1123 lines
37 KiB
Text
1123 lines
37 KiB
Text
# Serving an API
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Enough chit-chat about type-level combinators and representing an API as a
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type. Can we have a webservice already?
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## A first example
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Equipped with some basic knowledge about the way we represent APIs, let's now
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write our first webservice.
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## Setting up our project
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Don't forget to look at the [cabal file included with this example project](tutorial.cabal). You can run the main function provided in the following examples within the `Server` module without using a separate executable.
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If you're using Stack, then in your `stack.yaml` you may want to specify version 0.11.1.1 for `aeson`, and version 0.5 for `servant` and `servant-server` in your `extra-deps`.
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## Writing our Server
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The source for this tutorial section is a literate haskell file. To start our Server module, we
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need to have some language extensions and imports:
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``` haskell
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{-# LANGUAGE DataKinds #-}
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{-# LANGUAGE DeriveGeneric #-}
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{-# LANGUAGE FlexibleInstances #-}
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{-# LANGUAGE GeneralizedNewtypeDeriving #-}
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{-# LANGUAGE MultiParamTypeClasses #-}
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{-# LANGUAGE OverloadedStrings #-}
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{-# LANGUAGE ScopedTypeVariables #-}
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{-# LANGUAGE TypeOperators #-}
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module Server where
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import Prelude ()
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import Prelude.Compat
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import Control.Monad.Except
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import Control.Monad.Reader
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import Data.Aeson.Compat
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import Data.Aeson.Types
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import Data.Attoparsec.ByteString
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import Data.ByteString (ByteString)
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import Data.List
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import Data.Maybe
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import Data.String.Conversions
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import Data.Time.Calendar
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import GHC.Generics
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import Lucid
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import Network.HTTP.Media ((//), (/:))
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import Network.Wai
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import Network.Wai.Handler.Warp
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import Servant
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import System.Directory
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import Text.Blaze
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import Text.Blaze.Html.Renderer.Utf8
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import qualified Data.Aeson.Parser
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import qualified Text.Blaze.Html
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```
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**Important**: the `Servant` module comes from the **servant-server** package,
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the one that lets us run webservers that implement a particular API type. It
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reexports all the types from the **servant** package that let you declare API
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types as well as everything you need to turn your request handlers into a
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fully-fledged webserver. This means that in your applications, you can just add
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**servant-server** as a dependency, import `Servant` and not worry about anything
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else.
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We will write a server that will serve the following API.
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``` haskell
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type UserAPI1 = "users" :> Get '[JSON] [User]
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```
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Here's what we would like to see when making a GET request to `/users`.
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``` javascript
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[ {"name": "Isaac Newton", "age": 372, "email": "isaac@newton.co.uk", "registration_date": "1683-03-01"}
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, {"name": "Albert Einstein", "age": 136, "email": "ae@mc2.org", "registration_date": "1905-12-01"}
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]
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```
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Now let's define our `User` data type and write some instances for it.
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``` haskell
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data User = User
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{ name :: String
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, age :: Int
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, email :: String
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, registration_date :: Day
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} deriving (Eq, Show, Generic)
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instance ToJSON User
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```
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Nothing funny going on here. But we now can define our list of two users.
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``` haskell
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users1 :: [User]
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users1 =
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[ User "Isaac Newton" 372 "isaac@newton.co.uk" (fromGregorian 1683 3 1)
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, User "Albert Einstein" 136 "ae@mc2.org" (fromGregorian 1905 12 1)
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]
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```
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Let's also write our API type.
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``` haskell ignore
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type UserAPI1 = "users" :> Get '[JSON] [User]
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```
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We can now take care of writing the actual webservice that will handle requests
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to such an API. This one will be very simple, being reduced to just a single
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endpoint. The type of the web application is determined by the API type,
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through a *type family* named `Server`. (Type families are just functions that
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take types as input and return types.) The `Server` type family will compute
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the right type that a bunch of request handlers should have just from the
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corresponding API type.
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The first thing to know about the `Server` type family is that behind the
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scenes it will drive the routing, letting you focus only on the business
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logic. The second thing to know is that for each endpoint, your handlers will
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by default run in the `ExceptT ServantErr IO` monad. This is overridable very
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easily, as explained near the end of this guide. Third thing, the type of the
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value returned in that monad must be the same as the second argument of the
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HTTP method combinator used for the corresponding endpoint. In our case, it
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means we must provide a handler of type `ExceptT ServantErr IO [User]`. Well,
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we have a monad, let's just `return` our list:
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``` haskell
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server1 :: Server UserAPI1
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server1 = return users1
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```
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That's it. Now we can turn `server` into an actual webserver using
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[wai](http://hackage.haskell.org/package/wai) and
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[warp](http://hackage.haskell.org/package/warp):
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``` haskell
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userAPI :: Proxy UserAPI1
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userAPI = Proxy
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-- 'serve' comes from servant and hands you a WAI Application,
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-- which you can think of as an "abstract" web application,
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-- not yet a webserver.
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app1 :: Application
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app1 = serve userAPI server1
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```
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The `userAPI` bit is, alas, boilerplate (we need it to guide type inference).
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But that's about as much boilerplate as you get.
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And we're done! Let's run our webservice on the port 8081.
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``` haskell
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main :: IO ()
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main = run 8081 app1
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```
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You can put this all into a file or just grab [servant's
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repo](http://github.com/haskell-servant/servant) and look at the
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*doc/tutorial* directory. This code (the source of this web page) is in
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*doc/tutorial/Server.md*.
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If you run it, you can go to `http://localhost:8081/users` in your browser or
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query it with curl and you see:
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``` bash
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$ curl http://localhost:8081/users
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[{"email":"isaac@newton.co.uk","registration_date":"1683-03-01","age":372,"name":"Isaac Newton"},{"email":"ae@mc2.org","registration_date":"1905-12-01","age":136,"name":"Albert Einstein"}]
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```
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## More endpoints
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What if we want more than one endpoint? Let's add `/albert` and `/isaac` to
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view the corresponding users encoded in JSON.
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``` haskell
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type UserAPI2 = "users" :> Get '[JSON] [User]
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:<|> "albert" :> Get '[JSON] User
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:<|> "isaac" :> Get '[JSON] User
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```
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And let's adapt our code a bit.
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``` haskell
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isaac :: User
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isaac = User "Isaac Newton" 372 "isaac@newton.co.uk" (fromGregorian 1683 3 1)
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albert :: User
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albert = User "Albert Einstein" 136 "ae@mc2.org" (fromGregorian 1905 12 1)
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users2 :: [User]
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users2 = [isaac, albert]
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```
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Now, just like we separate the various endpoints in `UserAPI` with `:<|>`, we
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are going to separate the handlers with `:<|>` too! They must be provided in
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the same order as in in the API type.
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``` haskell
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server2 :: Server UserAPI2
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server2 = return users2
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:<|> return albert
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:<|> return isaac
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```
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And that's it! You can run this example in the same way that we showed for
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`server1` and check out the data available at `/users`, `/albert` and `/isaac`.
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## From combinators to handler arguments
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Fine, we can write trivial webservices easily, but none of the two above use
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any "fancy" combinator from servant. Let's address this and use `QueryParam`,
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`Capture` and `ReqBody` right away. You'll see how each occurence of these
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combinators in an endpoint makes the corresponding handler receive an
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argument of the appropriate type automatically. You don't have to worry about
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manually looking up URL captures or query string parameters, or
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decoding/encoding data from/to JSON. Never.
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We are going to use the following data types and functions to implement a
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server for `API`.
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``` haskell
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type API = "position" :> Capture "x" Int :> Capture "y" Int :> Get '[JSON] Position
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:<|> "hello" :> QueryParam "name" String :> Get '[JSON] HelloMessage
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:<|> "marketing" :> ReqBody '[JSON] ClientInfo :> Post '[JSON] Email
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data Position = Position
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{ xCoord :: Int
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, yCoord :: Int
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} deriving Generic
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instance ToJSON Position
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newtype HelloMessage = HelloMessage { msg :: String }
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deriving Generic
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instance ToJSON HelloMessage
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data ClientInfo = ClientInfo
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{ clientName :: String
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, clientEmail :: String
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, clientAge :: Int
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, clientInterestedIn :: [String]
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} deriving Generic
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instance FromJSON ClientInfo
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instance ToJSON ClientInfo
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data Email = Email
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{ from :: String
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, to :: String
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, subject :: String
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, body :: String
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} deriving Generic
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instance ToJSON Email
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emailForClient :: ClientInfo -> Email
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emailForClient c = Email from' to' subject' body'
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where from' = "great@company.com"
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to' = clientEmail c
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subject' = "Hey " ++ clientName c ++ ", we miss you!"
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body' = "Hi " ++ clientName c ++ ",\n\n"
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++ "Since you've recently turned " ++ show (clientAge c)
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++ ", have you checked out our latest "
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++ intercalate ", " (clientInterestedIn c)
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++ " products? Give us a visit!"
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```
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We can implement handlers for the three endpoints:
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``` haskell
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server3 :: Server API
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server3 = position
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:<|> hello
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:<|> marketing
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where position :: Int -> Int -> ExceptT ServantErr IO Position
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position x y = return (Position x y)
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hello :: Maybe String -> ExceptT ServantErr IO HelloMessage
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hello mname = return . HelloMessage $ case mname of
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Nothing -> "Hello, anonymous coward"
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Just n -> "Hello, " ++ n
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marketing :: ClientInfo -> ExceptT ServantErr IO Email
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marketing clientinfo = return (emailForClient clientinfo)
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```
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Did you see that? The types for your handlers changed to be just what we
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needed! In particular:
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- a `Capture "something" a` becomes an argument of type `a` (for `position`);
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- a `QueryParam "something" a` becomes an argument of type `Maybe a` (because
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an endpoint can technically be accessed without specifying any query
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string parameter, we decided to "force" handlers to be aware that the
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parameter might not always be there);
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- a `ReqBody contentTypeList a` becomes an argument of type `a`;
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And that's it. Here's the example in action:
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``` bash
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$ curl http://localhost:8081/position/1/2
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{"xCoord":1,"yCoord":2}
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$ curl http://localhost:8081/hello
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{"msg":"Hello, anonymous coward"}
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$ curl http://localhost:8081/hello?name=Alp
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{"msg":"Hello, Alp"}
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$ curl -X POST -d '{"clientName":"Alp Mestanogullari", "clientEmail" : "alp@foo.com", "clientAge": 25, "clientInterestedIn": ["haskell", "mathematics"]}' -H 'Accept: application/json' -H 'Content-type: application/json' http://localhost:8081/marketing
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{"subject":"Hey Alp Mestanogullari, we miss you!","body":"Hi Alp Mestanogullari,\n\nSince you've recently turned 25, have you checked out our latest haskell, mathematics products? Give us a visit!","to":"alp@foo.com","from":"great@company.com"}
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```
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For reference, here's a list of some combinators from **servant**:
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> - `Delete`, `Get`, `Patch`, `Post`, `Put`: these do not become arguments. They provide the return type of handlers, which usually is `ExceptT ServantErr IO <something>`.
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> - `Capture "something" a` becomes an argument of type `a`.
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> - `QueryParam "something" a`, `Header "something" a` all become arguments of type `Maybe a`, because there might be no value at all specified by the client for these.
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> - `QueryFlag "something"` gets turned into an argument of type `Bool`.
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> - `QueryParams "something" a` gets turned into an argument of type `[a]`.
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> - `ReqBody contentTypes a` gets turned into an argument of type `a`.
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## The `FromHttpApiData`/`ToHttpApiData` classes
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Wait... How does **servant** know how to decode the `Int`s from the URL? Or how
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to decode a `ClientInfo` value from the request body? This is what this and the
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following two sections address.
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`Capture`s and `QueryParam`s are represented by some textual value in URLs.
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`Header`s are similarly represented by a pair of a header name and a
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corresponding (textual) value in the request's "metadata". How types are
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decoded from headers, captures, and query params is expressed in a class
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`FromHttpApiData` (from the package
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[**http-api-data**](http://hackage.haskell.org/package/http-api-data)):
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``` haskell ignore
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class FromHttpApiData a where
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{-# MINIMAL parseUrlPiece | parseQueryParam #-}
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-- | Parse URL path piece.
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parseUrlPiece :: Text -> Either Text a
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parseUrlPiece = parseQueryParam
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-- | Parse HTTP header value.
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parseHeader :: ByteString -> Either Text a
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parseHeader = parseUrlPiece . decodeUtf8
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-- | Parse query param value.
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parseQueryParam :: Text -> Either Text a
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parseQueryParam = parseUrlPiece
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```
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As you can see, as long as you provide either `parseUrlPiece` (for `Capture`s)
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or `parseQueryParam` (for `QueryParam`s), the other methods will be defined in
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terms of this.
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**http-api-data** provides a decent number of instances, helpers for defining new
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ones, and wonderful documentation.
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There's not much else to say about these classes. You will need instances for
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them when using `Capture`, `QueryParam`, `QueryParams`, and `Header` with your
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types. You will need `FromHttpApiData` instances for server-side request
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handlers and `ToHttpApiData` instances only when using
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**servant-client**, as described in the [section about deriving haskell
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functions to query an API](Client.html).
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## Using content-types with your data types
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The same principle was operating when decoding request bodies from JSON, and
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responses *into* JSON. (JSON is just the running example - you can do this with
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any content-type.)
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This section introduces a couple of typeclasses provided by **servant** that make
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all of this work.
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### The truth behind `JSON`
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What exactly is `JSON` (the type as used in `Get '[JSON] User`)? Like the 3
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other content-types provided out of the box by **servant**, it's a really dumb
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data type.
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``` haskell ignore
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data JSON
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data PlainText
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data FormUrlEncoded
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data OctetStream
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```
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Obviously, this is not all there is to `JSON`, otherwise it would be quite
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pointless. Like most of the data types in **servant**, `JSON` is mostly there as
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a special *symbol* that's associated with encoding (resp. decoding) to (resp.
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from) the *JSON* format. The way this association is performed can be
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decomposed into two steps.
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The first step is to provide a proper
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`MediaType` (from
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[**http-media**](https://hackage.haskell.org/package/http-media-0.6.2/docs/Network-HTTP-Media.html))
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representation for `JSON`, or for your own content-types. If you look at the
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haddocks from this link, you can see that we just have to specify
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`application/json` using the appropriate functions. In our case, we can just
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use `(//) :: ByteString -> ByteString -> MediaType`. The precise way to specify
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the `MediaType` is to write an instance for the `Accept` class:
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``` haskell ignore
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-- for reference:
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class Accept ctype where
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contentType :: Proxy ctype -> MediaType
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instance Accept JSON where
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contentType _ = "application" // "json"
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```
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The second step is centered around the `MimeRender` and `MimeUnrender` classes.
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These classes just let you specify a way to encode and decode
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values into or from your content-type's representation.
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``` haskell ignore
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class Accept ctype => MimeRender ctype a where
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mimeRender :: Proxy ctype -> a -> ByteString
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-- alternatively readable as:
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mimeRender :: Proxy ctype -> (a -> ByteString)
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```
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Given a content-type and some user type, `MimeRender` provides a function that
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encodes values of type `a` to lazy `ByteString`s.
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In the case of `JSON`, this is easily dealt with! For any type `a` with a
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`ToJSON` instance, we can render values of that type to JSON using
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`Data.Aeson.encode`.
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``` haskell ignore
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instance ToJSON a => MimeRender JSON a where
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mimeRender _ = encode
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```
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And now the `MimeUnrender` class, which lets us extract values from lazy
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`ByteString`s, alternatively failing with an error string.
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``` haskell ignore
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class Accept ctype => MimeUnrender ctype a where
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mimeUnrender :: Proxy ctype -> ByteString -> Either String a
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```
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We don't have much work to do there either, `Data.Aeson.eitherDecode` is
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precisely what we need. However, it only allows arrays and objects as toplevel
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JSON values and this has proven to get in our way more than help us so we wrote
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our own little function around **aeson** and **attoparsec** that allows any type of
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JSON value at the toplevel of a "JSON document". Here's the definition in case
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you are curious.
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``` haskell
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eitherDecodeLenient :: FromJSON a => ByteString -> Either String a
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eitherDecodeLenient input = do
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v :: Value <- parseOnly (Data.Aeson.Parser.value <* endOfInput) (cs input)
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parseEither parseJSON v
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```
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This function is exactly what we need for our `MimeUnrender` instance.
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``` haskell ignore
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instance FromJSON a => MimeUnrender JSON a where
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mimeUnrender _ = eitherDecodeLenient
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```
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And this is all the code that lets you use `JSON` with `ReqBody`, `Get`,
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`Post` and friends. We can check our understanding by implementing support
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for an `HTML` content-type, so that users of your webservice can access an
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HTML representation of the data they want, ready to be included in any HTML
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document, e.g. using [jQuery's `load` function](https://api.jquery.com/load/),
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simply by adding `Accept: text/html` to their request headers.
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### Case-studies: **servant-blaze** and **servant-lucid**
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These days, most of the haskellers who write their HTML UIs directly from
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Haskell use either [**blaze-html**](http://hackage.haskell.org/package/blaze-html)
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or [**lucid**](http://hackage.haskell.org/package/lucid). The best option for
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**servant** is obviously to support both (and hopefully other templating
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solutions!). We're first going to look at **lucid**:
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``` haskell
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data HTMLLucid
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```
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Once again, the data type is just there as a symbol for the encoding/decoding
|
|
functions, except that this time we will only worry about encoding since
|
|
**lucid** doesn't provide a way to extract data from HTML.
|
|
|
|
``` haskell
|
|
instance Accept HTMLLucid where
|
|
contentType _ = "text" // "html" /: ("charset", "utf-8")
|
|
```
|
|
|
|
Note that this instance uses the `(/:)` operator from **http-media** which lets
|
|
us specify additional information about a content-type, like the charset here.
|
|
|
|
The rendering instances call similar functions that take
|
|
types with an appropriate instance to an "abstract" HTML representation and
|
|
then write that to a `ByteString`.
|
|
|
|
``` haskell
|
|
instance ToHtml a => MimeRender HTMLLucid a where
|
|
mimeRender _ = renderBS . toHtml
|
|
|
|
-- let's also provide an instance for lucid's
|
|
-- 'Html' wrapper.
|
|
instance MimeRender HTMLLucid (Html a) where
|
|
mimeRender _ = renderBS
|
|
```
|
|
|
|
For **blaze-html** everything works very similarly:
|
|
|
|
``` haskell
|
|
-- For this tutorial to compile 'HTMLLucid' and 'HTMLBlaze' have to be
|
|
-- distinct. Usually you would stick to one html rendering library and then
|
|
-- you can go with one 'HTML' type.
|
|
data HTMLBlaze
|
|
|
|
instance Accept HTMLBlaze where
|
|
contentType _ = "text" // "html" /: ("charset", "utf-8")
|
|
|
|
instance ToMarkup a => MimeRender HTMLBlaze a where
|
|
mimeRender _ = renderHtml . Text.Blaze.Html.toHtml
|
|
|
|
-- while we're at it, just like for lucid we can
|
|
-- provide an instance for rendering blaze's 'Html' type
|
|
instance MimeRender HTMLBlaze Text.Blaze.Html.Html where
|
|
mimeRender _ = renderHtml
|
|
```
|
|
|
|
Both [**servant-blaze**](http://hackage.haskell.org/package/servant-blaze) and
|
|
[**servant-lucid**](http://hackage.haskell.org/package/servant-lucid) let you use
|
|
`HTMLLucid` and `HTMLBlaze` in any content-type list as long as you provide an instance of the
|
|
appropriate class (`ToMarkup` for **blaze-html**, `ToHtml` for **lucid**).
|
|
|
|
We can now write a webservice that uses **servant-lucid** to show the `HTMLLucid`
|
|
content-type in action. We will be serving the following API:
|
|
|
|
``` haskell
|
|
type PersonAPI = "persons" :> Get '[JSON, HTMLLucid] [Person]
|
|
```
|
|
|
|
where `Person` is defined as follows:
|
|
|
|
``` haskell
|
|
data Person = Person
|
|
{ firstName :: String
|
|
, lastName :: String
|
|
} deriving Generic -- for the JSON instance
|
|
|
|
instance ToJSON Person
|
|
```
|
|
|
|
Now, let's teach **lucid** how to render a `Person` as a row in a table, and then
|
|
a list of `Person`s as a table with a row per person.
|
|
|
|
``` haskell
|
|
-- HTML serialization of a single person
|
|
instance ToHtml Person where
|
|
toHtml person =
|
|
tr_ $ do
|
|
td_ (toHtml $ firstName person)
|
|
td_ (toHtml $ lastName person)
|
|
|
|
-- do not worry too much about this
|
|
toHtmlRaw = toHtml
|
|
|
|
-- HTML serialization of a list of persons
|
|
instance ToHtml [Person] where
|
|
toHtml persons = table_ $ do
|
|
tr_ $ do
|
|
th_ "first name"
|
|
th_ "last name"
|
|
|
|
-- this just calls toHtml on each person of the list
|
|
-- and concatenates the resulting pieces of HTML together
|
|
foldMap toHtml persons
|
|
|
|
toHtmlRaw = toHtml
|
|
```
|
|
|
|
We create some `Person` values and serve them as a list:
|
|
|
|
``` haskell
|
|
people :: [Person]
|
|
people =
|
|
[ Person "Isaac" "Newton"
|
|
, Person "Albert" "Einstein"
|
|
]
|
|
|
|
personAPI :: Proxy PersonAPI
|
|
personAPI = Proxy
|
|
|
|
server4 :: Server PersonAPI
|
|
server4 = return people
|
|
|
|
app2 :: Application
|
|
app2 = serve personAPI server4
|
|
```
|
|
|
|
And we're good to go:
|
|
|
|
``` bash
|
|
$ curl http://localhost:8081/persons
|
|
[{"lastName":"Newton","firstName":"Isaac"},{"lastName":"Einstein","firstName":"Albert"}]
|
|
$ curl -H 'Accept: text/html' http://localhost:8081/persons
|
|
<table><tr><td>first name</td><td>last name</td></tr><tr><td>Isaac</td><td>Newton</td></tr><tr><td>Albert</td><td>Einstein</td></tr></table>
|
|
# or just point your browser to http://localhost:8081/persons
|
|
```
|
|
|
|
## The `ExceptT ServantErr IO` monad
|
|
|
|
At the heart of the handlers is the monad they run in, namely `ExceptT
|
|
ServantErr IO`
|
|
([haddock documentation for `ExceptT`](http://hackage.haskell.org/package/mtl-2.2.1/docs/Control-Monad-Except.html#t:ExceptT)).
|
|
One might wonder: why this monad? The answer is that it is the
|
|
simplest monad with the following properties:
|
|
|
|
- it lets us both return a successful result (using `return`)
|
|
or "fail" with a descriptive error (using `throwError`);
|
|
- it lets us perform IO, which is absolutely vital since most webservices exist
|
|
as interfaces to databases that we interact with in `IO`.
|
|
|
|
Let's recall some definitions.
|
|
|
|
``` haskell ignore
|
|
-- from the 'mtl' package at
|
|
newtype ExceptT e m a = ExceptT (m (Either e a))
|
|
```
|
|
|
|
In short, this means that a handler of type `ExceptT ServantErr IO a` is simply
|
|
equivalent to a computation of type `IO (Either ServantErr a)`, that is, an IO
|
|
action that either returns an error or a result.
|
|
|
|
The module [`Control.Monad.Except`](https://hackage.haskell.org/package/mtl-2.2.1/docs/Control-Monad-Except.html#t:ExceptT)
|
|
from which `ExceptT` comes is worth looking at.
|
|
Perhaps most importantly, `ExceptT` is an instance of `MonadError`, so
|
|
`throwError` can be used to return an error from your handler (whereas `return`
|
|
is enough to return a success).
|
|
|
|
Most of what you'll be doing in your handlers is running some IO and,
|
|
depending on the result, you might sometimes want to throw an error of some
|
|
kind and abort early. The next two sections cover how to do just that.
|
|
|
|
### Performing IO
|
|
|
|
Another important instance from the list above is `MonadIO m => MonadIO
|
|
(ExceptT e m)`.
|
|
[`MonadIO`](http://hackage.haskell.org/package/transformers-0.4.3.0/docs/Control-Monad-IO-Class.html)
|
|
is a class from the **transformers** package defined as:
|
|
|
|
``` haskell ignore
|
|
class Monad m => MonadIO m where
|
|
liftIO :: IO a -> m a
|
|
```
|
|
|
|
The `IO` monad provides a `MonadIO` instance. Hence for any type
|
|
`e`, `ExceptT e IO` has a `MonadIO` instance. So if you want to run any kind of
|
|
IO computation in your handlers, just use `liftIO`:
|
|
|
|
``` haskell
|
|
type IOAPI1 = "myfile.txt" :> Get '[JSON] FileContent
|
|
|
|
newtype FileContent = FileContent
|
|
{ content :: String }
|
|
deriving Generic
|
|
|
|
instance ToJSON FileContent
|
|
|
|
server5 :: Server IOAPI1
|
|
server5 = do
|
|
filecontent <- liftIO (readFile "myfile.txt")
|
|
return (FileContent filecontent)
|
|
```
|
|
|
|
### Failing, through `ServantErr`
|
|
|
|
If you want to explicitly fail at providing the result promised by an endpoint
|
|
using the appropriate HTTP status code (not found, unauthorized, etc) and some
|
|
error message, all you have to do is use the `throwError` function mentioned above
|
|
and provide it with the appropriate value of type `ServantErr`, which is
|
|
defined as:
|
|
|
|
``` haskell ignore
|
|
data ServantErr = ServantErr
|
|
{ errHTTPCode :: Int
|
|
, errReasonPhrase :: String
|
|
, errBody :: ByteString -- lazy bytestring
|
|
, errHeaders :: [Header]
|
|
}
|
|
```
|
|
|
|
Many standard values are provided out of the box by the `Servant.Server`
|
|
module. If you want to use these values but add a body or some headers, just
|
|
use record update syntax:
|
|
|
|
``` haskell
|
|
failingHandler :: ExceptT ServantErr IO ()
|
|
failingHandler = throwError myerr
|
|
|
|
where myerr :: ServantErr
|
|
myerr = err503 { errBody = "Sorry dear user." }
|
|
```
|
|
|
|
Here's an example where we return a customised 404-Not-Found error message in
|
|
the response body if "myfile.txt" isn't there:
|
|
|
|
``` haskell
|
|
server6 :: Server IOAPI1
|
|
server6 = do
|
|
exists <- liftIO (doesFileExist "myfile.txt")
|
|
if exists
|
|
then liftIO (readFile "myfile.txt") >>= return . FileContent
|
|
else throwError custom404Err
|
|
|
|
where custom404Err = err404 { errBody = "myfile.txt just isn't there, please leave this server alone." }
|
|
```
|
|
|
|
Here's how that server looks in action:
|
|
|
|
``` bash
|
|
$ curl --verbose http://localhost:8081/myfile.txt
|
|
[snip]
|
|
* Connected to localhost (127.0.0.1) port 8081 (#0)
|
|
> GET /myfile.txt HTTP/1.1
|
|
> User-Agent: curl/7.30.0
|
|
> Host: localhost:8081
|
|
> Accept: */*
|
|
>
|
|
< HTTP/1.1 404 Not Found
|
|
[snip]
|
|
myfile.txt just isnt there, please leave this server alone.
|
|
|
|
$ echo Hello > myfile.txt
|
|
|
|
$ curl --verbose http://localhost:8081/myfile.txt
|
|
[snip]
|
|
* Connected to localhost (127.0.0.1) port 8081 (#0)
|
|
> GET /myfile.txt HTTP/1.1
|
|
> User-Agent: curl/7.30.0
|
|
> Host: localhost:8081
|
|
> Accept: */*
|
|
>
|
|
< HTTP/1.1 200 OK
|
|
[snip]
|
|
< Content-Type: application/json
|
|
[snip]
|
|
{"content":"Hello\n"}
|
|
```
|
|
|
|
## Response headers
|
|
|
|
To add headers to your response, use
|
|
[addHeader](http://hackage.haskell.org/package/servant/docs/Servant-API-ResponseHeaders.html).
|
|
Note that this changes the type of your API, as we can see in the following example:
|
|
|
|
``` haskell
|
|
type MyHandler = Get '[JSON] (Headers '[Header "X-An-Int" Int] User)
|
|
|
|
myHandler :: Server MyHandler
|
|
myHandler = return $ addHeader 1797 albert
|
|
```
|
|
|
|
Note that the type of `addHeader x` is different than the type of `x`!
|
|
|
|
## Serving static files
|
|
|
|
**servant-server** also provides a way to just serve the content of a directory
|
|
under some path in your web API. As mentioned earlier in this document, the
|
|
`Raw` combinator can be used in your APIs to mean "plug here any WAI
|
|
application". Well, **servant-server** provides a function to get a file and
|
|
directory serving WAI application, namely:
|
|
|
|
``` haskell ignore
|
|
-- exported by Servant and Servant.Server
|
|
serveDirectory :: FilePath -> Server Raw
|
|
```
|
|
|
|
`serveDirectory`'s argument must be a path to a valid directory.
|
|
|
|
Here's an example API that will serve some static files:
|
|
|
|
``` haskell
|
|
type StaticAPI = "static" :> Raw
|
|
```
|
|
|
|
And the server:
|
|
|
|
``` haskell
|
|
staticAPI :: Proxy StaticAPI
|
|
staticAPI = Proxy
|
|
```
|
|
|
|
``` haskell
|
|
server7 :: Server StaticAPI
|
|
server7 = serveDirectory "static-files"
|
|
|
|
app3 :: Application
|
|
app3 = serve staticAPI server7
|
|
```
|
|
|
|
This server will match any request whose path starts with `/static` and will look
|
|
for a file at the path described by the rest of the request path, inside the
|
|
*static-files/* directory of the path you run the program from.
|
|
|
|
In other words: If a client requests `/static/foo.txt`, the server will look for a file at
|
|
`./static-files/foo.txt`. If that file exists it'll succeed and serve the file.
|
|
If it doesn't exist, the handler will fail with a `404` status code.
|
|
|
|
## Nested APIs
|
|
|
|
Let's see how you can define APIs in a modular way, while avoiding repetition.
|
|
Consider this simple example:
|
|
|
|
``` haskell
|
|
type UserAPI3 = -- view the user with given userid, in JSON
|
|
Capture "userid" Int :> Get '[JSON] User
|
|
|
|
:<|> -- delete the user with given userid. empty response
|
|
Capture "userid" Int :> Delete '[] ()
|
|
```
|
|
|
|
We can instead factor out the `userid`:
|
|
|
|
``` haskell
|
|
type UserAPI4 = Capture "userid" Int :>
|
|
( Get '[JSON] User
|
|
:<|> Delete '[] ()
|
|
)
|
|
```
|
|
|
|
However, you have to be aware that this has an effect on the type of the
|
|
corresponding `Server`:
|
|
|
|
``` haskell ignore
|
|
Server UserAPI3 = (Int -> ExceptT ServantErr IO User)
|
|
:<|> (Int -> ExceptT ServantErr IO ())
|
|
|
|
Server UserAPI4 = Int -> ( ExceptT ServantErr IO User
|
|
:<|> ExceptT ServantErr IO ()
|
|
)
|
|
```
|
|
|
|
In the first case, each handler receives the *userid* argument. In the latter,
|
|
the whole `Server` takes the *userid* and has handlers that are just
|
|
computations in `ExceptT`, with no arguments. In other words:
|
|
|
|
``` haskell
|
|
server8 :: Server UserAPI3
|
|
server8 = getUser :<|> deleteUser
|
|
|
|
where getUser :: Int -> ExceptT ServantErr IO User
|
|
getUser _userid = error "..."
|
|
|
|
deleteUser :: Int -> ExceptT ServantErr IO ()
|
|
deleteUser _userid = error "..."
|
|
|
|
-- notice how getUser and deleteUser
|
|
-- have a different type! no argument anymore,
|
|
-- the argument directly goes to the whole Server
|
|
server9 :: Server UserAPI4
|
|
server9 userid = getUser userid :<|> deleteUser userid
|
|
|
|
where getUser :: Int -> ExceptT ServantErr IO User
|
|
getUser = error "..."
|
|
|
|
deleteUser :: Int -> ExceptT ServantErr IO ()
|
|
deleteUser = error "..."
|
|
```
|
|
|
|
Note that there's nothing special about `Capture` that lets you "factor it
|
|
out": this can be done with any combinator. Here are a few examples of APIs
|
|
with a combinator factored out for which we can write a perfectly valid
|
|
`Server`.
|
|
|
|
``` haskell
|
|
-- we just factor out the "users" path fragment
|
|
type API1 = "users" :>
|
|
( Get '[JSON] [User] -- user listing
|
|
:<|> Capture "userid" Int :> Get '[JSON] User -- view a particular user
|
|
)
|
|
|
|
-- we factor out the Request Body
|
|
type API2 = ReqBody '[JSON] User :>
|
|
( Get '[JSON] User -- just display the same user back, don't register it
|
|
:<|> Post '[JSON] () -- register the user. empty response
|
|
)
|
|
|
|
-- we factor out a Header
|
|
type API3 = Header "Authorization" Token :>
|
|
( Get '[JSON] SecretData -- get some secret data, if authorized
|
|
:<|> ReqBody '[JSON] SecretData :> Post '[] () -- add some secret data, if authorized
|
|
)
|
|
|
|
newtype Token = Token ByteString
|
|
newtype SecretData = SecretData ByteString
|
|
```
|
|
|
|
This approach lets you define APIs modularly and assemble them all into one big
|
|
API type only at the end.
|
|
|
|
``` haskell
|
|
type UsersAPI =
|
|
Get '[JSON] [User] -- list users
|
|
:<|> ReqBody '[JSON] User :> Post '[] () -- add a user
|
|
:<|> Capture "userid" Int :>
|
|
( Get '[JSON] User -- view a user
|
|
:<|> ReqBody '[JSON] User :> Put '[] () -- update a user
|
|
:<|> Delete '[] () -- delete a user
|
|
)
|
|
|
|
usersServer :: Server UsersAPI
|
|
usersServer = getUsers :<|> newUser :<|> userOperations
|
|
|
|
where getUsers :: ExceptT ServantErr IO [User]
|
|
getUsers = error "..."
|
|
|
|
newUser :: User -> ExceptT ServantErr IO ()
|
|
newUser = error "..."
|
|
|
|
userOperations userid =
|
|
viewUser userid :<|> updateUser userid :<|> deleteUser userid
|
|
|
|
where
|
|
viewUser :: Int -> ExceptT ServantErr IO User
|
|
viewUser = error "..."
|
|
|
|
updateUser :: Int -> User -> ExceptT ServantErr IO ()
|
|
updateUser = error "..."
|
|
|
|
deleteUser :: Int -> ExceptT ServantErr IO ()
|
|
deleteUser = error "..."
|
|
```
|
|
|
|
``` haskell
|
|
type ProductsAPI =
|
|
Get '[JSON] [Product] -- list products
|
|
:<|> ReqBody '[JSON] Product :> Post '[] () -- add a product
|
|
:<|> Capture "productid" Int :>
|
|
( Get '[JSON] Product -- view a product
|
|
:<|> ReqBody '[JSON] Product :> Put '[] () -- update a product
|
|
:<|> Delete '[] () -- delete a product
|
|
)
|
|
|
|
data Product = Product { productId :: Int }
|
|
|
|
productsServer :: Server ProductsAPI
|
|
productsServer = getProducts :<|> newProduct :<|> productOperations
|
|
|
|
where getProducts :: ExceptT ServantErr IO [Product]
|
|
getProducts = error "..."
|
|
|
|
newProduct :: Product -> ExceptT ServantErr IO ()
|
|
newProduct = error "..."
|
|
|
|
productOperations productid =
|
|
viewProduct productid :<|> updateProduct productid :<|> deleteProduct productid
|
|
|
|
where
|
|
viewProduct :: Int -> ExceptT ServantErr IO Product
|
|
viewProduct = error "..."
|
|
|
|
updateProduct :: Int -> Product -> ExceptT ServantErr IO ()
|
|
updateProduct = error "..."
|
|
|
|
deleteProduct :: Int -> ExceptT ServantErr IO ()
|
|
deleteProduct = error "..."
|
|
```
|
|
|
|
``` haskell
|
|
type CombinedAPI = "users" :> UsersAPI
|
|
:<|> "products" :> ProductsAPI
|
|
|
|
server10 :: Server CombinedAPI
|
|
server10 = usersServer :<|> productsServer
|
|
```
|
|
|
|
Finally, we can realize the user and product APIs are quite similar and
|
|
abstract that away:
|
|
|
|
``` haskell
|
|
-- API for values of type 'a'
|
|
-- indexed by values of type 'i'
|
|
type APIFor a i =
|
|
Get '[JSON] [a] -- list 'a's
|
|
:<|> ReqBody '[JSON] a :> Post '[] () -- add an 'a'
|
|
:<|> Capture "id" i :>
|
|
( Get '[JSON] a -- view an 'a' given its "identifier" of type 'i'
|
|
:<|> ReqBody '[JSON] a :> Put '[] () -- update an 'a'
|
|
:<|> Delete '[] () -- delete an 'a'
|
|
)
|
|
|
|
-- Build the appropriate 'Server'
|
|
-- given the handlers of the right type.
|
|
serverFor :: ExceptT ServantErr IO [a] -- handler for listing of 'a's
|
|
-> (a -> ExceptT ServantErr IO ()) -- handler for adding an 'a'
|
|
-> (i -> ExceptT ServantErr IO a) -- handler for viewing an 'a' given its identifier of type 'i'
|
|
-> (i -> a -> ExceptT ServantErr IO ()) -- updating an 'a' with given id
|
|
-> (i -> ExceptT ServantErr IO ()) -- deleting an 'a' given its id
|
|
-> Server (APIFor a i)
|
|
serverFor = error "..."
|
|
-- implementation left as an exercise. contact us on IRC
|
|
-- or the mailing list if you get stuck!
|
|
```
|
|
|
|
## Using another monad for your handlers
|
|
|
|
Remember how `Server` turns combinators for HTTP methods into `ExceptT
|
|
ServantErr IO`? Well, actually, there's more to that. `Server` is actually a
|
|
simple type synonym.
|
|
|
|
``` haskell ignore
|
|
type Server api = ServerT api (ExceptT ServantErr IO)
|
|
```
|
|
|
|
`ServerT` is the actual type family that computes the required types for the
|
|
handlers that's part of the `HasServer` class. It's like `Server` except that
|
|
it takes another parameter which is the monad you want your handlers to run in,
|
|
or more generally the return types of your handlers. This third parameter is
|
|
used for specifying the return type of the handler for an endpoint, e.g when
|
|
computing `ServerT (Get '[JSON] Person) SomeMonad`. The result would be
|
|
`SomeMonad Person`.
|
|
|
|
The first and main question one might have then is: how do we write handlers
|
|
that run in another monad? How can we "bring back" the value from a given monad
|
|
into something **servant** can understand?
|
|
|
|
### Natural transformations
|
|
|
|
If we have a function that gets us from an `m a` to an `n a`, for any `a`, what
|
|
do we have?
|
|
|
|
``` haskell ignore
|
|
newtype m :~> n = Nat { unNat :: forall a. m a -> n a}
|
|
```
|
|
|
|
For example:
|
|
|
|
``` haskell
|
|
listToMaybeNat :: [] :~> Maybe
|
|
listToMaybeNat = Nat listToMaybe -- from Data.Maybe
|
|
```
|
|
|
|
(`Nat` comes from "natural transformation", in case you're wondering.)
|
|
|
|
So if you want to write handlers using another monad/type than `ExceptT
|
|
ServantErr IO`, say the `Reader String` monad, the first thing you have to
|
|
prepare is a function:
|
|
|
|
``` haskell ignore
|
|
readerToHandler :: Reader String :~> ExceptT ServantErr IO
|
|
```
|
|
|
|
Let's start with `readerToHandler'`. We obviously have to run the `Reader`
|
|
computation by supplying it with a `String`, like `"hi"`. We get an `a` out
|
|
from that and can then just `return` it into `ExceptT`. We can then just wrap
|
|
that function with the `Nat` constructor to make it have the fancier type.
|
|
|
|
``` haskell
|
|
readerToHandler' :: forall a. Reader String a -> ExceptT ServantErr IO a
|
|
readerToHandler' r = return (runReader r "hi")
|
|
|
|
readerToHandler :: Reader String :~> ExceptT ServantErr IO
|
|
readerToHandler = Nat readerToHandler'
|
|
```
|
|
|
|
We can write some simple webservice with the handlers running in `Reader String`.
|
|
|
|
``` haskell
|
|
type ReaderAPI = "a" :> Get '[JSON] Int
|
|
:<|> "b" :> Get '[JSON] String
|
|
|
|
readerAPI :: Proxy ReaderAPI
|
|
readerAPI = Proxy
|
|
|
|
readerServerT :: ServerT ReaderAPI (Reader String)
|
|
readerServerT = a :<|> b
|
|
|
|
where a :: Reader String Int
|
|
a = return 1797
|
|
|
|
b :: Reader String String
|
|
b = ask
|
|
```
|
|
|
|
We unfortunately can't use `readerServerT` as an argument of `serve`, because
|
|
`serve` wants a `Server ReaderAPI`, i.e., with handlers running in `ExceptT
|
|
ServantErr IO`. But there's a simple solution to this.
|
|
|
|
### Enter `enter`
|
|
|
|
That's right. We have just written `readerToHandler`, which is exactly what we
|
|
would need to apply to all handlers to make the handlers have the
|
|
right type for `serve`. Being cumbersome to do by hand, we provide a function
|
|
`enter` which takes a natural transformation between two parametrized types `m`
|
|
and `n` and a `ServerT someapi m`, and returns a `ServerT someapi n`.
|
|
|
|
In our case, we can wrap up our little webservice by using `enter
|
|
readerToHandler` on our handlers.
|
|
|
|
``` haskell
|
|
readerServer :: Server ReaderAPI
|
|
readerServer = enter readerToHandler readerServerT
|
|
|
|
app4 :: Application
|
|
app4 = serve readerAPI readerServer
|
|
```
|
|
|
|
This is the webservice in action:
|
|
|
|
``` bash
|
|
$ curl http://localhost:8081/a
|
|
1797
|
|
$ curl http://localhost:8081/b
|
|
"hi"
|
|
```
|
|
|
|
## Conclusion
|
|
|
|
You're now equipped to write webservices/web-applications using
|
|
**servant**. The rest of this document focuses on **servant-client**,
|
|
**servant-js** and **servant-docs**.
|