Theano does have support for OpenCL but it is still in its early stages. Theano itself is not interested in OpenCL and relies on community support.
Most of the operations are already implemented and it is mostly a matter of tuning and optimizing the given operations.
To use the OpenCL backend you have to buildlibgpuarray yourself.
From personal experience I can tell you that you will get CPU performance if you are lucky. The memory allocation seems to be very naively implemented (therefore computation will be slow) and will crash when it runs out of memory. But I encourage you to try and maybe even optimize the code or help reporting bugs.
cuda-on-cl targets to be able to take any NVIDIA® CUDA™ soure-code, and compile it for OpenCL 1.2 devices. It's a very general goal, and a very general compiler
for now, the following functionalities are implemented:
reductions, argmin, argmax, again using Eigen, as per earlier info and links
learning, trainers, gradients. At least, StochasticGradientDescent trainer is working, and the others are commited, but not yet tested
it is developed on Ubuntu 16.04 (using Intel HD5500, and NVIDIA GPUs) and Mac Sierra (using Intel HD 530, and Radeon Pro 450)
This is not the only OpenCL fork of Tensorflow available. There is also a fork being developed by Codeplay https://www.codeplay.com , using Computecpp, https://www.codeplay.com/products/computesuite/computecpp Their fork has stronger requirements than my own, as far as I know, in terms of which specific GPU devices it works on. You would need to check the Platform Support Notes (at the bottom of hte computecpp page), to determine whether your device is supported. The codeplay fork is actually an official Google fork, which is here: https://github.com/benoitsteiner/tensorflow-opencl
The original question on this post was: How to get Keras and Tensorflow to run with an AMD GPU.
The answer to this question is as followed:
1.) Keras will work if you can make Tensorflow work correctly (optionally within your virtual/conda environment).
2.) To get Tensorflow to work on an AMD GPU, as others have stated, one way this could work is to compile Tensorflow to use OpenCl. To do so read the link below. But for brevity I will summarize the required steps here:
You will need AMDs proprietary drivers. These are currently only available on Ubuntu 14.04 (the version before Ubuntu decided to change the way the UI is rendered). Support for Ubuntu 16.04 is at the writing of this post limited to a few GPUs through AMDProDrivers. Readers who want to do deep learning on AMD GPUs should be aware of this!
Compiling Tensorflow with OpenCl support also requires you to obtain and install the following prerequisites: OpenCl headers, ComputeCpp.
After the prerequisites are fulfilled, configure your build. Note that there are 3 options for compiling Tensorflow: Std Tensorflow (stable), Benoits Steiner's Tensorflow-opencl (developmental), and Luke Iwanski's Tensorflow-opencl (highly experimental) which you can pull from github. Also note that if you decide to build from any of the opencl versions, the question to use opencl will be missing because it is assumed that you are using it. Conversely, this means that if you configure from the standard tensorflow, you will need to select "Yes" when the configure script asks you to use opencl and "NO" for CUDA.
Update: Doing this on my setup takes exceedingly long on my setup. The part that takes long are all the tests running. I am not sure what this means but a lot of my tests are timeing out at 1600 seconds. The duration can probably be shortened at the expense of more tests timeing out. Alternatively, you can just build tensor flow without tests. At the time of this writing, running the tests has taken 2 days already.
Please actually read the blog post over at Codeplay: Lukas Iwansky posted a comprehensive tutorial post on how to get Tensorflow to work with OpenCl just on March 30th 2017. So this is a very recent post. There are also some details which I did not write about here.
As indicated in the many posts above, little bits of information are spread throughout the interwebs. What Lukas' post adds in terms of value is that all the information was put together into one place which should make setting up Tensforflow and OpenCl a bit less daunting. I will only provide a link here:
I am unable to discern which approach is better at this time though it appears that this approach is less active. Fewer issues are posted, and fewer conversations to resolve those issues are happening. There was a major push last year. Additional pushes have ebbed off since November 2016 although Hugh seems to have pushed some updates a few days ago as of the writing of this post. (Update: If you read some of the documentation readme, this version of tensorflowo now only relies on community support as the main developer is busy with life.)
UPDATE (2017-04-25): I have some notes based on testing tensorflow-opencl below.
The future user of this package should note that using opencl means that all the heavy-lifting in terms of computing is shifted to the GPU. I mention this because I was personally thinking that the compute work-load would be shared between my CPU and iGPU. This means that the power of your GPU is very important (specifically, bandwidth, and available VRAM).
Following are some numbers for calculating 1 epoch using the CIFAR10 data set for MY SETUP (A10-7850 with iGPU). Your mileage will almost certainly vary!
Tensorflow (via pip install): ~ 1700 s/epoch
Tensorflow (w/ SSE + AVX): ~ 1100 s/epoch
Tensorflow (w/ opencl & iGPU): ~ 5800 s/epoch
You can see that in this particular case performance is worse. I attribute this to the following factors:
The iGPU only has 1GB. This leads to a lot of copying back and forth between CPU and GPU. (Opencl 1.2 does not have the ability to data pass via pointers yet; instead data has to be copied back and forth.)
The iGPU only has 512 stream processors (and 32 Gb/s memory bandwidth) which in this case is slower than 4 CPUs using SSE4 + AVX instruction sets.
The development of tensorflow-opencl is in it's beginning stages, and a lot of optimizations in SYCL etc. have not been done yet.
If you are using an AMD GPU with more VRAM and more stream processors, you are certain to get much better performance numbers. I would be interested to read what numbers people are achieving to know what's possible.
I will continue to maintain this answer if/when updates get pushed.
3.) An alternative way is currently being hinted at which is using AMD's RocM initiative, and miOpen (cuDNN equivalent) library. These are/will be open-source libraries that enable deep learning. The caveat is that RocM support currently only exists for Linux, and that miOpen has not been released to the wild yet, but Raja (AMD GPU head) has said in an AMA that using the above, it should be possible to do deep learning on AMD GPUs. In fact, support is planned for not only Tensorflow, but also Cafe2, Cafe, Torch7 and MxNet.
This is an old question, but since I spent the last few weeks trying to figure it out on my own:
OpenCL support for Theano is hit and miss. They added a libgpuarray back-end which appears to still be buggy (i.e., the process runs on the GPU but the answer is wrong--like 8% accuracy on MNIST for a DL model that gets ~95+% accuracy on CPU or nVidia CUDA). Also because ~50-80% of the performance boost on the nVidia stack comes from the CUDNN libraries now, OpenCL will just be left in the dust. (SEE BELOW!) :)
ROCM appears to be very cool, but the documentation (and even a clear declaration of what ROCM is/what it does) is hard to understand. They're doing their best, but they're 4+ years behind. It does NOT NOT NOT work on an RX550 (as of this writing). So don't waste your time (this is where 1 of the weeks went :) ). At first, it appears ROCM is a new addition to the driver set (replacing AMDGPU-Pro, or augmenting it), but it is in fact a kernel module and set of libraries that essentially replace AMDGPU-Pro. (Think of this as the equivalent of Nvidia-381 driver + CUDA some libraries kind of). https://rocm.github.io/dl.html (Honestly I still haven't tested the performance or tried to get it to work with more recent Mesa drivers yet. I will do that sometime.
Add MiOpen to ROCM, and that is essentially CUDNN. They also have some pretty clear guides for migrating. But better yet.
They created "HIP" which is an automagical translator from CUDA/CUDNN to MiOpen. It seems to work pretty well since they lined the API's up directly to be translatable. There are concepts that aren't perfect maps, but in general it looks good.
Now, finally, after 3-4 weeks of trying to figure out OpenCL, etc, I found this tutorial to help you get started quickly. It is a step-by-step for getting hipCaffe up and running. Unlike nVidia though,
please ensure you have supported hardware!!!! https://rocm.github.io/hardware.html. Think you can get it working without their supported hardware? Good luck. You've been warned. Once you have ROCM up and running (AND RUN THE VERIFICATION TESTS), here is the hipCaffe tutorial--if you got ROCM up you'll be doing an MNIST validation test within 10 minutes--sweet!
https://rocm.github.io/ROCmHipCaffeQuickstart.html
This should get you going in the right direction for tensorflow on the ROCm platform, but Selly's post about https://rocm.github.io/hardware.html is the deal with this route. That page is not an exhaustive list, I found out on my own that the Xeon E5 v2 Ivy Bridge works fine with ROCm even though they list v3 or newer, graphics cards however are a bit more picky. gfx8 or newer with a few small exceptions, polaris and maybe others as time goes on.
UPDATE - It looks like hiptensorflow has an option for opencl support during configure. I would say investigate the link even if you don't have gfx8+ or polaris gpu if the opencl implementation works. It is a long winded process but an hour or three (depending on hardware) following a well written instruction isn't too much to lose to find out.
One can use AMD GPU via the PlaidML Keras backend.
Fastest: PlaidML is often 10x faster (or more) than popular platforms (like TensorFlow CPU) because it supports all GPUs, independent of make and model.
PlaidML accelerates deep learning on AMD, Intel, NVIDIA, ARM, and embedded GPUs.
Easiest: PlaidML is simple to install and supports multiple frontends (Keras and ONNX currently)
Free: PlaidML is completely open source and doesn't rely on any vendor libraries with proprietary and restrictive licenses.
For most platforms, getting started with accelerated deep learning is as easy as running a few commands (assuming you have Python (v2 or v3) installed):
Technically you can if you use something like OpenCL, but Nvidia's CUDA is much better and OpenCL requires other steps that may or may not work. I would recommend if you have an AMD gpu, use something like Google Colab where they provide a free Nvidia GPU you can use when coding.