# How much perf can I get using half_floats for vertex attribs?

Currently I have a dynamic VBO (updated every frame, particle system). I send 4 floats for pos and 4 floats for color.

How much perf can I expect if I move to half_float data type? Is it something like 5% or maybe 30%?

Lets assume I want to send 100k...500k particles, in point sprites. So I send around 100k*8*4bytes = ~3MB

Of course I am aware that there might be differences between various GPUs...

• If you have this high number of vertices, first thing I would do is to use only three floats for position and omit the homogeneous coordinate (since it will be 1 in general). This will decrease the total VBO size dramatically.
– BDL
Feb 27, 2015 at 12:31
• yes, that's another good idea: it would save 1/8 of the bandwith. But half floats could reduce this even more
– fen
Feb 27, 2015 at 12:35
• and how to efficiently copy data from array of vec4 into array of vec3? just a simple for loop?
– fen
Feb 27, 2015 at 12:58
• Usually performance of the input assembler is related to the overall size and alignment of the vertex structure itself (32 or 64 bytes tend to be the most efficient). Using float16s can be useful to achieve improved vertex size/alignment. Feb 27, 2015 at 20:47

You are paying for the more for the conversion from full float to half float each time you change the data than you would for the 2 bytes you save per half float.

So check what saves you more in the long run, less memory bandwidth or spending more time filling the VBO. If the CPU is idle often (waiting for vsync) then optimizing bandwidth at the cost of cpu time will win out, however if a lot of time is spend doing physics on the CPU then you can't afford to convert to half float.

Unless you have a very efficient conversion function for a type that is usually not built-in and you can afford the CPU hit I wouldn't bother.

Given that you are looking for a compacter data format then I suggest using a linear scale (u)int16 (set uniform to true to map {-32768, 32767} to {-1, 1} or {0, 65565} to {0, 1}) instead, if you don't need the precision near 0 then this will provide better accuracy.

4 floats for color is very likely unnecessary to begin with.

You can probably get away with 4 unsigned bytes. Conversion from 8-bit fixed-point numbers to floating-point is ridiculously cheap on GPUs (this is what they were originally designed to do), so you can cut memory requirements for color down 75% with no inherent performance impact. Of course, as others have mentioned, alignment becomes an issue. Changing to a 4-byte color from 16-byte can easily mess up a vec4-aligned vertex data structure unless you pad it, add some extra attribute (like say a 3D vertex normal) or change another member of the data structure.

A `vec3` position plus a 4-byte color fits nicely into cache boundaries, and you should really try that first unless you actually use a non-1.0 homogeneous coordinate (seriously)? This will give you the same memory requirements as switching everything to half-floats, but you still get full precision position.

• how to convert from vec4 to rgba8 efficiently? or maybe it's better to perform computation directly on rgba8? My initial tests shows not much performance improvement... maybe I loose time on doing conversions inefficiently (vec4 array into vec3 and then vec4 into rgba8)
– fen
Mar 1, 2015 at 18:52
• I really wouldn't expect much in the way of performance improvements, to be honest. You're doing the transformation on the CPU and then transferring it to the GPU each frame, which is going to be more of a performance bottleneck than memory bandwidth. Ultimately moving the particle simulation onto the GPU itself is ideal - this is much easier to accomplish these days thanks to transform feedback / compute shaders. Mar 1, 2015 at 20:34
• yes, that's a good option, but I just want to explore CPU particle system. In the next "release" I'll probably stick with the GPU side.
– fen
Mar 2, 2015 at 19:28