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CUDA code compiled with a higher compute capability will execute perfectly for a long time on a device with lower compute capability, before silently failing one day in some kernel. I spent half a day chasing an elusive bug only to realize that the Build Rule had sm_21 while the device (Tesla C2050) was a 2.0.

Is there any CUDA API code I can add which can self-check if it is running on a device with compatible compute capability? I need to compile and work with devices of many compute capabilities. Is there any other action I can take to ensure such errors do not occur?

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3 Answers

up vote 10 down vote accepted

In the runtime API, cudaGetDeviceProperties returns two fields major and minor which return the compute capability any given enumerated CUDA device. You can use that to parse the compute capability of any GPU before establishing a context on it to make sure it is the right architecture for what your code does. nvcc can generate a object file containing multiple architectures from a single invocation using the -gencode option, for example:

nvcc -c -gencode arch=compute_20,code=sm_20  \
        -gencode arch=compute_13,code=sm_13

would produce an output object file with an embedded fatbinary object containing cubin files for GT200 and GF100 cards. The runtime API will automagically handle architecture detection and try loading suitable device code from the fatbinary object without any extra host code.

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Any idea why the binary can detect the device and load suitable version, but does not exit with a meaningful error when there is a single version (that does not match)? –  Ashwin Jul 14 '11 at 8:43
Too much abstraction, basically. If you do the process "by hand" using the driver API, a meaningful error message is returned if there is no suitable cubin for the target GPU. But a lot of steps all happen implicitly (device selection, context establishment, module loading, code and data retrieval), and if any of those deliberately abstracted processes fail, the runtime returns a generic initialization error. If you need that degree of control, explicitly manage the context yourself with the driver API, then use the context in the runtime API. Interoperability has been supported since CUDA 3.1 –  talonmies Jul 14 '11 at 8:51
@Ashwin: Accepted an answer two and a half years after it was posted. That must be some sort of record..... –  talonmies Oct 8 '13 at 20:54
Haha. Had forgotten to accept I guess. Came across it again today & did the right thing :-D –  Ashwin Oct 8 '13 at 23:58
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run device query. find compute capability for every device in the system. Then execute code at the desired device with SetDevice();

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Came across talonmies's answer as I was researching the implications of using the GENCODE_FLAGS which are in the CUDA samples makefiles. I understood that by having all the different GENCODE_FLAGS, nvcc was building all the different possible architecture types, but I was not sure how to know which it actually used when the code was run. The lowest arch? The most appropriate? How does it know what gpu capability I have if I do not set it manually (I am new to this, so the answer was not obvious to me). The answer from talonmies: "The runtime API will automagically handle architecture detection and try loading suitable device code from the fatbinary object without any extra host code." This was the confirmation I was looking for. But, I needed to know where this knowledge was officially stated in the nvidia materials, and I found it in this doc: http://docs.nvidia.com/cuda/cuda-c-programming-guide/index.html#compilation-nvcc

With this statement:

Which PTX and binary code gets embedded in a CUDA C application is controlled by the -arch >and -code compiler options or the -gencode compiler option as detailed in the nvcc user >manual. For example,

nvcc x.cu -gencode arch=compute_10,code=sm_10 -gencode arch=compute_11,code=\'compute_11,sm_11\'

embeds binary code compatible with compute capability 1.0 (first -gencode option) and PTX >and binary code compatible with compute capability 1.1 (second -gencode option).

Host code is generated to automatically select at runtime the most appropriate code to >load and execute, which, in the above example, will be:

  • 1.0 binary code for devices with compute capability 1.0,
  • 1.1 binary code for devices with compute capability 1.1, 1.2, 1.3,
  • binary code obtained by compiling 1.1 PTX code for devices with compute capabilities 2.0 and higher.

Read more at: http://docs.nvidia.com/cuda/cuda-c-programming-guide/index.html#ixzz37BlhkEij Follow us: @GPUComputing on Twitter | NVIDIA on Facebook

I apologize putting this as another answer rather than a comment, I do not have the reputation to put comments.

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