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sparse-autoencoder-training

@orchestra-research · 收录于 1 周前 · 上游提交 1 个月前

Provides guidance for training and analyzing Sparse Autoencoders (SAEs) using SAELens to decompose neural network activations into interpretable features. Use when discovering interpretable features, analyzing superposition, or studying monosemantic representations in language models.

适合你,如果正在研究语言模型内部表征或叠加现象

/ 下载安装
sparse-autoencoder-training.skill双击,或拖进 Claude 桌面版 / Cowork,即完成安装↓ .skill↓ .zip
用别的 agent?下载 .zip 解压,把文件夹放进它的技能目录
Claude Code~/.claude/skills/(项目级 .claude/skills/)
Codex CLI~/.codex/skills/
Cursor自动读取上面两处目录
其他工具见其文档的「skills」目录;两个下载是同一份文件,只是名字不同
/ 通过 npx 安装 校验哈希
npx oh-my-skill add orchestra-research/ai-research-skills/sparse-autoencoder-training
/ 通过 bash 安装
curl -fsSL https://oh-my-skill.com/install.sh | bash -s -- orchestra-research/ai-research-skills/sparse-autoencoder-training
/ 已经装过?验证本机副本,不用重装
npx oh-my-skill verify orchestra-research/ai-research-skills/sparse-autoencoder-training
安装目标可用 --agent / --scope 或 --to 明确指定;省略时只会在唯一已存在的 agent 目录上自动选择,零命中或多命中会停止并提示。content_hash 缺失或不一致均拒装。
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怎么用

商店整理自技能原文 · 版本 773a529 · 表述以原文为准
它做什么

安装后,Claude 能指导你使用 SAELens 库训练和分析稀疏自编码器(SAE),将神经网络激活分解为可解释的特征,用于理解模型内部概念。

什么时候触发

当你需要发现模型中的可解释特征、分析叠加现象或研究单义表示时触发。

装好后可以这样说
Claude 会给出加载和分析步骤。
Claude 会提供训练配置和代码。
Claude 会展示特征引导的生成方法。
技能原文 SKILL.md作者撰写 · MIT · 773a529

SAELens: Sparse Autoencoders for Mechanistic Interpretability

SAELens is the primary library for training and analyzing Sparse Autoencoders (SAEs) - a technique for decomposing polysemantic neural network activations into sparse, interpretable features. Based on Anthropic's groundbreaking research on monosemanticity.

GitHub: jbloomAus/SAELens (1,100+ stars)

The Problem: Polysemanticity & Superposition

Individual neurons in neural networks are polysemantic - they activate in multiple, semantically distinct contexts. This happens because models use superposition to represent more features than they have neurons, making interpretability difficult.

SAEs solve this by decomposing dense activations into sparse, monosemantic features - typically only a small number of features activate for any given input, and each feature corresponds to an interpretable concept.

When to Use SAELens

Use SAELens when you need to:

  • Discover interpretable features in model activations
  • Understand what concepts a model has learned
  • Study superposition and feature geometry
  • Perform feature-based steering or ablation
  • Analyze safety-relevant features (deception, bias, harmful content)

Consider alternatives when:

  • You need basic activation analysis → Use TransformerLens directly
  • You want causal intervention experiments → Use pyvene or TransformerLens
  • You need production steering → Consider direct activation engineering
Installation
pip install sae-lens

Requirements: Python 3.10+, transformer-lens>=2.0.0

Core Concepts
What SAEs Learn

SAEs are trained to reconstruct model activations through a sparse bottleneck:

Input Activation → Encoder → Sparse Features → Decoder → Reconstructed Activation
    (d_model)       ↓        (d_sae >> d_model)    ↓         (d_model)
                 sparsity                      reconstruction
                 penalty                          loss

Loss Function: MSE(original, reconstructed) + L1_coefficient × L1(features)

Key Validation (Anthropic Research)

In "Towards Monosemanticity", human evaluators found 70% of SAE features genuinely interpretable. Features discovered include:

  • DNA sequences, legal language, HTTP requests
  • Hebrew text, nutrition statements, code syntax
  • Sentiment, named entities, grammatical structures
Workflow 1: Loading and Analyzing Pre-trained SAEs
Step-by-Step
from transformer_lens import HookedTransformer
from sae_lens import SAE

# 1. Load model and pre-trained SAE
model = HookedTransformer.from_pretrained("gpt2-small", device="cuda")
sae, cfg_dict, sparsity = SAE.from_pretrained(
    release="gpt2-small-res-jb",
    sae_id="blocks.8.hook_resid_pre",
    device="cuda"
)

# 2. Get model activations
tokens = model.to_tokens("The capital of France is Paris")
_, cache = model.run_with_cache(tokens)
activations = cache["resid_pre", 8]  # [batch, pos, d_model]

# 3. Encode to SAE features
sae_features = sae.encode(activations)  # [batch, pos, d_sae]
print(f"Active features: {(sae_features > 0).sum()}")

# 4. Find top features for each position
for pos in range(tokens.shape[1]):
    top_features = sae_features[0, pos].topk(5)
    token = model.to_str_tokens(tokens[0, pos:pos+1])[0]
    print(f"Token '{token}': features {top_features.indices.tolist()}")

# 5. Reconstruct activations
reconstructed = sae.decode(sae_features)
reconstruction_error = (activations - reconstructed).norm()
Available Pre-trained SAEs

| Release | Model | Layers | |---------|-------|--------| | gpt2-small-res-jb | GPT-2 Small | Multiple residual streams | | gemma-2b-res | Gemma 2B | Residual streams | | Various on HuggingFace | Search tag saelens | Various |

Checklist
  • [ ] Load model with TransformerLens
  • [ ] Load matching SAE for target layer
  • [ ] Encode activations to sparse features
  • [ ] Identify top-activating features per token
  • [ ] Validate reconstruction quality
Workflow 2: Training a Custom SAE
Step-by-Step
from sae_lens import SAE, LanguageModelSAERunnerConfig, SAETrainingRunner

# 1. Configure training
cfg = LanguageModelSAERunnerConfig(
    # Model
    model_name="gpt2-small",
    hook_name="blocks.8.hook_resid_pre",
    hook_layer=8,
    d_in=768,  # Model dimension

    # SAE architecture
    architecture="standard",  # or "gated", "topk"
    d_sae=768 * 8,  # Expansion factor of 8
    activation_fn="relu",

    # Training
    lr=4e-4,
    l1_coefficient=8e-5,  # Sparsity penalty
    l1_warm_up_steps=1000,
    train_batch_size_tokens=4096,
    training_tokens=100_000_000,

    # Data
    dataset_path="monology/pile-uncopyrighted",
    context_size=128,

    # Logging
    log_to_wandb=True,
    wandb_project="sae-training",

    # Checkpointing
    checkpoint_path="checkpoints",
    n_checkpoints=5,
)

# 2. Train
trainer = SAETrainingRunner(cfg)
sae = trainer.run()

# 3. Evaluate
print(f"L0 (avg active features): {trainer.metrics['l0']}")
print(f"CE Loss Recovered: {trainer.metrics['ce_loss_score']}")
Key Hyperparameters

| Parameter | Typical Value | Effect | |-----------|---------------|--------| | d_sae | 4-16× d_model | More features, higher capacity | | l1_coefficient | 5e-5 to 1e-4 | Higher = sparser, less accurate | | lr | 1e-4 to 1e-3 | Standard optimizer LR | | l1_warm_up_steps | 500-2000 | Prevents early feature death |

Evaluation Metrics

| Metric | Target | Meaning | |--------|--------|---------| | L0 | 50-200 | Average active features per token | | CE Loss Score | 80-95% | Cross-entropy recovered vs original | | Dead Features | <5% | Features that never activate | | Explained Variance | >90% | Reconstruction quality |

Checklist
  • [ ] Choose target layer and hook point
  • [ ] Set expansion factor (d_sae = 4-16× d_model)
  • [ ] Tune L1 coefficient for desired sparsity
  • [ ] Enable L1 warm-up to prevent dead features
  • [ ] Monitor metrics during training (W&B)
  • [ ] Validate L0 and CE loss recovery
  • [ ] Check dead feature ratio
Workflow 3: Feature Analysis and Steering
Analyzing Individual Features
from transformer_lens import HookedTransformer
from sae_lens import SAE
import torch

model = HookedTransformer.from_pretrained("gpt2-small", device="cuda")
sae, _, _ = SAE.from_pretrained(
    release="gpt2-small-res-jb",
    sae_id="blocks.8.hook_resid_pre",
    device="cuda"
)

# Find what activates a specific feature
feature_idx = 1234
test_texts = [
    "The scientist conducted an experiment",
    "I love chocolate cake",
    "The code compiles successfully",
    "Paris is beautiful in spring",
]

for text in test_texts:
    tokens = model.to_tokens(text)
    _, cache = model.run_with_cache(tokens)
    features = sae.encode(cache["resid_pre", 8])
    activation = features[0, :, feature_idx].max().item()
    print(f"{activation:.3f}: {text}")
Feature Steering
def steer_with_feature(model, sae, prompt, feature_idx, strength=5.0):
    """Add SAE feature direction to residual stream."""
    tokens = model.to_tokens(prompt)

    # Get feature direction from decoder
    feature_direction = sae.W_dec[feature_idx]  # [d_model]

    def steering_hook(activation, hook):
        # Add scaled feature direction at all positions
        activation += strength * feature_direction
        return activation

    # Generate with steering
    output = model.generate(
        tokens,
        max_new_tokens=50,
        fwd_hooks=[("blocks.8.hook_resid_pre", steering_hook)]
    )
    return model.to_string(output[0])
Feature Attribution
# Which features most affect a specific output?
tokens = model.to_tokens("The capital of France is")
_, cache = model.run_with_cache(tokens)

# Get features at final position
features = sae.encode(cache["resid_pre", 8])[0, -1]  # [d_sae]

# Get logit attribution per feature
# Feature contribution = feature_activation × decoder_weight × unembedding
W_dec = sae.W_dec  # [d_sae, d_model]
W_U = model.W_U    # [d_model, vocab]

# Contribution to "Paris" logit
paris_token = model.to_single_token(" Paris")
feature_contributions = features * (W_dec @ W_U[:, paris_token])

top_features = feature_contributions.topk(10)
print("Top features for 'Paris' prediction:")
for idx, val in zip(top_features.indices, top_features.values):
    print(f"  Feature {idx.item()}: {val.item():.3f}")
Common Issues & Solutions
Issue: High dead feature ratio
# WRONG: No warm-up, features die early
cfg = LanguageModelSAERunnerConfig(
    l1_coefficient=1e-4,
    l1_warm_up_steps=0,  # Bad!
)

# RIGHT: Warm-up L1 penalty
cfg = LanguageModelSAERunnerConfig(
    l1_coefficient=8e-5,
    l1_warm_up_steps=1000,  # Gradually increase
    use_ghost_grads=True,   # Revive dead features
)
Issue: Poor reconstruction (low CE recovery)
# Reduce sparsity penalty
cfg = LanguageModelSAERunnerConfig(
    l1_coefficient=5e-5,  # Lower = better reconstruction
    d_sae=768 * 16,       # More capacity
)
Issue: Features not interpretable
# Increase sparsity (higher L1)
cfg = LanguageModelSAERunnerConfig(
    l1_coefficient=1e-4,  # Higher = sparser, more interpretable
)
# Or use TopK architecture
cfg = LanguageModelSAERunnerConfig(
    architecture="topk",
    activation_fn_kwargs={"k": 50},  # Exactly 50 active features
)
Issue: Memory errors during training
cfg = LanguageModelSAERunnerConfig(
    train_batch_size_tokens=2048,  # Reduce batch size
    store_batch_size_prompts=4,    # Fewer prompts in buffer
    n_batches_in_buffer=8,         # Smaller activation buffer
)
Integration with Neuronpedia

Browse pre-trained SAE features at neuronpedia.org:

# Features are indexed by SAE ID
# Example: gpt2-small layer 8 feature 1234
# → neuronpedia.org/gpt2-small/8-res-jb/1234
Key Classes Reference

| Class | Purpose | |-------|---------| | SAE | Sparse Autoencoder model | | LanguageModelSAERunnerConfig | Training configuration | | SAETrainingRunner | Training loop manager | | ActivationsStore | Activation collection and batching | | HookedSAETransformer | TransformerLens + SAE integration |

Reference Documentation

For detailed API documentation, tutorials, and advanced usage, see the references/ folder:

| File | Contents | |------|----------| | [references/README.md](references/README.md) | Overview and quick start guide | | [references/api.md](references/api.md) | Complete API reference for SAE, TrainingSAE, configurations | | [references/tutorials.md](references/tutorials.md) | Step-by-step tutorials for training, analysis, steering |

External Resources
Tutorials
Papers
Official Documentation
SAE Architectures

| Architecture | Description | Use Case | |--------------|-------------|----------| | Standard | ReLU + L1 penalty | General purpose | | Gated | Learned gating mechanism | Better sparsity control | | TopK | Exactly K active features | Consistent sparsity |

# TopK SAE (exactly 50 features active)
cfg = LanguageModelSAERunnerConfig(
    architecture="topk",
    activation_fn="topk",
    activation_fn_kwargs={"k": 50},
)
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