# State Many web applications have a need to maintain state. This can be as simple as maintaining a counter for the number of visits or as complex as needing to access job queues and multiple databases. Rocket provides the tools to enable these kinds of interactions in a safe and simple manner. ## Managed State The enabling feature for maintaining state is _managed state_. Managed state, as the name implies, is state that Rocket manages for your application. The state is managed on a per-type basis: Rocket will manage at most one value of a given type. The process for using managed state is simple: 1. Call `manage` on the `Rocket` instance corresponding to your application with the initial value of the state. 2. Add a `State` type to any request handler, where `T` is the type of the value passed into `manage`. ! note: All managed state must be thread-safe. Because Rocket automatically multithreads your application, handlers can concurrently access managed state. As a result, managed state must be thread-safe. Thanks to Rust, this condition is checked at compile-time by ensuring that the type of values you store in managed state implement `Send` + `Sync`. ### Adding State To instruct Rocket to manage state for your application, call the [`manage`](@api/rocket/struct.Rocket.html#method.manage) method on an instance of `Rocket`. For example, to ask Rocket to manage a `HitCount` structure with an internal `AtomicUsize` with an initial value of `0`, we can write the following: ```rust use std::sync::atomic::AtomicUsize; struct HitCount { count: AtomicUsize } rocket::ignite().manage(HitCount { count: AtomicUsize::new(0) }); ``` The `manage` method can be called any number of times as long as each call refers to a value of a different type. For instance, to have Rocket manage both a `HitCount` value and a `Config` value, we can write: ```rust # use std::sync::atomic::AtomicUsize; # struct HitCount { count: AtomicUsize } # type Config = &'static str; # let user_input = "input"; rocket::ignite() .manage(HitCount { count: AtomicUsize::new(0) }) .manage(Config::from(user_input)); ``` ### Retrieving State State that is being managed by Rocket can be retrieved via the [`State`](@api/rocket/struct.State.html) type: a [request guard](../requests/#request-guards) for managed state. To use the request guard, add a `State` type to any request handler, where `T` is the type of the managed state. For example, we can retrieve and respond with the current `HitCount` in a `count` route as follows: ```rust # #[macro_use] extern crate rocket; # fn main() {} # use std::sync::atomic::{AtomicUsize, Ordering}; # struct HitCount { count: AtomicUsize } use rocket::State; #[get("/count")] fn count(hit_count: State) -> String { let current_count = hit_count.count.load(Ordering::Relaxed); format!("Number of visits: {}", current_count) } ``` You can retrieve more than one `State` type in a single route as well: ```rust # #[macro_use] extern crate rocket; # fn main() {} # struct HitCount; # struct Config; # use rocket::State; #[get("/state")] fn state(hit_count: State, config: State) { /* .. */ } ``` ! warning If you request a `State` for a `T` that is not `managed`, Rocket won't call the offending route. Instead, Rocket will log an error message and return a **500** error to the client. You can find a complete example using the `HitCount` structure in the [state example on GitHub](@example/state) and learn more about the [`manage` method](@api/rocket/struct.Rocket.html#method.manage) and [`State` type](@api/rocket/struct.State.html) in the API docs. ### Within Guards It can also be useful to retrieve managed state from a `FromRequest` implementation. To do so, simply invoke `State` as a guard using the [`Request::guard()`] method. ```rust # #[macro_use] extern crate rocket; # fn main() {} use rocket::State; use rocket::request::{self, Request, FromRequest}; # use std::sync::atomic::{AtomicUsize, Ordering}; # struct T; # struct HitCount { count: AtomicUsize } # type ErrorType = (); #[rocket::async_trait] impl<'a, 'r> FromRequest<'a, 'r> for T { type Error = ErrorType; async fn from_request(req: &'a Request<'r>) -> request::Outcome { let hit_count_state = try_outcome!(req.guard::>().await); let current_count = hit_count_state.count.load(Ordering::Relaxed); /* ... */ # request::Outcome::Success(T) } } ``` [`Request::guard()`]: @api/rocket/struct.Request.html#method.guard ## Request-Local State While managed state is *global* and available application-wide, request-local state is *local* to a given request, carried along with the request, and dropped once the request is completed. Request-local state can be used whenever a `Request` is available, such as in a fairing, a request guard, or a responder. Request-local state is *cached*: if data of a given type has already been stored, it will be reused. This is especially useful for request guards that might be invoked multiple times during routing and processing of a single request, such as those that deal with authentication. As an example, consider the following request guard implementation for `RequestId` that uses request-local state to generate and expose a unique integer ID per request: ```rust # #[macro_use] extern crate rocket; # fn main() {} # use std::sync::atomic::{AtomicUsize, Ordering}; use rocket::request::{self, Request, FromRequest}; /// A global atomic counter for generating IDs. static ID_COUNTER: AtomicUsize = AtomicUsize::new(0); /// A type that represents a request's ID. struct RequestId(pub usize); /// Returns the current request's ID, assigning one only as necessary. #[rocket::async_trait] impl<'a, 'r> FromRequest<'a, 'r> for &'a RequestId { type Error = (); async fn from_request(request: &'a Request<'r>) -> request::Outcome { // The closure passed to `local_cache` will be executed at most once per // request: the first time the `RequestId` guard is used. If it is // requested again, `local_cache` will return the same value. request::Outcome::Success(request.local_cache(|| { RequestId(ID_COUNTER.fetch_add(1, Ordering::Relaxed)) })) } } #[get("/")] fn id(id: &RequestId) -> String { format!("This is request #{}.", id.0) } ``` Note that, without request-local state, it would not be possible to: 1. Associate a piece of data, here an ID, directly with a request. 2. Ensure that a value is generated at most once per request. For more examples, see the [`FromRequest` request-local state] documentation, which uses request-local state to cache expensive authentication and authorization computations, and the [`Fairing`] documentation, which uses request-local state to implement request timing. [`FromRequest` request-local state]: @api/rocket/request/trait.FromRequest.html#request-local-state [`Fairing`]: @api/rocket/fairing/trait.Fairing.html#request-local-state ## Databases Rocket includes built-in, ORM-agnostic support for databases. In particular, Rocket provides a procedural macro that allows you to easily connect your Rocket application to databases through connection pools. A _database connection pool_ is a data structure that maintains active database connections for later use in the application. This implementation of connection pooling support is based on [`r2d2`] and exposes connections through request guards. Databases are individually configured through Rocket's regular configuration mechanisms: a `Rocket.toml` file, environment variables, or procedurally. Connecting your Rocket application to a database using this library occurs in three simple steps: 1. Configure the databases in `Rocket.toml`. 2. Associate a request guard type and fairing with each database. 3. Use the request guard to retrieve and use a connection in a handler. Presently, Rocket provides built-in support for the following databases: | Kind | Driver | Version | `Poolable` Type | Feature | |----------|-----------------------|-----------|--------------------------------|------------------------| | MySQL | [Diesel] | `1` | [`diesel::MysqlConnection`] | `diesel_mysql_pool` | | MySQL | [`rust-mysql-simple`] | `18` | [`mysql::Conn`] | `mysql_pool` | | Postgres | [Diesel] | `1` | [`diesel::PgConnection`] | `diesel_postgres_pool` | | Postgres | [Rust-Postgres] | `0.17` | [`postgres::Client`] | `postgres_pool` | | Sqlite | [Diesel] | `1` | [`diesel::SqliteConnection`] | `diesel_sqlite_pool` | | Sqlite | [`Rusqlite`] | `0.23` | [`rusqlite::Connection`] | `sqlite_pool` | | Memcache | [`memcache`] | `0.15` | [`memcache::Client`] | `memcache_pool` | [`r2d2`]: https://crates.io/crates/r2d2 [Diesel]: https://diesel.rs [`rusqlite::Connection`]: https://docs.rs/rusqlite/0.23.0/rusqlite/struct.Connection.html [`diesel::SqliteConnection`]: http://docs.diesel.rs/diesel/prelude/struct.SqliteConnection.html [`postgres::Client`]: https://docs.rs/postgres/0.17/postgres/struct.Client.html [`diesel::PgConnection`]: http://docs.diesel.rs/diesel/pg/struct.PgConnection.html [`mysql::Conn`]: https://docs.rs/mysql/18/mysql/struct.Conn.html [`diesel::MysqlConnection`]: http://docs.diesel.rs/diesel/mysql/struct.MysqlConnection.html [`Rusqlite`]: https://github.com/jgallagher/rusqlite [Rust-Postgres]: https://github.com/sfackler/rust-postgres [`rust-mysql-simple`]: https://github.com/blackbeam/rust-mysql-simple [`diesel::PgConnection`]: http://docs.diesel.rs/diesel/pg/struct.PgConnection.html [`memcache`]: https://github.com/aisk/rust-memcache [`memcache::Client`]: https://docs.rs/memcache/0.15/memcache/struct.Client.html ### Usage To connect your Rocket application to a given database, first identify the "Kind" and "Driver" in the table that matches your environment. The feature corresponding to your database type must be enabled. This is the feature identified in the "Feature" column. For instance, for Diesel-based SQLite databases, you'd write in `Cargo.toml`: ```toml [dependencies.rocket_contrib] version = "0.5.0-dev" default-features = false features = ["diesel_sqlite_pool"] ``` Then, in `Rocket.toml` or the equivalent via environment variables, configure the URL for the database in the `databases` table: ```toml [global.databases] sqlite_logs = { url = "/path/to/database.sqlite" } ``` In your application's source code, create a unit-like struct with one internal type. This type should be the type listed in the "`Poolable` Type" column. Then decorate the type with the `#[database]` attribute, providing the name of the database that you configured in the previous step as the only parameter. You will need to either add `#[macro_use] extern crate rocket_contrib` to the crate root or have a `use rocket_contrib::database` in scope, otherwise the `database` attribute will not be available. Finally, attach the fairing returned by `YourType::fairing()`, which was generated by the `#[database]` attribute: ```rust # #[macro_use] extern crate rocket; #[macro_use] extern crate rocket_contrib; use rocket_contrib::databases::diesel; #[database("sqlite_logs")] struct LogsDbConn(diesel::SqliteConnection); #[launch] fn rocket() -> rocket::Rocket { rocket::ignite().attach(LogsDbConn::fairing()) } ``` That's it! Whenever a connection to the database is needed, use your type as a request guard. The database can be accessed by calling the `run` method: ```rust # #[macro_use] extern crate rocket; # #[macro_use] extern crate rocket_contrib; # fn main() {} # use rocket_contrib::databases::diesel; # #[database("sqlite_logs")] # struct LogsDbConn(diesel::SqliteConnection); # type Logs = (); #[get("/logs/")] async fn get_logs(conn: LogsDbConn, id: usize) -> Logs { # /* conn.run(|c| logs::filter(id.eq(log_id)).load(c)).await # */ } ``` ! note The above examples uses [Diesel] with some fictional `Logs` type. The example above contains the use of a `Logs` type that is application specific and not built into Rocket. It also uses [Diesel]'s query-building syntax. Rocket does not provide an ORM. It is up to you to decide how to model your application's data. ! note The database engines supported by `#[database]` are *synchronous*. Normally, using such a database would block the thread of execution. To prevent this, the `run()` function automatically uses a thread pool so that database access does not interfere with other in-flight requests. See [Cooperative Multitasking](../overview/#cooperative-multitasking) for more information on why this is necessary. If your application uses features of a database engine that are not available by default, for example support for `chrono` or `uuid`, you may enable those features by adding them in `Cargo.toml` like so: ```toml [dependencies] postgres = { version = "0.15", features = ["with-chrono"] } ``` For more on Rocket's built-in database support, see the [`rocket_contrib::databases`] module documentation. [`rocket_contrib::databases`]: @api/rocket_contrib/databases/index.html