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torchforge-rl-training

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

Provides guidance for PyTorch-native agentic RL using torchforge, Meta's library separating infra from algorithms. Use when you want clean RL abstractions, easy algorithm experimentation, or scalable training with Monarch and TorchTitan.

适合你,如果正在用 PyTorch 做强化学习研究或开发

/ 下载安装
torchforge-rl-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/torchforge-rl-training
/ 通过 bash 安装
curl -fsSL https://oh-my-skill.com/install.sh | bash -s -- orchestra-research/ai-research-skills/torchforge-rl-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/torchforge-rl-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 torchforge 库进行 PyTorch 原生的强化学习训练,包括 GRPO、SFT 等,并帮你配置分布式训练、定义奖励函数和损失函数。

什么时候触发

当你需要做强化学习实验,比如训练推理模型或实现自定义 RL 算法,并且希望使用 PyTorch 原生工具(如 Monarch、TorchTitan)时触发。

装好后可以这样说
会给出自定义损失类的代码示例。
会提供减少 GPU 需求的配置方案。
技能原文 SKILL.md作者撰写 · MIT · 773a529

torchforge: PyTorch-Native Agentic RL Library

torchforge is Meta's PyTorch-native RL library that separates infrastructure concerns from algorithm concerns. It enables rapid RL research by letting you focus on algorithms while handling distributed training, inference, and weight sync automatically.

When to Use torchforge

Choose torchforge when you need:

  • Clean separation between RL algorithms and infrastructure
  • PyTorch-native abstractions (no Ray dependency)
  • Easy algorithm experimentation (GRPO, DAPO, SAPO in ~100 lines)
  • Scalable training with Monarch actor system
  • Integration with TorchTitan for model parallelism

Consider alternatives when:

  • You need production-ready stability → use miles or verl
  • You want Megatron-native training → use slime
  • torchforge is experimental and APIs may change
Key Features
  • Algorithm isolation: Implement RL algorithms without touching infrastructure
  • Scalability: From single GPU to thousands via Monarch
  • Modern stack: TorchTitan (training), vLLM (inference), TorchStore (sync)
  • Loss functions: GRPO, DAPO, CISPO, GSPO, SAPO built-in
Architecture Overview
┌─────────────────────────────────────────────────────────┐
│ Application Layer (Your Code)                           │
│ - Define reward models, loss functions, sampling        │
└─────────────────────┬───────────────────────────────────┘
                      │
┌─────────────────────▼───────────────────────────────────┐
│ Forge API Layer                                         │
│ - Episode, Group dataclasses                           │
│ - Service interfaces (async/await)                      │
└─────────────────────┬───────────────────────────────────┘
                      │
┌─────────────────────▼───────────────────────────────────┐
│ Distributed Services (Monarch)                          │
│ ├── Trainer (TorchTitan FSDP)                          │
│ ├── Generator (vLLM inference)                          │
│ ├── Reference Model (frozen KL baseline)               │
│ └── Reward Actors (compute rewards)                    │
└─────────────────────────────────────────────────────────┘
Installation
# Create environment
conda create -n forge python=3.12
conda activate forge

# Install (handles PyTorch nightly + dependencies)
./scripts/install.sh

# Verify
python -c "import torch, forge, vllm; print('OK')"
ROCm Installation
./scripts/install_rocm.sh
Quick Start
SFT Training (2+ GPUs)
python -m apps.sft.main --config apps/sft/llama3_8b.yaml
GRPO Training (3+ GPUs)
python -m apps.grpo.main --config apps/grpo/qwen3_1_7b.yaml

Workflow 1: GRPO Training for Math Reasoning

Use this workflow for training reasoning models with group-relative advantages.

Prerequisites Checklist
  • [ ] 3+ GPUs (GPU0: trainer, GPU1: ref_model, GPU2: generator)
  • [ ] Model from HuggingFace Hub
  • [ ] Training dataset (GSM8K, MATH, etc.)
Step 1: Create Configuration
# config/grpo_math.yaml
model: "Qwen/Qwen2.5-7B-Instruct"

dataset:
  path: "openai/gsm8k"
  split: "train"
  streaming: true

training:
  batch_size: 4
  learning_rate: 1e-6
  seq_len: 4096
  dtype: bfloat16
  gradient_accumulation_steps: 4

grpo:
  n_samples: 8           # Responses per prompt
  clip_low: 0.2
  clip_high: 0.28
  beta: 0.1              # KL penalty coefficient
  temperature: 0.7

services:
  generator:
    procs: 1
    num_replicas: 1
    with_gpus: true
  trainer:
    procs: 1
    num_replicas: 1
    with_gpus: true
  ref_model:
    procs: 1
    num_replicas: 1
    with_gpus: true
Step 2: Define Reward Function
# rewards.py
# Reward functions are in forge.data.rewards
from forge.data.rewards import MathReward, ThinkingReward
import re

# Or define your own reward function
class CustomMathReward:
    def __call__(self, prompt: str, response: str, target: str) -> float:
        # Extract answer from response
        match = re.search(r'\\boxed{([^}]+)}', response)
        if not match:
            return 0.0

        answer = match.group(1).strip()
        return 1.0 if answer == target else 0.0
Step 3: Launch Training
python -m apps.grpo.main --config config/grpo_math.yaml
Step 4: Monitor Progress
  • [ ] Check W&B dashboard for loss curves
  • [ ] Verify entropy is decreasing (policy becoming more deterministic)
  • [ ] Monitor KL divergence (should stay bounded)

Workflow 2: Custom Loss Function

Use this workflow to implement new RL algorithms.

Step 1: Create Loss Class
# src/forge/losses/custom_loss.py
import torch
import torch.nn as nn

class CustomLoss(nn.Module):
    def __init__(self, clip_range: float = 0.2, beta: float = 0.1):
        super().__init__()
        self.clip_range = clip_range
        self.beta = beta

    def forward(
        self,
        logprobs: torch.Tensor,
        ref_logprobs: torch.Tensor,
        advantages: torch.Tensor,
        padding_mask: torch.Tensor,
    ) -> torch.Tensor:
        # Compute importance ratio
        ratio = torch.exp(logprobs - ref_logprobs)

        # Clipped policy gradient
        clipped_ratio = torch.clamp(
            ratio,
            1 - self.clip_range,
            1 + self.clip_range
        )
        pg_loss = -torch.min(ratio * advantages, clipped_ratio * advantages)

        # KL penalty
        kl = ref_logprobs - logprobs

        # Apply mask and aggregate
        masked_loss = (pg_loss + self.beta * kl) * padding_mask
        loss = masked_loss.sum() / padding_mask.sum()

        return loss
Step 2: Integrate into Application
# apps/custom/main.py
from forge.losses.custom_loss import CustomLoss

loss_fn = CustomLoss(clip_range=0.2, beta=0.1)

# In training loop
loss = loss_fn(
    logprobs=logprobs,
    ref_logprobs=ref_logprobs,
    advantages=advantages,
    padding_mask=padding_mask,
)

Workflow 3: Multi-GPU Distributed Training

Use this workflow for scaling to multiple GPUs or nodes.

Configuration for Distributed
# config/distributed.yaml
model: "meta-llama/Meta-Llama-3.1-8B-Instruct"

parallelism:
  tensor_parallel_degree: 2    # Split model across GPUs
  pipeline_parallel_degree: 1
  data_parallel_shard_degree: 2

services:
  generator:
    procs: 2                   # 2 processes for TP=2
    num_replicas: 1
    with_gpus: true
  trainer:
    procs: 2
    num_replicas: 1
    with_gpus: true
Launch with SLURM
# Submit job
sbatch --nodes=2 --gpus-per-node=8 run_grpo.sh
Launch Locally (Multi-GPU)
# 8 GPU setup
python -m apps.grpo.main \
    --config config/distributed.yaml \
    --trainer.procs 4 \
    --generator.procs 4

Core API Reference
Training Batch Format

torchforge uses dictionary-based batches for training:

# inputs: list of dicts with torch.Tensor values
inputs = [{"tokens": torch.Tensor}]

# targets: list of dicts with training signals
targets = [{
    "response": torch.Tensor,
    "ref_logprobs": torch.Tensor,
    "advantages": torch.Tensor,
    "padding_mask": torch.Tensor
}]

# train_step returns loss as float
loss = trainer.train_step(inputs, targets)
Completion

Generated output from vLLM:

@dataclass
class Completion:
    text: str              # Generated text
    token_ids: list[int]   # Token IDs
    logprobs: list[float]  # Log probabilities
    metadata: dict         # Custom metadata

Built-in Loss Functions
Loss Functions

Loss functions are in the forge.losses module:

from forge.losses import SimpleGRPOLoss, ReinforceLoss

# SimpleGRPOLoss for GRPO training
loss_fn = SimpleGRPOLoss(beta=0.1)

# Forward pass
loss = loss_fn(
    logprobs=logprobs,
    ref_logprobs=ref_logprobs,
    advantages=advantages,
    padding_mask=padding_mask
)
ReinforceLoss
from forge.losses.reinforce_loss import ReinforceLoss

# With optional importance ratio clipping
loss_fn = ReinforceLoss(clip_ratio=0.2)

Common Issues and Solutions
Issue: Not Enough GPUs

Symptoms: "Insufficient GPU resources" error

Solutions:

# Reduce service requirements
services:
  generator:
    procs: 1
    with_gpus: true
  trainer:
    procs: 1
    with_gpus: true
  # Remove ref_model (uses generator weights)

Or use CPU for reference model:

ref_model:
  with_gpus: false
Issue: OOM During Generation

Symptoms: CUDA OOM in vLLM

Solutions:

# Reduce batch size
grpo:
  n_samples: 4  # Reduce from 8

# Or reduce sequence length
training:
  seq_len: 2048
Issue: Slow Weight Sync

Symptoms: Long pauses between training and generation

Solutions:

# Enable RDMA (if available)
export TORCHSTORE_USE_RDMA=1

# Or reduce sync frequency
training:
  sync_interval: 10  # Sync every 10 steps
Issue: Policy Collapse

Symptoms: Entropy drops to zero, reward stops improving

Solutions:

# Increase KL penalty
grpo:
  beta: 0.2  # Increase from 0.1

# Or add entropy bonus
training:
  entropy_coef: 0.01

Resources
  • Documentation: https://meta-pytorch.org/torchforge
  • GitHub: https://github.com/meta-pytorch/torchforge
  • Discord: https://discord.gg/YsTYBh6PD9
  • TorchTitan: https://github.com/pytorch/torchtitan
  • Monarch: https://github.com/meta-pytorch/monarch
按 MIT 许可原样转载,未经改动 · 在 GitHub 查看 →

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