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distributed-llm-pretraining-torchtitan

✓ Official11

by firecrawl · part of firecrawl/ai-research-skills

Provides PyTorch-native distributed LLM pretraining using torchtitan with 4D parallelism (FSDP2, TP, PP, CP). Use when pretraining Llama 3.1, DeepSeek V3, or custom models at scale from 8 to 512+ GPUs with Float8, torch.compile, and distributed checkpointing.

🔥🔥🔥FreeQuick setup
🧩 One of 7 skills in the firecrawl/ai-research-skills package — works on its own, and pairs well with its siblings.

This is the playbook your agent receives when the skill activates — you don't need to read it to use the skill, but it's here to audit before installing.

TorchTitan - PyTorch Native Distributed LLM Pretraining

Common workflows

Workflow 1: Pretrain Llama 3.1 8B on single node

Copy this checklist:

Single Node Pretraining:
- [ ] Step 1: Download tokenizer
- [ ] Step 2: Configure training
- [ ] Step 3: Launch training
- [ ] Step 4: Monitor and checkpoint

Step 1: Download tokenizer

python scripts/download_hf_assets.py \
  --repo_id meta-llama/Llama-3.1-8B \
  --assets tokenizer \
  --hf_token=YOUR_HF_TOKEN

Step 2: Configure training

Edit or create a TOML config file:

# llama3_8b_custom.toml
[job]
dump_folder = "./outputs"
description = "Llama 3.1 8B training"

[model]
name = "llama3"
flavor = "8B"
hf_assets_path = "./assets/hf/Llama-3.1-8B"

[optimizer]
name = "AdamW"
lr = 3e-4

[lr_scheduler]
warmup_steps = 200

[training]
local_batch_size = 2
seq_len = 8192
max_norm = 1.0
steps = 1000
dataset = "c4"

[parallelism]
data_parallel_shard_degree = -1  # Use all GPUs for FSDP

[activation_checkpoint]
mode = "selective"
selective_ac_option = "op"

[checkpoint]
enable = true
folder = "checkpoint"
interval = 500

Step 3: Launch training

# 8 GPUs on single node
CONFIG_FILE="./llama3_8b_custom.toml" ./run_train.sh

# Or explicitly with torchrun
torchrun --nproc_per_node=8 \
  -m torchtitan.train \
  --job.config_file ./llama3_8b_custom.toml

Step 4: Monitor and checkpoint

TensorBoard logs are saved to ./outputs/tb/:

tensorboard --logdir ./outputs/tb

Workflow 2: Multi-node training with SLURM

Multi-Node Training:
- [ ] Step 1: Configure parallelism for scale
- [ ] Step 2: Set up SLURM script
- [ ] Step 3: Submit job
- [ ] Step 4: Resume from checkpoint

Step 1: Configure parallelism for scale

For 70B model on 256 GPUs (32 nodes):

[parallelism]
data_parallel_shard_degree = 32  # FSDP across 32 ranks
tensor_parallel_degree = 8        # TP within node
pipeline_parallel_degree = 1      # No PP for 70B
context_parallel_degree = 1       # Increase for long sequences

Step 2: Set up SLURM script

#!/bin/bash
#SBATCH --job-name=llama70b
#SBATCH --nodes=32
#SBATCH --ntasks-per-node=8
#SBATCH --gpus-per-node=8

srun torchrun \
  --nnodes=32 \
  --nproc_per_node=8 \
  --rdzv_backend=c10d \
  --rdzv_endpoint=$MASTER_ADDR:$MASTER_PORT \
  -m torchtitan.train \
  --job.config_file ./llama3_70b.toml

Step 3: Submit job

sbatch multinode_trainer.slurm

Step 4: Resume from checkpoint

Training auto-resumes if checkpoint exists in configured folder.

Workflow 3: Enable Float8 training for H100s

Float8 provides 30-50% speedup on H100 GPUs.

Float8 Training:
- [ ] Step 1: Install torchao
- [ ] Step 2: Configure Float8
- [ ] Step 3: Launch with compile

Step 1: Install torchao

USE_CPP=0 pip install git+https://github.com/pytorch/ao.git

Step 2: Configure Float8

Add to your TOML config:

[model]
converters = ["quantize.linear.float8"]

[quantize.linear.float8]
enable_fsdp_float8_all_gather = true
precompute_float8_dynamic_scale_for_fsdp = true
filter_fqns = ["output"]  # Exclude output layer

[compile]
enable = true
components = ["model", "loss"]

Step 3: Launch with compile

CONFIG_FILE="./llama3_8b.toml" ./run_train.sh \
  --model.converters="quantize.linear.float8" \
  --quantize.linear.float8.enable_fsdp_float8_all_gather \
  --compile.enable

Workflow 4: 4D parallelism for 405B models

4D Parallelism (FSDP + TP + PP + CP):
- [ ] Step 1: Create seed checkpoint
- [ ] Step 2: Configure 4D parallelism
- [ ] Step 3: Launch on 512 GPUs

Step 1: Create seed checkpoint

Required for consistent initialization across PP stages:

NGPU=1 CONFIG_FILE=./llama3_405b.toml ./run_train.sh \
  --checkpoint.enable \
  --checkpoint.create_seed_checkpoint \
  --parallelism.data_parallel_shard_degree 1 \
  --parallelism.tensor_parallel_degree 1 \
  --parallelism.pipeline_parallel_degree 1

Step 2: Configure 4D parallelism

[parallelism]
data_parallel_shard_degree = 8   # FSDP
tensor_parallel_degree = 8       # TP within node
pipeline_parallel_degree = 8     # PP across nodes
context_parallel_degree = 1      # CP for long sequences

[training]
local_batch_size = 32
seq_len = 8192

Step 3: Launch on 512 GPUs

# 64 nodes x 8 GPUs = 512 GPUs
srun torchrun --nnodes=64 --nproc_per_node=8 \
  -m torchtitan.train \
  --job.config_file ./llama3_405b.toml

When to use vs alternatives

Use TorchTitan when:

  • Pretraining LLMs from scratch (8B to 405B+)
  • Need PyTorch-native solution without third-party dependencies
  • Require composable 4D parallelism (FSDP2, TP, PP, CP)
  • Training on H100s with Float8 support
  • Want interoperable checkpoints with torchtune/HuggingFace

Use alternatives instead:

  • Megatron-LM: Maximum performance for NVIDIA-only deployments
  • DeepSpeed: Broader ZeRO optimization ecosystem, inference support
  • Axolotl/TRL: Fine-tuning rather than pretraining
  • LitGPT: Educational, smaller-scale training

Supported models

ModelSizesStatus
Llama 3.18B, 70B, 405BProduction
Llama 4VariousExperimental
DeepSeek V316B, 236B, 671B (MoE)Experimental
GPT-OSS20B, 120B (MoE)Experimental
Qwen 3VariousExperimental
FluxDiffusionExperimental

Performance benchmarks (H100)

ModelGPUsParallelismTPS/GPUTechniques
Llama 8B8FSDP5,762Baseline
Llama 8B8FSDP+compile+FP88,532+48%
Llama 70B256FSDP+TP+AsyncTP8762D parallel
Llama 405B512FSDP+TP+PP1283D parallel

Advanced topics

FSDP2 configuration: See references/fsdp.md for detailed FSDP2 vs FSDP1 comparison and ZeRO equivalents.

Float8 training: See references/float8.md for tensorwise vs rowwise scaling recipes.

Checkpointing: See references/checkpoint.md for HuggingFace conversion and async checkpointing.

Adding custom models: See references/custom-models.md for TrainSpec protocol.

Resources