| name | nemo-mbridge-perf-memory-tuning |
| description | Techniques for reducing peak GPU memory in Megatron Bridge — expandable segments, PEFT + SP input re-gather, parallelism resizing, activation recompute, CPU offloading constraints, and common OOM fixes. |
| license | Apache-2.0 |
| when_to_use | GPU OOM errors, reducing peak memory, reducing LoRA or PEFT activation memory with sequence parallelism, or tracing an OOM regression to a specific commit or config change; 'out of memory', 'OOM', 'memory fragmentation', 'expandable_segments', 'reduce GPU memory', 'LoRA memory', 'PEFT memory', 'sequence_parallel_input_regather', 'PYTORCH_CUDA_ALLOC_CONF'. |
Memory Tuning
Stable docs: @docs/parallelisms.md
Card: @skills/nemo-mbridge-perf-memory-tuning/card.yaml
What It Is
GPU OOM failures during training often stem from memory fragmentation rather
than raw capacity. PyTorch's default CUDA allocator can leave unusable gaps
between allocations. The single most effective fix is:
export PYTORCH_CUDA_ALLOC_CONF=expandable_segments:True
This tells PyTorch to use expandable (non-fixed-size) memory segments, which
dramatically reduces fragmentation and often eliminates borderline OOM without
any model or parallelism changes.
Beyond fragmentation, actual peak memory is determined by:
- Parameter + optimizer state memory — controlled by TP, PP, DP sharding
(distributed optimizer, FSDP)
- Activation memory — controlled by activation recompute, sequence length,
micro-batch size, and PEFT-specific retention of gathered inputs
- Temporary / workspace memory — CUDA kernels, NCCL buffers, CUDA graphs
For configuration planning, use the Bridge theoretical estimator before launching
large jobs:
from megatron.bridge.training.utils.theoretical_memory_utils import estimate_training_memory
estimate = estimate_training_memory(cfg, num_microbatches=num_microbatches)
The estimator reports the most-loaded GPU shard and separates dense/embedding,
routed MoE expert, and activation components. It does not include allocator
fragmentation, CUDA/NCCL workspace, CUDA graph buffers, token imbalance, or
dispatcher workspace, so validate final configs with runtime memory metrics.
Quick Decision
When a training run OOMs or is close to the memory limit:
- Set
PYTORCH_CUDA_ALLOC_CONF=expandable_segments:True first. This fixes
fragmentation-induced OOM with zero performance cost. Most Slurm launch
templates already include it.
- For LoRA with sequence parallelism, enable input re-gather
(
LoRA(sequence_parallel_input_regather=True)). This avoids retaining the
full gathered LoRA-A input in every eligible layer; it has no effect when SP
is disabled.
- Add selective activation recompute (
recompute_modules=[core_attn]) if
not already enabled. See @skills/nemo-mbridge-perf-activation-recompute/SKILL.md.
- Avoid increasing TP as a memory fix — doubling TP dramatically increases
NVLink all-reduce volume and often kills throughput (-28% on Llama3 70B).
- Avoid increasing PP at the cost of DP — halving DP doubles gradient
accumulation steps and hurts throughput (~6%).
- Consider
mlp recompute if still OOM. Saves ~3 GB but costs ~16% GPU
utilization on large dense models (Llama3 70B).
- CPU offloading is blocked when PP > 1.
Enablement
Expandable segments (recommended first step)
Set in the job's environment before launching:
export PYTORCH_CUDA_ALLOC_CONF=expandable_segments:True
In Slurm scripts this is typically placed alongside other env vars:
export CUDA_DEVICE_MAX_CONNECTIONS=1
export NVTE_ALLOW_NONDETERMINISTIC_ALGO=1
export PYTORCH_CUDA_ALLOC_CONF=expandable_segments:True
No model config changes needed. Zero throughput cost.
Parallelism resizing
If the model genuinely does not fit (not fragmentation), adjust parallelism:
| Strategy | Memory effect | Throughput cost | Notes |
|---|
| Increase PP (keeping DP) | Fewer layers per stage | Moderate (~6% if DP halved) | Only if GPU count allows |
| Increase TP | Fewer params per GPU | Severe (-28% on 70B) | Last resort |
| Distributed optimizer | Shards optimizer state across DP ranks | ~1-2% | Recommended for large models |
| FSDP | Shards params + grads + optimizer | Varies | See @skills/nemo-mbridge-perf-megatron-fsdp/SKILL.md |
Activation recompute
See @skills/nemo-mbridge-perf-activation-recompute/SKILL.md for full details.
PEFT + sequence-parallel input re-gather
For LoRA training with sequence parallelism, eligible column-parallel
linear_qkv and linear_fc1 adapters consume a gathered LayerNorm output.
Because LoRA-A is trainable, the default path retains that full gathered input
until backward for the LoRA-A weight gradient.
Enable input re-gather when constructing the PEFT config:
from megatron.bridge.peft.lora import LoRA
cfg.peft = LoRA(
sequence_parallel_input_regather=True,
)
With this option, forward still materializes the full input temporarily for the
LoRA-A GEMM, but MCore autograd retains only its sequence-local shard. Backward
asynchronously gathers the full input again, overlaps the collective with
dgrad when possible, computes the LoRA-A weight gradient, and then reuses the
temporary communication buffer.
This is a memory-for-communication tradeoff, not conventional activation
checkpointing: no LayerNorm, attention, MLP, or LoRA GEMM is rerun. Some
throughput degradation is expected, and the benefit grows with the amount of
eligible LoRA-A activation retained. The option has no effect when sequence
parallelism is disabled.
CPU offloading
cfg.model.cpu_offloading = True
Incompatible with PP > 1. Only usable when pipeline_model_parallel_size = 1.
A Note on VPP
Virtual pipeline parallelism (VPP) is primarily a throughput optimization
that reduces pipeline bubble overhead by interleaving smaller model chunks. Its
effect on peak memory is minimal — changing VPP does not meaningfully change
the total activation, parameter, or optimizer memory on a GPU.
In earlier experiments we incorrectly attributed an OOM fix to VPP tuning
(VPP 5→10). The actual fix was PYTORCH_CUDA_ALLOC_CONF=expandable_segments:True
which eliminated memory fragmentation. The VPP=10 run actually used slightly
more peak memory (60.2 GB vs 58.8 GB) but did not OOM because expandable
segments prevented fragmentation.
VPP should be tuned for pipeline bubble reduction (see @docs/parallelisms.md),
not as a memory fix.
Compatibility and Constraints
expandable_segments:True is incompatible with --use-nccl-ub (NCCL
user-buffer registration). See Megatron-FSDP docs.
- When using CUDA graphs with
expandable_segments:True, set
NCCL_GRAPH_REGISTER=0 (required on pre-Blackwell GPUs, enforced by MCore
CudaGraphManager).
- CPU offloading requires
pipeline_model_parallel_size = 1.
- Distributed optimizer requires
use_distributed_optimizer = True in the
optimizer config.
sequence_parallel_input_regather applies only to eligible non-expert
column-parallel LoRA-A projections. Row-parallel adapters, expert adapters,
TP=1, CUDA graphs, CPU activation offload, and overlapping full-layer or
selective MLP activation recompute fall back to the existing path.
Measured Results
Llama3 70B SFT on 32x H100 80GB, FP8 (Current Scaling):
- Baseline: TP=4, PP=4, VPP=5, DP=2, MBS=1, GBS=32, seq_len=4096
- Golden GPU utilization: 709.93 TFLOP/s/GPU
- Regression threshold: 5%
Strategy comparison: parallelism changes for memory reduction
| Experiment | TP | PP | VPP | DP | TFLOP/s/GPU | vs Golden | Peak Mem (GB) | Result |
|---|
| Baseline | 4 | 4 | 5 | 2 | ~704 | -0.8% | 58.8 | OOM (fragmentation) |
| More PP | 4 | 8 | 5 | 1 | 668.0 | -5.9% | 53.2 | Borderline perf |
| More TP | 8 | 4 | 5 | 1 | 508.7 | -28.4% | 50.2 | Severe regression |
| Baseline + expandable_segments | 4 | 4 | 5 | 2 | ~704 | -0.8% | ~59 | Passed |
Key takeaways:
expandable_segments:True is the winner. The baseline OOM was caused by
memory fragmentation, not insufficient capacity. Setting this env var
eliminated the OOM with zero throughput cost and no parallelism changes.
- PP=8 works for memory but loses DP (2→1), meaning 32 gradient accumulation
steps per batch, which hurts throughput by ~6%.
- TP=8 is catastrophic (-28%) because doubling TP increases all-reduce
communication volume proportionally across NVLink, and DP=1 means no
micro-batch overlap.
CPU offloading: blocked
| Experiment | offload_layers | Result |
|---|
| Exp 4 | 2 | Incompatible (PP > 1) |
| Exp 5 | 4 | Incompatible (PP > 1) |
| Exp 6 | 6 | Incompatible (PP > 1) |
ValueError: Currently there is no support for Pipeline parallelism with CPU offloading. This approach is blocked for any model using PP > 1.
Activation recompute: expensive alternative
Selective activation recompute with mlp saved ~3 GB peak memory but cost
~16% GPU utilization on this workload. See
@skills/nemo-mbridge-perf-activation-recompute/SKILL.md for full results.
LoRA + SP input re-gather
Real-checkpoint H100 training with SQuAD showed lower peak memory in all tested
configurations, with workload-dependent throughput cost:
| Model/config | Baseline peak | Input re-gather peak | Memory saved | Throughput change |
|---|
| Qwen3-8B, TP2, seq 8192 | 47.545 GB | 42.814 GB | 4.731 GB (10.0%) | -6.74% |
| Qwen3-30B-A3B, TP4/EP4 | 29.890 GB | 28.321 GB | 1.569 GB (5.2%) | -2.89% |
| GPT-OSS-120B, TP2/EP8 | 52.185 GB | 51.371 GB | 0.814 GB (1.6%) | -0.34% |
All runs had finite losses with zero skipped or NaN iterations. Two-rank BF16
and FP32 checks matched the baseline for outputs, input gradients, LoRA-A and
LoRA-B gradients, and two-microbatch fused main_grad accumulation.
Code Anchors
LoRA sequence-parallel input re-gather
src/megatron/bridge/peft/lora.py
LoRA.sequence_parallel_input_regather
src/megatron/bridge/peft/utils.py
ParallelLinearAdapter._sequence_parallel_input_regather_eligibility()
ParallelLinearAdapter.forward()
CPU offloading PP incompatibility (MCore)
if self.cpu_offloading and self.pipeline_model_parallel_size > 1:
raise ValueError(
"Currently there is no support for Pipeline parallelism with CPU offloading"
)
VPP config and layer divisibility validation (MCore)
if pipeline_parallel_size and self.virtual_pipeline_model_parallel_size is not None:
num_layers_per_middle_pipeline_rank = num_layers // pipeline_parallel_size
if (
not num_layers_per_middle_pipeline_rank
% self.virtual_pipeline_model_parallel_size
== 0
):
raise ValueError(
f"number of layers on each middle pipeline rank:"
f"{num_layers_per_middle_pipeline_rank} must be divisible by virtual"
f"pipeline parallel degree {self.virtual_pipeline_model_parallel_size}"
)
Parallelism docs on interleaved pipeline schedule
To minimize the pipeline bubble, the computation on each GPU can be divided into multiple subsets of layers (referred to as model chunks), rather than a single contiguous block. Enable this by setting `virtual_pipeline_model_parallel_size`:
model_config = GPTModelProvider(
pipeline_model_parallel_size=4,
virtual_pipeline_model_parallel_size=2, # 2 model chunks per pipeline stage
# ... other model parameters
)
Failure Diagnosis
| Symptom | Cause | Confirm | Fix |
|---|
| OOM on a single rank despite headroom on others | Memory fragmentation | check if expandable_segments:True is set | set PYTORCH_CUDA_ALLOC_CONF=expandable_segments:True |
OOM with expandable_segments already set | Genuine capacity limit | check nvidia-smi for param/optimizer memory | increase PP, use distributed optimizer, or add recompute |
| Estimated memory exceeds GPU capacity before launch | model state or activations genuinely too large | run estimate_training_memory and inspect the largest component | adjust PP/TP/CP/EP, distributed optimizer, or recompute before launching |
| LoRA + SP retains unexpectedly high activation memory | full gathered LoRA-A inputs are retained until backward | check whether cfg.peft.sequence_parallel_input_regather is enabled and the target is eligible | set LoRA(sequence_parallel_input_regather=True); verify fallback constraints |
ValueError: PP + CPU offloading | using cpu_offloading with PP > 1 | check PP config | disable CPU offloading or set PP=1 |
RuntimeError with --use-nccl-ub + expandable segments | NCCL UB incompatible with expandable allocator | check env vars | remove expandable_segments:True or disable --use-nccl-ub |
Known Limitations
- CPU offloading is blocked when PP > 1
- Parallelism resizing (TP/PP) often has significant throughput costs
- The theoretical estimator is formula-based and does not replace runtime
profiling or CUDA memory reports
- LoRA input re-gather does not cover row-parallel or expert adapters and may
have negligible benefit when few eligible LoRA-A activations dominate memory
Verification
Quick check that expandable_segments:True is active:
import os
assert "expandable_segments:True" in os.environ.get("PYTORCH_CUDA_ALLOC_CONF", "")
For Slurm jobs, verify the env var is exported before the training command
in the launch script.
For LoRA + SP input re-gather, run the focused configuration tests and the real
two-rank MCore backward-parity test:
uv run python -m pytest \
tests/unit_tests/peft/test_utils.py -k "sequence_parallel_input_regather" \
tests/unit_tests/peft/test_lora.py -k "sequence_parallel_input_regather"
uv run python -m torch.distributed.run --nproc_per_node=2 -m pytest \
tests/unit_tests/peft/test_lora_sp_input_regather_distributed.py