kiro-spec-tasks

# Implementation Tasks Generator

<background_information>
- **Success Criteria**:
  - All requirements mapped to specific tasks
  - Tasks properly sized (1-3 hours each)
  - Clear task progression with proper hierarchy
  - Natural language descriptions focused on capabilities
  - A lightweight task-plan sanity review confirms the task graph is executable before `tasks.md` is written
</background_information>

<instructions>
## Execution Steps

### Step 1: Load Context

**Read all necessary context**:
- `{{KIRO_DIR}}/specs/$1/spec.json`, `requirements.md`, `design.md`
- `{{KIRO_DIR}}/specs/$1/tasks.md` (if exists, for merge mode)
- Core steering context: `product.md`, `tech.md`, `structure.md`
- Additional steering files only when directly relevant to requirements coverage, design boundaries, runtime prerequisites, or team conventions that affect task executability

**Validate approvals**:
- If `-y` flag provided: Auto-approve requirements and design in spec.json. Tasks approval is also handled automatically in Step 4.
- Otherwise: Verify both approved (stop if not, see Safety & Fallback)
- Determine sequential mode based on presence of `--sequential`

### Step 2: Generate Implementation Tasks

**Load generation rules and template**:
- Read `rules/tasks-generation.md` from this skill's directory for principles
- If `sequential` is false: Read `rules/tasks-parallel-analysis.md` from this skill's directory for parallel judgement criteria
- Read `{{KIRO_DIR}}/settings/templates/specs/tasks.md` for format (supports `(P)` markers)

#### Parallel Research

The following research areas are independent and can be executed in parallel:
1. **Context loading**: Spec documents (requirements.md, design.md), steering files
2. **Rules loading**: tasks-generation.md, tasks-parallel-analysis.md, tasks template

If multi-agent is enabled, spawn sub-agents for each area above. Otherwise execute sequentially.

After all parallel research completes, synthesize findings before generating tasks.

**Generate task list following all rules**:
- Use language specified in spec.json
- Map all requirements to tasks
- When documenting requirement coverage, list numeric requirement IDs only (comma-separated) without descriptive suffixes, parentheses, translations, or free-form labels
- Ensure all design components included
- Verify task progression is logical and incremental
- Ensure each executable sub-task includes at least one detail bullet that states what "done" looks like in observable terms
- Keep normal implementation tasks within a single responsibility boundary; if work crosses boundaries, make it an explicit integration task
- Collapse single-subtask structures by promoting them to major tasks and avoid duplicating details on container-only major tasks (use template patterns accordingly)
- Apply `(P)` markers to tasks that satisfy parallel criteria (omit markers when sequential mode requested)
- Mark optional test coverage subtasks with `- [ ]*` only when they strictly cover acceptance criteria already satisfied by core implementation and can be deferred post-MVP
- If existing tasks.md found, merge with new content

### Step 3: Review Task Plan

- Keep the draft task plan in working memory; do NOT write `tasks.md` yet
- Run the `Task Plan Review Gate` from `rules/tasks-generation.md`
- Review coverage:
  - Every requirement ID appears in at least one task
  - Every design component, contract, integration point, runtime prerequisite, and validation concern is represented
- Review executability:
  - Each sub-task is an executable 1-3 hour work unit
  - Each sub-task has a verifiable deliverable
  - Each executable sub-task includes an observable completion bullet
  - No implicit prerequisites remain hidden
  - `_Depends:_`, `_Boundary:_`, and `(P)` markers still match the dependency graph and architecture boundaries
- If issues are task-plan-local, repair the draft and re-run the review gate before writing
- Keep the review bounded to at most 2 repair passes
- If review exposes a real requirements/design gap or contradiction, stop and send the user back to requirements/design instead of inventing filler tasks

### Step 3.5: Run Task-Graph Sanity Review

Before writing `tasks.md`, run one lightweight independent sanity review of the task graph.

- If fresh subagent dispatch is available, spawn one fresh review subagent for this step. Otherwise perform the same review in the current context.
- Provide only file paths, the draft task plan, and merge context if an existing `tasks.md` is being updated. The reviewer should read `requirements.md`, `design.md`, and the task-generation rules directly instead of relying on a parent-synthesized coverage summary.
- Check only:
  - hidden prerequisites or missing setup tasks
  - dependency or ordering mistakes
  - boundary overlap or ambiguous ownership between tasks
  - tasks that are too large, too vague, cross boundaries without being explicit integration tasks, or are missing a verifiable deliverable
  - contradictions introduced between requirements, design, and the task graph
- Return one verdict:
  - `PASS`
  - `NEEDS_FIXES`
  - `RETURN_TO_DESIGN`
- If `NEEDS_FIXES`, repair the draft once and re-run the sanity review one time.
- If `RETURN_TO_DESIGN`, stop without writing `tasks.md` and point back to the exact gap in requirements/design.
- Keep this bounded. Do not turn it into a second full planning cycle.

### Step 4: Finalize

**Write tasks.md**:
- Create/update `{{KIRO_DIR}}/specs/$1/tasks.md`
- Update spec.json metadata:
  - Set `phase: "tasks-generated"`
  - Set `approvals.tasks.generated: true, approved: false`
  - Set `approvals.requirements.approved: true`
  - Set `approvals.design.approved: true`
  - Update `updated_at` timestamp

**Approval**:
- If auto-approve flag (`-y`) is provided:
  - Set `approvals.tasks.approved: true` in spec.json
  - Display task summary (task count, major groups, parallel markers)
  - Respond: "Tasks generated and auto-approve