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We have some nightly build machines that have the cuda libraries installed, but which do not have a cuda-capable GPU installed. These machines are capable of building cuda-enabled programs, but they are not capable of running these programs.

In our automated nightly build process, our cmake scripts use the cmake command


to determine whether the cuda software is installed. This sets the cmake variable CUDA_FOUND on platforms that have cuda software installed. This is great and it works perfectly. When CUDA_FOUND is set, it is OK to build cuda-enabled programs. Even when the machine has no cuda-capable GPU.

But cuda-using test programs naturally fail on the non-GPU cuda machines, causing our nightly dashboards look "dirty". So I want cmake to avoid running those tests on such machines. But I still want to build the cuda software on those machines.

After getting a positive CUDA_FOUND result, I would like to test for the presence of an actual GPU, and then set a variable, say CUDA_GPU_FOUND, to reflect this.

What is the simplest way to get cmake to test for the presence of a cuda-capable gpu?

This needs to work on three platforms: Windows with MSVC, Mac, and Linux. (That's why we use cmake in the first place)

EDIT: There are a couple of good looking suggestions in the answers for how write a program to test for the presence of a GPU. What is still missing is the means of getting CMake to compile and run this program at configuration time. I suspect that the TRY_RUN command in CMake will be critical here, but unfortunately that command is nearly undocumented, and I cannot figure out how to make it work. This CMake part of the problem might be a much more difficult question. Perhaps I should have asked this as two separate questions...

share|improve this question
up vote 16 down vote accepted

The answer to this question consists of two parts:

  1. A program to detect the presence of a cuda-capable GPU.
  2. CMake code to compile, run, and interpret the result of that program at configuration time.

For part 1, the gpu sniffing program, I started with the answer provided by fabrizioM because it is so compact. I quickly discovered that I needed many of the details found in unknown's answer to get it to work well. What I ended up with is the following C source file, which I named has_cuda_gpu.c:

#include <stdio.h>
#include <cuda_runtime.h>

int main() {
    int deviceCount, device;
    int gpuDeviceCount = 0;
    struct cudaDeviceProp properties;
    cudaError_t cudaResultCode = cudaGetDeviceCount(&deviceCount);
    if (cudaResultCode != cudaSuccess) 
        deviceCount = 0;
    /* machines with no GPUs can still report one emulation device */
    for (device = 0; device < deviceCount; ++device) {
        cudaGetDeviceProperties(&properties, device);
        if (properties.major != 9999) /* 9999 means emulation only */
    printf("%d GPU CUDA device(s) found\n", gpuDeviceCount);

    /* don't just return the number of gpus, because other runtime cuda
       errors can also yield non-zero return values */
    if (gpuDeviceCount > 0)
        return 0; /* success */
        return 1; /* failure */

Notice that the return code is zero in the case where a cuda-enabled GPU is found. This is because on one of my has-cuda-but-no-GPU machines, this program generates a runtime error with non-zero exit code. So any non-zero exit code is interpreted as "cuda does not work on this machine".

You might ask why I don't use cuda emulation mode on non-GPU machines. It is because emulation mode is buggy. I only want to debug my code, and work around bugs in cuda GPU code. I don't have time to debug the emulator.

The second part of the problem is the cmake code to use this test program. After some struggle, I have figured it out. The following block is part of a larger CMakeLists.txt file:

    message("${RUN_OUTPUT_VAR}") # Display number of GPUs found
    # COMPILE_RESULT_VAR is TRUE when compile succeeds
    # RUN_RESULT_VAR is zero when a GPU is found
        set(CUDA_HAVE_GPU TRUE CACHE BOOL "Whether CUDA-capable GPU is present")
        set(CUDA_HAVE_GPU FALSE CACHE BOOL "Whether CUDA-capable GPU is present")

This sets a CUDA_HAVE_GPU boolean variable in cmake that can subsequently be used to trigger conditional operations.

It took me a long time to figure out that the include and link parameters need to go in the CMAKE_FLAGS stanza, and what the syntax should be. The try_run documentation is very light, but there is more information in the try_compile documentation, which is a closely related command. I still needed to scour the web for examples of try_compile and try_run before getting this to work.

Another tricky but important detail is the third argument to try_run, the "bindir". You should probably always set this to ${CMAKE_BINARY_DIR}. In particular, do not set it to ${CMAKE_CURRENT_BINARY_DIR} if you are in a subdirectory of your project. CMake expects to find the subdirectory CMakeFiles/CMakeTmp within bindir, and spews errors if that directory does not exist. Just use ${CMAKE_BINARY_DIR}, which is one location where those subdirectories seem to naturally reside.

share|improve this answer

Write a simple program like


int main (){
    int deviceCount;
    cudaError_t e = cudaGetDeviceCount(&deviceCount);
    return e == cudaSuccess ? deviceCount : -1;

and check the return value.

share|improve this answer
+1 This answer, along with unknown's, gave me a great start on solving this problem. – Christopher Bruns Feb 19 '10 at 16:31

You can compile small GPU query program if cuda was found. here is a simple one you can adopt the needs:

#include <stdlib.h>
#include <stdio.h>
#include <cuda.h>
#include <cuda_runtime.h>

int main(int argc, char** argv) {
  int ct,dev;
  cudaError_t code;
  struct cudaDeviceProp prop;

 code = cudaGetLastError();
 if(code)  printf("%s\n", cudaGetErrorString(code));

if(ct == 0) {
   printf("Cuda device not found.\n");
 printf("Found %i Cuda device(s).\n",ct);

for (dev = 0; dev < ct; ++dev) {
printf("Cuda device %i\n", dev);

printf("\tname : %s\n",;
 printf("\ttotalGlobablMem: %lu\n", (unsigned long)prop.totalGlobalMem);
printf("\tsharedMemPerBlock: %i\n", prop.sharedMemPerBlock);
printf("\tregsPerBlock: %i\n", prop.regsPerBlock);
printf("\twarpSize: %i\n", prop.warpSize);
printf("\tmemPitch: %i\n", prop.memPitch);
printf("\tmaxThreadsPerBlock: %i\n", prop.maxThreadsPerBlock);
printf("\tmaxThreadsDim: %i, %i, %i\n", prop.maxThreadsDim[0], prop.maxThreadsDim[1], prop.maxThreadsDim[2]);
printf("\tmaxGridSize: %i, %i, %i\n", prop.maxGridSize[0], prop.maxGridSize[1], prop.maxGridSize[2]);
printf("\tclockRate: %i\n", prop.clockRate);
printf("\ttotalConstMem: %i\n", prop.totalConstMem);
printf("\tmajor: %i\n", prop.major);
printf("\tminor: %i\n", prop.minor);
printf("\ttextureAlignment: %i\n", prop.textureAlignment);
printf("\tdeviceOverlap: %i\n", prop.deviceOverlap);
printf("\tmultiProcessorCount: %i\n", prop.multiProcessorCount);
share|improve this answer
+1 this is a very good start for the part that sniffs the GPU. But I am hesitant to accept this answer without the cmake part. – Christopher Bruns Feb 19 '10 at 2:07
@Christopher no problem, unfortunately I do not know cmake (I use automake). is a relevant part of autoconf. Perhaps it will help you to find corresponding cmake function – Anycorn Feb 19 '10 at 2:59

I just wrote a pure Python script that does some of the things you seem to need (I took much of this from the pystream project). It's basically just a wrapper for some functions in the CUDA run time library (it uses ctypes). Look at the main() function to see example usage. Also, be aware that I just wrote it, so it's likely to contain bugs. Use with caution.


import sys
import platform
import ctypes

""" used to access pars of the CUDA runtime library.
Most of this code was lifted from the pystream project (it's BSD licensed):

Note that this is likely to only work with CUDA 2.3
To extend to other versions, you may need to edit the DeviceProp Class

cudaSuccess = 0
errorDict = {
    1: 'MissingConfigurationError',
    2: 'MemoryAllocationError',
    3: 'InitializationError',
    4: 'LaunchFailureError',
    5: 'PriorLaunchFailureError',
    6: 'LaunchTimeoutError',
    7: 'LaunchOutOfResourcesError',
    8: 'InvalidDeviceFunctionError',
    9: 'InvalidConfigurationError',
    10: 'InvalidDeviceError',
    11: 'InvalidValueError',
    12: 'InvalidPitchValueError',
    13: 'InvalidSymbolError',
    14: 'MapBufferObjectFailedError',
    15: 'UnmapBufferObjectFailedError',
    16: 'InvalidHostPointerError',
    17: 'InvalidDevicePointerError',
    18: 'InvalidTextureError',
    19: 'InvalidTextureBindingError',
    20: 'InvalidChannelDescriptorError',
    21: 'InvalidMemcpyDirectionError',
    22: 'AddressOfConstantError',
    23: 'TextureFetchFailedError',
    24: 'TextureNotBoundError',
    25: 'SynchronizationError',
    26: 'InvalidFilterSettingError',
    27: 'InvalidNormSettingError',
    28: 'MixedDeviceExecutionError',
    29: 'CudartUnloadingError',
    30: 'UnknownError',
    31: 'NotYetImplementedError',
    32: 'MemoryValueTooLargeError',
    33: 'InvalidResourceHandleError',
    34: 'NotReadyError',
    0x7f: 'StartupFailureError',
    10000: 'ApiFailureBaseError'}

    if platform.system() == "Microsoft":
        _libcudart = ctypes.windll.LoadLibrary('cudart.dll')
    elif platform.system()=="Darwin":
        _libcudart = ctypes.cdll.LoadLibrary('libcudart.dylib')
        _libcudart = ctypes.cdll.LoadLibrary('')
    _libcudart_error = None
except OSError, e:
    _libcudart_error = e
    _libcudart = None

def _checkCudaStatus(status):
    if status != cudaSuccess:
        eClassString = errorDict[status]
        # Get the class by name from the top level of this module
        eClass = globals()[eClassString]
        raise eClass()

def _checkDeviceNumber(device):
    assert isinstance(device, int), "device number must be an int"
    assert device >= 0, "device number must be greater than 0"
    assert device < 2**8-1, "device number must be < 255"

# cudaDeviceProp
class DeviceProp(ctypes.Structure):
    _fields_ = [
         ("name", 256*ctypes.c_char), #  < ASCII string identifying device
         ("totalGlobalMem", ctypes.c_size_t), #  < Global memory available on device in bytes
         ("sharedMemPerBlock", ctypes.c_size_t), #  < Shared memory available per block in bytes
         ("regsPerBlock", ctypes.c_int), #  < 32-bit registers available per block
         ("warpSize", ctypes.c_int), #  < Warp size in threads
         ("memPitch", ctypes.c_size_t), #  < Maximum pitch in bytes allowed by memory copies
         ("maxThreadsPerBlock", ctypes.c_int), #  < Maximum number of threads per block
         ("maxThreadsDim", 3*ctypes.c_int), #  < Maximum size of each dimension of a block
         ("maxGridSize", 3*ctypes.c_int), #  < Maximum size of each dimension of a grid
         ("clockRate", ctypes.c_int), #  < Clock frequency in kilohertz
         ("totalConstMem", ctypes.c_size_t), #  < Constant memory available on device in bytes
         ("major", ctypes.c_int), #  < Major compute capability
         ("minor", ctypes.c_int), #  < Minor compute capability
         ("textureAlignment", ctypes.c_size_t), #  < Alignment requirement for textures
         ("deviceOverlap", ctypes.c_int), #  < Device can concurrently copy memory and execute a kernel
         ("multiProcessorCount", ctypes.c_int), #  < Number of multiprocessors on device
         ("kernelExecTimeoutEnabled", ctypes.c_int), #  < Specified whether there is a run time limit on kernels
         ("integrated", ctypes.c_int), #  < Device is integrated as opposed to discrete
         ("canMapHostMemory", ctypes.c_int), #  < Device can map host memory with cudaHostAlloc/cudaHostGetDevicePointer
         ("computeMode", ctypes.c_int), #  < Compute mode (See ::cudaComputeMode)
         ("__cudaReserved", 36*ctypes.c_int),

    def __str__(self):
        return """NVidia GPU Specifications:
    Name: %s
    Total global mem: %i
    Shared mem per block: %i
    Registers per block: %i
    Warp size: %i
    Mem pitch: %i
    Max threads per block: %i
    Max treads dim: (%i, %i, %i)
    Max grid size: (%i, %i, %i)
    Total const mem: %i
    Compute capability: %i.%i
    Clock Rate (GHz): %f
    Texture alignment: %i
""" % (, self.totalGlobalMem, self.sharedMemPerBlock,
       self.regsPerBlock, self.warpSize, self.memPitch,
       self.maxThreadsDim[0], self.maxThreadsDim[1], self.maxThreadsDim[2],
       self.maxGridSize[0], self.maxGridSize[1], self.maxGridSize[2],
       self.totalConstMem, self.major, self.minor,
       float(self.clockRate)/1.0e6, self.textureAlignment)

def cudaGetDeviceCount():
    if _libcudart is None: return  0
    deviceCount = ctypes.c_int()
    status = _libcudart.cudaGetDeviceCount(ctypes.byref(deviceCount))
    return deviceCount.value

def getDeviceProperties(device):
    if _libcudart is None: return  None
    props = DeviceProp()
    status = _libcudart.cudaGetDeviceProperties(ctypes.byref(props), device)
    return props

def getDriverVersion():
    if _libcudart is None: return  None
    version = ctypes.c_int()
    v = "%d.%d" % (version.value//1000,
    return v

def getRuntimeVersion():
    if _libcudart is None: return  None
    version = ctypes.c_int()
    v = "%d.%d" % (version.value//1000,
    return v

def getGpuCount():
    for ii in range(cudaGetDeviceCount()):
        props = getDeviceProperties(ii)
        if props.major!=9999: count+=1
    return count

def getLoadError():
    return _libcudart_error

version = getDriverVersion()
if version is not None and not version.startswith('2.3'):
    sys.stdout.write("WARNING: Driver version %s may not work with %s\n" %
                     (version, sys.argv[0]))

version = getRuntimeVersion()
if version is not None and not version.startswith('2.3'):
    sys.stdout.write("WARNING: Runtime version %s may not work with %s\n" %
                     (version, sys.argv[0]))

def main():

    sys.stdout.write("Driver version: %s\n" % getDriverVersion())
    sys.stdout.write("Runtime version: %s\n" % getRuntimeVersion())

    nn = cudaGetDeviceCount()
    sys.stdout.write("Device count: %s\n" % nn)

    for ii in range(nn):
        props = getDeviceProperties(ii)
        sys.stdout.write("\nDevice %d:\n" % ii)
        #sys.stdout.write("%s" % props)
        for f_name, f_type in props._fields_:
            attr = props.__getattribute__(f_name)
            sys.stdout.write( "  %s: %s\n" % (f_name, attr))

    gpuCount = getGpuCount()
    if gpuCount > 0:
    sys.stdout.write("GPU count: %d\n" % getGpuCount())
    e = getLoadError()
    if e is not None:
        sys.stdout.write("There was an error loading a library:\n%s\n\n" % e)

if __name__=="__main__":
share|improve this answer
That's an interesting idea to use python. This way the cmake portion would presumably include FIND_PACKAGE(PythonInterp) and EXECUTE_PROCESS(...), which seems like it might be simpler. On the other hand I am concerned that that python script is rather long, and looks like it might depend on aspects of the CUDA API that might change. – Christopher Bruns Feb 21 '10 at 17:15
Agreed. The DeviceProp class may need to be updated with each new CUDA runtime version. – Randall Radmer Feb 22 '10 at 2:12

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