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In Keras, the high-level deep learning library, there are multiple types of recurrent layers; these include LSTM (Long short term memory) and CuDNNLSTM. According to the Keras documentation, a CuDNNLSTM is a:

Fast LSTM implementation backed by CuDNN. Can only be run on GPU, with the TensorFlow backend.

It is my belief that Keras automatically uses the GPU wherever possible. According to the TensorFlow build instructions, to have a working TensorFlow GPU backend, you will need CuDNN:

The following NVIDIA software must be installed on your system:

  • NVIDIA's Cuda Toolkit (>= 7.0). We recommend version 9.0. For details, see NVIDIA's documentation. Ensure that you append the relevant Cuda pathnames to the LD_LIBRARY_PATH environment variable as described in the NVIDIA documentation.
  • The NVIDIA drivers associated with NVIDIA's Cuda Toolkit.
  • cuDNN (>= v3). We recommend version 6.0. For details, see NVIDIA's documentation, particularly the description of appending the appropriate pathname to your LD_LIBRARY_PATH environment variable.

Therefore, how would a CuDNNLSTM differ in any way from a normal LSTM using a TensorFlow GPU backend? Will CuDNNLSTM be automatically selected and replace the normal LSTM when an available TensorFlow GPU backend is found?

  • I guess they are the same? It probably only differs when it is run without a GPU. – TYZ Apr 23 '18 at 20:03
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    Choice of LSTM <-> CuDNNLSTM is important if you are going to deploy the model into production. For example, Google Cloud Platform allows you to use only CPU machines in their "AI Platform" so far. So, if you train the model with CuDNNLSTM, you won't be able to deploy it. – Vlad-HC Oct 21 '19 at 11:55
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Why don't you try it out for yourself and see? In my case, training a model with LSTM took 10mins 30seconds. Simply switching the call from LSTM() to CuDNNLSTM() took less than a minute.

I also noticed that switching to CuDNNLSTM() speeds up model.evaluate() and model.predict() substantially as well.

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    Why am I just finding out about this, it's amazing! It used to take me 3h to evaluate a model on a large dataset, now it only takes about 20mins. – aL_eX Sep 7 '18 at 15:08
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    CuDNNLSTM is faster (it uses the GPU support) but it has less options than LSTM (dropout for example) – lbcommer Dec 27 '18 at 16:20
  • see this thread for more info: reddit.com/r/learnmachinelearning/comments/9jv0gx/… – Arayan Singh May 4 '19 at 12:37
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TL;DR; The difference is 15x speed up in model training time!

Setup Steps

Dependencies

Performance Benchmark: Comparison of the standard test machines.
1 iteration of Training on 612235 samples.

keras.layers.LSTM Intel i5-4690 CPU only: 612235/612235 [==============================] - 3755s 6ms/step - loss: 2.7339 - acc: 0.5067 - val_loss: 2.1149 - val_acc: 0.6175

GTX:950 & Intel i5-4690: 612235/612235 [==============================] - 1417s 2ms/step - loss: 2.7007 - acc: 0.5137 - val_loss: 2.0983 - val_acc: 0.6199

2.5x gain with GPU.

GTX:970 & Intel i5-4690: 612235/612235 [==============================] - 1322s 2ms/step - loss: 1.9214 - acc: 0.6442 - val_loss: 1.8808 - val_acc: 0.6461

Ignorable gain with powerful GPU.

RTX 2070 & Intel i7-9700K: 612235/612235 [==============================] - 1012s 2ms/step - loss: 2.7268 - acc: 0.5111 - val_loss: 2.1162 - val_acc: 0.6234

Very minimal gain even with awesome HW upgrades!!!

keras.layers.CuDNNLSTM RTX 2070 & Intel i7-9700K: 612235/612235 [==============================] - 69s 112us/step - loss: 1.9139 - acc: 0.6437 - val_loss: 1.8668 - val_acc: 0.6469

54x gain over CPU!
15x gain over traditional(non Cuda) LSTM implementation!

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    it seems like only the last 2 cases need to be shown since they are a fair test - same components, only CuDNNLSTM vs LSTM is different.. The first few examples just make your post confusing. – cryanbhu Dec 1 '19 at 12:18
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GPUs are good for massive parallel computation, most of the linear algebra ops can be parallelized to improve performance, Vector operations like matrix multiplication and gradient descent can be applied to large matrices that are executed in parallel with GPU support. CUDA - Compute Unified Device Architecture provides an interface that allows vector ops to take advantage of GPU parallelism. CuDNN implements kernels for large matrix operations on GPU using CUDA.

Here, CuDNNLSTM is designed for CUDA parallel processing and cannot run if there is no GPU. But LSTM is designed for normal CPUs. Faster time of execution is because of parallelism.

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