spark-memory-thermal-ops
Manage unified memory and thermals during long-running ML jobs on NVIDIA DGX Spark. Use when planning memory headroom for a training run on GB10, when a job OOMs on unified memory, or when monitoring temperature and power during multi-hour training.
How do I install this agent skill?
npx skills add https://github.com/wshobson/agents --skill spark-memory-thermal-opsIs this agent skill safe to install?
- Gen Agent Trust Hubpass
This skill is a utility for managing memory and thermal performance on NVIDIA DGX Spark hardware. It provides a background sampling script and detailed instructions for diagnosing memory pressure. No malicious behavior or security risks were detected.
- Socketpass
No alerts
- Snykwarn
Risk: MEDIUM · 1 issue
What does this agent skill do?
Spark Memory & Thermal Ops
DGX Spark's GB10 chip has one 128GB unified
memory (UMA) pool shared by CPU and GPU, and a
sustained power ceiling well below its rated
figure. Both break discrete-GPU assumptions:
headroom isn't what nvidia-smi reports, and a
run that starts fast will slow down mid-job
with nothing misconfigured. This skill covers
planning memory headroom, working an actual
OOM, and watching thermals across a long job.
For launch-time failure modes (ABI mismatches,
flash-attn, playbook breakage), see
spark-training-gotchas — this skill assumes
the job starts.
Common Issues Quick Reference
| Situation | Do this |
|---|---|
| Planning headroom before launch | Budget against free -g, not nvidia-smi — see UMA Memory Model |
| Job OOMs on unified memory | Work the OOM Ladder in order: flush, then batch/pack, then method downgrade |
| Throughput drops mid-run | Check the power/temp log before assuming a config bug — see Thermal Monitoring |
| Trainer + inference server both wanted | Run one at a time — see Concurrent Workloads |
When to Use This Skill
- Sizing a training run against the 128GB pool before launch — will this model, method, and batch/pack combination fit.
- A run OOMs mid-load or mid-step and the remediation order matters — what to try first, second, third.
- Watching temperature and power during a multi-hour job, deciding whether a slowdown is thermal throttling or something else.
- Planning to run a trainer alongside an inference server (vLLM, Ollama) on the same box.
UMA Memory Model
Spark has no separate GPU VRAM — the GPU and CPU share one 128GB pool. Two consequences:
-
nvidia-smiandcudaMemGetInfounderreport pressure — or report nothing at all. Both report CUDA-allocator-visible memory, not the pool's actual state — a box can show headroom innvidia-smiand still OOM, because page-cache and mmap'd pages the allocator doesn't see consume the same pool. On some driver/setups, the memory query returns[N/A], [N/A]outright instead of a number — a script grepping for a numeric value there gets nothing, not a misleading undercount (seespark-training-gotchasgotcha G3). -
Model load is a transient peak, not the steady state. Loading safetensors weights mmaps the file, then copies into CUDA tensors — for a window during load, both the mmap'd pages and the CUDA copy count against the pool at once. A model that fits while training can still OOM during load if headroom was sized for the post-load footprint instead of this doubled transient.
Plan and diagnose with free -g, not
nvidia-smi:
free -g | awk 'NR==2 {print "free:", $4, "GB"}'
Rule of thumb: take that free figure, subtract a
few GB for OS/driver overhead, and budget against
the result — not the 128GB spec number.
The worksheet in references/uma-accounting.md
accepts parameter count, dtype, and method as
input, and returns a memory estimate to compare
against known anchors.
Planning Sequence
Before launch, work through these in order:
- Read
free -g; subtract OS/driver overhead for the budget. - Estimate weights + optimizer + gradients +
activations from
references/uma-accounting.md. - Compare against the closest anchor (70B QLoRA, 27B LoRA, 9B full FT), not the estimate alone.
- If the estimate is close to the budget, start with shorter packing or a smaller batch — cheaper than hitting the OOM Ladder mid-run.
Example: Sizing a 70B QLoRA Run
A sanity check of the worksheet formula against the ≈40GB anchor:
params = 70e9
weights_gb = params * 0.5 / 1e9 # NF4, step 1
adapter_gb = 0.5 # step 5, negligible
total_gb = weights_gb + adapter_gb # + activations
print(f"{total_gb:.0f}GB before activations")
Weights alone land near the ≈40GB anchor — a plan estimating far above that for the same model class is a signal to recheck dtype and method.
The OOM Ladder
When a job OOMs on unified memory, work this ladder in order. Each step is more disruptive than the last — don't skip ahead: reducing batch size is never step 1.
-
Flush the buffer cache. Page cache from a previous run or a large dataset read often accounts for GB of the "missing" headroom. This costs nothing but a rerun and doesn't touch the job's configuration:
sync; echo 3 > /proc/sys/vm/drop_cachesNeeds root; a between-run reset, not a mid-training step. See
spark-training-gotchas(gotcha G3) for the full diagnostic behind this step. -
Reduce batch size or packing length. Only after a flush fails to free enough headroom, cut batch size or packing length — the first step that changes what the run does. Prefer packing length first; it drives activation footprint more directly at long context.
-
Downgrade the method: bf16 LoRA before QLoRA. If flushing and shrinking batch/pack still OOM, drop the method a tier — bf16 LoRA is next, not the reverse. QLoRA's bitsandbytes dequantization buffers are transient CUDA-side allocations that can OOM before an equivalent bf16 LoRA run would, even though QLoRA's steady-state footprint is smaller. A QLoRA OOM is not proof the model doesn't fit.
Fall back further (smaller model, multi-Spark) only after all three steps and the job still won't fit.
Thermal Monitoring
Multi-hour runs push into Spark's sustained power ceiling, well under the rated figure — expected platform behavior, not a symptom to explain away:
-
Sample temperature and power alongside the training logs, not after a slowdown is noticed — every 30-60 seconds correlates a throughput drop with a thermal event. Keep the CSV output format
assets/thermal-sample.shwrites, so timestamps line up against the log:bash assets/thermal-sample.sh 30 thermal.log -
A sustained ~100W power draw is the platform cap, not a configuration bug. Don't re-tune batch size or precision to "fix" a plateau that's the box behaving normally under load. If temperature climbs while power stays flat under the rated 240W figure, that's the signature to recognize.
-
Log throttle events explicitly instead of letting a run silently slow down unrecorded. A run whose per-step time doubles two hours in should show that in the log, correlated against the thermal sample at that timestamp. Full throttling diagnostics:
spark-training-gotchas(gotcha G4).
Concurrent Workloads
Because the 128GB pool is global, eviction happens without either process's logs showing an OOM:
-
The one-heavy-job rule applies to uncapped or near-capacity workloads — an uncapped trainer and inference server (vLLM, Ollama) compete for the same pool. A small, capped workload doesn't: a <4GB LoRA fine-tune coexists fine alongside vLLM capped at
gpu-memory-utilization<=0.5— check the other process's cap, not just its presence, before stopping it. -
Inference servers evict trainer pages silently under uncapped/near-capacity contention, and vice versa — neither logs an error, so a slow run or lost KV cache is a contention symptom to check for. Stop unrelated uncapped servers before a long or full-pool run.
Check for GPU-resident processes first:
ps aux | grep -E 'vllm|ollama|trl|axolotl' | grep -v grep
This procedure complements spark-training-gotchas
(gotchas G3, G4, G6) — that skill covers launch-time
failures; this one, the running job.
Memory math worksheets:
references/uma-accounting.md.
How can the creator link this skill?
Add the canonical catalog link to the repository README so users can inspect current installs and available audits. The publishing guide covers the complete discovery path.
<a href="https://skillzs.dev/skills/wshobson/agents/spark-memory-thermal-ops">View spark-memory-thermal-ops on skillZs</a>