || index >= (bm->totvert + bm->totedge + bm->totface)) { return OPERATOR_CANCELLED; } if (index < bm->totvert) { eve = BM_vert_at_index_find_or_table(bm, index); } else if (index < (bm->totvert + bm->totedge)) { index -= bm->totvert; eed = BM_edge_at_index_find_or_table(bm, index); } else if (index < (bm->totvert + bm->totedge + bm->totface)) { index -= (bm->totvert + bm->totedge); efa = BM_face_at_index_find_or_table(bm, index); } edbm_select_linked_pick_ex(em, eve, eed, efa, sel, delimit); WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit); return OPERATOR_FINISHED; } void MESH_OT_select_linked_pick(wmOperatorType *ot) { PropertyRNA *prop; /* identifiers */ ot->name = "Select Linked"; ot->idname = "MESH_OT_select_linked_pick"; ot->description = "(De)select all vertices linked to the edge under the mouse cursor"; /* api callbacks */ ot->invoke = edbm_select_linked_pick_invoke; ot->exec = edbm_select_linked_pick_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; RNA_def_boolean(ot->srna, "deselect", 0, "Deselect", ""); RNA_def_enum_flag(ot->srna, "delimit", mesh_delimit_mode_items, BMO_DELIM_SEAM, "Delimit", "Delimit selected region"); /* use for redo */ prop = RNA_def_int(ot->srna, "index", -1, -1, INT_MAX, "", "", 0, INT_MAX); RNA_def_property_flag(prop, PROP_HIDDEN | PROP_SKIP_SAVE); } static int edbm_select_face_by_sides_exec(bContext *C, wmOperator *op) { Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); BMFace *efa; BMIter iter; const int numverts = RNA_int_get(op->ptr, "number"); const int type = RNA_enum_get(op->ptr, "type"); if (!RNA_boolean_get(op->ptr, "extend")) EDBM_flag_disable_all(em, BM_ELEM_SELECT); BM_ITER_MESH (efa, &iter, em->bm, BM_FACES_OF_MESH) { bool select; switch (type) { case 0: select = (efa->len < numverts); break; case 1: select = (efa->len == numverts); break; case 2: select = (efa->len > numverts); break; case 3: select = (efa->len != numverts); break; default: BLI_assert(0); select = false; break; } if (select) { BM_face_select_set(em->bm, efa, true); } } EDBM_selectmode_flush(em); WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit->data); return OPERATOR_FINISHED; } void MESH_OT_select_face_by_sides(wmOperatorType *ot) { static const EnumPropertyItem type_items[] = { {0, "LESS", 0, "Less Than", ""}, {1, "EQUAL", 0, "Equal To", ""}, {2, "GREATER", 0, "Greater Than", ""}, {3, "NOTEQUAL", 0, "Not Equal To", ""}, {0, NULL, 0, NULL, NULL} }; /* identifiers */ ot->name = "Select Faces by Sides"; ot->description = "Select vertices or faces by the number of polygon sides"; ot->idname = "MESH_OT_select_face_by_sides"; /* api callbacks */ ot->exec = edbm_select_face_by_sides_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; /* properties */ RNA_def_int(ot->srna, "number", 4, 3, INT_MAX, "Number of Vertices", "", 3, INT_MAX); RNA_def_enum(ot->srna, "type", type_items, 1, "Type", "Type of comparison to make"); RNA_def_boolean(ot->srna, "extend", true, "Extend", "Extend the selection"); } static int edbm_select_loose_exec(bContext *C, wmOperator *op) { Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); BMesh *bm = em->bm; BMIter iter; if (!RNA_boolean_get(op->ptr, "extend")) EDBM_flag_disable_all(em, BM_ELEM_SELECT); if (em->selectmode & SCE_SELECT_VERTEX) { BMVert *eve; BM_ITER_MESH (eve, &iter, bm, BM_VERTS_OF_MESH) { if (!eve->e) { BM_vert_select_set(bm, eve, true); } } } if (em->selectmode & SCE_SELECT_EDGE) { BMEdge *eed; BM_ITER_MESH (eed, &iter, bm, BM_EDGES_OF_MESH) { if (BM_edge_is_wire(eed)) { BM_edge_select_set(bm, eed, true); } } } if (em->selectmode & SCE_SELECT_FACE) { BMFace *efa; BM_ITER_MESH (efa, &iter, bm, BM_FACES_OF_MESH) { BMIter liter; BMLoop *l; bool is_loose = true; BM_ITER_ELEM (l, &liter, efa, BM_LOOPS_OF_FACE) { if (!BM_edge_is_boundary(l->e)) { is_loose = false; break; } } if (is_loose) { BM_face_select_set(bm, efa, true); } } } EDBM_selectmode_flush(em); WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit->data); return OPERATOR_FINISHED; } void MESH_OT_select_loose(wmOperatorType *ot) { /* identifiers */ ot->name = "Select Loose Geometry"; ot->description = "Select loose geometry based on the selection mode"; ot->idname = "MESH_OT_select_loose"; /* api callbacks */ ot->exec = edbm_select_loose_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; /* props */ RNA_def_boolean(ot->srna, "extend", false, "Extend", "Extend the selection"); } static int edbm_select_mirror_exec(bContext *C, wmOperator *op) { Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); bool extend = RNA_boolean_get(op->ptr, "extend"); if (em->bm->totvert && em->bm->totvertsel) { int totmirr, totfail; EDBM_select_mirrored(em, extend, &totmirr, &totfail); if (totmirr) { EDBM_selectmode_flush(em); WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit->data); } ED_mesh_report_mirror_ex(op, totmirr, totfail, em->bm->selectmode); } return OPERATOR_FINISHED; } void MESH_OT_select_mirror(wmOperatorType *ot) { /* identifiers */ ot->name = "Select Mirror"; ot->description = "Select mesh items at mirrored locations"; ot->idname = "MESH_OT_select_mirror"; /* api callbacks */ ot->exec = edbm_select_mirror_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; /* props */ RNA_def_boolean(ot->srna, "extend", 0, "Extend", "Extend the existing selection"); } /* ******************** **************** */ static int edbm_select_more_exec(bContext *C, wmOperator *op) { Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); const bool use_face_step = RNA_boolean_get(op->ptr, "use_face_step"); EDBM_select_more(em, use_face_step); WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit); return OPERATOR_FINISHED; } void MESH_OT_select_more(wmOperatorType *ot) { /* identifiers */ ot->name = "Select More"; ot->idname = "MESH_OT_select_more"; ot->description = "Select more vertices, edges or faces connected to initial selection"; /* api callbacks */ ot->exec = edbm_select_more_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; RNA_def_boolean(ot->srna, "use_face_step", true, "Face Step", "Connected faces (instead of edges)"); } static int edbm_select_less_exec(bContext *C, wmOperator *op) { Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); const bool use_face_step = RNA_boolean_get(op->ptr, "use_face_step"); EDBM_select_less(em, use_face_step); WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit); return OPERATOR_FINISHED; } void MESH_OT_select_less(wmOperatorType *ot) { /* identifiers */ ot->name = "Select Less"; ot->idname = "MESH_OT_select_less"; ot->description = "Deselect vertices, edges or faces at the boundary of each selection region"; /* api callbacks */ ot->exec = edbm_select_less_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; RNA_def_boolean(ot->srna, "use_face_step", true, "Face Step", "Connected faces (instead of edges)"); } /** * Check if we're connected to another selected efge. */ static bool bm_edge_is_select_isolated(BMEdge *e) { BMIter viter; BMVert *v; BM_ITER_ELEM (v, &viter, e, BM_VERTS_OF_EDGE) { BMIter eiter; BMEdge *e_other; BM_ITER_ELEM (e_other, &eiter, v, BM_EDGES_OF_VERT) { if ((e_other != e) && BM_elem_flag_test(e_other, BM_ELEM_SELECT)) { return false; } } } return true; } /* Walk all reachable elements of the same type as h_act in breadth-first * order, starting from h_act. Deselects elements if the depth when they * are reached is not a multiple of "nth". */ static void walker_deselect_nth(BMEditMesh *em, int nth, int skip, int offset, BMHeader *h_act) { BMElem *ele; BMesh *bm = em->bm; BMWalker walker; BMIter iter; int walktype = 0, itertype = 0, flushtype = 0; short mask_vert = 0, mask_edge = 0, mask_face = 0; /* No active element from which to start - nothing to do */ if (h_act == NULL) { return; } /* Determine which type of iter, walker, and select flush to use * based on type of the elements being deselected */ switch (h_act->htype) { case BM_VERT: itertype = BM_VERTS_OF_MESH; walktype = BMW_CONNECTED_VERTEX; flushtype = SCE_SELECT_VERTEX; mask_vert = BMO_ELE_TAG; break; case BM_EDGE: /* When an edge has no connected-selected edges, * use face-stepping (supports edge-rings) */ itertype = BM_EDGES_OF_MESH; walktype = bm_edge_is_select_isolated((BMEdge *)h_act) ? BMW_FACE_SHELL : BMW_VERT_SHELL; flushtype = SCE_SELECT_EDGE; mask_edge = BMO_ELE_TAG; break; case BM_FACE: itertype = BM_FACES_OF_MESH; walktype = BMW_ISLAND; flushtype = SCE_SELECT_FACE; mask_face = BMO_ELE_TAG; break; } /* grr, shouldn't need to alloc BMO flags here */ BM_mesh_elem_toolflags_ensure(bm); /* Walker restrictions uses BMO flags, not header flags, * so transfer BM_ELEM_SELECT from HFlags onto a BMO flag layer. */ BMO_push(bm, NULL); BM_ITER_MESH (ele, &iter, bm, itertype) { if (BM_elem_flag_test(ele, BM_ELEM_SELECT)) { BMO_elem_flag_enable(bm, (BMElemF *)ele, BMO_ELE_TAG); } } /* Walk over selected elements starting at active */ BMW_init(&walker, bm, walktype, mask_vert, mask_edge, mask_face, BMW_FLAG_NOP, /* don't use BMW_FLAG_TEST_HIDDEN here since we want to desel all */ BMW_NIL_LAY); /* use tag to avoid touching the same verts twice */ BM_ITER_MESH (ele, &iter, bm, itertype) { BM_elem_flag_disable(ele, BM_ELEM_TAG); } BLI_assert(walker.order == BMW_BREADTH_FIRST); for (ele = BMW_begin(&walker, h_act); ele != NULL; ele = BMW_step(&walker)) { if (!BM_elem_flag_test(ele, BM_ELEM_TAG)) { /* Deselect elements that aren't at "nth" depth from active */ const int depth = BMW_current_depth(&walker) - 1; if ((offset + depth) % (skip + nth) >= skip) { BM_elem_select_set(bm, ele, false); } BM_elem_flag_enable(ele, BM_ELEM_TAG); } } BMW_end(&walker); BMO_pop(bm); /* Flush selection up */ EDBM_selectmode_flush_ex(em, flushtype); } static void deselect_nth_active(BMEditMesh *em, BMVert **r_eve, BMEdge **r_eed, BMFace **r_efa) { BMIter iter; BMElem *ele; *r_eve = NULL; *r_eed = NULL; *r_efa = NULL; EDBM_selectmode_flush(em); ele = BM_mesh_active_elem_get(em->bm); if (ele && BM_elem_flag_test(ele, BM_ELEM_SELECT)) { switch (ele->head.htype) { case BM_VERT: *r_eve = (BMVert *)ele; return; case BM_EDGE: *r_eed = (BMEdge *)ele; return; case BM_FACE: *r_efa = (BMFace *)ele; return; } } if (em->selectmode & SCE_SELECT_VERTEX) { BMVert *v; BM_ITER_MESH (v, &iter, em->bm, BM_VERTS_OF_MESH) { if (BM_elem_flag_test(v, BM_ELEM_SELECT)) { *r_eve = v; return; } } } else if (em->selectmode & SCE_SELECT_EDGE) { BMEdge *e; BM_ITER_MESH (e, &iter, em->bm, BM_EDGES_OF_MESH) { if (BM_elem_flag_test(e, BM_ELEM_SELECT)) { *r_eed = e; return; } } } else if (em->selectmode & SCE_SELECT_FACE) { BMFace *f = BM_mesh_active_face_get(em->bm, true, false); if (f && BM_elem_flag_test(f, BM_ELEM_SELECT)) { *r_efa = f; return; } } } static bool edbm_deselect_nth(BMEditMesh *em, int nth, int skip, int offset) { BMVert *v; BMEdge *e; BMFace *f; deselect_nth_active(em, &v, &e, &f); if (v) { walker_deselect_nth(em, nth, skip, offset, &v->head); return true; } else if (e) { walker_deselect_nth(em, nth, skip, offset, &e->head); return true; } else if (f) { walker_deselect_nth(em, nth, skip, offset, &f->head); return true; } return false; } static int edbm_select_nth_exec(bContext *C, wmOperator *op) { Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); const int nth = RNA_int_get(op->ptr, "nth") - 1; const int skip = RNA_int_get(op->ptr, "skip"); int offset = RNA_int_get(op->ptr, "offset"); /* so input of offset zero ends up being (nth - 1) */ offset = mod_i(offset, nth + skip); if (edbm_deselect_nth(em, nth, skip, offset) == false) { BKE_report(op->reports, RPT_ERROR, "Mesh has no active vert/edge/face"); return OPERATOR_CANCELLED; } EDBM_update_generic(em, false, false); return OPERATOR_FINISHED; } void MESH_OT_select_nth(wmOperatorType *ot) { /* identifiers */ ot->name = "Checker Deselect"; ot->idname = "MESH_OT_select_nth"; ot->description = "Deselect every Nth element starting from the active vertex, edge or face"; /* api callbacks */ ot->exec = edbm_select_nth_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; RNA_def_int(ot->srna, "nth", 2, 2, INT_MAX, "Nth Selection", "", 2, 100); RNA_def_int(ot->srna, "skip", 1, 1, INT_MAX, "Skip", "", 1, 100); RNA_def_int(ot->srna, "offset", 0, INT_MIN, INT_MAX, "Offset", "", -100, 100); } void em_setup_viewcontext(bContext *C, ViewContext *vc) { view3d_set_viewcontext(C, vc); if (vc->obedit) { vc->em = BKE_editmesh_from_object(vc->obedit); } } static int edbm_select_sharp_edges_exec(bContext *C, wmOperator *op) { /* Find edges that have exactly two neighboring faces, * check the angle between those faces, and if angle is * small enough, select the edge */ Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); BMIter iter; BMEdge *e; BMLoop *l1, *l2; const float sharp = RNA_float_get(op->ptr, "sharpness"); BM_ITER_MESH (e, &iter, em->bm, BM_EDGES_OF_MESH) { if (BM_elem_flag_test(e, BM_ELEM_HIDDEN) == false && BM_edge_loop_pair(e, &l1, &l2)) { /* edge has exactly two neighboring faces, check angle */ const float angle = angle_normalized_v3v3(l1->f->no, l2->f->no); if (fabsf(angle) > sharp) { BM_edge_select_set(em->bm, e, true); } } } WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit->data); return OPERATOR_FINISHED; } void MESH_OT_edges_select_sharp(wmOperatorType *ot) { PropertyRNA *prop; /* identifiers */ ot->name = "Select Sharp Edges"; ot->description = "Select all sharp-enough edges"; ot->idname = "MESH_OT_edges_select_sharp"; /* api callbacks */ ot->exec = edbm_select_sharp_edges_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; /* props */ prop = RNA_def_float_rotation(ot->srna, "sharpness", 0, NULL, DEG2RADF(0.01f), DEG2RADF(180.0f), "Sharpness", "", DEG2RADF(1.0f), DEG2RADF(180.0f)); RNA_def_property_float_default(prop, DEG2RADF(30.0f)); } static int edbm_select_linked_flat_faces_exec(bContext *C, wmOperator *op) { Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); BMesh *bm = em->bm; BLI_LINKSTACK_DECLARE(stack, BMFace *); BMIter iter, liter, liter2; BMFace *f; BMLoop *l, *l2; const float angle_limit = RNA_float_get(op->ptr, "sharpness"); BM_mesh_elem_hflag_disable_all(bm, BM_FACE, BM_ELEM_TAG, false); BLI_LINKSTACK_INIT(stack); BM_ITER_MESH (f, &iter, bm, BM_FACES_OF_MESH) { if ((BM_elem_flag_test(f, BM_ELEM_HIDDEN) != 0) || (BM_elem_flag_test(f, BM_ELEM_TAG) != 0) || (BM_elem_flag_test(f, BM_ELEM_SELECT) == 0)) { continue; } BLI_assert(BLI_LINKSTACK_SIZE(stack) == 0); do { BM_face_select_set(bm, f, true); BM_elem_flag_enable(f, BM_ELEM_TAG); BM_ITER_ELEM (l, &liter, f, BM_LOOPS_OF_FACE) { BM_ITER_ELEM (l2, &liter2, l, BM_LOOPS_OF_LOOP) { float angle; if (BM_elem_flag_test(l2->f, BM_ELEM_TAG) || BM_elem_flag_test(l2->f, BM_ELEM_HIDDEN)) { continue; } angle = angle_normalized_v3v3(f->no, l2->f->no); if (angle < angle_limit) { BLI_LINKSTACK_PUSH(stack, l2->f); } } } } while ((f = BLI_LINKSTACK_POP(stack))); } BLI_LINKSTACK_FREE(stack); WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit->data); return OPERATOR_FINISHED; } void MESH_OT_faces_select_linked_flat(wmOperatorType *ot) { PropertyRNA *prop; /* identifiers */ ot->name = "Select Linked Flat Faces"; ot->description = "Select linked faces by angle"; ot->idname = "MESH_OT_faces_select_linked_flat"; /* api callbacks */ ot->exec = edbm_select_linked_flat_faces_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; /* props */ prop = RNA_def_float_rotation(ot->srna, "sharpness", 0, NULL, DEG2RADF(0.01f), DEG2RADF(180.0f), "Sharpness", "", DEG2RADF(1.0f), DEG2RADF(180.0f)); RNA_def_property_float_default(prop, DEG2RADF(1.0f)); } static int edbm_select_non_manifold_exec(bContext *C, wmOperator *op) { Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); BMVert *v; BMEdge *e; BMIter iter; const bool use_wire = RNA_boolean_get(op->ptr, "use_wire"); const bool use_boundary = RNA_boolean_get(op->ptr, "use_boundary"); const bool use_multi_face = RNA_boolean_get(op->ptr, "use_multi_face"); const bool use_non_contiguous = RNA_boolean_get(op->ptr, "use_non_contiguous"); const bool use_verts = RNA_boolean_get(op->ptr, "use_verts"); if (!RNA_boolean_get(op->ptr, "extend")) EDBM_flag_disable_all(em, BM_ELEM_SELECT); /* Selects isolated verts, and edges that do not have 2 neighboring * faces */ if (em->selectmode == SCE_SELECT_FACE) { BKE_report(op->reports, RPT_ERROR, "Does not work in face selection mode"); return OPERATOR_CANCELLED; } if (use_verts) { BM_ITER_MESH (v, &iter, em->bm, BM_VERTS_OF_MESH) { if (!BM_elem_flag_test(v, BM_ELEM_HIDDEN)) { if (!BM_vert_is_manifold(v)) { BM_vert_select_set(em->bm, v, true); } } } } if (use_wire || use_boundary || use_multi_face || use_non_contiguous) { BM_ITER_MESH (e, &iter, em->bm, BM_EDGES_OF_MESH) { if (!BM_elem_flag_test(e, BM_ELEM_HIDDEN)) { if ((use_wire && BM_edge_is_wire(e)) || (use_boundary && BM_edge_is_boundary(e)) || (use_non_contiguous && (BM_edge_is_manifold(e) && !BM_edge_is_contiguous(e))) || (use_multi_face && (BM_edge_face_count_is_over(e, 2)))) { /* check we never select perfect edge (in test above) */ BLI_assert(!(BM_edge_is_manifold(e) && BM_edge_is_contiguous(e))); BM_edge_select_set(em->bm, e, true); } } } } WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit->data); EDBM_selectmode_flush(em); return OPERATOR_FINISHED; } void MESH_OT_select_non_manifold(wmOperatorType *ot) { /* identifiers */ ot->name = "Select Non Manifold"; ot->description = "Select all non-manifold vertices or edges"; ot->idname = "MESH_OT_select_non_manifold"; /* api callbacks */ ot->exec = edbm_select_non_manifold_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; /* props */ RNA_def_boolean(ot->srna, "extend", true, "Extend", "Extend the selection"); /* edges */ RNA_def_boolean(ot->srna, "use_wire", true, "Wire", "Wire edges"); RNA_def_boolean(ot->srna, "use_boundary", true, "Boundaries", "Boundary edges"); RNA_def_boolean(ot->srna, "use_multi_face", true, "Multiple Faces", "Edges shared by 3+ faces"); RNA_def_boolean(ot->srna, "use_non_contiguous", true, "Non Contiguous", "Edges between faces pointing in alternate directions"); /* verts */ RNA_def_boolean(ot->srna, "use_verts", true, "Vertices", "Vertices connecting multiple face regions"); } static int edbm_select_random_exec(bContext *C, wmOperator *op) { Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); const bool select = (RNA_enum_get(op->ptr, "action") == SEL_SELECT); const float randfac = RNA_float_get(op->ptr, "percent") / 100.0f; BMIter iter; if (em->selectmode & SCE_SELECT_VERTEX) { BMVert *eve; BM_ITER_MESH (eve, &iter, em->bm, BM_VERTS_OF_MESH) { if (!BM_elem_flag_test(eve, BM_ELEM_HIDDEN) && BLI_frand() < randfac) { BM_vert_select_set(em->bm, eve, select); } } } else if (em->selectmode & SCE_SELECT_EDGE) { BMEdge *eed; BM_ITER_MESH (eed, &iter, em->bm, BM_EDGES_OF_MESH) { if (!BM_elem_flag_test(eed, BM_ELEM_HIDDEN) && BLI_frand() < randfac) { BM_edge_select_set(em->bm, eed, select); } } } else { BMFace *efa; BM_ITER_MESH (efa, &iter, em->bm, BM_FACES_OF_MESH) { if (!BM_elem_flag_test(efa, BM_ELEM_HIDDEN) && BLI_frand() < randfac) { BM_face_select_set(em->bm, efa, select); } } } if (select) { /* was EDBM_select_flush, but it over select in edge/face mode */ EDBM_selectmode_flush(em); } else { EDBM_deselect_flush(em); } WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit->data); return OPERATOR_FINISHED; } void MESH_OT_select_random(wmOperatorType *ot) { /* identifiers */ ot->name = "Select Random"; ot->description = "Randomly select vertices"; ot->idname = "MESH_OT_select_random"; /* api callbacks */ ot->exec = edbm_select_random_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; /* props */ RNA_def_float_percentage(ot->srna, "percent", 50.0f, 0.0f, 100.0f, "Percent", "Percentage of elements to select randomly", 0.0f, 100.0f); WM_operator_properties_select_action_simple(ot, SEL_SELECT); } static int edbm_select_ungrouped_poll(bContext *C) { if (ED_operator_editmesh(C)) { Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); const int cd_dvert_offset = CustomData_get_offset(&em->bm->vdata, CD_MDEFORMVERT); if ((em->selectmode & SCE_SELECT_VERTEX) == 0) { CTX_wm_operator_poll_msg_set(C, "Must be in vertex selection mode"); } else if (BLI_listbase_is_empty(&obedit->defbase) || cd_dvert_offset == -1) { CTX_wm_operator_poll_msg_set(C, "No weights/vertex groups on object"); } else { return true; } } return false; } static int edbm_select_ungrouped_exec(bContext *C, wmOperator *op) { Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); const int cd_dvert_offset = CustomData_get_offset(&em->bm->vdata, CD_MDEFORMVERT); BMVert *eve; BMIter iter; if (!RNA_boolean_get(op->ptr, "extend")) { EDBM_flag_disable_all(em, BM_ELEM_SELECT); } BM_ITER_MESH (eve, &iter, em->bm, BM_VERTS_OF_MESH) { if (!BM_elem_flag_test(eve, BM_ELEM_HIDDEN)) { MDeformVert *dv = BM_ELEM_CD_GET_VOID_P(eve, cd_dvert_offset); /* no dv or dv set with no weight */ if (ELEM(NULL, dv, dv->dw)) { BM_vert_select_set(em->bm, eve, true); } } } EDBM_selectmode_flush(em); WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit->data); return OPERATOR_FINISHED; } void MESH_OT_select_ungrouped(wmOperatorType *ot) { /* identifiers */ ot->name = "Select Ungrouped"; ot->idname = "MESH_OT_select_ungrouped"; ot->description = "Select vertices without a group"; /* api callbacks */ ot->exec = edbm_select_ungrouped_exec; ot->poll = edbm_select_ungrouped_poll; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; RNA_def_boolean(ot->srna, "extend", false, "Extend", "Extend the selection"); } /* BMESH_TODO - some way to select on an arbitrary axis */ static int edbm_select_axis_exec(bContext *C, wmOperator *op) { Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); BMesh *bm = em->bm; BMVert *v_act = BM_mesh_active_vert_get(bm); const int axis = RNA_enum_get(op->ptr, "axis"); const int mode = RNA_enum_get(op->ptr, "mode"); /* -1 == aligned, 0 == neg, 1 == pos */ if (v_act == NULL) { BKE_report(op->reports, RPT_WARNING, "This operator requires an active vertex (last selected)"); return OPERATOR_CANCELLED; } else { BMVert *v; BMIter iter; const float limit = RNA_float_get(op->ptr, "threshold"); float value = v_act->co[axis]; if (mode == 0) value -= limit; else if (mode == 1) value += limit; BM_ITER_MESH (v, &iter, bm, BM_VERTS_OF_MESH) { if (!BM_elem_flag_test(v, BM_ELEM_HIDDEN)) { switch (mode) { case -1: /* aligned */ if (fabsf(v->co[axis] - value) < limit) BM_vert_select_set(bm, v, true); break; case 0: /* neg */ if (v->co[axis] > value) BM_vert_select_set(bm, v, true); break; case 1: /* pos */ if (v->co[axis] < value) BM_vert_select_set(bm, v, true); break; } } } } EDBM_selectmode_flush(em); WM_event_add_notifier(C, NC_GEOM | ND_DATA, obedit->data); return OPERATOR_FINISHED; } void MESH_OT_select_axis(wmOperatorType *ot) { static EnumPropertyItem axis_mode_items[] = { {0, "POSITIVE", 0, "Positive Axis", ""}, {1, "NEGATIVE", 0, "Negative Axis", ""}, {-1, "ALIGNED", 0, "Aligned Axis", ""}, {0, NULL, 0, NULL, NULL} }; static EnumPropertyItem axis_items_xyz[] = { {0, "X_AXIS", 0, "X Axis", ""}, {1, "Y_AXIS", 0, "Y Axis", ""}, {2, "Z_AXIS", 0, "Z Axis", ""}, {0, NULL, 0, NULL, NULL} }; /* identifiers */ ot->name = "Select Axis"; ot->description = "Select all data in the mesh on a single axis"; ot->idname = "MESH_OT_select_axis"; /* api callbacks */ ot->exec = edbm_select_axis_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; /* properties */ RNA_def_enum(ot->srna, "mode", axis_mode_items, 0, "Axis Mode", "Axis side to use when selecting"); RNA_def_enum(ot->srna, "axis", axis_items_xyz, 0, "Axis", "Select the axis to compare each vertex on"); RNA_def_float(ot->srna, "threshold", 0.0001f, 0.000001f, 50.0f, "Threshold", "", 0.00001f, 10.0f); } static int edbm_select_next_loop_exec(bContext *C, wmOperator *UNUSED(op)) { Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); BMFace *f; BMVert *v; BMIter iter; BM_ITER_MESH (v, &iter, em->bm, BM_VERTS_OF_MESH) { BM_elem_flag_disable(v, BM_ELEM_TAG); } BM_ITER_MESH (f, &iter, em->bm, BM_FACES_OF_MESH) { BMLoop *l; BMIter liter; BM_ITER_ELEM (l, &liter, f, BM_LOOPS_OF_FACE) { if (BM_elem_flag_test(l->v, BM_ELEM_SELECT)) { BM_elem_flag_enable(l->next->v, BM_ELEM_TAG); BM_vert_select_set(em->bm, l->v, false); } } } BM_ITER_MESH (v, &iter, em->bm, BM_VERTS_OF_MESH) { if (BM_elem_flag_test(v, BM_ELEM_TAG)) { BM_vert_select_set(em->bm, v, true); } } WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit); return OPERATOR_FINISHED; } void MESH_OT_select_next_loop(wmOperatorType *ot) { /* identifiers */ ot->name = "Select Next Loop"; ot->idname = "MESH_OT_select_next_loop"; ot->description = "Select next edge loop adjacent to a selected loop"; /* api callbacks */ ot->exec = edbm_select_next_loop_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; } static int edbm_region_to_loop_exec(bContext *C, wmOperator *UNUSED(op)) { Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); BMFace *f; BMEdge *e; BMIter iter; BM_mesh_elem_hflag_disable_all(em->bm, BM_EDGE, BM_ELEM_TAG, false); BM_ITER_MESH (f, &iter, em->bm, BM_FACES_OF_MESH) { BMLoop *l1, *l2; BMIter liter1, liter2; BM_ITER_ELEM (l1, &liter1, f, BM_LOOPS_OF_FACE) { int tot = 0, totsel = 0; BM_ITER_ELEM (l2, &liter2, l1->e, BM_LOOPS_OF_EDGE) { tot++; totsel += BM_elem_flag_test(l2->f, BM_ELEM_SELECT) != 0; } if ((tot != totsel && totsel > 0) || (totsel == 1 && tot == 1)) BM_elem_flag_enable(l1->e, BM_ELEM_TAG); } } EDBM_flag_disable_all(em, BM_ELEM_SELECT); BM_ITER_MESH (e, &iter, em->bm, BM_EDGES_OF_MESH) { if (BM_elem_flag_test(e, BM_ELEM_TAG)) { BM_edge_select_set(em->bm, e, true); } } /* If in face-only select mode, switch to edge select mode so that * an edge-only selection is not inconsistent state */ if (em->selectmode == SCE_SELECT_FACE) { em->selectmode = SCE_SELECT_EDGE; EDBM_selectmode_set(em); EDBM_selectmode_to_scene(C); } WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit->data); return OPERATOR_FINISHED; } void MESH_OT_region_to_loop(wmOperatorType *ot) { /* identifiers */ ot->name = "Select Boundary Loop"; ot->idname = "MESH_OT_region_to_loop"; ot->description = "Select boundary edges around the selected faces"; /* api callbacks */ ot->exec = edbm_region_to_loop_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; } static int loop_find_region(BMLoop *l, int flag, GSet *visit_face_set, BMFace ***region_out) { BMFace **region = NULL; BMFace **stack = NULL; BLI_array_declare(region); BLI_array_declare(stack); BMFace *f; BLI_array_append(stack, l->f); BLI_gset_insert(visit_face_set, l->f); while (BLI_array_count(stack) > 0) { BMIter liter1, liter2; BMLoop *l1, *l2; f = BLI_array_pop(stack); BLI_array_append(region, f); BM_ITER_ELEM (l1, &liter1, f, BM_LOOPS_OF_FACE) { if (BM_elem_flag_test(l1->e, flag)) continue; BM_ITER_ELEM (l2, &liter2, l1->e, BM_LOOPS_OF_EDGE) { /* avoids finding same region twice * (otherwise) the logic works fine without */ if (BM_elem_flag_test(l2->f, BM_ELEM_TAG)) { continue; } if (BLI_gset_add(visit_face_set, l2->f)) { BLI_array_append(stack, l2->f); } } } } BLI_array_free(stack); *region_out = region; return BLI_array_count(region); } static int verg_radial(const void *va, const void *vb) { const BMEdge *e_a = *((const BMEdge **)va); const BMEdge *e_b = *((const BMEdge **)vb); int a, b; a = BM_edge_face_count(e_a); b = BM_edge_face_count(e_b); if (a > b) return -1; if (a < b) return 1; return 0; } /** * This function leaves faces tagged which are apart of the new region. * * \note faces already tagged are ignored, to avoid finding the same regions twice: * important when we have regions with equal face counts, see: T40309 */ static int loop_find_regions(BMEditMesh *em, const bool selbigger) { GSet *visit_face_set; BMIter iter; const int edges_len = em->bm->totedgesel; BMEdge *e, **edges; int count = 0, i; visit_face_set = BLI_gset_ptr_new_ex(__func__, edges_len); edges = MEM_mallocN(sizeof(*edges) * edges_len, __func__); i = 0; BM_ITER_MESH (e, &iter, em->bm, BM_EDGES_OF_MESH) { if (BM_elem_flag_test(e, BM_ELEM_SELECT)) { edges[i++] = e; BM_elem_flag_enable(e, BM_ELEM_TAG); } else { BM_elem_flag_disable(e, BM_ELEM_TAG); } } /* sort edges by radial cycle length */ qsort(edges, edges_len, sizeof(*edges), verg_radial); for (i = 0; i < edges_len; i++) { BMIter liter; BMLoop *l; BMFace **region = NULL, **region_out; int c, tot = 0; e = edges[i]; if (!BM_elem_flag_test(e, BM_ELEM_TAG)) continue; BM_ITER_ELEM (l, &liter, e, BM_LOOPS_OF_EDGE) { if (BLI_gset_haskey(visit_face_set, l->f)) continue; c = loop_find_region(l, BM_ELEM_SELECT, visit_face_set, ®ion_out); if (!region || (selbigger ? c >= tot : c < tot)) { /* this region is the best seen so far */ tot = c; if (region) { /* free the previous best */ MEM_freeN(region); } /* track the current region as the new best */ region = region_out; } else { /* this region is not as good as best so far, just free it */ MEM_freeN(region_out); } } if (region) { int j; for (j = 0; j < tot; j++) { BM_elem_flag_enable(region[j], BM_ELEM_TAG); BM_ITER_ELEM (l, &liter, region[j], BM_LOOPS_OF_FACE) { BM_elem_flag_disable(l->e, BM_ELEM_TAG); } } count += tot; MEM_freeN(region); } } MEM_freeN(edges); BLI_gset_free(visit_face_set, NULL); return count; } static int edbm_loop_to_region_exec(bContext *C, wmOperator *op) { Object *obedit = CTX_data_edit_object(C); BMEditMesh *em = BKE_editmesh_from_object(obedit); BMIter iter; BMFace *f; const bool select_bigger = RNA_boolean_get(op->ptr, "select_bigger"); int a, b; /* find the set of regions with smallest number of total faces */ BM_mesh_elem_hflag_disable_all(em->bm, BM_FACE, BM_ELEM_TAG, false); a = loop_find_regions(em, select_bigger); b = loop_find_regions(em, !select_bigger); BM_mesh_elem_hflag_disable_all(em->bm, BM_FACE, BM_ELEM_TAG, false); loop_find_regions(em, ((a <= b) != select_bigger) ? select_bigger : !select_bigger); EDBM_flag_disable_all(em, BM_ELEM_SELECT); BM_ITER_MESH (f, &iter, em->bm, BM_FACES_OF_MESH) { if (BM_elem_flag_test(f, BM_ELEM_TAG) && !BM_elem_flag_test(f, BM_ELEM_HIDDEN)) { BM_face_select_set(em->bm, f, true); } } EDBM_selectmode_flush(em); WM_event_add_notifier(C, NC_GEOM | ND_SELECT, obedit->data); return OPERATOR_FINISHED; } void MESH_OT_loop_to_region(wmOperatorType *ot) { /* identifiers */ ot->name = "Select Loop Inner-Region"; ot->idname = "MESH_OT_loop_to_region"; ot->description = "Select region of faces inside of a selected loop of edges"; /* api callbacks */ ot->exec = edbm_loop_to_region_exec; ot->poll = ED_operator_editmesh; /* flags */ ot->flag = OPTYPE_REGISTER | OPTYPE_UNDO; RNA_def_boolean(ot->srna, "select_bigger", 0, "Select Bigger", "Select bigger regions instead of smaller ones"); } /************************ Select Path Operator *************************/