.github | ||
migrations | ||
sqlxmq_macros | ||
src | ||
.env | ||
.gitignore | ||
Cargo.toml | ||
README.md |
sqlxmq
A job queue built on sqlx
and PostgreSQL
.
This library allows a CRUD application to run background jobs without complicating its
deployment. The only runtime dependency is PostgreSQL
, so this is ideal for applications
already using a PostgreSQL
database.
Although using a SQL database as a job queue means compromising on latency of delivered jobs, there are several show-stopping issues present in ordinary job queues which are avoided altogether.
With most other job queues, in-flight jobs are state that is not covered by normal database backups. Even if jobs are backed up, there is no way to restore both a database and a job queue to a consistent point-in-time without manually resolving conflicts.
By storing jobs in the database, existing backup procedures will store a perfectly consistent state of both in-flight jobs and persistent data. Additionally, jobs can be spawned and completed as part of other transactions, making it easy to write correct application code.
Leveraging the power of PostgreSQL
, this job queue offers several features not
present in other job queues.
Features
-
Send/receive multiple jobs at once.
This reduces the number of queries to the database.
-
Send jobs to be executed at a future date and time.
Avoids the need for a separate scheduling system.
-
Reliable delivery of jobs.
-
Automatic retries with exponential backoff.
Number of retries and initial backoff parameters are configurable.
-
Transactional sending of jobs.
Avoids sending spurious jobs if a transaction is rolled back.
-
Transactional completion of jobs.
If all side-effects of a job are updates to the database, this provides true exactly-once execution of jobs.
-
Transactional check-pointing of jobs.
Long-running jobs can check-point their state to avoid having to restart from the beginning if there is a failure: the next retry can continue from the last check-point.
-
Opt-in strictly ordered job delivery.
Jobs within the same channel will be processed strictly in-order if this option is enabled for the job.
-
Fair job delivery.
A channel with a lot of jobs ready to run will not starve a channel with fewer jobs.
-
Opt-in two-phase commit.
This is particularly useful on an ordered channel where a position can be "reserved" in the job order, but not committed until later.
-
JSON and/or binary payloads.
Jobs can use whichever is most convenient.
-
Automatic keep-alive of jobs.
Long-running jobs will automatically be "kept alive" to prevent them being retried whilst they're still ongoing.
-
Concurrency limits.
Specify the minimum and maximum number of concurrent jobs each runner should handle.
-
Built-in job registry via an attribute macro.
Jobs can be easily registered with a runner, and default configuration specified on a per-job basis.
-
Implicit channels.
Channels are implicitly created and destroyed when jobs are sent and processed, so no setup is required.
-
Channel groups.
Easily subscribe to multiple channels at once, thanks to the separation of channel name and channel arguments.
-
NOTIFY-based polling.
This saves resources when few jobs are being processed.
Getting started
Defining jobs
The first step is to define a function to be run on the job queue.
use sqlxmq::{job, CurrentJob};
// Arguments to the `#[job]` attribute allow setting default job options.
#[job(channel_name = "foo")]
async fn example_job(
mut current_job: CurrentJob,
) -> sqlx::Result<()> {
// Decode a JSON payload
let who: Option<String> = current_job.json()?;
// Do some work
println!("Hello, {}!", who.as_deref().unwrap_or("world"));
// Mark the job as complete
current_job.complete().await?;
Ok(())
}
Listening for jobs
Next we need to create a job runner: this is what listens for new jobs and executes them.
use sqlxmq::JobRegistry;
#[tokio::main]
async fn main() -> Result<(), Box<dyn Error>> {
// You'll need to provide a Postgres connection pool.
let pool = connect_to_db().await?;
// Construct a job registry from our single job.
let mut registry = JobRegistry::new(&[example_job]);
// Here is where you can configure the registry
// registry.set_error_handler(...)
let runner = registry
// Create a job runner using the connection pool.
.runner(&pool)
// Here is where you can configure the job runner
// Aim to keep 10-20 jobs running at a time.
.set_concurrency(10, 20)
// Start the job runner in the background.
.run()
.await?;
// The job runner will continue listening and running
// jobs until `runner` is dropped.
}
Spawning a job
The final step is to actually run a job.
example_job.new()
// This is where we override job configuration
.set_channel_name("bar")
.set_json("John")
.spawn(&pool)
.await?;