spark-environment-setup
Set up a working ML training/inference environment on NVIDIA DGX Spark (GB10, aarch64, CUDA 13). Use when installing PyTorch/Unsloth/TRL/vLLM on DGX Spark, hitting libcudart or wheel-ABI errors on aarch64, or choosing between NGC containers and bare pip installs.
How do I install this agent skill?
npx skills add https://github.com/wshobson/agents --skill spark-environment-setupIs this agent skill safe to install?
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This skill provides technical instructions for configuring machine learning environments on NVIDIA DGX Spark hardware. It outlines best practices for resolving driver and library compatibility issues, specifically recommending the use of official NVIDIA container registries and verified PyTorch wheel repositories. The provided setup commands and references are standard for ML development and originate from reputable, well-known sources.
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What does this agent skill do?
Spark Environment Setup
DGX Spark ships a GB10 Grace Blackwell chip: aarch64 CPU, SM121 GPU, 128GB unified memory, CUDA 13. This is a narrower and younger platform than a standard x86 CUDA 12 box, so package selection and ABI matching matter more than usual — the wheel ecosystem for aarch64 + CUDA 13 is still filling in.
When to Use This Skill
- Setting up a fresh Spark box for training or inference.
- Hitting an import error mentioning
libcudart, a missing symbol, or a wheel that "installed fine but won't load." - A framework install (PyTorch, Unsloth, TRL, vLLM, xformers) fails, hangs, or silently falls back to CPU.
- Deciding whether to use an NGC container or bare pip.
- Restoring a working setup after an OS reinstall or a base-image update, needing to re-verify from scratch.
Each of these accepts the same general fix: match the container/wheel combination to CUDA 13 and SM121, don't fight the ABI.
Container-First Rule
Quick decision, before the detail below:
- Standard training/inference work → NGC PyTorch container.
- Unsloth-centric fine-tuning → Unsloth container (it ships the pinned Triton/xformers/transformers combination already validated for that path).
- Neither fits (custom system package, local IDE interpreter) → bare pip, following the exact sequence further down.
Default to a container. Use nvcr.io/nvidia/pytorch:25.09-py3
as the base for general work — the newest tag confirmed working
on this hardware; pull a newer blessed tag if locally available
rather than hard-blocking on 25.11-py3. NGC's tag is dated, so
running it directly is fine:
docker run --runtime=nvidia --gpus all -it --rm \
nvcr.io/nvidia/pytorch:25.09-py3
unsloth/unsloth:dgxspark-latest is a moving tag by
contrast — resolve and pin its digest before running it for
anything reproducible; the bare tag is a discovery step only,
not the default invocation. Full pull-inspect-pin sequence and
flag rationale/volume mounts for finetuning/ run dirs:
references/container-workflow.md. Treat bare pip as the exception.
The reason for the container-first stance is pinning, not convenience. Triton, xformers, and transformers versions interact narrowly with GB10's SM121 target and CUDA 13; a container locks all of them together against a combination already validated on this hardware. Bare pip leaves that resolution to you, one broken import at a time.
When bare pip is warranted, follow the NVIDIA playbook's install sequence verbatim and in order:
pip install "transformers==5.13.1" "peft==0.19.1" "hf_transfer==0.1.9" "datasets==4.3.0" "trl==1.8.0"
pip install --no-deps "unsloth==2026.7.2" "unsloth_zoo==2026.7.2" "bitsandbytes==0.49.2"
pip install -U "torchao==0.17.0"
The second command's --no-deps flag is not optional —
letting pip re-resolve Unsloth's dependency tree on aarch64 is
a common way to pull in an incompatible torch or triton build.
The third line is not optional either: the NGC base image's
bundled torchao is too old for current peft's LoRA-attach
path (ImportError: ... torchao ... only versions above 0.16.0 are supported) — a hard blocker, not a warning. Every == pin
above is load-bearing, taken from the dated known-good version
matrix in references/stack-matrix.md (its Last verified date
governs staleness) — an unpinned install resolves current PyPI
versions well outside what this Unsloth release supports.
Pull a fresh tag when a new blessed release is announced.
Rebuild locally from one of the two bases only when a project
needs an extra system package layered in — not to "upgrade" a
component the image already pins. Details on both paths:
references/container-workflow.md.
One more preflight: official DGX Spark playbooks have shipped
broken before. Check recent issues on
github.com/NVIDIA/dgx-spark-playbooks (and the other
resources in references/stack-matrix.md) before trusting a
recipe verbatim for a long run.
The ABI Rule
The single most common failure on Spark is a CUDA 12/13 ABI
mismatch: a wheel built against libcudart.so.12 loaded on a
system that only has libcudart.so.13. The install usually
succeeds; the failure surfaces later as a missing-symbol error
or a segfault that doesn't obviously point at CUDA.
Fix: pull wheels from download.pytorch.org/whl/cu130 (the
cu130-tagged aarch64 builds), or use one of the containers
above, which already carry a matched build. Before chasing a
stack trace that mentions a CUDA symbol, check which CUDA tag
the installed wheel was built against:
python3 -c "import torch; print(torch.version.cuda)"
If that output doesn't start with 13, the ABI mismatch is the
first thing to fix. NGC container builds (e.g.
nvcr.io/nvidia/pytorch:25.09-py3) build torch internally
against CUDA 13 with no +cu130 wheel tag — pip show torch
won't say cu130 there, and that absence alone is not a failure.
Typical symptoms:
ImportError: undefined symbolreferencing a CUDA runtime function.- A segfault on the first
.cuda()call, no useful traceback. - A wheel that installs cleanly, then fails at import time — pip's resolver doesn't check CUDA ABI, only version constraints.
- Two "identical" environments behaving differently — usually one has a cu130 wheel, the other a cu121/cu124 leftover.
The fix is the same regardless of symptom: match the wheel's CUDA tag to the system, or use a container that already does.
Component Quick Table
Condensed status for the components most likely to come up.
Full table with wheel URLs, build flags, the sm_121 vs sm_121a
distinction, and the dated known-good version matrix:
references/stack-matrix.md.
| Component | Status |
|---|---|
| PyTorch | ✅ official cu130 aarch64 wheels |
| bitsandbytes | ✅ works out of the box |
| Triton | ✅ needs the TRITON_PTXAS_PATH parameter set |
| flash-attn | ❌ skip pip build; NGC bundles a working one — see spark-training-gotchas G2 |
| xformers | source build only (TORCH_CUDA_ARCH_LIST=12.1) |
| vLLM | nightly wheels only |
| TransformerEngine / NVFP4 train | container-only |
Everything else — Unsloth, Axolotl, TRL, PEFT — installs cleanly through the container-first path above. LLaMA-Factory and NeMo are fragile on Spark; check upstream issues first.
Verification Commands
Confirm the environment can actually see the GPU before running anything expensive:
import torch
print(torch.cuda.is_available(), torch.version.cuda)
This call returns two values; the exact output format is one
line, <bool> <cuda-version>:
True 13.0
If it prints False instead, don't jump straight to a wheel
reinstall — ABI mismatch is one cause among several:
| Hypothesis | Quick check |
|---|---|
| Runtime/flags | nvidia-smi fails in-container too |
| Device visibility | echo $CUDA_VISIBLE_DEVICES |
| Permissions | ls -l /dev/nvidia* |
| CUDA init state | wedged process; retry fresh shell/container |
| ABI mismatch (usual culprit) | torch.version.cuda not 13.x |
Check nvidia-smi first — if it doesn't show the GPU, it's one
of the first three, not ABI. Reinstall a wheel only once ABI is
confirmed. Per-hypothesis detail: references/stack-matrix.md.
Run right after the container starts, before installing
project-specific packages.
One more check: if Triton kernel compilation fails once
training starts, set
TRITON_PTXAS_PATH=/usr/local/cuda/bin/ptxas and retry — see
references/stack-matrix.md for the full workaround list.
Next Steps
A verified environment is only the starting point. See also:
spark-training-gotchas for failure preflights before a
training run, and spark-memory-thermal-ops for unified-memory
OOMs and thermal throttling during long ones.
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-environment-setup">View spark-environment-setup on skillZs</a>