This package provides for parsing and printing JSON in pure Julia.
Type ] add JSON
and then hit ⏎ Return at the REPL. You should see pkg> add JSON
.
import JSON
# JSON.parse - string or stream to Julia data structures
s = "{\"a_number\" : 5.0, \"an_array\" : [\"string\", 9]}"
j = JSON.parse(s)
# Dict{AbstractString,Any} with 2 entries:
# "an_array" => {"string",9}
# "a_number" => 5.0
# JSON.json - Julia data structures to a string
JSON.json([2,3])
# "[2,3]"
JSON.json(j)
# "{\"an_array\":[\"string\",9],\"a_number\":5.0}"
JSON.print(io::IO, s::AbstractString)
JSON.print(io::IO, s::Union{Integer, AbstractFloat})
JSON.print(io::IO, n::Nothing)
JSON.print(io::IO, b::Bool)
JSON.print(io::IO, a::AbstractDict)
JSON.print(io::IO, v::AbstractVector)
JSON.print{T, N}(io::IO, v::Array{T, N})
Writes a compact (no extra whitespace or indentation) JSON representation to the supplied IO.
JSON.print(a::AbstractDict, indent)
JSON.print(io::IO, a::AbstractDict, indent)
Writes a JSON representation with newlines, and indentation if specified. Non-zero indent
will be applied recursively to nested elements.
json(a::Any)
Returns a compact JSON representation as an AbstractString
.
JSON.parse(s::AbstractString; dicttype=Dict, inttype=Int64)
JSON.parse(io::IO; dicttype=Dict, inttype=Int64)
JSON.parsefile(filename::AbstractString; dicttype=Dict, inttype=Int64, use_mmap=true)
Parses a JSON AbstractString
or IO stream into a nested Array
or Dict
.
The dicttype
indicates the dictionary type (<: Associative
), or a function that
returns an instance of a dictionary type,
that JSON objects are parsed to. It defaults to Dict
(the built-in Julia
dictionary), but a different type can be passed for additional functionality.
For example, if you import DataStructures
(assuming the DataStructures
package is
installed)
- you can pass
dicttype=DataStructures.OrderedDict
to maintain the insertion order of the items in the object; - or you can pass
()->DefaultDict{String,Any}(Missing)
to having any non-found keys returnmissing
when you index the result.
The inttype
argument controls how integers are parsed. If a number in a JSON
file is recognized to be an integer, it is parsed as one; otherwise it is parsed
as a Float64
. The inttype
defaults to Int64
, but, for example, if you know
that your integer numbers are all small and want to save space, you can pass
inttype=Int32
. Alternatively, if your JSON input has integers which are too large
for Int64, you can pass inttype=Int128
or inttype=BigInt
. inttype
can be any
subtype of Real
.
JSONText(s::AbstractString)
A wrapper around a Julia string representing JSON-formatted text,
which is inserted as-is in the JSON output of JSON.print
and JSON.json
.
JSON.lower(p::Point2D) = [p.x, p.y]
Define a custom serialization rule for a particular data type. Must return a value that can be directly serialized; see help for more details.
Users may find the default behaviour of JSON inappropriate for their use case. In
such cases, JSON provides two mechanisms for users to customize serialization. The
first method, JSON.Writer.StructuralContext
, is used to customize the cosmetic
properties of the serialized JSON. (For example, the default pretty printing vs.
compact printing is supported by provided two different StructuralContext
s.)
Examples of applications for which StructuralContext
is appropriate include:
particular formatting demands for JSON (maybe not in compliance with the JSON
standard) or JSON-like formats with different syntax.
The second method, JSON.Serializations.Serialization
, is used to control the
translation of Julia objects into JSON serialization instructions. In most cases,
writing a method for JSON.lower
(as mentioned above) is sufficient to define
JSON serializations for user-defined objects. However, this is not appropriate for
overriding or deleting predefined serializations (since that would globally affect
users of the JSON
module and is an instance of dangerous
type piracy).
For these use-cases, users should define a custom instance of Serialization
.
An example of an application for this use case includes: a commonly requested
extension to JSON which serializes float NaN and infinite values as NaN
or Inf
,
in contravention of the JSON standard.
Both methods are controlled by the JSON.show_json
function, which has the following
signature:
JSON.show_json(io::StructuralContext, serialization::Serialization, object)
which is expected to write to io
in a way appropriate based on the rules of
Serialization
, but here io
is usually (but not required to be) handled in a
higher-level manner than a raw IO
object would ordinarily be.
To define a new StructuralContext
, the following boilerplate is recommended:
import JSON.Writer.StructuralContext
[mutable] struct MyContext <: StructuralContext
io::IO
[ ... additional state / settings for context goes here ... ]
end
If your structural context is going to be very similar to the existing JSON
contexts, it is also possible to instead subtype the abstract subtype
JSONContext
of StructuralContext
. If this is the case, an io::IO
field (as
above) is preferred, although the default implementation will only use this
for write
, so replacing that method is enough to avoid this requirement.
The following methods should be defined for your context, regardless of whether it
subtypes JSONContext
or StructuralContext
directly. If some of these methods
are omitted, then CommonSerialization
cannot be generally used with this context.
# called when the next object in a vector or next pair of a dict is to be written
# (requiring a newline and indent for some contexts)
# can do nothing if the context need not support indenting
JSON.Writer.indent(io::MyContext)
# called for vectors/dicts to separate items, usually writes ","
# unless this is the first element in a JSON array
# (default implementation for JSONContext exists, but requires a mutable bool
# `first` field, and this is an implementation detail not to be relied on;
# to define own or delegate explicitly)
JSON.Writer.delimit(io::MyContext)
# called for dicts to separate key and value, usually writes ": "
JSON.Writer.separate(io::MyContext)
# called to indicate start and end of a vector
JSON.Writer.begin_array(io::MyContext)
JSON.Writer.end_array(io::MyContext)
# called to indicate start and end of a dict
JSON.Writer.begin_object(io::MyContext)
JSON.Writer.end_object(io::MyContext)
For the following methods, JSONContext
provides a default implementation,
but it can be specialized. For StructuralContext
s which are not
JSONContext
s, the JSONContext
defaults are not appropriate and so are
not available.
# directly write a specific byte (if supported)
# default implementation writes to underlying `.io` field
# note that this enables JSONContext to act as any `io::IO`,
# i.e. one can use `print`, `show`, etc.
Base.write(io::MyContext, byte::UInt8)
# write "null"
# default implementation writes to underlying `.io` field
JSON.Writer.show_null(io::MyContext)
# write an object or string in a manner safe for JSON string
# default implementation calls `print` but escapes each byte as appropriate
# and adds double quotes around the content of `elt`
JSON.Writer.show_string(io::MyContext, elt)
# write a new element of JSON array
# default implementation calls delimit, then indent, then show_json
JSON.Writer.show_element(io::MyContext, elt)
# write a key for a JSON object
# default implementation calls delimit, then indent, then show_string,
# then seperate
JSON.Writer.show_key(io::MyContext, elt)
# write a key-value pair for a JSON object
# default implementation calls show key, then show_json
JSON.Writer.show_pair(io::MyContext, s::Serialization, key, value)
What follows is an example of a JSONContext
subtype which is very similar
to the default context, but which uses None
instead of null
for JSON nulls,
which is then generally compatible with Python object literal notation (PYON). It
wraps a default JSONContext
to delegate all the required methods to. Since
the wrapped context already has a .io
, this object does not need to include
an .io
field, and so the write
method must also be delegated, since the default
is not appropriate. The only other specialization needed is show_null
.
import JSON.Writer
import JSON.Writer.JSONContext
mutable struct PYONContext <: JSONContext
underlying::JSONContext
end
for delegate in [:indent,
:delimit,
:separate,
:begin_array,
:end_array,
:begin_object,
:end_object]
@eval JSON.Writer.$delegate(io::PYONContext) = JSON.Writer.$delegate(io.underlying)
end
Base.write(io::PYONContext, byte::UInt8) = write(io.underlying, byte)
JSON.Writer.show_null(io::PYONContext) = print(io, "None")
pyonprint(io::IO, obj) = let io = PYONContext(JSON.Writer.PrettyContext(io, 4))
JSON.print(io, obj)
return
end
The usage of this pyonprint
function is as any other print
function, e.g.
julia> pyonprint(stdout, [1, 2, nothing])
[
1,
2,
None
]
julia> sprint(pyonprint, missing)
"None"
For cases where the JSON cosmetics are unimportant, but how objects are converted into their
JSON equivalents (arrays, objects, numbers, etc.) need to be changed, the appropriate
abstraction is Serialization
. A Serialization
instance is used as the second argument in
show_json
. Thus, specializing show_json
for custom Serialization
instances enables
either creating more restrictive or different ways to convert objects into JSON.
The default serialization is called JSON.Serializations.StandardSerialization
, which is a
subtype of CommonSerialization
. Methods of show_json
are not added to
StandardSerialization
, but rather to CommonSerialization
, by both JSON
and by
other packages for their own types. The lower
functionality is also specific to
CommonSerialization
. Therefore, to create a serialization instance that inherits from and
may extend or override parts of the standard serialization, it suffices to define a new
serialization subtyping CommonSerialization
. In the example below, the new serialization
is the same as StandardSerialization
except that numbers are serialized with an additional
type tag.
import JSON.Serializations: CommonSerialization, StandardSerialization
import JSON.Writer: StructuralContext, show_json
struct TaggedNumberSerialization <: CommonSerialization end
tag(f::Real) = Dict(:type => string(typeof(f)), :value => f)
show_json(io::StructuralContext,
::TaggedNumberSerialization,
f::Union{Integer, AbstractFloat}) =
show_json(io, StandardSerialization(), tag(f))
Note that the recursive call constructs a StandardSerialization()
, as otherwise this would
result in a stack overflow, and serializes a Dict
using that. In this toy example, this is
fine (with only the overhead of constructing a Dict
), but this is not always possible.
(For instance, if the constructed Dict
could have other numbers within its values that
need to be tagged.)
To deal with these more complex cases, or simply to eliminate the overhead of constructing
the intermediate Dict
, the show_json
method can be implemented more carefully by
explicitly calling the context’s begin_object
, show_pair
, and end_object
methods, as
documented above, and use the StandardSerialization()
only for the show_pair
call for
f
.
# More careful implementation
# No difference in this case, but could be needed if recursive data structures are to be
# serialized in more complex cases.
import JSON.Writer: begin_object, show_pair, end_object
function show_json(io::StructuralContext,
s::TaggedNumberSerialization,
f::Union{Integer, AbstractFloat})
begin_object(io)
show_pair(io, s, :tag => string(typeof(f)))
show_pair(io, StandardSerialization(), :value => f)
end_object(io)
end
To use the custom serialization, sprint
can be used (and this can be encapsulated by a
convenient user-defined inteface):
julia> JSON.parse(sprint(show_json, TaggedNumberSerialization(), Any[1, 2.0, "hi"]))
3-element Array{Any,1}:
Dict{String,Any}("value" => 1,"type" => "Int64")
Dict{String,Any}("value" => 2.0,"type" => "Float64")
"hi"
If it is not desired to inherit all the functionality of StandardSerialization
, users may
also choose to start from scratch by directly subtyping JSON.Serializations.Serialization
.
This is useful if the user wishes to enforce a strict JSON which throws errors when
attempting to serialize objects that aren’t explicitly supported. Note that this means you
will need to define a method to support serializing any kind of object, including the
standard JSON objects like booleans, integers, strings, etc.!