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I'd like to hear from people with experience of coding for both. Myself, I only have experience with NVIDIA.

NVIDIA CUDA seems to be a lot more popular than the competition. (Just counting question tags on this forum, 'cuda' outperforms 'opencl' 3:1, and 'nvidia' outperforms 'ati' 15:1, and there's no tag for 'ati-stream' at all).

On the other hand, according to Wikipedia, ATI/AMD cards should have a lot more potential, especially per dollar. The fastest NVIDIA card on the market as of today, GeForce 580 ($500), is rated at 1.6 single-precision TFlops. AMD Radeon 6970 can be had for $370 and it is rated at 2.7 TFlops. The 580 has 512 execution units at 772 MHz. The 6970 has 1536 execution units at 880 MHz.

How realistic is that paper advantage of AMD over NVIDIA, and is it likely to be realized in most GPGPU tasks? What happens with integer tasks?

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Interesting question, but I'm not sure it's really programming-related ? –  Paul R Jan 9 '11 at 8:31
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It is essentially a question about two programming languages and practical aspects of their implementations. So I'd say yes. –  user434507 Jan 9 '11 at 8:41
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I wonder how relevant answers to this question have become in light of C++ AMP. –  Dmitri Nesteruk Mar 12 '12 at 17:22
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At one point, I was looking into why Bitcoin mining is so slow on NVIDIA hardware as compared to AMD. The resulting thread, "AMD Radeon 3x faster on bitcoin mining (SHA-256 hashing performance)", contains information that you may find interesting re. your question. forums.nvidia.com/… –  Roger Dahl Mar 23 '12 at 18:40

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up vote 42 down vote accepted

Metaphorically speaking ati has a good engine compared to nvidia. But nvidia has a better car :D

This is mostly because nvidia has invested good amount of its resources (in money and people) to develop important libraries required for scientific computing (BLAS, FFT), and then a good job again in promoting it. This may be the reason CUDA dominates the tags over here compared to ati (or OpenCL)

As for the advantage being realized in GPGPU tasks in general, it would end up depending on other issues (depending on the application) such as, memory transfer bandwidth, a good compiler and probably even the driver. nvidia having a more mature compiler, a more stable driver on linux (linux because, its use is widespread in scientific computing), tilt the balance in favor of CUDA (at least for now).


EDIT Jan 12, 2013

It's been two years since I made this post and it still seems to attract views sometimes. So I have decided to clarify a few things

  • AMD has stepped up their game. They now have both BLAS and FFT libraries. Numerous third party libraries are also cropping up around OpenCL.
  • Intel has introduced Xeon Phi into the wild supporting both OpenMP and OpenCL. It also has the ability use existing x86 code. as noted in the comments, limited x86 without SSE for now
  • NVIDIA and CUDA still have the edge in the range of libraries available. However they may not be focusing on OpenCL as much as they did before.

In short OpenCL has closed the gap in the past two years. There are new players in the field. But CUDA is still a bit ahead of the pack.

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Xeon Phi has only limited ability of x86 code execution. No MMX/SSE/SSE*. –  osgx Jan 13 '13 at 2:55
    
@osgx Thanks. I should have mentioned that. –  Pavan Yalamanchili Jan 13 '13 at 4:29
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@osgx But it performs well in DP FP –  Csaba Toth Oct 25 '13 at 18:14
    
Xeon Phi has 512-bit wide registers and instructions which is 4x of what SSE supports. –  zr. Nov 21 '13 at 19:32

I don't have any strong feelings about CUDA vs. OpenCL; presumably OpenCL is the long-term future, just by dint of being an open standard.

But current-day NVIDIA vs ATI cards for GPGPU (not graphics performance, but GPGPU), that I do have a strong opinion about. And to lead into that, I'll point out that on the current Top 500 list of big clusters, NVIDIA leads AMD 4 systems to 1, and on gpgpu.org, search results (papers, links to online resources, etc) for NVIDIA outnumber results for AMD 6:1.

A huge part of this difference is the amount of online information available. Check out the NVIDIA CUDA Zone versus AMD's GPGPU Developer Central. The amount of stuff there for developers starting up doesn't even come close to comparing. On NVIDIAs site you'll find tonnes of papers - and contributed code - from people probably working on problems like yours. You'll find tonnes of online classes, from NVIDIA and elsewhere, and very useful documents like the developers' best pratice guide, etc. The availability of free devel tools - the profiler, the cuda-gdb, etc - overwhelmingly tilts NVIDIAs way.

And some of the difference is also hardware. AMDs cards have better specs in terms of peak flops, but to be able to get a significiant fraction of that, you have to not only break your problem up onto many completely independent stream processors, each work item also needs to be vectorized. Given that GPGPUing ones code is hard enough, that extra architectural complexity is enough to make or break some projects.

And the result of all of this is that the NVIDIA user community continues to grow. Of the three or four groups I know thinking of building GPU clusters, none of them are seriously considering AMD cards. And that will mean still more groups writing papers, contributing code, etc on the NVIDIA side.

I'm not an NVIDIA shill; I wish it weren't this way, and that there were two (or more!) equally compelling GPGPU platforms. Competition is good. Maybe AMD will step up its game very soon - and the upcoming fusion products look very compelling. But in giving someone advice about which cards to buy today, and where to spend their time putting effort in right now, I can't in good conscience say that both development environments are equally good.

Edited to add: I guess the above is a little elliptical in terms of answering the original question, so let me make it a bit more explicit. The performance you can get from a piece of hardware is, an ideal world with infinite time available, dependant only on the underlying hardware and the capabilities of the programming language; but in reality, the amount of performance you can get in a fixed amount of time invested is also strongly dependant on devel tools, existing community code bases (eg, publically available libraries, etc). Those considerations all point strongly to NVIDIA.

In terms of hardware, the reqiurement for vectorization within SIMD units in the AMD cards also make achieving paper performance even harder than with NVIDIA hardware.

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I am learning OpenCL using ATI Stream, appreciate the note about vectorizing :) While I realize NVIDIA benefits are..fairly large, I simply support AMD/ATI and the company itself and I have time to spend making libraries :D I think OpenCL performance will definitely increase in coming years and I'd like my code to be ready for that as well. –  Garet Claborn Jan 28 '11 at 13:30
    
It would be interesting to see what you think of AMD`s GCN and OpenCL 1.2, now (2013) that simds are a thing of the past. Any net difference? –  danstermeister Sep 12 '13 at 22:30
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@Jonathan it's now 3 years since you wrote this great post. I was wondering if in your view the AMD platform, community and ecosystem have closed the gap. –  spaceCamel Jan 22 at 15:35

The main difference between AMD's and NVIDIA's architectures is that AMD is optimized for problems where the behavior of the algorithm can be determined at compile-time while NVIDIA is optimized for problems where the behavior of the algorithm can only be determined at run-time.

AMD has a relatively simple architecture that allows them to spend more transistors on ALU's. As long as the problem can be fully defined at compile-time and be successfully mapped to the architecture in a somewhat static or linear way, there is a good chance that AMD will be able to run the algorithm faster than NVIDIA.

On the other hand, NVIDIA's compiler is doing less analysis at compile time. Instead, NVIDIA has a more advanced architecture where they have spent more transistors on logic that is able to handle dynamic behavior of the algorithm that only emerges at run-time.

I believe the fact that most supercomputers that use GPUs go with NVIDIA is that the type of problem that scientists are interested in running calculations on, in general map better to NVIDIA's architecture than AMD's.

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With GCN (Graphics Core Next), AMD has moved away from SIMD and VLIW to an architecture more similar to NVIDIA's (SIMT and more flexible instruction scheduling). –  Aleksandr Dubinsky Oct 7 '13 at 10:06
    
@AleksandrDubinsky: And with hardware of Compute Capability 3.0, NVIDIA has moved closer to AMD by removing dynamic scheduling. I think their architectures will converge somewhere in the middle. –  Roger Dahl Oct 7 '13 at 14:45

I've done some iterative coding in OpenCL. And the results of running it in NVIDIA and ATI, are pretty much the same. Near the same speed in the same value ($) cards.

In both cases, speeds were ~10x-30x comparing to a CPU.

I didn't test CUDA, but I doubt it could solve my random memory fetch problems magically. Nowadays, CUDA and OpenCL are more or less the same, and I see more future on OpenCL than on CUDA. The main reason is that Intel is launching drivers with OpenCL for their processors. This will be a huge advance in the future (running 16, 32 or 64 threads of OpenCL in CPU is REALLY fast, and really easy to port to GPU).

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My experience in evaluating OpenCL floating point performance tends to favor NVIDIA cards. I've worked with a couple of floating point benchmarks on NVIDIA cards ranging from the 8600M GT to the GTX 460. NVIDIA cards consistently achieve about half of theoretical single-precisino peak on these benchmarks.
The ATI cards I have worked with rarely achieve better than one third of single-precision peak. Note that my experience with ATI is skewed; I've only been able to work with one 5000 series card. My experience is mostly with HD 4000 series cards, which were never well supported. Support for the HD 5000 series cards is much better.

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I am new to GPGPU but I have some experience in scientific computing (PhD in Physics). I am putting together a research team and I want to go towards using GPGPU for my calculations. I had to choose between the available platforms. I decided on Nvidia, for a couple of reasons: while ATI might be faster on paper, Nvidia has a more mature platform and more documentation so it will be possible to get closer to the peak performance on this platform.

Nvidia also has an academic research support program, one can apply for support, I just received a TESLA 2075 card which I am very happy about. I don't know if ATI or Intel supports research this way.

What I heard about OpenCL is that it's trying to be everything at once, it is true that your OpenCL code will be more portable but it's also likely to not exploit the full capabilities of either platform. I'd rather learn a bit more and write programs that utilize the resources better. With the TESLA K10 that just came out this year Nvidia is in the 4.5 TeraFlops range so it is not clear that Nvidia is behind ... however Intel MICs could prove to be a real competitor, especially if they succeed in moving the GPGPU unit to the motherboard. But for now, I chose Nvidia.

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I would like to add to the debate. For us in the business of software, we can compromise raw single-precision performance to productivity but even that I do not have to compromise since, as already pointed out, you cannot achieve as much performance on on ATI's hardware using OpenCL as you can achieve if you write in CUDA on NVIDIA's hardware.

And yes, with PGI's announcement of x86 compiler for CUDA, there won't be any good reason to spend more time and resources writing in OpenCL :)

P.S: My argument might be biased since we do almost all our GPGPU work on CUDA. We have an Image Processing/Computer Vision library CUVI (CUDA for Vision and Imaging) which accelerates some core IP/CV functionality on CUDA.

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in my experience:

  • if you want best absolute performance then you need to see who is on the latest hardware iteration, and use their stack (including latest / beta releases).

  • if you want the best performance for the money you will be aiming at gamer cards rather than "professional" cards and the flexibility of targetting different platforms favors opencl.

  • if you are starting out, in particular, cuda tends to be more polished and have more tools and libraries.

finally, my personal take, after appalling "support" from nvidia (we got a dead tesla and it wasn't changed for months, while a client was waiting): the flexibility to jump ship with opencl is worth the risk of slightly lower performance when nvidia are ahead in the release cycle.

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Similar experience with "support" from nvidia: crash in libcuda.so (only with OpenCL, CUDA works) and no response from them whatsoever. –  eudoxos Mar 9 '12 at 6:52
    
With our dealer we have no problem in replacing dead tesla, usually we receive the new hardware before to send the faulty one, so I guess it's not a NVidia problem but your dealer one. –  Gaetano Mendola May 2 '12 at 14:04
    
I thought Tesla were super-duper reliable. What marketing fud. –  Aleksandr Dubinsky Oct 7 '13 at 10:09

I tried Aparapi(in Java Eclipse) for a 16k nbody experiment. Each kernel execution took 10 ms. There was only gravity. Then i added more potentials like Lennard-Jones and a custom excluding force for each interaction(there are 16k * 16k = 256M interactions total) and kernel time increased to 12 ms which is only %20 increase even though i added %300 pure calculations. All these means, if you go with simple real-world calculations, you will hit the memory-bandwidth. So, if both AMD Radeon 6970 and GTX-580 has same memory bandwidth then they will work at same speed nearly.

Each interaction i mentioned above had nearly 80 floating-point(add,multiplication,..) Java-commands to be parsed by Aparapi byte-code-to-kernel translator.

10ms: nearly 100 times per sec. * 80 fp * 256M(interactions)=2147 Gfloats

But i dont really believe above math is right. There are fused-multiply-add native-instructions in gpu so these floating point operations must be executed by 1/4 (or 1/5) rate of above so i assume true GFLOPS is around 500Gflops for HD7870 for nbody kernel of gravity+LJ+Exclusion+some more experimental potential. For just gravity it was 150Gflops or something like that because of the memory bandwidth-limit. More calculations you add more gflops you get also less frames per second you get.

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Cuda is certainly popular than OpenCL as of today, as it was released 3 or 4 years before OpenCL. Since OpenCL been has released, Nvidia has not contributed much for the language as they concentrate much on CUDA. They have not even released openCL 1.2 version for any driver.

As far as heterogenous computing as well as hand held devices as concerned OpenCl will surely gain more popularity in near future. As of now biggest contributor to OpenCL is AMD, It's visible on their site.

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