This page has been translated automatically.
Video Tutorials
Interface
Essentials
Advanced
How To
UnigineEditor
Interface Overview
Assets Workflow
Settings and Preferences
Working With Projects
Adjusting Node Parameters
Setting Up Materials
Setting Up Properties
Lighting
Landscape Tool
Sandworm
Using Editor Tools for Specific Tasks
Extending Editor Functionality
Built-in Node Types
Nodes
Objects
Effects
Decals
Light Sources
Geodetics
World Nodes
Sound Objects
Pathfinding Objects
Players
Programming
Fundamentals
Setting Up Development Environment
Usage Examples
C++
C#
UnigineScript
UUSL (Unified UNIGINE Shader Language)
Plugins
File Formats
Rebuilding the Engine Tools
GUI
Double Precision Coordinates
API
Containers
Common Functionality
Controls-Related Classes
Engine-Related Classes
Filesystem Functionality
GUI-Related Classes
Math Functionality
Node-Related Classes
Objects-Related Classes
Networking Functionality
Pathfinding-Related Classes
Physics-Related Classes
Plugins-Related Classes
IG Plugin
CIGIConnector Plugin
Rendering-Related Classes
Content Creation
Materials
Material Nodes Library
Miscellaneous
Input
Math
Matrix
Textures
Art Samples
Tutorials
Warning! This version of documentation is OUTDATED, as it describes an older SDK version! Please switch to the documentation for the latest SDK version.
Warning! This version of documentation describes an old SDK version which is no longer supported! Please upgrade to the latest SDK version.

Occlusion Culling

Object culling allows you not to render objects which are not presented in the viewing frustum. The particular cases of occlusion culling are the following:

Notice
As the object's bounding box is used for occlusion culling (it is checked if the bounding box is visible or not), it is recommended to export objects from 3D computer graphics software in local coordinates to make bounds of the mesh closer to geometry.

Occluders#

Occluders allow culling geometry that isn't visible behind them. There are 2 types of occluders:

The type of occluder to be used is defined by geometry to be culled.

Occluders can be very effective in case of complex environments where there are many objects that occlude each other and are costly to render (they have a lot of polygons and/or heavy shaders).

Notice
Using occluders to cull large objects with a few surfaces may cause additional performance loss. Moreover, occluders aren't effective in scenes with flat objects, or when a camera looks down on the scene from above. So, when using the occluders, you should take into account peculiarities of objects to be culled.

Before using occluders, check the following:

  • Rendering of occluders is enabled: in the Menu Bar, Rendering -> Occlusion Culling -> Occluders is toggled on.
  • Rendering of shadows from the occluded objects is disabled: in the Menu Bar, choose Rendering -> Occlusion Culling and toggle Shadows Culling on.
    Notice
    You can leave shadows rendering enabled, if necessary.

Usage of occluders is shown in the Content Optimization video tutorial.

Using a Box-Shaped Occluder#

The occluder is a box shape that culls objects' surfaces, bounds of which aren't visible behind it. This is the simplest type of occluders that should be used together with box-shaped objects that block off other objects. For example, you can add an occluder the shape of which coincides with the bounds of a building to avoid rendering of objects behind this building.

Box-shaped occluder inside building

To create a box-shaped occluder, perform the following:

  1. In the Menu Bar, choose Create -> Optimization -> Occluder and add the occluder as a child to the node that should occlude other objects.
  2. In the Common section of the Node tab in the Parameters window, set the position of the occluder to the parent one.

  3. In the World Occluder section of the Node tab, click Edit Size to enable the editing mode for the occluder. Resize the occluder by using the colored rectangles on the occluder box sides so that it coincides with the parent node size.
    Notice
    You can also use the Size parameter to set the size along the axes.

  4. Specify the Distance between the camera and the occluder, at which the occluder doesn't occlude anything and, therefore, should be disabled to avoid negative impact on the performance.

To check how the occluder works, disable the parent node and then try to toggle the occluder on and off:

By default, the front faces of the occluder are used to cull objects. However, if the camera is inside the occluder (e.g. inside the building), occlusion culling won't be performed. To avoid such situation, enable the Back Face parameter in the World Occluder section of the Node tab.

Using a Mesh-Based Occluder#

The occluder mesh is based on an arbitrary mesh that culls objects' surfaces, bounds of which aren't visible behind it. The occluder mesh is used together with the geometry that cannot be approximated with a box.

To create a mesh-based occluder, perform the following:

  1. Prepare a low-poly mesh to be used for the occluder.
    Notice
    It isn't recommended to use the same detailed mesh that is used for the node that should occlude other objects: the mesh for the occluder should be as simple as possible to avoid performance loss.

  2. In the Menu Bar, choose Create -> Optimization -> Occluder Mesh and specify the prepared mesh.
    Notice
    You can load a new mesh for the occluder at any time.
  3. Add the occluder as a child to the node that should occlude other objects.
  4. In the Common section of the Node tab in the Parameters window, set the position of the occluder to the parent one.

  5. Specify the Distance between the camera and the occluder, at which the occluder doesn't occlude anything and, therefore, should be disabled to avoid negative impact on the performance.

Hardware Occlusion Queries#

One more option to cull geometry that is not visible in the camera viewport is to use a hardware occlusion query. It allows skipping rendering of objects, the bounding boxes of which are covered by another solid geometry. As a result, the number of rendered polygons is reduced and the performance grows.

To run the hardware occlusion test for the scene before sending data to the GPU, toggle the Rendering -> Occlusion Culling -> Occlusion Query flag on in the Menu Bar.

Notice
Culling will be performed for all objects with the Culled by Occlusion Query flag set in the Node tab of the Parameters window.

To run the hardware occlusion test, perform the following:

  1. In the Menu Bar, toggle the Rendering -> Occlusion Culling -> Occlusion Query flag on to enable testing for the scene before sending data to the GPU.

  2. For all objects, that should be culled, enable the Culled by Occlusion Query flag in the Node tab of the Parameters window.
    Notice
    Only nodes with this flag set are tested on the hardware occlusion culling.

When culling is enabled for the object, an occlusion query box is rendered for it.

Material ball and its occlusion query box
Notice
To visualize such boxes, toggle the Helpers -> Occlusion Queries option on.

The occlusion query box coincides with the size of the object's bounding box. When this box is overlapped (i.e. it isn't in the camera viewport), it is highlighted red, which means the occlusion test is not passed and the mesh will not be drawn.

Occlusion query test passed
Occlusion query test failed, material ball isn't rendered
Notice
Hardware occlusion queries should be used only for objects that use heavy shaders. Otherwise, performance will decrease instead of increasing. It is recommended to enable queries for water or objects with reflections.

You can check the effect of this technique by enabling the second wireframe mode to see all triangles in the scene. Type render_show_triangles 2 in the console and check the way the occluded polygons act.

An example of using hardware occlusion queries is also available in the Content Optimization video tutorial.

Last update: 2021-12-13
Build: ()