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nnsight-remote-interpretability

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

Provides guidance for interpreting and manipulating neural network internals using nnsight with optional NDIF remote execution. Use when needing to run interpretability experiments on massive models (70B+) without local GPU resources, or when working with any PyTorch architecture.

适合你,如果需要在无本地GPU条件下分析大模型内部机制。

/ 下载安装
nnsight-remote-interpretability.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/nnsight-remote-interpretability
/ 通过 bash 安装
curl -fsSL https://oh-my-skill.com/install.sh | bash -s -- orchestra-research/ai-research-skills/nnsight-remote-interpretability
/ 已经装过?验证本机副本,不用重装
npx oh-my-skill verify orchestra-research/ai-research-skills/nnsight-remote-interpretability
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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~2.8K最小装载
~6.5K含声明引用
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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 能帮你用 nnsight 库读取和修改神经网络内部状态(如隐藏层输出、注意力权重),并支持在本地小模型或远程大模型(70B+)上运行相同的代码。

什么时候触发

当你需要分析或干预神经网络内部机制,尤其是处理超大模型(如 70B、405B)且本地 GPU 资源不足时触发。

装好后可以这样说
Claude 会生成代码并解释如何获取和保存该层输出。
Claude 会指导设置 NDIF 远程执行并编写修补代码。
技能原文 SKILL.md作者撰写 · MIT · 773a529

nnsight: Transparent Access to Neural Network Internals

nnsight (/ɛn.saɪt/) enables researchers to interpret and manipulate the internals of any PyTorch model, with the unique capability of running the same code locally on small models or remotely on massive models (70B+) via NDIF.

GitHub: ndif-team/nnsight (730+ stars) Paper: NNsight and NDIF: Democratizing Access to Foundation Model Internals (ICLR 2025)

Key Value Proposition

Write once, run anywhere: The same interpretability code works on GPT-2 locally or Llama-3.1-405B remotely. Just toggle remote=True.

# Local execution (small model)
with model.trace("Hello world"):
    hidden = model.transformer.h[5].output[0].save()

# Remote execution (massive model) - same code!
with model.trace("Hello world", remote=True):
    hidden = model.model.layers[40].output[0].save()
When to Use nnsight

Use nnsight when you need to:

  • Run interpretability experiments on models too large for local GPUs (70B, 405B)
  • Work with any PyTorch architecture (transformers, Mamba, custom models)
  • Perform multi-token generation interventions
  • Share activations between different prompts
  • Access full model internals without reimplementation

Consider alternatives when:

  • You want consistent API across models → Use TransformerLens
  • You need declarative, shareable interventions → Use pyvene
  • You're training SAEs → Use SAELens
  • You only work with small models locally → TransformerLens may be simpler
Installation
# Basic installation
pip install nnsight

# For vLLM support
pip install "nnsight[vllm]"

For remote NDIF execution, sign up at login.ndif.us for an API key.

Core Concepts
LanguageModel Wrapper
from nnsight import LanguageModel

# Load model (uses HuggingFace under the hood)
model = LanguageModel("openai-community/gpt2", device_map="auto")

# For larger models
model = LanguageModel("meta-llama/Llama-3.1-8B", device_map="auto")
Tracing Context

The trace context manager enables deferred execution - operations are collected into a computation graph:

from nnsight import LanguageModel

model = LanguageModel("gpt2", device_map="auto")

with model.trace("The Eiffel Tower is in") as tracer:
    # Access any module's output
    hidden_states = model.transformer.h[5].output[0].save()

    # Access attention patterns
    attn = model.transformer.h[5].attn.attn_dropout.input[0][0].save()

    # Modify activations
    model.transformer.h[8].output[0][:] = 0  # Zero out layer 8

    # Get final output
    logits = model.output.save()

# After context exits, access saved values
print(hidden_states.shape)  # [batch, seq, hidden]
Proxy Objects

Inside trace, module accesses return Proxy objects that record operations:

with model.trace("Hello"):
    # These are all Proxy objects - operations are deferred
    h5_out = model.transformer.h[5].output[0]  # Proxy
    h5_mean = h5_out.mean(dim=-1)              # Proxy
    h5_saved = h5_mean.save()                   # Save for later access
Workflow 1: Activation Analysis
Step-by-Step
from nnsight import LanguageModel
import torch

model = LanguageModel("gpt2", device_map="auto")

prompt = "The capital of France is"

with model.trace(prompt) as tracer:
    # 1. Collect activations from multiple layers
    layer_outputs = []
    for i in range(12):  # GPT-2 has 12 layers
        layer_out = model.transformer.h[i].output[0].save()
        layer_outputs.append(layer_out)

    # 2. Get attention patterns
    attn_patterns = []
    for i in range(12):
        # Access attention weights (after softmax)
        attn = model.transformer.h[i].attn.attn_dropout.input[0][0].save()
        attn_patterns.append(attn)

    # 3. Get final logits
    logits = model.output.save()

# 4. Analyze outside context
for i, layer_out in enumerate(layer_outputs):
    print(f"Layer {i} output shape: {layer_out.shape}")
    print(f"Layer {i} norm: {layer_out.norm().item():.3f}")

# 5. Find top predictions
probs = torch.softmax(logits[0, -1], dim=-1)
top_tokens = probs.topk(5)
for token, prob in zip(top_tokens.indices, top_tokens.values):
    print(f"{model.tokenizer.decode(token)}: {prob.item():.3f}")
Checklist
  • [ ] Load model with LanguageModel wrapper
  • [ ] Use trace context for operations
  • [ ] Call .save() on values you need after context
  • [ ] Access saved values outside context
  • [ ] Use .shape, .norm(), etc. for analysis
Workflow 2: Activation Patching
Step-by-Step
from nnsight import LanguageModel
import torch

model = LanguageModel("gpt2", device_map="auto")

clean_prompt = "The Eiffel Tower is in"
corrupted_prompt = "The Colosseum is in"

# 1. Get clean activations
with model.trace(clean_prompt) as tracer:
    clean_hidden = model.transformer.h[8].output[0].save()

# 2. Patch clean into corrupted run
with model.trace(corrupted_prompt) as tracer:
    # Replace layer 8 output with clean activations
    model.transformer.h[8].output[0][:] = clean_hidden

    patched_logits = model.output.save()

# 3. Compare predictions
paris_token = model.tokenizer.encode(" Paris")[0]
rome_token = model.tokenizer.encode(" Rome")[0]

patched_probs = torch.softmax(patched_logits[0, -1], dim=-1)
print(f"Paris prob: {patched_probs[paris_token].item():.3f}")
print(f"Rome prob: {patched_probs[rome_token].item():.3f}")
Systematic Patching Sweep
def patch_layer_position(layer, position, clean_cache, corrupted_prompt):
    """Patch single layer/position from clean to corrupted."""
    with model.trace(corrupted_prompt) as tracer:
        # Get current activation
        current = model.transformer.h[layer].output[0]

        # Patch only specific position
        current[:, position, :] = clean_cache[layer][:, position, :]

        logits = model.output.save()

    return logits

# Sweep over all layers and positions
results = torch.zeros(12, seq_len)
for layer in range(12):
    for pos in range(seq_len):
        logits = patch_layer_position(layer, pos, clean_hidden, corrupted)
        results[layer, pos] = compute_metric(logits)
Workflow 3: Remote Execution with NDIF

Run the same experiments on massive models without local GPUs.

Step-by-Step
from nnsight import LanguageModel

# 1. Load large model (will run remotely)
model = LanguageModel("meta-llama/Llama-3.1-70B")

# 2. Same code, just add remote=True
with model.trace("The meaning of life is", remote=True) as tracer:
    # Access internals of 70B model!
    layer_40_out = model.model.layers[40].output[0].save()
    logits = model.output.save()

# 3. Results returned from NDIF
print(f"Layer 40 shape: {layer_40_out.shape}")

# 4. Generation with interventions
with model.trace(remote=True) as tracer:
    with tracer.invoke("What is 2+2?"):
        # Intervene during generation
        model.model.layers[20].output[0][:, -1, :] *= 1.5

    output = model.generate(max_new_tokens=50)
NDIF Setup
  1. Sign up at login.ndif.us
  2. Get API key
  3. Set environment variable or pass to nnsight:
import os
os.environ["NDIF_API_KEY"] = "your_key"

# Or configure directly
from nnsight import CONFIG
CONFIG.API_KEY = "your_key"
Available Models on NDIF
  • Llama-3.1-8B, 70B, 405B
  • DeepSeek-R1 models
  • Various open-weight models (check ndif.us for current list)
Workflow 4: Cross-Prompt Activation Sharing

Share activations between different inputs in a single trace.

from nnsight import LanguageModel

model = LanguageModel("gpt2", device_map="auto")

with model.trace() as tracer:
    # First prompt
    with tracer.invoke("The cat sat on the"):
        cat_hidden = model.transformer.h[6].output[0].save()

    # Second prompt - inject cat's activations
    with tracer.invoke("The dog ran through the"):
        # Replace with cat's activations at layer 6
        model.transformer.h[6].output[0][:] = cat_hidden
        dog_with_cat = model.output.save()

# The dog prompt now has cat's internal representations
Workflow 5: Gradient-Based Analysis

Access gradients during backward pass.

from nnsight import LanguageModel
import torch

model = LanguageModel("gpt2", device_map="auto")

with model.trace("The quick brown fox") as tracer:
    # Save activations and enable gradient
    hidden = model.transformer.h[5].output[0].save()
    hidden.retain_grad()

    logits = model.output

    # Compute loss on specific token
    target_token = model.tokenizer.encode(" jumps")[0]
    loss = -logits[0, -1, target_token]

    # Backward pass
    loss.backward()

# Access gradients
grad = hidden.grad
print(f"Gradient shape: {grad.shape}")
print(f"Gradient norm: {grad.norm().item():.3f}")

Note: Gradient access not supported for vLLM or remote execution.

Common Issues & Solutions
Issue: Module path differs between models
# GPT-2 structure
model.transformer.h[5].output[0]

# LLaMA structure
model.model.layers[5].output[0]

# Solution: Check model structure
print(model._model)  # See actual module names
Issue: Forgetting to save
# WRONG: Value not accessible outside trace
with model.trace("Hello"):
    hidden = model.transformer.h[5].output[0]  # Not saved!

print(hidden)  # Error or wrong value

# RIGHT: Call .save()
with model.trace("Hello"):
    hidden = model.transformer.h[5].output[0].save()

print(hidden)  # Works!
Issue: Remote timeout
# For long operations, increase timeout
with model.trace("prompt", remote=True, timeout=300) as tracer:
    # Long operation...
Issue: Memory with many saved activations
# Only save what you need
with model.trace("prompt"):
    # Don't save everything
    for i in range(100):
        model.transformer.h[i].output[0].save()  # Memory heavy!

    # Better: save specific layers
    key_layers = [0, 5, 11]
    for i in key_layers:
        model.transformer.h[i].output[0].save()
Issue: vLLM gradient limitation
# vLLM doesn't support gradients
# Use standard execution for gradient analysis
model = LanguageModel("gpt2", device_map="auto")  # Not vLLM
Key API Reference

| Method/Property | Purpose | |-----------------|---------| | model.trace(prompt, remote=False) | Start tracing context | | proxy.save() | Save value for access after trace | | proxy[:] | Slice/index proxy (assignment patches) | | tracer.invoke(prompt) | Add prompt within trace | | model.generate(...) | Generate with interventions | | model.output | Final model output logits | | model._model | Underlying HuggingFace model |

Comparison with Other Tools

| Feature | nnsight | TransformerLens | pyvene | |---------|---------|-----------------|--------| | Any architecture | Yes | Transformers only | Yes | | Remote execution | Yes (NDIF) | No | No | | Consistent API | No | Yes | Yes | | Deferred execution | Yes | No | No | | HuggingFace native | Yes | Reimplemented | Yes | | Shareable configs | No | No | Yes |

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 LanguageModel, tracing, proxy objects | | [references/tutorials.md](references/tutorials.md) | Step-by-step tutorials for local and remote interpretability |

External Resources
Tutorials
Official Documentation
Papers
Architecture Support

nnsight works with any PyTorch model:

  • Transformers: GPT-2, LLaMA, Mistral, etc.
  • State Space Models: Mamba
  • Vision Models: ViT, CLIP
  • Custom architectures: Any nn.Module

The key is knowing the module structure to access the right components.

按 MIT 许可原样转载,未经改动 · 在 GitHub 查看 →

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