I've been wanting to learn how to procedurally generate meshes in Unreal for some time now, and have noticed interest from the community as well.
There have been a few good discussions on the Unreal forums, but not a lot of samples for how to do this.
The purpose of this project is to provide examples for how to generate geometry in code, from simple cubes to more complex geometry generated from fractal algorithms.
I would love for this to become a community project, so I will accept both pull requests for new samples as well as any corrections to my code. I'm also willing to add contributors directly if anyone is interested (see contact information below).
I wrote the code to be readable, trying my best to explain each step along the way. There are many ways this code could be optimized to run better, but I wanted to keep things simple in the first few examples.
There is a lot of code duplication between the different examples which I felt was OK for the first few examples, but I will refactor some of the common functions into a utility class soon.
PLEASE NOTE: I update these examples from time to time to follow the latest Unreal versions. If you get really stuck feel free to send a PR or contact me below.
Meshes are created by setting up 3d coordinates and then defining polygons between those.
When creating meshes we enter data into a few different arrays. All of the arrays are of the same length except the Triangles one, and all of them reference the Vertices array in some way.
This is a collection of all the points (vectors) in the 3d mesh.
A triangular polygon is defined by 3 points in space, and this array contains references to what entries in the Vertices array define a polygon.
The order in which we add the vertices governs the way the polygon will face, and if you look at the back of a polygon it will simply be invisible (they are all one sided).
If you add vertices on a polygon in a counter-clockwise order, the polygon will face "towards you".
Example: We have 9 entries in the Vertices array and want to create a polygon from entries 4 to 6. The Triangles array would then contain the numbers: 3, 4, 5 (zero-based arrays).
A UV coordinate is simply the X,Y coordinate on a texture that the corresponding vertex will have. The GPU then interpolates how to display the texture in between the vertices.
A normal is a vector that defines the direction a polygon is facing, or in this case the direction the polygon faces where the vertex is positioned.
Normally (pun intended) this can be calculated easily from the vectors in the polygon, but sometimes we want to manipulate this to provide smooth surfaces and other tricks. See SimpleCylinder for an example of smoothing a curved surface.
A tangent is a vector that is perpendicular (forms a 90 degree angle) with the normal and is parallell to the polygon surface.
At first this project was using Epic's ProceduralMeshComponent but I later converted it to using Koderz's excellent RuntimeMeshComponent. See: https://github.com/Koderz/UE4RuntimeMeshComponent
We start off with a very simple example of drawing a cube where you can set the Depth, Width and Height dimensions.
Shows how to draw a cylinder with configurable radius, height and how many polygons to use on the sides.
Shows how to use normals to smooth out a surface, draw polygons on both sides and how to close the ends of the cylinder.
In this example we show how you can define multiple points in space and then draw a cylinder section between each point to form a line.
Note that this example does not join the meshes where the lines meet at the corners. I'm planning on providing an example for that later on, both in the form of a quick method (rotated cross sections that skew the cylinder) and a more expensive method that looks correct (projecting a circle on a plane defined by the angle where the lines meet).
I have always been fascinated by fractals, and they are one of the reasons I wanted to learn how to make custom geometry in Unreal.
All fractals are drawn by a few very simple rules, but can create incredibly complicated results.
One of the first examples of a fractal I learned to draw is the Sierpinski pyramid, which looks like a triangle made out of other triangles!
For this example I went one step further and created a 3d pyramid version of the Sierpinski triangle, drawing it with cylindrical lines in 3d space.
Later on I want to provide an example pyramid drawn with a polygonal surface instead of lines.
Another simple algorhitm that can create complex shapes seen in nature, including trees and lightning.
You start by defining two points in space and draw a line between them. Then add a point in the center of that line, and shift it out in a random direction. Then repeat this step for the two new sections created and repeat!
Simple grid mesh with noise on the Z axis.
Grid mesh with an animated Z axis using sine and cosine.
I want to provide more examples in the future, and would love if members of the community could provide some! Of course you will get full credit for your contributions.
- Joined cylinders (fast method and properly joined).
- Proper UV maps for Sierpinski pyramid and branching lines
- Sphere
- Sierpinski pyramid without lines
- Mesh exporter function that creates a new static mesh asset in the editor.
- Proper L-systems
- Animated lightning
- Geometry shaders?
Using the ProceduralMeshComponent has some limitations as mention above. I also want to provide animated examples in the future where updates are sent to the GPU on every frame, and I think its going to be far more efficient to do that by writing my own UPrimitiveComponent, PrimitiveSceneProxy and RHI rendering implementations.
If you have any questions, suggestions or want to contribute to this project please contact me at one of these places:
- You can reach me via email at [email protected]
- Message me on the Unreal forums on username SiggiG.
- Twitter: https://twitter.com/SiggiGG
MIT License
Copyright (c) 2016 Sigurdur Gunnarsson
Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
- UV checking texture by Lukas Dubeda - http://blog.duber.cz/