This folder contains TF 2.0 model examples for image classification:
- MNIST
- Classifier Trainer, a framework that uses the Keras
compile/fit methods for image classification models, including:
- ResNet
- EfficientNet1
Please make sure that you have the latest version of TensorFlow installed and add the models folder to your Python path.
classifier_trainer.py
supports ImageNet with
TensorFlow Datasets (TFDS).
Please see the following example snippet for more information on how to use TFDS to download and prepare datasets, and specifically the TFDS ImageNet readme for manual download instructions.
Download the ImageNet dataset and convert it to TFRecord format. The following script and README provide a few options.
Note that the legacy ResNet runners, e.g. resnet/resnet_ctl_imagenet_main.py
require TFRecords whereas classifier_trainer.py
can use both by setting the
builder to 'records' or 'tfds' in the configurations.
Note: These models will not work with TPUs on Colab.
You can train image classification models on Cloud TPUs using tf.distribute.experimental.TPUStrategy. If you are not familiar with Cloud TPUs, it is strongly recommended that you go through the quickstart to learn how to create a TPU and GCE VM.
You can also train these models on multiple hosts, each with GPUs, using tf.distribute.experimental.MultiWorkerMirroredStrategy.
The easiest way to run multi-host benchmarks is to set the
TF_CONFIG
appropriately at each host. e.g., to run using MultiWorkerMirroredStrategy
on
2 hosts, the cluster
in TF_CONFIG
should have 2 host:port
entries, and
host i
should have the task
in TF_CONFIG
set to {"type": "worker", "index": i}
. MultiWorkerMirroredStrategy
will automatically use all the
available GPUs at each host.
To download the data and run the MNIST sample model locally for the first time, run one of the following command:
python3 mnist_main.py \
--model_dir=$MODEL_DIR \
--data_dir=$DATA_DIR \
--train_epochs=10 \
--distribution_strategy=one_device \
--num_gpus=$NUM_GPUS \
--download
To train the model on a Cloud TPU, run the following command:
python3 mnist_main.py \
--tpu=$TPU_NAME \
--model_dir=$MODEL_DIR \
--data_dir=$DATA_DIR \
--train_epochs=10 \
--distribution_strategy=tpu \
--download
Note: the --download
flag is only required the first time you run the model.
The classifier trainer is a unified framework for running image classification models using Keras's compile/fit methods. Experiments should be provided in the form of YAML files, some examples are included within the configs/examples folder. Please see configs/examples for more example configurations.
The provided configuration files use a per replica batch size and is scaled
by the number of devices. For instance, if batch size
= 64, then for 1 GPU
the global batch size would be 64 * 1 = 64. For 8 GPUs, the global batch size
would be 64 * 8 = 512. Similarly, for a v3-8 TPU, the global batch size would
be 64 * 8 = 512, and for a v3-32, the global batch size is 64 * 32 = 2048.
python3 classifier_trainer.py \
--mode=train_and_eval \
--model_type=resnet \
--dataset=imagenet \
--model_dir=$MODEL_DIR \
--data_dir=$DATA_DIR \
--config_file=configs/examples/resnet/imagenet/gpu.yaml \
--params_override='runtime.num_gpus=$NUM_GPUS'
python3 classifier_trainer.py \
--mode=train_and_eval \
--model_type=resnet \
--dataset=imagenet \
--tpu=$TPU_NAME \
--model_dir=$MODEL_DIR \
--data_dir=$DATA_DIR \
--config_file=configs/examples/resnet/imagenet/tpu.yaml
Note: EfficientNet development is a work in progress.
python3 classifier_trainer.py \
--mode=train_and_eval \
--model_type=efficientnet \
--dataset=imagenet \
--model_dir=$MODEL_DIR \
--data_dir=$DATA_DIR \
--config_file=configs/examples/efficientnet/imagenet/efficientnet-b0-gpu.yaml \
--params_override='runtime.num_gpus=$NUM_GPUS'
python3 classifier_trainer.py \
--mode=train_and_eval \
--model_type=efficientnet \
--dataset=imagenet \
--tpu=$TPU_NAME \
--model_dir=$MODEL_DIR \
--data_dir=$DATA_DIR \
--config_file=configs/examples/efficientnet/imagenet/efficientnet-b0-tpu.yaml
Note that the number of GPU devices can be overridden in the command line using
--params_overrides
. The TPU does not need this override as the device is fixed
by providing the TPU address or name with the --tpu
flag.
Footnotes
-
Currently a work in progress. We cannot match "AutoAugment (AA)" in the original version. For more information about other types of models, please refer to this README file. ↩