TransformerLens: Mechanistic Interpretability for Transformers
TransformerLens is the de facto standard library for mechanistic interpretability research on GPT-style language models. Created by Neel Nanda and maintained by Bryce Meyer, it provides clean interfaces to inspect and manipulate model internals via HookPoints on every activation.
GitHub: TransformerLensOrg/TransformerLens (2,900+ stars)
When to Use TransformerLens
Use TransformerLens when you need to:
- Reverse-engineer algorithms learned during training
- Perform activation patching / causal tracing experiments
- Study attention patterns and information flow
- Analyze circuits (e.g., induction heads, IOI circuit)
- Cache and inspect intermediate activations
- Apply direct logit attribution
Consider alternatives when:
- You need to work with non-transformer architectures → Use nnsight or pyvene
- You want to train/analyze Sparse Autoencoders → Use SAELens
- You need remote execution on massive models → Use nnsight with NDIF
- You want higher-level causal intervention abstractions → Use pyvene
Installation
pip install transformer-lens
For development version:
pip install git+https://github.com/TransformerLensOrg/TransformerLens
Core Concepts
HookedTransformer
The main class that wraps transformer models with HookPoints on every activation:
from transformer_lens import HookedTransformer # Load a model model = HookedTransformer.from_pretrained("gpt2-small") # For gated models (LLaMA, Mistral) import os os.environ["HF_TOKEN"] = "your_token" model = HookedTransformer.from_pretrained("meta-llama/Llama-2-7b-hf")
Supported Models (50+)
| Family | Models |
|---|---|
| GPT-2 | gpt2, gpt2-medium, gpt2-large, gpt2-xl |
| LLaMA | llama-7b, llama-13b, llama-2-7b, llama-2-13b |
| EleutherAI | pythia-70m to pythia-12b, gpt-neo, gpt-j-6b |
| Mistral | mistral-7b, mixtral-8x7b |
| Others | phi, qwen, opt, gemma |
Activation Caching
Run the model and cache all intermediate activations:
# Get all activations tokens = model.to_tokens("The Eiffel Tower is in") logits, cache = model.run_with_cache(tokens) # Access specific activations residual = cache["resid_post", 5] # Layer 5 residual stream attn_pattern = cache["pattern", 3] # Layer 3 attention pattern mlp_out = cache["mlp_out", 7] # Layer 7 MLP output # Filter which activations to cache (saves memory) logits, cache = model.run_with_cache( tokens, names_filter=lambda name: "resid_post" in name )
ActivationCache Keys
| Key Pattern | Shape | Description |
|---|---|---|
resid_pre, layer | [batch, pos, d_model] | Residual before attention |
resid_mid, layer | [batch, pos, d_model] | Residual after attention |
resid_post, layer | [batch, pos, d_model] | Residual after MLP |
attn_out, layer | [batch, pos, d_model] | Attention output |
mlp_out, layer | [batch, pos, d_model] | MLP output |
pattern, layer | [batch, head, q_pos, k_pos] | Attention pattern (post-softmax) |
q, layer | [batch, pos, head, d_head] | Query vectors |
k, layer | [batch, pos, head, d_head] | Key vectors |
v, layer | [batch, pos, head, d_head] | Value vectors |
Workflow 1: Activation Patching (Causal Tracing)
Identify which activations causally affect model output by patching clean activations into corrupted runs.
Step-by-Step
from transformer_lens import HookedTransformer, patching import torch model = HookedTransformer.from_pretrained("gpt2-small") # 1. Define clean and corrupted prompts clean_prompt = "The Eiffel Tower is in the city of" corrupted_prompt = "The Colosseum is in the city of" clean_tokens = model.to_tokens(clean_prompt) corrupted_tokens = model.to_tokens(corrupted_prompt) # 2. Get clean activations _, clean_cache = model.run_with_cache(clean_tokens) # 3. Define metric (e.g., logit difference) paris_token = model.to_single_token(" Paris") rome_token = model.to_single_token(" Rome") def metric(logits): return logits[0, -1, paris_token] - logits[0, -1, rome_token] # 4. Patch each position and layer results = torch.zeros(model.cfg.n_layers, clean_tokens.shape[1]) for layer in range(model.cfg.n_layers): for pos in range(clean_tokens.shape[1]): def patch_hook(activation, hook): activation[0, pos] = clean_cache[hook.name][0, pos] return activation patched_logits = model.run_with_hooks( corrupted_tokens, fwd_hooks=[(f"blocks.{layer}.hook_resid_post", patch_hook)] ) results[layer, pos] = metric(patched_logits) # 5. Visualize results (layer x position heatmap)
Checklist
- Define clean and corrupted inputs that differ minimally
- Choose metric that captures behavior difference
- Cache clean activations
- Systematically patch each (layer, position) combination
- Visualize results as heatmap
- Identify causal hotspots
Workflow 2: Circuit Analysis (Indirect Object Identification)
Replicate the IOI circuit discovery from "Interpretability in the Wild".
Step-by-Step
from transformer_lens import HookedTransformer import torch model = HookedTransformer.from_pretrained("gpt2-small") # IOI task: "When John and Mary went to the store, Mary gave a bottle to" # Model should predict "John" (indirect object) prompt = "When John and Mary went to the store, Mary gave a bottle to" tokens = model.to_tokens(prompt) # 1. Get baseline logits logits, cache = model.run_with_cache(tokens) john_token = model.to_single_token(" John") mary_token = model.to_single_token(" Mary") # 2. Compute logit difference (IO - S) logit_diff = logits[0, -1, john_token] - logits[0, -1, mary_token] print(f"Logit difference: {logit_diff.item():.3f}") # 3. Direct logit attribution by head def get_head_contribution(layer, head): # Project head output to logits head_out = cache["z", layer][0, :, head, :] # [pos, d_head] W_O = model.W_O[layer, head] # [d_head, d_model] W_U = model.W_U # [d_model, vocab] # Head contribution to logits at final position contribution = head_out[-1] @ W_O @ W_U return contribution[john_token] - contribution[mary_token] # 4. Map all heads head_contributions = torch.zeros(model.cfg.n_layers, model.cfg.n_heads) for layer in range(model.cfg.n_layers): for head in range(model.cfg.n_heads): head_contributions[layer, head] = get_head_contribution(layer, head) # 5. Identify top contributing heads (name movers, backup name movers)
Checklist
- Set up task with clear IO/S tokens
- Compute baseline logit difference
- Decompose by attention head contributions
- Identify key circuit components (name movers, S-inhibition, induction)
- Validate with ablation experiments
Workflow 3: Induction Head Detection
Find induction heads that implement [A][B]...[A] → [B] pattern.
from transformer_lens import HookedTransformer import torch model = HookedTransformer.from_pretrained("gpt2-small") # Create repeated sequence: [A][B][A] should predict [B] repeated_tokens = torch.tensor([[1000, 2000, 1000]]) # Arbitrary tokens _, cache = model.run_with_cache(repeated_tokens) # Induction heads attend from final [A] back to first [B] # Check attention from position 2 to position 1 induction_scores = torch.zeros(model.cfg.n_layers, model.cfg.n_heads) for layer in range(model.cfg.n_layers): pattern = cache["pattern", layer][0] # [head, q_pos, k_pos] # Attention from pos 2 to pos 1 induction_scores[layer] = pattern[:, 2, 1] # Heads with high scores are induction heads top_heads = torch.topk(induction_scores.flatten(), k=5)
Common Issues & Solutions
Issue: Hooks persist after debugging
# WRONG: Old hooks remain active model.run_with_hooks(tokens, fwd_hooks=[...]) # Debug, add new hooks model.run_with_hooks(tokens, fwd_hooks=[...]) # Old hooks still there! # RIGHT: Always reset hooks model.reset_hooks() model.run_with_hooks(tokens, fwd_hooks=[...])
Issue: Tokenization gotchas
# WRONG: Assuming consistent tokenization model.to_tokens("Tim") # Single token model.to_tokens("Neel") # Becomes "Ne" + "el" (two tokens!) # RIGHT: Check tokenization explicitly tokens = model.to_tokens("Neel", prepend_bos=False) print(model.to_str_tokens(tokens)) # ['Ne', 'el']
Issue: LayerNorm ignored in analysis
# WRONG: Ignoring LayerNorm pre_activation = residual @ model.W_in[layer] # RIGHT: Include LayerNorm ln_scale = model.blocks[layer].ln2.w ln_out = model.blocks[layer].ln2(residual) pre_activation = ln_out @ model.W_in[layer]
Issue: Memory explosion with large models
# Use selective caching logits, cache = model.run_with_cache( tokens, names_filter=lambda n: "resid_post" in n or "pattern" in n, device="cpu" # Cache on CPU )
Key Classes Reference
| Class | Purpose |
|---|---|
HookedTransformer | Main model wrapper with hooks |
ActivationCache | Dictionary-like cache of activations |
HookedTransformerConfig | Model configuration |
FactoredMatrix | Efficient factored matrix operations |
Integration with SAELens
TransformerLens integrates with SAELens for Sparse Autoencoder analysis:
from transformer_lens import HookedTransformer from sae_lens import SAE model = HookedTransformer.from_pretrained("gpt2-small") sae = SAE.from_pretrained("gpt2-small-res-jb", "blocks.8.hook_resid_pre") # Run with SAE tokens = model.to_tokens("Hello world") _, cache = model.run_with_cache(tokens) sae_acts = sae.encode(cache["resid_pre", 8])
Reference Documentation
For detailed API documentation, tutorials, and advanced usage, see the references/ folder:
| File | Contents |
|---|---|
| references/README.md | Overview and quick start guide |
| references/api.md | Complete API reference for HookedTransformer, ActivationCache, HookPoints |
| references/tutorials.md | Step-by-step tutorials for activation patching, circuit analysis, logit lens |
External Resources
Tutorials
- Main Demo Notebook
- Activation Patching Demo
- ARENA Mech Interp Course - 200+ hours of tutorials
Papers
- A Mathematical Framework for Transformer Circuits
- In-context Learning and Induction Heads
- Interpretability in the Wild (IOI)
Official Documentation
Version Notes
- v2.0: Removed HookedSAE (moved to SAELens)
- v3.0 (alpha): TransformerBridge for loading any nn.Module