I just finished implementing VBO's in my 3D app and saw a roughly 5-10x speed increase in rendering. What used to render at 1-2 frames per second now renders at 10-11 frames per second.

My question is, are there any further improvements I can make to increase rendering speed? Will triangle strips make a big difference? Currently vertices are not being shared between faces, each faces vertices are unique but overlapping.

My Device Utilization is 100%, Tiler Utilization is 100%, Renderer Utilization is 11%, and resource bytes is 114819072. This is rendering 912,120 faces on a CAD model.

Any suggestions?


A Tiler Utilization of 100% indicates that your bottleneck is in the size of the geometry being sent to the GPU. Whatever you can do to shrink the geometry size can lead to an almost linear reduction in rendering time, in my experience. These tuning steps have worked for me in the past:

  • If you're not already, you could look at using indexing, which might cut down on geometry by eliminating some redundant vertices. The PowerVR GPUs in the iOS devices are optimized for using indexed geometry, as well.

  • Try using a smaller data type for your vertex information. I found that I could use GLshort instead of GLfloat for my vertices and normals without losing much precision in the rendering. This will significantly compact your geometry and lead to a nice speed boost in rendering.

  • Bin similarly colored vertices and render them as one group at a set color, rather than supplying per-vertex color information. The overhead from the few extra draw calls this requires will be vastly outweighed by the speedup you get from not having to send all that color information. I saw a ~18% reduction in rendering time by binning the colors in one of my larger models.

  • You're already using VBOs, so you've taken advantage of that optimization.

  • Don't halt the rendering pipeline at any point. Cut out anything that reads the current state, like all glGet* calls, because they really mess with the flow of the PowerVR GPUs.

There are other things you can do that will lead to smaller performance improvements, like using interleaved vertex, normal, texture data in your VBOs, aligning your data to 4 byte boundaries, etc., but the ones above are what I've found to have the largest impact in the tuning of my own OpenGL ES 1.1 application.

Most of these points are covered well in the "Best Practices for Working with Vertex Data" section of Apple's OpenGL ES Programming Guide for iOS.

  • How does indexed geometry (bullet point 1) work with interleaved vertex arrays? Apple says that interleaved arrays are the most efficient, but I can't figure out how it would work with indexing. Currently I'm using glDrawArrays(). Can you post a quick code sample of how to render using VBO's with glDrawElements? Thanks. – Davido Apr 20 '11 at 16:19
  • @Davido - Put per-vertex information in the VBOs as groupings (vertex, normal, texture coordinate, vertex, normal, texture coordinate...). Each index refers to a vertex, so for each index the corresponding vertex, normal, and texture coordinate will be pulled in when drawing. Grab the code to Molecules, where you can see an example of interleaved indexed drawing: sunsetlakesoftware.com/molecules . Unfortunately, I don't yet have the version of the application on there which also does color-based binning, but I will soon. – Brad Larson Apr 20 '11 at 16:26
  • Ahhh, after much searching I now remember why I used glDrawArrays as opposed to glDrawElements in the first place. glDrawElements does not support GL_UNSIGNED_INT, which effectively limits it to rendering no more than 65536 vertices for a single index array. Problem is, my model that has a million faces has about 760,000 indices in the index array. Using glDrawElements would greatly increase the complexity of the code by being limited to 65536 indices per array. Any ideas on this one, or am I stuck with glDrawArrays? – Davido Apr 20 '11 at 17:15
  • @Davido - In my case, I use multiple VBOs for storing geometry with more than 65536 indices. It's not that hard to construct an array of them, and segment your model appropriately. I still suspect that the buffer switching and drawing call overhead would be outweighed by the faster rendering from the reduced geometry size. You could do a quick calculation to see what your size is with and without indexing to see how much you could gain be going this way. – Brad Larson Apr 20 '11 at 17:30
  • The theoretical limit that I should be able to achieve with 920,000 faces is 9,807,360 (based on my own run of GLBenchmark) polygons per second (iPad2), divided by my number of faces, which is 10.66 frames per second, correct? So if I'm currently getting my frame rate switching back and forth between 10 and 11 fps in instruments, how will further optimizations affect my app performance if I'm already at the limit? Just curious. – Davido Apr 21 '11 at 17:13

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