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Requests
Together, a route's attribute and function signature specify what must be true about a request in order for the route's handler to be called. You've already seen an example of this in action:
#[get("/world")]
fn handler() { .. }
This route indicates that it only matches against GET
requests to the /world
route. Rocket ensures that this is the case before handler
is called. Of
course, you can do much more than specify the method and path of a request.
Among other things, you can ask Rocket to automatically validate:
- The type of a dynamic path segment.
- The type of many dynamic path segments.
- The type of incoming data.
- The types of query strings, forms, and form values.
- The expected incoming or outgoing format of a request.
- Any arbitrary, user-defined security or validation policies.
The route attribute and function signature work in tandem to describe these validations. Rocket's code generation takes care of actually validating the properties. This section describes how to ask Rocket to validate against all of these properties and more.
Methods
A Rocket route attribute can be any one of get
, put
, post
, delete
,
head
, patch
, or options
, each corresponding to the HTTP method to match
against. For example, the following attribute will match against POST
requests
to the root path:
#[post("/")]
The grammar for these attributes is defined formally in the
rocket_codegen
API docs.
HEAD Requests
Rocket handles HEAD
requests automatically when there exists a GET
route
that would otherwise match. It does this by stripping the body from the
response, if there is one. You can also specialize the handling of a HEAD
request by declaring a route for it; Rocket won't interfere with HEAD
requests
your application handles.
Reinterpreting
Because browsers can only send GET
and POST
requests, Rocket reinterprets
request methods under certain conditions. If a POST
request contains a body of
Content-Type: application/x-www-form-urlencoded
, and the form's first
field has the name _method
and a valid HTTP method name as its value (such as
"PUT"
), that field's value is used as the method for the incoming request.
This allows Rocket applications to submit non-POST
forms. The todo
example
makes use of this feature to submit PUT
and DELETE
requests from a web form.
Dynamic Segments
You can declare path segments as dynamic by using angle brackets around variable names in a route's path. For example, if we want to say Hello! to anything, not just the world, we can declare a route like so:
#[get("/hello/<name>")]
fn hello(name: &RawStr) -> String {
format!("Hello, {}!", name.as_str())
}
If we were to mount the path at the root (.mount("/", routes![hello])
), then
any request to a path with two non-empty segments, where the first segment is
hello
, will be dispatched to the hello
route. For example, if we were to
visit /hello/John
, the application would respond with Hello, John!
.
Any number of dynamic path segments are allowed. A path segment can be of any
type, including your own, as long as the type implements the FromParam
trait. Rocket implements FromParam
for many of the standard library types, as
well as a few special Rocket types. For the full list of supplied
implementations, see the FromParam
API docs. Here's a more complete route to
illustrate varied usage:
#[get("/hello/<name>/<age>/<cool>")]
fn hello(name: String, age: u8, cool: bool) -> String {
if cool {
format!("You're a cool {} year old, {}!", age, name)
} else {
format!("{}, we need to talk about your coolness.", name)
}
}
Raw Strings
You may have noticed an unfamiliar RawStr
type in the code example above.
This is a special type, provided by Rocket, that represents an unsanitized,
unvalidated, and undecoded raw string from an HTTP message. It exists to
separate validated string inputs, represented by types such as String
, &str
,
and Cow<str>
types, from unvalidated inputs, represented by &RawStr
. It
provides helpful methods to convert the unvalidated string into a validated one.
Because &RawStr
implements FromParam
, it can be used as the type of a
dynamic segment, as in the example above. When used as the type of a dynamic
segment, a RawStr
points to a potentially undecoded string. By contrast, a
String
is guaranteed to be decoded. Which you should use depends on whether
you want direct but potentially unsafe access to the string (&RawStr
), or safe
access to the string at the cost of an allocation (String
).
Forwarding
Let's take a closer look at the route attribute and signature pair from the last example:
#[get("/hello/<name>/<age>/<cool>")]
fn hello(name: String, age: u8, cool: bool) -> String { ... }
What if cool
isn't a bool
? Or, what if age
isn't a u8
? When a parameter
type mismatch occurs, Rocket forwards the request to the next matching route,
if there is any. This continues until a route doesn't forward the request or
there are no remaining routes to try. When there are no remaining routes, a
customizable 404 error is returned.
Routes are attempted in increasing rank order. Rocket chooses a default
ranking from -4 to -1, detailed in the next section, for all routes, but a
route's rank can also be manually set with the rank
attribute. To illustrate,
consider the following routes:
#[get("/user/<id>")]
fn user(id: usize) -> T { ... }
#[get("/user/<id>", rank = 2)]
fn user_int(id: isize) -> T { ... }
#[get("/user/<id>", rank = 3)]
fn user_str(id: &RawStr) -> T { ... }
Notice the rank
parameters in user_int
and user_str
. If we run this
application with the routes mounted at the root, requests to /user/<id>
will
be routed as follows:
-
The
user
route matches first. If the string at the<id>
position is an unsigned integer, then theuser
handler is called. If it is not, then the request is forwarded to the next matching route:user_int
. -
The
user_int
route matches next. If<id>
is a signed integer,user_int
is called. Otherwise, the request is forwarded. -
The
user_str
route matches last. Since<id>
is a always string, the route always matches. Theuser_str
handler is called.
Forwards can be caught by using a Result
or Option
type. For example, if
the type of id
in the user
function was Result<usize, &RawStr>
, then user
would never forward. An Ok
variant would indicate that <id>
was a valid
usize
, while an Err
would indicate that <id>
was not a usize
. The
Err
's value would contain the string that failed to parse as a usize
.
By the way, if you were to omit the rank
parameter in the user_str
or
user_int
routes, Rocket would emit an error and abort launch, indicating that
the routes collide, or can match against similar incoming requests. The rank
parameter resolves this collision.
Default Ranking
If a rank is not explicitly specified, Rocket assigns a default ranking. By default, routes with static paths and query strings have lower ranks (higher precedence) while routes with dynamic paths and without query strings have higher ranks (lower precedence). The table below describes the default ranking of a route given its properties.
static path | query string | rank | example |
---|---|---|---|
yes | yes | -4 | /hello?world=true |
yes | no | -3 | /hello |
no | yes | -2 | /<hi>?world=true |
no | no | -1 | /<hi> |
Multiple Segments
You can also match against multiple segments by using <param..>
in a route
path. The type of such parameters, known as segments parameters, must
implement FromSegments
. Segments parameters must be the final component of a
path: any text after a segments parameter will result in a compile-time error.
As an example, the following route matches against all paths that begin with
/page/
:
#[get("/page/<path..>")]
fn get_page(path: PathBuf) -> T { ... }
The path after /page/
will be available in the path
parameter. The
FromSegments
implementation for PathBuf
ensures that path
cannot lead to
path traversal attacks. With
this, a safe and secure static file server can be implemented in 4 lines:
#[get("/<file..>")]
fn files(file: PathBuf) -> Option<NamedFile> {
NamedFile::open(Path::new("static/").join(file)).ok()
}
Format
A route can specify the data format it is willing to accept or respond with
using the format
route parameter. The value of the parameter is a string
identifying an HTTP media type. For instance, for JSON data, the string
application/json
can be used.
When a route indicates a payload-supporting method (PUT
, POST
, DELETE
, and
PATCH
), the format
route parameter instructs Rocket to check against the
Content-Type
header of the incoming request. Only requests where the
Content-Type
header matches the format
parameter will match to the route.
As an example, consider the following route:
#[post("/user", format = "application/json", data = "<user>")]
fn new_user(user: Json<User>) -> T { ... }
The format
parameter in the post
attribute declares that only incoming
requests with Content-Type: application/json
will match new_user
. (The
data
parameter is described in the next section.) Shorthand is also supported
for the most common format
arguments. Instead of using the full Content-Type,
format = "application/json"
, you can also write shorthands like format = "json"
. For a full list of available shorthands, see the
ContentType::parse_flexible()
documentation.
When a route indicates a non-payload-supporting method (HEAD
, OPTIONS
, and,
these purposes, GET
) the format
route parameter instructs Rocket to check
against the Accept
header of the incoming request. Only requests where the
preferred media type in the Accept
header matches the format
parameter will
match to the route.
As an example, consider the following route:
#[get("/user/<id>", format = "json")]
fn user(id: usize) -> Json<User> { ... }
The format
parameter in the get
attribute declares that only incoming
requests with application/json
as the preferred media type in the Accept
header will match user
. If instead the route had been declared as post
,
Rocket would match the format
against the Content-Type
header of the
incoming response.
Request Guards
Request guards are one of Rocket's most powerful instruments. As the name might
imply, a request guard protects a handler from being called erroneously based on
information contained in an incoming request. More specifically, a request guard
is a type that represents an arbitrary validation policy. The validation policy
is implemented through the FromRequest
trait. Every type that implements
FromRequest
is a request guard.
Request guards appear as inputs to handlers. An arbitrary number of request
guards can appear as arguments in a route handler. Rocket will automatically
invoke the FromRequest
implementation for request guards before calling the
handler. Rocket only dispatches requests to a handler when all of its guards
pass.
As an example, the following dummy handler makes use of three request guards,
A
, B
, and C
. An input can be identified as a request guard if it is not
named in the route attribute. This is why param
is not a request guard.
#[get("/<param>")]
fn index(param: isize, a: A, b: B, c: C) -> ... { ... }
Request guards always fire in left-to-right declaration order. In the example
above, the order will be A
followed by B
followed by C
. Failure is
short-circuiting; if one guard fails, the remaining are not attempted. To learn
more about request guards and implementing them, see the FromRequest
documentation.
Custom Guards
You can implement FromRequest
for your own types. For instance, to protect a
sensitive
route from running unless an ApiKey
is present in the request
headers, you might create an ApiKey
type that implements FromRequest
and
then use it as a request guard:
#[get("/sensitive")]
fn sensitive(key: ApiKey) -> &'static str { ... }
You might also implement FromRequest
for an AdminUser
type that
authenticates an administrator using incoming cookies. Then, any handler with an
AdminUser
or ApiKey
type in its argument list is assured to only be invoked
if the appropriate conditions are met. Request guards centralize policies,
resulting in a simpler, safer, and more secure applications.
Forwarding Guards
Request guards and forwarding are a powerful combination for enforcing policies. To illustrate, we consider how a simple authorization system might be implemented using these mechanisms.
We start with two request guards:
-
User
: A regular, authenticated user.The
FromRequest
implementation forUser
checks that a cookie identifies a user and returns aUser
value if so. If no user can be authenticated, the guard forwards. -
AdminUser
: A user authenticated as an administrator.The
FromRequest
implementation forAdminUser
checks that a cookie identifies an administrative user and returns anAdminUser
value if so. If no user can be authenticated, the guard forwards.
We now use these two guards in combination with forwarding to implement the
following three routes, each leading to an administrative control panel at
/admin
:
#[get("/admin")]
fn admin_panel(admin: AdminUser) -> &'static str {
"Hello, administrator. This is the admin panel!"
}
#[get("/admin", rank = 2)]
fn admin_panel_user(user: User) -> &'static str {
"Sorry, you must be an administrator to access this page."
}
#[get("/admin", rank = 3)]
fn admin_panel_redirect() -> Redirect {
Redirect::to("/login")
}
The three routes above encode authentication and authorization. The
admin_panel
route only succeeds if an administrator is logged in. Only then is
the admin panel displayed. If the user is not an admin, the AdminUser
route
will forward. Since the admin_panel_user
route is ranked next highest, it is
attempted next. This route succeeds if there is any user signed in, and an
authorization failure message is displayed. Finally, if a user isn't signed in,
the admin_panel_redirect
route is attempted. Since this route has no guards,
it always succeeds. The user is redirected to a log in page.
Cookies
Cookies
is an important, built-in request guard: it allows you to get, set,
and remove cookies. Because Cookies
is a request guard, an argument of its
type can simply be added to a handler:
use rocket::http::Cookies;
#[get("/")]
fn index(cookies: Cookies) -> Option<String> {
cookies.get("message")
.map(|value| format!("Message: {}", value))
}
This results in the incoming request's cookies being accessible from the
handler. The example above retrieves a cookie named message
. Cookies can also
be set and removed using the Cookies
guard. The cookies example on GitHub
illustrates further use of the Cookies
type to get and set cookies, while the
Cookies
documentation contains complete usage information.
Private Cookies
Cookies added via the Cookies::add()
method are set in the clear. In other
words, the value set is visible by the client. For sensitive data, Rocket
provides private cookies.
Private cookies are just like regular cookies except that they are encrypted using authenticated encryption, a form of encryption which simultaneously provides confidentiality, integrity, and authenticity. This means that private cookies cannot be inspected, tampered with, or manufactured by clients. If you prefer, you can think of private cookies as being signed and encrypted.
The API for retrieving, adding, and removing private cookies is identical except
methods are suffixed with _private
. These methods are: get_private
,
add_private
, and remove_private
. An example of their usage is below:
/// Retrieve the user's ID, if any.
#[get("/user_id")]
fn user_id(cookies: Cookies) -> Option<String> {
cookies.get_private("user_id")
.map(|cookie| format!("User ID: {}", cookie.value()))
}
/// Remove the `user_id` cookie.
#[post("/logout")]
fn logout(mut cookies: Cookies) -> Flash<Redirect> {
cookies.remove_private(Cookie::named("user_id"));
Flash::success(Redirect::to("/"), "Successfully logged out.")
}
Secret Key
To encrypt private cookies, Rocket uses the 256-bit key specified in the
secret_key
configuration parameter. If one is not specified, Rocket will
automatically generate a fresh key. Note, however, that a private cookie can
only be decrypted with the same key with which it was encrypted. As such, it is
important to set a secret_key
configuration parameter when using private
cookies so that cookies decrypt properly after an application restart. Rocket
emits a warning if an application is run in production without a configured
secret_key
.
Generating a string suitable for use as a secret_key
configuration value is
usually done through tools like openssl
. Using openssl
, a 256-bit base64 key
can be generated with the command openssl rand -base64 32
.
For more information on configuration, see the Configuration section of the guide.
One-At-A-Time
For safety reasons, Rocket currently requires that at most one Cookies
instance be active at a time. It's uncommon to run into this restriction, but it
can be confusing to handle if it does crop up.
If this does happen, Rocket will emit messages to the console that look as follows:
=> Error: Multiple `Cookies` instances are active at once.
=> An instance of `Cookies` must be dropped before another can be retrieved.
=> Warning: The retrieved `Cookies` instance will be empty.
The messages will be emitted when a violating handler is called. The issue can
be resolved by ensuring that two instances of Cookies
cannot be active at once
due to the offending handler. A common error is to have a handler that uses a
Cookies
request guard as well as a Custom
request guard that retrieves
Cookies
, as so:
#[get("/")]
fn bad(cookies: Cookies, custom: Custom) { .. }
Because the cookies
guard will fire before the custom
guard, the custom
guard will retrieve an instance of Cookies
when one already exists for
cookies
. This scenario can be fixed by simply swapping the order of the
guards:
#[get("/")]
fn good(custom: Custom, cookies: Cookies) { .. }
Body Data
At some point, your web application will need to process body data. Data
processing, like much of Rocket, is type directed. To indicate that a handler
expects data, annotate it with data = "<param>"
, where param
is an argument
in the handler. The argument's type must implement the FromData
trait. It
looks like this, where T: FromData
:
#[post("/", data = "<input>")]
fn new(input: T) -> String { ... }
Any type that implements FromData
is also known as data guard.
Forms
Forms are the most common type of data handled in web applications, and Rocket
makes handling them easy. Say your application is processing a form submission
for a new todo Task
. The form contains two fields: complete
, a checkbox, and
description
, a text field. You can easily handle the form request in Rocket
as follows:
#[derive(FromForm)]
struct Task {
complete: bool,
description: String,
}
#[post("/todo", data = "<task>")]
fn new(task: Form<Task>) -> String { ... }
The Form
type implements the FromData
trait as long as its generic parameter
implements the FromForm
trait. In the example, we've derived the FromForm
trait automatically for the Task
structure. FromForm
can be derived for any
structure whose fields implement FromFormValue
. If a POST /todo
request
arrives, the form data will automatically be parsed into the Task
structure.
If the data that arrives isn't of the correct Content-Type, the request is
forwarded. If the data doesn't parse or is simply invalid, a customizable 400 - Bad Request
or 422 - Unprocessable Entity
error is returned. As before, a
forward or failure can be caught by using the Option
and Result
types:
#[post("/todo", data = "<task>")]
fn new(task: Option<Form<Task>>) -> String { ... }
Lenient Parsing
Rocket's FromForm
parsing is strict by default. In other words, A Form<T>
will parse successfully from an incoming form only if the form contains the
exact set of fields in T
. Said another way, a Form<T>
will error on missing
and/or extra fields. For instance, if an incoming form contains the fields "a",
"b", and "c" while T
only contains "a" and "c", the form will not parse as
Form<T>
.
Rocket allows you to opt-out of this behavior via the LenientForm
data type.
A LenientForm<T>
will parse successfully from an incoming form as long as the
form contains a superset of the fields in T
. Said another way, a
LenientForm<T>
automatically discards extra fields without error. For
instance, if an incoming form contains the fields "a", "b", and "c" while T
only contains "a" and "c", the form will parse as LenientForm<T>
.
You can use a LenientForm
anywhere you'd use a Form
. Its generic parameter
is also required to implement FromForm
. For instance, we can simply replace
Form
with LenientForm
above to get lenient parsing:
#[derive(FromForm)]
struct Task { .. }
#[post("/todo", data = "<task>")]
fn new(task: LenientForm<Task>) { .. }
Field Renaming
By default, Rocket matches the name of an incoming form field to the name of a
structure field. While this behavior is typical, it may also be desired to use
different names for form fields and struct fields while still parsing as
expected. You can ask Rocket to look for a different form field for a given
structure field by using the #[form(field = "name")]
field annotation.
As an example, say that you're writing an application that receives data from an
external service. The external service POST
s a form with a field named type
.
Since type
is a reserved keyword in Rust, it cannot be used as the name of a
field. To get around this, you can use field renaming as follows:
#[derive(FromForm)]
struct External {
#[form(field = "type")]
api_type: String
}
Rocket will then match the form field named type
to the structure field named
api_type
automatically.
Field Validation
Fields of forms can be easily validated via implementations of the
FromFormValue
trait. For example, if you'd like to verify that some user is
over some age in a form, then you might define a new AdultAge
type, use it as
a field in a form structure, and implement FromFormValue
so that it only
validates integers over that age:
struct AdultAge(usize);
impl<'v> FromFormValue<'v> for AdultAge {
type Error = &'v RawStr;
fn from_form_value(form_value: &'v RawStr) -> Result<AdultAge, &'v RawStr> {
match form_value.parse::<usize>() {
Ok(age) if age >= 21 => Ok(AdultAge(age)),
_ => Err(form_value),
}
}
}
#[derive(FromForm)]
struct Person {
age: AdultAge
}
If a form is submitted with a bad age, Rocket won't call a handler requiring a
valid form for that structure. You can use Option
or Result
types for fields
to catch parse failures:
#[derive(FromForm)]
struct Person {
age: Option<AdultAge>
}
The forms validation and forms kitchen sink examples on GitHub provide further illustrations.
JSON
Handling JSON data is no harder: simply use the
Json
type:
#[derive(Deserialize)]
struct Task {
description: String,
complete: bool
}
#[post("/todo", data = "<task>")]
fn new(task: Json<Task>) -> String { ... }
The only condition is that the generic type in Json
implements the
Deserialize
trait from Serde. See the
JSON example on GitHub for a complete example.
Streaming
Sometimes you just want to handle incoming data directly. For example, you might
want to stream the incoming data out to a file. Rocket makes this as simple as
possible via the Data
type:
#[post("/upload", format = "plain", data = "<data>")]
fn upload(data: Data) -> io::Result<String> {
data.stream_to_file("/tmp/upload.txt").map(|n| n.to_string())
}
The route above accepts any POST
request to the /upload
path with
Content-Type: text/plain
The incoming data is streamed out to
tmp/upload.txt
, and the number of bytes written is returned as a plain text
response if the upload succeeds. If the upload fails, an error response is
returned. The handler above is complete. It really is that simple! See the
GitHub example
code
for the full crate.
Query Strings
Query strings are handled just like forms. A query string can be parsed into any
structure that implements the FromForm
trait. They are matched against by
appending a ?
to the path followed by a static query string or a dynamic
parameter <param>
.
For instance, say you change your mind and decide to use query strings instead
of POST
forms for new todo tasks in the previous forms example, reproduced
below:
#[derive(FromForm)]
struct Task { .. }
#[post("/todo", data = "<task>")]
fn new(task: Form<Task>) -> String { ... }
Rocket makes the transition simple: simply declare <task>
as a query parameter
as follows:
#[get("/todo?<task>")]
fn new(task: Task) -> String { ... }
Rocket will parse the query string into the Task
structure automatically by
matching the structure field names to the query parameters. If the parse fails,
the request is forwarded to the next matching route. Parse failures can be
captured on a per-field or per-form basis.
To catch failures on a per-field basis, use a type of Option
or Result
for
the given field:
#[derive(FromForm)]
struct Task<'r> {
description: Result<String, &'r RawStr>,
complete: Option<bool>
}
To catch failures on a per-form basis, change the type of the query string
target to either Option
or Result
:
#[get("/todo?<task>")]
fn new(task: Option<Task>) { ... }
For a concrete illustration on how to handle query parameters, see the
query_params
example.
Error Catchers
Routing may fail for a variety of reasons. These include:
- A request guard returns
Failure
. - A handler returns a
Responder
that fails. - No matching route was found.
If any of these conditions occur, Rocket returns an error to the client. To do
so, Rocket invokes the catcher corresponding to the error's status code. A
catcher is like a route, except it only handles errors. Rocket provides default
catchers for all of the standard HTTP error codes. To override a default
catcher, or declare a catcher for a custom status code, use the catch
attribute, which takes a single integer corresponding to the HTTP status code to
catch. For instance, to declare a catcher for 404 Not Found
errors, you'd
write:
use rocket::catch;
#[catch(404)]
fn not_found(req: &Request) -> T { .. }
As with routes, the return type (here T
) must implement Responder
. A
concrete implementation may look like:
#[catch(404)]
fn not_found(req: &Request) -> String {
format!("Sorry, '{}' is not a valid path.", req.uri())
}
Also as with routes, Rocket needs to know about a catcher before it is used to
handle errors. The process, known as "registering" a catcher, is similar to
mounting a route: call the register
method with a list of catchers via the
catchers!
macro. The invocation to add the 404 catcher declared above
looks like:
rocket::ignite().register(catchers![not_found])
Unlike route request handlers, catchers take exactly zero or one parameters. If
the catcher takes a parameter, it must be of type
&Request
The error
catcher example
on GitHub illustrates their use in full.