Expand description
Types and traits for extracting data from requests.
§Table of contents
- Intro
- Common extractors
- Applying multiple extractors
- The order of extractors
- Optional extractors
- Customizing extractor responses
- Accessing inner errors
- Defining custom extractors
- Accessing other extractors in
FromRequest
orFromRequestParts
implementations - Request body limits
- Wrapping extractors
- Logging rejections
§Intro
A handler function is an async function that takes any number of
“extractors” as arguments. An extractor is a type that implements
FromRequest
or FromRequestParts
.
For example, Json
is an extractor that consumes the request body and
deserializes it as JSON into some target type:
use axum::{
extract::Json,
routing::post,
handler::Handler,
Router,
};
use serde::Deserialize;
#[derive(Deserialize)]
struct CreateUser {
email: String,
password: String,
}
async fn create_user(Json(payload): Json<CreateUser>) {
// ...
}
let app = Router::new().route("/users", post(create_user));
§Common extractors
Some commonly used extractors are:
use axum::{
extract::{Request, Json, Path, Extension, Query},
routing::post,
http::header::HeaderMap,
body::{Bytes, Body},
Router,
};
use serde_json::Value;
use std::collections::HashMap;
// `Path` gives you the path parameters and deserializes them. See its docs for
// more details
async fn path(Path(user_id): Path<u32>) {}
// `Query` gives you the query parameters and deserializes them.
async fn query(Query(params): Query<HashMap<String, String>>) {}
// `HeaderMap` gives you all the headers
async fn headers(headers: HeaderMap) {}
// `String` consumes the request body and ensures it is valid utf-8
async fn string(body: String) {}
// `Bytes` gives you the raw request body
async fn bytes(body: Bytes) {}
// We've already seen `Json` for parsing the request body as json
async fn json(Json(payload): Json<Value>) {}
// `Request` gives you the whole request for maximum control
async fn request(request: Request) {}
// `Extension` extracts data from "request extensions"
// This is commonly used to share state with handlers
async fn extension(Extension(state): Extension<State>) {}
#[derive(Clone)]
struct State { /* ... */ }
let app = Router::new()
.route("/path/:user_id", post(path))
.route("/query", post(query))
.route("/string", post(string))
.route("/bytes", post(bytes))
.route("/json", post(json))
.route("/request", post(request))
.route("/extension", post(extension));
§Applying multiple extractors
You can also apply multiple extractors:
use axum::{
extract::{Path, Query},
routing::get,
Router,
};
use uuid::Uuid;
use serde::Deserialize;
let app = Router::new().route("/users/:id/things", get(get_user_things));
#[derive(Deserialize)]
struct Pagination {
page: usize,
per_page: usize,
}
impl Default for Pagination {
fn default() -> Self {
Self { page: 1, per_page: 30 }
}
}
async fn get_user_things(
Path(user_id): Path<Uuid>,
pagination: Option<Query<Pagination>>,
) {
let Query(pagination) = pagination.unwrap_or_default();
// ...
}
§The order of extractors
Extractors always run in the order of the function parameters that is from left to right.
The request body is an asynchronous stream that can only be consumed once. Therefore you can only have one extractor that consumes the request body. axum enforces this by requiring such extractors to be the last argument your handler takes.
For example
use axum::{extract::State, http::{Method, HeaderMap}};
async fn handler(
// `Method` and `HeaderMap` don't consume the request body so they can
// put anywhere in the argument list (but before `body`)
method: Method,
headers: HeaderMap,
// `State` is also an extractor so it needs to be before `body`
State(state): State<AppState>,
// `String` consumes the request body and thus must be the last extractor
body: String,
) {
// ...
}
We get a compile error if String
isn’t the last extractor:
use axum::http::Method;
async fn handler(
// this doesn't work since `String` must be the last argument
body: String,
method: Method,
) {
// ...
}
This also means you cannot consume the request body twice:
use axum::Json;
use serde::Deserialize;
#[derive(Deserialize)]
struct Payload {}
async fn handler(
// `String` and `Json` both consume the request body
// so they cannot both be used
string_body: String,
json_body: Json<Payload>,
) {
// ...
}
axum enforces this by requiring the last extractor implements FromRequest
and all others implement FromRequestParts
.
§Optional extractors
All extractors defined in axum will reject the request if it doesn’t match.
If you wish to make an extractor optional you can wrap it in Option
:
use axum::{
extract::Json,
routing::post,
Router,
};
use serde_json::Value;
async fn create_user(payload: Option<Json<Value>>) {
if let Some(payload) = payload {
// We got a valid JSON payload
} else {
// Payload wasn't valid JSON
}
}
let app = Router::new().route("/users", post(create_user));
Wrapping extractors in Result
makes them optional and gives you the reason
the extraction failed:
use axum::{
extract::{Json, rejection::JsonRejection},
routing::post,
Router,
};
use serde_json::Value;
async fn create_user(payload: Result<Json<Value>, JsonRejection>) {
match payload {
Ok(payload) => {
// We got a valid JSON payload
}
Err(JsonRejection::MissingJsonContentType(_)) => {
// Request didn't have `Content-Type: application/json`
// header
}
Err(JsonRejection::JsonDataError(_)) => {
// Couldn't deserialize the body into the target type
}
Err(JsonRejection::JsonSyntaxError(_)) => {
// Syntax error in the body
}
Err(JsonRejection::BytesRejection(_)) => {
// Failed to extract the request body
}
Err(_) => {
// `JsonRejection` is marked `#[non_exhaustive]` so match must
// include a catch-all case.
}
}
}
let app = Router::new().route("/users", post(create_user));
§Customizing extractor responses
If an extractor fails it will return a response with the error and your handler will not be called. To customize the error response you have a two options:
- Use
Result<T, T::Rejection>
as your extractor like shown in “Optional extractors”. This works well if you’re only using the extractor in a single handler. - Create your own extractor that in its
FromRequest
implementation calls one of axum’s built in extractors but returns a different response for rejections. See the customize-extractor-error example for more details.
§Accessing inner errors
axum’s built-in extractors don’t directly expose the inner error. This gives us more flexibility and allows us to change internal implementations without breaking the public API.
For example that means while Json
is implemented using serde_json
it
doesn’t directly expose the serde_json::Error
thats contained in
JsonRejection::JsonDataError
. However it is still possible to access via
methods from std::error::Error
:
use std::error::Error;
use axum::{
extract::{Json, rejection::JsonRejection},
response::IntoResponse,
http::StatusCode,
};
use serde_json::{json, Value};
async fn handler(
result: Result<Json<Value>, JsonRejection>,
) -> Result<Json<Value>, (StatusCode, String)> {
match result {
// if the client sent valid JSON then we're good
Ok(Json(payload)) => Ok(Json(json!({ "payload": payload }))),
Err(err) => match err {
JsonRejection::JsonDataError(err) => {
Err(serde_json_error_response(err))
}
JsonRejection::JsonSyntaxError(err) => {
Err(serde_json_error_response(err))
}
// handle other rejections from the `Json` extractor
JsonRejection::MissingJsonContentType(_) => Err((
StatusCode::BAD_REQUEST,
"Missing `Content-Type: application/json` header".to_string(),
)),
JsonRejection::BytesRejection(_) => Err((
StatusCode::INTERNAL_SERVER_ERROR,
"Failed to buffer request body".to_string(),
)),
// we must provide a catch-all case since `JsonRejection` is marked
// `#[non_exhaustive]`
_ => Err((
StatusCode::INTERNAL_SERVER_ERROR,
"Unknown error".to_string(),
)),
},
}
}
// attempt to extract the inner `serde_path_to_error::Error<serde_json::Error>`,
// if that succeeds we can provide a more specific error.
//
// `Json` uses `serde_path_to_error` so the error will be wrapped in `serde_path_to_error::Error`.
fn serde_json_error_response<E>(err: E) -> (StatusCode, String)
where
E: Error + 'static,
{
if let Some(err) = find_error_source::<serde_path_to_error::Error<serde_json::Error>>(&err) {
let serde_json_err = err.inner();
(
StatusCode::BAD_REQUEST,
format!(
"Invalid JSON at line {} column {}",
serde_json_err.line(),
serde_json_err.column()
),
)
} else {
(StatusCode::BAD_REQUEST, "Unknown error".to_string())
}
}
// attempt to downcast `err` into a `T` and if that fails recursively try and
// downcast `err`'s source
fn find_error_source<'a, T>(err: &'a (dyn Error + 'static)) -> Option<&'a T>
where
T: Error + 'static,
{
if let Some(err) = err.downcast_ref::<T>() {
Some(err)
} else if let Some(source) = err.source() {
find_error_source(source)
} else {
None
}
}
Note that while this approach works it might break in the future if axum changes its implementation to use a different error type internally. Such changes might happen without major breaking versions.
§Defining custom extractors
You can also define your own extractors by implementing either
FromRequestParts
or FromRequest
.
§Implementing FromRequestParts
Implement FromRequestParts
if your extractor doesn’t need access to the
request body:
use axum::{
async_trait,
extract::FromRequestParts,
routing::get,
Router,
http::{
StatusCode,
header::{HeaderValue, USER_AGENT},
request::Parts,
},
};
struct ExtractUserAgent(HeaderValue);
#[async_trait]
impl<S> FromRequestParts<S> for ExtractUserAgent
where
S: Send + Sync,
{
type Rejection = (StatusCode, &'static str);
async fn from_request_parts(parts: &mut Parts, state: &S) -> Result<Self, Self::Rejection> {
if let Some(user_agent) = parts.headers.get(USER_AGENT) {
Ok(ExtractUserAgent(user_agent.clone()))
} else {
Err((StatusCode::BAD_REQUEST, "`User-Agent` header is missing"))
}
}
}
async fn handler(ExtractUserAgent(user_agent): ExtractUserAgent) {
// ...
}
let app = Router::new().route("/foo", get(handler));
§Implementing FromRequest
If your extractor needs to consume the request body you must implement FromRequest
use axum::{
async_trait,
extract::{Request, FromRequest},
response::{Response, IntoResponse},
body::{Bytes, Body},
routing::get,
Router,
http::{
StatusCode,
header::{HeaderValue, USER_AGENT},
},
};
struct ValidatedBody(Bytes);
#[async_trait]
impl<S> FromRequest<S> for ValidatedBody
where
Bytes: FromRequest<S>,
S: Send + Sync,
{
type Rejection = Response;
async fn from_request(req: Request, state: &S) -> Result<Self, Self::Rejection> {
let body = Bytes::from_request(req, state)
.await
.map_err(IntoResponse::into_response)?;
// do validation...
Ok(Self(body))
}
}
async fn handler(ValidatedBody(body): ValidatedBody) {
// ...
}
let app = Router::new().route("/foo", get(handler));
§Cannot implement both FromRequest
and FromRequestParts
Note that you will make your extractor unusable by implementing both
FromRequest
and FromRequestParts
directly for the same type, unless it is
wrapping another extractor:
use axum::{
Router,
routing::get,
extract::{FromRequest, Request, FromRequestParts},
http::request::Parts,
body::Body,
async_trait,
};
use std::convert::Infallible;
// Some extractor that doesn't wrap another extractor
struct MyExtractor;
// `MyExtractor` implements both `FromRequest`
#[async_trait]
impl<S> FromRequest<S> for MyExtractor
where
S: Send + Sync,
{
type Rejection = Infallible;
async fn from_request(req: Request, state: &S) -> Result<Self, Self::Rejection> {
// ...
}
}
// and `FromRequestParts`
#[async_trait]
impl<S> FromRequestParts<S> for MyExtractor
where
S: Send + Sync,
{
type Rejection = Infallible;
async fn from_request_parts(parts: &mut Parts, state: &S) -> Result<Self, Self::Rejection> {
// ...
}
}
let app = Router::new().route(
"/",
// This fails when we go to actually use `MyExtractor` in a handler function.
// This is due to a limit in Rust's type system.
//
// The workaround is to implement either `FromRequest` or `FromRequestParts`
// but not both, if your extractor doesn't wrap another extractor.
//
// See "Wrapping extractors" for how to wrap other extractors.
get(|_: MyExtractor| async {}),
);
§Accessing other extractors in FromRequest
or FromRequestParts
implementations
When defining custom extractors you often need to access another extractor in your implementation.
use axum::{
async_trait,
extract::{Extension, FromRequestParts},
http::{StatusCode, HeaderMap, request::Parts},
response::{IntoResponse, Response},
routing::get,
Router,
};
#[derive(Clone)]
struct State {
// ...
}
struct AuthenticatedUser {
// ...
}
#[async_trait]
impl<S> FromRequestParts<S> for AuthenticatedUser
where
S: Send + Sync,
{
type Rejection = Response;
async fn from_request_parts(parts: &mut Parts, state: &S) -> Result<Self, Self::Rejection> {
// You can either call them directly...
let headers = HeaderMap::from_request_parts(parts, state)
.await
.map_err(|err| match err {})?;
// ... or use `extract` / `extract_with_state` from `RequestExt` / `RequestPartsExt`
use axum::RequestPartsExt;
let Extension(state) = parts.extract::<Extension<State>>()
.await
.map_err(|err| err.into_response())?;
unimplemented!("actually perform the authorization")
}
}
async fn handler(user: AuthenticatedUser) {
// ...
}
let state = State { /* ... */ };
let app = Router::new().route("/", get(handler)).layer(Extension(state));
§Request body limits
For security reasons, Bytes
will, by default, not accept bodies larger than
2MB. This also applies to extractors that uses Bytes
internally such as
String
, Json
, and Form
.
For more details, including how to disable this limit, see DefaultBodyLimit
.
§Wrapping extractors
If you want write an extractor that generically wraps another extractor (that
may or may not consume the request body) you should implement both
FromRequest
and FromRequestParts
:
use axum::{
Router,
body::Body,
routing::get,
extract::{Request, FromRequest, FromRequestParts},
http::{HeaderMap, request::Parts},
async_trait,
};
use std::time::{Instant, Duration};
// an extractor that wraps another and measures how long time it takes to run
struct Timing<E> {
extractor: E,
duration: Duration,
}
// we must implement both `FromRequestParts`
#[async_trait]
impl<S, T> FromRequestParts<S> for Timing<T>
where
S: Send + Sync,
T: FromRequestParts<S>,
{
type Rejection = T::Rejection;
async fn from_request_parts(parts: &mut Parts, state: &S) -> Result<Self, Self::Rejection> {
let start = Instant::now();
let extractor = T::from_request_parts(parts, state).await?;
let duration = start.elapsed();
Ok(Timing {
extractor,
duration,
})
}
}
// and `FromRequest`
#[async_trait]
impl<S, T> FromRequest<S> for Timing<T>
where
S: Send + Sync,
T: FromRequest<S>,
{
type Rejection = T::Rejection;
async fn from_request(req: Request, state: &S) -> Result<Self, Self::Rejection> {
let start = Instant::now();
let extractor = T::from_request(req, state).await?;
let duration = start.elapsed();
Ok(Timing {
extractor,
duration,
})
}
}
async fn handler(
// this uses the `FromRequestParts` impl
_: Timing<HeaderMap>,
// this uses the `FromRequest` impl
_: Timing<String>,
) {}
§Logging rejections
All built-in extractors will log rejections for easier debugging. To see the
logs, enable the tracing
feature for axum (enabled by default) and the
axum::rejection=trace
tracing target, for example with
RUST_LOG=info,axum::rejection=trace cargo run
.
Re-exports§
Modules§
- Extractor for getting connection information from a client.
- Extractor that will get captures from the URL and parse them using
serde
. - Rejection response types.
- Handle WebSocket connections.
Structs§
- Extractor for getting connection information produced by a
Connected
. - Layer for configuring the default request body limit.
- Extractor that resolves the hostname of the request.
- Access the path in the router that matches the request.
- Access the path the matched the route is nested at.
- Extractor that gets the original request URI regardless of nesting.
- Extractor that will get captures from the URL and parse them using
serde
. - Extractor that deserializes query strings into some type.
- Extractor that extracts raw form requests.
- Extractor that will get captures from the URL without deserializing them.
- Extractor that extracts the raw query string, without parsing it.
- Extractor for state.
- Extractor for establishing WebSocket connections.
Traits§
- Used to do reference-to-value conversions thus not consuming the input value.
- Types that can be created from requests.
- Types that can be created from request parts.
Type Aliases§
- Type alias for
http::Request
whose body type defaults toBody
, the most common body type used with axum.