Shodh-Memory
Provides persistent memory for robots using ROS2 and Zenoh, enabling context retention across missions.
Click on "Install Server".
Wait a few minutes for the server to deploy. Once ready, it will show a "Started" state.
In the chat, type
@followed by the MCP server name and your instructions, e.g., "@Shodh-Memoryremember that I like coffee"
That's it! The server will respond to your query, and you can continue using it as needed.
Here is a step-by-step guide with screenshots.
AI agents forget everything between sessions. Robots lose context between missions. They repeat mistakes, miss patterns, and treat every interaction like the first one.
Shodh-Memory fixes this. It's persistent memory that actually learns — memories you use often become easier to find, old irrelevant context fades automatically, and recalling one thing brings back related things. Works for chat agents (MCP/HTTP), robots (Zenoh/ROS2), and edge devices. No API keys. No cloud. No external databases. No LLM in the loop. One binary.
Why Not Just Use mem0 / Cognee / Zep?
Shodh | mem0 | Cognee | Zep | |
LLM calls to store a memory | 0 | 2+ per add | 3+ per cognify | 2+ per episode |
External services needed | None | OpenAI + vector DB | OpenAI + Neo4j + vector DB | OpenAI + Neo4j |
Time to store a memory | 55ms | ~20 seconds | seconds | seconds |
Learns from usage | Yes (Hebbian) | No | No | No |
Forgets irrelevant data | Yes (decay) | No | No | Temporal only |
Runs fully offline | Yes | No | No | No |
Robotics / ROS2 native | Yes (Zenoh) | No | No | No |
Binary size | ~17MB | pip install + API keys | pip install + API keys + Neo4j | Cloud only |
Every other memory system delegates intelligence to LLM API calls — that's why they're slow, expensive, and can't work offline.
Related MCP server: aimemory
No LLM in the Loop
Storing a memory makes zero LLM calls. Recalling makes zero LLM calls. Entity extraction, relation typing, knowledge-graph construction, causal tracing, ranking, decay, consolidation — all of it runs locally as algorithms, not API round-trips:
Local embeddings — MiniLM (22MB, INT8) via ONNX Runtime, on-device semantic search
Local NER — GLiNER bi-edge-v2 span typer (ONNX, schema-driven: 141 fine / 18 coarse entity types), auto-downloaded on first run from the pinned release, with a rule-based fallback
Typed relation extraction without an LLM — directed lexical cues + exemplar-matched semantic typing build a typed knowledge graph (
LocatedIn,WorksAt,Causes…) from plain textCausal lineage — "what was the root cause of X?" is answered by walking typed causal edges backward through the graph, not by asking a model
Mathematical memory dynamics — Hebbian strengthening, exponential→power-law decay, spreading activation, long-term potentiation
What that buys you: fully offline operation, millisecond latency instead of multi-second API calls, zero inference cost at any scale, deterministic, testable behavior, and data that never leaves the machine. Your agent's LLM does the reasoning — its memory doesn't need one.
Get Started
Unified CLI
# Download from GitHub Releases (or brew tap varun29ankuS/shodh-memory && brew install shodh-memory)
shodh init # First-time setup — creates config, generates API key, downloads AI model
shodh server # Start the memory server on :3030
shodh setup-hooks # Print instructions to set up Claude Code hooks
shodh tui # Launch the TUI dashboard
shodh status # Check server health
shodh doctor # Diagnose issuesOne binary, all functionality. No Docker, no API keys, no external dependencies.
Claude Code
# 1. Add the MCP server (auto-downloads the backend binary)
claude mcp add shodh-memory -- npx -y @shodh/memory-mcp
# 2. Enable automatic memory capture (optional but recommended)
npx @shodh/memory-mcp setup-hooksStep 1 gives Claude persistent memory tools. Step 2 installs Claude Code hooks that automatically capture context from every session — memories surface without you having to ask.
# 1. Start the server
docker run -d -p 3030:3030 -v shodh-data:/data varunshodh/shodh-memory
# 2. Add to Claude Code
claude mcp add shodh-memory -- npx -y @shodh/memory-mcpFor Linux users who want the Rust HTTP server supervised separately from MCP clients, see Direct server mode with systemd.
{
"mcpServers": {
"shodh-memory": {
"command": "npx",
"args": ["-y", "@shodh/memory-mcp"]
}
}
}For local use, no API key is needed — one is generated automatically. For remote servers, add "env": { "SHODH_API_KEY": "your-key" }.
Python
pip install shodh-memoryfrom shodh_memory import Memory
memory = Memory(storage_path="./my_data")
memory.remember("User prefers dark mode", memory_type="Decision")
results = memory.recall("user preferences", limit=5)Rust
[dependencies]
shodh-memory = "0.1"use shodh_memory::{MemorySystem, MemoryConfig};
let memory = MemorySystem::new(MemoryConfig::default())?;
memory.remember("user-1", "User prefers dark mode", MemoryType::Decision, vec![])?;
let results = memory.recall("user-1", "user preferences", 5)?;Docker
docker run -d -p 3030:3030 -v shodh-data:/data varunshodh/shodh-memoryWhat It Does
You use a memory often → it becomes easier to find (Hebbian learning)
You stop using a memory → it fades over time (activation decay)
You recall one memory → related memories surface too (spreading activation)
A connection is used → it becomes permanent (long-term potentiation)Under the hood, memories flow through three tiers:
Working Memory ──overflow──▶ Session Memory ──importance──▶ Long-Term Memory
(100 items) (100 MB) (RocksDB)This is based on Cowan's working memory model and Wixted's memory decay research. The neuroscience isn't a gimmick — it's why the system gets better with use instead of just accumulating data.
Performance
Operation | Latency |
Store memory (API response) | <200ms |
Store memory (core) | 55-60ms |
Semantic search | 34-58ms |
Tag search | ~1ms |
Entity lookup | 763ns |
Graph traversal (3-hop) | 30µs |
Single binary. No GPU required. Content-hash dedup ensures identical memories are never stored twice.
51 MCP Tools
Full list of tools available to Claude, Cursor, and other MCP clients:
remember · recall · recall_by_tags · proactive_context · context_summary · list_memories · read_memory · forget
quick_recall · query · topic · what_i_know · recent_memories · pending_work · count · memory_health · session_summary
session_digest · session_history · fact_narratives · purge_facts
add_todo · list_todos · update_todo · complete_todo · delete_todo · reorder_todo · list_subtasks · add_todo_comment · list_todo_comments · update_todo_comment · delete_todo_comment · todo_stats
add_project · list_projects · archive_project · delete_project
set_reminder · list_reminders · dismiss_reminder
memory_stats · verify_index · repair_index · token_status · reset_token_session · consolidation_report · backup_create · backup_list · backup_verify · backup_restore · backup_purge
REST API
160+ endpoints on http://localhost:3030. All /api/* endpoints require X-API-Key header.
# Store a memory
curl -X POST http://localhost:3030/api/remember \
-H "Content-Type: application/json" \
-H "X-API-Key: your-key" \
-d '{"user_id": "user-1", "content": "User prefers dark mode", "memory_type": "Decision"}'
# Search memories
curl -X POST http://localhost:3030/api/recall \
-H "Content-Type: application/json" \
-H "X-API-Key: your-key" \
-d '{"user_id": "user-1", "query": "user preferences", "limit": 5}'Robotics & ROS2
Shodh-Memory isn't just for chat agents. It's persistent memory for robots — Spot, drones, humanoids, any system running ROS2 or Zenoh. No cloud, survives power cycles, learns from rewards, speaks Zenoh natively.
# Enable Zenoh transport (compile with --features zenoh)
SHODH_ZENOH_ENABLED=true SHODH_ZENOH_LISTEN=tcp/0.0.0.0:7447 shodh server
# ROS2 robots connect via zenoh-bridge-ros2dds or rmw_zenoh — zero code changes
ros2 run zenoh_bridge_ros2dds zenoh_bridge_ros2ddsSee Robotics Quickstart for full setup and examples.
What robots can do over Zenoh:
Operation | Key Expression | Description |
Remember |
| Store with GPS, local position, heading, sensor data, mission context |
Recall |
| Spatial search (haversine), mission replay, action-outcome filtering |
Stream |
| Auto-remember high-frequency sensor data via extraction pipeline |
Mission |
| Track mission boundaries, searchable across missions |
Fleet |
| Automatic peer discovery via Zenoh liveliness tokens |
Each robot uses its own user_id as the key segment (e.g., shodh/spot-1/remember). The robot_id is an optional payload field for fleet grouping.
Every Experience carries 26 robotics-specific fields: geo_location, local_position, heading, sensor_data, robot_id, mission_id, action_type, reward, terrain_type, nearby_agents, decision_context, action_params, outcome_type, confidence, failure/anomaly tracking, recovery actions, and prediction learning.
{
"user_id": "spot-1",
"content": "Detected crack in concrete at waypoint alpha",
"robot_id": "spot_v2",
"mission_id": "building_inspection_2026",
"geo_location": [37.7749, -122.4194, 10.0],
"local_position": [12.5, 3.2, 0.0],
"heading": 90.0,
"sensor_data": {"battery": 72.5, "temperature": 28.3},
"action_type": "inspect",
"reward": 0.9,
"terrain_type": "indoor",
"tags": ["crack", "concrete", "structural"]
}{
"user_id": "spot-1",
"query": "structural damage near entrance",
"mode": "spatial",
"lat": 37.7749,
"lon": -122.4194,
"radius_meters": 50.0,
"mission_id": "building_inspection_2026"
}SHODH_ZENOH_ENABLED=true # Enable Zenoh transport
SHODH_ZENOH_MODE=peer # peer | client | router
SHODH_ZENOH_LISTEN=tcp/0.0.0.0:7447 # Listen endpoints
SHODH_ZENOH_CONNECT=tcp/1.2.3.4:7447 # Connect endpoints
SHODH_ZENOH_PREFIX=shodh # Key expression prefix
# Auto-subscribe to ROS2 topics (via zenoh-bridge-ros2dds)
SHODH_ZENOH_AUTO_TOPICS='[
{"key_expr": "rt/spot1/status", "user_id": "spot-1", "mode": "sensor"},
{"key_expr": "rt/nav/events", "user_id": "spot-1", "mode": "event"}
]'Works with ROS2 Kilted (rmw_zenoh), PX4 drones, Boston Dynamics Spot, humanoids — anything that speaks Zenoh or ROS2 DDS.
Platform Support
Linux x86_64 · Linux ARM64 · macOS Apple Silicon · macOS Intel · Windows x86_64
Production Deployment
SHODH_ENV=production # Production mode
SHODH_API_KEYS=key1,key2,key3 # Comma-separated API keys
SHODH_HOST=127.0.0.1 # Bind address (default: localhost)
SHODH_PORT=3030 # Port (default: 3030)
SHODH_MEMORY_PATH=/var/lib/shodh # Data directory
# SHODH_IPC_ENABLED=false # Local IPC is enabled by default; false disables it
# SHODH_IPC_ENDPOINT=/private/path/shodh-memory.sock # Optional platform-specific override
# SHODH_IPC_REQUIRED=true # Fail closed instead of falling back to HTTP
SHODH_REQUEST_TIMEOUT=60 # Request timeout in seconds
SHODH_MAX_CONCURRENT=200 # Max concurrent requests
SHODH_ROCKSDB_BLOCK_CACHE_MB=256 # Shared RocksDB block cache (MiB)
SHODH_CORS_ORIGINS=https://app.example.comThe server enables authenticated local IPC by default and keeps HTTP available.
Native shodh serve prefers the platform-default IPC endpoint and falls back to
SHODH_API_URL unless fail-closed mode is enabled; the TypeScript MCP client uses IPC only when
SHODH_IPC_ENDPOINT is set. See the local IPC architecture
for platform defaults, security properties, and limitations.
services:
shodh-memory:
image: varunshodh/shodh-memory:latest
environment:
- SHODH_ENV=production
- SHODH_HOST=0.0.0.0
- SHODH_API_KEYS=${SHODH_API_KEYS}
volumes:
- shodh-data:/data
networks:
- internal
caddy:
image: caddy:latest
ports:
- "443:443"
volumes:
- ./Caddyfile:/etc/caddy/Caddyfile
networks:
- internal
volumes:
shodh-data:
networks:
internal:The server binds to 127.0.0.1 by default. For network deployments, place behind a reverse proxy:
memory.example.com {
reverse_proxy localhost:3030
}Community
Project | Description | Author |
Edge-native implementation on Cloudflare Workers |
References
[1] Cowan, N. (2010). The Magical Mystery Four. Current Directions in Psychological Science. [2] Magee & Grienberger (2020). Synaptic Plasticity Forms and Functions. Annual Review of Neuroscience. [3] Subramanya et al. (2019). DiskANN. NeurIPS 2019.
License
Apache 2.0
Keywords: LLM-free memory · no LLM in the loop · local-first AI memory · offline agent memory · persistent memory for AI agents · long-term memory for LLM agents · MCP memory server · Claude Code memory · knowledge graph memory · hybrid vector + graph search · causal lineage · Hebbian learning · memory decay · edge AI memory · robotics memory · ROS2 / Zenoh robot memory · air-gapped RAG alternative
This server cannot be installed
Maintenance
Resources
Unclaimed servers have limited discoverability.
Looking for Admin?
If you are the server author, to access and configure the admin panel.
Latest Blog Posts
- Your AI Chatbot Just Exposed Your CEO's Salary to an InternBy Om-Shree-0709 on .Agent IdentityMCP SecurityOAuth Delegation
- Why MCP Servers Need Execution Sandboxing (And Why Your Current Stack Isn't Enough)By Om-Shree-0709 on .Agentic AiPrompt InjectionWebAssembly
MCP directory API
We provide all the information about MCP servers via our MCP API.
curl -X GET 'https://glama.ai/api/mcp/v1/servers/varun29ankuS/shodh-memory'
If you have feedback or need assistance with the MCP directory API, please join our Discord server