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test/source/blender/blenkernel/intern/object_dupli.cc
Jacques Lucke c55d38f00b Geometry Nodes: viewport preview 
This adds support for showing geometry passed to the Viewer in the 3d
viewport (instead of just in the spreadsheet). The "viewer geometry"
bypasses the group output. So it is not necessary to change the final
output of the node group to be able to see the intermediate geometry.

**Activation and deactivation of a viewer node**
* A viewer node is activated by clicking on it.
* Ctrl+shift+click on any node/socket connects it to the viewer and
  makes it active.
* Ctrl+shift+click in empty space deactivates the active viewer.
* When the active viewer is not visible anymore (e.g. another object
  is selected, or the current node group is exit), it is deactivated.
* Clicking on the icon in the header of the Viewer node toggles whether
  its active or not.

**Pinning**
* The spreadsheet still allows pinning the active viewer as before.
  When pinned, the spreadsheet still references the viewer node even
  when it becomes inactive.
* The viewport does not support pinning at the moment. It always shows
  the active viewer.

**Attribute**
* When a field is linked to the second input of the viewer node it is
  displayed as an overlay in the viewport.
* When possible the correct domain for the attribute is determined
  automatically. This does not work in all cases. It falls back to the
  face corner domain on meshes and the point domain on curves. When
  necessary, the domain can be picked manually.
* The spreadsheet now only shows the "Viewer" column for the domain
  that is selected in the Viewer node.
* Instance attributes are visualized as a constant color per instance.

**Viewport Options**
* The attribute overlay opacity can be controlled with the "Viewer Node"
  setting in the overlays popover.
* A viewport can be configured not to show intermediate viewer-geometry
  by disabling the "Viewer Node" option in the "View" menu.

**Implementation Details**
* The "spreadsheet context path" was generalized to a "viewer path" that
  is used in more places now.
* The viewer node itself determines the attribute domain, evaluates the
  field and stores the result in a `.viewer` attribute.
* A new "viewer attribute' overlay displays the data from the `.viewer`
  attribute.
* The ground truth for the active viewer node is stored in the workspace
  now. Node editors, spreadsheets and viewports retrieve the active
  viewer from there unless they are pinned.
* The depsgraph object iterator has a new "viewer path" setting. When set,
  the viewed geometry of the corresponding object is part of the iterator
  instead of the final evaluated geometry.
* To support the instance attribute overlay `DupliObject` was extended
  to contain the information necessary for drawing the overlay.
* The ctrl+shift+click operator has been refactored so that it can make
  existing links to viewers active again.
* The auto-domain-detection in the Viewer node works by checking the
  "preferred domain" for every field input. If there is not exactly one
  preferred domain, the fallback is used.

Known limitations:
* Loose edges of meshes don't have the attribute overlay. This could be
  added separately if necessary.
* Some attributes are hard to visualize as a color directly. For example,
  the values might have to be normalized or some should be drawn as arrays.
  For now, we encourage users to build node groups that generate appropriate
  viewer-geometry. We might include some of that functionality in future versions.
  Support for displaying attribute values as text in the viewport is planned as well.
* There seems to be an issue with the attribute overlay for pointclouds on
  nvidia gpus, to be investigated.

Differential Revision: https://developer.blender.org/D15954
2022-09-28 17:54:59 +02:00

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/* SPDX-License-Identifier: GPL-2.0-or-later
* Copyright 2001-2002 NaN Holding BV. All rights reserved. */
/** \file
* \ingroup bke
*/
#include <climits>
#include <cstddef>
#include <cstdlib>
#include "MEM_guardedalloc.h"
#include "BLI_listbase.h"
#include "BLI_string_utf8.h"
#include "BLI_array.hh"
#include "BLI_float4x4.hh"
#include "BLI_math.h"
#include "BLI_math_vec_types.hh"
#include "BLI_rand.h"
#include "BLI_span.hh"
#include "BLI_vector.hh"
#include "DNA_anim_types.h"
#include "DNA_collection_types.h"
#include "DNA_curves_types.h"
#include "DNA_mesh_types.h"
#include "DNA_meshdata_types.h"
#include "DNA_modifier_types.h"
#include "DNA_pointcloud_types.h"
#include "DNA_scene_types.h"
#include "DNA_vfont_types.h"
#include "DNA_volume_types.h"
#include "BKE_collection.h"
#include "BKE_duplilist.h"
#include "BKE_editmesh.h"
#include "BKE_editmesh_cache.h"
#include "BKE_geometry_set.h"
#include "BKE_geometry_set.hh"
#include "BKE_global.h"
#include "BKE_idprop.h"
#include "BKE_lattice.h"
#include "BKE_main.h"
#include "BKE_mesh.h"
#include "BKE_mesh_iterators.h"
#include "BKE_mesh_runtime.h"
#include "BKE_modifier.h"
#include "BKE_object.h"
#include "BKE_particle.h"
#include "BKE_scene.h"
#include "BKE_vfont.h"
#include "DEG_depsgraph.h"
#include "DEG_depsgraph_query.h"
#include "BLI_hash.h"
#include "NOD_geometry_nodes_log.hh"
using blender::Array;
using blender::float3;
using blender::float4x4;
using blender::Span;
using blender::Vector;
namespace geo_log = blender::nodes::geo_eval_log;
/* -------------------------------------------------------------------- */
/** \name Internal Duplicate Context
* \{ */
struct DupliContext {
Depsgraph *depsgraph;
/** XXX child objects are selected from this group if set, could be nicer. */
Collection *collection;
/** Only to check if the object is in edit-mode. */
Object *obedit;
Scene *scene;
Object *object;
float space_mat[4][4];
/**
* Index of the top-level instance that contains this context or -1 when unused.
* This is an index into the instances component of #preview_base_geometry.
*/
int preview_instance_index;
/**
* Top level geometry set that is previewed.
*/
const GeometrySet *preview_base_geometry;
/**
* A stack that contains all the "parent" objects of a particular instance when recursive
* instancing is used. This is used to prevent objects from instancing themselves accidentally.
* Use a vector instead of a stack because we want to use the #contains method.
*/
Vector<Object *> *instance_stack;
int persistent_id[MAX_DUPLI_RECUR];
int level;
const struct DupliGenerator *gen;
/** Result containers. */
ListBase *duplilist; /* Legacy doubly-linked list. */
};
struct DupliGenerator {
short type; /* Dupli Type, see members of #OB_DUPLI. */
void (*make_duplis)(const DupliContext *ctx);
};
static const DupliGenerator *get_dupli_generator(const DupliContext *ctx);
/**
* Create initial context for root object.
*/
static void init_context(DupliContext *r_ctx,
Depsgraph *depsgraph,
Scene *scene,
Object *ob,
const float space_mat[4][4],
Vector<Object *> &instance_stack)
{
r_ctx->depsgraph = depsgraph;
r_ctx->scene = scene;
r_ctx->collection = nullptr;
r_ctx->object = ob;
r_ctx->obedit = OBEDIT_FROM_OBACT(ob);
r_ctx->instance_stack = &instance_stack;
if (space_mat) {
copy_m4_m4(r_ctx->space_mat, space_mat);
}
else {
unit_m4(r_ctx->space_mat);
}
r_ctx->level = 0;
r_ctx->gen = get_dupli_generator(r_ctx);
r_ctx->duplilist = nullptr;
r_ctx->preview_instance_index = -1;
r_ctx->preview_base_geometry = nullptr;
}
/**
* Create sub-context for recursive duplis.
*/
static bool copy_dupli_context(
DupliContext *r_ctx, const DupliContext *ctx, Object *ob, const float mat[4][4], int index)
{
*r_ctx = *ctx;
/* XXX annoying, previously was done by passing an ID* argument,
* this at least is more explicit. */
if (ctx->gen && ctx->gen->type == OB_DUPLICOLLECTION) {
r_ctx->collection = ctx->object->instance_collection;
}
r_ctx->object = ob;
r_ctx->instance_stack = ctx->instance_stack;
if (mat) {
mul_m4_m4m4(r_ctx->space_mat, (float(*)[4])ctx->space_mat, mat);
}
r_ctx->persistent_id[r_ctx->level] = index;
++r_ctx->level;
if (r_ctx->level == MAX_DUPLI_RECUR - 1) {
std::cerr << "Warning: Maximum instance recursion level reached.\n";
return false;
}
r_ctx->gen = get_dupli_generator(r_ctx);
return true;
}
/**
* Generate a dupli instance.
*
* \param mat: is transform of the object relative to current context (including #Object.obmat).
*/
static DupliObject *make_dupli(
const DupliContext *ctx, Object *ob, const ID *object_data, const float mat[4][4], int index)
{
DupliObject *dob;
int i;
/* Add a #DupliObject instance to the result container. */
if (ctx->duplilist) {
dob = MEM_cnew<DupliObject>("dupli object");
BLI_addtail(ctx->duplilist, dob);
}
else {
return nullptr;
}
dob->ob = ob;
dob->ob_data = const_cast<ID *>(object_data);
mul_m4_m4m4(dob->mat, (float(*)[4])ctx->space_mat, mat);
dob->type = ctx->gen == nullptr ? 0 : ctx->gen->type;
dob->preview_base_geometry = ctx->preview_base_geometry;
dob->preview_instance_index = ctx->preview_instance_index;
/* Set persistent id, which is an array with a persistent index for each level
* (particle number, vertex number, ..). by comparing this we can find the same
* dupli-object between frames, which is needed for motion blur.
* The last level is ordered first in the array. */
dob->persistent_id[0] = index;
for (i = 1; i < ctx->level + 1; i++) {
dob->persistent_id[i] = ctx->persistent_id[ctx->level - i];
}
/* Fill rest of values with #INT_MAX which index will never have as value. */
for (; i < MAX_DUPLI_RECUR; i++) {
dob->persistent_id[i] = INT_MAX;
}
/* Meta-balls never draw in duplis, they are instead merged into one by the basis
* meta-ball outside of the group. this does mean that if that meta-ball is not in the
* scene, they will not show up at all, limitation that should be solved once. */
if (object_data && GS(object_data->name) == ID_MB) {
dob->no_draw = true;
}
/* Random number.
* The logic here is designed to match Cycles. */
dob->random_id = BLI_hash_string(dob->ob->id.name + 2);
if (dob->persistent_id[0] != INT_MAX) {
for (i = 0; i < MAX_DUPLI_RECUR; i++) {
dob->random_id = BLI_hash_int_2d(dob->random_id, uint(dob->persistent_id[i]));
}
}
else {
dob->random_id = BLI_hash_int_2d(dob->random_id, 0);
}
if (ctx->object != ob) {
dob->random_id ^= BLI_hash_int(BLI_hash_string(ctx->object->id.name + 2));
}
return dob;
}
static DupliObject *make_dupli(const DupliContext *ctx,
Object *ob,
const float mat[4][4],
int index)
{
return make_dupli(ctx, ob, static_cast<ID *>(ob->data), mat, index);
}
/**
* Recursive dupli-objects.
*
* \param space_mat: is the local dupli-space (excluding dupli #Object.obmat).
*/
static void make_recursive_duplis(const DupliContext *ctx,
Object *ob,
const float space_mat[4][4],
int index)
{
if (ctx->instance_stack->contains(ob)) {
/* Avoid recursive instances. */
printf("Warning: '%s' object is trying to instance itself.\n", ob->id.name + 2);
return;
}
/* Simple preventing of too deep nested collections with #MAX_DUPLI_RECUR. */
if (ctx->level < MAX_DUPLI_RECUR) {
DupliContext rctx;
if (!copy_dupli_context(&rctx, ctx, ob, space_mat, index)) {
return;
}
if (rctx.gen) {
ctx->instance_stack->append(ob);
rctx.gen->make_duplis(&rctx);
ctx->instance_stack->remove_last();
}
}
}
/** \} */
/* -------------------------------------------------------------------- */
/** \name Internal Child Duplicates (Used by Other Functions)
* \{ */
using MakeChildDuplisFunc = void (*)(const DupliContext *ctx, void *userdata, Object *child);
static bool is_child(const Object *ob, const Object *parent)
{
const Object *ob_parent = ob->parent;
while (ob_parent) {
if (ob_parent == parent) {
return true;
}
ob_parent = ob_parent->parent;
}
return false;
}
/**
* Create duplis from every child in scene or collection.
*/
static void make_child_duplis(const DupliContext *ctx,
void *userdata,
MakeChildDuplisFunc make_child_duplis_cb)
{
Object *parent = ctx->object;
if (ctx->collection) {
eEvaluationMode mode = DEG_get_mode(ctx->depsgraph);
FOREACH_COLLECTION_VISIBLE_OBJECT_RECURSIVE_BEGIN (ctx->collection, ob, mode) {
if ((ob != ctx->obedit) && is_child(ob, parent)) {
DupliContext pctx;
if (copy_dupli_context(&pctx, ctx, ctx->object, nullptr, _base_id)) {
/* Meta-balls have a different dupli handling. */
if (ob->type != OB_MBALL) {
ob->flag |= OB_DONE; /* Doesn't render. */
}
make_child_duplis_cb(&pctx, userdata, ob);
}
}
}
FOREACH_COLLECTION_VISIBLE_OBJECT_RECURSIVE_END;
}
else {
/* FIXME: using a mere counter to generate a 'persistent' dupli id is very weak. One possible
* better solution could be to use `session_uuid` of ID's instead? */
int persistent_dupli_id = 0;
DEGObjectIterSettings deg_iter_settings{};
deg_iter_settings.depsgraph = ctx->depsgraph;
/* NOTE: this set of flags ensure we only iterate over objects that have a base in either the
* current scene, or the set (background) scene. */
deg_iter_settings.flags = DEG_ITER_OBJECT_FLAG_LINKED_DIRECTLY |
DEG_ITER_OBJECT_FLAG_LINKED_VIA_SET;
DEG_OBJECT_ITER_BEGIN (&deg_iter_settings, ob) {
if ((ob != ctx->obedit) && is_child(ob, parent)) {
DupliContext pctx;
if (copy_dupli_context(&pctx, ctx, ctx->object, nullptr, persistent_dupli_id)) {
/* Meta-balls have a different dupli-handling. */
if (ob->type != OB_MBALL) {
ob->flag |= OB_DONE; /* Doesn't render. */
}
make_child_duplis_cb(&pctx, userdata, ob);
}
}
persistent_dupli_id++;
}
DEG_OBJECT_ITER_END;
}
}
/** \} */
/* -------------------------------------------------------------------- */
/** \name Internal Data Access Utilities
* \{ */
static const Mesh *mesh_data_from_duplicator_object(Object *ob,
BMEditMesh **r_em,
const float (**r_vert_coords)[3],
const float (**r_vert_normals)[3])
{
/* Gather mesh info. */
BMEditMesh *em = BKE_editmesh_from_object(ob);
const Mesh *me_eval;
*r_em = nullptr;
*r_vert_coords = nullptr;
if (r_vert_normals != nullptr) {
*r_vert_normals = nullptr;
}
/* We do not need any render-specific handling anymore, depsgraph takes care of that. */
/* NOTE: Do direct access to the evaluated mesh: this function is used
* during meta balls evaluation. But even without those all the objects
* which are needed for correct instancing are already evaluated. */
if (em != nullptr) {
/* Note that this will only show deformation if #eModifierMode_OnCage is enabled.
* We could change this but it matches 2.7x behavior. */
me_eval = BKE_object_get_editmesh_eval_cage(ob);
if ((me_eval == nullptr) || (me_eval->runtime.wrapper_type == ME_WRAPPER_TYPE_BMESH)) {
EditMeshData *emd = me_eval ? me_eval->runtime.edit_data : nullptr;
/* Only assign edit-mesh in the case we can't use `me_eval`. */
*r_em = em;
me_eval = nullptr;
if ((emd != nullptr) && (emd->vertexCos != nullptr)) {
*r_vert_coords = emd->vertexCos;
if (r_vert_normals != nullptr) {
BKE_editmesh_cache_ensure_vert_normals(em, emd);
*r_vert_normals = emd->vertexNos;
}
}
}
}
else {
me_eval = BKE_object_get_evaluated_mesh(ob);
}
return me_eval;
}
/** \} */
/* -------------------------------------------------------------------- */
/** \name Dupli-Collection Implementation (#OB_DUPLICOLLECTION)
* \{ */
static void make_duplis_collection(const DupliContext *ctx)
{
Object *ob = ctx->object;
Collection *collection;
float collection_mat[4][4];
if (ob->instance_collection == nullptr) {
return;
}
collection = ob->instance_collection;
/* Combine collection offset and `obmat`. */
unit_m4(collection_mat);
sub_v3_v3(collection_mat[3], collection->instance_offset);
mul_m4_m4m4(collection_mat, ob->obmat, collection_mat);
/* Don't access 'ob->obmat' from now on. */
eEvaluationMode mode = DEG_get_mode(ctx->depsgraph);
FOREACH_COLLECTION_VISIBLE_OBJECT_RECURSIVE_BEGIN (collection, cob, mode) {
if (cob != ob) {
float mat[4][4];
/* Collection dupli-offset, should apply after everything else. */
mul_m4_m4m4(mat, collection_mat, cob->obmat);
make_dupli(ctx, cob, mat, _base_id);
/* Recursion. */
make_recursive_duplis(ctx, cob, collection_mat, _base_id);
}
}
FOREACH_COLLECTION_VISIBLE_OBJECT_RECURSIVE_END;
}
static const DupliGenerator gen_dupli_collection = {
OB_DUPLICOLLECTION, /* type */
make_duplis_collection /* make_duplis */
};
/** \} */
/* -------------------------------------------------------------------- */
/** \name Dupli-Vertices Implementation (#OB_DUPLIVERTS for Geometry)
* \{ */
/** Values shared between different mesh types. */
struct VertexDupliData_Params {
/**
* It's important we use this context instead of the `ctx` passed into #make_child_duplis
* since these won't match in the case of recursion.
*/
const DupliContext *ctx;
bool use_rotation;
};
struct VertexDupliData_Mesh {
VertexDupliData_Params params;
int totvert;
const MVert *mvert;
const float (*vert_normals)[3];
const float (*orco)[3];
};
struct VertexDupliData_EditMesh {
VertexDupliData_Params params;
BMEditMesh *em;
/* Can be nullptr. */
const float (*vert_coords)[3];
const float (*vert_normals)[3];
/**
* \note The edit-mesh may assign #DupliObject.orco in cases when a regular mesh wouldn't.
* For edit-meshes we only check for deformation, for regular meshes we check if #CD_ORCO exists.
*
* At the moment this isn't a meaningful difference since requesting #CD_ORCO causes the
* edit-mesh to be converted into a mesh.
*/
bool has_orco;
};
/**
* \param no: The direction,
* currently this is copied from a `short[3]` normal without division.
* Can be null when \a use_rotation is false.
*/
static void get_duplivert_transform(const float co[3],
const float no[3],
const bool use_rotation,
const short axis,
const short upflag,
float r_mat[4][4])
{
float quat[4];
const float size[3] = {1.0f, 1.0f, 1.0f};
if (use_rotation) {
/* Construct rotation matrix from normals. */
float no_flip[3];
negate_v3_v3(no_flip, no);
vec_to_quat(quat, no_flip, axis, upflag);
}
else {
unit_qt(quat);
}
loc_quat_size_to_mat4(r_mat, co, quat, size);
}
static DupliObject *vertex_dupli(const DupliContext *ctx,
Object *inst_ob,
const float child_imat[4][4],
int index,
const float co[3],
const float no[3],
const bool use_rotation)
{
/* `obmat` is transform to vertex. */
float obmat[4][4];
get_duplivert_transform(co, no, use_rotation, inst_ob->trackflag, inst_ob->upflag, obmat);
float space_mat[4][4];
/* Make offset relative to inst_ob using relative child transform. */
mul_mat3_m4_v3(child_imat, obmat[3]);
/* Apply `obmat` _after_ the local vertex transform. */
mul_m4_m4m4(obmat, inst_ob->obmat, obmat);
/* Space matrix is constructed by removing `obmat` transform,
* this yields the world-space transform for recursive duplis. */
mul_m4_m4m4(space_mat, obmat, inst_ob->imat);
DupliObject *dob = make_dupli(ctx, inst_ob, obmat, index);
/* Recursion. */
make_recursive_duplis(ctx, inst_ob, space_mat, index);
return dob;
}
static void make_child_duplis_verts_from_mesh(const DupliContext *ctx,
void *userdata,
Object *inst_ob)
{
VertexDupliData_Mesh *vdd = (VertexDupliData_Mesh *)userdata;
const bool use_rotation = vdd->params.use_rotation;
const MVert *mvert = vdd->mvert;
const int totvert = vdd->totvert;
invert_m4_m4(inst_ob->imat, inst_ob->obmat);
/* Relative transform from parent to child space. */
float child_imat[4][4];
mul_m4_m4m4(child_imat, inst_ob->imat, ctx->object->obmat);
for (int i = 0; i < totvert; i++) {
DupliObject *dob = vertex_dupli(
vdd->params.ctx, inst_ob, child_imat, i, mvert[i].co, vdd->vert_normals[i], use_rotation);
if (vdd->orco) {
copy_v3_v3(dob->orco, vdd->orco[i]);
}
}
}
static void make_child_duplis_verts_from_editmesh(const DupliContext *ctx,
void *userdata,
Object *inst_ob)
{
VertexDupliData_EditMesh *vdd = (VertexDupliData_EditMesh *)userdata;
BMEditMesh *em = vdd->em;
const bool use_rotation = vdd->params.use_rotation;
invert_m4_m4(inst_ob->imat, inst_ob->obmat);
/* Relative transform from parent to child space. */
float child_imat[4][4];
mul_m4_m4m4(child_imat, inst_ob->imat, ctx->object->obmat);
BMVert *v;
BMIter iter;
int i;
const float(*vert_coords)[3] = vdd->vert_coords;
const float(*vert_normals)[3] = vdd->vert_normals;
BM_ITER_MESH_INDEX (v, &iter, em->bm, BM_VERTS_OF_MESH, i) {
const float *co, *no;
if (vert_coords != nullptr) {
co = vert_coords[i];
no = vert_normals ? vert_normals[i] : nullptr;
}
else {
co = v->co;
no = v->no;
}
DupliObject *dob = vertex_dupli(vdd->params.ctx, inst_ob, child_imat, i, co, no, use_rotation);
if (vdd->has_orco) {
copy_v3_v3(dob->orco, v->co);
}
}
}
static void make_duplis_verts(const DupliContext *ctx)
{
Object *parent = ctx->object;
const bool use_rotation = parent->transflag & OB_DUPLIROT;
/* Gather mesh info. */
BMEditMesh *em = nullptr;
const float(*vert_coords)[3] = nullptr;
const float(*vert_normals)[3] = nullptr;
const Mesh *me_eval = mesh_data_from_duplicator_object(
parent, &em, &vert_coords, use_rotation ? &vert_normals : nullptr);
if (em == nullptr && me_eval == nullptr) {
return;
}
VertexDupliData_Params vdd_params{ctx, use_rotation};
if (em != nullptr) {
VertexDupliData_EditMesh vdd{};
vdd.params = vdd_params;
vdd.em = em;
vdd.vert_coords = vert_coords;
vdd.vert_normals = vert_normals;
vdd.has_orco = (vert_coords != nullptr);
make_child_duplis(ctx, &vdd, make_child_duplis_verts_from_editmesh);
}
else {
VertexDupliData_Mesh vdd{};
vdd.params = vdd_params;
vdd.totvert = me_eval->totvert;
vdd.mvert = me_eval->verts().data();
vdd.vert_normals = BKE_mesh_vertex_normals_ensure(me_eval);
vdd.orco = (const float(*)[3])CustomData_get_layer(&me_eval->vdata, CD_ORCO);
make_child_duplis(ctx, &vdd, make_child_duplis_verts_from_mesh);
}
}
static const DupliGenerator gen_dupli_verts = {
OB_DUPLIVERTS, /* type */
make_duplis_verts /* make_duplis */
};
/** \} */
/* -------------------------------------------------------------------- */
/** \name Dupli-Vertices Implementation (#OB_DUPLIVERTS for 3D Text)
* \{ */
static Object *find_family_object(
Main *bmain, const char *family, size_t family_len, uint ch, GHash *family_gh)
{
void *ch_key = POINTER_FROM_UINT(ch);
Object **ob_pt;
if ((ob_pt = (Object **)BLI_ghash_lookup_p(family_gh, ch_key))) {
return *ob_pt;
}
char ch_utf8[BLI_UTF8_MAX + 1];
size_t ch_utf8_len;
ch_utf8_len = BLI_str_utf8_from_unicode(ch, ch_utf8, sizeof(ch_utf8) - 1);
ch_utf8[ch_utf8_len] = '\0';
ch_utf8_len += 1; /* Compare with null terminator. */
LISTBASE_FOREACH (Object *, ob, &bmain->objects) {
if (STREQLEN(ob->id.name + 2 + family_len, ch_utf8, ch_utf8_len)) {
if (STREQLEN(ob->id.name + 2, family, family_len)) {
/* Inserted value can be nullptr, just to save searches in future. */
BLI_ghash_insert(family_gh, ch_key, ob);
return ob;
}
}
}
return nullptr;
}
static void make_duplis_font(const DupliContext *ctx)
{
Object *par = ctx->object;
GHash *family_gh;
Object *ob;
Curve *cu;
struct CharTrans *ct, *chartransdata = nullptr;
float vec[3], obmat[4][4], pmat[4][4], fsize, xof, yof;
int text_len, a;
size_t family_len;
const char32_t *text = nullptr;
bool text_free = false;
/* Font dupli-verts not supported inside collections. */
if (ctx->collection) {
return;
}
copy_m4_m4(pmat, par->obmat);
/* In `par` the family name is stored, use this to find the other objects. */
BKE_vfont_to_curve_ex(
par, (Curve *)par->data, FO_DUPLI, nullptr, &text, &text_len, &text_free, &chartransdata);
if (text == nullptr || chartransdata == nullptr) {
return;
}
cu = (Curve *)par->data;
fsize = cu->fsize;
xof = cu->xof;
yof = cu->yof;
ct = chartransdata;
/* Cache result. */
family_len = strlen(cu->family);
family_gh = BLI_ghash_int_new_ex(__func__, 256);
/* Safety check even if it might fail badly when called for original object. */
const bool is_eval_curve = DEG_is_evaluated_id(&cu->id);
/* Advance matching BLI_str_utf8_as_utf32. */
for (a = 0; a < text_len; a++, ct++) {
/* XXX That G.main is *really* ugly, but not sure what to do here.
* Definitively don't think it would be safe to put back `Main *bmain` pointer
* in #DupliContext as done in 2.7x? */
ob = find_family_object(G.main, cu->family, family_len, uint(text[a]), family_gh);
if (is_eval_curve) {
/* Workaround for the above hack. */
ob = DEG_get_evaluated_object(ctx->depsgraph, ob);
}
if (ob) {
vec[0] = fsize * (ct->xof - xof);
vec[1] = fsize * (ct->yof - yof);
vec[2] = 0.0;
mul_m4_v3(pmat, vec);
copy_m4_m4(obmat, par->obmat);
if (UNLIKELY(ct->rot != 0.0f)) {
float rmat[4][4];
zero_v3(obmat[3]);
axis_angle_to_mat4_single(rmat, 'Z', -ct->rot);
mul_m4_m4m4(obmat, obmat, rmat);
}
copy_v3_v3(obmat[3], vec);
make_dupli(ctx, ob, obmat, a);
}
}
if (text_free) {
MEM_freeN((void *)text);
}
BLI_ghash_free(family_gh, nullptr, nullptr);
MEM_freeN(chartransdata);
}
static const DupliGenerator gen_dupli_verts_font = {
OB_DUPLIVERTS, /* type */
make_duplis_font /* make_duplis */
};
/** \} */
/* -------------------------------------------------------------------- */
/** \name Instances Geometry Component Implementation
* \{ */
static void make_duplis_geometry_set_impl(const DupliContext *ctx,
const GeometrySet &geometry_set,
const float parent_transform[4][4],
bool geometry_set_is_instance,
bool use_new_curves_type)
{
int component_index = 0;
if (ctx->object->type != OB_MESH || geometry_set_is_instance) {
if (const Mesh *mesh = geometry_set.get_mesh_for_read()) {
make_dupli(ctx, ctx->object, &mesh->id, parent_transform, component_index++);
}
}
if (ctx->object->type != OB_VOLUME || geometry_set_is_instance) {
if (const Volume *volume = geometry_set.get_volume_for_read()) {
make_dupli(ctx, ctx->object, &volume->id, parent_transform, component_index++);
}
}
if (!ELEM(ctx->object->type, OB_CURVES_LEGACY, OB_FONT, OB_CURVES) || geometry_set_is_instance) {
if (const CurveComponent *component = geometry_set.get_component_for_read<CurveComponent>()) {
if (use_new_curves_type) {
if (const Curves *curves = component->get_for_read()) {
make_dupli(ctx, ctx->object, &curves->id, parent_transform, component_index++);
}
}
else {
if (const Curve *curve = component->get_curve_for_render()) {
make_dupli(ctx, ctx->object, &curve->id, parent_transform, component_index++);
}
}
}
}
if (ctx->object->type != OB_POINTCLOUD || geometry_set_is_instance) {
if (const PointCloud *pointcloud = geometry_set.get_pointcloud_for_read()) {
make_dupli(ctx, ctx->object, &pointcloud->id, parent_transform, component_index++);
}
}
const bool creates_duplis_for_components = component_index >= 1;
const InstancesComponent *component = geometry_set.get_component_for_read<InstancesComponent>();
if (component == nullptr) {
return;
}
const DupliContext *instances_ctx = ctx;
/* Create a sub-context if some duplis were created above. This is to avoid dupli id collisions
* between the instances component below and the other components above. */
DupliContext new_instances_ctx;
if (creates_duplis_for_components) {
if (!copy_dupli_context(&new_instances_ctx, ctx, ctx->object, nullptr, component_index)) {
return;
}
instances_ctx = &new_instances_ctx;
}
Span<float4x4> instance_offset_matrices = component->instance_transforms();
Span<int> instance_reference_handles = component->instance_reference_handles();
Span<int> almost_unique_ids = component->almost_unique_ids();
Span<InstanceReference> references = component->references();
for (int64_t i : instance_offset_matrices.index_range()) {
const InstanceReference &reference = references[instance_reference_handles[i]];
const int id = almost_unique_ids[i];
const DupliContext *ctx_for_instance = instances_ctx;
/* Set the #preview_instance_index when necessary. */
DupliContext tmp_ctx_for_instance;
if (instances_ctx->preview_base_geometry == &geometry_set) {
tmp_ctx_for_instance = *instances_ctx;
tmp_ctx_for_instance.preview_instance_index = i;
ctx_for_instance = &tmp_ctx_for_instance;
}
switch (reference.type()) {
case InstanceReference::Type::Object: {
Object &object = reference.object();
float matrix[4][4];
mul_m4_m4m4(matrix, parent_transform, instance_offset_matrices[i].values);
make_dupli(ctx_for_instance, &object, matrix, id);
float space_matrix[4][4];
mul_m4_m4m4(space_matrix, instance_offset_matrices[i].values, object.imat);
mul_m4_m4_pre(space_matrix, parent_transform);
make_recursive_duplis(ctx_for_instance, &object, space_matrix, id);
break;
}
case InstanceReference::Type::Collection: {
Collection &collection = reference.collection();
float collection_matrix[4][4];
unit_m4(collection_matrix);
sub_v3_v3(collection_matrix[3], collection.instance_offset);
mul_m4_m4_pre(collection_matrix, instance_offset_matrices[i].values);
mul_m4_m4_pre(collection_matrix, parent_transform);
DupliContext sub_ctx;
if (!copy_dupli_context(
&sub_ctx, ctx_for_instance, ctx_for_instance->object, nullptr, id)) {
break;
}
eEvaluationMode mode = DEG_get_mode(ctx_for_instance->depsgraph);
int object_id = 0;
FOREACH_COLLECTION_VISIBLE_OBJECT_RECURSIVE_BEGIN (&collection, object, mode) {
if (object == ctx_for_instance->object) {
continue;
}
float instance_matrix[4][4];
mul_m4_m4m4(instance_matrix, collection_matrix, object->obmat);
make_dupli(&sub_ctx, object, instance_matrix, object_id++);
make_recursive_duplis(&sub_ctx, object, collection_matrix, object_id++);
}
FOREACH_COLLECTION_VISIBLE_OBJECT_RECURSIVE_END;
break;
}
case InstanceReference::Type::GeometrySet: {
float new_transform[4][4];
mul_m4_m4m4(new_transform, parent_transform, instance_offset_matrices[i].values);
DupliContext sub_ctx;
if (copy_dupli_context(
&sub_ctx, ctx_for_instance, ctx_for_instance->object, nullptr, id)) {
make_duplis_geometry_set_impl(
&sub_ctx, reference.geometry_set(), new_transform, true, false);
}
break;
}
case InstanceReference::Type::None: {
break;
}
}
}
}
static void make_duplis_geometry_set(const DupliContext *ctx)
{
const GeometrySet *geometry_set = ctx->object->runtime.geometry_set_eval;
make_duplis_geometry_set_impl(ctx, *geometry_set, ctx->object->obmat, false, false);
}
static const DupliGenerator gen_dupli_geometry_set = {
0,
make_duplis_geometry_set,
};
/** \} */
/* -------------------------------------------------------------------- */
/** \name Dupli-Faces Implementation (#OB_DUPLIFACES)
* \{ */
/** Values shared between different mesh types. */
struct FaceDupliData_Params {
/**
* It's important we use this context instead of the `ctx` passed into #make_child_duplis
* since these won't match in the case of recursion.
*/
const DupliContext *ctx;
bool use_scale;
};
struct FaceDupliData_Mesh {
FaceDupliData_Params params;
int totface;
const MPoly *mpoly;
const MLoop *mloop;
const MVert *mvert;
const float (*orco)[3];
const MLoopUV *mloopuv;
};
struct FaceDupliData_EditMesh {
FaceDupliData_Params params;
BMEditMesh *em;
bool has_orco, has_uvs;
int cd_loop_uv_offset;
/* Can be nullptr. */
const float (*vert_coords)[3];
};
static void get_dupliface_transform_from_coords(Span<float3> coords,
const bool use_scale,
const float scale_fac,
float r_mat[4][4])
{
using namespace blender::math;
/* Location. */
float3 location(0);
for (const float3 &coord : coords) {
location += coord;
}
location *= 1.0f / float(coords.size());
/* Rotation. */
float quat[4];
float3 f_no = normalize(cross_poly(coords));
tri_to_quat_ex(quat, coords[0], coords[1], coords[2], f_no);
/* Scale. */
float scale;
if (use_scale) {
const float area = area_poly_v3((const float(*)[3])coords.data(), uint(coords.size()));
scale = sqrtf(area) * scale_fac;
}
else {
scale = 1.0f;
}
loc_quat_size_to_mat4(r_mat, location, quat, float3(scale));
}
static DupliObject *face_dupli(const DupliContext *ctx,
Object *inst_ob,
const float child_imat[4][4],
const int index,
const bool use_scale,
const float scale_fac,
Span<float3> coords)
{
float obmat[4][4];
float space_mat[4][4];
/* `obmat` is transform to face. */
get_dupliface_transform_from_coords(coords, use_scale, scale_fac, obmat);
/* Make offset relative to inst_ob using relative child transform. */
mul_mat3_m4_v3(child_imat, obmat[3]);
/* XXX ugly hack to ensure same behavior as in master.
* This should not be needed, #Object.parentinv is not consistent outside of parenting. */
{
float imat[3][3];
copy_m3_m4(imat, inst_ob->parentinv);
mul_m4_m3m4(obmat, imat, obmat);
}
/* Apply `obmat` _after_ the local face transform. */
mul_m4_m4m4(obmat, inst_ob->obmat, obmat);
/* Space matrix is constructed by removing `obmat` transform,
* this yields the world-space transform for recursive duplis. */
mul_m4_m4m4(space_mat, obmat, inst_ob->imat);
DupliObject *dob = make_dupli(ctx, inst_ob, obmat, index);
/* Recursion. */
make_recursive_duplis(ctx, inst_ob, space_mat, index);
return dob;
}
static DupliObject *face_dupli_from_mesh(const DupliContext *ctx,
Object *inst_ob,
const float child_imat[4][4],
const int index,
const bool use_scale,
const float scale_fac,
/* Mesh variables. */
const MPoly *mpoly,
const MLoop *mloopstart,
const MVert *mvert)
{
const int coords_len = mpoly->totloop;
Array<float3, 64> coords(coords_len);
const MLoop *ml = mloopstart;
for (int i = 0; i < coords_len; i++, ml++) {
coords[i] = float3(mvert[ml->v].co);
}
return face_dupli(ctx, inst_ob, child_imat, index, use_scale, scale_fac, coords);
}
static DupliObject *face_dupli_from_editmesh(const DupliContext *ctx,
Object *inst_ob,
const float child_imat[4][4],
const int index,
const bool use_scale,
const float scale_fac,
/* Mesh variables. */
BMFace *f,
const float (*vert_coords)[3])
{
const int coords_len = f->len;
Array<float3, 64> coords(coords_len);
BMLoop *l_first, *l_iter;
int i = 0;
l_iter = l_first = BM_FACE_FIRST_LOOP(f);
if (vert_coords != nullptr) {
do {
copy_v3_v3(coords[i++], vert_coords[BM_elem_index_get(l_iter->v)]);
} while ((l_iter = l_iter->next) != l_first);
}
else {
do {
copy_v3_v3(coords[i++], l_iter->v->co);
} while ((l_iter = l_iter->next) != l_first);
}
return face_dupli(ctx, inst_ob, child_imat, index, use_scale, scale_fac, coords);
}
static void make_child_duplis_faces_from_mesh(const DupliContext *ctx,
void *userdata,
Object *inst_ob)
{
FaceDupliData_Mesh *fdd = (FaceDupliData_Mesh *)userdata;
const MPoly *mpoly = fdd->mpoly, *mp;
const MLoop *mloop = fdd->mloop;
const MVert *mvert = fdd->mvert;
const float(*orco)[3] = fdd->orco;
const MLoopUV *mloopuv = fdd->mloopuv;
const int totface = fdd->totface;
const bool use_scale = fdd->params.use_scale;
int a;
float child_imat[4][4];
invert_m4_m4(inst_ob->imat, inst_ob->obmat);
/* Relative transform from parent to child space. */
mul_m4_m4m4(child_imat, inst_ob->imat, ctx->object->obmat);
const float scale_fac = ctx->object->instance_faces_scale;
for (a = 0, mp = mpoly; a < totface; a++, mp++) {
const MLoop *loopstart = mloop + mp->loopstart;
DupliObject *dob = face_dupli_from_mesh(
fdd->params.ctx, inst_ob, child_imat, a, use_scale, scale_fac, mp, loopstart, mvert);
const float w = 1.0f / float(mp->totloop);
if (orco) {
for (int j = 0; j < mp->totloop; j++) {
madd_v3_v3fl(dob->orco, orco[loopstart[j].v], w);
}
}
if (mloopuv) {
for (int j = 0; j < mp->totloop; j++) {
madd_v2_v2fl(dob->uv, mloopuv[mp->loopstart + j].uv, w);
}
}
}
}
static void make_child_duplis_faces_from_editmesh(const DupliContext *ctx,
void *userdata,
Object *inst_ob)
{
FaceDupliData_EditMesh *fdd = (FaceDupliData_EditMesh *)userdata;
BMEditMesh *em = fdd->em;
float child_imat[4][4];
int a;
BMFace *f;
BMIter iter;
const bool use_scale = fdd->params.use_scale;
const float(*vert_coords)[3] = fdd->vert_coords;
BLI_assert((vert_coords == nullptr) || (em->bm->elem_index_dirty & BM_VERT) == 0);
invert_m4_m4(inst_ob->imat, inst_ob->obmat);
/* Relative transform from parent to child space. */
mul_m4_m4m4(child_imat, inst_ob->imat, ctx->object->obmat);
const float scale_fac = ctx->object->instance_faces_scale;
BM_ITER_MESH_INDEX (f, &iter, em->bm, BM_FACES_OF_MESH, a) {
DupliObject *dob = face_dupli_from_editmesh(
fdd->params.ctx, inst_ob, child_imat, a, use_scale, scale_fac, f, vert_coords);
if (fdd->has_orco) {
const float w = 1.0f / float(f->len);
BMLoop *l_first, *l_iter;
l_iter = l_first = BM_FACE_FIRST_LOOP(f);
do {
madd_v3_v3fl(dob->orco, l_iter->v->co, w);
} while ((l_iter = l_iter->next) != l_first);
}
if (fdd->has_uvs) {
BM_face_uv_calc_center_median(f, fdd->cd_loop_uv_offset, dob->uv);
}
}
}
static void make_duplis_faces(const DupliContext *ctx)
{
Object *parent = ctx->object;
/* Gather mesh info. */
BMEditMesh *em = nullptr;
const float(*vert_coords)[3] = nullptr;
const Mesh *me_eval = mesh_data_from_duplicator_object(parent, &em, &vert_coords, nullptr);
if (em == nullptr && me_eval == nullptr) {
return;
}
FaceDupliData_Params fdd_params = {ctx, (parent->transflag & OB_DUPLIFACES_SCALE) != 0};
if (em != nullptr) {
const int uv_idx = CustomData_get_render_layer(&em->bm->ldata, CD_MLOOPUV);
FaceDupliData_EditMesh fdd{};
fdd.params = fdd_params;
fdd.em = em;
fdd.vert_coords = vert_coords;
fdd.has_orco = (vert_coords != nullptr);
fdd.has_uvs = (uv_idx != -1);
fdd.cd_loop_uv_offset = (uv_idx != -1) ?
CustomData_get_n_offset(&em->bm->ldata, CD_MLOOPUV, uv_idx) :
-1;
make_child_duplis(ctx, &fdd, make_child_duplis_faces_from_editmesh);
}
else {
const int uv_idx = CustomData_get_render_layer(&me_eval->ldata, CD_MLOOPUV);
FaceDupliData_Mesh fdd{};
fdd.params = fdd_params;
fdd.totface = me_eval->totpoly;
fdd.mpoly = me_eval->polys().data();
fdd.mloop = me_eval->loops().data();
fdd.mvert = me_eval->verts().data();
fdd.mloopuv = (uv_idx != -1) ? (const MLoopUV *)CustomData_get_layer_n(
&me_eval->ldata, CD_MLOOPUV, uv_idx) :
nullptr;
fdd.orco = (const float(*)[3])CustomData_get_layer(&me_eval->vdata, CD_ORCO);
make_child_duplis(ctx, &fdd, make_child_duplis_faces_from_mesh);
}
}
static const DupliGenerator gen_dupli_faces = {
OB_DUPLIFACES, /* type */
make_duplis_faces /* make_duplis */
};
/** \} */
/* -------------------------------------------------------------------- */
/** \name Dupli-Particles Implementation (#OB_DUPLIPARTS)
* \{ */
static void make_duplis_particle_system(const DupliContext *ctx, ParticleSystem *psys)
{
Scene *scene = ctx->scene;
Object *par = ctx->object;
eEvaluationMode mode = DEG_get_mode(ctx->depsgraph);
bool for_render = mode == DAG_EVAL_RENDER;
Object *ob = nullptr, **oblist = nullptr;
DupliObject *dob;
ParticleSettings *part;
ParticleData *pa;
ChildParticle *cpa = nullptr;
ParticleKey state;
ParticleCacheKey *cache;
float ctime, scale = 1.0f;
float tmat[4][4], mat[4][4], pamat[4][4], size = 0.0;
int a, b, hair = 0;
int totpart, totchild;
int no_draw_flag = PARS_UNEXIST;
if (psys == nullptr) {
return;
}
part = psys->part;
if (part == nullptr) {
return;
}
if (!psys_check_enabled(par, psys, for_render)) {
return;
}
if (!for_render) {
no_draw_flag |= PARS_NO_DISP;
}
/* NOTE: in old animation system, used parent object's time-offset. */
ctime = DEG_get_ctime(ctx->depsgraph);
totpart = psys->totpart;
totchild = psys->totchild;
if ((for_render || part->draw_as == PART_DRAW_REND) &&
ELEM(part->ren_as, PART_DRAW_OB, PART_DRAW_GR)) {
ParticleSimulationData sim = {nullptr};
sim.depsgraph = ctx->depsgraph;
sim.scene = scene;
sim.ob = par;
sim.psys = psys;
sim.psmd = psys_get_modifier(par, psys);
/* Make sure emitter `imat` is in global coordinates instead of render view coordinates. */
invert_m4_m4(par->imat, par->obmat);
/* First check for loops (particle system object used as dupli-object). */
if (part->ren_as == PART_DRAW_OB) {
if (ELEM(part->instance_object, nullptr, par)) {
return;
}
}
else { /* #PART_DRAW_GR. */
if (part->instance_collection == nullptr) {
return;
}
const ListBase dup_collection_objects = BKE_collection_object_cache_get(
part->instance_collection);
if (BLI_listbase_is_empty(&dup_collection_objects)) {
return;
}
if (BLI_findptr(&dup_collection_objects, par, offsetof(Base, object))) {
return;
}
}
/* If we have a hair particle system, use the path cache. */
if (part->type == PART_HAIR) {
if (psys->flag & PSYS_HAIR_DONE) {
hair = (totchild == 0 || psys->childcache) && psys->pathcache;
}
if (!hair) {
return;
}
/* We use cache, update `totchild` according to cached data. */
totchild = psys->totchildcache;
totpart = psys->totcached;
}
RNG *rng = BLI_rng_new_srandom(31415926u + uint(psys->seed));
psys->lattice_deform_data = psys_create_lattice_deform_data(&sim);
/* Gather list of objects or single object. */
int totcollection = 0;
const bool use_whole_collection = part->draw & PART_DRAW_WHOLE_GR;
const bool use_collection_count = part->draw & PART_DRAW_COUNT_GR && !use_whole_collection;
if (part->ren_as == PART_DRAW_GR) {
if (use_collection_count) {
psys_find_group_weights(part);
LISTBASE_FOREACH (ParticleDupliWeight *, dw, &part->instance_weights) {
FOREACH_COLLECTION_VISIBLE_OBJECT_RECURSIVE_BEGIN (
part->instance_collection, object, mode) {
if (dw->ob == object) {
totcollection += dw->count;
break;
}
}
FOREACH_COLLECTION_VISIBLE_OBJECT_RECURSIVE_END;
}
}
else {
FOREACH_COLLECTION_VISIBLE_OBJECT_RECURSIVE_BEGIN (
part->instance_collection, object, mode) {
(void)object;
totcollection++;
}
FOREACH_COLLECTION_VISIBLE_OBJECT_RECURSIVE_END;
}
oblist = (Object **)MEM_callocN(size_t(totcollection) * sizeof(Object *),
"dupcollection object list");
if (use_collection_count) {
a = 0;
LISTBASE_FOREACH (ParticleDupliWeight *, dw, &part->instance_weights) {
FOREACH_COLLECTION_VISIBLE_OBJECT_RECURSIVE_BEGIN (
part->instance_collection, object, mode) {
if (dw->ob == object) {
for (b = 0; b < dw->count; b++, a++) {
oblist[a] = dw->ob;
}
break;
}
}
FOREACH_COLLECTION_VISIBLE_OBJECT_RECURSIVE_END;
}
}
else {
a = 0;
FOREACH_COLLECTION_VISIBLE_OBJECT_RECURSIVE_BEGIN (
part->instance_collection, object, mode) {
oblist[a] = object;
a++;
}
FOREACH_COLLECTION_VISIBLE_OBJECT_RECURSIVE_END;
}
}
else {
ob = part->instance_object;
}
if (totchild == 0 || part->draw & PART_DRAW_PARENT) {
a = 0;
}
else {
a = totpart;
}
for (pa = psys->particles; a < totpart + totchild; a++, pa++) {
if (a < totpart) {
/* Handle parent particle. */
if (pa->flag & no_draw_flag) {
continue;
}
#if 0 /* UNUSED */
pa_num = pa->num;
#endif
size = pa->size;
}
else {
/* Handle child particle. */
cpa = &psys->child[a - totpart];
#if 0 /* UNUSED */
pa_num = a;
#endif
size = psys_get_child_size(psys, cpa, ctime, nullptr);
}
/* Some hair paths might be non-existent so they can't be used for duplication. */
if (hair && psys->pathcache &&
((a < totpart && psys->pathcache[a]->segments < 0) ||
(a >= totpart && psys->childcache[a - totpart]->segments < 0))) {
continue;
}
if (part->ren_as == PART_DRAW_GR) {
/* Prevent divide by zero below T28336. */
if (totcollection == 0) {
continue;
}
/* For collections, pick the object based on settings. */
if (part->draw & PART_DRAW_RAND_GR && !use_whole_collection) {
b = BLI_rng_get_int(rng) % totcollection;
}
else {
b = a % totcollection;
}
ob = oblist[b];
}
if (hair) {
/* Hair we handle separate and compute transform based on hair keys. */
if (a < totpart) {
cache = psys->pathcache[a];
psys_get_dupli_path_transform(&sim, pa, nullptr, cache, pamat, &scale);
}
else {
cache = psys->childcache[a - totpart];
psys_get_dupli_path_transform(&sim, nullptr, cpa, cache, pamat, &scale);
}
copy_v3_v3(pamat[3], cache->co);
pamat[3][3] = 1.0f;
}
else {
/* First key. */
state.time = ctime;
if (psys_get_particle_state(&sim, a, &state, false) == 0) {
continue;
}
float tquat[4];
normalize_qt_qt(tquat, state.rot);
quat_to_mat4(pamat, tquat);
copy_v3_v3(pamat[3], state.co);
pamat[3][3] = 1.0f;
}
if (part->ren_as == PART_DRAW_GR && psys->part->draw & PART_DRAW_WHOLE_GR) {
b = 0;
FOREACH_COLLECTION_VISIBLE_OBJECT_RECURSIVE_BEGIN (
part->instance_collection, object, mode) {
copy_m4_m4(tmat, oblist[b]->obmat);
/* Apply collection instance offset. */
sub_v3_v3(tmat[3], part->instance_collection->instance_offset);
/* Apply particle scale. */
mul_mat3_m4_fl(tmat, size * scale);
mul_v3_fl(tmat[3], size * scale);
/* Individual particle transform. */
mul_m4_m4m4(mat, pamat, tmat);
dob = make_dupli(ctx, object, mat, a);
dob->particle_system = psys;
psys_get_dupli_texture(psys, part, sim.psmd, pa, cpa, dob->uv, dob->orco);
b++;
}
FOREACH_COLLECTION_VISIBLE_OBJECT_RECURSIVE_END;
}
else {
float obmat[4][4];
copy_m4_m4(obmat, ob->obmat);
float vec[3];
copy_v3_v3(vec, obmat[3]);
zero_v3(obmat[3]);
/* Particle rotation uses x-axis as the aligned axis,
* so pre-rotate the object accordingly. */
if ((part->draw & PART_DRAW_ROTATE_OB) == 0) {
float xvec[3], q[4], size_mat[4][4], original_size[3];
mat4_to_size(original_size, obmat);
size_to_mat4(size_mat, original_size);
xvec[0] = -1.0f;
xvec[1] = xvec[2] = 0;
vec_to_quat(q, xvec, ob->trackflag, ob->upflag);
quat_to_mat4(obmat, q);
obmat[3][3] = 1.0f;
/* Add scaling if requested. */
if ((part->draw & PART_DRAW_NO_SCALE_OB) == 0) {
mul_m4_m4m4(obmat, obmat, size_mat);
}
}
else if (part->draw & PART_DRAW_NO_SCALE_OB) {
/* Remove scaling. */
float size_mat[4][4], original_size[3];
mat4_to_size(original_size, obmat);
size_to_mat4(size_mat, original_size);
invert_m4(size_mat);
mul_m4_m4m4(obmat, obmat, size_mat);
}
mul_m4_m4m4(tmat, pamat, obmat);
mul_mat3_m4_fl(tmat, size * scale);
copy_m4_m4(mat, tmat);
if (part->draw & PART_DRAW_GLOBAL_OB) {
add_v3_v3v3(mat[3], mat[3], vec);
}
dob = make_dupli(ctx, ob, mat, a);
dob->particle_system = psys;
psys_get_dupli_texture(psys, part, sim.psmd, pa, cpa, dob->uv, dob->orco);
}
}
BLI_rng_free(rng);
}
/* Clean up. */
if (oblist) {
MEM_freeN(oblist);
}
if (psys->lattice_deform_data) {
BKE_lattice_deform_data_destroy(psys->lattice_deform_data);
psys->lattice_deform_data = nullptr;
}
}
static void make_duplis_particles(const DupliContext *ctx)
{
/* Particle system take up one level in id, the particles another. */
int psysid;
LISTBASE_FOREACH_INDEX (ParticleSystem *, psys, &ctx->object->particlesystem, psysid) {
/* Particles create one more level for persistent `psys` index. */
DupliContext pctx;
if (copy_dupli_context(&pctx, ctx, ctx->object, nullptr, psysid)) {
make_duplis_particle_system(&pctx, psys);
}
}
}
static const DupliGenerator gen_dupli_particles = {
OB_DUPLIPARTS, /* type */
make_duplis_particles /* make_duplis */
};
/** \} */
/* -------------------------------------------------------------------- */
/** \name Dupli-Generator Selector For The Given Context
* \{ */
static const DupliGenerator *get_dupli_generator(const DupliContext *ctx)
{
int transflag = ctx->object->transflag;
int visibility_flag = ctx->object->visibility_flag;
if ((transflag & OB_DUPLI) == 0 && ctx->object->runtime.geometry_set_eval == nullptr) {
return nullptr;
}
/* Metaball objects can't create instances, but the dupli system is used to "instance" their
* evaluated mesh to render engines. We need to exit early to avoid recursively instancing the
* evaluated metaball mesh on metaball instances that already contribute to the basis. */
if (ctx->object->type == OB_MBALL && ctx->level > 0) {
return nullptr;
}
/* Should the dupli's be generated for this object? - Respect restrict flags. */
if (DEG_get_mode(ctx->depsgraph) == DAG_EVAL_RENDER ? (visibility_flag & OB_HIDE_RENDER) :
(visibility_flag & OB_HIDE_VIEWPORT)) {
return nullptr;
}
/* Give "Object as Font" instances higher priority than geometry set instances, to retain
* the behavior from before curve object meshes were processed as instances internally. */
if (transflag & OB_DUPLIVERTS) {
if (ctx->object->type == OB_FONT) {
return &gen_dupli_verts_font;
}
}
if (ctx->object->runtime.geometry_set_eval != nullptr) {
if (BKE_object_has_geometry_set_instances(ctx->object)) {
return &gen_dupli_geometry_set;
}
}
if (transflag & OB_DUPLIPARTS) {
return &gen_dupli_particles;
}
if (transflag & OB_DUPLIVERTS) {
if (ctx->object->type == OB_MESH) {
return &gen_dupli_verts;
}
}
else if (transflag & OB_DUPLIFACES) {
if (ctx->object->type == OB_MESH) {
return &gen_dupli_faces;
}
}
else if (transflag & OB_DUPLICOLLECTION) {
return &gen_dupli_collection;
}
return nullptr;
}
/** \} */
/* -------------------------------------------------------------------- */
/** \name Dupli-Container Implementation
* \{ */
ListBase *object_duplilist(Depsgraph *depsgraph, Scene *sce, Object *ob)
{
ListBase *duplilist = MEM_cnew<ListBase>("duplilist");
DupliContext ctx;
Vector<Object *> instance_stack;
instance_stack.append(ob);
init_context(&ctx, depsgraph, sce, ob, nullptr, instance_stack);
if (ctx.gen) {
ctx.duplilist = duplilist;
ctx.gen->make_duplis(&ctx);
}
return duplilist;
}
ListBase *object_duplilist_preview(Depsgraph *depsgraph,
Scene *sce,
Object *ob_eval,
const ViewerPath *viewer_path)
{
ListBase *duplilist = MEM_cnew<ListBase>("duplilist");
DupliContext ctx;
Vector<Object *> instance_stack;
instance_stack.append(ob_eval);
init_context(&ctx, depsgraph, sce, ob_eval, nullptr, instance_stack);
ctx.duplilist = duplilist;
Object *ob_orig = DEG_get_original_object(ob_eval);
LISTBASE_FOREACH (ModifierData *, md_orig, &ob_orig->modifiers) {
if (md_orig->type != eModifierType_Nodes) {
continue;
}
NodesModifierData *nmd_orig = reinterpret_cast<NodesModifierData *>(md_orig);
if (nmd_orig->runtime_eval_log == nullptr) {
continue;
}
geo_log::GeoModifierLog *log = static_cast<geo_log::GeoModifierLog *>(
nmd_orig->runtime_eval_log);
if (const geo_log::ViewerNodeLog *viewer_log = log->find_viewer_node_log_for_path(
*viewer_path)) {
ctx.preview_base_geometry = &viewer_log->geometry;
make_duplis_geometry_set_impl(
&ctx, viewer_log->geometry, ob_eval->obmat, true, ob_eval->type == OB_CURVES);
}
}
return duplilist;
}
void free_object_duplilist(ListBase *lb)
{
BLI_freelistN(lb);
MEM_freeN(lb);
}
/** \} */
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