{-# LANGUAGE CPP #-} -- | -- Module: Data.Aeson -- Copyright: (c) 2011, 2012 Bryan O'Sullivan -- (c) 2011 MailRank, Inc. -- License: Apache -- Maintainer: Bryan O'Sullivan -- Stability: experimental -- Portability: portable -- -- Types and functions for working efficiently with JSON data. -- -- (A note on naming: in Greek mythology, Aeson was the father of Jason.) module Data.Aeson ( -- * How to use this library -- $use -- ** Working with the AST -- $ast -- ** Decoding to a Haskell value -- $haskell -- ** Decoding a mixed-type object -- $mixed -- ** Automatically decoding data types -- $typeable -- ** Pitfalls -- $pitfalls -- * Encoding and decoding -- $encoding_and_decoding decode , decode' , eitherDecode , eitherDecode' , encode -- ** Variants for strict bytestrings , decodeStrict , decodeStrict' , eitherDecodeStrict , eitherDecodeStrict' -- * Core JSON types , Value(..) , Array , Object -- * Convenience types , DotNetTime(..) -- * Type conversion , FromJSON(..) , Result(..) , fromJSON , ToJSON(..) #ifdef GENERICS -- ** Generic JSON classes , GFromJSON(..) , GToJSON(..) , genericToJSON , genericParseJSON #endif -- * Inspecting @'Value's@ , withObject , withText , withArray , withNumber , withBool -- * Constructors and accessors , (.=) , (.:) , (.:?) , (.!=) , object -- * Parsing , json , json' ) where import Data.Aeson.Encode (encode) import Data.Aeson.Parser.Internal (decodeWith, decodeStrictWith, eitherDecodeWith, eitherDecodeStrictWith, jsonEOF, json, jsonEOF', json') import Data.Aeson.Types import qualified Data.ByteString as B import qualified Data.ByteString.Lazy as L -- | Efficiently deserialize a JSON value from a lazy 'L.ByteString'. -- If this fails due to incomplete or invalid input, 'Nothing' is -- returned. -- -- The input must consist solely of a JSON document, with no trailing -- data except for whitespace. This restriction is necessary to ensure -- that if data is being lazily read from a file handle, the file -- handle will be closed in a timely fashion once the document has -- been parsed. -- -- This function parses immediately, but defers conversion. See -- 'json' for details. decode :: (FromJSON a) => L.ByteString -> Maybe a decode = decodeWith jsonEOF fromJSON {-# INLINE decode #-} -- | Efficiently deserialize a JSON value from a strict 'B.ByteString'. -- If this fails due to incomplete or invalid input, 'Nothing' is -- returned. -- -- The input must consist solely of a JSON document, with no trailing -- data except for whitespace. -- -- This function parses immediately, but defers conversion. See -- 'json' for details. decodeStrict :: (FromJSON a) => B.ByteString -> Maybe a decodeStrict = decodeStrictWith jsonEOF fromJSON {-# INLINE decodeStrict #-} -- | Efficiently deserialize a JSON value from a lazy 'L.ByteString'. -- If this fails due to incomplete or invalid input, 'Nothing' is -- returned. -- -- The input must consist solely of a JSON document, with no trailing -- data except for whitespace. This restriction is necessary to ensure -- that if data is being lazily read from a file handle, the file -- handle will be closed in a timely fashion once the document has -- been parsed. -- -- This function parses and performs conversion immediately. See -- 'json'' for details. decode' :: (FromJSON a) => L.ByteString -> Maybe a decode' = decodeWith jsonEOF' fromJSON {-# INLINE decode' #-} -- | Efficiently deserialize a JSON value from a lazy 'L.ByteString'. -- If this fails due to incomplete or invalid input, 'Nothing' is -- returned. -- -- The input must consist solely of a JSON document, with no trailing -- data except for whitespace. -- -- This function parses and performs conversion immediately. See -- 'json'' for details. decodeStrict' :: (FromJSON a) => B.ByteString -> Maybe a decodeStrict' = decodeStrictWith jsonEOF' fromJSON {-# INLINE decodeStrict' #-} -- | Like 'decode' but returns an error message when decoding fails. eitherDecode :: (FromJSON a) => L.ByteString -> Either String a eitherDecode = eitherDecodeWith jsonEOF fromJSON {-# INLINE eitherDecode #-} -- | Like 'decodeStrict' but returns an error message when decoding fails. eitherDecodeStrict :: (FromJSON a) => B.ByteString -> Either String a eitherDecodeStrict = eitherDecodeStrictWith jsonEOF fromJSON {-# INLINE eitherDecodeStrict #-} -- | Like 'decode'' but returns an error message when decoding fails. eitherDecode' :: (FromJSON a) => L.ByteString -> Either String a eitherDecode' = eitherDecodeWith jsonEOF' fromJSON {-# INLINE eitherDecode' #-} -- | Like 'decodeStrict'' but returns an error message when decoding fails. eitherDecodeStrict' :: (FromJSON a) => B.ByteString -> Either String a eitherDecodeStrict' = eitherDecodeStrictWith jsonEOF' fromJSON {-# INLINE eitherDecodeStrict' #-} -- $use -- -- This section contains basic information on the different ways to -- decode data using this library. These range from simple but -- inflexible, to complex but flexible. -- -- The most common way to use the library is to define a data type, -- corresponding to some JSON data you want to work with, and then -- write either a 'FromJSON' instance, a to 'ToJSON' instance, or both -- for that type. For example, given this JSON data: -- -- > { "name": "Joe", "age": 12 } -- -- we create a matching data type: -- -- > data Person = Person -- > { name :: Text -- > , age :: Int -- > } deriving Show -- -- To decode data, we need to define a 'FromJSON' instance: -- -- > {-# LANGUAGE OverloadedStrings #-} -- > -- > instance FromJSON Person where -- > parseJSON (Object v) = Person <$> -- > v .: "name" <*> -- > v .: "age" -- > -- A non-Object value is of the wrong type, so fail. -- > parseJSON _ = mzero -- -- We can now parse the JSON data like so: -- -- > >>> decode "{\"name\":\"Joe\",\"age\":12}" :: Maybe Person -- > Just (Person {name = "Joe", age = 12}) -- -- To encode data, we need to define a 'ToJSON' instance: -- -- > instance ToJSON Person where -- > toJSON (Person name age) = object ["name" .= name, "age" .= age] -- -- We can now encode a value like so: -- -- > >>> encode (Person {name = "Joe", age = 12}) -- > "{\"name\":\"Joe\",\"age\":12}" -- -- There are predefined 'FromJSON' and 'ToJSON' instances for many -- types. Here's an example using lists and 'Int's: -- -- > >>> decode "[1,2,3]" :: Maybe [Int] -- > Just [1,2,3] -- -- And here's an example using the 'Data.Map.Map' type to get a map of -- 'Int's. -- -- > >>> decode "{\"foo\":1,\"bar\":2}" :: Maybe (Map String Int) -- > Just (fromList [("bar",2),("foo",1)]) -- While the notes below focus on decoding, you can apply almost the -- same techniques to /encoding/ data. (The main difference is that -- encoding always succeeds, but decoding has to handle the -- possibility of failure, where an input doesn't match our -- expectations.) -- -- See the documentation of 'FromJSON' and 'ToJSON' for some examples -- of how you can automatically derive instances in some -- circumstances. -- $ast -- -- Sometimes you want to work with JSON data directly, without first -- converting it to a custom data type. This can be useful if you want -- to e.g. convert JSON data to YAML data, without knowing what the -- contents of the original JSON data was. The 'Value' type, which is -- an instance of 'FromJSON', is used to represent an arbitrary JSON -- AST (abstract syntax tree). Example usage: -- -- > >>> decode "{\"foo\": 123}" :: Maybe Value -- > Just (Object (fromList [("foo",Number 123)])) -- -- > >>> decode "{\"foo\": [\"abc\",\"def\"]}" :: Maybe Value -- > Just (Object (fromList [("foo",Array (fromList [String "abc",String "def"]))])) -- -- Once you have a 'Value' you can write functions to traverse it and -- make arbitrary transformations. -- $haskell -- -- Any instance of 'FromJSON' can be specified (but see the -- \"Pitfalls\" section here—"Data.Aeson#pitfalls"): -- -- > λ> decode "[1,2,3]" :: Maybe [Int] -- > Just [1,2,3] -- -- Alternatively, there are instances for standard data types, so you -- can use them directly. For example, use the 'Data.Map.Map' type to -- get a map of 'Int's. -- -- > λ> :m + Data.Map -- > λ> decode "{\"foo\":1,\"bar\":2}" :: Maybe (Map String Int) -- > Just (fromList [("bar",2),("foo",1)]) -- $mixed -- -- The above approach with maps of course will not work for mixed-type -- objects that don't follow a strict schema, but there are a couple -- of approaches available for these. -- -- The 'Object' type contains JSON objects: -- -- > λ> decode "{\"name\":\"Dave\",\"age\":2}" :: Maybe Object -- > Just (fromList) [("name",String "Dave"),("age",Number 2)] -- -- You can extract values from it with a parser using 'parse', -- 'parseEither' or, in this example, 'parseMaybe': -- -- > λ> do result <- decode "{\"name\":\"Dave\",\"age\":2}" -- > flip parseMaybe result $ \obj -> do -- > age <- obj .: "age" -- > name <- obj .: "name" -- > return (name ++ ": " ++ show (age*2)) -- > -- > Just "Dave: 4" -- -- Considering that any type that implements 'FromJSON' can be used -- here, this is quite a powerful way to parse JSON. See the -- documentation in 'FromJSON' for how to implement this class for -- your own data types. -- -- The downside is that you have to write the parser yourself; the -- upside is that you have complete control over the way the JSON is -- parsed. -- $typeable -- -- If you don't want fine control and would prefer the JSON be parsed -- to your own data types automatically according to some reasonably -- sensible isomorphic implementation, you can use the generic parser -- based on 'Data.Typeable.Typeable' and 'Data.Data.Data'. Switch to -- the 'Data.Aeson.Generic' module, and you can do the following: -- -- > λ> decode "[1]" :: Maybe [Int] -- > Just [1] -- > λ> :m + Data.Typeable Data.Data -- > λ> :set -XDeriveDataTypeable -- > λ> data Person = Person { personName :: String, personAge :: Int } deriving (Data,Typeable,Show) -- > λ> encode Person { personName = "Chris", personAge = 123 } -- > "{\"personAge\":123,\"personName\":\"Chris\"}" -- > λ> decode "{\"personAge\":123,\"personName\":\"Chris\"}" :: Maybe Person -- > Just (Person { -- > personName = "Chris", personAge = 123 -- > }) -- -- Be aware that the encoding may not always be what you'd naively -- expect: -- -- > λ> data Foo = Foo Int Int deriving (Data,Typeable,Show) -- > λ> encode (Foo 1 2) -- > "[1,2]" -- -- With this approach, it's best to treat the -- 'Data.Aeson.Generic.decode' and 'Data.Aeson.Generic.encode' -- functions as an isomorphism, and not to rely upon (or care about) -- the specific intermediate representation. -- $pitfalls -- #pitfalls# -- -- Note that the JSON standard requires that the top-level value be -- either an array or an object. If you try to use 'decode' with a -- result type that is /not/ represented in JSON as an array or -- object, your code will typecheck, but it will always \"fail\" at -- runtime: -- -- > >>> decode "1" :: Maybe Int -- > Nothing -- > >>> decode "1" :: Maybe String -- > Nothing -- -- So stick to objects (e.g. maps in Haskell) or arrays (lists or -- vectors in Haskell): -- -- > >>> decode "[1,2,3]" :: Maybe [Int] -- > Just [1,2,3] -- -- When encoding to JSON you can encode anything that's an instance of -- 'ToJSON', and this may include simple types. So beware that this -- aspect of the API is not isomorphic. You can round-trip arrays and -- maps, but not simple values: -- -- > >>> encode [1,2,3] -- > "[1,2,3]" -- > >>> decode (encode [1]) :: Maybe [Int] -- > Just [1] -- > >>> encode 1 -- > "1" -- > >>> decode (encode (1 :: Int)) :: Maybe Int -- > Nothing -- -- Alternatively, see 'Data.Aeson.Parser.value' to parse non-top-level -- JSON values. -- $encoding_and_decoding -- -- Encoding and decoding are each two-step processes. -- -- * To encode a value, it is first converted to an abstract syntax -- tree (AST), using 'ToJSON'. This generic representation is then -- encoded as bytes. -- -- * When decoding a value, the process is reversed: the bytes are -- converted to an AST, then the 'FromJSON' class is used to convert -- to the desired type. -- -- For convenience, the 'encode' and 'decode' functions combine both -- steps.