This package provides a CUDA implementation for many of the modules in the base nn package: nn
- Modules: There are also additional GPU-related modules not found in the nn package.
git clone https://github.com/torch/cunn
cd cunn
luarocks make rocks/cunn-scm-1.rockspec
Simply convert your network model to CUDA by calling :cuda()
:
local model = nn.Sequential()
model:add(nn.Linear(2,2))
model:add(nn.LogSoftMax())
model:cuda() -- convert model to CUDA
... and similarly for your tensors:
local input = torch.Tensor(32,2):uniform()
input = input:cuda()
local output = model:forward(input)
... or create them directly as CudaTensor
s:
local input = torch.CudaTensor(32,2):uniform()
local output = model:forward(input)
luajit -l cunn -e 'cunn.test()'
Performance
- data should be transferred between main memory and gpu in batches, otherwise the transfer time will be dominated by latency associated with speed of light, and execution overheads, rather than by bandwidth
- therefore, train and predict using mini-batches
- allocating GPU memory causes a sync-point, which will noticeably affect performance
- therefore try to allocate any
CudaTensor
s once, at the start of the program, and then simply copy data backwards and forwards between main memory and existingCudaTensor
s
- therefore try to allocate any
- similarly, try to avoid any operations that implicitly allocate new tensors. For example, if you write:
require 'cutorch'
local a = torch.CudaTensor(1000):uniform()
for it=1,1000 do
local b = torch.add(a, 1)
end
... this will allocate one thousand new CudaTensor
s, one for each call to torch.add(a, 1)
.
Use instead this form:
require 'cutorch'
local a = torch.CudaTensor(1000):uniform()
local b = torch.CudaTensor(1000):uniform()
for it=1,1000 do
b:add(a, 1)
end
In this form, b
is allocated only once, before the loop. Then the b:add(a,1)
operation will perform
the add inside the GPU kernel, and store the result into the original b
CudaTensor
. This
will run noticeably faster, in general. It's also a lot less likely to eat up arbitrary amounts of memory,
and less likely to need frequent calls to collectgarbage(); collectgarbage()
.
Benchmarking
- GPU operations will typically continue after an instruction has been issued
- eg, if you do:
require 'cutorch'
local a = torch.CudaTensor(1000,1000):uniform()
a:add(1)
... the GPU kernel to add 1 will only be scheduled for launch by a:add(1)
. It might not have completed yet, or
even have reached the GPU, at the time that the a:add(1)
instructions has completed
- therefore for running wall-clock timings, you should call
cutorch.synchronize()
before each timecheck point:
require 'cutorch'
require 'sys'
local a = torch.CudaTensor(1000,1000):uniform()
cutorch.synchronize()
start = sys.tic()
a:add(1)
cutorch.synchronize()
print(sys.toc())