jsonizer ~master
Flexible JSON serializer requiring minimal boilerplate
To use this package, run the following command in your project's root directory:
Manual usage
Put the following dependency into your project's dependences section:
jsonizer: D language JSON serializer
The primary purpose of jsonizer is to automate the generation of methods
needed to serialize and deserialize user-defined D structs and classes from JSON
data. jsonizer is not a standalone json parser, but rather a convenience layer
on top of std.json
, allowing you to more easily work with JSONValue
objects.
To use jsonizer, the main components you ened to be aware of are
the methods fromJSON!T
and toJSON
, the attribute @jsonize
, and the mixin
template JsonizeMe
.
Overview
Jsonizer consists of the following modules:
jsonizer.fromjson
- parse a
T
from aJSONValue
usingfromJSON!T
- parse a
T
from a json string usingfromJSONString!T
- parse a
T
from a json file usingreadJSON!T
jsonizer.tojson
- convert a
T
to aJSONValue
usingtoJSON!T
- convert a
T
to a json string usingtoJSONString!T
- write a
T
to a json file usingwriteJSON!T
jsonizer.jsonize
- mixin
JsonizeMe
to enable json serialization for a user-defined type - use
@jsonize
to mark members for serialization jsonizer.all
- imports
jsonizer.tojson
,jsonizer.fromjson
, andjsonizer.jsonize
fromJSON!T
fromJSON!T
converts a JSONValue
into an object of type T
.
import jsonizer.fromjson;
JSONValue json; // lets assume this has some data in it
int i = json.fromJSON!int;
MyEnum e = json.fromJSON!MyEnum;
MyStruct[] s = json.fromJSON!(MyStruct[]);
MyClass[string] c = json.fromJSON!(MyClass[string]);
fromJSON!T
will fail by throwing a JsonizeTypeException
if the json object's type is not
something it knows how to convert to T
.
For primitive types, fromJSON
leans on the side of flexibility -- for example,
fromJSON!int
on a json entry of type string
will try to parse an int
from
the string
.
For user-defined types, you have to do a little work to set up your struct or class for jsonizer.
@jsonize and JsonizeMe
The simplest way to make your type support json serialization is to mark its
members with the @jsonize
attribute and have mixin JsonizeMe;
somewhere in
your type definition. For example:
struct S {
mixin JsonizeMe; // this is required to support jsonization
@jsonize { // public serialized members
int x;
float f;
}
string dontJsonMe; // jsonizer won't touch members not marked with @jsonize
}
The above could be deserialized by calling fromJSON!S
from a json object like:
{ "x": 5, "f": 1.2 }
Your struct could be converted back into a JSONValue
by calling toJSON
on an
instance of it.
jsonizer can do more than just convert public members though:
struct S {
mixin JsonizeMe; // this is required to support jsonization
// jsonize can convert private members too.
// by default, jsonizer looks for a key in the json matching the member name
// you can change this by passing a string to @jsonize
private @jsonize("f") float _f;
// you can use properties for more complex serialization
// this is useful for converting types that are non-primitive
// but also not defined by you, like std.datetime's Date
private Date _date;
@property @jsonize {
string date() { return dateToString(_date); }
void date(string str) { _date = dateFromString(str); }
}
}
Assuming dateToString
and dateFromString
are some functions you defined, the
above could be fromJSON
ed from a json object looking like:
{ "f": 2.1, "date": "2015-05-01" }
The above examples work on both classes and structs provided the following:
- Your type mixes in
JsonizeMe
- Your members are marked with
@jsonize
- Your type has a no-args constructor
Optional members
By default, if a matching json entry is not found for a member marked with @jsonize
,
deserialization will fail.
If this is not desired for a given member, mark it with JsonizeIn.opt
.
class MyClass {
@jsonize int i;
@jsonize(JsonizeIn.opt) float f;
}
In the above example json.fromJSON!MyClass
will fail if it does not find a key named "i" in the
json object, but will silently ignore the abscence of a key "f".
Missing non-optional members trigger a JsonizeMismatchException
, which contains a list of the
missing keys in missingKeys
:
auto ex = collectException!JsonizeMismatchException(`{ "q": 5.0 }`.parseJSON.fromJSON!MyClass);
assert(ex.missingKeys == [ "i" ]);
The way @jsonize
takes parameters is rather flexible. While I can't condone making your class look
like the below example, it demonstrates the flexibility of @jsonize
:
class TotalMess {
@jsonize(JsonizeIn.opt) {
@jsonize("i") int _i;
@jsonize("f", JsonizeIn.yes) float _f;
@jsonize(JsonizeIn.yes, "s") float _s;
}
}
As the above shows, parameters may be passed in any order to @jsonize.
If you want to serialize only non-default (val != typeof(val).init
) fields, you can use JsonizeOut
class TotalMess {
@jsonize(JsonizeOut.opt) {
@jsonize("i") int _i;
@jsonize("f", JsonizeOut.yes) float _f;
@jsonize(JsonizeOut.no, "s") float _s; // never serialized, only requred for deserialization
}
}
As a shortcut to JsonizeIn/JsonizeOut
, you can just use Jsonize
:
class TotalMess {
// equivalent to: @jsonize(JsonizeIn.opt, JsonizeOut.opt)
@jsonize(Jsonize.opt) int a;
}
Extra Members
If you would like to ensure that every entry in a json object is being
deserialized, you can pass JsonizeIgnoreExtraKeys.no
to JsonizeMe
.
In the example below, fromJSON!S(jobject)
will throw a
JsonizeMismatchException
than if fields other than s
and i
exist in
jobject
.
struct S {
mixin JsonizeMe(JsonizeIgnoreExtraKeys.no);
string s;
int i;
}
When a JsonizeMismatchException
is caught, you can inspect the extra fields by
looking at extraKeys
:
auto ex = collectException!JsonizeMismatchException(
`{ "i": 5, "f": 0.2, "s": "hi"}`.parseJSON.fromJSON!S);
assert(ex.extraKeys == [ "f" ]);
Constructors
In some cases, #3 above may not seem so great. What if your type needs to
support serialization but shouldn't have a default constructor?
In this case, you want to @jsonize
your constructor:
class Custom {
mixin JsonizeMe;
@jsonize this(int i, string s = "hello") {
_i = i;
_s = s;
}
private:
@jsonize("i") int _i;
@jsonize("s") string _s;
}
Given a type T
with one or more constructors tagged with @jsonize
,
fromJSON!T
will try to match the member names and types to a constructor and
invoke that with the corresponding values from the json object.
Parameters with default values are considered optional; if they are not found in
the json, the default value will be used. The above example could be constructed
from json looking like:
{ "i": 5, "s": "hi" }
If "s" were not present, it would be assigned the value "hello".
Note that while you can @jsonize
multiple constructors, there should be no
overlap between situations that could satisfy them. If a given json object could
possibly match multiple constructors, jsonizer chooses arbitrarily (it does not
attempt to pick the 'most appropriate' constructor).
The method of jsonizing your constructor is also useful for types that need to perform a more complex setup sequence.
Also note that when using @jsonize
constructors, mixing in JsonizeMe
and
marking members with @jsonize
are only necessary for serialization -- if your
object only needs to support deserialization, marking a constructor is
sufficient.
If a type has no default (no-args) constructor and jsonizer cannot invoke any constructor marked
with @jsonize, it will throw a JsonizeConstructorException
which provides info on what
constructors were attempted.
Primitive Constructors
If a type has a constructor marked with @jsonize that takes a single argument, it can be constructed from a JSONValue of non-object type. For example, the following struct could be constructed from a json integer:
class IntStruct {
mixin JsonizeMe;
int i;
@jsonize this(int i) { this.i = i; }
}
Factory construction
This is one of the newer and least tested features of jsonizer. Suppose you have the following classes:
module test;
class TestComponent {
mixin JsonizeMe;
@jsonize int c;
}
class TestCompA : TestComponent {
mixin JsonizeMe;
@jsonize int a;
}
class TestCompB : TestComponent {
mixin JsonizeMe;
@jsonize string b;
}
and the following json:
[
{
"class": "test.TestCompA",
"c": 1,
"a": 5
},
{
"class": "test.TestCompB",
"c": 2,
"b": "hello"
}
]
Calling fromJSON!(TestComponent[])
on a JSONValue
parsed from the above json
string should yield a TestComponent[] of length 2.
While both have the static type TestComponent
, one is actually a TestCompA
and the other is a TestCompB
, both with their fields appropriately populated.
Behind the scenes, jsonizer looks for a special key 'class' in the json (chosen
because class is a D keyword and could not be a member of your type). If it
finds this, it calls Object.factory using the specified string. It then calls
populateFromJSON
, which is a method generated by the JsonizeMe
mixin.
For this to work, your type must:
- Have a default constructor
- mixin JsonizeMe in every class in the hierarchy
- Registered by Ryan Roden-Corrent
- ~master released 2 years ago
- rcorre/jsonizer
- MIT
- Copyright © 2015, rcorre
- Authors:
- Dependencies:
- none
- Versions:
-
0.7.7 2022-Jan-06 0.7.6 2018-Jul-08 0.7.5 2018-Mar-27 0.7.4 2017-Aug-05 0.7.3 2016-Nov-27 - Download Stats:
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- Short URL:
- jsonizer.dub.pm