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APIs are the bread and butter of how a modern and fast-paced web environment. Frontend application, other web services and IoT devices need to be able to talk to your service. API endpoints are like doors to which you decide what comes in and in which format.

Since Rust is a static typed language with a strong compiler you won't face many of the common pitfalls about running a web service in production. Although there are still run time errors which you have to cover.

HTTP Requests

When we talk about creating an API we basically mean a web application which listens on certain paths and responds accordingly. But first things first. For two devices to be able to communicate with each other there has to be an established TCP connection.

TCP is a protocol which the two parties can use to establish a connection. After establishing this connection, you can receive and send messages to the other party. HTTP is another protocol, which is built on top of TCP, and it's defining the contents of the requests and responses.

So on the Rust side of things, TCP is implemented in the Rust core library, HTTP is not. Whatever framework you chose in the previous article they all implement HTTP and therefore are able to receive and send HTTP formatted messages.

An example GET requests for example looks like this:



GET / HTTP/1.1 Host: api.awesomerustwebapp.com Accept-Language: en

It includes:

GET : the HTTP method

: the HTTP method / : The path

: The path HTTP/1.1 : The version of the HTTP protocol

: The version of the HTTP protocol HOST : The host/domain of the server we want to request data from

: The host/domain of the server we want to request data from Accept-Language : Which language we prefer and understand

The most common used HTTP methods are:

GET

POST

PUT

PATCH

DELETE

POST/PUT/PATCH/DELETE are special

We are using GET every time we browse the web. If we want to alter data however (like using POST to send data over to another server), we need to be more cautions and precise.

First, not everyone is allowed to just send a bunch of data to another server. Our API can for example say: "I just accept data from the server with the host name allowed.awesomerustapp.com .

Therefore, when you send a POST to another server, what actually happens is the CORS workflow:

We first ask the server what is allowed, where do you accept requests from and what are your accepted headers. If we fulfill all of these requirements, then we can send a POST .

The web framework actix for example has its own cors middleware.

Disclaimer: Not all frameworks (like rocket and tide) are implementing CORS in their core. However, in a professional environment, you handle CORS on the DevOps side of things and put it for example in your NGINX config.

The Job of a Framework

We use the hard work of other people to create web applications. Everything has to be implemented at some point, just not from you for most of the time. A framework covers the following concerns:

Start a web server and open a PORT

Listen to requests on this PORT

If a request comes in, look at the Path in the HTTP header

Route the request to the handler according to the Path

according to the Path Help you extract the information out of the request

Pack the generated data and HTTP StatusCode (created from you) and form a response

and (created from you) and form a Send the response back to the sender

The Rust web framework tide includes http-service, which provides the basic abstractions you need when working with HTTP calls. The crate http-service is built on top of hyper, which transforms TCP-Streams to valid HTTP requests and responses.

Your job is to create routes like /users/:id and add a route_handler which is a function to handle the requests on this particular path. The framework makes sure that it directs the incoming HTTP requests to this particular handler.

Creating an API spec

You have to define your resources first to get an idea what your application needs to handle and uncover relationships between them. So if you want to build a idea-up-voting site, you would have:

Users

Ideas

Votes

A simple spec for this scenario would look like this:

Users POST /users GET /users PUT /users/:user_id PATCH /users/:user_id DELETE /users/:user_id GET /users/:user_id



Ideas and Votes behave accordingly. A spec is helpful for two reasons:

It gives you guidelines not to forget a path

It helps to communicate to your API users what to expect

You can tools like swagger to write a full spec which also describes the structure of the data and the messages/responses for each path and route.

A more professional spec would include the return values for each route and the request and response bodies. However, the spec can be finalized once you know how your API should look like and behave. To get started, a simple list is enough.

Crafting the API

Depending on the framework you are using, your implementation will look different. You have to have the following features on your radar to look out for:

Creating routes for each method (like app.at("/users").post(post_users_handler) )

) Extracting information from the request (like headers, uri-params and JSON from the request body)

Creating responses with proper HTTP codes ( 200 , 201 , 400 , 404 etc.)

I am using the latest version of tide for this web series. You can add it in your Cargo.toml file and use it for your web app:



[dependencies] tide = "0.1.0"

Our first User implementation will look like this:



async fn handle_get_users ( cx : Context < Database > ) -> EndpointResult { Ok ( response :: json ( cx .app_data () .get_all ())) } async fn handle_get_user ( cx : Context < Database > ) -> EndpointResult { let id = cx .param ( "id" ) .client_err () ? ; if let Some ( user ) = cx .app_data () .get ( id ) { Ok ( response :: json ( user )) } else { Err ( StatusCode :: NOT_FOUND ) ? } } async fn handle_update_user ( mut cx : Context < Database > ) -> EndpointResult < () > { let user = await ! ( cx .body_json ()) .client_err () ? ; let id = cx .param ( "id" ) .client_err () ? ; if cx .app_data () .set ( id , user ) { Ok (()) } else { Err ( StatusCode :: NOT_FOUND ) ? } } async fn handle_create_user ( mut cx : Context < Database > ) -> EndpointResult < String > { let user = await ! ( cx .body_json ()) .client_err () ? ; Ok ( cx .app_data () .insert ( user ) .to_string ()) } async fn handle_delete_user ( cx : Context < Database > ) -> EndpointResult < String > { let id = cx .param ( "id" ) .client_err () ? ; Ok ( cx .app_data () .delete ( id ) .to_string ()) } fn main () { // We create a new application with a basic, local database // You can use your own implementation, or none: App::new(()) let mut app = App :: new ( Database :: default ()); app .at ( "/users" ) .post ( handle_create_user ) .get ( handle_get_users ); app .at ( "/users/:id" ) .get ( handle_get_user ) .patch ( handle_update_user ) .delete ( handle_delete_user ); app .serve ( "127.0.0.1:8000" ) .unwrap (); }

You can find the full implementation of the code in the GitHub repository to this series.

We see that we first have to create a new App



let mut app = App :: new (())

add routes



app .at ( "/users" )

and for each route add the HTTP requests we want to handle



app .at ( "/users" ) .get ( handle_get_users )

Each framework has a different method of extracting parameters and JSON bodies. Actix is using Extractors, rocket is using Query Guards.

With tide, you can access request parameters and bodies and database connections through Context . So when we want to update a User with a specific id , we send a PATCH to /users/:id . From there, we call the handle_update_user method.

Inside this method, we can access the id from the URI like this:



let id = cx .param ( "id" ) .client_err () ? ;

Each framework is also handling its own way of sending responses back to the sender. Tide is using EndpointResult , rocket is using Response and actix HttpResponse.

Everything else is completely up to you. The framework might help you with session management and authentication, but you can also implement this yourself.

My suggestion is: Build the first skeleton of your app with the framework of your choice, figure out how to extract information out of requests and how to form responses. Once this is working, you can use your Rust skills to build small or big applications as you wish.

Input Validation

Your best friend in the Rust world will be serde. It will help you parse JSON and other formats, but will also allow you to serialize your data.

When we talk about input validation, we want to make sure the data we are getting has the right format. Lets say we are extracting the JSON body out of a request:



let user : User = serde_json :: from_str ( & request_body );

We are using serde_json here to transform a JSON-String into a Struct of our choice. So if we created this struct:



struct User { name : String , height : u32 , }

we want to make sure the sender is including name and height . If we just do serde_json::from_str , and the sender forgot to pass on the height, the app will panic and shut down, since we expect the response to be a user: let user: User .

We can improve the error handling like this:



let user : User = match serde_json :: from_str ( & request_body ) { Ok ( user ) => user , Err ( error ) => handle_error_case ( error ), };

We catch the error and call our handle_error_case method to handle it gracefully.

Summary