03ec505fa5
The "PROP" in the name reflects its generic status, and removing "LOOP" makes sense because it is no longer associated with just mesh face corners. In general the goal is to remove extra semantic meaning from the custom data types.
357 lines
9.6 KiB
C
357 lines
9.6 KiB
C
/* SPDX-License-Identifier: GPL-2.0-or-later */
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/** \file
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* \ingroup bmesh
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*
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* Convert triangle to quads.
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*
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* TODO
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* - convert triangles to any sided faces, not just quads.
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*/
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#include "MEM_guardedalloc.h"
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#include "DNA_meshdata_types.h"
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#include "BLI_math.h"
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#include "BLI_sort_utils.h"
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#include "BKE_customdata.h"
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#include "bmesh.h"
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#include "intern/bmesh_operators_private.h" /* own include */
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/* assumes edges are validated before reaching this poin */
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static float quad_calc_error(const float v1[3],
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const float v2[3],
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const float v3[3],
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const float v4[3])
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{
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/* Gives a 'weight' to a pair of triangles that join an edge
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* to decide how good a join they would make. */
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/* NOTE: this is more complicated than it needs to be and should be cleaned up. */
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float error = 0.0f;
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/* Normal difference */
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{
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float n1[3], n2[3];
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float angle_a, angle_b;
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float diff;
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normal_tri_v3(n1, v1, v2, v3);
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normal_tri_v3(n2, v1, v3, v4);
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angle_a = (compare_v3v3(n1, n2, FLT_EPSILON)) ? 0.0f : angle_normalized_v3v3(n1, n2);
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normal_tri_v3(n1, v2, v3, v4);
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normal_tri_v3(n2, v4, v1, v2);
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angle_b = (compare_v3v3(n1, n2, FLT_EPSILON)) ? 0.0f : angle_normalized_v3v3(n1, n2);
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diff = (angle_a + angle_b) / (float)(M_PI * 2);
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error += diff;
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}
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/* Co-linearity */
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{
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float edge_vecs[4][3];
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float diff;
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sub_v3_v3v3(edge_vecs[0], v1, v2);
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sub_v3_v3v3(edge_vecs[1], v2, v3);
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sub_v3_v3v3(edge_vecs[2], v3, v4);
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sub_v3_v3v3(edge_vecs[3], v4, v1);
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normalize_v3(edge_vecs[0]);
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normalize_v3(edge_vecs[1]);
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normalize_v3(edge_vecs[2]);
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normalize_v3(edge_vecs[3]);
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/* a completely skinny face is 'pi' after halving */
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diff = (fabsf(angle_normalized_v3v3(edge_vecs[0], edge_vecs[1]) - (float)M_PI_2) +
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fabsf(angle_normalized_v3v3(edge_vecs[1], edge_vecs[2]) - (float)M_PI_2) +
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fabsf(angle_normalized_v3v3(edge_vecs[2], edge_vecs[3]) - (float)M_PI_2) +
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fabsf(angle_normalized_v3v3(edge_vecs[3], edge_vecs[0]) - (float)M_PI_2)) /
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(float)(M_PI * 2);
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error += diff;
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}
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/* Concavity */
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{
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float area_min, area_max, area_a, area_b;
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float diff;
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area_a = area_tri_v3(v1, v2, v3) + area_tri_v3(v1, v3, v4);
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area_b = area_tri_v3(v2, v3, v4) + area_tri_v3(v4, v1, v2);
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area_min = min_ff(area_a, area_b);
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area_max = max_ff(area_a, area_b);
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diff = area_max ? (1.0f - (area_min / area_max)) : 1.0f;
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error += diff;
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}
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return error;
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}
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static void bm_edge_to_quad_verts(const BMEdge *e, const BMVert *r_v_quad[4])
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{
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BLI_assert(e->l->f->len == 3 && e->l->radial_next->f->len == 3);
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BLI_assert(BM_edge_is_manifold(e));
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r_v_quad[0] = e->l->v;
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r_v_quad[1] = e->l->prev->v;
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r_v_quad[2] = e->l->next->v;
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r_v_quad[3] = e->l->radial_next->prev->v;
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}
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/* cache customdata delimiters */
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struct DelimitData_CD {
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int cd_type;
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int cd_size;
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int cd_offset;
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int cd_offset_end;
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};
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struct DelimitData {
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uint do_seam : 1;
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uint do_sharp : 1;
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uint do_mat : 1;
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uint do_angle_face : 1;
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uint do_angle_shape : 1;
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float angle_face;
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float angle_face__cos;
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float angle_shape;
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struct DelimitData_CD cdata[4];
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int cdata_len;
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};
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static bool bm_edge_is_contiguous_loop_cd_all(const BMEdge *e,
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const struct DelimitData_CD *delimit_data)
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{
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int cd_offset;
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for (cd_offset = delimit_data->cd_offset; cd_offset < delimit_data->cd_offset_end;
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cd_offset += delimit_data->cd_size) {
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if (BM_edge_is_contiguous_loop_cd(e, delimit_data->cd_type, cd_offset) == false) {
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return false;
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}
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}
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return true;
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}
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static bool bm_edge_delimit_cdata(CustomData *ldata,
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CustomDataType type,
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struct DelimitData_CD *r_delim_cd)
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{
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const int layer_len = CustomData_number_of_layers(ldata, type);
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r_delim_cd->cd_type = type;
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r_delim_cd->cd_size = CustomData_sizeof(r_delim_cd->cd_type);
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r_delim_cd->cd_offset = CustomData_get_n_offset(ldata, type, 0);
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r_delim_cd->cd_offset_end = r_delim_cd->cd_offset + (r_delim_cd->cd_size * layer_len);
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return (r_delim_cd->cd_offset != -1);
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}
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static float bm_edge_is_delimit(const BMEdge *e, const struct DelimitData *delimit_data)
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{
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BMFace *f_a = e->l->f, *f_b = e->l->radial_next->f;
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#if 0
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const bool is_contig = BM_edge_is_contiguous(e);
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float angle;
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#endif
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if ((delimit_data->do_seam) && (BM_elem_flag_test(e, BM_ELEM_SEAM))) {
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goto fail;
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}
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if ((delimit_data->do_sharp) && (BM_elem_flag_test(e, BM_ELEM_SMOOTH) == 0)) {
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goto fail;
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}
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if ((delimit_data->do_mat) && (f_a->mat_nr != f_b->mat_nr)) {
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goto fail;
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}
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if (delimit_data->do_angle_face) {
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if (dot_v3v3(f_a->no, f_b->no) < delimit_data->angle_face__cos) {
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goto fail;
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}
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}
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if (delimit_data->do_angle_shape) {
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const BMVert *verts[4];
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bm_edge_to_quad_verts(e, verts);
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/* if we're checking the shape at all, a flipped face is out of the question */
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if (is_quad_flip_v3(verts[0]->co, verts[1]->co, verts[2]->co, verts[3]->co)) {
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goto fail;
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}
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else {
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float edge_vecs[4][3];
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sub_v3_v3v3(edge_vecs[0], verts[0]->co, verts[1]->co);
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sub_v3_v3v3(edge_vecs[1], verts[1]->co, verts[2]->co);
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sub_v3_v3v3(edge_vecs[2], verts[2]->co, verts[3]->co);
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sub_v3_v3v3(edge_vecs[3], verts[3]->co, verts[0]->co);
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normalize_v3(edge_vecs[0]);
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normalize_v3(edge_vecs[1]);
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normalize_v3(edge_vecs[2]);
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normalize_v3(edge_vecs[3]);
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if ((fabsf(angle_normalized_v3v3(edge_vecs[0], edge_vecs[1]) - (float)M_PI_2) >
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delimit_data->angle_shape) ||
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(fabsf(angle_normalized_v3v3(edge_vecs[1], edge_vecs[2]) - (float)M_PI_2) >
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delimit_data->angle_shape) ||
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(fabsf(angle_normalized_v3v3(edge_vecs[2], edge_vecs[3]) - (float)M_PI_2) >
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delimit_data->angle_shape) ||
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(fabsf(angle_normalized_v3v3(edge_vecs[3], edge_vecs[0]) - (float)M_PI_2) >
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delimit_data->angle_shape)) {
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goto fail;
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}
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}
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}
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if (delimit_data->cdata_len) {
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int i;
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for (i = 0; i < delimit_data->cdata_len; i++) {
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if (!bm_edge_is_contiguous_loop_cd_all(e, &delimit_data->cdata[i])) {
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goto fail;
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}
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}
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}
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return false;
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fail:
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return true;
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}
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#define EDGE_MARK (1 << 0)
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#define FACE_OUT (1 << 0)
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#define FACE_INPUT (1 << 2)
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void bmo_join_triangles_exec(BMesh *bm, BMOperator *op)
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{
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float angle_face, angle_shape;
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BMIter iter;
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BMOIter siter;
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BMFace *f;
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BMEdge *e;
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/* data: edge-to-join, sort_value: error weight */
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struct SortPtrByFloat *jedges;
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uint i, totedge;
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uint totedge_tag = 0;
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struct DelimitData delimit_data = {0};
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delimit_data.do_seam = BMO_slot_bool_get(op->slots_in, "cmp_seam");
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delimit_data.do_sharp = BMO_slot_bool_get(op->slots_in, "cmp_sharp");
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delimit_data.do_mat = BMO_slot_bool_get(op->slots_in, "cmp_materials");
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angle_face = BMO_slot_float_get(op->slots_in, "angle_face_threshold");
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if (angle_face < DEG2RADF(180.0f)) {
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delimit_data.angle_face = angle_face;
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delimit_data.angle_face__cos = cosf(angle_face);
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delimit_data.do_angle_face = true;
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}
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else {
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delimit_data.do_angle_face = false;
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}
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angle_shape = BMO_slot_float_get(op->slots_in, "angle_shape_threshold");
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if (angle_shape < DEG2RADF(180.0f)) {
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delimit_data.angle_shape = angle_shape;
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delimit_data.do_angle_shape = true;
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}
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else {
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delimit_data.do_angle_shape = false;
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}
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if (BMO_slot_bool_get(op->slots_in, "cmp_uvs") &&
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bm_edge_delimit_cdata(&bm->ldata, CD_MLOOPUV, &delimit_data.cdata[delimit_data.cdata_len])) {
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delimit_data.cdata_len += 1;
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}
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delimit_data.cdata[delimit_data.cdata_len].cd_offset = -1;
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if (BMO_slot_bool_get(op->slots_in, "cmp_vcols") &&
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bm_edge_delimit_cdata(
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&bm->ldata, CD_PROP_BYTE_COLOR, &delimit_data.cdata[delimit_data.cdata_len])) {
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delimit_data.cdata_len += 1;
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}
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/* flag all edges of all input face */
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BMO_ITER (f, &siter, op->slots_in, "faces", BM_FACE) {
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if (f->len == 3) {
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BMO_face_flag_enable(bm, f, FACE_INPUT);
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}
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}
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/* flag edges surrounded by 2 flagged triangles */
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BM_ITER_MESH (e, &iter, bm, BM_EDGES_OF_MESH) {
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BMFace *f_a, *f_b;
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if (BM_edge_face_pair(e, &f_a, &f_b) &&
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(BMO_face_flag_test(bm, f_a, FACE_INPUT) && BMO_face_flag_test(bm, f_b, FACE_INPUT))) {
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if (!bm_edge_is_delimit(e, &delimit_data)) {
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BMO_edge_flag_enable(bm, e, EDGE_MARK);
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totedge_tag++;
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}
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}
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}
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if (totedge_tag == 0) {
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return;
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}
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/* over alloc, some of the edges will be delimited */
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jedges = MEM_mallocN(sizeof(*jedges) * totedge_tag, __func__);
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i = 0;
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BM_ITER_MESH (e, &iter, bm, BM_EDGES_OF_MESH) {
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const BMVert *verts[4];
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float error;
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if (!BMO_edge_flag_test(bm, e, EDGE_MARK)) {
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continue;
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}
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bm_edge_to_quad_verts(e, verts);
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error = quad_calc_error(verts[0]->co, verts[1]->co, verts[2]->co, verts[3]->co);
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jedges[i].data = e;
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jedges[i].sort_value = error;
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i++;
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}
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totedge = i;
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qsort(jedges, totedge, sizeof(*jedges), BLI_sortutil_cmp_float);
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for (i = 0; i < totedge; i++) {
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BMLoop *l_a, *l_b;
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e = jedges[i].data;
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l_a = e->l;
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l_b = e->l->radial_next;
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/* check if another edge already claimed this face */
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if ((l_a->f->len == 3) && (l_b->f->len == 3)) {
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BMFace *f_new;
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f_new = BM_faces_join_pair(bm, l_a, l_b, true);
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if (f_new) {
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BMO_face_flag_enable(bm, f_new, FACE_OUT);
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}
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}
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}
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MEM_freeN(jedges);
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BMO_slot_buffer_from_enabled_flag(bm, op, op->slots_out, "faces.out", BM_FACE, FACE_OUT);
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}
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