10. Other Features

10.1. Decals

Use the Render Alpha On Surface component with a material using the Crest/Ocean Surface Alpha shader. For an example, please see the CrestLogo game object floating in the Main example scene.

Use the Decal Projector. Make sure to enable Affects Transparent.

Use the Render Alpha On Surface component with a material using the Crest/Ocean Surface Alpha shader. For an example, please see the CrestLogo game object floating in the Main example scene.

10.2. Floating origin

Crest has support for ‘floating origin’ functionality, based on code from the Unity Community Wiki. See the original Floating Origin wiki page for an overview and original code.

It is tricky to get pop free results for world space texturing. To make it work the following is required:

  • Set the floating origin threshold to a power of 2 value (such as 4096).

  • Set the size/scale of any world space textures to be a smaller power of 2. This way the texture tiles an integral number of times across the threshold, and when the origin moves no change in appearance is noticeable. This includes the following textures:

    • Normals: set the Normal Mapping Scale on the ocean material

    • Foam texture: set the Foam Scale on the ocean material

    • Caustics: also should be a power of 2 scale, if caustics are visible when origin shifts happen

By default the FloatingOrigin script will call FindObjectsOfType() for a few different component types, which is a notoriously expensive operation. It is possible to provide custom lists of components to the “override” fields, either by hand or programmatically, to avoid searching the entire scene(s) for the components. Managing these lists at run-time is left to the user.


Surface details like foam and normals can pop on teleports.


Sponsoring us will help increase our development bandwidth which could work towards improving this feature.

10.3. Buoyancy


Buoyancy physics for boats is not a core focus of Crest. For a professional physics solution we recommend the DWP2 asset which is compatible with Crest.

With that said, we do provide rudimentary physics scripts.

SimpleFloatingObject is a simple buoyancy script that attempts to match the object position and rotation with the surface height and normal. This can work well enough for small water craft that don’t need perfect floating behaviour, or floating objects such as buoys, barrels, etc.

BoatProbes is a more advanced implementation that computes buoyancy forces at a number of ForcePoints and uses these to apply force and torque to the object. This gives more accurate results at the cost of more queries.

BoatAlignNormal is a rudimentary boat physics emulator that attaches an engine and rudder to SimpleFloatingObject. It is not recommended for cases where high animation quality is required.

10.3.1. Adding boats

Setting up a boat with physics can be a dark art. The authors recommend duplicating and modifying one of the existing boat prefabs, and proceeding slowly and carefully as follows:

  1. Pick an existing boat to replace. Only use BoatAlignNormal if good floating behaviour is not important, as mentioned above. The best choice is usually BoatProbes.

  2. Duplicate the prefab of the one you want to replace, such as crest/Assets/Crest/Crest-Examples/BoatDev/Data/BoatProbes.prefab

  3. Remove the render meshes from the prefab, and add the render mesh for your boat. We recommend lining up the meshes roughly.

  4. Switch out the collision shape as desired. Some people report issues if the are multiple overlapping physics collision primitives (or multiple rigidbodies which should never be the case). We recommend keeping things as simple as possible and using only one collider if possible.

  5. We recommend placing the render mesh so its approximate center of mass matches the center of the collider and is at the center of the boat transform. Put differently, we usually try to eliminate complex hierarchies or having nested non-zero’d transforms whenever possible within the boat hierarchy, at least on or above physical parts.

  6. If you have followed these steps you will have a new boat visual mesh and collider, with the old rigidbody and boat script. You can then modify the physics settings to move the behaviour towards how you want it to be.

  7. The mass and drag settings on the boat scripts and rigdibody help to give a feeling of weight.

  8. Set the boat dimension:

    • BoatProbes: Set the Min Spatial Length param to the width of the boat.

    • BoatAlignNormal: Set the boat Boat Width and Boat Length to the width and length of the boat.

    • If, even after experimenting with the mass and drag, the boat is responding too much to small waves, increase these parameters (try doubling or quadrupling at first and then compensate).

  9. There are power settings for engine turning which also help to give a feeling of weight.

  10. The dynamic wave interaction is driven by the object in the boat hierarchy called WaterObjectInteractionSphere. It can be scaled to match the dimensions of the boat. The Weight param controls the strength of the interaction.

The above steps should maintain a working boat throughout - we recommend testing after each step to catch issues early.