.. _apiref: ************* API Reference ************* .. highlight:: c Preliminaries ============= All declarations are in :file:`jansson.h`, so it's enough to :: #include in each source file. All constants are prefixed with ``JSON_`` (except for those describing the library version, prefixed with ``JANSSON_``). Other identifiers are prefixed with ``json_``. Type names are suffixed with ``_t`` and ``typedef``\ 'd so that the ``struct`` keyword need not be used. Library Version =============== The Jansson version is of the form *A.B.C*, where *A* is the major version, *B* is the minor version and *C* is the micro version. If the micro version is zero, it's omitted from the version string, i.e. the version string is just *A.B*. When a new release only fixes bugs and doesn't add new features or functionality, the micro version is incremented. When new features are added in a backwards compatible way, the minor version is incremented and the micro version is set to zero. When there are backwards incompatible changes, the major version is incremented and others are set to zero. The following preprocessor constants specify the current version of the library: ``JANSSON_VERSION_MAJOR``, ``JANSSON_VERSION_MINOR``, ``JANSSON_VERSION_MICRO`` Integers specifying the major, minor and micro versions, respectively. ``JANSSON_VERSION`` A string representation of the current version, e.g. ``"1.2.1"`` or ``"1.3"``. ``JANSSON_VERSION_HEX`` A 3-byte hexadecimal representation of the version, e.g. ``0x010201`` for version 1.2.1 and ``0x010300`` for version 1.3. This is useful in numeric comparisions, e.g.:: #if JANSSON_VERSION_HEX >= 0x010300 /* Code specific to version 1.3 and above */ #endif Value Representation ==================== The JSON specification (:rfc:`4627`) defines the following data types: *object*, *array*, *string*, *number*, *boolean*, and *null*. JSON types are used dynamically; arrays and objects can hold any other data type, including themselves. For this reason, Jansson's type system is also dynamic in nature. There's one C type to represent all JSON values, and this structure knows the type of the JSON value it holds. .. type:: json_t This data structure is used throughout the library to represent all JSON values. It always contains the type of the JSON value it holds and the value's reference count. The rest depends on the type of the value. Objects of :type:`json_t` are always used through a pointer. There are APIs for querying the type, manipulating the reference count, and for constructing and manipulating values of different types. Unless noted otherwise, all API functions return an error value if an error occurs. Depending on the function's signature, the error value is either *NULL* or -1. Invalid arguments or invalid input are apparent sources for errors. Memory allocation and I/O operations may also cause errors. Type ---- The type of a JSON value is queried and tested using the following functions: .. type:: enum json_type The type of a JSON value. The following members are defined: +--------------------+ | ``JSON_OBJECT`` | +--------------------+ | ``JSON_ARRAY`` | +--------------------+ | ``JSON_STRING`` | +--------------------+ | ``JSON_INTEGER`` | +--------------------+ | ``JSON_REAL`` | +--------------------+ | ``JSON_TRUE`` | +--------------------+ | ``JSON_FALSE`` | +--------------------+ | ``JSON_NULL`` | +--------------------+ These correspond to JSON object, array, string, number, boolean and null. A number is represented by either a value of the type ``JSON_INTEGER`` or of the type ``JSON_REAL``. A true boolean value is represented by a value of the type ``JSON_TRUE`` and false by a value of the type ``JSON_FALSE``. .. function:: int json_typeof(const json_t *json) Return the type of the JSON value (a :type:`json_type` cast to :type:`int`). *json* MUST NOT be *NULL*. This function is actually implemented as a macro for speed. .. function:: json_is_object(const json_t *json) json_is_array(const json_t *json) json_is_string(const json_t *json) json_is_integer(const json_t *json) json_is_real(const json_t *json) json_is_true(const json_t *json) json_is_false(const json_t *json) json_is_null(const json_t *json) These functions (actually macros) return true (non-zero) for values of the given type, and false (zero) for values of other types and for *NULL*. .. function:: json_is_number(const json_t *json) Returns true for values of types ``JSON_INTEGER`` and ``JSON_REAL``, and false for other types and for *NULL*. .. function:: json_is_boolean(const json_t *json) Returns true for types ``JSON_TRUE`` and ``JSON_FALSE``, and false for values of other types and for *NULL*. .. _apiref-reference-count: Reference Count --------------- The reference count is used to track whether a value is still in use or not. When a value is created, it's reference count is set to 1. If a reference to a value is kept (e.g. a value is stored somewhere for later use), its reference count is incremented, and when the value is no longer needed, the reference count is decremented. When the reference count drops to zero, there are no references left, and the value can be destroyed. The following functions are used to manipulate the reference count. .. function:: json_t *json_incref(json_t *json) Increment the reference count of *json* if it's not non-*NULL*. Returns *json*. .. function:: void json_decref(json_t *json) Decrement the reference count of *json*. As soon as a call to :func:`json_decref()` drops the reference count to zero, the value is destroyed and it can no longer be used. Functions creating new JSON values set the reference count to 1. These functions are said to return a **new reference**. Other functions returning (existing) JSON values do not normally increase the reference count. These functions are said to return a **borrowed reference**. So, if the user will hold a reference to a value returned as a borrowed reference, he must call :func:`json_incref`. As soon as the value is no longer needed, :func:`json_decref` should be called to release the reference. Normally, all functions accepting a JSON value as an argument will manage the reference, i.e. increase and decrease the reference count as needed. However, some functions **steal** the reference, i.e. they have the same result as if the user called :func:`json_decref()` on the argument right after calling the function. These functions are suffixed with ``_new`` or have ``_new_`` somewhere in their name. For example, the following code creates a new JSON array and appends an integer to it:: json_t *array, *integer; array = json_array(); integer = json_integer(42); json_array_append(array, integer); json_decref(integer); Note how the caller has to release the reference to the integer value by calling :func:`json_decref()`. By using a reference stealing function :func:`json_array_append_new()` instead of :func:`json_array_append()`, the code becomes much simpler:: json_t *array = json_array(); json_array_append_new(array, json_integer(42)); In this case, the user doesn't have to explicitly release the reference to the integer value, as :func:`json_array_append_new()` steals the reference when appending the value to the array. In the following sections it is clearly documented whether a function will return a new or borrowed reference or steal a reference to its argument. Circular References ------------------- A circular reference is created when an object or an array is, directly or indirectly, inserted inside itself. The direct case is simple:: json_t *obj = json_object(); json_object_set(obj, "foo", obj); Jansson will refuse to do this, and :func:`json_object_set()` (and all the other such functions for objects and arrays) will return with an error status. The indirect case is the dangerous one:: json_t *arr1 = json_array(), *arr2 = json_array(); json_array_append(arr1, arr2); json_array_append(arr2, arr1); In this example, the array ``arr2`` is contained in the array ``arr1``, and vice versa. Jansson cannot check for this kind of indirect circular references without a performance hit, so it's up to the user to avoid them. If a circular reference is created, the memory consumed by the values cannot be freed by :func:`json_decref()`. The reference counts never drops to zero because the values are keeping the references to each other. Moreover, trying to encode the values with any of the encoding functions will fail. The encoder detects circular references and returns an error status. True, False and Null ==================== These values are implemented as singletons, so each of these functions returns the same value each time. .. function:: json_t *json_true(void) .. refcounting:: new Returns the JSON true value. .. function:: json_t *json_false(void) .. refcounting:: new Returns the JSON false value. .. function:: json_t *json_null(void) .. refcounting:: new Returns the JSON null value. String ====== Jansson uses UTF-8 as the character encoding. All JSON strings must be valid UTF-8 (or ASCII, as it's a subset of UTF-8). Normal null terminated C strings are used, so JSON strings may not contain embedded null characters. All other Unicode codepoints U+0001 through U+10FFFF are allowed. .. function:: json_t *json_string(const char *value) .. refcounting:: new Returns a new JSON string, or *NULL* on error. *value* must be a valid UTF-8 encoded Unicode string. .. function:: json_t *json_string_nocheck(const char *value) .. refcounting:: new Like :func:`json_string`, but doesn't check that *value* is valid UTF-8. Use this function only if you are certain that this really is the case (e.g. you have already checked it by other means). .. function:: const char *json_string_value(const json_t *string) Returns the associated value of *string* as a null terminated UTF-8 encoded string, or *NULL* if *string* is not a JSON string. The retuned value is read-only and must not be modified or freed by the user. It is valid as long as *string* exists, i.e. as long as its reference count has not dropped to zero. .. function:: int json_string_set(const json_t *string, const char *value) Sets the associated value of *string* to *value*. *value* must be a valid UTF-8 encoded Unicode string. Returns 0 on success and -1 on error. .. function:: int json_string_set_nocheck(const json_t *string, const char *value) Like :func:`json_string_set`, but doesn't check that *value* is valid UTF-8. Use this function only if you are certain that this really is the case (e.g. you have already checked it by other means). Number ====== The JSON specification only contains one numeric type, "number". The C programming language has distinct types for integer and floating-point numbers, so for practical reasons Jansson also has distinct types for the two. They are called "integer" and "real", respectively. For more information, see :ref:`rfc-conformance`. .. type:: json_int_t This is the C type that is used to store JSON integer values. It represents the widest integer type available on your system. In practice it's just a typedef of ``long long`` if your compiler supports it, otherwise ``long``. Usually, you can safely use plain ``int`` in place of ``json_int_t``, and the implicit C integer conversion handles the rest. Only when you know that you need the full 64-bit range, you should use ``json_int_t`` explicitly. ``JSON_INTEGER_IS_LONG_LONG`` This is a preprocessor variable that holds the value 1 if :type:`json_int_t` is ``long long``, and 0 if it's ``long``. It can be used as follows:: #if JSON_INTEGER_IS_LONG_LONG /* Code specific for long long */ #else /* Code specific for long */ #endif ``JSON_INTEGER_FORMAT`` This is a macro that expands to a :func:`printf()` conversion specifier that corresponds to :type:`json_int_t`, without the leading ``%`` sign, i.e. either ``"lld"`` or ``"ld"``. This macro is required because the actual type of :type:`json_int_t` can be either ``long`` or ``long long``, and :func:`printf()` reuiqres different length modifiers for the two. Example:: json_int_t x = 123123123; printf("x is %" JSON_INTEGER_FORMAT "\n", x); .. function:: json_t *json_integer(json_int_t value) .. refcounting:: new Returns a new JSON integer, or *NULL* on error. .. function:: json_int_t json_integer_value(const json_t *integer) Returns the associated value of *integer*, or 0 if *json* is not a JSON integer. .. function:: int json_integer_set(const json_t *integer, json_int_t value) Sets the associated value of *integer* to *value*. Returns 0 on success and -1 if *integer* is not a JSON integer. .. function:: json_t *json_real(double value) .. refcounting:: new Returns a new JSON real, or *NULL* on error. .. function:: double json_real_value(const json_t *real) Returns the associated value of *real*, or 0.0 if *real* is not a JSON real. .. function:: int json_real_set(const json_t *real, double value) Sets the associated value of *real* to *value*. Returns 0 on success and -1 if *real* is not a JSON real. In addition to the functions above, there's a common query function for integers and reals: .. function:: double json_number_value(const json_t *json) Returns the associated value of the JSON integer or JSON real *json*, cast to double regardless of the actual type. If *json* is neither JSON real nor JSON integer, 0.0 is returned. Array ===== A JSON array is an ordered collection of other JSON values. .. function:: json_t *json_array(void) .. refcounting:: new Returns a new JSON array, or *NULL* on error. Initially, the array is empty. .. function:: size_t json_array_size(const json_t *array) Returns the number of elements in *array*, or 0 if *array* is NULL or not a JSON array. .. function:: json_t *json_array_get(const json_t *array, size_t index) .. refcounting:: borrow Returns the element in *array* at position *index*. The valid range for *index* is from 0 to the return value of :func:`json_array_size()` minus 1. If *array* is not a JSON array, if *array* is *NULL*, or if *index* is out of range, *NULL* is returned. .. function:: int json_array_set(json_t *array, size_t index, json_t *value) Replaces the element in *array* at position *index* with *value*. The valid range for *index* is from 0 to the return value of :func:`json_array_size()` minus 1. Returns 0 on success and -1 on error. .. function:: int json_array_set_new(json_t *array, size_t index, json_t *value) Like :func:`json_array_set()` but steals the reference to *value*. This is useful when *value* is newly created and not used after the call. .. function:: int json_array_append(json_t *array, json_t *value) Appends *value* to the end of *array*, growing the size of *array* by 1. Returns 0 on success and -1 on error. .. function:: int json_array_append_new(json_t *array, json_t *value) Like :func:`json_array_append()` but steals the reference to *value*. This is useful when *value* is newly created and not used after the call. .. function:: int json_array_insert(json_t *array, size_t index, json_t *value) Inserts *value* to *array* at position *index*, shifting the elements at *index* and after it one position towards the end of the array. Returns 0 on success and -1 on error. .. function:: int json_array_insert_new(json_t *array, size_t index, json_t *value) Like :func:`json_array_insert()` but steals the reference to *value*. This is useful when *value* is newly created and not used after the call. .. function:: int json_array_remove(json_t *array, size_t index) Removes the element in *array* at position *index*, shifting the elements after *index* one position towards the start of the array. Returns 0 on success and -1 on error. .. function:: int json_array_clear(json_t *array) Removes all elements from *array*. Returns 0 on sucess and -1 on error. .. function:: int json_array_extend(json_t *array, json_t *other_array) Appends all elements in *other_array* to the end of *array*. Returns 0 on success and -1 on error. Object ====== A JSON object is a dictionary of key-value pairs, where the key is a Unicode string and the value is any JSON value. .. function:: json_t *json_object(void) .. refcounting:: new Returns a new JSON object, or *NULL* on error. Initially, the object is empty. .. function:: size_t json_object_size(const json_t *object) Returns the number of elements in *object*, or 0 if *object* is not a JSON object. .. function:: json_t *json_object_get(const json_t *object, const char *key) .. refcounting:: borrow Get a value corresponding to *key* from *object*. Returns *NULL* if *key* is not found and on error. .. function:: int json_object_set(json_t *object, const char *key, json_t *value) Set the value of *key* to *value* in *object*. *key* must be a valid null terminated UTF-8 encoded Unicode string. If there already is a value for *key*, it is replaced by the new value. Returns 0 on success and -1 on error. .. function:: int json_object_set_nocheck(json_t *object, const char *key, json_t *value) Like :func:`json_object_set`, but doesn't check that *key* is valid UTF-8. Use this function only if you are certain that this really is the case (e.g. you have already checked it by other means). .. function:: int json_object_set_new(json_t *object, const char *key, json_t *value) Like :func:`json_object_set()` but steals the reference to *value*. This is useful when *value* is newly created and not used after the call. .. function:: int json_object_set_new_nocheck(json_t *object, const char *key, json_t *value) Like :func:`json_object_set_new`, but doesn't check that *key* is valid UTF-8. Use this function only if you are certain that this really is the case (e.g. you have already checked it by other means). .. function:: int json_object_del(json_t *object, const char *key) Delete *key* from *object* if it exists. Returns 0 on success, or -1 if *key* was not found. .. function:: int json_object_clear(json_t *object) Remove all elements from *object*. Returns 0 on success and -1 if *object* is not a JSON object. .. function:: int json_object_update(json_t *object, json_t *other) Update *object* with the key-value pairs from *other*, overwriting existing keys. Returns 0 on success or -1 on error. The following functions implement an iteration protocol for objects: .. function:: void *json_object_iter(json_t *object) Returns an opaque iterator which can be used to iterate over all key-value pairs in *object*, or *NULL* if *object* is empty. .. function:: void *json_object_iter_at(json_t *object, const char *key) Like :func:`json_object_iter()`, but returns an iterator to the key-value pair in *object* whose key is equal to *key*, or NULL if *key* is not found in *object*. Iterating forward to the end of *object* only yields all key-value pairs of the object if *key* happens to be the first key in the underlying hash table. .. function:: void *json_object_iter_next(json_t *object, void *iter) Returns an iterator pointing to the next key-value pair in *object* after *iter*, or *NULL* if the whole object has been iterated through. .. function:: const char *json_object_iter_key(void *iter) Extract the associated key from *iter*. .. function:: json_t *json_object_iter_value(void *iter) .. refcounting:: borrow Extract the associated value from *iter*. .. function:: int json_object_iter_set(json_t *object, void *iter, json_t *value) Set the value of the key-value pair in *object*, that is pointed to by *iter*, to *value*. .. function:: int json_object_iter_set_new(json_t *object, void *iter, json_t *value) Like :func:`json_object_iter_set()`, but steals the reference to *value*. This is useful when *value* is newly created and not used after the call. The iteration protocol can be used for example as follows:: /* obj is a JSON object */ const char *key; json_t *value; void *iter = json_object_iter(obj); while(iter) { key = json_object_iter_key(iter); value = json_object_iter_value(iter); /* use key and value ... */ iter = json_object_iter_next(obj, iter); } Encoding ======== This sections describes the functions that can be used to encode values to JSON. Only objects and arrays can be encoded, since they are the only valid "root" values of a JSON text. By default, the output has no newlines, and spaces are used between array and object elements for a readable output. This behavior can be altered by using the ``JSON_INDENT`` and ``JSON_COMPACT`` flags described below. A newline is never appended to the end of the encoded JSON data. Each function takes a *flags* parameter that controls some aspects of how the data is encoded. Its default value is 0. The following macros can be ORed together to obtain *flags*. ``JSON_INDENT(n)`` Pretty-print the result, using newlines between array and object items, and indenting with *n* spaces. The valid range for *n* is between 0 and 32, other values result in an undefined output. If ``JSON_INDENT`` is not used or *n* is 0, no newlines are inserted between array and object items. ``JSON_COMPACT`` This flag enables a compact representation, i.e. sets the separator between array and object items to ``","`` and between object keys and values to ``":"``. Without this flag, the corresponding separators are ``", "`` and ``": "`` for more readable output. ``JSON_ENSURE_ASCII`` If this flag is used, the output is guaranteed to consist only of ASCII characters. This is achived by escaping all Unicode characters outside the ASCII range. ``JSON_SORT_KEYS`` If this flag is used, all the objects in output are sorted by key. This is useful e.g. if two JSON texts are diffed or visually compared. ``JSON_PRESERVE_ORDER`` If this flag is used, object keys in the output are sorted into the same order in which they were first inserted to the object. For example, decoding a JSON text and then encoding with this flag preserves the order of object keys. The following functions perform the actual JSON encoding. The result is in UTF-8. .. function:: char *json_dumps(const json_t *root, size_t flags) Returns the JSON representation of *root* as a string, or *NULL* on error. *flags* is described above. The return value must be freed by the caller using :func:`free()`. .. function:: int json_dumpf(const json_t *root, FILE *output, size_t flags) Write the JSON representation of *root* to the stream *output*. *flags* is described above. Returns 0 on success and -1 on error. If an error occurs, something may have already been written to *output*. In this case, the output is undefined and most likely not valid JSON. .. function:: int json_dump_file(const json_t *json, const char *path, size_t flags) Write the JSON representation of *root* to the file *path*. If *path* already exists, it is overwritten. *flags* is described above. Returns 0 on success and -1 on error. Decoding ======== This sections describes the functions that can be used to decode JSON text to the Jansson representation of JSON data. The JSON specification requires that a JSON text is either a serialized array or object, and this requirement is also enforced with the following functions. In other words, the top level value in the JSON text being decoded must be either array or object. See :ref:`rfc-conformance` for a discussion on Jansson's conformance to the JSON specification. It explains many design decisions that affect especially the behavior of the decoder. .. function:: json_t *json_loads(const char *input, size_t flags, json_error_t *error) .. refcounting:: new Decodes the JSON string *input* and returns the array or object it contains, or *NULL* on error, in which case *error* is filled with information about the error. See above for discussion on the *error* parameter. *flags* is currently unused, and should be set to 0. .. function:: json_t *json_loadf(FILE *input, size_t flags, json_error_t *error) .. refcounting:: new Decodes the JSON text in stream *input* and returns the array or object it contains, or *NULL* on error, in which case *error* is filled with information about the error. See above for discussion on the *error* parameter. *flags* is currently unused, and should be set to 0. .. function:: json_t *json_load_file(const char *path, size_t flags, json_error_t *error) .. refcounting:: new Decodes the JSON text in file *path* and returns the array or object it contains, or *NULL* on error, in which case *error* is filled with information about the error. See above for discussion on the *error* parameter. *flags* is currently unused, and should be set to 0. .. type:: json_error_t This data structure is used to return information on decoding errors from the decoding functions. .. member:: const char *text The error message (in UTF-8), or an empty string if a message is not available. .. member:: int line The line number on which the error occurred, or -1 if this information is not available. .. member:: int column The character column on which the error occurred, or -1 if this information is not available. .. member:: const char *source Source of the error. This is (a part of) the file name when using :func:`json_load_file()`, or a special identifier in angle brackets otherwise (e.g. ````). The normal use of :type:`json_error_t` is to allocate it on the stack, and pass a pointer to a decoding function. Example:: int main() { json_t *json; json_error_t error; json = json_load_file("/path/to/file.json", 0, &error); if(!json) { /* the error variable contains error information */ } ... } Also note that if the decoding succeeded (``json != NULL`` in the above example), the contents of ``error`` are unspecified. All decoding functions also accept *NULL* as the :type:`json_error_t` pointer, in which case no error information is returned to the caller. .. _apiref-building-values: Building values =============== This sectinon describes functions that help to create, or *pack*, complex JSON values, especially nested objects and arrays. Value building is based on a *format string* that is used to tell the functions about the expected arguments. For example, the format string ``"i"`` specifies a single integer value, while the format string ``"[ssb]"`` or the equivalent ``"[s, s, b]"`` specifies an array value with two integers and a boolean as its items:: /* Create the JSON integer 42 */ json_pack("i", 42); /* Create the JSON array ["foo", "bar", true] */ json_pack("[ssb]", "foo", "bar", 1); Here's the full list of format characters. The type in parentheses denotes the resulting JSON type, and the type in brackets (if any) denotes the C type that is expected as the corresponding argument. ``s`` (string) [const char \*] Convert a NULL terminated UTF-8 string to a JSON string. ``n`` (null) Output a JSON null value. No argument is consumed. ``b`` (boolean) [int] Convert a C :type:`int` to JSON boolean value. Zero is converted to ``false`` and non-zero to ``true``. ``i`` (integer) [int] Convert a C :type:`int` to JSON integer. ``I`` (integer) [json_int_t] Convert a C :type:`json_int_t` to JSON integer. ``f`` (real) [double] Convert a C :type:`double` to JSON real. ``o`` (any value) [json_t \*] Output any given JSON value as-is. If the value is added to an array or object, the reference to the value passed to ``o`` is stealed by the container. ``O`` (any value) [json_t \*] Like ``o``, but the argument's reference count is incremented. This is useful if you pack and array an array or object and want to keep the reference for the JSON value consumed by ``O`` to yourself. ``[fmt]`` (array) Build an array with contents from the inner format string. ``fmt`` may contain objects and arrays, i.e. recursive value building is supported. ``{fmt}`` (object) Build an object with contents from the inner format string ``fmt``. The first, third, etc. format character represent a key, and must be ``s`` (as object keys are always strings). The second, fourth, etc. format character represent a value. Any value may be an object or array, i.e. recursive value building is supported. The following functions compose the value building API: .. function:: json_t *json_pack(const char *fmt, ...) .. refcounting:: new Build a new JSON value according to the format string *fmt*. For each format character (except for ``{}[]n``), one argument is consumed and used to build the corresponding value. Returns *NULL* on error. .. function:: json_t *json_pack_ex(json_error_t *error, size_t flags, const char *fmt, ...) json_t *json_vpack_ex(json_error_t *error, size_t flags, const char *fmt, va_list ap) .. refcounting:: new Like :func:`json_pack()`, but an in the case of an error, an error message is written to *error*, if it's not *NULL*. The *flags* parameter is currently unused and should be set to 0. As only the errors in format string (and out-of-memory errors) can be caught by the packer, these two functions are most likely only useful for debugging format strings. More examples:: /* Build an empty JSON object */ json_pack("{}"); /* Build the JSON object {"foo": 42, "bar": 7} */ json_pack("{sisb}", "foo", 42, "bar", 7); /* Like above, ':', ',' and whitespace are ignored */ json_pack("{s:i, s:b}", "foo", 42, "bar", 7); /* Build the JSON array [[1, 2], {"cool": true}] */ json_pack("[[i,i],{s:b]]", 1, 2, "cool", 1); Parsing and validating values ============================= This sectinon describes functions that help to validate complex values and extract, or *unpack*, data from them. Like :ref:`building values `, this is also based on format strings. While a JSON value is unpacked, the type specified in the format string is checked to match that of the JSON value. This is the validation part of the process. In addition to this, the unpacking functions can also check that all items of arrays and objects are unpacked. This check be enabled with the format character ``!`` or by using the flag ``JSON_STRICT``. See below for details. Here's the full list of format characters. The type in parentheses denotes the JSON type, and the type in brackets (if any) denotes the C type whose address should be passed. ``s`` (string) [const char \*] Convert a JSON string to a pointer to a NULL terminated UTF-8 string. ``n`` (null) Expect a JSON null value. Nothing is extracted. ``b`` (boolean) [int] Convert a JSON boolean value to a C :type:`int`, so that ``true`` is converted to 1 and ``false`` to 0. ``i`` (integer) [int] Convert a JSON integer to C :type:`int`. ``I`` (integer) [json_int_t] Convert a JSON integer to C :type:`json_int_t`. ``f`` (real) [double] Convert a JSON real to C :type:`double`. ``F`` (integer or real) [double] Convert a JSON number (integer or real) to C :type:`double`. ``o`` (any value) [json_t \*] Store a JSON value with no conversion to a :type:`json_t` pointer. ``O`` (any value) [json_t \*] Like ``O``, but the JSON value's reference count is incremented. ``[fmt]`` (array) Convert each item in the JSON array according to the inner format string. ``fmt`` may contain objects and arrays, i.e. recursive value extraction is supporetd. ``{fmt}`` (object) Convert each item in the JSON object according to the inner format string ``fmt``. The first, third, etc. format character represent a key, and must be ``s``. The corresponding argument to unpack functions is read as the object key. The second fourth, etc. format character represent a value and is written to the address given as the corresponding argument. **Note** that every other argument is read from and every other is written to. ``fmt`` may contain objects and arrays as values, i.e. recursive value extraction is supporetd. ``!`` This special format character is used to enable the check that all object and array items are accessed, on a per-value basis. It must appear inside an array or object as the last format character before the closing bracket or brace. To enable the check globally, use the ``JSON_STRICT`` unpacking flag. ``*`` This special format character is the opposite of ``!``. If the ``JSON_STRICT`` flag is used, ``*`` can be used to disable the strict check on a per-value basis. It must appear inside an array or object as the last format character before the closing bracket or brace. The following functions compose the parsing and validation API: .. function:: int json_unpack(json_t *root, const char *fmt, ...) Validate and unpack the JSON value *root* according to the format string *fmt*. Returns 0 on success and -1 on failure. .. function:: int json_unpack_ex(json_t *root, json_error_t *error, size_t flags, const char *fmt, ...) int json_vunpack_ex(json_t *root, json_error_t *error, size_t flags, const char *fmt, va_list ap) Validate and unpack the JSON value *root* according to the format string *fmt*. If an error occurs and *error* is not *NULL*, write error information to *error*. *flags* can be used to control the behaviour of the unpacker, see below for the flags. Returns 0 on success and -1 on failure. The following unpacking flags are available: ``JSON_STRICT`` Enable the extra validation step checking that all object and array items are unpacked. This is equivalent to appending the format character ``!`` to the end of every array and object in the format string. ``JSON_VALIDATE_ONLY`` Don't extract any data, just validate the JSON value against the given format string. Note that object keys must still be specified after the format string. Examples:: /* root is the JSON integer 42 */ int myint; json_unpack(root, "i", &myint); assert(myint == 42); /* root is the JSON object {"foo": "bar", "quux": true} */ const char *str; int boolean; json_unpack(root, "{s:s, s:b}", "foo", &str, "quux", &boolean); assert(strcmp(str, "bar") == 0 && boolean == 1); /* root is the JSON array [[1, 2], {"baz": null} */ json_error_t error; json_unpack_ex(root, &error, JSON_VALIDATE_ONLY, "[[i,i], {s:n}]", "baz"); /* returns 0 for validation success, nothing is extracted */ /* root is the JSON array [1, 2, 3, 4, 5] */ int myint1, myint2; json_unpack(root, "[ii!]", &myint1, &myint2); /* returns -1 for failed validation */ Equality ======== Testing for equality of two JSON values cannot, in general, be achieved using the ``==`` operator. Equality in the terms of the ``==`` operator states that the two :type:`json_t` pointers point to exactly the same JSON value. However, two JSON values can be equal not only if they are exactly the same value, but also if they have equal "contents": * Two integer or real values are equal if their contained numeric values are equal. An integer value is never equal to a real value, though. * Two strings are equal if their contained UTF-8 strings are equal, byte by byte. Unicode comparison algorithms are not implemented. * Two arrays are equal if they have the same number of elements and each element in the first array is equal to the corresponding element in the second array. * Two objects are equal if they have exactly the same keys and the value for each key in the first object is equal to the value of the corresponding key in the second object. * Two true, false or null values have no "contents", so they are equal if their types are equal. (Because these values are singletons, their equality can actually be tested with ``==``.) The following function can be used to test whether two JSON values are equal. .. function:: int json_equal(json_t *value1, json_t *value2) Returns 1 if *value1* and *value2* are equal, as defined above. Returns 0 if they are inequal or one or both of the pointers are *NULL*. Copying ======= Because of reference counting, passing JSON values around doesn't require copying them. But sometimes a fresh copy of a JSON value is needed. For example, if you need to modify an array, but still want to use the original afterwards, you should take a copy of it first. Jansson supports two kinds of copying: shallow and deep. There is a difference between these methods only for arrays and objects. Shallow copying only copies the first level value (array or object) and uses the same child values in the copied value. Deep copying makes a fresh copy of the child values, too. Moreover, all the child values are deep copied in a recursive fashion. .. function:: json_t *json_copy(json_t *value) .. refcounting:: new Returns a shallow copy of *value*, or *NULL* on error. .. function:: json_t *json_deep_copy(json_t *value) .. refcounting:: new Returns a deep copy of *value*, or *NULL* on error. Custom memory allocation ======================== By default, Jansson uses :func:`malloc()` and :func:`free()` for memory allocation. These functions can be overridden if custom behavior is needed. .. type:: json_malloc_t A typedef for a function pointer with :func:`malloc()`'s signature:: typedef void *(*json_malloc_t)(size_t); .. type:: json_free_t A typedef for a function pointer with :func:`free()`'s signature:: typedef void (*json_free_t)(void *); .. function:: void json_set_alloc_funcs(json_malloc_t malloc_fn, json_free_t free_fn) Use *malloc_fn* instead of :func:`malloc()` and *free_fn* instead of :func:`free()`. This function has to be called before any other Jansson's API functions to ensure that all memory operations use the same functions. Examples: Use the `Boehm's conservative garbage collector`_ for memory operations:: json_set_alloc_funcs(GC_malloc, GC_free); .. _Boehm's conservative garbage collector: http://www.hpl.hp.com/personal/Hans_Boehm/gc/ Allow storing sensitive data (e.g. passwords or encryption keys) in JSON structures by zeroing all memory when freed:: static void *secure_malloc(size_t size) { /* Store the memory area size in the beginning of the block */ void *ptr = malloc(size + 8); *((size_t *)ptr) = size; return ptr + 8; } static void secure_free(void *ptr) { size_t size; ptr -= 8; size = *((size_t *)ptr); guaranteed_memset(ptr, 0, size); free(ptr); } int main() { json_set_alloc_funcs(secure_malloc, secure_free); /* ... */ } For more information about the issues of storing sensitive data in memory, see http://www.dwheeler.com/secure-programs/Secure-Programs-HOWTO/protect-secrets.html. The page also examplains the :func:`guaranteed_memset()` function used in the example and gives a sample implementation for it.