contextfs 0.1.7

Universal AI memory layer - cross-client, cross-repo context management with RAG

ContextFS

Universal AI Memory Layer - Cross-client, cross-repo context management with RAG.

Works with Claude Code, Claude Desktop, Gemini CLI, Codex CLI, and any MCP client.

Documentation | Developer Memory Workflow Guide | GitHub

Features

• Semantic Search - ChromaDB + sentence-transformers for intelligent retrieval
• Auto Code Indexing - Automatically index repositories for semantic code search
• Dual Storage - Smart routing between FTS (keywords) and RAG (semantic)
• Cross-Repo Memory - Memories track source repository automatically
• Session Management - Automatic capture and replay of conversation context
• MCP Server - Standard protocol for universal client support
• Plugins - Native integrations for Claude Code, Gemini CLI, Codex CLI
• Web UI - Browse and search memories with side-by-side FTS/RAG comparison

Quick Start

# Run with uvx (no install needed)
uvx contextfs --help
uvx contextfs-mcp  # Start MCP server

# Or install with pip
pip install contextfs

# Or install from source
git clone https://github.com/MagnetonIO/contextfs.git
cd contextfs
pip install -e .

Usage

CLI

# Save memories
contextfs save "Use PostgreSQL for the database" --type decision --tags db,architecture
contextfs save "API uses snake_case keys" --type fact --tags api,style

# Search
contextfs search "database decisions"
contextfs search "api conventions" --type fact

# Recall specific memory
contextfs recall abc123

# List recent
contextfs list --limit 20 --type decision

# Sessions
contextfs sessions

Python API

from contextfs import ContextFS, MemoryType

ctx = ContextFS()

# Save
ctx.save(
    "Use JWT for authentication",
    type=MemoryType.DECISION,
    tags=["auth", "security"],
)

# Search
results = ctx.search("authentication")
for r in results:
    print(f"[{r.score:.2f}] {r.memory.content}")

# Get context for a task
context = ctx.get_context_for_task("implement login")
# Returns formatted strings ready for prompt injection

MCP Server

Add to your MCP client config (Claude Code, Claude Desktop):

{
  "mcpServers": {
    "contextfs": {
      "command": "uvx",
      "args": ["contextfs-mcp"]
    }
  }
}

Or with Python directly:

{
  "mcpServers": {
    "contextfs": {
      "command": "python",
      "args": ["-m", "contextfs.mcp_server"]
    }
  }
}

MCP Tools:

Tool	Description
contextfs_save	Save memory (auto-indexes repo, logs to session)
contextfs_search	Semantic search with cross-repo support
contextfs_recall	Get specific memory by ID
contextfs_list	List recent memories
contextfs_index	Index current repository for code search
contextfs_list_repos	List all repositories with memories
contextfs_list_projects	List all projects
contextfs_sessions	List sessions
contextfs_load_session	Load session messages
contextfs_message	Add message to current session

MCP Prompts:

Prompt	Description
contextfs-save-memory	Guided memory save with type selection
contextfs-index	Index repository for semantic search
contextfs-session-guide	Instructions for session capture
contextfs-save-session	Save current session

Plugins

Claude Code

# Install hooks for automatic context capture
python -c "from contextfs.plugins.claude_code import install_claude_code; install_claude_code()"

Gemini CLI / Codex CLI

from contextfs.plugins.gemini import install_gemini
from contextfs.plugins.codex import install_codex

install_gemini()  # For Gemini CLI
install_codex()   # For Codex CLI

Cross-Repo Namespaces

ContextFS automatically detects your git repository and isolates memories:

# In repo A
ctx = ContextFS()  # namespace = "repo-<hash-of-repo-a>"
ctx.save("Repo A specific fact")

# In repo B
ctx = ContextFS()  # namespace = "repo-<hash-of-repo-b>"
# Won't see Repo A's memories

# Global namespace (shared across repos)
ctx = ContextFS(namespace_id="global")
ctx.save("Shared across all repos")

Configuration

Environment variables:

CONTEXTFS_DATA_DIR=~/.contextfs
CONTEXTFS_EMBEDDING_MODEL=all-MiniLM-L6-v2
CONTEXTFS_CHUNK_SIZE=1000
CONTEXTFS_DEFAULT_SEARCH_LIMIT=10
CONTEXTFS_AUTO_SAVE_SESSIONS=true
CONTEXTFS_AUTO_LOAD_ON_STARTUP=true

Supported Languages

ContextFS supports 50+ file types for code ingestion:

Top 20 Programming Languages: Python, JavaScript, TypeScript, Java, C++, C, C#, Go, Rust, PHP, Ruby, Swift, Kotlin, Scala, R, MATLAB, Perl, Lua, Haskell, Elixir

Plus: Dart, Julia, Clojure, Erlang, F#, Zig, Nim, Crystal, Groovy, and more.

Web: HTML, CSS, SCSS, JSX, TSX, Vue, Svelte

Config: JSON, YAML, TOML, XML, INI

Documentation: Markdown, RST, TeX, Org

Developer Memory Workflow (DMW)

ContextFS enables persistent developer memory that follows you across sessions:

# Save decisions as you make them
ctx.save(
    "Use PostgreSQL for production",
    type=MemoryType.DECISION,
    tags=["database", "architecture"]
)

# Document bug fixes for future reference
ctx.save(
    "CORS fix: allow_methods=['*'] required for credentials",
    type=MemoryType.ERROR,
    tags=["cors", "api", "bug-fix"]
)

# Later sessions can search for context
results = ctx.search("database decisions")
results = ctx.search("CORS issues", type=MemoryType.ERROR)

Memory Types

Type	Use Case
fact	Project configurations, conventions
decision	Architectural choices with rationale
code	Algorithms, patterns, important snippets
error	Bug fixes, error patterns, solutions
procedural	Setup guides, deployment steps
episodic	Session transcripts, conversations

Solo vs Team Workflows

• Solo: Per-repo namespace, personal memory bank
• Team: Shared namespace, collective knowledge base

See the full Developer Memory Workflow Guide for detailed patterns.

Web UI

Start the web server to browse and search memories:

contextfs web
# Opens at http://localhost:8000

contextfs web --port 3000  # Custom port

Features:

• Browse all memories with filtering by type, repo, and project
• Side-by-side FTS vs RAG search comparison
• Session browser and message viewer
• Real-time memory statistics

Architecture

┌─────────────────────────────────────────────────────────────┐
│                     ContextFS Core                          │
├─────────────────────────────────────────────────────────────┤
│  ┌──────────┐  ┌──────────┐  ┌──────────┐  ┌──────────┐    │
│  │   CLI    │  │   MCP    │  │  Web UI  │  │  Python  │    │
│  │          │  │  Server  │  │          │  │   API    │    │
│  └────┬─────┘  └────┬─────┘  └────┬─────┘  └────┬─────┘    │
│       │             │             │             │           │
│       └─────────────┴──────┬──────┴─────────────┘           │
│                            │                                │
│                    ┌───────▼───────┐                        │
│                    │  ContextFS()  │                        │
│                    │   core.py     │                        │
│                    └───────┬───────┘                        │
│                            │                                │
│          ┌─────────────────┼─────────────────┐              │
│          │                 │                 │              │
│  ┌───────▼───────┐ ┌───────▼───────┐ ┌───────▼───────┐     │
│  │  AutoIndexer  │ │  RAG Backend  │ │  FTS Backend  │     │
│  │  (Code Index) │ │  (ChromaDB)   │ │  (SQLite)     │     │
│  └───────────────┘ └───────────────┘ └───────────────┘     │
└─────────────────────────────────────────────────────────────┘

Dual Storage

SQLite + FTS5	ChromaDB
Fast keyword queries	Vector similarity search
Session/message storage	Code semantic search
Exact matches	Conceptual matching
Metadata & filtering	Embedding-based retrieval

License

MIT

Authors

Matthew Long and The YonedaAI Collaboration