aeson-0.11.2.0: Fast JSON parsing and encoding

Copyright(c) 2011-2016 Bryan O'Sullivan (c) 2011 MailRank, Inc.
LicenseBSD3
MaintainerBryan O'Sullivan <bos@serpentine.com>
Stabilityexperimental
Portabilityportable
Safe HaskellNone
LanguageHaskell2010

Data.Aeson

Contents

Description

Types and functions for working efficiently with JSON data.

(A note on naming: in Greek mythology, Aeson was the father of Jason.)

Synopsis

How to use this library

This section contains basic information on the different ways to work with 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:

{-# LANGUAGE DeriveGeneric #-}

import GHC.Generics

data Person = Person {
      name :: Text
    , age  :: Int
    } deriving (Generic, Show)

The LANGUAGE pragma and Generic instance let us write empty FromJSON and ToJSON instances for which the compiler will generate sensible default implementations.

instance ToJSON Person where
    -- No need to provide a toJSON implementation.

    -- For efficiency, we write a simple toEncoding implementation, as
    -- the default version uses toJSON.
    toEncoding = genericToEncoding defaultOptions

instance FromJSON Person
    -- No need to provide a parseJSON implementation.

We can now encode a value like so:

>>> encode (Person {name = "Joe", age = 12})
"{\"name\":\"Joe\",\"age\":12}"

Writing instances by hand

When necessary, we can write ToJSON and FromJSON instances by hand. This is valuable when the JSON-on-the-wire and Haskell data are different or otherwise need some more carefully managed translation. Let's revisit our JSON data:

{ "name": "Joe", "age": 12 }

We once again create a matching data type, without bothering to add a Generic instance this time:

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 _          = empty

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. Let's begin with an instance written entirely by hand.

instance ToJSON Person where
    -- this generates a Value
    toJSON (Person name age) =
        object ["name" .= name, "age" .= age]

    -- this encodes directly to a bytestring Builder
    toEncoding (Person name age) =
        pairs ("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 Ints:

>>> decode "[1,2,3]" :: Maybe [Int]
Just [1,2,3]

And here's an example using the Map type to get a map of Ints.

>>> decode "{\"foo\":1,\"bar\":2}" :: Maybe (Map String Int)
Just (fromList [("bar",2),("foo",1)])

Working with the 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.

Decoding to a Haskell value

We can decode to any instance of FromJSON:

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 Map type to get a map of Ints.

λ> import Data.Map
λ> decode "{\"foo\":1,\"bar\":2}" :: Maybe (Map String Int)
Just (fromList [("bar",2),("foo",1)])

Decoding a mixed-type object

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.

Encoding and decoding

Decoding is a two-step process.

  • When decoding a value, the process is reversed: the bytes are converted to a Value, then the FromJSON class is used to convert to the desired type.

There are two ways to encode a value.

  • Convert to a Value using toJSON, then possibly further encode. This was the only method available in aeson 0.9 and earlier.
  • Directly encode (to what will become a ByteString) using toEncoding. This is much more efficient (about 3x faster, and less memory intensive besides), but is only available in aeson 0.10 and newer.

For convenience, the encode and decode functions combine both steps.

Direct encoding

In older versions of this library, encoding a Haskell value involved converting to an intermediate Value, then encoding that.

A "direct" encoder converts straight from a source Haskell value to a ByteString without constructing an intermediate Value. This approach is faster than toJSON, and allocates less memory. The toEncoding method makes it possible to implement direct encoding with low memory overhead.

To complicate matters, the default implementation of toEncoding uses toJSON. Why? The toEncoding method was added to this library much more recently than toJSON. Using toJSON ensures that packages written against older versions of this library will compile and produce correct output, but they will not see any speedup from direct encoding.

To write a minimal implementation of direct encoding, your type must implement GHC's Generic class, and your code should look like this:

    toEncoding = genericToEncoding defaultOptions

What if you have more elaborate encoding needs? For example, perhaps you need to change the names of object keys, omit parts of a value.

To encode to a JSON "object", use the pairs function.

    toEncoding (Person name age) =
        pairs ("name" .= name <> "age" .= age)

Any container type that implements Foldable can be encoded to a JSON "array" using foldable.

> import Data.Sequence as Seq
> encode (Seq.fromList [1,2,3])
"[1,2,3]"

decode :: FromJSON a => ByteString -> Maybe a Source #

Efficiently deserialize a JSON value from a lazy 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.

decode' :: FromJSON a => ByteString -> Maybe a Source #

Efficiently deserialize a JSON value from a lazy 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.

eitherDecode :: FromJSON a => ByteString -> Either String a Source #

Like decode but returns an error message when decoding fails.

eitherDecode' :: FromJSON a => ByteString -> Either String a Source #

Like decode' but returns an error message when decoding fails.

encode :: ToJSON a => a -> ByteString Source #

Efficiently serialize a JSON value as a lazy ByteString.

This is implemented in terms of the ToJSON class's toEncoding method.

Variants for strict bytestrings

decodeStrict :: FromJSON a => ByteString -> Maybe a Source #

Efficiently deserialize a JSON value from a strict 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 => ByteString -> Maybe a Source #

Efficiently deserialize a JSON value from a lazy 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.

eitherDecodeStrict :: FromJSON a => ByteString -> Either String a Source #

Like decodeStrict but returns an error message when decoding fails.

eitherDecodeStrict' :: FromJSON a => ByteString -> Either String a Source #

Like decodeStrict' but returns an error message when decoding fails.

Core JSON types

data Value Source #

A JSON value represented as a Haskell value.

Instances

Eq Value Source # 

Methods

(==) :: Value -> Value -> Bool #

(/=) :: Value -> Value -> Bool #

Data Value Source # 

Methods

gfoldl :: (forall d b. Data d => c (d -> b) -> d -> c b) -> (forall g. g -> c g) -> Value -> c Value #

gunfold :: (forall b r. Data b => c (b -> r) -> c r) -> (forall r. r -> c r) -> Constr -> c Value #

toConstr :: Value -> Constr #

dataTypeOf :: Value -> DataType #

dataCast1 :: Typeable (* -> *) t => (forall d. Data d => c (t d)) -> Maybe (c Value) #

dataCast2 :: Typeable (* -> * -> *) t => (forall d e. (Data d, Data e) => c (t d e)) -> Maybe (c Value) #

gmapT :: (forall b. Data b => b -> b) -> Value -> Value #

gmapQl :: (r -> r' -> r) -> r -> (forall d. Data d => d -> r') -> Value -> r #

gmapQr :: (r' -> r -> r) -> r -> (forall d. Data d => d -> r') -> Value -> r #

gmapQ :: (forall d. Data d => d -> u) -> Value -> [u] #

gmapQi :: Int -> (forall d. Data d => d -> u) -> Value -> u #

gmapM :: Monad m => (forall d. Data d => d -> m d) -> Value -> m Value #

gmapMp :: MonadPlus m => (forall d. Data d => d -> m d) -> Value -> m Value #

gmapMo :: MonadPlus m => (forall d. Data d => d -> m d) -> Value -> m Value #

Read Value Source # 
Show Value Source # 

Methods

showsPrec :: Int -> Value -> ShowS #

show :: Value -> String #

showList :: [Value] -> ShowS #

IsString Value Source # 

Methods

fromString :: String -> Value #

Lift Value Source # 

Methods

lift :: Value -> Q Exp #

NFData Value Source # 

Methods

rnf :: Value -> () #

Hashable Value Source # 

Methods

hashWithSalt :: Int -> Value -> Int #

hash :: Value -> Int #

fromEncoding :: Encoding -> Builder Source #

Acquire the underlying bytestring builder.

type Array = Vector Value Source #

A JSON "array" (sequence).

type Object = HashMap Text Value Source #

A JSON "object" (key/value map).

Convenience types

newtype DotNetTime Source #

A newtype wrapper for UTCTime that uses the same non-standard serialization format as Microsoft .NET, whose System.DateTime type is by default serialized to JSON as in the following example:

/Date(1302547608878)/

The number represents milliseconds since the Unix epoch.

Constructors

DotNetTime 

Fields

Type conversion

class FromJSON a where Source #

A type that can be converted from JSON, with the possibility of failure.

In many cases, you can get the compiler to generate parsing code for you (see below). To begin, let's cover writing an instance by hand.

There are various reasons a conversion could fail. For example, an Object could be missing a required key, an Array could be of the wrong size, or a value could be of an incompatible type.

The basic ways to signal a failed conversion are as follows:

  • empty and mzero work, but are terse and uninformative
  • fail yields a custom error message
  • typeMismatch produces an informative message for cases when the value encountered is not of the expected type

An example type and instance:

-- Allow ourselves to write Text literals.
{-# LANGUAGE OverloadedStrings #-}

data Coord = Coord { x :: Double, y :: Double }

instance FromJSON Coord where
  parseJSON (Object v) = Coord    <$>
                         v .: "x" <*>
                         v .: "y"

  -- We do not expect a non-Object value here.
  -- We could use mzero to fail, but typeMismatch
  -- gives a much more informative error message.
  parseJSON invalid    = typeMismatch "Coord" invalid

Instead of manually writing your FromJSON instance, there are two options to do it automatically:

  • Data.Aeson.TH provides Template Haskell functions which will derive an instance at compile time. The generated instance is optimized for your type so will probably be more efficient than the following two options:
  • The compiler can provide a default generic implementation for parseJSON.

To use the second, simply add a deriving Generic clause to your datatype and declare a FromJSON instance for your datatype without giving a definition for parseJSON.

For example, the previous example can be simplified to just:

{-# LANGUAGE DeriveGeneric #-}

import GHC.Generics

data Coord = Coord { x :: Double, y :: Double } deriving Generic

instance FromJSON Coord

If DefaultSignatures doesn't give exactly the results you want, you can customize the generic decoding with only a tiny amount of effort, using genericParseJSON with your preferred Options:

instance FromJSON Coord where
    parseJSON = genericParseJSON defaultOptions

data Result a Source #

The result of running a Parser.

Constructors

Error String 
Success a 

Instances

Monad Result Source # 

Methods

(>>=) :: Result a -> (a -> Result b) -> Result b #

(>>) :: Result a -> Result b -> Result b #

return :: a -> Result a #

fail :: String -> Result a #

Functor Result Source # 

Methods

fmap :: (a -> b) -> Result a -> Result b #

(<$) :: a -> Result b -> Result a #

MonadFail Result Source # 

Methods

fail :: String -> Result a #

Applicative Result Source # 

Methods

pure :: a -> Result a #

(<*>) :: Result (a -> b) -> Result a -> Result b #

(*>) :: Result a -> Result b -> Result b #

(<*) :: Result a -> Result b -> Result a #

Foldable Result Source # 

Methods

fold :: Monoid m => Result m -> m #

foldMap :: Monoid m => (a -> m) -> Result a -> m #

foldr :: (a -> b -> b) -> b -> Result a -> b #

foldr' :: (a -> b -> b) -> b -> Result a -> b #

foldl :: (b -> a -> b) -> b -> Result a -> b #

foldl' :: (b -> a -> b) -> b -> Result a -> b #

foldr1 :: (a -> a -> a) -> Result a -> a #

foldl1 :: (a -> a -> a) -> Result a -> a #

toList :: Result a -> [a] #

null :: Result a -> Bool #

length :: Result a -> Int #

elem :: Eq a => a -> Result a -> Bool #

maximum :: Ord a => Result a -> a #

minimum :: Ord a => Result a -> a #

sum :: Num a => Result a -> a #

product :: Num a => Result a -> a #

Traversable Result Source # 

Methods

traverse :: Applicative f => (a -> f b) -> Result a -> f (Result b) #

sequenceA :: Applicative f => Result (f a) -> f (Result a) #

mapM :: Monad m => (a -> m b) -> Result a -> m (Result b) #

sequence :: Monad m => Result (m a) -> m (Result a) #

Alternative Result Source # 

Methods

empty :: Result a #

(<|>) :: Result a -> Result a -> Result a #

some :: Result a -> Result [a] #

many :: Result a -> Result [a] #

MonadPlus Result Source # 

Methods

mzero :: Result a #

mplus :: Result a -> Result a -> Result a #

Eq a => Eq (Result a) Source # 

Methods

(==) :: Result a -> Result a -> Bool #

(/=) :: Result a -> Result a -> Bool #

Show a => Show (Result a) Source # 

Methods

showsPrec :: Int -> Result a -> ShowS #

show :: Result a -> String #

showList :: [Result a] -> ShowS #

Semigroup (Result a) Source # 

Methods

(<>) :: Result a -> Result a -> Result a #

sconcat :: NonEmpty (Result a) -> Result a #

stimes :: Integral b => b -> Result a -> Result a #

Monoid (Result a) Source # 

Methods

mempty :: Result a #

mappend :: Result a -> Result a -> Result a #

mconcat :: [Result a] -> Result a #

NFData a => NFData (Result a) Source # 

Methods

rnf :: Result a -> () #

fromJSON :: FromJSON a => Value -> Result a Source #

Convert a value from JSON, failing if the types do not match.

class ToJSON a where Source #

A type that can be converted to JSON.

An example type and instance:

-- Allow ourselves to write Text literals.
{-# LANGUAGE OverloadedStrings #-}

data Coord = Coord { x :: Double, y :: Double }

instance ToJSON Coord where
  toJSON (Coord x y) = object ["x" .= x, "y" .= y]

  toEncoding (Coord x y) = pairs ("x" .= x <> "y" .= y)

Instead of manually writing your ToJSON instance, there are two options to do it automatically:

  • Data.Aeson.TH provides Template Haskell functions which will derive an instance at compile time. The generated instance is optimized for your type so will probably be more efficient than the following two options:
  • The compiler can provide a default generic implementation for toJSON.

To use the second, simply add a deriving Generic clause to your datatype and declare a ToJSON instance for your datatype without giving definitions for toJSON or toEncoding.

For example, the previous example can be simplified to a more minimal instance:

{-# LANGUAGE DeriveGeneric #-}

import GHC.Generics

data Coord = Coord { x :: Double, y :: Double } deriving Generic

instance ToJSON Coord where
    toEncoding = genericToEncoding defaultOptions

Why do we provide an implementation for toEncoding here? The toEncoding function is a relatively new addition to this class. To allow users of older versions of this library to upgrade without having to edit all of their instances or encounter surprising incompatibilities, the default implementation of toEncoding uses toJSON. This produces correct results, but since it performs an intermediate conversion to a Value, it will be less efficient than directly emitting an Encoding. Our one-liner definition of toEncoding above bypasses the intermediate Value.

If DefaultSignatures doesn't give exactly the results you want, you can customize the generic encoding with only a tiny amount of effort, using genericToJSON and genericToEncoding with your preferred Options:

instance ToJSON Coord where
    toJSON     = genericToJSON defaultOptions
    toEncoding = genericToEncoding defaultOptions

Methods

toJSON :: a -> Value Source #

Convert a Haskell value to a JSON-friendly intermediate type.

toJSON :: (Generic a, GToJSON (Rep a)) => a -> Value Source #

Convert a Haskell value to a JSON-friendly intermediate type.

toEncoding :: a -> Encoding Source #

Encode a Haskell value as JSON.

The default implementation of this method creates an intermediate Value using toJSON. This provides source-level compatibility for people upgrading from older versions of this library, but obviously offers no performance advantage.

To benefit from direct encoding, you must provide an implementation for this method. The easiest way to do so is by having your types implement Generic using the DeriveGeneric extension, and then have GHC generate a method body as follows.

instance ToJSON Coord where
    toEncoding = genericToEncoding defaultOptions

class KeyValue kv where Source #

A key-value pair for encoding a JSON object.

Minimal complete definition

(.=)

Methods

(.=) :: ToJSON v => Text -> v -> kv infixr 8 Source #

Generic JSON classes and options

class GFromJSON f where Source #

Class of generic representation types (Rep) that can be converted from JSON.

Minimal complete definition

gParseJSON

Methods

gParseJSON :: Options -> Value -> Parser (f a) Source #

This method (applied to defaultOptions) is used as the default generic implementation of parseJSON.

class GToJSON f where Source #

Class of generic representation types (Rep) that can be converted to JSON.

Minimal complete definition

gToJSON

Methods

gToJSON :: Options -> f a -> Value Source #

This method (applied to defaultOptions) is used as the default generic implementation of toJSON.

class GToEncoding f where Source #

Class of generic representation types (Rep) that can be converted to a JSON Encoding.

Minimal complete definition

gToEncoding

Methods

gToEncoding :: Options -> f a -> Encoding Source #

This method (applied to defaultOptions) can be used as the default generic implementation of toEncoding.

genericToJSON :: (Generic a, GToJSON (Rep a)) => Options -> a -> Value Source #

A configurable generic JSON creator. This function applied to defaultOptions is used as the default for toJSON when the type is an instance of Generic.

genericToEncoding :: (Generic a, GToEncoding (Rep a)) => Options -> a -> Encoding Source #

A configurable generic JSON encoder. This function applied to defaultOptions is used as the default for toEncoding when the type is an instance of Generic.

genericParseJSON :: (Generic a, GFromJSON (Rep a)) => Options -> Value -> Parser a Source #

A configurable generic JSON decoder. This function applied to defaultOptions is used as the default for parseJSON when the type is an instance of Generic.

Inspecting Values

withObject :: String -> (Object -> Parser a) -> Value -> Parser a Source #

withObject expected f value applies f to the Object when value is an Object and fails using typeMismatch expected otherwise.

withText :: String -> (Text -> Parser a) -> Value -> Parser a Source #

withText expected f value applies f to the Text when value is a String and fails using typeMismatch expected otherwise.

withArray :: String -> (Array -> Parser a) -> Value -> Parser a Source #

withArray expected f value applies f to the Array when value is an Array and fails using typeMismatch expected otherwise.

withNumber :: String -> (Number -> Parser a) -> Value -> Parser a Source #

Deprecated: Use withScientific instead

withNumber expected f value applies f to the Number when value is a Number. and fails using typeMismatch expected otherwise.

withScientific :: String -> (Scientific -> Parser a) -> Value -> Parser a Source #

withScientific expected f value applies f to the Scientific number when value is a Number. and fails using typeMismatch expected otherwise.

withBool :: String -> (Bool -> Parser a) -> Value -> Parser a Source #

withBool expected f value applies f to the Bool when value is a Bool and fails using typeMismatch expected otherwise.

Constructors and accessors

data Series Source #

A series of values that, when encoded, should be separated by commas. Since 0.11.0.0, the .= operator is overloaded to create either (Text, Value) or Series. You can use Series when encoding directly to a bytestring builder as in the following example:

toEncoding (Person name age) = pairs ("name" .= name <> "age" .= age)

pairs :: Series -> Encoding Source #

Encode a series of key/value pairs, separated by commas.

foldable :: (Foldable t, ToJSON a) => t a -> Encoding Source #

Encode a Foldable as a JSON array.

(.:) :: FromJSON a => Object -> Text -> Parser a Source #

Retrieve the value associated with the given key of an Object. The result is empty if the key is not present or the value cannot be converted to the desired type.

This accessor is appropriate if the key and value must be present in an object for it to be valid. If the key and value are optional, use .:? instead.

(.:?) :: FromJSON a => Object -> Text -> Parser (Maybe a) Source #

Retrieve the value associated with the given key of an Object. The result is Nothing if the key is not present, or empty if the value cannot be converted to the desired type.

This accessor is most useful if the key and value can be absent from an object without affecting its validity. If the key and value are mandatory, use .: instead.

(.:!) :: FromJSON a => Object -> Text -> Parser (Maybe a) Source #

Like .:?, but the resulting parser will fail, if the key is present but is Null.

(.!=) :: Parser (Maybe a) -> a -> Parser a Source #

Helper for use in combination with .:? to provide default values for optional JSON object fields.

This combinator is most useful if the key and value can be absent from an object without affecting its validity and we know a default value to assign in that case. If the key and value are mandatory, use .: instead.

Example usage:

 v1 <- o .:? "opt_field_with_dfl" .!= "default_val"
 v2 <- o .:  "mandatory_field"
 v3 <- o .:? "opt_field2"

object :: [Pair] -> Value Source #

Create a Value from a list of name/value Pairs. If duplicate keys arise, earlier keys and their associated values win.

Parsing

json :: Parser Value Source #

Parse a top-level JSON value.

The conversion of a parsed value to a Haskell value is deferred until the Haskell value is needed. This may improve performance if only a subset of the results of conversions are needed, but at a cost in thunk allocation.

This function is an alias for value. In aeson 0.8 and earlier, it parsed only object or array types, in conformance with the now-obsolete RFC 4627.

json' :: Parser Value Source #

Parse a top-level JSON value.

This is a strict version of json which avoids building up thunks during parsing; it performs all conversions immediately. Prefer this version if most of the JSON data needs to be accessed.

This function is an alias for value'. In aeson 0.8 and earlier, it parsed only object or array types, in conformance with the now-obsolete RFC 4627.