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28288a17b7
* Derive `Show` instance for `ClientSSLKeyCertPair` * Add a couple client helper functions & add additional exports * Add `grpc-haskell-core` target; add `c2hs` dep * Fix examples broken by #68 * rm `build-tools` and `include-dirs` directives from toplevel `.cabal` * More `ClientConfig` fixes * Ensure examples are built
217 lines
12 KiB
Markdown
217 lines
12 KiB
Markdown
## Introduction to gRPC-Haskell
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*This tutorial assumes that you already have a basic understanding of gRPC as well as Haskell.* For an intoduction to the concepts of gRPC, see the [official tutorials](http://www.grpc.io/docs/tutorials/).
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This will go through a basic example of using the library, with the `arithmetic` example in the `examples/arithmetic` directory. After cloning this repository, it would be a good idea to run `stack haddock` from within the repository directory to generate the documentation so you can read more about the functions and types we're using as we go. Also remember that [typed holes](https://wiki.haskell.org/GHC/Typed_holes) can be very handy.
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To build the examples, you can run
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```
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$ stack build --flag grpc-haskell:with-examples
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```
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The gRPC service we will be implementing provides two amazing functions:
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1. `Add`, which adds two integers.
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2. `RunningSum`, which receives a stream of integers from the client and finally returns a single integer that is the sum of all the integers it has received.
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You can run the examples by running `stack exec arithmetic-server` and `stack exec arithmetic-client`.
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### Library Organization
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**tl;dr: you probably only need to import `Network.GRPC.HighLevel.Generated`.** Other modules are exposed for advanced users only.
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This library exposes quite a few modules, but you won't need to worry about most of them. They are currently organized based on the level of abstraction they afford over using the C [gRPC Core library](http://www.grpc.io/grpc/core/) directly:
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* *`Unsafe`* modules directly wrap functions in the gRPC Core library. Using them directly is like using C: you need to think about memory management, pointers, and so on. The rest of the library is built on top of these functions and users of gRPC-haskell should never need to deal with the `Unsafe` modules directly.
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* *`LowLevel`* modules still require an understanding of the gRPC Core library, but guarantee memory and thread safety. Only advanced users with special requirements would use `LowLevel` modules directly.
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* *`HighLevel`* modules give you an opinionated Haskell interface to gRPC that should cover most use cases while (hopefully) being easy to use. You should only need to import the `Network.GRPC.HighLevel.Generated` module to start using the library. If you need to import other modules, we probably forgot to re-export something and you should open an issue or PR.
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### Getting started
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To start out, we need to generate code for our protocol buffers and RPCs. The `compile-proto-file` command is provided as part of `proto3-suite`. You can either use `stack install` in the `proto3-suite` repository to install the command globally, or use `stack exec` from within the `grpc-haskell` directory.
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```
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$ stack exec -- compile-proto-file --proto examples/echo/echo.proto > examples/echo/echo-hs/Echo.hs
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```
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The `.proto` file compiler always names the generated module the same as the `.proto` file, capitalizing the first letter if it is not already. Since our proto file is `arithmetic.proto`, the generated code should be placed in `Arithmetic.hs`.
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The important things to notice in this generated file are:
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1. For each proto message type, an equivalent Haskell type with the same name has been generated.
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2. The `arithmeticServer` function takes a a record containing handlers for each RPC endpoint and some options, and starts a server. So, you just need to call this function to get a server running.
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3, The `arithmeticClient` function takes a `Client` (which is just a proof that the gRPC core has been started) and gives you a record of functions that can be used to run RPCs.
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### The server
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First, we need to turn on some language extensions:
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```haskell
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{-# LANGUAGE DataKinds #-}
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{-# LANGUAGE GADTs #-}
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{-# LANGUAGE OverloadedLists #-}
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{-# LANGUAGE OverloadedStrings #-}
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```
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All we need to do to run a server is call the `arithmeticServer` function:
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```haskell
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main :: IO ()
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main = arithmeticServer handlers options
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```
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So we just need to define `handlers` and `options`.
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`options` is easy-- it's just some basic options for the server. We can just use the default options for now, which will start the server listening on `localhost:50051`:
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```haskell
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options :: ServiceOptions
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options = defaultServiceOptions
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```
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`handlers` is a bit more involved. Its type is `Arithmetic ServerRequest ServerResponse`. Values of this type contain a record field for each RPC defined in your `.proto` file.
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```haskell
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handlers :: Arithmetic ServerRequest ServerResponse
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handlers = Arithmetic { arithmeticAdd = addHandler
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, arithmeticRunningSum = runningSumHandler
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}
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```
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You can think of the handlers as being of type `ServerRequest -> ServerResponse`, though there are a few more type parameters in there. The most important one is the first parameter, which specifies whether the RPC is streaming (`ClientStreaming`, `ServerStreaming`, or `BidiStreaming`) or not (`Normal`).
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The `ServerRequest` passed to your handler contains all the tools you will need to handle the request, including:
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1. The metadata the client sent with the request.
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2. The protocol buffer message sent with the request, which has already been parsed into a Haskell type for you.
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3. If it's a streaming request, you will also be given functions for sending or receiving messages in the stream.
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#### The unary RPC handler for `Add`
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So, let's pattern match on the `ServerRequest` for the `addHandler` function:
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```haskell
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addHandler (ServerNormalRequest metadata (TwoInts x y)) = -- to be continued!
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```
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The body of the `addHandler` function just needs to add `x` and `y` and then bundle the answer up in a `ServerResponse`:
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```haskell
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addHandler (ServerNormalRequest _metadata (TwoInts x y)) = do
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let answer = OneInt (x + y)
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return (ServerNormalResponse answer
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[("metadata_key_one", "metadata_value")]
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StatusOk
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"addition is easy!")
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```
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Since this is a non-streaming "Normal" RPC, we use the the `ServerNormalResponse` constructor. Its parameters are the response message, some (optional) metadata key-value pairs, a status code, and a string with additional details about the status, which would normally be used to explain any errors in handling the request.
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#### The client streaming handler for `RunningSum`
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Now let's make our `runningSumHandler`. Since this is an RPC where the server reads from a stream of numbers, we pattern match on the `ServerReaderRequest` constructor:
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```haskell
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runningSumHandler req@(ServerReaderRequest metadata recv) = -- to be continued!
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```
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Unlike the unary "Normal" request handler, we don't get a message from the client in this pattern match. Instead, we get an IO action `recv`, which we can run to wait for the client to send us another message.
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There are three possibilities when we try to receive another message from the client:
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1. The RPC breaks with some gRPC error, such as losing the connection with the client.
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2. We receive another message from the client.
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3. The client has sent its last message and is waiting for a response.
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We write a simple loop that keeps track of the running sum and finally sends off a `ServerReaderResponse` when the client finishes streaming or an error occurs:
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```haskell
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runningSumHandler req@(ServerReaderRequest metadata recv) =
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loop 0
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where loop !i =
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do msg <- recv
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case msg of
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Left err -> return (ServerReaderResponse
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Nothing
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[]
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StatusUnknown
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(fromString (show err)))
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Right (Just (OneInt x)) -> loop (i + x)
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Right Nothing -> return (ServerReaderResponse
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(Just (OneInt i))
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[]
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StatusOk
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"")
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```
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The `ServerReaderResponse` type is almost the same as `ServerNormalResponse`, except that the first argument, the message to send back to the client, is optional. Otherwise, it takes metadata (which we leave empty), a status code, and a string containing more information about the status code.
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### The client
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The client-side code generated for us is `arithmeticClient`, which takes a `Client` as input and gives us a record containing actions that execute RPCs. To start up the C gRPC library and get a `Client`, we use `withGRPCClient`, which takes a `ClientConfig`:
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```haskell
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clientConfig :: ClientConfig
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clientConfig = ClientConfig { clientServerHost = "localhost"
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, clientServerPort = 50051
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, clientArgs = []
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, clientSSLConfig = Nothing
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, clientAuthority = Nothing
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}
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main :: IO ()
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main = withGRPCClient clientConfig $ \client -> do
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(Arithmetic arithmeticAdd arithmeticRunningSum) <- arithmeticClient client
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-- to be continued!
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```
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Now that we are on the client side, the `Arithmetic` record contains functions that make RPC requests. You can think of these functions as roughly having the type `ClientRequest -> ClientResult`. Like before, the particular constructors will vary depending on whether the RPC is streaming or not.
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#### Requesting unary RPC
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Here we construct a `ClientNormalRequest`, which takes as input a message, a timeout in seconds, and metadata. The result is a `ClientNormalResponse`, containing the server's response, the initial and trailing metadata for the call, and the status and status details string.
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```haskell
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-- Request for the Add RPC
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ClientNormalResponse (OneInt x) _meta1 _meta2 _status _details
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<- arithmeticAdd (ClientNormalRequest (TwoInts 2 2) 1 [])
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print ("2 + 2 = " ++ (show x))
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```
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#### Executing a client streaming RPC
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Doing a streaming request is slightly trickier. As input to the streaming RPC action, we pass in another IO action that tells `grpc-haskell` what to send. It takes a `send` action as input. This is a bit convoluted, but it guarantees that you can't send streaming messages outside of the context of a streaming call!
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```haskell
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-- Request for the RunningSum RPC
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ClientWriterResponse reply _streamMeta1 _streamMeta2 streamStatus streamDtls
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<- arithmeticRunningSum $ ClientWriterRequest 1 [] $ \send -> do
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eithers <- mapM send [OneInt 1, OneInt 2, OneInt 3]
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:: IO [Either GRPCIOError ()]
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case sequence eithers of
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Left err -> error ("Error while streaming: " ++ show err)
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Right _ -> return ()
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```
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Each `send` potentially returns an error message, with the type `Either GRPCIOError ()`. We use `sequence` to run all the `send` actions, and then use `sequence` again to collapse all the `Either`s. If an error is encountered while streaming, there's nothing we can do to salvage the RPC, so a more serious program would need to do some application-specific error-handling. Since this is just a tutorial, we print an error message and exit. Otherwise, we `return ()` to finish sending.
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We can now inspect the `reply` to get our answer to the RPC.
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```haskell
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case reply of
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Just (OneInt y) -> print ("1 + 2 + 3 = " ++ show y)
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Nothing -> putStrLn ("Client stream failed with status "
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++ show streamStatus
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++ " and details "
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++ show streamDtls)
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```
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To run the examples and see the requests, start the `arithmetic-server` process in the background, and then run the `arithmetic-client` process:
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```
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$ stack exec -- arithmetic-server &
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$ stack exec -- arithmetic-client
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```
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