惯性聚合 高效追踪和阅读你感兴趣的博客、新闻、科技资讯
阅读原文 在惯性聚合中打开

推荐订阅源

博客园 - 聂微东
Threat Intelligence Blog | Flashpoint
Threat Intelligence Blog | Flashpoint
L
LangChain Blog
钛媒体:引领未来商业与生活新知
钛媒体:引领未来商业与生活新知
博客园 - 司徒正美
WordPress大学
WordPress大学
T
The Blog of Author Tim Ferriss
Blog — PlanetScale
Blog — PlanetScale
J
Java Code Geeks
Y
Y Combinator Blog
H
Hackread – Cybersecurity News, Data Breaches, AI and More
GbyAI
GbyAI
Vercel News
Vercel News
大猫的无限游戏
大猫的无限游戏
T
Tailwind CSS Blog
Jina AI
Jina AI
B
Blog
Recorded Future
Recorded Future
MyScale Blog
MyScale Blog
I
InfoQ
aimingoo的专栏
aimingoo的专栏
博客园_首页
OSCHINA 社区最新新闻
OSCHINA 社区最新新闻
The Cloudflare Blog
雷峰网
雷峰网
奇客Solidot–传递最新科技情报
奇客Solidot–传递最新科技情报
腾讯CDC
爱范儿
爱范儿
Last Week in AI
Last Week in AI
博客园 - 三生石上(FineUI控件)
博客园 - Franky
Schneier on Security
Schneier on Security
V
V2EX
TaoSecurity Blog
TaoSecurity Blog
H
Hacker News: Front Page
Cloudbric
Cloudbric
D
DataBreaches.Net
B
Blog RSS Feed
P
Palo Alto Networks Blog
云风的 BLOG
云风的 BLOG
NISL@THU
NISL@THU
I
Intezer
Recent Commits to openclaw:main
Recent Commits to openclaw:main
Cyberwarzone
Cyberwarzone
F
Fortinet All Blogs
D
Darknet – Hacking Tools, Hacker News & Cyber Security
C
Cybersecurity and Infrastructure Security Agency CISA
C
Cisco Blogs
K
Kaspersky official blog
Forbes - Security
Forbes - Security

Hacker News - Newest: "LLM"

GitHub - lechmazur/position_bias: A benchmark for testing whether LLM judges keep the same preference when two lightly edited versions of the same story are shown in opposite orders. Flex routing (EU and EFTA) Dark Factories: Retooling for LLM Velocity Ask HN: What would be the impact of a LLM output injection attack? GitHub - AronDaron/dataset-generator: No-code desktop app for generating high-quality synthetic datasets to fine-tune LLMs — plan-then-execute pipeline, LLM-as-judge, HuggingFace upload. GitHub - Oaklight/llm-rosetta: Production-ready LLM API translation layer for Python — bidirectional conversion between OpenAI, Anthropic & Google formats via hub-and-spoke IR. Optional API gateway. Streaming & non-streaming. Zero core deps. Contributions welcome! GitHub - browser-use/browser-harness: Self-healing browser harness that enables LLMs to complete any task. GitHub - moeen-mahmud/remen: Remen turns thoughts into something you can return to Analyzing 156 LLM Launch Posts on Hacker News ChatGPT vs Gemini vs Claude: The Best LLM Subscription You Should Buy GitHub - salaamalykum/quran-semantic-search: High-density RAG Semantic Search Engine & Quran Corpus (GEO/SEO Architecture) GitHub - NVIDIA/TensorRT-LLM: TensorRT LLM provides users with an easy-to-use Python API to define Large Language Models (LLMs) and supports state-of-the-art optimizations to perform inference efficiently on NVIDIA GPUs. TensorRT LLM also contains components to create Python and C++ runtimes that orchestrate the inference execution in a performant way. The State of LLM Bug Bounties in 2026 Operational Readiness Criteria for Tool-Using LLM Agents Meshcore: Architecture for a Decentralized P2P LLM Inference Network How an LLM becomes more coherent as we train it GitHub - seetrex-ai/laimark GitHub - Jossifresben/BibCrit: AI-assited biblical textual criticism GitHub - wastedcode/memex: File system based wiki, maintained by Claude 99helpers.com GitHub - cliver-project/AITrigram GitHub - unbody-io/adapt: A self-evolving memory layer for AI agents. GitHub - hb20007/awesome-gen-ai-fails: A list of incidents where reliance on generative AI and LLMs resulted in harm to companies, individuals, or society GitHub - nevenkordic/localmind: Run any local LLM with persistent memory and context. CLI agent over Ollama with SQLite-backed hybrid recall. No cloud. Ask HN: What are the machine requirements for a LLM like Llama-3.1-8B? Faster LLM Inference via Sequential Monte Carlo grpo explained: group relative policy optimization for llm finetuning - cgft Stop comparing price per million tokens: the hidden LLM API costs · TensorZero Andrej Karpathy's LLM Wiki Is a Bad Idea GitHub - GG-QandV/mnemostroma: Offline RAM-first cognitive leer/coprocessor for AI agents and robotics. Solves "Context Abandonment" with 20-80ms latency using a dual-thread biomimetic memory architecture (ONNX + SQLite WAL). mempalace/agent at agent · skorotkiewicz/mempalace GitHub - Nyquest-ai/nyquest-rust-fullstack-pub: Nyquest — Semantic Compression Proxy for LLMs. 350+ rules, local LLM stage, 15-75% token savings. Full Rust stack. GitHub - TheoV823/mneme: Enforce architectural decisions in AI-assisted development. GitHub - klemenvod/TokenBrawl: A 1v1 Bomberman-style game where two LLM agents play autonomously against each other. No human plays — you watch the AIs fight. Each agent receives a text description of the board state, reasons about it, and outputs a move as JSON. The game engine executes it. Introducing the Common AI Provider: LLM and AI Agent Support for Apache Airflow Power Circuit AI: Designing Power Electronic Circuits for Motor Drives with Generative Artificial Intelligence Ask HN: How to program with IDE and LLM on CPU locally? Show HN: Agent-cache – Multi-tier LLM/tool/session caching for Valkey and Redis Bonsai 1-bit WebGPU - a Hugging Face Space by webml-community The LLM Fallacy: Misattribution in AI-Assisted Cognitive Workflows Ask HN: Simple tooling for local LLM code critique without IDE integration? Can a General LLM Diagnose a DICOM Slice? A 10-Case Public Benchmark Charts-of-Thought: Enhancing LLM Visualization Literacy (PDF, 2026) GitHub - Mesh-LLM/mesh-llm: Distributed AI/LLM for the people. Share compute privately or publicly to power your agents and chat. GitHub - seamus-brady/springdrift: A persistent runtime for long-lived LLM agents Writing an LLM from scratch, part 32k -- Interventions: training a better model locally with gradient accumulation Ask HN: Which LLM model and agentic CLI are you using for local development? GitHub - wayneColt/modelcascade: Route local. Escalate smart. Never overspend. Open-source multi-model cascade routing for autonomous agents. LLM pricing is 100x harder than you think GitHub - asakin/llm-primer: Pre-warmed Claude Code sessions in tmux. No startup wait. GitHub - EggerMarc/chat-rs: A multi-provider LLM framework for Rust. GitHub - SynapseKit/SynapseKit: Minimal, async-first Python framework for production LLM apps- 2 hard deps, no magic, no SaaS. A Claude Skill that Makes LLM Paragraphs More Bearable Does Gas Town 'steal' usage from users' LLM credits & paid services to improve itself? What's Claude Code Actually Doing? Open the Black Box with the Arthur Engine Milla Jovovich's New Open Source LLM Memory App and the Dark Code Problem Your intuition of LLM token usage might be wrong Show HN: Bloomberg Terminal for LLM ops – free and open source GitHub - 0xchamin/mcptube: Transform YouTube videos into a compounding knowledge base with transcripts, vision analysis, and agentic search. Works as an MCP server for Claude, Copilot & more. Show HN: Open KB: Open LLM Knowledge Base Your LLM is a compiler, not a runtime GitHub - sapountzis/Unslop: A Web Feed That Deserves You crates.io: Rust Package Registry Beyond Karpathy's LLM-Wiki: The Necessity of Cognitive Governance GitHub - amitshekhariitbhu/llm-internals: Learn LLM internals step by step - from tokenization to attention to inference optimization. GitHub - parallem-ai/parallem: An expressive library for running agents with the Batch API. GitHub - stfurkan/pi-llm LLM-Wiki Show HN: Formal – Formal verification for AI-generated code using Lean 4 LRTS – Regression testing for LLM prompts (open source, local-first) LLM Wiki Skill: Build a Second Brain with Claude Code and Obsidian I built an LLM Wiki and RAG solution: here's a demo for a security KB The biggest advance in AI since the LLM Predict-Rlm: The LLM Runtime That Lets Models Write Their Own Control Flow the-synthetic-library/the-synthetic-mind at main · joshferrer1/the-synthetic-library GitHub - yisding/reviewwiggum GitHub - Donnyb369/mcp-spine: Context Minifier & State Guard — Local-first MCP middleware proxy GitHub - Beledarian/wgpu-llm: A from-scratch LLM inference engine that uses wgpu (the cross-platform WebGPU implementation) to dispatch WGSL compute shaders for every math operation a Transformer needs. No CUDA. No Python. No massive framework dependencies. Just Rust, raw shaders, and your GPU. GitHub - anitiue/Hindsight: An experience-driven self-improvement framework for LLM agents — 基于经验的 LLM Agent 自我改进框架 GitHub - stef41/lmscan: 🔍 Detect AI-generated text and fingerprint which LLM wrote it. Open-source GPTZero alternative. Zero dependencies, works offline. GitHub - alainnothere/AmdPerformanceTesting: Amd Performance Testing Ask HN: Is a purely Markdown-based CRM a terrible idea? Optimized for LLM agents Context Engineering - LLM Memory and Retrieval for AI Agents | Weaviate little_helper_tui/letter.md at main · sleepyeldrazi/little_helper_tui GitHub - EvanZhouDev/umr: The Unified Model Registry for all your local AI apps. GitHub - JordanCT/VigIA-Orchestrator Your Agent Is Mine: Measuring Malicious Intermediary Attacks on the LLM Supply Chain A Taxonomy of RL Environments for LLM Agents Llama LLM Network Feture GitHub - genedeng-ca/ai-mac-migration: AI-powered Mac-to-Mac migration tool - replace Apple Migration Assistant with intelligent, selective transfer using local LLMs GitHub - lunargate-ai/gateway: High-performance self-hosted AI gateway (OpenAI-compatible) with routing, retries, and streaming GitHub - AuthBits/webmcp: A lightweight, prompt-driven MCP web research server for high-quality LLM powered information extraction. Externalization in LLM Agents: A Unified Review of Memory, Skills, Protocols and Harness Engineering Springdrift: An Auditable Persistent Runtime for LLM Agents with Case-Based Memory, Normative Safety, and Ambient Self-Perception High-Stakes Personalization: Rethinking LLM Customization for Individual Investor Decision-Making From Static Templates to Dynamic Runtime Graphs: A Survey of Workflow Optimization for LLM Agents HUOZIIME: An On-Device LLM-enhanced Input Method for Deep Personalization TIDE: Token-Informed Depth Execution for Per-Token Early Exit in LLM Inference Characterizing WebGPU Dispatch Overhead for LLM Inference Across Four GPU Vendors, Three Backends, and Three Browsers LLM Targeted Underperformance Disproportionately Impacts Vulnerable Users
GitHub - mirkofr/FERNme: A lightweight memory engine for AI agents using fuzzy graphs, Hebbian updates, and optional LLM gating.
mirkofr · 2026-06-21 · via Hacker News - Newest: "LLM"

Fuzzy-Edged Recall Network

A user-owned, near-zero-LLM memory layer for AI agents. It learns each person from their behavior — including how they talk and feel — stays token-flat forever, and lets people see, edit, and own what's remembered. The engine is substrate-agnostic: it remembers wherever an agent acts — websites today (shopping, support, booking, healthcare, tutoring, gov), desktop and mobile next.

License: Apache 2.0 Site Python 3.10+ Tests Storage Status

Cheap to write · flat to read · interpretable by design · owned by the user

fernme.dev


✨ The one-paragraph pitch

Most agent memory is written by an LLM on every turn (expensive, hallucination-prone), evaluated on question-answering (not actions), and assumes a single user. FERNme is built for the opposite world — agents that act for many people, in any domain (a sale, a booking, a resolved ticket, a completed lesson, a kept appointment — "outcome" is whatever the goal is). It starts where agents already act today — websites — and the same user-owned memory is designed to extend to desktop and mobile. Each user is a sparse, fuzzily-weighted node in a per-site graph; edges update by a Hebbian co-occurrence rule with zero LLM calls, retrieval is spreading activation, and the prompt-facing "card" stores only deviations from a population prior. The result: per-turn cost stays flat as a profile grows for years, the user can read and correct their own memory, and the same engine assembles — only with the user's consent — into a cross-site supernode they fully control.


🎯 Why FERNme (the strong points)

🪶 Zero-LLM writes Memory updates are arithmetic on a graph — 0 LLM calls per interaction vs. ~2 for extraction-based memory. No write-time cost, no write-time hallucination.
📉 Flat token cost forever The prompt card holds ~25 tokens whether it's a visitor's first day or fifth year. A full-history baseline is 77× larger by 120 interactions.
🧠 Strong in every regime Ties a frequency counter on static recall, beats it 0.72 → 0.13 on drift, and wins on context (0.62 → 0.51). Decay + spreading activation unify stability and adaptivity.
🪟 Glass-box & user-owned Every preference is visible and editable. People fix what's wrong, delete everything, or export it. Privacy becomes a feature, not a liability.
🏬 Built for outcomes Evaluated by conversion, not QA. A simulated storefront shows +16% conversion lift vs. non-personalized recommendations.
🧩 User-owned supernode Sign in across sites → your memories assemble like Lego into one profile you control, default-deny, sensitive data walled off. Not surveillance — the mirror image of it.
🎚 Cost/quality dial One engine, a memory_mode switch: free key-less pure by default, opt-in gated/offline LLM enrichment when you need Mem0-grade nuance — pay only for the compute you use.
🔐 Verifiable & unlearnable Every action is logged in a tamper-evident HMAC chain the user can replay to detect any alteration; forget_everywhere wipes the profile and unlearns the person from the population prior — provable right-to-be-forgotten.
🛡 Injection-proof by design Writes are arithmetic, not LLM extraction, so page/user text can't be "talked into" becoming a belief — tested that injected instructions never enter memory.
🧠 Private collective intelligence New users benefit from crowd patterns on turn one (cold-start from a population prior), with k-anonymity + differential privacy so no individual leaks. A network-effect moat single-user memories can't have.
🗣 Style & mood memory Learns how each person communicates (terse/verbose, formal/casual, energy) and tracks their mood with trend detection, so the agent can match tone and notice when someone's frustration is rising — in any domain.
🎯 Outcome-learning, any goal Memory is reinforced by results — not just recall. record_outcome(success) strengthens what worked and weakens what backfired, where "success" is any goal (purchase, booking, resolved ticket, completed lesson…).
🔍 Explainable Ask why(user, attr) — get the evidence (observations + good/bad outcomes + dates). No black box.
🔌 Deployable plumbing (research preview; harden per SECURITY.md) SQLite or Postgres (tested on real PG 16), REST + MCP servers, consent gating, injection-safe writes, proactive triggers — all tested.

📊 Benchmarks

Honest scope: the numbers below are on synthetic or LLM-authored data, not real users. They validate the mechanism and surface failures; a real-human pilot is the pending next step. The Mem0 (LLM) head-to-head needs an API key and is not yet run.

On LLM-authored people (closest to real, agentic ingestion)

A sample of 16 of 92 third-person profiles (ChatGPT-authored), read as prose only and remembered agentically, then scored against hidden answer keys:

metric result
preference coverage vs. hidden key 75%
communication style — formality 100%
mood sign / mood arc 94% / 100%
preference drift detected 94%
injection attempts ignored 100%
note → card compression 7.3×

(The "agent" here is an LLM reading prose, so these reflect agent + engine together — the engine is solid; the extraction quality is the agent's.)

Cost, recall, and Pareto (synthetic, multi-seed)

Reproduce: python -m fernme.eval.cost_variance · ... quality · ... drift · ... context · ... ablation · ... pilot

Cost — per-turn memory tokens vs. profile size (5 seeds):

metric FERNme baseline
card size 24.9 ± 0.5 tokens (flat) full history grows linearly
at 120 interactions 77× ± 1.3 larger
LLM calls per write 0 ~2 (extraction memory)

Recall quality — precision@5 vs. ground-truth preferences (5 seeds × 40 users):

regime 🌿 FERNme frequency recency
static recall 0.74 0.74 0.47
drift (taste shifts) 0.72 0.13 ❌ 0.59
context (precision@3) 0.62 0.51 (blind)

The headline: FERNme is the only method strong everywhere. Frequency can't forget (fails drift); recency is noisy (fails static). FERNme's decay + spreading activation get both.

Cold-start ablation — population prior gives +0.06 precision@5 at turns 1–3, washing out by turn 10 (a real but modest, cold-start-only benefit).

Cost / quality Pareto (python -m fernme.eval.pareto) — measured FERNme recall & tokens, modeled LLM nuance & price (assumptions in-file). Per 1,000 interactions:

strategy quality $/1k vs Mem0
FERNme-pure 0.52 $0.008 122× cheaper
FERNme+gated 0.66 $0.023 42× cheaper
FERNme+offline 0.73 $0.104 9× cheaper
full-history@120 0.82 $0.59 (grows)
Mem0-style 0.82 $0.95

FERNme+gated/offline sit on the efficient knee: ~80–90% of the LLM-ceiling quality at 1–2 orders of magnitude less cost. (Modeled assumptions; shape is the point.)

Cost/quality Pareto — FERNme+gated/offline on the efficient knee

Simulated outcome pilot — fake storefront, learn-from-behavior shoppers: +16% relative conversion lift over a popularity baseline; tied at visit 1 (cold start), pulling ahead as it learns, recovering through a mid-pilot taste drift.


🎚 Memory modes (one engine, a cost/quality dial)

FERNme ships one core with a deployment-level switch — FernService(memory_mode=...). The default is free, key-less, and tested; LLM modes are opt-in and pluggable.

mode LLM use cost status
pure (default) none cheapest, flat ✅ tested, key-less
gated one small call only on novel free-text ~tiny 🧪 experimental — needs a model
offline batched consolidate() enrichment, off the hot path ~tiny, amortized 🧪 experimental — needs a model
  • A pluggable tagger (tagging.py) does the LLM work; you pass llm_fn, optionally constrained to a controlled vocabulary (the real consistency lever across models).
  • The hot write path stays LLM-free in every mode; gated spends a call only when the deterministic mapping finds nothing, and svc.llm_calls counts every invocation for cost transparency.
  • See the cost/quality Pareto above for where each mode lands. Honest note: the gated/ offline quality is modeled until run against a real model — the wiring is tested here with a mock LLM, not validated for quality.

🧭 The 9 leapfrog dimensions (status)

FERNme's edge isn't the mechanism (that's now a crowded 2026 category) — it's competing on dimensions single-user, vendor-owned, recall-optimized systems structurally can't.

# Dimension Status
9 Communication-style & mood memory ✅ built + tested
2 Outcome-learning for any goal (reinforce on results) ✅ built + tested
8 Explainable provenance (why) ✅ built + tested
1 Private collective priors (network-effect cold-start; k-anonymity + bounded-mean DP) ✅ built + tested
4 Verifiable, cryptographic data ownership (tamper-evident HMAC chain, cascading unlearning) ✅ built + tested
7 Multi-timescale memory (fast context vs. slow identity) ✅ built + tested
6 Self-tuning forgetting (learn decay from outcomes; adapts to drift) ✅ built + tested
5 Injection-resistant by construction (deterministic writes can't be talked into beliefs) ✅ built + tested
3 Open user-owned memory protocol (portable across any agent, with consent) ◑ spec stage

These are deliberately the things HippoGraph et al. can't follow: they're single-user (no collective priors), vendor-owned (no user-owned protocol), and recall-optimized (no outcome loop). Built in honest, tested slices — research-dependent ones are marked.

🏗 Architecture

flowchart TD
    V[Visitor on a website] -->|prompt + action| API[FERNme Service]
    API --> CONSENT{consent?}
    CONSENT -->|no| STOP[blocked]
    CONSENT -->|yes| ENGINE
    subgraph ENGINE[Engine - no LLM in the write path]
      W[Hebbian write + decay] --> G[(Per-site preference graph<br/>fuzzy 0-9 edges)]
      G --> R[Spreading-activation retrieval]
      R --> CARD[Token-minimal card ~25 tok]
      PRIOR[Population prior<br/>differential encoding] --> R
    end
    CARD --> AGENT[Agent: recommend / act]
    G --> CAB[(Cabinet: raw event log)]
    API --> STORE[(SQLite or Postgres<br/>multi-tenant)]
    API --> GLASS[🪟 Glass-box editor]
    API -.user signs in.-> SUPER[User-owned Supernode<br/>cross-site, default-deny]
Loading

🧠 How FERNme works (visual walkthrough)

Why FERNme Why FERNme — adaptive local memory instead of expensive RAG/vector retrieval in the loop.

Seven core principles What makes it different — near-zero-LLM, deterministic-first, Hebbian, fuzzy, memory cards, action-aware, user-owned.

How memory grows How memory grows — new event → connect → strengthen → decay → update the card (Hebbian learning).

Fuzzy Hebbian graph The fuzzy Hebbian graph — sparse, weighted (0–9) edges; nodes for users, preferences, topics, goals.

The LLM gate The LLM gate — an exception, not the default. Most events are handled deterministically; the LLM is a rare fallback when uncertain.

Memory card The memory card — a bounded, interpretable, token-minimal summary of what matters.

Action-aware learning Action-aware learning — good outcomes strengthen connections, bad outcomes weaken them.

The road ahead The road ahead — today's local memory; tomorrow's recursive organization and user-owned supernode (roadmap, not yet built).

FERNme architecture Full architecture: ingestion bridge → namespaced vocabulary → fuzzy Hebbian graph → memory card → agent, with the LLM gate only when uncertain.

🚀 Quickstart

pip install -e ".[dev,api]"

python run_demo.py                      # cold-start → learning → glass-box edit
python supernode_demo.py                # one person, three sites, one owned profile
pytest -q                               # 88 tests (engine, store, supernode, safety, auth…)

# experiments
python -m fernme.eval.drift               # FERNme beats a frequency counter when tastes change
python -m fernme.eval.pilot               # +16% simulated conversion lift

# run it live
FERNME_API_KEY=secret uvicorn fernme.api.rest:app --port 8077   # REST API (docs at /docs)
open http://localhost:8077/ui                               # glass-box memory editor
open http://localhost:8077/graph                            # your memory as a graph — focus by site / PC / phone
python -m fernme.api.mcp_server                               # MCP server for agents/Claude

🗄 Storage: defaults to ~/.fernme/fernme.db (SQLite). For production use PostgresStore — same interface, tested against a real Postgres 16. Keep SQLite off cloud-synced folders.


🧱 What's inside

  • Engine — saturating Hebbian write (no LLM), ACT-R decay, spreading activation, token-minimal card.
  • Population prior — IDF cold-start; differential (deviation-only) storage is enforced by an explicit prune_to_prior pass (redundant edges read through to the prior).
  • StoresSQLiteStore (zero-setup) and PostgresStore (tested vs real PG 16), one interface.
  • Ingestion bridge — a per-site catalog (item_id->tags) plus a controlled, namespaced vocabulary (vocabulary.py) that canonicalizes every tag (catalog, free text, or LLM) to one form (pref:, topic:, goal:, context:) so the same concept never drifts across months. Deterministic by default; gated-LLM only for novel free text. This is the product-critical layer — and the foundation a future recursive/region organization would group on.
  • The Cabinet — append-only event log with recall() for specific facts.
  • Supernode (supernode.py + auth.py) — user-owned cross-site profile, built by sign-in (verified token → opaque person id), default-deny scoped views, sensitive categories walled off.
  • Proactive triggers — due-to-reorder + fading-favorite nudges.
  • Safety — event tags treated as untrusted data: injection-pattern dropping, size/value caps.
  • Interfaces — REST (/observe /card /recall /edit /export /delete /triggers …) + MCP tools + a glass-box web UI (editor at /ui, cross-surface memory graph at /graph — one memory, focusable by site / PC / phone).
  • Governance — consent-gated everywhere; export & right-to-be-forgotten built in.

🔬 How FERNme compares

FERNme is a different category from conversational memories — it's a per-user preference graph evaluated by actions, not a QA memory. Don't benchmark it on LoCoMo; that's the wrong axis.

🌿 FERNme Mem0 Zep/Graphiti Letta MemOS
Write no LLM LLM LLM → KG LLM-paged LLM
Retrieval spreading activation vector graph+time OS paging hybrid
Eval axis outcomes QA temporal QA long-horizon QA
User-owned + glass-box
Multi-tenant per-site passport

Leads on: write cost, interpretability, per-site user-ownership/consent. Honestly behind on: nuanced/causal preferences (LLM extraction wins), benchmark credibility, ecosystem & distribution.


⚖️ Honest status

Done & tested (88 tests): engine, SQLite + real-Postgres stores, supernode + sign-in, triggers, safety, REST/MCP, glass-box UI + memory-graph view, and the full results suite above.

🚧 Still open (genuinely needs the outside world):

  • A real-human per-site pilot — only live users close the loop a simulator can't.
  • The Mem0 (LLM) head-to-head — harness wired; run locally with OPENAI_API_KEY.
  • Embeddings for context→attribute matching; offline LLM catalog enrichment for messy inputs.
  • Desktop & mobile surfaces — the engine is substrate-agnostic; web ingestion ships today, desktop/mobile adapters are on the roadmap. The user-owned supernode is the bridge that assembles them, with consent, into one cross-surface profile.

Every claim above is backed by a test or a reproducible experiment. Where a result is simulated, it says so — a simulator proves the mechanism, not real-world behavior.


📁 Layout

fernme/
  core/      graph types · fuzzy 0–9 edges · event record
  write/     event→attr mapping (no LLM) · Hebbian update · decay
  retrieve/  base-level + spreading activation · token-minimal card
  prior/     population prior · differential encoding · IDF cold-start
  store/     sqlite_store · postgres_store (one interface)
  supernode.py · auth.py · triggers.py · safety.py · service.py
  api/       rest.py (FastAPI) · mcp_server.py · web/glassbox.html · web/graph.html
  eval/      simulator · cost · quality · drift · context · ablation · pilot
tests/       88 tests   ·   *_demo.py walkthroughs

📜 License & citation

Apache-2.0, © 2026 Acquilab Inc. — see LICENSE and NOTICE. Security notes in SECURITY.md; the name is a working codename (see NAMING.md). If you use FERNme in research, please cite it via CITATION.cff.