Crates.io | redis |
lib.rs | redis |
version | |
source | src |
created_at | 2014-11-21 15:32:46.563387 |
updated_at | 2024-12-03 18:47:55.466884 |
description | Redis driver for Rust. |
homepage | https://github.com/redis-rs/redis-rs |
repository | https://github.com/redis-rs/redis-rs |
max_upload_size | |
id | 309 |
Cargo.toml error: | TOML parse error at line 18, column 1 | 18 | autolib = false | ^^^^^^^ unknown field `autolib`, expected one of `name`, `version`, `edition`, `authors`, `description`, `readme`, `license`, `repository`, `homepage`, `documentation`, `build`, `resolver`, `links`, `default-run`, `default_dash_run`, `rust-version`, `rust_dash_version`, `rust_version`, `license-file`, `license_dash_file`, `license_file`, `licenseFile`, `license_capital_file`, `forced-target`, `forced_dash_target`, `autobins`, `autotests`, `autoexamples`, `autobenches`, `publish`, `metadata`, `keywords`, `categories`, `exclude`, `include` |
size | 0 |
Redis-rs is a high level Rust library for Redis. It provides convenient access to all Redis functionality through a very flexible but low-level API. It uses a customizable type conversion trait so that any operation can return results in just the type you are expecting. This makes for a very pleasant development experience.
The crate is called redis
and you can depend on it via cargo:
[dependencies]
redis = "0.27.6"
Documentation on the library can be found at docs.rs/redis.
To open a connection you need to create a client and then to fetch a connection from it.
Many commands are implemented through the Commands
trait but manual
command creation is also possible.
use redis::Commands;
fn fetch_an_integer() -> redis::RedisResult<isize> {
// connect to redis
let client = redis::Client::open("redis://127.0.0.1/")?;
let mut con = client.get_connection()?;
// throw away the result, just make sure it does not fail
let _: () = con.set("my_key", 42)?;
// read back the key and return it. Because the return value
// from the function is a result for integer this will automatically
// convert into one.
con.get("my_key")
}
Variables are converted to and from the Redis format for a wide variety of types
(String
, num types, tuples, Vec<u8>
). If you want to use it with your own types,
you can implement the FromRedisValue
and ToRedisArgs
traits, or derive it with the
redis-macros crate.
To enable asynchronous clients, enable the relevant feature in your Cargo.toml,
tokio-comp
for tokio users or async-std-comp
for async-std users.
# if you use tokio
redis = { version = "0.27.6", features = ["tokio-comp"] }
# if you use async-std
redis = { version = "0.27.6", features = ["async-std-comp"] }
When using a sync connection, it is recommended to use a connection pool in order to handle
disconnects or multi-threaded usage. This can be done using the r2d2
feature.
redis = { version = "0.27.6", features = ["r2d2"] }
For async connections, connection pooling isn't necessary, unless blocking commands are used.
The MultiplexedConnection
is cloneable and can be used safely from multiple threads, so a
single connection can be easily reused. For automatic reconnections consider using
ConnectionManager
with the connection-manager
feature.
Async cluster connections also don't require pooling and are thread-safe and reusable.
Multiplexing won't help if blocking commands are used since the server won't handle commands from blocked connections until the connection is unblocked. If you want to be able to handle non-blocking commands concurrently with blocking commands, you should send the blocking commands on another connection.
To enable TLS support, you need to use the relevant feature entry in your Cargo.toml.
Currently, native-tls
and rustls
are supported.
To use native-tls
:
redis = { version = "0.27.6", features = ["tls-native-tls"] }
# if you use tokio
redis = { version = "0.27.6", features = ["tokio-native-tls-comp"] }
# if you use async-std
redis = { version = "0.27.6", features = ["async-std-native-tls-comp"] }
To use rustls
:
redis = { version = "0.27.6", features = ["tls-rustls"] }
# if you use tokio
redis = { version = "0.27.6", features = ["tokio-rustls-comp"] }
# if you use async-std
redis = { version = "0.27.6", features = ["async-std-rustls-comp"] }
With rustls
, you can add the following feature flags on top of other feature flags to enable additional features:
tls-rustls-insecure
: Allow insecure TLS connectionstls-rustls-webpki-roots
: Use webpki-roots
(Mozilla's root certificates) instead of native root certificatesthen you should be able to connect to a redis instance using the rediss://
URL scheme:
let client = redis::Client::open("rediss://127.0.0.1/")?;
To enable insecure mode, append #insecure
at the end of the URL:
let client = redis::Client::open("rediss://127.0.0.1/#insecure")?;
Deprecation Notice: If you were using the tls
or async-std-tls-comp
features, please use the tls-native-tls
or async-std-native-tls-comp
features respectively.
Support for Redis Cluster can be enabled by enabling the cluster
feature in your Cargo.toml:
redis = { version = "0.27.6", features = [ "cluster"] }
Then you can simply use the ClusterClient
, which accepts a list of available nodes. Note
that only one node in the cluster needs to be specified when instantiating the client, though
you can specify multiple.
use redis::cluster::ClusterClient;
use redis::Commands;
fn fetch_an_integer() -> String {
let nodes = vec!["redis://127.0.0.1/"];
let client = ClusterClient::new(nodes).unwrap();
let mut connection = client.get_connection().unwrap();
let _: () = connection.set("test", "test_data").unwrap();
let rv: String = connection.get("test").unwrap();
return rv;
}
Async Redis Cluster support can be enabled by enabling the cluster-async
feature, along
with your preferred async runtime, e.g.:
redis = { version = "0.27.6", features = [ "cluster-async", "tokio-std-comp" ] }
use redis::cluster::ClusterClient;
use redis::AsyncCommands;
async fn fetch_an_integer() -> String {
let nodes = vec!["redis://127.0.0.1/"];
let client = ClusterClient::new(nodes).unwrap();
let mut connection = client.get_async_connection().await.unwrap();
let _: () = connection.set("test", "test_data").await.unwrap();
let rv: String = connection.get("test").await.unwrap();
return rv;
}
Support for the RedisJSON Module can be enabled by specifying "json" as a feature in your Cargo.toml.
redis = { version = "0.27.6", features = ["json"] }
Then you can simply import the JsonCommands
trait which will add the json
commands to all Redis Connections (not to be confused with just Commands
which only adds the default commands)
use redis::Client;
use redis::JsonCommands;
use redis::RedisResult;
use redis::ToRedisArgs;
// Result returns Ok(true) if the value was set
// Result returns Err(e) if there was an error with the server itself OR serde_json was unable to serialize the boolean
fn set_json_bool<P: ToRedisArgs>(key: P, path: P, b: bool) -> RedisResult<bool> {
let client = Client::open("redis://127.0.0.1").unwrap();
let connection = client.get_connection().unwrap();
// runs `JSON.SET {key} {path} {b}`
connection.json_set(key, path, b)?
}
To parse the results, you'll need to use serde_json
(or some other json lib) to deserialize
the results from the bytes. It will always be a Vec
, if no results were found at the path it'll
be an empty Vec
. If you want to handle deserialization and Vec
unwrapping automatically,
you can use the Json
wrapper from the
redis-macros crate.
To test redis
you're going to need to be able to test with the Redis Modules, to do this
you must set the following environment variable before running the test script
REDIS_RS_REDIS_JSON_PATH
= The absolute path to the RedisJSON module (Either librejson.so
for Linux or librejson.dylib
for MacOS).
Please refer to this link to access the RedisJSON module:
If you want to develop on the library there are a few commands provided by the makefile:
To build:
$ make
To test:
$ make test
To run benchmarks:
$ make bench
To build the docs (require nightly compiler, see rust-lang/rust#43781):
$ make docs
We encourage you to run clippy
prior to seeking a merge for your work. The lints can be quite strict. Running this on your own workstation can save you time, since Travis CI will fail any build that doesn't satisfy clippy
:
$ cargo clippy --all-features --all --tests --examples -- -D clippy::all -D warnings
To run fuzz tests with afl, first install cargo-afl (cargo install -f afl
),
then run:
$ make fuzz
If the fuzzer finds a crash, in order to reproduce it, run:
$ cd afl/<target>/
$ cargo run --bin reproduce -- out/crashes/<crashfile>