Responses
You may have noticed that the return type of a handler appears to be arbitrary, and that's because it is! A value of any type that implements the Responder
trait can be returned, including your own. In this section, we describe the Responder
trait as well as several useful Responder
s provided by Rocket. We'll also briefly discuss how to implement your own Responder
.
Responder
Types that implement Responder
know how to generate a Response
from their values. A Response
includes an HTTP status, headers, and body. The body may either be fixed-sized or streaming. The given Responder
implementation decides which to use. For instance, String
uses a fixed-sized body, while File
uses a streamed response. Responders may dynamically adjust their responses according to the incoming Request
they are responding to.
Wrapping
Before we describe a few responders, we note that it is typical for responders to wrap other responders. That is, responders can be of the following form, where R
is some type that implements Responder
:
1
;
A wrapping responder modifies the response returned by R
before responding with that same response. For instance, Rocket provides Responder
s in the status
module that override the status code of the wrapped Responder
. As an example, the Accepted
type sets the status to 202 - Accepted
. It can be used as follows:
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use status;
Similarly, the types in the content
module can be used to override the Content-Type of a response. For instance, to set the Content-Type of &'static str
to JSON, as well as setting the status code to an arbitrary one like 418 I'm a teapot
, combine [content::RawJson
] with status::Custom
:
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use Status;
use ;
This is not the same as serde::json::Json
!
The built-in (Status, R)
and (ContentType, R)
responders, where R: Responder
, also override the Status
and Content-Type
of responses, respectively:
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use ;
For pithy reusability, it is advisable to derive a custom responder:
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;
Errors
Responders may fail instead of generating a response by returning an Err
with a status code. When this happens, Rocket forwards the request to the error catcher for that status code.
If an error catcher has been registered for the given status code, Rocket will invoke it. The catcher creates and returns a response to the client. If no error catcher has been registered and the error status code is one of the standard HTTP status code, a default error catcher will be used. Default error catchers return an HTML page with the status code and description. If there is no catcher for a custom status code, Rocket uses the 500 error catcher to return a response.
Status
While not encouraged, you can also forward a request to a catcher manually by returning a Status
directly. For instance, to forward to the catcher for 406: Not Acceptable, you would write:
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use Status;
The response generated by Status
depends on the status code itself. As indicated above, for error status codes (in range [400, 599]), Status
forwards to the corresponding error catcher. The table below summarizes responses generated by Status
for these and other codes:
Status Code Range | Response |
---|---|
[400, 599] | Forwards to catcher for given status. |
100, [200, 205] | Empty with given status. |
All others. | Invalid. Errors to 500 catcher. |
Custom Responders
The Responder
trait documentation details how to implement your own custom responders by explicitly implementing the trait. For most use cases, however, Rocket makes it possible to automatically derive an implementation of Responder
. In particular, if your custom responder wraps an existing responder, headers, or sets a custom status or content-type, Responder
can be automatically derived:
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use ;
For the example above, Rocket generates a Responder
implementation that:
- Set the response's status to
500: Internal Server Error
. - Sets the Content-Type to
application/json
. - Adds the headers
self.header
andself.more
to the response. - Completes the response using
self.inner
.
Note that the first field is used as the inner responder while all remaining fields (unless ignored with #[response(ignore)]
) are added as headers to the response. The optional #[response]
attribute can be used to customize the status and content-type of the response. Because ContentType
is itself a header, you can also dynamically set a content-type by simply including a field of type ContentType
. To set an HTTP status dynamically, leverage the (Status, R: Responder)
responder:
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use ;
You can also use derive Responder
for enum
s, allowing dynamic selection of a responder:
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use ;
use NamedFile;
For more on using the Responder
derive, including details on how to use the derive to define generic responders, see the Responder
derive documentation.
Implementations
Rocket implements Responder
for many types in Rust's standard library including String
, &str
, File
, Option
, and Result
. The Responder
documentation describes these in detail, but we briefly cover a few here.
Strings
The Responder
implementations for &str
and String
are straight-forward: the string is used as a sized body, and the Content-Type of the response is set to text/plain
. To get a taste for what such a Responder
implementation looks like, here's the implementation for String
:
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use Cursor;
use Request;
use ;
use ContentType;
Because of these implementations, you can directly return an &str
or String
type from a handler:
1 2 3 4
Option
Option
is a wrapping responder: an Option<T>
can only be returned when T
implements Responder
. If the Option
is Some
, the wrapped responder is used to respond to the client. Otherwise, an error of 404 - Not Found is returned to the client.
This implementation makes Option
a convenient type to return when it is not known until process-time whether content exists. For example, because of Option
, we can implement a file server that returns a 200
when a file is found and a 404
when a file is not found in just 4, idiomatic lines:
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use NamedFile;
async
Result
Result
is another wrapping responder: a Result<T, E>
can only be returned when T
implements Responder
and E
implements Responder
.
The wrapped Responder
in Ok
or Err
, whichever it might be, is used to respond to the client. This means that the responder can be chosen dynamically at run-time, and two different kinds of responses can be used depending on the circumstances. Revisiting our file server, for instance, we might wish to provide more feedback to the user when a file isn't found. We might do this as follows:
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use NamedFile;
use NotFound;
async
Rocket Responders
Some of Rocket's best features are implemented through responders. Among these are:
NamedFile
- Streams a file to the client; automatically sets the Content-Type based on the file's extension.Redirect
- Redirects the client to a different URI.content
- Contains types that override the Content-Type of a response.status
- Contains types that override the status code of a response.Flash
- Sets a "flash" cookie that is removed when accessed.Json
- Automatically serializes values into JSON.MsgPack
- Automatically serializes values into MessagePack.Template
- Renders a dynamic template using Handlebars, Tera or MiniJinja.
Async Streams
The stream
responders allow serving potentially infinite async Stream
s. A stream can be created from any async Stream
or AsyncRead
type, or via generator syntax using the stream!
macro and its typed equivalents. Streams are the building blocks for unidirectional real-time communication. For instance, the chat
example uses an EventStream
to implement a real-time, multi-room chat application using Server-Sent Events (SSE).
The simplest version creates a ReaderStream
from a single AsyncRead
type. For example, to stream from a TCP connection, we might write:
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use io;
use SocketAddr;
use TcpStream;
use ReaderStream;
async >
Streams can also be created using generator syntax. The following example returns an infinite TextStream
that produces one "hello"
every second:
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use ;
use TextStream;
/// Produce an infinite series of `"hello"`s, one per second.
!
See the stream
docs for full details on creating streams including notes on how to detect and handle graceful shutdown requests.
WebSockets
Enabled by Rocket's support for HTTP connection upgrades, the official rocket_ws
crate implements first-class support for WebSockets. Working with rocket_ws
to implement an echo server looks like this:
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use ;
!
As with async
streams, rocket_ws
also supports using generator syntax for WebSocket messages:
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use ;
!
For complete usage details, see the rocket_ws
documentation.
JSON
The Json
responder in allows you to easily respond with well-formed JSON data: simply return a value of type Json<T>
where T
is the type of a structure to serialize into JSON. The type T
must implement the Serialize
trait from serde
, which can be automatically derived.
As an example, to respond with the JSON value of a Task
structure, we might write:
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use ;
You must enable Rocket's json
crate feature to use the Json
type.
The Json
type serializes the structure into JSON, sets the Content-Type to JSON, and emits the serialized data in a fixed-sized body. If serialization fails, a 500 - Internal Server Error is returned.
The serialization example provides further illustration.
Templates
Rocket has first-class templating support that works largely through a Template
responder in the rocket_dyn_templates
contrib library. To render a template named "index", for instance, you might return a value of type Template
as follows:
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use Template;
Templates are rendered with the render
method. The method takes in the name of a template and a context to render the template with. The context can be any type that implements Serialize
and serializes into an Object
value, such as structs, HashMaps
, and others.
You can also use context!
to create ad-hoc templating contexts without defining a new type:
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use Template;
To render a template, it must first be registered. The Template
fairing automatically registers all discoverable templates when attached. The Fairings sections of the guide provides more information on fairings. To attach the template fairing, simply call .attach(Template::fairing())
on an instance of Rocket
as follows:
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use Template;
Rocket discovers templates in the configurable template_dir
directory. Templating support in Rocket is engine agnostic. The engine used to render a template depends on the template file's extension. For example, if a file ends with .hbs
, Handlebars is used, while if a file ends with .tera
, Tera is used.
The name of the template does not include its extension.
For a template file named index.html.tera
, call render("index")
and use the name "index"
in templates, i.e, extends "index"
or extends "base"
for base.html.tera
.
Live Reloading
When your application is compiled in debug
mode (without the --release
flag passed to cargo
), templates are automatically reloaded when they are modified on supported platforms. This means that you don't need to rebuild your application to observe template changes: simply refresh! In release builds, reloading is disabled.
The Template
API documentation contains more information about templates, including how to customize a template engine to add custom helpers and filters. The templating example uses Tera, Handlebars and MiniJinja templating to implement the same application.
Typed URIs
Rocket's uri!
macro allows you to build URIs to routes in your application in a robust, type-safe, and URI-safe manner. Type or route parameter mismatches are caught at compile-time, and changes to route URIs are automatically reflected in the generated URIs.
The uri!
macro returns an Origin
structure with the URI of the supplied route interpolated with the given values. Each value passed into uri!
is rendered in its appropriate place in the URI using the UriDisplay
implementation for the value's type. The UriDisplay
implementation ensures that the rendered value is URI-safe.
Note that Origin
implements Into<Uri>
(and by extension, TryInto<Uri>
), so it can be converted into a Uri
using .into()
as needed and passed into methods such as Redirect::to()
.
For example, given the following route:
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URIs to person
can be created as follows:
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// with unnamed parameters, in route path declaration order
let mike = uri!;
assert_eq!;
// with named parameters, order irrelevant
let mike = uri!;
assert_eq!;
let mike = uri!;
assert_eq!;
// with a specific mount-point
let mike = uri!;
assert_eq!;
// with optional (defaultable) query parameters ignored
let mike = uri!;
assert_eq!;
let mike = uri!;
assert_eq!;
Rocket informs you of any mismatched parameters at compile-time:
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error: `person` route uri expects 3 parameters but 1 was supplied
-/uri/main.rs:7:26
|
7 | let x = uri!;
= note: expected parameters: id: Option <usize>, name: &str, age: Option <u8>
Rocket also informs you of any type errors at compile-time:
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-/uri/src/main.rs:7:31
|
7 | let x = uri!;
We recommend that you use uri!
exclusively when constructing URIs to your routes.
Ignorables
As illustrated in the previous above, query parameters can be ignored using _
in place of an expression in a uri!
invocation. The corresponding type in the route URI must implement Ignorable
. Ignored parameters are not interpolated into the resulting Origin
. Path parameters are not ignorable.
Deriving UriDisplay
The UriDisplay
trait can be derived for custom types. For types that appear in the path part of a URI, derive using UriDisplayPath
; for types that appear in the query part of a URI, derive using UriDisplayQuery
.
As an example, consider the following form structure and route:
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use Form;
By deriving using UriDisplayQuery
, an implementation of UriDisplay<Query>
is automatically generated, allowing for URIs to add_user
to be generated using uri!
:
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let link = uri!;
assert_eq!;
Typed URI Parts
The Part
trait categorizes types that mark a part of the URI as either a Path
or a Query
. Said another way, types that implement Part
are marker types that represent a part of a URI at the type-level. Traits such as UriDisplay
and FromUriParam
bound a generic parameter by Part
: P: Part
. This creates two instances of each trait: UriDisplay<Query>
and UriDisplay<Path>
, and FromUriParam<Query>
and FromUriParam<Path>
.
As the names might imply, the Path
version of the traits is used when displaying parameters in the path part of the URI while the Query
version is used when displaying parameters in the query part of the URI. These distinct versions of the traits exist exactly to differentiate, at the type-level, where in the URI a value is to be written to, allowing for type safety in the face of differences between the two locations. For example, while it is valid to use a value of None
in the query part, omitting the parameter entirely, doing so is not valid in the path part. By differentiating in the type system, both of these conditions can be enforced appropriately through distinct implementations of FromUriParam<Path>
and FromUriParam<Query>
.
This division has an effect on how the uri!
macro can be invoked. In query parts, for a route type of Option<T>
, you must supply a type of Option
, Result
, or an ignored _
to the uri!
invocation. By contrast, you cannot supply such a type in the path part. This ensures that a valid URI is always generated.
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// Note that `id` is `Option<usize>` in the route, but `id` in `uri!` _cannot_
// be an `Option`. `age`, on the other hand, _must_ be an `Option` (or `Result`
// or `_`) as its in the query part and is allowed to be ignored.
let mike = uri!;
assert_eq!;
Conversions
FromUriParam
is used to perform a conversion for each value passed to uri!
before it is displayed with UriDisplay
. If a T: FromUriParam<P, S>
implementation exists for a type T
for part URI part P
, then a value of type S
can be used in uri!
macro for a route URI parameter declared with a type of T
in part P
. For example, the following implementation, provided by Rocket, allows an &str
to be used in a uri!
invocation for route URI parameters declared as String
:
1 2 3
Other conversions to be aware of are:
&T
toT
&mut T
toT
String
to&str
&str
to&Path
&str
toPathBuf
T
toForm<T>
The following conversions only apply to path parts:
T
toOption<T>
T
toResult<T, E>
The following conversions are implemented only in query parts:
Option<T>
toResult<T, E>
(for anyE
)Result<T, E>
toOption<T>
(for anyE
)
Conversions are transitive. That is, a conversion from A -> B
and a conversion B -> C
implies a conversion from A -> C
. For instance, a value of type &str
can be supplied when a value of type Option<PathBuf>
is expected:
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use PathBuf;
uri!;
See the FromUriParam
documentation for further details.