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Now I need to allocate all available memory with cuda technology. I do it with Tesla C2050, Quadro 600 and GeForce GTX 560 Ti by: First, I allocate 0 bytes of global memory on device. Second step is define available memory of device by cudaMemGetInfo function and make allocation of that available memory. It works for devices listed above. But this mechanism doesn't work with GeForce GTX 690.

Could somebody help me, what mechanism can I use to allocate memory on the GeForce GTX 690 device or any paradigm for that operation?

It looks like this:


int (*reservedMemory);

cudaMalloc(&reservedMemory, 0);

size_t freeMemory, totalMemory;

cudaMemGetInfo(&freeMemory, &totalMemory);

cudaMalloc(&reservedMemory, freeMemory);

On the GeForce GTX 690, one of two existing streaming multiprocessors operate on 2147483648 bytes of memory, but I can allocate only 1341915136 bytes of free global memory that is equal to 2050109440 bytes. On the Quadro 600, one existing streaming multiprocessor operate on 1073414144 bytes of memory, and I can allocate all available 859803648 bytes of free global memory that is equal to 859803648 bytes.

For an example on Quadro 600 (showed compilation, linking and execution procedure):

D:\Gdmt> nvcc -arch=compute_20 -code=sm_21 -c ./ -o ./Gdmt.obj

D:\Gdmt> nvcc ./Gdmt.obj -o ./Gdmt.exe

D:\Gdmt> nvcc -arch=compute_20 -code=sm_21 -c ./ -o ./Gdmt_add

D:\Gdmt> nvcc ./Gdmt_additional.obj -o ./Gdmt_additional.exe

D:\Gdmt> Gdmt.exe
Total amount of memory: 1073414144 Bytes;
Memory to reserve: 859803648 Bytes;
Memory reserved: 859803648 Bytes;
D:\Gdmt> Gdmt_additional.exe
Allocation is succeeded on 890830848 bytes of reserved memory.

For an example on GeForce GTX 690 (showed compilation, linking and execution procedure):

J:\Gdmt> nvcc -arch=compute_30 -code=sm_30 -c ./ -o ./Gdmt.obj

J:\Gdmt> nvcc ./Gdmt.obj -o ./Gdmt.exe

J:\Gdmt> nvcc -arch=compute_30 -code=sm_30 -c ./ -o ./Gdmt_add

J:\Gdmt> nvcc ./Gdmt_additional.obj -o ./Gdmt_additional.exe

J:\Gdmt> Gdmt.exe
Total amount of memory: 2147483648 Bytes;
Memory to reserve: 2050109440 Bytes;
Warning, memory allocation process is not succeeded!
J:\Gdmt> Gdmt_additional.exe
Allocation is succeeded on 1341915136 bytes of reserved memory.

Examples is archived and located at:

(z7 archive - 78.5 KB ~ 80,434 bytes) (zip archive - 163 KB ~ 167,457 bytes)

This topic is a clone of topic posted at "The GeForce Lounge" and "CUDA Programming and Performance", with the same name.

share|improve this question
You are clearly running this on a Windows host. Are the other devices you mention also running on Windows hosts? Also, you show a build process for compiling to a compute 2.0 target. Is the behaviour the same with the GTX690 if you compile for a compute 3.0 target? – talonmies Feb 6 '13 at 11:37
So you can allocate 2GB at one of the GTX 690 sub gpu and approximately 1.3GB on the other sub gpu? If yes, one of my first guesses would be the use of this sub gpu as display card, which uses up some memory (although 700MB would be a bit much). – GeorgT Feb 6 '13 at 13:16
Thanks to talonmies and GeorgT. talonmies, for first - yes, i use Windows as operating system platform for this devices, for second - in the build process shown above, target of compute number 2.0 is applied for Quadro 600 device, target of compute number 3.0 is applied for GeForce GTX 690 device. GeorgT - no, i can allocate 1.3 * 8^9.98 (9.98 is the degree of 8) bytes of global memory on two of existing streaming multiprocessors using GeForce GTX 690 device. – gence Feb 7 '13 at 3:57

I could rerun your examples and came to the same result.

I tried to tackle the problem from the other side, and tried to allocate blocks of decreasing size.

int (*reservedMemory);
size_t const NBlockSize = 1300 *1024*1024; 
size_t freeMemory, totalMemory;
cudaError_t nErr = cudaSuccess;
size_t nTotalAlloc=0;
while( nErr == cudaSuccess )
    cudaMemGetInfo(&freeMemory, &totalMemory);
    std::cout << "===========================================================" << std::endl;
    std::cout << "Free/Total(kB): " << freeMemory/1024 << "/" << totalMemory/1024 << std::endl;

    size_t nAllocSize = NBlockSize;
    while( nAllocSize > freeMemory )
        nAllocSize /= 2;

    nErr = cudaMalloc(&reservedMemory, nAllocSize );
    if( nErr == cudaSuccess )
        nTotalAlloc += nAllocSize;
    std::cout << "AllocSize(kB): " << nAllocSize/1024 << ", error: " << cudaGetErrorString(nErr) << std::endl;

std::cout << "TotalAlloc/Total (kB): " << nTotalAlloc/1024 << "/" << totalMemory/1024 << std::endl;

The program starts with a block of size NBlockSize and if freeMemory decreases, also decrease nAllocSize. Looking at the output below, it seems cudaMalloc behaves a bit unpredictable when allocating blocks which are kind of big related to freeMemory. At one point it manages to allocate more than 98% of free memory, at another point it fails to allocate 800MB out of 1GB of available memory.

The most interesting run is the one with starting block size of 700MB. It manages to 1400kB out of 1428 in the last successful loop, and fails at allocating 10 out of 20 kB in the next run.

Depending on the starting size, the program managed to allocate all free space except 8kB at the best run, and left over one gigabyte on the worst.

NBlockSize(MB): 1000
Free/Total(kB): 1797120/2097152
AllocSize(kB): 1024000, percentage of freememory: 0.569801, error: no error
Free/Total(kB): 773120/2097152
AllocSize(kB): 512000, percentage of freememory: 0.662252, error: no error
Free/Total(kB): 261120/2097152
AllocSize(kB): 256000, percentage of freememory: 0.980392, error: no error
Free/Total(kB): 5128/2097152
AllocSize(kB): 4000, percentage of freememory: 0.780031, error: no error
Free/Total(kB): 1032/2097152
AllocSize(kB): 1000, percentage of freememory: 0.968992, error: no error
Free/Total(kB): 8/2097152
AllocSize(kB): 7, percentage of freememory: 0.976563, error: out of memory
TotalAlloc/Total (kB): 1797000/2097152

NBlockSize(MB): 1200
Free/Total(kB): 1796864/2097152
AllocSize(kB): 1228800, percentage of freememory: 0.683858, error: no error
Free/Total(kB): 568072/2097152
AllocSize(kB): 307200, percentage of freememory: 0.540777, error: no error
Free/Total(kB): 260872/2097152
AllocSize(kB): 153600, percentage of freememory: 0.588795, error: no error
Free/Total(kB): 107272/2097152
AllocSize(kB): 76800, percentage of freememory: 0.715937, error: no error
Free/Total(kB): 30472/2097152
AllocSize(kB): 19200, percentage of freememory: 0.630087, error: no error
Free/Total(kB): 11272/2097152
AllocSize(kB): 9600, percentage of freememory: 0.851668, error: no error
Free/Total(kB): 1672/2097152
AllocSize(kB): 1200, percentage of freememory: 0.717703, error: no error
Free/Total(kB): 392/2097152
AllocSize(kB): 300, percentage of freememory: 0.765306, error: out of memory
TotalAlloc/Total (kB): 1796400/2097152

NBlockSize(MB): 800
Free/Total(kB): 1844448/2097152
AllocSize(kB): 819200, percentage of freememory: 0.444144, error: no error
Free/Total(kB): 1025248/2097152
AllocSize(kB): 819200, percentage of freememory: 0.799026, error: out of memory
TotalAlloc/Total (kB): 819200/2097152

NBlockSize(MB): 700
Free/Total(kB): 1835528/2097152
AllocSize(kB): 716800, percentage of freememory: 0.390514, error: no error
Free/Total(kB): 1118740/2097152
AllocSize(kB): 716800, percentage of freememory: 0.640721, error: no error
Free/Total(kB): 401940/2097152
AllocSize(kB): 358400, percentage of freememory: 0.891675, error: no error
Free/Total(kB): 43540/2097152
AllocSize(kB): 22400, percentage of freememory: 0.514469, error: no error
Free/Total(kB): 21140/2097152
AllocSize(kB): 11200, percentage of freememory: 0.529801, error: no error
Free/Total(kB): 9876/2097152
AllocSize(kB): 5600, percentage of freememory: 0.567031, error: no error
Free/Total(kB): 4244/2097152
AllocSize(kB): 2800, percentage of freememory: 0.659755, error: no error
Free/Total(kB): 1428/2097152
AllocSize(kB): 1400, percentage of freememory: 0.980392, error: no error
Free/Total(kB): 20/2097152
AllocSize(kB): 10, percentage of freememory: 0.546875, error: out of memory
TotalAlloc/Total (kB): 1835400/2097152
share|improve this answer
I got a GTX660 with obviously 2GB of RAM. Compiled with sm_30 and compute_30. – GeorgT Feb 7 '13 at 16:26
Memory size output is obtained by integer division. – GeorgT Feb 7 '13 at 16:30
I tested this on Ubuntu 11.10 (amd64) with cuda 5.0 installed, and came to the result of the fact that the previously described algorithm, for first allocation zero bytes of memory to initialize the device, and then the rest of the available memory - is not working. We can reserve all available memory, but no one megabyte on GeForce GTX 690. – gence Mar 15 '13 at 10:42

I recently remembered, about the "Page-Locked" mechanism in cuda. I test it, and do not get satisfactory results of performance (calculation using this mechanism is ten times slower, then a version with very limited memory reservation feature for Windows with GeForce GTX 690). I just thought that copying the data to device for later calculation and writing back will be done automatically, but in fact the memory of the device is not involved.

share|improve this answer
I wonder whether the problem for GeForce GTX Titan in the operating system Windows. – gence Mar 18 '13 at 9:47

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