void Octree::Raycast(RayOctreeQuery& query) const
{
PROFILE(Raycast);
query.result_.Clear();
WorkQueue* queue = GetSubsystem<WorkQueue>();
// If no worker threads or no triangle-level testing, do not create work items
if (!queue->GetNumThreads() || query.level_ < RAY_TRIANGLE)
GetDrawablesInternal(query);
else
{
// Threaded ray query: first get the drawables
rayQuery_ = &query;
rayQueryDrawables_.Clear();
GetDrawablesOnlyInternal(query, rayQueryDrawables_);
// Check that amount of drawables is large enough to justify threading
if (rayQueryDrawables_.Size() >= RAYCASTS_PER_WORK_ITEM * 2)
{
for (unsigned i = 0; i < rayQueryResults_.Size(); ++i)
rayQueryResults_[i].Clear();
PODVector<Drawable*>::Iterator start = rayQueryDrawables_.Begin();
while (start != rayQueryDrawables_.End())
{
SharedPtr<WorkItem> item = queue->GetFreeItem();
item->priority_ = M_MAX_UNSIGNED;
item->workFunction_ = RaycastDrawablesWork;
item->aux_ = const_cast<Octree*>(this);
PODVector<Drawable*>::Iterator end = rayQueryDrawables_.End();
if (end - start > RAYCASTS_PER_WORK_ITEM)
end = start + RAYCASTS_PER_WORK_ITEM;
item->start_ = &(*start);
item->end_ = &(*end);
queue->AddWorkItem(item);
start = end;
}
// Merge per-thread results
queue->Complete(M_MAX_UNSIGNED);
for (unsigned i = 0; i < rayQueryResults_.Size(); ++i)
query.result_.Insert(query.result_.End(), rayQueryResults_[i].Begin(), rayQueryResults_[i].End());
}
else
{
for (PODVector<Drawable*>::Iterator i = rayQueryDrawables_.Begin(); i != rayQueryDrawables_.End(); ++i)
(*i)->ProcessRayQuery(query, query.result_);
}
}
Sort(query.result_.Begin(), query.result_.End(), CompareRayQueryResults);
}
void Renderer2D::HandleBeginViewUpdate(StringHash eventType, VariantMap& eventData)
{
using namespace BeginViewUpdate;
// Check that we are updating the correct scene
if (GetScene() != eventData[P_SCENE].GetPtr())
return;
frame_ = static_cast<View*>(eventData[P_VIEW].GetPtr())->GetFrameInfo();
URHO3D_PROFILE(UpdateRenderer2D);
Camera* camera = static_cast<Camera*>(eventData[P_CAMERA].GetPtr());
frustum_ = &camera->GetFrustum();
if (camera->IsOrthographic() && camera->GetNode()->GetWorldDirection() == Vector3::FORWARD)
{
// Define bounding box with min and max points
frustumBoundingBox_.Define(frustum_->vertices_[2], frustum_->vertices_[4]);
frustum_ = 0;
}
viewMask_ = camera->GetViewMask();
// Check visibility
{
URHO3D_PROFILE(CheckDrawableVisibility);
WorkQueue* queue = GetSubsystem<WorkQueue>();
int numWorkItems = queue->GetNumThreads() + 1; // Worker threads + main thread
int drawablesPerItem = drawables_.Size() / numWorkItems;
PODVector<Drawable2D*>::Iterator start = drawables_.Begin();
for (int i = 0; i < numWorkItems; ++i)
{
SharedPtr<WorkItem> item = queue->GetFreeItem();
item->priority_ = M_MAX_UNSIGNED;
item->workFunction_ = CheckDrawableVisibility;
item->aux_ = this;
PODVector<Drawable2D*>::Iterator end = drawables_.End();
if (i < numWorkItems - 1 && end - start > drawablesPerItem)
end = start + drawablesPerItem;
item->start_ = &(*start);
item->end_ = &(*end);
queue->AddWorkItem(item);
start = end;
}
queue->Complete(M_MAX_UNSIGNED);
}
ViewBatchInfo2D& viewBatchInfo = viewBatchInfos_[camera];
// Create vertex buffer
if (!viewBatchInfo.vertexBuffer_)
viewBatchInfo.vertexBuffer_ = new VertexBuffer(context_);
UpdateViewBatchInfo(viewBatchInfo, camera);
// Go through the drawables to form geometries & batches and calculate the total vertex / index count,
// but upload the actual vertex data later. The idea is that the View class copies our batch vector to
// its internal data structures, so we can reuse the batches for each view, provided that unique Geometry
// objects are used for each view to specify the draw ranges
batches_.Resize(viewBatchInfo.batchCount_);
for (unsigned i = 0; i < viewBatchInfo.batchCount_; ++i)
{
batches_[i].material_ = viewBatchInfo.materials_[i];
batches_[i].geometry_ = viewBatchInfo.geometries_[i];
}
}
void Octree::Update(const FrameInfo& frame)
{
// Let drawables update themselves before reinsertion. This can be used for animation
if (!drawableUpdates_.Empty())
{
PROFILE(UpdateDrawables);
// Perform updates in worker threads. Notify the scene that a threaded update is going on and components
// (for example physics objects) should not perform non-threadsafe work when marked dirty
Scene* scene = GetScene();
WorkQueue* queue = GetSubsystem<WorkQueue>();
scene->BeginThreadedUpdate();
int numWorkItems = queue->GetNumThreads() + 1; // Worker threads + main thread
int drawablesPerItem = Max((int)(drawableUpdates_.Size() / numWorkItems), 1);
PODVector<Drawable*>::Iterator start = drawableUpdates_.Begin();
// Create a work item for each thread
for (int i = 0; i < numWorkItems; ++i)
{
SharedPtr<WorkItem> item = queue->GetFreeItem();
item->priority_ = M_MAX_UNSIGNED;
item->workFunction_ = UpdateDrawablesWork;
item->aux_ = const_cast<FrameInfo*>(&frame);
PODVector<Drawable*>::Iterator end = drawableUpdates_.End();
if (i < numWorkItems - 1 && end - start > drawablesPerItem)
end = start + drawablesPerItem;
item->start_ = &(*start);
item->end_ = &(*end);
queue->AddWorkItem(item);
start = end;
}
queue->Complete(M_MAX_UNSIGNED);
scene->EndThreadedUpdate();
}
// Notify drawable update being finished. Custom animation (eg. IK) can be done at this point
Scene* scene = GetScene();
if (scene)
{
using namespace SceneDrawableUpdateFinished;
VariantMap& eventData = GetEventDataMap();
eventData[P_SCENE] = scene;
eventData[P_TIMESTEP] = frame.timeStep_;
scene->SendEvent(E_SCENEDRAWABLEUPDATEFINISHED, eventData);
}
// Reinsert drawables that have been moved or resized, or that have been newly added to the octree and do not sit inside
// the proper octant yet
if (!drawableUpdates_.Empty())
{
PROFILE(ReinsertToOctree);
for (PODVector<Drawable*>::Iterator i = drawableUpdates_.Begin(); i != drawableUpdates_.End(); ++i)
{
Drawable* drawable = *i;
drawable->updateQueued_ = false;
Octant* octant = drawable->GetOctant();
const BoundingBox& box = drawable->GetWorldBoundingBox();
// Skip if no octant or does not belong to this octree anymore
if (!octant || octant->GetRoot() != this)
continue;
// Skip if still fits the current octant
if (drawable->IsOccludee() && octant->GetCullingBox().IsInside(box) == INSIDE && octant->CheckDrawableFit(box))
continue;
InsertDrawable(drawable);
#ifdef _DEBUG
// Verify that the drawable will be culled correctly
octant = drawable->GetOctant();
if (octant != this && octant->GetCullingBox().IsInside(box) != INSIDE)
{
LOGERROR("Drawable is not fully inside its octant's culling bounds: drawable box " + box.ToString() +
" octant box " + octant->GetCullingBox().ToString());
}
#endif
}
}
drawableUpdates_.Clear();
}
void DrawableProxy2D::HandleBeginViewUpdate(StringHash eventType, VariantMap& eventData)
{
using namespace BeginViewUpdate;
// Check that we are updating the correct scene
if (GetScene() != eventData[P_SCENE].GetPtr())
return;
PROFILE(UpdateDrawableProxy2D);
if (orderDirty_)
{
Sort(drawables_.Begin(), drawables_.End(), CompareDrawable2Ds);
orderDirty_ = false;
}
Camera* camera = static_cast<Camera*>(eventData[P_CAMERA].GetPtr());
frustum_ = &camera->GetFrustum();
if (camera->IsOrthographic() && camera->GetNode()->GetWorldDirection() == Vector3::FORWARD)
{
// Define bounding box with min and max points
frustumBoundingBox_.Define(frustum_->vertices_[2], frustum_->vertices_[4]);
frustum_ = 0;
}
{
PROFILE(CheckDrawableVisibility);
WorkQueue* queue = GetSubsystem<WorkQueue>();
int numWorkItems = queue->GetNumThreads() + 1; // Worker threads + main thread
int drawablesPerItem = drawables_.Size() / numWorkItems;
PODVector<Drawable2D*>::Iterator start = drawables_.Begin();
for (int i = 0; i < numWorkItems; ++i)
{
SharedPtr<WorkItem> item = queue->GetFreeItem();
item->priority_ = M_MAX_UNSIGNED;
item->workFunction_ = CheckDrawableVisibility;
item->aux_ = this;
PODVector<Drawable2D*>::Iterator end = drawables_.End();
if (i < numWorkItems - 1 && end - start > drawablesPerItem)
end = start + drawablesPerItem;
item->start_ = &(*start);
item->end_ = &(*end);
queue->AddWorkItem(item);
start = end;
}
queue->Complete(M_MAX_UNSIGNED);
}
vertexCount_ = 0;
for (unsigned i = 0; i < drawables_.Size(); ++i)
{
if (drawables_[i]->GetVisibility())
vertexCount_ += drawables_[i]->GetVertices().Size();
}
indexCount_ = vertexCount_ / 4 * 6;
// Go through the drawables to form geometries & batches, but upload the actual vertex data later
materials_.Clear();
Material* material = 0;
unsigned iStart = 0;
unsigned iCount = 0;
unsigned vStart = 0;
unsigned vCount = 0;
for (unsigned d = 0; d < drawables_.Size(); ++d)
{
if (!drawables_[d]->GetVisibility())
continue;
Material* usedMaterial = drawables_[d]->GetUsedMaterial();
const Vector<Vertex2D>& vertices = drawables_[d]->GetVertices();
if (material != usedMaterial)
{
if (material)
{
AddBatch(material, iStart, iCount, vStart, vCount);
iStart += iCount;
iCount = 0;
vStart += vCount;
vCount = 0;
}
material = usedMaterial;
}
iCount += vertices.Size() / 4 * 6;
vCount += vertices.Size();
}
if (material)
AddBatch(material, iStart, iCount, vStart, vCount);
// Now the amount of batches is known. Build the part of source batches that are sensitive to threading issues
// (material & geometry pointers)
unsigned count = materials_.Size();
batches_.Resize(count);
for (unsigned i = 0; i < count; ++i)
{
batches_[i].material_ = materials_[i];
batches_[i].geometry_ = geometries_[i];
}
}