# Mnemosyne *"The electric light did not come from the continuous improvement of candles."* — Oren Harari **The memory of everything you know.** Mnemosyne is a content-type-aware, multimodal personal knowledge management system built on Neo4j knowledge graphs and Qwen3-VL multimodal AI models. Named after the Titan goddess of memory and mother of the nine Muses, Mnemosyne doesn't just store your knowledge — it understands what kind of knowledge it is, connects it through relationships, and makes it all searchable through text, images, and natural language. ## What Makes This Different Every existing knowledge base tool treats all documents identically: text in, chunks out, vectors stored. A novel and a PostgreSQL manual get the same treatment. Mnemosyne knows the difference: - **A textbook** has chapters, an index, technical terminology, and pedagogical structure. It's chunked accordingly, and when an LLM retrieves results, it knows this is instructional content. - **A novel** has narrative flow, characters, plot arcs, dialogue. The LLM knows to interpret results as creative fiction. - **Album artwork** is a visual asset tied to an artist, genre, and era. It's embedded multimodally — searchable by both image similarity and text description. - **A journal entry** is personal, temporal, reflective. The LLM treats it differently than a reference manual. This **content-type awareness** flows through every layer: chunking strategy, embedding instructions, re-ranking, and the final LLM prompt. ## Core Architecture | Component | Technology | Purpose | |-----------|-----------|---------| | **Knowledge Graph** | Neo4j 5.x | Relationships + vector storage (no dimension limits) | | **Multimodal Embeddings** | Qwen3-VL-Embedding-8B | Text + image + video in unified vector space (4096d) | | **Multimodal Re-ranking** | Synesis (Qwen3-VL-Reranker-2B) | Cross-attention precision scoring via `/v1/rerank` | | **Web Framework** | Django 5.x + DRF | Auth, admin, API, content management | | **Object Storage** | S3/MinIO | Original content + chunk text storage | | **Async Processing** | Celery + RabbitMQ | Document embedding, graph construction | | **LLM Interface** | MCP Server | Primary interface for Claude, Copilot, etc. | | **GPU Serving** | vLLM + llama.cpp | Local model inference | ## Library Types | Library | Example Content | Multimodal? | Graph Relationships | |---------|----------------|-------------|-------------------| | **Fiction** | Novels, short stories | Cover art | Author → Book → Character → Theme | | **Nonfiction** | History, biography, science writing | Photos, charts | Author → Work → Topic → Person/Place | | **Technical** | Textbooks, manuals, docs | Diagrams, screenshots | Product → Manual → Section → Procedure | | **Music** | Lyrics, liner notes | Album artwork | Artist → Album → Track → Genre | | **Film** | Scripts, synopses | Stills, posters | Director → Film → Scene → Actor | | **Art** | Descriptions, catalogs | The artwork itself | Artist → Piece → Style → Movement | | **Journal** | Personal entries, plans, observations | Photos | Date → Entry → Topic → Person/Place | | **Business** | Proposals, marketing, strategy | Logos, charts | Client → Engagement → Deliverable | | **Finance** | Statements, tax, market commentary | Charts, statement scans | Account → Instrument → Period | ## Search Pipeline ``` Query → Vector Search (Neo4j) + Graph Traversal (Cypher) + Full-Text Search → Candidate Fusion → Qwen3-VL Re-ranking → Ranked Chunks + Metadata → MCP tool result (the calling LLM does its own synthesis) ``` ## Heritage Mnemosyne's RAG pipeline architecture is inspired by [Spelunker](https://git.helu.ca/r/spelunker), an enterprise RFP response platform. The proven patterns — hybrid search, two-stage RAG (responder + reviewer), citation-based retrieval, and async document processing — are carried forward and enhanced with multimodal capabilities and knowledge graph relationships. ## Running Mnemosyne Mnemosyne runs as three cooperating processes: the Django web app (REST API + admin), the MCP server (LLM-facing tools), and one or more Celery workers (async embedding + ingest). All three read configuration from `mnemosyne/.env` (copy from `mnemosyne/.env example` and fill in secrets). Hosts in the Ouranos lab: - **Postgres** — `portia.incus:5432` (Django ORM: users, IngestJob) - **Neo4j** — `ariel.incus:25554` (knowledge graph + vectors) - **RabbitMQ** — `oberon.incus:5672` (Celery broker) - **MinIO** — `nyx.helu.ca:8555` (S3-compatible; `mnemosyne-content` and `daedalus` buckets) - **Memcached** — `127.0.0.1:11211` (task progress) ### One-time setup ```bash cd mnemosyne/ python manage.py migrate # Apply Django ORM migrations python manage.py setup_neo4j_indexes # Create Neo4j vector + full-text indexes python manage.py load_library_types # Load LIBRARY_TYPE_DEFAULTS into Neo4j ``` ### Start the web app The Django REST API serves `/library/api/*` (libraries, collections, items, search, workspaces, ingest) and Django admin. Use Gunicorn in production; `runserver` for dev. ```bash cd mnemosyne/ # Development python manage.py runserver 0.0.0.0:8000 # Production gunicorn --bind 0.0.0.0:8000 --workers 3 mnemosyne.wsgi:application ``` ### Start the MCP server The MCP server exposes the LLM-facing tools (`search`, `get_chunk`, `list_libraries`, `list_collections`, `list_items`, `get_health`) over Streamable HTTP at `/mcp` and SSE at `/mcp/sse`. Run as a separate Uvicorn process, on its own port, so it can be reverse-proxied or scaled independently of the Django app. ```bash cd mnemosyne/ # Single command: ASGI server hosting the FastMCP app uvicorn mnemosyne.asgi:app --host 0.0.0.0 --port 22091 --workers 1 ``` The `mcp_server/asgi.py` mounts FastMCP at `/mcp` (Streamable HTTP) and `/mcp/sse` (SSE), with a `/mcp/health` JSON probe for HAProxy/Pallas. ### Start a Celery worker A single worker that handles all queues (development) plus the focused command Daedalus depends on (the `embedding` queue, where the Daedalus ingest task lives). ```bash cd mnemosyne/ # Development — one worker, all queues celery -A mnemosyne worker -l info -Q celery,embedding,batch # Production — embedding queue (handles Daedalus ingest + embed_item) celery -A mnemosyne worker -l info -Q embedding -c 1 -n embedding@%h # Production — batch queue (collection/library bulk operations) celery -A mnemosyne worker -l info -Q batch -c 2 -n batch@%h # Production — default queue (LLM validation, misc) celery -A mnemosyne worker -l info -Q celery -c 2 -n default@%h ``` Daedalus's `POST /library/api/ingest/` dispatches `library.tasks.ingest_from_daedalus` to the **embedding** queue. If you only run one worker, make sure it consumes `embedding` or that task will sit in the broker. To bypass workers in dev/test, set `CELERY_TASK_ALWAYS_EAGER=True` in `.env`. **Scheduler & monitoring (optional):** ```bash celery -A mnemosyne beat -l info # Periodic task scheduler celery -A mnemosyne flower --port=5555 # Web monitoring UI ``` See [Phase 2: Celery Workers & Scheduler](docs/PHASE_2_EMBEDDING_PIPELINE.md#celery-workers--scheduler) for queue tuning, reliability settings, and task progress tracking. ### Daedalus integration endpoints These endpoints are used by the Daedalus FastAPI backend (HTTP Basic auth). All under `/library/api/`: | Method | Route | Purpose | |--------|-------|---------| | POST | `/workspaces/` | Create a workspace (idempotent on `workspace_id`); body: `{workspace_id, name, library_type, description?}` | | GET | `/workspaces/{workspace_id}/` | Workspace status (item/chunk counts) | | DELETE | `/workspaces/{workspace_id}/` | Delete workspace + reachable content; preserves shared concepts | | POST | `/ingest/` | Queue a file for ingestion + embedding | | GET | `/jobs/{job_id}/` | Poll ingest job status | | POST | `/jobs/{job_id}/retry/` | Re-dispatch a failed job | | GET | `/jobs/?status=&library_uid=` | List recent jobs | See [docs/mnemosyne_integration.md](docs/mnemosyne_integration.md) for the full Daedalus contract. ## Production Deployment Production runs as four containers from a single image (built and pushed by [`.gitea/workflows/cve-scan-docker-build.yml`](.gitea/workflows/cve-scan-docker-build.yml) on every push to `main`): | Service | Role | Port | |---------|------|------| | `web` | Django REST API + admin (gunicorn) | internal :8000 | | `mcp` | FastMCP server (uvicorn) | internal :22091 | | `worker` | Celery worker — embedding/ingest/batch | — | | `nginx` | Reverse proxy + static files | host :23090 | Plus a one-shot `static-init` service that copies `/app/staticfiles` (baked into the image at build time via `collectstatic`) into the shared volume nginx reads from. It runs to completion on every `up`, so static-file changes propagate on each deploy without manual intervention. External services (NOT spun up by compose): Postgres on Portia, Neo4j on Ariel, RabbitMQ on Oberon, S3/MinIO on Nyx, Memcached, embedder + reranker. All reached over the internal 10.10.0.0/24 network. URLs and credentials live in `mnemosyne/.env`. ### First-time bring-up ```bash # Pull the image (or build locally with `docker compose build`) docker compose pull # DB migrations (one-shot) docker compose run --rm web migrate # Neo4j indexes + library_type defaults (one-shot) docker compose run --rm web setup # Bring the stack up docker compose up -d ``` ### Day-to-day ```bash docker compose ps # service status + health docker compose logs -f web # tail web logs docker compose logs -f worker # tail Celery worker logs docker compose restart mcp # restart just the MCP server # After a new image is published: docker compose pull && docker compose up -d ``` ### Things to verify in `mnemosyne/.env` before bringing up The development `.env` has a few values that need adjusting for production: - `DEBUG=False` - `USE_LOCAL_STORAGE=False` (already set; just confirm) - `KVDB_LOCATION=:11211` — `127.0.0.1` does not resolve from inside containers - `AWS_ACCESS_KEY_ID` / `AWS_SECRET_ACCESS_KEY` filled in - `DAEDALUS_S3_*` filled in for cross-bucket reads from the Daedalus bucket - `ALLOWED_HOSTS` includes the public hostname HAProxy routes to (e.g. `mnemosyne.ouranos.helu.ca`) - `LLM_API_SECRETS_ENCRYPTION_KEY` set to a real Fernet key ### Health probes - `GET http://nginx-host:23090/healthz` → proxies to `/mcp/health`, returns `{"status":"ok"}` when the MCP server is up - `GET http://nginx-host:23090/metrics` → Prometheus scrape endpoint, internal-network-only ## Architecture Note: Retrieval, Not Synthesis Mnemosyne is a **retrieval engine**, not a RAG pipeline. It stores, embeds, and ranks — it does not synthesize answers. The earlier roadmap had a server-side RAG layer that took a query and returned a written answer with citations. That layer has been removed. Calling LLMs (Claude via MCP, principally) are perfectly capable of driving iterative retrieval themselves when given the right primitives, and a server-side synthesis hop adds latency, cost, and a place where errors are harder to debug. Letting the calling LLM see chunks directly — and follow citations, pivot mid-search, or call `get_chunk` for full text — beats pre-digesting them. If a "knowledge subagent" is ever wanted (a wrapper that takes a question and returns a written answer), it lives **outside** Mnemosyne as a thin client over the MCP tools, with its own system prompt. No coupling, no extra inference hop inside the server, and the subagent's behavior can iterate independently. ## Documentation - **[Architecture Documentation](docs/mnemosyne.html)** — Full system architecture with diagrams - **[Phase 1: Foundation](docs/PHASE_1_FOUNDATION.md)** — Project skeleton, Neo4j data model, content-type system - **[Phase 2: Embedding Pipeline](docs/PHASE_2_EMBEDDING_PIPELINE.md)** — Qwen3-VL multimodal embedding - **[Phase 3: Search & Re-ranking](docs/PHASE_3_SEARCH_AND_RERANKING.md)** — Hybrid search + re-ranker - **[Phase 5: MCP Server](docs/PHASE_5_MCP_SERVER.md)** — Retrieval primitives for LLMs (`search`, `get_chunk`, `list_libraries`, …) - **[Phase 6: Backport to Spelunker](docs/PHASE_6_BACKPORT_TO_SPELUNKER.md)** — Proven patterns flowing back