| name | prd-taskmaster |
| description | Zero-config goal-to-tasks engine (the Atlas engine). Takes any goal (software, pentest, business, learning), runs adaptive discovery via brainstorming, generates a validated spec, parses into TaskMaster tasks, and hands off to execution. Use when user says "PRD", "product requirements", "I want to build", invokes /atlas, or wants task-driven development. |
| allowed-tools | ["Read","Write","Edit","Grep","Glob","Bash","Skill","AskUserQuestion","WebSearch","ToolSearch","mcp__atlas-engine","mcp__plugin_prd_go","mcp__plugin_prd-taskmaster_go","mcp__plugin_atlas-go_go"] |
prd-taskmaster — the Atlas engine
Zero-config goal-to-tasks engine. AI handles discovery and content; the engine backend (MCP
server preferred, script.py fallback — see Phase 0) handles mechanics.
Command: /atlas is the canonical invocation (or /prd-taskmaster, or just say "I want to
build …"). The full plugin install also exposes phase skills; this standalone skill runs the whole
pipeline inline.
Script: ~/.claude/skills/prd-taskmaster/script.py (all commands output JSON). It is a thin
shim over the bundled prd_taskmaster/ package — the single source of truth shared with the plugin.
Manual flag: If the user says --manual, manual=true, or "do it manually", perform the
TaskMaster mechanics yourself: write .taskmaster/docs/prd.md, write .taskmaster/tasks/tasks.json
with tasks and subtasks, run validate-tasks, then run enrich-tasks. Do not block on TaskMaster
CLI/MCP parsing.
When to Use
Activate: PRD, product requirements, taskmaster, task-driven development, "I want to build X", any goal.
Skip: API docs, test specs, project timelines, PDF creation.
Phase 0: Engine Backend Resolution (MANDATORY — before any other engine operation)
The engine has two interchangeable backends: the atlas-engine MCP server (preferred)
and script.py (zero-dependency fallback). Resolve which one this session uses NOW.
Do NOT silently default to script.py.
Claude Code note — deferred tools: MCP tools are often deferred: their names appear
in a system-reminder list but they are NOT callable until you load their schemas with the
ToolSearch tool. "I don't see a callable engine_preflight tool" does NOT mean the server
is absent — it almost always means you have not run ToolSearch yet.
Resolution procedure, in order:
- If a
ToolSearch tool exists in your session:
a. ToolSearch(query="select:mcp__atlas-engine__engine_preflight")
b. If no match: ToolSearch(query="+engine preflight atlas", max_results=10) — this
also catches plugin-scoped ids such as mcp__plugin_prd_go__engine_preflight.
c. If a schema loads → MCP-mode = ON. Record the prefix (e.g. mcp__atlas-engine__).
If both user-scope and plugin-scope match, prefer mcp__atlas-engine__.
- No ToolSearch, but an
engine_preflight MCP tool is already directly callable →
MCP-mode = ON with that prefix.
- Otherwise → MCP-mode = OFF (CLI-mode).
Announce the result before Phase 1, exactly one line:
Engine backend: MCP (<prefix>*) or Engine backend: script.py (CLI fallback).
Hard rules for the rest of the run:
- MCP-mode ON: every operation in the "Engine operations" table below MUST use its MCP
tool. Running
python3 script.py <cmd> for an op that has an MCP tool in this session's
prefix is a compliance failure — the only exceptions are ops in the "Script/agent-only"
table and ops whose tool is missing from the resolved prefix (some plugin installs expose
fewer tools — fall back to script.py for just those ops).
- MCP-mode OFF: use the script.py commands exactly as documented below. Other harnesses
(codex, gemini) have no ToolSearch and may have no MCP server — CLI-mode is fully
supported and not a degraded experience.
- If an MCP call errors mid-run (server died/disconnected), say so explicitly, flip to
CLI-mode, and continue.
Phase 1: Zero-Config Preflight
Run preflight and auto-detect everything. Ask zero setup questions.
MCP-mode (from Phase 0 — ONE batched call, no script spam): call
<prefix>engine_preflight once — it covers preflight + taskmaster detection + provider
configuration + capabilities and returns a summary list to present verbatim.
Skip every individual script call below entirely.
CLI-mode (zero-dependency installs): one batched subcommand, same result:
python3 ~/.claude/skills/prd-taskmaster/script.py engine-preflight
From preflight JSON, determine the state:
| Condition | Action |
|---|
prd_path exists + task_count > 0 | Ask: execute tasks / update PRD / new PRD / review |
backend.ai_ops == "agent" | Backend resolves automatically; print ONE info line: add an API key or install task-master-ai for headless AI ops; proceed |
| manual flag present | Proceed using Native Mode (TaskMaster optional), regardless of TaskMaster CLI/MCP state |
has_taskmaster == false + backend selected | Run init-project (below), then continue |
has_taskmaster but no PRD | Proceed to Discovery |
has_crash_state | Offer: resume from crash point or start fresh |
Initialise the project if needed, then auto-configure providers (silent). Use
init-project for the resolved backend. For the taskmaster backend, this preserves
an existing .mcp.json; raw task-master init overwrites it with a placeholder template.
Use init-taskmaster only when explicitly operating the taskmaster backend:
python3 ~/.claude/skills/prd-taskmaster/script.py init-project
python3 ~/.claude/skills/prd-taskmaster/script.py init-taskmaster
python3 ~/.claude/skills/prd-taskmaster/script.py configure-providers
python3 ~/.claude/skills/prd-taskmaster/script.py detect-providers
If configure-providers returns recommended_action: "init_taskmaster", run
init-project first; if the backend is explicitly taskmaster, init-taskmaster
is also safe and preserves .mcp.json.
Report compact status:
✓ Backend: taskmaster-api|native-api|agent
✓ Detected: TaskMaster (MCP|CLI)
✓ Detected: Provider (Claude Code|Codex CLI|Anthropic API)
✓ Detected: Research (Perplexity API Free|Perplexity MCP|Perplexity API|fallback)
Gate: backend resolved (always true). Report ai_ops capability. Proceed to Discovery.
Provider Defaults
Always prefer subscription/native providers before paid API keys:
- Main:
claude-code / sonnet when claude exists; otherwise codex-cli / gpt-5.2-codex when codex exists.
- Fallback:
codex-cli / gpt-5.2-codex when available; otherwise claude-code / sonnet.
- Research: local Perplexity API Free through TaskMaster
openai-compatible provider:
- model:
sonar
- baseURL:
http://127.0.0.1:8765
.env key: OPENAI_COMPATIBLE_API_KEY="local-perplexity-api-free" (dummy local key only)
Do not require ANTHROPIC_API_KEY or paid PERPLEXITY_API_KEY when native Claude/Codex and Perplexity API Free are available.
Phase 2: Discovery
Read the phase file and follow it:
Read ~/.claude/skills/prd-taskmaster/phases/DISCOVER.md
Progressive, adaptive, domain-agnostic discovery via superpowers:brainstorming.
Gate: Discovery complete and user approved design. Proceed to Generate.
Phase 3: Generate & Validate
Read the phase file and follow it:
Read ~/.claude/skills/prd-taskmaster/phases/GENERATE.md
Generate spec, validate quality, parse tasks, enrich with metadata.
Gate: PRD validated GOOD+ and tasks created through TaskMaster parse/expand OR Native Mode. Proceed to Handoff.
Native Mode (TaskMaster optional)
Formerly "Manual Mechanics Mode". The engine produces the same validated task graph without
TaskMaster — use it when the user passes --manual, TaskMaster isn't installed, or its
parsing/expansion is a poor fit.
- Generate
.taskmaster/docs/prd.md normally.
- Manually write
.taskmaster/tasks/tasks.json in TaskMaster-compatible shape:
- top-level object with
tasks: []
- each task has
id, title, description, details, testStrategy, status, dependencies, priority, and subtasks
- every task has at least 2 subtasks with
id, title, description, status, and dependencies
- Run:
python3 ~/.claude/skills/prd-taskmaster/script.py validate-tasks
python3 ~/.claude/skills/prd-taskmaster/script.py enrich-tasks
python3 ~/.claude/skills/prd-taskmaster/script.py validate-tasks --require-phase-config
- Treat successful validation + enrichment + phaseConfig validation as equivalent to TaskMaster parse + expand.
Phase 4: Handoff
Read the phase file and follow it:
Read ~/.claude/skills/prd-taskmaster/phases/HANDOFF.md
Detect capabilities, recommend ONE execution mode, hand off. Modes (user-facing names):
Verified Loop (recommended when superpowers + a loop runner are present), Auto-Execute
(TaskMaster's native loop), Plan & Drive (plan only). Atlas Fleet — parallel multi-session
execution — appears as an Atlas Pro option when a licensed atlas-launcher is detected;
otherwise it shows as a locked teaser pointing to https://atlas-ai.au/pro. The free engine is
always fully usable on its own.
Gate: User chose mode and handoff complete.
Feedback
At debrief time, every executing agent records how the run went. MCP-mode:
<prefix>feedback_submit / <prefix>feedback_report. CLI-mode:
python3 script.py feedback-add --rating <1-5> --agent <name> --harness <claude-code|codex|gemini|api|other> --task-ref <id> --well <text> --failed <text> --suggest <text>. Feedback is stored in
.atlas-ai/feedback.jsonl; summarize it with python3 script.py feedback-report.
Engine operations
This table is normative — instruction sites reference operations by name. In MCP-mode use
the MCP tool (substitute the Phase-0 prefix); in CLI-mode use the script.py command.
| Operation | MCP tool (MCP-mode) | script.py (CLI-mode / fallback) |
|---|
engine-preflight | engine_preflight | engine-preflight |
preflight | preflight | preflight |
detect-taskmaster | detect_taskmaster | detect-taskmaster |
backend-detect | backend_detect | backend-detect |
init | init_project | init-project |
init-taskmaster | init_taskmaster | init-taskmaster |
validate-setup | validate_setup | (covered by engine-preflight) |
detect-capabilities | detect_capabilities | detect-capabilities |
load-template | load_template | load-template --type comprehensive|minimal |
calc-tasks | calc_tasks | calc-tasks --requirements <count> [--scale solo|team|enterprise] |
validate-prd | validate_prd | validate-prd --input <path> |
backup-prd | backup_prd | backup-prd --input <path> |
parse-prd | parse_prd | parse-prd --input <path> --num-tasks N [--tag] |
rate | rate_tasks | rate [--tag] [--no-research] |
expand | expand_tasks | expand [--id N ...] [--no-research] [--tag] |
next | next_task | next-task [--tag] |
set-status | set_task_status | set-status --id <id> --status <status> [--tag] |
fleet-waves | compute_fleet_waves | fleet-waves |
feedback-add | feedback_submit | feedback-add --rating <1-5> ... |
feedback-report | feedback_report | feedback-report |
status | render_status | status [--phase P] [--format boxed|ascii|json] [--all] |
Render the progress panel at each phase boundary (and on demand) via status / render_status
— the boxed phase tracker, validation scorecard, ship-check gates, and execute progress.
Backend behavior is identical through either interface: the taskmaster backend wraps native
TaskMaster operations safely (init/parse/rate/expand); the native
backend uses direct API calls or returns agent_action_required; next/set-status are
engine-native under every backend.
Script/agent-only operations (no MCP tool — always script.py, any mode)
| Command | Purpose |
|---|
configure-providers | Configure native Claude/Codex + local Perplexity API Free defaults |
detect-providers | Auto-detect AI providers |
validate-tasks [--input <path>] [--require-phase-config] | Validate manually-authored tasks.json |
enrich-tasks | Add phaseConfig metadata to tasks |
parallel-plan [--missing-only] | Emit per-task research packets for parallel subagents |
parallel-apply --input <results.json> | Merge parallel research results atomically |
parallel-extract --output <path> / parallel-inject --input <path> | Tagged ⇄ flat tasks bridge |
economy-report | Summarize telemetry per (op_class, model) |
Parallel Research & Complexity
Decision tree for expansion + research (token-economy aware):
Manual flag → Native Mode (unchanged)
pending tasks ≤ 3 → TaskMasterBackend.expand internal: serial NATIVE
rate --research, then expand per task (main dir)
task-master ≥ 0.43 AND research
role is a REAL structured API → TaskMasterBackend.expand internal: NATIVE-PARALLEL
(sonar/anthropic/openai… key) one serial analyze-complexity, then N isolated workdirs each running
native `expand --id N --research` with an economy-tier model; ONE
atomic harvest merge. Failed packets → agent-parallel rerun.
free local proxy / no API key /
TM provider errors / TM < 0.43 → native/agent path: AGENT-PARALLEL (fallback):
parallel-plan → N subagents → parallel-apply
Why isolation dirs: task-master 0.43+ uses proper-lockfile + atomic writes, but its 10s lock-stale
window vs 30–120s AI calls makes concurrent invocations in ONE directory unsafe — N isolated
project dirs sidestep the lock entirely and double as the per-attempt model mechanism (expand has
no --model flag; each workdir carries its own config.json). The free local Perplexity proxy returns
prose where TaskMaster needs strict JSON — that is why the proxy keeps the agent-normalized path
while real APIs get the native path.
Pattern — the parallelism lives in the AGENT, not the script:
python3 ~/.claude/skills/prd-taskmaster/script.py parallel-plan --missing-only
python3 ~/.claude/skills/prd-taskmaster/script.py parallel-apply --input results.json
If the perplexity-api-free MCP wrapper times out or says the proxy is unreachable, check direct
proxy health:
curl -sS -X POST http://127.0.0.1:8765/chat/completions \
-H 'Content-Type: application/json' \
-d '{"model":"sonar","messages":[{"role":"user","content":"Return exactly: ok"}],"max_tokens":16}'
If direct curl works, continue: use MCP, direct proxy calls, or agent research to produce the
results.json schema, then normalize prose into valid JSON before parallel-apply. Do not block on
native task-master analyze-complexity --research.
Tag bridge for explicit flat-file workflows (the script also reads tagged TaskMaster files directly):
python3 ~/.claude/skills/prd-taskmaster/script.py parallel-extract --output /tmp/flat.json
python3 ~/.claude/skills/prd-taskmaster/script.py validate-tasks --input /tmp/flat.json
python3 ~/.claude/skills/prd-taskmaster/script.py enrich-tasks --input /tmp/flat.json
python3 ~/.claude/skills/prd-taskmaster/script.py validate-tasks --input /tmp/flat.json --require-phase-config
python3 ~/.claude/skills/prd-taskmaster/script.py parallel-inject --input /tmp/flat.json
All commands default --tag to .taskmaster/state.json currentTag and run from the project root.
Context
Standalone: Works on its own. Takes any goal, produces spec + tasks.
Produces: spec.md + tasks.json (in .taskmaster/).
Then: hand off to an execution mode (Verified Loop / Auto-Execute / Plan & Drive), or
Atlas Fleet for parallel multi-session execution with Atlas Pro.
Critical Rules
- Zero setup questions — detect everything, ask only discovery questions
- Discovery via superpowers:brainstorming — one question at a time, adaptive
- Domain-agnostic — works for any goal (app, pentest, business, anything)
- Validate PRDs catch placeholders — mustache, TBD, TODO patterns fail validation
- Manual flag means "do the TaskMaster mechanics manually", not "skip validation"
- Handoff recommends ONE mode — present best fit, not equal choices
- Phase files must be Read explicitly — they are not auto-loaded
- Native/free provider defaults are enforced by
configure-providers; do not drift back to paid Anthropic/Perplexity APIs unless native/free routes are unavailable
- Perplexity API Free research must be normalized through
parallel-apply; native TaskMaster research is only acceptable when it returns valid structured output and validation passes
- Phase 0 backend resolution is mandatory — in MCP-mode, script.py is forbidden for any op that has an MCP tool in the resolved prefix