JSON: Difference between revisions
Line 1,530:
strings, and objects. Nor is there a standardized Forth library to build
and use such structures. But there are many different Forth libraries,
written by individuals, available
The library code used below can be found here:
https://github.com/DouglasBHoffman/FMS2
Load a JSON Forth string into a data structure.
<pre>
s\" {\"value\":10,\"flag\":false,\"array\":[1,2,3]}" $>json value j
Line 1,549 ⟶ 1,548:
Create a new data structure and serialize it into JSON.
<pre>
j{ "another":"esc\"
</pre>
Prints the modified JSON:
Line 1,556 ⟶ 1,554:
{
"value": 10,
"another": "esc"
"flag": false,
"array": [ 1, 2, 3]
Line 1,562 ⟶ 1,560:
Convert the JSON object into a string object. Print the string.
<pre>
j json>$ :.
</pre>
{
=={{header|Fortran}}==
|
Revision as of 11:37, 26 January 2021
You are encouraged to solve this task according to the task description, using any language you may know.
Load a JSON string into a data structure. Also, create a new data structure and serialize it into JSON.
Use objects and arrays (as appropriate for your language) and make sure your JSON is valid (https://jsonformatter.org).
8th
8th uses JSON as its data description language, so:
[1,2,3] . cr
Prints an array of [1,2,3].
Converting a string to an object:
"{ \"a\": 123 }" json>
Takes the string and converts to the JSON object (which is an 8th object). Convert back to a string:
{"a": 123} >s
That takes the object and converts to the JSON string given above.
Ada
Alternative using GNATCOLL
<lang ada> with Ada.Text_IO; with GNATCOLL.JSON;
procedure JSON_Test is
use Ada.Text_IO; use GNATCOLL.JSON; JSON_String : constant String := "{""name"":""Pingu"",""born"":1986}"; Penguin : JSON_Value := Create_Object; Parents : JSON_Array;
begin
Penguin.Set_Field (Field_Name => "name", Field => "Linux"); Penguin.Set_Field (Field_Name => "born", Field => 1992); Append (Parents, Create ("Linus Torvalds")); Append (Parents, Create ("Alan Cox")); Append (Parents, Create ("Greg Kroah-Hartman")); Penguin.Set_Field (Field_Name => "parents", Field => Parents); Put_Line (Penguin.Write);
Penguin := Read (JSON_String, "json.errors"); Penguin.Set_Field (Field_Name => "born", Field => 1986); Parents := Empty_Array; Append (Parents, Create ("Otmar Gutmann")); Append (Parents, Create ("Silvio Mazzola")); Penguin.Set_Field (Field_Name => "parents", Field => Parents); Put_Line (Penguin.Write);
end JSON_Test; </lang>
- Output:
{"parents":["Linus Torvalds", "Alan Cox", "Greg Kroah-Hartman"], "name":"Linux", "born":1992} {"parents":["Otmar Gutmann", "Silvio Mazzola"], "name":"Pingu", "born":1986}
Alternative using Matreshka
<lang ada> with Ada.Wide_Wide_Text_IO; use Ada.Wide_Wide_Text_IO; with League.JSON.Arrays; use League.JSON.Arrays; with League.JSON.Documents; use League.JSON.Documents; with League.JSON.Objects; use League.JSON.Objects; with League.JSON.Values; use League.JSON.Values; with League.Strings; use League.Strings;
procedure Main is
function "+" (Item : Wide_Wide_String) return Universal_String renames To_Universal_String;
JSON_String : constant Universal_String := +"{""name"":""Pingu"",""born"":1986}";
Penguin : JSON_Object; Parents : JSON_Array;
begin
Penguin.Insert (+"name", To_JSON_Value (+"Linux")); Penguin.Insert (+"born", To_JSON_Value (1992));
Parents.Append (To_JSON_Value (+"Linus Torvalds")); Parents.Append (To_JSON_Value (+"Alan Cox")); Parents.Append (To_JSON_Value (+"Greg Kroah-Hartman"));
Penguin.Insert (+"parents", To_JSON_Value (Parents));
Put_Line (To_JSON_Document (Penguin).To_JSON.To_Wide_Wide_String);
Penguin := From_JSON (JSON_String).To_JSON_Object;
Parents := Empty_JSON_Array;
Parents.Append (To_JSON_Value (+"Otmar Gutmann")); Parents.Append (To_JSON_Value (+"Silvio Mazzola"));
Penguin.Insert (+"parents", To_JSON_Value (Parents));
Put_Line (To_JSON_Document (Penguin).To_JSON.To_Wide_Wide_String);
end Main; </lang>
- Output:
{"parents":["Linus Torvalds","Alan Cox","Greg Kroah-Hartman"],"name":"Linux","born":1992} {"parents":["Otmar Gutmann","Silvio Mazzola"],"name":"Pingu","born":1986}
AntLang
JSON parser (maybe failes with "invalid JSON" error) <lang AntLang> json:{[data]catch[eval[,|{[y]catch[{":" = "="; "[" = "<"; "]" = ">"; "," = ";"}[y];{x};{[]y}]}'("""("(\\.|[^\\"])*"|\-?[0-9]+(\.[0-9]+)?|\{|\}|\[|\]|\:|\,)"""~data)["strings"]];{x};{error["Invalid JSON"]}]} </lang>
ANTLR
Java
<lang java> // Parse JSON // // Nigel Galloway - April 27th., 2012 // grammar JSON ; @members { String Indent = ""; } Number : (('0')|('-'? ('1'..'9') ('0'..'9')*)) ('.' ('0'..'9')+)? (('e'|'E') ('+'|'-')? ('0'..'9')+)?; WS : (' ' | '\t' | '\r' |'\n') {skip();}; Tz : ' ' .. '!' | '#' .. '[' | ']' .. '~'; Control : '\\' ('"'|'\\'|'/'|'b'|'f'|'n'|'r'|'t'|UCode); UCode : 'u' ('0'..'9'|'a'..'f'|'A'..'F') ('0'..'9'|'a'..'f'|'A'..'F') ('0'..'9'|'a'..'f'|'A'..'F') ('0'..'9'|'a'..'f'|'A'..'F'); Keyword : 'true' | 'false' | 'null'; String : '"' (Control? Tz)* '"'; object : '{' {System.out.println(Indent + "{Object}"); Indent += " ";} (pair (',' pair*)*)? '}' {Indent = Indent.substring(4);}; pair : e = String {System.out.println(Indent + "{Property}\t" + $e.text);} ':' value; value : Number {System.out.println(Indent + "{Number} \t" + $Number.text);} | object | String {System.out.println(Indent + "{String} \t" + $String.text);} | Keyword {System.out.println(Indent + "{Keyword} \t" + $Keyword.text);} | array; array : '[' {System.out.println(Indent + "Array"); Indent += " ";} (value (',' value)*)? ']' {Indent = Indent.substring(4);}; </lang> Produces:
>java Test { "Nigel" : -110.2e-13 , "Fred" : { "Joe" : [3,true,"Nigel"] } "Harry" : [23,"Hello"] } ^Z {Object} {Property} "Nigel" {Number} -110.2e-13 {Property} "Fred" {Object} {Property} "Joe" Array {Number} 3 {Keyword} true {String} "Nigel" {Property} "Harry" Array {Number} 23 {String} "Hello"
Apex
JSON serialization and deserialization is built in <lang apex>class TestClass{
String foo {get;set;} Integer bar {get;set;}
}
TestClass testObj = new TestClass(); testObj.foo = 'ABC'; testObj.bar = 123;
String serializedString = JSON.serialize(testObj); TestClass deserializedObject = (TestClass)JSON.deserialize(serializedString, TestClass.class);
//"testObj.foo == deserializedObject.foo" is true //"testObj.bar == deserializedObject.bar" is true </lang>
Arturo
<lang arturo>// set some json string json: "{ \"foo\": 1, \"bar\": [10, \"apples\"] }"
// parsing json string to object print "JSON:" inspect [parseJson json]
// set some object object: #{ name: "john" surname: "doe" address: #{ number: 10 street: "unknown" country: "Spain" } married: false }
// generate json string from object print "OBJECT:" print [generateJson object] </lang>
- Output:
JSON: #{ bar : #( 10 "apples" ) foo : 1 } OBJECT: { "name": "john", "surname": "doe", "address": { "number": 10, "street": "unknown", "country": "Spain" }, "married": false }
Bracmat
Bracmat has built-in functionality for reading and writing JSON data. A full roundtrip from JSON file over a Bracmat internal representation back to a JSON file looks like this:
<lang bracmat>put$(jsn$(get$("input.json",JSN)),"output.JSN,NEW)</lang>
Let us split this into separate steps.
To read a JSON file "myfile.json", use
<lang bracmat>get$("myfile.json",JSN)</lang>
If the JSON data, e.g, an array, has to be read from a string value, use the MEM
option on the get
function, like this:
<lang bracmat>get$("[1,2,3]",JSN,MEM)</lang>
To convert the corresponding Bracmat data structure (,1 2 3)
back to a JSON string, use
<lang bracmat>jsn$(,1 2 3)</lang>
To write a JSON string "[1,2,3]"
to a file "array.json", use
<lang bracmat>put$("[1,2,3]","array.json",NEW)</lang>
Bracmat and JSON/Javascript do far from represent data in similar ways.
Bracmat has arbitrary-precision arithmetic. Floating point numbers are not a native datatype in Bracmat.
Bracmat has no Boolean values true
and false
and no null
value.
Bracmat has arrays and objects, but they are second class citizens. Most data is best represented as binary tree structures, with binary operators like the plus, comma, dot or white space sitting in the nodes and the atomic parts of the data sitting in the leaves.
The only data type that is somewhat the same in JSON/JavaScript and Bracmat is the string, but there is a slight difference in the representation of strings in code. Whereas strings in JSON always are enclosed in quotation marks, this is only necessary in Bracmat if a string contains operator characters or starts with flag characters.
Here are the mapping rules:
Bracmat representation | JSON representation | Comment |
---|---|---|
null
|
null
|
|
true
|
true
| |
false
|
false
| |
12345
|
12345
| |
2/3
|
6.66666666666666666667E-1
|
Most rational numbers cannot be represented as floating point numbers, see note (1) |
(.string)
|
"string"
| |
(,1 2)
|
[1,2]
| |
((a.1)+(b.2),)
|
{"a":1,"b":2}
|
The + operator sorts its arguments. See note (2)
|
Note (1) All floating point numbers can be represented as rational numbers. Therefore, a round trip of a Bracmat number to a JSON number and back to a Bracmat number can give a different number: 2/3
becomes 666666666666666666667/1000000000000000000000
.
Note (2) The objects {"a":1,"b":2}
and {"b":2,"a":1}
are equivalent in Bracmat, as they are both internally represented as ((a.1)+(b.2),)
Here is a full round trip of the following JSON data, which is assumed to be stored in a file "rosetta.json". The employed code is: <lang bracmat> ( get$("rosetta.json",JSN):?json & lst$(json,"json.bra",NEW) & put$(jsn$!json,"rosetta-roundtrip.json",NEW) )</lang>
rosetta.json:
[ { "ape": "\"King Kong\"", "C:\\projects": "23", "OS\/2": { "White\b\f\n\r\tspace": {} }, "Cyrillic": [ "Ya \u042F", "ya \u044f" ] }, "TAB ", [ "elem1", "elem2" ], "Bernhard", [], [ "x", "y", "z" ], [ "true", true, false, null ], { "fixed point": [ 3.4, 0.00987654321, -10.01, 56.78, 56.780 ] }, { "floating point": [ 0e0, 0.0000006e-007, 17E123, -17.87E123, 0.87E123, 286e400 ] }, { "integer": [ -0, 0, -5, 1234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567890 ] } ]
Content of json.bra:
json= , ( ("C:\\projects"..23) + (Cyrillic.,(."Ya Я") (."ya я")) + (OS/2.("White\b\f \r space".0,),) + (ape.."\"King Kong\"") , ) (.TAB\t) (,(.elem1) (.elem2)) (.Bernhard) (,) (,(.x) (.y) (.z)) (,(.true) true false null) ( ("fixed point".,34/10 987654321/100000000000 -1001/100 5678/100 56780/1000) , ) ( ( "floating point" . , 0 6/100000000000000 17000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000 -17870000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000 870000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000 2860000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000 ... ) , ) ( ( integer . , -0 0 -5 1234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891 ... ) , );
The file "rosetta-roundtrip.json" will contain a single line. There is no beautify option when constructing a JSON string using the jsn
function. The http://jsonlint.com service can be used to view the JSON string, but notice that some of the numbers are to big to be handled by this service and are turned into null values.
Content of rosetta-roundtrip.json (1402 characters):
[{"C:\\projects":"23","Cyrillic":["Ya Я","ya я"],"OS/2":{"White\b\f\n\r\tspace":{}},"ape":"\"King Kong\""},"TAB\t",["elem1","elem2"],"Bernhard",[],["x","y","z"],["true",true,false,null],{"fixed point":[3.4,0.00987654321,-10.01,56.78,56.78]},{"floating point":[0,0.00000000000006,17000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000,-17870000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000,870000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000,2860000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000]},{"integer":[-0,0,-5,1234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567890]}]
After manual reformatting, again shortened where lines run off the screen:
[ { "C:\\projects": "23", "Cyrillic": [ "Ya Я", "ya я" ], "OS/2": { "White\b\f\n\r\tspace": {} }, "ape": "\"King Kong\"" }, "TAB\t", [ "elem1", "elem2" ], "Bernhard", [], [ "x", "y", "z" ], [ "true", true, false, null ], { "fixed point": [ 3.4, 0.00987654321, -10.01, 56.78, 56.78 ] }, { "floating point": [ 0, 0.00000000000006, 17000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000, -17870000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000, 870000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000, 2860000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000 ... ] }, { "integer": [ -0, 0, -5, 1234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891234567891 ... ] } ]
C
Reads a snippet of JSON into YAJL's tree format, then walks the tree to print it back out again. The tree contains numbers both in an unparsed, string form, and also converted to long long or double when possible. The example below demonstrates both ways of dealing with numbers.
<lang C>#include <stdio.h>
- include <stdlib.h>
- include <string.h>
- include <yajl/yajl_tree.h>
- include <yajl/yajl_gen.h>
static void print_callback (void *ctx, const char *str, size_t len) {
FILE *f = (FILE *) ctx; fwrite (str, 1, len, f);
}
static void check_status (yajl_gen_status status) {
if (status != yajl_gen_status_ok) { fprintf (stderr, "yajl_gen_status was %d\n", (int) status); exit (EXIT_FAILURE); }
}
static void serialize_value (yajl_gen gen, yajl_val val, int parse_numbers) {
size_t i;
switch (val->type) { case yajl_t_string: check_status (yajl_gen_string (gen, (const unsigned char *) val->u.string, strlen (val->u.string))); break; case yajl_t_number: if (parse_numbers && YAJL_IS_INTEGER (val)) check_status (yajl_gen_integer (gen, YAJL_GET_INTEGER (val))); else if (parse_numbers && YAJL_IS_DOUBLE (val)) check_status (yajl_gen_double (gen, YAJL_GET_DOUBLE (val))); else check_status (yajl_gen_number (gen, YAJL_GET_NUMBER (val), strlen (YAJL_GET_NUMBER (val)))); break; case yajl_t_object: check_status (yajl_gen_map_open (gen)); for (i = 0 ; i < val->u.object.len ; i++) { check_status (yajl_gen_string (gen, (const unsigned char *) val->u.object.keys[i], strlen (val->u.object.keys[i]))); serialize_value (gen, val->u.object.values[i], parse_numbers); } check_status (yajl_gen_map_close (gen)); break; case yajl_t_array: check_status (yajl_gen_array_open (gen)); for (i = 0 ; i < val->u.array.len ; i++) serialize_value (gen, val->u.array.values[i], parse_numbers); check_status (yajl_gen_array_close (gen)); break; case yajl_t_true: check_status (yajl_gen_bool (gen, 1)); break; case yajl_t_false: check_status (yajl_gen_bool (gen, 0)); break; case yajl_t_null: check_status (yajl_gen_null (gen)); break; default: fprintf (stderr, "unexpectedly got type %d\n", (int) val->type); exit (EXIT_FAILURE); }
}
static void print_tree (FILE *f, yajl_val tree, int parse_numbers) {
yajl_gen gen;
gen = yajl_gen_alloc (NULL); if (! gen) { fprintf (stderr, "yajl_gen_alloc failed\n"); exit (EXIT_FAILURE); }
if (0 == yajl_gen_config (gen, yajl_gen_beautify, 1) || 0 == yajl_gen_config (gen, yajl_gen_validate_utf8, 1) || 0 == yajl_gen_config (gen, yajl_gen_print_callback, print_callback, f)) { fprintf (stderr, "yajl_gen_config failed\n"); exit (EXIT_FAILURE); }
serialize_value (gen, tree, parse_numbers); yajl_gen_free (gen);
}
int main (int argc, char **argv) {
char err_buf[200]; const char *json = "{\"pi\": 3.14, \"large number\": 123456789123456789123456789, " "\"an array\": [-1, true, false, null, \"foo\"]}"; yajl_val tree;
tree = yajl_tree_parse (json, err_buf, sizeof (err_buf)); if (! tree) { fprintf (stderr, "parsing failed because: %s\n", err_buf); return EXIT_FAILURE; }
printf ("Treating numbers as strings...\n"); print_tree (stdout, tree, 0); printf ("Parsing numbers to long long or double...\n"); print_tree (stdout, tree, 1);
yajl_tree_free (tree);
return EXIT_SUCCESS;
}</lang>
- Output:
Treating numbers as strings... { "pi": 3.14, "large number": 123456789123456789123456789, "an array": [ -1, true, false, null, "foo" ] } Parsing numbers to long long or double... { "pi": 3.1400000000000001243, "large number": 1.2345678912345679134e+26, "an array": [ -1, true, false, null, "foo" ] }
C#
This uses the JavaScriptSerializer class which was shipped with .NET 3.5.
<lang csharp>using System; using System.Collections.Generic; using System.Web.Script.Serialization;
class Program {
static void Main() { var people = new Dictionary<string, object> {{"1", "John"}, {"2", "Susan"}}; var serializer = new JavaScriptSerializer(); var json = serializer.Serialize(people); Console.WriteLine(json);
var deserialized = serializer.Deserialize<Dictionary<string, object>>(json); Console.WriteLine(deserialized["2"]);
var jsonObject = serializer.DeserializeObject(@"{ ""foo"": 1, ""bar"": [10, ""apples""] }"); var data = jsonObject as Dictionary<string, object>; var array = data["bar"] as object[]; Console.WriteLine(array[1]); }
}</lang>
C++
<lang cpp>#include "Core/Core.h"
using namespace Upp;
CONSOLE_APP_MAIN { JsonArray a; a << Json("name", "John")("phone", "1234567") << Json("name", "Susan")("phone", "654321"); String txt = ~a; Cout() << txt << '\n'; Value v = ParseJSON(txt); for(int i = 0; i < v.GetCount(); i++) Cout() << v[i]["name"] << ' ' << v[i]["phone"] << '\n'; } </lang>
C++11
<lang cpp>#include <iostream>
- include <iomanip> // std::setw
- include <sstream>
- include <cassert>
- include "json.hpp"
using json = nlohmann::json;
int main( int argc, char* argv[] ) {
std::string const expected =
R"delim123({
"answer": { "everything": 42 }, "happy": true, "list": [ 1, 0, 2 ], "name": "Niels", "nothing": null, "object": { "currency": "USD", "value": 42.99 }, "pi": 3.141
})delim123";
json const jexpected = json::parse( expected );
assert( jexpected["list"][1].get<int>() == 0 ); assert( jexpected["object"]["currency"] == "USD" );
json jhandmade = { {"pi", 3.141}, {"happy", true}, {"name", "Niels"}, {"nothing", nullptr}, {"answer", { {"everything", 42} } }, {"list", {1, 0, 2}}, {"object", { {"currency", "USD"}, {"value", 42.99} } } };
assert( jexpected == jhandmade );
std::stringstream jhandmade_stream; jhandmade_stream << std::setw(4) << jhandmade;
std::string jhandmade_string = jhandmade.dump(4);
assert( jhandmade_string == expected ); assert( jhandmade_stream.str() == expected ); return 0;
} </lang>
Caché ObjectScript
<lang cos> Class Sample.JSON [ Abstract ] {
ClassMethod GetPerson(ByRef pParms, Output pObject As %RegisteredObject) As %Status { Set pObject=##class(Sample.Person).%OpenId(pParms("oid")) Quit $$$OK }
} </lang>
- Examples:
SAMPLES>Set pParms("oid")=5 SAMPLES>Do ##class(%ZEN.Auxiliary.jsonProvider).%WriteJSONFromObject("", "Sample.JSON", "GetPerson", .pParms) { "_class":"Sample.Person", "_id":5, "Age":80, "DOB":33603, "FavoriteColors":["White","Purple"], "Home": { "_class":"Sample.Address", "City":"Denver", "State":"SC", "Street":"6932 Second Court", "Zip":51309 }, "Name":"Tillem,Will D.", "Office": { "_class":"Sample.Address", "City":"Queensbury", "State":"NV", "Street":"1169 Main Drive", "Zip":25310 }, "SSN":"729-56-4619", "Spouse":null } SAMPLES>Read json {"_class":"Sample.Person","_id":5,"Age":80,"DOB":33603,"FavoriteColors":["White" ,"Purple"],"Home":{"_class":"Sample.Address","City":"Denver","State":"S C","Stre et":"6932 Second Court","Zip":51309},"Name":"Tillem,Will D.","O ffice":{"_class" :"Sample.Address","City":"Queensbury","State":"NV"," Street":"1169 Main Drive"," Zip":25310},"SSN":"729-56-4619","Spouse":null} SAMPLES>Do ##class(%ZEN.Auxiliary.jsonProvider).%ConvertJSONToObject(json, "", .person) SAMPLES>Write person.Name Tillem,Will D. SAMPLES>Write person.FavoriteColors.Count() 2 SAMPLES>Write person.Home.Street 6932 Second Court
Clojure
Library: data.json <lang clojure>(use 'clojure.data.json)
; Load as Clojure data structures and bind the resulting structure to 'json-map'.
(def json-map (read-json "{ \"foo\": 1, \"bar\": [10, \"apples\"] }"))
- Use pr-str to print out the Clojure representation of the JSON created by read-json.
(pr-str json-map)
- Pretty-print the Clojure representation of JSON. We've come full circle.
(pprint-json json-map)</lang>
CoffeeScript
<lang coffeescript> sample =
blue: [1, 2] ocean: 'water'
json_string = JSON.stringify sample json_obj = JSON.parse json_string
console.log json_string console.log json_obj </lang>
ColdFusion
<lang cfm> <cfset json = {
string: "Hello", number: 42, arrayOfNumbers: [1, 2, 3, 4], arrayOfStrings: ["One", "Two", "Three", "Four"], arrayOfAnything: [1, "One", [1, "One"], { one: 1 }], object: { key: "value" }
} />
<cfset jsonSerialized = serializeJSON(json) /> <cfset jsonDeserialized = deserializeJSON(jsonSerialized) />
<cfdump var="#jsonSerialized#" /> <cfdump var="#jsonDeserialized#" /> </lang>
Common Lisp
Library: cl-json <lang lisp> (ql:quickload '("cl-json"))
(json:encode-json
'#( ((foo . (1 2 3)) (bar . t) (baz . #\!)) "quux" 4/17 4.25))
(print (with-input-from-string (s "{\"foo\": [1, 2, 3], \"bar\": true, \"baz\": \"!\"}") (json:decode-json s)))
</lang>
To load "cl-json": Load 1 ASDF system: cl-json ; Loading "cl-json" [{"foo":[1,2,3],"bar":true,"baz":"!"},"quux",0.23529412,4.25] ((:FOO 1 2 3) (:BAR . T) (:BAZ . "!"))
Crystal
<lang Ruby> require "json"
class Foo
JSON.mapping( num: Int64, array: Array(String), )
end
def json
foo = Foo.from_json(%({"num": 1, "array": ["a", "b"]})) puts("#{foo.num} #{foo.array}") puts(foo.to_json)
end </lang>
<lang Bash> 1 ["a", "b"] {"num":1,"array":["a","b"]} </lang>
D
<lang d>import std.stdio, std.json;
void main() {
auto j = parseJSON(`{ "foo": 1, "bar": [10, "apples"] }`); writeln(toJSON(&j));
}</lang>
{"foo":1,"bar":[10,"apples"]}
Dart
<lang javascript>import 'dart:convert' show jsonDecode, jsonEncode;
main(){ var json_string = { "rosetta_code": { "task": "json", "language": "dart", "descriptions": [ "fun!", "easy to learn!", "awesome!" ] } } ;
// decode string into Map<String, dynamic> var json_object = jsonDecode(json_string);
for ( var description in json_object["rosetta_code"]["descriptions"] ) print( "dart is $description" );
var dart = { "compiled": true, "interpreted": true, "creator(s)":[ "Lars Bak", "Kasper Lund"], "development company": "Google" };
var as_json_text = jsonEncode(dart);
assert(as_json_text == '{"compiled":true,"interpreted":true,"creator(s)":["Lars Bak","Kasper Lund"],"development company":"Google"}'); } </lang>
- Output:
dart is fun! dart is easy to learn! dart is awesome!
<lang javascript>import 'dart:convert';
main(){ var data = jsonDecode('{ "foo": 1, "bar": [10, "apples"] }');
var sample = { "blue": [1,2], "ocean": "water" };
var json_string = jsonEncode(sample); } </lang>
Delphi
<lang Delphi> program JsonTest;
{$APPTYPE CONSOLE}
{$R *.res}
uses
System.SysUtils, Json;
type
TJsonObjectHelper = class helper for TJsonObject public class function Deserialize(data: string): TJsonObject; static; function Serialize: string; end;
{ TJsonObjectHelper }
class function TJsonObjectHelper.Deserialize(data: string): TJsonObject; begin
Result := TJSONObject.ParseJSONValue(data) as TJsonObject;
end;
function TJsonObjectHelper.Serialize: string; begin
Result := ToJson;
end;
var
people, deserialized: TJsonObject; bar: TJsonArray; _json: string;
begin
people := TJsonObject.Create(); people.AddPair(TJsonPair.Create('1', 'John')); people.AddPair(TJsonPair.Create('2', 'Susan'));
_json := people.Serialize; Writeln(_json);
deserialized := TJSONObject.Deserialize(_json); Writeln(deserialized.Values['2'].Value);
deserialized := TJSONObject.Deserialize('{"foo":1 , "bar":[10,"apples"]}');
bar := deserialized.Values['bar'] as TJSONArray; Writeln(bar.Items[1].Value);
deserialized.Free; people.Free;
Readln;
end. </lang>
- Output:
{"1":"John","2":"Susan"} Susan apples
EchoLisp
The json library allows to import/export basic JSON types (string ,numbers, arrays) and to translate EchoLisp objects (lists, dates, ..) from/to JSON objects and types. See reference documentation [[1]]. <lang lisp>
- JSON standard types
- strings, numbers, and arrays (vectors)
(export-json #(6 7 8 9)) → "[6,7,8,9]" (export-json #("alpha" "beta" "gamma")) → "["alpha","beta","gamma"]"
(json-import "[6,7,8,9]") → #( 6 7 8 9) (json-import #<< ["alpha","beta","gamma"] >>#) → #( "alpha" "beta" "gamma")
- EchoLisp types
- dates, rational, complex, big int
(export-json 3/4) → "{"_instanceof":"Rational","a":3,"b":4}" (json-import #<< {"_instanceof":"Rational","a":666,"b":42} >>#) → 111/7
- Symbols
(export-json 'Simon-Gallubert) → "{"_instanceof":"Symbol","name":"Simon-Gallubert"}" (json-import #<< {"_instanceof":"Symbol","name":"Antoinette-de-Gabolde"} >>#)
→ Antoinette-de-Gabolde
- Lists
(define my-list
(export-json '( 43 4 5 ( 6 7 ( 8 9 ))))) → "{"_instanceof":"List" ,"array":[43,4,5,{"_instanceof":"List", "array":[6,7,{"_instanceof":"List", "array":[8,9],"circular":false}],"circular":false}],"circular":false}"
(json-import my-list) → (43 4 5 (6 7 (8 9)))
- Structures
(struct Person (name pict)) → #struct:Person [name pict] (define antoinette (Person "antoinette" "👰")) → # (antoinette 👰)
(export-json antoinette) →
"{"_instanceof":"Struct", "struct":"Person","id":17,"fields":["antoinette","👰"]}"
(json-import
#<< {"_instanceof":"Struct","struct":"Person","id":18,"fields":["simon","🎩"]} >>#)
→ # (simon 🎩)
</lang>
EGL
Structures used both to construct and to parse JSON strings: <lang EGL>record familyMember person person; relationships relationship[]?; end
record person firstName string; lastName string; age int; end
record relationship relationshipType string; id int; end</lang>
Construct JSON string: <lang EGL>people Person[]; // Array of people
people.appendElement(new Person { firstName = "Frederick", lastName = "Flintstone", age = 35} ); people.appendElement(new Person { firstName = "Wilma", lastName = "Flintstone", age = 34} ); people.appendElement(new Person { firstName = "Pebbles", lastName = "Flintstone", age = 2} ); people.appendElement(new Person { firstName = "Bernard", lastName = "Rubble", age = 32} ); people.appendElement(new Person { firstName = "Elizabeth", lastName = "Rubble", age = 29} ); people.appendElement(new Person { firstName = "Bam Bam", lastName = "Rubble", age = 2} );
family Dictionary; // A dictionary of family members using a uid as key family["1"] = new FamilyMember{ person = people[1], relationships = [new Relationship{ relationshipType="spouse", id = 2 }, new Relationship{ relationshipType="child", id = 3}] }; family["2"] = new FamilyMember{ person = people[2], relationships = [new Relationship{ relationshipType="spouse", id = 1 }, new Relationship{ relationshipType="child", id = 3}] }; family["3"] = new FamilyMember{ person = people[3], relationships = [new Relationship{ relationshipType="mother", id = 2 }, new Relationship{ relationshipType="father", id = 1}] }; family["4"] = new FamilyMember{ person = people[4], relationships = [new Relationship{ relationshipType="spouse", id = 5 }, new Relationship{ relationshipType="child", id = 6}] }; family["5"] = new FamilyMember{ person = people[5], relationships = [new Relationship{ relationshipType="spouse", id = 4 }, new Relationship{ relationshipType="child", id = 6}] }; family["6"] = new FamilyMember{ person = people[6], relationships = [new Relationship{ relationshipType="mother", id = 5 }, new Relationship{ relationshipType="father", id = 4}] };
// Convert dictionary of family members to JSON string jsonString string = jsonLib.convertToJSON(family);
// Show JSON string SysLib.writeStdout(jsonString);</lang>
- Raw Output:
{ "1":{"person":{"firstName":"Frederick","lastName":"Flintstone","age":35},"relationships":[{"relationshipType":"spouse","id":2},{"relationshipType":"child","id":3}]}, "2":{"person":{"firstName":"Wilma","lastName":"Flintstone","age":34},"relationships":[{"relationshipType":"spouse","id":1},{"relationshipType":"child","id":3}]}, "3":{"person":{"firstName":"Pebbles","lastName":"Flintstone","age":2},"relationships":[{"relationshipType":"mother","id":2},{"relationshipType":"father","id":1}]}, "4":{"person":{"firstName":"Bernard","lastName":"Rubble","age":32},"relationships":[{"relationshipType":"spouse","id":5},{"relationshipType":"child","id":6}]}, "5":{"person":{"firstName":"Elizabeth","lastName":"Rubble","age":29},"relationships":[{"relationshipType":"spouse","id":4},{"relationshipType":"child","id":6}]}, "6":{"person":{"firstName":"Bam Bam","lastName":"Rubble","age":2},"relationships":[{"relationshipType":"mother","id":5},{"relationshipType":"father","id":4}]} }
- Validated Output (partial):
{ "1": { "person": { "firstName": "Frederick", "lastName": "Flintstone", "age": 35 }, "relationships": [ { "relationshipType": "spouse", "id": 2 }, { "relationshipType": "child", "id": 3 } ] }, ... }
Parse JSON: <lang EGL>// Convert JSON string into dictionary of family members family Dictionary; jsonLib.convertFromJSON(jsonString, family);
// List family members and their relationships familyMember FamilyMember; relation FamilyMember;
keys string[] = family.getKeys(); for(i int from 1 to keys.getSize())
SysLib.writeStdout("----------------------------------------------------");
familyMember = family[keys[i]];
SysLib.writeStdout(familyMember.person.lastName + ", " + familyMember.person.firstName + " - " + familyMember.person.age);
for(j int from 1 to familyMember.relationships.getSize()) id string = familyMember.relationships[j].id; relation = family[id]; SysLib.writeStdout(familyMember.relationships[j].relationshipType + ": " + relation.person.lastName + ", " + relation.person.firstName); end
end</lang>
- Output:
Flintstone, Frederick - 35 spouse: Flintstone, Wilma child: Flintstone, Pebbles ---------------------------------------------------- Flintstone, Wilma - 34 spouse: Flintstone, Frederick child: Flintstone, Pebbles ---------------------------------------------------- Flintstone, Pebbles - 2 mother: Flintstone, Wilma father: Flintstone, Frederick ---------------------------------------------------- Rubble, Bernard - 32 spouse: Rubble, Elizabeth child: Rubble, Bam Bam ---------------------------------------------------- Rubble, Elizabeth - 29 spouse: Rubble, Bernard child: Rubble, Bam Bam ---------------------------------------------------- Rubble, Bam Bam - 2 mother: Rubble, Elizabeth father: Rubble, Bernard
The examples above illustrate that it is possible to perform manual conversions to and from a JSON format but in EGL it is much more common for the programming language to handle these conversion automatically as a natural part of service invocations. Below is an example of a function definition designed to consume the Google Maps Geocoding service. The results are returned in a JSON format and parsed by EGL into records that mirror the structure of the reply.
<lang EGL>// Service function definition function geocode(address String) returns (GoogleGeocoding) {
@Resource{uri = "binding:GoogleGeocodingBinding"}, @Rest{method = _GET, uriTemplate = "/json?address={address}&sensor=false", requestFormat = None, responseFormat = JSON}
}
// Invoke service function call geocode("111 Maple Street, Somewhere, CO") returning to callback;
function callBack(result GoogleGeocoding in)
SysLib.writeStdout(result.status); SysLib.writeStdout(result.results[1].geometry.location.lat); SysLib.writeStdout(result.results[1].geometry.location.lng);
end</lang>
Elena
ELENA 4.x <lang elena>import extensions; import extensions'dynamic;
public program() {
var json := "{ ""foo"": 1, ""bar"": [10, ""apples""] }"; var o := json.fromJson(); console.printLine("json.foo=",o.foo); console.printLine("json.bar=",o.bar)
}</lang>
- Output:
json.foo=1 json.bar=10,apples
Emacs Lisp
A JSON encoder and decoder is in package json, so load it first: <lang Lisp>(require 'json)</lang>
Decoding
<lang Lisp>(setq example "{\"foo\": \"bar\", \"baz\": [1, 2, 3]}") (json-read-from-string example) </lang>
- Output:
<lang Lisp>((foo . "bar")
(baz . [1 2 3]))</lang>
Decoding, representing data as property lists
<lang Lisp>(let ((json-object-type 'plist))
(json-read-from-string))</lang>
- Output:
<lang Lisp>(:foo "bar" :baz
[1 2 3])</lang>
Decoding, representing data as hash table
<lang Lisp>(let ((json-object-type 'hash-table))
(json-read-from-string example))</lang>
- Output:
#<hash-table equal 2/65 0x1563c39805fb>
Encoding
<Lang Lisp>(json-encode example-object)</Lang>
- Output:
"{\"list\":{\"cons\":[[\"quote\",\"x\"],2],\"cons\":[[\"quote\",\"y\"],\"a string\"]}}"
Encoding, pretty printing output
<lang Lisp>(let ((json-encoding-pretty-print t))
(json-encode example-object))</lang>
- Output:
"{ \"list\": { \"cons\": [ [ \"quote\", \"x\" ], 2 ], \"cons\": [ [ \"quote\", \"y\" ], \"a string\" ] } }"
Encoding, with options
<lang Lisp>(let* ((json-encoding-pretty-print t)
(json-object-type 'alist) (json-array-type 'vector) (json-key-type 'symbol)
(vec (make-vector 3 "element")))
(aset vec 1 "second") (aset vec 2 -3) (json-encode (list (cons 'x 2) (cons 'y "a string") (cons 'z vec))))</lang>
- Output:
"{ \"x\": 2, \"y\": \"a string\", \"z\": [ \"element\", \"second\", -3 ] }"
Erlang
Use the JSON library for Erlang (mochijson) from mochiweb. The JSON code is extracted from wikipedia <lang Erlang> -module(json). -export([main/0]).
main() -> JSON = "{ \"firstName\": \"John\", \"lastName\": \"Smith\", \"age\": 25, \"address\": { \"streetAddress\": \"21 2nd Street\", \"city\": \"New York\", \"state\": \"NY\", \"postalCode\": \"10021\" }, \"phoneNumber\": [ { \"type\": \"home\", \"number\": \"212 555-1234\" }, { \"type\": \"fax\", \"number\": \"646 555-4567\" } ] }", Erlang = {struct, [{"firstName","John"}, {"lastName","Smith"}, {"age",25}, {"address", {struct,[{"streetAddress","21 2nd Street"}, {"city","New York"}, {"state","NY"}, {"postalCode","10021"}]}}, {"phoneNumber", {array,[{struct,[{"type","home"},{"number","212 555-1234"}]}, {struct,[{"type","fax"},{"number","646 555-4567"}]}]}}]}, io:format("JSON -> Erlang\n~p\n",[mochijson:decode(JSON)]), io:format("Erlang -> JSON\n~s\n",[mochijson:encode(Erlang)]). </lang>
- Output:
JSON -> Erlang {struct,[{"firstName","John"}, {"lastName","Smith"}, {"age",25}, {"address", {struct,[{"streetAddress","21 2nd Street"}, {"city","New York"}, {"state","NY"}, {"postalCode","10021"}]}}, {"phoneNumber", {array,[{struct,[{"type","home"},{"number","212 555-1234"}]}, {struct,[{"type","fax"},{"number","646 555-4567"}]}]}}]} Erlang -> JSON {"firstName":"John","lastName":"Smith","age":25,"address":{"streetAddress":"21 2nd Street","city":"New York","state":"NY","postalCode":"10021"},"phoneNumber":[{"type":"home","number":"212 555-1234"},{"type":"fax","number":"646 555-4567"}]}
F#
There are several ways:
1. Using Json.Net <lang fsharp> open Newtonsoft.Json type Person = {ID: int; Name:string} let xs = [{ID = 1; Name = "First"} ; { ID = 2; Name = "Second"}]
let json = JsonConvert.SerializeObject(xs) json |> printfn "%s"
let xs1 = JsonConvert.DeserializeObject<Person list>(json) xs1 |> List.iter(fun x -> printfn "%i %s" x.ID x.Name) </lang>
Print: <lang fsharp>[{"ID":1,"Name":"First"},{"ID":2,"Name":"Second"}] 1 First 2 Second </lang> 2. Using FSharp.Data <lang fsharp>open FSharp.Data open FSharp.Data.JsonExtensions
type Person = {ID: int; Name:string} let xs = [{ID = 1; Name = "First"} ; { ID = 2; Name = "Second"}]
let infos = xs |> List.map(fun x -> JsonValue.Record([| "ID", JsonValue.Number(decimal x.ID); "Name", JsonValue.String(x.Name) |]))
|> Array.ofList |> JsonValue.Array
infos |> printfn "%A" match JsonValue.Parse(infos.ToString()) with | JsonValue.Array(x) -> x |> Array.map(fun x -> {ID = System.Int32.Parse(string x?ID); Name = (string x?Name)}) | _ -> failwith "fail json" |> Array.iter(fun x -> printfn "%i %s" x.ID x.Name)</lang> Print: <lang fsharp>[
{ "ID": 1, "Name": "First" }, { "ID": 2, "Name": "Second" }
] 1 "First" 2 "Second" </lang> 3. Alternative way of parsing: JsonProvider <lang fsharp>open FSharp.Data type Person = {ID: int; Name:string} type People = JsonProvider<""" [{"ID":1,"Name":"First"},{"ID":2,"Name":"Second"}] """>
People.GetSamples() |> Array.map(fun x -> {ID = x.Id; Name = x.Name} ) |> Array.iter(fun x -> printfn "%i %s" x.ID x.Name) </lang> Print:<lang fsharp> 1 First 2 Second </lang>
Factor
<lang Factor> USING: json.writer json.reader ;
SYMBOL: foo
! Load a JSON string into a data structure "[[\"foo\",1],[\"bar\",[10,\"apples\"]]]" json> foo set
! Create a new data structure and serialize into JSON
{ { "blue" { "ocean" "water" } } >json
</lang>
Fantom
<lang fantom> using util
class Json {
public static Void main () { Str input := """{"blue": [1, 2], "ocean": "water"}""" Map jsonObj := JsonInStream(input.in).readJson
echo ("Value for 'blue' is: " + jsonObj["blue"]) jsonObj["ocean"] = ["water":["cold", "blue"]] Map ocean := jsonObj["ocean"] echo ("Value for 'ocean/water' is: " + ocean["water"]) output := JsonOutStream(Env.cur.out) output.writeJson(jsonObj) echo () }
} </lang>
- Output:
Value for 'blue' is: [1, 2] Value for 'ocean/water' is: [cold, blue] {"blue":[1,2], "ocean":{"water":["cold","blue"]}}
Forth
Forth has no built-in high level data structures such as arrays, strings, and objects. Nor is there a standardized Forth library to build and use such structures. But there are many different Forth libraries, written by individuals, available though finding them is not always easy and the syntax and behavior is different for each. The library code used below can be found here:
https://github.com/DouglasBHoffman/FMS2
Load a JSON Forth string into a data structure.
s\" {\"value\":10,\"flag\":false,\"array\":[1,2,3]}" $>json value j j :.
Prints a JSON as follows: { "value": 10, "flag": false, "array": [ 1, 2, 3] }
Create a new data structure and serialize it into JSON.
j{ "another":"esc\"ap\u20ACed" }j 1 j :insert j :.
Prints the modified JSON:
{ "value": 10, "another": "esc"ap€ed", "flag": false, "array": [ 1, 2, 3] }
Convert the JSON object into a string object. Print the string.
j json>$ :.
{"value":10,"another":"esc\"ap\u20ACed","flag":false,"array":[1,2,3]}
Fortran
Using json-fortran library. Creating the json example file / reading a JSON string.
{ "PhoneBook": [ { "name": "Adam", "phone": "0000001" }, { "name": "Eve", "phone": "0000002" }, { "name": "Julia", "phone": "6666666" } ] }
<lang fortran> program json_fortran
use json_module implicit none
type phonebook_type character(len=:),allocatable :: name character(len=:),allocatable :: phone end type phonebook_type
type(phonebook_type), dimension(3) :: PhoneBook integer :: i type(json_value),pointer :: json_phonebook,p,e type(json_file) :: json
PhoneBook(1) % name = 'Adam' PhoneBook(2) % name = 'Eve' PhoneBook(3) % name = 'Julia' PhoneBook(1) % phone = '0000001' PhoneBook(2) % phone = '0000002' PhoneBook(3) % phone = '6666666'
call json_initialize()
!create the root structure: call json_create_object(json_phonebook,)
!create and populate the phonebook array: call json_create_array(p,'PhoneBook') do i=1,3 call json_create_object(e,) call json_add(e,'name',PhoneBook(i)%name) call json_add(e,'phone',PhoneBook(i)%phone) call json_add(p,e) !add this element to array nullify(e) !cleanup for next loop end do call json_add(json_phonebook,p) !add p to json_phonebook nullify(p) !no longer need this
!write it to a file: call json_print(json_phonebook,'phonebook.json')
! read directly from a character string call json%load_from_string('{ "PhoneBook": [ { "name": "Adam", "phone": "0000001" },& { "name": "Eve", "phone": "0000002" }, { "name": "Julia", "phone": "6666666" } ]}') ! print it to the console call json%print_file()
end program json_fortran </lang>
FunL
Since FunL map syntax is conforms to JSON, the built-in function
eval()
can be used to parse a JSON string.
Built-in println()
also produces JSON conformant output.
This method only uses built-in functions but is comparatively slow.
<lang funl>println( eval('{ "foo": 1, "bar": [10, "apples"] }') )</lang>
Using module json
gives better performance and also pretty prints the JSON output.
<lang funl>import json.*
DefaultJSONWriter.write( JSONReader({'ints', 'bigInts'}).fromString('{ "foo": 1, "bar": [10, "apples"] }') )</lang>
- Output:
{"foo": 1, "bar": [10, "apples"]} { "foo": 1, "bar": [ 10, "apples" ] }
Go
Example below shows simple correspondence between JSON objects and Go maps, and shows that you don't have to know anything about the structure of the JSON data to read it in. <lang go>package main
import "encoding/json" import "fmt"
func main() {
var data interface{} err := json.Unmarshal([]byte(`{"foo":1, "bar":[10, "apples"]}`), &data) if err == nil { fmt.Println(data) } else { fmt.Println(err) }
sample := map[string]interface{}{ "blue": []interface{}{1, 2}, "ocean": "water", } json_string, err := json.Marshal(sample) if err == nil { fmt.Println(string(json_string)) } else { fmt.Println(err) }
}</lang>
- Output:
map[bar:[10 apples] foo:1] {"blue":[1,2],"ocean":"water"}
Example below demonstrates more typical case where you have an expected correspondence between JSON data and some composite data types in your program, and shows how the correspondence doesn't have to be exact. <lang go>package main
import "encoding/json" import "fmt"
type Person struct {
Name string `json:"name"` Age int `json:"age,omitempty"` Addr *Address `json:"address,omitempty"` Ph []string `json:"phone,omitempty"`
}
type Address struct {
Street string `json:"street"` City string `json:"city"` State string `json:"state"` Zip string `json:"zip"`
}
func main() {
// compare with output, note apt field ignored, missing fields // have zero values. jData := []byte(`{ "name": "Smith", "address": { "street": "21 2nd Street", "apt": "507", "city": "New York", "state": "NY", "zip": "10021" } }`) var p Person err := json.Unmarshal(jData, &p) if err != nil { fmt.Println(err) } else { fmt.Printf("%+v\n %+v\n\n", p, p.Addr) }
// compare with output, note empty fields omitted. pList := []Person{ { Name: "Jones", Age: 21, }, { Name: "Smith", Addr: &Address{"21 2nd Street", "New York", "NY", "10021"}, Ph: []string{"212 555-1234", "646 555-4567"}, }, } jData, err = json.MarshalIndent(pList, "", " ") if err != nil { fmt.Println(err) } else { fmt.Println(string(jData)) }
}</lang>
- Output:
{Name:Smith Age:0 Addr:0xf840026080 Ph:[]} &{Street:21 2nd Street City:New York State:NY Zip:10021} [ { "name": "Jones", "age": 21 }, { "name": "Smith", "address": { "street": "21 2nd Street", "city": "New York", "state": "NY", "zip": "10021" }, "phone": [ "212 555-1234", "646 555-4567" ] } ]
Gosu
Gosu consumes JSON as a Dynamic type via this core API: <lang javascript> gw.lang.reflect.json.Json#fromJson( String json ) : javax.script.Bindings </lang> As the signature of the method suggests, you pass in a JSON string and receive standard script Bindings in return. Bindings is basically a map mirroring the tree structure of the JSON object. Internally Gosu supports any Bindings instance as a Dynamic Expando object. Essentially this means you can directly cast any Bindings instance to Dynamic and treat it as an Expando.
The following JSON example illustrates this:
Sample Person JSON (from http://gosu-lang.github.io/data/person.json): <lang javascript>{
"Name": "Dickson Yamada", "Age": 39, "Address": { "Number": 9604, "Street": "Donald Court", "City": "Golden Shores", "State": "FL" }, "Hobby": [ { "Category": "Sport", "Name": "Baseball" }, { "Category": "Recreation", "Name": "Hiking" } ]
} </lang> And the dynamic Gosu code to access it: <lang javascript> var personUrl = new URL( "http://gosu-lang.github.io/data/person.json" ) var person: Dynamic = personUrl.JsonContent print( person.Name ) </lang> Notice the JsonContent property on URL: <lang javascript> personUrl.JsonContent </lang> This is a convenient enhancement property Gosu provides for Java’s URL class. It does all the work to get the JSON text and calls the new Json#fromJson() method for you. It also declares the Dynamic type for you as its return type, so the declared Dynamic type on the person var is unnecessary; it’s there to clearly demonstrate that the person var is indeed Dynamic.
As you can see we can access the Name property from the JSON object from the person var. This is all well and good, but falls short of our desired level of JSON support. Gosu being a static language, we really want that Name reference to be statically verified as well as code-completed in the IDE.
Here’s how we make the previous example work statically: <lang javascript> print( person.toStructure( "Person", false ) ) </lang> Gosu enhances Bindings with the method, toStructure( name: String, mutable: boolean ). Note the resulting structure is optionally mutable via the mutable argument. This method generates the complete nesting of types plus convenient factory methods: <lang javascript> structure Person {
static function fromJson( jsonText: String ): Person { return gw.lang.reflect.json.Json.fromJson( jsonText ) as Person } static function fromJsonUrl( url: String ): Person { return new java.net.URL( url ).JsonContent } static function fromJsonUrl( url: java.net.URL ): Person { return url.JsonContent } static function fromJsonFile( file: java.io.File ) : Person { return fromJsonUrl( file.toURI().toURL() ) } property get Address(): Address property get Hobby(): List<Hobby> property get Age(): Integer property get Name(): String structure Address { property get Number(): Integer property get State(): String property get Street(): String property get City(): String } structure Hobby { property get Category(): String property get Name(): String }
} </lang> The Person structure reflects the JSON object’s implied type nesting. You can do whatever you like with this type. You can embed it as an inner structure in an existing class or make a top-level type. In any case all the types in the JSON object are uniquely preserved in one structure. Use it like this: <lang javascript> var person = Person.fromJsonUrl( personUrl ) print( person.Name ) print( person.Address.City ) print( person.Hobby[0].Name ) </lang> All statically verified and fully code completion friendly!
Other features: <lang javascript> print( person.toJson() ) // toJson() generates the Expando bindings to a JSON string print( person.toGosu() ) // toGosu() generates any Bindings instance to a Gosu Expando initializer string print( person.toXml() ) // toXml() generates any Bindings instance to standard XML </lang> And similar to JavaScript, you can directly evaluate a Gosu Expando initializer string: <lang javascript> var clone = eval( person.toGosu() ) </lang>
Groovy
Solution requires Groovy 1.8 or later.
Note that JsonSlurper accepts an extra comma such as [1,2,3,]. This is an extension to the [JSON grammar].
<lang groovy>def slurper = new groovy.json.JsonSlurper() def result = slurper.parseText( {
"people":[ {"name":{"family":"Flintstone","given":"Frederick"},"age":35,"relationships":{"wife":"people[1]","child":"people[4]"}}, {"name":{"family":"Flintstone","given":"Wilma"},"age":32,"relationships":{"husband":"people[0]","child":"people[4]"}}, {"name":{"family":"Rubble","given":"Barnard"},"age":30,"relationships":{"wife":"people[3]","child":"people[5]"}}, {"name":{"family":"Rubble","given":"Elisabeth"},"age":32,"relationships":{"husband":"people[2]","child":"people[5]"}}, {"name":{"family":"Flintstone","given":"Pebbles"},"age":1,"relationships":{"mother":"people[1]","father":"people[0]"}}, {"name":{"family":"Rubble","given":"Bam-Bam"},"age":1,"relationships":{"mother":"people[3]","father":"people[2]"}}, ]
} )</lang>
Test: <lang groovy>result.each { println it.key; it.value.each {person -> println person} }
assert result.people[0].name == [family:'Flintstone', given:'Frederick'] assert result.people[4].age == 1 assert result.people[2].relationships.wife == 'people[3]' assert result.people[3].name == [family:'Rubble', given:'Elisabeth'] assert Eval.x(result, 'x.' + result.people[2].relationships.wife + '.name') == [family:'Rubble', given:'Elisabeth'] assert Eval.x(result, 'x.' + result.people[1].relationships.husband + '.name') == [family:'Flintstone', given:'Frederick']</lang>
- Output:
people [age:35, name:[given:Frederick, family:Flintstone], relationships:[child:people[4], wife:people[1]]] [age:32, name:[given:Wilma, family:Flintstone], relationships:[child:people[4], husband:people[0]]] [age:30, name:[given:Barnard, family:Rubble], relationships:[child:people[5], wife:people[3]]] [age:32, name:[given:Elisabeth, family:Rubble], relationships:[child:people[5], husband:people[2]]] [age:1, name:[given:Pebbles, family:Flintstone], relationships:[mother:people[1], father:people[0]]] [age:1, name:[given:Bam-Bam, family:Rubble], relationships:[mother:people[3], father:people[2]]]
Halon
<lang halon>$data = json_decode({ "foo": 1, "bar": [10, "apples"] });
$sample = ["blue" => [1, 2], "ocean" => "water"]; $jsonstring = json_encode($sample, ["pretty_print" => true]);</lang>
Harbour
Parse JSON string into the arr variable: <lang visualfoxpro>LOCAL arr hb_jsonDecode( '[101,[26,"Test1"],18,false]', @arr )</lang>
- Output:
the JSON representation of an array arr
<lang visualfoxpro>LOCAL arr := { 101, { 18, "Test1" }, 18, .F. } ? hb_jsonEncode( arr ) // The output is: // [101,[26,"Test1"],18,false]</lang>
Haskell
Uses the Aeson library from hackage (http://hackage.haskell.org/package/aeson).
<lang Haskell> {-# LANGUAGE OverloadedStrings #-}
import Data.Aeson import Data.Attoparsec (parseOnly) import Data.Text import qualified Data.ByteString.Lazy.Char8 as B import qualified Data.ByteString.Char8 as S
testdoc = object [
"foo" .= (1 :: Int), "bar" .= ([1.3, 1.6, 1.9] :: [Double]), "baz" .= ("some string" :: Text), "other" .= object [ "yes" .= ("sir" :: Text) ] ]
main = do
let out = encode testdoc B.putStrLn out case parseOnly json (S.concat $ B.toChunks out) of Left e -> error $ "strange error re-parsing json: " ++ (show e) Right v | v /= testdoc -> error "documents not equal!" Right v | otherwise -> print v
</lang>
An example using Aeson and TemplateHaskell. Note that it can handle the absence of keys. <lang haskell> {-# LANGUAGE TemplateHaskell, OverloadedStrings #-} import Data.Aeson import Data.Aeson.TH
data Person = Person { firstName :: String
, lastName :: String , age :: Maybe Int } deriving (Show, Eq)
$(deriveJSON defaultOptions Person)
main = do
let test1 = "{\"firstName\":\"Bob\", \"lastName\":\"Smith\"}" test2 = "{\"firstName\":\"Miles\", \"lastName\":\"Davis\", \"age\": 45}" print (decode test1 :: Maybe Person) print (decode test2 :: Maybe Person)
</lang>
An example using Aeson and GHC.Generics. Note that it can handle the absence of keys. <lang haskell> {-# LANGUAGE DeriveGeneric, OverloadedStrings #-} import Data.Aeson import GHC.Generics
data Person = Person { firstName :: String
, lastName :: String , age :: Maybe Int } deriving (Show, Eq, Generic)
instance FromJSON Person instance ToJSON Person
main = do
let test1 = "{\"firstName\":\"Bob\", \"lastName\":\"Smith\"}" test2 = "{\"firstName\":\"Miles\", \"lastName\":\"Davis\", \"age\": 45}" print (decode test1 :: Maybe Person) print (decode test2 :: Maybe Person)
</lang>
Hoon
<lang Hoon>:- %say |= [^ [in=@tas ~] ~]
- - %noun
=+ obj=(need (poja in)) :: try parse to json =+ typ=$:(name=@tas age=@ud) :: datastructure =+ spec=(ot name/so age/ni ~):jo :: parsing spec ?. ?=([%o *] obj) :: isnt an object? ~ =+ ^= o %. %. (spec obj) :: parse with spec need :: panic if failed ,typ :: cast to type =. age.o +(age.o) :: increment its age... %: crip %: pojo :: pretty-print result (jobe [%name s/name.o] [%age n/(crip <age.o>)] ~) :: convert back to json</lang>
Usage: Put code in gen/json.hoon
> +json '{"name":"pojo", "age":4}' '{"age":5,"name":"pojo"}'
J
Here is a minimal implementation based on an old email message.
<lang j>NB. character classes: NB. 0: whitespace NB. 1: " NB. 2: \ NB. 3: [ ] , { } : NB. 4: ordinary classes=.3<. '"\[],{}:' (#@[ |&>: i.) a. classes=.0 (I.a.e.' ',CRLF,TAB)} (]+4*0=])classes
words=:(0;(0 10#:10*".;._2]0 :0);classes)&;: NB. states:
0.0 1.1 2.1 3.1 4.1 NB. 0 whitespace 1.0 5.0 6.0 1.0 1.0 NB. 1 " 4.0 4.0 4.0 4.0 4.0 NB. 2 \ 0.3 1.2 2.2 3.2 4.2 NB. 3 { : , } [ ] 0.3 1.2 2.0 3.2 4.0 NB. 4 ordinary 0.3 1.2 2.2 3.2 4.2 NB. 5 "" 1.0 1.0 1.0 1.0 1.0 NB. 6 "\
)
tokens=. ;:'[ ] , { } :' actions=: lBra`rBracket`comma`lBra`rBrace`colon`value
NB. action verbs argument conventions: NB. x -- boxed json word NB. y -- boxed json state stack NB. result -- new boxed json state stack NB. NB. json state stack is an list of boxes of incomplete lists NB. (a single box for complete, syntactically valid json) jsonParse=: 0 {:: (,a:) ,&.> [: actions@.(tokens&i.@[)/ [:|.a:,words
lBra=: a: ,~ ] rBracket=: _2&}.@], [:< _2&{::@], _1&{@] comma=: ] rBrace=: _2&}.@], [:< _2&{::@](, <) [:|: (2,~ [: -:@$ _1&{::@]) $ _1&{::@] colon=: ] value=: _1&}.@], [:< _1&{::@], jsonValue&.>@[
NB. hypothetically, jsonValue should strip double quotes NB. interpret back slashes NB. and recognize numbers jsonValue=:]
require'strings'
jsonSer2=: jsonSer1@(<"_1^:(0>.#@$-1:))
jsonSer1=: ']' ,~ '[' }:@;@; (',' ,~ jsonSerialize)&.>
jsonSer0=: '"', jsonEsc@:":, '"'"_
jsonEsc=: rplc&(<;._1' \ \\ " \"')
jsonSerialize=:jsonSer0`jsonSer2@.(*@L.)</lang>
Example use:
<lang> jsonParse'{ "blue": [1,2], "ocean": "water" }' ┌────────────────┐ │┌──────┬───────┐│ ││"blue"│"ocean"││ │├──────┼───────┤│ ││┌─┬─┐ │"water"││ │││1│2│ │ ││ ││└─┴─┘ │ ││ │└──────┴───────┘│ └────────────────┘ └──────────────────────────────┘
jsonSerialize jsonParse'{ "blue": [1,2], "ocean": "water" }'
[[["\"blue\"","\"ocean\""],[["1","2"],"\"water\""]]]</lang>
Note that these are not strict inverses of each other. These routines allow data to be extracted from json and packed into json format, but only in a minimalistic sense. No attempts are made to preserve the subtleties of type and structure which json can carry. This should be good enough for most applications which are required to deal with json but will not be adequate for ill behaved applications which exploit the typing mechanism to carry significant information.
Also, a different serializer will probably be necessary, if you are delivering json to legacy javascript. Nevertheless, these simplifications are probably appropriate for practical cases.
Java
This uses Gson, a library to convert JSON to Java objects and vice-versa. <lang Java>import com.google.gson.Gson;
public class JsonExample {
public static void main(String[] args) { Gson gson = new Gson(); String json = "{ \"foo\": 1, \"bar\": [ \"10\", \"apples\"] }";
MyJsonObject obj = gson.fromJson(json, MyJsonObject.class);
System.out.println(obj.getFoo());
for(String bar : obj.getBar()) { System.out.println(bar); }
obj = new MyJsonObject(2, new String[] { "20", "oranges" }); json = gson.toJson(obj);
System.out.println(json); }
}
class MyJsonObject {
private int foo; private String[] bar;
public MyJsonObject(int foo, String[] bar) { this.foo = foo; this.bar = bar; }
public int getFoo() { return foo; }
public String[] getBar() { return bar; }
}</lang>
JavaScript
Requires JSON library, now present in all major browsers. <lang JavaScript>var data = JSON.parse('{ "foo": 1, "bar": [10, "apples"] }');
var sample = { "blue": [1,2], "ocean": "water" }; var json_string = JSON.stringify(sample);</lang>
JSON is called JavaScript Object Notation, but JSON differs form JavaScript object literal. cf. MDN/JSON
jq
JSON is jq's native data format, so nothing need be done to parse JSON input. For example, to "pretty print" a stream of JSON entities (including scalars), it would be sufficient to use the jq program:<lang jq> . </lang>
Here are the jq equivalents of the examples given in the section on Julia, assuming the file data.json holds the following JSON text:
{ "blue": [1,2], "ocean": "water" }
<lang jq>jq -c . data.json</lang> produces:
{"blue":[1,2],"ocean":"water"}
<lang jq>jq tostring data.json</lang> produces: "{\"blue\":[1,2],\"ocean\":\"water\"}"
Jsish
<lang javascript>prompt$ jsish Jsish interactive: see 'help [cmd]'
- var data = JSON.parse('{ "foo": 1, "bar": [10, "apples"] }');
variable
- data
{ bar:[ 10, "apples" ], foo:1 }
- var sample = { blue: [1,2], ocean: "water" };
variable
- sample
{ blue:[ 1, 2 ], ocean:"water" }
- puts(JSON.stringify(sample))
{ "blue":[ 1, 2 ], "ocean":"water" }</lang>
Julia
<lang julia># Pkg.add("JSON") ... an external library http://docs.julialang.org/en/latest/packages/packagelist/ using JSON
sample = Dict() sample["blue"] = [1, 2] sample["ocean"] = "water"
@show sample jsonstring = json(sample) @show jsonobj = JSON.parse(jsonstring)
@assert jsonstring == "{\"ocean\":\"water\",\"blue\":[1,2]}" @assert jsonobj == Dict("ocean" => "water", "blue" => [1, 2]) @assert typeof(jsonobj) == Dict{String, Any}</lang>
Kotlin
We use Kotlin JS here to obtain access to the JavaScript JSON object: <lang scala>// version 1.2.21
data class JsonObject(val foo: Int, val bar: Array<String>)
data class JsonObject2(val ocean: String, val blue: Array<Int>)
fun main(args: Array<String>) {
// JSON to object val data: JsonObject = JSON.parse("""{ "foo": 1, "bar": ["10", "apples"] }""") println(JSON.stringify(data))
// object to JSON val data2 = JsonObject2("water", arrayOf(1, 2)) println(JSON.stringify(data2))
}</lang>
- Output:
{"foo":1,"bar":["10","apples"]} {"ocean":"water","blue":[1,2]}
Lasso
<lang Lasso>// Javascript objects are represented by maps in Lasso local(mymap = map( 'success' = true, 'numeric' = 11, 'string' = 'Eleven' ))
json_serialize(#mymap) // {"numeric": 11,"string": "Eleven","success": true}
'
'
// Javascript arrays are represented by arrays local(opendays = array( 'Monday', 'Tuesday' ))
local(closeddays = array( 'Wednesday', 'Thursday', 'Friday' ))
json_serialize(#opendays) // ["Monday", "Tuesday"]
'
'
json_serialize(#closeddays) // ["Wednesday", "Thursday", "Friday"]
'
'
- mymap -> insert('Open' = #opendays)
- mymap -> insert('Closed' = #closeddays)
local(myjson = json_serialize(#mymap))
- myjson // {"Closed": ["Wednesday", "Thursday", "Friday"],"numeric": 11,"Open": ["Monday", "Tuesday"],"string": "Eleven","success": true}
'
'
json_deserialize(#myjson) // map(Closed = array(Wednesday, Thursday, Friday), numeric = 11, Open = array(Monday, Tuesday), string = Eleven, success = true)</lang>
LFE
This example uses the third-party library "Jiffy".
Encoding
<lang lisp> (: jiffy encode (list 1 2 3 '"apple" 'true 3.14)) </lang>
The result from that can be made a little more legible with the following: <lang lisp> (: erlang binary_to_list
(: jiffy encode (list 1 2 3 '"apple" 'true 3.14)))
</lang>
Decoding
We can run the encoding example in reverse, and get back what we put in above with the following: <lang lisp> (: jiffy decode '"[1,2,3,[97,112,112,108,101],true,3.14]") </lang>
Here's a key-value example: <lang lisp> (: jiffy decode '"{\"foo\": [1, 2, 3]}") </lang>
Decoding to Patterns
We can also extract the key and value using Erlang patterns: <lang lisp> (let (((tuple (list (tuple key value)))
(: jiffy decode '"{\"foo\": [1, 2, 3]}"))) (: io format '"~p: ~p~n" (list key value)))
</lang>
Lingo
Lingo has no native JSON support. A JSON library could of course be written in pure Lingo or as binary plugin ("Xtra").
But since Director - the only implementation of Lingo - also includes a SpiderMonkey JS engine (rather outdated and without native JSON object), we can implement a simple (unsafe) JSON encoder/decoder with the following two movie scripts:
JavaScript movie script "JSON": <lang javascript>//-------------------------------------- // Simple (unsafe) JSON decoder based on eval() // @param {string} json // @return {any} //-------------------------------------- function json_decode (json){
var o; eval('o='+json); return _json_decode_val(o);
}
function _json_decode_val (o){
if (o==null) return undefined; switch(typeof(o)){ case "object": if (o instanceof Array){ var v = list(); var cnt = o.length; for (i=0;i<cnt;i++){ v.add(_json_decode_val(o[i])); } }else{ var v = propList(); for (var i in o){ var p = i; v.setAProp(_json_decode_val(p), _json_decode_val(o[i])); } } return v; case "string": // optional support of special Lingo data type 'symbol' unknown to JavaScript if (o.substr(0,7)=='__sym__') return symbol(o.substr(7)); return o; default: return o; }
}
function _json_escape_string (str){
var hash={"\\":"\\\\", "/":"\\/", "\n":"\\n", "\t":"\\t", "\r":"\\r", "\b":"\\b", "\f":"\\f", "\"":"\\\""}; var patt = "["; for (i in hash) patt+=i;patt+="]"; return str.replace(RegExp(patt, "g"), function(c){ return hash[c] });
}</lang>
Lingo movie script "JSON":<lang lingo>---------------------------------------- -- JSON encoder -- Supported Lingo data types: VOID, integer, float, string, symbol, list, propList -- @param {any} o -- @return {string}
on json_encode (o)
case ilk(o) of #void: return "null" #integer, #float: return string(o) #string: return QUOTE & _json_escape_string(o) & QUOTE #list: res = [] repeat with v in o res.add(json_encode(v)) end repeat return "[" & _cimplode(res) & "]" #propList: res = [] cnt = count(o) repeat with i = 1 to cnt p = o.getPropAt(i) v = o[i] res.add( json_encode(p)&":"&json_encode(v) ) end repeat return "{" & _cimplode(res) & "}" #symbol: -- optional support of special Lingo data type 'symbol' unknown to JavaScript return QUOTE &"__sym__"&_json_escape_string(string(o)) & QUOTE otherwise: put "ERROR: unsupported data type" end case
end
-- Implodes list into comma-separated string -- @param {list} l -- @return {string}
on _cimplode (l)
str="" repeat with i=1 to l.count put l[i]&"," after str end repeat delete the last char of str return str
end</lang>
Usage: <lang lingo>data_org = [\
42,\ 3.14159,\ [2, 4, #fooBar, "apples", "bananas", "cherries" ],\ ["foo": 1, #bar: VOID, "Hello": "world!"],\ VOID\
]
json_str = json_encode(data_org) -- valid according to JSONLint
data_decoded = json_decode(json_str)
put data_org -- [42, 3.1416, [2, 4, #fooBar, "apples", "bananas", "cherries"], ["foo": 1, #bar: <Void>, "Hello": "world!"], <Void>] put data_decoded -- [42, 3.1416, [2, 4, #fooBar, "apples", "bananas", "cherries"], ["foo": 1, #bar: <Void>, "Hello": "world!"], <Void>]</lang>
Lua
Using the luajson library:
<lang lua>local json = require("json")
local json_data = [=[[
42, 3.14159, [ 2, 4, 8, 16, 32, 64, "apples", "bananas", "cherries" ], { "H": 1, "He": 2, "X": null, "Li": 3 }, null, true, false
]]=]
print("Original JSON: " .. json_data) local data = json.decode(json_data) json.util.printValue(data, 'Lua') print("JSON re-encoded: " .. json.encode(data))
local data = {
42, 3.14159, { 2, 4, 8, 16, 32, 64, "apples", "bananas", "cherries" }, { H = 1, He = 2, X = json.util.null(), Li = 3 }, json.util.null(), true, false
}
print("JSON from new Lua data: " .. json.encode(data))</lang>
Since in Lua nil
signifies an undefined value, i.e. a variable or table entry with a nil
value is undistinguishable from an undefined variable or non-existing table entry, a null
value in JSON notation is decoded to a special function value, which ensures that it can be re-encoded properly to null
again.
To manually insert a null
value in the JSON output,
use the json.util.null
function.
- Output:
Original JSON: [ 42, 3.14159, [ 2, 4, 8, 16, 32, 64, "apples", "bananas", "cherries" ], { "H": 1, "He": 2, "X": null, "Li": 3 }, null, true, false ] Lua= { 1=42 2=3.14159 3= { 1=2 2=4 3=8 4=16 5=32 6=64 7=apples 8=bananas 9=cherries 4= { Li=3 He=2 H=1 X=function: 0x8f6f00 5=function: 0x8f6f00 6=true 7=false JSON re-encoded: [42,3.14159,[2,4,8,16,32,64,"apples","bananas","cherries"],{"Li":3,"He":2,"H":1,"X":null},null,true,false] JSON from new Lua data: [42,3.14159,[2,4,8,16,32,64,"apples","bananas","cherries"],{"Li":3,"He":2,"H":1,"X":null},null,true,false]
M2000 Interpreter
We use a class written in M2000 for Json M2000 Interpreter Json Class in a module LIB1 <lang M2000 Interpreter> MODULE A {
\\ Process data in json format
\\ We can load from external file with Inline "libName" \\ or multiple files Inline "file1" && "file2" \\ but here we have the library in a module Inline Code Lib1 \\ So now we make a Parser object (a group type in M2000) Parser=ParserClass() \\ We can display any function, module that is public and known list Modules ? \\ And this are all known variables (or and objects) List ! Document json$ \\ We can load from file \\ Load.Doc json$, "alfa.json" json$={{ "alfa":-0.11221e+12, "array" : [ -0.67, "alfa1", [ 10, 20 ], "beta1", 1.21e12, 21.12145, "ok" ], "delta": false, "epsilon" : true, "Null Value" : null }} Save.Doc json$, "json2.json" \\ by default in Utf-8 with BOM \\ just show multiline text \\ Report display lines and stop after 3/4 of console height lines \\ just press a key or click mouse button Report json$ \\ so now we get text to a new object alfa=Parser.Eval(json$) \\ check it Print Type$(alfa) ' it is a group Print "alfa.type$=";alfa.type$ \\ this is a read only property
Report "as one line" Report Parser.Ser$(alfa, 0)
Report "as multiline" Report Parser.Ser$(alfa, 1)
Print "Using Print" Print Parser.ReadAnyString$(alfa)
Print "Value for alfa, id alfa" Print Parser.ReadAnyString$(alfa,"alfa") Report "as multiline" Report Parser.Ser$(Parser.Eval(Parser.ReadAnyString$(alfa,"array", 2)), 1) \\ We get a copy of an array as a Group (a group which return an array) Alfa3=Parser.Eval(Parser.ReadAnyString$(alfa,"array", 2)) \\ First value is for actual object, second value is a readonly property of this object Print type$(Alfa3), Alfa3.type$ Dim B() \\ Now Alfa3 run Value part and pass a pointer of array \\ B() is an array and here take a pointer to Alfa3 array (as value of Alfa3) B()=Alfa3 \\ each() make an iterator for B() N=each(B()) While N { \\ Using B() we get values always. but if we have "object" or "array" then Print prints items ** Print B(N^) } \\ Print show here nothing because if value is object then "print" just leave a column and continue to next one Print B() \\ we have to use Group() to get group not value of group (if any). \\ Group() works for "named" group, not for stored in an array or an inventory or a stack Print Parser.StringValue$(Group(Alfa3), 0) Print Parser.StringValue$(Group(Alfa3), 1) \\ Now we want to pass a new value \\ Interpreter want to match type of expression from left side to right side \\ Because Parser.StringValue$ is actual a Group (As property), \\ we have a second linked name: Parser.StringValue \\ we have to use Parser.StringValue() \\ and all values must be groups, as those provided by Parser Parser.StringValue(Group(Alfa3), 1)=Parser.Numeric(1234) Print Parser.StringValue$(Group(Alfa3), 1) Print Parser.StringValue$(Group(Alfa), "array", 2, 0) \\ we have to use Parser.StringValue$() Parser.StringValue$(Group(Alfa), "array", 2, 0)=Parser.JString$("Changed to String") Print Parser.StringValue$(Group(Alfa), "array", 2,0) Try ok { Print Parser.StringValue$(Group(Alfa), "array", 2) } If Error or not ok Then Print Error$ Parser.StringValue.Add = True Parser.StringValue$(Group(Alfa), "array", 2, 10)=Parser.JString$("Changed to String 2") Parser.StringValue(Group(Alfa), "Last value")=Parser.Boolean(true) Report "as multiline" Report Parser.Ser$(alfa3, 1) Report Parser.Ser$(alfa, 1) Parser.StringValue.Add = False Parser.StringValue.Del = True Parser.StringValue(Group(Alfa), "array", 0)=Parser.Null() Parser.StringValue(Group(Alfa), "delta")=Parser.Null() Parser.StringValue.Del = False For Parser { .StringValue(Group(Alfa), "array", 1,5)=.Arr((.Numeric(10), .Jstring$("ok 20"), .Boolean(true))) } Report Parser.Ser$(alfa, 1)
} // call A A </lang>
Maple
<lang Maple>> JSON:-ParseString("[{\"tree\": \"maple\", \"count\": 21}]");
[table(["tree" = "maple", "count" = 21])]
> JSON:-ToString( [table(["tree" = "maple", "count" = 21])] );
"[{\"count\": 21, \"tree\": \"maple\"}]"</lang>
Mathematica
<lang Mathematica> data = ImportString["{ \"foo\": 1, \"bar\": [10, \"apples\"] }","JSON"] ExportString[data, "JSON"] </lang>
MATLAB / Octave
<lang matlab>>> jsondecode('{ "foo": 1, "bar": [10, "apples"] }') ans =
struct with fields:
foo: 1 bar: {2×1 cell}
>> jsonencode(ans) ans = {"foo":1,"bar":[10,"apples"]}</lang> The toolbox JSONlab is doing a nice job to read (loadjson.m) and write (savejson.m) data in JSON format.
NetRexx
json.org Library
This uses a library provided by json.org to serialize/deserialize JSON objects. <lang NetRexx>/* NetRexx */ options replace format comments java crossref symbols nobinary
import java.util.List import org.json.JSONObject import org.json.JSONArray import org.json.JSONTokener import org.json.JSONException
/**
* Using library from json.org * * @see http://www.json.org/java/index.html */
class RJson01 public
properties private constant JSON_DWARFS = - '{\n' - ' "F1937_1" : {\n' - ' "title" : "Snow White and the Seven Dwarfs",\n' - ' "year" : 1937,\n' - ' "medium" : "film",\n' - ' "dwarfs" : [ "Grumpy", "Happy", "Sleepy", "Bashful", "Sneezy", "Dopey", "Doc" ]\n' - ' },\n' - ' "F2012_1" : {\n' - ' "title" : "Mirror, Mirror",\n' - ' "year" : 2012,\n' - ' "medium" : "film",\n' - ' "dwarfs" : [ "Grimm", "Butcher", "Wolf", "Napoleon", "Half Pint", "Grub", "Chuckles" ]\n' - ' },\n' - '}'
/** * A bean that looks like the following JSON
*
* { * "F2012_2" : { * "title" : "Snow White & the Huntsman", * "year" : 2012, * "medium" : "film", * "dwarfs" : [ "Beith", "Quert", "Muir", "Coll", "Duir", "Gus", "Gort", "Nion" ] * } * } *
*/ SAMPLE_BEAN = DwarfBean( - "F2012_2", - "Snow White & the Huntsman", - Long(2012), - "film", - Arrays.asList([String "Beith", "Quert", "Muir", "Coll", "Duir", "Gus", "Gort", "Nion"]) - )
method main(args = String[]) public static say json2bean(JSON_DWARFS) say say bean2json(SAMPLE_BEAN) say return
method json2bean(dwarfs) public static returns List
say "Make beans from this JSON string:" say dwarfs jsonBeans = ArrayList() do jd = JSONObject(JSONTokener(dwarfs)) ns = JSONObject.getNames(jd) name = String loop name over ns dwarves = ArrayList() jn = jd.getJSONObject(name) title = jn.getString('title') year = Long(jn.getLong('year')) medium = jn.getString('medium') dwa = jn.getJSONArray('dwarfs') loop di = 0 to dwa.length() - 1 dwarves.add(dwa.getString(di)) end di jb = DwarfBean(name, title, year, medium, dwarves) jsonBeans.add(jb.toString()) end name catch ex = JSONException ex.printStackTrace() end return jsonBeans
method bean2json(sb = DwarfBean) public static returns String
say "Make JSONObject from this bean:" say sb jsonString = String do jd = JSONObject(sb) jo = JSONObject() jo = jo.put(sb.keyGet(), jd) jsonString = jo.toString(2) catch ex = JSONException ex.printStackTrace() end return jsonString
-- ============================================================================= class RJson01.DwarfBean public binary
properties private key = String -- not part of bean properties indirect title = String year = Long medium = String dwarfs = List
method DwarfBean(key_ = String null, title_ = String null, year_ = Long null, medium_ = String null, dwarfs_ = List null) public keyPut(key_) setTitle(title_) setYear(year_) setMedium(medium_) setDwarfs(dwarfs_) return
method keyPut(key_ = String) public key = key_ return
method keyGet() returns String return key
method toString public returns String ts = StringBuilder() ts.append(String.format("%s@%08x ", [Object this.getClass().getSimpleName(), Integer(hashCode())])) ts.append('[') ts.append('key='String.valueOf(keyGet())', ') ts.append('title='String.valueOf(getTitle())', ') ts.append('year='String.valueOf(getYear())', ') ts.append('medium='String.valueOf(getMedium())', ') ts.append('dwarfs='String.valueOf(getDwarfs())) ts.append(']') return ts.toString()
</lang>
- Output:
Make beans from this JSON string: { "F1937_1" : { "title" : "Snow White and the Seven Dwarfs", "year" : 1937, "medium" : "film", "dwarfs" : [ "Grumpy", "Happy", "Sleepy", "Bashful", "Sneezy", "Dopey", "Doc" ] }, "F2012_1" : { "title" : "Mirror, Mirror", "year" : 2012, "medium" : "film", "dwarfs" : [ "Grimm", "Butcher", "Wolf", "Napoleon", "Half Pint", "Grub", "Chuckles" ] }, } [DwarfBean@07377711 [key=F2012_1, title=Mirror, Mirror, year=2012, medium=film, dwarfs=[Grimm, Butcher, Wolf, Napoleon, Half Pint, Grub, Chuckles]], DwarfBean@19f16e6e [key=F1937_1, title=Snow White and the Seven Dwarfs, year=1937, medium=film, dwarfs=[Grumpy, Happy, Sleepy, Bashful, Sneezy, Dopey, Doc]]] Make JSONObject from this bean: DwarfBean@39890510 [key=F2012_2, title=Snow White & the Huntsman, year=2012, medium=film, dwarfs=[Beith, Quert, Muir, Coll, Duir, Gus, Gort, Nion]] {"F2012_2": { "title": "Snow White & the Huntsman", "dwarfs": [ "Beith", "Quert", "Muir", "Coll", "Duir", "Gus", "Gort", "Nion" ], "year": 2012, "medium": "film" }}
Google gson Library
This uses Gson, a library to convert JSON to Java objects and vice-versa. <lang NetRexx>/* NetRexx */ options replace format comments java crossref symbols nobinary
import com.google.gson. import java.util.List
/**
* Using google-gson library * * @see https://code.google.com/p/google-gson/ */
class RJson02 public
properties private constant JSON_DWARFS = - '{\n' - ' "title" : "Snow White and the Seven Dwarfs",\n' - ' "year" : 1937,\n' - ' "medium": "film",\n' - ' "dwarfs": [ "Grumpy", "Happy", "Sleepy", "Bashful", "Sneezy", "Dopey", "Doc" ]\n' - '}'
/** * A bean that looks like the following JSON
*
* { * "title" : "Snow White & the Huntsman", * "year" : 2012, * "medium" : "film", * "dwarfs" : [ "Beith", "Quert", "Muir", "Coll", "Duir", "Gus", "Gort", "Nion" ] * } *
*/ SAMPLE_BEAN = RJSON02.DwarfBean( - /*"F2012_2",*/ - "Snow White and the Huntsman", - Long(2012), - "film", - Arrays.asList([String "Beith", "Quert", "Muir", "Coll", "Duir", "Gus", "Gort", "Nion"]) - )
-- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ method main(args = String[]) public static gsonObj = GsonBuilder().setPrettyPrinting().create() jsonBean = RJson02.DwarfBean gsonObj.fromJson(JSON_DWARFS, RJson02.DwarfBean.class) say JSON_DWARFS say jsonBean.toString() say
json = gsonObj.toJson(SAMPLE_BEAN); say json say SAMPLE_BEAN.toString() say
return
-- ============================================================================= class RJson02.DwarfBean public binary
properties indirect title = String year = Long medium = String dwarfs = List
method DwarfBean(title_ = String null, year_ = Long null, medium_ = String null, dwarfs_ = List null) public setTitle(title_) setYear(year_) setMedium(medium_) setDwarfs(dwarfs_) return
method toString public returns String ts = StringBuilder() ts.append(String.format("%s@%08x ", [Object this.getClass().getSimpleName(), Integer(hashCode())])) ts.append('[') ts.append('title='String.valueOf(getTitle())', ') ts.append('year='String.valueOf(getYear())', ') ts.append('medium='String.valueOf(getMedium())', ') ts.append('dwarfs='String.valueOf(getDwarfs())) ts.append(']') return ts.toString()
</lang>
- Output:
{ "title" : "Snow White and the Seven Dwarfs", "year" : 1937, "medium": "film", "dwarfs": [ "Grumpy", "Happy", "Sleepy", "Bashful", "Sneezy", "Dopey", "Doc" ] } DwarfBean@63f5e4b6 [title=Snow White and the Seven Dwarfs, year=1937, medium=film, dwarfs=[Grumpy, Happy, Sleepy, Bashful, Sneezy, Dopey, Doc]] { "title": "Snow White and the Huntsman", "year": 2012, "medium": "film", "dwarfs": [ "Beith", "Quert", "Muir", "Coll", "Duir", "Gus", "Gort", "Nion" ] } DwarfBean@6d63de20 [title=Snow White and the Huntsman, year=2012, medium=film, dwarfs=[Beith, Quert, Muir, Coll, Duir, Gus, Gort, Nion]]
Nim
<lang nim>import json
var data = parseJson("""{ "foo": 1, "bar": [10, "apples"] }""") echo data["foo"] echo data["bar"]
var js = %* [{"name": "John", "age": 30}, {"name": "Susan", "age": 31}] echo js</lang>
- Output:
1 [ 10, "apples"] [ { "name": "John", "age": 30 }, { "name": "Susan", "age": 31 }]
Objeck
<lang objeck> use Struct; use JSON;
bundle Default {
class Json { function : Main(args : String[]) ~ Nil { parser := JSONParser->New("{ \"foo\": 1, \"bar\": [10, \"apples\"] }"); root := parser->Parse(); if(root <> Nil) { root->ToString()->PrintLine(); }; } }
}</lang>
Objective-C
<lang objc>NSString *jsonString = @"{ \"foo\": 1, \"bar\": [10, \"apples\"] }"; id obj = [NSJSONSerialization
JSONObjectWithData: [jsonString dataUsingEncoding: NSUTF8StringEncoding] options: 0 error: NULL];
NSLog(@"%@", obj);
NSDictionary *dict = @{ @"blue": @[@1, @2], @"ocean": @"water"}; NSData *jsonData = [NSJSONSerialization dataWithJSONObject: dict
options: 0 error: NULL];
NSString *jsonString2 = [[NSString alloc] initWithData: jsonData
encoding: NSUTF8StringEncoding];
NSLog(@"%@", jsonString2); </lang>
OCaml
Using json-wheel/json-static libs
<lang ocaml>type json item =
< name "Name": string; kingdom "Kingdom": string; phylum "Phylum": string; class_ "Class": string; order "Order": string; family "Family": string; tribe "Tribe": string >
let str = "
{ \"Name\": \"camel\", \"Kingdom\": \"Animalia\", \"Phylum\": \"Chordata\", \"Class\": \"Mammalia\", \"Order\": \"Artiodactyla\", \"Family\": \"Camelidae\", \"Tribe\": \"Camelini\" }"
let () =
let j = Json_io.json_of_string str in print_endline (Json_io.string_of_json j);</lang>
compile with:
ocamlfind opt -o j.opt j.ml -linkpkg -package json-static -syntax camlp4o
Using yojson lib
<lang ocaml>open Yojson.Basic.Util
let s = " { \"name\": \"John Doe\",
\"pages\": [ { \"id\": 1, \"title\": \"The Art of Flipping Coins\", \"url\": \"http://example.com/398eb027/1\" }, { \"id\": 2, \"deleted\": true }, { \"id\": 3, \"title\": \"Artichoke Salad\", \"url\": \"http://example.com/398eb027/3\" }, { \"id\": 4, \"title\": \"Flying Bananas\", \"url\": \"http://example.com/398eb027/4\" } ]
}"
let extract_titles json =
[json] |> filter_member "pages" |> flatten |> filter_member "title" |> filter_string
let () =
let json = Yojson.Basic.from_string s in List.iter print_endline (extract_titles json)</lang>
Compile and run:
$ ocamlfind ocamlopt -o filtering filtering.ml -package yojson -linkpkg $ ./filtering The Art of Flipping Coins Artichoke Salad Flying Bananas
Oforth
In oforth, Json objects are builtin and can be interpreted natively
A String can be converted to Json object using #perform
A Json object can be converted to a string using #asString
<lang Oforth>>{"parents":["Otmar Gutmann", "Silvio Mazzola"], "name":"Pingu", "born":1986} .s [1] (Json) {"parents" : ["Otmar Gutmann", "Silvio Mazzola"], "name" : "Pingu", "born" : 1986 } ok >asString .s [1] (String) {"parents" : ["Otmar Gutmann", "Silvio Mazzola"], "name" : "Pingu", "born" :1986 } ok >perform .s [1] (Json) {"parents" : ["Otmar Gutmann", "Silvio Mazzola"], "name" : "Pingu", "born" : 1986 } ok ></lang>
Ol
Ol comes with library that provides JSON parsing and forming.
<lang scheme> (import (file json))
(define o (read-json-string "
{ 'name': 'John', 'full name': 'John Smith', 'age': 42, 'weight': 156.18, 'married': false, 'address': { 'street': '21 2nd Street', 'city': 'New York', }, 'additional staff': [ { 'type': 'numbers', 'numbers': [ 1, -2, 0.75, -4.567 ] }, { 'type': 'phone', 'number': '222 222-2222' } ] }"))
(print o)
(print-json-with display o) (print-json-with display {
'name "John" '|full name| "John Smith" 'age 42 'married #false 'address { 'street "21 2nd Street" 'city "New York" } '|additional staff| [ { 'type "numbers" 'numbers [ 1 2 3 4 ] } { 'type "phone" 'number "222 222-2222" } ]
</lang>
- Output:
#ff((name . John) (|full name| . John Smith) (age . 42) (married . #false) (address . #ff((street . 21 2nd Street) (city . New York))) (|additional staff| . #(#ff((type . numbers) (numbers . #(1 2 3 4))) #ff((type . phone) (number . 222 222-2222))))) {"name":"John","|full name|":"John Smith","age":42,"married":false,"address":{"street":"21 2nd Street","city":"New York"},"|additional staff|":[{"type":"numbers","numbers":[1,2,3,4]},{"type":"phone","number":"222 222-2222"}]} {"name":"John","|full name|":"John Smith","age":42,"married":false,"address":{"street":"21 2nd Street","city":"New York"},"|additional staff|":[{"type":"numbers","numbers":[1,2,3,4]},{"type":"phone","number":"222 222-2222"}]}
OpenEdge/Progress
The WRITE-JSON and READ-JSON methods were introduced in Progress OpenEdge 10.2B. <lang progress>/* using a longchar to read and write to, can also be file, memptr, stream */ DEFINE VARIABLE lcjson AS LONGCHAR NO-UNDO.
/* temp-table defines object, can also be dataset */ DEFINE TEMP-TABLE example
FIELD blue AS INTEGER EXTENT 2 FIELD ocean AS CHARACTER .
CREATE example. ASSIGN
example.blue [1] = 1 example.blue [2] = 2 example.ocean = "water" .
/* write-json to put result in lcjson, true indicates formatted */ TEMP-TABLE example:DEFAULT-BUFFER-HANDLE:WRITE-JSON( "LONGCHAR", lcjson, TRUE ).
/* display result */ MESSAGE
STRING( lcjson )
VIEW-AS ALERT-BOX.
/* empty results */ EMPTY TEMP-TABLE example.
/* read-json to get result from lcjson */ TEMP-TABLE example:DEFAULT-BUFFER-HANDLE:READ-JSON( "LONGCHAR", lcjson ).
FIND example. /* display results */ MESSAGE
example.blue [1] example.blue [2] SKIP example.ocean
VIEW-AS ALERT-BOX.</lang>
- Output:
write-json
--------------------------- Message --------------------------- {"example": [ { "blue": [ 1, 2 ], "ocean": "water" } ]} --------------------------- OK ---------------------------
- Output:
read-json
--------------------------- Message --------------------------- 1 2 water --------------------------- OK ---------------------------
Oz
Using the google.com/oz-code JSON library: <lang oz>declare
[JSON] = {Module.link ['JSON.ozf']}
{System.show {JSON.decode "{ \"foo\": 1, \"bar\": [10, \"apples\"] }"}}
Sample = object(blue:array(1 2) ocean:"water") {System.showInfo {JSON.encode Sample}}</lang>
- Output:
object(bar:array(10 [97 112 112 108 101 115]) foo:1) {"blue":[1,2],"ocean":"water"}
Perl
<lang perl>use JSON;
my $data = decode_json('{ "foo": 1, "bar": [10, "apples"] }');
my $sample = { blue => [1,2], ocean => "water" }; my $json_string = encode_json($sample);</lang>
Phix
The distribution now contains a simple json module <lang Phix>-- -- demo\rosetta\JSON.exw -- ===================== -- include builtins/json.e
puts(1,"roundtrip (10 examples):\n") sequence json_strings = {`{"this":"that","age":{"this":"that","age":29}}`,
`1`, `"hello"`, `null`, `[12]`, `[null,12]`, `[]`, `{"this":"that","age":29}`, `{}`, `[null,[null,12]]`}
for i=1 to length(json_strings) do
string s = json_strings[i] puts(1,s&"\n") object json_object = parse_json(s) puts(1,print_json("",json_object,true)&"\n") if not equal(print_json("",json_object,true),s) then ?9/0 end if
end for</lang>
- Output:
roundtrip (10 examples): {"this":"that","age":{"this":"that","age":29}} {"this":"that","age":{"this":"that","age":29}} 1 1 "hello" "hello" null null [12] [12] [null,12] [null,12] [] [] {"this":"that","age":29} {"this":"that","age":29} {} {} [null,[null,12]] [null,[null,12]]
PHP
<lang php><?php $data = json_decode('{ "foo": 1, "bar": [10, "apples"] }'); // dictionaries will be returned as objects $data2 = json_decode('{ "foo": 1, "bar": [10, "apples"] }', true); // dictionaries will be returned as arrays
$sample = array( "blue" => array(1,2), "ocean" => "water" ); $json_string = json_encode($sample); ?></lang>
PicoLisp
PicoLisp has no JSON library, but it is easy enough to write one. The following supports only fixpoint numbers (no floating point, as it doesn't exist in PicoLisp). Arrays and objects are both mapped to lists. <lang PicoLisp>(de checkJson (X Item)
(unless (= X Item) (quit "Bad JSON" Item) ) )
(de readJson ()
(case (read "_") ("{" (make (for (X (readJson) (not (= "}" X)) (readJson)) (checkJson ":" (readJson)) (link (cons X (readJson))) (T (= "}" (setq X (readJson)))) (checkJson "," X) ) ) ) ("[" (make (link T) # Array marker (for (X (readJson) (not (= "]" X)) (readJson)) (link X) (T (= "]" (setq X (readJson)))) (checkJson "," X) ) ) ) (T (let X @ (cond ((pair X) (pack X)) ((and (= "-" X) (format (peek))) (- (read)) ) (T X) ) ) ) ) )
(de printJson (Item) # For simplicity, without indentation
(cond ((atom Item) (if Item (print @) (prin "{}"))) ((=T (car Item)) (prin "[") (map '((X) (printJson (car X)) (and (cdr X) (prin ", ")) ) (cdr Item) ) (prin "]") ) (T (prin "{") (map '((X) (print (caar X)) (prin ": ") (printJson (cdar X)) (and (cdr X) (prin ", ")) ) Item ) (prin "}") ) ) )</lang>
This reads/prints JSON from/to files, pipes, sockets etc. To read from a string, a pipe can be used:
: (pipe (prinl "{ \"foo\": 1, \"bar\": [10, \"apples\"] }") (readJson) ) -> (("foo" . 1) ("bar" T 10 "apples")) : (printJson (quote ("name" . "Smith") ("age" . 25) ("address" ("street" . "21 2nd Street") ("city" . "New York") ("state" . "NY") ("zip" . "10021") ) ("phone" T "212 555-1234" "646 555-4567") ) ) {"name": "Smith", "age": 25, ... {"street": ... "phone": ["212 555-1234", ...
Pike
<lang pike>int main() { // Decoding string json = "{\"cake\":[\"desu\",1,2.3],\"foo\":1}"; write("%O\n", Standards.JSON.decode(json));
// Encoding mapping m = ([ "foo": ({ 1, 2, 3 }), "bar": "hello" ]);
write("%s\n", Standards.JSON.encode(m)); }</lang>
([ /* 2 elements */ "cake": ({ /* 3 elements */ "desu", 1, 2.3 }), "foo": 1 ]) {"foo":[1,2,3],"bar":"hello"}
PowerShell
<lang PowerShell>
- JSON input is being stored in ordered hashtable.
- Ordered hashtable is available in PowerShell v3 and higher.
[ordered]@{ "foo"= 1; "bar"= 10, "apples" } | ConvertTo-Json
- ConvertFrom-Json converts a JSON-formatted string to a custom object.
- If you use the Invoke-RestMethod cmdlet there is not need for the ConvertFrom-Json cmdlet
Invoke-WebRequest -Uri "http://date.jsontest.com" | ConvertFrom-Json </lang>
- Output:
<lang PowerShell> {
"foo": 1, "bar": [ 10, "apples" ]
}
time milliseconds_since_epoch date
------------------------ ----
12:25:25 PM 1414326325923 10-26-2014 </lang>
Prolog
Using SWI-Prolog 7's library(http/json), and the new dict datatype, there is nearly transparent handling of JSON objects. All of the serialization and parsing in the following code is accomplished with two predicates. The rest of the code is for the sake of example.
<lang Prolog>:- use_module([ library(http/json),
library(func) ]).
test_json('{"widget": { "debug": "on", "window": { "title": "Sample Konfabulator Widget", "name": "main_window", "width": 500, "height": 500 }, "image": { "src": "Images/Sun.png", "name": "sun1", "hOffset": 250, "vOffset": 250, "alignment": "center" }, "text": { "data": "Click Here", "size": 36, "style": "bold", "name": "text1", "hOffset": 250, "vOffset": 100, "alignment": "center", "onMouseUp": "sun1.opacity = (sun1.opacity / 100) * 90;" }}}').
reading_JSON_term :-
atom_json_dict(test_json(~), Dict, []), %% This accomplishes reading in the JSON data writeln( 'JSON as Prolog dict: ~w~n' $ Dict), writeln( 'Access field "widget.text.data": ~s~n' $ Dict.widget.text.data), writeln( 'Alter field "widget": ~w~n' $ Dict.put(widget, "Altered")).
searalize_a_JSON_term :-
Dict = _{book:_{title:"To Mock a Mocking Bird", author:_{first_name:"Ramond", last_name:"Smullyan"}, publisher:"Alfred A. Knopf", year:1985 }}, json_write(current_output, Dict). %% This accomplishes serializing the JSON object.</lang>
- Output:
from these two example predicates
<lang Prolog>?- reading_JSON_term. JSON as Prolog dict: _G5217{widget:_G5207{debug:on,image:_G5123{alignment:center,hOffset:250,name:sun1,src:Images/Sun.png,vOffset:250},text:_G5189{alignment:center,data:Click Here,hOffset:250,name:text1,onMouseUp:sun1.opacity = (sun1.opacity / 100) * 90;,size:36,style:bold,vOffset:100},window:_G5077{height:500,name:main_window,title:Sample Konfabulator Widget,width:500}}}
Access field "widget.text.data": Click Here
Alter field "widget": _G5217{widget:Altered}
true.
?- searalize_a_JSON_term. {
"book": { "author": {"first_name":"Ramond", "last_name":"Smullyan"}, "publisher":"Alfred A. Knopf", "title":"To Mock a Mocking Bird", "year":1985 }
} true.</lang>
PureBasic
<lang purebasic>OpenConsole() If CreateJSON(1)
PB_Team_Members=SetJSONObject(JSONValue(1)) SetJSONString(AddJSONMember(PB_Team_Members,"PB_Team_Member_1"),"Frederic Laboureur") SetJSONString(AddJSONMember(PB_Team_Members,"PB_Team_Member_2"),"Andre Beer") SetJSONString(AddJSONMember(PB_Team_Members,"PB_Team_Member_3"),"Timo Harter")
EndIf
If CreateJSON(2)
Former_Team_Members=SetJSONArray(JSONValue(2)) SetJSONString(AddJSONElement(Former_Team_Members),"Richard Andersson") SetJSONString(AddJSONElement(Former_Team_Members),"Benny Sels") SetJSONString(AddJSONElement(Former_Team_Members),"Danilo Krahn")
EndIf
PrintN("PureBasic - Team Members:") PrintN(ComposeJSON(1,#PB_JSON_PrettyPrint)+#CRLF$) PrintN("PureBasic - Former Team Members:") PrintN(ComposeJSON(2,#PB_JSON_PrettyPrint)+#CRLF$)
- DL=Chr(34)
PB_Special_thanks$="[ " +#DL+"Gary Willoughby"+#DL+", " +#DL+"Mark James"+#DL+", " +#DL+"Neil Hodgson"+#DL+" ]" NewList otherpersons.s()
If ParseJSON(3,PB_Special_thanks$)
ExtractJSONList(JSONValue(3),otherpersons()) PrintN("Pure Basic - and others:") ForEach otherpersons() : PrintN(otherpersons()) : Next
Else
PrintN(JSONErrorMessage() + " : " + Str(JSONErrorPosition())) PrintN(Left(PB_Special_thanks$,JSONErrorPosition())) PrintN(Mid(PB_Special_thanks$,JSONErrorPosition()+1))
EndIf Input()</lang>
- Output:
PureBasic - Team Members: { "PB_Team_Member_1": "Frederic Laboureur", "PB_Team_Member_2": "Andre Beer", "PB_Team_Member_3": "Timo Harter" } PureBasic - Former Team Members: [ "Richard Andersson", "Benny Sels", "Danilo Krahn" ] Pure Basic - and others: Gary Willoughby Mark James Neil Hodgson
Python
<lang Python>>>> import json >>> data = json.loads('{ "foo": 1, "bar": [10, "apples"] }') >>> sample = { "blue": [1,2], "ocean": "water" } >>> json_string = json.dumps(sample) >>> json_string '{"blue": [1, 2], "ocean": "water"}' >>> sample {'blue': [1, 2], 'ocean': 'water'} >>> data {'foo': 1, 'bar': [10, 'apples']}</lang>
Because most of JSON is valid Python syntax (except "true", "false", and "null", and a few obscure escape sequences), it is also possible (but not recommended) to parse JSON using eval(): <lang python>>>> true = True; false = False; null = None >>> data = eval('{ "foo": 1, "bar": [10, "apples"] }') >>> data {'foo': 1, 'bar': [10, 'apples']}</lang>
R
<lang R>library(rjson) data <- fromJSON('{ "foo": 1, "bar": [10, "apples"] }') data</lang>
data $foo [1] 1 $bar $bar[[1]] [1] 10 $bar[[2]] [1] "apples"
<lang R>cat(toJSON(data))</lang>
{"foo":1,"bar":[10,"apples"]}
Racket
<lang Racket>
- lang racket
(require json)
(string->jsexpr
"{\"foo\":[1,2,3],\"bar\":null,\"baz\":\"blah\"}")
(write-json '(1 2 "three" #hash((x . 1) (y . 2) (z . 3)))) </lang>
Raku
(formerly Perl 6)
Using JSON::Tiny
<lang perl6>use JSON::Tiny;
my $data = from-json('{ "foo": 1, "bar": [10, "apples"] }');
my $sample = { blue => [1,2], ocean => "water" }; my $json_string = to-json($sample);</lang>
REBOL
Using json.org/json.r
<lang rebol>json-str: {{"menu": {
"id": "file", "string": "File:", "number": -3, "boolean": true, "boolean2": false, "null": null, "array": [1, 0.13, null, true, false, "\t\r\n"], "empty-string": "" }
}}
res: json-to-rebol json-str js: rebol-to-json res </lang>
json-to-rebol Result:
make object! [ menu: make object! [ id: "file" string: "File:" number: -3 boolean: true boolean2: false null: none array: [1 0.13 none true false "^-^M^/"] empty-string: "" ] ]
rebol-to-json Result:
{ "menu": { "id": "file", "string": "File:", "number": -3, "boolean": true, "boolean2": false, "null": null, "array": [1, 0.13, null, true, false, "\t\r\n"], "empty-string": "" } }
Ruby
<lang ruby>require 'json'
ruby_obj = JSON.parse('{"blue": [1, 2], "ocean": "water"}') puts ruby_obj
ruby_obj["ocean"] = { "water" => ["fishy", "salty"] } puts JSON.generate(ruby_obj) puts JSON.pretty_generate(ruby_obj)</lang>
- Output:
{"blue"=>[1, 2], "ocean"=>"water"} {"blue":[1,2],"ocean":{"water":["fishy","salty"]}} { "blue": [ 1, 2 ], "ocean": { "water": [ "fishy", "salty" ] } }
Rust
Serializing and deserializing JSON in Rust is done by libraries.
<lang toml>[dependencies] serde = { version = "1.0", features = ["derive"] } serde_json = "1.0"</lang>
Serde is a general serialization/deserialization library. Serde-JSON implements JSON serialization for Serde.
Using said library is quite straight forward, one simply derives Serialize
/Deserialize
onto the types they want to convert into and from JSON strings.
<lang rust>use serde::{Serialize, Deserialize};
- [derive(Serialize, Deserialize, Debug)]
struct Point {
x: i32, y: i32,
}</lang>
Said type could then be used as such:
<lang rust>fn main() {
let point = Point { x: 1, y: 2 };
let serialized = serde_json::to_string(&point).unwrap(); let deserialized: Point = serde_json::from_str(&serialized).unwrap();
println!("serialized = {}", serialized); println!("deserialized = {:?}", deserialized);
}</lang>
The result of which is type-checked JSON (where extra entries get ignored), without need of a key-value container.
- Output:
serialized = {"x":1,"y":2} deserialized = Point { x: 1, y: 2 }
It also handles more Rust specific types like enums, tuples, struct tuples, and zero-sized types.
<lang rust>#[derive(Serialize, Deserialize)] struct W { a: i32, b: i32 } // => { "a": 0, "b": 0 }
- [derive(Serialize, Deserialize)]
struct X(i32, i32); // => [0, 0]
- [derive(Serialize, Deserialize)]
struct Y(i32); // => 0
- [derive(Serialize, Deserialize)]
struct Z; // => null
- [derive(Serialize, Deserialize)]
enum E {
W { a: i32, b: i32 }, // => { "W": { "a": 0, "b": 0 } } X(i32, i32), // => { "X": [0, 0] } Y(i32), // => { "Y": 0 } Z, // => { "Z" }
}</lang>
The traits are also implemented for HashMap
and Vec
which can be used as conventional objects/arrays, on top of macros and serde_json::Value
to handle all other potentially weird edge cases.
<lang rust>use std::collections::HashMap; use serde_json::Value;
- [derive(Serialize, Deserialize)]
struct Data {
points: Vec<Points>,
#[serde(flatten)] metadata: HashMap<String, Value>,
}</lang>
In this example metadata
would simply capture all other additional entries, for example:
<lang rust>fn main() {
let data = { let mut metadata = HashMap::new(); metadata.insert("triangle".to_string(), Value::Number(3.into())); metadata.insert("square".to_string(), Value::Bool(false)); Data { points: vec![Point { x: 1, y: 2 }, Point { x: 15, y: 32 }], metadata, } };
let serialized = serde_json::to_string(&data).unwrap(); let deserialized: Data = serde_json::from_str(&serialized).unwrap();
println!("serialized = {}", serialized); println!("deserialized = {:?}", deserialized);
}</lang>
- Output:
serialized = {"points":[{"x":1,"y":2},{"x":15,"y":32}],"square":false,"triangle":3} deserialized = Data { points: [Point { x: 1, y: 2 }, Point { x: 15, y: 32 }], metadata: {"triangle": Number(3), "square": Bool(false)} }
Scala
Using the builtin parsing lib (debatably slower than third-party libs such as lift-json from Liftweb).
<lang scala>scala> import scala.util.parsing.json.{JSON, JSONObject} import scala.util.parsing.json.{JSON, JSONObject}
scala> JSON.parseFull("""{"foo": "bar"}""") res0: Option[Any] = Some(Map(foo -> bar))
scala> JSONObject(Map("foo" -> "bar")).toString() res1: String = {"foo" : "bar"} </lang>
Scheme
Using the json egg: <lang scheme> (use json) (define object-example
(with-input-from-string "{\"foo\": \"bar\", \"baz\": [1, 2, 3]}" json-read))
(pp object-example)
- this prints #(("foo" . "bar") ("baz" 1 2 3))
(json-write #([foo . bar]
[baz 1 2 3] [qux . #((rosetta . code))]))
- this writes the following
- {"foo"
- "bar", "baz": [1, 2, 3], "qux": {"foo": "bar"}}
</lang>
SenseTalk
<lang SenseTalk>set jsonString to <<{"foo": 10, "bar": [1, 2, 3]}>> put JSONValue(jsonString)
set dataObject to (string_value: "lorem ipsum", int_value: 314, array_value: (2, 4, 6)) put JSONFormat(dataObject)</lang>
Sidef
<lang ruby>var json = require('JSON').new; var data = json.decode('{"blue": [1, 2], "ocean": "water"}'); say data; data{:ocean} = Hash.new(water => %w[fishy salty]); say json.encode(data);</lang>
- Output:
Hash.new( 'blue' => [1, 2], 'ocean' => 'water' ) {"blue":[1,2],"ocean":{"water":["fishy","salty"]}}
Smalltalk
Use the NeoJSON library: NeoJSON <lang smalltalk> NeoJSONReader fromString: '{ "foo": 1, "bar": [10, "apples"] }'. </lang>
- Output:
a Dictionary('bar'->#(10 'apples') 'foo'->1 )
Standard ML
Works on Unix/Linux/BSD with jq (github.com/stedolan/jq/ ) installed. Data storage in strings, so floating point numbers can be written back as received, in a recursive polymorphic structure, which can also be used to store the data as SML-types. (Without Jq on the system or on Microsoft systems, delete the Validate function and its call, and the code can be used for valid JSON-strings without any white space outside strings (only).) <lang Standard ML> val Validate = fn jsonstring => let
val Valid = fn jsonstring => let val json = String.translate (fn #"\"" => "\\\""|n=>str n ) jsonstring ; val textlength = (String.size json ) + 50 ; val app = " jq -c '.' " val fname = "/tmp/jsonval" ^ (String.extract (Time.toString (Posix.ProcEnv.time()),7,NONE) ); val shellCommand = "echo \"" ^ json ^ "\" | " ^ app val me = ( Posix.FileSys.mkfifo (fname, Posix.FileSys.S.flags [ Posix.FileSys.S.irusr,Posix.FileSys.S.iwusr ] ) ; Posix.Process.fork () ) ; in if (Option.isSome me) then let val fin =TextIO.openIn fname in ( Posix.Process.sleep (Time.fromReal 0.1) ; TextIO.inputN (fin,textlength) before
(TextIO.closeIn fin ; OS.FileSys.remove fname) )
end else ( OS.Process.system ( shellCommand ^ " > " ^fname ^ " 2>&1 ") ; (* remove fmt and validate *) "done\n" before OS.Process.exit OS.Process.success ) end val result = Valid jsonstring
in
if String.isPrefix "{" result then result else "JSON error\n"
end;
datatype ('a,'b) element = elem of 'a * 'b | markerb of int ; (* < internal structure v *) datatype 'a content = value of 'a | block of ('a,'a content) element list | arr of 'a content list |marker of int ;
exception Dtype of string ; val unarr = fn arr lst => lst | _ => (raise Dtype "unarr" ; []) ; val unblock = fn block lst => lst | _ => (raise Dtype "unblock" ; []) ;
(* --- example loop to apply a function 'dothis', which returns type jvals, to the structure ---- *)
datatype jvals = St of string | It of IntInf.int | Rl of real | Bl of bool ; (* returned type by 'dothis' *)
val rec gothruAndDo = fn dothis => fn storedObject =>
let val walk = fn elem ( n, value v) => elem (dothis n , value (dothis v) ) | elem ( n, block v) => elem (dothis n , block ( (gothruAndDo dothis) (rev (tl (rev v)))) ) | elem ( n, arr v) => elem (dothis n , arr ( List.map (block o (gothruAndDo dothis) o unblock) (rev (tl (rev v))) ) )
| _ => elem (St "", value (It (IntInf.fromInt ~1)))
in List.map walk storedObject end;
(* ------------------------------------ end of loop example ------------------------------------ *)
local
exception Dtype of string ; val markbToInt = fn markerb NrChars => NrChars | _ => (raise Dtype "markerb!" ; ~1) ; val markToInt = fn marker NrChars => NrChars | _ => (raise Dtype "marker!" ; ~1) ;
fun readarr rtag rc = fn #"]"::S => [ marker (List.length S) ] (* process array *)
| S => let val tmp = (rtag rc ("",S)) in (block tmp) :: ( readarr rtag rc ( List.drop (S,(List.length S) - markbToInt ( hd (rev tmp))) )) end ;
val rec readNaVa = fn rc : string * char list -> string content * char list => fn
("",[]) => []
| (sr,[]) => [ elem (sr, value "") ] | (sr,#":":: #"["::S) =>
let val tmp = arr (readarr readNaVa rc S) in (* field is array *) ( elem (sr, tmp )) :: (readNaVa rc ("" , List.drop (S,(List.length S) - (markToInt (hd (rev(unarr tmp)))) ) ))
end | (sr, #":":: #"{"::S) =>
let val tmp = readNaVa rc ("",S ) in (* field is object *) ( elem (sr, block tmp)) :: (readNaVa rc ("" , List.drop (S,(List.length S) -(markbToInt ( hd (rev tmp)))) )) end
| (sr,#"}":: #","::S) => [ markerb (List.length S) ] | (sr,#"}"::S) => [ markerb (List.length S) ] | (sr,#":"::S) =>
let val tmp = rc ("",S) in (* field is basic *) elem ( sr, #1 tmp) :: (readNaVa rc ("", #2 tmp ) ) end
| (sr,#","::S) => readNaVa rc (sr , S) | (sr,#"{"::a::S) => readNaVa rc (sr^(str a) , S) | (sr,a::S) => readNaVa rc (sr^(str a) , S) ; (* name field *)
val rec readcontent = fn (sc,a::[]) => (value ( sc^(str a) ),[])
| (sc,#","::t) => (value sc , t) | (sc, #"}"::t) => (value sc , #"}"::t) | (sc, #"]"::t) => (value sc , #"]"::t) | (sc, a::t) => readcontent( ( sc^(str a) ),t) ;
val putall = fn input =>
let val rec put = fn [] => "" | (elem h)::t => (#1 h) ^ ":" ^ ( ( fn value x=> x | block x => "{" ^ (put x )
| arr x => "[" ^ String.concat (( List.map (fn x=> "{"^( (put o unblock) x)^"," ) (rev (tl (rev x))))) ^ "]" ) (#2 h)) ^ "," ^ (put t)
| (markerb h)::t => "}" in "{" ^ (put input) end;
val commas = fn tok => fn S =>
( Substring.concatWith (str tok) ( List.map (Substring.dropr (fn x=> x= #"," )) (Substring.tokens (fn x=> x= tok ) (Substring.full S) )) ) ^ (if tok = #"}" then str tok else "" )
in
val storeJsString = fn input => readNaVa readcontent ("" , String.explode ( Validate input ) )
val writeJS = fn storedStruct => ( ( ( commas #"}" ) o ( commas #"]" ) o putall ) storedStruct )
end ; </lang>Example <lang Standard ML> val testString="{\"firstName\":\"John\",\"lastName\":\"Smith\",\"age\":25,\"address\":{\"streetAddress\":\"21 2nd Street\",\"city\":\"New York\",\"state\":\"NY\",\"postalCode\":\"10021\"},\"phoneNumber\":[{\"type\":\"home\",\"numbers\":[{\"o\":\"212 555-1234\",\"h\":\"119 323-1234\"}]},{\"type\":\"fax\",\"number\":\"646 555-4567\"}]}" ;
testString = (writeJS o storeJsString) testString ; val it = true : bool (* because the test string was unformatted *)
val toMlVal = fn input =>
case String.isPrefix "\"" input of true => St (String.substring (input,1,(String.size input)-2) ) | _ => case IntInf.fromString input of SOME n => It n | NONE => case Real.fromString input of
SOME x => Rl x
| NONE => case Bool.fromString input of
SOME b => Bl b
| NONE => St "" ;
val toMlVal = fn: string -> jvals
List.nth (gothruAndDo toMlVal (storeJsString testString ) ,3);
val it =
elem (St "address", block [elem (St "streetAddress", value (St "21 2nd Street")), elem (St "city", value (St "New York")), elem (St "state", value (St "NY")), elem (St "postalCode", value (St "10021"))]): (jvals, jvals content) element
</lang>
Swift
<lang Swift>import Foundation
let jsonString = "{ \"foo\": 1, \"bar\": [10, \"apples\"] }" if let jsonData = jsonString.data(using: .utf8) { if let jsonObject: Any = try? JSONSerialization.jsonObject(with: jsonData, options: .allowFragments) { print("Dictionary: \(jsonObject)") } }
let obj = [ "foo": [1, "Orange"], "bar": 1 ] as [String : Any]
if let objData = try? JSONSerialization.data(withJSONObject: obj, options: .prettyPrinted) { if let jsonString2 = String(data: objData, encoding: .utf8) { print("JSON: \(jsonString2)") } }</lang>
- Output:
Dictionary: { bar = ( 10, apples ); foo = 1; } JSON: { "foo" : [ 1, "Orange" ], "bar" : 1 }
Tailspin
A JSON parser and printer can fairly easily be created <lang tailspin> // Not all JSON object member keys can be represented, a fallback would need to be implemented // Currently Tailspin only supports integers so for now we leave numbers as strings, as we do for true, false and null
templates hexToInt
templates hexDigit <='0'> 0! <='1'> 1! <='2'> 2! <='3'> 3! <='4'> 4! <='5'> 5! <='6'> 6! <='7'> 7! <='8'> 8! <='9'> 9! <'[Aa]'> 10! <'[Bb]'> 11! <'[Cc]'> 12! <'[Dd]'> 13! <'[Ee]'> 14! <'[Ff]'> 15! end hexDigit @: 0; $... -> hexDigit -> @: $@ * 16 + $; $@ !
end hexToInt
composer jsonParser
<value> rule value: (<WS>?) <string|number|object|array|true|false|null> (<WS>?)
rule string: (<='"'>) <chars> (<='"'>) rule chars: [ <quote|backslash|slash|backspace|formfeed|linefeed|return|tab|unicode|'[^"]'>* ] -> '$...;' rule quote: <='\"'> -> '"' rule backslash: <='\\'> -> '\' rule slash: <='\/'> -> '/' rule backspace: <='\b'> -> '$#8;' rule formfeed: <='\f'> -> '$#12;' rule linefeed: <='\n'> -> '$#10;' rule return: <='\r'> -> '$#13;' rule tab: <='\t'> -> '$#9;' rule unicode: (<='\u'>) <'[0-9A-Fa-f]{4}'> -> hexToInt -> '$#$;'
rule number: <'-?(0|[1-9][0-9]*)(\.[0-9]+)?((e|E)(\+|-)?[0-9]+)?'> // TODO: represent this other than string
rule object: (<='{'> <WS>?) { <keyValues>? } (<='}'>) rule keyValues: <keyValue> <followingKeyValue>* rule keyValue: <string>: (<WS>? <=':'>) <value> rule followingKeyValue: (<=','> <WS>?) <keyValue>
rule array: (<='['>) [ <arrayValues>? ] (<=']'>) rule arrayValues: <value> <followingArrayValue>* rule followingArrayValue: (<=','>) <value>
rule true: <='true'> // TODO: represent this other than string rule false: <='false'> // TODO: represent this other than string rule null: <='null'> // TODO: represent this other than string
end jsonParser
templates printJson
templates printKeyValue '$::key -> printJson;: $::value -> printJson;' ! end printKeyValue templates encodeChars <='"'> '\"' ! <='\'> '\\' ! <='/'> '\/' ! <='$#8;'> '\b' ! <='$#12;'> '\f' ! <='$#10;'> '\n' ! <='$#13;'> '\r' ! <='$#9;'> '\t' ! <> $ ! end encodeChars $ -> # when <[]> do '[$(1) -> printJson;$(2..last)... -> ', $ -> printJson;';]' ! when <{}> do [ $... ] -> '{$(1) -> printKeyValue;$(2..last)... -> ', $ -> printKeyValue;';}' ! when <..0|0..> do '$;'! when <'.*'> do [ $... -> encodeChars ] -> '"$...;"' ! otherwise 'WTF!' ! // Other types do not yet exist in Tailspin
end printJson
'{ "foo": 1, "bar": [10, "apples"] }' -> jsonParser -> '$.bar(2); ' -> !OUT::write
{ blue: [1,2], ocean: 'water' } -> printJson -> '$; ' -> !OUT::write </lang>
- Output:
apples {"blue": [1, 2], "ocean": "water"}
Tcl
For parsing JSON,
provides the capability (see the Tcler's Wiki page on it for more discussion):
<lang tcl>package require json set sample {{ "foo": 1, "bar": [10, "apples"] }}
set parsed [json::json2dict $sample] puts $parsed</lang>
- Output:
foo 1 bar {10 apples}
However, that package is very weak in its generation of JSON because Tcl's official type system is substantially different to that envisaged by JSON. It's possible to work around this though the use of Tcl 8.6, as this next example shows:
<lang tcl>package require Tcl 8.6 package require json::write
proc tcl2json value {
# Guess the type of the value; deep *UNSUPPORTED* magic! regexp {^value is a (.*?) with a refcount} \
[::tcl::unsupported::representation $value] -> type
switch $type {
string { return [json::write string $value] } dict { return [json::write object {*}[ dict map {k v} $value {tcl2json $v}]] } list { return [json::write array {*}[lmap v $value {tcl2json $v}]] } int - double { return [expr {$value}] } booleanString { return [expr {$value ? "true" : "false"}] } default { # Some other type; do some guessing... if {$value eq "null"} { # Tcl has *no* null value at all; empty strings are semantically # different and absent variables aren't values. So cheat! return $value } elseif {[string is integer -strict $value]} { return [expr {$value}] } elseif {[string is double -strict $value]} { return [expr {$value}] } elseif {[string is boolean -strict $value]} { return [expr {$value ? "true" : "false"}] } return [json::write string $value] }
}
}</lang>
Sample code (note that the value is built with dict create
and list
so that there is some auxiliary type hints available, which the above procedure can read):
<lang tcl>set d [dict create blue [list 1 2] ocean water]
puts [tcl2json $d]</lang>
- Output:
{ "blue" : [1,2], "ocean" : "water" }
Note that this is capable of correctly handling the round-trip of values parsed from the json
package described above.
TXR
Parsing
The following implements the parsing half of the task. It is a parser closely based on the JSON grammar [[2]].
It is implemented with recursive horizontal pattern matching functions, and so basically the definition resembles a grammar. Horizontal functions are a new feature in TXR, and basically allow the language to easily specify LL grammars with indefinite lookahead, not restricted to regular languages (thanks to TXR's backtracking). The numerous occurences of @\ in the code are line continuations. Horizontal functions must be written on one logical line. @\ eats the whitespace at the start of the next physical line, to allow indentation.
The parser translates to a nested list structure in which the types are labeled with the strings "O", "A", "N", "S" and "K". (Object, array, number, string, and keyword).
The largest grammar rule handles JSON string literals. The strategy is to generate a HTML string and then filter from HTML using the :from_html
filter in TXR. For instance \uABCD is translated to ꯍ
and then the filter will produce the proper Unicode character. Similarly \" is translated to "
and \n is translated to
etc.
A little liberty is taken: the useless commas in JSON are treated as optional.
Superfluous terminating commas (not generated by the JSON grammar but accepted by some other parsers) are not allowed by this parser.
<lang txr>@(define value (v))@\
@(cases)@\ @(string v)@(or)@(num v)@(or)@(object v)@(or)@\ @(keyword v)@(or)@(array v)@\ @(end)@\
@(end) @(define ws)@/[\n\t ]*/@(end) @(define string (g))@\
@(local s hex)@\ @(ws)@\ "@(coll :gap 0 :vars (s))@\ @(cases)@\ \"@(bind s """)@(or)@\ \\@(bind s "\\\\")@(or)@\ \/@(bind s "\\/")@(or)@\ \b@(bind s "")@(or)@\ \f@(bind s "")@(or)@\ \n@(bind s " ")@(or)@\ \r@(bind s " ")@(or)@\ \t@(bind s " ")@(or)@\ \u@{hex /[0-9A-Fa-f][0-9A-Fa-f][0-9A-Fa-f][0-9A-Fa-f]/}@\ @(bind s `&#x@hex;`)@(or)@\ @{s /[^"\\]*/}@(filter :to_html s)@\ @(end)@\ @(until)"@\ @(end)"@\ @(ws)@\ @(cat s "")@\ @(filter :from_html s)@\ @(bind g ("S" s))@\
@(end) @(define num (v))@\
@(local n)@\ @(ws)@{n /-?[0-9]+((\.[0-9]+)?([Ee][+\-]?[0-9]+)?)?/}@(ws)@\ @(bind v ("N" n))@\
@(end) @(define keyword (v))@\
@(local k)@\ @(all)@(ws)@{k /true|false|null/}@(trailer)@/[^A-Za-z0-9_]/@(end)@(ws)@\ @(bind v ("K" k))@\
@(end) @(define object (v))@\
@(local p e pair)@\ @(ws){@(ws)@(coll :gap 0 :vars (pair))@\ @(string p):@(value e)@/,?/@\ @(bind pair (p e))@\ @(until)}@\ @(end)}@(ws)@\ @(bind v ("O" pair))@\
@(end) @(define array (v))@\
@(local e)@\ @(ws)[@(ws)@(coll :gap 0 :var (e))@(value e)@/,?/@(until)]@(end)]@(ws)@\ @(bind v ("A" e))@\
@(end) @(freeform) @(maybe)@(value v)@(end)@badsyntax</lang>
A few tests. Note, the badsyntax
variable is bound to any trailing portion of the input that does not match the syntax. The call to the parser @(value v)
extracts the longest prefix of the input which is consistent with the syntax, leaving the remainder to be matched into badsyntax
.
<lang bash>$ echo -n '{ "a" : { "b" : 3, "c" : [1,2,3] } }[' | ./txr -l json.txr - (v "O" ((("S" "a") ("O" ((("S" "b") ("N" "3")) (("S" "c") ("A" (("N" "1") ("N" "2") ("N" "3"))))))))) (badsyntax . "[\n")
$ echo -n '"\u1234"' | ./txr -l json.txr - (v "S" "\11064") (badsyntax . "")</lang>
Wren
<lang ecmascript>import "/json" for JSON
var s = "{ \"foo\": 1, \"bar\": [ \"10\", \"apples\"] }" var o = JSON.parse(s) System.print(o)
o = { "blue": [1, 2], "ocean": "water" } s = JSON.stringify(o) System.print(s)</lang>
- Output:
{foo: 1, bar: [10, apples]} {"ocean":"water","blue":[1,2]}
XQuery
The XPath 3.1 standard specifies an XML format to store JSON information. Different XQuery processors implement their own JSON parsers in addition to the XPath functions. One such function has been added, to show, how to map JSON into an XPath map using the BaseX processor. As XQuery is a superset of XPath, the following code is valid XQuery 3.1. Except for 'null', which does not exist in the XPath data model, all JSON datatypes have their XPath equivalent. 'Null' is being represented by the empty sequence. This gets shown at the last function invocation, which creates an XPath map. It may be interesting to note, that the different options for the json serializers and parsers have not been used here. <lang xquery> let $json := ' {
"Astring" : "string-value", "Anumber" : 5.7, "Anull" : null, "Aarray" : ["One","Two", 3], "Aobject" : { "key1": "value1", "key2": "value2" }, "Atrue" : true, "Afalse" : false
} ' let $xml := json-to-xml($local:json) return (
"XPath fn:json-to-xml#1 function:" ,"" ,$xml ,"" ,"Round trip, using fn:xml-to-json#1:" ,"" ,xml-to-json($xml) ,"" ,"Using BaseX json:parse#2 function to create an XPath 3.1 map:" ,"" ,json:parse($local:json, map{"format":"xquery"})
)
</lang>
Result:
XPath fn:json-to-xml#1 function: <map xmlns="http://www.w3.org/2005/xpath-functions"> <string key="Astring">string-value</string> <number key="Anumber">5.7</number> <null key="Anull"/> <array key="Aarray"> <string>One</string> <string>Two</string> <number>3</number> </array> <map key="Aobject"> <string key="key1">value1</string> <string key="key2">value2</string> </map> <boolean key="Atrue">true</boolean> <boolean key="Afalse">false</boolean> </map> Round trip, using fn:xml-to-json#1: { "Astring":"string-value", "Anumber":5.7, "Anull":null, "Aarray":[ "One", "Two", 3 ], "Aobject":{ "key1":"value1", "key2":"value2" }, "Atrue":true, "Afalse":false } Using BaseX json:parse#2 function to create an XPath 3.1 map: map { "Aobject": map { "key1": "value1", "key2": "value2" }, "Afalse": false(), "Anull": (), "Anumber": 5.7e0, "Atrue": true(), "Astring": "string-value", "Aarray": ["One", "Two", 3.0e0] }
zkl
zkl has a JSON codec based on yajl.
To convert from JSON to zkl: <lang zkl>a,b:=Import.lib("zklYAJL"); var [const] YAJL=a, toJSON=b; src:=
- <<<
0'|{
"pi": 3.14, "large number": 123456789123456791, "an array": [ -1, true, false, null, "foo" ]
}|;
- <<<
obj:=YAJL().write(src).close(); // or obj:=src.pump(YAJL()).close(); // for example, from file or socket obj.println();</lang>
- Output:
D(pi:3.14,an array:L(-1,True,False,Void,"foo"),large number:123456789123456791)
From zkl to JSON: <lang zkl>// using above code plus: toJSON(obj).println();</lang>
- Output:
{"pi":3.1400000000,"an array":[-1,true,false,null,"foo"],"large number":123456789123456791}
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