Delx Living Body
Meta-MCP that auto-detects installed wellness connectors and composes them into one body data layer.
README
delx-living-body
Meta-MCP that turns 15 wellness MCPs into one unified body data layer for AI agents.
Today, answering "should I train hard today?" forces an agent to orchestrate WHOOP recovery, Garmin Body Battery, Oura sleep, Nourish nutrition, and cycle phase across five separate MCP servers. That's brittle for users and confusing for the agent.
delx-living-body is one MCP server that:
- Auto-detects which of 15 Delx Wellness connectors you already have installed locally — no manual config
- Composes parallel calls to the right subset
- Synthesizes a natural-language answer plus a structured reasoning trace and per-source confidence — using rule-based reasoning, no LLM calls
Install it once. Get a unified body data layer. Works with whatever wellness MCPs you already have.
If it helps your agent workflow, star the repo. Stars make the single-entry Delx Wellness path easier for other AI builders to find.
- Try it now, no accounts —
npx -y delx-living-body demo("Should I train hard today?") - Run it in Claude · Cursor · ChatGPT · Hermes · OpenClaw — see agent setup examples
- Local-first —
delx-living-bodynever reads your tokens; children read their own creds (privacy) - Which connector should I use? — start at the Delx Wellness front door
The three flagship connectors this composes over: google-health-mcp (google-health-mcp-unofficial), garmin-mcp (garmin-mcp-unofficial), and wellness-nourish (wellness-nourish).
Install
npx -y delx-living-body
That's the whole install. No OAuth flow, no API keys — delx-living-body has no auth of its own. Each child connector handles its own credentials.
See the full agent demo → "Should I train hard today?" (no accounts needed)
npx -y delx-living-body demo
One command, no clone. The demo boots the real MCP server, fakes three
installed connectors (WHOOP + Oura + Garmin, backed by a bundled stub child that
carries synthetic body data), and drives it over stdio exactly the way an agent
does. No real accounts, API keys, or network. Add --scenario=red to see the
low-readiness ("back off today") path; demo --help lists options. Captured
output lives at
examples/demo-what-should-i-do-today.txt:
2) living_body_ask question="What should I do today?"
────────────────────────────────────────────────────────────────
Recommendation:
Today at a glance: recovery 74, sleep 83, body battery 68.
Confidence: high Sources: whoop, oura, garmin
3) living_body_ask question="Should I train hard today?"
────────────────────────────────────────────────────────────────
Recommendation:
Green light for a hard session. Recovery and sleep both support high intensity.
Confidence: high Sources: whoop, oura, garmin
Reasoning trace (rule-based, no LLM):
Intent classified as: training_readiness
- (rec_high) Recovery 74 supports a high-intensity day.
- (sleep_good) Sleep score 83 is supporting recovery.
One question in → one synthesized answer composed across all three connectors, with a stable reasoning trace and zero LLM calls. This is the Body-vertical entrypoint: install once, ask in plain language, get a unified answer.
Tools (6)
| Tool | Purpose |
|---|---|
living_body_status |
Which connectors are detected? Safe; no subprocess spawning. |
living_body_ask |
Main tool. Spawns detected children in parallel, returns synthesized answer. Requires explicit_user_intent: true. |
living_body_daily_brief |
Markdown brief built from each connector's daily_summary. |
living_body_compose_context |
Normalized delx-wellness-context/v1 shape merged across sources. |
living_body_health_check |
All 15 known connectors with install hints for missing ones. |
living_body_capabilities |
Self-description + per-connector availability matrix. |
How detection works
For each known connector, delx-living-body checks:
~/.<vendor>-mcp/tokens.jsonexists~/.<vendor>-mcp/config.jsonexists (password-based connectors like Eight Sleep)- An export file at the path in the vendor's env var (Apple Health, Samsung Health)
~/.delx-wellness/profile.jsonlists the device
If any check passes → detected. Otherwise → missing (with install hint). Stateless connectors (Cycle Coach) are always considered available.
Detection results cache for 60s (DELX_LIVING_BODY_DETECT_TTL).
Known connectors (15)
| ID | Package | Category |
|---|---|---|
whoop |
whoop-mcp-unofficial |
recovery |
oura |
oura-mcp-unofficial |
sleep |
garmin |
garmin-mcp-unofficial |
recovery |
strava |
strava-mcp-unofficial |
training |
fitbit |
fitbit-mcp-unofficial |
recovery |
google_health |
google-health-mcp-unofficial |
multi |
withings |
withings-mcp-unofficial |
multi |
apple_health |
apple-health-mcp-unofficial |
multi |
samsung_health |
samsung-health-mcp-unofficial |
multi |
polar |
polar-mcp-unofficial |
training |
eight_sleep |
eight-sleep-mcp-unofficial |
sleep |
nourish |
wellness-nourish |
nutrition |
air |
wellness-air |
environment |
cycle_coach |
wellness-cycle-coach |
cycle |
cgm |
wellness-cgm-mcp |
glucose |
Composition flow
When living_body_ask or living_body_compose_context runs:
- Detect installed connectors.
- For each, spawn it as a child MCP via
npx -y <package>over StdioClientTransport. - Call the child's
*_wellness_context(or*_daily_summary) tool in parallel. - Normalize results into a
delx-wellness-context/v1shape with merged scores. - Run the synthesizer (rule-based, offline) to produce a recommendation + reasoning trace.
Critically: delx-living-body never calls an LLM. Synthesis is deterministic so downstream agents can reason on top of a stable trace.
Synthesizer rules
14 heuristic rules, each with a stable rule_id that appears in the reasoning trace:
rec_low/rec_mid/rec_high— recovery score bandsbb_low/bb_high— Garmin Body Battery bandssleep_poor/sleep_good— sleep score bandsstrain_high— WHOOP strain ≥ 18cycle_luteal/cycle_follicular— cycle phase signalsload_high/load_low— aggregate training loadno_data— nothing installed, advisory onlyconflict— sources disagree → low confidence
Privacy & security
delx-living-bodynever reads child connector tokens or config files — children read their own credentials independently.- Upstream secret env vars (
*_CLIENT_SECRET,*_ACCESS_TOKEN,*_REFRESH_TOKEN,*_API_KEY,*_PASSWORD) are stripped before spawning children. - Children are spawned with
privacy_mode=structuredby default.rawis only honored when the caller setsexplicit_user_intent: trueonliving_body_ask. - Child responses are not logged verbatim — only counts and summary fields.
- Per-child call timeout: 30s. A hanging child is marked
timeoutand skipped. - Cache lives at
~/.delx-living-body/cache.sqlite(chmod 600), 5 min TTL. Disable withDELX_LIVING_BODY_NO_CACHE=true. - No phone-home from
delx-living-bodyitself.
See SECURITY.md for the full threat model.
Env vars
| Variable | Default | Purpose |
|---|---|---|
DELX_LIVING_BODY_DETECT_TTL |
60 |
Detection cache TTL in seconds |
DELX_LIVING_BODY_NO_CACHE |
unset | Disable SQLite response cache |
DELX_LIVING_BODY_CACHE_PATH |
~/.delx-living-body/cache.sqlite |
Override cache path |
DELX_LIVING_BODY_NPM_RUNNER |
npx |
Override npm runner for child spawning |
DELX_LIVING_BODY_CHILD_OVERRIDE_<ID> |
unset | Override child binary path (testing only) |
LIVING_BODY_MCP_HOST / LIVING_BODY_MCP_PORT |
127.0.0.1 / 3030 |
HTTP transport bind address |
CLI
living-body-mcp-server # MCP stdio server (default)
living-body-mcp-server --http # Local HTTP transport
living-body-mcp-server doctor # Detect installed connectors
living-body-mcp-server doctor --json # JSON output
living-body-mcp-server setup # Print profile path + install hints
living-body-mcp-server demo # Zero-secret end-to-end demo (--scenario=red, --help)
living-body-mcp-server version
Use with Claude Desktop
{
"mcpServers": {
"living-body": {
"command": "npx",
"args": ["-y", "delx-living-body"]
}
}
}
Use with Cursor
{
"mcpServers": {
"living-body": { "command": "npx", "args": ["-y", "delx-living-body"] }
}
}
Not medical advice
Outputs are operational context for training/recovery/sleep/nutrition agents. Not for medical diagnosis or clinical use.
License
MIT — see LICENSE. Built by David Mosiah.
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