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How to launch distributed Megatron-LM training jobs on a SLURM cluster. Covers a minimal sbatch skeleton, environment-variable setup for torch.distributed.run, CUDA_DEVICE_MAX_CONNECTIONS rules across hardware and parallelism modes, container conventions, monitoring, and per-rank failure diagnosis.
Investigate a failing GitHub Actions run or job and create a GitHub issue for the failure.
Bump the NVIDIA PyTorch base image (`nvcr.io/nvidia/pytorch:<YY.MM>-py3`) used by Megatron-LM CI. Covers the two pin sites (GitHub CI in `docker/.ngc_version.dev` and GitLab CI in `.gitlab/stages/01.build.yml`), the post-bump CI loop (re-run functional tests, refresh golden values, mark broken tests), and the gotchas that bit PRs
Domain knowledge for the nightly main-to-dev sync workflow. Covers merge strategy, CI architecture, failure investigation, and known issues.
Container-based dev environment setup and dependency management for Megatron-LM. Covers acquiring and launching the CI container, uv package management, and updating uv.lock.
CI/CD reference for Megatron-LM. Covers CI pipeline structure, PR scope labels, triggering internal GitLab CI, and CI failure investigation.
Linting and formatting for Megatron-LM. Covers running autoformat.sh, tools (ruff, black, isort, pylint, mypy), and code style rules.
| name | run-on-slurm |
| description | How to launch distributed Megatron-LM training jobs on a SLURM cluster. Covers a minimal sbatch skeleton, environment-variable setup for torch.distributed.run, CUDA_DEVICE_MAX_CONNECTIONS rules across hardware and parallelism modes, container conventions, monitoring, and per-rank failure diagnosis. |
| when_to_use | Submitting a SLURM job; writing or debugging an sbatch script; configuring multi-node distributed training; setting MASTER_ADDR / MASTER_PORT / WORLD_SIZE; diagnosing a SLURM job failure; 'how do I run on the cluster', 'sbatch', 'multi-node training'. |
uv installed; run uv sync --extra training --extra dev (or --extra lts) on the worktree once before submission so the .venv is materialized and visible to every node.Save as run_megatron.slurm in the worktree:
#!/bin/bash
#SBATCH --job-name=megatron
#SBATCH --account=<SLURM_ACCOUNT>
#SBATCH --partition=<SLURM_PARTITION>
#SBATCH --nodes=<NODES>
#SBATCH --ntasks-per-node=1
#SBATCH --gpus-per-node=<GPUS_PER_NODE>
#SBATCH --time=<HH:MM:SS>
#SBATCH --output=logs/%x-%j.out
#SBATCH --error=logs/%x-%j.err
set -euo pipefail
cd <MEGATRON_WORKTREE>
export MASTER_ADDR=$(scontrol show hostnames "$SLURM_JOB_NODELIST" | head -n1)
export MASTER_PORT=${MASTER_PORT:-29500}
export NNODES=${SLURM_NNODES}
export GPUS_PER_NODE=<GPUS_PER_NODE>
export WORLD_SIZE=$((NNODES * GPUS_PER_NODE))
# Set CUDA_DEVICE_MAX_CONNECTIONS only when your configuration requires it
# (see the section below). Example for pre-Blackwell with TP>1 or CP>1
# (non-FSDP):
# export CUDA_DEVICE_MAX_CONNECTIONS=1
srun --ntasks=${NNODES} --ntasks-per-node=1 bash -c '
# NODE_RANK comes from SLURM_NODEID with one task per node.
NODE_RANK=${SLURM_NODEID}
uv run python -m torch.distributed.run \
--nnodes='"${NNODES}"' \
--nproc-per-node='"${GPUS_PER_NODE}"' \
--node-rank=${NODE_RANK} \
--master-addr='"${MASTER_ADDR}"' \
--master-port='"${MASTER_PORT}"' \
pretrain_gpt.py \
<MEGATRON_ARGS>
'
Submit:
mkdir -p logs && JOB_ID=$(sbatch --parsable run_megatron.slurm)
echo "Submitted ${JOB_ID}"
cd to it in the script. All nodes must reach the same path on a shared filesystem (NFS, Lustre, or similar) — node-local paths will not be visible to peer ranks.torchrun worker group across all nodes; do not start independent single-node jobs.--nproc-per-node should equal the number of visible GPUs per node.The right value depends on your hardware and parallelism mode. Do not export it unconditionally:
1. The relevant code path asserts on this — you will get an assertion error if it is not 1, not a silent deadlock.1. Leave the env var unset, or set it to a value greater than 1.overlap_moe_expert_parallel_comm enabled: set to 32.Set it explicitly in the sbatch script when your configuration calls for it.
Many sites run Megatron-LM inside a container (enroot/pyxis on some clusters, singularity on others). If you do, the uv-managed .venv must live on a path that is visible from inside the container, and the container image must provide the CUDA / NCCL / torch versions the repo expects (see docker/.ngc_version.dev and .ngc_version.lts). The skeleton above stays the same; wrap the srun invocation with your scheduler's container flags (--container-image=…, --container-mounts=…, etc.).
squeue -j "$JOB_ID" -o "%.10i %.8T %.10M %.6D %R"
sacct -j "$JOB_ID" --format=JobID,State,ExitCode,Elapsed
scancel "$JOB_ID"
If your training script writes a result artifact (a JSON metrics file from rank 0, a final checkpoint, etc.), poll for the artifact rather than waiting only on squeue state. Useful output usually appears before SLURM marks the job complete, and polling on the artifact lets you cancel the job as soon as it lands instead of holding the allocation until the timeout.
Scan stderr from every rank, not just rank 0. The earliest non-NCCL Python traceback is usually the root cause; later NCCL timeouts on other ranks are downstream symptoms of the first crash.
Classify quickly:
WORLD_SIZE = TP × DP × CP × PP and head-count divisibility (num_attention_heads % TP == 0).uv sync, or stale PYTHONPATH. Confirm cd <MEGATRON_WORKTREE> before launch.MASTER_ADDR resolution, and command consistency across ranks.uv sync before the first submission. If the venv is missing, every job rebuilds it from inside srun, costing minutes per job.CUDA_DEVICE_MAX_CONNECTIONS=1 blindly. The right value depends on hardware and parallelism mode (see the dedicated section above). Setting it to 1 with FSDP causes a different problem; on Blackwell it has no effect; on pre-Blackwell with TP>1 or CP>1 (non-FSDP) the code asserts, it does not deadlock.torchrun instead of uv run python -m torch.distributed.run. Bare torchrun may dispatch through a python interpreter that does not see venv packages, depending on how the venv is set up.