Author: Kuno Kim
This repo contains the official implementation for the ICLR submission
Note: ** This repo is being actively updated. **
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PyTorch
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cudatoolkit
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PyYAML
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hydra
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dm_control
We assume you have access to a gpu that can run CUDA 9.2 or above. We used pytorch==1.10.1 with cudatoolkit==11.3.1 in our experiments. The simplest way to install all required dependencies is to create an anaconda environment and activate it:
conda env create -f conda_env.yaml
source activate gac
Next, install the ReparamModule package following the instructions from here.
train_gac.py is the common gateway to all experiments.
usage: train_gac.py env=ENV_NAME
experiment=EXP_NAME
seed=SEED
load_demo_path=PATH_TO_DEMO
load_expert_path=PATH_TO_EXPERT
num_transitions=NUM_DEMO
optional arguments:
experiment Name of experiment for logging purposes
seed Random seed
load_demo_path Global path to the saved expert demonstrations
load_expert_path Global path to the saved expert (only for evaluation purposes)
num_transitions Number of demonstrations to useConfiguration files are stored in config/. For example, the configuration file of GAC is config/imitate.yaml and config/agent/gac.yaml. Log files are commonly stored in exp/ including the tensorboard files.
Download the expert demonstations and place them in gac/saved_demo. Each pickle file contains 1000 demonstration trajectories for a different environment. The environment names match the file names. The usage of train_gac.py is quite self-evident. For example, we can train GAC for the walker_walk task with one demonstration by running
python train_gac.py env='walker_walk' experiment='walker_walk' seed=0 load_demo_path=/user/gac/saved_demo/walker_walk.pickle load_expert_path=/user/gac/saved_experts/walker_walk.pt num_transitions=1Choose from a variety of environments walker_stand, walker_walk, hopper_stand, cheetah_run, quadruped_run.
Running train_gac.py outputs evaluation metrics to the console. The long names for the shorthand acroynms can be found in logger.py. For the evaluation step outputs, L_R shows the average learner episode reward which quantifies control performance of the learner. Another convenient way to monitor training progress is to use tensorboard. For example, to visualize the runs started on 2022.10.01, one may run
tensorboard --logdir exp/2022.10.01 --port 8008The evaluation metrics are then found at http://localhost:8008. The "learner_episode_reward" graph shows the average episode reward obtained during the evaluation step. A sample learning curve for the walker_walk task should look like so.
