WASTE_CONFIG.turnSecret was shipped in plaintext config.js and used to compute coturn HMAC credentials client-side in browser.ts. Anyone reading the PWA's JS could read the secret and mint unlimited long-lived TURN credentials, turning the relay into an open proxy. The anchor now mints short-lived (1h) credentials server-side via a new GET /turn-credentials endpoint (-turn-secret flag), mirroring what the daemon already does. The browser fetches credentials instead of holding the secret. Daemon mode was unaffected (already server-side). Docs updated to drop turnSecret from config.js examples, document the new nginx route, and instruct anyone with an old config.js to rotate the coturn secret since it was previously exposed. Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
12 KiB
waste-go Protocol Extensions
These are additive extensions to YAW/2 implemented by waste-go. They do not break compatibility — YAW/2-only peers silently ignore all new fields. Where a waste-go peer connects to a YAW/2-only peer, the extension simply has no effect on that peer.
EXT-001 — Signed Invites
Status: implemented
Affects: waste: invite format, hello DataChannel message
Motivation
The base YAW/2 network model is open to anyone who knows the anchor URL and
network name (or hash). This extension adds opt-in cryptographic membership
gating: invites are signed by an existing peer, and peers that enforce
RequireInvite reject hellos that carry no valid signed invite.
Invite format changes
The waste: invite payload (base64-encoded JSON) gains two optional fields:
{
"anchor": "wss://...",
"network": "friends",
"net": "<64-hex SHA-256(yaw2-net:name)>",
"inviter": "<64-hex Ed25519 pubkey of signing peer>",
"sig": "<hex Ed25519 signature>"
}
The signature covers the following bytes (null-separated):
anchor \x00 network \x00 net \x00 inviter
Unsigned invites (inviter/sig absent) remain valid for backward compat.
Hello message extension
The YAW/2 §6 hello message gains one optional field:
{
"type": "hello",
"id": "<hex pubkey>",
"nick": "alice",
"caps": ["chat", "file"],
"sig": "<DTLS binding sig>",
"invite": "waste:eyJ..."
}
invite carries the full waste: string the connecting peer used to join.
YAW/2-only peers ignore this field.
Enforcement
Per-network flag RequireInvite (set via join_network IPC command).
When enabled:
- A peer that presents no
invitein hello is disconnected immediately. - A peer that presents an invite with no signature is disconnected.
- A peer whose invite signature is invalid is disconnected.
- A peer whose invite was signed by an unknown peer ID (not in the store or currently connected) is disconnected.
The inviter's key must be a known peer — i.e. previously connected and stored in the per-network SQLite store, or currently connected. This forms a chain of trust: Alice (founder) invites Bob; Bob's key is now known; Bob can invite Carol, whose invite Alice will also accept.
Default: off. Networks opt in. Existing networks with no RequireInvite behave exactly as before.
EXT-002 — Hash-based Hang Link
Status: implemented
Affects: web UI URL handling only, no wire changes
Motivation
A shareable URL that pre-fills the join form without conveying cryptographic membership. Suitable for public announcements ("come hang out here"). The fragment is never sent to the server, keeping the network name opaque to server logs and HTTP intermediaries.
Format
https://host/#waste:eyJ...
The fragment payload is the standard waste: base64 JSON with only network
and anchor fields — no inviter, no sig. This does not grant
membership on networks with RequireInvite enabled; it only pre-fills the
join form.
The web UI generates hang links via the 🔗 button in the Networks sidebar section. Arriving users see the join form pre-populated and still need a proper signed invite (if the network enforces it) to be accepted by peers.
EXT-003 — Multi-Share Configuration
Status: implemented
Affects: IPC protocol only, no peer-to-peer wire changes
New IPC commands
{"type":"add_share","path":"/home/alice/Music"} // global
{"type":"add_share","path":"/home/alice/Docs","network_ids":["abc123"]} // scoped
{"type":"remove_share","path":"/home/alice/Music"}
{"type":"list_shares"}
New IPC event
{"type":"shares_list","shares":[{"path":"...","networks":["*"]}]}
Persistence
shares.json in the data directory (next to identity.json). Each entry:
{ "path": "/absolute/path", "networks": ["*"] }
networks: ["*"] = global (all networks). Specific network IDs = scoped.
Coexists with the legacy set_share_dir single-dir mechanism.
File listings returned by get_file_list and MsgFileListReq include
entries from all applicable share roots, with relative path fields
(e.g. "path": "docs/report.pdf").
EXT-004 — TURN Relay (browser mode)
Status: implemented (browser mode + daemon mode)
Affects: ICE server configuration only, no wire changes
The browser adapter reads WASTE_CONFIG.turnURL and fetches short-lived
credentials from the anchor's GET /turn-credentials endpoint (derived from
WASTE_CONFIG.signalURL, or overridden via WASTE_CONFIG.turnCredentialsURL).
The anchor computes the credential using HMAC-SHA1 of the username (coturn
use-auth-secret scheme) — the shared secret itself is never sent to the
browser. Daemon mode does the equivalent computation locally, since the
daemon already holds -turn-secret server-side.
YAW/2 §0 explicitly declines TURN ("No relay (TURN)"). This extension is opt-in via server configuration and does not affect peers that omit it.
EXT-005 — Per-Network Path in FileEntry
Status: implemented
Affects: MsgFileListResp wire message (additive field)
FileEntry gains an optional path field carrying the file's relative path
within its share root (e.g. "docs/report.pdf"). Peers that don't understand
this field continue to use name for display and download requests.
MsgFileListReq / get requests use path as the lookup key when present,
falling back to name for backward compat with peers that don't send path.
EXT-006 — File Transfer Resume
Status: implemented (daemon mode)
Affects: file-accept wire message (additive field)
Motivation
A transfer interrupted mid-stream (peer disconnect, network drop) can be continued from where it left off on the next offer of the same file, avoiding a full re-download.
Protocol change
file-accept gains one optional field:
{ "type": "file-accept", "xid": "...", "resume_offset": 65536 }
resume_offset is the number of bytes the receiver already has on disk.
When non-zero, the sender seeks to that byte position before streaming.
Peers that don't understand this field ignore it and send from the start —
the receiver detects this by comparing incoming data to expected offset and
will still verify the final SHA-256, but the partial bytes from the interrupted
session will be overwritten (YAW/2-only interop degrades gracefully to a full
re-download, not corruption).
Receiver behaviour
- On
file-offer, the receiver scans its download directory for a.tmp.metasidecar whosesha256matches the offer. - If found, the corresponding
.tmpfile's size is the resume offset. This is sent back infile-accept. - On DC open, the receiver opens the existing
.tmpin append mode and re-hashes its existing bytes to restore the SHA-256 state. - On DC close with all bytes received, SHA-256 is verified. Success → sidecar removed, file renamed to final path. Hash mismatch → both files removed.
- On DC close with fewer bytes than expected (interrupted again) → both files kept for the next resume attempt.
Sidecar format
Each in-progress .tmp file has a corresponding .tmp.meta JSON sidecar:
{ "name": "archive.zip", "sha256": "abc...", "from": "<peer-id>", "size": 1048576 }
The sidecar is written when the transfer starts and removed on completion or corruption. Interrupted transfers keep the sidecar indefinitely.
EXT-007 — P2P Message History Gossip
Status: implemented (daemon mode) Affects: peer-to-peer wire (two new message types); IPC (new event)
Motivation
When a peer joins a network for the first time (or reconnects after an absence), they have no history. This extension lets them request recent messages from an existing peer over the already-established encrypted DataChannel, without involving the anchor.
Wire messages
history_request
Sent by the newly-connected peer to the first peer whose hello is verified. One request per room.
{
"type": "history_request",
"room": "general",
"since": 1700000000000,
"limit": 200
}
| Field | Type | Description |
|---|---|---|
room |
string | Room to request history for. |
since |
int64 (ms) | Only return messages with ts > since. 0 = return up to limit most recent. |
limit |
int (max 500) | Maximum messages to return. Responder may return fewer. |
history_chunk
{
"type": "history_chunk",
"room": "general",
"history": [
{ "mid": "...", "from": "<peer-id>", "from_alias": "alice", "text": "hello", "ts": 1700000001000 }
],
"history_done": true
}
| Field | Type | Description |
|---|---|---|
history |
array | Messages, oldest-first. |
history_done |
bool | Always true (single-chunk response). |
Deduplication
mid is the deduplication key. The store uses INSERT OR IGNORE on mid,
so receiving a message twice (live or via gossip) is a no-op. Messages
without a mid are assigned one at receive time and are not gossipped.
Behaviour
- The receiver sends one
history_requestper known room immediately after hello verification with the first peer it connects to. Requesting only the first peer avoids fan-out amplification. - The responder queries its SQLite store and replies with a single
history_chunk.limitis capped at 500 server-side. Rate-limited to one request per (peer, room) per 60 seconds. - Received history messages are saved to the local store (
INSERT OR IGNORE) and emitted ashistory_loadedIPC events so the UI can display them.
IPC event
{ "type": "history_loaded", "room": "general", "messages": [...] }
Emitted once per room after a history_chunk is fully processed. The UI
should render these messages with a visual separator from live messages.
EXT-008 — Message Reactions
Wire message (PeerMessage)
{
"type": "reaction",
"reaction_mid": "<32-hex mid of the target message>",
"reaction_emoji": "👍"
}
Sent on the normal mesh DataChannel (same as chat). No signing beyond
the existing channel-level encryption.
Semantics
- A reaction is idempotent: the same
(mid, emoji, from_peer)triple is stored withINSERT OR IGNORE— receiving a duplicate is a no-op. - There is no "un-react" wire message. Toggling off a reaction in the UI is a local-only operation in the current implementation.
reaction_midmust reference a message that exists in the local store; unknown mids are silently ignored.
Storage
SQLite table added as a migration:
CREATE TABLE IF NOT EXISTS reactions (
mid TEXT NOT NULL,
emoji TEXT NOT NULL,
from_peer TEXT NOT NULL,
reacted_at DATETIME NOT NULL,
PRIMARY KEY (mid, emoji, from_peer)
)
IPC
Command — send a reaction (daemon and browser mode):
{ "type": "send_reaction", "network_id": "...", "reaction_mid": "<hex>", "reaction_emoji": "👍" }
Event — reaction received or replayed from history:
{ "type": "reaction", "network_id": "...", "peer_id": "<64-hex>", "reaction_mid": "<hex>", "reaction_emoji": "👍" }
Stored reactions are replayed as reaction IPC events when history is
loaded (sendStoredHistory), so the UI always sees reactions alongside
their messages.
History replay
When sendStoredHistory sends a history_chunk, it also queries
ReactionsForRoom and emits one reaction event per stored reaction so
clients receive the full reaction state on reconnect.
Browser mode
browser.ts mirrors the daemon behaviour independently:
PeerConn.sendReaction(mid, emoji)broadcasts{ type: "reaction", reaction_mid, reaction_emoji }over the DataChannel.- Incoming
reactionwire frames are dispatched asreactionIPC events. BrowserAdapter.send()handlessend_reactioncommands and both broadcasts to all peers and emits a localreactionevent.sendChatincludes themidin the wire frame so reactions can reference it correctly across peers.