Claude-code-templates pyvene-interventions
Provides guidance for performing causal interventions on PyTorch models using pyvene's declarative intervention framework. Use when conducting causal tracing, activation patching, interchange intervention training, or testing causal hypotheses about model behavior.
install
source · Clone the upstream repo
git clone https://github.com/davila7/claude-code-templates
Claude Code · Install into ~/.claude/skills/
T=$(mktemp -d) && git clone --depth=1 https://github.com/davila7/claude-code-templates "$T" && mkdir -p ~/.claude/skills && cp -r "$T/cli-tool/components/skills/ai-research/mechanistic-interpretability-pyvene" ~/.claude/skills/davila7-claude-code-templates-pyvene-interventions && rm -rf "$T"
manifest:
cli-tool/components/skills/ai-research/mechanistic-interpretability-pyvene/SKILL.mdsource content
pyvene: Causal Interventions for Neural Networks
pyvene is Stanford NLP's library for performing causal interventions on PyTorch models. It provides a declarative, dict-based framework for activation patching, causal tracing, and interchange intervention training - making intervention experiments reproducible and shareable.
GitHub: stanfordnlp/pyvene (840+ stars) Paper: pyvene: A Library for Understanding and Improving PyTorch Models via Interventions (NAACL 2024)
When to Use pyvene
Use pyvene when you need to:
- Perform causal tracing (ROME-style localization)
- Run activation patching experiments
- Conduct interchange intervention training (IIT)
- Test causal hypotheses about model components
- Share/reproduce intervention experiments via HuggingFace
- Work with any PyTorch architecture (not just transformers)
Consider alternatives when:
- You need exploratory activation analysis → Use TransformerLens
- You want to train/analyze SAEs → Use SAELens
- You need remote execution on massive models → Use nnsight
- You want lower-level control → Use nnsight
Installation
pip install pyvene
Standard import:
import pyvene as pv
Core Concepts
IntervenableModel
The main class that wraps any PyTorch model with intervention capabilities:
import pyvene as pv from transformers import AutoModelForCausalLM, AutoTokenizer # Load base model model = AutoModelForCausalLM.from_pretrained("gpt2") tokenizer = AutoTokenizer.from_pretrained("gpt2") # Define intervention configuration config = pv.IntervenableConfig( representations=[ pv.RepresentationConfig( layer=8, component="block_output", intervention_type=pv.VanillaIntervention, ) ] ) # Create intervenable model intervenable = pv.IntervenableModel(config, model)
Intervention Types
| Type | Description | Use Case |
|---|---|---|
| Swap activations between runs | Activation patching |
| Add activations to base run | Steering, ablation |
| Subtract activations | Ablation |
| Zero out activations | Component knockout |
| DAS trainable intervention | Causal discovery |
| Collect activations | Probing, analysis |
Component Targets
# Available components to intervene on components = [ "block_input", # Input to transformer block "block_output", # Output of transformer block "mlp_input", # Input to MLP "mlp_output", # Output of MLP "mlp_activation", # MLP hidden activations "attention_input", # Input to attention "attention_output", # Output of attention "attention_value_output", # Attention value vectors "query_output", # Query vectors "key_output", # Key vectors "value_output", # Value vectors "head_attention_value_output", # Per-head values ]
Workflow 1: Causal Tracing (ROME-style)
Locate where factual associations are stored by corrupting inputs and restoring activations.
Step-by-Step
import pyvene as pv from transformers import AutoModelForCausalLM, AutoTokenizer import torch model = AutoModelForCausalLM.from_pretrained("gpt2-xl") tokenizer = AutoTokenizer.from_pretrained("gpt2-xl") # 1. Define clean and corrupted inputs clean_prompt = "The Space Needle is in downtown" corrupted_prompt = "The ##### ###### ## ## ########" # Noise clean_tokens = tokenizer(clean_prompt, return_tensors="pt") corrupted_tokens = tokenizer(corrupted_prompt, return_tensors="pt") # 2. Get clean activations (source) with torch.no_grad(): clean_outputs = model(**clean_tokens, output_hidden_states=True) clean_states = clean_outputs.hidden_states # 3. Define restoration intervention def run_causal_trace(layer, position): """Restore clean activation at specific layer and position.""" config = pv.IntervenableConfig( representations=[ pv.RepresentationConfig( layer=layer, component="block_output", intervention_type=pv.VanillaIntervention, unit="pos", max_number_of_units=1, ) ] ) intervenable = pv.IntervenableModel(config, model) # Run with intervention _, patched_outputs = intervenable( base=corrupted_tokens, sources=[clean_tokens], unit_locations={"sources->base": ([[[position]]], [[[position]]])}, output_original_output=True, ) # Return probability of correct token probs = torch.softmax(patched_outputs.logits[0, -1], dim=-1) seattle_token = tokenizer.encode(" Seattle")[0] return probs[seattle_token].item() # 4. Sweep over layers and positions n_layers = model.config.n_layer seq_len = clean_tokens["input_ids"].shape[1] results = torch.zeros(n_layers, seq_len) for layer in range(n_layers): for pos in range(seq_len): results[layer, pos] = run_causal_trace(layer, pos) # 5. Visualize (layer x position heatmap) # High values indicate causal importance
Checklist
- Prepare clean prompt with target factual association
- Create corrupted version (noise or counterfactual)
- Define intervention config for each (layer, position)
- Run patching sweep
- Identify causal hotspots in heatmap
Workflow 2: Activation Patching for Circuit Analysis
Test which components are necessary for a specific behavior.
Step-by-Step
import pyvene as pv from transformers import AutoModelForCausalLM, AutoTokenizer import torch model = AutoModelForCausalLM.from_pretrained("gpt2") tokenizer = AutoTokenizer.from_pretrained("gpt2") # IOI task setup clean_prompt = "When John and Mary went to the store, Mary gave a bottle to" corrupted_prompt = "When John and Mary went to the store, John gave a bottle to" clean_tokens = tokenizer(clean_prompt, return_tensors="pt") corrupted_tokens = tokenizer(corrupted_prompt, return_tensors="pt") john_token = tokenizer.encode(" John")[0] mary_token = tokenizer.encode(" Mary")[0] def logit_diff(logits): """IO - S logit difference.""" return logits[0, -1, john_token] - logits[0, -1, mary_token] # Patch attention output at each layer def patch_attention(layer): config = pv.IntervenableConfig( representations=[ pv.RepresentationConfig( layer=layer, component="attention_output", intervention_type=pv.VanillaIntervention, ) ] ) intervenable = pv.IntervenableModel(config, model) _, patched_outputs = intervenable( base=corrupted_tokens, sources=[clean_tokens], ) return logit_diff(patched_outputs.logits).item() # Find which layers matter results = [] for layer in range(model.config.n_layer): diff = patch_attention(layer) results.append(diff) print(f"Layer {layer}: logit diff = {diff:.3f}")
Workflow 3: Interchange Intervention Training (IIT)
Train interventions to discover causal structure.
Step-by-Step
import pyvene as pv from transformers import AutoModelForCausalLM import torch model = AutoModelForCausalLM.from_pretrained("gpt2") # 1. Define trainable intervention config = pv.IntervenableConfig( representations=[ pv.RepresentationConfig( layer=6, component="block_output", intervention_type=pv.RotatedSpaceIntervention, # Trainable low_rank_dimension=64, # Learn 64-dim subspace ) ] ) intervenable = pv.IntervenableModel(config, model) # 2. Set up training optimizer = torch.optim.Adam( intervenable.get_trainable_parameters(), lr=1e-4 ) # 3. Training loop (simplified) for base_input, source_input, target_output in dataloader: optimizer.zero_grad() _, outputs = intervenable( base=base_input, sources=[source_input], ) loss = criterion(outputs.logits, target_output) loss.backward() optimizer.step() # 4. Analyze learned intervention # The rotation matrix reveals causal subspace rotation = intervenable.interventions["layer.6.block_output"][0].rotate_layer
DAS (Distributed Alignment Search)
# Low-rank rotation finds interpretable subspaces config = pv.IntervenableConfig( representations=[ pv.RepresentationConfig( layer=8, component="block_output", intervention_type=pv.LowRankRotatedSpaceIntervention, low_rank_dimension=1, # Find 1D causal direction ) ] )
Workflow 4: Model Steering (Honest LLaMA)
Steer model behavior during generation.
import pyvene as pv from transformers import AutoModelForCausalLM, AutoTokenizer model = AutoModelForCausalLM.from_pretrained("meta-llama/Llama-2-7b-hf") tokenizer = AutoTokenizer.from_pretrained("meta-llama/Llama-2-7b-hf") # Load pre-trained steering intervention intervenable = pv.IntervenableModel.load( "zhengxuanzenwu/intervenable_honest_llama2_chat_7B", model=model, ) # Generate with steering prompt = "Is the earth flat?" inputs = tokenizer(prompt, return_tensors="pt") # Intervention applied during generation outputs = intervenable.generate( inputs, max_new_tokens=100, do_sample=False, ) print(tokenizer.decode(outputs[0]))
Saving and Sharing Interventions
# Save locally intervenable.save("./my_intervention") # Load from local intervenable = pv.IntervenableModel.load( "./my_intervention", model=model, ) # Share on HuggingFace intervenable.save_intervention("username/my-intervention") # Load from HuggingFace intervenable = pv.IntervenableModel.load( "username/my-intervention", model=model, )
Common Issues & Solutions
Issue: Wrong intervention location
# WRONG: Incorrect component name config = pv.RepresentationConfig( component="mlp", # Not valid! ) # RIGHT: Use exact component name config = pv.RepresentationConfig( component="mlp_output", # Valid )
Issue: Dimension mismatch
# Ensure source and base have compatible shapes # For position-specific interventions: config = pv.RepresentationConfig( unit="pos", max_number_of_units=1, # Intervene on single position ) # Specify locations explicitly intervenable( base=base_tokens, sources=[source_tokens], unit_locations={"sources->base": ([[[5]]], [[[5]]])}, # Position 5 )
Issue: Memory with large models
# Use gradient checkpointing model.gradient_checkpointing_enable() # Or intervene on fewer components config = pv.IntervenableConfig( representations=[ pv.RepresentationConfig( layer=8, # Single layer instead of all component="block_output", ) ] )
Issue: LoRA integration
# pyvene v0.1.8+ supports LoRAs as interventions config = pv.RepresentationConfig( intervention_type=pv.LoRAIntervention, low_rank_dimension=16, )
Key Classes Reference
| Class | Purpose |
|---|---|
| Main wrapper for interventions |
| Configuration container |
| Single intervention specification |
| Activation swapping |
| Trainable DAS intervention |
| Activation collection |
Supported Models
pyvene works with any PyTorch model. Tested on:
- GPT-2 (all sizes)
- LLaMA / LLaMA-2
- Pythia
- Mistral / Mixtral
- OPT
- BLIP (vision-language)
- ESM (protein models)
- Mamba (state space)
Reference Documentation
For detailed API documentation, tutorials, and advanced usage, see the
references/| File | Contents |
|---|---|
| references/README.md | Overview and quick start guide |
| references/api.md | Complete API reference for IntervenableModel, intervention types, configurations |
| references/tutorials.md | Step-by-step tutorials for causal tracing, activation patching, DAS |
External Resources
Tutorials
Papers
- Locating and Editing Factual Associations in GPT - Meng et al. (2022)
- Inference-Time Intervention - Li et al. (2023)
- Interpretability in the Wild - Wang et al. (2022)
Official Documentation
Comparison with Other Tools
| Feature | pyvene | TransformerLens | nnsight |
|---|---|---|---|
| Declarative config | Yes | No | No |
| HuggingFace sharing | Yes | No | No |
| Trainable interventions | Yes | Limited | Yes |
| Any PyTorch model | Yes | Transformers only | Yes |
| Remote execution | No | No | Yes (NDIF) |