spray-json is a lightweight, clean and efficient JSON implementation in Scala.
It sports the following features:
- A simple immutable model of the JSON language elements
- An efficient JSON PEG parser (implemented with parboiled)
- Choice of either compact or pretty JSON-to-string printing
- Type-class based (de)serialization of custom objects (no reflection, no intrusion)
spray-json allows you to convert between
- String JSON documents
- JSON Abstract Syntax Trees (ASTs) with base type JsValue
- instances of arbitrary Scala types
as depicted in this diagram:
spray-json is available from the repo.spray.io repository.
The latest release is 1.2.6
and is built against Scala 2.9.3, Scala 2.10.4 and Scala 2.11.0-RC4.
If you use SBT you can include spray-json in your project with
resolvers += "spray" at "http://repo.spray.io/"
libraryDependencies += "io.spray" %% "spray-json" % "1.2.6"
spray-json has only one dependency: the parsing library parboiled (which is also a dependency of spray-http, so if you use spray-json together with other modules of the spray suite you are not incurring any additional dependency).
spray-json is really easy to use. Just bring all relevant elements in scope with
import spray.json._
import DefaultJsonProtocol._ // !!! IMPORTANT, else `convertTo` and `toJson` won't work correctly
and do one or more of the following:
- Parse a JSON string into its Abstract Syntax Tree (AST) representation
val source = """{ "some": "JSON source" }"""
val jsonAst = source.parseJson // or JsonParser(source)
- Print a JSON AST back to a String using either the
CompactPrinter
or thePrettyPrinter
val json = jsonAst.prettyPrint // or .compactPrint
- Convert any Scala object to a JSON AST using the pimped
toJson
method
val jsonAst = List(1, 2, 3).toJson
- Convert a JSON AST to a Scala object with the
convertTo
method
val myObject = jsonAst.convertTo[MyObjectType]
In order to make steps 3 and 4 work for an object of type T
you need to bring implicit values in scope that
provide JsonFormat[T]
instances for T
and all types used by T
(directly or indirectly).
The way you normally do this is via a "JsonProtocol".
spray-json uses SJSONs Scala-idiomatic type-class-based approach to connect an existing type T
with the logic how
to (de)serialize its instances to and from JSON. (In fact spray-json even reuses some of SJSONs code, see the
'Credits' section below).
This approach has the advantage of not requiring any change (or even access) to T
s source code. All (de)serialization
logic is attached 'from the outside'. There is no reflection involved, so the resulting conversions are fast. Scalas
excellent type inference reduces verbosity and boilerplate to a minimum, while the Scala compiler will make sure at
compile time that you provided all required (de)serialization logic.
In spray-jsons terminology a 'JsonProtocol' is nothing but a bunch of implicit values of type JsonFormat[T]
, whereby
each JsonFormat[T]
contains the logic of how to convert instance of T
to and from JSON. All JsonFormat[T]
s of a
protocol need to be "mece" (mutually exclusive, collectively exhaustive), i.e. they are not allowed to overlap and
together need to span all types required by the application.
This may sound more complicated than it is.
spray-json comes with a DefaultJsonProtocol
, which already covers all of Scalas value types as well as the most
important reference and collection types. As long as your code uses nothing more than these you only need the
DefaultJsonProtocol
. Here are the types already taken care of by the DefaultJsonProtocol
:
- Byte, Short, Int, Long, Float, Double, Char, Unit, Boolean
- String, Symbol
- BigInt, BigDecimal
- Option, Either, Tuple1 - Tuple7
- List, Array
- immutable.{Map, Iterable, Seq, IndexedSeq, LinearSeq, Set, Vector}
- collection.{Iterable, Seq, IndexedSeq, LinearSeq, Set}
- JsValue
In most cases however you'll also want to convert types not covered by the DefaultJsonProtocol
. In these cases you
need to provide JsonFormat[T]
s for your custom types. This is not hard at all.
If your custom type T
is a case class then augmenting the DefaultJsonProtocol
with a JsonFormat[T]
is really easy:
case class Color(name: String, red: Int, green: Int, blue: Int)
object MyJsonProtocol extends DefaultJsonProtocol {
implicit val colorFormat = jsonFormat4(Color)
}
import MyJsonProtocol._
val json = Color("CadetBlue", 95, 158, 160).toJson
val color = json.convertTo[Color]
The jsonFormatX
methods reduce the boilerplate to a minimum, just pass the right one the companion object of your
case class and it will return a ready-to-use JsonFormat
for your type (the right one is the one matching the number
of arguments to your case class constructor, e.g. if your case class has 13 fields you need to use the jsonFormat13
method). The jsonFormatX
methods try to extract the field names of your case class before calling the more general
jsonFormat
overloads, which let you specify the field name manually. So, if spray-json has trouble determining the
field names or if your JSON objects use member names that differ from the case class fields you can also use
jsonFormat
directly.
There is one additional quirk: If you explicitly declare the companion object for your case class the notation above will
stop working. You'll have to explicitly refer to the companion objects apply
method to fix this:
case class Color(name: String, red: Int, green: Int, blue: Int)
object Color
object MyJsonProtocol extends DefaultJsonProtocol {
implicit val colorFormat = jsonFormat4(Color.apply)
}
If your case class is generic in that it takes type parameters itself the jsonFormat
methods can also help you.
However, there is a little more boilerplate required as you need to add context bounds for all type parameters
and explicitly refer to the case classes apply
method as in this example:
case class NamedList[A](name: String, items: List[A])
object MyJsonProtocol extends DefaultJsonProtocol {
implicit def namedListFormat[A :JsonFormat] = jsonFormat2(NamedList.apply[A])
}
The NullOptions
trait supplies an alternative rendering mode for optional case class members. Normally optional
members that are undefined (None
) are not rendered at all. By mixing in this trait into your custom JsonProtocol you
can enforce the rendering of undefined members as null
.
(Note that this only affect JSON writing, spray-json will always read missing optional members as well as null
optional members as None
.)
Of course you can also supply (de)serialization logic for types that aren't case classes. Here is one way to do it:
class Color(val name: String, val red: Int, val green: Int, val blue: Int)
object MyJsonProtocol extends DefaultJsonProtocol {
implicit object ColorJsonFormat extends RootJsonFormat[Color] {
def write(c: Color) =
JsArray(JsString(c.name), JsNumber(c.red), JsNumber(c.green), JsNumber(c.blue))
def read(value: JsValue) = value match {
case JsArray(JsString(name) :: JsNumber(red) :: JsNumber(green) :: JsNumber(blue) :: Nil) =>
new Color(name, red.toInt, green.toInt, blue.toInt)
case _ => deserializationError("Color expected")
}
}
}
import MyJsonProtocol._
val json = Color("CadetBlue", 95, 158, 160).toJson
val color = json.convertTo[Color]
This serializes Color
instances as a JSON array, which is compact but does not make the elements semantics explicit.
You need to know that the color components are ordered "red, green, blue".
Another way would be to serialize Color
s as JSON objects:
object MyJsonProtocol extends DefaultJsonProtocol {
implicit object ColorJsonFormat extends RootJsonFormat[Color] {
def write(c: Color) = JsObject(
"name" -> JsString(c.name),
"red" -> JsNumber(c.red),
"green" -> JsNumber(c.green),
"blue" -> JsNumber(c.blue)
)
def read(value: JsValue) = {
value.asJsObject.getFields("name", "red", "green", "blue") match {
case Seq(JsString(name), JsNumber(red), JsNumber(green), JsNumber(blue)) =>
new Color(name, red.toInt, green.toInt, blue.toInt)
case _ => throw new DeserializationException("Color expected")
}
}
}
}
This is a bit more verbose in its definition and the resulting JSON but transports the field semantics over to the JSON side. Note that this is the approach spray-json uses for case classes.
According to the JSON specification not all of the defined JSON value types are allowed at the root level of a JSON
document. A JSON string for example (like "foo"
) does not constitute a legal JSON document by itself.
Only JSON objects or JSON arrays are allowed as JSON document roots.
In order to distinguish, on the type-level, "regular" JsonFormats from the ones producing root-level JSON objects or
arrays spray-json defines the RootJsonFormat
type, which is nothing but a marker specialization of JsonFormat
.
Libraries supporting spray-json as a means of document serialization might choose to depend on a RootJsonFormat[T]
for a custom type T
(rather than a "plain" JsonFormat[T]
), so as to not allow the rendering of illegal document
roots. E.g., the SprayJsonSupport
trait of spray-routing is one notable example of such a case.
All default converters in the DefaultJsonProtocol
producing JSON objects or arrays are actually implemented as
RootJsonFormat
. When "manually" implementing a JsonFormat
for a custom type T
(rather than relying on case class
support) you should think about whether you'd like to use instances of T
as JSON document roots and choose between
a "plain" JsonFormat
and a RootJsonFormat
accordingly.
If your type is recursive such as
case class Foo(i: Int, foo: Foo)
you need to wrap your format constructor with lazyFormat
and supply an explicit type annotation:
implicit val fooFormat: JsonFormat[Foo] = lazyFormat(jsonFormat(Foo, "i", "foo"))
Otherwise your code will either not compile (no explicit type annotation) or throw an NPE at runtime (no lazyFormat
wrapper). Note, that lazyFormat
returns a JsonFormat
even if it was given a RootJsonFormat
which means it isn't
picked up by SprayJsonSupport
. To get back a RootJsonFormat
just wrap the complete lazyFormat
call with another
call to rootFormat
.
Most of type-class (de)serialization code is nothing but a polished copy of what Debasish Ghosh made available with his SJSON library. These code parts therefore bear his copyright. Additionally the JSON AST model is heavily inspired by the one contributed by Jorge Ortiz to Databinder-Dispatch.
spray-json is licensed under APL 2.0.
Please use the spray-user mailing list if you have any questions.
Feedback and contributions to the project, no matter what kind, are always very welcome. However, patches can only be accepted from their original author. Along with any patches, please state that the patch is your original work and that you license the work to the spray-json project under the project’s open source license.