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After many years of hearing about Vertex Buffer Objects (VBOs), I finally decided to experiment with them (my stuff isn't normally performance critical, obviously...)

I'll describe my experiment below, but to make a long story short, I'm seeing indistinguishable performance between "simple" direct mode (glBegin()/glEnd()), vertex array (CPU side) and VBO (GPU side) rendering modes. I'm trying to understand why this is, and under what conditions I can expect to see the VBOs significantly outshine their primitive (pun intended) ancestors.

Experiment Details

For the experiment, I generated a (static) 3D Gaussian cloud of a large number of points. Each point has vertex & color information associated with it. Then I rotated the camera around the cloud in successive frames in sort of an "orbiting" behavior. Again, the points are static, only the eye moves (via gluLookAt()). The data are generated once prior to any rendering & stored in two arrays for use in the rendering loop.

For direct rendering, the entire data set is rendered in a single glBegin()/glEnd() block with a loop containing a single call each to glColor3fv() and glVertex3fv().

For vertex array and VBO rendering, the entire data set is rendered with a single glDrawArrays() call.

Then, I simply run it for a minute or so in a tight loop and measure average FPS with the high performance timer.

Performance Results ##

As mentioned above, performance was indistinguishable on both my desktop machine (XP x64, 8GB RAM, 512 MB Quadro 1700), and my laptop (XP32, 4GB ram, 256 MB Quadro NVS 110). It did scale as expected with the number of points, however. Obviously, I also disabled vsync.

Specific results from laptop runs (rendering w/GL_POINTS):

glBegin()/glEnd():

  • 1K pts --> 603 FPS
  • 10K pts --> 401 FPS
  • 100K pts --> 97 FPS
  • 1M pts --> 14 FPS

Vertex Arrays (CPU side):

  • 1K pts --> 603 FPS
  • 10K pts --> 402 FPS
  • 100K pts --> 97 FPS
  • 1M pts --> 14 FPS

Vertex Buffer Objects (GPU side):

  • 1K pts --> 604 FPS
  • 10K pts --> 399 FPS
  • 100K pts --> 95 FPS
  • 1M pts --> 14 FPS

I rendered the same data with GL_TRIANGLE_STRIP and got similarly indistinguishable (though slower as expected due to extra rasterization). I can post those numbers too if anybody wants them. .

Question(s)

  • What gives?
  • What do I have to do to realize the promised performance gain of VBOs?
  • What am I missing?
share|improve this question
    
Maybe nVidia's drivers are optimising things behind your back? The problem there is it's impossible to test that in isolation... –  flussence Jan 10 '09 at 4:37
    
That thought occurred to me as well. I also thought that perhaps Quadro vs. GeForce (i.e. professional vs. gamer card) might have something to do with it. –  Drew Hall Jan 11 '09 at 2:39
    
How can they optimise the glBegin()/glEnd() version? @Shy: Out of curiosity, why did you edit the question? @Drew Hall: Could you post the program or the source somewhere? I'd like to give it a try (and maybe watch the cloud for a minute or two.) –  aib Jan 12 '09 at 23:10
    
@aib: Sorry, I'd like to but I can't post the code. I'll see if I can post an executable or at least a screenshot somewhere. –  Drew Hall Jan 15 '09 at 2:53
    
@Drew Hall: Never mind, ended up building one myself :) –  aib Jan 22 '09 at 1:43

6 Answers 6

There are a lot of factors to optimizing 3D rendering. usually there are 4 bottlenecks:

  • CPU (creating vertices, APU calls, everything else)
  • Bus (CPU<->GPU transfer)
  • Vertex (vertex shader over fixed function pipeline execution)
  • Pixel (fill, fragment shader execution and rops)

Your test is giving skewed results because you have a lot of CPU (and bus) while maxing out vertex or pixel throughput. VBOs are used to lower CPU (fewer api calls, parallel to CPU DMA transfers). Since you are not CPU bound, they don't give you any gain. This is optimization 101. In a game for example CPU becomes precious as it is needed for other things like AI and physics, not just for issuing tons of api calls. It is easy to see that writing vertex data (3 floats for example) directly to a memory pointer is much faster than calling a function that writes 3 floats to memory - at the very least you save the cycles for the call.

share|improve this answer
    
My understanding was that Vertex Arrays (GL 1.1) were used to lower CPU (minimize function calls), while VBOs built on that to also knock down bus activity. I thought that my experiment would be bus bound (or CPU bound for simple glBegin() drawing) but I guess I was wrong. Can you comment? Thks! –  Drew Hall Jan 10 '09 at 18:40
    
vbos will only lower bus activity if your geometry is static, that is reused across frames. also make sure that you flag them write only in that case. further reading: developer.nvidia.com/object/using_VBOs.html –  starmole Jan 14 '09 at 4:38
    
@starmole: Great link. I had the VBOs flagged as STATIC_DRAW, but hadn't marked them as WRITE_ONLY (I wasn't using glMapBuffer()). I'll make the change & see what happens. Thanks for the tip! –  Drew Hall Jan 14 '09 at 4:52
    
@starmole: I tried mapping as WRITE_ONLY (actually, tried all three modes) with no effect. Did a quick map/unmap immediately after glBufferData--did I do that right? Still confused... :( –  Drew Hall Jan 14 '09 at 5:16
1  
@Drew Hall: strange. Here's some other empirical measures in a game engine that is evaluating moving from vertex arrays to VBOs: glest.org/glest_board/index.php?topic=6260.msg65644#msg65644 –  Will Jan 28 '11 at 10:41

There might be a few things missing:

  1. It's a wild guess, but your laptop's card might be missing this kind of operation at all (i.e. emulating it).

  2. Are you copying the data to GPU's memory (via glBufferData(GL_ARRAY_BUFFER with either GL_STATIC_DRAW or GL_DYNAMIC_DRAW param) or are you using pointer to main (non GPU) array in memory? (that requires copying it every frame and therefore performance is slow)

  3. Are you passing indices as another buffer sent via glBufferData and GL_ELEMENT_ARRAY_BUFFER params?

If those three things are done, the performance gain is big. For Python (v/pyOpenGl) it's about 1000 times faster on arrays bigger than a couple 100 elemnts, C++ up to 5 times faster, but on arrays 50k-10m vertices.

Here are my test results for c++ (Core2Duo/8600GTS):

 pts   vbo glb/e  ratio
 100  3900  3900   1.00
  1k  3800  3200   1.18
 10k  3600  2700   1.33
100k  1500   400   3.75
  1m   213    49   4.34
 10m    24     5   4.80

So even with 10m vertices it was normal framerate while with glB/e it was sluggish.

share|improve this answer

As a side note:
The "direct mode" (glBegin/glEnd) is not supported in:

  • OpenGLES.
  • OpenGL 3.x.
  • So if you ever plan to port your application to a mobile platform (e.g. iPhone), don't even get used to it.

    I teach OpenGL at University and the slide explaining glBegin/glEnd has a big red box around it with an extra bold "DO NOT USE" header.

    Using vertex arrays is just two lines more and you save cycles right from the start.

    share|improve this answer
        
    Thanks. I included the direct mode calls just so I could see the VBO performance improvement in all its glory (best vs. worst performance). –  Drew Hall Jan 14 '09 at 3:07
    3  
    Direct mode isn't supported in OpenGL 3+'s core profile. There's still the compatibility profile, so you can use it. The general gist of "don't use glBegin/glEnd" is good advice though. –  Bernard Jul 30 '12 at 6:11

    From reading the Red Book, I remember a passage that stated that VBOs are possibly faster depending on the hardware. Some hardware optimizes those, while others don't. It's possible that your hardware doesn't.

    share|improve this answer
        
    Thanks. It's hard to see how keeping the data resident on the card wouldn't always be faster (even without significant extra optimization in the driver), but I guess I'm having trouble getting my code to be "bus bound". –  Drew Hall Jan 14 '09 at 3:11
        
    @Will Mc (again): Also hard to imagine that Nvidia wouldn't be somewhere near the cutting edge in terms of implementing VBO optimizations. Seems more likely that they've (also) found a way to optimize the direct path to me. –  Drew Hall Jan 14 '09 at 3:15

    14Mpoints/s is not a whole lot. It's suspect. can we see the complete code doing the drawing, as well as the initialisation ? (compare that 14M/s to the 240M/s (!) that Slava Vishnyakov gets). It's even more suspicious that it drops to 640K/s for 1K draws (compared with his 3.8M/s, that looks capped by the ~3800 SwapBuffers, anyways).

    I'd be beting the test does not measure what you think it measures.

    share|improve this answer

    Assuming I remember this right my OpenGL teacher, who is well known in the OpenGL community, said they are faster on static geometry which is going to be render a lot of time's on a typical game this will be tables chair and small static entities.

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