I'm trying to decide what the most efficient way to render a bunch of cubes with different textures in a Minecraft-like game is.

I discovered instanced rendering. What I've done is I've created a single "cube model" which stores all the vertices, normals, and texture coordinates for a cube, I create an array buffer out of that and pass it to the GPU once. Then I created a array of (translation vector, texture index) structs and I use instanced rendering to redraw the same cube over and over, each time translated and with the appropriate texture.

(Hopefully Notch doesn't mind me using his textures until I make my own)

The problem is that not all 6 sides will always have the same texture, and I'm trying to figure out how I can get them to be different for each block type. The two solutions I've come up with are:

  1. Use a different Model for each block type. This way I can specify different texture coordinates on each of the vertices. I can still use instanced rendering, but I'd have do a separate pass for each block type.
  2. Pass 6 "texture indexes" (1 for each face) instead of 1 for every block.

The 2nd solution requires passing a lot more, possibly redundant, data. I'm not sure how great the benefits of instanced rendering are... so I don't know if it would be better to do, say, up to 256 "passes" (1 for each block type), or "one big pass" with all the data, and render every block in one shot.

Or perhaps there's another method I'm not aware of?


I don't think you can do it efficiently with instances. Vast majority of faces/cubes is never visible and you can save a lot of time by not rendering them. Unfortunately that makes every cube a different object.

The standard solution (and how it's done in Minecraft) is to divide your terrain into sectors . Compute which faces are visible and upload them to GPU. When a cube changes you just need to re-upload it's sector. When rendering a sector you just draw primitives without any other computations.

You can do something based on sparse voxel octrees. It's much more work, but you would be able to efficiently and accurately tell which parts of your world are visible.

  • Good point, but here, I'd give a simple "instance culling" pass using geometry shaders and transform feedback a chance first, which can be combined with octrees and partitions later on. – Sam Feb 5 '12 at 20:28
  • Things suddenly got a lot more complicated. I was going to decide how to do the textures first, and then look into pruning methods. I thought I'd end up pruning the non-visible cubes, but I guess doing it based on faces makes more sense now that you mention it. This raises a few new questions though. That essentially means I'm doing the culling/pruning on the CPU, no? Wouldn't that a) be slower, and b) reimplementing all the logic the GPU normally does for me? With regard to octrees, are you suggesting I keep the terrain data in such a data structure or would I use that for pruning purposes... – mpen Feb 5 '12 at 20:47
  • ...only? This article suggests that octrees are actually inefficient for storing the terrain as each access now has the overhead of doing through m layers of the octree. Lastly, if a prune out the majority of the cubes/faces, what happens when I want to do lighting? Won't some relevant data be missing from the GPU/GLSL? i.e., a face might not be visible to the viewer, but it can still block light? Or are my dreams of nice shadows on this scale unrealistic to begin with? – mpen Feb 5 '12 at 20:48
  • 1
    When it comes to light and shadow, which require individual transformed render passes, instance culling can be applied for each. As long as lights and their corresponding lighted cubes dont move/change, the culling / shadow map pass needs not to be redone. I don't think its unrealistic. To lookup, in which light cone or partition a cube changed (user interactions), the CPU is the right location to do this and initiate GPU supported processing of that section. – Sam Feb 5 '12 at 21:06
  • I suggest to implement instanced rendering within a reusable 'section' class, which can have a shape required for any intersection tests required for cubes in lights or partitions. This section class should have its own instance array containing each cube it intersects. This will be filled on init and modified if a cube gets out or in – Sam Feb 5 '12 at 21:16

I know this question is almost two years old, but may I would make a 3D texture which stores all of the individual textures, where the z texture coordinate would be sorta like the block ID. With the 3D texture, you can now bind all of your individual block textures at once, meaning you can use instanced rendering to pass in you transformations along with a blockID to grab the correct block texture for the 3D sampler.


On my nVidia 8600M GT I found out, that instancing performs best "in the middle" with moderate vertex and instance counts, but I ended up instancing a couple of vertices thousands of times to eliminate redundant data along with the effort to update it.

I'd choose 2, using a texture array along with a single, instanced cube in the vertex array and select the face texture using your texture indices of your 'per instance array', where the 6 indices may even be packed into few integers. For supplying instance attribs, GL_ARB_instanced_arrays can also be of use, where one does not need to access a buffer using gl_InstanceID (predictable and therefore faster in most cases). If you need to have instance specific texture coords, I'd bind an additional per instance and vertex texture coord array, along with an accordingly modified shader.

  • I wasn't using gl_InstanceID -- you'd use that with a uniform holding your texture indices I suppose? Didn't think of doing it that way. I'm using glDrawElementsInstancedBaseVertex, and putting the instance data in the GL_ARRAY_BUFFER with usage hint GL_DYNAMIC_DRAW. Where does "ARB_instanced_arrays" come into play? Not sure what that is. – mpen Feb 5 '12 at 20:18
  • Your choice of "2" seems at odds with your first paragraph. "1" would be the "more middle" solution, no? 1 uses instances, just with smaller chunks of data in each pass. You'd go with 2, even with say, 200K cubes on screen? – mpen Feb 5 '12 at 20:20
  • EDIT: Yes, I'd do benchmarks first.... You will run out of uniform components sooner or later, so I'd use "texture buffer objects". – Sam Feb 5 '12 at 20:25
  • The alternative to using texture buffer objects with gl_InstanceID are aforesaid instanced arrays. The 8600M GT is rather old, new cards are better at hardware supported instancing, where less vertices may be advantageous due to caching etc.. I can't give a clear hint here, but I'd postpone this for benchmarks and optimization later on, as it shouldn't break your basic concept. – Sam Feb 5 '12 at 20:46
  • Well I'm about to embark down one path or the other. I'd rather not waste too much time on benchmarking this early on until it becomes a barrier, as you said. The problem though is I'm already down to about 60 FPS and even lower (~20) at full screen. This is before any pruning though... that's another issue I haven't worked out yet. – mpen Feb 5 '12 at 20:54

Really late answer, but somebody's bound to need it.

Have a method in the main block class that returns the texture, with a parameter for the face. In the individual classes that need multiple textures, override this method and use a switch case or a series of if/else statements.

This is what the method would look like in the block class:

public int getBlockTexture(int face){
     if(face = top){
         return grass top
     } else if(face = bottom){
         return grass bottom
     } else {
         return grass side

As for how you use this in the renderer, grab the texture before you render each face. Similar to how you do culling.

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