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resnet

ResNet in TensorFlow

Deep residual networks, or ResNets for short, provided the breakthrough idea of identity mappings in order to enable training of very deep convolutional neural networks. This folder contains an implementation of ResNet for the ImageNet dataset written in TensorFlow.

See the following papers for more background:

[1] Deep Residual Learning for Image Recognition by Kaiming He, Xiangyu Zhang, Shaoqing Ren, and Jian Sun, Dec 2015.

[2] Identity Mappings in Deep Residual Networks by Kaiming He, Xiangyu Zhang, Shaoqing Ren, and Jian Sun, Jul 2016.

In code, v1 refers to the ResNet defined in [1] but where a stride 2 is used on the 3x3 conv rather than the first 1x1 in the bottleneck. This change results in higher and more stable accuracy with less epochs than the original v1 and has shown to scale to higher batch sizes with minimal degradation in accuracy. There is no originating paper. The first mention we are aware of was in the torch version of ResNetv1. Most popular v1 implementations are this implementation which we call ResNetv1.5.

In testing we found v1.5 requires ~12% more compute to train and has 6% reduced throughput for inference compared to ResNetv1. CIFAR-10 ResNet does not use the bottleneck and is thus the same for v1 as v1.5.

v2 refers to [2]. The principle difference between the two versions is that v1 applies batch normalization and activation after convolution, while v2 applies batch normalization, then activation, and finally convolution. A schematic comparison is presented in Figure 1 (left) of [2].

Please proceed according to which dataset you would like to train/evaluate on:

CIFAR-10

Setup

You need to have the latest version of TensorFlow installed. First, make sure the models folder is in your Python path; otherwise you may encounter ImportError: No module named official.resnet.

Then, download and extract the CIFAR-10 data from Alex's website, specifying the location with the --data_dir flag. Run the following:

python cifar10_download_and_extract.py --data_dir <DATA_DIR>

Then, to train the model:

python cifar10_main.py --data_dir <DATA_DIR>/cifar-10-batches-bin --model_dir <MODEL_DIR>

Use --data_dir to specify the location of the CIFAR-10 data used in the previous step. There are more flag options as described in cifar10_main.py.

To export a SavedModel from the trained checkpoint:

python cifar10_main.py --data_dir <DATA_DIR>/cifar-10-batches-bin --model_dir <MODEL_DIR> --eval_only --export_dir <EXPORT_DIR>

Note: The <EXPORT_DIR> must be present. You might want to run mkdir <EXPORT_DIR> beforehand.

The SavedModel can then be loaded in order to use the ResNet for prediction.

ImageNet

Setup

To begin, you will need to download the ImageNet dataset and convert it to TFRecord format. The following script and README provide a few options.

Once your dataset is ready, you can begin training the model as follows:

python imagenet_main.py --data_dir=/path/to/imagenet

The model will begin training and will automatically evaluate itself on the validation data roughly once per epoch.

Note that there are a number of other options you can specify, including --model_dir to choose where to store the model and --resnet_size to choose the model size (options include ResNet-18 through ResNet-200). See resnet_run_loop.py for the full list of options.

Compute Devices

Training is accomplished using the DistributionStrategies API. (https://github.com/tensorflow/tensorflow/blob/master/tensorflow/contrib/distribute/README.md)

The appropriate distribution strategy is chosen based on the --num_gpus flag. By default this flag is one if TensorFlow is compiled with CUDA, and zero otherwise.

num_gpus:

  • 0: Use OneDeviceStrategy and train on CPU.
  • 1: Use OneDeviceStrategy and train on GPU.
  • 2+: Use MirroredStrategy (data parallelism) to distribute a batch between devices.

Pre-trained model

You can download pre-trained versions of ResNet-50. Reported accuracies are top-1 single-crop accuracy for the ImageNet validation set. Models are reported as both checkpoints produced by Estimator during training, and as SavedModels which are more portable. Checkpoints are fragile, and these are not guaranteed to work with future versions of the code. Both ResNet v1 and ResNet v2 have been trained in both fp16 and fp32 precision. (Here v1 refers to "v1.5". See the note above.) Furthermore, SavedModels are generated to accept either tensor or JPG inputs, and with channels_first (NCHW) and channels_last (NHWC) convolutions. NCHW is generally better for GPUs, while NHWC is generally better for CPUs. See the TensorFlow performance guide for more details.

ResNet-50 v2 (fp32, Accuracy 76.47%):

ResNet-50 v2 (fp16, Accuracy 76.56%):

ResNet-50 v1 (fp32, Accuracy 76.53%):

ResNet-50 v1 (fp16, Accuracy 76.18%):

Transfer Learning

You can use a pretrained model to initialize a training process. In addition you are able to freeze all but the final fully connected layers to fine tune your model. Transfer Learning is useful when training on your own small datasets. For a brief look at transfer learning in the context of convolutional neural networks, we recommend reading these short notes.

To fine tune a pretrained resnet you must make three changes to your training procedure:

  1. Build the exact same model as previously except we change the number of labels in the final classification layer.

  2. Restore all weights from the pre-trained resnet except for the final classification layer; this will get randomly initialized instead.

  3. Freeze earlier layers of the network

We can perform these three operations by specifying two flags: --pretrained_model_checkpoint_path and --fine_tune. The first flag is a string that points to the path of a pre-trained resnet model. If this flag is specified, it will load all but the final classification layer. A key thing to note: if both --pretrained_model_checkpoint_path and a non empty model_dir directory are passed, the tensorflow estimator will load only the model_dir. For more on this please see WarmStartSettings and Estimators.

The second flag --fine_tune is a boolean that indicates whether earlier layers of the network should be frozen. You may set this flag to false if you wish to continue training a pre-trained model from a checkpoint. If you set this flag to true, you can train a new classification layer from scratch.