// Convert single-node scripts to multi-node Slurm sbatch jobs and debug common multi-node failures. Covers srun-native vs uv run torch.distributed approaches, container setup, NCCL timeouts, OOM sizing for MoE models, and interactive allocation.
Guide for adding support for new LLM or VLM models in Megatron-Bridge. Covers bridge, provider, recipe, tests, docs, and examples.
Validate and use packed sequences and long-context training in Megatron-Bridge, distinguishing offline packed SFT for LLMs from in-batch packing for VLMs, and applying the right CP constraints.
Operational guide for enabling hierarchical context parallelism in Megatron-Bridge, including config knobs, code anchors, pitfalls, and verification.
Operational guide for choosing and combining parallelism strategies in Megatron Bridge, including sizing rules, hardware topology mapping, and combined parallelism configuration.
Resiliency features in Megatron Bridge including fault tolerance, straggler detection, in-process restart, preemption, and re-run state machine.
External NeMo-RL end-to-end validation workflow for Megatron-Bridge model/provider changes, including downstream compatibility checks, external RL lifecycle behavior, Megatron policy setup, HF import/export, checkpoint/resume, non-colocated vLLM refit, delta weight transfer, optional LoRA/generation variants, and questions such as "does this model work in NeMo-RL", "run NeMo-RL e2e", or "external RL loop validation". Covers running NeMo-RL Megatron policy jobs from a Bridge checkout, choosing GRPO/SFT/checkpoint/non-colocated refit variants, setting PYTHONPATH so NeMo-RL imports the local Bridge tree, and reporting pass/fail evidence.
| name | multi-node-slurm |
| description | Convert single-node scripts to multi-node Slurm sbatch jobs and debug common multi-node failures. Covers srun-native vs uv run torch.distributed approaches, container setup, NCCL timeouts, OOM sizing for MoE models, and interactive allocation. |
| when_to_use | Writing or converting Slurm sbatch scripts, scaling to multiple nodes, debugging NCCL/launch failures, or investigating a commit that caused multi-node training failures; 'run on multiple nodes', 'sbatch script', 'NCCL timeout', 'multi-node OOM'. |
Convert single-node uv run python -m torch.distributed.run commands into multi-node Slurm sbatch scripts with Enroot container support, and debug common multi-node failures.
| Approach | ntasks-per-node | Process spawning | Best for |
|---|---|---|---|
| srun-native (preferred) | 8 | Slurm spawns 8 tasks/node | Conversion, inference, Bridge scripts |
| uv run torch.distributed (legacy) | 1 | uv run python -m torch.distributed.run spawns 8 procs/node | MLM pretrain_gpt.py |
Prefer srun-native — simpler, avoids shell escaping issues with TRAIN_CMD. Megatron Bridge auto-derives RANK, WORLD_SIZE, LOCAL_RANK, MASTER_ADDR, MASTER_PORT from SLURM env vars (SLURM_PROCID, SLURM_NTASKS, SLURM_LOCALID, SLURM_NODELIST) via common_utils.py helpers called during initialize.py distributed init, so you never need to set them manually.
CONTAINER_IMAGE="<PATH_TO_YOUR_CONTAINER>.sqsh"
CONTAINER_MOUNTS="<SHARED_FS>:<SHARED_FS>,<PATH_TO_MEGATRON_BRIDGE>:/opt/Megatron-Bridge,<PATH_TO_DATA>:/opt/data"
WORKDIR="/opt/Megatron-Bridge"
DATA_PATH="<PATH_TO_PREPROCESSED_DATA>/dclm_01_01_text_document"
export GH_TOKEN=<YOUR_GITHUB_TOKEN>
export HF_TOKEN=<YOUR_HF_TOKEN>
export HF_HOME=<SHARED_FS>/HF_HOME
export UV_CACHE_DIR="<SHARED_FS>/uv_cache"
export NEMO_HOME="<SHARED_FS>/cache/nemo"
Important: NEMO_HOME must point to a shared filesystem (e.g. Lustre) for multi-node SFT/PEFT jobs.
The default (/root/.cache/nemo) is container-local and not shared across nodes.
Without this, packed-sequence data files prepared on node 0 are invisible to other
nodes, causing TypeError: 'NoneType' object is not an iterator.
<SHARED_FS>/logs/<job_name>_<suffix>
Slurm spawns all processes directly. No torch.distributed.run, no TRAIN_CMD escaping.
#SBATCH --job-name=<model>-<task>
#SBATCH --nodes=<NNODES>
#SBATCH --ntasks-per-node=8 # Slurm spawns 8 tasks per node
#SBATCH --gpus-per-node=8
#SBATCH --time=00:30:00
#SBATCH --account=<YOUR_ACCOUNT>
#SBATCH --partition=batch
#SBATCH --output=<SHARED_FS>/logs/<job_name>_%j.log
#SBATCH --exclusive
Two-phase srun: first a single-process srun to populate the uv cache, then the full multi-node srun.
# Env exports at sbatch level (before srun)
export TORCH_NCCL_AVOID_RECORD_STREAMS=1
export NCCL_NVLS_ENABLE=0
# Phase 1: Single-process uv sync to build/populate the shared cache
srun --mpi=pmix -N 1 --ntasks=1 \
--container-image="$CONTAINER_IMAGE" \
--container-mounts="$CONTAINER_MOUNTS" \
--no-container-mount-home \
bash -c "cd $WORKDIR && uv sync"
# Phase 2: Full multi-node run (uv sync is a fast no-op since cache is warm)
srun --mpi=pmix \
--container-image="$CONTAINER_IMAGE" \
--container-mounts="$CONTAINER_MOUNTS" \
--no-container-mount-home \
bash -c "cd $WORKDIR && uv sync && uv run --no-sync python <script.py> <args>"
uv sync once on a single node/process, building all wheels into the shared cache on Lustreuv sync is a fast no-op (everything is cached) — safe to run on all ranks without sleep guardsinitialize.py + common_utils.py auto-set RANK, WORLD_SIZE, LOCAL_RANK, MASTER_ADDR, MASTER_PORT from SLURM env varsHF_TOKEN, HF_HOME, UV_CACHE_DIR exported at sbatch level are inherited by srun tasksexamples/models/glm/glm_45v/slurm_sft.sh, examples/models/minimax/minimax_m2/slurm_conversion.shUse when the script requires torch.distributed.run (e.g., MLM pretrain_gpt.py) or when Bridge's initialize.py is not in the call path.
#SBATCH --job-name=<model>-<framework>
#SBATCH --nodes=<NNODES>
#SBATCH --ntasks-per-node=1 # ALWAYS 1 — torchrun handles per-node spawning
#SBATCH --gpus-per-node=8
#SBATCH --time=00:30:00
#SBATCH --account=<YOUR_ACCOUNT>
#SBATCH --partition=batch
#SBATCH --output=<SHARED_FS>/logs/<job_name>_%j.log
#SBATCH --exclusive
Critical: --ntasks-per-node=1, NOT 8. uv run python -m torch.distributed.run --nproc_per_node=8 spawns 8 processes per node. Using ntasks-per-node=8 causes EADDRINUSE port collisions (8 tasks x 8 procs = 64 per node).
Replace single-node:
uv run python -m torch.distributed.run --nproc_per_node=8 \
<script> <args>
With multi-node (inside TRAIN_CMD string):
uv run python -m torch.distributed.run \
--nproc_per_node=8 \
--nnodes=\${SLURM_JOB_NUM_NODES} \
--node_rank=\${SLURM_NODEID} \
<script> <args>
MASTER_ADDR and MASTER_PORT are auto-derived from SLURM env vars by initialize.py / common_utils.py — no need to set them.
Use the same two-phase pattern: first a single-process srun to warm the uv cache, then the full run.
Environment exports go inside TRAIN_CMD (they must be set inside the container):
TRAIN_CMD="
export CUDA_DEVICE_MAX_CONNECTIONS=1 && \
export NVTE_ALLOW_NONDETERMINISTIC_ALGO=1 && \
export PYTORCH_CUDA_ALLOC_CONF=expandable_segments:True && \
export NCCL_NVLS_ENABLE=0 && \
export GH_TOKEN=$GH_TOKEN && \
export HF_TOKEN=$HF_TOKEN && \
export HF_HOME=$HF_HOME && \
export UV_CACHE_DIR=$UV_CACHE_DIR && \
wandb login \$WANDB_API_KEY && \
mkdir -p $LOGDIR && \
cd $WORKDIR && \
uv sync && \
<training command here>
"
# Phase 1: Single-process uv sync to build/populate the shared cache
srun --mpi=pmix -N 1 --ntasks=1 \
--container-image="$CONTAINER_IMAGE" \
--container-mounts="$CONTAINER_MOUNTS" \
--no-container-mount-home \
bash -c "cd $WORKDIR && uv sync"
# Phase 2: Full multi-node run (uv sync in TRAIN_CMD is a fast no-op)
srun --mpi=pmix --no-kill \
--container-image="$CONTAINER_IMAGE" \
--container-mounts="$CONTAINER_MOUNTS" \
--no-container-mount-home \
bash -c "$TRAIN_CMD" 2>&1 | tee "$LOGDIR/<prefix>_${SLURM_JOB_ID}.log"
echo "======================================"
echo "Done. Losses:"
echo "======================================"
grep -E "iteration\s+" "$LOGDIR/<prefix>_${SLURM_JOB_ID}.log" | grep -iE "lm loss|reduced_train_loss" | head -25
salloc + srun)For ad-hoc testing (inference, conversion debugging), always follow these 3 steps:
salloc --account <YOUR_ACCOUNT> -N 1 \
-J <YOUR_ACCOUNT>-debug \
-p interactive --gpus-per-node=8 -t 240
srun --mpi=pmix --no-kill \
--container-image $CONTAINER_IMAGE \
--container-mounts $CONTAINER_MOUNTS \
--account <YOUR_ACCOUNT> -N 1 \
-J <YOUR_ACCOUNT>-debug \
--no-container-mount-home --gpus-per-node=8 \
-p interactive --pty bash
export GH_TOKEN=<YOUR_GITHUB_TOKEN>
wandb login <YOUR_WANDB_KEY>
export HF_TOKEN=<YOUR_HF_TOKEN>
export HF_HOME=<SHARED_FS>/HF_HOME
export UV_CACHE_DIR="<SHARED_FS>/uv_cache"
export NEMO_HOME="<SHARED_FS>/cache/nemo"
uv sync
Then run commands with uv run (uses the synced virtualenv):
uv run python -m torch.distributed.run --nproc_per_node=8 \
examples/conversion/hf_to_megatron_generate_text.py \
--hf_model_path <org>/<model> --prompt "What is AI?" --max_new_tokens 50 --ep 8
Pitfalls with interactive allocation:
| Error | Cause | Fix |
|---|---|---|
Cannot find GPU specification | Missing --gpus-per-node | Always include --gpus-per-node=8 in both salloc and srun |
invalid partition specified: pool0 | Wrong partition name | Use interactive for interactive, batch for sbatch. Check: sinfo --summarize |
Invalid account or account/partition combination | Partition not available for account | Check combos: sacctmgr -nP show assoc where user=$USER format=account,partition |
Unable to create step for job... Requested node configuration is not available | -w <node> conflicts with allocation | Remove -w flag — HF cache is on shared filesystem, accessible from any node |
uv: command not found inside container | Container doesn't have uv pre-installed | Use a container with uv pre-installed, or pip install uv |
No space left on device during uv or pip | Container's /root/.cache/ is full | Redirect: export UV_CACHE_DIR=<SHARED_FS>/uv_cache |
ModuleNotFoundError: No module named 'megatron.core.activations' | Container's pre-installed megatron-core conflicts with local 3rdparty/Megatron-LM | Install local: pip install -e 3rdparty/Megatron-LM --no-deps --no-build-isolation |
Check the log for these patterns (in order):
# 1. Find the actual error (filter noise)
grep -a 'Error\|OOM\|CUDA out of memory\|FAILED\|Killed' job.log \
| grep -v 'UserWarning\|AllocatorConfig\|transformer_engine\|frame\|srun: error'
# 2. Check which rank crashed first
grep -a 'Failures:' -A 20 job.log | head -25
# 3. Check for NCCL timeout
grep -a 'ncclUniqueId\|timeout\|crash on rank 0' job.log | head -5
When a multi-node job fails:
num_experts / EP fits in GPU memory with headroomsalloc -N 2 -p interactive to iterate faster than sbatch queuedist.barrier() — "crash on rank 0"Symptom: All ranks on node 2+ show:
[rank8] is setting up NCCL communicator and retrieving ncclUniqueId from [0]
... wait timeout after 600000ms
This may indicate a possible application crash on rank 0
Root causes (check in order):
| Cause | How to verify | Fix |
|---|---|---|
save_artifacts hangs on rank 0 | Error is in save_hf_weights → dist.barrier() | Increase timeout: init_process_group("nccl", timeout=timedelta(minutes=60)) |
ImportError in custom model code | grep ImportError job.log | Catch ImportError in save_artifacts (see below) |
| Rank 0 OOM during export | grep 'OutOfMemory' job.log | Increase EP or nodes |
| Network issue between nodes | Error only on cross-node ranks | Check sinfo, try different nodes |
The save_artifacts problem: When trust_remote_code=True, rank 0 runs save_artifacts() (downloads tokenizer, config, custom modeling code) while all other ranks skip directly to dist.barrier(). If save_artifacts is slow or crashes, other ranks timeout.
Fix for ImportError in save_artifacts (hf_pretrained/base.py):
# Change:
except OSError:
pass
# To:
except (OSError, ImportError):
pass
Symptom: torch.OutOfMemoryError: CUDA out of memory during model loading or forward pass.
Key insight: TP does NOT reduce expert memory. Only EP splits experts across GPUs.
Sizing formula:
experts_per_gpu = num_experts / EP
expert_memory_gb ≈ experts_per_gpu * expert_params * 2 / 1e9 (bf16)
total_per_gpu ≈ expert_memory_gb + attention_memory_gb + kv_cache_gb
MiniMax-M2 example (256 experts, ~230GB fp8 → ~460GB bf16):
| Config | Nodes | GPUs | Experts/GPU | Result |
|---|---|---|---|---|
| TP=2, EP=4 | 1 | 8 | 64 | OOM (too many experts) |
| TP=2, EP=8 | 2 | 16 | 32 | Works for roundtrip (weight-only), OOM for inference |
| TP=1, EP=16 | 2 | 16 | 16 | Works for inference |
| TP=2, EP=32 | 8 | 64 | 8 | Comfortable for training |
Rules of thumb:
ModuleNotFoundError: No module named 'megatron.core.tensor_parallel'Cause: Container's pre-installed megatron-core conflicts with local 3rdparty/Megatron-LM.
Fix: Add uv sync before running:
CMD="if [ \"\$SLURM_LOCALID\" -eq 0 ]; then uv sync; else sleep 10; fi && "
CMD="${CMD}uv run --no-sync python <script> <args>"
Symptom: Roundtrip completes but shows ❌ for all expert weights and raises ValueError: Weight mismatch detected.
Cause: Original HF weights are FP8, Megatron stores in BF16. Exported weights are BF16. Comparison against original FP8 exceeds atol=1e-1.
This is expected for FP8 models. The conversion is correct; the comparison tolerance is insufficient for the FP8→BF16 precision gap.
WORLD_SIZE Not Set with srunSymptom: Script exits with "must be launched with torchrun".
Cause: Scripts check os.environ.get("WORLD_SIZE") which torchrun sets but srun doesn't.
Fix: Also check SLURM_NTASKS:
if os.environ.get("WORLD_SIZE") is None and os.environ.get("SLURM_NTASKS") is None:
sys.exit(1)
Bridge's common_utils.py helpers (called by initialize.py) populate env vars from SLURM:
if "RANK" not in os.environ:
os.environ["RANK"] = str(get_rank_safe()) # uses SLURM_PROCID
if "WORLD_SIZE" not in os.environ:
os.environ["WORLD_SIZE"] = str(get_world_size_safe()) # uses SLURM_NTASKS
if "MASTER_ADDR" not in os.environ:
os.environ["MASTER_ADDR"] = get_master_addr_safe() # parses SLURM_NODELIST
if "MASTER_PORT" not in os.environ:
os.environ["MASTER_PORT"] = str(get_master_port_safe()) # derives from SLURM_JOB_ID
Two-phase srun for uv sync: Run a single-process srun first to warm the cache, then the full multi-node srun. The second uv sync is a fast no-op since everything is already cached on the shared filesystem.
--no-container-mount-home is an srun flag, NOT an #SBATCH directive.
Escaping inside TRAIN_CMD: Since TRAIN_CMD is a double-quoted string, escape inner $ for Slurm variables that must expand at runtime (not sbatch time):
\${SLURM_PROCID}, \${SLURM_JOB_NUM_NODES}, \${SLURM_NODEID}$GH_TOKEN, $LOGDIR, $WORKDIR expand at sbatch time — no escaping needed.Bridge rm -rf nemo_experiments: Add before training to avoid stale checkpoint auto-resume.
MLM needs PYTHONPATH: For pretrain_gpt.py scripts, add inside TRAIN_CMD:
PYTHONPATH=${WORKDIR}/3rdparty/Megatron-LM:\${PYTHONPATH:-} \
Node count heuristic: Total GPUs = NNODES * 8. Must satisfy: TP * PP * EP * DP >= total_GPUs where DP = total_GPUs / (TP * PP * EP).
NEMO_HOME on shared filesystem for multi-node SFT: The default nemo cache (/root/.cache/nemo)
is container-local. Multi-node SFT with packed sequences prepares .npy files on one node
that are invisible to others. Set export NEMO_HOME=<SHARED_FS>/cache/nemo so packed data
is shared. Without this, ranks on other nodes fail with TypeError: 'NoneType' object is not an iterator.
#!/bin/bash
# ==============================================================================
# <MODEL_NAME> <pretrain|sft> — <Framework: MLM | Megatron Bridge>
#
# Default: TP<X> PP<Y> EP<Z>, NNODES=<N> (<N*8> GPUs), MBS=<M>, GBS=<G>
#
# Usage:
# sbatch <script_name>.sh
# ==============================================================================
#SBATCH --job-name=<job-name>
#SBATCH --nodes=<NNODES>
#SBATCH --ntasks-per-node=1
#SBATCH --gpus-per-node=8
#SBATCH --time=00:30:00
#SBATCH --account=<YOUR_ACCOUNT>
#SBATCH --partition=batch
#SBATCH --output=<SHARED_FS>/logs/<job_name>_%j.log
#SBATCH --exclusive
# ── Container ────────────────────────────────────────────────────────────
CONTAINER_IMAGE="<PATH_TO_YOUR_CONTAINER>.sqsh"
CONTAINER_MOUNTS="<SHARED_FS>:<SHARED_FS>,<PATH_TO_MEGATRON_BRIDGE>:/opt/Megatron-Bridge,<PATH_TO_DATA>:/opt/data"
# ── Paths ────────────────────────────────────────────────────────────────
WORKDIR="/opt/Megatron-Bridge"
LOGDIR="<SHARED_FS>/logs/<logdir_name>"
DATA_PATH="<PATH_TO_PREPROCESSED_DATA>/dclm_01_01_text_document"
# ── Parallelism ──────────────────────────────────────────────────────────
TP=1; PP=1; EP=1
# ── Training ─────────────────────────────────────────────────────────────
MBS=1; GBS=256
SEQ=4096
SEED=1234
TRAIN_ITERS=20
# ── Tokens / Caches ──────────────────────────────────────────────────────
export GH_TOKEN=<YOUR_GITHUB_TOKEN>
export HF_TOKEN=<YOUR_HF_TOKEN>
export HF_HOME=<SHARED_FS>/HF_HOME
export UV_CACHE_DIR="<SHARED_FS>/uv_cache"
export NEMO_HOME="<SHARED_FS>/cache/nemo"
# ── Build training command ───────────────────────────────────────────────
TRAIN_CMD="
export CUDA_DEVICE_MAX_CONNECTIONS=1 && \
export NVTE_ALLOW_NONDETERMINISTIC_ALGO=1 && \
export PYTORCH_CUDA_ALLOC_CONF=expandable_segments:True && \
export NCCL_NVLS_ENABLE=0 && \
export GH_TOKEN=$GH_TOKEN && \
export HF_TOKEN=$HF_TOKEN && \
export HF_HOME=$HF_HOME && \
export UV_CACHE_DIR=$UV_CACHE_DIR && \
export NEMO_HOME=$NEMO_HOME && \
wandb login \$WANDB_API_KEY && \
mkdir -p $LOGDIR && \
cd $WORKDIR && \
uv sync && \
<TRAINING_COMMAND_HERE>
"
echo \"======================================\"
echo \"<MODEL_NAME> <Framework> Pretrain\"
echo \"Job: \$SLURM_JOB_ID | Nodes: \$SLURM_JOB_NUM_NODES\"
echo \"TP=\$TP PP=\$PP EP=\$EP MBS=\$MBS GBS=\$GBS\"
echo \"======================================\"
# Phase 1: Single-process uv sync to build/populate the shared cache
srun --mpi=pmix -N 1 --ntasks=1 \
--container-image="$CONTAINER_IMAGE" \
--container-mounts="$CONTAINER_MOUNTS" \
--no-container-mount-home \
bash -c "cd $WORKDIR && uv sync"
# Phase 2: Full multi-node run (uv sync in TRAIN_CMD is a fast no-op)
srun --mpi=pmix --no-kill \
--container-image="$CONTAINER_IMAGE" \
--container-mounts="$CONTAINER_MOUNTS" \
--no-container-mount-home \
bash -c "$TRAIN_CMD" 2>&1 | tee "$LOGDIR/<prefix>_${SLURM_JOB_ID}.log"
echo ""
echo "======================================"
echo "Done. Losses:"
echo "======================================"
grep -E "iteration\s+" "$LOGDIR/<prefix>_${SLURM_JOB_ID}.log" | grep -iE "lm loss|reduced_train_loss" | head -25
rm -rf nemo_experiments && \
uv run python -m torch.distributed.run \
--nproc_per_node=8 \
--nnodes=\${SLURM_JOB_NUM_NODES} \
--node_rank=\${SLURM_NODEID} \
scripts/training/run_recipe.py \
--recipe <recipe_name> \
model.tensor_model_parallel_size=$TP \
model.pipeline_model_parallel_size=$PP \
...overrides...
PYTHONPATH=${WORKDIR}/3rdparty/Megatron-LM:\${PYTHONPATH:-} \
uv run python -m torch.distributed.run \
--nproc_per_node=8 \
--nnodes=\${SLURM_JOB_NUM_NODES} \
--node_rank=\${SLURM_NODEID} \
3rdparty/Megatron-LM/pretrain_gpt.py \
--tensor-model-parallel-size $TP \
--pipeline-model-parallel-size $PP \
...args...