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31a620b9420cab6292b0aa1ea21c9dd1cf70b8bc
blender-archive/intern/cycles/blender/blender_object.cpp
Kévin Dietrich 31a620b942 Cycles API: encapsulate Node socket members 
This encapsulates Node socket members behind a set of specific methods;
as such it is no longer possible to directly access Node class members
from exporters and parts of Cycles.

The methods are defined via the NODE_SOCKET_API macros in `graph/
node.h`, and are for getting or setting a specific socket's value, as
well as querying or modifying the state of its update flag.

The setters will check whether the value has changed and tag the socket
as modified appropriately. This will let us know how a Node has changed
and what to update, which is the first concrete step toward a more
granular scene update system.

Since the setters will tag the Node sockets as modified when passed
different data, this patch also removes the various modified methods
on Nodes in favor of Node::is_modified which checks the sockets'
update flags status.

Reviewed By: brecht

Maniphest Tasks: T79174

Differential Revision: https://developer.blender.org/D8544
2020-11-04 13:03:33 +01:00

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/*
* Copyright 2011-2013 Blender Foundation
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include "render/camera.h"
#include "render/graph.h"
#include "render/integrator.h"
#include "render/light.h"
#include "render/mesh.h"
#include "render/nodes.h"
#include "render/object.h"
#include "render/particles.h"
#include "render/scene.h"
#include "render/shader.h"
#include "blender/blender_object_cull.h"
#include "blender/blender_sync.h"
#include "blender/blender_util.h"
#include "util/util_foreach.h"
#include "util/util_hash.h"
#include "util/util_logging.h"
#include "util/util_task.h"
CCL_NAMESPACE_BEGIN
/* Utilities */
bool BlenderSync::BKE_object_is_modified(BL::Object &b_ob)
{
/* test if we can instance or if the object is modified */
if (b_ob.type() == BL::Object::type_META) {
/* multi-user and dupli metaballs are fused, can't instance */
return true;
}
else if (ccl::BKE_object_is_modified(b_ob, b_scene, preview)) {
/* modifiers */
return true;
}
else {
/* object level material links */
BL::Object::material_slots_iterator slot;
for (b_ob.material_slots.begin(slot); slot != b_ob.material_slots.end(); ++slot)
if (slot->link() == BL::MaterialSlot::link_OBJECT)
return true;
}
return false;
}
bool BlenderSync::object_is_geometry(BL::Object &b_ob)
{
BL::ID b_ob_data = b_ob.data();
if (!b_ob_data) {
return false;
}
BL::Object::type_enum type = b_ob.type();
if (type == BL::Object::type_VOLUME || type == BL::Object::type_HAIR) {
/* Will be exported attached to mesh. */
return true;
}
else if (type == BL::Object::type_CURVE) {
/* Skip exporting curves without faces, overhead can be
* significant if there are many for path animation. */
BL::Curve b_curve(b_ob_data);
return (b_curve.bevel_object() || b_curve.extrude() != 0.0f || b_curve.bevel_depth() != 0.0f ||
b_curve.dimensions() == BL::Curve::dimensions_2D || b_ob.modifiers.length());
}
else {
return (b_ob_data.is_a(&RNA_Mesh) || b_ob_data.is_a(&RNA_Curve) ||
b_ob_data.is_a(&RNA_MetaBall));
}
}
bool BlenderSync::object_is_light(BL::Object &b_ob)
{
BL::ID b_ob_data = b_ob.data();
return (b_ob_data && b_ob_data.is_a(&RNA_Light));
}
/* Object */
Object *BlenderSync::sync_object(BL::Depsgraph &b_depsgraph,
BL::ViewLayer &b_view_layer,
BL::DepsgraphObjectInstance &b_instance,
float motion_time,
bool use_particle_hair,
bool show_lights,
BlenderObjectCulling &culling,
bool *use_portal,
TaskPool *geom_task_pool)
{
const bool is_instance = b_instance.is_instance();
BL::Object b_ob = b_instance.object();
BL::Object b_parent = is_instance ? b_instance.parent() : b_instance.object();
BL::Object b_ob_instance = is_instance ? b_instance.instance_object() : b_ob;
const bool motion = motion_time != 0.0f;
/*const*/ Transform tfm = get_transform(b_ob.matrix_world());
int *persistent_id = NULL;
BL::Array<int, OBJECT_PERSISTENT_ID_SIZE> persistent_id_array;
if (is_instance) {
persistent_id_array = b_instance.persistent_id();
persistent_id = persistent_id_array.data;
}
/* light is handled separately */
if (!motion && object_is_light(b_ob)) {
if (!show_lights) {
return NULL;
}
/* TODO: don't use lights for excluded layers used as mask layer,
* when dynamic overrides are back. */
#if 0
if (!((layer_flag & view_layer.holdout_layer) && (layer_flag & view_layer.exclude_layer)))
#endif
{
sync_light(b_parent,
persistent_id,
b_ob,
b_ob_instance,
is_instance ? b_instance.random_id() : 0,
tfm,
use_portal);
}
return NULL;
}
/* only interested in object that we can create meshes from */
if (!object_is_geometry(b_ob)) {
return NULL;
}
/* Perform object culling. */
if (culling.test(scene, b_ob, tfm)) {
return NULL;
}
/* Visibility flags for both parent and child. */
PointerRNA cobject = RNA_pointer_get(&b_ob.ptr, "cycles");
bool use_holdout = get_boolean(cobject, "is_holdout") ||
b_parent.holdout_get(PointerRNA_NULL, b_view_layer);
uint visibility = object_ray_visibility(b_ob) & PATH_RAY_ALL_VISIBILITY;
if (b_parent.ptr.data != b_ob.ptr.data) {
visibility &= object_ray_visibility(b_parent);
}
/* TODO: make holdout objects on excluded layer invisible for non-camera rays. */
#if 0
if (use_holdout && (layer_flag & view_layer.exclude_layer)) {
visibility &= ~(PATH_RAY_ALL_VISIBILITY - PATH_RAY_CAMERA);
}
#endif
/* Clear camera visibility for indirect only objects. */
bool use_indirect_only = !use_holdout &&
b_parent.indirect_only_get(PointerRNA_NULL, b_view_layer);
if (use_indirect_only) {
visibility &= ~PATH_RAY_CAMERA;
}
/* Don't export completely invisible objects. */
if (visibility == 0) {
return NULL;
}
/* Use task pool only for non-instances, since sync_dupli_particle accesses
* geometry. This restriction should be removed for better performance. */
TaskPool *object_geom_task_pool = (is_instance) ? NULL : geom_task_pool;
/* key to lookup object */
ObjectKey key(b_parent, persistent_id, b_ob_instance, use_particle_hair);
Object *object;
/* motion vector case */
if (motion) {
object = object_map.find(key);
if (object && object->use_motion()) {
/* Set transform at matching motion time step. */
int time_index = object->motion_step(motion_time);
if (time_index >= 0) {
array<Transform> motion = object->get_motion();
motion[time_index] = tfm;
object->set_motion(motion);
}
/* mesh deformation */
if (object->get_geometry())
sync_geometry_motion(b_depsgraph,
b_ob_instance,
object,
motion_time,
use_particle_hair,
object_geom_task_pool);
}
return object;
}
/* test if we need to sync */
bool object_updated = false;
if (object_map.add_or_update(&object, b_ob, b_parent, key))
object_updated = true;
/* mesh sync */
/* b_ob is owned by the iterator and will go out of scope at the end of the block.
* b_ob_instance is the original object and will remain valid for deferred geometry
* sync. */
Geometry *geometry = sync_geometry(b_depsgraph,
b_ob_instance,
b_ob_instance,
object_updated,
use_particle_hair,
object_geom_task_pool);
object->set_geometry(geometry);
/* special case not tracked by object update flags */
if (sync_object_attributes(b_instance, object)) {
object_updated = true;
}
/* holdout */
object->set_use_holdout(use_holdout);
if (object->use_holdout_is_modified()) {
scene->object_manager->tag_update(scene);
}
object->set_visibility(visibility);
bool is_shadow_catcher = get_boolean(cobject, "is_shadow_catcher");
object->set_is_shadow_catcher(is_shadow_catcher);
float shadow_terminator_offset = get_float(cobject, "shadow_terminator_offset");
object->set_shadow_terminator_offset(shadow_terminator_offset);
/* sync the asset name for Cryptomatte */
BL::Object parent = b_ob.parent();
ustring parent_name;
if (parent) {
while (parent.parent()) {
parent = parent.parent();
}
parent_name = parent.name();
}
else {
parent_name = b_ob.name();
}
object->set_asset_name(parent_name);
/* object sync
* transform comparison should not be needed, but duplis don't work perfect
* in the depsgraph and may not signal changes, so this is a workaround */
if (object->is_modified() || object_updated ||
(object->get_geometry() && object->get_geometry()->is_modified()) ||
tfm != object->get_tfm()) {
object->name = b_ob.name().c_str();
object->set_pass_id(b_ob.pass_index());
object->set_color(get_float3(b_ob.color()));
object->set_tfm(tfm);
array<Transform> motion;
object->set_motion(motion);
/* motion blur */
Scene::MotionType need_motion = scene->need_motion();
if (need_motion != Scene::MOTION_NONE && object->get_geometry()) {
Geometry *geom = object->get_geometry();
geom->set_use_motion_blur(false);
geom->set_motion_steps(0);
uint motion_steps;
if (need_motion == Scene::MOTION_BLUR) {
motion_steps = object_motion_steps(b_parent, b_ob, Object::MAX_MOTION_STEPS);
geom->set_motion_steps(motion_steps);
if (motion_steps && object_use_deform_motion(b_parent, b_ob)) {
geom->set_use_motion_blur(true);
}
}
else {
motion_steps = 3;
geom->set_motion_steps(motion_steps);
}
motion.resize(motion_steps, transform_empty());
if (motion_steps) {
motion[motion_steps / 2] = tfm;
/* update motion socket before trying to access object->motion_time */
object->set_motion(motion);
for (size_t step = 0; step < motion_steps; step++) {
motion_times.insert(object->motion_time(step));
}
}
}
/* dupli texture coordinates and random_id */
if (is_instance) {
object->set_dupli_generated(0.5f * get_float3(b_instance.orco()) -
make_float3(0.5f, 0.5f, 0.5f));
object->set_dupli_uv(get_float2(b_instance.uv()));
object->set_random_id(b_instance.random_id());
}
else {
object->set_dupli_generated(make_float3(0.0f, 0.0f, 0.0f));
object->set_dupli_uv(make_float2(0.0f, 0.0f));
object->set_random_id(hash_uint2(hash_string(object->name.c_str()), 0));
}
object->tag_update(scene);
}
if (is_instance) {
/* Sync possible particle data. */
sync_dupli_particle(b_parent, b_instance, object);
}
return object;
}
/* This function mirrors drw_uniform_property_lookup in draw_instance_data.cpp */
static bool lookup_property(BL::ID b_id, const string &name, float4 *r_value)
{
PointerRNA ptr;
PropertyRNA *prop;
if (!RNA_path_resolve(&b_id.ptr, name.c_str(), &ptr, &prop)) {
return false;
}
PropertyType type = RNA_property_type(prop);
int arraylen = RNA_property_array_length(&ptr, prop);
if (arraylen == 0) {
float value;
if (type == PROP_FLOAT)
value = RNA_property_float_get(&ptr, prop);
else if (type == PROP_INT)
value = RNA_property_int_get(&ptr, prop);
else
return false;
*r_value = make_float4(value, value, value, 1.0f);
return true;
}
else if (type == PROP_FLOAT && arraylen <= 4) {
*r_value = make_float4(0.0f, 0.0f, 0.0f, 1.0f);
RNA_property_float_get_array(&ptr, prop, &r_value->x);
return true;
}
return false;
}
/* This function mirrors drw_uniform_attribute_lookup in draw_instance_data.cpp */
static float4 lookup_instance_property(BL::DepsgraphObjectInstance &b_instance,
const string &name,
bool use_instancer)
{
string idprop_name = string_printf("[\"%s\"]", name.c_str());
float4 value;
/* If requesting instance data, check the parent particle system and object. */
if (use_instancer && b_instance.is_instance()) {
BL::ParticleSystem b_psys = b_instance.particle_system();
if (b_psys) {
if (lookup_property(b_psys.settings(), idprop_name, &value) ||
lookup_property(b_psys.settings(), name, &value)) {
return value;
}
}
if (lookup_property(b_instance.parent(), idprop_name, &value) ||
lookup_property(b_instance.parent(), name, &value)) {
return value;
}
}
/* Check the object and mesh. */
BL::Object b_ob = b_instance.object();
BL::ID b_data = b_ob.data();
if (lookup_property(b_ob, idprop_name, &value) || lookup_property(b_ob, name, &value) ||
lookup_property(b_data, idprop_name, &value) || lookup_property(b_data, name, &value)) {
return value;
}
return make_float4(0.0f);
}
bool BlenderSync::sync_object_attributes(BL::DepsgraphObjectInstance &b_instance, Object *object)
{
/* Find which attributes are needed. */
AttributeRequestSet requests = object->get_geometry()->needed_attributes();
/* Delete attributes that became unnecessary. */
vector<ParamValue> &attributes = object->attributes;
bool changed = false;
for (int i = attributes.size() - 1; i >= 0; i--) {
if (!requests.find(attributes[i].name())) {
attributes.erase(attributes.begin() + i);
changed = true;
}
}
/* Update attribute values. */
foreach (AttributeRequest &req, requests.requests) {
ustring name = req.name;
std::string real_name;
BlenderAttributeType type = blender_attribute_name_split_type(name, &real_name);
if (type != BL::ShaderNodeAttribute::attribute_type_GEOMETRY) {
bool use_instancer = (type == BL::ShaderNodeAttribute::attribute_type_INSTANCER);
float4 value = lookup_instance_property(b_instance, real_name, use_instancer);
/* Try finding the existing attribute value. */
ParamValue *param = NULL;
for (size_t i = 0; i < attributes.size(); i++) {
if (attributes[i].name() == name) {
param = &attributes[i];
break;
}
}
/* Replace or add the value. */
ParamValue new_param(name, TypeDesc::TypeFloat4, 1, &value);
assert(new_param.datasize() == sizeof(value));
if (!param) {
changed = true;
attributes.push_back(new_param);
}
else if (memcmp(param->data(), &value, sizeof(value)) != 0) {
changed = true;
*param = new_param;
}
}
}
return changed;
}
/* Object Loop */
void BlenderSync::sync_objects(BL::Depsgraph &b_depsgraph,
BL::SpaceView3D &b_v3d,
float motion_time)
{
/* Task pool for multithreaded geometry sync. */
TaskPool geom_task_pool;
/* layer data */
bool motion = motion_time != 0.0f;
if (!motion) {
/* prepare for sync */
light_map.pre_sync();
geometry_map.pre_sync();
object_map.pre_sync();
particle_system_map.pre_sync();
motion_times.clear();
}
else {
geometry_motion_synced.clear();
}
/* initialize culling */
BlenderObjectCulling culling(scene, b_scene);
/* object loop */
bool cancel = false;
bool use_portal = false;
const bool show_lights = BlenderViewportParameters(b_v3d).use_scene_lights;
BL::ViewLayer b_view_layer = b_depsgraph.view_layer_eval();
BL::Depsgraph::object_instances_iterator b_instance_iter;
for (b_depsgraph.object_instances.begin(b_instance_iter);
b_instance_iter != b_depsgraph.object_instances.end() && !cancel;
++b_instance_iter) {
BL::DepsgraphObjectInstance b_instance = *b_instance_iter;
BL::Object b_ob = b_instance.object();
/* Viewport visibility. */
const bool show_in_viewport = !b_v3d || b_ob.visible_in_viewport_get(b_v3d);
if (show_in_viewport == false) {
continue;
}
/* Load per-object culling data. */
culling.init_object(scene, b_ob);
/* Ensure the object geom supporting the hair is processed before adding
* the hair processing task to the task pool, calling .to_mesh() on the
* same object in parallel does not work. */
const bool sync_hair = b_instance.show_particles() && object_has_particle_hair(b_ob);
/* Object itself. */
if (b_instance.show_self()) {
sync_object(b_depsgraph,
b_view_layer,
b_instance,
motion_time,
false,
show_lights,
culling,
&use_portal,
sync_hair ? NULL : &geom_task_pool);
}
/* Particle hair as separate object. */
if (sync_hair) {
sync_object(b_depsgraph,
b_view_layer,
b_instance,
motion_time,
true,
show_lights,
culling,
&use_portal,
&geom_task_pool);
}
cancel = progress.get_cancel();
}
geom_task_pool.wait_work();
progress.set_sync_status("");
if (!cancel && !motion) {
sync_background_light(b_v3d, use_portal);
/* handle removed data and modified pointers */
light_map.post_sync();
geometry_map.post_sync();
object_map.post_sync();
particle_system_map.post_sync();
}
if (motion)
geometry_motion_synced.clear();
}
void BlenderSync::sync_motion(BL::RenderSettings &b_render,
BL::Depsgraph &b_depsgraph,
BL::SpaceView3D &b_v3d,
BL::Object &b_override,
int width,
int height,
void **python_thread_state)
{
if (scene->need_motion() == Scene::MOTION_NONE)
return;
/* get camera object here to deal with camera switch */
BL::Object b_cam = b_scene.camera();
if (b_override)
b_cam = b_override;
int frame_center = b_scene.frame_current();
float subframe_center = b_scene.frame_subframe();
float frame_center_delta = 0.0f;
if (scene->need_motion() != Scene::MOTION_PASS &&
scene->camera->get_motion_position() != Camera::MOTION_POSITION_CENTER) {
float shuttertime = scene->camera->get_shuttertime();
if (scene->camera->get_motion_position() == Camera::MOTION_POSITION_END) {
frame_center_delta = -shuttertime * 0.5f;
}
else {
assert(scene->camera->get_motion_position() == Camera::MOTION_POSITION_START);
frame_center_delta = shuttertime * 0.5f;
}
float time = frame_center + subframe_center + frame_center_delta;
int frame = (int)floorf(time);
float subframe = time - frame;
python_thread_state_restore(python_thread_state);
b_engine.frame_set(frame, subframe);
python_thread_state_save(python_thread_state);
if (b_cam) {
sync_camera_motion(b_render, b_cam, width, height, 0.0f);
}
sync_objects(b_depsgraph, b_v3d, 0.0f);
}
/* Insert motion times from camera. Motion times from other objects
* have already been added in a sync_objects call. */
if (b_cam) {
uint camera_motion_steps = object_motion_steps(b_cam, b_cam);
for (size_t step = 0; step < camera_motion_steps; step++) {
motion_times.insert(scene->camera->motion_time(step));
}
}
/* note iteration over motion_times set happens in sorted order */
foreach (float relative_time, motion_times) {
/* center time is already handled. */
if (relative_time == 0.0f) {
continue;
}
VLOG(1) << "Synchronizing motion for the relative time " << relative_time << ".";
/* fixed shutter time to get previous and next frame for motion pass */
float shuttertime = scene->motion_shutter_time();
/* compute frame and subframe time */
float time = frame_center + subframe_center + frame_center_delta +
relative_time * shuttertime * 0.5f;
int frame = (int)floorf(time);
float subframe = time - frame;
/* change frame */
python_thread_state_restore(python_thread_state);
b_engine.frame_set(frame, subframe);
python_thread_state_save(python_thread_state);
/* Syncs camera motion if relative_time is one of the camera's motion times. */
sync_camera_motion(b_render, b_cam, width, height, relative_time);
/* sync object */
sync_objects(b_depsgraph, b_v3d, relative_time);
}
/* we need to set the python thread state again because this
* function assumes it is being executed from python and will
* try to save the thread state */
python_thread_state_restore(python_thread_state);
b_engine.frame_set(frame_center, subframe_center);
python_thread_state_save(python_thread_state);
}
CCL_NAMESPACE_END
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