| name | KernelWiki |
| description | Use when the user asks about optimizing NVIDIA Blackwell (SM100, B200) or Hopper (SM90, H100) GPU kernels — tcgen05/TMEM/CLC/NVFP4/2-SM cooperative, warp specialization, FlashAttention-4, DeepGEMM, FlashMLA, MoE, grouped GEMM, CuTe-DSL/PTX/Triton on Blackwell, or wants concrete PR references from CUTLASS/SGLang/vLLM/FlashInfer/PyTorch. Do NOT use for generic CUDA Q&A that is not Blackwell/Hopper-specific, host-side framework integration, or distributed systems (DeepEP/EPLB/DualPipe). |
| argument-hint | [natural-language-question] | [--tag foo --type kernel] | [page-id] |
| allowed-tools | Bash Read Grep Glob |
KernelWiki — Blackwell & Hopper Kernel Optimization Wiki
Query a structured, cross-referenced knowledge base of GPU kernel optimization for NVIDIA Blackwell (SM100) and Hopper (SM90). The repository update date is recorded in README.md; run python3 scripts/repo_status.py for current corpus counts.
When To Use This Skill
Trigger this skill when the user asks about:
- Blackwell/SM100 kernel programming — tcgen05.mma, TMEM, CLC, 2-SM cooperative, NVFP4, FP8/FP4 block scaling, PDL/GDC
- Kernel implementations — FlashAttention-4, DeepGEMM, FlashMLA, NSA, GatedDeltaNet, NVFP4 GEMM/GEMV, fused MoE, gated dual GEMM
- Performance patterns — low SM utilization, memory-bound, register pressure, compute-bound, tail effects, pipeline stalls
- DSLs for Blackwell — CuTe DSL, CUDA C++ with PTX inline, Triton on Blackwell
- Hopper → Blackwell migration — wgmma → tcgen05, register → TMEM accumulators
- PR references — "how did vLLM/SGLang/FlashInfer/CUTLASS/PyTorch implement X for SM100?"
- Competition solutions — GPU Mode NVFP4 hackathon, FlashInfer MLSys 2026 submissions
Do NOT use this skill for:
- Generic CUDA questions unrelated to Blackwell/Hopper tensor cores
- Host-side framework integration (model loading, request routing, scheduling policy)
- Distributed systems topics — DeepEP, EPLB, DualPipe are out of scope
How To Query
All commands below run from the skill directory (the clone root — the directory this SKILL.md lives in). The scripts auto-resolve the wiki root; no environment variable required.
Path 1: Unified search (preferred for natural language)
python3 scripts/query.py "how to fuse gate-up dual GEMM on Blackwell"
python3 scripts/query.py --tag nvfp4 --type kernel
python3 scripts/query.py --repo cutlass --limit 20
python3 scripts/query.py --symptom tail-effect --compact
Filters: --type, --tag, --repo, --language, --architecture,
--symptom, --confidence, --limit, --compact, --paths-only. --tag
and --architecture accept aliases — --tag UMMA matches tcgen05,
--architecture B200 matches sm100, etc.
Path 2: Fetch a specific page by id or path
python3 scripts/get_page.py kernel-flash-attention-4
python3 scripts/get_page.py pr-cutlass-2472
python3 scripts/get_page.py kernel-flash-attention-4 --follow-sources
python3 scripts/get_page.py kernel-flash-attention-4 --body-only
Path 3: Regex text search across wiki bodies and PR pages
python3 scripts/grep_wiki.py "tcgen05\\.fence"
python3 scripts/grep_wiki.py "2-CTA backward" --only wiki
python3 scripts/grep_wiki.py "nvfp4" "block_scale" --any
Path 4: Pre-built cross-reference indices
Auto-generated under queries/:
queries/by-problem.md — symptom → pattern page → candidate techniques
queries/by-technique.md — 15 techniques with architectures, confidence, reproducibility, source count
queries/by-hardware-feature.md — tcgen05/tmem/clc/tma/nvfp4/etc. → related wiki + PR pages
queries/by-kernel-type.md — gemm/attention/moe/mla/gated-delta-net → pages
queries/by-language.md — cute-dsl/cuda-cpp/ptx/triton → guide page + related kernels/sources
queries/by-repo.md — PR pages grouped by source repository
Path 5: Primer, schema, examples
Companion docs under references/:
references/primer.md — topic map: hardware features, techniques, symptoms, canonical page IDs. Read this first when the question is broad.
references/schema.md — condensed frontmatter schema, confidence rules, reproducibility ladder, controlled vocabulary, canonical aliases.
references/examples.md — 10 worked query patterns mapping user questions → command sequences → synthesis.
Output Pattern
When answering from this KB:
- Cite specific pages with paths (e.g.,
wiki/kernels/flash-attention-4.md) and IDs (kernel-flash-attention-4).
- Follow
sources: fields to trace claims back to PRs/blogs/docs.
- Respect confidence levels —
verified > source-reported > inferred > experimental. Call out when a claim is experimental or inferred.
- Include code snippets from wiki pages when they exist — technique/kernel/language pages are guaranteed
snippet-reproducibility (validator-enforced).
- Report performance claims with all six fields —
gpu, dtype, shape, metric, value, source_id.
Knowledge Base Contents
- Source PR pages, synthesized wiki pages, blog/doc/contest summaries, candidate ledgers, query indices, and artifact bundles.
- Verbatim/extracted/derived asset bundles in
artifacts/ (PR diffs, kernel files, blog code) — pinned to upstream SHAs via PROVENANCE.yaml
- Auto-generated query indices in
queries/
- Controlled vocabulary (80+ tags) in
data/tags.yaml, alias map in data/aliases.yaml
- Hybrid version-claim registry — per-page
version_sensitive: <id> pointers + data/version-claims.yaml central registry, validated for bidirectional consistency
- Status script
scripts/repo_status.py — current corpus counts
- Validator
scripts/validate.py — schema, link, artifact, and ledger checks
- Blackwell-first — SM90 pages only appear when they carry explicit
blackwell_relevance
To refresh the corpus: run scripts/refresh_candidate_ledger.py, regenerate PR pages and query indices, then validate.
Quality Guarantees
- Every
verified page has official-doc + upstream-code evidence
- Every technique/kernel/language page has a compilable snippet
- Every PR page has
inclusion_reason and status: merged
- All Hopper-inclusive pages have explicit
blackwell_relevance