Copyright	(c) Nike Inc. 2018
License	BSD3
Maintainer	nathan.fairhurst@nike.com, fernando.freire@nike.com
Stability	stable
Safe Haskell	None
Language	Haskell2010

AWS.Lambda.Combinators

Description

These combinators are for those who need to peek below the abstraction of the basic runtimes, for whatever reason.

They map functions (instead of values) to turn basic handlers into handlers compatible with the base runtime. These combinators allow us to expose functionality across many dimensions in an abstract way. It also allows simple building blocks for those who need to "get in the middle" or adapt the basic runtimes in new ways without rebuilding everything from the ground up.

Synopsis

withIOInterface :: (MonadReader c m, MonadIO m) => (c -> b -> IO (Either String a)) -> b -> m a
withFallibleInterface :: MonadReader c m => (c -> b -> Either String a) -> b -> m a
withPureInterface :: MonadReader c m => (c -> b -> a) -> b -> m a
withoutContext :: a -> b -> a
withInfallibleParse :: FromJSON a => (a -> b) -> Value -> b

Documentation

withIOInterface :: (MonadReader c m, MonadIO m) => (c -> b -> IO (Either String a)) -> b -> m a Source #

Deprecated: This combinator is useful when combined with the current mRuntimeWithContext, which is deprecated.

Upgrades a handler that uses the IO monad with an Either inside into a base runtime handler.

In the example below, we reconstruct ioRuntimeWithContext without actually using it. The readerTRuntime expects a handler in the form of event -> ReaderT LambdaContext IO result (ignoring constraints). By composing it with withIOInterface we get a new runtime which expects a function in the form of LambdaContext -> event -> IO result which matches that of myHandler.

    {-# LANGUAGE NamedFieldPuns, DeriveGeneric #-}

    module Main where

    import AWS.Lambda.Context (LambdaContext(..))
    import AWS.Lambda.Runtime (readerTRuntime)
    import AWS.Lambda.Combinators (withIOInterface)
    import Data.Aeson (FromJSON)
    import Data.Text (unpack)
    import System.Environment (getEnv)
    import GHC.Generics (Generic)

    data Named = Named {
      name :: String
    } deriving Generic
    instance FromJSON Named

    myHandler :: LambdaContext -> Named -> IO (Either String String)
    myHandler (LambdaContext { functionName }) (Named { name }) = do
      greeting <- getEnv "GREETING"
      return $ if name == "World" then
        Right $ "Hello, World from " ++ unpack functionName ++ "!"
      else
        Left "Can only greet the world."

    main :: IO ()
    main = (readerTRuntime . withIOInterface) myHandler

withFallibleInterface :: MonadReader c m => (c -> b -> Either String a) -> b -> m a Source #

Deprecated: This combinator is useful when combined with the current mRuntimeWithContext, which is deprecated.

Upgrades a handler that accepts LambdaContext and an event to return a value inside an Either inside into a base runtime handler.

In the example below, we reconstruct fallibleRuntimeWithContext without actually using it. The readerTRuntime expects a handler in the form of event -> ReaderT LambdaContext IO result (ignoring constraints). By composing it with withFallibleInterface we get a new runtime which expects a function in the form of LambdaContext -> event -> Either String result which matches that of myHandler.

    {-# LANGUAGE NamedFieldPuns, DeriveGeneric #-}

    module Main where

    import AWS.Lambda.Context (LambdaContext(..))
    import AWS.Lambda.Runtime (readerTRuntime)
    import AWS.Lambda.Combinators (withFallibleInterface)
    import Data.Aeson (FromJSON)
    import Data.Text (unpack)
    import GHC.Generics (Generic)

    data Named = Named {
      name :: String
    } deriving Generic
    instance FromJSON Named

    myHandler :: LambdaContext -> Named -> Either String String
    myHandler (LambdaContext { functionName }) (Named { name }) =
      if name == "World" then
        Right $ "Hello, World from " ++ unpack functionName ++ "!"
      else
        Left "Can only greet the world."

    main :: IO ()
    main = (readerTRuntime . withFallibleInterface) myHandler

withPureInterface :: MonadReader c m => (c -> b -> a) -> b -> m a Source #

Deprecated: This combinator is useful when combined with the current mRuntimeWithContext, which is deprecated.

This combinator takes a handler that accepts both an event and LambdaContext and converts it into a handler that is compatible with the base monadic runtime.

In the example below, we reconstruct pureRuntimeWithContext without actually using it. The readerTRuntime expects a handler in the form of event -> ReaderT LambdaContext IO result (ignoring constraints). By composing it with withPureInterface we get a new runtime which expects a function in the form of LambdaContext -> event -> result which matches that of myHandler.

    {-# LANGUAGE NamedFieldPuns, DeriveGeneric #-}

    module Main where

    import AWS.Lambda.Context (LambdaContext(..))
    import AWS.Lambda.Runtime (readerTRuntime)
    import AWS.Lambda.Combinators (withPureInterface)
    import Data.Aeson (FromJSON)
    import Data.Text (unpack)
    import GHC.Generics (Generic)

    data Named = Named {
      name :: String
    } deriving Generic
    instance FromJSON Named

    myHandler :: LambdaContext -> Named -> String
    myHandler (LambdaContext { functionName }) (Named { name }) =
      "Hello, " ++ name ++ " from " ++ unpack functionName ++ "!"

    main :: IO ()
    main = (readerTRuntime . withPureInterface) myHandler

withoutContext :: a -> b -> a Source #

An alias of const, this upgrades a handler that does not accept LambdaContext as its first curried argument to one that does.

This allows us to use other combinators to construct a lambda runtime that accepts a handler that ignores LambdaContext.

In the example below, we reconstruct pureRuntime without actually using it. The readerTRuntime expects a handler in the form of event -> ReaderT LambdaContext IO result (ignoring constraints). By composing it with withPureInterface we get a new runtime which expects a function in the form of LambdaContext -> event -> result, And then finally we also compose withoutContext so it accepts the signature event -> result which matches that of myHandler.

    {-# LANGUAGE NamedFieldPuns, DeriveGeneric #-}

    module Main where

    import AWS.Lambda.Runtime (readerTRuntime)
    import AWS.Lambda.Combinators (withPureInterface, withoutContext)
    import Data.Aeson (FromJSON)
    import GHC.Generics (Generic)

    data Named = Named {
      name :: String
    } deriving Generic
    instance FromJSON Named

    myHandler :: Named -> String
    myHandler (Named { name }) =
      "Hello, " ++ name

    main :: IO ()
    main = (readerTRuntime . withPureInterface . withoutContext) myHandler

withInfallibleParse :: FromJSON a => (a -> b) -> Value -> b Source #

This modifies a function to accept a JSON AST (Value), instead of its JSON parsable input. It also assumes that the JSON AST passed in will ALWAYS be convertable into the original input type.

This allows us to write handlers of the types we're interested in, but then map back to the "native" handler that is only guaranteed JSON (but not necessarily in a useful or restricted structure).

This is essentially the glue that converts the AWS.Lambda.Runtime.Value to (the more standard) AWS.Lambda.Runtime. While both export a mRuntimeWithContext, the difference is that the Value Runtime makes no attempt to convert the JSON AST, the standard Runtime does.

Rarely would this function be used directly, and you wouldn't want to use it at all, (directly or indirectly via Runtime runtimes), if you wanted to act on a failure to convert the JSON AST sent to the Lambda.