Ultralightweight JSON parser in ANSI C
Go to file
2017-04-18 18:02:32 +02:00
.github Add contributing guideline 2017-03-03 22:14:11 +01:00
fuzzing Replace sizeof('\0') with sizeof("") 2017-04-08 01:29:19 +02:00
tests print_number: Make locale independent 2017-04-08 03:38:49 +02:00
.gitignore gitignore: ignore *.orig 2017-01-04 20:40:34 +01:00
.travis.yml Add support for Travis-CI 2017-02-07 21:35:38 +01:00
CHANGELOG.md Update Changelog 2017-04-18 18:02:32 +02:00
cJSON_Utils.c cJSONUtils_ApplyPatches: Fix not accepting arrays 2017-04-11 16:41:50 +02:00
cJSON_Utils.h add CJSON_PUBLIC macro to public functions to support visibility and dllimport/dllexport 2017-02-27 13:47:06 -06:00
cJSON.c Release version 1.4.6 2017-04-08 17:54:55 +02:00
cJSON.h cJSON_GetObjectItemCaseSensitive: Fix inconsistent prototype 2017-04-18 17:37:43 +02:00
cJSONConfig.cmake.in cJSON: Option to disable exporting targets 2016-11-14 19:14:13 +07:00
cJSONConfigVersion.cmake.in CMake: Use standard variables for the version 2016-11-14 19:14:12 +07:00
CMakeLists.txt Release version 1.4.6 2017-04-08 17:54:55 +02:00
CONTRIBUTORS.md Contributors: Add Mike Jerris 2017-02-28 23:04:29 +01:00
libcjson_utils.pc.in pkg-config: Add URL and link math library 2016-11-14 19:14:12 +07:00
libcjson.pc.in pkg-config: Add URL and link math library 2016-11-14 19:14:12 +07:00
LICENSE license file separated out :) 2013-08-14 13:16:18 +00:00
Makefile Release version 1.4.6 2017-04-08 17:54:55 +02:00
README.md README: Caveat about zero terminated strings 2017-04-18 17:58:36 +02:00
test_utils.c Rename some variables to avoid shadowing. 2016-11-27 18:16:28 +01:00
test.c Update space requirements of cJSON_PrintPreallocated 2017-04-08 03:42:44 +02:00

cJSON

Ultralightweight JSON parser in ANSI C.

Table of contents

License

Copyright (c) 2009-2016 Dave Gamble

Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions:

The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software.

THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.

Usage

Welcome to cJSON.

cJSON aims to be the dumbest possible parser that you can get your job done with. It's a single file of C, and a single header file.

JSON is described best here: http://www.json.org/ It's like XML, but fat-free. You use it to move data around, store things, or just generally represent your program's state.

As a library, cJSON exists to take away as much legwork as it can, but not get in your way. As a point of pragmatism (i.e. ignoring the truth), I'm going to say that you can use it in one of two modes: Auto and Manual. Let's have a quick run-through.

I lifted some JSON from this page: http://www.json.org/fatfree.html That page inspired me to write cJSON, which is a parser that tries to share the same philosophy as JSON itself. Simple, dumb, out of the way.

Building

There are several ways to incorporate cJSON into your project.

copying the source

Because the entire library is only one C file and one header file, you can just copy cJSON.h and cJSON.c to your projects source and start using it.

cJSON is written in ANSI C (C89) in order to support as many platforms and compilers as possible.

CMake

With CMake, cJSON supports a full blown build system. This way you get the most features. CMake with an equal or higher version than 2.8.5 is supported. With CMake it is recommended to do an out of tree build, meaning the compiled files are put in a directory separate from the source files. So in order to build cJSON with CMake on a Unix platform, make a build directory and run CMake inside it.

mkdir build
cd build
cmake ..

This will create a Makefile and a bunch of other files. You can then compile it:

make

And install it with make install if you want. By default it installs the headers /usr/local/include/cjson and the libraries to /usr/local/lib. It also installs files for pkg-config to make it easier to detect and use an existing installation of CMake. And it installs CMake config files, that can be used by other CMake based projects to discover the library.

You can change the build process with a list of different options that you can pass to CMake. Turn them on with On and off with Off:

  • -DENABLE_CJSON_TEST=On: Enable building the tests. (on by default)
  • -DENABLE_CJSON_UTILS=On: Enable building cJSON_Utils. (off by default)
  • -DENABLE_TARGET_EXPORT=On: Enable the export of CMake targets. Turn off if it makes problems. (on by default)
  • -DENABLE_CUSTOM_COMPILER_FLAGS=On: Enable custom compiler flags (currently for Clang and GCC). Turn off if it makes problems. (on by default)
  • -DENABLE_VALGRIND=On: Run tests with valgrind. (off by default)
  • -DENABLE_SANITIZERS=On: Compile cJSON with AddressSanitizer and UndefinedBehaviorSanitizer enabled (if possible). (off by default)
  • -DBUILD_SHARED_LIBS=On: Build the shared libraries. (on by default)
  • -DCMAKE_INSTALL_PREFIX=/usr: Set a prefix for the installation.

If you are packaging cJSON for a distribution of Linux, you would probably take these steps for example:

mkdir build
cd build
cmake .. -DENABLE_CJSON_UTILS=On -DENABLE_CJSON_TEST=Off -DCMAKE_INSTALL_PREFIX=/usr
make
make DESTDIR=$pkgdir install

Makefile

If you don't have CMake available, but still have GNU make. You can use the makefile to build cJSON:

Run this command in the directory with the source code and it will automatically compile static and shared libraries and a little test program.

make all

If you want, you can install the compiled library to your system using make install. By default it will install the headers in /usr/local/include/cjson and the libraries in /usr/local/lib. But you can change this behavior by setting the PREFIX and DESTDIR variables: make PREFIX=/usr DESTDIR=temp install.

Some JSON:

{
    "name": "Jack (\"Bee\") Nimble",
    "format": {
        "type":       "rect",
        "width":      1920,
        "height":     1080,
        "interlace":  false,
        "frame rate": 24
    }
}

Assume that you got this from a file, a webserver, or magic JSON elves, whatever, you have a char * to it. Everything is a cJSON struct. Get it parsed:

cJSON * root = cJSON_Parse(my_json_string);

This is an object. We're in C. We don't have objects. But we do have structs. What's the framerate?

cJSON *format = cJSON_GetObjectItem(root, "format");
cJSON *framerate_item = cJSON_GetObjectItem(format, "frame rate");
double framerate = 0;
if (cJSON_IsNumber(framerate_item))
{
  framerate = framerate_item->valuedouble;
}

Want to change the framerate?

cJSON *framerate_item = cJSON_GetObjectItem(format, "frame rate");
cJSON_SetNumberValue(framerate_item, 25);

Back to disk?

char *rendered = cJSON_Print(root);

Finished? Delete the root (this takes care of everything else).

cJSON_Delete(root);

That's AUTO mode. If you're going to use Auto mode, you really ought to check pointers before you dereference them. If you want to see how you'd build this struct in code?

cJSON *root;
cJSON *fmt;
root = cJSON_CreateObject();
cJSON_AddItemToObject(root, "name", cJSON_CreateString("Jack (\"Bee\") Nimble"));
cJSON_AddItemToObject(root, "format", fmt = cJSON_CreateObject());
cJSON_AddStringToObject(fmt, "type", "rect");
cJSON_AddNumberToObject(fmt, "width", 1920);
cJSON_AddNumberToObject(fmt, "height", 1080);
cJSON_AddFalseToObject (fmt, "interlace");
cJSON_AddNumberToObject(fmt, "frame rate", 24);

Hopefully we can agree that's not a lot of code? There's no overhead, no unnecessary setup. Look at test.c for a bunch of nice examples, mostly all ripped off the json.org site, and a few from elsewhere.

What about manual mode? First up you need some detail. Let's cover how the cJSON objects represent the JSON data. cJSON doesn't distinguish arrays from objects in handling; just type. Each cJSON has, potentially, a child, siblings, value, a name.

  • The root object has: Object Type and a Child
  • The Child has name "name", with value "Jack ("Bee") Nimble", and a sibling:
  • Sibling has type Object, name "format", and a child.
  • That child has type String, name "type", value "rect", and a sibling:
  • Sibling has type Number, name "width", value 1920, and a sibling:
  • Sibling has type Number, name "height", value 1080, and a sibling:
  • Sibling has type False, name "interlace", and a sibling:
  • Sibling has type Number, name "frame rate", value 24

Here's the structure:

typedef struct cJSON {
    struct cJSON *next,*prev;
    struct cJSON *child;

    int type;

    char *valuestring;
    int valueint; /* writing to valueint is DEPRECATED, please use cJSON_SetNumberValue instead */
    double valuedouble;

    char *string;
} cJSON;

By default all values are 0 unless set by virtue of being meaningful.

next/prev is a doubly linked list of siblings. next takes you to your sibling, prev takes you back from your sibling to you. Only objects and arrays have a child, and it's the head of the doubly linked list. A child entry will have prev == 0, but next potentially points on. The last sibling has next == 0. The type expresses Null/True/False/Number/String/Array/Object, all of which are #defined in cJSON.h.

A Number has valueint and valuedouble. valueint is a relict of the past, so always use valuedouble.

Any entry which is in the linked list which is the child of an object will have a string which is the "name" of the entry. When I said "name" in the above example, that's string. string is the JSON name for the 'variable name' if you will.

Now you can trivially walk the lists, recursively, and parse as you please. You can invoke cJSON_Parse to get cJSON to parse for you, and then you can take the root object, and traverse the structure (which is, formally, an N-tree), and tokenise as you please. If you wanted to build a callback style parser, this is how you'd do it (just an example, since these things are very specific):

void parse_and_callback(cJSON *item, const char *prefix)
{
    while (item)
    {
        char *newprefix = malloc(strlen(prefix) + strlen(item->string) + 2);
        sprintf(newprefix, "%s/%s", prefix, item->string);
        int dorecurse = callback(newprefix, item->type, item);
        if (item->child && dorecurse)
        {
            parse_and_callback(item->child, newprefix);
        }
        item = item->next;
        free(newprefix);
    }
}

The prefix process will build you a separated list, to simplify your callback handling. The dorecurse flag would let the callback decide to handle sub-arrays on it's own, or let you invoke it per-item. For the item above, your callback might look like this:

int callback(const char *name, int type, cJSON *item)
{
    if (!strcmp(name, "name"))
    {
        /* populate name */
    }
    else if (!strcmp(name, "format/type"))
    {
        /* handle "rect" */ }
    else if (!strcmp(name, "format/width"))
    {
        /* 800 */
    }
    else if (!strcmp(name, "format/height"))
    {
        /* 600 */
    }
    else if (!strcmp(name, "format/interlace"))
    {
        /* false */
    }
    else if (!strcmp(name, "format/frame rate"))
    {
        /* 24 */
    }

    return 1;
}

Alternatively, you might like to parse iteratively. You'd use:

void parse_object(cJSON *item)
{
    int i;
    for (i = 0; i < cJSON_GetArraySize(item); i++)
    {
        cJSON *subitem = cJSON_GetArrayItem(item, i);
        // handle subitem
    }
}

Or, for PROPER manual mode:

void parse_object(cJSON *item)
{
    cJSON *subitem = item->child;
    while (subitem)
    {
        // handle subitem
        if (subitem->child)
        {
            parse_object(subitem->child);
        }

        subitem = subitem->next;
    }
}

Of course, this should look familiar, since this is just a stripped-down version of the callback-parser.

This should cover most uses you'll find for parsing. The rest should be possible to infer.. and if in doubt, read the source! There's not a lot of it! ;)

In terms of constructing JSON data, the example code above is the right way to do it. You can, of course, hand your sub-objects to other functions to populate. Also, if you find a use for it, you can manually build the objects. For instance, suppose you wanted to build an array of objects?

cJSON *objects[24];

cJSON *Create_array_of_anything(cJSON **items, int num)
{
    int i;
    cJSON *prev;
    cJSON *root = cJSON_CreateArray();
    for (i = 0; i < 24; i++)
    {
        if (!i)
        {
            root->child = objects[i];
        }
        else
        {
            prev->next = objects[i];
            objects[i]->prev = prev;
        }

        prev = objects[i];
    }

    return root;
}

and simply: Create_array_of_anything(objects, 24);

cJSON doesn't make any assumptions about what order you create things in. You can attach the objects, as above, and later add children to each of those objects.

As soon as you call cJSON_Print, it renders the structure to text.

The test.c code shows how to handle a bunch of typical cases. If you uncomment the code, it'll load, parse and print a bunch of test files, also from json.org, which are more complex than I'd care to try and stash into a const char array[].

Caveats

Zero Character

cJSON doesn't support strings that contain the zero character '\0' or \u0000. This is impossible with the current API because strings are zero terminated.

Character Encoding

cJSON only supports UTF-8 encoded input and will always produce UTF-8 as output (If the input contained invalid UTF-8, it will most likely propagate it through to the output, thereby making the output non-valid UTF-8).

C Standard

cJSON is written in ANSI C (or C89, C90). If your compiler or C library doesn't follow this standard, correct behavior is not guaranteed.

NOTE: ANSI C is not C++ therefore it shouldn't be compiled by a C++ compiler. You can compile it with a C compiler and link it with your C++ code however. Although compiling with a C++ compiler might work, correct behavior is not guaranteed.

Floating Point Numbers

cJSON does not officially support any double implementations other than IEE754 double precision floating point numbers. It might still work with other implementations but bugs with these will be considered invalid.

The maximum length of a floating point literal that cJSON supports is currently 63 characters.

Thread Safety

In general cJSON is not thread safe.

However it is thread safe under the following conditions:

  • cJSON_GetErrorPtr is never used (the return_parse_end parameter of cJSON_ParseWithOpts can be used instead)
  • cJSON_InitHooks is only ever called before using cJSON in any threads.
  • setlocale is never called before all calls to cJSON functions have returned.

Enjoy cJSON!

  • Dave Gamble, Aug 2009