Marmot is a distributed SQLite replicator with leaderless, and eventual consistency. It allows you to build a robust replication between your nodes by building on top of fault-tolerant NATS JetStream.
So if you are running a read heavy website based on SQLite, you should be easily able to scale it out by adding more SQLite replicated nodes. SQLite is probably the most ubiquitous DB that exists almost everywhere, Marmot aims to make it even more ubiquitous for server side applications by building a replication layer on top.
Download latest Marmot and extract package using:
tar vxzf marmot-v*.tar.gz
From extracted directory run examples/run-cluster.sh
. Make a change in /tmp/marmot-1.db
using:
bash > sqlite3 /tmp/marmot-1.db
sqlite3 > INSERT INTO Books (title, author, publication_year) VALUES ('Pride and Prejudice', 'Jane Austen', 1813);
Now observe changes getting propagated to other database /tmp/marmot-2.db
:
bash > sqlite3 /tmp/marmot-2.db
sqlite3 > SELECT * FROM Books;
You should be able to make changes interchangeably and see the changes getting propagated.
Here are some official, and community demos/usages showing Marmot out in wild:
- 2-node HA for edge Kubernetes - Using Marmot
- Scaling Isso with Marmot on Fly.io
- Scaling PocketBase with Marmot on Fly.io
- Scaling PocketBase with Marmot 0.4.x
- Scaling Keystone 6 with Marmot 0.4.x
Marmot is essentially a CDC (Change Data Capture) and replication pipeline running top of NATS. It can automatically configure appropriate JetStreams making sure those streams evenly distribute load over those shards, so scaling simply boils down to adding more nodes, and re-balancing those JetStreams (auto rebalancing not implemented yet).
There are a few solutions like rqlite, dqlite, and LiteFS etc. All of them either are layers on top of SQLite (e.g. rqlite, dqlite) that requires them to sit in the middle with network layer in order to provide replication; or intercept physical page level writes to stream them off to replicas. In both cases they require a single primary node where all the writes have to go, and then these changes are applied to multiple readonly replicas.
Marmot on the other hand is born different. It's born to act as a side-car to your existing processes:
- Instead of requiring single primary, there is no primary! Which means any node can make changes to its local DB. Marmot will use triggers to capture your changes, and then stream them off to NATS.
- Instead of being strongly consistent, Marmot is eventually consistent. Which means no locking, or blocking of nodes.
- It does not require any changes to your existing SQLite application logic for reading/writing.
Making these choices has multiple benefits:
- You can read, and write to your SQLite database like you normally do. No extension, or VFS changes.
- You can write on any node! You don't have to go to single primary for writing your data.
- As long as you start with same copy of database, all the mutations will eventually converge (hence eventually consistent).
In Marmot every row is uniquely mapped to a JetStream. This guarantees that for any node to publish changes for a row it has to go through same JetStream as everyone else. If two nodes perform a change to same row in parallel, both of the nodes will compete to publish their change to JetStream cluster. Due to RAFT quorum constraint only one of the writer will be able to get its changes published first. Now as these changes are applied (even the publisher applies its own changes to database) the last writer will always win. This means there is NO serializability guarantee of a transaction spanning multiple tables. This is a design choice, in order to avoid any sort of global locking, and performance.
Right now there are a few limitations on current solution:
- Marmot does not support schema changes propagation, so any tables you create or columns you change won't be reflected. This feature is being debated and will be available in future versions of Marmot.
- You can't watch tables selectively on a DB. This is due to various limitations around snapshot and restore mechanism.
- WAL mode required - since your DB is going to be processed by multiple processes the only way to have multi-process changes reliably is via WAL.
- Marmot is eventually consistent - This simply means rows can get synced out of order, and
SERIALIZABLE
assumptions on transactions might not hold true anymore. However your application can choose to redirect writes to single node so that your changes are always replayed in order.
-
Leaderless replication never requiring a single node to handle all write load.
-
Ability to snapshot and fully recover from those snapshots. Multiple storage options for snapshot:
-
Built with NATS, abstracting stream distribution and replication.
-
Support for log entry compression, handling content heavy CMS needs.
-
Sleep timeout support for serverless scenarios.
Starting 0.8+ Marmot comes with embedded nats-server with JetStream support. This not only reduces the dependencies/processes that one might have to spin up, but also provides with out-of-box tooling like nat-cli. You can also use existing libraries to build additional tooling and scripts due to standard library support. Here is one example using Deno:
deno run --allow-net https://gist.githubusercontent.com/maxpert/d50a49dfb2f307b30b7cae841c9607e1/raw/6d30803c140b0ba602545c1c0878d3394be548c3/watch-marmot-change-logs.ts -u <nats_username> -p <nats_password> -s <comma_seperated_server_list>
The output will look something like this:
v0.8.x
introduced support for embedded NATS. This is recommended version for production.v0.7.x
moves to file based configuration rather than CLI flags, and S3 compatible snapshot storage.v0.6.x
introduces snapshot save/restore. It's in pre-production state.v0.5.x
introduces change log compression with zstd.v0.4.x
introduces NATS based change log streaming, and continuous multi-directional sync.v0.3.x
is deprecated, and unstable. DO NOT USE IT IN PRODUCTION.
Marmot picks simplicity, and lesser knobs to configure by choice. Here are command line options you can use to configure marmot:
config
- Path to a TOML configuration file. Check outconfig.toml
comments for detailed documentation on various configurable options.cleanup
(default:false
) - Just cleanup and exit marmot. Useful for scenarios where you are performing a cleanup of hooks and change logs.save-snapshot
(default:false
Since 0.6.x
) - Just snapshot the local database, and upload snapshot to NATS/S3 servercluster-addr
(default: noneSince 0.8.x
) - Sets the binding address for cluster, when specifying this flag at-least two nodes will be required (orreplication_log.replicas
). It's a simple<bind_address>:<port>
pair that can be used to bind cluster listening server.- Since
v0.8.4
Marmot will automatically expose a leaf server on<bind_address>:<port + 1>
. This is intended to reduce the number for flags. So if you expose cluster on port4222
the port4223
will be automatically a leaf server listener.
- Since
cluster-peers
(default: noneSince 0.8.x
) - Comma separated list ofnats://<host>:<port>/
peers of NATS cluster. You can also use (Since versionv0.8.4
)dns://<dns>:<port>/
to A/AAAA record lookups. Marmot will automatically resolve the DNS IPs at boot time to expand the routes with value ofnats://<ip>:<port>/
value, where<ip>
is replaced with all the DNS entries queried. There are two additional query parameters you can use:min
- forcing Marmot to wait for minimum number of entries (e.g.dns://foo:4222/?min=3
will require 3 DNS entries to be present before embedded NATs server is started)interval_ms
- delay between DNS queries, which will prevent Marmot from flooding DNS server.
leaf-server
(default: noneSince v0.8.4
)- Comma separated list ofnats://<host>:<port>/
ordns://<dns>:<port>/
just likecluster-peers
can be used to connect to a cluster as a leaf node.
For more details and internal workings of marmot go to these docs.
Last but not least we would like to thank our sponsors who have been supporting development of this project.