* 📡 Fix documentation gaps found in a full GitHub Discussions review Reviewed all 1008 GitHub Discussions (2020-2026) for recurring questions that better or more visible documentation would have avoided. Adds/expands documentation for ~26 distinct gaps, including: - New "Debugging" page collecting natvis, GDB pretty printer, LLDB status, and JSON_DIAGNOSTICS pointers (previously scattered/undiscoverable) - Thread-safety and schema-validation FAQ entries - StringType's char-based requirement (no wstring/u16string/u32string) - Brace-initialization-yields-arrays warning directly on the constructor reference page (previously only in the FAQ, missed by users reading the constructor docs) - std::any exclusion from get<T>(), with a manual-dispatch example - Non-string-keyed std::map serializing as an array of pairs - ordered_json compatibility with NLOHMANN_DEFINE_TYPE_* macros (already worked, was undocumented) - std::array truncation on size-mismatched conversion (no exception) - static_cast vs. get<std::optional<T>>() divergence - Recipe for omitting a std::optional field instead of emitting null - No built-in nesting-depth limit during parsing + a callback-based workaround recipe - Recipe for streaming a large homogeneous array via parser callbacks - operator>> stream-position semantics for concatenated JSON values - JSON Pointer array-vs-object creation rule for non-existing paths - CMake target name (nlohmann_json_modules) needed to link C++20 modules - ESP-IDF/PlatformIO: no official package, link to a community fork - get(key, default) as the Python dict.get() equivalent - reserve() recipe for pre-allocating array capacity - JSONC as an alias for the existing ignore_comments/ignore_trailing_commas combination (distinct from the unsupported JSON5) - items() dereferenced-element type: decltype() idiom + detail-namespace stability caveat - Various macro/type-conversion limitations (MSGPACK_DEFINE_ARRAY equivalent, char-array round-tripping, ADL serializer macro gap) Signed-off-by: Niels Lohmann <mail@nlohmann.me> * 🚶 fix format Signed-off-by: Niels Lohmann <mail@nlohmann.me> --------- Signed-off-by: Niels Lohmann <mail@nlohmann.me>
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Parser Callbacks
Overview
With a parser callback function, the result of parsing a JSON text can be influenced. When passed to parse, it is
called on certain events (passed as parse_event_t via parameter event) with a set recursion depth depth and
context JSON value parsed. The return value of the callback function is a boolean indicating whether the element that
emitted the callback shall be kept or not.
The type of the callback function is:
template<typename BasicJsonType>
using parser_callback_t =
std::function<bool(int depth, parse_event_t event, BasicJsonType& parsed)>;
Callback event types
We distinguish six scenarios (determined by the event type) in which the callback function can be called. The following
table describes the values of the parameters depth, event, and parsed.
parameter event |
description | parameter depth |
parameter parsed |
|---|---|---|---|
parse_event_t::object_start |
the parser read { and started to process a JSON object |
depth of the parent of the JSON object | a JSON value with type discarded |
parse_event_t::key |
the parser read a key of a value in an object | depth of the currently parsed JSON object | a JSON string containing the key |
parse_event_t::object_end |
the parser read } and finished processing a JSON object |
depth of the parent of the JSON object | the parsed JSON object |
parse_event_t::array_start |
the parser read [ and started to process a JSON array |
depth of the parent of the JSON array | a JSON value with type discarded |
parse_event_t::array_end |
the parser read ] and finished processing a JSON array |
depth of the parent of the JSON array | the parsed JSON array |
parse_event_t::value |
the parser finished reading a JSON value | depth of the value | the parsed JSON value |
??? example
When parsing the following JSON text,
```json
{
"name": "Berlin",
"location": [
52.519444,
13.406667
]
}
```
these calls are made to the callback function:
| event | depth | parsed |
| -------------- | ----- | ------ |
| `object_start` | 0 | *discarded* |
| `key` | 1 | `#!json "name"` |
| `value` | 1 | `#!json "Berlin"` |
| `key` | 1 | `#!json "location"` |
| `array_start` | 1 | *discarded* |
| `value` | 2 | `#!json 52.519444` |
| `value` | 2 | `#!json 13.406667` |
| `array_end` | 1 | `#!json [52.519444,13.406667]` |
| `object_end` | 0 | `#!json {"location":[52.519444,13.406667],"name":"Berlin"}` |
!!! note "No built-in nesting depth limit"
The library has no built-in limit on recursion/nesting depth while parsing. A parser callback can only
*discard* content it has already parsed (by returning `#!c false`); it cannot make parsing fail once a
nesting limit is exceeded partway through reading a deeply nested value. If you need to reject over-deep
untrusted input outright, track `depth` in a callback and `throw` from it once your limit is exceeded (a
thrown exception propagates out of `parse()` as usual).
Return value
Discarding a value (i.e., returning #!c false) has different effects depending on the context in which the function
was called:
- Discarded values in structured types are skipped. That is, the parser will behave as if the discarded value was never read.
- In case a value outside a structured type is skipped, it is replaced with
#!json null. This case happens if the top-level element is skipped.
??? example
The example below demonstrates the `parse()` function with and without callback function.
```cpp
--8<-- "examples/parse__string__parser_callback_t.cpp"
```
Output:
```json
--8<-- "examples/parse__string__parser_callback_t.output"
```
Recipe: rejecting duplicate object keys
The JSON specification leaves the handling of objects with repeated keys up to the implementation. As described in
object_t, it is unspecified which value for a repeated key ends up in
the resulting #!c json value -- once parsing has produced that value, the duplicate is already gone, because object
storage maps each key to a single value. If duplicate keys should instead be treated as an error, a parser callback
can detect them while the object is still being read, before that ambiguity ever applies.
??? example
```cpp
--8<-- "examples/reject_duplicate_keys.cpp"
```
Output:
```json
--8<-- "examples/reject_duplicate_keys.output"
```
This approach has two limitations:
- The depth-indexed bookkeeping must account for the fact that
object_startreports the depth of the parent of the object, while thekeyevents inside that object are reported one depth deeper (see the event table above); it is easy to get this off by one for nested objects. - The thrown exception cannot carry a
parse_error-style byte offset, because position tracking only exists inside the parser and lexer, not at the callback layer.
For strict validation with precise error positions, implementing a SAX interface instead gives access to the parser's position information directly.
Recipe: streaming a large homogeneous array
A common use case is a huge top-level array of many similarly-shaped objects, too large to hold entirely in
memory as a #!c json value. A parser callback can hand off each completed element to a user function and then
discard it, so memory usage stays bounded by a single element (plus the not-yet-parsed tail of the input) rather
than the whole document. Since the top-level array's array_start/array_end are reported at depth == 0 (its
parent is the document root), the object elements it contains are reported at depth == 1:
??? example
```cpp
std::ifstream input("large_array.json");
auto callback = [](int depth, json::parse_event_t event, json& parsed) -> bool {
if (depth == 1 && event == json::parse_event_t::object_end) {
handle_element(parsed); // process the element, e.g. write it elsewhere
return false; // discard it -- frees its memory before the next one is parsed
}
return true; // keep everything else, including the (by then empty) top-level array
};
json::parse(input, callback);
```
If the array's elements are scalars or nested arrays instead of objects, check for parse_event_t::value or
parse_event_t::array_end at depth == 1 instead. The same approach works for a top-level object of many
homogeneous values by checking object_end/value events at depth == 1 there too.
Recipe: max nesting depth via a callback
Since there is no built-in nesting-depth limit (see the note above), a callback can enforce one manually by
tracking the maximum depth seen and throwing once it is exceeded:
??? example
```cpp
constexpr int max_depth = 32;
auto callback = [](int depth, json::parse_event_t /*event*/, json& /*parsed*/) -> bool {
if (depth > max_depth) {
throw std::runtime_error("maximum nesting depth exceeded");
}
return true;
};
json::parse(input, callback);
```