An in-process JSON database with automatic peer-to-peer background synchronization between devices on a local network. Keep your apps in sync without a cloud!
🚧 WORK-IN-PROGRESS 🚧: Osmosis is not yet usable. The npm modules mentioned in this README are not available yet. Watch this space for updates.
The library itself is @nels.onl/osmosis-js. Separate modules exist for the
JSON CRDT datastore (@nels.onl/osmosis-store-js) and the network stack
(@nels.onl/osmosis-net-js).
The library is called
osmosis-jsinstead ofosmosisbecause this Node module is a non-portable reference implementation. Osmosis is really meant for mobile apps, but, unfortunately, this Node module with native dependencies is not easily usable on mobile.My plan is to develop a portable native implementation in C, and to provide bindings for several languages, including a Node wrapper at
@nels.onl/osmosis. See the Roadmap for more information.
Consider an app with both mobile and desktop versions, like a notetaking app, a password manager, or a podcast client. The user would like to keep its state synced between a laptop and a phone.
Normally, this requires a cloud service to store the synced data. But, with Osmosis, after pairing the mobile and desktop apps once, they will detect each other every time they connect to the same Wi-Fi network, and will create a direct p2p connection to sync data.
Osmosis synchronization is automatic, encrypted, and relatively safe from conflicts. Updates are modeled with a JSON CRDT. It is possible for updates to fail, but this can only happen if a path is updated after its parent is deleted, or if non-typesafe changes are made (e.g., replacing an object with an array).
An Osmosis database is a single JSON object. Osmosis has the API of a reactive data store like Redux:
- Updates are Actions, which are JSON messages.
- Queries are listener callbacks, called every time the data at a given path is updated. Paths are expressed as JsonPath.
Actions are sent with dispatch, and queries are created with subscribe.
import Osmosis from '@nels.onl/osmosis-js';
const store = new Osmosis({
appId: '82feacaf-3ae0-41c2-9aff-dd7dcb0a2a80'
});
// Create an array at the top-level key "numbers"
store.dispatch({
action: 'InitArray',
path: '$.numbers'
});
// Print the list of numbers every time it changes
store.subscribe('$.numbers', (numbers) => {
console.log(`Numbers: ${numbers.join(', ')}`);
});
// Add some entries to the numbers array
store.dispatch({ action: 'InsertUnique', path: '$.numbers', payload: 1 });
store.dispatch({ action: 'InsertUnique', path: '$.numbers', payload: 2 });
store.dispatch({ action: 'InsertUnique', path: '$.numbers', payload: 3 });The pairing process looks like this:
- One device (the Requester) dispatches a
RequestPairaction, with a payload containing the UUID of another device (the Responder) and a secret string (usually a randomly-generated PIN). - The Requester displays the secret to the user.
- The Responder receives the request and prompts the user for the secret.
- The user enters the secret.
- The Responder dispatches an
AcceptPairaction, with a payload containing the Requester's UUID and the secret. - The Requester receives the response. The devices are now paired, and will begin syncing in the background.
A basic pairing setup for Osmosis, which can send and receive pairing requests, looks like this:
import Osmosis from '@nels.onl/osmosis-js';
const store = new Osmosis({
appId: 'f8e8eec8-d219-4e6e-b8fc-3363504860ff',
peerName: 'Peer 1'
});
let peers = [];
store.subscribeMeta('$.peers', (peerList) => {
peers = peerList;
});
store.on('pairRequest', (evt) => {
const secret = prompt(
`Received pair request from ${evt.peerName} (${evt.peerId}). ` +
'Please enter the PIN displayed on this device.'
);
if (secret) {
store.dispatch({
action: 'AcceptPair',
payload: {
uuid: evt.uuid,
secret
}
});
} else {
store.dispatch({
action: 'RejectPair',
payload: evt.uuid
});
}
});
store.on('pairResponse', (evt) => {
if (evt.accepted) {
console.log(`Pair request to ${evt.peerName} accepted`);
} else {
console.log(`Pair request to ${evt.peerName} rejected`);
}
});
function pairWithFirstPeer() {
if (!peers.length) return;
// Generate a 4-digit PIN
const secret = `${Math.floor(Math.random() * 10000)}`.padStart(4, '0');
store.dispatch({
action: 'RequestPair',
payload: {
id: peers[0].uuid;
secret
}
});
alert(`Pairing PIN: ${secret}`);
}There's a lot going on in this example, so let's take it one step at a time.
subscribeMeta is like subscribe, except that it queries the Osmosis store's
Metadata instead of its data. Metadata includes things like network
state, action history, and failures. All of this data is available as one
queryable JSON object. peers is the list of visible peers, which updates every
time a peer enters or leaves the network.
An Osmosis store also emits Events, which can be listened to with the
on method. Events are mostly network-related.
Pairing Osmosis instances requires a few event listeners:
pairRequest- fires when a pair request is received.pairResponse- fires when a pair request is accepted or rejected.
Finally, the pairing process uses some actions that operate on network state
instead of data. RequestPair, AcceptPair, and RejectPair, among others,
control the pairing process but are not part of the Osmosis store's history.
These actions are documented in Network Actions.
The first time an Osmosis instance is created, it generates a Peer ID and a public/private keypair. This data should be saved to disk, and loaded every time this Osmosis instance is started.
Osmosis uses two kinds of sockets: broadcast UDP sockets that send heartbeat packets, and unicast TCP sockets that send Monocypher-encrypted, zstandard-compressed JSON-RPC messages.
When a TCP socket is opened, each side sends its 16-byte Peer ID to the other. All subsequent TCP messages are formatted like this:
[..][......................][.................... . . .
| | |
| Nonce (24 bytes) Message (abs(Length) bytes)
|
Length (4 bytes, big-endian 32-bit int)If Length is negative, it signifies that the decrypted contents of Message
are compressed. The length of Message is the absolute value of Length.
Message is encrypted using Monocypher's AEAD and a shared key computed from
one peer's private key and the other's public key. Inside is a JSON-RPC message,
which may be compressed with zstandard.
Each Osmosis instance starts a TCP service, called the Gateway Service, on a random ephemeral port. This service receives pair requests and connection requests.
Osmosis sends out a UDP heartbeat packet every minute, on the broadcast address of every broadcast-compatible IPv4 network interface, on a port computed from the first 2 bytes of the App ID:
heartbeatPort = appId[0] | appId[1] << 8 | 0x8000; // always >= 32768The heartbeat is a binary message, with this layout:
[..][..............][..............][..............................][][... . . .
| | | | | |
| App ID (16B) Peer ID (16B) Public key (32 bytes) | |
| | |
Magic number (4 bytes: 0x054d0515) | |
| |
Port (2 bytes, big-endian 16-bit uint) |
|
Peer name (UTF-8 string prefixed with 8-bit uint length)When peer A receives peer B's heartbeat, it is only considered valid if the following conditions apply:
- A and B have the same App ID
- A and B have different Peer IDs
- B's Gateway port is > 1024
- A has not recently seen a heartbeat with B's Peer ID from a different IP address, or with a different port or public key
- If A is already paired with B, B's public key has not changed since pairing
When A receives a valid heartbeat from B, B is added to A's list of visible peers; it is removed if A does not receive a new heartbeat for 3 minutes.
Pairing is done using the Gateway Service. Once two peers are paired, they will connect as soon as one receives a valid heartbeat from the other. Connecting involves one peer creating a new TCP Connection Service on a random ephemeral port, with a random keypair, then sending this port and public key to the other peer, which responds with its own newly-generated public key. Once one peer is connected to the other's Connection Service, they synchronize their lists of paired peers and begin exchanging state updates.
The Osmosis store is a Causal Tree JSON CRDT made up of two parts:
- A list of Actions, each of which is tagged with an ID (peer UUID + Lamport number).
- A list of Save Points, which are copies of the full JSON tree at specific points in time, with exponentially increasing gaps (first few are ~4 actions apart, then 8, then 16, and so on).
The Save Points are a performance optimization to avoid reconstructing the full JSON tree from scratch every time a merge happens.
When a new Action is dispatched, its path is compiled to a JSON
representation. This may split the Action into multiple Actions. Each path is
then further compiled to a Causal Tree representation by replacing the longest
prefix referring to an existing location with that location's ID. Actions are
only stored or synced in this fully-compiled form.
// Given this Osmosis store state:
{ foo: { bar: { baz: 1 } } }
// Composed of these (uncompiled) actions:
[{
action: "InitObject",
path: "$.foo",
id: { author: "ef6d1530-5ed7-4330-abb9-4d4accd1ead5", index: 1 }
}, {
action: "InitObject",
path: "$.foo.bar",
id: { author: "ef6d1530-5ed7-4330-abb9-4d4accd1ead5", index: 2 }
}, {
action: "Set",
path: "$.foo.bar.baz",
payload: 1,
id: { author: "ef6d1530-5ed7-4330-abb9-4d4accd1ead5", index: 3 }
}]
// Then, this new action:
{ action: "Set", path: "$.foo.bar.qux", payload: 2 }
// Has a path that compiles to this:
[{ type: "Key", query: "foo" },
{ type: "Key", query: "bar" },
{ type: "Key", query: "qux" }]
// Which can be further compiled to this Causal Tree form:
[{
type: "Id",
query: { author: "ef6d1530-5ed7-4330-abb9-4d4accd1ead5", index: 2 }
}, {
type: "Key",
query: "qux"
}]When two Osmosis instances establish a connection, they send each other a State Summary. The State Summary consists of a State Hash and a mapping from each known peer's Peer ID to its latest Lamport number.
The State Hash is a cumulative hash of the IDs of an instance's entire Action history, in order. It is computed recursively:
StateHash(0) = 00000000000000000000000000000000...
StateHash(i + 1) = Blake2B([........ . . . ........][......][..............])
| | |
StateHash(i) (64 bytes) | |
| |
Lamport number of Actions[i] (8 bytes, big-endian 64-bit uint) |
|
Peer ID of Actions[i] (16 bytes)If two peers have different State Hashes, they are out of sync and must be synchronized.
Action synchronization uses a Causal Tree algorithm. Actions are sorted by ID, first by Lamport timestamp and then by peer UUID. Synchronization involves rolling back to the latest Save Point that is earlier than all new Actions, then applying all Actions after that point, while inserting new Actions in sorted order.
If a merged action fails, the failure is added to the failures metadata key
and the action is skipped, but the remaining actions are applied as usual.
Osmosis supports two kinds of sync operations:
-
Live Sync: While an Osmosis instance is connected to one or more peers, newly dispatched Actions are sent to all connected peers as soon as they are dispatched.
Peers return their new State Hashes after a Live Sync update is applied. If, after a Live Sync, a peer's State Hash differs from the local State Hash, then a Full Sync is performed.
-
Full Sync: When a connection between two peers is opened, or whenever a Live Sync results in an inconsistent state, peers will negotiate a sync session to ensure that their State Hashes match.
An Osmosis instance may only perform one Full Sync at a time. While a Full Sync is in progress, all other sync requests and dispatched actions will be enqueued until the sync has completed.
A Full Sync consists of two steps, performed by both peers:
-
Peer A looks at every Lamport number in Peer B's State Summary, and sends Peer B a list of every Action whose Lamport number is greater than Peer B's latest Lamport number for that Action's Peer ID.
-
If Peers A and B still do not have the same State Hash, Peer A sends a list of its Save Points to Peer B, and Peer B returns the latest Action ID in its history that matches a Save Point's ID and State Hash.
If a shared ID is found, Peer A sends Peer B all of its Actions with an ID later than the shared ID. Peer B rewinds its state to the timestamp of the shared ID, then applies all Actions from both A and B that are later than the shared ID.
If no shared ID is found, the peers have no history in common. This can happen if one peer has garbage-collected too much of its history. This is an unrecoverable error, and the peers will unpair automatically.
-
Creates a new Osmosis store from the given configuration object.
config is an object with the following properties, all of which (except
appId) are optional:
appId: A UUID that uniquely identifies this Osmosis app. Osmosis will only detect peers with the sameappId.peerName: A human-readable string to identify this device when pairing. Will appear in the UI of other devices when listing peers. Defaults to something based on the device's hostname.saveState: An instance of theSaveStateclass, which controls how the store's data is persisted to disk.InMemorySaveState(the default) andJsonFileSaveStateare aways available. Additional modules are planned forSqliteSaveStateandLevelDbSaveState.minHistory: An integer, defaults to0. The minimum number of past actions that Osmosis will preserve, even if it knows it doesn't need them (i.e., all known peers are synced). If you intend to do anything with Osmosis's history besides syncing, this should be set to something other than0. If it is-1, history will never be deleted.maxHistory: An integer, defaults to32768. The maximum number of actions that Osmosis will remember while preserving history for a pending sync that may need that history. If Osmosis accumulates more than this amount of history without syncing, it will start deleting history, which could make future synchronization impossible. If it is-1, there is no limit.visibleToPeers: Whether this Osmosis instance is initially visible to other, non-paired peers on the network. Defaults totrue.syncEnabled: Whether this Osmosis instance is initially able to connect to paired peers and sync. Defaults totrue.
Submits an Action to the store. Throws an OsmosisFailureError if
the action reports any failures. If returnFailures is true, it does not throw,
and instead returns an array of failures, which will be empty if the action did
not cause any failures.
Subscribes to update events on the data queried by the JsonPath string path.
callback is called with an array of JSON values, which may be empty if there
is nothing at the subscribed path. Whenever the subscribed data is updated,
callback is called again with a new array of query results.
variables, if present, is an array or object containing variables to
interpolate into path.
Returns an object with one method, cancel. Calling cancel() on this object
will cancel the subscription, and callback will not be called again.
Subscribes to update events on the Metadata queried by the JsonPath
string path. callback is called with an array of JSON values, which may be
empty if there is nothing at the subscribed path. Whenever the subscribed data
is updated, callback is called again with a new array of query results.
variables, if present, is an array or object containing variables to
interpolate into path.
Returns an object with one method, cancel. Calling cancel() on this object
will cancel the subscription, and callback will not be called again.
Synchronously queries the store using the JsonPath string path, and returns
the result as an array of JSON values.
variables, if present, is an array or object containing variables to
interpolate into path.
Synchronously queries the store's Metadata using the JsonPath
string path, and returns the result as an array of JSON values.
variables, if present, is an array or object containing variables to
interpolate into path.
Registers an event listener for the Event eventName. callback is
called with one argument (the event) whenever an event of this type occurs.
Throws an exception if eventName is not a known event type.
Returns an object with one method, cancel. Calling cancel() on this object
will cancel the event listener, and callback will not be called again.
{ action: "Set", path: JsonPath string, payload: JSON value }
To be written.
{ action: "Delete", path: JsonPath string }
To be written.
{ action: "InitObject", path: JsonPath string }
To be written.
{ action: "InitArray", path: JsonPath string }
To be written.
{ action: "InsertBefore", path: JsonPath string, payload: JSON value }
To be written.
{ action: "InsertAfter", path: JsonPath string, payload: JSON value }
To be written.
{ action: "InsertUnique", path: JsonPath string, payload: JSON value }
To be written.
{ action: "Add", path: JsonPath string, payload: number }
To be written.
{ action: "Multiply", path: JsonPath string, payload: number }
To be written.
{ action: "Move", path: JsonPath string, payload: JsonPath string }
To be written.
{ action: "Copy", path: JsonPath string, payload: JsonPath string }
To be written.
{ action: "Transaction", payload: array of data actions }
To be written.
{ action: "RequestPair", payload: { id: UUID string, secret: string } }
To be written.
{ action: "AcceptPair", payload: { id: UUID string, secret: string } }
To be written.
{ action: "RejectPair", payload: UUID string }
To be written.
{ action: "Unpair", payload: UUID string }
To be written.
{ action: "SetVisibleToPeers", payload: boolean }
To be written.
{ action: "SetSyncEnabled", payload: boolean }
To be written.
To be written.
To be written.
An array containing the data actions that make up this Osmosis store's history, except for actions that have been removed by garbage collection.
Actions are stored in a different format than the format used by dispatch.
Each action has a timestamp and an id, JsonPath strings are compiled into
JSON objects, and actions with complex paths may be split up into multiple
actions.
Note that, by default, Osmosis's garbage collection is extremely aggressive.
History is only preserved if it is absolutely necessary for a pending sync, and
is deleted as soon as all known paired peers are synced. If you want more
history (for example, as an Undo feature), set the minHistory and maxHistory
config parameters when constructing a new Osmosis object.
The configuration options for this Osmosis instance, which are a combination of
some options set in the new Osmosis constructor and these additional options
that are saved to the SaveState's file:
peerIdpublicKeyprivateKey
An array of all failures caused by all actions in this store's history. If
synced actions from other peers cause failures, this is the only place they will
be reported. Each failure has an id linking it to the action that caused it.
When an action is deleted by garbage collection, its failures will also be removed from this array.
An array of all paired peers, whether they are currently visible or not.
An array of all peers currently visible on the network. Peers are visible only
if they share the same appId.
- MVP reference implementation in Node
- RxJS wrapper library
- Sample app
- Chronofold-like string actions
- LevelDB support
- SQLite support
- Blobs and blob actions
- Standalone database app
- Port to C
- More language bindings:
- Node
- Cordova plugin
- Java (+ Android)
- Python
- Go
- At-rest encryption support
- More sample apps:
- Notes app
- Password manager
- Podcast client
- Dropbox clone
Copyright © 2020-2021 Adam Nelson
Osmosis is distributed under the Blue Oak Model License. It is a MIT/BSD-style license, but with some clarifying improvements around patents, attribution, and multiple contributors.