Beyond that headline, the release also ships whisper messages, offline compose, unread badges, and a significant render-performance pass. Here is what changed and why.
End-to-End Encryption with OpenPGP
When end-to-end encryption is on, your messages are scrambled on your device before they leave it. Your XMPP server relays ciphertext, but it cannot read your conversations, even if the server is compromised or an administrator goes looking. The same applies to any relay between servers.
Fluux implements OpenPGP for XMPP (XEP-0373, also called OX) — the modern redesign of OpenPGP encryption for XMPP. If you have come across XEP-0027 (the older "Current Jabber OpenPGP Usage"), that is a different, now-deprecated approach with well-documented weaknesses: no authenticated message envelope, signed-plaintext exposure, and no multi-device story. Fluux implements XEP-0373 only. It uses a proper content-encryption layer (XEP-0420) that authenticates the full message context and hides metadata from the server. It builds on the same OpenPGP cryptography used in encrypted email for decades, adapted correctly to instant messaging.
Once you enable encryption in Settings → Encryption, your key pair is generated and your public key is published to your server. From that point, whenever a contact also has encryption enabled, Fluux automatically starts encrypting messages to them. A lock icon above the composer confirms it. Nothing to configure per conversation.
Encrypted messages cover more than just text: reactions, edits, retractions, link previews, and file attachments all ride inside the same encrypted envelope. The server cannot see which emoji you reacted with, what you edited a message to say, or which files you shared.
Why OpenPGP first?
The choice of OpenPGP as the first E2EE protocol was deliberate, and it comes down to four practical properties.
Multi-device without friction. A single OpenPGP key pair works across all your devices. You generate it once; every device you add simply loads the same key. There is no per-device key negotiation, no session bootstrapping required before encrypted history loads. This stands in contrast to ratchet-based protocols that issue a key per client installation and require all clients to exchange session state before decryption is possible.
Encrypted backup you control. When you click Back up in the encryption settings, Fluux generates a backup code — 24 upper-case characters drawn from an unambiguous alphabet (no O or 0), grouped into 4-character chunks with dashes (e.g. TWNK-KD5Y-MT3T-E1GS-DRDB-KVTW). This format follows XEP-0373 §5.4 and is accepted by other compliant clients such as Gajim. Fluux encrypts your secret key with this code and stores the encrypted blob on your own XMPP server under a private node only you can access. The code never leaves your device.
Your full history stays readable. Because every device shares the same key, messages encrypted months ago on one device remain decryptable on another. The server&aposs message archive (MAM) becomes a true history, not a graveyard of ciphertext only the originating device can open. Outgoing messages are also encrypted to your own key, so your sent history is fully accessible on every device.
Simple, comprehensible verification. Trust On First Use (TOFU) gives you safe, convenient defaults. When you want a stronger guarantee, you compare fingerprints out-of-band, i.e. in person, over a phone call, on a separate verified channel. The fingerprint lives in the tooltip on the lock icon and in Settings → Encryption. You verify once per contact, per key, and you are done.
Whisper messages — private threads inside group chats
It is now possible to reply privately to a single occupant of a room without leaving the room. These whisper messages follow XEP-0045 §7.5 and appear in a distinct private thread so it is always clear they are not visible to the room at large.
Other improvements worth knowing
Compose while offline. Messages typed before a connection is established are queued locally and sent as soon as the session comes online.
Connection status banner. A banner now appears while the app is reconnecting, so you always know when you are temporarily offline rather than wondering whether a message failed to send.
Render-performance pass. This release eliminates a class of re-render storms that affected the conversation list, command palette, room config modals, occupant panel, roster, search, and individual message rows during background sync and group-chat presence churn. The result is a noticeably smoother experience on busy accounts.
XMPP Console cleanup. Stream Management packets are now hidden by default in the developer XMPP console. The toggle remains available for when you need to trace them.
What comes next for encryption
The encryption engine is a plugin layer sitting between the XMPP client and the UI. OpenPGP is the first plugin loaded into that framework. Adding a second protocol means writing a new plugin that implements the same interface: key management, encrypt, decrypt, trust state. The rest of the app — message routing, UI indicators, backup flow — does not need to change.
This matters because no single protocol wins every use case. OpenPGP&aposs shared-key model is ideal for multi-device history access; ratchet-based protocols like OMEMO excel at forward secrecy on single-device deployments; MLS is designed for large groups where pairwise key agreement would be impractical. The plan is to support several, letting users and deployments choose.
The framework is in place; the question is which protocol to add second. OMEMO (XEP-0384) is the most widely deployed XMPP encryption protocol today. Adding it would maximise interoperability with existing XMPP clients. MLS (RFC 9420) is the newer IETF standard, designed from the ground up for multi-device and group scenarios, and is where the industry is heading long term.
We have not decided yet. If you have a strong opinion, whether you are running an ejabberd deployment or just a user who cares, we would genuinely like to hear it. Just comment under that blog post.
Release notes and download
Full changelog on GitHub. Desktop builds for macOS, Windows, and Linux — plus the web version — are available on the ProcessOne website.
we’ve implemented SASL channel binding (
