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test/source/blender/blenkernel/intern/displist.c
Sergey Sharybin d9637fb3be Fix T38745: Curve parent crash when rendering animation 
Issue was caused by curve orco calculation for rendering being freed
curve path and not calculating it back.

This left depsgraph in a state that it believed all the object data
is up to date but in fact some parts of data was freed by convert
blender.

Now made it so path is not being freed by render thread. This is
rather a workaround actually because ideally render thread need
to use copy-on-write here or at least use local cache here. But
current logic should be closer to what was happening in previous
release.
2014-02-25 13:27:46 +06:00

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/*
* ***** 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) 2001-2002 by NaN Holding BV.
* All rights reserved.
*
* The Original Code is: all of this file.
*
* Contributor(s): none yet.
*
* ***** END GPL LICENSE BLOCK *****
*/
/** \file blender/blenkernel/intern/displist.c
* \ingroup bke
*/
#include <math.h>
#include <stdio.h>
#include <string.h>
#include "MEM_guardedalloc.h"
#include "DNA_curve_types.h"
#include "DNA_meshdata_types.h"
#include "DNA_scene_types.h"
#include "DNA_object_types.h"
#include "DNA_material_types.h"
#include "DNA_vfont_types.h"
#include "BLI_blenlib.h"
#include "BLI_memarena.h"
#include "BLI_math.h"
#include "BLI_scanfill.h"
#include "BLI_utildefines.h"
#include "BKE_global.h"
#include "BKE_depsgraph.h"
#include "BKE_displist.h"
#include "BKE_cdderivedmesh.h"
#include "BKE_object.h"
#include "BKE_main.h"
#include "BKE_mball.h"
#include "BKE_material.h"
#include "BKE_curve.h"
#include "BKE_key.h"
#include "BKE_anim.h"
#include "BKE_font.h"
#include "BKE_lattice.h"
#include "BKE_modifier.h"
#include "BLI_sys_types.h" // for intptr_t support
static void boundbox_displist_object(Object *ob);
void BKE_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);
if (dl->col1) MEM_freeN(dl->col1);
if (dl->col2) MEM_freeN(dl->col2);
if (dl->bevelSplitFlag) MEM_freeN(dl->bevelSplitFlag);
MEM_freeN(dl);
}
}
void BKE_displist_free(ListBase *lb)
{
DispList *dl;
while ((dl = BLI_pophead(lb))) {
BKE_displist_elem_free(dl);
}
}
DispList *BKE_displist_find_or_create(ListBase *lb, int type)
{
DispList *dl;
dl = lb->first;
while (dl) {
if (dl->type == type)
return dl;
dl = dl->next;
}
dl = MEM_callocN(sizeof(DispList), "find_disp");
dl->type = type;
BLI_addtail(lb, dl);
return dl;
}
DispList *BKE_displist_find(ListBase *lb, int type)
{
DispList *dl;
dl = lb->first;
while (dl) {
if (dl->type == type)
return dl;
dl = dl->next;
}
return NULL;
}
bool BKE_displist_has_faces(ListBase *lb)
{
DispList *dl;
for (dl = lb->first; dl; dl = dl->next) {
if (ELEM3(dl->type, DL_INDEX3, DL_INDEX4, DL_SURF)) {
return true;
}
}
return false;
}
void BKE_displist_copy(ListBase *lbn, ListBase *lb)
{
DispList *dln, *dl;
BKE_displist_free(lbn);
dl = lb->first;
while (dl) {
dln = MEM_dupallocN(dl);
BLI_addtail(lbn, dln);
dln->verts = MEM_dupallocN(dl->verts);
dln->nors = MEM_dupallocN(dl->nors);
dln->index = MEM_dupallocN(dl->index);
dln->col1 = MEM_dupallocN(dl->col1);
dln->col2 = MEM_dupallocN(dl->col2);
if (dl->bevelSplitFlag)
dln->bevelSplitFlag = MEM_dupallocN(dl->bevelSplitFlag);
dl = dl->next;
}
}
void BKE_displist_normals_add(ListBase *lb)
{
DispList *dl = NULL;
float *vdata, *ndata, nor[3];
float *v1, *v2, *v3, *v4;
float *n1, *n2, *n3, *n4;
int a, b, p1, p2, p3, p4;
dl = lb->first;
while (dl) {
if (dl->type == DL_INDEX3) {
if (dl->nors == NULL) {
dl->nors = MEM_callocN(sizeof(float) * 3, "dlnors");
if (dl->verts[2] < 0.0f)
dl->nors[2] = -1.0f;
else
dl->nors[2] = 1.0f;
}
}
else if (dl->type == DL_SURF) {
if (dl->nors == NULL) {
dl->nors = MEM_callocN(sizeof(float) * 3 * dl->nr * dl->parts, "dlnors");
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;
}
}
}
dl = dl->next;
}
}
void BKE_displist_count(ListBase *lb, int *totvert, int *totface, int *tottri)
{
DispList *dl;
for (dl = lb->first; dl; dl = dl->next) {
int vert_tot = 0;
int face_tot = 0;
int tri_tot = 0;
switch (dl->type) {
case DL_SURF:
{
vert_tot = dl->nr * dl->parts;
face_tot = (dl->nr - 1) * (dl->parts - 1);
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(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 displists ********************* */
static void curve_to_displist(Curve *cu, ListBase *nubase, ListBase *dispbase, int forRender, int renderResolution)
{
Nurb *nu;
DispList *dl;
BezTriple *bezt, *prevbezt;
BPoint *bp;
float *data;
int a, len, resolu;
const int editmode = (!forRender && (cu->editnurb || cu->editfont));
nu = nubase->first;
while (nu) {
if (nu->hide == 0 || editmode == 0) {
if (renderResolution && cu->resolu_ren != 0)
resolu = cu->resolu_ren;
else
resolu = nu->resolu;
if (!BKE_nurb_check_valid_u(nu)) {
/* pass */
}
else if (nu->type == CU_BEZIER) {
/* count */
len = 0;
a = nu->pntsu - 1;
if (nu->flagu & CU_NURB_CYCLIC) a++;
prevbezt = nu->bezt;
bezt = prevbezt + 1;
while (a--) {
if (a == 0 && (nu->flagu & CU_NURB_CYCLIC))
bezt = nu->bezt;
if (prevbezt->h2 == HD_VECT && bezt->h1 == HD_VECT)
len++;
else
len += resolu;
if (a == 0 && (nu->flagu & CU_NURB_CYCLIC) == 0)
len++;
prevbezt = bezt;
bezt++;
}
dl = MEM_callocN(sizeof(DispList), "makeDispListbez");
/* len+1 because of 'forward_diff_bezier' function */
dl->verts = MEM_callocN((len + 1) * 3 * sizeof(float), "dlverts");
BLI_addtail(dispbase, dl);
dl->parts = 1;
dl->nr = len;
dl->col = nu->mat_nr;
dl->charidx = nu->charidx;
data = dl->verts;
if (nu->flagu & CU_NURB_CYCLIC) {
dl->type = DL_POLY;
a = nu->pntsu;
}
else {
dl->type = DL_SEGM;
a = nu->pntsu - 1;
}
prevbezt = nu->bezt;
bezt = prevbezt + 1;
while (a--) {
if (a == 0 && dl->type == DL_POLY)
bezt = nu->bezt;
if (prevbezt->h2 == HD_VECT && bezt->h1 == HD_VECT) {
copy_v3_v3(data, prevbezt->vec[1]);
data += 3;
}
else {
int j;
for (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, resolu, 3 * sizeof(float));
}
data += 3 * resolu;
}
if (a == 0 && dl->type == DL_SEGM) {
copy_v3_v3(data, bezt->vec[1]);
}
prevbezt = bezt;
bezt++;
}
}
else if (nu->type == CU_NURBS) {
len = (resolu * SEGMENTSU(nu));
dl = MEM_callocN(sizeof(DispList), "makeDispListsurf");
dl->verts = MEM_callocN(len * 3 * sizeof(float), "dlverts");
BLI_addtail(dispbase, dl);
dl->parts = 1;
dl->nr = len;
dl->col = nu->mat_nr;
dl->charidx = nu->charidx;
data = dl->verts;
if (nu->flagu & CU_NURB_CYCLIC)
dl->type = DL_POLY;
else dl->type = DL_SEGM;
BKE_nurb_makeCurve(nu, data, NULL, NULL, NULL, resolu, 3 * sizeof(float));
}
else if (nu->type == CU_POLY) {
len = nu->pntsu;
dl = MEM_callocN(sizeof(DispList), "makeDispListpoly");
dl->verts = MEM_callocN(len * 3 * sizeof(float), "dlverts");
BLI_addtail(dispbase, dl);
dl->parts = 1;
dl->nr = len;
dl->col = nu->mat_nr;
dl->charidx = nu->charidx;
data = dl->verts;
if (nu->flagu & CU_NURB_CYCLIC) dl->type = DL_POLY;
else dl->type = DL_SEGM;
a = len;
bp = nu->bp;
while (a--) {
copy_v3_v3(data, bp->vec);
bp++;
data += 3;
}
}
}
nu = nu->next;
}
}
/**
* \param normal_proj Optional normal thats used to project the scanfill verts into 2d coords.
* Pass this along if known since it saves time calculating the normal.
* \param flipnormal Flip the normal (same as passing \a normal_proj negated)
*/
void BKE_displist_fill(ListBase *dispbase, ListBase *to, const float normal_proj[3], const bool flipnormal)
{
ScanFillContext sf_ctx;
ScanFillVert *sf_vert, *sf_vert_new, *sf_vert_last;
ScanFillFace *sf_tri;
MemArena *sf_arena;
DispList *dlnew = NULL, *dl;
float *f1;
int colnr = 0, charidx = 0, cont = 1, tot, a, *index, nextcol = 0;
int totvert;
const int scanfill_flag = BLI_SCANFILL_CALC_REMOVE_DOUBLES | BLI_SCANFILL_CALC_POLYS | BLI_SCANFILL_CALC_HOLES;
if (dispbase == NULL)
return;
if (BLI_listbase_is_empty(dispbase))
return;
sf_arena = BLI_memarena_new(BLI_SCANFILL_ARENA_SIZE, __func__);
while (cont) {
cont = 0;
totvert = 0;
nextcol = 0;
BLI_scanfill_begin_arena(&sf_ctx, sf_arena);
dl = dispbase->first;
while (dl) {
if (dl->type == DL_POLY) {
if (charidx < dl->charidx)
cont = 1;
else if (charidx == dl->charidx) { /* character with needed index */
if (colnr == dl->col) {
sf_ctx.poly_nr++;
/* make editverts and edges */
f1 = dl->verts;
a = dl->nr;
sf_vert = sf_vert_new = NULL;
while (a--) {
sf_vert_last = sf_vert;
sf_vert = BLI_scanfill_vert_add(&sf_ctx, f1);
totvert++;
if (sf_vert_last == NULL)
sf_vert_new = sf_vert;
else {
BLI_scanfill_edge_add(&sf_ctx, sf_vert_last, sf_vert);
}
f1 += 3;
}
if (sf_vert != NULL && sf_vert_new != NULL) {
BLI_scanfill_edge_add(&sf_ctx, sf_vert, sf_vert_new);
}
}
else if (colnr < dl->col) {
/* got poly with next material at current char */
cont = 1;
nextcol = 1;
}
}
}
dl = dl->next;
}
/* XXX (obedit && obedit->actcol) ? (obedit->actcol-1) : 0)) { */
if (totvert && (tot = BLI_scanfill_calc_ex(&sf_ctx,
scanfill_flag,
normal_proj)))
{
if (tot) {
dlnew = MEM_callocN(sizeof(DispList), "filldisplist");
dlnew->type = DL_INDEX3;
dlnew->col = colnr;
dlnew->nr = totvert;
dlnew->parts = tot;
dlnew->index = MEM_mallocN(tot * 3 * sizeof(int), "dlindex");
dlnew->verts = MEM_mallocN(totvert * 3 * sizeof(float), "dlverts");
/* vert data */
f1 = dlnew->verts;
totvert = 0;
for (sf_vert = sf_ctx.fillvertbase.first; sf_vert; sf_vert = sf_vert->next) {
copy_v3_v3(f1, sf_vert->co);
f1 += 3;
/* index number */
sf_vert->tmp.i = totvert;
totvert++;
}
/* index data */
index = dlnew->index;
for (sf_tri = sf_ctx.fillfacebase.first; sf_tri; sf_tri = sf_tri->next) {
index[0] = sf_tri->v1->tmp.i;
index[1] = sf_tri->v2->tmp.i;
index[2] = sf_tri->v3->tmp.i;
if (flipnormal)
SWAP(int, index[0], index[2]);
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(Curve *cu, ListBase *dispbase)
{
const float z_up[3] = {0.0f, 0.0f, 1.0f};
ListBase front, back;
DispList *dl, *dlnew;
float *fp, *fp1;
int a, dpoly;
BLI_listbase_clear(&front);
BLI_listbase_clear(&back);
dl = dispbase->first;
while (dl) {
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)) {
dlnew = MEM_callocN(sizeof(DispList), "filldisp");
BLI_addtail(&front, dlnew);
dlnew->verts = fp1 = MEM_mallocN(sizeof(float) * 3 * dl->parts, "filldisp1");
dlnew->nr = dl->parts;
dlnew->parts = 1;
dlnew->type = DL_POLY;
dlnew->col = dl->col;
dlnew->charidx = dl->charidx;
fp = dl->verts;
dpoly = 3 * dl->nr;
a = dl->parts;
while (a--) {
copy_v3_v3(fp1, fp);
fp1 += 3;
fp += dpoly;
}
}
if ((cu->flag & CU_FRONT) && (dl->flag & DL_FRONT_CURVE)) {
dlnew = MEM_callocN(sizeof(DispList), "filldisp");
BLI_addtail(&back, dlnew);
dlnew->verts = fp1 = MEM_mallocN(sizeof(float) * 3 * dl->parts, "filldisp1");
dlnew->nr = dl->parts;
dlnew->parts = 1;
dlnew->type = DL_POLY;
dlnew->col = dl->col;
dlnew->charidx = dl->charidx;
fp = dl->verts + 3 * (dl->nr - 1);
dpoly = 3 * dl->nr;
a = dl->parts;
while (a--) {
copy_v3_v3(fp1, fp);
fp1 += 3;
fp += dpoly;
}
}
}
}
dl = dl->next;
}
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(Curve *cu, ListBase *UNUSED(nurb), ListBase *dispbase)
{
if (!CU_DO_2DFILL(cu))
return;
if (dispbase->first && ((DispList *) dispbase->first)->type == DL_SURF) {
bevels_to_filledpoly(cu, dispbase);
}
else {
/* TODO, investigate passing zup instead of NULL */
BKE_displist_fill(dispbase, dispbase, NULL, 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(Scene *scene, Object *taperobj, float fac)
{
DispList *dl;
if (taperobj == NULL || taperobj->type != OB_CURVE)
return 1.0;
dl = taperobj->curve_cache ? taperobj->curve_cache->disp.first : NULL;
if (dl == NULL) {
BKE_displist_make_curveTypes(scene, taperobj, 0);
dl = taperobj->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 coord
}
}
return 1.0;
}
float BKE_displist_calc_taper(Scene *scene, Object *taperobj, int cur, int tot)
{
float fac = ((float)cur) / (float)(tot - 1);
return displist_calc_taper(scene, taperobj, fac);
}
void BKE_displist_make_mball(EvaluationContext *eval_ctx, Scene *scene, Object *ob)
{
if (!ob || ob->type != OB_MBALL)
return;
if (ob->curve_cache) {
BKE_displist_free(&(ob->curve_cache->disp));
}
else {
ob->curve_cache = MEM_callocN(sizeof(CurveCache), "CurveCache for MBall");
}
if (ob->type == OB_MBALL) {
if (ob == BKE_mball_basis_find(scene, ob)) {
BKE_mball_polygonize(eval_ctx, scene, ob, &ob->curve_cache->disp);
BKE_mball_texspace_calc(ob);
object_deform_mball(ob, &ob->curve_cache->disp);
}
boundbox_displist_object(ob);
}
}
void BKE_displist_make_mball_forRender(EvaluationContext *eval_ctx, Scene *scene, Object *ob, ListBase *dispbase)
{
BKE_mball_polygonize(eval_ctx, scene, ob, dispbase);
BKE_mball_texspace_calc(ob);
object_deform_mball(ob, dispbase);
}
static ModifierData *curve_get_tessellate_point(Scene *scene, Object *ob, int renderResolution, int editmode)
{
VirtualModifierData virtualModifierData;
ModifierData *md = modifiers_getVirtualModifierList(ob, &virtualModifierData);
ModifierData *pretessellatePoint;
int required_mode;
if (renderResolution)
required_mode = eModifierMode_Render;
else
required_mode = eModifierMode_Realtime;
if (editmode)
required_mode |= eModifierMode_Editmode;
pretessellatePoint = NULL;
for (; md; md = md->next) {
ModifierTypeInfo *mti = modifierType_getInfo(md->type);
if (!modifier_isEnabled(scene, md, required_mode))
continue;
if (mti->type == eModifierTypeType_Constructive)
return pretessellatePoint;
if (ELEM3(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;
}
static void curve_calc_modifiers_pre(Scene *scene, Object *ob, ListBase *nurb,
int forRender, int renderResolution)
{
VirtualModifierData virtualModifierData;
ModifierData *md = modifiers_getVirtualModifierList(ob, &virtualModifierData);
ModifierData *pretessellatePoint;
Curve *cu = ob->data;
int numVerts = 0;
const int editmode = (!forRender && (cu->editnurb || cu->editfont));
ModifierApplyFlag app_flag = 0;
float (*deformedVerts)[3] = NULL;
float *keyVerts = NULL;
int required_mode;
modifiers_clearErrors(ob);
if (editmode)
app_flag |= MOD_APPLY_USECACHE;
if (renderResolution) {
app_flag |= MOD_APPLY_RENDER;
required_mode = eModifierMode_Render;
}
else
required_mode = eModifierMode_Realtime;
pretessellatePoint = curve_get_tessellate_point(scene, ob, renderResolution, editmode);
if (editmode)
required_mode |= eModifierMode_Editmode;
if (cu->editnurb == NULL) {
keyVerts = BKE_key_evaluate_object(scene, ob, &numVerts);
if (keyVerts) {
/* 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_keyVertexCos_get(nurb, keyVerts);
BLI_assert(BKE_nurbList_verts_count(nurb) == numVerts);
}
}
if (pretessellatePoint) {
for (; md; md = md->next) {
ModifierTypeInfo *mti = modifierType_getInfo(md->type);
md->scene = scene;
if (!modifier_isEnabled(scene, md, required_mode))
continue;
if (mti->type != eModifierTypeType_OnlyDeform)
continue;
if (!deformedVerts) {
deformedVerts = BKE_curve_nurbs_vertexCos_get(nurb, &numVerts);
}
mti->deformVerts(md, ob, NULL, deformedVerts, numVerts, app_flag);
if (md == pretessellatePoint)
break;
}
}
if (deformedVerts) {
BK_curve_nurbs_vertexCos_apply(nurb, deformedVerts);
MEM_freeN(deformedVerts);
}
if (keyVerts) /* these are not passed through modifier stack */
BKE_curve_nurbs_keyVertexTilts_apply(nurb, keyVerts);
if (keyVerts)
MEM_freeN(keyVerts);
}
static float (*displist_get_allverts(ListBase *dispbase, int *totvert))[3]
{
DispList *dl;
float (*allverts)[3], *fp;
*totvert = 0;
for (dl = dispbase->first; dl; dl = dl->next)
*totvert += (dl->type == DL_INDEX3) ? dl->nr : dl->parts * dl->nr;
allverts = MEM_mallocN((*totvert) * sizeof(float) * 3, "displist_get_allverts allverts");
fp = (float *)allverts;
for (dl = dispbase->first; dl; dl = dl->next) {
int offs = 3 * ((dl->type == DL_INDEX3) ? dl->nr : dl->parts * dl->nr);
memcpy(fp, dl->verts, sizeof(float) * offs);
fp += offs;
}
return allverts;
}
static void displist_apply_allverts(ListBase *dispbase, float (*allverts)[3])
{
DispList *dl;
float *fp;
fp = (float *)allverts;
for (dl = dispbase->first; dl; dl = dl->next) {
int offs = 3 * ((dl->type == DL_INDEX3) ? dl->nr : dl->parts * dl->nr);
memcpy(dl->verts, fp, sizeof(float) * offs);
fp += offs;
}
}
static void curve_calc_modifiers_post(Scene *scene, Object *ob, ListBase *nurb,
ListBase *dispbase, DerivedMesh **derivedFinal,
int forRender, int renderResolution)
{
VirtualModifierData virtualModifierData;
ModifierData *md = modifiers_getVirtualModifierList(ob, &virtualModifierData);
ModifierData *pretessellatePoint;
Curve *cu = ob->data;
int required_mode = 0, totvert = 0;
int editmode = (!forRender && (cu->editnurb || cu->editfont));
DerivedMesh *dm = NULL, *ndm;
float (*vertCos)[3] = NULL;
int useCache = !forRender;
ModifierApplyFlag app_flag = 0;
if (renderResolution) {
app_flag |= MOD_APPLY_RENDER;
required_mode = eModifierMode_Render;
}
else
required_mode = eModifierMode_Realtime;
pretessellatePoint = curve_get_tessellate_point(scene, ob, renderResolution, editmode);
if (editmode)
required_mode |= eModifierMode_Editmode;
if (pretessellatePoint) {
md = pretessellatePoint->next;
}
if (derivedFinal && *derivedFinal) {
(*derivedFinal)->release(*derivedFinal);
}
for (; md; md = md->next) {
ModifierTypeInfo *mti = modifierType_getInfo(md->type);
ModifierApplyFlag appf = app_flag;
md->scene = scene;
if (!modifier_isEnabled(scene, md, required_mode))
continue;
if (mti->type == eModifierTypeType_OnlyDeform ||
(mti->type == eModifierTypeType_DeformOrConstruct && !dm))
{
if (editmode)
appf |= MOD_APPLY_USECACHE;
if (dm) {
if (!vertCos) {
totvert = dm->getNumVerts(dm);
vertCos = MEM_mallocN(sizeof(*vertCos) * totvert, "dfmv");
dm->getVertCos(dm, vertCos);
}
mti->deformVerts(md, ob, dm, vertCos, totvert, appf);
}
else {
if (!vertCos) {
vertCos = displist_get_allverts(dispbase, &totvert);
}
mti->deformVerts(md, ob, NULL, vertCos, totvert, appf);
}
}
else {
if (!derivedFinal) {
/* makeDisplistCurveTypes could be used for beveling, where derived mesh
* is totally unnecessary, so we could stop modifiers applying
* when we found constructive modifier but derived mesh is unwanted result
*/
break;
}
if (dm) {
if (vertCos) {
DerivedMesh *tdm = CDDM_copy(dm);
dm->release(dm);
dm = tdm;
CDDM_apply_vert_coords(dm, vertCos);
}
}
else {
if (vertCos) {
displist_apply_allverts(dispbase, vertCos);
}
if (ELEM(ob->type, OB_CURVE, OB_FONT) && (cu->flag & CU_DEFORM_FILL)) {
curve_to_filledpoly(cu, nurb, dispbase);
}
dm = CDDM_from_curve_displist(ob, dispbase);
}
if (vertCos) {
/* Vertex coordinates were applied to necessary data, could free it */
MEM_freeN(vertCos);
vertCos = NULL;
}
if (useCache)
appf |= MOD_APPLY_USECACHE;
ndm = modwrap_applyModifier(md, ob, dm, appf);
if (ndm) {
/* Modifier returned a new derived mesh */
if (dm && dm != ndm) /* Modifier */
dm->release(dm);
dm = ndm;
}
}
}
if (vertCos) {
if (dm) {
DerivedMesh *tdm = CDDM_copy(dm);
dm->release(dm);
dm = tdm;
CDDM_apply_vert_coords(dm, vertCos);
CDDM_calc_normals_mapping(dm);
MEM_freeN(vertCos);
}
else {
displist_apply_allverts(dispbase, vertCos);
MEM_freeN(vertCos);
vertCos = NULL;
}
}
if (derivedFinal) {
if (dm) {
/* see: mesh_calc_modifiers */
if (dm->getNumTessFaces(dm) == 0) {
dm->recalcTessellation(dm);
}
/* Even if tessellation is not needed, some modifiers might have modified CD layers
* (like mloopcol or mloopuv), hence we have to update those. */
else if (dm->dirty & DM_DIRTY_TESS_CDLAYERS) {
DM_update_tessface_data(dm);
}
if (dm->type == DM_TYPE_CDDM) {
CDDM_calc_normals_mapping_ex(dm, (dm->dirty & DM_DIRTY_NORMALS) ? false : true);
}
}
(*derivedFinal) = dm;
}
}
static void displist_surf_indices(DispList *dl)
{
int a, b, p1, p2, p3, p4;
int *index;
dl->totindex = 0;
index = dl->index = MEM_mallocN(4 * sizeof(int) * (dl->parts + 1) * (dl->nr + 1), "index array nurbs");
for (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 DerivedMesh *create_orco_dm(Scene *scene, Object *ob)
{
DerivedMesh *dm;
ListBase disp = {NULL, NULL};
/* OrcoDM should be created from underformed disp lists */
BKE_displist_make_curveTypes_forOrco(scene, ob, &disp);
dm = CDDM_from_curve_displist(ob, &disp);
BKE_displist_free(&disp);
return dm;
}
static void add_orco_dm(Object *ob, DerivedMesh *dm, DerivedMesh *orcodm)
{
float (*orco)[3], (*layerorco)[3];
int totvert, a;
Curve *cu = ob->data;
totvert = dm->getNumVerts(dm);
orco = MEM_callocN(sizeof(float) * 3 * totvert, "dm orco");
if (orcodm->getNumVerts(orcodm) == totvert)
orcodm->getVertCos(orcodm, orco);
else
dm->getVertCos(dm, orco);
for (a = 0; a < totvert; a++) {
float *co = orco[a];
co[0] = (co[0] - cu->loc[0]) / cu->size[0];
co[1] = (co[1] - cu->loc[1]) / cu->size[1];
co[2] = (co[2] - cu->loc[2]) / cu->size[2];
}
if ((layerorco = DM_get_vert_data_layer(dm, CD_ORCO))) {
memcpy(layerorco, orco, sizeof(float) * totvert);
MEM_freeN(orco);
}
else
DM_add_vert_layer(dm, CD_ORCO, CD_ASSIGN, orco);
}
static void curve_calc_orcodm(Scene *scene, Object *ob, DerivedMesh *derivedFinal, int forRender, int renderResolution)
{
/* this function represents logic of mesh's orcodm calculation
* for displist-based objects
*/
VirtualModifierData virtualModifierData;
ModifierData *md = modifiers_getVirtualModifierList(ob, &virtualModifierData);
ModifierData *pretessellatePoint;
Curve *cu = ob->data;
int required_mode;
int editmode = (!forRender && (cu->editnurb || cu->editfont));
DerivedMesh *ndm, *orcodm = NULL;
ModifierApplyFlag app_flag = MOD_APPLY_ORCO;
if (renderResolution) {
app_flag |= MOD_APPLY_RENDER;
required_mode = eModifierMode_Render;
}
else
required_mode = eModifierMode_Realtime;
pretessellatePoint = curve_get_tessellate_point(scene, ob, renderResolution, editmode);
if (editmode)
required_mode |= eModifierMode_Editmode;
if (pretessellatePoint) {
md = pretessellatePoint->next;
}
/* If modifiers are disabled, we wouldn't be here because
* this function is only called if there're enabled constructive
* modifiers applied on the curve.
*
* This means we can create ORCO DM in advance and assume it's
* never NULL.
*/
orcodm = create_orco_dm(scene, ob);
for (; md; md = md->next) {
ModifierTypeInfo *mti = modifierType_getInfo(md->type);
md->scene = scene;
if (!modifier_isEnabled(scene, md, required_mode))
continue;
if (mti->type != eModifierTypeType_Constructive)
continue;
ndm = modwrap_applyModifier(md, ob, orcodm, app_flag);
if (ndm) {
/* if the modifier returned a new dm, release the old one */
if (orcodm && orcodm != ndm) {
orcodm->release(orcodm);
}
orcodm = ndm;
}
}
/* add an orco layer if needed */
add_orco_dm(ob, derivedFinal, orcodm);
orcodm->release(orcodm);
}
void BKE_displist_make_surf(Scene *scene, Object *ob, ListBase *dispbase,
DerivedMesh **derivedFinal, int forRender, int forOrco, int renderResolution)
{
ListBase nubase = {NULL, NULL};
Nurb *nu;
Curve *cu = ob->data;
DispList *dl;
float *data;
int len;
if (!forRender && cu->editnurb) {
BKE_nurbList_duplicate(&nubase, BKE_curve_editNurbs_get(cu));
}
else {
BKE_nurbList_duplicate(&nubase, &cu->nurb);
}
if (!forOrco)
curve_calc_modifiers_pre(scene, ob, &nubase, forRender, renderResolution);
for (nu = nubase.first; nu; nu = nu->next) {
if (forRender || nu->hide == 0) {
int resolu = nu->resolu, resolv = nu->resolv;
if (renderResolution) {
if (cu->resolu_ren)
resolu = cu->resolu_ren;
if (cu->resolv_ren)
resolv = cu->resolv_ren;
}
if (nu->pntsv == 1) {
len = SEGMENTSU(nu) * resolu;
dl = MEM_callocN(sizeof(DispList), "makeDispListsurf");
dl->verts = MEM_callocN(len * 3 * sizeof(float), "dlverts");
BLI_addtail(dispbase, dl);
dl->parts = 1;
dl->nr = len;
dl->col = nu->mat_nr;
dl->charidx = nu->charidx;
/* dl->rt will be used as flag for render face and */
/* CU_2D conflicts with R_NOPUNOFLIP */
dl->rt = nu->flag & ~CU_2D;
data = dl->verts;
if (nu->flagu & CU_NURB_CYCLIC) dl->type = DL_POLY;
else dl->type = DL_SEGM;
BKE_nurb_makeCurve(nu, data, NULL, NULL, NULL, resolu, 3 * sizeof(float));
}
else {
len = (nu->pntsu * resolu) * (nu->pntsv * resolv);
dl = MEM_callocN(sizeof(DispList), "makeDispListsurf");
dl->verts = MEM_callocN(len * 3 * sizeof(float), "dlverts");
BLI_addtail(dispbase, dl);
dl->col = nu->mat_nr;
dl->charidx = nu->charidx;
/* dl->rt will be used as flag for render face and */
/* CU_2D conflicts with R_NOPUNOFLIP */
dl->rt = nu->flag & ~CU_2D;
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);
}
}
}
if (!forOrco) {
curve_calc_modifiers_post(scene, ob, &nubase, dispbase, derivedFinal,
forRender, renderResolution);
}
BKE_nurbList_free(&nubase);
}
static void rotateBevelPiece(Curve *cu, BevPoint *bevp, BevPoint *nbevp, DispList *dlb, float bev_blend, float widfac, float fac, float **data_r)
{
float *fp, *data = *data_r;
int b;
fp = dlb->verts;
for (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 == NULL) {
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] += fac * vec[0];
data[1] += fac * vec[1];
data[2] += fac * vec[2];
}
else {
float sina, cosa;
if (nbevp == NULL) {
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] += fac * (widfac + fp[1]) * sina;
data[1] += fac * (widfac + fp[1]) * cosa;
data[2] += fac * fp[2];
}
}
*data_r = data;
}
static void fillBevelCap(Nurb *nu, DispList *dlb, float *prev_fp, ListBase *dispbase)
{
DispList *dl;
dl = MEM_callocN(sizeof(DispList), "makeDispListbev2");
dl->verts = MEM_mallocN(3 * sizeof(float) * dlb->nr, "dlverts");
memcpy(dl->verts, prev_fp, 3 * sizeof(float) * dlb->nr);
dl->type = DL_POLY;
dl->parts = 1;
dl->nr = dlb->nr;
dl->col = nu->mat_nr;
dl->charidx = nu->charidx;
/* dl->rt will be used as flag for render face and */
/* CU_2D conflicts with R_NOPUNOFLIP */
dl->rt = nu->flag & ~CU_2D;
BLI_addtail(dispbase, dl);
}
static void do_makeDispListCurveTypes(Scene *scene, Object *ob, ListBase *dispbase,
DerivedMesh **derivedFinal, int forRender, int forOrco, int renderResolution)
{
Curve *cu = ob->data;
/* we do allow duplis... this is only displist on curve level */
if (!ELEM3(ob->type, OB_SURF, OB_CURVE, OB_FONT)) return;
if (ob->type == OB_SURF) {
BKE_displist_make_surf(scene, ob, dispbase, derivedFinal, forRender, forOrco, renderResolution);
}
else if (ELEM(ob->type, OB_CURVE, OB_FONT)) {
ListBase dlbev;
ListBase nubase = {NULL, NULL};
BLI_freelistN(&(ob->curve_cache->bev));
/* We only re-evlauate path if evaluation is not happening for orco.
* If the calculation happens for orco, we should never free data which
* was needed before and only not needed for orco calculation.
*/
if (!forOrco) {
if (ob->curve_cache->path) free_path(ob->curve_cache->path);
ob->curve_cache->path = NULL;
}
if (ob->type == OB_FONT) {
BKE_vfont_to_curve_nubase(G.main, ob, FO_EDIT, &nubase);
}
else {
BKE_nurbList_duplicate(&nubase, BKE_curve_nurbs_get(cu));
}
if (!forOrco)
curve_calc_modifiers_pre(scene, ob, &nubase, forRender, renderResolution);
BKE_curve_bevelList_make(ob, &nubase, forRender != FALSE);
/* If curve has no bevel will return nothing */
BKE_curve_bevel_make(scene, ob, &dlbev, forRender, renderResolution);
/* no bevel or extrude, and no width correction? */
if (!dlbev.first && cu->width == 1.0f) {
curve_to_displist(cu, &nubase, dispbase, forRender, renderResolution);
}
else {
float widfac = cu->width - 1.0f;
BevList *bl = ob->curve_cache->bev.first;
Nurb *nu = nubase.first;
for (; bl && nu; bl = bl->next, nu = nu->next) {
DispList *dl;
float *data;
BevPoint *bevp;
int a;
if (bl->nr) { /* blank bevel lists can happen */
/* exception handling; curve without bevel or extrude, with width correction */
if (BLI_listbase_is_empty(&dlbev)) {
dl = MEM_callocN(sizeof(DispList), "makeDispListbev");
dl->verts = MEM_callocN(3 * sizeof(float) * bl->nr, "dlverts");
BLI_addtail(dispbase, dl);
if (bl->poly != -1) dl->type = DL_POLY;
else dl->type = DL_SEGM;
if (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 will be used as flag for render face and */
/* CU_2D conflicts with R_NOPUNOFLIP */
dl->rt = nu->flag & ~CU_2D;
a = dl->nr;
bevp = (BevPoint *)(bl + 1);
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 {
DispList *dlb;
ListBase bottom_capbase = {NULL, NULL};
ListBase top_capbase = {NULL, NULL};
float bottom_no[3] = {0.0f};
float top_no[3] = {0.0f};
for (dlb = dlbev.first; dlb; dlb = dlb->next) {
const float bevfac1 = min_ff(cu->bevfac1, cu->bevfac2);
const float bevfac2 = max_ff(cu->bevfac1, cu->bevfac2);
float firstblend = 0.0f, lastblend = 0.0f;
int i, start, steps;
if (bevfac2 - bevfac1 == 0.0f)
continue;
start = (int)(bevfac1 * (bl->nr - 1));
steps = 2 + (int)((bevfac2) * (bl->nr - 1)) - start;
firstblend = 1.0f - (bevfac1 * (bl->nr - 1) - (int)(bevfac1 * (bl->nr - 1)));
lastblend = bevfac2 * (bl->nr - 1) - (int)(bevfac2 * (bl->nr - 1));
if (start + steps > bl->nr) {
steps = bl->nr - start;
lastblend = 1.0f;
}
/* for each part of the bevel use a separate displblock */
dl = MEM_callocN(sizeof(DispList), "makeDispListbev1");
dl->verts = data = MEM_callocN(3 * sizeof(float) * dlb->nr * steps, "dlverts");
BLI_addtail(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) dl->flag |= DL_CYCL_V;
dl->parts = steps;
dl->nr = dlb->nr;
dl->col = nu->mat_nr;
dl->charidx = nu->charidx;
/* dl->rt will be used as flag for render face and */
/* CU_2D conflicts with R_NOPUNOFLIP */
dl->rt = nu->flag & ~CU_2D;
dl->bevelSplitFlag = MEM_callocN(sizeof(*dl->col2) * ((steps + 0x1F) >> 5),
"bevelSplitFlag");
/* for each point of poly make a bevel piece */
bevp = (BevPoint *)(bl + 1) + start;
for (i = start, a = 0; a < steps; i++, bevp++, a++) {
float fac = 1.0;
float *cur_data = data;
if (cu->taperobj == NULL) {
fac = bevp->radius;
}
else {
float len, taper_fac;
if (cu->flag & CU_MAP_TAPER) {
len = (steps - 3) + firstblend + lastblend;
if (a == 0)
taper_fac = 0.0f;
else if (a == steps - 1)
taper_fac = 1.0f;
else
taper_fac = ((float) a - (1.0f - firstblend)) / len;
}
else {
len = bl->nr - 1;
taper_fac = (float) i / len;
if (a == 0)
taper_fac += (1.0f - firstblend) / len;
else if (a == steps - 1)
taper_fac -= (1.0f - lastblend) / len;
}
fac = displist_calc_taper(scene, cu->taperobj, taper_fac);
}
if (bevp->split_tag) {
dl->bevelSplitFlag[a >> 5] |= 1 << (a & 0x1F);
}
/* rotate bevel piece and write in data */
if (a == 0)
rotateBevelPiece(cu, bevp, bevp + 1, dlb, 1.0f - firstblend, widfac, fac, &data);
else if (a == steps - 1)
rotateBevelPiece(cu, bevp, bevp - 1, dlb, 1.0f - lastblend, widfac, fac, &data);
else
rotateBevelPiece(cu, bevp, NULL, dlb, 0.0f, widfac, fac, &data);
if (cu->bevobj && (cu->flag & CU_FILL_CAPS) && !(nu->flagu & CU_NURB_CYCLIC)) {
if (a == 1) {
fillBevelCap(nu, dlb, cur_data - 3 * dlb->nr, &bottom_capbase);
negate_v3_v3(bottom_no, bevp->dir);
}
if (a == steps - 1) {
fillBevelCap(nu, dlb, cur_data, &top_capbase);
copy_v3_v3(top_no, bevp->dir);
}
}
}
/* gl array drawing: using indices */
displist_surf_indices(dl);
}
if (bottom_capbase.first) {
BKE_displist_fill(&bottom_capbase, dispbase, bottom_no, false);
BKE_displist_fill(&top_capbase, dispbase, top_no, false);
BKE_displist_free(&bottom_capbase);
BKE_displist_free(&top_capbase);
}
}
}
}
BKE_displist_free(&dlbev);
}
if (!(cu->flag & CU_DEFORM_FILL)) {
curve_to_filledpoly(cu, &nubase, dispbase);
}
if (!forOrco) {
if ((cu->flag & CU_PATH) ||
DAG_get_eval_flags_for_object(scene, ob) & DAG_EVAL_NEED_CURVE_PATH)
{
calc_curvepath(ob, &nubase);
}
}
if (!forOrco)
curve_calc_modifiers_post(scene, ob, &nubase, dispbase, derivedFinal, forRender, renderResolution);
if (cu->flag & CU_DEFORM_FILL && !ob->derivedFinal) {
curve_to_filledpoly(cu, &nubase, dispbase);
}
BKE_nurbList_free(&nubase);
}
}
void BKE_displist_make_curveTypes(Scene *scene, Object *ob, int forOrco)
{
ListBase *dispbase;
/* The same check for duplis as in do_makeDispListCurveTypes.
* Happens when curve used for constraint/bevel was converted to mesh.
* check there is still needed for render displist and orco displists. */
if (!ELEM3(ob->type, OB_SURF, OB_CURVE, OB_FONT))
return;
BKE_object_free_derived_caches(ob);
if (!ob->curve_cache) {
ob->curve_cache = MEM_callocN(sizeof(CurveCache), "CurveCache for curve types");
}
dispbase = &(ob->curve_cache->disp);
do_makeDispListCurveTypes(scene, ob, dispbase, &ob->derivedFinal, 0, forOrco, 0);
boundbox_displist_object(ob);
}
void BKE_displist_make_curveTypes_forRender(Scene *scene, Object *ob, ListBase *dispbase,
DerivedMesh **derivedFinal, int forOrco, int renderResolution)
{
if (ob->curve_cache == NULL) {
ob->curve_cache = MEM_callocN(sizeof(CurveCache), "CurveCache for MBall");
}
do_makeDispListCurveTypes(scene, ob, dispbase, derivedFinal, 1, forOrco, renderResolution);
}
void BKE_displist_make_curveTypes_forOrco(struct Scene *scene, struct Object *ob, struct ListBase *dispbase)
{
if (ob->curve_cache == NULL) {
ob->curve_cache = MEM_callocN(sizeof(CurveCache), "CurveCache for MBall");
}
do_makeDispListCurveTypes(scene, ob, dispbase, NULL, 1, 1, 1);
}
/* add Orco layer to the displist object which has got derived mesh and return orco */
float *BKE_displist_make_orco(Scene *scene, Object *ob, DerivedMesh *derivedFinal, int forRender, int renderResolution)
{
float *orco;
if (derivedFinal == NULL)
derivedFinal = ob->derivedFinal;
if (!derivedFinal->getVertDataArray(derivedFinal, CD_ORCO)) {
curve_calc_orcodm(scene, ob, derivedFinal, forRender, renderResolution);
}
orco = derivedFinal->getVertDataArray(derivedFinal, CD_ORCO);
if (orco) {
orco = MEM_dupallocN(orco);
}
return orco;
}
void BKE_displist_minmax(ListBase *dispbase, float min[3], float max[3])
{
DispList *dl;
float *vert;
int a, tot = 0;
int doit = 0;
for (dl = dispbase->first; dl; dl = dl->next) {
tot = (dl->type == DL_INDEX3) ? dl->nr : dl->nr * dl->parts;
vert = dl->verts;
for (a = 0; a < tot; a++, vert += 3) {
minmax_v3v3_v3(min, max, vert);
}
doit |= (tot != 0);
}
if (!doit) {
/* there's no geometry in displist, use zero-sized boundbox */
zero_v3(min);
zero_v3(max);
}
}
/* this is confusing, there's also min_max_object, appplying the obmat... */
static void boundbox_displist_object(Object *ob)
{
if (ELEM3(ob->type, OB_CURVE, OB_SURF, OB_FONT)) {
/* Curver's BB is already calculated as a part of modifier stack,
* here we only calculate object BB based on final display list.
*/
/* object's BB is calculated from final displist */
if (ob->bb == NULL)
ob->bb = MEM_callocN(sizeof(BoundBox), "boundbox");
if (ob->derivedFinal) {
DM_set_object_boundbox(ob, ob->derivedFinal);
}
else {
float min[3], max[3];
INIT_MINMAX(min, max);
BKE_displist_minmax(&ob->curve_cache->disp, min, max);
BKE_boundbox_init_from_minmax(ob->bb, min, max);
}
}
}
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