# nlohmann::basic_json::operator[] ``` // (1) reference operator[](size_type idx); const_reference operator[](size_type idx) const; // (2) reference operator[](typename object_t::key_type key); const_reference operator[](const typename object_t::key_type& key) const; // (3) template reference operator[](KeyType&& key); template const_reference operator[](KeyType&& key) const; // (4) reference operator[](const json_pointer& ptr); const_reference operator[](const json_pointer& ptr) const; ``` 1. Returns a reference to the array element at specified location `idx`. 1. Returns a reference to the object element with specified key `key`. The non-const qualified overload takes the key by value. 1. See 2. This overload is only available if `KeyType` is comparable with `typename object_t::key_type` and `typename object_comparator_t::is_transparent` denotes a type. 1. Returns a reference to the element with specified JSON pointer `ptr`. ## Template parameters `KeyType` : A type for an object key other than [`json_pointer`](https://json.nlohmann.me/api/json_pointer/index.md) that is comparable with [`string_t`](https://json.nlohmann.me/api/basic_json/string_t/index.md) using [`object_comparator_t`](https://json.nlohmann.me/api/basic_json/object_comparator_t/index.md). This can also be a string view (C++17). ## Iterator invalidation For the non-const versions 1. and 4., when passing an **array** index that does not exist, it is created and filled with a `null` value before a reference to it is returned. For this, a reallocation can happen, in which case all iterators (including the [`end()`](https://json.nlohmann.me/api/basic_json/end/index.md) iterator) and all references to the elements are invalidated. For [`ordered_json`](https://json.nlohmann.me/api/ordered_json/index.md), also passing an **object key** to the non-const versions 2., 3., and 4., a reallocation can happen which again invalidates all iterators and all references. ## Parameters `idx` (in) : index of the element to access `key` (in) : object key of the element to access `ptr` (in) : JSON pointer to the desired element ## Return value 1. (const) reference to the element at index `idx` 1. (const) reference to the element at key `key` 1. (const) reference to the element at key `key` 1. (const) reference to the element pointed to by `ptr` ## Exception safety Strong exception safety: if an exception occurs, the original value stays intact. ## Exceptions 1. The function can throw the following exceptions: - Throws [`type_error.305`](https://json.nlohmann.me/home/exceptions/#jsonexceptiontype_error305) if the JSON value is not an array or null; in that case, using the `[]` operator with an index makes no sense. 1. The function can throw the following exceptions: - Throws [`type_error.305`](https://json.nlohmann.me/home/exceptions/#jsonexceptiontype_error305) if the JSON value is not an object or null; in that case, using the `[]` operator with a key makes no sense. 1. See 2. 1. The function can throw the following exceptions: - Throws [`parse_error.106`](https://json.nlohmann.me/home/exceptions/#jsonexceptionparse_error106) if an array index in the passed JSON pointer `ptr` begins with '0'. - Throws [`parse_error.109`](https://json.nlohmann.me/home/exceptions/#jsonexceptionparse_error109) if an array index in the passed JSON pointer `ptr` is not a number. - Throws [`out_of_range.402`](https://json.nlohmann.me/home/exceptions/#jsonexceptionout_of_range402) if the array index '-' is used in the passed JSON pointer `ptr` for the const version. - Throws [`out_of_range.404`](https://json.nlohmann.me/home/exceptions/#jsonexceptionout_of_range404) if the JSON pointer `ptr` can not be resolved. - Throws [`out_of_range.410`](https://json.nlohmann.me/home/exceptions/#jsonexceptionout_of_range410) if an array index in the passed JSON pointer `ptr` exceeds the range of `size_type` (e.g., on 32-bit platforms). ## Complexity 1. Constant if `idx` is in the range of the array. Otherwise, linear in `idx - size()`. 1. Logarithmic in the size of the container. 1. Logarithmic in the size of the container. 1. Logarithmic in the size of the container. ## Notes Undefined behavior and runtime assertions The following cases apply to the **const** overloads; the non-const overloads instead insert the missing element (see the notes below). 1. If the element at index `idx` does not exist, the behavior is undefined. 1. If the element with key `key` does not exist, the behavior is undefined and is **guarded by a [runtime assertion](https://json.nlohmann.me/features/assertions/index.md)**! 1. The non-const version may add values: If `idx` is beyond the range of the array (i.e., `idx >= size()`), then the array is silently filled up with `null` values to make `idx` a valid reference to the last stored element. In case the value was `null` before, it is converted to an array. 1. If `key` is not found in the object, then it is silently added to the object and filled with a `null` value to make `key` a valid reference. In case the value was `null` before, it is converted to an object. 1. See 2. 1. `null` values are created in arrays and objects if necessary. In particular: - If the JSON pointer points to an object key that does not exist, it is created and filled with a `null` value before a reference to it is returned. - If the JSON pointer points to an array index that does not exist, it is created and filled with a `null` value before a reference to it is returned. All indices between the current maximum and the given index are also filled with `null`. - The special value `-` is treated as a synonym for the index past the end. ## Examples Example: (1) access specified array element The example below shows how array elements can be read and written using `[]` operator. Note the addition of `null` values. ``` #include #include using json = nlohmann::json; int main() { // create a JSON array json array = {1, 2, 3, 4, 5}; // output element at index 3 (fourth element) std::cout << array[3] << '\n'; // change last element to 6 array[array.size() - 1] = 6; // output changed array std::cout << array << '\n'; // write beyond array limit array[10] = 11; // output changed array std::cout << array << '\n'; } ``` Output: ``` 4 [1,2,3,4,6] [1,2,3,4,6,null,null,null,null,null,11] ``` Example: (1) access specified array element (const) The example below shows how array elements can be read using the `[]` operator. ``` #include #include using json = nlohmann::json; int main() { // create JSON array const json array = {"first", "2nd", "third", "fourth"}; // output element at index 2 (third element) std::cout << array.at(2) << '\n'; } ``` Output: ``` "third" ``` Example: (2) access specified object element The example below shows how object elements can be read and written using the `[]` operator. ``` #include #include #include using json = nlohmann::json; int main() { // create a JSON object json object = { {"one", 1}, {"two", 2}, {"three", 2.9} }; // output element with key "two" std::cout << object["two"] << "\n\n"; // change element with key "three" object["three"] = 3; // output changed array std::cout << std::setw(4) << object << "\n\n"; // mention nonexisting key object["four"]; // write to nonexisting key object["five"]["really"]["nested"] = true; // output changed object std::cout << std::setw(4) << object << '\n'; } ``` Output: ``` 2 { "one": 1, "three": 3, "two": 2 } { "five": { "really": { "nested": true } }, "four": null, "one": 1, "three": 3, "two": 2 } ``` Example: (2) access specified object element (const) The example below shows how object elements can be read using the `[]` operator. ``` #include #include using json = nlohmann::json; int main() { // create a JSON object const json object = { {"one", 1}, {"two", 2}, {"three", 2.9} }; // output element with key "two" std::cout << object["two"] << '\n'; } ``` Output: ``` 2 ``` Example: (3) access specified object element using string_view The example below shows how object elements can be read using the `[]` operator. ``` #include #include #include #include using namespace std::string_view_literals; using json = nlohmann::json; int main() { // create a JSON object json object = { {"one", 1}, {"two", 2}, {"three", 2.9} }; // output element with key "two" std::cout << object["two"sv] << "\n\n"; // change element with key "three" object["three"sv] = 3; // output changed array std::cout << std::setw(4) << object << "\n\n"; // mention nonexisting key object["four"sv]; // write to nonexisting key object["five"sv]["really"sv]["nested"sv] = true; // output changed object std::cout << std::setw(4) << object << '\n'; } ``` Output: ``` 2 { "one": 1, "three": 3, "two": 2 } { "five": { "really": { "nested": true } }, "four": null, "one": 1, "three": 3, "two": 2 } ``` Example: (3) access specified object element using string_view (const) The example below shows how object elements can be read using the `[]` operator. ``` #include #include #include using namespace std::string_view_literals; using json = nlohmann::json; int main() { // create a JSON object const json object = { {"one", 1}, {"two", 2}, {"three", 2.9} }; // output element with key "two" std::cout << object["two"sv] << '\n'; } ``` Output: ``` 2 ``` Example: (4) access specified element via JSON Pointer The example below shows how values can be read and written using JSON Pointers. ``` #include #include using json = nlohmann::json; using namespace nlohmann::literals; int main() { // create a JSON value json j = { {"number", 1}, {"string", "foo"}, {"array", {1, 2}} }; // read-only access // output element with JSON pointer "/number" std::cout << j["/number"_json_pointer] << '\n'; // output element with JSON pointer "/string" std::cout << j["/string"_json_pointer] << '\n'; // output element with JSON pointer "/array" std::cout << j["/array"_json_pointer] << '\n'; // output element with JSON pointer "/array/1" std::cout << j["/array/1"_json_pointer] << '\n'; // writing access // change the string j["/string"_json_pointer] = "bar"; // output the changed string std::cout << j["string"] << '\n'; // "change" a nonexisting object entry j["/boolean"_json_pointer] = true; // output the changed object std::cout << j << '\n'; // change an array element j["/array/1"_json_pointer] = 21; // "change" an array element with nonexisting index j["/array/4"_json_pointer] = 44; // output the changed array std::cout << j["array"] << '\n'; // "change" the array element past the end j["/array/-"_json_pointer] = 55; // output the changed array std::cout << j["array"] << '\n'; } ``` Output: ``` 1 "foo" [1,2] 2 "bar" {"array":[1,2],"boolean":true,"number":1,"string":"bar"} [1,21,null,null,44] [1,21,null,null,44,55] ``` Example: (4) access specified element via JSON Pointer (const) The example below shows how values can be read using JSON Pointers. ``` #include #include using json = nlohmann::json; using namespace nlohmann::literals; int main() { // create a JSON value const json j = { {"number", 1}, {"string", "foo"}, {"array", {1, 2}} }; // read-only access // output element with JSON pointer "/number" std::cout << j["/number"_json_pointer] << '\n'; // output element with JSON pointer "/string" std::cout << j["/string"_json_pointer] << '\n'; // output element with JSON pointer "/array" std::cout << j["/array"_json_pointer] << '\n'; // output element with JSON pointer "/array/1" std::cout << j["/array/1"_json_pointer] << '\n'; } ``` Output: ``` 1 "foo" [1,2] 2 ``` ## See also - documentation on [unchecked access](https://json.nlohmann.me/features/element_access/unchecked_access/index.md) - documentation on [runtime assertions](https://json.nlohmann.me/features/assertions/index.md) - see [`at`](https://json.nlohmann.me/api/basic_json/at/index.md) for access by reference with range checking - see [`value`](https://json.nlohmann.me/api/basic_json/value/index.md) for access with default value ## Version history 1. Added in version 1.0.0. 1. Added in version 1.0.0. Added overloads for `T* key` in version 1.1.0. Removed overloads for `T* key` (replaced by 3) in version 3.11.0. 1. Added in version 3.11.0. 1. Added in version 2.0.0.