| name | design |
| description | Design complex features by decomposing them into vertical slices, generating code slice-by-slice with per-slice verifier dispatch and post-finalization independent code review, and producing a design artifact (architecture decisions, slice breakdown, file map) in .rpiv/artifacts/designs/. The design feeds the plan or blueprint skill. Use for complex multi-component features touching 6+ files across multiple layers, when the user wants a feature designed before implementation. Requires a research artifact or a solutions artifact (from explore). Prefer design over plan or blueprint when the focus is architecture and decomposition rather than phased execution steps. |
| argument-hint | [research artifact path] |
| shell-timeout | 10 |
| disable-model-invocation | true |
| contract | {"produces":{"kind":"produces","meta":{"artifactKind":"design"},"data":{"type":"object","properties":{"status":{"enum":["in-progress","in-review","ready"]}}}},"consumes":{"data":{"type":"object","properties":{"status":{"const":"ready"}}},"meta":{"artifactKind":["research","solutions"]}}} |
Design
You are tasked with designing how code will be shaped for a feature or change. This iterative variant decomposes features into vertical slices and generates code slice-by-slice with developer micro-checkpoints between slices. The design artifact feeds directly into plan, which sequences it into phases.
Input
$ARGUMENTS — path to a research artifact (.rpiv/artifacts/research/*.md) or a solutions artifact (.rpiv/artifacts/solutions/*.md).
Metadata
node "${SKILL_DIR}/../_shared/now.mjs"
echo
node "${SKILL_DIR}/../_shared/git-context.mjs"
echo
echo "### recent (read only in case of empty user input)"
echo "recent research:"
node "${SKILL_DIR}/../_shared/list-recent.mjs" .rpiv/artifacts/research 4
echo
echo "recent solutions:"
node "${SKILL_DIR}/../_shared/list-recent.mjs" .rpiv/artifacts/solutions 4
Copy values verbatim — do not reformat the timezone offset.
Flow
- Input → 2. Research → 3. Dimension sweep → 4. Checkpoint → 5. Decompose → 6. Generate slices (code + Success Criteria) → 7. Finalize → 8. Present artifact → 9. Handle follow-ups
The final artifact is plan-compatible: ## Slices boundaries become phase boundaries 1:1, and Success Criteria pass through unchanged. Post-finalization code + coverage review runs inside /skill:plan Step 4.
Steps
Step 1: Input Handling
When this command is invoked:
-
Read research artifact:
Research artifact provided (argument contains a path to a .md file in .rpiv/artifacts/):
- Read the research artifact FULLY using the Read tool WITHOUT limit/offset
- Extract: Summary, Code References, Integration Points, Architecture Insights, Precedents & Lessons, Developer Context, Open Questions
- Read the key source files from Code References into the main context — especially hooks, shared utilities, and integration points the design will depend on. Read them FULLY. This ensures you have complete understanding before proceeding.
- These become starting context — no need to re-discover what exists
- Research Developer Context Q/As = inherited decisions (record in Decisions, never re-ask); Open Questions = starting ambiguity queue, filtered by dimension in Step 3
No arguments provided, branch on the recent research: and recent solutions: listings in the Metadata block:
- Both empty — no upstream artifacts available; tell the user and suggest running
/skill:research (or /skill:explore for option comparison) first.
- Exactly one entry total — confirm with
ask_user_question: "Design from this artifact?" with options "Design from [<source>] <filename> (Recommended)" and "Pick a different path".
- Two or more entries total — present up to 4 most-recent across both listings as
ask_user_question options, each prefixed [research] or [solutions] to flag source class.
-
Read any additional files mentioned — tickets, related designs, existing implementations. Read them FULLY before proceeding.
Step 2: Targeted Research
This is NOT a discovery sweep. Focus on DEPTH (how things work, what patterns to follow) not BREADTH (where things are).
-
Spawn parallel research agents using the Agent tool — all in a single assistant message with multiple Agent calls (concurrent, synchronous). Never run_in_background: its completion can't re-drive a workflow session, so the skill ends its turn before writing the design and the stage fails with no artifact.
- Use codebase-pattern-finder to find existing implementations to model after — the primary template for code shape
- Use codebase-analyzer to understand HOW integration points work in detail
- Use integration-scanner to map the wiring surface — inbound refs, outbound deps, config/DI/event registration
- Use precedent-locator to find similar past changes in git history — what commits introduced comparable features, what broke, and what lessons apply to this design. Only when
commit is available (not no-commit); otherwise skip and note "git history unavailable" in Verification Notes.
Novel work (new libraries, first-time patterns, no existing codebase precedent):
- Add web-search-researcher for external documentation, API references, and community patterns
- Instruct it to return LINKS with findings — include those links in the final design artifact
Agent prompts should focus on (labeled by target agent):
- codebase-pattern-finder: "Find the implementation pattern I should model after for {feature type}"
- codebase-analyzer: "How does {integration point} work in detail"
- integration-scanner: "What connects to {component} — inbound refs, outbound deps, config"
NOT: "Find all files related to X" — that's discovery's job, upstream of this skill.
-
Read all key files identified by agents into the main context — especially the pattern templates you'll model after.
-
Wait for ALL agents to complete before proceeding.
-
Analyze and verify understanding:
- Cross-reference research findings with actual code read in Step 1
- Identify any discrepancies or misunderstandings
- Note assumptions that need verification
- Determine true scope based on codebase reality
Step 3: Identify Ambiguities — Dimension Sweep
Walk Step 2 findings, inherited research Q/As, and carried Open Questions through six architectural dimensions that map 1:1 to the downstream phased plan's section coverage — the sweep guarantees downstream completeness. Add migration as a seventh dimension only if the feature changes persisted schema.
- Data model — types, schemas, entities
- API surface — signatures, exports, routes
- Integration wiring — mount points, DI, events, config
- Scope — in / explicitly deferred
- Verification — tests, assertions, risk-bearing behaviors
- Performance — load paths, caching, N+1 risks
For each dimension, classify findings into three classes:
- simple — one valid option, obvious from codebase, no directional weight. Record in Decisions with
file:line evidence; do not ask.
- directional — obvious fit, but the choice encodes a direction: propagates an existing pattern across new files, picks extend-vs-replace, or spreads a convention the project may be moving off. Queue for the directional confirm (Step 4, one batched ask).
- genuine ambiguity — multiple valid options, conflicting patterns, scope questions, novel choices. Queue for Step 4, one-at-a-time.
Inherited research Q/As land as simple unless directional; Open Questions filter by dimension — architectural survives, implementation-detail defers.
Pre-validate every option before queuing it against research constraints and runtime code behavior. Eliminate or caveat options that contradict Steps 1-2 evidence. Coverage check: every Step 2 file read appears in at least one decision, directional confirm, or ambiguity; every dimension is addressed (silently-resolved valid, skipped-unchecked not).
Step 4: Developer Checkpoint
Use the grounded-questions-one-at-a-time pattern. Use a ❓ Question: prefix so the developer knows their input is needed. Each question must:
- Reference real findings with
file:line evidence
- Present concrete options (not abstract choices)
- Pull a DECISION from the developer, not confirm what you already found
Directional confirms first. Before the one-at-a-time questions, clear every directional finding from Step 3 in a single batched ask_user_question (up to 4 per call). Do not mark the "follow" option Recommended.
Question: "About to follow {pattern X} (file:line, used ×N) across {the N new files} — confirm that's the direction, or moving off it?". Header: "Direction". Options: "Follow {X}" (propagate as-is); "Moving off {X}" (deliberate departure).
Follow records the decision as stated. Moving off promotes the finding to a genuine ambiguity — ask it one-at-a-time below with the alternative in view.
Question patterns by ambiguity type:
- Pattern conflict: "Found 2 patterns for {X}: {pattern A} at
file:line and {pattern B} at file:line. They differ in {specific way}. Which should the new {feature} follow?"
- Missing pattern: "No existing {pattern type} in the codebase. Options: (A) {approach} modeled after {external reference}, (B) {approach} extending {existing code at file:line}. Which fits the project's direction?"
- Scope boundary: "The {research/description} mentions both {feature A} and {feature B}. Should this design cover both, or just {feature A} with {feature B} deferred?"
- Integration choice: "{Feature} can wire into {point A} at
file:line or {point B} at file:line. {Point A} matches the {existing pattern} pattern. Agree, or prefer {point B}?"
- Novel approach: "No existing {X} in the project. Options: (A) {library/pattern} — {evidence/rationale}, (B) {library/pattern} — {evidence/rationale}. Which fits?"
Critical rules:
- Ask ONE question at a time. Wait for the answer before asking the next.
- Lead with the most architecturally significant ambiguity.
- Every answer becomes a FIXED decision — no revisiting unless the developer explicitly asks.
Choosing question format:
-
ask_user_question tool — when your question has 2-4 concrete options from code analysis (pattern conflicts, integration choices, scope boundaries, priority overrides). The user can always pick "Other" for free-text. Example:
Use the ask_user_question tool with the following question: "Found 2 mapping approaches — which should new code follow?". Header: "Pattern". Options: "Manual mapping (Recommended)" (Used in OrderService (src/services/OrderService.ts:45) — 8 occurrences); "AutoMapper" (Used in UserService (src/services/UserService.ts:12) — 2 occurrences).
-
Open-ended (discovery, "what am I missing?", corrections) — still ask_user_question; offer your best 1-2 guesses and let "Other" carry the unpredictable answer.
Batching: When you have 2-4 independent questions (answers don't depend on each other), you MAY batch them in a single ask_user_question call. Keep dependent questions sequential.
Classify each response:
Decision (e.g., "use pattern A", "yes, follow that approach"):
- Record in Developer Context. Fix in Decisions section.
Correction (e.g., "no, there's a third option you missed", "check the events module"):
- Spawn targeted rescan: codebase-analyzer on the new area (max 1-2 agents).
- Merge results. Update ambiguity assessment.
Scope adjustment (e.g., "skip the UI, backend only", "include tests"):
- Record in Developer Context. Adjust scope.
After all ambiguities are resolved, present a brief design summary (under 15 lines):
Design: {feature name}
Approach: {1-2 sentence summary of chosen architecture}
Decisions:
- {Decision 1}: {choice} — modeled after `file:line`
- {Decision 2}: {choice}
- {Decision 3}: {choice}
Scope: {what's in} | Not building: {what's out}
Files: {N} new, {M} modified
Use the ask_user_question tool to confirm before proceeding. Question: "{Summary from design brief above}. Ready to proceed to decomposition?". Header: "Design". Options: "Proceed (Recommended)" (Decompose into vertical slices, then generate code slice-by-slice); "Adjust decisions" (Revisit one or more architectural decisions above); "Change scope" (Add or remove items from the building/not-building lists).
Step 5: Feature Decomposition
After the design summary is confirmed, decompose the feature into vertical slices. Each slice is a self-contained unit: types + implementation + wiring for one concern.
-
Decompose holistically — define ALL slices, dependencies, and ordering before generating any code:
Feature Breakdown: {feature name}
Slice 1: {name} — {what this slice delivers}
Files: path/to/file.ext (NEW), path/to/file.ext (MODIFY)
Depends on: nothing (foundation)
Slice 2: {name} — {what this slice delivers}
Files: path/to/file.ext (NEW), path/to/file.ext (MODIFY)
Depends on: Slice 1
Slice 3: {name} — {what this slice delivers}
Files: path/to/file.ext (NEW)
Depends on: Slice 2
-
Slice properties:
- End-to-end vertical: each slice is a complete cross-section of one concern (types + impl + wiring)
- ~512-1024 tokens per slice (maps to individual file blocks)
- Sequential: each builds on the previous (never parallel)
- Foundation first: types/interfaces always Slice 1
-
Confirm decomposition using the ask_user_question tool. Question: "{N} slices for {feature}. Slice 1: {name} (foundation). Slices 2-N: {brief}. Approve decomposition?". Header: "Slices". Options: "Approve (Recommended)" (Proceed to slice-by-slice code generation); "Adjust slices" (Reorder, merge, or split slices before generating); "Change scope" (Add or remove files from the decomposition).
-
Create skeleton artifact — immediately after decomposition is approved:
- Determine metadata from the Metadata block above: filename
.rpiv/artifacts/designs/<slug>_<topic>.md (use <slug> from line 1 of the Metadata block above); repository: from repo:; branch: / commit: from matching labels; author: ← matching label (fallback: unknown).
- Timestamp: use
<iso> from line 1 of the Metadata block above for date: and last_updated: (copy the offset verbatim).
- Write skeleton using the Write tool with
status: in-progress in frontmatter
- Include all prose sections filled from Steps 1-5: Summary, Requirements, Current State Analysis, Scope, Decisions, Desired End State, File Map, Ordering Constraints, Verification Notes, Performance Considerations, Migration Notes, Pattern References, Developer Context, References
- Architecture section: one
### path/to/file.ext — NEW/MODIFY heading per file from the decomposition, with empty code fences as placeholders
- Design History section: list all slices with
— pending status
- This is the living artifact — all subsequent writes use the Edit tool
Artifact template sections (all required in skeleton):
- Frontmatter: date, author, commit, branch, repository, topic, tags,
status: in-progress, parent, last_updated, last_updated_by
- # Design: {Feature Name}
- ## Summary: 2-3 sentences — what we're building and the chosen architectural approach. Settled decision, not a discussion.
- ## Requirements: Bullet list from ticket, research, or developer input.
- ## Current State Analysis: What exists now, what's missing, key constraints. Include
### Key Discoveries with file:line references, patterns to follow, constraints to work within.
- ## Scope:
### Building — concrete deliverables. ### Not Building — developer-stated exclusions AND likely scope-creep vectors (alternative architectures not chosen, nearby code that looks related but shouldn't be touched).
- ## Decisions:
### per decision. Complex: Ambiguity → Explored (Option A/B with file:line + pro/con) → Decision. Simple: just state decision with evidence.
- ## Architecture:
### per file with NEW/MODIFY label. Empty code fences in skeleton (filled in Step 6.4). NEW files get full implementation. MODIFY files get only modified/added code — no "Current" block.
- ## Slices:
### Slice N: {name} per slice from the decomposition. In skeleton, each subsection contains a **Files**: line listing the slice's file paths AND empty #### Automated Verification: / #### Manual Verification: subsections (filled in Step 6.4 from 6.1's Success Criteria). This section is the contract handed to /skill:plan: slice ≡ phase 1:1, criteria pass through unchanged.
- ## Desired End State: Usage examples showing the feature in use from a consumer's perspective — concrete code, not prose.
- ## File Map:
path/to/file.ext # NEW/MODIFY — purpose per line.
- ## Ordering Constraints: What must come before what. What can run in parallel.
- ## Verification Notes: Carry forward from research — known risks, build/test warnings, precedent lessons. Format as verifiable checks (commands, grep patterns, visual inspection). plan converts these to success criteria.
- ## Performance Considerations: Any performance implications or optimizations.
- ## Migration Notes: If applicable — existing data, schema changes, rollback strategy, backwards compatibility. Empty if not applicable.
- ## Pattern References:
path/to/similar.ext:line-range — what pattern to follow and why.
- ## Developer Context: Record questions exactly as asked during checkpoint, including
file:line evidence. For iterative variant: also record micro-checkpoint interactions from Step 6.3.
- ## Design History: Slice approval/revision log.
- Slice N: {name} — pending/approved as generated/revised: {what changed}. plan ignores this section.
- ## References: Research artifacts, tickets, similar implementations.
Architecture format in skeleton:
- NEW files: heading + empty code fence (filled with full implementation in Step 6.4)
- MODIFY files: heading with
file:line-range + empty code fence (filled with only the modified code in Step 6.4 — no "Current" block, the original is on disk)
Step 6: Generate Slices (Iterative)
Generate code one slice at a time. Each slice sees the fixed code from all previous slices.
For each slice in the decomposition (sequential order):
6.1. Generate slice code and Success Criteria (internal)
Generate complete, copy-pasteable code AND the slice's ### Success Criteria: for every file in this slice — but hold both for the artifact, do NOT present full code to the developer. The developer sees a condensed review in 6.3; the full code and criteria go into the artifact in 6.4.
- New files: complete code — imports, types, implementation, exports. Follow the pattern template from Step 2.
- Modified files: read current file FULLY, generate only the modified/added code scoped to changed sections (no full "Current" block — the original is on disk)
- Test files: complete test suites following project patterns
- Wiring: show where new code hooks into existing code
- Success Criteria: derive
### Success Criteria: from this slice's file changes plus ## Verification Notes entries that map to this slice's scope. Use the same - [ ] format as 6.4 (see template below). Project-baseline checks (npm run check, npm test) go on the terminal slice only. Commands in backticks. Criteria authored here flow through to plan as the phase's Success Criteria — slice ≡ phase, 1:1.
If additional context is needed, spawn a targeted codebase-analyzer agent.
No pseudocode, no TODOs, no placeholders — the code must be copy-pasteable by implement. Success Criteria must be atomic for this slice: no bullets that depend on symbols/files a later slice introduces.
Context grounding (after slice 2): Before generating, re-read the artifact's Architecture section for files this slice touches AND the ## Slices section for slices already locked. The artifact is the source of truth — generate code and criteria that extend what's already there, not what you remember from conversation.
6.2. Verify slice
Mandatory for every slice — no skipping, no shortcuts. Dispatch the slice-verifier agent with:
artifact_path: the Step-5 Write file_path (contains the skeleton plus locked prior slices)
slice_id: Slice N
current_slice_code: inline the just-generated slice verbatim — every ### path/... block under Architecture with its full code fence AND the slice's ### Success Criteria: block (Automated + Manual subsections from 6.1).
target_files: files this slice modifies, plus key files prior slices introduced
The agent emits a 3-row summary (Decisions / Cross-slice / Research). On any VIOLATION, take one of:
- Fix-and-re-dispatch: when the finding is a real gap, fix the slice in-place per the citation and re-dispatch until OK.
- Surface-and-proceed: when the finding is plausibly by-design (e.g. foundation-slice atomicity tension, deferred resolution covered by ordering constraints), include the verbatim VIOLATION row in the 6.3 slice presentation with a one-line by-design rationale. The existing 6.3 approve question is the ratification — no separate prompt.
Never proceed to 6.3 with a VIOLATION absent from the presentation.
6.3. Developer micro-checkpoint
Present a condensed review of the slice — NOT the full generated code. The developer reviews the design shape, not every line. For each file in the slice, show:
- Summary (1-2 sentences): what changed, what pattern used, what it connects to
- Signatures: type/interface definitions, exported function signatures with parameter and return types
- Key code blocks: factory calls, wiring, non-obvious logic — the interesting parts that show the design decision in action
Then, once per slice, a mandatory Fit line (always shown, regardless of the omit list below):
Fit — Reused: {existing helpers/utils/types this slice builds on, file:line}. New surface: {new abstractions/exports introduced}. Convention: {naming/error/logging pattern followed + source file:line}.
If the slice introduces a new abstraction where an existing one would serve, or reuses nothing, say so explicitly.
Omit: boilerplate, import lists, full function bodies, obvious implementations.
MODIFY files: focused diff (- old / + new) with ~3 lines context. Test files: test case names only.
If the developer asks to see full code, show it inline — exception, not default.
Use the ask_user_question tool to confirm. Question: "Slice {N/M}: {slice name} — {files affected}. {1-line summary}. Approve?". Header: "Slice {N}". Options: "Approve (Recommended)" (Lock this slice, write to artifact, proceed to slice {N+1}); "Revise this slice" (Adjust code before proceeding — describe what to change); "Rethink remaining slices" (This slice reveals a design issue — revisit decomposition); "Revisit a decision" (A Step-4 decision is wrong — return to Step 4 for that decision before continuing).
Checkpoint cadence: One slice per checkpoint. Present each slice individually, regardless of slice count.
6.4. Incorporate feedback
Approve: Lock this slice's code AND Success Criteria and Edit the artifact immediately:
-
For each file in this slice, Edit the skeleton artifact to replace the empty code fence under that file's Architecture heading with the full generated code from 6.1
-
If a later slice contributes to a file already filled by an earlier slice: rewrite the entire code fence with the merged result (do not append alongside existing code)
-
After merge, verify within Architecture: no duplicate function definitions, imports deduplicated, exports list complete
-
Write the slice's ## Slices entry: Edit the artifact to add a new ### Slice N: {name} subsection under the top-level ## Slices heading, containing:
### Slice N: {slice name}
**Files**: `path/to/file1.ext`, `path/to/file2.ext`
#### Automated Verification:
- [ ] Type checking passes: `npm run check`
- [ ] Tests pass: `npm test`
- [ ] Grep pattern from Verification Note: `grep -r "newApi" packages/ | wc -l` returns >= 3
#### Manual Verification:
- [ ] New widget renders correctly above the editor
- [ ] Performance acceptable with 1000+ todo items
This section is the contract handed to /skill:plan — slice boundaries become phase boundaries 1:1, and Success Criteria pass through unchanged. The bullets are the same - [ ] shape implement flips to - [x] and validate extracts commands from.
-
Update the Design History section: - Slice N: {name} — approved as generated
Revise: Update code per developer feedback. Re-run verify (6.2). Re-present the same slice (6.3). The artifact is NOT touched — only "Approve" writes to the artifact.
Rethink: Developer spotted a design issue. If a previously approved slice is affected, flag the conflict and offer cascade revision — developer decides whether to reopen (if yes, Edit artifact entry).
Update decomposition (add/remove/reorder remaining slices) and confirm before continuing.
Revisit a decision: Re-run Step 4 for the flagged ambiguity (one question). If decomposition is unaffected, update ## Decisions and resume 6.1. If affected, cascade like Rethink — for each invalidated approved slice, ask reopen vs. annotate Design History, then update remaining slices. Re-run 6.2 before re-presenting 6.3; artifact untouched until approval.
Step 7: Finalize Design Artifact
The artifact was created as a skeleton in Step 5 and filled progressively in Step 6.4. This step verifies completeness and flips status.
-
Verify all Architecture entries are filled: Every file heading from the decomposition must have a non-empty code block. If any are still empty, return to Step 6 — never fill at finalize time (bypasses 6.2/6.3). Empty here = workflow off-rail.
-
Verify all ## Slices entries are filled: Every ### Slice N: {name} subsection must have a **Files**: line AND non-empty #### Automated Verification: + #### Manual Verification: subsections. If any are still empty, return to Step 6 — Success Criteria authored in 6.1 must be written in 6.4 alongside code. Empty here = workflow off-rail (same invariant as empty code fences).
-
Verify cross-slice file merges: For files touched by multiple slices, confirm the Architecture entry contains the final merged code, not just the last slice's contribution.
-
Update frontmatter via Edit: status: in-progress → status: ready. Design owns no post-finalization review — /skill:plan runs the artifact-code-reviewer + artifact-coverage-reviewer pair against the phased plan that inherits this design's ## Slices boundaries 1:1. Leave last_updated / last_updated_by as-is.
-
Verify template completeness: Ensure all sections from the template reference in Step 5 are present and filled. Edit to fix any gaps.
-
Architecture format reminder:
- NEW files:
### path/to/file.ext — NEW + one-line purpose + full implementation code block
- MODIFY files:
### path/to/file.ext:line-range — MODIFY + code block with only the modified/added code (no "Current" block — the original is on disk, implement reads it)
Step 8: Present Design Artifact
Design owns no post-finalization review. Both artifact-code-reviewer and artifact-coverage-reviewer run inside /skill:plan Step 4 against the phased plan that inherits this design's ## Slices boundaries 1:1 — that's where code + Success Criteria + phasing are all visible in one artifact for joint review.
Present the design artifact location to the developer:
Design artifact written to:
`.rpiv/artifacts/designs/{filename}.md`
{N} architectural decisions fixed, {M} new files designed, {K} existing files modified.
{Sl} slices generated, {R} revisions during generation. Success Criteria authored alongside each slice in 6.1 and verified by slice-verifier in 6.2.
Please review and let me know:
- Are the architectural decisions correct?
- Does the code match what you envision?
- Any missing integration points or edge cases?
---
💬 Follow-up: describe the change in chat to append a timestamped Follow-up section to this artifact. Re-run `/skill:design` for a fresh artifact.
**Next step:** `/skill:plan .rpiv/artifacts/designs/{filename}.md` — sequence the design into implementation phases (slice ≡ phase, 1:1) and run the artifact reviewer pair.
> 🆕 Tip: start a fresh session with `/new` first — chained skills work best with a clean context window.
Step 9: Handle Follow-ups
- Edit in-place. Use the Edit tool to update the design artifact directly — sliced design code stays one source of truth.
- Bump frontmatter. Update
last_updated + last_updated_by; set last_updated_note: "Updated <brief description>".
- Sync decisions ↔ code ↔ criteria. If the change affects decisions, update the Decisions section, the Architecture code, AND the relevant
## Slices Success Criteria. Code is source of truth — if they conflict, the code wins, update the prose and criteria.
- Return to checkpoint on new ambiguities. If new ambiguities surface, return to Step 4 (developer checkpoint) before re-generating slices.
- When to re-invoke instead. If the underlying research is now stale or the feature scope changed materially, re-run
/skill:research then /skill:design for a fresh artifact. The previous block's Next step: stays valid for the existing design.
Guidelines
-
Be Architectural: Design shapes code; plans sequence work. Every decision must be grounded in file:line evidence from the actual codebase.
-
Be Interactive: Don't produce the full design in one shot. Resolve ambiguities through the checkpoint first, get buy-in on the approach, THEN decompose and generate slice-by-slice.
-
Be Complete: Code in the Architecture section must be copy-pasteable by implement. No pseudocode, no TODOs, no "implement here" placeholders. If you can't write complete code, an ambiguity wasn't resolved.
-
Be Skeptical: Question vague requirements. If an existing pattern doesn't fit the new feature, say so and propose alternatives. Don't force a pattern where it doesn't belong.
-
Resolve Everything: No unresolved questions in the final artifact. If something is ambiguous, ask during the checkpoint or micro-checkpoint. The design must be complete enough that plan can mechanically decompose it into phases.
-
Present Condensed, Persist Complete: Micro-checkpoints show the developer summaries, signatures, and key code blocks. The artifact always contains full copy-pasteable code. If the developer asks to see full code, show it — but never default to walls of code in checkpoints.
Subagent Usage
| Context | Agents Spawned |
|---|
| Default (research artifact provided) | codebase-pattern-finder, codebase-analyzer, integration-scanner, precedent-locator |
| Novel work (new library/pattern) | + web-search-researcher |
| Step 6.1 mid-generation gap (specific anchor unclear) | targeted codebase-analyzer (max 1) |
| Step 6.2 per-slice verify (mandatory; sees code + Success Criteria) | slice-verifier |
Spawn multiple agents in parallel when they're searching for different things. Each agent runs in isolation — provide complete context in the prompt, including specific directory paths when the feature targets a known module. Don't write detailed prompts about HOW to search — just tell it what you're looking for and where.
Important Notes
- Always chained: This skill requires a research artifact produced by the research skill. There is no standalone design mode.
- File reading: Always read research artifacts and referenced files FULLY (no limit/offset) before spawning agents
- Critical ordering: Follow the numbered steps exactly
- ALWAYS read input files first (Step 1) before spawning agents (Step 2)
- ALWAYS wait for all agents to complete before identifying ambiguities (Step 3)
- ALWAYS resolve all ambiguities (Step 4) before decomposing into slices (Step 5)
- ALWAYS complete holistic decomposition before generating any slice code (Step 6)
- ALWAYS create the skeleton artifact immediately after decomposition approval (Step 5)
- ALWAYS generate Success Criteria in Step 6.1 alongside code; NEVER leave Architecture code fences OR
## Slices Success Criteria empty after their slice is approved — both are written via Edit in Step 6.4 from what 6.1 produced
- NEVER fill empty Architecture content OR empty
## Slices Success Criteria at Step 7 — empty at finalize time = return to Step 6 (preserves the 6.3 micro-checkpoint)
- ALWAYS dispatch slice-verifier at Step 6.2 for every slice before presenting at 6.3; never skip, never batch across slices; slice-verifier sees code AND Success Criteria together
- NEVER silently dismiss a slice-verifier VIOLATION — either fix and re-dispatch, or surface the verbatim finding to the developer at 6.3 for ratification
- Post-finalization code + coverage review runs in
/skill:plan Step 4 (not here); design's quality gate is per-slice via slice-verifier at 6.2
- Design flips
status: in-progress → status: ready directly at Step 7; no in-review intermediate (no Step 8 reviewer to wait for)
- NEVER skip the developer checkpoint — developer input on architectural decisions is the highest-value signal in the design process
- NEVER edit source files — all code goes into the design document, not the codebase. This skill produces a document, not implementation. Source file editing is implement's job.
- Code is source of truth — if the Architecture code section conflicts with the Decisions prose or the
## Slices Success Criteria, the code wins. Update the prose and criteria.
- Checkpoint recordings: Record micro-checkpoint interactions in Developer Context with
file:line references, same as Step 4 questions.
- Frontmatter consistency: Always include frontmatter, use snake_case for multi-word fields, keep tags relevant
Common Design Patterns
- New Features: types first → backend logic → API surface → UI last. Research existing patterns first. Include tests alongside each implementation.
- Modifications: Read current file FULLY. Show only the modified/added code scoped to changed sections. Check integration points for side effects.
- Database Changes: schema/migration → store/repository → business logic → API → client. Include rollback strategy.
- Refactoring: Document current behavior first. Plan incremental backwards-compatible changes. Verify existing behavior preserved.
- Novel Work: Include approach comparison in Decisions. Ground in codebase evidence OR web research. Get explicit developer sign-off BEFORE writing code.