GPU training of neural network with parallel computing toolbox unreasonably slow, what am I missing?
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PetterS
le 30 Juin 2015
Commenté : PetterS
le 15 Juil 2015
I’m trying to speed up the training of some NARNET neural networks by using the GPU support that you get from the parallel computing toolbox but so far I haven’t been getting it to work. Or rather, it is working but it’s unreasonably slow. According to the documentation training on a GPU instead of the CPU shouldn’t be any harder than adding the statement 'useGPU','yes” to the training command. However, if I simply create some dummy data, for example a sine wave with 900 values, and train a NARNET on it using the CPU like so:
%CPU training
T = num2cell(sin(1:0.01:10));
net = narnet( 1:2, 10 );
[ Xs, Xsi, Asi, Ts] = preparets( net, {}, {}, T );
rng(0)
net.trainFcn = 'trainscg';
tic
net = train(net,Xs,Ts,'showResources','yes' );
toc %2.77
The training takes less than 3 seconds. But when doing the exact same thing on a CUDA supported GTX 760 GPU:
%GPU training
T = num2cell(sin(1:0.01:10));
net = narnet( 1:2, 10 );
[ Xs, Xsi, Asi, Ts] = preparets( net, {}, {}, T );
rng(0)
net.trainFcn = 'trainscg';
tic
net = train(net,Xs,Ts,'useGPU','yes','showResources','yes' );
toc % 1247.6
Incredibly the training takes over 20 minutes!
I’ve read through Mathworks fairly extensive documentation on parallel and GPU computing with the neural network toolbox ( link here ) and seen that there are a few things that can/should be done when calculating with a GPU for example converting the input and target data to GPU arrays before training with the nndata2gpu command and replacing any tansig activation functions with elliotsig which does speed up the training a bit:
%Improved GPU training
T = num2cell(sin(1:0.01:10));
net = narnet( 1:2, 10 );
[ Xs, Xsi, Asi, Ts ] = preparets( net, {}, {}, T );
rng(0)
net = configure(net,Xs,Ts);
Xs = nndata2gpu(Xs);
Ts = nndata2gpu(Ts);
Xsi = nndata2gpu(Xsi);
for i=1:net.numLayers
if strcmp(net.layers{i}.transferFcn,'tansig')
net.layers{i}.transferFcn = 'elliotsig';
end
end
net.trainFcn = 'trainscg';
tic
net = train(net,Xs,Ts,'showResources','yes' );
toc %70.79
The training here only takes about 70 seconds, but still it’s many times slower compared to just doing it on my CPU. I’ve tried several different sized data series and network architectures but I’ve never seen the GPU training being able to compete with the CPU which is strange since as I understand it most professional ANN research is done using GPU’s?
What am I doing wrong here? Clearly I must be missing something fundamental.
Thanks
1 commentaire
Greg Heath
le 10 Juil 2015
Modifié(e) : Greg Heath
le 10 Juil 2015
You don't need an if statement to replace tansig by elliotsig. Just replace it right after you define the net.
My elliot4sig is a little faster
elliot4sig(x) = x/(0.25 + abs(x))
Greg
Réponse acceptée
Mark Hudson Beale
le 15 Juil 2015
Getting a speed up with a GPU requires a couple things:
1) The amount of time spent in gradient calculations (which happen on CPU or GPU as you request) is significant compared to the training step update (which still happens on the CPU).
2) The problem allows enough parallelism to run efficiently on the much slower but much greater number of GPU cores relative to the CPU.
For both requirements, the larger the dataset and the larger the neural network, the more parallelism that can be taken advantage of and the greater percentage of calculations are in the gradient so the training steps are not a speed bottleneck.
The NAR problem you defined only has 899 steps with a 10 neuron network. The fact that both dataset and network are very small is why you are not seeing a speedup. Problems that take only a few seconds on CPU probably are not going to see much of a speedup with GPU.
You are correct, that at this time NAR networks using NNDATA2GPU formatted data result in faster training than gpuArray.
Plus de réponses (1)
Adam Hug
le 2 Juil 2015
I suspect the problem size of 900 values may be too small for you to benefit from GPU architecture. Especially since you can easily fit 900 values into a CPU cache. The problem sizes need to be much larger for the communication between the CPU and GPU to be small in comparison to the computation. Try a sine wave with one million values and see if the GPU outperforms the CPU.
4 commentaires
Amanjit Dulai
le 14 Juil 2015
You should be able to convert the data to single precision with nndata2gpu as follows:
Xs = nndata2gpu(Xs,'single');
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