* For foundation models like the GPT models, it automates the experimentation and optimization of their performance to maximize the effectiveness for applications and minimize the inference cost. FLAML enables users to build and use adaptive AI agents with minimal effort.
* For common machine learning tasks like classification and regression, it quickly finds quality models for user-provided data with low computational resources. It is easy to customize or extend. Users can find their desired customizability from a smooth range: minimal customization (computational resource budget), medium customization (e.g., search space and metric), or full customization (arbitrary training/inference/evaluation code).
* It supports fast and economical automatic tuning, capable of handling large search space with heterogeneous evaluation cost and complex constraints/guidance/early stopping. FLAML is powered by a [cost-effective
- A drop-in replacement of `openai.Completion` or `openai.ChatCompletion` with powerful functionalites like tuning, caching, templating, filtering. For example, you can optimize generations by LLM with your own tuning data, success metrics and budgets.
- LLM-driven intelligent agents which can perform tasks autonomously or with human feedback, including tasks that require using tools via code. For example,
```python
assistant = AssistantAgent("assistant")
user = UserProxyAgent("user", human_input_mode="TERMINATE")
assistant.receive("Draw a rocket and save to a file named 'rocket.svg'")
It automatically tunes the hyperparameters and selects the best model from default learners such as LightGBM, XGBoost, random forest etc. for the specified time budget 60 seconds. [Customizing](/docs/Use-Cases/task-oriented-automl#customize-automlfit) the optimization metrics, learners and search spaces etc. is very easy. For example,
FLAML offers a unique, seamless and effortless way to leverage AutoML for the commonly used classifiers and regressors such as LightGBM and XGBoost. For example, if you are using `lightgbm.LGBMClassifier` as your current learner, all you need to do is to replace `from lightgbm import LGBMClassifier` by:
Then, you can use it just like you use the original `LGMBClassifier`. Your other code can remain unchanged. When you call the `fit()` function from `flaml.default.LGBMClassifier`, it will automatically instantiate a good data-dependent hyperparameter configuration for your dataset, which is expected to work better than the default configuration.
* Understand the use cases for [Auto Generation](/docs/Use-Cases/Auto-Generation), [Task-oriented AutoML](/docs/Use-Cases/Task-Oriented-Automl), [Tune user-defined function](/docs/Use-Cases/Tune-User-Defined-Function) and [Zero-shot AutoML](/docs/Use-Cases/Zero-Shot-AutoML).
* Find code examples under "Examples": from [AutoGen - OpenAI](/docs/Examples/AutoGen-OpenAI) to [Tune - PyTorch](/docs/Examples/Tune-PyTorch).
* Learn about [research](/docs/Research) around FLAML and check [blogposts](/blog).
If you like our project, please give it a [star](https://github.com/microsoft/FLAML/stargazers) on GitHub. If you are interested in contributing, please read [Contributor's Guide](/docs/Contribute).
