This repository contains a Sparse Autoencoder (SAE) designed to interpret and steer the Mistral 7B language model. By training the SAE on the residual activations of Mistral 7B, we aim to understand the internal representations of the model and manipulate its outputs in a controlled manner.
Large Language Models (LLMs) like Mistral 7B have complex internal mechanisms that are not easily interpretable. This project leverages a Sparse Autoencoder to:
- Decode internal activations: Transforming high-dimensional activations into sparse, interpretable features.
- Steer model behavior: Manipulating specific features to influence the model's output.
This approach is based on the hypothesis that internal features are superimposed in the model's activations and can be disentangled using sparse representations.
I have written the following articles that provide foundational insights guiding the development of this project:
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This article explores how reversing transformers can shed light on in-context learning mechanisms, phase transitions, and feature dimensionality in large language models.
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Superposition Hypothesis for Steering LLM with Sparse Autoencoder
This post discusses how the superposition hypothesis can be applied to steer large language models using sparse autoencoders by isolating and manipulating specific features within the model.
These writings provide foundational insights that have guided the development of this project.
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Clone the repository:
git clone https://github.com/yourusername/mistral-sae.git cd mistral-sae -
Install dependencies:
pip install -r requirements.txt
Ensure you have the appropriate version of PyTorch installed, preferably with CUDA support for GPU acceleration.
The train.py script trains the SAE on activations from a specified layer of the Mistral 7B model.
python train.py- Adjust hyperparameters like
D_MODEL,D_HIDDEN,BATCH_SIZE, andlrwithin the script. - Set the
MISTRAL_MODEL_PATHandtarget_layerto specify which model and layer to use.
Use explain.py to generate natural language explanations for the features learned by the SAE.
python explain.py- Ensure you have access to the required datasets (e.g., The Pile) and APIs.
- Configure parameters such as
batch_size,data_path, andtarget_layer.
The demo.py script demonstrates how to steer the Mistral 7B model by manipulating specific features.
python demo.py- Set
FEATURE_INDEXto the index of the feature you wish to manipulate. - Toggle
STEERING_ONtoTrueto enable steering. - Adjust the
coeffvariable to control the strength of the manipulation.
config.py: Contains model configurations and helper functions.train.py: Script for training the Sparse Autoencoder.explain.py: Generates explanations for the features identified by the SAE.demo.py: Demonstrates how to steer the Mistral 7B model using the SAE.mistral_sae/: Directory containing the SAE implementation and related utilities.requirements.txt: Lists the Python dependencies required for the project.
Understanding the internal workings of LLMs is crucial for both interpretability and control. By applying a Sparse Autoencoder to the activations of Mistral 7B, we can:
- Identify monosemantic neurons that correspond to specific concepts or features.
- Test the superposition hypothesis by examining how multiple features are represented within the same neurons.
- Enhance our ability to steer the model's outputs towards desired behaviors by manipulating these features.
This project is inspired by and builds upon several key works:
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Scaling Monosemanticity: Extracting Interpretable Features from Claude 3
Templeton et al., 2024
Explores methods for extracting interpretable features from large language models.
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Scaling and Evaluating Sparse Autoencoders
Gao et al., 2024
Discusses techniques for scaling sparse autoencoders and evaluating their performance.
- Model Weights: Available on Hugging Face at tylercosgrove/mistral-7b-sparse-autoencoder-layer16.
- SAE Lens Compatibility: This project is compatible with SAE Lens, a tool for analyzing sparse autoencoders.