blender-legacy/blender-2.79b/source/blender/bmesh/operators/bmo_extrude.c

/*
 * ***** 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.
 *
 * Contributor(s): Joseph Eagar.
 *
 * ***** END GPL LICENSE BLOCK *****
 */

/** \file blender/bmesh/operators/bmo_extrude.c
 *  \ingroup bmesh
 *
 * Extrude faces and solidify.
 */

#include "MEM_guardedalloc.h"

#include "DNA_meshdata_types.h"

#include "BLI_math.h"
#include "BLI_buffer.h"

#include "BKE_customdata.h"

#include "bmesh.h"

#include "intern/bmesh_operators_private.h" /* own include */

#define USE_EDGE_REGION_FLAGS

enum {
	EXT_INPUT   = 1,
	EXT_KEEP    = 2,
	EXT_DEL     = 4
};

#define VERT_MARK 1
#define EDGE_MARK 1
#define FACE_MARK 1
#define VERT_NONMAN 2
#define EDGE_NONMAN 2

void bmo_extrude_discrete_faces_exec(BMesh *bm, BMOperator *op)
{
	const bool use_select_history = BMO_slot_bool_get(op->slots_in, "use_select_history");
	GHash *select_history_map = NULL;

	BMOIter siter;
	BMFace *f_org;

	if (use_select_history) {
		select_history_map = BM_select_history_map_create(bm);
	}

	BMO_ITER (f_org, &siter, op->slots_in, "faces", BM_FACE) {
		BMFace *f_new;
		BMLoop *l_org, *l_org_first;
		BMLoop *l_new;

		BMO_face_flag_enable(bm, f_org, EXT_DEL);

		f_new = BM_face_copy(bm, bm, f_org, true, true);
		BMO_face_flag_enable(bm, f_new, EXT_KEEP);

		if (select_history_map) {
			BMEditSelection *ese;
			ese = BLI_ghash_lookup(select_history_map, f_org);
			if (ese) {
				ese->ele = (BMElem *)f_new;
			}
		}

		l_org = l_org_first = BM_FACE_FIRST_LOOP(f_org);
		l_new = BM_FACE_FIRST_LOOP(f_new);

		do {
			BMFace *f_side;
			BMLoop *l_side_iter;

			BM_elem_attrs_copy(bm, bm, l_org, l_new);

			f_side = BM_face_create_quad_tri(bm,
			                                 l_org->next->v, l_new->next->v, l_new->v, l_org->v,
			                                 f_org, BM_CREATE_NOP);

			l_side_iter = BM_FACE_FIRST_LOOP(f_side);

			BM_elem_attrs_copy(bm, bm, l_org->next, l_side_iter);  l_side_iter = l_side_iter->next;
			BM_elem_attrs_copy(bm, bm, l_org->next, l_side_iter);  l_side_iter = l_side_iter->next;
			BM_elem_attrs_copy(bm, bm, l_org, l_side_iter);        l_side_iter = l_side_iter->next;
			BM_elem_attrs_copy(bm, bm, l_org, l_side_iter);

			if (select_history_map) {
				BMEditSelection *ese;

				ese = BLI_ghash_lookup(select_history_map, l_org->v);
				if (ese) {
					ese->ele = (BMElem *)l_new->v;
				}
				ese = BLI_ghash_lookup(select_history_map, l_org->e);
				if (ese) {
					ese->ele = (BMElem *)l_new->e;
				}
			}

		} while (((void)
		          (l_new = l_new->next),
		          (l_org = l_org->next)) != l_org_first);
	}

	if (select_history_map) {
		BLI_ghash_free(select_history_map, NULL, NULL);
	}

	BMO_op_callf(bm, op->flag,
	             "delete geom=%ff context=%i",
	             EXT_DEL, DEL_ONLYFACES);
	BMO_slot_buffer_from_enabled_flag(bm, op, op->slots_out, "faces.out", BM_FACE, EXT_KEEP);
}

/**
 * \brief Copy the loop pair from an adjacent face to both sides of this quad.
 *
 * The face is assumed to be a quad, created by extruding.
 * This function won't crash if its not but won't work right either.
 * \a e_b is the new edge.
 *
 * \note The edge this face comes from needs to be from the first and second verts to the face.
 * The caller must ensure this else we will copy from the wrong source.
 */
static void bm_extrude_copy_face_loop_attributes(BMesh *bm, BMFace *f)
{
	/* edge we are extruded from */
	BMLoop *l_first_0 = BM_FACE_FIRST_LOOP(f);
	BMLoop *l_first_1 = l_first_0->next;
	BMLoop *l_first_2 = l_first_1->next;
	BMLoop *l_first_3 = l_first_2->next;

	BMLoop *l_other_0;
	BMLoop *l_other_1;

	if (UNLIKELY(l_first_0 == l_first_0->radial_next)) {
		return;
	}

	l_other_0 = BM_edge_other_loop(l_first_0->e, l_first_0);
	l_other_1 = BM_edge_other_loop(l_first_0->e, l_first_1);

	/* copy data */
	BM_elem_attrs_copy(bm, bm, l_other_0->f, f);
	BM_elem_flag_disable(f, BM_ELEM_HIDDEN);  /* possibly we copy from a hidden face */

	BM_elem_attrs_copy(bm, bm, l_other_0, l_first_0);
	BM_elem_attrs_copy(bm, bm, l_other_0, l_first_3);

	BM_elem_attrs_copy(bm, bm, l_other_1, l_first_1);
	BM_elem_attrs_copy(bm, bm, l_other_1, l_first_2);
}

/* Disable the skin root flag on the input vert, assumes that the vert
 * data includes an CD_MVERT_SKIN layer */
static void bm_extrude_disable_skin_root(BMesh *bm, BMVert *v)
{
	MVertSkin *vs;
	
	vs = CustomData_bmesh_get(&bm->vdata, v->head.data, CD_MVERT_SKIN);
	vs->flag &= ~MVERT_SKIN_ROOT;
}

void bmo_extrude_edge_only_exec(BMesh *bm, BMOperator *op)
{
	BMOIter siter;
	BMOperator dupeop;
	BMFace *f;
	BMEdge *e, *e_new;
	
	BMO_ITER (e, &siter, op->slots_in, "edges", BM_EDGE) {
		BMO_edge_flag_enable(bm, e, EXT_INPUT);
		BMO_vert_flag_enable(bm, e->v1, EXT_INPUT);
		BMO_vert_flag_enable(bm, e->v2, EXT_INPUT);
	}

	BMO_op_initf(
	        bm, &dupeop, op->flag,
	        "duplicate geom=%fve use_select_history=%b",
	        EXT_INPUT, BMO_slot_bool_get(op->slots_in, "use_select_history"));

	BMO_op_exec(bm, &dupeop);

	/* disable root flag on all new skin nodes */
	if (CustomData_has_layer(&bm->vdata, CD_MVERT_SKIN)) {
		BMVert *v;
		BMO_ITER (v, &siter, dupeop.slots_out, "geom.out", BM_VERT) {
			bm_extrude_disable_skin_root(bm, v);
		}
	}

	for (e = BMO_iter_new(&siter, dupeop.slots_out, "boundary_map.out", 0); e; e = BMO_iter_step(&siter)) {
		BMVert *f_verts[4];
		e_new = BMO_iter_map_value_ptr(&siter);

		if (e->l && e->v1 != e->l->v) {
			f_verts[0] = e->v1;
			f_verts[1] = e->v2;
			f_verts[2] = e_new->v2;
			f_verts[3] = e_new->v1;
		}
		else {
			f_verts[0] = e->v2;
			f_verts[1] = e->v1;
			f_verts[2] = e_new->v1;
			f_verts[3] = e_new->v2;
		}
		/* not sure what to do about example face, pass NULL for now */
		f = BM_face_create_verts(bm, f_verts, 4, NULL, BM_CREATE_NOP, true);
		bm_extrude_copy_face_loop_attributes(bm, f);
		
		if (BMO_edge_flag_test(bm, e, EXT_INPUT)) {
			e = e_new;
		}
		
		BMO_face_flag_enable(bm, f, EXT_KEEP);
		BMO_edge_flag_enable(bm, e, EXT_KEEP);
		BMO_vert_flag_enable(bm, e->v1, EXT_KEEP);
		BMO_vert_flag_enable(bm, e->v2, EXT_KEEP);
		
	}

	BMO_op_finish(bm, &dupeop);

	BMO_slot_buffer_from_enabled_flag(bm, op, op->slots_out, "geom.out", BM_ALL_NOLOOP, EXT_KEEP);
}

void bmo_extrude_vert_indiv_exec(BMesh *bm, BMOperator *op)
{
	const bool use_select_history = BMO_slot_bool_get(op->slots_in, "use_select_history");
	BMOIter siter;
	BMVert *v, *dupev;
	BMEdge *e;
	const bool has_vskin = CustomData_has_layer(&bm->vdata, CD_MVERT_SKIN);
	GHash *select_history_map = NULL;

	if (use_select_history) {
		select_history_map = BM_select_history_map_create(bm);
	}

	for (v = BMO_iter_new(&siter, op->slots_in, "verts", BM_VERT); v; v = BMO_iter_step(&siter)) {
		dupev = BM_vert_create(bm, v->co, v, BM_CREATE_NOP);
		BMO_vert_flag_enable(bm, dupev, EXT_KEEP);

		if (has_vskin)
			bm_extrude_disable_skin_root(bm, v);

		if (select_history_map) {
			BMEditSelection *ese;
			ese = BLI_ghash_lookup(select_history_map, v);
			if (ese) {
				ese->ele = (BMElem *)dupev;
			}
		}

		/* not essential, but ensures face normals from extruded edges are contiguous */
		if (BM_vert_is_wire_endpoint(v)) {
			if (v->e->v1 == v) {
				SWAP(BMVert *, v, dupev);
			}
		}

		e = BM_edge_create(bm, v, dupev, NULL, BM_CREATE_NOP);
		BMO_edge_flag_enable(bm, e, EXT_KEEP);
	}

	if (select_history_map) {
		BLI_ghash_free(select_history_map, NULL, NULL);
	}

	BMO_slot_buffer_from_enabled_flag(bm, op, op->slots_out, "verts.out", BM_VERT, EXT_KEEP);
	BMO_slot_buffer_from_enabled_flag(bm, op, op->slots_out, "edges.out", BM_EDGE, EXT_KEEP);
}

#ifdef USE_EDGE_REGION_FLAGS
/**
 * When create an edge for an extruded face region
 * check surrounding edge flags before creating a new edge.
 */
static bool bm_extrude_region_edge_flag(const BMVert *v, char r_e_hflag[2])
{
	BMEdge *e_iter;
	const char hflag_enable  = BM_ELEM_SEAM;
	const char hflag_disable = BM_ELEM_SMOOTH;
	bool ok = false;

	r_e_hflag[0] = 0x0;
	r_e_hflag[1] = 0xff;

	/* clear flags on both disks */
	e_iter = v->e;
	do {
		if (e_iter->l && !BM_edge_is_boundary(e_iter)) {
			r_e_hflag[0] |= e_iter->head.hflag;
			r_e_hflag[1] &= e_iter->head.hflag;
			ok = true;
		}
	} while ((e_iter = BM_DISK_EDGE_NEXT(e_iter, v)) != v->e);

	if (ok) {
		r_e_hflag[0] &= hflag_enable;
		r_e_hflag[1]  = hflag_disable & ~r_e_hflag[1];
	}
	return ok;
}
#endif  /* USE_EDGE_REGION_FLAGS */

void bmo_extrude_face_region_exec(BMesh *bm, BMOperator *op)
{
	BMOperator dupeop, delop;
	BMOIter siter;
	BMIter iter, fiter, viter;
	BMEdge *e, *e_new;
	BMVert *v;
	BMFace *f;
	bool found, fwd, delorig = false;
	BMOpSlot *slot_facemap_out;
	BMOpSlot *slot_edges_exclude;

	/* initialize our sub-operators */
	BMO_op_initf(
	        bm, &dupeop, op->flag,
	        "duplicate use_select_history=%b",
	        BMO_slot_bool_get(op->slots_in, "use_select_history"));

	BMO_slot_buffer_flag_enable(bm, op->slots_in, "geom", BM_EDGE | BM_FACE, EXT_INPUT);
	
	/* if one flagged face is bordered by an un-flagged face, then we delete
	 * original geometry unless caller explicitly asked to keep it. */
	if (!BMO_slot_bool_get(op->slots_in, "use_keep_orig")) {
		BM_ITER_MESH (e, &iter, bm, BM_EDGES_OF_MESH) {

			int edge_face_tot;

			if (!BMO_edge_flag_test(bm, e, EXT_INPUT)) {
				continue;
			}

			found = false; /* found a face that isn't input? */
			edge_face_tot = 0; /* edge/face count */

			BM_ITER_ELEM (f, &fiter, e, BM_FACES_OF_EDGE) {
				if (!BMO_face_flag_test(bm, f, EXT_INPUT)) {
					found = true;
					delorig = true;
					break;
				}

				edge_face_tot++;
			}

			if ((edge_face_tot > 1) && (found == false)) {
				/* edge has a face user, that face isn't extrude input */
				BMO_edge_flag_enable(bm, e, EXT_DEL);
			}
		}
	}

	/* calculate verts to delete */
	BM_ITER_MESH (v, &iter, bm, BM_VERTS_OF_MESH) {
		if (v->e) {  /* only deal with verts attached to geometry [#33651] */
			found = false;

			BM_ITER_ELEM (e, &viter, v, BM_EDGES_OF_VERT) {
				if (!BMO_edge_flag_test(bm, e, EXT_INPUT) ||
				    !BMO_edge_flag_test(bm, e, EXT_DEL))
				{
					found = true;
					break;
				}
			}

			/* avoid an extra loop */
			if (found == true) {
				BM_ITER_ELEM (f, &viter, v, BM_FACES_OF_VERT) {
					if (!BMO_face_flag_test(bm, f, EXT_INPUT)) {
						found = true;
						break;
					}
				}
			}

			if (found == false) {
				BMO_vert_flag_enable(bm, v, EXT_DEL);
			}
		}
	}
	
	BM_ITER_MESH (f, &iter, bm, BM_FACES_OF_MESH) {
		if (BMO_face_flag_test(bm, f, EXT_INPUT)) {
			BMO_face_flag_enable(bm, f, EXT_DEL);
		}
	}

	if (delorig == true) {
		BMO_op_initf(bm, &delop, op->flag,
		             "delete geom=%fvef context=%i",
		             EXT_DEL, DEL_ONLYTAGGED);
	}

	BMO_slot_copy(op,      slots_in, "geom",
	              &dupeop, slots_in, "geom");
	BMO_op_exec(bm, &dupeop);

	/* disable root flag on all new skin nodes */
	if (CustomData_has_layer(&bm->vdata, CD_MVERT_SKIN)) {
		BMO_ITER (v, &siter, dupeop.slots_out, "geom.out", BM_VERT) {
			bm_extrude_disable_skin_root(bm, v);
		}
	}

	slot_facemap_out = BMO_slot_get(dupeop.slots_out, "face_map.out");
	if (bm->act_face && BMO_face_flag_test(bm, bm->act_face, EXT_INPUT)) {
		bm->act_face = BMO_slot_map_elem_get(slot_facemap_out, bm->act_face);
	}

	if (delorig) {
		BMO_op_exec(bm, &delop);
	}
	
	/* if not delorig, reverse loops of original face */
	if (!delorig) {
		BM_ITER_MESH (f, &iter, bm, BM_FACES_OF_MESH) {
			if (BMO_face_flag_test(bm, f, EXT_INPUT)) {
				BM_face_normal_flip(bm, f);
			}
		}
	}
	
	BMO_slot_copy(&dupeop, slots_out, "geom.out",
	              op,      slots_out, "geom.out");

	slot_edges_exclude = BMO_slot_get(op->slots_in, "edges_exclude");
	for (e = BMO_iter_new(&siter, dupeop.slots_out, "boundary_map.out", 0); e; e = BMO_iter_step(&siter)) {
		BMVert *f_verts[4];
#ifdef USE_EDGE_REGION_FLAGS
		BMEdge *f_edges[4];
#endif

		/* this should always be wire, so this is mainly a speedup to avoid map lookup */
		if (BM_edge_is_wire(e) && BMO_slot_map_contains(slot_edges_exclude, e)) {
			BMVert *v1 = e->v1, *v2 = e->v2;

			/* The original edge was excluded,
			 * this would result in a standalone wire edge - see [#30399] */
			BM_edge_kill(bm, e);

			/* kill standalone vertices from this edge - see [#32341] */
			if (!v1->e)
				BM_vert_kill(bm, v1);
			if (!v2->e)
				BM_vert_kill(bm, v2);

			continue;
		}

		/* skip creating face for excluded edges see [#35503] */
		if (BMO_slot_map_contains(slot_edges_exclude, e)) {
			/* simply skip creating the face */
			continue;
		}

		e_new = BMO_iter_map_value_ptr(&siter);

		if (!e_new) {
			continue;
		}

		/* orient loop to give same normal as a loop of newedge
		 * if it exists (will be an extruded face),
		 * else same normal as a loop of e, if it exists */
		if (!e_new->l)
			fwd = !e->l || !(e->l->v == e->v1);
		else
			fwd = (e_new->l->v == e_new->v1);

		
		if (fwd) {
			f_verts[0] = e->v1;
			f_verts[1] = e->v2;
			f_verts[2] = e_new->v2;
			f_verts[3] = e_new->v1;
		}
		else {
			f_verts[0] = e->v2;
			f_verts[1] = e->v1;
			f_verts[2] = e_new->v1;
			f_verts[3] = e_new->v2;
		}

#ifdef USE_EDGE_REGION_FLAGS
		/* handle new edges */
		f_edges[0] = e;
		f_edges[2] = e_new;

		f_edges[1] = BM_edge_exists(f_verts[1], f_verts[2]);
		if (f_edges[1] == NULL) {
			char e_hflag[2];
			bool e_hflag_ok = bm_extrude_region_edge_flag(f_verts[2], e_hflag);
			f_edges[1] = BM_edge_create(bm, f_verts[1], f_verts[2], NULL, BM_CREATE_NOP);
			if (e_hflag_ok) {
				BM_elem_flag_enable(f_edges[1], e_hflag[0]);
				BM_elem_flag_disable(f_edges[1], e_hflag[1]);
			}
		}

		f_edges[3] = BM_edge_exists(f_verts[3], f_verts[0]);
		if (f_edges[3] == NULL) {
			char e_hflag[2];
			bool e_hflag_ok = bm_extrude_region_edge_flag(f_verts[3], e_hflag);
			f_edges[3] = BM_edge_create(bm, f_verts[3], f_verts[0], NULL, BM_CREATE_NOP);
			if (e_hflag_ok) {
				BM_elem_flag_enable(f_edges[3], e_hflag[0]);
				BM_elem_flag_disable(f_edges[3], e_hflag[1]);
			}
		}

		f = BM_face_create(bm, f_verts, f_edges, 4, NULL, BM_CREATE_NOP);
#else
		f = BM_face_create_verts(bm, f_verts, 4, NULL, BM_CREATE_NOP, true);
#endif

		bm_extrude_copy_face_loop_attributes(bm, f);
	}

	/* link isolated vert */
	for (v = BMO_iter_new(&siter, dupeop.slots_out, "isovert_map.out", 0); v; v = BMO_iter_step(&siter)) {
		BMVert *v2 = BMO_iter_map_value_ptr(&siter);

		/* not essential, but ensures face normals from extruded edges are contiguous */
		if (BM_vert_is_wire_endpoint(v)) {
			if (v->e->v1 == v) {
				SWAP(BMVert *, v, v2);
			}
		}

		BM_edge_create(bm, v, v2, NULL, BM_CREATE_NO_DOUBLE);
	}

	/* cleanup */
	if (delorig) BMO_op_finish(bm, &delop);
	BMO_op_finish(bm, &dupeop);
}

/*
 * Compute higher-quality vertex normals used by solidify.
 * Only considers geometry in the marked solidify region.
 * Note that this does not work so well for non-manifold
 * regions.
 */
static void calc_solidify_normals(BMesh *bm)
{
	BMIter viter, eiter, fiter;
	BMVert *v;
	BMEdge *e;
	BMFace *f, *f1, *f2;
	float edge_normal[3];
	int i;

	/* can't use BM_edge_face_count because we need to count only marked faces */
	int *edge_face_count = MEM_callocN(sizeof(int) * bm->totedge, __func__);

	BM_ITER_MESH (v, &viter, bm, BM_VERTS_OF_MESH) {
		BM_elem_flag_enable(v, BM_ELEM_TAG);
	}

	BM_mesh_elem_index_ensure(bm, BM_EDGE);

	BM_ITER_MESH (f, &fiter, bm, BM_FACES_OF_MESH) {
		if (!BMO_face_flag_test(bm, f, FACE_MARK)) {
			continue;
		}

		BM_ITER_ELEM (e, &eiter, f, BM_EDGES_OF_FACE) {

			/* And mark all edges and vertices on the
			 * marked faces */
			BMO_edge_flag_enable(bm, e, EDGE_MARK);
			BMO_vert_flag_enable(bm, e->v1, VERT_MARK);
			BMO_vert_flag_enable(bm, e->v2, VERT_MARK);
			edge_face_count[BM_elem_index_get(e)]++;
		}
	}

	BM_ITER_MESH (e, &eiter, bm, BM_EDGES_OF_MESH) {
		if (!BMO_edge_flag_test(bm, e, EDGE_MARK)) {
			continue;
		}

		i = edge_face_count[BM_elem_index_get(e)]++;

		if (i == 0 || i > 2) {
			/* Edge & vertices are non-manifold even when considering
			 * only marked faces */
			BMO_edge_flag_enable(bm, e, EDGE_NONMAN);
			BMO_vert_flag_enable(bm, e->v1, VERT_NONMAN);
			BMO_vert_flag_enable(bm, e->v2, VERT_NONMAN);
		}
	}
	MEM_freeN(edge_face_count);
	edge_face_count = NULL; /* don't re-use */

	BM_ITER_MESH (v, &viter, bm, BM_VERTS_OF_MESH) {
		if (!BM_vert_is_manifold(v)) {
			BMO_vert_flag_enable(bm, v, VERT_NONMAN);
			continue;
		}

		if (BMO_vert_flag_test(bm, v, VERT_MARK)) {
			zero_v3(v->no);
		}
	}

	BM_ITER_MESH (e, &eiter, bm, BM_EDGES_OF_MESH) {

		/* If the edge is not part of a the solidify region
		 * its normal should not be considered */
		if (!BMO_edge_flag_test(bm, e, EDGE_MARK)) {
			continue;
		}

		/* If the edge joins more than two marked faces high
		 * quality normal computation won't work */
		if (BMO_edge_flag_test(bm, e, EDGE_NONMAN)) {
			continue;
		}

		f1 = f2 = NULL;

		BM_ITER_ELEM (f, &fiter, e, BM_FACES_OF_EDGE) {
			if (BMO_face_flag_test(bm, f, FACE_MARK)) {
				if (f1 == NULL) {
					f1 = f;
				}
				else {
					BLI_assert(f2 == NULL);
					f2 = f;
				}
			}
		}

		BLI_assert(f1 != NULL);

		if (f2 != NULL) {
			const float angle = angle_normalized_v3v3(f1->no, f2->no);

			if (angle > 0.0f) {
				/* two faces using this edge, calculate the edge normal
				 * using the angle between the faces as a weighting */
				add_v3_v3v3(edge_normal, f1->no, f2->no);
				normalize_v3_length(edge_normal, angle);
			}
			else {
				/* can't do anything useful here!
				 * Set the face index for a vert in case it gets a zero normal */
				BM_elem_flag_disable(e->v1, BM_ELEM_TAG);
				BM_elem_flag_disable(e->v2, BM_ELEM_TAG);
				continue;
			}
		}
		else {
			/* only one face attached to that edge */
			/* an edge without another attached- the weight on this is undefined,
			 * M_PI_2 is 90d in radians and that seems good enough */
			copy_v3_v3(edge_normal, f1->no);
			mul_v3_fl(edge_normal, M_PI_2);
		}

		add_v3_v3(e->v1->no, edge_normal);
		add_v3_v3(e->v2->no, edge_normal);
	}

	/* normalize accumulated vertex normal */
	BM_ITER_MESH (v, &viter, bm, BM_VERTS_OF_MESH) {
		if (!BMO_vert_flag_test(bm, v, VERT_MARK)) {
			continue;
		}

		if (BMO_vert_flag_test(bm, v, VERT_NONMAN)) {
			/* use standard normals for vertices connected to non-manifold edges */
			BM_vert_normal_update(v);
		}
		else if (normalize_v3(v->no) == 0.0f && !BM_elem_flag_test(v, BM_ELEM_TAG)) {
			/* exceptional case, totally flat. use the normal
			 * of any marked face around the vertex */
			BM_ITER_ELEM (f, &fiter, v, BM_FACES_OF_VERT) {
				if (BMO_face_flag_test(bm, f, FACE_MARK)) {
					break;
				}
			}
			copy_v3_v3(v->no, f->no);
		}
	}
}

static void solidify_add_thickness(BMesh *bm, const float dist)
{
	BMFace *f;
	BMVert *v;
	BMLoop *l;
	BMIter iter, loopIter;
	float *vert_angles = MEM_callocN(sizeof(float) * bm->totvert * 2, "solidify"); /* 2 in 1 */
	float *vert_accum = vert_angles + bm->totvert;
	int i, index;

	BLI_buffer_declare_static(float,   face_angles_buf, BLI_BUFFER_NOP, BM_DEFAULT_NGON_STACK_SIZE);
	BLI_buffer_declare_static(float *, verts_buf,       BLI_BUFFER_NOP, BM_DEFAULT_NGON_STACK_SIZE);

	BM_mesh_elem_index_ensure(bm, BM_VERT);

	BM_ITER_MESH (f, &iter, bm, BM_FACES_OF_MESH) {
		if (BMO_face_flag_test(bm, f, FACE_MARK)) {

			/* array for passing verts to angle_poly_v3 */
			float  *face_angles = BLI_buffer_reinit_data(&face_angles_buf, float, f->len);
			/* array for receiving angles from angle_poly_v3 */
			float **verts = BLI_buffer_reinit_data(&verts_buf, float *, f->len);

			BM_ITER_ELEM_INDEX (l, &loopIter, f, BM_LOOPS_OF_FACE, i) {
				verts[i] = l->v->co;
			}

			angle_poly_v3(face_angles, (const float **)verts, f->len);

			i = 0;
			BM_ITER_ELEM (l, &loopIter, f, BM_LOOPS_OF_FACE) {
				v = l->v;
				index = BM_elem_index_get(v);
				vert_accum[index] += face_angles[i];
				vert_angles[index] += shell_v3v3_normalized_to_dist(v->no, f->no) * face_angles[i];
				i++;
			}
		}
	}

	BLI_buffer_free(&face_angles_buf);
	BLI_buffer_free(&verts_buf);

	BM_ITER_MESH (v, &iter, bm, BM_VERTS_OF_MESH) {
		index = BM_elem_index_get(v);
		if (vert_accum[index]) { /* zero if unselected */
			madd_v3_v3fl(v->co, v->no, dist * (vert_angles[index] / vert_accum[index]));
		}
	}

	MEM_freeN(vert_angles);
}

void bmo_solidify_face_region_exec(BMesh *bm, BMOperator *op)
{
	BMOperator extrudeop;
	BMOperator reverseop;
	float thickness;

	thickness = BMO_slot_float_get(op->slots_in, "thickness");

	/* Flip original faces (so the shell is extruded inward) */
	BMO_op_init(bm, &reverseop, op->flag, "reverse_faces");
	BMO_slot_bool_set(reverseop.slots_in, "flip_multires", true);
	BMO_slot_copy(op,         slots_in, "geom",
	              &reverseop, slots_in, "faces");
	BMO_op_exec(bm, &reverseop);
	BMO_op_finish(bm, &reverseop);

	/* Extrude the region */
	BMO_op_initf(bm, &extrudeop, op->flag, "extrude_face_region use_keep_orig=%b", true);
	BMO_slot_copy(op,         slots_in, "geom",
	              &extrudeop, slots_in, "geom");
	BMO_op_exec(bm, &extrudeop);

	/* Push the verts of the extruded faces inward to create thickness */
	BMO_slot_buffer_flag_enable(bm, extrudeop.slots_out, "geom.out", BM_FACE, FACE_MARK);
	calc_solidify_normals(bm);
	solidify_add_thickness(bm, thickness);

	BMO_slot_copy(&extrudeop, slots_out, "geom.out",
	              op,         slots_out, "geom.out");

	BMO_op_finish(bm, &extrudeop);
}