| name | profile-model |
| description | Profile a model running on MAX to find where it spends time and whether the GPU is saturated. Use when the user asks to "profile my model," "where is my model spending time," "why is inference slow," "is my GPU being utilized," "how much GPU am I using," "get a kernel breakdown," "capture an nsys/rocprof/ncu trace of max serve," or wants to measure MAX inference performance. Works for any model MAX can run — built-in architectures and custom ones loaded with --custom-architectures — from a pip or pixi install (max generate, max serve, or a Python script) on NVIDIA or AMD GPUs. Decide cheapest-first: a GPU utilization check, then a kernel breakdown, then a single-kernel deep dive only when one kernel dominates.
|
| compatibility | Requires a pip/pixi MAX install and a GPU (NVIDIA or AMD). The kernel-breakdown and deep-dive steps also need the vendor profiler (nsys/ncu for NVIDIA, rocprofv3 for AMD). |
| argument-hint | [model-path] [serve/generate flags] |
Profile a model on MAX
This skill answers three questions about any model you can run on MAX, whether
it's a built-in architecture or a custom one loaded with
--custom-architectures:
- Is my GPU actually being used? (utilization, memory, clocks)
- Where does my model spend the most time? (which kernels / phases)
- Why is this kernel slow? (occupancy, stalls, roofline)
It works from a pip or pixi install of MAX, driving the public max CLI or
a Python script.
How to decide what to run
Each question needs a deeper, more expensive capture than the last. Work from
the cheapest check toward the most invasive, and let each result decide whether
going deeper is even worth it — don't capture more than the question needs.
- Start with the utilization check. If the GPU is idle or lightly loaded
while the workload runs, the bottleneck is host-side (CPU, transfers, small
batch) — stop and report that. A kernel trace won't tell you anything a
busy GPU wouldn't.
- If the GPU is busy, capture a kernel breakdown. This is the common case
and usually the final answer: it shows which kernels dominate GPU time.
- Only if one kernel dominates and you need to know why, do a single-kernel
deep dive on that one kernel. Skip this unless a breakdown has already
pointed at a specific kernel — it replays the kernel many times and is slow.
| What you're answering | Tool | Cost |
|---|
| Is the GPU busy? | max.profiler.gpu (pure Python, NVIDIA + AMD) | seconds, no extra installs |
| Where does time go? | max ... --profile, or nsys (NVIDIA) / rocprofv3 (AMD) | a couple of profiled runs |
| Why is one kernel slow? | Nsight Compute (ncu), NVIDIA only | one slow capture per kernel |
Read the reference for the step you're on rather than loading all of them:
Models loaded with --custom-architectures
Profiling itself works the same for a custom architecture as for a built-in
one. What differs is loading: a custom architecture has extra prerequisites and
failure modes — import compatibility with your installed MAX version,
PYTHONPATH traps, architecture-name collisions, base models with no chat
template, and a max serve limitation for custom embeddings models. Those stop
the model from loading before any profiling can run. If you're profiling a
model passed via --custom-architectures, read
references/custom-architectures.md
first.
Reading the result (what the kernel mix tells you)
Profiling answers two things: is the GPU saturated (the utilization check) and
where does time go (the kernel breakdown). Map what you see back to a
diagnosis:
- Decode dominated by
gemv_split_k_* GEMVs, with *_mha_* attention and
rms_norm below — this is the normal, healthy shape for a dense LLM token
generation (decode is memory-bound GEMV). Nothing to chase.
- Sparse-MoE decode dominated by grouped / block-scaled matmul plus routing
kernels — the per-expert grouped matmul (
*grouped* / block_scaled_*
matmul) is the dominant kernel instead of a dense GEMM, alongside top-k
routing (topk_*, moe_create_indices) and expert gather/scatter; on
multi-GPU, EP dispatch/combine collectives appear too. This is the healthy
shape for a Mixture-of-Experts model — routing and gather overhead is
expected, and only worth chasing if it rivals the matmul itself.
- Low-bit weights (FP8 / FP4 / NVFP4) add quant-prep kernels — alongside the
matmul you'll see dynamic activation-quantization and scale-layout kernels
(
*quantize*, *block_scales*) and block-scaled matmul variants rather than
plain gemv/gemm. Time spent in quant/dequant prep is normal for a low-bit
model; flag it only if it dwarfs the matmul it feeds. Kernel prefixes are
GPU-arch-specific (sm100_* on Blackwell, different on Hopper / MI) — match
on the kernel family, not the exact name.
- A custom architecture not hitting the expected fused kernel (for example
attention showing as generic
elementwise/matmul instead of a *_mha_*
kernel, or norms/RoPE unfused) — a wiring signal: the graph may not be built
the way you think, even if logits pass. Worth a look during bring-up.
- Pathologically low decode tok/s + an outsized prefill-shaped kernel mix
repeating every step — classic O(n²) re-prefill (no/broken KV cache). This
is a correctness-adjacent bug, not just slowness.
- Low
gpu_usage_percent while a workload runs — host-bound, launch/sync
overhead, or batch too small; the GPU isn't the bottleneck.
- Throttle reasons present — the GPU is clock-limited; numbers aren't
representative until you address thermal/power.
The durable algorithm
Tooling and MAX packaging change often; this shape is the part worth
preserving. Whichever capture you run, follow it:
- Detect the environment before committing to a tool. Run
nvidia-smi or
rocm-smi to learn the vendor — the kernel-breakdown and deep-dive tools
differ by vendor. Confirm the profiler is installed (which nsys /
which rocprofv3 / which ncu); if it's missing, tell the user the exact
install line (see the reference) rather than failing midway.
- Confirm before any long-lived run. Profiling
max serve warms a
compile cache (cold compile can take minutes), launches a server, and runs a
benchmark. Before doing that, show the user the model, the flags, and the
planned commands, and wait for confirmation. A one-shot
max generate --profile on a tiny model is cheap enough to skip this.
- Warm caches first, profile second. The first run of a model pays
one-time compile and weight-load costs that drown out the real kernel time.
Do an unprofiled warm-up run, then the profiled run, so the capture
reflects steady-state inference — not compilation.
- Keep the capture window small. A 10-second window at concurrency 1 is
enough to see the kernel mix. Long captures produce huge trace files that
are slow to open and no more informative.
- Fail fast. After launching a server, check within a few seconds that the
process is alive and the log has no early error (model not found, OOM, bad
flag) before you start polling for
/health. Don't wait out a full timeout
on a server that already died.
- Verify the artifact, then report. Confirm the output file exists and is
non-trivial in size before claiming success. Report the artifact path, how
to open it, and the headline numbers (top kernels, or peak GPU utilization).
- Clean up only what you started. Kill the server / benchmark process
group you launched. Avoid broad
pkill -f max on a shared box — you may
stop someone else's run.
Nightly vs stable
Profiling features land in nightly before stable, so this skill targets the
nightly modular build. Install it with pixi:
pixi init quickstart -c https://conda.modular.com/max-nightly/ -c conda-forge
cd quickstart && pixi add modular
pixi run max --version
The utilization API (GPUDiagContext, BackgroundRecorder) ships in the
conda modular package, so install via pixi or conda rather than a plain
pip install modular wheel, which may not expose max.profiler.gpu. If a
command below 404s or an import fails, confirm you're on a recent nightly
build.
Install notes
- MAX itself: a project with the nightly
modular package installed via pixi
(see Nightly vs stable above). All
max CLI commands below assume you can run pixi run max ... in that
project.
nsys and ncu ship with the CUDA Toolkit. If which nsys fails but CUDA is
present, export PATH=/usr/local/cuda/bin:$PATH. Otherwise install Nsight
Systems / Nsight Compute from NVIDIA, or
sudo apt-get install nsight-systems.
rocprofv3 ships with ROCm (/opt/rocm/bin). Add it to PATH if needed.
- The utilization API needs no extra tooling beyond
modular — it talks to
NVML / ROCm SMI directly through max.profiler.gpu.
Fast paths
The lowest-friction commands, each expanded in its reference file:
- "Is my GPU being used?" → run
scripts/gpu_snapshot.py alongside a short
benchmark. Pure Python, works on NVIDIA and AMD.
- "Give me a kernel breakdown, fast." →
pixi run max generate --model <m> --prompt "hello" --num-warmups 1 --profile. Prints a ranked top-N GPU-kernel
table
and writes a .nsys-rep (NVIDIA). Falls back to a CPU summary without a GPU.
- "Profile my serving benchmark." → the serving-endpoint flow with
MODULAR_ENABLE_PROFILING=detailed + nsys launch / rocprofv3.