mnemocore 4.5.0

MnemoCore – Infrastructure for Persistent Cognitive Memory. A hierarchical AI memory engine with hot/warm/cold tiers, vector search, and subconscious consolidation.

MnemoCore

Infrastructure for Persistent Cognitive Memory

"Memory is not a container. It is a living process — a holographic continuum where every fragment contains the whole."

---

What is MnemoCore?

MnemoCore is a research-grade cognitive memory infrastructure that gives AI agents a brain — not just a database.

Traditional vector stores retrieve. MnemoCore thinks. It is built on the mathematical framework of Binary Hyperdimensional Computing (HDC) and Vector Symbolic Architectures (VSA), principles rooted in Pentti Kanerva's landmark 2009 theory of cognitive computing. Every memory is encoded as a 16,384-dimensional binary holographic vector — a format that is simultaneously compact (2,048 bytes), noise-tolerant (Hamming geometry), and algebraically rich (XOR binding, majority bundling, circular permutation).

At its core lives the Holographic Active Inference Memory (HAIM) Engine — a system that does not merely answer queries, but:

• Evaluates the epistemic novelty of every incoming memory before deciding to store it
• Dreams — strengthening synaptic connections between related memories during idle cycles
• Reasons by analogy — if king:man :: ?:woman, the VSA soul computes queen
• Self-organizes into tiered storage based on biologically-inspired Long-Term Potentiation (LTP)
• Scales from a single process to distributed nodes targeting 1B+ memories

Phase 4.x introduces cognitive enhancements including contextual masking, reliability feedback loops, semantic consolidation, gap detection/filling, and temporal recall (episodic chaining + chrono-weighted query).

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Table of Contents

• Architecture
• Core Technology
• The Memory Lifecycle
• Tiered Storage
• Phase 4.0 Cognitive Enhancements
• API Reference
• Python Library Usage
• Installation
• Configuration
• MCP Server Integration
• Observability
• Roadmap
• Contributing

---

Architecture

┌─────────────────────────────────────────────────────────────────┐
│                        MnemoCore Stack                          │
├─────────────────────────────────────────────────────────────────┤
│                                                                 │
│   ┌──────────────────────────────────────────────────────────┐  │
│   │              REST API  (FastAPI / Async)                  │  │
│   │   /store  /query  /feedback  /insights/gaps  /stats      │  │
│   │   Rate Limiting · API Key Auth · Prometheus Metrics      │  │
│   └─────────────────────────┬────────────────────────────────┘  │
│                             │                                   │
│   ┌─────────────────────────▼────────────────────────────────┐  │
│   │                  HAIM Engine                              │  │
│   │                                                          │  │
│   │   ┌──────────────┐  ┌──────────────┐  ┌──────────────┐  │  │
│   │   │ Text Encoder │  │  EIG / Epist │  │  Subconsc.   │  │  │
│   │   │ (token→HDV)  │  │  Drive       │  │  Dream Loop  │  │  │
│   │   └──────────────┘  └──────────────┘  └──────────────┘  │  │
│   │                                                          │  │
│   │   ┌──────────────────────────────────────────────────┐  │  │
│   │   │            Binary HDV Core (VSA)                 │  │  │
│   │   │  XOR bind · majority_bundle · permute · Hamming  │  │  │
│   │   └──────────────────────────────────────────────────┘  │  │
│   └─────────────────────────┬────────────────────────────────┘  │
│                             │                                   │
│   ┌─────────────────────────▼────────────────────────────────┐  │
│   │                  Tier Manager                             │  │
│   │                                                          │  │
│   │   🔥 HOT         🌡 WARM            ❄️ COLD               │  │
│   │   In-Memory      Redis / mmap       Qdrant / Disk / S3   │  │
│   │   ≤2,000 nodes   ≤100,000 nodes     ∞ nodes              │  │
│   │   <1ms           <10ms              <100ms               │  │
│   └──────────────────────────────────────────────────────────┘  │
│                                                                 │
│   ┌─────────────────────────────────────────────────────────┐   │
│   │                  Conceptual Layer ("The Soul")           │   │
│   │   ConceptualMemory · Analogy Engine · Symbol Algebra     │   │
│   └─────────────────────────────────────────────────────────┘   │
│                                                                 │
└─────────────────────────────────────────────────────────────────┘

Component Overview

Component	File	Responsibility
HAIM Engine	src/core/engine.py	Central cognitive coordinator — store, query, dream, delete
BinaryHDV	src/core/binary_hdv.py	16384-dim binary vector math (XOR, Hamming, bundle, permute)
TextEncoder	src/core/binary_hdv.py	Token→HDV pipeline with positional permutation binding
MemoryNode	src/core/node.py	Memory unit with LTP, epistemic values, tier state
TierManager	src/core/tier_manager.py	HOT/WARM/COLD orchestration with LTP-driven eviction
SynapticConnection	src/core/synapse.py	Hebbian synapse with strength, decay, and fire tracking
ConceptualMemory	src/core/holographic.py	VSA soul for analogy and cross-domain symbolic reasoning
AsyncRedisStorage	src/core/async_storage.py	Async Redis backend (WARM tier + pub/sub)
API	src/api/main.py	FastAPI REST interface with async wrappers and middleware
MCP Server	src/mcp/server.py	Model Context Protocol adapter for agent tool integration

---

Core Technology: Binary HDV & VSA

MnemoCore's mathematical foundation is Hyperdimensional Computing — a computing paradigm that encodes information in very high-dimensional binary vectors (HDVs), enabling noise-tolerant, distributed, and algebraically composable representations.

The Vector Space

Every piece of information — a word, a sentence, a concept, a goal — is encoded as a 16,384-dimensional binary vector:

Dimension D = 16,384 bits = 2,048 bytes per vector
Storage:      packed as numpy uint8 arrays
Similarity:   Hamming distance (popcount of XOR result)
Random pair:  ~50% similarity (orthogonality by probability)

At this dimensionality, two random vectors will differ in ~50% of bits. This near-orthogonality is the foundation of the system's expressive power — related concepts cluster together while unrelated ones remain maximally distant.

VSA Algebra

Four primitive operations make the entire system work:

Binding — XOR ⊕

Creates an association between two concepts. Crucially, the result is dissimilar to both inputs (appears as noise), making it a true compositional operation.

# Bind content to its context
bound = content_vec.xor_bind(context_vec)  # content ⊕ context

# Self-inverse: unbind by re-binding
recovered = bound.xor_bind(context_vec)   # ≈ content (XOR cancels)

Key mathematical properties:

• Self-inverse: A ⊕ A = 0 (XOR cancels itself)
• Commutative: A ⊕ B = B ⊕ A
• Distance-preserving: hamming(A⊕C, B⊕C) = hamming(A, B)

Bundling — Majority Vote

Creates a prototype that is similar to all inputs. This is how multiple memories combine into a concept.

from mnemocore.core.binary_hdv import majority_bundle

# Create semantic prototype from related memories
concept = majority_bundle([vec_a, vec_b, vec_c, vec_d])  # similar to all inputs

Permutation — Circular Shift

Encodes sequence and roles without separate positional embeddings.

# Positional encoding: token at position i
positioned = token_vec.permute(shift=i)  # circular bit-shift

# Encode "hello world" with order information
hello_positioned = encoder.get_token_vector("hello").permute(0)
world_positioned = encoder.get_token_vector("world").permute(1)
sentence_vec = majority_bundle([hello_positioned, world_positioned])

Similarity — Hamming Distance

Fast comparison using vectorized popcount over XOR results:

# Normalized similarity: 1.0 = identical, 0.5 = unrelated
sim = vec_a.similarity(vec_b)  # 1.0 - hamming(a, b) / D

# Batch nearest-neighbor search (no Python loops)
distances = batch_hamming_distance(query, database_matrix)

Text Encoding Pipeline

The TextEncoder converts natural language to HDVs using a token-position binding scheme:

"Python TypeError" →
  token_hdv("python") ⊕ permute(0)  =  positioned_0
  token_hdv("typeerror") ⊕ permute(1)  =  positioned_1
  majority_bundle([positioned_0, positioned_1])  =  final_hdv

Token vectors are deterministic — seeded via SHAKE-256 hash — meaning the same word always produces the same base vector, enabling cross-session consistency without a vocabulary file.

---

The Memory Lifecycle

Every memory passes through a defined lifecycle from ingestion to long-term storage:

Incoming Content
      │
      ▼
 ┌─────────────┐
 │ TextEncoder │  → 16,384-dim binary HDV
 └──────┬──────┘
        │
        ▼
 ┌──────────────────┐
 │ Context Binding  │  → XOR bind with goal_context if present
 │  (XOR)           │     bound_vec = content ⊕ context
 └──────┬───────────┘
        │
        ▼
 ┌──────────────────┐
 │  EIG Evaluation  │  → Epistemic Information Gain
 │  (Novelty Check) │     eig = normalized_distance(vec, context_vec)
 └──────┬───────────┘     tag "epistemic_high" if eig > threshold
        │
        ▼
 ┌─────────────────┐
 │  MemoryNode     │  → id, hdv, content, metadata
 │  Creation       │     ltp_strength = I × log(1+A) × e^(-λT)
 └──────┬──────────┘
        │
        ▼
 ┌─────────────────┐
 │  HOT Tier       │  → In-memory dict (max 2000 nodes)
 │  (RAM)          │     LTP eviction: low-LTP nodes → WARM
 └──────┬──────────┘
        │     (background)
        ▼
 ┌─────────────────┐
 │ Subconscious    │  → Dream cycle fires
 │ Dream Loop      │     Query similar memories
 └──────┬──────────┘     Strengthen synapses (Hebbian)
        │
        ▼
 ┌─────────────────┐
 │  WARM Tier      │  → Redis-backed persistence
 │  (Redis/mmap)   │     async dual-write + pub/sub events
 └──────┬──────────┘
        │     (scheduled, nightly)
        ▼
 ┌─────────────────┐
 │  COLD Tier      │  → Qdrant / Disk / S3
 │  (Archival)     │     ANN search, long-term persistence
 └─────────────────┘

Long-Term Potentiation (LTP)

Memories are not equal. Importance is computed dynamically using a biologically-inspired LTP formula:

S = I × log(1 + A) × e^(-λ × T)

Where:
  S = LTP strength (determines tier placement)
  I = Importance (derived from epistemic + pragmatic value)
  A = Access count (frequency of retrieval)
  λ = Decay lambda (configurable, default ~0.01)
  T = Age in days

Memories with high LTP remain in HOT tier. Those that decay are automatically promoted to WARM, then COLD — mirroring how biological memory consolidates from working memory to long-term storage.

Synaptic Connections

Memories are linked by SynapticConnection objects that implement Hebbian learning: "neurons that fire together, wire together."

Every time two memories are co-retrieved (via the background dream loop or explicit binding), their synaptic strength increases. During query time, synaptic spreading amplifies scores of connected memories even when they do not directly match the query vector — enabling associative recall.

# Explicit synapse creation
engine.bind_memories(id_a, id_b, success=True)

# Associative spreading: query top seeds spread activation to neighbors
# neighbor_score += seed_score × synapse_strength × 0.3

---

Tiered Storage: HOT / WARM / COLD

Tier	Backend	Capacity	Latency	Eviction Trigger
🔥 HOT	Python dict (RAM)	2,000 nodes	< 1ms	LTP < threshold
🌡 WARM	Redis + mmap	100,000 nodes	< 10ms	Age + low access
❄️ COLD	Qdrant / Disk / S3	Unlimited	< 100ms	Manual / scheduled

Promotion is automatic: accessing a WARM or COLD memory re-promotes it to HOT based on recalculated LTP. Eviction is LRU-weighted by LTP strength — the most biologically active memories always stay hot.

---

Phase 4.0 Cognitive Enhancements

MnemoCore Phase 4.0 introduces five architectural enhancements that elevate the system from data retrieval to cognitive reasoning. Full implementation specifications are in COGNITIVE_ENHANCEMENTS.md.

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1. Contextual Query Masking (XOR Attention)

Problem: Large multi-project deployments suffer from cross-context interference. A query for "Python error handling" returns memories from all projects equally, diluting precision.

Solution: Bidirectional XOR context binding — apply the same context vector at both storage and query time:

Store:  bound_vec   = content ⊕ context_vec
Query:  masked_query = query   ⊕ context_vec

Result: (content ⊕ C) · (query ⊕ C) ≈ content · query
        (context cancels, cross-project noise is suppressed)

# Store memories in a project context
engine.store("API rate limiting logic", goal_id="ProjectAlpha")
engine.store("Garden watering schedule", goal_id="HomeProject")

# Query with context mask — only ProjectAlpha memories surface
results = engine.query("API logic", top_k=5, context="ProjectAlpha")

Expected impact: +50–80% query precision (P@5) in multi-project deployments.

---

2. Reliability Feedback Loop (Self-Correcting Memory)

Problem: Wrong or outdated memories persist with the same retrieval weight as correct ones. The system has no mechanism to learn from its own mistakes.

Solution: Bayesian reliability scoring with real-world outcome feedback:

reliability = (successes + 1) / (successes + failures + 2)  # Laplace smoothing

LTP_enhanced = I × log(1+A) × e^(-λT) × reliability

# After using a retrieved memory:
engine.provide_feedback(memory_id, outcome=True)   # Worked → boost reliability
engine.provide_feedback(memory_id, outcome=False)  # Failed → reduce reliability

# System auto-tags consistently wrong memories as "unreliable"
# and verified memories (>5 successes, >0.8 score) as "verified"

The system converges toward high-confidence knowledge — memories that have demonstrably worked in practice rank above theoretically similar but unproven ones.

---

3. Semantic Memory Consolidation (Dream-Phase Synthesis)

Problem: Episodic memory grows without bound. 1,000 memories about "Python TypeError" are semantically equivalent but consume 2MB of vector space and slow down linear scan queries.

Solution: Nightly ConsolidationWorker clusters similar WARM tier memories and replaces them with a semantic anchor — a majority-bundled prototype:

BEFORE consolidation:
  mem_001: "Python TypeError in line 45"    (2KB vector)
  mem_002: "TypeError calling function"     (2KB vector)
  ...   ×100 similar memories              (200KB total)

AFTER consolidation:
  anchor_001: "Semantic pattern: python typeerror function"
              metadata: {source_count: 100, confidence: 0.94}
              hdv: majority_bundle([mem_001.hdv, ..., mem_100.hdv])  (2KB)

# Manual trigger (runs automatically at 3 AM)
stats = engine.trigger_consolidation()
# → {"abstractions_created": 12, "memories_consolidated": 847}

# Via API (admin endpoint)
POST /admin/consolidate

Expected impact: 70–90% memory footprint reduction, 10x query speedup at scale.

---

4. Auto-Associative Cleanup Loop (Vector Immunology)

Problem: Holographic vectors degrade over time through repeated XOR operations, noise accumulation, and long-term storage drift. After months of operation, retrieved vectors become "blurry" and similarity scores fall.

Solution: Iterative attractor dynamics — when a retrieved vector appears noisy, snap it to the nearest stable concept in a codebook of high-confidence prototypes:

noisy_vec → find K nearest in codebook
         → majority_bundle(K neighbors)
         → check convergence (Hamming distance < 5%)
         → iterate until converged or max iterations reached

# Cleanup runs automatically on retrieval when noise > 15%
node = engine.get_memory(memory_id, auto_cleanup=True)
# node.metadata["cleaned"] = True  (if cleanup was triggered)
# node.metadata["cleanup_iterations"] = 3

# Codebook is auto-populated from most-accessed, high-reliability memories

Expected impact: Maintain >95% similarity fidelity even after years of operation.

---

5. Knowledge Gap Detection (Proactive Curiosity)

Problem: The system is entirely reactive — it answers queries but never identifies what it doesn't know. True cognitive autonomy requires self-directed learning.

Solution: Temporal co-occurrence analysis — detect concepts that are frequently accessed close in time but have no synaptic connection, flagging them as knowledge gaps:

# Automatically runs hourly
gaps = engine.detect_knowledge_gaps(time_window_seconds=300)

# Returns structured insight:
# [
#   {
#     "concept_a": "Python asyncio event loop",
#     "concept_b": "FastAPI dependency injection",
#     "suggested_query": "How does asyncio relate to FastAPI dependency injection?",
#     "co_occurrence_count": 4
#   }
# ]

# Query endpoint
GET /insights/gaps?lookback_hours=24

# Fill gap manually (or via LLM agent)
POST /insights/fill-gap
{"concept_a_id": "mem_xxx", "concept_b_id": "mem_yyy",
 "explanation": "FastAPI uses asyncio's event loop internally..."}

The system becomes capable of saying what it doesn't understand and requesting clarification — the first step toward genuine cognitive autonomy.

---

API Reference

Authentication

All endpoints require an API key via the X-API-Key header:

export HAIM_API_KEY="your-secure-key"
curl -H "X-API-Key: $HAIM_API_KEY" ...

Endpoints

POST /store

Store a new memory with optional context binding.

Request:
{
  "content": "FastAPI uses Pydantic v2 for request validation.",
  "metadata": {"source": "docs", "tags": ["python", "fastapi"]},
  "context": "ProjectAlpha",
  "agent_id": "agent-001",
  "ttl": 3600
}

Response:
{
  "ok": true,
  "memory_id": "mem_1739821234567",
  "message": "Stored memory: mem_1739821234567"
}

POST /query

Query memories by semantic similarity with optional context masking.

Request:
{
  "query": "How does FastAPI handle request validation?",
  "top_k": 5,
  "context": "ProjectAlpha"
}

Response:
{
  "ok": true,
  "query": "How does FastAPI handle request validation?",
  "results": [
    {
      "id": "mem_1739821234567",
      "content": "FastAPI uses Pydantic v2 for request validation.",
      "score": 0.8923,
      "metadata": {"source": "docs"},
      "tier": "hot"
    }
  ]
}

POST /feedback

Report outcome of a retrieved memory (Phase 4.0 reliability loop).

Request:
{
  "memory_id": "mem_1739821234567",
  "outcome": true,
  "comment": "This solution worked perfectly."
}

Response:
{
  "ok": true,
  "memory_id": "mem_1739821234567",
  "reliability_score": 0.714,
  "success_count": 4,
  "failure_count": 1
}

GET /memory/{memory_id}

Retrieve a specific memory with full metadata.

Response:
{
  "id": "mem_1739821234567",
  "content": "...",
  "metadata": {...},
  "created_at": "2026-02-17T20:00:00Z",
  "ltp_strength": 1.847,
  "epistemic_value": 0.73,
  "reliability_score": 0.714,
  "tier": "hot"
}

DELETE /memory/{memory_id}

Delete memory from all tiers and clean up synapses.

POST /concept

Define a symbolic concept for analogical reasoning.

{"name": "king", "attributes": {"gender": "man", "role": "ruler", "domain": "royalty"}}

POST /analogy

Solve analogies using VSA algebra: source:value :: target:?

Request:  {"source_concept": "king", "source_value": "man", "target_concept": "queen"}
Response: {"results": [{"value": "woman", "score": 0.934}]}

GET /insights/gaps

Detect knowledge gaps from recent temporal co-activity (Phase 4.0).

Response:
{
  "gaps_detected": 3,
  "knowledge_gaps": [
    {
      "concept_a": "asyncio event loop",
      "concept_b": "FastAPI middleware",
      "suggested_query": "How does event loop relate to middleware?",
      "co_occurrence_count": 5
    }
  ]
}

POST /admin/consolidate

Trigger manual semantic consolidation (normally runs automatically at 3 AM).

GET /stats

Engine statistics — tiers, synapse count, consolidation state.

GET /health

Health check — Redis connectivity, engine readiness, degraded mode status.

GET /metrics

Prometheus metrics endpoint.

---

Python Library Usage

Basic Store and Query

from mnemocore.core.engine import HAIMEngine

engine = HAIMEngine(persist_path="./data/memory.jsonl")

# Store memories
engine.store("Python generators are lazy iterators", metadata={"topic": "python"})
engine.store("Use 'yield' to create generator functions", metadata={"topic": "python"})
engine.store("Redis XADD appends to a stream", goal_id="infrastructure")

# Query (global)
results = engine.query("How do Python generators work?", top_k=3)
for mem_id, score in results:
    mem = engine.get_memory(mem_id)
    print(f"[{score:.3f}] {mem.content}")

# Query with context masking
results = engine.query("data streams", top_k=5, context="infrastructure")

engine.close()

Analogical Reasoning

# Define concepts
engine.define_concept("king",  {"gender": "man",   "role": "ruler"})
engine.define_concept("queen", {"gender": "woman", "role": "ruler"})
engine.define_concept("man",   {"gender": "man"})

# VSA analogy: king:man :: ?:woman → queen
result = engine.reason_by_analogy(
    src="king", val="man", tgt="woman"
)
print(result)  # [("queen", 0.934), ...]

Working with the Binary HDV Layer Directly

from mnemocore.core.binary_hdv import BinaryHDV, TextEncoder, majority_bundle

encoder = TextEncoder(dimension=16384)

# Encode text
python_vec  = encoder.encode("Python programming")
fastapi_vec = encoder.encode("FastAPI framework")
error_vec   = encoder.encode("error handling")

# Bind concept to role
python_in_fastapi = python_vec.xor_bind(fastapi_vec)

# Bundle multiple concepts into prototype
web_dev_prototype = majority_bundle([python_vec, fastapi_vec, error_vec])

# Similarity
print(python_vec.similarity(web_dev_prototype))  # High (part of bundle)
print(python_vec.similarity(error_vec))          # ~0.5 (unrelated)

# Batch nearest-neighbor search
from mnemocore.core.binary_hdv import batch_hamming_distance
import numpy as np

database = np.stack([v.data for v in [python_vec, fastapi_vec, error_vec]])
distances = batch_hamming_distance(python_vec, database)

Reliability Feedback Loop

mem_id = engine.store("Always use asyncio.Lock() in async code, not threading.Lock()")
results = engine.query("async locking")

# It works — report success
engine.provide_feedback(mem_id, outcome=True, comment="Solved deadlock issue")

# Over time, high-reliability memories get 'verified' tag
# and are ranked above unproven ones in future queries

Semantic Consolidation

stats = engine.trigger_consolidation()
print(f"Created {stats['abstractions_created']} semantic anchors")
print(f"Consolidated {stats['memories_consolidated']} episodic memories")

# Automatic: runs every night at 3 AM via background asyncio task

---

Installation

Prerequisites

• Python 3.10+
• Redis 6+ — Required for WARM tier and async event streaming
• Qdrant (optional) — For COLD tier at billion-scale
• Docker (recommended) — For Redis and Qdrant services

Quick Start

# 1. Clone
git clone https://github.com/RobinALG87/MnemoCore-Infrastructure-for-Persistent-Cognitive-Memory.git
cd MnemoCore-Infrastructure-for-Persistent-Cognitive-Memory

# 2. Create virtual environment
python -m venv venv
source venv/bin/activate       # Linux/macOS
# venv\Scripts\activate         # Windows

# 3. Install dependencies
pip install -r requirements.txt

# 4. Start Redis
docker run -d -p 6379:6379 redis:alpine

# 5. Set API key
export HAIM_API_KEY="your-secure-key-here"

# 6. Start the API
uvicorn src.api.main:app --host 0.0.0.0 --port 8100

The API is now live at http://localhost:8100. Visit http://localhost:8100/docs for the interactive Swagger UI.

With Qdrant (Phase 4.x Scale)

# Start Qdrant alongside Redis
docker run -d -p 6333:6333 qdrant/qdrant

# Enable in config.yaml
qdrant:
  enabled: true
  host: localhost
  port: 6333

---

Configuration

All configuration lives in config.yaml. Values can be overridden with environment variables (HAIM_ prefix).

haim:
  version: "4.3"
  dimensionality: 16384        # Binary vector dimensions (must be multiple of 8)

  encoding:
    mode: "binary"             # "binary" (recommended) or "float" (legacy)

  tiers:
    hot:
      max_memories: 2000       # Max nodes in RAM
      ltp_threshold: 0.3       # Evict below this LTP strength
    warm:
      max_memories: 100000     # Max nodes in Redis/mmap
    cold:
      enabled: true

  ltp:
    initial_importance: 0.5
    decay_lambda: 0.01         # Higher = faster forgetting
    permanence_threshold: 2.0  # LTP above this is considered permanent

  redis:
    url: "redis://localhost:6379/0"

  qdrant:
    enabled: false
    host: "localhost"
    port: 6333
    collection: "mnemocore_warm"

  security:
    api_key: "${HAIM_API_KEY}"  # Never hardcode — use env variable
    cors_origins: ["http://localhost:3000"]

  observability:
    metrics_enabled: true
    log_level: "INFO"

  paths:
    data_dir: "./data"
    memory_file: "./data/memory.jsonl"
    synapses_file: "./data/synapses.jsonl"

Security Note

MnemoCore requires an explicit API key. There is no default fallback key in production builds.

# Required — will raise exception if not set
export HAIM_API_KEY="$(openssl rand -hex 32)"

---

MCP Server Integration

MnemoCore exposes a Model Context Protocol (MCP) server, enabling direct integration with Claude, GPT-4, and any MCP-compatible agent framework.

Setup

# Start API first
uvicorn src.api.main:app --host 0.0.0.0 --port 8100

# Configure MCP in config.yaml
haim:
  mcp:
    enabled: true
    transport: "stdio"  # or "sse" for streaming

# Run MCP server
python -m src.mcp.server

Claude Desktop Configuration

Add to your Claude Desktop config.json:

{
  "mcpServers": {
    "mnemocore": {
      "command": "python",
      "args": ["-m", "src.mcp.server"],
      "env": {
        "HAIM_API_KEY": "your-key",
        "HAIM_BASE_URL": "http://localhost:8100"
      }
    }
  }
}

Once connected, the agent can:

• store_memory(content, context) — persist learned information
• query_memory(query, context, top_k) — recall relevant memories
• provide_feedback(memory_id, outcome) — signal what worked
• get_knowledge_gaps() — surface what it doesn't understand

---

Observability

MnemoCore ships with built-in Prometheus metrics and structured logging.

Prometheus Metrics

Available at GET /metrics:

Metric	Description
haim_api_request_count	Total requests by endpoint and status
haim_api_request_latency_seconds	Request latency histogram
haim_storage_operation_count	Store/query/delete operations
haim_hot_tier_size	Current HOT tier memory count
haim_synapse_count	Active synaptic connections

Grafana Dashboard

A sample Grafana dashboard config is available at observability/grafana_dashboard.json.

Structured Logging

All components use structured Python logging with contextual fields:

2026-02-17 20:00:00 INFO  Stored memory mem_1739821234567 (EIG: 0.7823)
2026-02-17 20:00:01 INFO  Memory mem_1739821234567 reliability updated: 0.714 (4✓ / 1✗)
2026-02-17 03:00:00 INFO  Consolidation complete: abstractions_created=12, consolidated=847
2026-02-17 04:00:00 INFO  Knowledge gap detected: asyncio ↔ FastAPI middleware (5 co-occurrences)

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Testing

# Run full test suite
pytest

# Run with coverage
pytest --cov=src --cov-report=html

# Run specific feature tests
pytest tests/test_xor_attention.py         # Contextual masking
pytest tests/test_stability.py             # Reliability/Bayesian stability
pytest tests/test_consolidation.py         # Semantic consolidation
pytest tests/test_engine_cleanup.py        # Cleanup and decay
pytest tests/test_phase43_regressions.py   # Phase 4.3 regression guardrails

# End-to-end flow
pytest tests/test_e2e_flow.py -v

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Roadmap

Current Beta (v4.3)

• Binary HDV core (XOR bind / bundle / permute / Hamming)
• Three-tier HOT/WARM/COLD memory lifecycle
• Async API + MCP integration
• XOR attention masking + Bayesian reliability updates
• Semantic consolidation, immunology cleanup, and gap detection/filling
• Temporal recall: episodic chaining + chrono-weighted query
• Regression guardrails for Phase 4.3 critical paths

Next Steps

• Hardening pass for distributed/clustered HOT-tier behavior
• Extended observability standardization (mnemocore_* transition)
• Self-improvement loop (design documented, staged rollout pending)

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Contributing

MnemoCore is an active research project. Contributions are welcome — especially:

• Performance: CUDA kernels, FAISS integration, async refactoring
• Algorithms: Better clustering for consolidation, improved EIG formulas
• Integrations: New storage backends, LLM connectors
• Tests: Coverage for edge cases, property-based testing

Process

# Fork and clone
git checkout -b feature/your-feature-name

# Make changes, ensure tests pass
pytest

# Commit with semantic message
git commit -m "feat(consolidation): add LLM-powered prototype labeling"

# Open PR — describe the what, why, and performance impact

Please follow the implementation patterns in COGNITIVE_ENHANCEMENTS.md and CODE_REVIEW_ISSUES.md for architectural guidance.

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License

MIT License — see LICENSE for details.

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Contact

Robin Granberg
📧 robin@veristatesystems.com

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Building the cognitive substrate for the next generation of autonomous AI.