griefith/test
1
0
Fork 0
Code Issues Pull Requests Actions 1 Packages Projects Releases Wiki Activity
Files
a5814607289a7e01d4844ee5ef724e6388cf044e
test/source/blender/blenkernel/intern/displist.cc
Hans Goudey 5606942c63 Curves: Skip CurveEval in legacy curve conversion 
Currently when converting from the legacy curve type to the new type,
which happens during evaluation of every legacy curve object, the
`CurveEval` type is used as an intermediate step. This involves
copying all data twice, and allocating a bunch of temporary arrays.
It's also another use of `CurveEval` that has to be removed before
we remove the type.

The main user difference besides the subtlety described below
will be improved performance.

**Invalid Handles and Types**
One important note is that there are two cases (that I know of)
where handles and handle types can be invalid in the old curve
type. The first is animation, where animated handle positions don't
necessary respect the types. The second is control points with a
single aligned handle that didn't necessarily align with the other.

In master (partially on purpose) the code corrects the first situation
(which caused T98965). But it doesn't correct the second situation.
It's trivial to correct for the second case with this patch (because of the
eager calculation decided on in D14464), but this patch makes the choice
not to correct for //either//.

Though not correcting the handle types puts curves in an invalid state,
it also adds flexibility by allowing that option. Users must understand
that any deformation may correct invalid handles.

Fixes T98965

Differential Revision: https://developer.blender.org/D15290
2022-06-25 11:11:59 -05:00

1535 lines
46 KiB
C++
Raw Blame History

/* SPDX-License-Identifier: GPL-2.0-or-later
* Copyright 2001-2002 NaN Holding BV. All rights reserved. */
/** \file
* \ingroup bke
*/
#include <cmath>
#include <cstdio>
#include <cstring>
#include "MEM_guardedalloc.h"
#include "DNA_curve_types.h"
#include "DNA_mesh_types.h"
#include "DNA_object_types.h"
#include "DNA_scene_types.h"
#include "DNA_vfont_types.h"
#include "BLI_bitmap.h"
#include "BLI_index_range.hh"
#include "BLI_linklist.h"
#include "BLI_listbase.h"
#include "BLI_math.h"
#include "BLI_memarena.h"
#include "BLI_scanfill.h"
#include "BLI_span.hh"
#include "BLI_string.h"
#include "BLI_utildefines.h"
#include "BKE_anim_path.h"
#include "BKE_curve.h"
#include "BKE_curve_legacy_convert.hh"
#include "BKE_displist.h"
#include "BKE_geometry_set.hh"
#include "BKE_key.h"
#include "BKE_lattice.h"
#include "BKE_lib_id.h"
#include "BKE_mball.h"
#include "BKE_mball_tessellate.h"
#include "BKE_mesh.h"
#include "BKE_modifier.h"
#include "BKE_object.h"
#include "BKE_vfont.h"
#include "BLI_sys_types.h" /* For #intptr_t support. */
#include "DEG_depsgraph.h"
#include "DEG_depsgraph_query.h"
using blender::IndexRange;
static void displist_elem_free(DispList *dl)
{
if (dl) {
if (dl->verts) {
MEM_freeN(dl->verts);
}
if (dl->nors) {
MEM_freeN(dl->nors);
}
if (dl->index) {
MEM_freeN(dl->index);
}
MEM_freeN(dl);
}
}
void BKE_displist_free(ListBase *lb)
{
DispList *dl;
while ((dl = (DispList *)BLI_pophead(lb))) {
displist_elem_free(dl);
}
}
DispList *BKE_displist_find(ListBase *lb, int type)
{
LISTBASE_FOREACH (DispList *, dl, lb) {
if (dl->type == type) {
return dl;
}
}
return nullptr;
}
void BKE_displist_copy(ListBase *lbn, const ListBase *lb)
{
BKE_displist_free(lbn);
LISTBASE_FOREACH (const DispList *, dl, lb) {
DispList *dln = (DispList *)MEM_dupallocN(dl);
BLI_addtail(lbn, dln);
dln->verts = (float *)MEM_dupallocN(dl->verts);
dln->nors = (float *)MEM_dupallocN(dl->nors);
dln->index = (int *)MEM_dupallocN(dl->index);
}
}
void BKE_displist_normals_add(ListBase *lb)
{
float *vdata, *ndata, nor[3];
float *v1, *v2, *v3, *v4;
float *n1, *n2, *n3, *n4;
int a, b, p1, p2, p3, p4;
LISTBASE_FOREACH (DispList *, dl, lb) {
if (dl->type == DL_INDEX3) {
if (dl->nors == nullptr) {
dl->nors = (float *)MEM_callocN(sizeof(float[3]), __func__);
if (dl->flag & DL_BACK_CURVE) {
dl->nors[2] = -1.0f;
}
else {
dl->nors[2] = 1.0f;
}
}
}
else if (dl->type == DL_SURF) {
if (dl->nors == nullptr) {
dl->nors = (float *)MEM_callocN(sizeof(float[3]) * dl->nr * dl->parts, __func__);
vdata = dl->verts;
ndata = dl->nors;
for (a = 0; a < dl->parts; a++) {
if (BKE_displist_surfindex_get(dl, a, &b, &p1, &p2, &p3, &p4) == 0) {
break;
}
v1 = vdata + 3 * p1;
n1 = ndata + 3 * p1;
v2 = vdata + 3 * p2;
n2 = ndata + 3 * p2;
v3 = vdata + 3 * p3;
n3 = ndata + 3 * p3;
v4 = vdata + 3 * p4;
n4 = ndata + 3 * p4;
for (; b < dl->nr; b++) {
normal_quad_v3(nor, v1, v3, v4, v2);
add_v3_v3(n1, nor);
add_v3_v3(n2, nor);
add_v3_v3(n3, nor);
add_v3_v3(n4, nor);
v2 = v1;
v1 += 3;
v4 = v3;
v3 += 3;
n2 = n1;
n1 += 3;
n4 = n3;
n3 += 3;
}
}
a = dl->parts * dl->nr;
v1 = ndata;
while (a--) {
normalize_v3(v1);
v1 += 3;
}
}
}
}
}
void BKE_displist_count(const ListBase *lb, int *totvert, int *totface, int *tottri)
{
LISTBASE_FOREACH (const DispList *, dl, lb) {
int vert_tot = 0;
int face_tot = 0;
int tri_tot = 0;
bool cyclic_u = dl->flag & DL_CYCL_U;
bool cyclic_v = dl->flag & DL_CYCL_V;
switch (dl->type) {
case DL_SURF: {
int segments_u = dl->nr - (cyclic_u == false);
int segments_v = dl->parts - (cyclic_v == false);
vert_tot = dl->nr * dl->parts;
face_tot = segments_u * segments_v;
tri_tot = face_tot * 2;
break;
}
case DL_INDEX3: {
vert_tot = dl->nr;
face_tot = dl->parts;
tri_tot = face_tot;
break;
}
case DL_INDEX4: {
vert_tot = dl->nr;
face_tot = dl->parts;
tri_tot = face_tot * 2;
break;
}
case DL_POLY:
case DL_SEGM: {
vert_tot = dl->nr * dl->parts;
break;
}
}
*totvert += vert_tot;
*totface += face_tot;
*tottri += tri_tot;
}
}
bool BKE_displist_surfindex_get(
const DispList *dl, int a, int *b, int *p1, int *p2, int *p3, int *p4)
{
if ((dl->flag & DL_CYCL_V) == 0 && a == (dl->parts) - 1) {
return false;
}
if (dl->flag & DL_CYCL_U) {
(*p1) = dl->nr * a;
(*p2) = (*p1) + dl->nr - 1;
(*p3) = (*p1) + dl->nr;
(*p4) = (*p2) + dl->nr;
(*b) = 0;
}
else {
(*p2) = dl->nr * a;
(*p1) = (*p2) + 1;
(*p4) = (*p2) + dl->nr;
(*p3) = (*p1) + dl->nr;
(*b) = 1;
}
if ((dl->flag & DL_CYCL_V) && a == dl->parts - 1) {
(*p3) -= dl->nr * dl->parts;
(*p4) -= dl->nr * dl->parts;
}
return true;
}
/* ****************** Make #DispList ********************* */
#ifdef __INTEL_COMPILER
/* ICC with the optimization -02 causes crashes. */
# pragma intel optimization_level 1
#endif
static void curve_to_displist(const Curve *cu,
const ListBase *nubase,
const bool for_render,
ListBase *r_dispbase)
{
const bool editmode = (!for_render && (cu->editnurb || cu->editfont));
LISTBASE_FOREACH (Nurb *, nu, nubase) {
if (nu->hide != 0 && editmode) {
continue;
}
if (!BKE_nurb_check_valid_u(nu)) {
continue;
}
const int resolution = (for_render && cu->resolu_ren != 0) ? cu->resolu_ren : nu->resolu;
const bool is_cyclic = nu->flagu & CU_NURB_CYCLIC;
const BezTriple *bezt_first = &nu->bezt[0];
const BezTriple *bezt_last = &nu->bezt[nu->pntsu - 1];
if (nu->type == CU_BEZIER) {
int samples_len = 0;
for (int i = 1; i < nu->pntsu; i++) {
const BezTriple *prevbezt = &nu->bezt[i - 1];
const BezTriple *bezt = &nu->bezt[i];
if (prevbezt->h2 == HD_VECT && bezt->h1 == HD_VECT) {
samples_len++;
}
else {
samples_len += resolution;
}
}
if (is_cyclic) {
/* If the curve is cyclic, sample the last edge between the last and first points. */
if (bezt_first->h1 == HD_VECT && bezt_last->h2 == HD_VECT) {
samples_len++;
}
else {
samples_len += resolution;
}
}
else {
/* Otherwise, we only need one additional sample to complete the last edge. */
samples_len++;
}
/* Check that there are more than two points so the curve doesn't loop back on itself. This
* needs to be separate from `is_cyclic` because cyclic sampling can work with two points
* and resolution > 1. */
const bool use_cyclic_sample = is_cyclic && (samples_len != 2);
DispList *dl = MEM_cnew<DispList>(__func__);
/* Add one to the length because of 'BKE_curve_forward_diff_bezier'. */
dl->verts = (float *)MEM_mallocN(sizeof(float[3]) * (samples_len + 1), __func__);
BLI_addtail(r_dispbase, dl);
dl->parts = 1;
dl->nr = samples_len;
dl->col = nu->mat_nr;
dl->charidx = nu->charidx;
dl->type = use_cyclic_sample ? DL_POLY : DL_SEGM;
float *data = dl->verts;
for (int i = 1; i < nu->pntsu; i++) {
const BezTriple *prevbezt = &nu->bezt[i - 1];
const BezTriple *bezt = &nu->bezt[i];
if (prevbezt->h2 == HD_VECT && bezt->h1 == HD_VECT) {
copy_v3_v3(data, prevbezt->vec[1]);
data += 3;
}
else {
for (int j = 0; j < 3; j++) {
BKE_curve_forward_diff_bezier(prevbezt->vec[1][j],
prevbezt->vec[2][j],
bezt->vec[0][j],
bezt->vec[1][j],
data + j,
resolution,
sizeof(float[3]));
}
data += 3 * resolution;
}
}
if (is_cyclic) {
if (bezt_first->h1 == HD_VECT && bezt_last->h2 == HD_VECT) {
copy_v3_v3(data, bezt_last->vec[1]);
}
else {
for (int j = 0; j < 3; j++) {
BKE_curve_forward_diff_bezier(bezt_last->vec[1][j],
bezt_last->vec[2][j],
bezt_first->vec[0][j],
bezt_first->vec[1][j],
data + j,
resolution,
sizeof(float[3]));
}
}
}
else {
copy_v3_v3(data, bezt_last->vec[1]);
}
}
else if (nu->type == CU_NURBS) {
const int len = (resolution * SEGMENTSU(nu));
DispList *dl = MEM_cnew<DispList>(__func__);
dl->verts = (float *)MEM_mallocN(len * sizeof(float[3]), __func__);
BLI_addtail(r_dispbase, dl);
dl->parts = 1;
dl->nr = len;
dl->col = nu->mat_nr;
dl->charidx = nu->charidx;
dl->type = is_cyclic ? DL_POLY : DL_SEGM;
BKE_nurb_makeCurve(nu, dl->verts, nullptr, nullptr, nullptr, resolution, sizeof(float[3]));
}
else if (nu->type == CU_POLY) {
const int len = nu->pntsu;
DispList *dl = MEM_cnew<DispList>(__func__);
dl->verts = (float *)MEM_mallocN(len * sizeof(float[3]), __func__);
BLI_addtail(r_dispbase, dl);
dl->parts = 1;
dl->nr = len;
dl->col = nu->mat_nr;
dl->charidx = nu->charidx;
dl->type = (is_cyclic && (dl->nr != 2)) ? DL_POLY : DL_SEGM;
float(*coords)[3] = (float(*)[3])dl->verts;
for (int i = 0; i < len; i++) {
const BPoint *bp = &nu->bp[i];
copy_v3_v3(coords[i], bp->vec);
}
}
}
}
void BKE_displist_fill(const ListBase *dispbase,
ListBase *to,
const float normal_proj[3],
const bool flip_normal)
{
if (dispbase == nullptr) {
return;
}
if (BLI_listbase_is_empty(dispbase)) {
return;
}
const int scanfill_flag = BLI_SCANFILL_CALC_REMOVE_DOUBLES | BLI_SCANFILL_CALC_POLYS |
BLI_SCANFILL_CALC_HOLES;
MemArena *sf_arena = BLI_memarena_new(BLI_SCANFILL_ARENA_SIZE, __func__);
short colnr = 0;
int charidx = 0;
bool should_continue = true;
while (should_continue) {
should_continue = false;
bool nextcol = false;
ScanFillContext sf_ctx;
BLI_scanfill_begin_arena(&sf_ctx, sf_arena);
int totvert = 0;
short dl_flag_accum = 0;
short dl_rt_accum = 0;
LISTBASE_FOREACH (const DispList *, dl, dispbase) {
if (dl->type == DL_POLY) {
if (charidx < dl->charidx) {
should_continue = true;
}
else if (charidx == dl->charidx) { /* character with needed index */
if (colnr == dl->col) {
sf_ctx.poly_nr++;
/* Make verts and edges. */
ScanFillVert *sf_vert = nullptr;
ScanFillVert *sf_vert_last = nullptr;
ScanFillVert *sf_vert_new = nullptr;
for (int i = 0; i < dl->nr; i++) {
sf_vert_last = sf_vert;
sf_vert = BLI_scanfill_vert_add(&sf_ctx, &dl->verts[3 * i]);
totvert++;
if (sf_vert_last == nullptr) {
sf_vert_new = sf_vert;
}
else {
BLI_scanfill_edge_add(&sf_ctx, sf_vert_last, sf_vert);
}
}
if (sf_vert != nullptr && sf_vert_new != nullptr) {
BLI_scanfill_edge_add(&sf_ctx, sf_vert, sf_vert_new);
}
}
else if (colnr < dl->col) {
/* got poly with next material at current char */
should_continue = true;
nextcol = true;
}
}
dl_flag_accum |= dl->flag;
dl_rt_accum |= dl->rt;
}
}
const int triangles_len = BLI_scanfill_calc_ex(&sf_ctx, scanfill_flag, normal_proj);
if (totvert != 0 && triangles_len != 0) {
DispList *dlnew = MEM_cnew<DispList>(__func__);
dlnew->type = DL_INDEX3;
dlnew->flag = (dl_flag_accum & (DL_BACK_CURVE | DL_FRONT_CURVE));
dlnew->rt = (dl_rt_accum & CU_SMOOTH);
dlnew->col = colnr;
dlnew->nr = totvert;
dlnew->parts = triangles_len;
dlnew->index = (int *)MEM_mallocN(sizeof(int[3]) * triangles_len, __func__);
dlnew->verts = (float *)MEM_mallocN(sizeof(float[3]) * totvert, __func__);
/* vert data */
int i;
LISTBASE_FOREACH_INDEX (ScanFillVert *, sf_vert, &sf_ctx.fillvertbase, i) {
copy_v3_v3(&dlnew->verts[3 * i], sf_vert->co);
sf_vert->tmp.i = i; /* Index number. */
}
/* index data */
int *index = dlnew->index;
LISTBASE_FOREACH (ScanFillFace *, sf_tri, &sf_ctx.fillfacebase) {
index[0] = sf_tri->v1->tmp.i;
index[1] = flip_normal ? sf_tri->v3->tmp.i : sf_tri->v2->tmp.i;
index[2] = flip_normal ? sf_tri->v2->tmp.i : sf_tri->v3->tmp.i;
index += 3;
}
BLI_addhead(to, dlnew);
}
BLI_scanfill_end_arena(&sf_ctx, sf_arena);
if (nextcol) {
/* stay at current char but fill polys with next material */
colnr++;
}
else {
/* switch to next char and start filling from first material */
charidx++;
colnr = 0;
}
}
BLI_memarena_free(sf_arena);
/* do not free polys, needed for wireframe display */
}
static void bevels_to_filledpoly(const Curve *cu, ListBase *dispbase)
{
ListBase front = {nullptr, nullptr};
ListBase back = {nullptr, nullptr};
LISTBASE_FOREACH (const DispList *, dl, dispbase) {
if (dl->type == DL_SURF) {
if ((dl->flag & DL_CYCL_V) && (dl->flag & DL_CYCL_U) == 0) {
if ((cu->flag & CU_BACK) && (dl->flag & DL_BACK_CURVE)) {
DispList *dlnew = MEM_cnew<DispList>(__func__);
BLI_addtail(&front, dlnew);
dlnew->verts = (float *)MEM_mallocN(sizeof(float[3]) * dl->parts, __func__);
dlnew->nr = dl->parts;
dlnew->parts = 1;
dlnew->type = DL_POLY;
dlnew->flag = DL_BACK_CURVE;
dlnew->col = dl->col;
dlnew->charidx = dl->charidx;
const float *old_verts = dl->verts;
float *new_verts = dlnew->verts;
for (int i = 0; i < dl->parts; i++) {
copy_v3_v3(new_verts, old_verts);
new_verts += 3;
old_verts += 3 * dl->nr;
}
}
if ((cu->flag & CU_FRONT) && (dl->flag & DL_FRONT_CURVE)) {
DispList *dlnew = MEM_cnew<DispList>(__func__);
BLI_addtail(&back, dlnew);
dlnew->verts = (float *)MEM_mallocN(sizeof(float[3]) * dl->parts, __func__);
dlnew->nr = dl->parts;
dlnew->parts = 1;
dlnew->type = DL_POLY;
dlnew->flag = DL_FRONT_CURVE;
dlnew->col = dl->col;
dlnew->charidx = dl->charidx;
const float *old_verts = dl->verts + 3 * (dl->nr - 1);
float *new_verts = dlnew->verts;
for (int i = 0; i < dl->parts; i++) {
copy_v3_v3(new_verts, old_verts);
new_verts += 3;
old_verts += 3 * dl->nr;
}
}
}
}
}
const float z_up[3] = {0.0f, 0.0f, -1.0f};
BKE_displist_fill(&front, dispbase, z_up, true);
BKE_displist_fill(&back, dispbase, z_up, false);
BKE_displist_free(&front);
BKE_displist_free(&back);
BKE_displist_fill(dispbase, dispbase, z_up, false);
}
static void curve_to_filledpoly(const Curve *cu, ListBase *dispbase)
{
if (!CU_DO_2DFILL(cu)) {
return;
}
if (dispbase->first && ((DispList *)dispbase->first)->type == DL_SURF) {
bevels_to_filledpoly(cu, dispbase);
}
else {
const float z_up[3] = {0.0f, 0.0f, -1.0f};
BKE_displist_fill(dispbase, dispbase, z_up, false);
}
}
/* taper rules:
* - only 1 curve
* - first point left, last point right
* - based on subdivided points in original curve, not on points in taper curve (still)
*/
static float displist_calc_taper(Depsgraph *depsgraph,
const Scene *scene,
Object *taperobj,
float fac)
{
if (taperobj == nullptr || taperobj->type != OB_CURVES_LEGACY) {
return 1.0;
}
DispList *dl = taperobj->runtime.curve_cache ?
(DispList *)taperobj->runtime.curve_cache->disp.first :
nullptr;
if (dl == nullptr) {
BKE_displist_make_curveTypes(depsgraph, scene, taperobj, false);
dl = (DispList *)taperobj->runtime.curve_cache->disp.first;
}
if (dl) {
float minx, dx, *fp;
int a;
/* horizontal size */
minx = dl->verts[0];
dx = dl->verts[3 * (dl->nr - 1)] - minx;
if (dx > 0.0f) {
fp = dl->verts;
for (a = 0; a < dl->nr; a++, fp += 3) {
if ((fp[0] - minx) / dx >= fac) {
/* interpolate with prev */
if (a > 0) {
float fac1 = (fp[-3] - minx) / dx;
float fac2 = (fp[0] - minx) / dx;
if (fac1 != fac2) {
return fp[1] * (fac1 - fac) / (fac1 - fac2) + fp[-2] * (fac - fac2) / (fac1 - fac2);
}
}
return fp[1];
}
}
return fp[-2]; /* Last y coordinate. */
}
}
return 1.0;
}
float BKE_displist_calc_taper(
Depsgraph *depsgraph, const Scene *scene, Object *taperobj, int cur, int tot)
{
const float fac = ((float)cur) / (float)(tot - 1);
return displist_calc_taper(depsgraph, scene, taperobj, fac);
}
void BKE_displist_make_mball(Depsgraph *depsgraph, Scene *scene, Object *ob)
{
if (!ob || ob->type != OB_MBALL) {
return;
}
if (ob == BKE_mball_basis_find(scene, ob)) {
if (ob->runtime.curve_cache) {
BKE_displist_free(&(ob->runtime.curve_cache->disp));
}
else {
ob->runtime.curve_cache = MEM_cnew<CurveCache>(__func__);
}
BKE_mball_polygonize(depsgraph, scene, ob, &ob->runtime.curve_cache->disp);
BKE_mball_texspace_calc(ob);
object_deform_mball(ob, &ob->runtime.curve_cache->disp);
}
}
static ModifierData *curve_get_tessellate_point(const Scene *scene,
const Object *ob,
const bool for_render,
const bool editmode)
{
VirtualModifierData virtualModifierData;
ModifierData *md = BKE_modifiers_get_virtual_modifierlist(ob, &virtualModifierData);
ModifierMode required_mode = for_render ? eModifierMode_Render : eModifierMode_Realtime;
if (editmode) {
required_mode = (ModifierMode)((int)required_mode | eModifierMode_Editmode);
}
ModifierData *pretessellatePoint = nullptr;
for (; md; md = md->next) {
const ModifierTypeInfo *mti = BKE_modifier_get_info((ModifierType)md->type);
if (!BKE_modifier_is_enabled(scene, md, required_mode)) {
continue;
}
if (mti->type == eModifierTypeType_Constructive) {
return pretessellatePoint;
}
if (ELEM(md->type, eModifierType_Hook, eModifierType_Softbody, eModifierType_MeshDeform)) {
pretessellatePoint = md;
/* this modifiers are moving point of tessellation automatically
* (some of them even can't be applied on tessellated curve), set flag
* for information button in modifier's header. */
md->mode |= eModifierMode_ApplyOnSpline;
}
else if (md->mode & eModifierMode_ApplyOnSpline) {
pretessellatePoint = md;
}
}
return pretessellatePoint;
}
void BKE_curve_calc_modifiers_pre(Depsgraph *depsgraph,
const Scene *scene,
Object *ob,
ListBase *source_nurb,
ListBase *target_nurb,
const bool for_render)
{
const Curve *cu = (const Curve *)ob->data;
BKE_modifiers_clear_errors(ob);
const bool editmode = (!for_render && (cu->editnurb || cu->editfont));
ModifierMode required_mode = for_render ? eModifierMode_Render : eModifierMode_Realtime;
if (editmode) {
required_mode = (ModifierMode)((int)required_mode | eModifierMode_Editmode);
}
ModifierApplyFlag apply_flag = (ModifierApplyFlag)0;
if (editmode) {
apply_flag = MOD_APPLY_USECACHE;
}
if (for_render) {
apply_flag = MOD_APPLY_RENDER;
}
float *keyVerts = nullptr;
float(*deformedVerts)[3] = nullptr;
int numVerts = 0;
if (!editmode) {
int numElems = 0;
keyVerts = BKE_key_evaluate_object(ob, &numElems);
if (keyVerts) {
BLI_assert(BKE_keyblock_curve_element_count(source_nurb) == numElems);
/* split coords from key data, the latter also includes
* tilts, which is passed through in the modifier stack.
* this is also the reason curves do not use a virtual
* shape key modifier yet. */
deformedVerts = BKE_curve_nurbs_key_vert_coords_alloc(source_nurb, keyVerts, &numVerts);
}
}
const ModifierEvalContext mectx = {depsgraph, ob, apply_flag};
ModifierData *pretessellatePoint = curve_get_tessellate_point(scene, ob, for_render, editmode);
if (pretessellatePoint) {
VirtualModifierData virtualModifierData;
for (ModifierData *md = BKE_modifiers_get_virtual_modifierlist(ob, &virtualModifierData); md;
md = md->next) {
const ModifierTypeInfo *mti = BKE_modifier_get_info((ModifierType)md->type);
if (!BKE_modifier_is_enabled(scene, md, required_mode)) {
continue;
}
if (mti->type != eModifierTypeType_OnlyDeform) {
continue;
}
if (!deformedVerts) {
deformedVerts = BKE_curve_nurbs_vert_coords_alloc(source_nurb, &numVerts);
}
mti->deformVerts(md, &mectx, nullptr, deformedVerts, numVerts);
if (md == pretessellatePoint) {
break;
}
}
}
if (deformedVerts) {
BKE_curve_nurbs_vert_coords_apply(target_nurb, deformedVerts, false);
MEM_freeN(deformedVerts);
}
if (keyVerts) { /* these are not passed through modifier stack */
BKE_curve_nurbs_key_vert_tilts_apply(target_nurb, keyVerts);
}
if (keyVerts) {
MEM_freeN(keyVerts);
}
}
/**
* \return True if the deformed curve control point data should be implicitly
* converted directly to a mesh, or false if it can be left as curve data via #CurveEval.
*/
static bool do_curve_implicit_mesh_conversion(const Curve *curve,
ModifierData *first_modifier,
const Scene *scene,
const ModifierMode required_mode)
{
/* Skip implicit filling and conversion to mesh when using "fast text editing". */
if (curve->flag & CU_FAST) {
return false;
}
/* Do implicit conversion to mesh with the object bevel mode. */
if (curve->bevel_mode == CU_BEV_MODE_OBJECT && curve->bevobj != nullptr) {
return true;
}
/* 2D curves are sometimes implicitly filled and converted to a mesh. */
if (CU_DO_2DFILL(curve)) {
return true;
}
/* Curve objects with implicit "tube" meshes should convert implicitly to a mesh. */
if (curve->extrude != 0.0f || curve->bevel_radius != 0.0f) {
return true;
}
/* If a non-geometry-nodes modifier is enabled before a nodes modifier,
* force conversion to mesh, since only the nodes modifier supports curve data. */
ModifierData *md = first_modifier;
for (; md; md = md->next) {
if (BKE_modifier_is_enabled(scene, md, required_mode)) {
if (md->type == eModifierType_Nodes) {
break;
}
return true;
}
}
return false;
}
static GeometrySet curve_calc_modifiers_post(Depsgraph *depsgraph,
const Scene *scene,
Object *ob,
const ListBase *dispbase,
const bool for_render)
{
const Curve *cu = (const Curve *)ob->data;
const bool editmode = (!for_render && (cu->editnurb || cu->editfont));
const bool use_cache = !for_render;
ModifierApplyFlag apply_flag = for_render ? MOD_APPLY_RENDER : (ModifierApplyFlag)0;
ModifierMode required_mode = for_render ? eModifierMode_Render : eModifierMode_Realtime;
if (editmode) {
required_mode = (ModifierMode)((int)required_mode | eModifierMode_Editmode);
}
const ModifierEvalContext mectx_deform = {
depsgraph, ob, editmode ? (ModifierApplyFlag)(apply_flag | MOD_APPLY_USECACHE) : apply_flag};
const ModifierEvalContext mectx_apply = {
depsgraph,
ob,
use_cache ? (ModifierApplyFlag)(apply_flag | MOD_APPLY_USECACHE) : apply_flag};
ModifierData *pretessellatePoint = curve_get_tessellate_point(scene, ob, for_render, editmode);
VirtualModifierData virtualModifierData;
ModifierData *md = pretessellatePoint == nullptr ?
BKE_modifiers_get_virtual_modifierlist(ob, &virtualModifierData) :
pretessellatePoint->next;
GeometrySet geometry_set;
if (ob->type == OB_SURF || do_curve_implicit_mesh_conversion(cu, md, scene, required_mode)) {
Mesh *mesh = BKE_mesh_new_nomain_from_curve_displist(ob, dispbase);
geometry_set.replace_mesh(mesh);
}
else {
geometry_set.replace_curves(
blender::bke::curve_legacy_to_curves(*cu, ob->runtime.curve_cache->deformed_nurbs));
}
for (; md; md = md->next) {
const ModifierTypeInfo *mti = BKE_modifier_get_info((ModifierType)md->type);
if (!BKE_modifier_is_enabled(scene, md, required_mode)) {
continue;
}
if (md->type == eModifierType_Nodes) {
mti->modifyGeometrySet(md, &mectx_apply, &geometry_set);
continue;
}
if (!geometry_set.has_mesh()) {
geometry_set.replace_mesh(BKE_mesh_new_nomain(0, 0, 0, 0, 0));
}
Mesh *mesh = geometry_set.get_mesh_for_write();
if (mti->type == eModifierTypeType_OnlyDeform) {
int totvert;
float(*vertex_coords)[3] = BKE_mesh_vert_coords_alloc(mesh, &totvert);
mti->deformVerts(md, &mectx_deform, mesh, vertex_coords, totvert);
BKE_mesh_vert_coords_apply(mesh, vertex_coords);
MEM_freeN(vertex_coords);
}
else {
Mesh *output_mesh = mti->modifyMesh(md, &mectx_apply, mesh);
if (mesh != output_mesh) {
geometry_set.replace_mesh(output_mesh);
}
}
}
if (geometry_set.has_mesh()) {
Mesh *final_mesh = geometry_set.get_mesh_for_write();
BKE_mesh_ensure_normals_for_display(final_mesh);
BLI_strncpy(final_mesh->id.name, cu->id.name, sizeof(final_mesh->id.name));
*((short *)final_mesh->id.name) = ID_ME;
}
return geometry_set;
}
static void displist_surf_indices(DispList *dl)
{
int b, p1, p2, p3, p4;
dl->totindex = 0;
int *index = dl->index = (int *)MEM_mallocN(sizeof(int[4]) * (dl->parts + 1) * (dl->nr + 1),
__func__);
for (int a = 0; a < dl->parts; a++) {
if (BKE_displist_surfindex_get(dl, a, &b, &p1, &p2, &p3, &p4) == 0) {
break;
}
for (; b < dl->nr; b++, index += 4) {
index[0] = p1;
index[1] = p2;
index[2] = p4;
index[3] = p3;
dl->totindex++;
p2 = p1;
p1++;
p4 = p3;
p3++;
}
}
}
static GeometrySet evaluate_surface_object(Depsgraph *depsgraph,
const Scene *scene,
Object *ob,
const bool for_render,
ListBase *r_dispbase)
{
BLI_assert(ob->type == OB_SURF);
const Curve *cu = (const Curve *)ob->data;
ListBase *deformed_nurbs = &ob->runtime.curve_cache->deformed_nurbs;
if (!for_render && cu->editnurb) {
BKE_nurbList_duplicate(deformed_nurbs, BKE_curve_editNurbs_get_for_read(cu));
}
else {
BKE_nurbList_duplicate(deformed_nurbs, &cu->nurb);
}
BKE_curve_calc_modifiers_pre(depsgraph, scene, ob, deformed_nurbs, deformed_nurbs, for_render);
LISTBASE_FOREACH (const Nurb *, nu, deformed_nurbs) {
if (!(for_render || nu->hide == 0) || !BKE_nurb_check_valid_uv(nu)) {
continue;
}
const int resolu = (for_render && cu->resolu_ren) ? cu->resolu_ren : nu->resolu;
const int resolv = (for_render && cu->resolv_ren) ? cu->resolv_ren : nu->resolv;
if (nu->pntsv == 1) {
const int len = SEGMENTSU(nu) * resolu;
DispList *dl = MEM_cnew<DispList>(__func__);
dl->verts = (float *)MEM_mallocN(len * sizeof(float[3]), __func__);
BLI_addtail(r_dispbase, dl);
dl->parts = 1;
dl->nr = len;
dl->col = nu->mat_nr;
dl->charidx = nu->charidx;
dl->rt = nu->flag;
float *data = dl->verts;
if (nu->flagu & CU_NURB_CYCLIC) {
dl->type = DL_POLY;
}
else {
dl->type = DL_SEGM;
}
BKE_nurb_makeCurve(nu, data, nullptr, nullptr, nullptr, resolu, sizeof(float[3]));
}
else {
const int len = (nu->pntsu * resolu) * (nu->pntsv * resolv);
DispList *dl = MEM_cnew<DispList>(__func__);
dl->verts = (float *)MEM_mallocN(len * sizeof(float[3]), __func__);
BLI_addtail(r_dispbase, dl);
dl->col = nu->mat_nr;
dl->charidx = nu->charidx;
dl->rt = nu->flag;
float *data = dl->verts;
dl->type = DL_SURF;
dl->parts = (nu->pntsu * resolu); /* in reverse, because makeNurbfaces works that way */
dl->nr = (nu->pntsv * resolv);
if (nu->flagv & CU_NURB_CYCLIC) {
dl->flag |= DL_CYCL_U; /* reverse too! */
}
if (nu->flagu & CU_NURB_CYCLIC) {
dl->flag |= DL_CYCL_V;
}
BKE_nurb_makeFaces(nu, data, 0, resolu, resolv);
/* gl array drawing: using indices */
displist_surf_indices(dl);
}
}
curve_to_filledpoly(cu, r_dispbase);
GeometrySet geometry_set = curve_calc_modifiers_post(
depsgraph, scene, ob, r_dispbase, for_render);
if (!geometry_set.has_mesh()) {
geometry_set.replace_mesh(BKE_mesh_new_nomain(0, 0, 0, 0, 0));
}
return geometry_set;
}
static void rotateBevelPiece(const Curve *cu,
const BevPoint *bevp,
const BevPoint *nbevp,
const DispList *dlb,
const float bev_blend,
const float widfac,
const float radius_factor,
float **r_data)
{
float *data = *r_data;
const float *fp = dlb->verts;
for (int b = 0; b < dlb->nr; b++, fp += 3, data += 3) {
if (cu->flag & CU_3D) {
float vec[3], quat[4];
vec[0] = fp[1] + widfac;
vec[1] = fp[2];
vec[2] = 0.0;
if (nbevp == nullptr) {
copy_v3_v3(data, bevp->vec);
copy_qt_qt(quat, bevp->quat);
}
else {
interp_v3_v3v3(data, bevp->vec, nbevp->vec, bev_blend);
interp_qt_qtqt(quat, bevp->quat, nbevp->quat, bev_blend);
}
mul_qt_v3(quat, vec);
data[0] += radius_factor * vec[0];
data[1] += radius_factor * vec[1];
data[2] += radius_factor * vec[2];
}
else {
float sina, cosa;
if (nbevp == nullptr) {
copy_v3_v3(data, bevp->vec);
sina = bevp->sina;
cosa = bevp->cosa;
}
else {
interp_v3_v3v3(data, bevp->vec, nbevp->vec, bev_blend);
/* perhaps we need to interpolate angles instead. but the thing is
* cosa and sina are not actually sine and cosine
*/
sina = nbevp->sina * bev_blend + bevp->sina * (1.0f - bev_blend);
cosa = nbevp->cosa * bev_blend + bevp->cosa * (1.0f - bev_blend);
}
data[0] += radius_factor * (widfac + fp[1]) * sina;
data[1] += radius_factor * (widfac + fp[1]) * cosa;
data[2] += radius_factor * fp[2];
}
}
*r_data = data;
}
static void fillBevelCap(const Nurb *nu,
const DispList *dlb,
const float *prev_fp,
ListBase *dispbase)
{
DispList *dl = MEM_cnew<DispList>(__func__);
dl->verts = (float *)MEM_mallocN(sizeof(float[3]) * dlb->nr, __func__);
memcpy(dl->verts, prev_fp, sizeof(float[3]) * dlb->nr);
dl->type = DL_POLY;
dl->parts = 1;
dl->nr = dlb->nr;
dl->col = nu->mat_nr;
dl->charidx = nu->charidx;
dl->rt = nu->flag;
BLI_addtail(dispbase, dl);
}
static void calc_bevfac_segment_mapping(
const BevList *bl, float bevfac, float spline_length, int *r_bev, float *r_blend)
{
float normsum = 0.0f;
float *seglen = bl->seglen;
int *segbevcount = bl->segbevcount;
int bevcount = 0, nr = bl->nr;
float bev_fl = bevfac * (bl->nr - 1);
*r_bev = (int)bev_fl;
while (bevcount < nr - 1) {
float normlen = *seglen / spline_length;
if (normsum + normlen > bevfac) {
bev_fl = bevcount + (bevfac - normsum) / normlen * *segbevcount;
*r_bev = (int)bev_fl;
*r_blend = bev_fl - *r_bev;
break;
}
normsum += normlen;
bevcount += *segbevcount;
segbevcount++;
seglen++;
}
}
static void calc_bevfac_spline_mapping(
const BevList *bl, float bevfac, float spline_length, int *r_bev, float *r_blend)
{
const float len_target = bevfac * spline_length;
BevPoint *bevp = bl->bevpoints;
float len_next = 0.0f, len = 0.0f;
int i = 0, nr = bl->nr;
while (nr--) {
bevp++;
len_next = len + bevp->offset;
if (len_next > len_target) {
break;
}
len = len_next;
i++;
}
*r_bev = i;
*r_blend = (len_target - len) / bevp->offset;
}
static void calc_bevfac_mapping_default(
const BevList *bl, int *r_start, float *r_firstblend, int *r_steps, float *r_lastblend)
{
*r_start = 0;
*r_steps = bl->nr;
*r_firstblend = 1.0f;
*r_lastblend = 1.0f;
}
static void calc_bevfac_mapping(const Curve *cu,
const BevList *bl,
const Nurb *nu,
int *r_start,
float *r_firstblend,
int *r_steps,
float *r_lastblend)
{
float tmpf, total_length = 0.0f;
int end = 0, i;
if ((BKE_nurb_check_valid_u(nu) == false) ||
/* not essential, but skips unnecessary calculation */
(min_ff(cu->bevfac1, cu->bevfac2) == 0.0f && max_ff(cu->bevfac1, cu->bevfac2) == 1.0f)) {
calc_bevfac_mapping_default(bl, r_start, r_firstblend, r_steps, r_lastblend);
return;
}
if (ELEM(cu->bevfac1_mapping, CU_BEVFAC_MAP_SEGMENT, CU_BEVFAC_MAP_SPLINE) ||
ELEM(cu->bevfac2_mapping, CU_BEVFAC_MAP_SEGMENT, CU_BEVFAC_MAP_SPLINE)) {
for (i = 0; i < SEGMENTSU(nu); i++) {
total_length += bl->seglen[i];
}
}
switch (cu->bevfac1_mapping) {
case CU_BEVFAC_MAP_RESOLU: {
const float start_fl = cu->bevfac1 * (bl->nr - 1);
*r_start = (int)start_fl;
*r_firstblend = 1.0f - (start_fl - (*r_start));
break;
}
case CU_BEVFAC_MAP_SEGMENT: {
calc_bevfac_segment_mapping(bl, cu->bevfac1, total_length, r_start, r_firstblend);
*r_firstblend = 1.0f - *r_firstblend;
break;
}
case CU_BEVFAC_MAP_SPLINE: {
calc_bevfac_spline_mapping(bl, cu->bevfac1, total_length, r_start, r_firstblend);
*r_firstblend = 1.0f - *r_firstblend;
break;
}
}
switch (cu->bevfac2_mapping) {
case CU_BEVFAC_MAP_RESOLU: {
const float end_fl = cu->bevfac2 * (bl->nr - 1);
end = (int)end_fl;
*r_steps = 2 + end - *r_start;
*r_lastblend = end_fl - end;
break;
}
case CU_BEVFAC_MAP_SEGMENT: {
calc_bevfac_segment_mapping(bl, cu->bevfac2, total_length, &end, r_lastblend);
*r_steps = end - *r_start + 2;
break;
}
case CU_BEVFAC_MAP_SPLINE: {
calc_bevfac_spline_mapping(bl, cu->bevfac2, total_length, &end, r_lastblend);
*r_steps = end - *r_start + 2;
break;
}
}
if (end < *r_start || (end == *r_start && *r_lastblend < 1.0f - *r_firstblend)) {
SWAP(int, *r_start, end);
tmpf = *r_lastblend;
*r_lastblend = 1.0f - *r_firstblend;
*r_firstblend = 1.0f - tmpf;
*r_steps = end - *r_start + 2;
}
if (*r_start + *r_steps > bl->nr) {
*r_steps = bl->nr - *r_start;
*r_lastblend = 1.0f;
}
}
static GeometrySet evaluate_curve_type_object(Depsgraph *depsgraph,
const Scene *scene,
Object *ob,
const bool for_render,
ListBase *r_dispbase)
{
BLI_assert(ELEM(ob->type, OB_CURVES_LEGACY, OB_FONT));
const Curve *cu = (const Curve *)ob->data;
ListBase *deformed_nurbs = &ob->runtime.curve_cache->deformed_nurbs;
if (ob->type == OB_FONT) {
BKE_vfont_to_curve_nubase(ob, FO_EDIT, deformed_nurbs);
}
else {
BKE_nurbList_duplicate(deformed_nurbs, BKE_curve_nurbs_get_for_read(cu));
}
BKE_curve_calc_modifiers_pre(depsgraph, scene, ob, deformed_nurbs, deformed_nurbs, for_render);
BKE_curve_bevelList_make(ob, deformed_nurbs, for_render);
if ((cu->flag & CU_PATH) ||
DEG_get_eval_flags_for_id(depsgraph, &ob->id) & DAG_EVAL_NEED_CURVE_PATH) {
BKE_anim_path_calc_data(ob);
}
/* If curve has no bevel will return nothing */
ListBase dlbev = BKE_curve_bevel_make(cu);
/* no bevel or extrude, and no width correction? */
if (BLI_listbase_is_empty(&dlbev) && cu->offset == 1.0f) {
curve_to_displist(cu, deformed_nurbs, for_render, r_dispbase);
}
else {
const float widfac = cu->offset - 1.0f;
const BevList *bl = (BevList *)ob->runtime.curve_cache->bev.first;
const Nurb *nu = (Nurb *)deformed_nurbs->first;
for (; bl && nu; bl = bl->next, nu = nu->next) {
float *data;
if (bl->nr == 0) { /* blank bevel lists can happen */
continue;
}
/* exception handling; curve without bevel or extrude, with width correction */
if (BLI_listbase_is_empty(&dlbev)) {
DispList *dl = MEM_cnew<DispList>("makeDispListbev");
dl->verts = (float *)MEM_mallocN(sizeof(float[3]) * bl->nr, "dlverts");
BLI_addtail(r_dispbase, dl);
if (bl->poly != -1) {
dl->type = DL_POLY;
}
else {
dl->type = DL_SEGM;
dl->flag = (DL_FRONT_CURVE | DL_BACK_CURVE);
}
dl->parts = 1;
dl->nr = bl->nr;
dl->col = nu->mat_nr;
dl->charidx = nu->charidx;
dl->rt = nu->flag;
int a = dl->nr;
BevPoint *bevp = bl->bevpoints;
data = dl->verts;
while (a--) {
data[0] = bevp->vec[0] + widfac * bevp->sina;
data[1] = bevp->vec[1] + widfac * bevp->cosa;
data[2] = bevp->vec[2];
bevp++;
data += 3;
}
}
else {
ListBase bottom_capbase = {nullptr, nullptr};
ListBase top_capbase = {nullptr, nullptr};
float bottom_no[3] = {0.0f};
float top_no[3] = {0.0f};
float first_blend = 0.0f, last_blend = 0.0f;
int start, steps = 0;
if (nu->flagu & CU_NURB_CYCLIC) {
calc_bevfac_mapping_default(bl, &start, &first_blend, &steps, &last_blend);
}
else {
if (fabsf(cu->bevfac2 - cu->bevfac1) < FLT_EPSILON) {
continue;
}
calc_bevfac_mapping(cu, bl, nu, &start, &first_blend, &steps, &last_blend);
}
LISTBASE_FOREACH (DispList *, dlb, &dlbev) {
/* for each part of the bevel use a separate displblock */
DispList *dl = MEM_cnew<DispList>(__func__);
dl->verts = data = (float *)MEM_mallocN(sizeof(float[3]) * dlb->nr * steps, __func__);
BLI_addtail(r_dispbase, dl);
dl->type = DL_SURF;
dl->flag = dlb->flag & (DL_FRONT_CURVE | DL_BACK_CURVE);
if (dlb->type == DL_POLY) {
dl->flag |= DL_CYCL_U;
}
if ((bl->poly >= 0) && (steps > 2)) {
dl->flag |= DL_CYCL_V;
}
dl->parts = steps;
dl->nr = dlb->nr;
dl->col = nu->mat_nr;
dl->charidx = nu->charidx;
dl->rt = nu->flag;
/* for each point of poly make a bevel piece */
BevPoint *bevp_first = bl->bevpoints;
BevPoint *bevp_last = &bl->bevpoints[bl->nr - 1];
BevPoint *bevp = &bl->bevpoints[start];
for (int i = start, a = 0; a < steps; i++, bevp++, a++) {
float radius_factor = 1.0;
float *cur_data = data;
if (cu->taperobj == nullptr) {
radius_factor = bevp->radius;
}
else {
float taper_factor;
if (cu->flag & CU_MAP_TAPER) {
float len = (steps - 3) + first_blend + last_blend;
if (a == 0) {
taper_factor = 0.0f;
}
else if (a == steps - 1) {
taper_factor = 1.0f;
}
else {
taper_factor = ((float)a - (1.0f - first_blend)) / len;
}
}
else {
float len = bl->nr - 1;
taper_factor = (float)i / len;
if (a == 0) {
taper_factor += (1.0f - first_blend) / len;
}
else if (a == steps - 1) {
taper_factor -= (1.0f - last_blend) / len;
}
}
radius_factor = displist_calc_taper(depsgraph, scene, cu->taperobj, taper_factor);
if (cu->taper_radius_mode == CU_TAPER_RADIUS_MULTIPLY) {
radius_factor *= bevp->radius;
}
else if (cu->taper_radius_mode == CU_TAPER_RADIUS_ADD) {
radius_factor += bevp->radius;
}
}
/* rotate bevel piece and write in data */
if ((a == 0) && (bevp != bevp_last)) {
rotateBevelPiece(
cu, bevp, bevp + 1, dlb, 1.0f - first_blend, widfac, radius_factor, &data);
}
else if ((a == steps - 1) && (bevp != bevp_first)) {
rotateBevelPiece(
cu, bevp, bevp - 1, dlb, 1.0f - last_blend, widfac, radius_factor, &data);
}
else {
rotateBevelPiece(cu, bevp, nullptr, dlb, 0.0f, widfac, radius_factor, &data);
}
if ((cu->flag & CU_FILL_CAPS) && !(nu->flagu & CU_NURB_CYCLIC)) {
if (a == 1) {
fillBevelCap(nu, dlb, cur_data - 3 * dlb->nr, &bottom_capbase);
copy_v3_v3(bottom_no, bevp->dir);
}
if (a == steps - 1) {
fillBevelCap(nu, dlb, cur_data, &top_capbase);
negate_v3_v3(top_no, bevp->dir);
}
}
}
/* gl array drawing: using indices */
displist_surf_indices(dl);
}
if (bottom_capbase.first) {
BKE_displist_fill(&bottom_capbase, r_dispbase, bottom_no, false);
BKE_displist_fill(&top_capbase, r_dispbase, top_no, false);
BKE_displist_free(&bottom_capbase);
BKE_displist_free(&top_capbase);
}
}
}
}
BKE_displist_free(&dlbev);
curve_to_filledpoly(cu, r_dispbase);
return curve_calc_modifiers_post(depsgraph, scene, ob, r_dispbase, for_render);
}
void BKE_displist_make_curveTypes(Depsgraph *depsgraph,
const Scene *scene,
Object *ob,
const bool for_render)
{
BLI_assert(ELEM(ob->type, OB_SURF, OB_CURVES_LEGACY, OB_FONT));
BKE_object_free_derived_caches(ob);
/* It's important to retrieve this after calling #BKE_object_free_derived_caches,
* which may reset the object data pointer in some cases. */
const Curve &original_curve = *static_cast<const Curve *>(ob->data);
ob->runtime.curve_cache = MEM_cnew<CurveCache>(__func__);
ListBase *dispbase = &ob->runtime.curve_cache->disp;
if (ob->type == OB_SURF) {
GeometrySet geometry = evaluate_surface_object(depsgraph, scene, ob, for_render, dispbase);
ob->runtime.geometry_set_eval = new GeometrySet(std::move(geometry));
}
else {
GeometrySet geometry = evaluate_curve_type_object(depsgraph, scene, ob, for_render, dispbase);
if (geometry.has_curves()) {
/* Create a copy of the original curve and add necessary pointers to evaluated and edit mode
* data. This is needed for a few reasons:
* - Existing code from before curve evaluation was changed to use #GeometrySet expected to
* have a copy of the original curve data. (Any evaluated data was placed in
* #Object.runtime.curve_cache).
* - The result of modifier evaluation is not a #Curve data-block but a #Curves data-block,
* which can support constructive modifiers and geometry nodes.
* - The dependency graph has handling of edit mode pointers (see #update_edit_mode_pointers)
* but it doesn't seem to work in this case.
*
* Since the the plan is to replace this legacy curve object with the curves data-block
* (see T95355), this somewhat hacky inefficient solution is relatively temporary.
*/
Curve &cow_curve = *reinterpret_cast<Curve *>(
BKE_id_copy_ex(nullptr, &original_curve.id, nullptr, LIB_ID_COPY_LOCALIZE));
cow_curve.curve_eval = geometry.get_curves_for_read();
/* Copy edit mode pointers necessary for drawing to the duplicated curve. */
cow_curve.editnurb = original_curve.editnurb;
cow_curve.editfont = original_curve.editfont;
cow_curve.edit_data_from_original = true;
BKE_object_eval_assign_data(ob, &cow_curve.id, true);
}
ob->runtime.geometry_set_eval = new GeometrySet(std::move(geometry));
}
BKE_object_boundbox_calc_from_evaluated_geometry(ob);
}
void BKE_displist_minmax(const ListBase *dispbase, float min[3], float max[3])
{
bool doit = false;
LISTBASE_FOREACH (const DispList *, dl, dispbase) {
const int tot = (ELEM(dl->type, DL_INDEX3, DL_INDEX4)) ? dl->nr : dl->nr * dl->parts;
for (const int i : IndexRange(tot)) {
minmax_v3v3_v3(min, max, &dl->verts[i * 3]);
}
if (tot != 0) {
doit = true;
}
}
if (!doit) {
/* there's no geometry in displist, use zero-sized boundbox */
zero_v3(min);
zero_v3(max);
}
}
Reference in New Issue View Git Blame Copy Permalink