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diffusion-kernel
Index for SGLang Diffusion kernel development skills.
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Index for SGLang Diffusion kernel development skills.
Install with Codex or Claude Copy this prompt, paste it into Codex, Claude, or another assistant, and let it review the skill page and install it for you.
Based on SOC occupation classification
| name | diffusion-kernel |
| description | Index for SGLang Diffusion kernel development skills. |
If the user explicitly states a preference for Triton or CUDA, follow that preference when implementing and optimizing kernels (even if the other option could work). Do not “pick for convenience”.
python/sglang/multimodal_gen/.claude/skills/diffusion-kernel/
├── SKILL.md
├── add-triton-kernel.md
├── add-cuda-kernel.md
├── diffusion-benchmark-and-profile.md
├── nsight-profiler.md
├── use-efficient-diffusion-kernels.md
├── references/
│ ├── kernel-templates.md # Copy-paste CUDA kernel templates (sglang JIT style)
│ ├── troubleshooting.md # Build/perf/integration issues & fixes
│ ├── h100-optimization-guide.md # H100 (sm_90) deep dive
│ ├── a100-optimization-guide.md # A100 (sm_80) deep dive
│ └── t4-optimization-guide.md # T4 (sm_75, FP16 only) deep dive
└── scripts/
├── bench_diffusion_rmsnorm.py # RMSNorm micro-benchmark vs PyTorch
└── bench_diffusion_denoise.py # End-to-end denoise benchmark (sglang generate)
Before running any benchmark, profiler, or kernel-validation command, use
scripts/diffusion_skill_env.py to derive the repo root from sglang.__file__,
verify the repo is writable, export FLASHINFER_DISABLE_VERSION_CHECK=1, and
choose idle GPU(s) before starting perf work.
scripts/diffusion_skill_env.py
Shared preflight helper for all diffusion skill commands. Use it to print the repo root, create benchmark/profile output directories, and choose idle GPUs before running sglang generate, torch profiler, nsys, or ncu.
Step-by-step guide for adding a new Triton kernel to SGLang Diffusion's jit_kernel/diffusion/triton/ module, including authoring, autotune, torch.compile compatibility, integration, and tests. Use for fused elementwise ops, norm variants, RoPE variants, or when NPU/CPU fallback is needed.
Step-by-step guide for adding a JIT CUDA kernel. CUDA source goes in jit_kernel/csrc/diffusion/<op>.cuh; Python wrapper at jit_kernel/diffusion/<op>.py. Uses SGLang's JIT compilation system (load_jit, cache_once) and internal abstractions (TensorMatcher, device::AlignedVector, host::LaunchKernel, device::warp::reduce_sum). Use for bandwidth-bound reductions (RMSNorm, LayerNorm) or ops needing fine-grained vectorization and shared memory control. Adapted from HuggingFace kernels cuda-kernels skill.
use-efficient-diffusion-kernels.md
Practical guidance for using SGLang Diffusion fused kernels and fast CUDA paths, including constraints, fallbacks, and where the fused ops are wired into the runtime.
diffusion-benchmark-and-profile.md
Denoise-stage benchmark and profiling guide for SGLang Diffusion models. Three profiling levels: Level 1 (torch.profiler — kernel time ranking), Level 2 (nsys — category breakdown), Level 3 (ncu — per-kernel bandwidth/occupancy/roofline analysis). ncu is critical for kernel optimization — always use it when writing or tuning custom kernels to verify hardware saturation.
Advanced profiling skill for NVIDIA Nsight Systems / Nsight Compute: collecting traces, reading reports, and interpreting kernel-level performance metrics.
Loaded by add-cuda-kernel.md. Adapted from HuggingFace kernels cuda-kernels skill.
sglang.__file__, write-access probe, benchmark/profile output directories, idle GPU selectionsglang generate, baseline vs custom kernels comparison tableGuide for achieving optimal performance with SGLang-Diffusion. Covers all perf-related CLI flags, env vars, and best practices for lossless and lossy speedup.
Step-by-step guide for adding a new diffusion model to SGLang. Covers the recommended Hybrid Monolithic pipeline pattern (BeforeDenoisingStage), as well as when to use the Modular Composition Style. Includes pipeline config, model components, registration, and testing.