The mini-AlphaStar (mini-AS, or mAS) project is a mini-scale version of the AlphaStar (AS) program. AlphaStar is the intelligent AI proposed by DeepMind to play StarCraft II. Note the mini-AS is a research project. It is not an official product of DeepMind.
The "mini-scale" means making the original AS's hyper-parameters adjustable so that we can train mini-AS on a small scale, e.g., in a single common commercial server machine.
We referred to the "Occam's Razor Principle" when designing the mini-AS: simple is good. Therefore, we build the mini-AS from scratch. Unless the function significantly impacts speed and performance, we shall omit it. Meanwhile, we also try not to use too many dependency packages so that mini-AS should only depend on the PyTorch. In this way, we simplify the learning cost of the mini-AS and make the architecture of mini-AS relatively easy.
The Chinese shows a simple readme in Chinese.
Below 4 GIFs are mini-AS' trained performance on Simple64, supervised learning on 50 expert replays.
Left: At the start of the game. Right: In the middle period of the game.
Left: The agent's 1st attack. Right: The agent's 2nd Attack.
This release is the "v_1.09" version. The main changes are as follows:
- Fixed some known bugs and issues;
- Improve to a new SL setting to train a good SL model more likely;
- Change STEP_MUL to 8 to gain more good RL training results;
- Add logs for all the losses in the RL training to gain better information about the process;
- Increase the win rate against level-1 bot to 0.85 (the best so far);
- For the first time, provide the pre-trained SL model for RL training to use;
- For the first time, provide the final RL model for others to reproduce the results easily;
Warning: SC2 is extremely difficult, and AlphaStar is also very complex. Though our project is a mini-AlphaStar, it has almost the similar technologies as AS, and the training resource also costs very high. We can hardly train mini-AS on a laptop. The recommended way is to use a commercial server with a GPU card plus large memory and disk space. For someone interested in this project for the first time, we recommend you collect (star) this project. Devolve deeply into researching it only when you have enough free time and training resources.
We store the codes and show videos in two places.
Codes location | Result video location | Usage |
---|---|---|
Github | Youtube | for global users |
Gitee | Bilibili | for users in China |
The table below shows the corresponding packages in the project.
Packages | Content |
---|---|
alphastarmini.core.arch | deep neural architecture |
alphastarmini.core.sl | supervised learning |
alphastarmini.core.rl | reinforcement learning |
alphastarmini.core.ma | multi-agent league traning |
alphastarmini.lib | lib functions |
alphastarmini.third | third party functions |
PyTorch >= 1.5, others please see requirements.txt.
The SCRIPT Guide gives some commands to install PyTorch by conda (this will automatically install CUDA and cudnn, which is convenient).
E.g., like (to install PyTorch 1.5 with accompanied CUDA and cudnn):
conda create -n th_1_5 python=3.7 pytorch=1.5 -c pytorch
Next, activate the conda environment, like:
conda activate th_1_5
Then you can install other python packages by pip, e.g., the command in the below line:
pip install -r requirements.txt
After you have done all requirements, run the below python file to run the program:
python run.py
You may use comments and uncomments in "run.py" to select the training process you want.
The USAGE Guide provides answers to some problems and questions.
You should follow the following instructions to get similar or better results than the provided gifs on the main page.
We summarised the usage sequences as the following:
- Transform replays: download the replays for training, then use the script in mAS to transform the replays to trainable data;
- Supervised learning: use the trainable data to supervise learning an initial model;
- Evaluate SL model: the trained SL model should be evaluated on the RL environment to make sure it behaves right;
- Reinforcement learning: use the trained SL model to do reinforcement learning in the SC environment, seeing the win rate starts growing.
We give detailed descriptions below.
In supervised learning, you first need to download SC2 replays.
The REPLAY Guide shows a guide to download these SC2 replays.
The ZHIHU Guide provides Chinese users who are not convenient to use Battle.net (outside China) a guide to download replays.
After downloading replays, you should move the replays to "./data/Replays/filtered_replays_1" (you can change the name in transform_replay_data.py
).
Then use transform_replay_data.py
to transform these replays to pickles or tensors (you can change the output type in the code of that file).
You don't need to run the transform_replay_data.py directly. Only run "run.py" is OK. Make the run.py has the following code
# from alphastarmini.core.sl import transform_replay_data
# transform_replay_data.test(on_server=P.on_server)
uncommented. Then you can directly run "run.py".
Note: To get the effect of the trained agent in the gifs, use the replays in Useful-Big-Resources. These replays are generatedy by our experts, to get an agent having the ability to win the built-in bot.
After getting the trainable data (we recommend using tensor dat). Make the run.py has the following code
# from alphastarmini.core.sl import sl_train_by_tensor
# sl_train_by_tensor.test(on_server=P.on_server)
uncommented. Then you can directly run "run.py" to do supervised learning.
The default learning rate is 1e-4, and the training epochs should best be 10 (more epochs may cause the training effect overfitting).
From the v_1.05 version, we support multi-GPU supervised learning (not recommended now) training for mini-AS, improving the training speed. The way to use multi-GPU training is straightforward, as follows:
python run_multi-gpu.py
Multi-GPU training has some unstable factors (caused because of PyTorch). If you find your multi-GPU training has training instability errors, please switch to the single-GPU training.
We currently support four types of supervised training, which all reside in the "alphastarmini.core.sl" package.
File | Content |
---|---|
sl_train_by_pickle.py |
pickle (data not preprocessed) training: Slow, but need small disk space. |
sl_train_by_tensor.py |
tensor (data preprocessed) training: Fast, but cost colossal disk space. |
sl_multi_gpu_by_pickle.py |
multi-GPU, pickle training: It has a requirement need for large shared memory. |
sl_multi_gpu_by_tensor.py |
multi-GPU, tensor training: It needs both large memory and large shared memory. |
You can use the load_pickle.py
to transform the generated pickles (in "./data/replay_data") to tensors (in "./data/replay_data_tensor").
From the v_1.06 version, we still recommend using single-GPU training.
The newest training ways (e.g., in v_1.07) are still in the single GPU type due to multi-GPU training cost too much memory.
After getting the supervised learning model, we should test the model's performance in the SC2 environment. The reason is that there is a domain shift from the SL data to the RL environment.
Make the run.py has the following code
# from alphastarmini.core.rl import rl_eval_sl
# rl_eval_sl.test(on_server=P.on_server)
uncommented. Then you can directly run "run.py" to do an evaluation of the SL model.
The evaluation is similar to RL training, but the updating is closed. The running is also in single-thread, to make the randomness due to multi-thread not affect the evaluation.
After ensuring the supervised learning model is OK and suitable for RL training, we can do RL based on the learned supervised learning model.
Make the run.py has the following code
# from alphastarmini.core.rl import rl_vs_inner_bot_mp
# rl_vs_inner_bot_mp.test(on_server=P.on_server, replay_path=P.replay_path)
uncommented. Then you can directly run "run.py" to do reinforcement learning.
Note RL training uses a multi-process plus multi-thread manner (to accelerate the learning speed), so make sure to run these codes on a high-performance computer.
E.g., we run 15 processes, and each has two actor threads and one learner thread. If your computer is not strong, reduce the parallel nums.
The learning rate should be low (below 1e-5 because you are training on an initially trained model). The training iterations should be as long as best (more training iterations can reduce the instability of RL training).
If you find the training result is not good as you imagine, please open an issue to ask us or discuss with us (though we can not make sure to respond to it in time or there is any solution to every problem).
You can find the pre-trained models here.
The "sl_21-12-29_08-15-43.pth" is the supervised learning pre-trained model by our method.
The "rl_22-02-07_16-26-48.pth" is the reinforcement learning trained model by our method based on the previous model.
The "rl_22-02-09_19-16-39.pth" is the reinforcement learning (more time) final model by our method based on the previous supervised learning model.
Here are some illustration figures of the SL training process below:
We can see the loss (one primary loss and six argument losses) fall quickly.
We provide more curves (like the accuracy curve) for the SL training process after the v_1.05 version.
The trained behavior of the agents shows in the gifs on this page.
Our later paper will provide a more detailed illustration of the experiments (such as the effects of different hyper-parameters).
The HISTORY is the historical introduction of the previous versions of mini-AS.
If you find our repository useful, please cite our project or the below technical report:
@misc{liu2021mAS,
author = {Ruo{-}Ze Liu and Wenhai Wang and Yang Yu and Tong Lu},
title = {mini-AlphaStar},
year = {2021},
publisher = {GitHub},
journal = {GitHub repository},
howpublished = {\url{https://github.com/liuruoze/mini-AlphaStar}},
}
The An Introduction of mini-AlphaStar is a technical report introducing the mini-AS (not full version).
@article{liu2021mASreport,
author = {Ruo{-}Ze Liu and
Wenhai Wang and
Yanjie Shen and
Zhiqi Li and
Yang Yu and
Tong Lu},
title = {An Introduction of mini-AlphaStar},
journal = {CoRR},
volume = {abs/2104.06890},
year = {2021},
}
The Rethinking of AlphaStar is our thinking of the advantages and disadvantages of AlphaStar.
We present detailed experiments and evaluations using the mini-AS in this paper.