| name | quick-start |
| description | Interactive onboarding for the MCP Task Orchestrator. Detects empty or populated workspaces and walks through how plan mode, persistent tracking, and the MCP work together. Use when a user says "get started", "how do I use this", "quick start", "first time setup", "onboard me", "what can this MCP do", or "help me learn task orchestrator". |
| argument-hint | [optional: describe what you want to track, e.g. 'a web app project'] |
Quick Start — MCP Task Orchestrator
Interactive onboarding that teaches by doing. Detects your workspace state and adapts.
Step 1: Detect Workspace State
Resolve the project rootId first: check session context for a rootId injected by the SessionStart hook, or read .taskorchestrator/config.yaml's top-level project.rootId (a file read, not an MCP call).
Call the health check to determine which path to follow:
get_context()
When a rootId is known, pass it to scope the check to this project: get_context(ancestorId="<rootId>"). When no rootId is known — the common case for a truly fresh workspace, or one that hasn't been bootstrapped yet — call unscoped exactly as shown.
If no active or stalled items exist — follow the Fresh-Start Path (Steps 2-8).
If active items exist — follow the Orientation Path (Steps A-C).
Step 1.5: Project Anchor Bootstrap (if needed)
Before following either path, check whether this workspace has a project anchor yet:
- If
.taskorchestrator/config.yaml does not exist at all, skip this step — that's the truly fresh workspace covered by the Fresh-Start Path below. Bootstrap can happen on a later run once a config file exists (e.g., after /manage-schemas creates one).
- If
.taskorchestrator/config.yaml exists and already has a top-level project: block, read its rootId and use it for scoping throughout this session — no bootstrap needed.
- If
.taskorchestrator/config.yaml exists but has no project: block, offer to create one via AskUserQuestion: "This workspace doesn't have a project anchor yet — want me to create one? It lets /work-summary, /create-item, and other skills scope to just this project if multiple projects ever share the same database."
If the user accepts:
-
Determine a project name — from $ARGUMENTS, conversation context, or by asking.
-
Create the anchor item at depth 0:
manage_items(operation="create", items=[{title: "<project name>", type: "project", priority: "low"}])
-
Write the canonical block into .taskorchestrator/config.yaml:
project:
rootId: "<created-item-uuid>"
name: "<project name>"
-
Older servers may not expose it, so check the tool list before calling — if a manage_project_config tool is available, push the full current file text (not just the project: block — the server never reads that block itself; see references/config-format.md → Project Scoping) so per-root schema resolution picks it up immediately without waiting on a config reload:
manage_project_config(operation="push", rootId="<created-item-uuid>", configYaml="<full current file text from step 3>")
- Success → the returned
fingerprint confirms the push landed; re-pushing identical content later returns the same fingerprint (idempotent).
VALIDATION_ERROR → surface the parse error to the user; the config.yaml write from step 3 is already saved locally, so nothing is lost — tell them to fix the file and retry the push (or run /manage-schemas validate).
CONFLICT_ERROR (superseded) → the local file is older than the server's stored config (rare during onboarding — usually means another checkout already synced a newer version). Fetch the server's copy with manage_project_config(operation="get", ...) and reconcile, or pass force: true if overwriting is intentional.
- A
warning field → relay it to the user (non-fatal).
If the tool isn't available, note this and skip — the config.yaml write from step 3 is authoritative on its own; the server will pick it up on its normal config read path.
If the user declines, proceed unscoped — nothing else in this skill requires an anchor.
Fresh-Start Path
Step 2: Welcome — The Big Picture
Explain briefly:
- When you ask Claude to build something non-trivial, it enters plan mode — exploring the codebase and writing a plan saved as a persistent markdown file
- The MCP Task Orchestrator complements the plan file by tracking execution state — what's been started, what's blocked, what's done, and what's next
- Think of it this way: the plan file is your design document (the what and how), while the MCP is your project board (the progress and status)
- The MCP also helps during planning — Claude automatically checks for existing tracked work and schema requirements before planning, setting a definition floor so the plan accounts for documentation gates and doesn't duplicate what's already in progress
- Together, they give you full continuity across sessions — the plan tells you the approach, the MCP tells you where you left off
Step 3: The Plan Mode Pipeline
Show how plan mode and the MCP work together. This is the workflow users will experience:
You describe what you want
│
▼
EnterPlanMode ← Claude explores the codebase
│
pre-plan hook fires ← Plugin sets the definition floor: existing work, schemas, gate requirements
│
▼
Plan written to disk ← Persistent markdown file — your design document
│
Plan approved (ExitPlanMode)
│
post-plan hook fires ← Plugin tells Claude to materialize before implementing
│
▼
Materialize ← Claude creates MCP items from the plan
│ Items, dependencies, notes — execution tracking
▼
Implement ← Subagents work, each transitioning their MCP item
│ advance_item(start) → work → advance_item(complete)
▼
Health check ← get_context() shows what completed and what didn't
Reinforce to the user:
- The plan file and MCP items are not duplicates — they serve different roles
- MCP items track individual units of work through a lifecycle: who's working on what, what's blocked, and what's done
- The plugin hooks inject guidance automatically so Claude follows this pipeline — you don't need to ask for it
Step 4: Hands-On — Create Your First Items
Now let's create some MCP items to see how the execution tracking works.
Determine the project topic:
- If
$ARGUMENTS is provided, use it as the project topic
- Otherwise, ask via
AskUserQuestion with options like "A web app feature", "A bug fix workflow", "A documentation project", or Other
Create a container with child items and dependencies in one atomic call:
create_work_tree(
root: {
title: "<Project Name> — Tutorial",
summary: "Quick-start tutorial project to learn MCP Task Orchestrator",
type: "container",
priority: "medium"
},
children: [
{ ref: "design", title: "Design <topic>", summary: "Define requirements and approach", type: "feature-task", priority: "high" },
{ ref: "implement", title: "Implement <topic>", summary: "Build the solution", type: "feature-task", priority: "high" },
{ ref: "test", title: "Test <topic>", summary: "Verify the implementation", type: "feature-task", priority: "medium" }
],
deps: [
{ from: "design", to: "implement", type: "BLOCKS" },
{ from: "implement", to: "test", type: "BLOCKS" }
]
)
Explain to the user:
create_work_tree creates everything atomically — the container, three child items, and two dependency edges
- In a real workflow, Claude creates these automatically after a plan is approved — the post-plan hook triggers this
- The
BLOCKS dependency means: implement cannot start until design completes, test cannot start until implement completes
- The
ref names ("design", "implement", "test") are local aliases used only within this call
Show the structure:
<Project Name> — Tutorial (container)
├── Design <topic> ← actionable (no blockers)
├── Implement <topic> ← blocked by Design
└── Test <topic> ← blocked by Implement
This is the project board side — these items track progress. The plan file (if this were a real feature) would contain the design decisions behind each of these tasks.
Fill required notes (gate prerequisite): feature-task items require a task-scope note (queue, required) before advance_item(trigger="start") will succeed, and a complete trigger checks ALL required notes across every phase the resolved schema declares — not just the current phase, and not just the base schema's own notes. Traits merge in too: a session-tracked default trait adds a required session-tracking work note, for example, while review-phase notes like review-checklist are typically opt-in per item via a trait (e.g. needs-task-review), not a base requirement. Call get_context(itemId="<design-UUID>") to see the exact resolved note list before filling — schemas vary per project. create_work_tree above created the children with no notes — its createNotes option only auto-fills blank bodies, which don't count as "filled" for gate purposes — so fill every required note the resolved schema lists on the design item now, before Step 5a, so both the start and complete calls succeed. For a feature-task schema with the common task-scope + implementation-notes base plus a session-tracked default trait:
manage_notes(
operation="upsert",
notes=[
{ itemId: "<design-UUID>", key: "task-scope", role: "queue", body: "Define requirements and approach for <topic>." },
{ itemId: "<design-UUID>", key: "implementation-notes", role: "work", body: "Design work completed for <topic>." },
{ itemId: "<design-UUID>", key: "session-tracking", role: "work", body: "Design phase completed this session." }
]
)
Explain to the user: in a real workflow, subagents fill these notes as work actually happens, phase by phase. Here we're pre-filling all of them up front purely so the tutorial's Step 5b complete call isn't gate-blocked — note bodies don't need to match the item's current role to be saved, only to satisfy the gate check at advance time. If get_context shows additional required notes (e.g. a review-checklist from an opted-in review trait), fill those too before advancing.
Step 5: The Role Lifecycle
Items move queue → work → review → terminal via advance_item triggers — see the advance_item tool description for full trigger semantics.
5a. Start the design task:
advance_item(transitions=[{ itemId: "<design-UUID>", trigger: "start" }])
Point out in the response: cascadeEvents shows the container cascading queue → work (first child started). In a real workflow, each subagent calls this when it begins its assigned item.
5b. Complete the design task:
advance_item(transitions=[{ itemId: "<design-UUID>", trigger: "complete" }])
Point out in the response: unblockedItems shows implement is now unblocked; the container stays in work because siblings are still active.
5c. Confirm what's next:
get_next_item(limit=3, includeDetails=true)
Point out: the implement task is now recommended — it was unblocked when design completed. This is how the MCP answers "what should I work on next?" across sessions.
Step 6: Cross-Session Continuity
This is where the plan file and MCP complement each other most visibly. Explain:
- If a session ends mid-work, the next session can call
get_context() or /work-summary to see exactly which items are in progress, which are blocked, and which are done
- The plan file is still on disk — Claude can re-read it to recall the design approach
- The MCP items show execution state — no need to re-explain what's been completed
- Together: "Read the plan to remember the approach. Check the MCP to see where you left off."
This is the difference between having a plan document alone vs. having a plan document plus a live project board. The plan doesn't change as work progresses — the MCP does.
Step 7: Note Schemas (Optional Power Feature)
Briefly mention that MCP items can have required notes that act as documentation gates:
- A
.taskorchestrator/config.yaml file defines schemas under work_item_schemas: — which notes must be filled before an item can advance
- Items match schemas via their
type field (e.g., type: "feature-implementation" activates that schema's notes and gates)
- Example: the
feature-implementation schema requires a feature-summary note before work can start, and a review-checklist note before completion
- Each schema can set a lifecycle mode (auto, manual, auto-reopen, permanent) controlling cascade behavior
- Notes can carry a
guidance field (authoring hints) and a skill field (structured evaluation framework to invoke before filling)
- Composable traits add additional note requirements per-item — e.g.,
traits: "needs-security-review" adds a security-assessment note at the review phase
- Run
/manage-schemas to set one up interactively — it can also generate a companion lifecycle skill for your schema
Step 8: What's Next
Present this capabilities table:
| Want to... | Skill | What it does |
|---|
| Track a feature with documentation gates | /manage-schemas | Create schemas with lifecycle gates, then use companion skills |
| Create items from conversation context | /create-item | Infers type, priority, and container placement |
| Build custom workflow schemas | /manage-schemas | Create, view, edit, delete, and validate note schemas |
| See project health dashboard | /work-summary | Active work, blockers, next actions at a glance |
| Advance an item through gates | /status-progression | Shows current role, gate status, correct trigger |
| Change how the server runs (HTTP, REST API, config-sync) | /configure-server | Transport, REST API mode, port publishing, config mount |
Offer cleanup: Ask via AskUserQuestion whether to keep the tutorial items for reference or delete them. If delete, use the container UUID returned in Step 4 above:
manage_items(operation="delete", itemIds=["<container-UUID>"], recursive=true)
Orientation Path
For users with an existing populated workspace.
Step A: Health Check Dashboard
Run two calls in parallel:
get_context()
query_items(operation="overview", includeChildren=true)
Add ancestorId="<rootId>" to both when a rootId is known (resolved in Step 1) — this keeps the orientation dashboard scoped to the current project in multi-project workspaces. Call unscoped exactly as shown when no rootId is known.
Present a condensed dashboard with these sections:
- Active Work (role=work or review): items currently in progress — show title, role, and ancestor path
- Blocked / Stalled: items that cannot advance — either dependency-blocked or missing required notes
- Containers: root items with child counts by role
- Recommendations: from
get_next_item(limit=3, includeDetails=true) — add ancestorId="<rootId>" when known
Use status symbols: ◉ in-progress, ⊘ blocked, ○ pending, ✓ completed
Step B: Explain What You're Seeing
For each section of the dashboard, add a brief annotation:
- Active items are in
work or review role — these are things being worked on right now
- Blocked items have unsatisfied dependencies (another item must complete first) or are missing required notes that gate advancement
- Stalled items have required notes that haven't been filled — use
get_context(itemId=...) to see which notes are missing, then manage_notes(upsert) to fill them
- Containers at depth 0 organize your work hierarchically — items can nest up to depth 3
If blocked items exist, explain: "Run /status-progression on a blocked item to see exactly what's needed to unblock it."
Explain the plan mode connection: These MCP items are the execution tracking side of your work. When Claude enters plan mode, it writes a persistent plan file (your design document). When the plan is approved, the plugin hooks tell Claude to create MCP items like these to track implementation progress. The plan file and MCP items are complementary — the plan captures what and how, the MCP tracks progress and status.
Step C: Suggested Next Action
Based on the dashboard, recommend one concrete action:
| Situation | Recommendation |
|---|
| Stalled items with missing notes | Fill the required notes — show the exact manage_notes call |
| Blocked items with satisfied deps | Advance with advance_item(trigger="start") |
| No active work, queue items exist | Start the highest-priority queue item |
| Empty workspace | Switch to the Fresh-Start path (Step 2) |
| Everything terminal | Suggest creating new work with /create-item |
End with: "Run /work-summary anytime to see this dashboard. When you're ready to build something, just describe it — Claude will enter plan mode, write a plan file, and create MCP items to track the work automatically."